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THE
ANATOMY
OF THE
HUmAM BODY.
BY J. CRUVEILHIER,
n07X8S0B OF ANATOMY TO THE FACULTY OF MEDICINE OF PARIS, PHYSICIAN TO THE HOSPITAL Of
8ALPETBIEBE, AND PRESIDENT OF THE ANATOMICAL SOCIETY OF PARIS.
THE FIRST AMERICAN, FROM THP USJ" .^ARIS EDITION.
Edited by
GRANVILLE SHARP PATTISON, M.D.,
VK07ESSOR OF ANATOMY IN THE UNIVEItSITY OF NEW-YORK, MEMBER OF THE MEDIC0-CHIRUR0IC4I
SOCIETY OF LONDON, OF THE WARNF.RIAN SOCIETY OF NATURAL HISTORY OF EDINBURGH, OF
THE SOCIETE MEDICALS D'EMULATION, AND SOCIETE PHILOMATIQUE OF PARIS.
THIRD EDITION.
NEW-YORK:
HARPER & BROTHERS, PUBLISHERS
329 & 331 PEARL STREET,
FRANKLIN SQUARE.
1853.
1\
Entered, according to Act of Congress, in the year 1844, by
Harper & Brothers,
In the Clerk's Office of the Southern District of New-TC ork
» .
EDITOR'S PREFACE.
Numerous and excellent as the works on Anatomy are which have
lately been reprinted in this country, still they are, all of them, so de-
cidedly inferior to the " Svstem op Anatomy by Cruveilhier," that
the editor feels it unnecessary to offer any apology for having under-
taken its republication. Occupying, however, as he does the Chair of
Anatomy in the Metropolitan University of the United States, the pro-
fession may perhaps think that it would have been more becoming of
him to have published a System of Anatomy of his own, rather than to
have undertaken the humble office of editing the work of a European
anatomist.
The reasons which have influenced him in the course he has pur-
sued are the following :
The science of Anatomy, viewed abstractly, and without reference
to its connexion with Physiology, Pathology, and the Practice of Med-
icine and Surgery, is to the student just commencing a very dry and
uninteresting study. Yet in this way it is generally taught in the
schools, each system being demonstrated separately, without refer-
ence to the others, or to the Physiological and Pathological facts which
its demonstrations tend to illustrate. The course followed by the
editor, as a teacher of Anatomy, as his numerous students are aware, is
very difierent. His great object has always been to endeavour to give
interest to every lesson, by making it not a mere lecture on Anatomy,
but a discourse illustrating Physiological and Pathological science, and
elucidating the principles which should guide the practitioner in the
practice of his profession.
For the editor to have prepared a mere system of Anatomy would
have been, in fact, merely to have undertaken the work of a compiler ;
originality was out of the question, and no industry nor effort could
have enabled him to have produced, on this plan, a better work tha^
the systems of Wilson, Quain, or the numerous other systematic trea-
tises on Anatomy which have already been published. The editor
having been a teacher of Anatomy for more than thirty years, from
his experience is fully aware of the vast importance to the successful
performance of his duties as an anatomical professor, of his being en-
abled to interest his pupils and to fix and enchain their attention, that he
is very unwilling to do anything which could have the effect of taking
from the intoi'(>Ht or diminishing the freshness of his lectures. To pub-
13430
IV EDITOR 8 PREFACE.
lish a system of Anatomy on the same plan as that adopted in his lec-
tures, he would, of necessity, require to imbody in it the same Phys-
iological, Pathological, and practical views with which they are illus-
trated ; and to have done so> he cannot doubt but that the interest of
his lectures would have been diminished, and that he would in future
have found it much more difficult to fix the attention of his pupils.
This consideration has decided him never to publish, so long as he is
engaged in the duties of teaching, an original work on Anatomy.
The system of Anatomy of Cruveilhier has recommended itself to
the editor for publication : First, on account of its decided superiority
to any other work on Anatomy which has ever been published ; and,
secondly, from its being prepared, in some measure, in accordance
with the plan which he follows in his lectures, many of its details be-
ing illustrated by Physiological and Pathological references.
In republishing the work, the editor has so restricted himself in the
performance of liis task that he feels it can neither add to nor take
from his reputation. He has merely furnished to the members of the
profession in the United States The System of Anatomy op Cru-
veilhier. Several reasons have influenced him in being sparing in
the introduction of notes or additional matter. First. The work is in
itself so perfect as not to require them. Secondly. It is very volumi-
nous, and to have increased its size would have been to have diminish-
ed its value. Thirdly. The editor has ever thought that an inde-
pendent mind will shrink from mixing up and incorporating his
thoughts with those of another. If a man wishes to obtain reputation
as an author, let him publish an original work, and not attempt to gain
popularity by illustrating and enlarging the labours of another.
Since the English edition of Cruveilhier has been published in Lon-
don, the first and second volumes of a second edition of the work have
been published by the author in Paris. The editor has carefully com-
pared the second edition with the fi»st, so far as it has been published,
and has incorporated in the American edition whatever he thought
could increase its value. He has, however, only followed the second
edition when he thought that the changes introduced were improve-
ments. In many instances, with the view of keeping down the size o^
the book, he has condensed into a few short paragraphs the substance
of several pages. In the department of Myology the author has in
his second edition made very numerous alterations from the first. As
these, in the opinion of the editor, have rather diminished than in-
creased the value of the work, he has only in a very few instances adopt-
ed them. The student, he feels satisfied, will find the description of the
muscles sufficiently minute. The subdivisions introduced, and the
minutiae which are added to their descriptions in the second edition.
EDITOR :> l'Rt:rACF
would tend rather to embarrass than to piuiuure their improvement;
he has, therefore, very generally preferred to follow the first edition
in the description of the muscles.
In the original work there are no engravings ; this is a great desidera-
tum, which has been removed in the English edition by the introduc-
tion of numerous woodcuts, selected with care from the best anatomi-
cal engravings, and marked with letters of reference. This greatly
enhances the value of the work. The translation, which is an excel-
lent one, was made by Dr. Madden.
Systems of Anatomy generally offer little interest except to the
anatomical student. This cannot be said of the system of Anatomy of
Cruveilhier. It imbodies a fund of information, in connexion with
Physiology and Pathology, which will, in the opinion of the editor, pro-
cure for it a place in the library of every physician and surgeon who
feels any interest in his profession. If the members of the profession
only procure the book and peruse it, he cannot doubt but that the
cause of Anatomical science will be greatly promoted in the United
States ; and should this be the case, the editor will be amply repaid for
any trouble he may have had in undertaking the republication of Cru-
veilhier.
University of New-York, Sept. Ist, l^A^.
k
AUTHOR'S PREFACE.
The study of man offers three very different objects for contemplation ; viz., his or-
ganization, his vital functions, and his moral and intellectual faculties.
The organization or structure of man is the object of anatomy, a science which in-
vestigates every distinguishable material condition of the different parts that enter into
the construction of his frame. Anatomy is a science of observation, and is, in this re-
spect, susceptible of mathematical precision and physical certainty.
The vital functions of man are the objects of physiology, which reveals to us the ac-
tions of organs, with whose structure anatomy has previously made us acquainted. The
science of physiology inquires into the various motions that occur within the human
body, just as anatomy investigates the form of its component parts. All that we know,
in fact, concerning material objects, may be resolved into a knowledge of their motions
and their forms.
As a moral and intellectual being, man is the object of the science of psychology,
which contemplates him in the exercise of thought and volition, analyzes the operations
of his mind and will, and classifies them according to their supremacy.
A perfect acquaintance with man necessarily presupposes a combination of all that is
taught by these three sciences ; and it is because his anatomy, his physiology, and his
moral and intellectual endowments have not been studied by the same class of philoso-
phers, that in the sciences relating to himself so much yet remains to be desired.
Anatomy — the immediate object of this work — constitutes the foundation of medicine.
In order to discover the precise seat of a defect in some complicated machine, and the
means to be adopted for the reparation of its disordered mechanism, it is necessary to
be acquainted with the relative importance, and the particular action of all its constitu-
ent parts. " The human body," says Bacon, " may be compared, from its complex and
delicate organization, to a musical instrument of the most perfect construction, but ex-
ceedingly liable to derangement." And the whole science of medicine is therefore re-
duced to a knowledge of the means by which that harmonious instrument, the human
frame, may be so tuned and touched as to yield correct and pleasing sounds.
But since anatomy forms, as it were, the vestibule of medical science, it is of im-
portance that he who is entering upon its pursuit should fully understand the path he is
about to tread ; it is necessary, therefore, to assign, on the one hand, the rank which
medicine holds as a natural science, and, on the other, the position of anatomy among
the various sciences relating to medicine.
The term science, according to the admirable definition of the Roman orator, signifies
certain knowledge, deduced from certain principles — cognitio certa ex principiis certis ex-
orta. Sciences are divided into the metaphysical, the mathematical, and the natural ; but
since the two former are not connected with our present subject, we shall direct atten-
tion to the natural sciences only.
The object of the natural sciences, or of physics, taken in its widest signification, is a
knowledge of the materials of which the universe is composed, and of the laws by which
they are governed. They are subdivided into the physical, and the physiological or zoo-
logical.
The physical sciences take into consideration all the phenomena presented by inor-
ganic bodies; they comprise, 1. Astronomy, which studies the heavenly bodies as they
revolve in space, and estimates, by the aid of numbers, the laws by which their move-
ments are governed ; 2. Physics, properly so called, or the study of the properties of
matter in general ; in aid of which, experiments are performed in order to exhibit phe-
nomena in every possible light, and calculation is employed to render fruitful the results
of experiment ; 3. Geology, or that science which studies the surface of the globe, and
the successive strata which are met with in its interior ; which goes back far beyond all
historical traditions, brings to light, as it were, the very depths of the earth, and traces,
with a sure hand, the history of the globe, and the various revolutions it has undergone ;
4. Chemistry, which consists in the study of the reciprocal actions of bodies, when re-
duced to their atomic condition.
The zoological or physiological sciences embrace all the phenomena presented by living
bodies. The science of botany examines into the structure and functions of plants ; but
zoology, properly so called, investigates the organization and the life of animals. The
examination into structure or organization constitutes anatomy. Physiology embraces
the study of functions or of life.
The facts presented to us in the zoological are of a totally different character from
those comprised in the physical sciences, Inorganic bodies, in fact, are governed by
constant and immutable laws, acting in perfect harmony with each other ; but living
bodies are subject not only to physical, but also to vital laws, the latter of which are
constantly struggling against the former. This struggle constitutes life ; death is the
triumph of the physical over the vital laws. In consequence, however, of this continual
strife, derangements of structure and disordered functions very often occur ; and these
become more frequent and more complicated, in proportion as the organization is more
highly developed, and the animal more elevated in the scale of creation.
A knowledge of these derangements and of the proper means for restoring both or
vui author's preface.
ganization and life to a healthy condition, constitutes the science of medicine ; and the
station which I have just assigned to this most important branch of zoological science
will prove, better than any arguments, that the study of the physiological or healthy
state of organization and of life should precede that of their pathological or diseased
conditions ; and that anatomy forms the first link in the chain of medical science.
Each science has its own methods of investigation, and its peculiar elements of cer-
tainty. Metaphysics and moral philosophy have a metaphysical and moral certainty.
The mathematical sciences set out from a small number of self-evident propositions or
axioms founded upon the nature of things, proceed gradually from the known to the un-
known, and trust to problems already demonstrated as to so many axioms, by means of
which, as steps, they again ascend towards new truths. The natural sciences, again,
are founded upon observation, and observation is merely the evidence of our senses ;
hence arises the necessity of exercising them, in order to increase their acuteness and
their activity. Facts, therefore, constitute the elements of the natural sciences ; and
then reasoning follows, founded upon those facts and upon analogy. It would be absurd
to study the natural sciences after the same method as metaphysics.
It may readily be understood, that as the purely physical sciences are based upon con-
stant phenomena, mathematics are directly applicable to them, and hence they are termed
physico-mathematical sciences; but in the zoological sciences, effects are continually
varying, according to their causes. Any attempts, therefore, to apply the art of numbers
to the elements of medicine, would be to imitate the philosopher, Condorcet, who enter-
tained the whimsical notion of subjecting moral probabilities to the test of mathematical
precision ; who was anxious to substitute a-\-b for either oral or written legal testimony ;
who admitted half proofs and fractional proofs, and then reduced them to equations, by
means of which he supposed he could arrive at arithmetical decisions, regarding the
lives, the fortunes, and the characters of his fellow-men.
It must, however, be reluctantly confessed, that we can acquire a knowledge only of
the surfaces of a body ; and that to say we are acquainted with its texture, is to state,
in other words, that we have a knowledge of the smallest surfaces comprised within its
general surface. Sight, touch, &c., the only means of investigation by which we can
appreciate the qualities of matter in general, can recognise nothing but surfaces, appear-
ances, and relative properties. Absolute properties they are unable to detect. With our
organization, we shall never know of what material objects essentially consist, but only
what they are in relation to ourselves.
This work being essentially of an elementary nature, and in some measure adapted
for the lecture-room, I have endeavoured to confine myself within narrow limits, and
strictly to avoid all considerations which are not inunediately connected with the anato-
my of organs. At the same time I have not forgotten that this work was intended for
the student of medicine, and not for the naturalist ; I have, therefore, been induced, in
the following pages, if not expressly to indicate, at least to direct attention to the more
immediate applications of anatomy to physiology, surgery, and medicine.
The objects which I have constantly had in view have been to exhibit the actual state
of the science of anatomy ; to present its numerous facts in their most natural order ;
to describe each fact clearly, precisely, and methodically ; to adopt such a method as
would form an easy guide to the student, and not involve him in confusion ; and, lastly,
to give to each detail its peculiar value, by invariably directing particular attention to
the more important points, instead of confounding them with matters of less consequence,
in an indigested and monotonous enumeration of facts.
The following is the order in which the principal divisions of the subject have been
treated.
The first division comprises Osteology, Arthrology or Syndesmology, and Odontology.
1. Osteology, which, notwithstanding the great number of works on the subject, seema
always to offer some new facts to those who study it with zeal, has been treated with
the attention it deserves, as forming the basis of anatomical knowledge. An account
of the development of the osseous system has appeared to me necessary for the comple-
tion of its history. I have therefore considered the following points in connexion with
the development of each bone : the number of ossific points ; the time of appearance of
the primitive and complementary ossific points ; the periods at which the several points
unite, and the changes occurring in the bone subsequently to its growth. By adopting
this method, the most complicated ossifications are reduced to a few propositions easily
retained in the memory.
The inconvenience arising from including in a description of the bones all the attach-
ments of the muscles, and nearly the whole anatomy of the part, is so totally at variance
with a methodical arrangement of facts, that it is unnecessary to offer an apology for the
changes made in this respect. Occasionally, however, I have mentioned those muscu-
lar attachments which might serve to characterize the osseous surfaces on which they
are situated.
2. Under the title of Syndesmology, or Arthrology, are united all the articulations of
the human body. Assummg as the only basis of classification the form of the articula-
ted surfaces, which is always in aocordanoc with the means of union and tlic movements
of tlie joint. I have bnen iu'liieofl tn mo lify thi- division.'^ nsuallv adopted. Tlic runilt'Li-
AUTHOR S PREFACE. IX
throsis, or comyloid arliculaium, and the articulation by mutiial reception, form quite as
natural genera as the enarthrosis and the arthrodia. It will, perhaps, be found that the
characters of the different kinds of articulation, and in particular those of the anpxlar
ginglymus, which I have called the trochlear articulation, and those of the lateral gingly-
mus, or the trochoid articulation of the ancients, are more clearly defined than in other
anatomical works.
The mechanism, t. e., the movements of a joint, is so intimately connected with its
anatomy, that it was impossible to pass it over in silence ; on the other hand, it was
sometimes difficult to determine the limit which ought to distinguish an anatomical from
a physiological treatise. I have endeavoured to avoid both extremes, by confining my-
self strictly to the mechanism of each joint in particular, referring to works on physiol-
ogy for the principal movements of locomotion, and of animal statics, such as waUiing,
running, standing, &c.
3. Odontology, or the description of the teeth, concludes the first division. I have ta-
ken care to point out that this juxtaposition of the bones and the teeth was founded upon
their common indestructibility, and not upon the identity of their nature ; the bones be-
ing organs composed of living tissues, while the hard portion of the teeth, on the other
hand, is but the solidified product of secretion.*
The second division includes Myology, Aponeurology, and Splanchnology.
1. In treating of Myology, I have preferred the topographical to the physiological ar-
rangement of the muscles, for this reason only, that it admits of all of them being studied
upon the same subject. To unite, as far as was practicable, the undoubted advantages
possessed by both methods, I have given, at the conclusion of myology, a general sketch
of the muscles, arranged according to their physiological relations ; and by grouping
them, not after their order of super-imposition, but according to their several actions, I
have arranged them around the articulations to which they may belong, and have point-
ed out the extensors, the flexors, &c.
A muscle being known when its attachments are ascertained, I have thought it advi-
sable to commence the description of each by a brief announcement of its origin and in-
sertion, as a sort of definition or summary. The particular details concerning its mode
of insertion, whether it be aponeurotic or fleshy, and concerning the direction of its fibres,
complete the description of each muscle considered by itself ; the history of which is
concluded by an examination of its relations to neighbouring parts, and of its uses. The
individual or combined action of the muscles, for the production of simple movements,
follows so naturally after their description, and presupposes so correct and positive a
knowledge of their anatomy, that it can be treated of with propriety only in a work on
anatomy. The compound movements necessary for the consecutive or simultaneous
action of a great number of muscles come within the province of physiology.
2. The aponeuroses, those important appendages of the muscular system, are separ-
ately noticed, in connexion with the muscles to which they belong ; but I have also de-
scribed them together under the head of Aponeurology. This combination of analogous
parts possesses the twofold advantage of simplifying the science, by enabling one part
to elucidate the structure of another, and of permitting us to discover the general laws
according to which these structures are disposed.
3. With some modification, I have adopted that old division of anatomy, which treats
of the viscera and organs, and which is known by the name of Splanchnology.
The brain and the organs of the senses, which were included in this division in all
anatomical works preceding those of Soemmering and Bichat, have been removed from
it, and described with the other portions of the nervous system. The description of the
heart, in like manner, will be found with that of the other organs of circulation. In
short, the old classification of the viscera, according to their locality, that is, into those
of the head, the neck, the chest, &c., has been replaced by a more physiological arrange-
ment. Splanchnology will therefore comprehend a description of the organs of digestion
and their appendages, of the organs of respiration (among which is included the larynx,
or the organ of voice), and, lastly, the genito-urinary organs.
To the inquiry why I have departed from the usual custom of placing splanchnology
at the end of anatomy, I reply that, in order to study, with advantage, the vessels and
the nerves, it is necessary to have a previous acquaintance with the organs to which
they are distributed.
The importance of the parts described in this division, and the practical results which
flow from even the most superficial knowledge of their forms, connexions, and intimate
structure, are at once my reason and excuse for extending, to so great a length, this
portion of the work ; and, moreover, it is necessary to state, that there are many medi-
cal practitioners who learn anatomy only from elementary works.
The third and the last division treats of the organs of circulation, viz., the heart, arter-
ies, veins, and lymphatics ; and of the sensory apparatus, viz., the organs of the senses,
the brain, and the nerves.
1 . No part of anatomy, perhaps, has been better known than the arteries, since the
appearance of Haller's admirable works ; I could neither have followed a better guide
nor a more perfect model.
* See n.ilr. n. 1S3.
u
X author's peeface.
2. The study of the vei?is has acquired an unexpected degree of importance, in conse-
quence of the works of various physicians on phlebitis ; and our knowledge of them has
been mucli extended by the researches of M. Dupuytren into the veins of the spine, and
the excellent plates of this order of vessels published by M. Breschet.
3. The study of the lymphatics has been almost abandoned since the very remarkable
publications of Mascagni : I have endeavoured to ascertain what credit was to be given
to the assertions of some modern writers concerning the frequent communication be-
tween the veins and the lyniphatics.
4. The work of Soemmering on the organs of the senses constitutes, perhaps, the high-
est title to fame possessed by that great anatomist ; and it might even be said that he
has left nothing for his successors to accomplish, did not the constant study of a science
of observation unceasingly proclaim this important truth, that it is in the power of no
man to declare, beyond this limit thou shalt not pass.
The brain and the nerves, to which so many able and laborious inquirers have lately
directed their attention, have been my favourite objects of investigation ; on account of
their importance, and perhaps, also, from the difficulties attending their study. Not sat-
isfied with simply tracing the nerves to the various organs in the body, I have studied
them in the interior of those organs, and have endeavoured to ascertain the precise
branches that are distributed to each particular part.
I may add, that, in order to facilitate the dissection of the nervous system, and, indeed,
of all the other parts of the body, I have presented, whenever it was necessary, a short
account of the best method of preparation.
With regard to the general spirit of this work, I have been anxious to render it clas-
sical ; and have avoided, most scrupulously, that species of induction and analogical rea-
soning, which, in a great measure, constitutes philosophical anatomy. To this kind of
anatomy I have never even introduced any allusions, except when its general ideas and
views (almost always ingenious, but usually bold and speculative) might elucidate our
own subjects.
All the descriptions have been made from actual dissections. It was only after hav-
ing completed from nature the account of each organ that I consulted writers, whose
imposing authority could then no longer confine my thoughts, but always excited me to
renewed investigations wherever any discrepancy existed.
Anatomy being, as already stated, the basis of medical science, we should greatly
misapprehend its nature did we not consider it the chief of the accessory sciences of
medicine.
Without it, the physiologist rears his structure upon sand ; for physiology is nothing
more than the interpretation of anatomy. It is anatomy that guides the eye and the
hand of the surgeon ; that inspires him with that ready confidence, which leads him to
search among structures, whose lesion would be dangerous or mortal, for some vessel
that must be tied, or for a tumour which must be extirpated. Nor is it less indispensa-
ble to the physician, to whom it reveals the seat of diseases, and the changes of form,
size, relation, and texture, which the affected organs have undergone.
Anatomy is, moreover, the science which, of all others, excites the greatest curiosity.
If the mineralogist and the botanist are so eager, the one to determine the nature of a
stone, the other to ascertain the characters of a flower ; if the love of their particular
science induces them to undertake the most dangerous voyages, in order to enrich it
with a new species, what ought to be our ardour in pursuing the study of man, that
masterpiece of creation, whose structure, possessed of both delicacy and strength, ex-
hibits so much harmony as a whole, and displays so much perfection in its parts !
And while contemplating this marvellous organization, in which all has been provided
and prearranged with such intelligence and wisdom, that no single fibre can acquire the
slightest addition, or undergo the least diminution of power, without the equilibrium be-
ing destroyed and disorder being induced — what anatomist is there who would not feel
tempted to exclaim, with Galen, that a work on anatomy is the most beautiful hymn
which man can chant in honour of his Creator !*
May this work inspire among students an ever-increasing ardour for the study of the
organization of man, which, even if it were not the most eminently useful, would still
be the most interesting, and the most beautiful of all the sciences. And what more
powerful motive for emulation can present itself to a generous mind, than the idea,
"that every acquisition of knowledge is a conquest achieved for the relief of suffering
humanity !" Let it never be forgotten that, without anatomy, there is no physiology, no
surgery, no medicine ; that, in a word, all the medical sciences are grafted upon anato-
my as upon a stock ; and that the deeper its roots descend, the more vigorous will be
its branches, and the more abundantly laden with flowers and with fruit.
I must here express my acknowledgments to M. Chassaignac, the anatomical assist-
ant to the Faculty, who has distinguished himself in several concours, and who has as-
sisted me with the greatest zeal in the execution of this work.
* " Sacrum sermonem quem ego Conditoris nostri verum hyranum compono, existimoque in hoc veram esse
pietatem, non si tauroruni hecatombas ei sacrificaverim. et casias, aliaque sexcenta odoramenta ac unguenta
suffumigaverim, sod si noverini ipse primus, deiude ct aliis exposuerim quffinam sit ipsius sapicntia.quce virtus.
ciUii! bomtas."— (Galen, De usu part., lib iii.)
CONTENTS.
INTRODUCTION.
Object and Division of Anatomy. — General View of the Human Frame. — Apparatus of Sensation— of lo-
comotion—of Nutrition— of Reproduction. — General Plan of tlie Worli Page 1
APPARATUS OF LOCOMOTION.
OSTEOLOGY.
Of the Bones in Oeneral.
The Bones— Importance of their Study.— General View of the Skeleton. — Number of the Bones.— Method
of Description.— Nomenclature.— Situation in general.— Direction.— Size, Weight, and Density of Bones.
— Figure. — Distinction into long, broad, and flat Bones. — Regions of Bones. — Eminences and Cavities. —
Internal Conformation. — Texture. — Development, or Osteogeny.— Nutrition 5
The Vertebral Column.
General Characters of the Vertebrse. — Characters peculiar to the Vertebrse of each Region. — Characters
proper to certain Vertebrae. — Vertebree of the Sacro-coccygeal Region. — The Vertebral Column in general.
— Development 18
The Scull.
Composed of the Cranium and Face. — Cranial Bones — Occipital — Frontal — Sphenoid — CEthmoid — Parietal
— Temporal. — The Cranium in general. — Development. — Bones of the Face— Superior Maxillary. — Palate.
— Malar. — Nasal. — Lachrymal — Inferior turbinated. — Vomer— Inferior Maxillary. — The Face in general.
— Cavities. — Development 33
The Thorax, or Chest.
The Sternum.— Ribs.— Costal Cartilages.— The Thorax in general.— Development 64
The Superior, or Thoracic Extremities.
The Shoulder.— Clavicle.— Scapula.— The Shoulder in general.— Development.— Humerus.— Ulna.— Radius.
—The Hand— The Carpus and Carpal Bones.— The Metacarpus and Metacarpal Bones.— The Fingers.—
General Development of the Superior Extremities 73
The Inferior, or .Abdominal Extremities.
The Haunch.— Os Coxse.— The Pelvis.— Development.— Femur.— Patella.— Tibia.— Fibula.— The Foot.—
The Tarsus and Tarsal Bones. — The Metatarsus and Metatarsal Bones.— The Toes. — Development of the
Lower ExUemities. — Comparison of the Upper and Lower Extremities. — Os Hyoides . . . .87
The .Articulations, or Arthrology.
General Observations. — Articular Cartilages. — Ligaments. — Synovial Membranes. — Classification of the
Joints,— Diarthroses. — Synarthroses. — Amphiarthroses, or Symphyses Ill
.Articulations of the Vertebral Column.
Articulations of the Vertebra with each other. — Those peculiar to certain Vertebra;. — Sacro-vertebral. Sa-
cro-coccygeal, and Coccygeal Articulations. — Articulations of the Cranium— of the Face — of the Tho-
rax 115
Articulations of the Superior or Thoracic Extremities.
Articulations of the Shoulder. — Scapulo-humeral. — Humero-cubital. — Radio-cubital. — Radio-carpal. — Of
the Carpus and Metacarpus. — Of the Fingers 135
Articulations of the Inferior or Abdominal Extremities.
Articulations of the Pelvis.— Coxo-femoral. — Knee-joint.— Peroneo-tibial. — Ankle-joint.— Of the Tarsus.—
Tarso-metatarsal. — Of the Toes 154
ODONTOLOGY.
Circumstances in which the Teeth differ from Bones. — Number. — Position.— External Conformation.— Gen-
eral Characters. — Classification— Incisor — Canine— Molar.— Structure. — Development . . . .177
MYOLOGY.
The Muscles in general. — Nomenclature. — Number. — Volume and Substance. — Figure. — Dissection. — Rela-
tions.— Attachments. — Structure. — Uses. — Preparation. — Order of Description . . . .190
Muscles of the Posterior Region of the TVunk.
The Trapezius.— Latissimus Dorsi and Teres Major.— Rhomboideus. — Levator Anguli Scapula.- Serrati ,
Postici. — Splenius. — Posterior Spinal Muscles. — Complexus. — Inter-spinales Colli. — Recti Capitis Postici, |
Major et Minor. — Obliqui Capitis, Major et Minor. — General View and Action of the Posterior Spinal
Muscles 198
Muscles of the Anterior Abdominal Region.
The Obliquus Externus Abdominis. — Obliquuslntemus and Cremaster. — Transversalis Abdominis. — Rectus
Abdominis.— Pyramidalis 208
Diaphragmatic Region 212
Lumbar Region.
The Psoas and lUacus. — Psoas Parvus. — Ciuadratus Lumborum . . 214 ^
Lateral Vertebral Region.
Tholnter-transversales and Rectus Capitis Lateralis.— Scaleni .217
#
XU CONTENTS.
Deep Anterior Cervical, or Prevertebral, Region.
The Recti Capitis Antici, Major et Minor.— Longus Colli.— Action of these Muscles . . . Page 318
Thoracic Region.
The Pectoralis Major.— Pectoralis Minor.— Sub-clavius.—Serratus Magnus. — Intercostalei.— Supra-costales.
— Infra-costales. — Triangularis Sterni 220
Superficial Anterior Cervical Region.
The Platysma Myoides. — Sterno-cleido-itiastoideus 234
Muscles of the Infra-hyoid Region.
The Sterno-hyoideus. — Scapulo- or Omo-hyoideus. — Sterno-thyroideus. — Thyrohyoideus . . . 5^
Muscles of the Supra-hyoid Region.
The Digastricus — Stylo-hyoideus. — Mylo-hyoideus. — Genio-hyoideus.— Their Action .... 228
Muscles of the Cranial Region.
Occipito-frontalis. — Auricular Muscles 230
Muscles of the Palpebral Region.
Orbicularis Palpebrarum. — Superciliaris. — Levator Palpebrae Superioris .... . . 231
JVasal Region.
The Pjramidalis Nasi.— Levator Labii Superioris Alaeque Nasi.— TransTersalis, or Triangularis Nasi^— De
pressor Alie Nasi. — N^so-labialis 233
Muscles of the Labial Region.
The Orbicularis Oris. — Buccinator. — Levator Labii Superioris. — Caninus. — Zygontatici, Major et Minor.
Triangularis. — Quadratus Menti. — Levator Labii Superioris. — Movements of the Lips and those of the
Face 234
Muscles of the Temporo-maxillary Region.
The Masseter and Temporalis 339
The Pterygo-maxillary Region.
The Pterygoideiu Intemus. — The Pterygoideus Kxternus 240
Muscles of the Shoulder.
The Deltoideus. — Supraspinatus. — Infra-spinatug and Teres Minor. — Sub-scapularis .... 341
Muscles of the Arm.
The Biceps. — Brachialis Anticus. — Coraco-brachialis. — ^Triceps Extensor Cubiti 244
Muscles of the Forearm 349
Muscles of the Hand.
The Abductor Brevis Pollicis. — Opponens Pollicis. — Flexor Brevis Pollicis. — Adductor PoIIicis. — Palmaris
Brevis. — Abductor Digit! Minimi. — Flexor Brevis Digiti Minimi. — Opponens Digiti Minimi. — ^The Interos-
seous Muscles, Dorsal and Palmar 260
Muscles of the Pelvis.
The GIutsBi Maximus, Medius, et Minimus. — Pyriformis. — Obturator Intemus. — Gemelli, Superior et Inferior.
^^iuadratus Femoris. — Obturator Extern us. — Action of these Muscles 364
Muscles of the Thigh.
The Biceps Cruris. — Semi-tendinosus. — Semi-membranosus. — Tensor Vagina Femoris. — Sartorius. — Triceps
Extensor Cruris. — Gracilis. — Adductor Muscles of the Thigh 369
Muscles of the Leg.
The Tibialis Anticus. — The Extensor Communis Digitorum. — Extensor Proprius Pollicis. — Peronei Longus
et Brevis. — Gastrocnemius, Plantaris and Solaris. — Popliteus. — Tibialis Posticus. — Flexor Longus Pol-
licis 377
Muscles of the Fbot.
The Extensor Brevis Digitorum. — Abductor Pollicis Pedis. — Flexor Brevis Pollicis Pedis. — Adductor Pollicis
Pedis. — Transveisus Pollicis Pedis. — Abductor Digiti Minimi.— Flexor Brevis Digiti Minimi. — Flexor Bre-
vis Digitorum. — Flexor Accessorius. — Lumbricales. — Interossei 386
APONEUROLOGY.
Geaeral Observations on the Aponeuroses. — Structure. — Uses 294
Particular Aponeuroses.
Superficial Fascia. — Aponeuroses of the Cranium — of the Face — of the Neck — of the Thorax — of the Abdo-
men—of the Pelvis — of the Thigh, Leg, and Foot — of the Shoulder, Arm, Forearm, and Hand . . 397
SPLANCHNOLOGY.
General Observations on the Viscera.— External Conformation.- tructure.— Development.— Functions.—
Dissection 330
Tbk Qsgans of Digestion and theik Aitendages.
Alimentary or Digestive Canal.
General Observations. — Division. — Mouth and its Appendages. — Lips.— Cheeks. — Hard and soft Palate. —
Tonsils. — Tongue. — Salivary Glands. — Buccal Mucous Membrane. — Pharynx. — CEsophagus. — Stomach. —
Small Intestine. — Large Intestine. — Muscles of the Perineum. — Development of the Intestinal Canal . 333
Appendages of the Alimentary Canal.
Tlie Liver and its Excretory Apparatus.— The Pancreas. — ^The Spleen 384
The Organs of Respiration
General Observations.— The Lungs and Pleura;.— The Trachea and Bronchi.— Development of the Lungs.
—The Larynx— its Structure, Development, and Functions.— The Thyroid Gland .... 409
CONTENTS. XUl
The Genito-Urinaey Organs.
Tlie Urinary Organs.
DiTiskw.— The Kidneys and Ureters.— The Bladder.— The Supra-renal Capsnles . . . Page 435
The Generative Organs.
The Oenerative Organs of the Male.
The Testicles and their Coverings.— The Epididymis, the Vasa Deferentia, and Vealcalsi Seminallte.— The
Penis.— The Urethra.— The Prostate and Cowper's Glands 446
The Generative Organs of the Female.
The Ovaries.- The FalloiMan Tubes.— The Uterus.— The Vagina.— The Urethra.— The Vulva . . 461
The Mammte.
Number.— Situation. — Size.— Form. — Structure.— Development 473
The Peritoneum.
The Sub-ombiUcal Portion. — The Supra-umbilical Portion.— General Description and Structure . . 479
ANGEIOLOGY.
Definition and Objects of Angeiology 479
The Heart.
General Description. — External and Internal Conformation. — Structure. — Development.— Functions. — The
Pericardium . 479
The Arteries.
Definition. — Nomenclature. — Origin. — Varieties. — Course. — Anastomoses. — Form and Relations. — Termina-
tion.— Structure. — Preparation 496
Description of the Arteries.
The Pulmonary Artery.
Preparation. — Description. — Relations. — Size. — Development 499
The Aorta.
Preparation.-Definition.— Situation. — Direction.— Size. — Division into the Arch of the Aorta, the Thoracic
Aorta, and the Abdominal Aorta 501
Collateral Branches of the Aorta.
Ehiumeration and Classification. — Arteries arising from the Aorta at its Origin, viz., the Coronary or Car-
diac.^Arteries arising from the Thoracic Aorta, viz., the Bronchial, the (Esophageal, the Intercostal.—
Arteries arising from the Abdominal Aorta, viz., the Lumbar, the Inferior Phrenic, the CcBliac Axis, in-
cluding the Coronary of the Stomach, the Hepatic, and the Splenic, the Superior Mesenteric, the Inferior
Mesenteric, the Spermatic, the Renal, and the Supra-renal or Capsular . . . . . .503
Arteries arising from the Arch of the Aorta.
Enumeration and Varieties. — The Common Carotids. — ^The External Carotid — the Superior Thyroid — the
Facial — the Lingual — the Occipital — the Posterior Auricular — the Parotid — the ascending Pharyngeal —
the Temporal — the Internal Maxillary. — ^The Internal Carotid— the Ophthalmic — the Cerebral Branches
of the Internal Carotid. — Summary of the Distribution of the Common Carotids. — Artery of the Upper
Extremity.— The Brachio-cephalic. — The Right and Left Sub-clavians— the Vertebral and its Cerebral
Branches, with Remarks on the Arteries of the Brain, Cerebellum, and Medulla — the Inferior Thyroid —
the Supra-scapular — the Posterior Scapular — the Internal Mammary — the deep Cervical — the Superior
Litercostal. — ^The Axillary — the Acromio-thoracic — the Long Thoracic — the Sub-scapular — the Posterior
Circumflex— the Anterior Circumflex. — ^The Brachial and its Collateral Branches. — The Radial, its Col-
lateral Branches, and the deep Palmar Arch. — The Ulnar, its Collateral Branches, and the Superficial
Palmar Arch. — General Remarks on the Arteries of the Upper Extremity 513
Arteries arising from the Termination of the Aorta.
Enumeration. — The Middle Sacral.— The Common Iliacs. — The Internal Iliac, or Hypogastric — ^the Umbil-
ical— the Vesical — the middle Haemorrhoidal — the Uterine — the Vaginal — the Obturator — the Ilio-lurabar
—the Lateral Sacral — the Glutsal — the Sciatic — the Internal Pudic. — Summary of the Distribution of
the Internal Iliac. — Artery of the Lower Extremity. — The External Iliac — the Epigastric— the Circumflex
Iliac. — The Femoral — the Superficial Epigastric — the External Pudic — the Muscular — the deep Femoral,
its Circumflex and Perforating Branches. — The Popliteal, and its Collateral Branches. — The Anterior
Tibial and the Dorsal Artery of the Foot. — The Tibio-peronenl — Peroneal — Posterior Tibial, and the In-
ternal and External Plantar. — Comparison between the Arteries of the Upper and Lower Extremities . 552
The Veins.
Definition.— The Venous System. — Origin of the Veins.— Course. — Anastomoses and Plexuses. — Varieties.
— Termiaation. — Valves. — Structure. — Preparation. — Method of Description 573
Description op the Veins.
The Pulmonary Veins
Preparation.— Description.— Relations.— Size.— Peculiarities 577
The Veins of the Heart.
The Great Coronaiy or Cardiac Vein.— The Small Cardiac Veins 577
The Superior, or Descending Vena Cava and its Branches,
The Superior Vena Cava. — The Brachio-cephalic Veins — the Inferior Thyroid — the Internal Mammary —
the Superior Phrenic, the Thymic, Pericardiac, and Mediastinal— the Vertebral. — ^The Jugular Veins, viz.,
the External — the Anterior — and the Internal. — The Encephalic Veins, and the Sinuses of the Diuu
Mater, viz., the Lateral — the Superior Longitudinal — the Straight — the Superior and Inferior Petrosal —
the Cavernous — the Coronary — and the Anterior and Posterior Occipital Sinuses — the Conflux of the
Sinuses.— The Branches of Origin of the Jugular Veins— the Facial— tlie Temporo-maxiilarv- the Pos-
k
XIT CONTENTS.
terior Auricular— the Occipital— the Lingual— the Pharyngeal— the Superior and Midcile ThsToid— the
Veins of the Dipioe. — Summary of the Distribution of the Veins of the Head. — The deep Veins of the
Upper Extremity — the Palmar, Radial, Ulnar, Brachial, and Axillary — the Sub-clavian. — The Superficial
Veins of the Upper Extremity — in the Hand — in the Forearm — at the Elbow— €uid in the Arm. — General
Remarks on these Superficial Veins Page 578
The Inferior, or Ascending Vena Cava and its Branches.
The Inferior Vena Cava — the Lumbar or Vertebro-lumbar Veins — the Renal — the Middle Supra-renal — the
Spermatic and Ovarian — the Inferior Phrenic. — The Portal System of Veins — the Branches of Origin of
tlie Vena Porta— the Vena Portae — the Hepatic Veins. — The Common liiacs — the Internal Iliac — the
Hemorrhoidal Veins and Plexuses — the Pelvic Veins and Plexuses in the Male and in the Female. — ^The
deep Veins of the Lower Extremity — the Plantar, Posterior Tibial, Peroneal, Dorsal, Anterior Tibial, and
Popliteal — the Femoral — the External Iliac. — The Superficial Veins of the Lower Extremity — the Inter-
nal Saphenous — the External Saphenous 596
The Veins of the Spine.
General Remarks. — The Superficial Veins of the Spine. — The Anterior Superficial Spinal Veins, viz., the
Greater Azygos — the Lesser Azygos — the Left Superior Vertebro-costals — the Right Vertebro-costals —
the Vertebro-lumbar — the Ilio-lurabar, and Middle and Lateral Sacral — the Anterior Superficial Spinal
Veins in the Neck. — The Posterior Superficial Spinal Veins. — The deep Spinal or Intra-spinal Veins —
the Anterior Longitudinal, and the Transverse Veins or Plexuses, and the Veins of the Vertebrte — the
Posterior and the Posterior and Lateral Transverse Veins or Plexuses — the Medullary Veins. — General
Remarks on the Veins of the Spine 605
The Lymphatic System.
Definition, History, and general View of the Lymphatic System. — Origin. — Course. — Termination and
Structure of the Lymphatic Vessels. — The Lymphatic Glands. — Preparation of the Lymphatic Vessels
and Glands 611
Description of the Lymphatic System.
The Thoracic Duct — the Right Thoracic Duct. — The Lymphatic System of the Lower Extremity — of t e
Pelvic and Lumbar Regions — of the Liver — of the Stomach, Spleen, and Pancreas— of the Intestines — of
the Thorax — of the Head — of the Cervical Regions — of the Upper Extremity and Upper Part of the
Trunk 620
NEUROLOGY.
The Organs of the Senses.
The Skin — its External Characters, Structure, and Appendages. — The Tongue considered as the Orgaa of
Taste. — The Organ of Smell — the Nose— the Pituitary Membrane. — The Organ of Sight — the Eyebrows
— the Eyelids — the Muscles of the Orbit — the Lachrymal Apparatus — the Globe of the Eye, its Mem-
branes and Humours — the Vessels and Nerves of the Eye. — The Organ of Hearing — the External Ear —
the Middle Ear or Tympanum — the Internal Ear or Labyrinth — the Nerves and Vessels of the Ear . 62fl
The Cerebro-spinal Axis.
General Observations 681
The Membranes of the Cerebro-spinal Axis.
General Remarks. — The Dura Mater — the Cranial Portion, its Structure and Uses— the Spinal Portion. —
The Arachnoid — its Cranial Portion — its Spinal Portion — the Sub-arachnoid Fluid — their Uses. — The Pia
Mater — its External Cerebral Portion 682
The Spinal Cord, and the Medulla Oblongata.
General View of the Cord — its Limits and Situation — the Ligamentum Denticulatum. — Size of the Spinal
Cord — Form, Directions, and Relations — the Cord in its Proper Membrane — the Proper Membrane, or
Neurilemma of the Cord — the Cord deprived of its Proper Membrane. — Internal Structure of the Cord —
Sections — Examination by means of Water, and when hardened in Alcohol — the Cavities or Ventricles
of the Cord. — ^The Medulla Oblongata — Situation — External Conformation — Anterior Surface, the Ante-
rior Pyramids and the Olivary Bodies — the Posterior Surface — the Lateral Surfaces — the Internal Struc-
ture— Sections — Examination by Dissection, and under Water. — Development of the Spinal Cord.— De-
velopment of the Medulla Oblongata. — Comparative Anatomy of the Spinal Cord. — Comparative Anatomy
of the Medulla Oblongata 693
The Isthmus of the Encephalon.
General Description and Division. — The Pons Varolii and Middle Peduncles of the Cerebellum — the Pedun-
cles of the Cerebrum — the Superior Peduncles of the Cerebellum and the Valve of Vieussens — the Cor-
pora Quadrigemina. — Internal Structure of the Isthmus, viz., of its Inferior, Middle, and Superior Strata.
— Sections. — Development. — Comparative Anatomy 710
The Cerebellum.
General Description. — External Characters and Conformation — Furrows, Lobules, Lamins, and Lamellte.
— Internal Conformation — the Fourth Ventricle, its Fibrous Layers, its Inferior Orifice, and its Choroid
Plexus. — Sections of the Cerebellum, Vertical and Horizontal. — Examination by Means of Water, and of
the hardened Cerebellum. — General Viev% nf the Organ. — Development. — Comparative Anatomy . 715
The Cerebrum, or Brain Proper.
Definition — Situation — Size and Weight — General Form. — The Superior or Convex Surtice. — 1 ne Inferior
Surface or Base — its Median Region, containing the Inter-peduncular Space, the Corpora Albicantia, the
Optic Tracts and Commissure, the Tuber Cinereum, Infundibuluni, and Pituitary Body, the Anterior Part
of the Floor of the Third Ventricle, the reflected Part of the Corpus Callosum, the Anterior Part of the
Longitudinal Fissure, the Posterior Part of the Longitudinal Fissure, the Posterior Extremity of the Corpus
Callosum and Median Portion of the Transverse Fissiu-e, and the Transverse Fissure. — The Lateral Re-
gions, including the Fissiu-e of Sylvius and the Lobes of the Brain. — The Convolutions and Anfractuosi-
ties of the Brain, upon its Inner Surface, its Base, and its Convex Surface — Uses of the Convolutions and
Anfractuosities. — The Internal Structure of the Brain — Examination by Sections — Horizontal Sections
showing the Corpus Callosum, the Septum Luciduni, the Fornix and Corpus Fimbriatum, the Velum In-
terpositum, the Middle or Third Ventricle, the Aqueduct of Sylvius, the Pineal Gland, the Lateral Ven-
tricle?, their Superior and Inferior Portions, the Choroid Plexus, and the Lining Membrane and the Fluid
of the Ventriclus — Mrdlan Vertical Section — Transverse Vertical Sections — Section of Willis. — General
CONTENTS. XV
Remirks on this Method of examining the Brain.— Methods of Varolius, Vienssens, and Gall.— Gall and
Spurzheim's Views on the Structure of the Brain. — General Idea of the Brain.— Development. — Compar-
ative Anatomy ... Page 725
The Nerves, ob the Peripheral Portion of the Nervous System.
General Remarks. — History and Classification. — Origin, or Central Extremity. — Different Kinds. — Course,
Plexuses, and Anastomoses. — Direction, Relations, and Mode of Division. — Termination. — Nervous Gan-
glia, and the great Sympathetic System.— Conne.\ions of the Ganglia with each other, and with the Spi-
nal Nerves.— Structure of Nerves.— Structure of Ganglia.— Preparation of Nerves . . . .759
Description of the Nerves.
General Remarks.— Division into Spinal, Cranial, and Sympathetic Nerves 769
TVke Spinal JVerves.
Enumeration and Classification. — ^The Central Extremities, or Origins of the Spinal Nerves — Apparent Ori-
gins— Deep or real Origins. — The Posterior Branches of the Spinal Nerves — Common Characters — the
Posterior Branches of the Cervical Nerves, their Common and Proper Characters — the Posterior Branches
of the Dorsal, Lumbar, and Sacral Nerves. — The Anterior Branches of the Spinal Nerves — their General
Arrangement 770
The interior Branches of the Cervical JVerves.
Dissection. — Anterior Branch of the First, Second, Third, and Fourth Cervical Nerves. — The Cervical
Plexus— its Anterior Branch, the Superficial Cervical— its Ascending Branches, the great Auricular and
the External or Lesser Occipital— its Superficial Descending Branches, the Supra-clavicular— its deep De
scending Branches, the Nerve to the Descendens Noni and the Phrenic — its deep Posterior Branches. —
The Anterior Branches of the Fifth, Sixth, Seventh, and Eighth Cervical, and First Dorsal Nerves. — The
Brachial Plexus — its Collateral Branches above the Clavicle — its Muscular Branches, Posterior Thoracic,
Supra-scapular — opposite to the Clavicle the Thoracic, below the Clavicle the Circumflex — its Terminal
Branches, the Internal Cutaneous and its Accessory, the Musculo-cutaneous, the Median, the Ulnar, the
Musculo-spiral or Radial. — Summary of the Distribution of the Branches of the Brachial Plexus . 776
The interior Branches of the Dorsal JVerves, or the Intercostal JVerves.
Dissection. — Enumeration. — Common Characters. — Characters proper to each 794
The interior Branches of the Lumbar JVerves.
Enumeration.— The Lumbar Plexus.— Collateral Branches, Abdominal and Inguinal.— Terminal Branches
— the Obturator Nerve— the Crural Nerve and its Branches, viz., the Musculo-cutaneous— the Accessory
of the Internal Saphenous— the Branch to the Sheath of the Vessels— the Muscular Branches— the Inter-
nal Saphenous 796
The Anterior Branches of the Sacral M'erves.
Dissection. — Enumeration. — The Sacral Plexus. — Collateral Branches, viz., the Visceral Nerves — the Mus-
cular Nerves — the Inferior Hemorrhoidal — the Internal Pudic and its Branches — the Superior Gluteal
Nerve— the Inferior Gluteal, or Lesser Sciatic Nerve — the Nerves for the Pyramidalis, (iuadratus Fe-
moris, and Gemelli. — Terminal Branch of the Sacral Plexus, or the great Sciatic Nerve. — The External
Popliteal and its Branches — the Peroneal, Saphenous, Cutaneous, and Muscular Branches — the Musculo-
cutaneous— the Anterior Tibial. — The Internal Popliteal and its Branches — the Tibial or External Saphe-
nous— Muscular and Articular Branches — the Internal Plantar — the External Plantar. — Summary of the
Nerves of the Lower Extremity. — Comparison of the Nerves of the Upper with those of the Lower Ex-
tremity 804
T%e Cranial JVerves.
Definition and Classification. — ^The Central Extremities of the Cranial Nerves, viz., of the Olfactory— of
the Optic — of the Common Motor Oculi — of the Pathetic — of the Trigeminal — of the External Motor Oculi
— of the Portio Dura and Portio Mollis of the Seventh — of the Glosso-pharyngeal, Pneumogastric, and
Spinal Accessory Divisions of the Eighth — and of the Ninth Nerves 816
Distribution of the Cranial JVerves.
The First Pair, or Olfactory Nerves. — ^The Second, or Optic Nerves. — The Third, or Common Mdlor Nerves.
— The Fourth, or Pathetic Nerves. — The Fifth, or Trigeminal Nerves — the Ophthalmic Division of the
Fifth, and its Lachrymal, Frontal, and Nasal Branches — the Ophthalmic Ganglion — the Superior Maxil-
lary Division of the Fifth, and its Orbital Branch — the Spheno-palatine Ganglion, and its Palatine, Spheno-
palatine, and Vidian Branches — the Posterior and Anterior Dental, and the Terminal Branches of the Su-
perior Maxillary Nerve — the Inferior Maxillary Division of the Fifth — its Collateral Branches, viz., the
deep Temporal, the Masseteric, Buccal, and Internal Pterygoid, and Auriculo-temporal — its Terminal
Branches, viz., the Lingual and Inferior Dental — the Otic Ganglion. — The Sixth Pair, or External Motor
Nerves. — The Seventh Pair — the Portio Dura, or the Facial Nerve — its Collateral Branches — its Terminal
Branches, viz., the Temporo-facial and Cervico-facial — the Portio Mollis, or Auditory Nerve. — The Eighth
Pair — its First Portion, or the Glosso-pharyngeal' Nerve — its Second Portion, or the Pneumogastric Nerve,
divided into a Cranial, Cervical, Thoracic, and Abdominal Part— its Third Portion, or the Spinal Acces-
sory Nerve.— The Ninth Pair, or the Hypoglossal Nerves.— General View of the Cranial Nerves . 824
The Sympathetic System of JVerves.
€eneral Remarks.— The Cervical Portion of the Sympathetic. — The Superior Cervical Ganglion — its Supe-
rior Branch, Carotid Plexus, and Cavernous Plexus — its Anterior, External, Inferior, and Internal Branch-
es.—The Middle Cervical Ganglion. — The Inferior Cervical Ganglion. — The Vertebral Plexus. — The
Cardiac Nerves ; Right, Superior, Middle, and Inferior ; Left.— The Cardiac Ganglion and Plexuses.— The
Thoracic Portion of the Sympathetic- The External and Internal Branches.— The Splanchnic Nerves,
Great and Small.— The Visceral Ganglia and Plexuses in the Abdomen, viz., the Solar Plexus and Semi-
lunar Ganglia.— The Diaphragmatic and Supra-renal, the Coeliac, the Superior Mesenteric, the Inferior
Mesenteric, and the Renal, Spermatic, and Ovarian Plexuses.— The Lumbar Portion of the Sympathetic.
—The Communicating, External, and Internal Branches.— The Lumbar Splanchnic Nerves and Visceral
Plexuses in the Pelvis. — The Sacral Portion of the Sympathetic. — General View of the Sympathetic
System 854
DESCRIPTIVE ANATOMY.
INTRODUCTION.
Object and Division of Anatomy. — General View of the Human Frame. — Apparatus of Sen-
sation— of Locomotion — of Nutrition — of Reproduction. — General Plan of the Work.
Considered in its most extended signification, Anatomy* is the science which has for
its object the structure of Uving beings.
Living beings are divided into two great classes, vegetables and animals ; there is,
therefore, a vegetable anatomy and an animal anatomy. When anatomy embraces, in one
general view, the whole series of animals, comparing the same organs as they exist in
^he different species, it receives the name of zoological, or comparative anatomy.
Zoological anatomy is denominated philosophical or transcendental, when from the com-
bination and comparison of particular facts it deduces general results, and laws of orga-
nization.
When anatomy is confined to the examination of one species only, it receives the
name of special ; such as the anatomy of man, the anatomy of the horse, &c. Physio-
logical anatomy considers the organs in their healthy state. Pathological anatomy regards
them as altered by disease.
\Vhen physiological anatomy is confined to the examination of the external conforma-
tion of organs, that is to say, of aU their qualities which may be ascertained without di-
vision of their substance, it is called descriptive anatomy. If, on the contrary, it pene-
trates into the interior of organs, in order to determine their constituent or elementary
parts, it receives the name general anatomy, or of the anatomy of textures.
Descriptive anatomy informs us of the names of organs {anatomical nomenclature),
their number, situation, direction, size, colour, weight, consistence, figure, and relations ;
it traces, in fact, the topography of the hmnan body. In more than one respect, it is to
medicine what geography is to history. The anatomy used by painters and sculptors may
be regarded as one of its dependances, and may be defined to be the knowledge of the
external surface of the body, in the different attitudes of repose, and in its various move-
ments. On this subject it may be observed, that the precise determination of the ex-
ternal eminences and depressions may afford most important indications regarding the
situation and state of deeply-seated parts, and is therefore worthy the attention of the
physician.
Descriptive anatomy, in the sense here meant, has arrived at a high degree of perfec-
tion. It is to this branch that reference is made by those who affirm that nothing now
remains to be done in anatomy. But although descriptive anatomy may be all that the
surgeon requires to enable him to comprehend the lesions which most commonly fall
under his notice, and to perform operations, it will by no means suffice for the physician
or the physiologist. For their purposes, anatomical investigations must not be confined
to the surface, but penetrate into, and analyze the substance of organs. Now such is
the object of general or textural anatomy. By its means the different organs are re-
solved into their component tissues : these tissues, again, are reduced to their simple
elements, which are then studied by themselves, independently of the organs which they
form ; and subsequently, by considering the elementary constituents as combined in va-
rious proportions, the organization of even the most comphcated and dissimilar parts is
made manifest.
There is one species of anatomy which has of late been cultivated with the greatest
success. I mean the anatomy of the fatus.
The anatomy of the fatus, or the anatomy of the body at different periods of life, naiMcd
the anatomy of evolution, has for its object the study of the development of organs, their
successive modifications, and sometimes even the metamorphoses which they undergo,
from the time of their first appearance until they arrive at perfection.
Lastly, there is a species of anatomy to which the term of " applied anatomy''' may be
given, because it comprehends all the practical applications of the science to medicine
* The word Anatomy is derived from the Greek [ava, up, and rtuvai, I cut). It is, in fact, by means of
dissection principally that we are enabled to separate and study the different organs. But injections, desicca-
tion, the action of alcohol, concentrated acids, &c., are also means employed by the anatomist
A
2 INTRODUCTION.
and surgery. With this view, the body is divided into regions or departments, and each
region into successive layers. The relation of the different layers is pointed out, and
in each layer the parts Avhich compose it. In a word, the constant object is the solution
of the following question : A region, or any part of the surface of the body being given,
to determine the subjacent parts which correspond to it at different depths, and their
order of superposition. This has generally been denominated the anatomy of regions,
topographical or surgical anatomy, because it has hitherto been studied only with refer-
ence to its uses in surgery. It may easily be shown, however, that with the exception of
the limbs or extremities, the anatomical knowledge of which has few applications to
medicine, properly so called, the study of regions is no less important to the physician
than to the surgeon. To give it, therefore, a name corresponding with its use, it should
be called medico-chirurgical topographical anatomy.
Such are the different aspects under which anatomy may be regarded. The following
work is essentially devoted to descriptive anatomy.*
General View of the Human Body.
Before entering on a detailed description of the munerous organs which enter into the
composition of the human body, it is advisable to present a rapid sketch of the whole.
Such general views, instead of embarrassing the mind, at once enlighten and satisfy it,
by exhibiting the objects of its research in their true relations, and showing the end to
be attained.
There is one general covering, which, like a garment, envelops the whole body, and
is moulded, at it were, round all its parts. This covering is the skin, of which the nails
and hair are dependances. The skin presents a certain number of apertures, by means
of which a communication is established between the exterior and the interior of the body.
These apertures, however, are not formed by a mere perforation or breach of continuity
in the skin ; on the contrary, this membrane passes inward at the circumference of
these openings, and having undergone certain important modifications in its structure,
forms the mucous membranes, a kind of internal tegument, which may be considered as
a prolongation of the external envelope. We might, therefore, strictly speaking, regard
the human body as essentially composed of a skin folded back upon itself This idea is,
indeed, realized in some of the inferior animals, which consist of a mere tube or canal.
In proportion, however, as we ascend in the scale, we find the layers which separate
these two teguments become more and more increased in thickness, and cavities are at
length formed between them. Nevertheless, however widely these membranes may be
separated from each other, and however different they may be in external aspect, there
are abundant analogies to establish unequivocally their common origin.
Under the skin there is a layer of adipose cellular tissue, which gently elevates it, fiUa
up the depressions, and contributes to impart that roundness of form which character-
izes all animals, and particularly the human species. In some parts, there are muscles
inserted into the skin, which are intended for its movement ; these are the cutaneoua
muscles. In man they are very inconsiderable, and are confined to the neck and face,
where they play an important part in giving expression to the physiognomy ; but in the
larger animals they line the whole skin, and in certain classes, of very simple organiza-
tion, they constitute the entire locomotive apparatus.
The superficial veins and lymphatics traverse the subcutaneous cellular tissue : tlie
latter, at various parts of their course, pass through enlargements denominated lymphatic
ganglions, or lymphatic glands, which are grouped together in certain regions.
Below the cellular tissue are the muscles, red, fleshy bundles, arranged in many layers.
In the centre of all these structures are placed the bones, inflexible columns, v/hich
serve for a support to all that surrounds them. The vessels and the nerves are in the
immediate neighbourhood of the bones, and, consequently, removed as much as possible
from external injury. Lastly, around the muscles and under the subcutaneous adipose
tissue are certain strong membranes, which bind the parts together, and which, by pro
longations detached from their internal surface, separate and retain in their situation
the different muscular layers, frequently each particular muscle : these envelopes are
the aponeuroses.
Such is the general structure of the limbs or extremities.
If next we examine the trunk, we find in its parietes a similar structure, but more in
ternally are cavities lined by thin transparent membranes, named serous, on account of
a liquid or serosity with which they are moistened. In these cavities are situated or-
gans of a complex structure, called viscera, of which we shall give a rapid enumeration
m an order conformable to the offices they perform in the animal economy.
The hmnan body, as well as that of other organized beings, is composed of certain
parts, denominated organs {bpyavov, an instrument), which differ from each other in
* Descriptive anatomy ought, in strictness, to be confined to the consideration of the external characters ol
organs, or what is understood by the term external conformation ; nevertheless, in order to present a complete
view of each organ, after having described its exterior, we shall give a short account of its texture and deveJ-
onment.
GENERAL VIEV^'6'p¥kte' HUMAN BODY. 3
their structure and use, but are all combined, for the double purpose of the preservation
of the individual, and the continuance of the species.
To accomplish these purposes, the organs are distributed in a certain number of
groups or series, each of which has a definite end to fulfil. This end is denominated a
function : the series of organs receives the name of an apparatus. Of those necessary
for the preservation of the individual, some are designed to place him in relation with
external objects, and these constitute the apparatus of relation : the others are destined
to repair the loss which the parts of the body are constantly suffering ; they form the
apparatus of nutrition.
The apparatus of relation may be subdivided into two classes : 1. The apparaius of
sensation. 2. The apparatus of motion.
Apparatus of Sensation. — The apparatus of sensation consists, 1. Of the organs of
sense ; 2. Of the nerves ; 3. Of the brain and spinal cord.
The organs of the senses are, 1. The skin, which possesses sensibility, the exercise
of which constitutes tact. The skin being placed under the direction of the will, and
rendered mobile in consequence of the peculiar mechanism of the human hand, is called
the organ of touch. 2. The organ of taste, the seat of which is in the cavity of the
mouth, that is, at the entrance of the digestive canal. 3. The organ of smell, placed in
the nasal fossee, the commencement of the respiratory passages, by which we are en-
abled to recognise the odorous emanations of bodies. 4. The organ of hearing, con-
structed in accordance with the principles of acoustics, and placed in relation with the
vibrations of the air. 5. TTie organ of sight, which bears relation to the hght, and ex-
hibits a construction in harmony with the most important laws of dioptrics.
The organs of sense receive impressions from without. Four of them occupy the
face, and are, therefore, placed in the vicinity of the brain, to which they transmit im-
pressions with great rapidity and precision ; and that organ seems, in its turn, to extend
into them, so to speak, by means of the nerves. Indeed, the impressions received by
the external organs would be arrested in them, were it not for certain conductors of
such impressions : these conductors are the nerves — white, fasciculated cords, one ex-
tremity of which passes into the organs, while the other is connected to the spinal mar-
row and the brain, which are the central parts of the nervous system, the nerves con-
stituting the peripheral part.
Apparatus of Locomotion. — The apparatus of locomotion consists, 1. Of an active or
contractile portion, the muscles. These are terminated by tendons, organs of a pearly
white colour, which direct upon a single point the action of many forces ; 2. Of a pas-
sive portion, the bones, true levers, which constitute the framework of the body, and tlie
extremities of which, by their mutual contact, form the articulations : in the latter we
perceive (a) the cartilages, compressible, elastic substances, which deaden the violence
of shocks, and render the contact uniform ; (jb) an unctuous liquid, the synovia, secreted
by membranes denominated synovial : this liquid performs the office of the grease em-
ployed in the wheel- work of machinery ; (c) bands or ligaments, which maintain the con-
nexion of the bones.
Such is the apparatus designed to establish the relation between man and external
objects.
Apparatus of Nutrition. — The apparatus which performs in the human body the im-
portant office of nutrition consists of the following parts :
A. The digestive apparatus, which consists essentially of a continuous tube or canal,
denominated the alimentary canal. This canal has not the same form and structure
throughout the whole extent : on the contrary, it is composed of a series of vei7 dissim-
ilar organs, all, however, contributing to the formation of one common passage. These
organs are, 1. The mouth; 2. The pharynx; 3. The msophagus, or gullet; 4. The stom-
ach ; 5. The intestines ; which are farther subdivided into the small intestines, consisting
of the duodenum, jejunum, and ileum, and the large intestines, comprising the cacum, colon,
and rectum.
To this long tube, the greater part of which is contained in the abdomen, where it
forms numerous reduplications, are annexed, 1. The liver, a glandular organ, whose
office it is to secrete the bile, and which occupies the superior and right portion of the
abdomen ; 2. The spleen, whose functions are involved in great obscurity, but which
may, perhaps, be termed an appendix to the liver, on the left side ; 3. The pancreas, which
pours a fluid into the duodemmi, by an orifice common to it and the biliary duct.
B. On the internal surface of the digestive canal, and particularly that portion of it
which bears the name of the small intestine, certain vessels open by numerous orifices
or mouths,* and carry otfthe nutritive fluids prepared by the process of digestion : these
are the chyliferous or absorbent vessels, which are also called lacteal vessels, on account of
the white, milky aspect presented by their contents while absorption is going on. The
absorbent appai'atus consists, also, of another set of vessels denominated lymphatics, be-
cause they contain a colourless liquid named lymph, which they collect from a,H parts ol
* (This must not be understood literally. See account of the lacteals, infni.l
4 INTRODUCTION.
the body. All the absorbent vessels, of whatever order they may be, traverse at differ^
ent parts of their course certain grayish bodies, called lymphatic gangUmis or glands, and
finally terminate in the venous system.
C. The venous system arises from all parts of the body : it takes up, on the one hand,
all those matters which, having been employed a sufficient time as part of the body, must
be eliminated from it ; and, on the other hand, all those substances which are carried into
the system, to contribute to its reparation : it is composed of vessels denominated veins
which at various distances are provided with valves, and at last unite in forming two
large veins called vena cavce, of which one, the superior, receives the blood from the upper
part of the body ; the other, the inferior, brings back that which has circulated in the
lower portion.
These two venae cavae terminate in the central organ of the circalation, the heart, a
hollow muscle, containing four contractile cavities : two on the right side, the right au-
ricle and ventricle, and two on the left, the left auricle and ventricle.
D. Next to these in order of function is the respiratory apparatus, composed of two
spongy sacs, placed on each side of the heart, and occupying almost the whole of the
chest : these are the lungs. They receive the air from a common tube, the trachea,
which is surmounted by a vibratile organ, the larynx, which opens externally by the nose
and mouth, and constitutes the organ of voice.
E. From that cavity of the heart which is called the left ventricle, arises a large ves-
sel, the aorta : this forms the principal and primitive trunk of the whole class of vessels
named arteries, whose office it is to convey red blood to all parts of the body, to main-
tain their heat and life.
F. There still remains one other portion of the nutritive system, the urinary appara-
tus, consisting of, 1. The kidneys, organs which secrete the urine : 2. The ureters, by
means of which the urine, as soon as secreted, passes off into a spacious receptacle, the
bladder, from whence it is at intervals expelled along a passage which has received the
name of urethra.
Apparatus of Reproduction. — ^The apparatus above mentioned is destined for individual
preservation : the organs which secure the continuance of the species constitute the
generative or reproductive apparatus. They differ in the male and in the female.
In the male they are, 1 . The testicles, which prepare the spermatic or fecundating fluid ,
2. The vasa deferentia, tubes which transmit this fluid from the testicle where it is se-
creted to the vesiculse seminales ; 3. The vesicula. seminales, or receptacles of semen ;
4. The cjaculatory ducts, through which the semmal fluid passes into the urethra ; 5. The
prostate and Cowpefs glands, glandular appendages of the organs for the transmission
of the semen ; 6. The penis, by means of which the fecundating fluid is conveyed into
the interior of the genital organs of the female.
The generative apparatus in the female is composed of the following organs : 1. The
ovaries, the function of which is to produce, or keep in readiness, the ovulum or germ ;
2. The uterine tubes, which transmit the germ, when fecundated, to the uterus ; 3. The
uterus or womb, in which the product of conception remains and is developed during the
period of gestation ; 4. The vagina, a canal which permits the passage of the foetus at its
final expulsion ; 5. As appertaining to the system should be mentioned the mammary
glands, which secrete the milk destined for the nourishment of the new-bom infant.
Genkral Plan of the Work.
There are two methods by which the numerous facts that come within the range of
anatomy may be explained. The different organs may be studied in their order of super-
position, or in the topographic order, a capite ad calcem ; in this way the most dissimilar
parts are brought together, while others are separated which have the greatest analogy ;
or they may be considered in a physiological order, i. e., an order founded upon the same
grounds as serve for the classification of functions. This is clearly the most rational,
because it has the incontestable advantage of preparing for the study of the functions by
that of the organs. It may be easily seen, however, that this physiological arrangement
should be modified according to the relative difficulty in the study of the different parts
of the body ; for the great aim in a work of instruction should be to conduct the mind, by
degrees, from simple and easy objects to those which are more complicated. It is for
this reason that the consideration of the nervous system, which, in strict accordance
with physiological arrangement, should be placed near to that of the locomotive appara-
tus, is deferred. The object proposed has been to adopt an arrangement which would,
as far as possible, reconcile both these views, and, at the same time, be compatible with
the greatest economy of subjects for dissection ; and this appears to be secured by the
method generally adopted, at least with a few slight modifications.
The following table presents a view of the general plan of this work :
f 1 . Of the bones— Osteology.
, • . , , ^ 1 2. Of the articulations — SyndeHHology.
1. Apparatus of locomotion S 3. Of the muscles-Myology.
14. Of the aponeuroses — Aponeurolog .
GENERAL OBSERVATIONS.
B. Apparatus of digestion, apparams of respiration, ) Splanchnoloffv
genito-urinary apparatus ....)'
f Heart T
3. Apparatus of the circulation .... 'S Veins'*^ [ >Angeiology.
I Lymphatics J
f Organs of the senses'!
4, Apparatus of sensation and innervation . , < jj^^^ ""'^ ' ' > Neurology.
LNerves . . .J
APPARATUS OF LOCOMOTION.
OSTEOLOGY.
OF THE BONES IN GENER.4.L.
The Bones — Importance of their Study. — General View of the Skeleton. — Number of the
Bones. — Method of Description. — Nomenclature. — Situation in general. — Direction. — Size,
Weight, and Density of Bones. — Figure. — Distinction into Long, Broad, and Flat Banes.
— Regions of Bones. — Eminences and Cavities. — Internal Cofiformation. — Texture. — De-
velopment of Osteogeny. — Nutrition.
The bones are parts of a stony hardness, but yet organized and living. They serve
as a support to all other parts of the body, are a means of protection to many, and aiford
points of attachment to the muscles, in the midst of which they are situated. All the
hard parts of the body, however, are not bones. The fundamental character of a bone
consists in its being at once hard and organized. As the bones receive vessels for the
purpose of nutrition at every part of their surface, they are surrounded on all sides by a
membrane which is fibrous and vascular, named the Periosteum (nepl, around ; dareov,
a bone).
According to this definition, the teeth, horns, nails, and, in articulated animals, the ex-
terior skeleton, are not to be considered as bones, but merely ossiform concretions. We
may add, that true bones belong exclusively to vertebrated animals.
The study of the bones constitutes Osteology, which may be regarded as the basis of
anatomy, for without a knowledge of the bones it is impossible to become acquainted
with the muscular insertions, or the exact relations between the muscles, nerves, vis-
cera, and, above all, the vessels, for which the bones afford the anatomist invariable
points of reference. Osteology has, therefore, ever since the time of the Alexandrian
school, formed the commencement of the study of anatomy.
In the present day, the transcendental anatomists have particularly engaged in the
study of the osseous system, doubtless on account of the facility with which it may be
investigated ; and from their labours, though in many respects speculative, a more ac-
curate knowledge has been obtained of some of the nicer points of osteology, which had
scarce attracted notice from the older anatomists.
Lastly, from the admirable researches of Cuvier respecting fossil animals, osteology
has become one of the most important bases of comparative anatomy and geology. By
the study of bones the anatomist has been enabled to determine genera and species, no
longer existing on the face of the globe, and to give, as it were, new life to these old and
disjointed relics of the antediluvian animal kingdom. Thus the fossil bones, deposited
in an invariable order of superposition in the crust of the earth, have been transformed
into monuments more authentic than historical records.
General View of the Skeleton. — ^The bones form a system or whole, of which the different
parts are contiguous, and united to each other. The only exception to this rule is the
OS hyoides, and yet the ligaments by which it is connected with the rest of the system
are evidently the representatives of the osseous pieces, which in the lower animals con-
nect this bone with the temporal.
The assemblage of the bones constitutes the skeleton. It is called a natural skeleton
when its different parts are connected by their own ligaments ; an artificial skeleton, on
the other hand, is one of which the bones are joined together by artificial connexions,
such as metallic wires, &c.
The result of this union is a symmetrical and regular structure, essentially composed
of a central column, denominated the vertebral column or spine, which terminates superi-
orly in a considerable enlargement, the cranium, and inferiorly in certain immovably
united vertebrae, which constitute the sacrum and coccyx. To this column the following
appendages are attached : 1. In front of and below the cranium, a complicated osseous
structure, the face, divided into two maxillce, the superior and inferior. 2. On each side
twelve bony arches, flexible, elastic, and curved — the ribs, which are united in front to
another column, the sternum. These parts, taken together, form the thorax. 3. Four
prolongations, called limbs or extremities : two superior, or thoracic, as they are termed,
because they correspond with the chest or thorax ; and two inferior or pelvic, so named
g 6 OSTEOLOGY.
on account of their connexion with the basin or pelvis, but better uamed^ abdominal a
tremities. The thoracic and abdominal extremities are evidently modifications of the
same fundamental type, and are essentially composed of the same number of analogous
parts, viz. : 1. An osseous girdle, the superior constituted by the bones of the shoulder,
the inferior by the pelvis. 2. A part Avhich may be in some measure regarded as the
body of the limb, viz., the humerus, in the thoracic extremity, the femur in the abdominal.
3. A manubrium or handle, to use an expression of Galen, above the forearm, below
the leg. 4. Lastly, digitated appendages which form the extremities, properly so called,
viz., the hand and the /oof.
Number of the Bones. — Authors do not agree respecting the number of the bones.
Some, for instance, describe the sphenoid and the occipital as forming only one bone,
while most anatomists consider them two distinct bones. Some admit three pieces in
the sternum, which they describe separately. Many, after the example of the older
writers, divide the haunch into three distinct bones — ^the pubes, the ischium, and the
ileum : others recognise five pelvic or sacral vertebrae ; three or five parts of the os
hyoides ; and, lastly, the ossa sesamoidea and the ossa wormiana- are omitted by some,
but by others are reckoned in the enumeration of the bones.
The ideas of certain modem authors with respect to the development of the bones, in-
stead of dispelling the uncertainty which attaches to the enumeration of the parts of the
skeleton, have tended not a little to increase the confusion, because many of them have
made no distinction between bones, properly so called, and pieces of ossification. All
doubt, however, in this respect will cease, provided we consider as distinct bones only
those portions of the skeleton which are separable at the time of complete development.
The time at which the osseous system arrives at its perfect development is between
the twenty-fifth and thirtieth year.
According to these views, we may count in the human body 198 bones, viz. :
Vertebral column, including the sacrum and coccyx .... 26
Cranium 8
Face 14
Os hyoides 1
Thorax (ribs, sternum) 25
Superior extremities, each 32, viz., shoulder, arm, forearm, and hand 64
Inferior extremities, each 30, viz., pelvis, thigh, leg, and foot . 60
198
This enumeration does not include the ossa wormiana, nor the ossa sesamoidea, among
which we include the patella.
Of these 198 bones, 34 only are single : all the others are in pairs, which reduces the
number to be studied to 116.
Before proceeding to examine each piece of the skeleton in particular, we shall state
the method we intend to pursue in the description. The chief points embraced by de-
tailed descriptions of a bone are, 1. Its name; 2. Its general situation; 3. Its direction ;
4. Its bulk and weight ; 5. Its figure ; 6. Its regions ; 7. Its relations ; 8. Its internal
conformation ; 9. Its intimate texture ; 10. Its development.
Nomenclature. — Osteological nomenclature has many imperfections. Persuaded of
the importance of a suitable choice of language in the study of all the sciences, some
anatomists have endeavoured to introduce reforms, but with little success, the old de-
nominations being still for the most part retained. From these modern systems of no-
menclature we shall adopt only such terms as Eire strikingly appropriate, or such as have
already been sanctioned by usage. We may here observe that the denominations of
bones have been derived, 1. From their situation ; as the frontal, which is so called be-
cause it is situated in the forehead : 2. From a resemblance, usually very obscure, to some
well-known object, as the bones named tibia, scaphoid, malleus, incus, stapes ; or to some
geometrical figure, as the cuboid : 3. From their size ; as the os magnum of the carpus,
and the small bones or ossicula of the ear : 4. From some circumstance of their external
conformation ; as the cribriform or ethmoid bone, the unciform or hooked bone : 5. From
the name of the author who first most carefully described them ; as the ossicles of Ber
tin, of Morgagni — swings of Jngrassias, &c.
General Situation of Bones. — The situation of a bone is determined by comparing the
place which it occupies with that occupied by other bones of the skeleton. In order to
make this comparison, the skeleton is supposed to be surrounded by certain planes,
which are thus denominated : 1 . A7i anterior plane, passing before the forehead, the
breast, and the feet ; 2. A posterior plane, passing behind the occiput and the heels ; 3. A
superior plane, placed horizontally above the head ; 4. An inferior plane, which passes be-
low the soles of the feet ; 5 and 6. The two lateral planes, which complete the sort of
case or parallelepiped with which we suppose the skeleton to be surrounded. Lastly,
the skeleton being symmetrical, i. e., exactly divisible into two similar halves, we admit
a seventh imaginary plane, the median or antero-posterior, separating these two halves.
By the term median line is understood an imaginary line traced so as to mark exteriorly
the division of all the symmetrical bone" of the skeleton into two similar halves.
GENEEAL OBSERVATIONS. 7
These points being understood, nothing is more easy than to determine the position
of a bone. If it approach nearer to the anterior plane than others with which it is com-
pared, it is said to be anterior to them ; if it be nearer the posterior plane, it is said to be
posterior to them. Let us take, for example, the malar or cheek bones. With respect
to the whole face, they are placed at the anterior, superior, and in some degree the lateral
part; relatively to the neighbouring bones, they are situated, 1. Below the frontal; 2.
Above and a little external to the maxillary ; 3. Before the great wings of the sphenoid
and the zygomatic process of the temporal.
Direction of Bones. — The direction of a bone is absolute or relative. The absolute di-
rection is expressed by the terms straight, curved, angular, or twisted ; in a word, it is the
direction of a bone considered by itself, or independently of its situation in the skeleton.
The long bones are never quite straight : sometimes they present a shght degree of cur-
vature, as the femur ; sometimes their extremities are curved in opposite directions,
like the letter S, as the clavicle : sometimes, again, they are twisted upon their own
axes, as the humerus, the fibula, &c.
The relative direction is determined by reference to .the planes which circumscribe
the skeleton. Viewed in this manner, a bone is vertical, horizontal, or oblique. It is
needless to enter into any explanation of the terms vertical and horizontal ; but with re-
gard to the oblique direction, it may be stated that this is determined by the respective
situations of its two extremities. For example, a bone is oblique when one extremity
approximates the superior, the median, and the posterior planes, while the other ap-
proaches nearer to the inferior, lateral, and anterior planes ; such a bone is said to be
obhque from above downward, from within outward, and from behind forward. It is easy
to see that in this way the situation of a bone relatively to the different planes may be
determined with the greatest exactness. It should be observed, that in describing the
direction of a bone, we should always set out from the same point. Thus, if the direc-
tion of a bone from above downward is spoken of in determining its obhquity from be-
fore backward, and from vrithin outward, we should always commence with the supe
rior extremity.
\^ Size, Weight, and Density of Bones. — The size of a bone may be measured by the ex-
/* tent of its three dimensions ; but as an exact estimate is not in general required, it is
sufficient to indicate the voliftne of each bone relatively to others, whence has arisen
the division of bones into great, middle-sized, and small ; a distinction, however, altogeth-
er vague and futile, since from the largest to the smallest bones there is so regular a
gradation that the limits assigned must be quite arbitrary.
The weight, or the mass of the skeleton compared with the rest of the body, the weight
of each bone, and the comparative weight of different bones, are points of little inter-
est ; such, however, is not the case with the specific weight or density of bones.
In respect of density, viz., the number of molecules in a given volume, the bones are
the heaviest of all organs. The truth of this assertion is by no means contradicted by
the lightness of certain bones, which is only apparent, and which is caused by vacant
spaces or cells in their substance. This density varies in different kinds of bones, in
bones of the same kind, and even in different parts of the same bone. Thus, in the long
bones, the greatest density is in the middle : the extremities of the long bones and the
short bones have a much lower density. The broad or flat bones hold a middle place
between the shaft of long bones and the short bones. Of these broad bones, those of the
cranium are heavier than those of the pelvis. Age has a remarkable influence upon the
specific weight of bones. It has been said that the bones of the aged are specificcdly
more heavy than those of the adult, just as the bones of the adult are specifically heavi-
er than those of the infant ; and this assertion appears the more probable, from it being
generally admitted, as a law of organization, that the phosphate of lime increases in
bones with the progress of age ; and it is well known that the weight of bones depends,
in part, on the presence of this calcareous phosphate. But on this point, as on many
others, experience has refuted these preconceived opinions. Thus, it is certain that the
specific, as well as the absolute weight of bones, is much less considerable in the old
person than in the adult ; and this difference depends upon the loss of substance which
the bones undergo, in common with all other tissues, during the progress of age : thus,
in aged subjects, the walls of the cylinder of the long bones are remarkably diminished
in thickness, while the medullary cavity is proportionally increased. We rnay even af-
firm, with Chaussier, that the medullary cavity of the shaft of long bones has a greater
diameter, in proportion as the individual is advanced in age. In like manner, the cells
of the spongy tissue become much larger, and their w-alls acquire an extreme tenuity.
It may, nevertheless, be contended, that the weight of the osseous fibre, or, rather, of
the osseous molecules of the old people, is gieater, comparatively, than that of the same
parts in the adult ; and this presumption is ahnost converted into certainty by chemical
iinalysis, which shows an excess of phosphate of lime in the bones of the aged : to re-
move all doubts upon this point, it would he necessary to grind an adult bone and an old
one, and to weigh in the balance an equal bulk of each powder. In this way the contra-
dictory statements of certain authors might be reconciled.
-K
8 OSTEOLOGY.
The increasing fragility of bones, and the consequent frequency of fractures in old age,
are CEisily explained, since along with the accumulation of phosphate of lime, which di-
minishes the elasticity while it increases the brittleness, there occurs a diminution of
bulk, and, consequently, there is less resistance. It is with respect to the quantity of
calcareous phosphate alone that the osseous system can be said to preponderate in old age.
Shape of Bones. — The shape of a bone is determined, 1. By comparison either with
different known objects, or with geometrical figures : thus the frontal bone has been
compared to the scallop-shells of pilgrims, the sphenoid to a bat with extended wings,
&c. It may be readily conceived that, notwithstanding its want of exactness, this meth-
od of comparison, so familiar to the ancients, cannot be altogether proscribed. The
comparison of bones whose forms are so irregular with the regular solid figures of which
geometry treats is no less inaccurate than the preceding ; nevertheless, we shall con-
tinue, like other anatomists, to speak of the short bones as cuboidal, the shafts of long
bones as being prismatic and triangular, the lower maxdlaj parabolic, &c. We shall
speak of spheres, of cones, of ovoids, of cylinders, &c.
2. The symmetry or want of synmietry of bones is a fundamental point in the deter-
mination of their figure : thus, some bones are divisible into two halves exactly resem-
bling each other ; these are the syimnetrical or azygos bones, also called median, be-
cause they always occupy the middle line. The others can not be divided into two sim-
ilar parts : these are the asymmetrical bones, called also lateral or corresponding, because
they are always in pairs, and situated on opposite sides of the median line.
3. The figure of a bone comprehends, also, the proportion which its three dimensions
bear to each other. When the three dimensions, length, breadth, and thickness, are
nearly equal, the bone is said to be short ; when the length and breadth are almost the
same, and both greater than the thickness, the bone is called broad or fiat. Lastly, the
predominance of one dimension over the two others constitutes the character of long
bones. The distinction here drawn, however, is not altogether exact, because there are
certain mixed bones which partake at the seime time of the character of the long and the
broad bones.
Some general observations upon the three great classes will not be out of place here,
as they will be applicable in the description of the individual bones.
Ge?ieral Characters of Long, Flat, and Short Bones.
Of Long Bones. — The long bones are situated in the extremities, in the centre of which
they form a set of pillars or levers placed upon each other. The bones of the abdominal
extremities are generally longer and larger than those of the thoracic. The longest
bones are in the upper part of the limbs ; it may be said, indeed, that the length of bones
is in the direct ratio of their proximity to the trunk. The diameter of the long bones is
smallest in their middle. From this part, as from a centre, they gradually increase in
volume, and at their extremities are much enlarged, so as to present a diameter doubld
or treble that of the shaft. Every long bone, therefore, presents a biconical form, i. e.,
is shaped like two cones united by their summits.
A long bone consists of a shaft and extremities. The shaft of the long bones is almost
always prismatic and triangular ; so much so, that in this respect the bones seem to be
an exception to the general rule of organized bodies, which have usually a rounded form,
and to approach nearer that of the mineral kingdom, the characteristic shape of which
is angular.
The extremities of long bones are enlarged, that they may serve, 1. For articula-
tions ; 2. For the insertion of ligaments and muscles ; 3. For the reflection of tendons,
the direction of which they alter. Each extremity presents a smooth articular surface,
covered with cartilage in the fresh state, and not perforated by any foramina, and a
non-articular portion, rough, pierced with apertures, and covered with eminences and
depressions.
Of Broad or Flat Bones. — These bones, intended to form the parietes of cavities, are
more or less curved, and present for consideration a circumference and two surfaces ;
the internal concave, the external convex. No single broad bone constitutes a cavity ;
there are always a certain number united for this purpose. Some broad bones are alter-
nately concave and convex on the same surface, as the haunch bones. In flat or broad
bones there is no accurate correspondence between the inequalities, ridges, or depres-
sions of the two surfaces. Thus, the iliac portion of the haunch bones, instead of pre
senting a convexity on the inner surface, to correspond with the external iliac fossa, is
hoUowed out into another depression, the internal iliac fossa. In like manner, in the
cranium certain impressions and eminences exist on the internal surface, whUe the ex-
ternal is uniformly convex, and almost smooth. The parietal, and even the occipital
protuberances, would be twice or three times more prominent if the interior concavity
were faithfully represented by a corresponding external prominence, and if this concav-
ity were not in a great measure hollowed out from the substance of the bone.
The circumference of broad bones being intended either for articulations or for inser-
tions, is for this purpose greatly thickened. Thus the parietal bones, which are very
GENERAL OBSERVAT[ONS. 9
thin at their centre, become considerably thicker at the circumterence. The broad
bones present at their circumference sometimes a simple enlargement, when it is in-
tended for muscular insertions only ; for example, the haunch bones : sometimes indent-
ations of various kinds, and sinuosities, when it is to serve the purpose of articulation ;
for instance, the bones of the cranium.
Of Short Bones. — These are principally met with in the vertebral column, the carpus,
and the tarsus ; in fact, wherever great solidity is required in connexion with slight mo-
bility : several of them are always grouped together ; their form is extremely irregular,
but generally cuboid ; they have also numerous facettes for articulation. The non-artic-
ular portion is rough, for the insertion of ligaments and tendons.
Regions of Bones. — There are so many objects to be considered on the surface of a
bone, that it is necessary, in order to prevent the omission of any essential detail in
the description, to divide the surface into a certain number of parts or regions, which
should be successively examined. These different parts or regions have been denom-
inated faces, borders, and angles. Thus, in the prismatic and triangular shafts of long
bones, there are three faces and three borders to be considered ; in the flat bones, two faces
and a circumference, which is again subdivided into borders and angles formed by the meet-
ing of these borders. There are six faces in the short bones. These faces and borders are
named sometimes, from their situation, superior, inferior, anterior, posterior, &c. ; some-
times from the parts which they contribute to form, such as the orbital and palatine fa-
ces of the superior maxillary bone ; sometimes from their relations to other parts, as
the cerebral and cutaneous face of the bones of the cranium, the frontal, occipital, and tem-
poral borders of the parietal bones. When the borders give insertion to a great number
of muscles, it has been deemed advisable to divide these into three parts or parallel
lines : the middle is then called the interstice, and the two lateral are named lips, the in-
ternal and external lip ; the superior border of the haunch bone, and the linea aspera of
the femur, are examples.
Eminences and Cavities of Bones. — ^The bones present certain eminences and cavities,
of which it is proper to take a general survey in this place.
Eminences of Bones. — The osseous eminences or processes were divided by the an-
cients into two great classes, apophyses and epiphyses, distinguished by the difference
of their mode of development. According to their view, some of these eminences arise
from the body of the bone, appearing to be nothing more than prolongations or vege-
tations of its substance : these they called apophyses ; others, on the contrary, are
formed by separate osseous centres or nuclei, which make their appearance at various
times during the process of the development of bone : to these they gave the name of
epiphyses. This distinction, however, founded upon incomplete observation, has been
totally rejected, since the researches of M. Serres on Osteogeny have rendered it evi-
dent that almost aU the osseous eminences are developed from isolated nodules ; so
that an eminence, which at one time is an epiphysis, becomes afterward an apophysis.
If, therefore, the majority of eminences are formed from separate osseous points, the dif-
ference between them can apply only to the relative periods at which they become uni-
ted to the body of the bone.
A far more important distinction is that by which the eminences are divided into
articular and non-articular.
The articular eminences have received different names. 1. They are called dentic-
ulations when they form angular eminences resembling the teeth of a saw ; these are
best seen in the bones of the cranium. This kind of eminence is employed only in im-
movable articulations.
The others belong to joints which admit of motion, and have received the folloMing
names : 1. They are called heads when they represent a portion of a sphere supported
by a more contracted portion, to which the name of neck is given ; for example, the head
and neck of the femur. 2. The term condyle is applied to them when they resemble an
elongated head, or a portion of an ovoid cut parallel to its greatest diameter ; for exsim-
ple, the condyles of the inferior maxilla.
The non-articular eminences are, for the most part, designed for muscular insertions.
Their appellations are in general derived from their shape. Thus, they are denominated,
1 . Prominences. When they are but slightly elevated, smooth, and almost equally ex-
tended in all directions ; as the parietal and frontal eminences.
2. Mamillary Processes. When they resemble papillas ; for instance, the mamillary
processes of the internal surface of the bones of the cranium.
3. Tuberosities. When they are of a larger size, round, but uneven ; for example, the
occipital protuberance, the bicipital tuberosity (or tubercle) of the radius.
4. Spines or Spinous Processes. When, from their acuminated, but generaUy rugged
form, they bear some resemblance to a thorn ; as the spine of the tibia, the spinous pro-
cesses of the vertebrae.
5. Lines. When their length greatly exceeds their breadth ; as the semicircular lines
of the occipital bone. When these lines are more prominent, and covered with asper-
ities, they receive the name of linear asperae ; as the hnea aspera of the femur.
B
10 OSTEOLOGY.
6. Crests. When they are elevated, and have a sharp edge ; as the external and inter
nal crest of the occipital bone, the crest of the tibia. One of these eminences has been
denominated the crista galli, because it bears some resemblance to the comb of a cock.
7. The term apophyses (or processes) has been retained for those eminences which are
of a certain size, and appear to form, as it were, a little bone superadded to that from
which they spring ; they are distinguished, for the most part, by epithets derived from
their shape. Thus, the clinoid processes of the sphenoid are so called from their supposed
resemblance to the supporters of a bed {kMvjj, a bed ; ehhc, shape). Pterygoid processes
are those wliich are like wings (Trrcptf, a wing). Mastoid, such as resemble a nipple
(fiaardc, manrmia). Zygomatic, such as have the form of a yoke {Cvyoc, a yoke). Styloid,
such as are like a style. Coronoid, such as are shaped like one of the angular projec-
tirns of a diadem.* Odontoid, such as resemble a tooth ; as the odontoid process of the
second cervical vertebra. Coracoid, such as have the form of a raven's beak («dpaf, a
raven) ; as the coracoid process of the scapula. Malleoli, euch as are like a hammer
(malleus, a hammer).
Some processes have received names, 1 . From the parts they contribute to form —
orbitar processes, malar processes, olecranon {uTiivrj, the elbow ; Kpdvov, head) : 2. From
their direction ; as the ascending process of the superior maxilla : 3. From their uses ;
as the trochanters (jpoxau, to turn), because they serve for the insertion of muscles,
which rotate the leg on its own axis.
No part of the language of osteology, perhaps, is more faulty than the nomenclature of
the eminences. Thus, how unlike is the spine of the scapula to the spinous processes
of the vertebrae, or the styloid process of the temporal to the diminutive projection call-
ed styloid of the radius ! Many eminences which perform analogous offices have re-
ceived different names : thus, the eminences of the humerus, which give attachment to
its rotating muscles, are called the great and small tuberosities ; while the correspond-
ing parts of the femur have been denominated trochanters. While, therefore, we retain
the names consecrated by usage, we shall be careful to point out the more rational terms
substituted by modern anatomists, and particularly by Chaussier.
The size of the eminences of insertion is in general proportional to the number and
strength of the muscles and ligaments which are attached to them. To be convinced
of this fact, it is only necessary to compare the male and female skeleton, or that of a
man of sedentary habits and that of a person devoted to athletic exercises. This re-
markable correspondence between the size of osseous eminences and the strength of the
muscles which are inserted into them, has given rise to the opinion that these eminences
are formed by muscular traction. It is easy to refute this notion, and without entering
into details which belong to general anatomy, we shall prove, by facts, that the osseous
projections enter into the primordial plan of organization, so much so, that they would
have doubtless existed, even though the muscles had never exercised any traction upon
the bones. I have twee had occasion to dissect the thoracic extremities of individuals,
who, in consequence of convulsions during their earliest infancy, had suffered complete
paralysis of these parts. The limb affected had scarcely the proportions of that of a
child of eight or nine years, while the opposite hmb was perfectly developed. Never-
theless, in this atrophied limb, the smallest as well as the largest projections were per-
fectly marked. Moreover, very powerful muscles are often inserted into cavities, as,
for instance, the pterygoid cavity of the sphenoid.
Cavities of Bones. — Besides the great cavities of the skeleton, cavities in the formation
of which many bones concur, and which are destined to lodge and defend the organs
most important to Ufe, there are a great number of smaller excavations formed in the
substance of the bone itself.
These cavities, like the eminences, are divided into two great classes, articular and
non-articular. The articular cavities have received different names. 1. The term cotyloid
designates the articular cavity in the haunch bone, because it is deep and round, like a
vessel known by the ancients under the name of kotvIt]. 2. The name glenoid (from
y7ir)vr]) is applied to many articular cavities, which are more shallow ; for example, the
glenoid cavity of the scapula, the glenoid cavity of the temporal bone. 3. The term al-
veoli has been assigned to the cells or sockets in which the roots of the teeth are lodged.
It is not correct, however, to consider as an articulation the union of the teeth with the
jaws, because, as we shall afterward show, the teeth are not true bones.
The non-articular cavities are to be considered with reference both to their figure and
their uses. From their figure, they have received the following denominations : 1. Fossa,
or pits, are cavities largely excavated, wider at the margin than at the bottom ; e. g., the
parietal fossaj. 2. Sinuses are cavities with a narrow entrance ; as the sphenoidal sinus,
maxillary sinus, &c. 3. The term cells is applied when the cavities are small, but nu-
merous, and communicating with each other ; as the ethmoidal cells, &c. 4. Channels
{gutters) are cavities which resemble an open semi-cyhndrical canal ; as the channels for
the longitudinal and lateral sinuses of the scull. 5, These take the name of grooves
* [Also from Kopiivt], a wow — like a crow's beak.]
GENERAL OBSERVATIONS. 11
(coulisses) when they are lined by a thin layer of cartilage, for the passage of tendons ;
as the bicipital groove of the humerus. The terra pulley or trochlea is applied to grooves
which have their two borders also covered with cartilage. 6. Furrows are superficial
impressions, long, but very narrow, and intended for the lodgment of vessels or nerves,
as the furrows for the middle meningeal artery. 7. When more deeply excavated than
the last, and angular at the bottom, they are named by the Frencli anatomists Rainures.
8. A notch {incisura) is a cavity cut in the edge of a bone.*
The cavities wliich we have described exist only on one surface of a bone ; those which
perforate its substance are usually denominated foramina or holes.
1. When a foramen has an irregular, and, as it were, lacerated orifice, it is named a
foramen lacerum. 2. When its orifice is very small and irregular, it is called hiatus ;
when the opening is long, narrow, and resembling a crack or slit, it is denominated a
fissure ; as the sphenoidal fissure, the glenoid fissure, &c. 3. If the perforation runs
some way through the substance of a bone, it is called a conduit or canal ; as the Vidian
canal, carotid canal, &c.
There are some canals which lodge the vessels intended for the nourishment of the
bone : these are called nutritious canals. They are divided into three kinds.
The first, which belong exclusively to the shafts of long bones, and to some broad bones,
penetrate the substance of the bone very obUquely. These are the nutritious canals prop-
erly so called. Anatomists carefully point out their situation, size, and direction, in de-
scribing each bone.
The second kind are seen on the extremities of long bones, on the borders, or adjoin-
ing the borders, of broad bones. Cansds of this kind are generally near the articular sur-
faces. Their number is always considerable. Bichat has counted 140 on the lower end
of the thigh bone, twenty upon a vertebra, and fifty upon the os calcis.
The third kind of nutritious canals are exceedingly small, and might be denominated
the capillary canals of bones. They are found in great numbers on the surfaces of all
bones. They may be easily seen by the aid of a good magnifying glass ; their presence
is also indicated by the drops of blood which appear upon the surface of a bone on tear-
ing off the periosteum ; for example, on the internal surface of the cranium, after sep-
arating the dura mater. The diameter of these little canals has been calculated to be
about the l-20th of a line.
The farther progress of the above-mentioned canals is as follows : those of the first
kind, which belong to the long bones, soon divide into two secondary canals, one ascend-
ing, the other descending, and communicating with the central or medullary cavity.
Tliose which are situated in the broad bones form winding passages, which run for a
considerable distance in the substance of the bone.
The canals of the second kind sometimes pass completely through the bone (as in the
bodies of the vertebrae), and they communicate with the spongy tissue. The canals of
the third kind terminate at a greater or less depth, in the compact substance of the long
bones, and in the spongy tissue of the short bones. Such are the forms and general ar-
rangement of all the cavities which exist on the surface of the bone ; the following are
their uses : 1. They serve for the reception and protection of certain organs ; ex., the
occipital fossa;, which receive a portion of the cerebellum. 2. For insertion or surfaces
of attachment, as those on which muscular fibres are implanted, as the temporal and
pterygoid foss£e. 3. For the transmission of certain organs, such as vessels and nerves
which have to pass into or out of an osseous cavity ; such are the fissures, canals, fora-
mina, &.C. 4. For increasing the extent of surface ; as the sinuses and cells connected
with the organ of smelling, the surface of which they greatly enlarge by their numerous
anfractuosities.t 5. For the easy passage of tendons, and sometimes for their reflec-
tion, so that the original direction of the force is changed. To this class belong the bi-
cipital groove of the humerus, that for the tendon of the obturator intemus, &c. They
are generally converted into canals by means of fibrous tissue, which lines and com-
pletes them. 6. For the nutrition of bones, such being the use of the three orders of
nutritious canals already described. We must mention, along with these osseous cavi-
ties, other markings or impressions seen on the surface of many bones ; for example,
the shallow depressions in the lower jaw bone for the sub-lingual and sub-maxillary
glands, the impressions named digital on the internal surface of the cranium.
As the eminences of bones have been attributed to the mechanical effect of muscular
traction, so the various impressions and VEiscular furrows upon the internal surface of
the cranium have been considered to be the result of pressure and pulsation ; but it
would be more correct to limit ourselves to the simple statement, that the impressions
and eminences on the inside of the cranial bones exactly correspond with the elevations
and depressions on the surface of the brain, and also that the osseous furrows for the
middle meningeal artery correctly represent the ramifications of that vessel.
* [There is great latitude amo!ig anatomical writers in the use of these terms.]
t [Whatever other purpose tliey may serve, such cells and sinuses are, in most instances, to be regard-
ed as a provision for increasing the bulk and strength of bones without a corresponding augmentation ol
weight.T
\
12 OSTEOLOGY.
We may here point out certain rules to be followed in describing the external confor-
mation of bones. 1 . In describing the surface of a bone, it should be so divided that the
description may comprehend but few objects at a time. Thus, a broad bone is to be di-
vided into two surfaces, into angles and borders, which are to be successively studied.
2. The bone being thus subdivided into regions, each of these is then examined, care
being taken regularly to proceed from one part to its opposite, i. e., to pass from the su-
perior to the inferior surface, and from the anterior to the posterior. This is the only
method which, in a long description, will guard against omissions and avoid tiresome
repetitions. 3. It is also of great importance, in considering the objects presented by
each region or surface, to follow an invariable and regularly progressive order. Thus,
after exposing the objects placed in front, the examination should be continued uninter-
ruptedly from this point backward. 4. In the symmetrical bones, it is advisable to de-
scribe, first, the objects situated in the median line, and afterward those placed lateraDy.
Internal Conformation of Bones. — The tissue of bones, like that of most other organs,
presents the appearance of fibres, whose properties are throughout identical, but which,
by certain differences in their mode of arrangement, give rise to two forms or modifica-
tions of structure. To one of these the name of compact substance has been given ; to
the other, that of sjioncry or cancellated substance. A subordinate modification of the lat-
ter has long been described under the name of reticular tissue.
The spongy or cellular substance has the appearance of cells and areola?, of an irregu-
lar shape and variable size, all of which communicate with each other, and their walls
are partly fibrous, partly lamellar. The compact substance seems to consist of fibres
strongly compressed, so as to form a close, firm tissue. It is both fibrous and areolar.
By means of careful inspection, softening the bone in nitric acid, and studying its devel-
opment, it has been clearly proved that it is fibrous, and that in long bones the fibres are
arranged longitudinally, v.hile in broad bones they seem to diverge like rays from the
centre to every part of the circumference ; and that in the short bones they are disposed
irregularly, so as to form a superficial layer or crust. The researches of Malpighi have
conclusively shown that it is also areolar or spongy. By examining a bone softened by
nitric acid, or studying it in the fcetal state, it may be seen that, in fkct, the compact tis-
sue is nothing more than an areolar substance, the meshes of which are extremely close
and much elongated. Accidental ossifications, and the diseases of bone which so fre-
quently exhibit the compact tissue converted into spongy, and the spongy changed into
compact, complete the demonstration.*
In strictness, therefore, but one form of osseous tissue can be admitted, namely, the
areolar, which presents itself under two aspects, sometimes being close, compact, and
fasciculated ; sometimes spongy and cellular. Having thus become acquainted with these
two forms of osseous tissue, their general arrangement in the different kinds of bones is
next to be examined.
Internal Structure of Long Bones. — A vertical section of a long bone presents, in the
body or shaft, a cylindrical cavity, which, in the fresh state, is filled with a soft, fatty
substance, named the marrow. This cavity, or medullary canal, is of greatest diameter
at the middle of the shaft ; and, as it recedes from this point, it is narrowed and inter-
sected at various parts by lamellae detached from the sides, and forming a sort of incom-
plete partitions. Sometimes, however, there is a complete partition ; thus, I have seen
the cylinder of a femur divided into two distinct halves by a horizontal partition situa-
ted precisely in the middle of the bone. The medullary canal is not regularly cylindri-
cal, nor does it correspond in figure with the external surface of the bone. It commu-
nicates with the exterior by means of the nutritious canals, which sometimes run, for a
considerable distance in the substance of the bone, parallel to the medullary cavity, with
which they communicate by numerous apertures, and transmit the vessels as far as the
extremities of the bone. Some have supposed that the cavity existed only in order to
receive the man-ow, while, on the other hand, it has been maintained that the marrow
existed only to fill up the cavity. Whatever be the uses of the marrow, it is certain
that the existence of a cavity in the centre of long bones is an advantageous provision
for strength ; for it is proved in physics, that, of two cylinders, composed of the same
material in equal quantity, the one which is hollow, and whose diameters are, conse-
quently, greater, will offer greater resistance than that which is solid. By the contri
vance, therefore, of the medullary canal, there is an increase of strength without aug-
* [The description in the text applies to the more obvious structure of bone ; but, when examined with the
microscope, the osseous substance, both compact and spongy, is seen to consist of exceedingly fine lamell»
laid on one another. In the compact external crust of bones, these lamellae run parallel with the surface ;
they also surround, concentrically, the small cavities of the compact substance aad the cells of the spongy
texture, the parietes of which they form. They are not to be confounded with the coarser layers and plates
described in the compact substance by Gagliardi, Monro, and others of the older writers. Along with the la-
mellce there are minute, opaque, white bodies, with extremely fine lines irregularly branching out from thera.
These bodies, which can be seen only with the aid of the microscope, are named the osseous corpuscules ;
they obviously contain ralcareous matter, and are, probably, minute ramified cavities lined with earthy salts.
The earthy matter of bone, however, is not confined to the corpuscules, for the intermediate substance is
»lfx) impregnated with it. For a representation of the minute structure of bone, see Mullefs Physiology,
translated by Baly, pkte 1.]
GENERAL OBSERVATIONS. 13
mentation of weight. There is another advantage in this arrangement, viz., the in-
crease of volume without corresponding increase of weight ; for, since the bones are
intended to give insertion to numerous muscles, it is necessary that their surfaces
should not be reduced to too small dimensions ; but this must have been the result had
the walls of the hollow cylinder been compressed so as to form a solid rod. The mar-
row consists of two distinct parts : 1. The medullary membrane, which lines the walls
of the canal. 2. The fatty tissue, properly so called, or the medullary hquid.
The membrane, highly vascular, serves to nourish the internal layers of the bone : it
possesses great sensibility and a high degree of vitality. The fatty tissue, on the con-
trary, is altogether insensible. If a probe be introduced into the centre of the meduUa
of a long bone in a living animal, no sign of pain is evinced so long as the instrument does
not touch the walls of the cavity ; but whenever the walls are rubbed or scratched, the pain
becomes excessive, and is manifested by piercing cries and violent struggles.
The proportion between the thickness of the walls of the cylinder and the diameter ot
the medullary canal varies not only in different individuals, but in the same person at dif-
ferent periods of life. In the aged, the thickness of the walls is proportionally much less
than in the adult : this is one cause of the great fragility of the bones in old age. Some-
times in the adult the walls are so thin, that the bone breaks by the slightest force : in
such cases, there is in some sort hypertrophy of the medulla and atrophy of the bone.
It is in such cases that fractures occur from the simple effect of muscular contraction,
or even from moving in bed.
It is in the central canal of long bones that those very deUcate osseous filaments are
observed, which, interlacing with each other, and forming large meshes, give rise to that
variety of spongy tissue wliich has received the name of reticular, and which appears in-
tended to give support to the medulla. The compact tissue diminishes, and the cells
increase in number, the greater the distance from the centre of the bone, so that the ex-
tremities are entirely composed of spongy substance covered by a thin layer of compact
tissue. It appears that the compact tissue which fonns the shafts of the bones divides
and subdivides into lamellae, in order to form the cells of the extremities. It is easy to
perceive the advantage of a spongy structure in the usually voluminous extremities of the
long bones : they could not have been compact without a great increase of weight, while
the additional strength thus acquired would have been redundant, and altogether useless.
The cells of the spongy substance are filled by an adipose tissue, similar to that which
exists in the bodies of long bones : from its greater fluidity, it has been denominated
meiullary juice.
Internal Structure of Broad Bones. — If the surface of a broad bone be scraped, or if the
bone be sawn across perpendicularly or obliquely, it will be found to consist of two lamellcB
or tables, separated by a greater or less thickness of spongy tissue. Hence the two plates
are insulated, and one may be fissured or broken without injury to the other. The thick-
ness of the compact laminae and of the spongy tissue is not uniform throughout the whole
extent of a broad bone. At the centre, for example, there is scarcely any spongy tissue,
and hence the transparency of the bone at this part. Towards the circumference, on
the contrary, the spongy tissue forms a very thick layer.
In the bones which form the vault of the cranium, the spongy substance takes the
name of diplo'e {6in?.6og, double), because it occupies the interval between the two tables.
From what has been said regarding the internal structure of broad bones, it is evident
that their distinctive character depends as much upon their internal as their external
conformation, and therefore the ribs, which, according to their external characters, seem
rather to belong to the long bones, have been classed among the broad, because they
exhibit in their internal structure the characters of the latter kind of bones.
Internal Structure of Short Bones. — The extremity of a long bone, if separated from the
shaft, would represent a short bone, both in its external and internal conformation ; for
a short bone is a spongy mass, covered by a thin layer of compact tissue. To their spongy
structure the short bones, as well as the extremities of the long, owe their specific lightness.
It should be observed, that what has been said concerning the internal structure of
bones applies, in strictness, only to those of the adult, because the younger the subject, the
less are the cells of the spongy tissue developed. And, in like manner, as the walls of the
cylinder of long bones diminish in thickness, and the medullary cavity increases in diam-
eter in the aged, so by the progress of age the walls of the cells become extremely thin,
and the cells themselves very large. In some cases of disease, for example, after white
swelling of the ankle-joint, I have observed true medullary canals in the cuboid bone
and calcaneum ; and I have remarked in one case of cancer of the breast, that the ribs
adjoining the tumour were hollowed out by a sort of medullary canal. It is to this dimi-
nution of the osseous substance, this kind of atrophy of the bone, that I am disposed to
attribute the fragility so often observed in the whole osseous system in cancerous diseases.
Chemical Composition of Bones. — The bony tissue consists essentially of two distinct
elements, one inorganic, the other organized. When a bone is subjected to the action
of dUute nitric acid, the salts are removed ; it becomes flexible and elastic like cartilage,
and though retaining its original bulk and form, it is found to have lost a great part of
T^ OSTEOLOGY.
its weight. By this process its saline ingredients have been dissolved, and nothing re-
mains but its organic constituents, which, being subjected to boiling, present all the
characters of gelatine.
On the other hand, if a bone be calcined, the whole of its organic matter is destroyed,
giving out during the process the odour of burned horn. A substance remains which
preserves exactly the shape and size of the original bone, but at the same time is very
light, porous, and so friable that it crumbles to powder under the slightest pressure. If
the calcination be complete, the bone is rendered perfectly white, but it is black when
the burning has not been carried sufficiently far ; it m^y even be vitrified by a more in-
tense heat applied for a longer time. Prolonged exposure to the action of air and moist-
ure in like manner remove the organized substance, and leave only a calcareous residue.
The two elements of bone do not bear the same proportion at different ages. Certain
diseases greatly affect the predominance of one or the other, producing almost the ssune
effects as chemical agents.
To the inorganic matter the bones owe their hardness and durability ; to the organized
substance they are indebted for their vitality and the slight degree of flexibility and elas-
ticity which they possess.
The following are the results furnished by the cKemical analysis of M. Berzelius :
1. Okganized Part \ ^ Animal matter reduced to gelatine by boiling . 32-17
12. Insoluble animal matter rlS
{Phosphate of lime 51'04
Carbonate of lime ....... ll'SO
Fluate of lime 2'0
Phosphate of magnesia ri6
Soda and chloride of sodium 1"20
The bones are furnished with vessels : by one set arterial blood is transmitted, by
another venous blood is returned.
1. The arteries are of three orders, corresponding with the osseous canals, which have
been described in speaking of the cavities of bones.
First Order, or Arteries of the Medullary Canal of Long Bones. — In each medullary canal
there is at least one principal artery which enters by the nutritious canal and divides
almost immediately into two branches, one ascending, the other descending. These
subdivide into an infinite number of small branches, the interlacements of which form
that vascular network called the medullary membrane. With this network the vessels
of the second order freely anastomose after their entrance at the extremities of the bone.
In consequence of this important communication, the vessels, notwithstanding the great
difference in the manner of their entering the bone, can reciprocally supply each other
with blood. In illustration of this, Bichat relates a singular case, in which the nutritious
foramen of a tibia was completely obliterated, and yet the nutrition of the bone was un-
impaired. The medullary artery gives off the twigs for those layers of compact tissue
which form the parietes of the medullary cavity.
The arteries of the second order, destined for the spongy tissue, enter the bones by the
nutritious foramina of the second order ; but their number by no means corresponds with
that of the foramina, which are for the most part destined for the transmission of veins.
These arteries communicate hoth with the medullary artery already mentioned and vdth
the arteries of the periosteum.
The arteries of the third order, or the periosteal arteries, are exceedingly numerous. This
class comprehends the innumerable httle arteries which, after ramifying in the perioste-
um, enter the bone by the minute canals of the third order. These small vessels, spe-
cially distributed to the exterior layers of compact substance, anastomose with the two
preceding orders of vessels.
2. The veins of bones follow the course of the arteries. But there are peculiar venous
canals in the interior of the broad and the short bones, and in the spongy extremities of
the long bones. These canals were first described by M. Dupuytren in the cranial bones,
where they are very obvious : they are perforated with lateral openings, by which they
receive blood from the adjoining parts ; their parietes are formed by a very thin plate of
compact tissue, and they are lined by a prolongation of the internal membrane of the
veins. We shall afterward see that there is a complete analogy between these venous
canals and the sinuses of the dura mater, the only difference being in the nature of their
parietes, which are fibrous in the sinuses, but bony in the canals in question. I have
remarked, that in the foetus and new-bom infants, the cells of the spongy tissue, which
subsequently contain adipose matter, are filled with venous blood.
Lymphatic vessels have not yet been actually demonstrated in the bony tissue ; but it
is probable that they really exist there ; at least, the process of nutrition in bones, and
certain morbid phenomena which they present, lead to the beUef of their existence.
The cellular tissue also enters into the composition of the bones : it contributes to form
their fibrous structure.
Nerves can be demonstrated in connexion with most of the bones of the skeleton.
But it is necessary to distinguish those nerves which merely pass through the bones
from those which are distributed on their substance.
DEVELOPMENT OF BONES. J|^
Development of Bones, or Osteogeny.
From the time of their first appearance in the foetus, to the period of their complete
development, the bones pass through a series of changes, which constitute one of the
most important circumstances in their history. The investigation of these changes, or
of the successive periods of development, is the object o{ osteogeny.
The development of the bones, considered generally, presents three phases or periods,
designated by the name mucous, cartilaginous, and osseous stage.
1. The mucous stage. The mucous condition, the cellular of some authors, has not
been well defined. Some apply the term to that period of formation in which the bonea
and the other organs of the body form but one homogeneous mass of a mucous aspect
others use the term to signify a more advanced stage, in which the bones, acquiring a
greater consistence than the surrounding parts, begin to show their development through
these more transparent tissues. In the latter sense, the mucous stage is obviously no-
thing but the commencement of the cartilaginous, and therefore the first acceptation is
the only one to be retained.
2. The cartilaginous stage succeeds the mucous, though the time of the transition from
the one to the other has not been precisely ascertained. Several anatomists are of opin-
ion, with Mr. Howship, that the cartilaginous state does not necessarily intervene be-
tween the mucous and osseous conditions ; that its occurrence is only satisfactorily de-
monstrated in such bones as are late in ossifying, and that it constitutes a sort of provis-
ional condition, in which the cartilage is employed to perform the office of bone. Bui
when we take into consideration, in the first place, the rapid transition from the cartila-
ginous to the osseous stage in certain bones, and, secondly, the translucency of newly-
formed cartilage when of inconsiderable thickness, as in the cranium, where the carti-
lage is scarcely to be distinguished from the two membranes between which it is placed,
we can conceive that the cartilaginous stage may easily have been overlooked. On the
other hand, the constant result of my observations proves that, in the natural process of
ossification, every bone passes through the state of cartilage.
When the different pieces of the skeleton assume the cartilaginous condition, the
change occurs throughout their whole substance at once. The notion of central points
of cartilaginification, corresponding with the points of ossification, is purely hypotheti-
cal : a bone becomes cartilaginous in all parts simultaneously, and never by insulated
points. The cartilage has the same figure as the future bone.
Bones which are to be permanently united by intermediate cartilage, are formed from
m ;. imitive piece of cartilage, as those of the cranium and face : those, on the other
haau, which are connected together only by ligaments, are distinct and separable while
in the cartilaginous -state.
3. The osseous stage. The cartilaginous condition of the skeleton is completed by
the end of the second month ;* but ossification conunences in several places long before
this period. The first point of ossification appears after the fourth week in the clavicle ;
the second, in the lower jaw. From the thirty-fifth to the fortieth day points of ossifica-
tion appear sometimes successively, in other cases simultaneously, in the thigh-bone,
the humerus, the tibia, and upper jaw-bone. From the fortieth to the fifty-fifth day,
points of ossification appear at short intervals in the annular portion of the uppermost
vertebrse, in the bodies of the dorsal vertebrae, in the ribs, the tabular bones of the scull,
the fibula, the scapula, the ilium, the nasal, palatine, and metacarpal bones, the phalan-
ges of the fingers and toes, the metatarsus, &c. Once commenced, the ossification pro-
ceeds with more or less rapidity in the different bones during the remainder of intra-
uterine hfe.
In the child at birth, the shafts of the long, as well as the broad bones, are far advan-
ced in development. As to the short bones, the vertebrae are scarcely less early in their
evolution than the long and broad bones ; the calcaneum, cuboid, and sometimes the as-
tragalus, have points of ossification, but only commencing. The extremities of the long
bones, with a single exception, the lower end of the femur, are as yet without ossifying
points. The remaining short bones and extremities of long bones ossify subsequently.
Of the tarsal bones, the scaphoid is the last to ossify ; the pisiform is the latest among
the carpal bones ; the patella is ossified at the age of three years.
In regard to the process of ossification, a question of the highest interest presents it-
self, viz.. Is the successive appearance of the centres of ossification governed by any general law?
The order of commencement of the points of ossification is in no way dependant on
the size of the bones. It is true that the smaller bones, excepting the ossicles of the
ear, are later in appearing ; but, at the same time, it is not the largest bones that are the
earliest ; thus, the bones of the pelvis appear long after the clavicle.
* [The relative time of ossification of the different bones, or, at least, the order in which it commences in
them, is easily determined ; but owing to the uncertainty respecting the age of the embryo in its early stages,
the absolute time of foetal life at which each bone begins to ossify is very uncertain, and, accordingly, the
statements of many anatomists differ from that given in the text : thus the seventh week is assigned by some
as the period when ossification commences in the clavicle. The age fixed by the author appears too early.]
16 OSTEOLOGY.
Proximity to the heart or great vessels has no effect on the precocity of development.
Though the ribs vt'hich are near the heart ossify speedily, the breast-bone, on the other
hand, which is still nearer, is one of the bones latest in ossifying. Again, the anterior
and inferior angle of the parietal, which is close to the anterior branch of the middle
meningeal artery, is the part of the bone which last ossifies. The femoral artery lies on
the confines of the os pubis and ilium, which at that part long remain cartilaginous.
The true law which governs the order of appearance of the points of ossification is
this, viz., that the period of formation is earlier or later in the several bones according
to the period at which they are required to fulfil their oflice in the economy. Thus, the
jaws being required to act immediately after birth, are ossified before the other bones of
the head. In the same way, the ribs, destined for a function which must commence
from the moment of birth, are for this purpose completely ossified : the vertebrae and
bones of the cranium appear early, because of their use as protecting the spinal cord and
brain ; and it is thus that the pretended correspondence between the rapidity of ossifica-
tion and proximity to the nervous centres is explained.
Although several of the bones are completed solely by an extension of the primitive
nuclei of ossification, the greater number acquire, in addition to these principal or es-
sential pieces, complementary points of ossification named epiphyses. Thus, while in
the frontal the two original points of ossification suffice by their extension for the- com-
pletion of the bone, the vertebrse, on the other hand, have three primary osseous nuclei,
one for the body, and two for the laminae and processes ; and five complementary pieces
of ossification, namely, two for the body, and one each for the tips of the spinous and
transverse processes.
The transition from the state of cartilage to bone is attended with the following phenom-
ena : the cartilage becomes more dense ; its colour is at first a dull white, but subse-
quently changes to deep yellow ; small irregular cavities are formed in its substance ;
red vessels show themselves ; a bony point appears in the midst of these vessels, and
this bony nucleus is spongy and penetrated with blood. The ossification spreads by lit-
tle and little, always preceded by a great development of vessels ; so that, in attentively
examining an ossifying cartilage, we find first an osseous point, then a red zone, next
an opaque layer of cartilage which is permeated by canals, and, lastly, the remaining car-
tilage traversed only by a few vascular canals which run towards the point of ossifica-
tion. Moreover, it is always at some aepth within the substance of the cartilage that
the first osseous points appear, and never at the surface. It is only in cases of accident-
al or diseased ossification, as in the cartilages of the ribs, that it occasionally begins at
the surface. It is unnecessary to pursue farther the immediate process of ossification •
nor need we here discuss the purely speculative question, whether the bone is really a
new part essentially distinct from the cartilage, which is absorbed and gives place to it,
or merely a deposite of earthy phosphate in a cartilaginous tissue.
In admitting that ossification is always preceded and accompanied by a great devel-
opment of vessels, a fact proved incontestably by Haller and Bichat, I must, neverthe-
less, decidedly dissent from the opinion that the appearance of blood in a cartilage is a
constant indication of approaching ossification; for several cartilages have naturally
bloodvessels, as may be seen in the cartilages of the ribs and larynx.
Tlie study of the development of the bones does not consist merely in determining the
number and time of appearance of their points of ossification : it comprehends, also, the
ulterior changes which take place in the osseous system, viz., the union of the primitive
points of ossification, and the appearance and junction of the complementary points of ossifica-
tion. It is to be remarked, that the order of development and union of the points of os-
sification does not always correspond with that in which they originally appear ; nay, it
is often the reverse. Thus, the lower epiphysis of the femur is the earliest in appearing,
and it is the last in joining ; while, on the other hand, the upper end of the radius is one
of the latest of the epiphyses in appearing, but is joined to the bone before all, or nearly
all, the rest. The junction of the pieces of ossification is not complete till about the age
of twenty-five years, at which time the lower epiphysis of the femur unites with the body
of the bone.
General Mode of Ossification of Eminences and Cavities. — M. Serres, in a very remarka-
ble work, has given, under the title of General Laws of Osteogeny, the results of his ob-
servations concerning the development of azygos or median bones, and of eminences
and cavities ; and with a rapid notice of these, we shall conclude what is to be said on
the points of ossification.
1. By the law of symmetry, which, according to M. Serres, governs the development
of all bones situated on the median line, every such bone is originally double, that is,
composed of two separate halves, which, advancing to meet each other, are at last join-
ed. Thus there are originally two osseous halves of the spinal column, and two demi-
sterna. The basilar portion of the occipital, the body of the sphenoid, the cribriform
plate of the ethmoid, the vomer, and the spinous processes of the vertebrae, have, ac-
cording to this view, originally been double. But this law has many exceptions. Thus,
although some of the pieces of the sternum are conunonly formed from two lateral
DEVELOPMENT OF BONES. iT
points, the first and the last are always, or almost always, developed from a single point
in their middle. The bodies of the vertebrae are most commonly formed from a single
primitive nucleus : the same is the case with the basilar portion of the occipital, the per-
pendicular plate of the ethmoid, the vomer, and the spinous processes of the vertebrae.
Instances of incomplete division of bones on the median Une must not be adduced in
proof of the existence of two primitive points of ossification.
2. Every eminence, according to M. Serres, is developed by a special point of ossifi-
cation. This is true generally : but how many eminences are formed merely by the ex-
tension of ossification from the piece which supports them ! Where, it may be asked, is
the special point of ossification for the articular processes of the vertebrae, the coronoid
process of the ulna, the external and internal protuberances of the occipital, &c. 1 There
are even double eminences developed from a single point, £is the condyles of the femur.
SPEvery cavity is formed by the union of at least two pieces of ossification ; so that,
when a bone furnished with a cavity consists of several pieces, the place of junction of
these pieces is at the cavity. Thus, the three pieces of the os innominatum meet together
at the cotyloid cavity. The same law, according to M. Serres, regulates the formation
of the foramina and osseous canals of every kind, as the medullary cavity of the long
bones, all the canals for vessels and nerves, as the carotid, vidian, &c. : according to
the same law, all the foramina in the bones of the scuU are formed originally of two
halves. But the facts are opposed to this doctrine when applied so universally.
Progress of Ossification in the three Kinds of Bones. — 1. In the loTig hones. Ossifica-
tion commences in their middle part. A small cylinder of bone appears, narrow in the
middle, expanded at the ends, tubular within, perforated already with the nutritious fo-
ramen, which is very obvious, and receives very large vessels. This Uttle cylinder grows
gradually thicker and longer, extending towards the extremities of the bone, which it
reaches about the time of birth ; while at this period the ossification is so far advanced
in the body of the long bones, their extremities are not yet osseous. It is only at later
periods, varying in different bones, that an osseous nucleus appears in the cartilaginous
extremities, increasing and encroaching upon the portion of cartilage which separates it
from the bony shaft, until that cartilaginous partition, gradually becoming thinner, is at
last itself invaded by the ossification. All the long bones have two essential or princi-
pal epiphyses, to which complementary epiphyses are sometimes added. The phalan-
ges* are an exception ; they have only one. It is this process which is named junction
of the epiphyses. The time of its completion is not confined to any very definite limits,
but it is over by twenty or twenty-five years.
Throughout the whole time of development the growth in length takes place, chiefly
by ossification of the intermediate cartilage, which separates the epiphyses from the
shaft, but partly, also, by longitudinal expansion of the ossified shaft itself The former
mode of increase has been satisfactorily established by Hunter ; the latter is proved by
the following experiment of Duhamel : Three needles being fixed in the shaft of a long
bone of a bird, at measured distances, it is found that after a certain time they become
farther separated, which proves that the osseous cylinder has undergone an elongation.
2. In the broad bones. 1. Among the broad bones, those which are symmetrical often
conmience by two points placed one on each side of the median line. 2. The asymmet-
rical bones are developed sometimes from a single point of ossification, as the parietal ;
sometimes by several, as the temporal.
One of the most remarkable circumstances in the development of broad bones is the
sort of radiation by which the deposition of calcareous phosphate extends, which spreads
from the centre where the first osseous point was deposited, and advances by divergent
rays to all points of the circumference, forming bony striae separated by intervals, which
are soon filled up by new osseous rays. As these rays are of unequal length, and are
separated at the circumference by intervals of greater or less extent, it follows that a
broad bone in the process of ossification must have at its circumference a scalloped or
jagged border, like the toothed edge of a comb. It is this form of ossification which
gives rise to the serratures of the sutures.
The broad bones are proportionally much thinner in the early periods of ossification
than subsequently, because at first the spongy texture is scarcely developed. At the
time of birth, the primary pieces of ossification not having united except in very few
places, and the ossification which spreads from the centre of the bones not having yet
reached the limits of their circumference, it follows that the constituent parts of bones,
and the edges of different bones which are destined in the end to meet together, are at
this period separated by cartilaginous, and, in some measure, membranous intervals,
which in the cranium constitute the fontanelles. After birth, ossification spreads more
and more in the broad bones ; at the same time they increase in hardness and thickness,
appearing as if to separate into two plates or tables, the interval between which be-
comes filled with spongy tissue.
The epiphysary or complementary points of ossification of some of the broad bones
* [Also the clavicle, the metatarsal, and usually the metacarpal bones.]
c
1 8 OSTEOLOGY.
represent, in a certain degree, the epiphyses of the long bones. They occupy the cu-
cumference, and are thence named marginal epiphyses. Thus, in the cartilaginous bor-
der of the haunch-bone, which represents the crest of the ilium, a point of ossification
commences, and extending along its whole length, forms a marginal epiphysis, which
subsequently joins the rest of the bone, and in this respect is perfectly analogous to the
epiphyses at the extremities of the long bones. The epiphyses, then, are not an exclu-
sive attribute of the long bones, as Bichat maintained. They are found, also, in some of
the short bones. But it would be indulging in a false analogy to class the Wormian
bones, formed during the development of the cranium, with the epiphyses of the long
and the broad bones ; for they have peculiarities which are never found in true epiphy-
ses. Thus, 1. They are not joined by osseous union, as is the case with epiphyses, but
always by suture. 2. There is no constancy in their time of appearance, nor in ^eir
figure, which is irregular, nor in their size, which is, in general, greater the earlierlftey
have appeared, because they have then had longer time to extend themselves before
meeting the neighbouring bones.
From what has been said, we conclude that the broad bones have a twofold mode of
mcrease in breadth, namely, the successive addition of bony substance to their borders,
and the formation of marginal epiphyses. In every broad bone which is formed from
several pieces, and which has on its surface a part for articulation, this last becomes
the centre in which the different pieces meet, and are ultimately joined when the ossi
fication is completed.
3. In the short bones. These are the latest in being ossified ; a great number of them
are still cartilaginous at birth. The short bones are not destitute of epiphyses, as is
proved by the ossification of the vertebrae and calcaneum. Their ossification, in fine,
presents the same phases, and follows the same progress, as that of the extremities of
the long bones, which they resemble in so many respects.
Changes which take place in Bones after Maturity.
To obtain a complete notion of the development of the bones, we must not rest satis-
fied with ascertaining the number of points of ossification, their successive appearance,
and their mode of junction ; we must also study the changes which they undergo after
they have attained their full growth.
The increase of the bones in height teraiinates when their several pieces have become
united : the time when this is accomplished varies from the age of twenty to thirty
years ; but they continue to increase in thickness for a considerable time longer. In
proof of this, we need only compare the bones of a young man with those of an adult of
forty. In old age the bones still undergo important changes : the medullary canal of the
long bones augments in width, and the tliickness of its parietes diminishes in proportion ;
and something similar takes place in the broad and the short bones.
Another important fact to be here mentioned is, that the relative proportion of calca-
reous phosphate and animal matter undergoes continual changes in the course of life.
Thus, by an analysis of Dr. I. Davy, it was shown that the proportion of calcareious phos-
phate was a fifth less in a child of fifteen years than in the adult. The same chemist
found that the proportion of phosphate of lime in an adult occipital was to that in an
occipital bone of an aged person as sixty-four to sixty-nine.
JSTutrition of Bones.
The fact of the nutrition of bones, and the process of composition and decomposition
in which it consists, appear to me to be demonstrated by the experiment with madder.
If an animal is fed for some time with food impregnated with thfe juice of madder, its
bones soon become coloured red, as may be ascertained by ampirfttfang a limb ; but, by
suspending the use of that substance for some time, the bones recover their natural col-
our. In this experiment, there is no doubt that the calcareous phosphate is the vehicle
of the colouring matter, for the bones are the only parts that become coloured ; aU that
is cartilaginous remains free from colour. We may infer from this that a twofold move-
ment continually goes on in bones, by which new molecules are first deposited and then
removed, after they have for a longer or shorter period formed part of these organs.*
The administration of madder, moreover, demonstrates a fact, which was proved by
Duhamel du Monceau in a very curious set of experiments, namely, that the growth of
bones takes place by the successive deposition of new layers, formed by the undermost
or contiguous layers of the periosteum. Thus, let a pigeon be fed with food impregnated
with madder, suspend the use of the madder for a time, then renew it ; after this, the
bones, when cut through, exhibit a red layer next their surface, then a white layer, then
a red layer again.
Thus the bones grow in two ways, namely, by the interstitial mode of groAvth, or by
intussusception, which they have in common with the other tissues ; and, secondly, by
juxtaposition.
* A somewhat subtle objection would be the following : May not the colouring matter be deposited and
again carried off without the particles of phosphate of lime being necessarily subject to the same vicissitudes !
THE VERTEBRAL COLUMN.
19
THE VERTEBRAL COLUMN.
Gene-al Characters of the Vertehra. — Characters peculiar to the Vertehra of each Region.
— Characters proper to certain Vertcbree. — Vertebrae of the Sacro-Coccygeal Regvm. — Tht
Vertebral Column in general. — Development.
The vertebral column (from the Latin word vertere, to turn, because ^' *•
the body turns round this as an axis), spine, or rachis, is that long, flex- c _; <i
ible, hollow, bony stem, the principal lever of the body, which affords
support to almost the entire skeleton, and, at the same time, shields
and protects the spinal marrow. It is situated at the posterior and
median portion of the trunk, extending from the cranium to the pelvis,
where it terminates in two osseous pieces, tiie sacrum and coccyx,
which may, in fact, be regarded as a continuation of the column. The
sacrum and the coccyx have been separated from the vertebral column
merely on account of the osseous junction of the vertebrae of which
they are composed.* It is articulated with the base of the cranium
at the part where the posterior joins the two anterior thirds of this
cavity : it corresponds with the posterior portion of the pelvis, an ar-
rangement most favorable for maintaining the erect position.
The vertebral column is situated behind the alimentary canal in
man, above it in the lower animals. In front are suspended the or-
gans of respiration and circulation, to which it affords protection, and
which constantly tend to incline it forward : to its sides are attached
the ribs and the extremities, the thoracic having an indirect and
movable, the abdominal a fixed connexion.
From the limits here assigned to the vertebral column, it follows
that this part of the skeleton extends the whole length of the trunk,
forming the entire osseous support of the neck and loins, the poste-
rior column of the thorax, and even the posterior wall of the pelvis.
Hence it is divided into four regions, viz., a cervical, a dorsd or tho-
racic, an abdominal, and a pelvic or sacro-coccygeal region.
The vertebral column (fig. 1) is composed of twenty-six bones
piled above each other : the last two have received the names of
sacrum and coccyx, and the others, which constitute the vertebred col--
umn, properly so called (a d), are denominated vertebra : they have
also been called true vertcbree, as distinguished from the false vertc-
bree, which, by their osseous union, form the sacrum {d e) and coccyx
(c/). The sacrum is composed of five of these false vertebrae, and
the coccyx of four, in a rudimentary state. The description of these
latter bones will be deferred, in the mean time. The first seven true
vertebrae form the cervical region (a b) ; the twelve which succeed
constitute the dorsal {b c) ; and the last five the lumbar region (c d).
There are occasionally, but very rarely, some variations in the
number of vertebrae. In a few cases only six cervical vertebrae have
been found ; and Morgagni, who first observed this anomaly, consid-
ers it to be a predisposing cause of apoplexy, on account of the ac-
companying shortness of the neck, and consequent approximation
of the heart and brain. There are sometimes thirteen dorsal ver-
tebrae : sometimes the fifth lumbar is united to the first sacral, and
there are then only four lumbar vertebra?. In other cases, the first
sacral vertebra is distinct from the rest, and the lumbar portion of the
column then consists of six.
The vertebrae present general characters, which distinguish them / 1^'*^
from all other bones : they have also characters peculiar to each particular region ; and
in each group or region certain vertebrae have individual distinctive characters.
General Characters of the Vertcbree.
Every vertebra {figs. 2, 3, 4, 5, 6, 7) is essentially asymmet-
rical ring, a segment of the cylinder which protects the spinal
marrow, and is, consequently, perforated by a foramen, denom-
inated the vertebral or rachidian foramen {I, fig. 2). As it con-
curs also to form part of a supporting column, it presents a kind
of enlargement or solid cylinder, of which the posterior fifth
has been removed. I'his enlargement is the body of the ver-
tebra (2). Each vertebra gives attachment to numerous mus-
cles, by very marked eminences for insertion — the spinous (3)
and transverse processes (4 4). It is articulated with the other
* The same is true of anchylosis, as of certain differences of form and development, viz., that ihev lead t*
die establishment of varieties, but cannot form the ground of total separation.
Fig. 2.
20
OSTEOLOGY.
vertebrae by four articular processes (5 5), two superior and two injeriar. Lastly, it pre-
sents two superior and two inferior notches {7, Jigs. 4, 5), which unite to form the inter-
vertebral foramiTia, through which the vessels and nerves are transmitted.
Fig. 3. A. The body of the vertebra (2) occupies the anterior portion of
/ ,^, 5 the vertebral ring, and presents /owr surfaces. The superior and
"* ■'"' inferior surfaces are connected with the contiguous vertebra, and
are slightly hollowed for the reception of the intervertebral sub-
stance. This double excavation is the vestige of the deep bicon-
ical cavity, so remarkable in the vertebrae of fishes. The ante-
rior surface is convex transversely, and presents a horizontal
^"*' groove (2, Jigs. 4 and 5), which is deeper laterally than in the me-
dian line, and in cases of abnormal curvature is greater on one side than on the other. This
groove is the rudiment of that circular constriction which exists in the vertebrae of reptUes
and fishes, and in the cervical vertebrae of birds : it has the double advantage of economy,
both as to the weight and the bulk of the bone. The posterior surface is concave, and
forms part of the vertebral canal. It is pierced by numerous foramina of considerable size,
which are the orifices of venous canals hollowed out in the substance of the vertebra.
Smaller foramina of the same nature exist also on the anterior surface.
B. The vertebral foramen {I, fig. 2) exhibits certain variations in form and dimensions
in the different regions of the spine ; but in nearly all the vertebrae it approaches more
or less to the triangular form. The differences which it presents in the extent of its
diameters bear reference partly to the size of the spinal marrow, and partly to the ex-
tent of motion in each region.
C. The spinous process {3, figs. 2, 3, 4, 5) is that eminence of considerable size which
arises in form of a spine from the posterior part of the vertebral arch. It forms a lever
for the extensor muscles of the trunk, and accordingly varies in length, shape, and di-
rection, in the different regions. It bifurcates, as it were, at its base, and passes into the
two lamina (6 b, fig. 2), which constitute the lateral and posterior portions of the arch.
D. The articular processes (5 5) arise from the lateral portions of the arch near its junc-
tion with the body of the vertebra : their direction is in general vertical, i. e., perpendicu-
lar to the direction of the articulating surfaces of the body, which are horizontal. They
are four in number, two superior or ascending, and two inferior or descending ; they are
placed symmetrically on each side of the median line, and are covered with cartilage in
the fresh state, to form a movable joint with the articular processes of the adjacent
vertebrae ; they project beyond the level of the bodies of the vertebrae, so that their artic-
ulations correspond with the intervertebrtd substances. Hence the vertebral column
presents two successive series of articulations : one constituted in front, by the union of
the bodies ; the other behind, by the articular processes.
E. The transverse processes (4 4) are lateral prolongations, which arise from each side
of the vertebral ring, pass horizontally outward, and vary in length and size in the dif-
ferent regions.
F. In front of the articular and transverse processes, immediately behind and at the
side of the body of the vertebra, are four notches cut in the lateral parts of the ring (7,
figs. 4 and 5) : the inferior are generally deeper than the superior, but their depth varies
considerably in the different regions. The part of the vertebral ring between the upper
and lower notches is reduced to a sort of pedicle ; it is the weakest part of the vertebra,
and, consequently, it is the principal seat of torsion in curvatures of the spine. The con-
stituent parts of a vertebra are, therefore, 1. In the median line, the body, the foramen, the
spinous process, and the lamina ; 2. On each side, the articular and transverse processes, the
notch, and the pedicle.
Characters peculiar to the Vertebra of each Region.
^^s- 4. The characters distinctive of the vertebrae of each region
of the spine are most marked in those placed in the middle
of the respective region, for at its extremes the vertebrae
acquire intermediate or mixed characters belonging to the
two regions near the confines of which they are situated. It
may be remarked, that the vertebrae of each region may be
at once recognised by Fig. 5.
one single distinctive
character : thus, the cer-
vical vertebrae are al-
ways known by a fora-
men in the base of the
transverse processes (a,
fig. 2) ; the dorsal vertebrae by facettes hollowed out
on the sides of the bodies (6 6, fig. 4) ; and the lum-
bar {fig 5) by the absence of the two preceding
•Tnarks." The characters just mentioned might, then, suffice as mere distinctive marks, bu*
THE VERTEBRAL, COLUMN.
M
they woiild not answer the purposes of exact anatomical description. Indeed, a vertebra
is cervical, dorsal, or lumbar, rather in virtue of its entire form and structure than by
reason of any single circumstance pertaining to it.
We shaU examine in regular order each part of a vertebra, as it exists in the different
regions.
Bodies of the Vertebrae in different Regions. \:
The first distinctive character is their size. This progressively increases from the cer-
vical to the lumbar region (a, 6, c, d,fig. 1) : taking the size of the bodies of the lumbiir
vertebrae as unity, that of the dorsal would be two thirds, and that of the cervical one half
The second distinctive character is the proportion of the diameters. In all vertebrae the
transverse diameter is the greatest, and the vertical the smallest. In the lumbar verte-
brae the height or vertical diameter is twelve lines (one inch), in the dorsal nine lines
(three quarters of-^ inch), and in the cervical six lines (half an inch). In the cervical
and lumbar regions, the vertical diameter of the body is less behind than before, which
inequality gives rise to the anterior convexity of these regions. In the dorsal region, on
the other hand, the vertical diameter is shortest anteriorly. In the lumbar region, the
transverse diameter does not exceed the vertical and the antero-posterior by more than
one third at most. In the dorsal region no one diameter is strikingly predominant ; but
in the cervical the transverse is almost double that of the antero-posterior and the ver-
tical diameters.
The third distinctive character is formed by the lateral ridges of the bodies of the cervi-
cal vertebra. From the two sides of tlip superior surface of the bodies of the cervical
vertebrae arise two small ridges {fig. 2, on each side of 2), which are received into
corresponding depressions on the inferior surface of the vertebra above. This mutual
fitting-in of the bodies of the cervical vertebrae compensates for the less secure connex-
ion of their articular processes, and which insecurity is, moreover, of less importance,
from the bodies being united by disks of intervertebral substance.
The fourth distinctive character consists in the two demi-facettes on each side of the
bodies of the dorsal vertebra. (6 6, fig. 4). These demi-facettes, when united with the cor-
responding parts of the neighbouring vertebrae, form angular excavations, in which the
posterior extremities of the ribs are received. This character belongs exclusively to the
dorsal vertebrae.
The fifth distinctive character is the excavation of the superior and inferior surfaces of
the bodies, which is less in the dorsal region than in the cervical or lumbar. From this dis-
position it results, that a lenticular space of a much greater size intervenes between
every two of the lumbar and cervical vertebrae than between the dorsal : the mobility is
consequently much increased, from the greater size of the intervertebral substance.
The specific characters, then, of the bodies of the vertebrae in the different regions are
the following : 1. Lateral ridges on the superior surface of the cervical vertebra. 2. Lateral
facettes on the dorsal vertebra. 3. TTie absence of these two characters, and the preponder-
ance of size in the lumbar vertebra. If the body of a vertebra be presented for our inspec-
tion, we can at once determine from these characters the region to which it belongs.
The Vertebral Foramen and the Jfotches in the different Regions of the Spine.
The vertebral foramen and the notches present certain marked distinctions in the ver-
tebrae of the three regions, by which they may be recognised by a practised eye.
1. In the cervical region, the transverse diameter of the foramen {I, fig. 2) considera
bly exceeds the antero-posterior. 2. In the dorsal region, the two diameters are almost
equal, but there is this much which is remarkable, that a very considerable depression
exists on the posterior surface of the body of the bone. 3. In the lumbar region, the
transverse diameter is the greater, but the difference is much less remarkable than in the
cervical. The following is a comparative table of the diameters in the three regions •
Transverse diameter. Antero-posterior diameter.
In the neck, 6 lines
back, 6 lines,
loins, 8 lines.
In the neck, 1 1 lines,
back, 7 lines,
loins, 10 lines.
It may be remarked here, that these differences correspond with the extent of motion
in each region. In the lumbar region, which is more movable than the dorsal, the fora-
men is larger ; and in the cervical region, where the lateral motions are more extended
than in the loins, the transverse diameter is still greater, in the proportion of eleven to
ten. It must be observed, however, that the diameters of the foramen bear reference
not only to the mobility of the part, but also to the size of the spinal marrow.
The notches present also certain differences in the different regions ; thus, in the dor-
sal and lumbar regions (7,figs. 4 and 5), the inferior are much deeper than the superior ;
in the cervical region they are of almost equal depth {fig. 3). It may also be remarked,
that the depth of the notches, and, consequently, the size of the intervertebral foramina.
82 OSTEOLOGY.
are generally proportional, not only to the size of the spinal ganglions, but also to tlie
capacity of the venous canals, which establish a communication between the external
and internal veins of the spine. It is then possible, when only the vertebral foramen
and the notches are seen, to determine the region to which the bone belongs.
The Spinous Processes and Lamincs in the different Regions.
1. In the cervical region, the spinous processes are prismatic and triangular {3, figs. 2,
3), grooved inferiorly for the reception of the spinous process of the vertebra below du-
ring the movements of extension, and bifurcated at their summit, for the purpose of
muscular insertion. Their direction is horizontal, and, consequently, favourable to
extension.
2. In the dorsal region (3, fig. 4) they are prismatic and triangular, with a tubercle at
their summit ; their direction is extremely obhque, approaching to the vertical. This
direction, together with their great length, causes them to descen^tfonsiderably below
the inferior surface of the body of the vertebra. Hence a sort of injBncation, and to such
a degree that a very slight movement of extension causes them to touch each other.
3. In the lumbar region the spinous processes (3, fig. 5) are broad, thick, and quadrilat-
eral, presenting on their sides a large surface for muscular insertion ; their posterior
border is thick, tuberculated, and triangular. Their direction, being horizontal, presents
no obstacle to extension.
The two laminae {b b, fig. 2), which form the posterior arch of the vertebra, are con-
tinuous with the base of the spinous process. Their length is directly proportionate to
the dimensions of the part of the canal to which they correspond, and their thickness is
in proportion to the size of the spinous process'.
1. In the cervical region the laminae are thin, very long, and so inclined that when the
head is erect, i. e., in a position intermediate between flexion and extension, the inferior
edge of the superior laminae passes beyond the superior border of the vertebra below, so
that there is a true imbrication of these laminae, not less marked than that which we
have observed of the spinous processes in the dorsal region. There has been, conse-
quently, no case recorded of the entrance of any penetrating instrument into the spinal
canal, in the situation of the undermost five cervical vertebrae ; which fact is the more
easily conceivable when we reflect that the least impression upon the back of the neck
excites, instinctively, an extension of the head, and thus increases the imbrication of
the laminae. 2. In the dorsal region the thickness of the laminae is greater than in the
neck, but still inferior to that in the loins ; they are comparatively much shorter than in
the cervical region, and, instead of forming an elongated rectangle, they represent a
square — nay, their vertical dimension almost exceeds the transverse. 3. In the lumbar
region they are characterized by great thickness, by diminution of the transverse, and
marked increase of tlie vertical diameter. In general, it may be stated that the height
of the lamina corresponds with the thickness of the body of the vertebra to which it be-
longs ; hence they are so narrow in the cervical region.
To sum up, then, the characters of the spinous processes and the laminae :
1. Cervical Region. — Processes prismatic and triangular, grooved inferiorly, bifurcated
with two tubercles at their summit, horizontal, short, and continuous, with long, narrow, and
thin lamina,, inclined so as to become imbricated. 2. Dorsal Region. — Spinous processes
prismatic and triangular, long, oblique, and tuberculated at their summit, with short vertical
laminae. 3. Lumbar Region. — Spinous processes quadrilateral, strong, and horizontal, with
very sJiort, thick, and vertical lamina. It is possible, then, from the spinous process and
its laminae alone, to determine the region of any vertebra.
The Articular Processes in the different Regions.
In the cervical region (5 5, figs. 2 and 3) the articular processes form small columns,
and are so directed that their articular siu'face makes, with the horizon, an angle of
about 45° ; the superior look upward and backward, the inferior downward and forward.
It is important to remark this direction, because it permits the movements of flexion,
extension, and lateral inclination : it is owing to the same circumstance, also, that lux-
ations of the cervical vertebrae may occur without fracture of their articular processes.
It should be also observed that the articular surfaces of the right and left sides are in
the same plane.
2. In the dorsal region (5 5, fig. 4) the articular processes are simple laminae, the di
rection of which is vertical and the surface plane. The superior look backward and out-
ward, the inferior forward and inward. The articular facette of the right side is not on
the same plane as that of the left.
I should observe that, in certain cases, the dorsal articular processes are found, as it
were, locked together, the extremity of the superior process being received into a deep
notch on the surface of the inferior process of the vertebra above.
3. In the lumbar region (5 5, fig. 5) the articular processes are very strong, with curved
THE VERTEBRAL COLUMN. 23
surfaces. The superior concave look backward and inward, the inferior convex forward
and outward. They both represent two segments of a cyhnder, one of which complete-
ly surrounds the other, or, rather, the inferior resemble half hinges, which are received
into the half rings formed by the superior processes. It should be observed here, that
the superior articular processes are prolonged by certain tubercles, to which the name
of ajpophysary may be correctly appUed, and which serve for the insertion of muscles.
To sum up, then, what has been said : The cervical articular processes are small columns,
cut with plane faces, at an inclijiation of 45°, those of both sides on the same plane ; the dor-
sal are thin lamina, plane and vertical, but not in the same plane ; the lunibar strong, vertical,
and tuicrculated lamincz, with a curved articular surface. The region of any given verte-
bra may be easily recognised from its articular processes alone.
The Transverse Processes in the different Regions of the Spine.
No part of the vertebrae presents more decided variations in the different regions than
the transverse processes.
1. In the cervical region (4 i,Jigs. 2 and 3) they are grooved superiorly for the lodg-
ment of the anterior branches of the cervical nerves ; their base is perforated {a, fig. 2)
for the passage of the vertebral artery ; they have two borders, an anterior and posterior,
to which the inter-transversal muscles are attached ; their free extremity is bifurcated
for the attachment of muscles. It should be added, that these transverse processes, be-
ing on the same plane with the bodies of the vertebrae, double their transverse diameter
in front, and enable them to afford support to a great number of parts.
2. In the dorsal region (4, fig. 4) they are large and horizontal, much stronger than in
the other regions, and twice or three times the size of the spinous processes ; they are
much incUned backward, and the anterior surface of their extremity has a depression
for articulation with the tubercle of the ribs. Some anatomists have attached great im-
portance to the direction of the articular facettes, making it the basis of their notions of
the mechanism of respiration. The important modifications which the transverse pro-
cesses of the dorsal vertebrae present are evidently connected vdth the nature of their
functions, which are not only that of affording points of insertion to muscles, but also of
supporting the ribs with which they are articulated.
3. In the lumbar region, the transverse processes (4, fig. 5) are thin, narrow laminae,
flattened from before backward. They are situated in a plane anterior to that which the
transverse processes of the dorsal vertebrae occupy, and almost correspond with that of
the ribs, with which, also, they have numerous other analogies : hence the name costi-
form processes given them by some anatomists.* The characteristics, then, of the three
kinds of transverse process are, in the cervical region, a grooved projection with a foramen
at the base ; in the dorsal region, a strong process inclined backward, tuberculated, and artic-
ular at the extremity ; in the lumbar region, a small, thin, blunted projection. It is, therefore,
extremely easy to determine the situation of a vertebra by the transverse process.
The truth of what we formerly remarked will be now evident, viz., that a vertebra is
distinguished as cervical, dorsal, or lumbar, by the form of all its constituent parts. Uni-
form in their fundamental type, these bones present, in each region, and in each part,
certain differences adapted to their respective uses.
Characters proper to certain Vertebras.
We have now noticed, 1 . The general characteristics of the vertebrae, by means of
which they may be recognised from all other bones ; 2. The peculiar distinguishing
chraracters of the vertebrae in each region. We have now to examine in each region
those vertebrae which are distinct from all the others of that part of the spine. The
place of each vertebra might, strictly speaking, be determined by comparing it with all
the other vertebrae of the same region : in this way, those who are accustomed to artic-
ulate skeletons acquire surprising readiness. But a few vertebrae only possess suffi-
ciently characteristic peculiarities to determine their situations without comparison with
the others. It is only in the vertebrae at the extremity of each region, and which, on
account of their position, have a mixed character, that such distinctive'and individual
attributes can be observed.
The first, second, and seventh cervical vertebrae, the first, eleventh, and twelfth dor-
sal, and the fifth lumbar, require special description.
First Cervical Vertebra, or Atlas (jig. 6).
In the first vertebra, or atlas, the place of the body is supplied by an arch (a g), flattened
* The description which we have given of the transverse processes is in accordance with that usually foniLd
m works on human anatomy. Several modern anatomists, however, do not admit of the arrangement which
we have adopted. From the existence of cervical and lumbar ribs in the skeletons of many vertebrated ani-
mals, they maintain that in man the anterior half of the cervical transverse processes, and the thin plates of the
lumbar transverse processes, represent the ribs of the dorsal region ; while the parts truly analogous to the
dorsal transverse processes are, 1. In the cervical region, the posterior half of the transverse process ; 2. lo
the lumbar region, those projections which we have called apophysary tubercles.
^ . - OSTEOLOGY.
j^ g from before backward, the wtaerior arch of the first verU'
a ' Irra. Its convexity, turned forward, is marked by a tu-
bercle (a), the anterior tubercle of the atlas. Its concav-
ity, looking backward, presents an oval facette, slightly
hollowed for articulation with the odontoid process of
the second vertebra. The superior and inferior borders
afford attachment to ligaments.
The foramen of the first vertebra is much larger than
that of all the others. The antero-posterior diameter,
^ which in the neck and back is six lines, and in the loins
eight, is here fourteen ; the transverse diameter, eleven lines in the neck, seven in the
back, and ten in the loins, is here thirteen. This remarkable extent of aU the diameters
is not simply owing to the size of the spinal marrow at this point, for the anterior por-
tion of the foramen (/, ^, /) gives lodgment to the odontoid process of the second verte-
bra, so that the antero-posterior diameter of the part which contains the spinal cord does
not greatly exceed that of the foramen in the succeeding vertebrae. The transverse di-
ameter alone is more considerable, whence the possibility of lateral displacements or
incomplete luxations of the first upon the second vertebra without any marked com-
pression of the cord.
The notches (A h) are situated on the posterior arch at its junction with the lateral
masses. They are posterior to the articular processes, while in aU the other vertebrae
they are anterior. The superior are very deep, often converted into foramina by a
bridge of bone, and seem to be continuous with the foramen in the base of the trans-
verse process, by means of a horizontal groove which winds round behind the articular
process. This groove is sometimes almost converted into a complete canal. From the
union of these parts, viz., the notch, groove, and foramen, a twisted canal results, verti-
cal at first, and afterward horizontal, along which the vertebral artery runs in its pas-
sage into the cranium. Through the superior notch, which almost forms by itself the
.first intervertebral foramen, the vertebral artery and vein and the first cervical nerve
pass. The inferior notches present nothing remarkable, excepting that they are sufi5-
ciently deep to form, by themselves, the intervertebral foramina between the first and
second vertebrae.
There is no spinous process : its place is supplied by a posterior tubercle (i) for muscu-
lar insertion, analogous to the anterior tubercle, or, more correctly, resembling a spinous
process truncated. Sometimes, instead of a tubercle, there are only some inequalities.
The posterior arch (A, i, h), which forms more than half the circumference of the verte-
bra, consists of two strong and long plates.
The articular processes or columns, which we have remarked throughout the whole cer-
vical region, are very large in the atlas, and bear the name of lateral masses. This struc-
ture is connected with the use of the bone, which is to support the occipital condyles,
and, consequently, the weight of the head.
Of the four articular processes, the superior (J b) are concave, slanting inward, oval,
and obliquely directed from behind forward, and from without inward. Their form ex-
actly corresponds with the convexity of the occipital condyles (7 7, fig. 10), which they
receive, and for this purpose their external borders and posterior extremities are con-
siderably elevated. Within and below the articular surface are certain inequalities
(//, fig. 6), which give attachment to the transverse ligament. The inferior articular
processes are circular and plain ; they look downward and a little inward.
The transverse processes (c c) are very large and triangular : they have only one tuber-
cle, into which are inserted the principal rotatory muscles of the head : they are per-
forated by a foramen (e) at the base, but are not grooved on their surface.
The characteristics, then, of the atlas are, a7i annular form ; great lateral dimensions,
so that it surmounts the vertebral column like a capital ; a very large vertebral foramen ; no
body, nor spinous process ; large lateral masses, supporting very strong transverse processes,
which are not grooved, and have only one tubercle.
Second Vertebra, ^xis, or Vertebra Dentata {Jig. 7, side view).
The body is surmounted by an eminence {g, a, I, fig. 7), "Which, in the connected skel-
pig_ 7_ eton, corresponds with the anterior arch of the atlas. This em-
inence has received the name odontoid process, or processus den-
tatus, from its tooth-like form. It constitutes a species of cylin-
drical pivot, about half an inch in length, round which the head
turns ; and hence the name axis given to the entire vertebra.
It is attached to the body of the bone by a broad basis, is then
constricted, and terminates superiorly in an enlargement called
the head, which is rough at its summit (a), and gives attachment
[^i to the odontoid ligaments. The contracted portion (l) is called
the neck ; it is the weakest part of the process, and is, conse-
quently, the invEiriable seat of its fractures. This circular cob-
THE VERTEBRAL COLUMN. 25
striction of the inferior part of the odontoid process contributes to maintain it in the
semi-osseous, semi-ligamentous ring in which it turns. Two articular facettes are seen
on this process : one in front {g), corresponding with the anterior arch of the atlas ; the
other behind (at /), for the transverse Ugament.
The body (c) of the axis presents anteriorly a triangular vertical ridge, which separ-
ates two lateral depressions for the attachment of muscles. The posterior surface cor-
responds with the vertebral canal. The greatest diameter of the inferior surface is the
antero-posterior : it is obliquely sloped downward and forward, and slightly concave, for
the reception of the body of the third cervical vertebra. This mutual reception of the
two bones does not take place between any of the succeeding vertebrae.
The foramen is shaped like the figure of a heart on playing cards : its antero-posterior
diameter is eight lines, which is two lines more than in the other cervical vertebrae, and
its transverse diameter is the same. This great size of the foramen of the second ver-
tebra corresponds with the extent of the movements between it and the atlas.
There is no superior notch, the inferior notch of the atlas forming by itself the inter-
vertebral foramen. The inferior notch presents nothing peculiar.
The spinous process {k, m), though of great length, is even more remarkable for its
breadth and thickness, presenting, as it were, in an exeiggerated degree, the characters
of the cervical spinous processes : its form is prismatic and triangular ; it is grooved
inferiorly, and terminates by two tubercles for the attachment of powerful muscles. The
spinous process is for the axis that which the transverse process is for the atlas, both
giving insertion to powerful muscles, which move the head upon the vertebral column.
The lamina, which correspond, as usual, with the size of the spinous process, are re-
markably strong.
The superior articular processes {d) are placed on each side of the body. Their facettes
are broad, flat, and almost horizontal, being slightly inclined outward. This direction
permits the atlanto-axoidean articulation to be the centre of all the rotatory movements
of the head.
The inferior articular processes (e) resemble those of the other cervical vertebrae.
The transverse processes («) are small, with only one tubercle, triangular, bent down-
ward, and perforated at the base by a foramen (/), or, rather, a bent canal, which is hol-
lowed out on each side of the body of the bone ; and is verticed in the first part of its
course, then horizontal. This canal, and that which we have described upon the atlas,
mark the winding course of the vertebral artery before it enters the cranium.
The specific characteristics, then, of the second vertebra are, the odontoid process, the
great size of the spinous process and the lamince, the large size and horizontal direction of
the superior articular processes, which are placed on each side of the body, and the shortness
of the transverse processes, which are triangular, and have one tubercle.
Seventh Cervical Vertebra, or Vertebra Prominens (6, fig. 1).
The body has the ordinary characters observed in the cervical vertebrae, but in size it
resembles that of the dorsal vertebrae, and frequently presents laterally a small impres-
sion for articulation with the head of the first rib. The spinous process bears the greatest
resemblance to those of the dorsal vertebrae : it is pyramidal, terminates in a single tu-
bercle, and is of great length, projecting considerably beyond the level of the other cervi-
cal vertebras ; hence its name of vertebra prominens. The articular processes are almost
vertical, and are not supported by small columns. The transverse process, although groov-
ed and perforated at the beise, as in all the other cervical vertebra, closely approaches
to the characters of the dorsal. The posterior border of the groove, or posterior root of
the process, is thick, tub-^rcular, and exactly similar to a dorsal transverse process, while
the anterior is thin and idimentary, excepting in cases where it is separated from the
body of the bone, and fonns a supernumerary rib. * The foramen in the base of the trans-
verse process is very rarely absent, but is most commonly small : in one case only I have
found it double. It is never traversed by the vertebral artery.
First Dorsal Vertebra.
This vertebra resembles the cervical, in having its body surmounted laterally by two
hook-like processes or ridges, but, in all other respects, it is strictly analogous to the
other dorsal vertebrae. It should be also observed, that the body presents an entire
facette for the first rib, and a third or fourth part of another for the second.
Eleventh and Twelfth Dorsal Vertebrce.
The eleventh dorsal vertebra presents on each side of the body an entire facette for the
eleventh rib. Its body is very large, and the place of the transverse process is supplied
by a tubercle.
The twelfth dorsal vertebra (c, fig: 1) resembles the lumbar in its body, which is scarcely
* This circumstance is one of the facts appealed to with most success by those who make the distinction of
transverse and costiform processes.
D
go OSTEOLOGY.
smaller than that of the lumbar vertebrae, and of which the transverse diameter begins
to predominate. The spinous process is horizontal, strong, and quadrilateral. The
transverse processes are represented by tubercles, which, like those of the preceding
bone, are evidently continued in the lumbar region by those tubercles which we have
denominated apophysary. Lastly, the body presents entire articular facettes. It ia
distinguished from the eleventh dorsal vertebra by the curved surface of the inferior
articular processes.
Fifth Lumbar Vertebra.
The inferior surface of the body slopes very obliquely dowTiward and forward. The
transverse processes vary in size, but are generally much larger than those of the other
lumbar vertebrae ; the inferior articular processes, which are farther separated fix)m each
other, have a flat surface, and look directly forward.
These are the only vertebrae which in each region present peculiarities. Excepting
the first and second cervical, which have many characters quite foreign to the vertebrae
of the region to which they belong, it might be said of those peculiar vertebrae which
have been specially described, that their peculiarities are comprehended in the general
statement that those vertebrae which are placed at the limits of any two regions possess
characters belonging to both regions.
Vertebra of the Sacro-coccygeal Region.
AU the vertebrae of this region, nine in number, are in the adult state united into two
bones : the five superior form the sacrum, the four inferior the coccyx.
The Sacrum (rf, e^figs. 1 and 8).
The scxrum has received its name from the alleged practice of the ancients of ofFering
this part of the victim in sacrifice. It occupies the posterior and median part of the
pelvis, behind the point where this cavity articulates with the thigh bone, an arrange-
ment advantageous for the erect position. It is inserted, like a wedge, between the two
haunch bones. Above, it corresponds with the true vertebral column ; below, with the
coccyx. It is directed obliquely backward and downward ; hence the column represent-
ed by the sacrum forms an obtuse angle with the lumbar column, the projection of which is
anterior. This angle is denominated the promontory, or the sacro-vertebral angle {d, fig. 1 ) :
it is an important object of study, both with reference to the mechanism of standing, and
in the practice of midwifery.* The sacrum is curved upon itself, from behind forward,
so as to present an anterior concavity. It is the largest of all the bones of the vertebral
column ; hence the name of great vertebra applied to it by Hippocrates. It is proportion-
ally more developed in man than in any other mammiferous animal, which is connected
with the erect bipedal attitude and the sitting attitude which belong to him in a special
manner, t The form of the sacrum is that of a quadrangular pyramid with a truncated
apex, the base looking upward. It is symmetrical, like all the median bones, and pre-
sents for consideration an anterior, a posterior, and two lateral surfaces, a base, and a summit.
The anterior, pelvic, or rectal surface {fig. 8) forms part of the cavity of the pelvis. Its
Pig_ 8. concavity varies much in different individuals, and in the two sex-
es : but on this latter point there is great diversity of opinion among
anatomists. Some believe that it is greater in the female, whence,
it is said, results the advantage of a larger capacity of the pelvis,
and, consequently, an increased facility for the passage of the head
of the fcetus during parturition. Others, on the contrary, contend
that the male sacrum is more curved, and that of the female al-
most straight ; and they argue that, had the opposite been the case,
the coccyx, which forms a continuation of the curve of the sacrum,
would have been directed forward, and thus diminished the ante-
ro-posterior diameter of the outlet of the pelvis ; whereas, with a
slight curve of the sacrum, the coccyx has no tendency to project,
but is easily bent backward during labour. J
In order to determine the validity of these opposing statements,
I have compared a great number of sacra from both sexes, but I
could never detect any difference sufficiently marked or constant to be considered as
characteristic of the sex.
* The sacro-vertebral angle is most remarkable in man, because he alone is destined for the erect posture.
By this angle the impetus of movement transmitted from the vertebral column to the sacrum is in part de-
stroyed. In midwifery it explains the rarity of median positions of the vertei
t Birds, -which, like man, are biped, are also remarkable for the size of their sacrum.
t A very great curvature of the sacrum diminishes not only the antero-posterior diameter of the inferior,
but also that of the superior aperture of the pelvis ; and it thus opposes the ascent of the uterus from the true
into the false pelvis. Accouclieurs cannot too carefully study the varieties presented by the curvature of this
bone. The sacrum is often affected by a species of rickets, vrhen the other bones of the pelvis are free from
deformity ; and this fact may be easily explained by a reference to the uses of this bone in suf Dorting the
whole weight of the trunk.
THE VEETEBRAL COLUMN. 27
The anterior concavity of the sacrum is interrupted by four transverse projections (1
1 1 l,Jig. 8), which correspond vi^ith the points of union of the sacral vertebrae, and are
analogous to the intervertebral prominences. The first is sometimes so prominent, that
it might be mistaken for the sacro-vertebral angle in an examination per vaginam.
On each side of the median line are the anterior sacral foramina (2 2 2), four in number,
the two superior much greater than the two inferior. They give passage to the anteri-
or branches of the sacral nerves, to the sacral veins, and some small arteries. External
to these are grooves for the nerves, and the attachment of the pyramidalis muscle. The
anterior surface of the sacrum is contiguous to the rectum, which follows its curvature.
Posterior, spinal, or cutaneous surface. Its convexity is exactly proportioned to the an-
terior concavity. 1. In the median line it presents the sacral ridge, formed by a continu-
ation of the spinous processes of the vertebral column. This is often entire in its whole
length, but sometimes interrupted : it bifurcates inferiorly, and fonns the borders of the
groove which terminates the sacral canal. The sacral ridge is rarely found cleft through-
out its whole length.
2. On each side of the median line are two shallow grooves, named the sacral grooves :
they are continuations of the vertebral grooves ; they are pierced by four posterior saeral
foramina, smaller than the anterior foramina, and differing less from each other in di£un-
eter. These afford passage to the posterior branches of the sacral nerves, to some veins
and arteries. They are bordered by two ranges of unequal projections : the first row,
placed interior to the foramina, represent the articular processes united together ; the
second, external to the foramina, are more marked, and correspond with the transverse
processes also united.
The lateral surfaces {d, e,fig. 1) are triangular, broad above, narrow below, where they
constitute mere borders. They slope obliquely from before backward and from without
inward, so that the sacrum is wedged between the haunch bones in an antero-posterior
as well as in a vertical direction. In front is a demi-oval or crescentic surface (7, fig.
8), compared from its shape to the human ear, and hence denominated auricular surface.
In the fresh state it is covered with cartilage, and articulates with the os innominatum.
Behind it is a very rugged surface with irregular depressions, giving attachment to the
posterior sacro-ihac hgaments. The sinuous border which terminates each lateral sur-
face inferiorly gives attaclunent to the sacro-sciatic ligaments.
The hose presents, 1. In the middle an oval facette (3,^^. 8), in all respects similar to
the body of a lumbar vertebra, with the last of which bones it is articulated. Behind
this is a triangular aperture resembling the foramen of other vertebrae, and completed
posteriorly by two lamince, which unite, and form a spinous process,* the commencement
of the sacral ridge. 2. On each side two triangular surfaces (4 4), smooth, looking for-
ward and upward, and constituting part of the greater or false pelvis. They are separ-
ated from the anterior surface of the sacrum by a blunt edge, which forms, as we shall
afterward see, a portion of the superior aperture of the pelvis. Behind the oval surface
of the body are notches, which complete the last intervertebral foramina ; and behind these
notches are the articular processes (5 5), which resemble the superior articular processes
of the fifth lumbar vertebra, and receive the inferior processes of that bone.
The apex (6) is truncated, and presents a transverse elliptical surface, which articu-
lates with the base of the coccyx. Behind it is the termination of the sacral groove,
bounded by two small apophyses, intended to unite with two similar projections of the
coccjrx. These are the sthoII cornua of the sacrum.
The sacral canal. The termination of the vertebral canal is prismatic and triangular,
wide superiorly, contracted and flattened inferiorly, where it degenerates into ar groove,
which is converted into a canal by ligaments. This canal lodges the sacral nerves, and
communicates both with the anterior and posterior sacral foramina.
The Coccyx (8, 9, jig. 8).
This consists of four, rarely of five, pieces of bone : they are flattened from before
backward, and diminish successively in size from the first to the last : they are common-
ly united together, rarely separate, the largest corresponding with the apex of the sa
crum ; the smallest is a mere nodule of bone, generally unattached. The wh«le knot-
ted-like bone, thus constituted, has a triangular shape, and follows the direction of the
lower part of the sacrum. It may be regarded as the rudiment of the tails of the lower
animals. In some cases I have seen it form a right angle, or even an acute angle with
the sacrum.
1 . The posterior, spinal, or cutaneous surface, is rough, for the insertion of the aponeuro-
sis of the gluteus maximus.
2. The anterior surface resembles the same part of the sacrum in miniature, and, like
it, is in immediate proximity to the rectum.
3. The borders are narrow, sinuous, and tubercular, and give attachment to the sacro*
sciatic ligaments.
* I have seen this spinous process completely bifurcated.
W8 '='■*■ OSTEOLOGY.
4. The base is often united by bone to the sacrum, even in young subjects ; it pre-
sents an elliptical articular surface, exactly corresponding with that on the lower end of
the sacrun . Behind are two processes directed upward (cornua of the cocc3rx, 8 8, fig.
8), which are sometimes continuous with the small cornua of the sacrum. ExternaUy
are two notches, which are converted into foramina by means of ligaments, and afford
passage to the fifth pair of sacral nerves.
5. The apex (9), which is sometimes enlarged and sometimes bifurcated, gives attach
ment to the levator ani muscle. It is not uncommon to find the last pieces of the coc-
cyx deviating from the median line.
Of the Vertebral Column in general.
Having already described the situation of the vertebral column, we shall now consid-
er its dimensions as an entire piece of the skeleton.
Dimensions of the Vertebral Column.
1. The length or height of the vertebral column does not correspond with the length ol
the spinal marrow, which does not extend below the first lumbar vertebra. It varies at
different ages : most commonly it increases up to the twenty-fifth year, but occasionally
its growth is completed before this period. In the adult it remains unaltered, but in old
age it becomes shortened by the incurvation of the trunk forward, and the yielding of
the bodies of the vertebrsB and the intervertebral substances. This latter cause is also
productive of a very appreciable shortening of the trunk, sometimes to the extent of half
an inch, after long walking or standing.
When measured along its curvatures, the length of the column is generally two feet
four inches ; in vertical height it is two feet two inches. These dimensions are not ex-
actly proportional to the height of the individual, which depends principally upon the
length of the lower extremities. In this respect I have never found any marked differ-
ence between tall and short persons. In an adult of medium stature, the cervical por-
tion measures five inches and a half, the dorsal nine inches and a half, the lumbar six
inches and a half, and the sacro-coccygeal six inches and a half
It may be easily conceived that, in cases of abnormal curvature, the vertical height
must present considerable differences, while the actual length of the column may remain
almost constant. In the skeleton of a female affected with rickets, a vertical line,
stretched from the tubercle of the atlas to the base of the sacrum, measured one foot,
six inches, and six lines ; while a line which followed the inflections of the column, meas-
ured two feet eighteen lines — giving a difference of seven inches. Hence the possibil-
ity of a rapid and considerable increase in length in those patients who are submitted to
continued extension.
2. Antero-posterior dimensions. The antero-posterior diameter, at the sacro-vertebral
angle and in the lumbar region, is three inches ; in the dorsal region, two inches, four
lines ; in the middle of the cervical region, one inch, six lines.
3. Trmisverse dimensions. The transverse diameter is eighteen lines in the lumbar
region, thirteen in the middle of the dorsal, and twenty-two in the cervical. It should,
however, be remarked, that the transverse processes are included in this measurement
of the cervical region, but not in the others.
Direction.
The general direction of the spinal column is vertical, but it presents certain alternate
curvatures. There are four antero-posterior curvatures, viz., in front, a convexity in the
neck (a, b,fig. 1), a concavity in the dorsal region (b, c), a convexity in the loins (c, d),
and a concavity in the sacro-coccygeal region {d, e, /). Behind, the opposite curvatures
are observed. The degree of each curvature is always proportioned to that of the oth-
ers ; thus, if there be a remarkable projection in the cervical region, there is a corre-
sponding degree of concavity in the dorsal, and a proportional convexity in the lumbar
regions. So great, indeed, is the mutual dependance of these curvatures, that the slight-
est modification of one produces corresponding alterations in all the others.
There are many individual varieties of these curvatures ; their effect appears to be
that of augmenting the power of resistance in the vertical direction, or, at least, of di-
minishing the effect of vertical pressure. It may be physically demonstrated, that of two
similar rods made of the same materifils, that which presents alternate curves will sup-
port a greater amount of pressure in the vertical direction than that which is straight,
on account of the decomposition of forces which occurs at each curvature.*
In addition to these antero-posterior curvatures, there is at the level of the third,
* Some physiologists have even gone so far as to express by figures what the difference of resistance of a
'ecto-lineal vertebral column would be, as compared to one formed with curves like the spine, and have made
It as 1 ; 16. It has also been asserted, that the curvatures of the spinal column were the result of muscular
action. This is certainly not the fact. These curves are too fixed and too important to be made to dopend
on an agent so variable as that of muscular contraction. They are produced by the general law which regu-
lates the organization of the body.
THE VEETEBRAL COLUMN. 29-
fourth, and fifth dorsal vertebrae a lateral inclination, the concavity of which is on the lefl
side. This being the exact situation in which the aorta, the principal artery of the body,
makes a curve downward, the older anatomists have ascribed the concavity of which
we speak to the curvature of this vessel. Bichat imagined it to be owing to the ahnost
universal habit of employing the right hand, in which action the upper part of the trunk
is inclined to the left, so as to afford a point of support, and, as it were, a counterbalance
to the action of the right arm, which inclination, by frequent repetition, becomes perma-
nent. According to this hypothesis, left-handed individuals should present a curvature
in the opposite direction, and Beclard has shown that such is in reality the case. I may
add, that I have always found the deviation greatest in those who used their right arm
in the most laborious employments. Of late years it has been supposed that the lateral
curvature depended upon the position of the foetus in utero ; had this been the case, it
should exist at birth, which, as I can affirm, 'it never does. Notwithstanding the likeU-
hood of Bichat's opinion, yet, if we consider that in every case in which an artery is im-
mediately contiguous to a bone, that bone presents a corresponding depression, it may
be questioned whether the opinion of the older anatoinists has not more foundation than
is generally admitted.* However slight this lateral incurvation may be, it always pro-
duces a correspondent one in the lumbar region, though in the majority of cases this is
scarcely perceptible. ^
The history of abnormal curvatures or deviations belongs to pathological anatomy. I
shall only observe, that they are all due to the following causes : 1. The wasting of the
vertebrae by caries or softening. 2. Want of equilibrium between the strength of the
vertebral column and the weight of the body, either alone or when loaded with burdens.
3. Muscular traction. 4. The frequent repetition of any attitude»in which the column
is curved.
Figure and Aspects.
Viewed in front, the vertebral column represents two pyramids united by their bases.
The inferior pyramid is constituted by the sacrum and coccyx: ; the superior pyramid is
the true spine ; its base rests on the former, and its summit is surmounted by the atlas.
The contraction which exists at the fourth and fifth dorsal vertebra; has led to the
subdivision of this superior pyramid into two others, united by their summits. Other
subdivisions have been instituted, which we shall not point out, since they are useless.
What it is important to know is, that the vertebral column increases progressively in size
from above downward, which satisfactorily proves that man was formed for the erect posi-
tion. There are partial enlargements in different parts, as, for instance, in the first two
cervical vertebrae, in the seventh cervical, and last dorsal, &c.
Upon the whole, it may be said that the vertebral column presents in front the appear-
ance of a knotted cylinder ; behind, that of a triangular pyramid, bristled with eminences
and perforated with holes. How irregular does the spine appear when cursorily exam-
ined ! Yet, when viewed as a whole, and when we examine its figure and processes in
reference to its uses, we are lost in admiration in perceiving that there is not the small-
est tubercle, nor the most minute hole, nor the most trifling circumstance in its configu-
ration, which is not of great importance in' securing the perfection of the entire colunm.
The vertebral column presents for coilsideration an anterior, a posterior, and two lat-
eral surfaces, a base, and a summit.
Anterior Surface. — Here are observed, 1. The curvatures already described ; 2. The
range of bodies of the vertebrae, having the form of small columns piled on each other
and separated in the fresh state by certain prominent disks of a white colour and fibrous
structure. 3. A range of transverse grooves on the bodies of the vertebrae, which are
deeper in the aged than in the young subject. This surface presents in its transverse
diameters those variations which we have already noticed. The parts placed in front
of the vertebral column are, 1. Immediately on its anterior surface a ligamentous layer,
which completely invests it, with the anterior recti muscles of the head, the longi colli,
the crura of the diaphragm, and the psoae muscles. 2. At a greater distance the aliment-
ary canal, which rests on the spine at its commencement and termination, and is attach-
ed to it by membranous connexions, even where it advances forward to form its numer-
ous convolutions. 3. The organs of circulation, viz., the heart, the aorta, in almost its
whole extent, the carotid, vertebral, and common iliac arteries, the venae cavae, the ju-
gular and common iliac veins, the vena azygos, and the thoracic duct. From this posi-
tion of parts arises the possibility of effectually compressing the arteries against the ver-
tebral column, a method which has been successfully adopted with the carotid arteries
and abdominal aorta. It also explains the marked pulsations in the abdominal region
frequently observed in emaciated subjects, and often giving rise to an erroneous suspi-
* This opinion seems to be still farther corroborated by a case lately reported to the Academy of Medicine
by Doctor Gery, of complete inversion of the viscera, where the aorta was placed on the right side of the ver-
tebral column, and where the concavity, or, rather, lateral depression, was situated on tlie right side. The
facts of the case are satisfactorily established by M. Bonamy, who examined the subject. Positive proof was
obtained that this individual was not left-handed.
b
30 OSTEOLOGY.
cion of aneurism. 4. The trachea and the lungs. 5. The great sympathetic nerves are
connected with it in its entire extent, and the ganglionic enlargements of which corre-
spond in number to the number of its different pieces.
Posterior Surface. — This presents, 1. In the median line, the row of spinous processes,
the whole of which constitute a vertical crest or ridge denominated spine, and hence the
names spinal column and rachis {(iaxk, spine). This ridge is far from being regular, but
its irregularities are all perfectly adapted for the fulfilment of the movements of the dif-
ferent regions. It commences with the tubercle of the first vertebra, is suddenly en-
larged at the second, diminishes again at the third, fourth, and fifth cervical vertebrae,
and projects anew at the sixth, and more remarkably at the seventh ; thence named
vertebra prominens. Below this point the processes become oblique, prismatic, trian-
gular, and with one tubercle : their obliquity increases, but they become more slender
from the first to the tenth : in the tenth, eleventh, and twelfth dorsal, they become hor-
izontal, shorter, and stronger ; and they are broad, square, rectangular, and horizontal
in the lumbar region. Lastly, the ridge gradually sinks down in the sacro-coccygeal re-
gion, when it ends by dividing into two smaller ridges, leaving between them a furrow,
which is continued along the coccyx. We cannot fail to perceive the importance of the
most trifling circumstance in the conformation of the spinal ridge, whether examined in
reference to physiology or pathology. 1st. In reference to physiology. This ridge must
be viewed as the lever of those powers which produce extension. We know that the
movements of extension are greatest in the cervical portion, that they scarcely exist in
the dorsal, and are again considerable in the lumbar. The interval between the spinous
processes measures the extent of motion. The three enlargements above referred to,
viz., that of the second cervical vertebra, that of the seventh cervical and first dorsal,
and that of the twelfth dorsal and first lumbar, explain these movements. The first is
for the articulation of the particular movements of the head, the second for the move-
ments of the neck, and the third for the insertion of the extensor muscles of the loins.
2d. In reference to pathology. The spinal ridge being the only part of the vertebral
column which we can see or feel in the living subject, it is clearly of the greatest im-
portance to study the shghtest differences which it presents, because it is thus alone
that we are able to judge of the extent of deviation in the column ; and yet the indica-
tions it affords are not absolutely certain, because the pedicles of the vertebrae being
susceptible of torsion, a curvature may exist in the bodies of the vertebrae without any
corresponding alteration of the spinous processes.
2. On each side of this median ridge are two grooves, broad and shallow in the cervi-
cjil, broad and deep in the upper part of the dorsal region, contracted at the lower part of
the back, enlarged again in the loins and at the base of the sacrum, contracted, and final-
ly obliterated, at the lower part of this bone. These grooves are filled by a muscular
mass, which, in robust individuals, projects beyond the spine, while in those who are
emaciated the ridge forms the most prominent part.
Lateral Surfaces. — ^These present, 1. In front, the sides of the bodies of the vertebrae
and their transverse grooves, which are deeper at the sides than in front, also deeper in
the loins than in the neck and back ; 2. In the dorsal region, facettes for the costo-ver-
tebral articulations ; 3. Still more posteriorly, the intervertebral foramina, equal in number
to that of the vertebrae. The largest of these foramina is the one situated between the
fourth and fifth lumbar vertebrae : from this point they gradually diminish in size to the
upper part of the back : in the cervical region, again, they are somewhat larger ; and in
the sacro-coccygeal they are double, with an anterior and a posterior opening,* in con-
sequence of the later2il conjunction of the false vertebrae of the sacrum. In general,
their dimensions are in proportion to the size of the veins which communicate between
the intra and the extra vertebral venous system. Between these foramina are the
transverse processes, which contribute to form the sides of the posterior grooves, and,
between the transverse processes, the articulating processes are visible.
The base and the summit of the vertebral column have been already considered, in the
special description of the atlas and the fifth lumbar vertebra.
Vertebral Canal. — ^This canal, into which the intervertebral foramina open, follows all
the curves of the spinal column, but does not altogether correspond in shape with its
external figure. It may be even said that its dimensions, at different heights, bear an
inverse proportion to those of the column ; thus, while the canal is most capacious in
the neck, the column, on the other hand, is largest in the loins. It has been said that
the widest portions of the canal correspond with the enlargements of the spinal cord :
but this is not correct. The capacity of the canal is proportioned to the mobility of the
respective portion of the column, so that, in the most extensive movements, the spinal
marrow is effectually guarded from compression : thus it is largest in the neck and loins,
and smallest in the back and sacrum, t
* [The foramina which lead from the sacred canal are single at their internal orifices, though, for the rea-
son given in the text, they open externally by two orifices. It is the internal orifice which answers to the
intervertebral foramen of the other vertebrae.]
t In the Philos. Trans., 1822, Mr. Earl has published a paper to establish this fact from observatioa in
comparative anatomy.
THE VERTEBRAL COLUMN. 31
The canal is almost equally well protected in front and behind : anterloily by the
bodies of the vertebrae, posteriorly by the spinous processes, which, as it were, ward off
mischief from the spinal canal. Laterally it is defended by the articular and transverse
processes. Behind, on each side of the median ridge, it is protected by the laminae, the
intervals of which are filled up by what are named the yellow ligaments. Any loss of se-
curity occasioned by the existence of these yellow ligaments is compensated by the fol-
•lowing circmnstances : 1. The ligaments are very short, so that the edges of the laminte
are almost contiguous. 2. In the neck, where the intervals are greatest, the laminae
are so inclined, that the inferior border of the one above overlaps the superior border of
the one below. 3. In the loins, where the intervals are nearly as great, the laminae are
small, and their place is in a great measure occupied by the lateral masses and the pedi-
cles, which are proportionally increased in development. It is impossible for an instru-
ment to penetrate into the canal in the lumbar region, excepting between the spinous
processes. The same difficulty exists in the cervical region during extension, on ac-
count of the imbrication of the laminae. During forcible flexion, however, an instrument
may enter between them, when directed from below upward.
Internal Structure of the Vertebrce.
Excepting the thin external layer of compact tissue, the bodies of the vertebrae arc
almost entirely composed of open, spongy texture. The different processes, on the
other hand, have a considerable quantity of compact tissue ; but, in all places where they
undergo any enlargement, they are cellular. The laminae are formed almost exclusively
of compact tissue. This abundance of the spongy tissue explains the fact of the weight
of the spinal column being so inconsiderable in proportion to its size.
The venous canals are larger in the vertebrae than in any other bones. They are, for the
most part, arranged within the body of the bone in the following manner : A single canal,
directed horizontally, and from behind forward, conunences at the posterior surface of
the body of the vertebra ; at the distance of a few lines from its commencement, it divides
into two, three, or four canals, which diverge from each other, and terminate partly upon
the anterior surface of the bone, partly in the cells in its interior ; all these canals are
lined by a thin layer of compact tissue, and perforated by foramina.
Development.
The development of the vertebral column comprises, 1. That of the vertebrae in gen
eral ; 2. That of certain vertebrae which differ from the rest ; and, 3. That of the column
considered as a whole.
Development of the Vertehrcz in general. — Each vertebra is developed at first from three
points of ossification,* viz., one median for the body, and two lateral for the rest of the
vertebral ring. To these primitive points are added, at different periods, five secondary
or epiphysary points, viz., one for the summit of each transverse process, one for the
siunmit of the spinous process, and two for the body, the one on the superior surface,
the other on the inferior surface, where they form two very thin plates, so that at one
time the body of every vertebra of the spine is, in fact, a triple disk. Lastly, there is a
complementary point for each apophysary tubercle of the lumbar vertebrae, which gives
to this class of vertebrae seven secondary points of ossification.
The first osseous points generally appear in the laminae ; they precede, by some days,
the deposition of bone in the bodies. This law, however, as Beclard has remarked, is
by no means general.
The first ossific points are visible from the fortieth to the fiftieth day ; that in the body
occupies the centre of the cartilage, under the form of an osseous granule, which ex-
tends horizontally, so as to present a lenticular aspect. The points of ossification of the
laminae appear in the situation of the future transverse and articular processes.
The complementary osseous points are not formed until the fifteenth or eighteenth
year. Sometimes, however, as Bichat has observed, the point for the summit of the
spinous process is included among the primitive nuclei, and in such cases it is situated
at the place where that process becomes continuous with the laminae.
The lateral osseous points are always united together before joining the body of the
bone : this union commences about a year after birth ; they are not united with that oi
the body until about four years and a half The lateral points are so joined to the cen-
tral one that they form the sides of the body, and in the cervical region, from their more
rapid increase, they constitute of themselves fully two fifths of the body of the vertebra.
It is, then, on the body of the vertebra, or on what is essentially the articular part of the
bone, that the three primitive points are united together. The epiphysary points of the
transverse and spinous processes are joined to the rest from the twentieth to the twen-
ty-fifth year ; the union of the epiphysary laminae of the bodies is not completed imtil
from the twenty-fifth to the thirtieth year.
* Some anatomists admit two primitive points for the body of the vertebra. It would •xceed our limitf to
give an account of the discussions to which this question of osteogeny has given rise.
I
88t OSTEOLOGY.
Development of particular Vertebra. — Those vertebrae which present great differences
of form present striking differences, also, in their mode of development ; such are the
atlas, axis, seventh cervical vertebra, first lumbjir, and those which constitute the sa-
crum and coccyx.
Adas. — Modern anatomists admit five or six points of ossification for this bone ; one
or two for the anterior arch, two for the lateral masses, and two for the posterior arch.
I have never observed more than two lateral points, the same point belonging at once
to the lateral masses, and half of the arch on each side. They appear in the following
order : those for the posterior arch make their appearance from the fortieth to the fiftieth
day ; those for the anterior arch not until during the first year after birth. The two
osseous points of the posterior arch unite together, those of the anterior arch do the
same, and then the anterior is united to the posterior arch.
Axis. — There are often two osseous points for the body of this bone, and always two
lateral ones for the odontoid process : it has, therefore, in all, five or six points, viz.,
two for the laminae or posterior arch, one or two for the body, and two for the odontoid
process. Meckel and Nesbit admit one other nucleus between the odontoid process and
the body, which appears in the course of the first year after birth. The points in the
laminae appear from the fortieth to the fiftieth day ; those in the body during the sixth
month ; and those in the odontoid process, a short time after. At birth the body of the
axis is proportionally more developed than that of the other vertebrae. The union of its
several parts takes place in the following order : the two laminae are joined together
shortly after birth ; the two points of the odontoid process remain distinct during the
whole of the first year ; the body and the odontoid process are united in the course of
the third year ; and the laminae and the body during the fourth or fifth year.
Seventh Cervical Vertebra. — Independently of the osseous points common to all the
vertebra;, this bone has two others situated on each side of the body in the cartilage
which forms the anterior half of the transverse process. The existence of this point,
which was described by Hunauld, but which does not appear to me to be constant,
establishes an analogy between the transverse processes of the cervical vertebrae and
the ribs ; it represents in a rudimentary state the permanent cervical ribs of some ani-
mals ; and explains an anomaly which is not very uncommon in the human subject, viz.,
the existence of a supernumerary cervical rib.
First Luvibar Vertebra. — Its transverse process is sometimes developed by a point which
remains separate from the body of the bone, and forms a supernmnerary lumbar rib.
Development of the Sacrum and Coccyx. — The first three sacral vertebrae each present
five primitive points, viz., one for the body, two for the laminae, and two for the anterior
portion of the lateral masses. The last two sacral vertebrae have only three points.
Each of the coccygeal vertebrae is developed from one point only, but it is not uncom-
mon to see the first two formed by two lateral points, which subsequently unite in the
median line : there are, therefore, twenty-one primitive points in the sacrum, and four
in the coccyx. Subsequently two epiphysary laminae are formed for the body of each
sacral vertebra, making ten new complementary osseous points. At a still later period
two laminae are developed, one on each side of the sacrum, corresponding with the au-
ricular surface, so that the whole number of osseous points in the sacrum is thirty-three.
Ossification proceeds more slowly in the sacral and coccygeal vertebrae than in the
others : it commences in the body, the first points appearing from the second to the third
month in the first three sacral vertebrae, from the fifth to the sixth month in the fourth
and fifth vertebrae ; the laminae begin to ossify in the interval between the sixth and
ninth month : the first vertebra of the coccyx usually begins to ossify during the first
year after birth ; the second, from the fifth to the tenth ; the third, from the tenth to the
fifteenth ; and the fourth, from the fifteenth to the twentieth year.
The union of the osseous points takes place at different times ; the osseous pieces of
each vertebra are first joined together, and subsequently the vertebrae themselves.
1. Union of the Osseous Nuclei of each Vertebra. — The osseous points of the laminae are
first united ; these then join with the anterior lateral nuclei of the first three vertebrae :
at a much later period the lateral masses become connected with the body.
The union of the lateral masses with the body takes place much earlier in the fourth
and fifth sacral vertebrae than in the three others, though these latter first showed osse-
ous points. After the union of the lateral masses, the sacrum is composed of five pieces,
which remain separate until the fifteenth year.
2. Union of the Sacral Vertebra, with one another. — This process commences between
the fifteenth and eighteenth year, at which time the epiphysary laminae of the bodies of
the sacral vertebra; are developed. At the age of twenty-five the epiphysary laminae of
the iliac surface of the sacrum are developed. The union commences with the lower
vertebrae, and proceeds upward. The first is not completely joined to the others until
from the twenty-fifth to the thirtieth year.
The union of the body of each vertebra with its epiphysary laminae proceeds from the
circumference to the centre, so that, in a vertical section of a sacrum, which is com-
pletely ossified externally, we often find an intermediate lamina of cartilage. I have
THE SCULL. 33
Observed this cartilage between the first and second sacral vertebrae in subjects of a
yery advanced age.
The union of the pieces of the coccyx takes place sooner than those of the sacrum.
It commences with the first two pieces ; the third and fourth then follow ; and, in the
last place, the second and third are united. Towards the fortieth or fiftieth, or some-
times the sixtieth year, the coccyx becomes united to the sacrum. This junction is
later in the female than in the male ; sometimes it never takes place.
Development of the Spine in general. — Up to the end of the first month of conception,
the length of the spine is commensurate with that of the body, the extremities as yet
only existing under the form of small tubercles. This disproportion between the spine
and members is gradually effaced by the elongation of the limbs, so that at birth the
vertebral column does not constitute more than three fifths of the height of the subject.
In the adult it forms only two fifths. /
All the parts which concur in forming the canal for the defence of the spinal cord are
developed prior to those which are specially devoted to locomotion, as is shown in the
development of the laminae, as compared with that of the body and processes. The os-
sification of the laminae proceeds in regular succession from above downward, from the
neck to the sacro-coccygeal region. The ossification of the bodies takes a different
course, commencing in the dorsal region as a centre, and proceeding to either extremity
of the column. The ossification of the bodies of the vertebrae commences in the centre
of the bone, and accordingly, if the spine of a foetus be dried, the cartilages shrink, and
the series of osseous nodules, which represent the bodies of the vertebrae, look like
grains of Indian corn strung together.
In the first periods of its development, the spinal column presents the following re-
markable differences from its subsequent condition. It is completely devoid of curva-
ture, and instead of resembling in shape a pyramid with the base below, it is precisely
the reverse, the base of the pyramid being uppermost. As the child grows up, the spine
gradually acquires those characters which it presents in the adult. In the old subject it
is always more or less bent forward. It is not uncommon to meet with several dorsal
or lumber vertebrae more or less completely united by a layer of bone, which forms a
sort of sheath or clasp. To this I have apphed the name of Emchylosis by invagination.
THE SCULL.
Composed of the Cranium and Face. — Cranial Bones. — Occipital. — Frontal. — Sphenoid.—
Ethmoid. — Pafielal. — Temporal. — The Cranium in general. — Development. — Bones of
the Face. — Superior Maxillary. — Palate. — Malar. — Nasal. — Lachrymal. — Inferior Tui
binated. — Vomer. — Inferior Maxillary. — The Face in general. — Cavities. — Development
The scull is the most complicated portion of the skeleton. It has been more minute-
ly investigated than any other part, probably on account of the difficulty of the study. It
is composed of two distinct portions : one, the cranium, designed to enclose and protect
the brain ; the other, the face, which affords lodgment to almost all the organs of the
senses, and, at the same time, is employed in the function of mastication.
The Cranium.
The cranium {Kpdvog, a helmet) is a round osseous case, composed of eight bones,
that is, of eight pieces, distinct and separable after the complete development of the
skeleton. Four of these are single, and placed on the median line, viz. (counting from
behind forward), the occipital, the sphenoid, the ethmoid, and the frontal ; the remaining
four are in pairs, and are situated laterally, viz., the two parietal and the two temporal.
To these must be added the two small supernumerary bones denominated ossa wormiana,
or triquctra.
The Occipital Bone (Jigs, 9 and 10).
The occipital bone occupies the posterior, inferior, and middle portion of the cranium,
a great part of the base of which it constitutes.* Below it is articulated with the ver-
tebral column ; in front with the sphenoid ; and it is, as it were, wedged in between the
parietal and temporal bones of the right and left sides. It is broad and symmetrical ;
in shape, an irregular segment of a spheroid, notched round the circumference. It has
an anterior and a posterior surface, and a circumference having four borders and four angles.
The posterior or cutaneous surface {fig. 9) is convex, and presents the inferior orifice of
the occipital foramen (1, fig. 9 ; d, fig. 21), (foramen magnum), the largest of all the fora-
mina in the skeleton, excepting the sub-pubic, or obturator foramen of the os innomina-
* It is the OS prora: of Fabricius of Aquapendente, who, following out the same metaphor, has given tb«
name of os puppis to the frontal, and os carinoe to the sphenoid.
E
H.
OSTEOLOGY.
turn. It gives passage to the spinal marrow with its envelopes, the spinal accessory
Fig. 9.
nerves, and vertebral arteries. In front of the foramen is the
inferior surface of the basUar process (2, fig. 9 ; n, fig. 21),
which forms the bony roof of the pharynx ; it is placed hor-
izontally, is rough, and has a ridge in the median line, more
or less prominent in different subjects. Behind the foramen,
and in the median line, is the external occipital ridge {perpe-ndic'
ular spine) (3 4,^^. 9; c a, fig. 21), extending from the poste-
rior edge of the foramen to the external occipital protuberance.
This projection is wanting in some individuals, and in others
its place is occupied by a depression. On each side of the
ridge are unequal surfaces, bounded above by a line, with the
concavity looking downward. Thus, the siiperior semicirctdar
line (5 5, fig. 9 ; a b,fig. 21) commences at the occipital protu-
berance (4, fig. 9 ; a, fig. 20), and proceeds horizontally out
ward. The irregular surface included between this line and
the foramen is again divided by a line whose concavity is directed upward (6 6, fig. 9),
and which is called the inferior semicircular line. These lines and these inequalities
are destined to receive the insertion of a great number of muscles.
On each side of the occipital foramen, and towards the fore part, are the condyles (7 7,
fig. 9 ; e,fig. 21), two articular eminences, convex, elliptical, directed from behind for-
ward, and from without inward, their surfaces looking downward, and somewhat out-
ward. They articulate with the atlas. Behind these are two fossae : the posterior con-
dyloid, which are often perforated by an aperture ; the posterior cmidyloii foramen (8, figs.
9 and 21), giving passage to a vein. In front, and external to the condyles, are the an-
terior condyloid fosscz and foramina (9 9, fig. 9) ; the latter are really flexuous canals,
through which the hypoglossal nerves pass out of the scull. External to the condyles
is a rough surface, the jugular surface {i,fig. 21), which gives attachment to the recti
laterales muscles of the head.
The anterior internal or encephalic surface {fig. 10), in common with all the other bones
Fig. 10.
of the cranium, is lined by the dura mater. It presents, 1.
The internal orifice of the occipital foramen {I, fig- 10), which
is larger than the external. 2. Before the foramen the ba-
silar groove (2), sloping gently from above downward and
backward : the sides- of the groove are marked by other
very small grooves, which concur in forming the inferior
petrosal groove. 3. On each side of the occipital foramen,
and towards the fore part, is a projection (3 3) which corre-
sponds with the condyle, and particularly with the anterior
condyloid canal. 4. A little more external and posterior is
a small portion of a groove (4), which contributes to form
the termination of the lateral sinus. 5. Behind the foramen
are the four occipital fossce, two superior or cerebral (5 5), and
two inferior or cerebellar (6 6), separated frohi each other by
a crucial ridge. The vertical branch of this ridge {g a) joins
the termination of the sagittal groove above ; below it is
formed by the internal occipital crest (7). The horizontal
branches (_g b) correspond with the grooves for the lateral
sinuses of the dura mater. The internal occipital protuberance (g) is situated at the conflu-
ence of the four branches. The right and left lateral grooves are rarely of the sEime
size and depth ; the right is generally the larger, and forms by itself the continuation of
the sagittal or longitudinal groove.
The circumference presents four borders and four angles. The superior or parietal bor-
ders (a b, a b), which are remarkable for the length of their indentations, articulate with
the posterior borders of the parietal bones forming the lamdoidal suture.
The inferior or temporal borders (b c, b c) are divided into two equal portions by the jugu^
lar eminence {d), which articulates with the temporal bone. This eminence, in most sub-
jects small, in some instances is largely developed, so as to form a true jugular process.
I have seen this process articulated to the transverse process of the atlas. The part
(J d) above this eminence is slightly denticulated, and united to the mastoid portion ot
the temporal bone ; the part {d c) below is thick, sinuous, but without indentations, and
articulates, by juxtaposition, with the petrous portion of the temporal. In front of the
jugular eminence is a deep notch, sometimes divided into two parts by a process of
bone, which contributes to form the foramen lacerum posterius.
The superior angle (a) is acute, and is received into the retreating angle formed by
the posterior borders of the parietal bones. Its place is sometimes supplied by a Wor-
mian bone. In the young subject, the posterior fontanelle is placed here. The inferior
angle (c) is truncated, and very thick ; it forms the basilar process, which presents a rough
articular surface for union with the body of the sphenoid. The connexion is estabUshed
FRONTAL BONE. 35
by means of a cartilage, which becomes ossified at a very early period, so that many
anatomists describe the sphenoid and occipital as one bone.*
The lateral angles {b b) are very obtuse, and are received into the retiring angle formed
by the union of the parietal with the temporal bone. At these angles the latcreU and pos-
terior fmitanelles are situated.
Connexions. — The occipital articulates with six bones ; the two parietal, the two tem-
poral, the sphenoid, and the atlas.
Structure. — The part of this bone which forms the occipital fossae consists almost ex-
clusively of compact tissue. It is here extremely thin, especially at the inferior fossse.
In the rest of its extent there is spongy tissue between the two tables. The external
table is much thicker and less brittle than the internal, which is named vitreous, on ac-
count of its fragility. The spongy tissue is very abundant in the condyles and in the ba-
silar process.
Development. — The occipital bone is developed from four points : one for the squamous
portion, that is, the part of the bone behind the foramen magnum ; one for each lateral
condyloid portion of the occipital, and one for the anterior or basilar portion. These
four parts are considered by some anatomists as so many distinct bones, which they de-
scribe under the names of posterior or superior occipital, lateral occipitals, and anterior
occipital or basilar bone. The first point of ossification appears in the squamous or back
part of the bone, under the form of a small oblong plate, placed transversely in the situ
ation of the protuberances. I have never seen this piece formed by two lateral points.
The part of the bone of which we are speaking is always visible towards the middle of
the second month. The condyloid portions make their appearance next, and, lastly, the
basilar portion, which I have never seen developed from two lateral points. In a foetus
of two months and a half, the ossified part of this process presented the appearance of a
linear streak, situated exactly in the median line, and directed from before backward.
The four points of ossification are finally united at the foramen magnum.
Anatomists, however, are not at all agreed respecting the number of points of ossifi-
cation. Meckel admits eight for the posterior part of the bone, two for the condyles, and
one for the basilar process. Beclard, on the other hand, admits only four in the poste-
rior part of the bone. His opinion is founded upon the existence of four fissures or di-
visions at the circumference of this portion ; viz., one at the superior angle, which
sometimes gives to the posterior fontanelle the lozenge shape of the anterior ; one be-
low, which is nothing more than a slight notch in the back of the foramen magnum ;
and two on each side, corresponding to the posterior lateral fontanelles. The opinion
of Meckel is perhaps grounded upon certain abnormal cases, in which this part of the
bone is divided into a considerable number of pieces, resembhng so many Wormian
bones united by suture.
The Frontal or Coronal Bone {jigs. 11 and 12).
The frontal bone is situated at the anterior part of the scull, and above the face. It
is symmetrical, and represents a considerable segment of a hollow sphere. From its
shape it has been compared to a shell. The superior three fourths are curved, placed
vertically, but more or less inclined from above downward and forward ; the inferior
fourth is flat and horizontal. It has an anterior, a posterior, and an inferior surface, and
three borders.
The anterior cutaneous or frontal surface is smooth and convex ; there is a suture in
the median line in young subjects, which in the adult is ^ig. 11.
obhterated, leaving scarcely any trace of its existence, ex-
cepting at its termination below. At this spot there is a
prominence named nasal eminence or glabella (or middle
frontal eminence) {I, fig. 11).
On the sides of the median line, proceeding from above
downward, we observe two smooth surfaces ; then the
frontal eminences (2 2), two projections which are most
strongly developed in young subjects ; and below these, on
each side of the glabella, the superciliary ridge, an arched
elevation which forms the margin of the orbit, and is more
prominent towards the nose than externally. Quite at the outside of'the anterior sur-
face of the frontal, there is a small, depressed, triangular surface (4), which looks directly
outward, and is separated from the frontal eminence by a sort of crest, running upward
and backward (5) : it forms the anterior part of the temporal fossa.
The anterior surface of the frontal bone is separated from the skin by the frontal, or-
bicular, and corrugator supercilii muscles, and the anterior portion of the cranial apo-
neurosis.
The inferior or orbito-ethmoidal surface {fig. 12) presents in the middle a large rectan-
* A reference to comparative anatomy would seem to justify this view, for in some inferior animals the
basilar process and the sphenoid are but one piece.
OSTEOLOGY.
'.W*!V't'^ ■ gular notch (6), which extends the whole length of this
surface from before backward. This notch, which is
named ethmoidal, because it receives the ethmoid bone,
has, 1. In front, and in the median line, a prolongation,
denominated the nasal spine (7) : this spine is rough in
front, for articulation with the proper nasal bones : be-
hind it is marked by two grooves, separated by a verti-
cal ridge ; the ridge joins the perpendicular lamella of the
ethmoid, and the two grooves form part of the vault of
the nasal fossae. 2. Farther back, and on each side, is
the large opening of the frontal sinuses. 3. The two
borders of the notch are marked with {b d, b d) incom-
plete cells, which join with those of the ethmoid. 4. On
the same borders there are two, or sometimes three
^''a small grooves, which contribute to form the anterior and
posterior internal orhitary canals.
On each side of the notch is the orbital plate (9 9), triangular and concave, especially
towards the external margin, where there is an excavation for the lachrymal gland {fos-
sa glandula lachrymalis). At the internal margin there is a small depression for the at-
tachment of the cartilaginous pulley, in which the tendon of the superior oblique muscle
of the eye is reflected.
The posterior or cerebral surface is concave, and marked by eminences and depressions
corresponding to the sulci and convolutions of the brain, and by furrows for arterial
branches. In the median line is a longitudinal groove, the sides of which unite below,
and form the frontal ridge, which terminates in a foramen called foramen cacum. The
ridge is sometimes absent, and occasionally the place of the foramen is occupied by a
notch, completed by the ethmoid, as already described. On each side of the median line
are the frontal fossce, which are deeper than the corresponding eminences on the outside
seem to indicate : below are the orbital prominences, which look directly upward, and form
a retiring angle* with the frontal fossae ; they are covered with acuminated eminences,
which are received into the anfractuosities of the brain.
The superior or parietal border {b a b) is semicircular, denticulated, and cut obliquely at
the expense of its internal plate above, and of its external below, and at the sides. In
the middle, it forms a very obtuse angle (a), which is received into the retiring angle
formed by the parietal bones. In young subjects this angle is wanting ; in its situation
the anterior angle of the anterior fontanelle is placed.
The inferior or sphenoidal border {b b b) is very short, thin, and straight, interrupted by
the ethmoidal notch, and adapted to the smaller wings of the sphenoid. It terminates
externally at its junction with the superior border, by two triangular surfaces slightly in-
dented, which articulate with the greater wings of the sphenoid.
The anterior or orUto-nasal border (c c, fig. 11) presents in the centre the nasal notch {d d),
articulated in the middle with the nasal bones, and at the sides with the ascending pro-
cesses of the superior maxillae. At the bottom of this notch is the anterior surface of
the nasal spine. On each side we observe the orbital arch (c d), more sharp and thin to-
wards its outer end. At the junction of the internal with the two external thirds of this
arch is situated a foramen (c), or, more frequently, a notch converted into a foramen by
a ligament ; it is called the superciliary or supra-orbital foramen, and gives passage to the
frontal vessels and nerves. At the bottom of this notch there are generally one or more
vascular openings, which lead into the diploe, and are the terminations of venous canals,
which run for a considerable way within the bone. The orbital arch terminates on each
side by a process ; the inner one, internal angular process (d), is broad and thin, and artic-
ulates with the OS unguis ; the external (c) is thick, and unites with the malar bone.
Connexions. — The frontal is articulated with twelve bones : the two parietal, the
sphenoid, the ethmoid, the two nasal and two malar bones, the ossa unguis, and the
two superior maxillary.
Internal Structure. — The vertical portion and external orbital processes are very thick ;
the horizontal part is very thin, and hence the facility with which instruments can pen-
etrate the cranium through the roof of the orbit. It contains large c&xiiies, frontal sinu-
ses (a, figs. 23 and 24), which open in the ethmoidal notch, and add greatly to the thick-
ness of the bone at its lower part. They are separated by a septum, which is often bent
to one side, and is generally imperfect. The capacity of these sinuses is very variable ;
they often extend throughout the whole of the orbital plates, almost to the edge of the
sphenoid. The study of these sinuses, which are connected with the organ of smelling,
is of great importance in determining the facial angle.
Development. — The frontal bone is developed from two lateral points of ossification,
which appear about the middle of the second month, and conunence in the orbital arches.
At this time the edges are in approximation below, but above are separated by an angular
* This retiring angle measures pretty exactly the facial angle.
SPHENOID BONE.
3f
interval, which forms the anterior angle of the anterior fontanelle. The two pieces are
united by suture during the first year ; it is gradually effaced afterward, being longest
visible at its inferior termination, though it is uncommon to find it permanent through
life. Independently of these general changes which the bone undergoes in the course
of its development, there are also certain peculiar alterations in which the sinuses are
concerned. These cavities make their appearance during the first year, and gradually
increase in size, not only up to the period of manhood, but even to old age.
The Sphenoid Bone {figs. 13 and 14).
This bone has received its name from the Greek word a^rjv [S. wedge,) because it is
inserted like a wedge between the other bones. It is situated at the anterior and mid-
dle part of the base of the cranium {fig. 23). Almost ^ j3
all anatomists agree in considering it as a separate
bone ; but Soemmering and Meckel describe it as united
with the occipital, under the name of basilar or spheno-
occipital bone. It is a single and symmetrical bone, con-
sisting of a bodi/ or central part, from which spring, on
each side, two horizontal portions, the greater and less-
er wings of the sphenoid ; and below two vertical col-
umns, the pterygoid processes. It has been compared to
a bat with extended wings. We shaU consider it as
divided into a body and lateral parts.
The body, or central part, is of a cubical form, and therefore presents six surfaces.
Superior or cerebral surface {of a d,fig. 13). Proceeding from before backward, we
observe, 1. A smooth plane surface (a), slightly depressed on each side, over which the
olfactory nerves pass. 2. A transverse groove, optic groove {b), on which the commis-
sure of the optic nerves rests, and which is continuous on each side with the optic fora-
men (1 1).* 3. A deep quadrilateral fossa (c), in which the pituitary gland is lodged,
called the sella turcica, supra-sphe7ioidal, or pituitary fossa. 4. On the sides of this fossa,
two grooves, named cavernous or carotid grooves, because they correspond to the carotid
arteries and cavernous sinuses. Anteriorly the cavernous groove gives attachment to
the ligament of Zinn, a tendon which gives origin to three muscles of the eye. Near its
anterior termination, and between it and the pituitary fossa, is the middle clinoid process,^
generally nothing more than a simple tubercle, but sometimes sufficiently developed to
unite either with the anterior or with the posterior clinoid processes, the former case
being the more common. 5. Behind the pituitary fossa we observe a quadrilateral plate
{d), directed obliquely from above downward and backward ; its anterior surface
forms part of the fossa, its posterior surface is continuous with the basilar groove, its
lateral edges are notched for the fourth and sixth pair of nerves, and the superior border,
which separates the basilar groove and the pituitary fossa, presents, at each extremity,
an angular process (e), the posterior clinoid (from kIivt], a bed, from a supposed resem-
blance of the anterior and posterior clinoid processes to the four corners of a bed).
6. From the lateral and anterior parts of the body of the sphenoid arise two triangular pro-
cesses (n 0, n o), flattened above and below, extremely thin and fragile, and directed
transversely : these are denominated the orbital or lesser wings of the sphenoid {alee mi-
nores), or the wings of Ingrassius, from the anatomist who first gave a good description
of them. The superior surface of these processes is flat, and corresponds to the ante-
rior lobes of the brain ; the inferior surface forms part of the roof of the orbits ; the ante-
rior edge is bevelled below, and rests upon the posterior border of the frontal and the eth-
moid ; the posterior edge is thin and sharp externally, thicker internally, and divides the
anterior and middle fossae of the base of the cranium ; the summit (o) is pointed, and
hence the processes are sometimes called ensiform or xiphoid ; the base presents the in-
ternal orifice of the optic canal or foramen (1), which is directed outward and forward,
and gives passage to the optic nerve and the ophthalmic artery. The base of the lesser
wing terminates behind in a projecting angle (w), which forms the anterior clinoid process ;
and beneath this is a deep notch, sometimes a foramen, for the carotid artery. Occasion-
sdly the anterior are united to the posterior clinoid processes by a long bridge of bone.
AH the part of the sphenoid in front of the sella turcica, including the smaller wings,
forms the anterior sphenoid of some modern anatomists. In this portion of the bone the an-
terior fossae of the base of the cranium are situated. The remaining portion of the bone,
placed inferior to the former, constitutes the posterior sphenoid, and in this the middle
fossae are situated. The separation of these two parts, which is but temporary in man,
existing only during the early months of foetal Hfe, is permanent in quadrupeds.
The inferior or guttural surface of the body {fig. 14) presents, in the median hne, a
ridge or crest, called the beak of the sphenoid or rostrum {g) ; it is more prominent anteri-
orly than posteriorly, is received into a groove of the vomer, and is continuous with the
* [The groove is formed on an eminence named the olivary process.^ • j i,
f When the middle clinoid processes are united with the posterior, they are then also joined to the anterior.
OSTEOLOGY
' %nterior ridge of the body of the bone. On each
side is a deep furrow concealed by a lamella (on each
side of g), under which the edges of the vomer are
insinuated. At the bottom of this furrow is seen
the orifice of a temporary canal, which exists only in
young subjects, and which, passing obliquely through
the sides of the bone, opens in the sphenoidal fissure.
This canal is the trace of the still incomplete union
of the anterior and posterior sphenoid ; it disappears
as soon as the sinuses within the bone are developed.
More externally, and on the same surface, is situated
a small groove running from before backward, which
lorms part of the ptery go-palatine canal, along which an artery of the same name passes.
Still more externally are the pterygoid processes (6 m h) {Trrepv^, ala), two large projections
directed perpendicularly downward. In front their surface is broad above, where it forms
part of the pterygo-m2ixilIary fossa, and rough below, for articulation with the palate bone.
Behind is a deep fossa, into which the internal pterygoid muscle is inserted : it is named
the pterygoid fossa, and is formed by two laminae, named the external and internal ptery-
goid plates, of which the external (b) is the broader, and the internal (m) the longer. At
the upper part of the internal plate is an elliptical depression called the scaphoid fossa,
which gives attachment to the circumflexus palati muscle. The internal surface of the
pterygoid process contributes to form the external wall, and posterior opening of the na-
sal fossa {h i, fig. 25). The outer surface of the external plate is broad, forms part of
the zygomatic fossa, and gives attachment to the external pterygoid muscle. Tlie base
of the pterygoid process is pierced from before backward by the vidian or pterygoid canal
(6 6, Jig. 14) ; its summit is deeply bifurcated, to receive the tuberosity of the palate bone.
The internal branch of this bifurcation (internal pterygoid plate) is very delicate, and is
curved into a hook-like process (s) {hamular process), round which is reflected the tendon
of the circumflexus or tensor palati muscle.
The anterior or ethmoidal surface of the body of the sphenoid presents, 1. Above and
in the median line, a small horizontal projecting angle {f,figs. 13 and 14), which artic-
ulates with the posterior border of the cribriform plate of the ethmoid. 2. Below this, a
vertical ridge {f g,fig. 14), continuous with the septum of the sphenoidal sinuses, and
articulating with the perpendicular lamella of the ethmoid. 3. On each side the open-
ings of the sphenoidal sinuses (7 7). These are two in number ; they are separated
from each other by a septum, which inclines sometimes to the right side, sometimes to
the left, and are subdivided into a number of irregular cells. They are wanting in the
young subject, but acquire a great size in the adult, occupying the whole body of the
sphenoid, and extending into the base of the lesser wings, and even occasionally into the
substance of the palate bone. External to the irregular orifice of the sphenoidal sinuses
is a rough surface, which articulates above with the lateral masses of the ethmoid, and
below with the palate bone. The orifice of the sinus is in a great measure closed by a
lamina of very variable shape, curved upon itself, and designated sphenoidal turbinated, or
triangular hone {cornu sphenoidale, ossiculum Bertini) {t t, and fgs. 15 and 16, c c). This
plate, which remains separate for some time, appears as if it arose from the upper part
of the palate bone, and formed the anterior and part of the inferior wall of the sinus. It
is not unusual to find it united either to the palate bone or to the ethmoid.
The posterior or occipital surface {u,fig. 13) is quadrilateral, rugged, and irregular ; it
articulates with a corresponding surface on the basilar process of the occipital bone, by
means of a cartilage, which is very early ossified. On the posterior aspect of the bone is
situated the posterior orifice of the vidian canal.
The lateral surfaces of the body of the sphenoid pass into the base of the great icings,
which we shall next describe.
Great or temporal wings {y z). This portion of the bone consists of two large triangu-
lar prolongations, on which there are three surfaces : a superior, an anterior, and an in-
ferior ; two borders, an external and an internal ; and two extremities, an anterior and a
posterior.
Superior or cerebral surface (y 2 z). This surface, which forms part of the middle fossa
of the base of the cranium, is concave, quadrilateral, and marked by cerebral impressions
and vascular furrows. Towards its inner part, and proceeding from before backward,
we observe, 1. The superior maxillary forameii (3), or foramen rotundum, directed obliquely
forward and outward, which gives passage to the superior maxillary nerve. 2. The in-
ferior maxillary foramen, or foramen ovale (4), which perforates the bone directly from
above downward, and transmits the inferior maxillary nerve. 3. The foramen spinosum,
or spheno-spinosum (5), which is the smallest of the whole, and gives passage to the mid-
dle meningeal artery.
External or temporo-zygomatic surface. This surface is divided into two parts by a
transverse ridge ; the superior or temporal {l,Jig- 14) forms part of the fossa of the same
name, and gives attachment to the temporal muscle ; the inferior (p) fonns the upper
SPHENOID BONE. ^
part of the zygomatic fossa, and gives attachment to the external pterygoid muscle. On
this last part we perceive the inferior orifices of the oval and spinous foramina.
Anterior or Orbital Surface. — This surface {w w) is four-sided and smooth, and forms the
greater part of the external wall of the orbit. Its superior border unites with the frontal
bone ; the inferior forms part of the spheno-maxillary fissure. The internal border con-
tributes to form the sphenoidal fissure, and has a small tubercle near its inner termina-
tion. The external joins the malar bone.
Internal Border. — This border is convex, and commences in front by a triangular and
very rough surface (y y,fig. 13), which articulates with a corresponding surface on the
frontal bone ; it then forms part of the sphenoidal fissure (2), and finally bends outward
to join the petrous portion of the temporal bone : in this place it is grooved for the lodg-
ment of the cartilaginous portion of the Eustachian tube. The sphenoidal fissure, or
foramen lacerum superius (2 2, figs. 13 and 14), partly formed in the way we have described,
is completed by the lesser wing of the sphenoid. Wide at its internal extremity, it be-
comes narrow at its outer end, where it is closed by the frontal bone at o. It gives pas-
sage to the third, fourth, the ophthalmic branch of the fifth, and the sixth pair of nerves,
to the ophthalmic vein, and to a prolongation of the dura mater. At the internal extremity
of the fissure there is a furrow, which is occasionally converted into a foramen for the pas-
sage of a recurrent branch of the ophthalmic artery, which goes to the dura mater.
The external border is concave, bevelled on the outside superiorly, and on the inside
inferiorly, for articulation with the temporal bone.
The anterior extremity is very thin (behind y, fig. 13), and bevelled on the inner side for
articulation with the anterior and inferior angle of the parietal.
The posterior extremity presents a vertical process (z), the spine or spinous process of
the sphenoid, which is received into the angle formed by the union of the squamous and
petrous portions of the temporal bone, and gives attachment to the internal lateral liga-
ment of the inferior maxilla, and the external or anterior muscle of the maUeus.
Connexions. — The sphenoid articulates with all the bones of the cranium, and with
the palatine, vomer, and malar bones of the face.
Structure. — The most remarkable circumstance in the structure of the sphenoid is the
presence of the sinuses, which convert the body of the bone into two or more cells (5,
fig. 22). The compact tissue prevails in the lesser and the greater wings, and in the
pterygoid processes, the thick part only of these containing spongy substance.
Development. — In the foetus, as we have already mentioned, the sphenoid is divided
into two quite distinct parts: 1. An anterior sphenoid, consisting of the lesser wings
and the portion of the body which supports them ; and, 2. A posterior sphenoid, formed
of the great wings and the part of the body which corresponds to the sella turcica.
1. The anterior sphenoid is developed from four points of ossification; two for the
body, and two for the alae minores.*
2. The posterior sphenoid is also developed from four points ; two for the body, and
two for the great wings.
Besides these eight points, there are two others on each side ; one for the internal
plate of the pterygoid process, and one for the sphenoidal turbinated bone ; so that the
whole number of centres of ossification of the sphenoid is twelve.
The osseous points of the great wings are the first to appear ; they are visible from
the fortieth to the forty-fifth day ; a short time afterward, those of the lesser wings,
which are situated on the outside of the optic foramen. At the end of the second month
the osseous points of the body of the posterior sphenoid are distinct ; at the end of the
third month, those of the body of the anterior sphenoid, and the internal pterygoid plates :
the sphenoidal turbinated bones begin to ossify, according to Beclard, in the seventh
month of intra-uterine life ; according to Bertin, in the second year after birth.
The two points of the body of the posterior sphenoid are united from the third to the
fourth month ; the great wings are joined to the body in the course of five or six months
after birth. The two points of the body of the anterior sphenoid are joined to those of
the small wings about the third or fourth month ; they then unite together in the me-
dian plane from about the eighth to the ninth month. The union of ttie internal ptery-
goid plates takes place during the sixth month, t The anterior and posterior sphenoid
are united from the eighth to the ninth month. The sphenoidal turbinated bones are
not joined to the body of the bone until from the fifteenth to the eighteenth year. The other
changes which the sphenoid afterward undergoes are connected with the development of
the sinuses. It is united with the occipital bone from the eighteenth to the twenty-fifth year.
* According to Albinns, the anttnor spheaoid is formed exclusively by the union of tho osseous points of
the lesser wings in the median line. B6clard observes, that the process takes place sometimes as descnbed
by Albinus, but that occasionally there is a median point ; and that at other times there are two points for each
of the smaller wings, the internal of wliich forms the base of the process, and the inner half of the optic fora-
men; and the external forms, the remainder of the wing. These are the two points which I conceive to form
the body of the anterior sphenoid. The very numerous osseous points which some anatomists have described
are nothing more than irregular grains, which have been mistaken for constant centres of ossification.
t In the lower animals the two sphenoid bones remain separate during the whole ot life. The inner plate
of the pterygoid process is also a distinct bone.
40 OSTEOLOGY.
The Ethmoid Bone (figs. 15 and 16).
The ethmoid is so named from the Greek word r/Ofibc, a sieve, because it is perfoj-ated
with a number of foramina ; it is placed in the anterior and middle part of the base of
the cranium, but belongs rather to the face and nasal fossse. It is included between the
median notch of the orbital part of the frontal and the sphenoid. It is a symmetrical
bone of a cuboidal figure, consisting of three parts— a middle part or cribrifmm plate, and
two lateral masses.
Cribriform Plate. — This is a lamina situated on the median line, horizon-
tal, quadrilateral, and pierced with numerous foramina. It has two surfa-
ces, and two borders. On the superior surface (« a, fig. 15) we observe in
the middle a vertical triangular process, the crista galli (i and n, fig. 22) ;
the summit of this eminence gives attachment to the fabc cerebri ; the an-
terior border terminates in front in two small processes {alee) (/), which
articulate with the frontal bone, and often complete the foramen caecum ;
the posterior border is very oblique, and is continued to the posterior edge
of the cribriform plate by a marked thickening. There are many varia-
tions in the size and direction of this process : it is frequently deflected to
one side.* On each side is the ethmoidal groove (a), deeper and narrower in front than
behind ; it is pierced throughout its whole extent with numerous foramina, which have
been very accurately described by Scarpa, and which form two rows ; the internal, sit-
uated along the base of the crista galli, being the largest. They all transmit filaments
of the olfactory nerves ; they are funnel-shaped, and are the orifices of canals, which
subdivide in traversing the cribriform plate, and terminate in grooves, either upon the
turbinated bones or the perpendicular plate of the ethmoid. Among these openings is
one which has the form of a longitudinal fissure by the side of the crista galli, and trans-
mits the ethmoidal or nasal branch of the ophthalmic nerve.
The inferior surface of the cribriform plate (fig. 16) forms part of the roof of the nasal
Fig. 16. fossa; ; it presents on the median line a vertical plate {g g,fig. 16), which
' y' passes from before backward, and divides it into two equal parts. This
is the perpendicular plate of the ethmoid, continuous with the base of the
crista gaUi, quadrilateral, often deflected to one side, and forms part of the
septum narium (1, 2, 3, ^,fig. 22) : in front, it articulates with the nasal
spine of the frontal bone, and with the proper bones of the nose ; behind,
with the anterior crest of the sphenoid ; below, with the vomer, and the
cartilage of the septum ; and above it is united to the cribriform plate,
along the line of the crista galli, which appears to grow out of it. The
anterior border of the cribriform plate articulates with the frontal. The
posterior is usually notched for the reception of the spine, or process (/,
figs. 13 and 14), which surmounts the median ridge of the sphenoid.
The lateral masses are cuboid in figure, and formed of large irregular cells, which to-
gether are named the labyrinth. They have six surfaces : in the superior surface we ob-
serve several imperfect cells {d d,fig. 15), which, in the united state, are completed, and,
as it were, roofed in by those we have already described as existing on each side of the
ethmoidal notch of the frontal. We find, also, two or three grooves, which join with
similar grooves in the frontal bone, and form the internal orbitary canals. On the infe-
rior surface we perceive thin, irregularly-twisted laminae, which narrow the opening of
the maxillary sinuses. The most considerable of these has received the name of unci-
form or great process of the ethmoid : it is a curved plate which arises from the inferior
surface of the transverse septa, which close the anterior ethmoidal cells, and is placed
between the anterior extremity of the middle turbinated bone and the os planum or la-
mina papyracea, to be afterward described ; it sometimes articulates with the inferior
turbinated bone. The anterior surface presents half cells, which are covered by the os
unguis and the ascending process of the maxillary bone. On the posterior surface we see
the posterior extremities of the superior and middle turbinated bones, and of the superior
and middle meatus, and a convex, uneven surface, which corresponds with the posterior
ethmoidal cells. This surface articulates with the sphenoid above, and with the palate
bone below. The external surface is formed by a smooth, quadrilateral plate {e,fig. 15),
placed vertically and very thin, to which the ancients gave the name of lamina papyracea
or os planum. It has an elongated, rectangular form, is slightly curved upon itself, and
constitutes a great part of the internal wall of the orbit. The superior border articu-
lates with the frontal, and assists in forming the orifice of the internal orbital canals :
the inferior articulates with the maxiUary and palate bones, the anterior with the os un-
guis, and the posterior with the sphenoid and palate bones.
The internal surface of the lateral masses constitutes the greatest part of the external
wall of the nasal fossae : on it we observe, in front, a rough, quadrilateral surface, marked
* Morgagni mentions the case of an asthmatic subject, in whom the crista galli was so obliquely placed,
that the ethmoidal groove on one side was very much contracted, and considerably enlarged on the othet
There was a much greater number of foramina on one side than on the other.
PARIETAL BONES. 41
by grooves and canals, which lodge the ramifications of the olfactory nerve ; behind, two
thin plates, twisted upon themselves like certain shells : they are the turbinated or spongy
bones of the ethmoid, or concha of the ethmoid. The superior {b, fig. 35) is the smaller,
and is sometimes named concha of Morgagni ; Bertin has seen it double. The inferior
{cfig. 37) is larger, and forms the middle concha ; it articulates by its posterior extremity
with the palate bone, and its superior border is continuous with a transverse septum,
which stretches across to the lower edge of the os planum, and partially closes the mid-
«lle or frontal cells. The superior and middle turbinated bones are separated by a hori-
zontal groove called the superior meaius of the nasal fossae (between b and c, fig. 37), at
the superior part pf which appears an opening of communication with the posterior eth-
moidal cells. Below the middle turbinated bone is a similar groove (between c and d,
fig. 37) running from before backward, and forming part of the middle meatus of the nose.
Anteriorly it leads into a cell, the lower part of which is broad and the upper narrow,
whence it has received the name of infundibulum. This cell communicates directly
with the frontal sinuses, and, by a small aperture, with the anterior ethmoidal cells.
Internal Structure. — ^The ethmoid is composed of extremely thin and fragile plates, ar-
ranged in more or less irregular cells, having a hexahedral, pentahedral, or tetrahedral
shape. They are disposed in distinct series, which have no communication with each
other. The anterior cells are the largest and most numerous ; they open into the mid-
dle meatus by the infundibulum ; the posterior'open into the superior meatus. There
is a little spongy substance in the crista galli, which is even sometimes hollowed into a
small sinus which communicates with the frontal sinuses. There is also spongy sub-
stance in the turbinated bones, and here, by a remarkable exception, it occupies the
surface. The specific lightness of the ethmoid is such that it floats in water, and its ex-
treme brittleness is readily explained by its spongy structure.
Connexions. — The ethmoid is connected with thirteen bones : the frontal, the sphe-
noid, the ossa unguis, the superior maxillary, the inferior turbinated, the nasal, the pal-
ate bones, and the vomer.
Development. — The ossification of the ethmoid does not conmience until the fifth
month. It begins in the lateral masses, and more particularly in the os planum ; shortly
afterward the spongy bones make their appearance. The middle portion is not ossified
until after birth. The crista galli and the contiguous part of the perpendicular plate, and
the cribriform plate, become bony between the sixth month and the first year. At the
end of the first year, the cribriform plate is united to the lateral masses. In the foetus,
at the full time, the lateral masses are so little developed, that their internal and exter-
nal walls are almost contiguous. The cells are completely formed about the fourth or
fifth year.
The Parietal Bones {figs. 17 and 18).
The parietal bones are so called because they form the greatest part of the s'aes oi
the head. They are two in number, the right and the
left ; but sometimes in the adult they are united so as
to form only one bone. They occupy the summit and
sides of the head. In shape they are quadrilateral, and
much thicker above than below, so that a force applied u^,^
to the crown of the head often causes a fracture of the \i~^
lower parts of these bones. The parietal bones have J'
two faces, four borders, and four angles. ^^^
The external or cutaneous surface (fig. 17) is convex '-
and smooth, with a projection in the centre, the parietal
protuberance (j), which is more prominent in the child
than in the adult, and corresponds with the point where
the breadth of the cranium is greatest. Below this
there is a semicircular line (g), with the concavity looking downward, which forms the
superior boundary of the temporal fossas, and gives attachment to the temporal aponeu-
rosis ; the rest of the surface below this curved line gives attachment to the fibres of the
temporal muscle. The rest of this surface is covered only by the cranial aponeurosis
and the skin.
The internal or encephalic surface {fig. 18) is concave, and marked with mammillary
projections and digital impressions ; it is traversed by ramified ^ooves, resembling the
veins of a leaf {ff, fig. 18), which converge partly to the anterior inferior, and partly to
the posterior inferior angle of the bone, and correspond to the branches of the menin-
geal artery. The parietal fossa, a concavity corresponding to the prominence of the same
name, is situated in the middle of this surface.
The superior or sagittal border ( a b,fig. 17 and 18) is the longest : it is thick and den-
ticiUated, and, by its union with the opposite bone, forms the sagittal suture. On its in-
ternal surface there is a furrow along its whole extent, which, with that in the oppo-
site bone, forms the groove for the longitudinal sinus. Near this border is sometimes
F
OSTEOLOGY.
found a foramen (c) {foramen parietalc), of very varia-
ble dimensions, which opens into the posterior part of
the groove, and transmits a vein which is sometimes
very large. We may farther state, that along this sur-
face the impressions made by the pacchionian glands
are to be observed. They are more remarkable in the
old than young subject.
The inferior or temporal border {d e) is the shortest :
it is concave, thin, and very obliquely cut on the out-
side, so as to resemble a scale with, radiated furrows ;
hence its name {margo squamosus) : it articulates with
the squamous portion of the temporal bone.
The anterior or frontal border {b e) is less thick and
less deeply indented than the occipital edge : it is bev-
elled externally above, and internally below, so as to articulate with the frontal bone,
which presents a precisely opposite arrangement.
The posterior or occipital border (a d) is very deeply indented, and articulates with the
superior border of the occipital by the lambdoid suture. Of the four angles, the two supe-
rior are right angles ; of the inferior, the anterior or sphenoidal (e) is acute, and rendered
very thin by the sloping of the anterior and inferior edges of the bone. Inside this angle
is situated the principal furrow, or sometimes canal, which lodges the middle meningeal
artery and veins : surgeons, therefore, recommend this angle to be avoided in perfonning
the operation of trepanning. The posterior or mastoid angle (d) is, as it were, truncated,
and is received mto the retreating angle formed by the union of the mastoid and squa-
mous portions of the temporal bone. Internally, it is grooved for the reception of part
of the lateral sinus (e, fig. 22).
Connexions. — Tlie parietal is articulated with five bones : the frontal, the occipital, the
temporal, the sphenoid, and the opposite parietal Above, it is separated from the skin
by the cranial aponeurosis only, and consequently it exposes a large extent of surface
to the action of external agents : hence fractures of this bone are very common, and
they are, more frequently than other fractures, accompanied by effusions of blood, on
account of the connexion with the middle meningeal artery and vein.
The internal structure is quite similar to that of the frontal. In that bone we find
venous canals traversing long tracts in the substance of the diploe.
Development. — The parietal bone is developed from one point of ossification alone,
which appears in the situation of the protuberance. Its firet traces are observed about
the forty-fifth day. The angles are the last parts of the bone which are developed : their
absence gives rise to the fontanelles of the cranium.
The Temporal Bones [jigs. 19 and 20).
The temporal bones are so called from being situated in the locality of the temples.
They are two in number, and occupy part of the sides and base of the cranium, below
the parietal bones, above the inferior maxillary, in front of the occipital, and behind the
sphenoid. The temporal bone contains the complicated apparatus of the organ of hearing.
Its figure is veiy irregular, and therefore, in order to facilitate the description, we shall
consider it as divided into three parts, the squamous, the mastoid, and the petrous portions.
Squamous portion. — The squamous portion has the form of a semicircular scale (a b c,
Jigs. 19 and 20), bearing a considerable resemblance to
one of the valves of certain shell-fish : it occupies the
anterior and superior part of the bone. It is by far the
thinnest part of the cranium ; and hence the common
but well-founded notion of the danger of blows upon
the temple, although this danger is much lessened by
the presence of the zygomatic arch and the temporal
^^ muscle.
The external surface (/, fig. 19) forms part of the
temporal fossa : it is smooth, convex, and marked by
vascular furrows. At its lower portion is situated the
zygomatic process (m n) {^evyvvu, I join), so called be-
cause it unites the sides of the cranium to the face : it
is also named a-iisa capitis, and is one of the longest
processes of the skeleton. At its origin it is broad and directed outward ; it then grad-
ually diminishes in size, and bends so as to turn horizontally forward and a little out-
ward : it is flattened from without inward. The external surface is convex, and may
be easily traced under the skin ; the internal surface is concave ; the superior border,
which gives attachment to the aponeurosis of the temporal muscle, convex and thin ;
the inferior, which gives origin to the meisseter muscle, concave, thick, and much shorter ;
and the extremity (m) is cut from below upward and forward, and denticulated for attach
ment Avith a corresponding surface on the malar bone. The base of this process is
TEMPORAL BONES. 43
grooved above, and serves as a julley for the reflection of piart of the temporal muscle.
Posteriorly, it separates into two portions or roots : the inferior (o) of these is the larger ;
it is transverse, covered with cartilage, and bounds the glenoid cavity in front, serving
also to increase the articular surface in the joint of the lower jaw. The superior (?i) is
longitudinal or antero-posterior in its direction : it also is bifurcated, one branch directed
upward, and forming part of the temporal semicircular line, the other passing between
the auditory meatus and the glenoid cavity. At the point of junction of the two roots
there is a tubercle, which gives insertion to the external lateraUigament of the lower jaw.
Between the two roots we observe the glenoid cavity (behind flitaivided into two portions ;
the anterior of which is articular, smoothjand in the fresh state covered with cartilage ;
the posterior (s) does not enter into the fOTfflation of the joint. The parts are separated
by a fissure, called glenoidal fissure, or fissure of Glasserius (before s), which transmits the
corda tyrapani nerve,* the laxator %mpani or external muscle of the malleus, the inter-
nal auditory vessels, and lodges the processus gracilis of the malleus {process of Raw).
The internal surface of the squamous portion (g, fig. 20) presents a concavity propor-
tionally greater than the convexity on the outside : it is
marked by the ordinary inequalities, and is generally trav-
ersed, towards the upper part, by a horizontal vascular fur-
row, running from before backward.
The circumference (a h c) forms about three fourths of a cir-
cle ; it is very obliquely cut internally in its two posterior
thirds, which unite with the parietal ; the anterior third is
thicker, and bevelled externally : it unites with the sphenoid.
Mastoid Portion (c e d,figs. 19 and 20). — ^The mastoid por-
tion is very prominent in adults, but only slightly developed
in young subjects : it occupies the posterior and inferior
part of the bone.
The external surface {fig. 19) is convex and rough, ter-
minating below and in front in a nipple-shaped process, the
mastoid process (e). Inside of this is a deep gi'oove called digastric (fossa digastrica),
because it gives origin to the muscle of that name. Behind the mastoid process we observe
the mastoid foramen, an opening which transmits the mastoid artery and vein, but which
is subject to numerous varieties in its size and position. Above the process is a rough
surface, for muscular attachments of the splenius and sterno-cleido mastoideus muscles.
The internal surface is concave, and forms part of the lateral and posterior fossae of the
cranium ; we observe on this surface a deep and broad semi-cylindrical groove {h i, fig.
20), which lodges the greater portion of the lateral sinus. At the bottom of this gi'oove
the mastoid foramen opens by one or more apertures. There is generally a considerable
difTerence in size between the grooves on the right and left side of the head.
The circumference, very thick and indented, unites in front with the circumference of
the squamous portion, forming a retiring angle (c), which is occupied by the posterior
inferior angle of the parietal bone, and then curves round in a semicircle to join the
occipital bone by means of a thick, uneven edge.
Petrous Portion ; Rocher or Pyramid {ci dv, fig. 20) Petrous Process. — This part of the
bone is placed between the squamous and mastoid portion, resembling a pyramid, pro-
jecting forward and inward into the cavity of the cranium. Its name sufficiently indi-
cates the extreme hardness of its osseous structure : a circumstance very important in
relation to its functions (for this part of the bone serves as the receptacle of the vibratory
apparatus of the ear), and at the same time is calculated to explain the frequency of frac-
tures in this situation. It has the form of a truncated pyramid with three faces, separated
by three borders.
The inferior surface, which is seen at the base of the cranium, is very irregular, and
presents the following objects, in an order from without inward: 1. A long, slender
process (k), generally from twelve to fifteen lines, sometimes two inches in length.
This process, which hcis been denominated styloid, is, in man, usually continuous with
the rest of the bone, but occasionally it is articulated by a movable joint, as in the lower
animals, where it is always separate, and is known by the name of styloid hone.
2. Behind this process, between it and the mastoid, is a sort of fossa, at the bottom
of which we find, besides one or two accessory foramina, the stylo-mastoid foramen (y, fig-
21), which forms the inferior aperture of a canal improperly called the aqueduct of Folio-
pius,i which transmits the facial nerve. 3. Inside of the styloid process and the stylo-
mastoid foramen is a triangular surface called the jugular, which joins with a correspond-
ing part of the occipital bone. 4. A little within and behind the styloid process is a deep
depression, which forms part of the jugular fossa, and lodges the enlarged commence-
ment or sinus of the jugular vein. 5. The inferior orifice of the carotid canal (», fig. 21),
Which is directed at first vertically, then horizontally, nmning forward and inward, and
* [The corda tympani, according to the author, passes through a special orifice by the side of the glenoid
fissure. See description of the ear, in/rd.]
i [Fallopius knew that this canal transmitted a nerve; he named it aqueduct merely on account of its direction.]
44 OSTEOLOGY.
again vertically at its termination in the cavity of the cranium. 6. A rough surface,
which gives attachment to the levator palati muscle. Lastly, in front of the styloid
process is an osseous lamma, in the form of a vertical crest {s,fig. 19), a continuation of
the plate which forms both the inferior portion of the auditory canal, and the posterior
portion of the glenoid cavity, which it completes. This crest, which has been described
by authors under the name of vaginal process, because it surrounds the styloid process
without adhering to it, extends inward to form part of the carotid canal, and outward to
the mastoid process.
The other two surfaces^ the petrous portion, of which one is superior and the other
posterior, are in the interior of the cranium.
The superior surface, which looks forward, has a furrow running from before backward
and from below upward, terminating about llie middle of the surface in a small iiTcgular
opening, the hiatus Fallopii, which communicates "^jith the aqueduct of Fallopiu^. The
furrow and the hiatus contain the superior or cranial filament of the vidian nerve, and a
small artery.
The posterior surface shows a canal directed obliquely from within outward and for-
ward. This is the internal auditory meatus {I, fig. 20) ; it is shorter than the external,
and is terminated by a lamina divided into two parts by a transverse ridge ; in the supe-
rior of these parts there is a single orifice, the commencemnet of the aqueduct of Fallopius,
which receives the facial nerve ; the inferior is perforated by numerous openings, through
which the fibres of the auditory nerve pass ; it is the cribriform plate of the auditory
nerve. Behind the internal auditory meatus is a small opening, which is the orifice of
a canal named aqueductus vestibuli.
These surfaces of the petrous process are separated by three borders.
On the superior border (m v) we observe a furrow for the superior petrosal sinus ; cdso
a projection which corresponds with the superior semicircular canal of the internal ear,
and which is most prominent in the young subject ; inside of this projection, a cavity,
the depth of which is in the inverse ratio of the age, and is gradually obliterated in the
adult, and near the summit a depression, on which the fifth or trifacial nerve rests.
The anterior or sphenoidal border, in the external half of its extent, is connected with
the squamous portion of the bone ; at first by a suture which often remains perfect even
in adult life, and subsequently in a great measure disappears, but is never completely
obliterated. The internal half is free, and forms, by its union with the squamous portion,
a retiring angle, at the apex of which are the openings of two canals, placed parallel,
like the barrels of a double-barrelled gun, and separated by a small osseous lamina. The
superior canal, much the smaller, contains the internal muscle of the malleus ; the in-
ferior canal forms the osseous portion of the Eustachian tube. They both communicate
with the cavity of the tympanum ; the bony lamella, which separates them, is called the
cochleariform process.
The inferior, posterior, or occipital border, rough, but without indentations, is united to
the occipital bone by juxtaposition. It has a deep notch, which forms part of ihe fora-
men lacerum posterius. This notch, which is continuous with the jugular fossa, already
described, is frequently divided into two portions by a tongue of bone, one being anterior,
the other posterior. Immediately in front of the notch is a small triangular opening,
the inferior orifice of the aqueduct of the cochlea.
On the base (fig. 19), which is not distinct from the rest of the bone, the only part to
be noticed is the external auditory meatus {y), which is situated behind the glenoid cavity.
It is rough infeiiorly for the insertion of the cartilage of the ear ; and the canal, which
is more contracted in the middle than at either extremity, takes a curved direction, the
concavity looking downward and forward : it is chiefly formed by a curved plate, named
the auditory process, which constitutes the posterior half of the glenoid cavity.
The summit of the pars petrosa (», fig. 20) is very irregular and truncated : it presents
the superior orifice of a carotid canal,, and forms part of the foramen lacerum anterius.
Connexions. — The temporal articulates with five bones, viz., three of the cranium, the
parietal, occipital, and sphenoid ; and two of the face, the malar and the inferior maxil-
lary ; we might add, also, the os hyoides, which is attached by a ligament to the styloid
process.
Internal Structure. — The squamous portion is compact throughout, excepting towards
the circumference, where traces of diploe may be seen. The petrous portion is still
more compact and hard, resembling in density the teeth, or certain ivory-like exostoses.
The mastoid portion is hollowed out into large cells, and is very liable to be affected by
caries. In the description of the orga7i of hearing we shall notice the cavities which ex-
ist in the petrous portion ; the nervous and vascular canals will be described with the
nerves and vessels which traverse them. (For the aqueduct of Fallopius, see the de-
scription of the Facial Nerve.)
Development. — The temporal bone is developed from five points of ossification : the
squamous, petrous, and mastoid portions, the auditory canal, and the styloid process,
being each distinct. The first osseous point which appears is situated in the squamous
portion, and is visible towards the end of the second month. Immediately afterward
THE CRANIUM IN GENERAL.. 45
tho petrous portion exhibits a bony nucleus, stretching from its base towards its apex.
The third point in order is that of the circle of the tympanum, a kind of ring channelled
all round for the membrana tympani. This circle, at first almost horizontal, becomes
gradually more and more oblique ; it is incomplete above, and the two extremities which
are applied to the squamous portion cross each other instead of uniting. In many ani-
mals the ring of the tympanum constitutes a distinct bone, named the lym-panic heme.
The fourth point of ossification appears in the mastoid portion during the fifth month.
The last which becomes visible is that of the styloid process : it also remains distinct
throughout life in the lower animals, and is called, the styloid lone. It is not uncommon
to find it in the same condition in the human subj'ect.
The development of these five pieces does not advance with equal rapidity. The
petrous portion is most quickly completed. The mastoid, squamous, and petrous por-
tions become united during the first year. The styloid process is attached to the rest
of the bone at the age of two or three years ; at birth, the glenoid cavity is almost flat,
on account of the absence of the auditory canal, and the slight development of the trans-
verse root of the zygomatic process. The ulterior changes which take place in the
temporal bone depend on the completion of the auditory canal and glenoid cavity, the
increasing size of the mastoid process, and the obliteration of the projections and filling
up of the hollows on the surface of the petrous portion.
It is worthy of remark, that traces of the union of the base of the petrous portion
with the squamous and mastoid portions, are visible in individuals of the most advan-
ced age.
The Cranium in general.
The different bones which we have described unite in forming the cranium, an osse-
ous cavity which encloses the brain, the cerebellum, and the annular protuberance. It
is situated above the face, is the most elevated portion of the skeleton, and forms a con-
tinuation of the vertebral column. "The form of the cranium is that of an ovoid, flatten-
ed below and at the sides, and with the large extremity turned backward. It is never
perfectly synametrical ; but a very great deviation has always appeared to me coincident
with disease of the brain. From attentive examination of a great number of sculls of
idiots and maniacs, I have observed that in these subjects there is a remarkable differ-
ence between the two sides.
The dimensions of the cranium have been very accurately determined by Bichat. The
antero-posterior diameter, measured from the foramen caecum to the occipital protuber-
ance, is about five inches ;* the transverse diameter, measured between the base of the
petrous portions of the temporal bones, is four inches and a half ; the vertical diameter,
extending from the anterior edge of the foramen magnum to the middle of the sagittal
suture, is rather less than the transverse. In front, and behind the spot where the
height and breadth of the cranium are measured, i. e., in front and behind the bases of
the petrous bones, the diameters progressively diminish. Hence it follows, that the
point where the cranium has the greatest capacity is the junction of the two anterior
thirds with the posterior third ; that is to say, at the place of meeting, or, if I may use
the expression, at the confluence of the brain, cerebellum, and spinal marrow.
The cranium, however, presents many varieties, both in regard to its dimensions and
shape. The varieties of form of the scull in different individuals appear generally to de-
pend upon the preponderance of one diameter over another ; and it may be remarked,
that in these cases, where one diameter is much increased, the others are almost in-
variably diminished in the same proportion, so that the absolute difference in size is by
no means considerable.
There are also variations in size and figure peculiar to the crania of different nations,
as has been shown by the researches of Blumenbach and Scemmerring. In the white,
or Caucasian race, the cranium is decidedly much larger than in the others, more es-
pecially than in the negro. Among certain tribes, the configuration of the cranium is
determined by the permanent or frequently-repeated compressions to which the sculls
of infants are subjected. It varies also according to age and sex, being proportionally
larger in the foetus than in the adult, and in the male than in the female. It should be
remarked that all these varieties are exclusively confined to the vault of the cavity.
Since the cranium is exactly moulded upon the brain, great interest has been attached
to the exact appreciation of its dimensions, and hence the different measurements which
have been adopted for this purpose. The oldest is the one proposed by Camper, under
the name of the facial angle. This angle is intended to measure the relative proportions
of the cranium and face. It is taken by drawing one line from the middle incisors of
the upper jaw along the front of the forehead, and another from the same point to the
auditory meatus. The angle included between these lines is in the European from 80"
-0 SS*, in the Mongolian race 75°, and in the negro, 70°. This anatomical fact had not
escaped the attention of the ancients. We observe that in the statues of their heroes
* [An old Paris inch is =1.065765 inch English ]
40'- OSTEOLOGY.
and gods they have even exaggerated the facial angle, which is generally 90°, and even
more in the case of Jupiter Tonans.
The facial angle gives no information respecting the capacity of the posterior regions
of the cranium, and, consequently, Daubenton had this specially in view in his mode of
measurement, which bears the name of the occipital angle of Daubenton. This, however,
like the preceding, and, in fact, all linear measurements applied to the determination of
the capacity of the scull, is necessarily inexact. The variable thickness of the walls of
the cavity, the greater or less development of the sinuses, and the projection of the al-
veoh, or their obliteration after loss of the teeth, are all important elements in the esti-
mate, which have been entirely neglected ; and, moreover, the facial and the occipital
angle can only express the dimensions in one direction. The capacity of a cavity, hke
the volume of a solid, can only be determined by an estimate of its three dimensions.
Hence, measures of surface, and measurements taken in the interior of the cranium,
must be employed for this purpose. Tliis is the object proposed by Cuvier, in comparing
the area of the cranium and the area of the face, cut vertically from before backward.
A section of the cranium represents an oval, with the broad end backward : a section
of the face is triangular. In the European, the area of the cranium equals four times
that of the face, without the lower jaw ; in the negro, the area of the face is increased
one fifth. The most general result which can be deduced from a comparison of the cra-
nimn and face in man and in mammaUa, is that they are developed in an inverse ratio.
One appears to augment at the expense of the other.
Division of the Cranium, and Description of its different Regions.
The cranium, considered as one piece, presents an external surface, and an internal, or
encephalic surface. Many of the objects seen on these surfaces have been already de-
scribed with the particular bones to which they belong ; these we shall merely point
out : others, which result from the union of the bones in one conunon whole, will be ex-
amined more in detail.
External Surface of the Cranium.
The external surface of the cranium offers for consideration a superior region or
vault, an inferior, and two lateral regions.
The superior region or vault is bounded by a circular line, passing from the middle,
frontal, or nasal protuberance {glabella), along the temporal fossa, to the external occipi-
tal protuberance. It is principally covered by the occipito-frontalis muscle, and presents
in the median line, 1, the trace of the union of the two primitive halves of the frontal
bone ; 2, the bi-parietal or sagittal suture (sagitta, an arroic), which forms a right angle,
in front, with the fronto-parietal or coronal suture, and terminates behind at the superior
angle of the occipito-parietal or lambdoidal suture (from the Greek letter lambda).
On each side we observe three eminences, more or less prominent in different indi-
viduals, and always most marked in the young. These are the frontal, the parietal, and
the superior occipital protuberances. Between the frontal and parietal protuberances,
the coronal suture is situated ; and between the parietal and the occipital, we find the
lambdoid suture. Besides these, there are a great number of smaller projections, which
Gall has also denominated protuberances, and to which much importance is attached in
his system.
The inferior region or base of the cranium {fig. 21) is flattened and very irregular. It is
p- 21 bounded, behind, by the external occipital protuberance
(a) and superior semicircular line {a b) ; in front, by
the glabella, or nasal eminence ; laterally, by a line
passing over the mastoid and external orbital process-
es. I shall content myself by describing in this place
the posterior half of the base of the cranium ; the
other half wiU be included in the description of the
face, with the bones of which it concurs in forming
the orbital, nasal, and zygomatic fossaj. The ptery-
goid processes below, and the posterior edge of the
sphenoid above, define the limits of these two portions.
The posterior half of the base of the cranium pre-
sents, in the median line, and in an order from behind
forward, the external occipital protuberance {a), the
external occipital crest {a c), the foramen magnum
(d), and condyles (c), the basilar process («)> ^^^ the
transverse suture, which results from the articulation
of the body of the sphenoid with the truncated inferior
angle of the occipital bone, the spheno-occipital suture.
On each side we observe the inferior occipital pro-
tuberances, presenting certain variations in size in
different subjects, to which Gall has attached great
importance in his craniological system. These pro
THE CRANIUM IN GENERAL. 47
tuberances are bounded above by the superior semicircular line of the occipital bone (J);
they are crossed in the middle by the inferior semicircular Une {g), which is separated
from the preceding by muscular impressions. Between the inferior semicircular line
and the occipital foramen are also a number of inequalities for the attachment of mus-
cular fibres. Still more anteriorly is the posterior condyloid fossa, and occasionally the
posterior condyloid foramen {g). Outside the condyles are the jugular surface (t), the
eminence of the same name, and the petro-occipital suture, running obliquely from behind
forward and inward (i k), without any indentations, or even complete juxtaposition of
the bones, and terminating behind in a large irregular opening (before i), the foramen
lacerum postcrius, which is divided into two parts by a tongue of bone : the anterior is
the smaller, and transmits the eighth pair of nerves ; the posterior is larger, and is call-
ed the jugular fossa, from its receiving the enlarged commencement {sinus or diverticu-
lum) of the jugular vein. The petro-occipital suture terminates in front in another irreg-
ularly triangular opening, the foramen lacerum. anterius (k), which is closed by cartilage,
and forms, in fact, a fontanelle between the edges of the occipital, temporal, and sphe-
noid bones. In front of the petro-occipital suture is the inferior surface of the petrous
bone, with its numerous asperities ; then, still proceeding from behind forward, we find
the mastoid process (Z), the digastric groove (m), the stylo-mastoid foramen (7), the sty-
loid and vaginal processes, the inferior orifice of the carotid canal (»), and the petro-sphe-
noidal suture, at the external termination of which the osseous portion of the Eustachian
tube opens by an orifice directed obliquely for\vard and downward.
Thus all the sutures of the posterior half of the base of the cranium meet in the fora-
men lacerum anterius. From its internal angle, the spheno-occipital suture stretches
across to the same part of the opposite foramen. The petro-sphenoidal suture sets out
from the external angle, and becomes continuous with the fissure of Glasserius ; and
the petro-occipital suture extends from the posterior angle to the occipito-mastoid suture,
which it joins at an obtuse angle : all these sutures are formed by juxtaposition, and not
by mutual reception, as those of the roof of the scull.
The lateral regions of the cranium are bounded, behind, by the lambdoid suture ; in front,
by the external orbital process ; and above, by the temporal ridge. This region, more or
less rounded in different subjects, is, nevertheless, the flattest part of the vault of the
scull. Proceeding from behind forward, we observe, 1, the mastoid region, comprehend-
ing the mastoid foramen (9, Jig. 21), the external auditory meatus, the glenoid cavity,
and the transverse root of the zygomatic process ; 2, the temporal region or fos&a, con-
cave in front, convex behind, bounded below by the zygomatic arch, which projects con-
siderably from the head, more especially in carnivorous animals, and by a ridge which
separates it from the zygomatic fossa. The temporal fossa is traversed by numerous
sutures, arranged in the following manner : The fronto-parietal or coronal suture (c b. Jig.
22) descends vertically ; from its inferior extremity two others proceed, one in front, the
sphe no-frontal, the other behind, the sphcno-parietal. Each of these soon divides into two
branches. From the spheno-parietal the spheno-temporal descends, and terminates in
the fissure of Glasserius ; the temporo-parietal (b i d) passes horizontally, and becomes
continuous with the lambdoidal suture {df). The spheno-temporal and temporo-parie-
tal sutures are, each, part of the squamous suturk. From the spheno-frontal suture the
two following proceed : the fronto-jugal,* running horizontally, and the spheno-jugal,
which passes downward ; the denominations of these sutures indicate at once the bones
by which they are formed. The explanation which we have given appears the most
Ukely to facilitate the recollection of these numerous sutures, by connecting them with
each other. The following table exliibits a summary of all that has been stated :
I^Spheno-frontaJ { gpheno-jugal.
All these sutures are remarkable, from the circumstance that the bones which enter
into their formation are cut obliquely like scales, and for the most part the edge of the
bone above is overlapped by the edge of the bone below, so that each inferior scale, like
the abutment of an arch, prevents the superior one which corresponds to it from being
forced outward. (Vide Mechanism of the Cranium. Sy\desmology.)
Internal Surface of the Cranium.
In order to examine the internal surface of the cranium, it is necessary to make two
sections, one horizontally from the occipital protuberance to the glabella {Jig. 23), the
other vertically along the median line from before backward {Jig. 22).
In the median line, proceeding from before backward, we observe the frontal crest or ridge,
and the longitudinal groove, stretching from the frontal crest, along the roof of the scull to
the internal occipital protuberance. In this groove, which is of no great depth, we find aline
which indicates the place of union of the two pieces of the frontal hone during the earJy
♦ Tho malar bone is often called the jvigal bone, and hence the names of fronto-jugal and spheno-jugaL
OSTEOLOGY.
Fig. 23.
Fig. 22. periods of life, and the internal surface of the
sagittal suture. It receives the superior longi-
tudinal sinus in its entire extent, and contains
the internal orifices of the parietal foramina.
On each side are the frontal fossae, correspond-
ing to the protuberances of the same name,
and the internal surface of the fronto-parietal
(coronal) suture {be, Jig. 22); the encephalic
surface of the parietal bone (^i dfc), and the
parietal fossa; the lambdoid suture {df), and
the superior occipital fossa. We may remark
that the fossce are deeper than would "seem to
be indicated by the external prominences, be
cause they are partly formed at the expense of
the bone itself; and that the sutures are less
deeply denticulated on their internal than on their external aspect.
Lastly, the whole internal surface of the vault of the cranium, but especially that of
the parietal bones, is traversed by ramified grooves (i i), partly for veins, partly for ar-
teries ; the venous grooves, which are not perceptible in all subjects, but which are very
large in some, are distinguished from the arterial, as M. Breschet has pointed out, by
their being perforated by numerous foramina.
The base of the cranium {fig. 23), presents three series of fossae, or three regions, ar-
ranged, as it were, in steps upon an inclined plane, from before backward, and from above
downward. They are described as the anterior, middle, and posterior regions.
Anteriw or cthmoido-frontal region. In this region we observe, in the middle, the eth-
moidal fossa, in which is the foramen caecum ; tl^e
crista gaUi (a) ; the ethmoidal grooves, and the for-
amina with which they are perforated ; the ethmoi
dal fissure, for the ethmoidal or nasal branch of the
ophthalmic nerve ; the ethmoido-frontal sutures, run-
ning from before backward ; the orifices of the inter-
nal orbitary foramina ; and the trace of the ethnw-sphe-
noidal suture, running transversely. Behind the eth-
moidal fossa, the surface of the sphenoid is slightly
impressed by the passage forward of the olfactory
nerves.
Laterally, we see the orbital plates {b), remarkable
for the prominence of their mammillary projections,
and traversed by small grooves for the ramifications
of the middle meningeal artery ; and the fronto-sfhe-
Twidal sutures (before c), which mark the union of the
lesser wings of the sphenoid (c), with the orbital por-
tion of the frontal bone {b). The orbital plates sup-
port the anterior lobes of the brain.
The middle region exhibits in the centre a fossa, in
which we observe the depression for the olfactory
nerves, the optic groove, and olivary process (before
d) ; the pituitary fossa (d), deeply excavated behind ; the quadrilateral plate (behind d) ;
the cavernous grooves ; and the anterior and posterior clinoid processes. On the sides
we find very deep fossae, which correspond with the middle lobes of the brain, called
middle lateral fossa of the base of the cranium; they are broad externally, narrow inter-
nally, and are bounded in front by the posterior edge of the lesser wings of the sphenoid (c),
and behind by the superior border of the petrous portion of the temporal bone (/«)• They
are formed by the superior surface of the petrous portion, the internal surface of the squa-
mous portion of the temporal, and the superior surface of the great wings of the sphe-
noid. They present, successively from before backward, the sphenoidal fissure (or for-
amen lacerum orbitale) ; the foramen rotundum, or superior maxillary '(2) ; the foramen
ovale (3) ; the foramen spinosum (4) ; the internal orifices of the foramen lacerum an-
terius and carotid canal (before 5), and the hiatus Fallopii. We see here, also, the union
of the sphenoid with the squamous and petrous portions of the temporal bone, forming
the sphcno-tcmporal {i and c) and pctro-sphe?ioidal sutures. This fossa is traversed from be-
hind forward and outward by a groove {i 4), which commences at the foramen spinosum,
passes along the external border of the sphenoid, or, rather, is hollowed out from the
spheno-temporal suture, and divides into two branches ; the anterior, the larger, pro-
ceeds to the anterior inferior angle of the parietal bone, with the anterior ramified groove
m which it becomes continuous ; the posterior is directed horizontally backward to the
posterior inferior angle of the parietal bone. In some cases, the portion of the groove
which extends from the foramen spinosum to the summit of the lesser wing of the sphe-
noid, almost equals in diameter the lateral grooves, and it is then almost always pierced
by foramina : it contains the middle meningeal artery, and a large vein
THE CEANIUM IN GENERAL. 49
Posterior region of the base of the cranium. This region presents in the middle the ba-
silar groove (k) ; the spheno-occipital suture, the foramen magnum (m), the anterior con-
dyloid foramina (8) {Ji,fig. 22), the internal occipital ridge, and protuberance {o,fig. 21).
Laterally, the inferior oceipital fossa, the deepest in the scull, which are formed by the
posterior surface of the petrous portion of the temporal bone, almost the whole of the en-
cephalic surface of the occipital bone, and the posterior inferior angle of the parietal.
We find here the foramen lacerum posterius (7), the suture which unites the temporal to
the occipital bone, and along the petro-occipital suture, a smedl groove named inferior pe-
trosal (on each side of A:),
The inferior occipital fossa is bounded above by a broad and deep groove (n), intend-
ed to lodge the lateral sinus, and called the lateral groove. It commences at the internal
occipital protuberance (o), and proceeds horizontedly outward to the base of the petrous
portion, where it is again enlarged, and passes roimd, extending downward and inward
along the occipital fossa, until it arrives at the occipito-meistoid suture (r), where it rises
and terminates in the foramen lacerum posterius. The inferior occipital fossa is divi-
ded into two parts by this groove : an anterior, formed by the posterior face of the pars
petrosa, and a posterior, formed by the occipital bone. In this groove, the mastoid fora-
men, the posterior condyloid foramen, when it exists, and the superior and inferior petrosal
grooves open.
The dimensions of the lateral grooves are extremely variable ; inost commonly the
left is smaller and shallower than the right, especially in its horizontal portion.
Of the eminences and depressions on the internal surface of the cranium, the most
deeply marked are those situated upon the base. This is more especially the case with
regard to the orbital plates and the middle and lateral fossae. Since the publication of
the works of Gall and Spurzheim, anatomists have re-adopted the opinion of the an-
cients, who regarded these eminences and depressions as corresponding respectively
with the anfractuosities and the convolutions of the brain : the cranium, in fact, is mould-
ed upon the brain ; to be convinced of which, it is only necessary to repeat the following
experiment, which I have often made for this purpose. Remove the brain from the
cavity of the cranium, and supply its place by plaster of Paris ; when dry, this substance
will present a faithful model of the convolutions and anfractuosities of the brain. In
cases of chronic hydrocephalus, where the inequalities of the brain are effaced by the
accumulation of fluid, the internal surface of the cranium shows scarcely any vestiges
of eminences and depressions. The osseous tissue, notwithstanding its hardness, is
easily moidded around organs, and yields with facility to the compression which soft
parts exercise upon it. It is very uncommon to open the cranium of a subject, some-
what advanced in years, without observing in some points a more or less considerable
absorption of the parietes of the scull, occasioned either by clusters of certain smaU
white bodies, called glandulae Pacchioni, or by dilated veins.
One anatomical fact worthy of notice is the want of any configuration of the external
surface conformable in its details with that of the internal surface : compare, for in-
stance, the roof of the orbit with the cranial surface of the orbital plate of the frontal
bone. This difference is due to the circumstance that the digital impressions encroach
on the diploe, and are, in part, excavated from the space otherwise occupied by it. The
two compact laminag which form the bones of the cranium are in some measure inde-
pendent of each other ; the internal one belongs, so to speak, to the brain ; the exter-
nal to the locomotive system. The diploe is the limit of these two laminae. This ana-
tomical fact is at variance with the doctrine of Gall respecting the protuberances ; it proves
that the cerebral convolutions are not faithfully represented by external prominences.
In order to complete the anatomical history of the cranium, it yet remains to consider,
1. Its general development; 2. The connexion of its several parts. (For this latter
subject, see Syndesmology.)
As to the analogies which have been so ingeniously established between the cranium
and the vertebral column, a detailed analysis of them would be out of place in an ele-
mentarv work like the present.
Development of the Cranium.
The cranium is remarkable for the early period at which its development commences.
As soon as ihe embryo is sufficiently advanced in growth to exhibit any distinction oi
parts, the head, under the form of an ovoid vesicle, greatly exceeds the magnitude of
the whole body With regard to the order in which the different parts are ossified, we
may remark, that the bones of the roof precede those of the base, in like manner as in
the vertebrae the laminae are ossified before the bodies. In both cases the evolution is
most prompt in those parts which are especially destined to protect import£uit organs.
Cranial Bones at Birth.
The bones of the roof of the scull appear before those of the base, but at birth ossifi-
cation is less advanced in the roof than in the base ; accordingly, in a foetus at the full
time, the bones of the base form a solid whole, and are immovable, while those of the
G
W OSTEOLGOY.
roof are separated by membranous intervals, which permit of pretty extensive move-
ments, so that at this period the roof of the cranium yields, in a great degree, to pressure.
At birth, there is nothing resembling the mode of union called suture. Nevertheless,
each bone presents denticulations like the teeth of a comb round the circumference.
The existence of these indentations before the period when the bones come into con-
tact, proves that they are not the result of any mechanical action produced by their
meeting; the only influence of this kind to which they are subjected during their forma
tion, is the deviation of opposing denticulations. The frontal suture is the first developed.
Another peculiarity of this stage of development is the existence of those membra-
nous intervals denominated fontanelles. They are produced in the following manner :
the process of ossification commences in the centre of the bone, and advances from that
point to the circumference, the most distant parts of the bone being, of course, the last
to be ossified. These points, in broad or flat bones, are the angles, and, consequently,
at the place where several angles of diflferent bones ultimately unite, there must exist
an unossified space at this time : these spaces are the fontanelles. They have all been
pointed out in the description of the cranial bones ; they are of especial importance to
the accoucheur, on account of the indications which they furnish for determining the
position of the child. All traces of the fontanelles are completely obliterated at the age
of four years.
The Wormian Bones.
The Wormian bones should be regarded as supplementary points or centres, developed
when the general ossification proceeds somewhat slowly ; and we therefore consider it
proper to include a description of them in the account of the development of the cranium.
The Wormian bones, so called because the first description of them has been assigned
to Wormius, a physician in Copenhagen, are also denominated exacted bones, ossa trique-
tra, or complimentary bones of the scull. They are extremely variable, both in situation,
number, and size ; but they are most common in the lambdoid suture, i. e., in the most
rugged of all the sutures, the asperities of which they tend to increase. This fact
should not be overlooked in examining fractures of the cranium. The most remarkable
of all the Wormian bones is the one which sometimes supplies the place of the superior
angle of the occipital, and which Blasius has called the triangular bone ; it is the epactal
bone properly so called. It is not uncommon to find a Wormian bone in the sagittal su-
ture, and this may be compared to the inter-parietal bone of some animals. Bertin has
described a quadrangular bone occupying the situation of the anterior fontanelle, and
resembling it in figure : I have myself met with such a fonnation. The anterior inferior
angle of the parietal is sometimes formed by a Wormian bone ; I have seen one in the
squamous suture.
In some sculls the whole of the occipital bone above the occipital protuberance is
formed by these bones. Generally both tables of the bone enter into the formation of
the Wormian bones ; but there are instances in which they are confined to the external,
and others to the internal table.
The Wormian bones are not always visible in the interior of the cranium : in some
cases they are, as it were, incrusted in the substance of the bone, at the circumference
of which they are observed.
Their mode of development resembles that of the broad bones, i. c., it proceeds by ra-
diation from the centre to the circumference. According to Beclard, they are not devel-
oped until five or six months after birth : at their junction with the surrounding bones
they form sutures, which are the first to become effaced in after life.
From all that has been said regarding this class of bones (which are in a manner acci-
dental, for they are neither constant in number nor in their existence), it is evident that
they can be only considered as supplementary points of ossification, and not as performing
an important office in contributing to the solidity of the cranium, as the name cles de
voiUe, given to them by some anatomists, would seem to indicate.
Progress of Development in the Adult and the Aged.
The cartilaginous lamina which separates the bones at first, gradually becomes ossi-
fied. The sutures become so serrated that it is almost impossible to separate the bones
without breaking some of their teeth. At the same time that the bones increase in
breadth, they augment in thickness ; the diploe, which at first did not exist, is developed
between the two plates. In the adult, several bones already begin to join by osseous
union ; of this we have an example in the sphenoid and occipital, which at an early pe-
riod form one bone.
In the aged, the traces of the sutures are in a great measure effaced, so that in cer-
tain cases the whole scull would seem to be composed of one entire piece. The con-
tinuity of some bones is occasionally such, that the venous canals of the one communi-
cate and open directly into those of the other. It is not uncommon to find the bones of
an old subject thin and translucent like horn, in a greater or less extent. This diminu-
tion of thickness, added to the increasing fragility of the osseous tissue, affords an ex-
SUPERIOR MAXILLARY BONES. 51
planation of the ease with which the sculls of old people may be broken : and the con-
tinuity of the bones explains the possibility of the fracture being much extended.
The greatest variety exists as to the thickness and density of the bones of the scull in
old age, Generally they are as brittle as glass, but in some instances they are so soft
and spongy that, although easily depressed, they can scarcely be fractured by the blow
of a hammer. I have frequently, in old people, seen the teeth of the parietal and lamb-
doidal sutures soft, placed in juxtaposition, and merely joined by a soft fibrous sub-
stance, which admitted of their being separated without difficulty. The lambdoidal su-
ture is the one which the most frequently presents this disposition, and in all the in-
stances of this kind which I have met with, the superior borders of the occipital overlap
the corresponding borders of the parietal.
The F^ce.
The face is tnat very complicated osseous structure, which is situated at the anterior
and inferior part of the head, and is hollowed out into deep cavities for the reception of
the organs of sight, smell, and taste, and for the apparatus of mastication.
The face is divided into two portions, the upper and the lower jaw. The lower jaw is
formed by one bone only ; the upper jaw consists of thirteen bones. But, although this
circumstance tends to establish a great difference between the two, yet it must be re-
marked, that all the parts of the upper jaw are so immovably united, that in appearance
they form only one bone ; and, moreover, that it is essentially formed by one fundamental
piece, the superior maxillary bone, to which all the others are attached as accessory parts.
Of the fourteen bones which constitute the face, two only are median or single : viz.,
the vomer, and the inferior maxilla. All the others are double, and form six pairs, viz.,
the superior maxillary, the malar, palate, and proper nasal bones, the ossa unguis, and
the inferior turbinated bones.
The Superior Maxillary Bones {figs. 24 and 25, with the Palate Bones).
They are two in number, united, to a certain extent, in the median line, and form al-
most the whole of the upper jaw. Their figure is very irregular : they belong to the
class of short bones. They have three surfaces, an external, an internal, and a superi-
or ; and three borders, an anterior, a posterior, and an inferior.
External or Facial Surface {fig. 24). — Proceeding from before backward, we observe a
small fossa in which the myrtiform muscle {depressor labii supe-
rioris et alee nasi) is inserted, and which is bounded externally
by the ridge which forms the alveolus of the canine tooth ; a
deeper fossa, named fossa canina, or infra orhitalis, surmounted
by the orifice of the infra orbitary canal (o) ; and, more posteri-
orly, a vertical ridge, which separates the fossa canina from the
maxillary tuberosity (m). This protuberance, which is most
prominent before the appearance of the wisdom tooth, is trav-
ersed by small canals, the posterior and superior dental, which
transmit vessels and nerves of the same name. From the an-
terior part of this region, a long vertical process arises, the as-
cending or nasal process {a b) of the superior maxilla. It is of a pyramidal shape, and flat-
tened. Its external surface is smooth, and presents the openings of certain vascular ca-
nals which communicate with the interior of the nasal fossae, and some inequalities for
the insertion of the common elevator of the upper lip and ala of the nose. On the inter-
nal surface {fig. 25) we observe, in succession from above downward, a rough surface,
which assists in closing the anterior cells of the ethmoid ; a horizontal ridge, to which
the middle turbinated bone is attached ; a concave surface, which forms part of the mid-
dle meatus of the nose ; and another horizontal ridge for articulation with the inferior
turbinated bone : like the external, this surface also is perforated by foramina, and mark-
ed by arterial furrows. Its anteriw edge {a b,figs. 24, 25) thin, and bevelled internally, i&
applied to the nasal bone. The posterior edge is thick, and marked by the lachrymo-nasal
g'oove, which forms part of the lachrymal groove above, and of the nasal duct below. It
has two edges or lips : the internal, which is very thin, articulates with the os unguis
and the inferior turbinated bone ; the external, which is rounded, gives attachment to
the straight tendon and some fibres of the orbicularis palpebrarum muscle. The direc-
tion of the lachrymo-nasal groove is slightly curved ; the convexity being internal and
in front, the concavity external and behind. The summit of the nasal process is trun-
cated and serrated for articulation with the nasal notch of the frontal bone.
Superior or Orbital Surface {c,fig. 24). — This is the smallest of the three surfaces. It
forms almost the entire floor of the orbit : it is triangular, and slightly oblique from within
outward, and from above downward, and presents a groove behind, which is continuous
with the infra-orbitary canal. This last-named passage, at first a mere channel, after-
ward a complete canal, passes from behind forward and inward, bends down and opens
at the upper part of the canine fossa. Before its termination, it gives off a small canal,
the anterior and superior dental, which runs in the anterior wall of the maxiUary sinus,
53 OSTEOLOGY.
and transmits the vessels and nerves which are distributed to the incisor and canine
teeth. Sometimes this branch of the canal opens into the maxillary sinus. In many
subjects I have seen it curve backward, and conduct a communicating branch between
the infra-orbitary and palatine nerves as far as the maxillary tuberosity. The orbiial
surface is bounded by an external edge, which forms part of the spheno-maxillary fissure ;
by an internal edge, which articulates with the os unguis, the os planum of the ethmoid, and
the palate bone ; and by an anterior edge, which forms part of the rim of the orbit. At
the external termination of this edge is a very irregular eminence, appearing as if part of
the bone had been broken off: this is the malar process, which corresponds with the sum-
mit of the maxillary sinus, and is articulated with the malar bone. At the internal ex-
tremity of the orbital edge, we find the ascending process already described.
Internal or Naso-palatine Surface {Jig. 25). — This surface is divided into two unequal
parts by a horizontal square plate, which intersects it at right
angles. This plate is the palatine process {t), the superior surface
of which, smooth and hollow, is broader posteriorly than anteri-
orly, and forms part of the floor of the nasal fossae : its inferior
surface is rough, and forms part of the roof of the palate : its
internal border (t) is very thick in front, and articulates with
the corresponding edge of the opposite bone. This border is
surmounted by a crest, which contributes to form the furrow
into which the vomer is received, and which presents, at the
junction of its anterior with the two posterior thirds, a groove
(r) running obliquely upward and backward. This groove, when
united with a similar one on the opposite bone, forms the anterior palatine or incisive ca-
nal, which is single below and double above. The anterior edge of the palatine process
is very narrow, and forms part of the anterior opening of the nasal fossae : the posterior
edge, bevelled at the expense of the superior table, supports the horizontal portion of the
palate bone.
That part (to) of the internal surface of the maxillary bone which is situated below
the palatine process, is of no great extent : it forms part of the arch of the palate. A
furrow more or less deep, and bounded by projecting edges, runs along the external bor-
der of the palatine process, and protects the posterior palatine vessels and nerves. The
raucous membrane of the palate covers this region of the bone. The part of the inter-
nal surface (n) of the superior maxillary bone which is above the palatine process, be-
longs to the nasal fossa : it is covered by the pituitary membrane. We observe here
from before backward, 1, the internal surface (c) of the ascending process (a) ; 2, below
the inferior ridge, a smooth surface which forms part of the inferior meatus of the nose ;
3, the inferior orifice (behind c) of the lachrymo-nasal groove, sometimes converted into
a complete canal by a bridge of bone ; 4, the opening of the maxillary sinus (s), which
appears wide in a detached bone, but in its natural connexion is contracted by prolonga-
tions of the palate bone, the ethmoid, the inferior turbinated bone, and the os unguis, all
of which are articulated with the circumference of this opening ; it is still farther dimin-
ished when the bones are covered by their pituitary membrane. At its lower part, this
orifice presents a fissure in which a lamina belonging to the palate bone is received : this
method of articulation has received the name of Schindylesis. At the upper part are
small cells, which unite with the ethmoid ; behind the orifice is a rough surface, which
articulates with the palate bone ; and, lastly, a groove, which forms part of the posterior
palatine canal.
The orifice which we have just described leads into the interior of a cavity denom-
inated maxillary sinus, or antrum of Highmore, although it had been before very accurate-
ly described by Vesalius. It is hollowed out from the substance of the maxillary bone,
and has the form of a pyramid, the base of which corresponds with the internal surface
of the bone ; the summit with the malar process ; the superior wall with the floor of the
ojbit ; the anterior wall with the fossa carina, and the posterior with the maxillary tuber-
osity. These two last-mentioned walls are traversed by linear projections or ridges,
which correspond with the anterior and posterior dental canals. There is also one ridge
upon the superior wall : it indicates the passage of the infra-orbitary canal. The ex-
treme tenuity of this superior or orbitary wall is an anatomical fact of great importance,
because it explains the influence which tumours developed in the sinus exert upon the
organs contained in the cavity of the orbit. The septum between the sinus and the bot-
tom of the alveoli is also so thin, that an instrument can easily penetrate into the sinus
in this situation. This remark applies particularly to the alveolus of the canine tooth.
The anterior harder {g a, figs. 24 and 25) of the superior maxilla presents, below, a ver-
tical portion (g- d), surmounted by a small eminence called the nasal spine (a) : it is then
hollowed out into a deep notch (a h), to form half the anterior orifice of the nasal fossae ;
and, lastly, becomes continuous with the anterior edge (h a) of the ascending process.
The posterior harder is vertical and very thick : it articulates below with the pterygoid
process, through the medium of the palate-bone : above, it forms part of the pteiygo-
maxillary fissure. •
PALATE BONES. 53
The inferior or alveolar border {g k) is the thickest and strongest part, being, in some
respects, the base of the bone. It is hollowed into conical cavities separated by thin
septa. These cavities are the alveoli or sockets of the teeth : they are proportioned in
dimensions to the size of the fangs vi^hich they are intended to lodge, and in like man-
ner are subdivided into two, three, or four secondary cavities. The bottom of these al-
veoU is in apposition with the maxillary sinus, into which they occasionally open. This
border presents, especiaUy in front, flutings or projections which correspond with the
alveoli, and depressions which mark the inter-alveolar septa.
In young subjects we may observe, chiefly behind the incisor teeth, some very remark-
able foramina, to which much importance has been attached as connected with the phe-
nomena of dentition.
Internal Structure. — This bone is remarkably light for its size, on account of the larg«
cavity which it encloses. It is more compact than most of the short bones, and has spongy
tissue only in the alveolar border, the maxillary tuberosity, and the malar eminence.
Connexions. — The superior maxilla is articulated with two bones of the cranium, the
frontal and the ethmoid, and with all the bones of the face. It lodges eight of the teeth
of the upper jaw.
Development. — Anatomists are not at all agreed respecting the number and arrange-
ment of the osseous points which concur in forming the superior maxilla.
In the maxillary bone of the fcetus, and sometimes even in that of the adult, there are,
as I can attest from observation, two very remarkable fissures, which would seem to in-
dicate the primitive separation of the bone into three pieces.
1. The first fissure, which may be called the incisive fissure, is visible on each side of
the arch of the palate. It commences at the septum, which divides the alveoli of the
canine tooth and lateral incisor, is continued backward to the anterior palatine canal,
and is prolonged above on the internal surface of the ascending process. This fissure
is apparent only on the internal surface of the superior maxilla : it either does not exist
at all upon the external surface, or is so early obliterated that it can scarcely ever be
met with. The portion of the maxilla circumscribed by this fissure sustains the incisor
teeth, and represents the incisor or inter-maxillary bone of the lower animals. In hare-
lip, the solution of continuity is in the situation of this fissure. It is therefore probable
that this anterior portion of the maxillary bone is developed from a special point. Bertin
asserts this, and Meckel and Beclard admit it. I have not been able to observe such
independent development at any period of foetal life at which I have examined the max-
illary bone.
2. A second and equally constant fissure is visible in the situation of the infra-orbital
canal, and is prolonged from the edge of the orbit in the form of a small suture to the
anterior orifice of this canal : it may be called the orbital fissure. This fissure, like the
preceding, has always seemed to me incomplete, and not occasioned by the separation
of a distinct piece.
The superior maxillary bone is one of the earliest in making its appearance. Ossifi-
cation commences in it from the thirtieth to the thirty-fifth day, in the situation of the
alveolar arch.
At birth the superior maxilla has little height, but a considerable extent from before
backward. At this period it is chiefly formed by the alveolar border, which is almost con-
tiguous to the floor of the orbit. The maxillary sinus is already very apparent. In the
adult, the vertical dimensions increase by enlargement of the sinus. In the aged, the al-
veolar process becomes flattened, and diminished in height.
The Palate Bones (Jigs. 24, 25, 26, and 27).
The palate bones are situated at the posterior part of the nasal fossae and the palatine
arch ; they are two in number, sjrmmetrical, and each pig. 26. Fig. ar.
composed of two thin quadrilateral laminae, one of which
is horizontal, the other vertical, and which are joined to-
gether at right angles.
The horizcmtal plate {b c, figs. 26 and 27), the only one
known to the ancients, and named by them the as quad-
ratum, presents a superior surface (jif), smooth and con-
tinuous with the floor of the nasal fossae, of which it forms
the broadest part : an inferior surface {b c), which com-
pletes the arch of the palate : it is rough, slightly concave
in front, and presents behind and to the outside a trans-
verse ridge for the insertion of the tensor palati muscle ;
and in front of this ridge is the inferior orifice of the pos-
terior palatine canal. The anterior edge of this plate is cut obliquely, so as to rest upon
the posterior edge of the palatine process of the superior maxillary. The posterior edge
is concave, and very thin ; it gives attachment to the velum palati. The internal edge
is sunnounted by a crest, which forms one of the sides of the vomer, and terminates be
aind by a sharp process (d), which, when united to the corresponding part of the opposite
M OSTEOLOGY.
bone, constitutes the posterior nasal spine, which gives attachment to the levator muscle
of the uvula (azygos uvulae). The external edge is united to the vertical portion of the bone.
The vertical portion, or lamina (a b), is slightly inclined inward, quadrilateral, longer,
broader, and thinner than the preceding. On it we observe, 1. An internal surface (mf
and 2, fig. 25), which contributes to form the external wall of the nasal fossae, and which
presents from above downward a horizontal ridge for articulation with the middle tur-
binated bone ; a groove belonging to the middle meatus ; another ridge for articulation
with the inferior turbinated bone (e and 2, fig. 25) ; and another groove which makes
part of the inferior meatus (e/and l,fig. 25). 2. An external surface (s b,fig. 26, and p
b, fig. 27), very irregular, which contributes to form the bottom of the zygomatic fossa
above, and which is rough in front for union with the superior maxillary. This surface
is traversed by a vertical groove, which, by itself, forms £dmost the entire extent of the
posterior palatine canal {g g, fig. 26). 3. An anterior or maxillary border {i, fig. 27), very
thin and irregular, which advances so far forward as to contract the entrance into the
maxillary sinus, and presents a tongue of bone, which is received into the fissure already
described as existing at this orifice. 4. A posterior or pterygoid border {I, fig. 26), which
is applied to the inner plate of the pterygoid process. There is below, at the angle form-
ed by its union with the posterior edge of the horizontal portion, a very considerable pro-
cess for the size of the bone : this has been called palatine process, or tuberosity of the os
palati (3, fig. 25 ; lb, fig. 26), but is better named pterygoid or pyramidal process : its base
is continuous with the test of the bone, and from this point passes downward, and is, as
it were, enclosed in the bifurcation of the pterygoid process of the sphenoid. Its upper
surface is traversed by three grooves, the middle of which forms part of the pterygoid
fossa, and the lateral ones are rough, and receive the simimits of the two pterygoid plates.
Below, the pyreunidal process exhibits the orifices of the accessory ducts of the posterior
palatine canal. Externally it presents a rough surface, which articulates above with the
tuberosity of the superior maxilla, and which is free in the rest of its extent, and forms
part of the zygomatic fossa. The middle of this process is grooved in a vertical direc-
tion, for the posterior palatine canal. 5. The inferior border of the vertical portion is
continuous with the external edge of the horizontal plate. 6. The superior or sphenmdal
border is connected with the sphenoid in almost the whole of its extent. It presents a
deep notch, forming three fourths or sometimes the entire spheno-palatine foramen {G,fig.
25 ; 0, figs. 26, 27 ; n, fig. 37), which corresponds with the spheno-palatine ganglion, and
gives passage to the vessels and nerves of the same name. This border is surmounted
by two processes, an anterior or orbital (4, fig. 25 ; a, figs. 26, 27), and a posterior or sphe-
noidal {5, fig. 25 ; m,figs. 26, 27). The sphenoidal process is the broader, particularly at
its base, but is not so elevated as the anterior : it presents three facettes — an internal,
which forms part of the nasal fossa ; an external, which is visible in the zygomatic fossa ;
and a superior, which articulates with the sphenoid, and presents a groove, which con-
tributes to form the ptcrygo-palatine canal.
The orbital process, inclined outward, and supported by a constricted portion or neck, has
five facettes. Three of these are articular, viz., the internal {n,fig. 27), which is concave, and
unites with the ethmoid, covering and completing its cells ; the anterior {p, fig. 27), which
joins the maxillary bone ; and the posterior (q, fig. 26), which is united to the sphenoid by
certain asperities surrounding a cell, which exists in the substance of the process, and com-
municates with the sphenoidal sinus. The other tico are non-articular, viz., the superior (r,
fig. 26), which forms the deepest part of the floor of the orbit, and the external (s, fig. 26),
which forms part of the zygomatic fossa, and is separated from the preceding by ,a small
edge, which constitutes a portion of the spheno-maxillary fissure.
Internal Structure. — The palate bone is compact throughout, excepting in the palatine
process, where it is thick and cellular.
Connexions. — The palate bone articulates with its fellow on the opposite side, with the
maxillary, the sphenoid, the ethmoid, the inferior turbinated bone, and the vomer.
Development. — This bone is developed from a single point of ossification, which ap-
pears from the fortieth to the fiftieth day, at the point of union of the vertical and hori-
zontal portions, and the pyramidal process. During its development, the bone appears
as it were crushed down, so that the vertical portion is shorter than the horizontal, and
there is a marked predominance in the antero-posterior diameter. This disposition is
in accordance with the shortness of the vertical diameter of the superior maxilla.
^s-^- The Malar Bones {fig. 28).
The malar hones, called also cheek, jugal, or zygomatic bones, are
situated in the superior and lateral part of the face : their form is
that of a very irregular four-sided figure. They have thn e sur-
faces, an anterior, a posterior, and a superior ; four borders, and
four angles.
The anterior or cutaneous surface (a) looks outward, is convex
and smooth, and presents the openings of several foramina {h).
NASAL BONES. 55
named malar, which are intended for nerves and vessels. This surface gives attach-
ment below to the zygomaticus major muscle. It forms the most prominent part of the
cheek, and is covered only by the skin and orbicularis palpebrarum muscle : it is, conse-
quently, much exposed to injury.
The superior or orbital surface (jb) is supported by a thick curved process, the orbital pro-
cess, which arises from the bone almost at a right angle. This surface is concave, and
of small extent : it forms part of the orbit, exhibits the internal openings of one or more
malar foramina, and terminates behind by a rough, serrated edge, which articulates
above with the frontal and sphenoid bone, and below with the superior maxillary. The
same maxiUary edge presents in the middle a retiring, smooth angle, which constitutes
the anterior extremity of the spheno maxillary fissure.
The posterior or temporal surface is concave, and presents a smooth surface Ijehind, which
contributes to form the temporal fossa, and on which one or more malar foramina open ;
and a rough surface in front, which unites with the malar process of the superior maxilla.
Of the /our borders, two are superior ; of these, the anterior or orbital {d e) is semi-lunar,
rounded and blunt, and forms the external third of the base of the orbit ; the posterior
or temporal {e f) is thin, and curved like the letter S, and bounds the temporal fossa in
front. Of the two inferior borders, the anterior or maxillary (d g) is very rough and
articulates with the maxillary bone ; the posterior or masseteric (gf) is horizontal, thick,
and tubercular, and gives attachment to the masseter muscle.
Of the/oMr angles, the superior ox frontal (e), which is much elongated, and vertical, is
the tliickest part of the bone, and articulates with the external angular process of the
frontal bone : the posterior or zygomatic (/), broader and thinner than the preceding, is
serrated, and slants downward and backward, for articulation with the zygomatic process
of the temporal bone, which rests upon it. The internal or orbital angle {d) looks in-
ward and forward, is very acute, and articulates with the superior maxillary near the
infra-orbitary canal. The inferior or malar angle {g) looks downward, is obtuse, and
unites with the outer part of the malar or jugal process of the superior maxillary.
Internal Structure. — Tlie malar bone is almost entirely compact, possessing spongy
tissue only in the anterior and inferior edge, and in the part where the orbital portion is
given off. It is constantly traversed by a canal called zygomatic. This passeige is gen-
erally simple, but sometimes double or even multiple, and opens by at least three orifices.
The superior or orbital orifice is visible on the surface of the same name ; the next or
external zygomatic foramen is on the cutaneous surface of the bone ; and the third or
internal zygomatic on the inner surface of the vertical portion.
Connexions. — The malar bone is articulated with the superior maxillary, the frontal,
the sphenoid, and the temporal.
Development. — It is developed from one point of ossification, which appears about the
fiftieth day of fcetal life. The ulterior changes which it undergoes do not require par-
ticular notice.
The Masai Bones {fgs. 29, 30).
The nasal bones are two in number, asymmetrical, and very small in the human sub-
Fig. 29. Fig. 30. ject ; they are closely contiguous to each other, sometimes united into
one piece superiorly. They are situated at the upper and middle part
of the face, and form, as their name indicates, the osseous part of the
nose, of which they constitute the root. They are directed obliquely
downward and forward, but with various degrees of inclination in dif-
ferent subjects ; and hence the varieties in the shape and prominence
of the middle or bridge of the nose. Their figure is rectangular and
oblong ; they are thick and narrow above, broad and thin below ; and
have two surfaces, an anterior and a posterior, and four edges.
The anterior or cutaneous surface {fig. 29) is covered only by the skin and pyramidalis
nasi muscle, and hence the ease with which these bones are fractured : it is concave
above, flat or even convex below : the orifice of a vascular canal is always very distinctly
seen, which is variable in its situation, sometimes single, but often accompanied by
others of smaller size.
The posterior or pituitary surface (fig. 30) is concave, and forms the anterior part of the
roof of the nostrils : it is marked by vascular and nervous furrows, and in the fresh state
is covered by the pituitary membrane.
Of the four edges, the superior (a, figs. 29, 30), short, thick, and serrated, articulates
with the nasal notch of the frontal bone. The inferior (d), very thin, and more elonga-
ted, has a slight notch in the centre for the passage of a nervous filament, and forms
part of the anterior orifice of the nasal fossae : it unites with the lateral cartilage of the
nose. The internal (b) edge is thick above, and bevelled, so that, when approximated to
the other bone, the two constitute a fiirrow, in which the nasal spine of the frontal and
the perpendicular lamella of the ethmoid bone are received. The external (c) edge is some-
what longer than the internal, is slightly bevelled on the outer table, and indented for
articulation with the ascending process of the superior maxilla, which rests upon it.
66 . OSTEOLOGY.
Connexions. — The two bones are articulated together : they unite also with the frontal,
the ethmoid, and the superior maxiUa, and likewise with the lateral cartilages cf the
nose : they afford passage to the vessels which establish a communication between the
skin of the nose, and the mucous membrane of the nasal fossae.
Internal Structure. — The nasal bones are thick and cellular in their upper parts, thin
dnd entirely compact in their lower, and are traversed by nervous and vascular grooves.
Development. — The nasal bone is developed from one single osseous point, which ap-
pears before the end of the second month.
Ossa Unguis^ or Lachrymal Bones {figs. 31, 32).
These are the smallest bones of the face : they are thin, like paper, and have the trans
Fig. 31. Fig 32. parence, tenuity, and even the shape of a nail, from which circum-
stance one of their names has been derived. They are situated at
the internal and anterior part of the orbit : their figure is irregularly
. quadrilateral : they are two in number, and, therefore, asymmetri-
If '7r cal. They have two surfaces and four edges.
' j,i#^ The external or orbital surface {fig. 32) is divided into two unequal
parts by a vertical ridge (a b), which terminates below in a sort of
'^ hook. The portion anterior to the ridge is narrow, and marked by
a porous groove (c), which, when joined to the channel on the ascending process of the
superior maxilla, forms the lachrymal groove (hence the name of lachrymal bone).* The
portion {d) of the os unguis, which is posterior to the ridge, completes the inner wall of
the orbit.
The internal or ethmoidal surface {fig. 31) presents a furrow (a' b), which corresponds
to the external ridge ; the portion {c') in front of the furrow forms part of the middle
meatus ; behind is a rough surface {d'), which covers the anterior cells of the ethmoid.
Of the four borders, the supcrior{a a) is rough, and articulates with the internal angu-
lar process of the frontal bone ; the inferior {b h') articulates with the inferior turbinated
bone by a small tongue which passes backward, and which contributes to form the nasal
canal, and with the internal edge of the orbital surface of the superior maxillary. The
anterior edge {e e') unites with the ascending process of the maxillary bone ; and the
■posterior edge {f f), slightly denticulated, joins the orbital portion or lamina papyracea
,^mhe ethmoid.
^^ Connexions. — The os unguis articulates with the frontal, the ethmoid, the superior
maxillary, and the inferior turbinated bone : they assist in the formation of the lachrymal
sac, the nasal canal, and the internal wall of the orbit.
Structure. — The os unguis consists of a very thin layer of compact tissue, and is the
inost brittle of all the bones. It is of importance to note its tenuity and fragility, be-
, Hji^aase it is concerned in the operation for fistula lachrymalis.
Development. — The os unguis is ossified at the commencement of the third month, from
one single point.
The Inferior Turbinated or Inferior Spongy Bones (figs. 33, 34, and d,
fig- 37).
The inferior turbinated bones, so called on account of their curved figure, are situated
Figs 33 34. ^^ *^^ lower part of the external wall of the nasal fossae {d,
' ' fig. 35), below the ethmoid, whence the name sub-ethmoidal
turbinated bones. They are two in number, asymmetrical, and
their greatest diameter is directed from before backward.
They have two surfaces, two edges, and two extremities.
The internal surface {fig. 34, and d,fig. 37) is convex, and
looks towards the nose, which it sometimes touches when
that part deviates from the straight direction ; the external sur-
face {fig. 33) is concave, and forms part of the middle meatus.
Both are rough, and, as it were, spongy, which has given rise
to the assertion that these bones form an exception to the general rule of the spongy
tissue being in the interior of bones : this appearance, however, is owing to the multi-
plicity of canals intended for nerves, and more particularly for the veins which expand
over the bone. The superior or articular edge {abed, figs. 33, 34) is very irregular, and
presents from before backward, 1. A thin edge {a b), which articulates with the ascend-
ing process df the superior maxilla. 2. A small eminence bearing the name of nasal or
lachrymal process (5), which articulates by its apex with the os unguis, and by its two
edges with the two lips of the ascending process of the superior maxillary, to complete the
nasal canal. 3. A curved pkte, called auricular process (e, fig. 33) by Bertin, who com-
pared it to the ear of a dog : this plate is directed downward, and applied partially upon
the orifice of the maxillary sinus, which it assists in closing. 4. Behind this process
* The existence of lachryma) bones is subordinate to that of the lachrymal secretion. The;r are not met
with in those animals -which bve in the water, and which have neither lachrymal glands nor ptjssages.
VOMER. INFERIOR MAXILLA. 57
we find a thin edge (c d, figs. 33, 34), which articulates with a small ridge on the palate
bone. 5. Between the auricular and the lachrymal processes are small prominences
which unite with tlie ethmoid.
The inferior or free border (a d) is convex, and thicker in the middle than at its ex
tremities : it is separated from the floor of the nostrils by an interval (m o, fig. 37) of un-
certain extent, a circumstance to be remembered during the introduction of instruments
into the nasal fossae.
The anterior extremity (a) is a little less pointed than the posterior {d), which distin-
guishes the bone of the right from that of the left side.
Connexions. — The inferior turbinated bones articulate with the superior maxillary, the
palate bones, the ethmoid, and the ossa unguis : they have important relations with the
inferior orifice of the nasal canal, which they defend from the contact of foreign bodies.
Structure. — ^Their external spongy appearance depends upon the multitude of canals
with which their surface is furrowed, but they are almost exclusively formed of compact
tissue.
Development. — Their ossification commences about the fifth mftith of foetal life, by a
point situated in the centre.
The Vomer {jig. 35, and 10, fig. 22).
The vomer is so called from its supposed resemblance to a ploughshare. It is situated
in the median plane, and forms the posterior part of the sep- jVe'. 35.
tmn of the nostrils. It is thin, flat, and quadrilateral, and
has two surfaces and four edges. The surfaces are placed
laterally (as at a, fig. 35), and are generally plane, but they
are often bent to one side or the other, and are then convex
and concave in opposite directions : they are always smooth,
and covered by the pituitary membrane, and present small
vascular and nervous furrows. The superior or sphenoidal border {Jb, fig. 35, and 3, fig.
22) is the shortest and thickest : it is marked by a deep groove, which receives the in-
ferior crest of the sphenoid ; the two lips of the groove are bent outward, and received
into furrows on the inferior surface of the same bone, and thus complete a small chan-
nel for the passage of vessels and nervous filaments. The inferior or maxillary (c) bor-
der is the longest, and is received into the furrow which is formed by the union of the
two palate bones behind and of the two superior maxiUary in front : it sometimes termi-
nates by a more or less prominent process behind the anterior nasal spine. The anterior
or ethmoidal border {d, fig. 35, and 3 4, fig. 22) presents the continuation of the groove on
the superior edge, and receives the inferior bcujder of the perpendicular plate of the eth-
moid. There is no groove where it is attach" to the cartilaginous septum. The pos-
terior or guttural edge {e,fig. 35, and t, 10, fig. 22) is free : it is thin and sharp, and in-
clines downward and forward : it separates the posterior openings of the nasal fossae.
Connexions. — The vomer is articulated with the sphenoid, the ethmoid, the superior
maxillary, the palate bones, and the cartilage of the septum.
Internal Structure. — ^The vomer is composed of two very thin compact laminae, which
are distinct above, but united below. Some anatomists have called these plates alee of
the vomer.
Development. — It is developed from one point of ossification, which is situated at the
lower part of the bone, and appears before the end of the second month. It then pre-
sents the form of a deep groove, embracing the cartilage just as, at a future period, it
embraces the sphenoidal crest. At birth the vomer is still only a groove ; afterward
this condition is confined to the sphenoidal and ethmoidal edges of the bone. It is not
uninteresting to note the peculiar and uncommon manner in which the ossification pro-
ceeds from the surface to the interior of the cartilage.
Inferior Maxilla {fig. 36).
While, as w^ have before observed, a considerable nimiber of bones to enter into the
formation of the upper jaw, the lower jaw consists of one pig. 36,
bone only. The inferior maxilla occupies the lower part of
the face. From the number and importance of the practi-
cal points connected with this bone, too much attention
cannot be bestowed on the study of its form and connex-
ions. It has the shape of a parabolic curve, the two ex-
tremities of which, called rami, form a right angle with the
middle portion or body.
Of the body or middle portion (a). — The body represents a
curved plate, convex in front and concave behind. It of-
fers to our notice an anterior and a posterior surface, and a
superior and inferior border. The anterior surface has in
the middle a vertical line, called symphysis menti (c d) ; it
H
9i OSTEOLOGY.
marks the place of union of the two pieces of \jfhich this bone is composed in young
subjects, and which, in a great number of animals, remain distinct through life.*
The mode in which the two halves of the body of the inferior maxilla are united,
forming an arch instead of an angle, as in other animals, constitutes one of the distinc
live characters of the human species ; and the vertical direction of the symphysis, com-
pared Avith its very oblique inclination downward and backward, or almost horizontal
position in the lower animals, is a no less characteristic mark of man, who alone can be
said to possess a chin.\
In front the symphysis terminates by a triangular eminence called mental 'process (d).
Behind, it presents below four small tubercles, two superior and two inferior, known by
the collective appellation of genial processes {yivcLov, the chin), and give attachment to
the genio-hyoid and genio-glossal muscles.
On each side of the symphysis, we observe on the anterior or cutaneous surface of the
body of the inferior maxilla, 1. A small depression for the attachment of muscles, named
mental fossa (e c). 2. A line, which commences at the mental process, passes obliquely
upward, and becomes' continuous with the anterior edge of the ramus of the jaw : it is
named the external oblique, or external maxillary line (c/), and is also intended for muscu-
lar insertions. 3. Above this line, the mental foramen (_g), the orifice of the inferior dental
canal, which transmits the mental vessels and nerves. 4. The anterior surface of the
alveolar arch (c h), marked by a series of projections corresponding to the alveoli, and
separated by vertical depressions, which point out the situation of the inter-alveolar sep-
ta. 5. Below the external oblique line, a smooth surface (a), separated from the skin by
the platysma myoides muscle.
The posterior or lingual surface is in some measure moulded upon the tongue : it pre-
sents, 1. The mylo-hjoidcan line (k) (jivXog, dens molaris), called also internal oblique or in-
ternal tnaxillary, which commences at the genial processes, and passes upward and back-
ward, becoming more prominent opposite the last molar tooth. 2. Below this line, a
broad but superficial depression, which lodges the sub-maxillary gland. 3. Above the
oblique line, and near the symphysis, a fossa, which lodges the sub-lingual gland, and a
sracfoth surface covered by the mucous membrane of the mouth and gums.
These two lines, the external and internal oblique, divide the body of the inferior max-
illa into two parts, a superior or alveolar, and an inferior or basilar. The first named
constitutes almost the entire body of the bone in the foetus and the infant ; in the adult it
forms only two thirds of the depth of the bone, the other third being the basilar portion : last-
ly, in the aged, the alveolar portion almost entirely disappears, and the basilar only is left.
The superior or alveolar border describes a smaller curve than the corresponding alveo-
lar edge of the superior maxilla ; so that, in a regular conformation of the parts, the in-
ferior incisor teeth are overlapped by thgl, superior. This border is less tliick in front
than behind, where it projects inward : it is pierced by a series of sockets or alveoli, re-
sembling those of the superior maxilla, and, like them, variable according to the kind of
teeth which they are intended to receive.
The inferior border or base of the jaw {d m) is the thickest part of the bone ; it forms
part of a larger curve than the superior border, so that the jaw projects forward in some
measure at the lower part : this projection varies much in different subjects.
Rami of the iyiferior maxilla {b b). — These are quadrilateral, and present, 1. An external
surface (A) covered by the masseter muscle, which is inserted into it, especially below,
where we may observe depressions and ridges, and where the bone itself is more or
less bent outward ; in front of these ridges is a slight mark, which corresponds with the
situation of the facial artery. 2. An internal or pterygoid surface, also rough, for the at-
tachment of the internal pterygoid muscle, and on which is observed the superior orifice
(I) of the inferior dental canal, which is wide, and has a sort of spine, to which the in-
ternal lateral ligament of the temporo-maxillary articulation is attached : a small groove
passes from this orifice in the same direction as the canal, and bears the name of mylo-
hyoidean furrow, because it lodges the nerve of that name. 3. A posterior or parotid edge,
which is round, and gives attachment below to the stylo-maxillary ligament : it is era-
braced by the parotid gland. 4. An anterior edge (r), marked by a groovi^ which is the
continuation of the alveolar border ; the anterior and posterior lips of this groove being
formed by the external and internal oblique lines. 5. A superior edge, very thin, and hol-
lowed out into gi deep notch, called sigmoid notch (n o), on account of its shape, giving
peissage to nerves and vessels. 6. An inferior edge, which is nothing more than a con-
tinuation of the inferior border of the body of the bone.
The angle which the rami form with the body of the bone is named the angle of the
jaw (m). It is a right angle in the adult, but very obtuse in the infant, as also in the
* In serpents these pieces form a movable joint ; and as a similar arrangement obtains between the two
halves of the upper jaw, these reptiles are enabled to swallow an object much larger than their head, or even
than their body.
t It is interesting to remark the difference in the dissection of the symphysis in the Caucasian and Ethi-
opian varieties of the human family. In the former it is placed nearly vertically, slightly oblique from above
to below, and from behind to before. In the latter it is oblique from before to behind, and in this respect re-
sembles the conformation in the inferior animals, more especially in the Simiie.
INFEBIOE MAXILLA. ^
«iaruivora and some of the rodentia^ this disposition enabling its muscles to act with
' greater power.
The rami of the inferior maxilla are terminated above by two processes : the anterior;
called the coronoid process (n) ; the posterior, named the condyle (p).
The coronoid process is triangular, and inclined forward ; broad at its base, and pointed
at its summit ; it gives attachment to the temporal muscle. The size of this process in
the different species of animals bears an exact and constant proportion, both to the depth
and extent of the temporal fossa, and to the strength and curvature of the zygomatic arch.
The condyle articulates with the glenoid cavity of the temporal bone ; it is an oblong
eminence, the greatest dizuneter of which is directed sUghtly inward and backward. It
is supported by a contracted portion, called the neck of the condyle {^cervix) (o). This neck
is turned inward in such a manner that the condyle, which it supports, does not project
beyond the external plane of the ramus of the jaw ; it is also pr§tty deeply excavated
internally, to afford attachment to the external pterygoid muscle. The neck of the con-
dyle is the weakest part of the inferior maxilla.
Connexions. — The inferior maxilla articidates with the temporal bone, and lodges the
lower range of teeth.
Structure. — The external surface of the inferior maxUla is composed of compact tis-
sue ; the interior of the bone assumes the form of diploe, and is traversed for a great
part of its extent by the dental or inferior maxillary canal, which transmits the vessels
and nerves that are distributed upon the teeth of this jaw. This canal commences at
the middle of the ramus, by a groove covered with a fibrous lamina, the only use of
which, as it appears to me, is to protect the vessels and nerves, and to separate them
from the internal pterygoid muscle. From this point it proceeds forward and inward be-
low the mylo-hyoidean line, the curvature of which it follows ; it gradually becomes con-
tracted in diameter ; and in the situation of the second smaU molar or bicuspid tooth, it
divides into two canals, the larger of which is very short, and opens upon the external
surface of the body of the bone at the mental foramen already described ; the other, very
minute, pursues the original track, and is lost near the middle incisor tooth. In its pas-
sage the inferior dental canal communicates with the alveoli, by one, and sometimes two
foramina, through which the vessels and nerves of the teeth are transmitted. The sit-
uation of the dental canal varies much in different periods of life. In the new-bom in-
fant, before the appearance of the teeth, it occupies the lowest portion of the jaw ; after
the second dentition, it corresponds pretty nearly with the mylo-hyoidean line ; and after
loss of the teeth, it runs along the alveolar border. In the inferior maxilla of the old
subject, the anterior orifice of the dental canal, or the mental foramen, is close to the su-
perior border of the bone. The dimensions of the dental canal are no less remarkable
for their variations ; it is very large in the foetus, and in the child before the appearance
of the second set of teeth ; it diminishes during adult age, and is much contracted in the
old subject.
Development. — The inferior maxilla is developed by two points of ossification, one for
each lateral half Antenrieth admits, in addition, three complementary points ; one for
the condyle, one for the coronoid process, and one for the angle ; but I have never ob-
served them. The case is different, however, with a point of ossification described and
figured by Spix, which forms the inner side of the alveolar border, or, rather, of the den-
tal canal. In a foetus of about fifty or sixty days, I have seen a kind of bony spiculum,
which passed along the internal surface of the body and ramus of the bone ; on the one
half of the maxillary bone this spiculum was entirely free ; but that of the other side ad-
hered by the internal third of its length. The spine which surmounts the dental canal
is nothing more than the extremity of this bony spiculum. It follows, therefore, that the
inferior maxilla is developed from four points of ossification.
The inferior maxilla takes precedence of all the bones of the head in its development,
and, indeed, of all the bones of the skeleton, excepting the clavicle. The inferior edge
of the body of the bone appears as early as the thirtieth or thirty-fifth day ; this extends
backward to form the ramus, and in front to form the portion which supports the incisor
teeth ; it is probable that the osseous point of the dental caned, mentioned above, appears
at the same time. From the fiftieth to the sixtieth day, each half of the bone appears
already marked by a groove common to the dental canal and the alveoli. At a later
period, the groove becomes very considerable, and is divided into alveoli by septa, which
at first are incomplete, but afterward become perfect ; the alveoli and their septa occupy
at this time the entire depth of the bone.
The point of ossification described by Spix is united to the rest of the bone from the
fiftieth to the sixtieth day. (Spix aflirms that it remains separate until the fourth
month.) The two halves of the maxilla are joined together during the first year after
birth. The traces of this union exist for some time, but are afterward effaced ; in the
lower animals the suture remains throughout life.
The changes which the inferior maxilla undergoes after birth, relate, 1- To the angle
which the ramus forms with the body of the bone, which is very obtuse at birth, and be-
oomes a right angle after devetopment is completed. 2. To the alterations effected in
60 OSTEOLOGY.
the booy of the bone, by the first and second dentitions, the loss of teeth in liie aged,
and the subsequent absorption and disappearance of the alveoli.
The Face in general.
The fourteen bones which we have described, united to each other, and joined to the
bones of the cranium, form a piece of bony sculpture, symmetrical, extremely complica-
ted, destined to lodge the organs of smell, sight, and taste, and to be the instrument of
mastication. This bony sculpture forms the face, which is situated below the cranium,
above the neck, and in front of the vertebral column, from which it is separated by the
pharynx, and is bounded on each side by the zygomatic arches.
Dimensions of the Face.
In order to form a just idea of the dimensions of the face, it is necessary to examine
a scull cut vertically from before backward (as in fig. 22). We then perceive that the
face is comprised within a triangular space, which is bounded above by an irregular line
that separates it from the cranium ; in front by the face, properly so called ; and below,
by a line passing below the symphysis menti. If a line be drawn above the inferior
maxilla, and under the arch of the palate, when prolonged backward, it will be in the
plane of the foramen magnum ; for the cranium having much less depth in front than
behind, a horizontal line, which touches the cranium behind, is separated from it in front
by the entire height of the upper jaw.
The vertical diameter, which extends from the frontal protuberance to the chin, is the
longest of all the diameters of the face. It gradually diminishes from before backward.
The transverse diameter is of considerable extent in the situation of the cheeks, but di-
minishes above and below this point. The antero-posterior diameter stretches above from
the nasal spine to the basilar process ; below it is greatly contracted ; and at the level
of the chin only measures the thickness of the symphysis.
With regard to the dimensions of the face as a whole, we shall only refer to what has
been already stated concerning the inverse proportion of the area of the cranium, and
that of the face, in different species of animals.*
The face represents a triangular pyramid, and offers for consideration three surfaces
or regions : an anterior, a superior, and an inferior.
Anterior or Facial Region.
The numerous anatomical differences which this region presents form distinctive
characters, not only of different nations, but also of different individuals.
It is bounded above by the forehead, below by the base of the inferior maxilla, and
laterally by a line which passes along the external angular process, the malar bone, and
the ridge which separates the canine fossa from the tuberosity of the maxilla. In this
region we observe, in the median line, the nasal eminence ; a transverse suture, formed
by the union of the proper nasal bones with the os frontis, the fronto-nasal suture ; below
this suture, the nose, a pyramidal eminence, narrow above or at its root, broad below or
at its base, and formed by two bones, which are united together by juxtaposition in the
median hne, and externally to the ascending process of the superior maxilla. Below
this eminence is the anterior orifice of the nasal fossa, which has the form of a heart on
playing cards, and presents at the bottom the anterior nasal spine, and below this a ver-
tical suture, the maxillary, the interval which separates the middle incisor teeth, the
opening of the mouth, and the symphysis menti. On each side, we find the opening or
base of the orbit, directed obliquely outward, of an irregular square form, and presenting
above the supra-orlitary foramen ; below, the infra-orhitary foramen ; on the outside, the
fronto-jugal suture ; and, on the inside, the fronto-maxillary suture. Below the opening
of the orbit is the canine fossa, then the alveoli and teeth of the two jaws, the extemsd
oblique line, the mental foramen, and the base of the inferior maxilla.
Superior or Cranial Region.
This region is so united with the inferior surface of the cranium, that the scull and
the superior maxilla form only one piece, and cannot be removed from each other. It
presents, in the median line, counting from behind forward, the articulation of the vomer
with the sphenoid, in which articulation there is a mutual reception of parts, the sphe-
noidal crest being received between the laminae of the vomer, and these, in their turn,
being lodged in corresponding fissures in the sphenoid ; the articulation of the vomer
with the posterior edge of the perpendicular plate of the ethmoid ; the articulation of
this perpendicular plate with the nasal spine of the frontal bone ; and the articulation of
this spine with the proper bones of the nose. On each side, proceeding from within out-
ward, we observe, 1. The roof of the nasal fossae, formed behind by the inferior surface
of the body of the sphenoid ; in the middle by tlie cribriform plate of the ethmoid ; and
in front by the pusterior surface of the nasal bones. 2. More externally, the base of the
' Vide of the cranium in general ; of the facial angle of Camper ; the occipital angle of Danbenton, and the
measurement of Cuvier, p. 45
THE FACE IN GENERAL. 01
pterygoid processes, the articulation of the palate bone with the sphenom, the pterygo-
palatine canal, and the spheno-palatine foramen. 3. The articulation of the lateral mass-
es of the ethmoid with the sphenoid behind, and with the frontal bone in front. 4. The
articulation of the internal angular process of the frontal bone with the os unguis. 5. The
articulation of the nasal notch of the frontal bone with the ascending process of the su-
perior maxilla, and the proper bones of the nose. 6. More externally still, the roof of the
orbit, bounded externally by the articulation of the frontal with the malar bone and the
sphenoid, and by the sphenoidal fissure. 7. The anterior surface of the great wing of
^ the sphenoid, which forms the largest portion of the external wall of the orbit ; 8. Out-
side the orbit, the zygomatic arch.
Inferior or Guttural Region.
This region forms part of the pharynx and cavity of the mouth. It presents from be-
hind forward, 1. A vertical portion; 2. A horizontal portion ; and, 3. Another vertical
portion.
The vertical portion {fig. 21) exhibits in the median line the posterior edge of the sep-
tum narium, formed by the vomer ; the posterior extremity of the articulation of the vo-
mer with the sphenoid (o, fig. 21) ; and the posterior nasal spine. On each side, the pos-
terior opening of the nasal fossa {k o, y), which is quadrilateral, longer in its vertical than
in its transverse diameter, and formed internally by the vomer, externally by the ptery-
goid process (r), above by the sphenoid united with the palate bone, and below by the
ualate bone. More externally is the pterygoid fossa (r), formed by the sphenoid, and a
small part of the palate bone. Still more externally, we find a deep fossa, or, rather, a
large space bounded internally by the external plate of the pterygoid process and th# tu-
berosity of the maxillary bone, and externally by the ramus of the inferior maxilla ; it is
known by the name of the zygomatic fossa.
The horizontal portion is the aixh of the palate {i x y, fig. 21). It is of a parabolic form,
extremely rough, and, in the fresh state, covered by the palatine mucous membrane. It
is constituted by the palatine processes of the maxillary bones (x), and by the horizontal
portions of the palate bones (y), and presents, in consequence, a crucial suture, at the cen-
tral point of which the vomer is attached : hence the piece of anatomical nicety which
consisted in Eisking at what part of the skeleton it is possible to touch five bones at once
with the point of a needle. The arch of the palate is pierced by several foramina ; we
find here the inferior opening of the anterior palatine canal (1), which is single below, but
double above, so as to open into each nostril separately ; the posterior palatine canals (2),
which open at the posterior and external part of the arch of the palate ; and a groove,
which runs along the external edge of the arch, and lodges the posterior palatine vessels
and ner\'es at their exit from their canals.
The third portion is also vertical : it presents, 1. In the median line, the suture of the
two superior maxillary bones, the interval between the middle incisor teeth of each jaw,
the symphysis menti, and the genial processes. 2. On each side, the posterior surface
of the alveolar border of the upper jaw, and the two rows of teeth which lie across each ,
other like the blades of scissors in the middle, but meet posteriorly. 3. The posterior
surface of the inferior maxilla, the internal oblique line, the sub-lingual and sub-maxillary
fossae, and, lastly, the base of the inferior maxilla.
Zygomatic or Lateral Regions.
These regions are bounded above and on the outside by the zygomatic arch ; above
and on the inside by the transverse ridge which separates the temporal from the zygo-
matic fossa. They present first a plane surface, formed by the ramus of the inferior
maxilla ; when this part is removed, we observe the zygomatic fossa, the superior wall of
which is formed by the inferior surface of the great wing of the sphenoid, the anterior
by the maxillary tuberosity, the internal by the outer plate of the pterygoid process, and
the external by the ramus of the inferior maxilla. The posterior and inferior walls are
wanting.
At the bottom of this fossa, between the maxiUary bone and the anterior surface of
the pterygoid process, is a large vertical fissure, named by Bichat the pterygo-maxillary
fissure ; this opening leads into a sort of fossa, denominated by the older anatomists bot-
tom of the zygomatic fossa, and by Bichat spheno-maxillary fossa, which it is important to
study carefully, because five foramina or canals open into it, viz., three behind ; thefora'
men rotundum, the vidian or pterygoid, and the ptery go-palatine canals : a fourth on the in-
side, the spheno-palatine ; and a fifth below, the superior orifice o{the posterior palatine canal.
Lastly, the spheno-maxillary fossa presents, at the union of its superior with its ante-
rior wall, the spheno-maxillary fissure [fig. 21, before 3), which, on the one hand, makes
an acute angle with the sphenoidal fissure (or foramen lacerum orbitale), and, on the
other, a right angle with the pterygo-maxillary fissure. The spheno-maxillary fissure,
which is traversed solely by some nerves and vessels, is formed internally by the max-
illary and palate bones, externally by the sphenoid, and at its anterior extremity, which
is very broad, it is completed by the malar bone.
62 OSTEOLOGY.
■' Cavities of the Face. ---i. >*»..:•,.
TTie study of those bones which we have been engaged in examining has made us ac-
quainted with the existence of a great number of cavities, which considerably augment
the size of the face, and multiply its internal surfaces, without proportionally increasing
the weight.
All the cavities of the face may be reduced to three principal : viz., 1. The orbital cav-
ities ; 2. The nasal fossae, of which ail the sinuses are dependances ; and, 3. The buc-
cal cavitv, or mouth.
The Orbits.
These cavities, two in number, have the form of quadrangular pyramids, the axes of
which, prolonged backward, would intersect each other in the situation of the sella tur-
cica. It shoidd, at the same time, be remarked, that the internal wall of the orbit does
not participate in this obliquity, but is directed straight from before backward. We have
to consider in each orbit, a superior, an inferior, an external, and an internal wall ; four
angles which correspond to the intersection of these surfaces ; a base and an apex.
The superior wall, or roof of the orbit, formed by the frontal bone in front, and by the
orbital or lesser wing of the sphenoid behind, is concave, and presents from before back-
ward, 1 . Towards the outside, the lachrymal fossa. 2. On the inside, the slight depres-
sion in which the pulley for the superior oblique muscle is attached. 3. The suture be-
tween the lesser wing of the sphenoid and the orbital plate of the frontal.bone. 4. The
foramen opticum.
The inferior wall, or floor, forms a plane inclined outward and downward, and pre-
senll from before backward, 1. The infra-orbital canal. 2. A suture which marks the
union of the malar bone with the superior maxilla. 3. The orbital surface of the superior
maxilla. 4. A suture which marks the union of the superior maxilla with the palate bone.
5. The orbital facette of the palate bone.
The external wall, formed by the sphenoid and the malar bone, presents an almost ver-
tical suture, which indicates internally the spheno-jugal suture.
The internal wall, formed by the os unguis, the ethmoid, and the sphenoid, presents
two vertical sutures : in front, that which unites the os unguis to the ethmoid, and be-
hind, that which unites the ethmoid to the sphenoid. In front of these sutures is the
lachrymal groove, formed by the union of the os unguis and the ascending process of the
superior maxilla ; at the lower part of this groove we find the wide and very oblique ori-
fice of the nasal canal or duct, which opens into the middle meatus of the nose, and es-
tablishes a direct communication between the orbital and nasal cavities.
Of the four angles, two are superior and two infetior. Of the two superior, one is in-
ternal, the other external. The external superior angle presents the sphenoidal fissure
behind, and the inner aspect of the spheno-frontal and fronto-jugal sutures.
The internal superior angle presents the suture of union of the frontal bone with the
ethmoid behind, and with the os unguis in front. The orifices of the two internal orbital
foramina are seen in the situation of this suture.
Of the two inferior angles, the external presents the spheno-maxillary fissure, a portion
of the malar bone, and the opening of the jugal canal. The internul presents an uninter-
rupted horizontal suture, which unites in front the maxillary bone to the os unguis ;
more posteriorly, the maxillary bone, and then the palate bone, to the ethmoid. The
base of the orbit is cut obhquely from within outward, and from before backward ; its ver-
tical diameter is, for the most part, quite perpendicular to the horizon, but is sometimes
rendered slightly oblique by the projection of the frontal sinuses. At the apex of the or
bit is the union of the sphenoidal, the spheno-maxillary, and pterygo-maxillary fissures.
The Nasal Fossa.
These fossae are two in number, separated from each other by a vertical septum di-
rected from before backward ; they are situated in the middle of the face, and are pro-
longed into the interior of several of the bones of the face and cranium by means of the
cavities called sinuses. To describe their situation more exactly, we may say that they
are placed below the anterior and middle part of the base of the cranium, above the cav-
ity of the mouth, between the orbits, and the canine and zygomatic fossae of each side.
In order to have an exact idea, either of the dimensions or the shape of the nasal fossae,
it is necessary to have recourse to horizontal and vertical sections, of which the latter
should be made both from before backward and from side to side.
With regard to their dimensions, the nasal fossae (see figs. 22 and 37) present, 1. A
vertical diameter, larger in the middle than before or behind. 2. A transverse diameter
much shorter than the other two, and gradually contracted* from the lower to the upper
part, on account of the obliquity of the external wall. 3. An antero-posterior diameter,
which measures the whole of the interval between the anterior and posterior openings
of the nares.
* This pro^essivo contraction of the nasal fosss from below upward, and the obliquity of the externa!
wall, ought to be remembered during the introduction of instruments into the nose.
THE FACE IN GENERAL. ^
■ The nasal fossae have a horizontal direction, but are nevertheless slightly inclined
backward and downward ; this is caused by the sloping of the inferior wall and the ob-
liquity of the body of the sphenoid, which fonns part of the superior wall. They are
irregular cavities, and have four walls ; a superior, an inferior, an internal, and an ex-
ternal ; and two orifices, an anterior and a posterior.
The superior wall or roof of the nasal fosses presents a concavity looking downward : it
o : :rraefl 1 In front by the proper bones of the nose, and in a small degree by the na-
sal spine of tne frontal bone. 2. In the middle, by the cribriform plate of the ethmoid.
3. Behind, by the body of the sphenoid. In this wall are two transverse sutures, name-
ly : before, the suture which indicates the union of the nasal and frontal bones, and be-
hind, that which marks the union of the ethmoid and sphenoid. At the back part of this
wall the opening of the sphenoidal sinus is seen.
The inferior wall or floor, much broader but shorter than the superior, presents a trans-
verse concavity ; it is directed from before backward, and slightly from above downward,
which arrangement concurs in determining the obliquity of the nasal fossae. It is form-
ed, in front by the superior maxilla ; behind, by the palate bone ; a transverse suture
marks the union of these bones. Near its anterior extremity, and at the side of the me-
dian line, the floor of the nasal fossa? shows the superior orifice of each branch of the an-
terior palatine canal {g, fig. 22, and o, fig. 37).
The internal wall (see fig. 22) formed by the septum is generally flat, but sometimes
concave or convex, according as it is bent to one or the other side.*
We find here the suture which indicates the union of the vomer with the perpendicu-
' lar plate of the ethmoid (3 4, fig. 22) ; the septum in the skeleton is deeply notched in
front, and this notch (14 8), which is formed above by the perpendicular plate of the eth-
moid, and below by the vomer, is occupied in the fresh state by a cartilage, called the
cartilage of the septum.
The external wall {fig. 37), remarkable for its anfractuosities, is formed by the ethmoid
(,6 c), the OS unguis, the palate bone (m y), the superior maxillary p^ 37_
(* ic o), and the inferior turbinated bone (d). It presents from
above downward, 1. The superior turbinated bone, superior concha,
or concha of Morgagni (i), in front of which is a rough square sur-
face. 2. The superior meatus (between b and c), at the back part
of which we find the spheno-palatine foramen (n), and the open-
ing of the posterior ethmoidal cells. 3. Below the superior mea-
tus, the middle turbinated bone, or middle concha (c). 4. Below, the
middle meatus (between c and d), at the back of which is the open-
ing of the maxillary sinus already described {s-ee maxillary bone,
Jig. 25) ; and in front, the infundibulum (s, fig. 37), which leads
into the anterior ethmoidal cells. 5. The inferior turbinated bone,
or inferior concha (d). 6. The inferior meatus (m o), in which we
find the inferior orifice of the nasal canal.
The anterior and posterior openings of the nasal fossae have been described with the
anterior and inferior regions of the face.
General DevelopTnent of the Face.
The development of the face is not effected solely by an equable increase of its dimen-
sions ; for certain regions are at one period of life predominant, at another period rela-
tively smaller, which circumstances give rise to very characteristic differences of form
at different ages.
State of the interior Region of the Face at different Periods of Life.
In the Foetus. — The upper part of the face shows a remarkable predominance, depend-
ant upon the early development of the frontal bone and the great capacity of the orbits.
The middle portion, or the superior maxilla, on the contrary, is very much contracted
by the absence of the maxillary sinus and canine fossa ; the vertical dimensions of the
superior maxilla and of the palate bone are so small, that the edge of the orbit and the
alveolar border are almost contiguous. We should mention here that the prominence
of the alveolar border, which still encloses all the germs of the teeth, is the principal
cause of the absence of the canine fossa. Lastly, the inferior maxilla is contracted in
its vertical diameter, like the superior, and, like it, presents a decided prominence in
front, by reason of its enclosing the germs of the teeth in the alveoli. The inclusion of
the dental germs also, by causing the alveolar border to project, produces a degree of
obliquity downward and backward of the symphysis ; to these causes of the small extent
of the vertical dimension of the face, we must add also the inconsiderable height of the
ethmoid at this period.
* Sometimes the deviation of the septum is so considerable that the internal touches the external wall, and,
consequently, there is great difficulty in th« passage of the air. This circumstance has given nse ir some
cases to a suspicion of the existence of polypus.
i
64 OSTEOLOGV.
The transverse dimensions of the face are very considerable at the level of the orbits ,
at the lower part of the face, on the contrary, they are proportionally much less than in
the adult.
The characteristics, then, of the face of the foetus are, 1. The smallness of its verti-
cal dimension. 2. The predominance in size of its upper over its lower part.
In the adult, the development of the maxillary sinus, the widening and vertical exten-
sion of the alveolar arches, give to the face the expression which characterizes it at that
period of life.
In the aged, the loss of the teeth, and the disappearance of the alveolar edge, partly
restore to the face the expression which it had in tlie foetus ; but the elongation and prom-
iuence of the chin, which, from the diminution of the vertical diameter, approaches the
nose, and the symphysis of which is now oblique from behind forward and downward,
impress upon it a peculiar character. The obliquity of the cliin, just mentioned, is pre-
cisely the reverse of that which exists in the foetus.
State of the Lateral Regions in different jjges.
These regions undergo the fewest changes of all ; for if, on the one hand, the devel-
opment of the maxillary sinus tends to increase the prominence of the maxillary tuber-
osity in the adult, on the other, the inclusion of the dental germs in the superior max-
illa, during foetal life, compensates for the want of the sinus.
State of the Posterior Region of the Face at different ^ges.
In the guttural portion, this region presents, in the foetus and the infant, the foUowmg
circumstances : the posterior borders of the rami of the jaw are very oblique, instead oi
being almost vertical, as in the adult ; the pterygoid processes, and the posterior nasal
openings, are also directed very obliquely downward and forward, instead of vertically,
on account of the absence as yet of the maxillary sinus, which, during its development,
carries them backward. From the obliquity of the posterior border of the ramus of the
jaw, it follows that the articular surface of the condyle which surmounts it looks back
ward instead of upward.
In the horizontal or palatine portion, the inferior region of the face has proportionally
less extent from before backward than in the adult, on account of the obliquity of the
pterygoid process, and the slight development of the maxillary sinus. We perceive,
then, how great an influence the varying conditions of these sinuses exercise over the
whole configuration of the face, at the different periods of life.
It may be easily conceived that the cavities of the face must undergo important chan
ges during these alterations in the shape of the face which we have been describing.
The most remarkable is the tardy development of the nasal fossae compared with that
of the orbits. It may even be said that they proceed in an inverse ratio. The orbital
cavity, intended to receive the globe of the eye, which is already highly developed at the
time of birth, is of great capacity. This magnitude it owes entirely to the rapid growth
of the frontal and sphenoid bones ; because the malar bone and the superior maxilla con-
tribute but little towards it, and the height of the ethmoid is so small, that the vertical
diameter of the orbit, which depends upon that of the ethmoid, is less considerable than
its transverse diameter. The nasal fossas, which are very small in the foetus, gradually
acquire an increased extent of surface, by the growth in height of the ethmoid, the pal-
ate bone, the superior maxillary, and the vomer, and by the augmented size of the turbi-
nated bones ; and their surface is still farther extended by the enlargement of the max-
illary, sphenoidal, and frontal sinuses, and the ethmoidal cells. The development of
the frontal sinus, it may be observed, is owing chiefly to the separation of the two tables
of the bone, the anterior of which is almost always thrown forward, the posterior remain-
ing stationary. There are, however, some examples on record, in which it was evident
that the sinus was formed almost exclusively by the retrocession of the posterior table.
THE THORAX, OR CHEST.
The Sternum. — Ribs. — Costal Cartilages. — The Thorax in general. — Development.
The thorax {■&upa^, the chest) is a sort of bony cage intended to contain and protect
the principal organs of respiration and circulation. The parts which enter into its com-
position are twelve dorsal vertebrae behind, the sternum in front, and twelve flexible
bones named ribs, on each side. We have already described the dorsal vertebrae, and
have now, therefore, only to notice the sternum and the ribs.
The Sternum (a b c,fig. 38).
The sternmn, so named from the Greek word arepvov, the breast, is a kind of flat-
tened, symmetrical, bony column, which occupies the anterior and middle part of the
thorax. It is situated between the ribs, which support it like props. The clavicles,
6S
and through them the upper extremities, rest upon its upper part as a basis, during their
movements. The sternum is not immovably fixed in its place; it is raised and de-
pressed, as we shall point out in describing the mechanism of the thorax.
The length of the sternum, which is proportionally smaller in the female than in the
male, varies from 5^ to 7i inches. At its upper part its breadth is from IHo 2 inches ;
it then becomes contracted, then again expands, and terminates below in a very nar-
row extremity. Its thickness above is about 6 lines ; at its lower part it is much thin-
ner, never exceeding 3 hues.
With regard to figure, the sternum was compared by the ancients to the sword of a
gladiator, and from this have arisen the denominations given to its various parts. The
upper part {a), which is broadest, has been called the handle (manubrium) ; the middle
part (J), the body {mucro) ; and the lower extremity (c), the poini ; xipJioid appendix {pro-
cessus cnsiformis). This division of the bone into three parts has been retained by some
modern anatomists, who describe the three pieces of the sternum separately as so many
distinct bones. We shall adhere to it only, however, in speaking of the development of
the bone.
The sternum presents two surfaces, two borders, and two extremities.
1. The anterior or cutaneous surface is shghly convex, and forms an oblique plane down-
ward and forward ; it presents three or four projecting transverse lines, which are tra-
ces of the union of the original pieces of the bone, and divide it into surfaces of unequal
size. The line which marks the union of the first two pieces of the bone is the most
remarkable ; it causes a projection of variable size in different individuals, which has
been sometimes mistaken for a fracture or exostosis. At the lower part of this surface,
we find in some subjects a foramen which perforates the bone : sometimes, in place ot
this foramen, there is a considerable aperture, to which much importance has been
attached, as affording a proof of the primitive separation of the bone in the median hne.
The existence of this opening explains how purulent matter, deposited behind the ster-
num, may in certain cases make its way outward without any absorption of the bone.
The anterior surface of the sternum is covered by the skin, and an interlacement of
very numerous aponeurotic fibres.
2. The posterior, mediastinal, or cardiac surface (a b c), is slightly concave from above
downward, and presents, in young subjects, lines (e e) corresponding to those which
occupy the anterior ; but all which, excepting the one between the first and second pieces
of the bone, are effaced at a more advanced age. This surface is in relation with many
organs contained in the chest, and especially the heart, in front of which the sternum
forms a kind of shield.* At the lower part of this surface are several nutritious foramina.
3. The borders, very thick and sinuous, present seven articular cavities {d d, &c.), sep-
arated from each other by semilunar notclies, which are longer above than below, where
the facettes closely approach one another. The uppermost of these seven cavities is
shallow, triangular, and at an early age becomes ingrained with the cartilage of the first
rib ; those which follow are d^Sfttu angular, and situated at the extremities of each of
the lines (e e) above mentionfd:^J^ey are all intended to articulate with the cartilages
of the first seven ribs. WhenjgiSmined in a dried specimen, they appear more angiSar
and deeper in proportion to the^buth of the subject.
4. The superior or clavicular extremity is the broadest and thickest part of the whole
bone, presenting a notch, transversely concave, which bears the name of fourchette (/)
of the sternum (or semilunar notch) ; on each side {g g) is an oblong articular surface,
concave from without inward, convex from before backward, articulated with the clav-
icle, and surrounded with inequalities for the insertion of muscles and ligaments. It
frequently happens that the two clavicular facettes are not at the same height ; a fact
which was noticed by Morgagni, and which I have attributed to the unequal wearing of
the two articular surfaces.
5. The inferior or abdomj^nal extremity is formed by the xiphoid appendix (c) {^i^o^, a
sword), called also xiphoid'^ ensiform cartilage, because it often remains cartilaginous to
Hdult age. In length, shape, and direction, it presents numerous varieties ; it is fre-
quently bifid, sometimes pierced by a foramen, and is accasionally bent forward, or to
one side, and, in certain cases, much depressed : its summit gives attachment to an ap-
oneurotic structure, called the linea alba ; behind, it indirectly corresponds with the
stomach, which rests upon it when the body is placed in a prone position.!
* This use of the bone is eiemplified in many animals which are provided with a sternum, though they
hav« no ribs ; for example, the frog.
This bone has attracted much of the attention of the modem transcendentalists. By them it is regarded as
a vertebral column anterior to the intestinal canal in man, and inferior to it in the lower animals. Many of
them have conceived that they have found in it a cervical, a dorsal, and a lumbar regfion, &c., &c.
M. Cruveilhier, in the opinion of the editor, with much propriety, in the first edition of his work, took no
notice of the idle and fanciful speculations of the transcendentalists, either in reference to the sternum, or to
the analogy which exists between the bones of the cranium and the vertebrae. Although he lias, in the sec-
ond edition, introduced some notices in reference to the analogy which these gentlemen have attempted to
establish between the cranium and the vertebral column, believing that they only increase the size of the
book without adding to its value, we have excluded them. — Ed.
t In front this appendix is sub-cutaneous, and the skin which covers it is so sensible that the slightest con-
I
66 OSTEOLOGY.
Connexions. — The sternum articulates with sixteen bones, viz., fourteen ribs through
the medium of their cartilages, and the two clavicles.
Structure. — It consists of two very thin compact laminae, with an intervening spongy
substance, the cells of which are very large, and have very delicate parietes ; it is one
of the most spongy bones of the body, and to this circumstance the frequency of its dis-
eases is doubtless attributable.
Development. — The sternum is one of the slowest bones in its ossification ; up tc the
sixth month of fcEtal life, the broad cartilage of which it is composed exhibits no bony
points. It is also, of aU the bones, the one in which the phenomena of ossification pro-
ceed with least regularity. For the sake of simplicity, we shall study in succession the
development of the three parts which we have indicated, under the names of manubrium,
body, and xiphoid appendix.
1. Ossification of the Manubrium. — This part of the bone sometimes presents a single
nucleus, rounded, and transversely oblong ; sometimes it presents two nuclei, and, in this
case, they may be either placed one above the other, or side by side. In the former
case, the uppermost nucleus is the larger ; in the latter, both may be symmetrical and
of equal size, or, what is far more common, they may be of unequal magnitude. Lastly,
the manubrium occasionally presents more than two osseous points. Albinus found three
in one subject and four in another.
It should be remarked, that in the case of plurality of osseous points, the largest are
generally situated above : the exceptions to this rule are very rare. The osseous points
make their appearance from the fifth to the sixth month of foetal life.
2. Of the Body. — The osseous nuclei which enter into the composition of the body of
the sternum have generally a rounded form when they are single, and are situated in the
median line ; when they exist in pairs, or are placed laterally, they are more elongated,
but smaller, and appear to represent only the half of one of the single nodules. These
different osseous points are always so arranged as to be situated between two costo-
sternal articulations, so that a portion of the sternum is developed in each of the inter-
vals comprised between two ribs. The last piece is the only exception, being common
to the articulation of the sixth and seventh ribs.
If there be more osseous points than one in an intercostal space, these, as Albinus has
remarked, are invariably placed laterally, not one above the other.
There are, therefore, four primitive pieces in the body of the sternum, and each of
these is sometimes formed by one point of ossification ; at other times, by two lateral
points.
The following is the order in which the ossification of the body of the sternum pro-
ceeds : the two upper pieces first appear from the fifth to the sixth month of foetal life ;
the third is visible at the sixth month ; the fourth most conunonly makes its appearance
after birth, but sometimes towards the end of gestation.
In the ossification of the body of the sternum, we more frequently find examples of
two symmetrical nodules placed on opposite sides of the median line, than in the develop-
ment of the manubrium, f^*^
Union of the Points of Ossification of the Body. — In cqjteidering the union of the differ-
ent parts which compose the body of the sternum, it i?|i|Mpssary to make a distinction
between the lateral conjunction, that is, the union of the osseous points which are situated
on each side of the median line, and the vertical conjunction, or the union of the pieces of
the sternum properly so called. The lateral conjunction, or the union of those osseous
germs which form a pair in the same interval, always precedes the vertical conjunction.
The vertical conjunction, oj the union of the pieces of the body of the sternum together,
commences with the two inferior portions. After this union, the body of the bone con-
sists only of three parts. The second piece then unites with the lower ; the sternal
foramen is found sometimes at the junction of these last-mentioned parts, sometimes at
the place where the two lateral points of the fourth and of the third portion of the body
are united. The first piece of the body is not united to the two others until from the
twentieth to the twenty-fifth year.
It should be observed, that the union of the divisions of the body of the sternum takes
place precisely in the inverse order of their appearance. In fact, the appearance of the
osseous points proceeds from above downward, their union from below upward ; a fact
which verifies an assertion formerly made, viz., that the order of development of osseous
points is not always correlative to the order of conjunction.
3. Ossification of the Appendix. — This is generally accomplished by one nodule : some-
tusion produces, even in the most powerful men, syncope.* This fact may explain the importance which has
been«ttached to the configuration of this process, and to the names "pit of the stomach," " scrobiculus cordis,"
" pracordittm," which have been given to the region which corresponds to it. Much has been said of the dis-
placement of the Kiphoid appendix, and of the accidents to which this has given place ; but, in reality, these
displacements hare never been observed, and the accidents which have been attributed to them have most cer-
tainly depended on&n injury inflicted on the parts situated behind it.
* We do not believe that the skin situated over this appendix is more sensible than the skin elsewhere.
The syncope which follows a blow here is, in our opinion, produced by the impression it produces on the in»
temal organs. — Ed.
THE RIBS.
6¥'
tunes there are two, and then they are rarely symmetrical. The process commences in
the upper part of the cartilage, and very rarely extends through the whole. The time
of appearance of the osseous point is extremely variable ; sometimes it is visible to-
wards the third or fourth year ; sometimes not until the twelfth, or even the eigh-
teenth year.
In adult age, the sternum is composed of the three parts the development of which I
have just noticed, and which the ancients considered and described as distinct bones.
From the fortieth to the fiftieth year, and sometimes later, the appendix becomes united
to the body, which very rarely joins the manubrium ; when such is the case, the union
is more apparent than real ; for if the bone be cut verticdly, the articulation is apparent,
under a very thin layer of osseous matter.
From what has been said of the numerous varieties of ossification, it will be evident
that it is impossible to assign to this bone a limited number of osseous points. To those
which have been noticed I would add two others, described by Beclard under the name
of supra-sternal points, which I have seen once only in the sternum of an adult, in the
form of pisiform nodules, placed on each side of the semilunar notch of the stemiun.
The Ribs (1 to 12, Jig. 38).
The ribs (^costce, from custodes, as if, according to the explanation of Monro, they were
the guardians of the organs of the chest) ^^^^ 3g
are osseous arches stretched from the ver-
tebral column to the sternum. Their pos-
terior four fifths consist of bone ; the ante-
rior fifth is cartilaginous. The osseous
portion is the rib, properly so called ; the
cartilaginous portion is named the costal
cartilage.
The ribs are 24 in number, 12 (1 to 12)
on each side. Sometimes there are 26,
thirteen being on each side, and then these
supernumerary ribs are formed either from
a part of the transverse process of the sev-
enth cervical vertebra, or of the transverse
process of the first lumbar, which affords an
evident proof of the analogy existing be-
tween these parts. Sometimes, but more
rarely, there are only 22 ribs, an anomaly
pointed out by Galen. In this case, we
sometimes find two adjacent ribs united
throughout their entire length, sometimes
the first rib in a rudimentary state, being
properly formed posteriorly, but having its
anterior extremity lost in the>substance of
the scaleni muscles, or united to the second
rib, and through it joined to the sternum.*
The ribs are divided into two classes :
1. Those which extend from the vertebrae
to the sternum, the true ribs, sternal or ver-
tebrosternal ribs (1 to 7). 2. Those which
do not reach the sternum, the false, aster-
nal, or vertebral ribs (8 to 12). The last two
false ribs (11 12) are called floating, because their anterior extremity is movable in the
fleshy parietes of the abdomen. The ribs are designated numerically ;5rs^, second, &c.,
counting from above downward. It should, however, be observed, that in many surgi-
cal works, the ribs are counted from below upward, which is the easiest method on the
living subject.
The ribs have certain general characters which distinguish them from all other bones
and certain proper characters, by which one is known from another.
General Characters of the Ribs.
The ribs resemble flattened bony arches of about six lines in breadth, and one in thick-
ness, and of lengths varying according to their situation. The first rib is almost hori-
lontal, and the others in succession slope gradually more obliquely from behind forward,
and from above downward, their anterior extremities being on a much lower plane than
the posterior. Considered with regard to their axes, i. e., their absolute direction, the
ribs represent portions of a circle which successively increase to the eighth, and dimin-
* la a subject prepared for my lectures, the transverse processes of the second, third, and fourth lumbar
vertebrae were elongated, so as to form supernumerary ribs, while the transverse process of the first was un-
changed.
09}, OSTEOLOGY.
ish again to the twelfth ; their curvature is not regular, the posterior part representing
the segment of a much smaller circle than the anterior. They are generally tvnsted upon
themselves, so that their two extremities cannot rest at once upon the same horizontal
plane. The point where this torsion exists is marked on the convex surface by an ob-
lique projecting line, called the angle (Ji) of the rib ; but it is not correct to consider the
angle of the rib as resulting from this torsion ; it appears to me simply intended for mus-
cular insertions.
The ribs have a body and two extremities. The posterior or vertebral extremity is
Fig. 39. thicker than the rest of the bone, whence it has received
the name of head (i) {capitulum casta), and presents two half
surfaces (c c, fig. 39), of which the upper is smaller than the
lower, separated by a horizontal ridge. These two facettes
articulate with corresponding surfaces on the bodies of the
dorsal vertebrae {d rf, fig. 39). The head is supported by a
constricted portion, the neck (k, fig. 38), which is flattened
from before backward, and is the weakest part of the bone.
It presents behind some inequalities which correspond to the
_ transverse process of the dorsal- vertebra below. Externally
to the neck is an eminence known as the tubercle \l I) of the rib ; it is divided into two
parts, which are united at an angle, viz., an internal and inferior portion {I), smooth and
convex, which articulates with the transverse process of the vertebra below the particu-
lar rib examined ; and an external rough portion (Z), which gives attachment to liga-
ments. The tubercle is in general most prominent in the upper ribs.
That part of the rib which is included between the head and the tubercle {neck, cervix)
is directed from within outward, and slightly from above downward, so as to reach the
summit of the transverse process of the vertebra below. Beyond the tubercle, the rib
still follows the same direction for not more than fifteen lines ; it is then bent decidedly
forward. The situation of this curve, which corresponds with the torsion of the edges
above mentioned, is at the angle of the rib. The interval which separates the tuberosity
from the angle is the thickest and strongest part of the rib.
The rest of the rib which is before the angle becomes broader and thinner, and is di-
rected forward, so that, as Haller expresses it, the line which it describes represents in
some measure the tangent of the posterior curve. The anterior extremity (m) has a
hollowed oval facette for receiving the cartilage. Besides the objects we have already
described, we observe, near the anterior extremity of the rib, an oblique line, analogous
to that which forms the angle, but much less marked. This line may be considered as
forming the anterior angle of the ribs, and, like the posterior, it is intended for muscular
insertions.
From what has been said, we perceive that the ribs present, 1. A posterior extremity
or head, supported by a neck ; S. An anterior extremity united to the costal cartilage ; 3. A
body, having an external, or cutaneous surface, which is convex ; and an internal, or pul-
monary surface, which is smooth and concave ; a superior edge, which is curved, thick,
and rounded ; and an inferior edge, which has a greater dujprature than the superior, is
thin and sharp, and marked by a groove or furrow on the inner surface, called the groove
of the ribs {e, fig. 39), which receives and protects the intercostal vessels and nerves.
Lastly, the ribs have a double curvature, one of the surfaces, another of the edges ; this
last is the curvature of torsion.
Connexions. — The ribs are articulated, behind, with the dorsal vertebrae ; in front, with
the costal cartilages.
Structure. — The external aspect of a rib resembles a long bone ; but the internal con-
formation is analogous to that of flat bones. The compact and spongy substances are
so distributed that these bones enjoy a certain degree of flexibility, with great power of
resistance. In young subjects, the compact substance is in excess ; in the aged, and in
certain diseases, the opposite is the case ; hence the extreme fragility of these bones,
which are then broken by the least effort.
Development of the Ribs. — The ribs are among the earliest developed of the bones, the
'ossification of their bodies commencing from the fortieth to the fiftieth day after concep-
tion. They are developed by three osseous points : one primitive, and two epiphysary.
The primitive point by itself forms the body of the bone. Of the two epiphysary points,
one is intended to form the hccid of the rib, the other the tubercle. They appear from
the sixteenth to the twentieth year, and they unite with the rest of the bone about the
twenty-fifth year. These epiphysary points do not exist in the two lower ribs, which,
consequently, have only one point of ossification.
Special Characters of different Ribs.
The differential characters of the ribs have reference, first, to the length, which increas-
es gradually from the first to the seventh, and diminishes again to the twelfth ; secondly,
to the curvature, the four upper ribs being parts of much smaller circles than the rest,
and thus forming the summit of the cone of the chest, while the lower ribs constitute its
COST'XL CAST ILAGES. 18^
ISase ; and, lastly, to certain peculiarities of conformation in the first, second, third, elev
enth, and twelfth ribs, which require special description.
The first rib {\,fig. 38, and^. 40) is the shortest, and proportionally the broadest of
all the ribs, thus forming an imperfect hd to the bony case which p- ^q
constitutes the thorax. Its edges are curved, but its surfaces
are flat. The curve which it describes forms part of the circum-
ference of a much smaller circle than any of the other ribs. The
posterior extremity has a small head with a single convex facette r^M ^^^k
(a, fig. 40), supported by a long, thin, and cylindrical neck (b).
The tubercle (c) is very prominent ; it occupies the external bor-
der, and gives an angular appearance to this rib. The anterior
extremity {d) is broader than that of any other rib. Of the two surfaces, one is directed
upward and slightly outward, the other downward and a little inward. The superioi
surface {fi^. 40) has two depressions separated by a tuberosity (e). The anterior corre-
sponds to the subclavian vein ; the posterior to the artery of the same name. The tu-
berosity which separates them gives attachment to the anterior scalenus muscle. The
internal edge (a e d) is concave ; the external (a c d) is convex, and has no groove. The
first rib has neither a curvature of torsion, nor an angle ; so that the whole of it can rest
upon the same horizontal plane. The superior surface presents, also, near its anterior
-extremity, a depression, which appears to result from pressure by the clavicle, which I
have seen, in some cases, immediately articulated with this bone.
The second rib (2, fig- 38) preser\'es many of the characters of the preceding, but dif-
fers essentially in its length, which is at least double ; it belongs to a much larger circle :
it has no curvature of torsion, and can rest upon the same plane with its two ends ; the
angle is scarcely visible. The external surface is directed upward ; it presents in the
middle a very rough eminence for the attachment of the serratus magnus muscle. The
internal surface looks obliquely downward ; near the tubercle it has a very smtill groove.
The third rib (3, fig. 38) differs from the second by its great length, by the presence
of the angle, and by a curvature of torsion sufficient to prevent the two ends from rest-
ing at once upon the same horizontal plane.
The eleventh and twelfth ribs (11 l^,fig- 38) differ from all the others by the following
characters: 1. They form segments of much larger circles than any of the others; 2.
Their heads have only one articular facette, and this is flattened ; 3. They have no
neck, properly so called ; 4. They have no tubercle : 5. They have no groove ; 6. They
have a very thin and pointed anterior extremity. These two ribs differ from each other
only in length, the twelfth being the shorter.
The Costal Cartilages (T to \1\jig. 38).
The flexibility and elasticity of the ribs is partly owing to their structure, but more
' especially to the costal cartilages which prolong them in front. There are twelve cos-
tal cartilages, distinguished niunerically as first, second, third, &c. ; they are separated
from each other by intervals, which are very considerable at the upper part of the tho-
rax, but gradually diminish as we proceed downward : it is not very uncommon to meet
with thirteen cartilages on one side ; at other times there are only eleven. We some-
times find two cartilages which are joined together, and articulated with the sides of
the sternum ; when there are thirteen cartilages, the supernumerary one generally exists
between the third and fourth ribs ; it is thin, and, as it were, rudimentary ; it does not
form the continuation of any rib, and terminates insensibly in the muscles. The first
seven cartilages (1 to 7) articulate immediately with the sternum ; and hence the name
of sternal given to the ribs with which they are connected. Of the other five cartilages,
the last two (11 12) have no connexion with those that precede them; and, from this
circumstance, the navae floating has been given to the last two ribs.
General Characters of the Costal Cartilages.
All the costal cartilages are flattened like the ribs, and precisely resemble, in breadth
and thickness, the bones to which they are attached. The external end is received into
a cavity hollowed out in the anterior extremity of the rib : their internal or sternal ex-
tremity, which is much narrower than the external, is angular, and articulates with the
corresponding angular facettes of the sternum. Their anterior or cutaneous surfaces
are slightly convex, and covered by the muscles of the anterior region of the trunk, to
many of which they give attachment. Their posterior or mediastinal surfaces are
slightly concave. Their superior and inferior edges bound the intercostal spaces, and
give attachment to the muscles of the same name. They are altogether distinct from
articular cartilages, and have a peculiar tendency to ossify, this process taking place
partly on the surface, and partly from within outward.
Differential Characters of the Costal Cartilages.
The costal cartilages increase in length from the first to the seventh, and sometimes
to the eighth, which in this case articulates with the sternum ; they diminish in length
70 OSTEOLOGY.
from the seventh to the twelfth. This difference depends on the circumstance that the
osseous parts of the upper ribs terminate anteriorly in a line directed obhquely from
above downward, and from within outward, and that the sternum is only about half the
length of the lateral wall of the thorax, so that only the first four or five cartilages could
join this bone, did not the others bend upward, so as to reach its sides or join the lower
edge of the cartilage above ; the first three cartilages alone, therefore, follow the same
direction as the bony rib. The first cartilage differs from all the others by its shortness,
its thickness and breadth, and its tendency to ossify ; it is ahnost always bony in the
■ adult ; it is often continuous with the sternum, but is sometimes only contiguous, in
which case its articulation to this bone presents a great difference as respects motion.
The second and third costal cartilages cannot be distinguished from each other, but they
differ from the rest in being joined at right angles with the sternum, in not being bent,
and in being as broad at their sternal as at their costal extremities. The fourth carti-
lage becomes bent upward, after having followed the direction of the rib for a little way.
The length and curvature of the cartilages of the fifth, sixth, and seventh ribs progres-
sively increase : the seventh is at least three inches long, whUe the fifth is not more
than thirteen or fourteen hues ; their inner ends become successively narrowed, so as
to correspond with the diminishing cavities on the edges of the sternum ; the borders
of the fifth, sixth, seventh, and eighth costal cartilages articulate together, and present,
for this purpose, articular facettes, supported by eminences. The cartilages of the
eighth, ninth, and tenth ribs gradually diminish in length ; externally they have the same
breadth as the rib, and decrease as they pass inward, so as to terminate by a pointed
extremity, which is applied to the lower edge of the rib above. The cartilages of the
eleventh and twelfth ribs are extremely short, especiaUy that of the twelfth, which is
only a few lines in length ; their internal free extremity loses itself, so to speak, in the
substance of the abdominal parietes, so that they are altogether unconnected with the
other cartilages.
The Thorax in genekal.
The sternum, the ribs, and the whole dorsal region of the vertebral column, form the
framework of a large visceral cavity, the thorax, intended to contain and protect the
chief organs of respiration and circulation. It occupies the upper part of the trunk, be-
tween the thoracic extremities ; its boundaries are very well defined above, but below
there is not any line of demarcation in the skeleton between the cavities of the thorax
and abdomen ; or, rather, the bony thorax is common to the thoracic and abdominal vis-
cera. We shall see afterward, that these two cavities are separated from each other
by a movable and muscular septum called the diaphragm.
With regard to capacity, the thorax holds a middle place between the cavity of the
cranium and that of the abdomen. In each individual, the capacity of the thor2ix is ex-
actly proportional to the volume of the lungs ; and as, in general, voluminous lungs co-
exist with a highly-developed muscular apparatus, it follows that the size of the thorax
is no equivocal sign of a vigorous constitution. The thorax differs much from the ab-
dominal cavity in regard to its extensibility, being only capable of very Umited alternate
movements of dilatation and contraction. In the structure of the thorax, we find the
twofold condition of solidity and mobility in so perfect a degree,, that the framework of
which it is composed is equally fitted to serve as a protecting structure and a respira-
tory apparatus. This limited dilatabihty contrasts, on the one hand, with the almost in-
definite extensibility of the abdominal cavity, and, on the other, with the absolute want
of extensibility in the cranium.
We should form a very incorrect idea of the dimensions and shape of the thorax, if
we were to judge of them by its external aspect while still covered by the soft parts,
and surrounded by that species of girdle which is formed by the shoulder round its upper
part ; for we should then conclude it to be a truncated cone, with the base above. On
the contrary, when the surrounding parts are removed, the thorax represents a cone,
the base of which is in precisely the opposite direction, that is, below. The height of
Ihe thorax cannot be measured with exactness, because it varies according to the de-
pression or elevation of the muscular septum, which intervenes between the thoracic
and the abdominal cavities. We can only say, that the bony framework should be di-
vided into two parts, a superior or supra-diaphragmatic, which belongs to the chest, prop-
erly so called, and contains the lungs and heart ; and an inferior, which forms part of
the cavity of the abdomen, and contains the liver, the spleen, the kidneys, the stomach,
the duodenum, and part of the colon. It should be also remarked, that the supra and
sub-diaphragmatic portions of the thorax constantly vary in their respective proportions ;
and that these variations of height principally take place at the sides, the middle remain-
ing always nearly the same. The transverse diameters increase rapidly from the upper
to the lower part of the thorax. The same is true of the antero-posterior diameters, and
these also sensibly increase opposite the concavity of the dorsal region of the spine.
The antero-posterior diameters are much greater laterally than in the median line,
where they are diminished by the considerable projection of the bodies of the dorsal ver-
THE THORAX IN GENERAL. 71
tebrae. This shortness of the antero-posterior diameters between the sternum and the
vertebral column is in proportion to the small size of the heart, which is situated in
this region, as compared with that of the lungs, which occupy the sides.
Antero-posterior Flattening. — The cone represented by the thorax is flattened from be-
fore backward. This flattening appears to be connected with the existence of the clav-
icle, for we meet with it in all animals provided with this bone, while in those in which
it does not exist the flattening is lateral, i. e., from one side to the other.
The shape of the thorax is subject to many varieties, as respects different individuals,
age, sex, &c. Of the individual varieties, some are compatible with health, others are
pathological, and constitute malformations, the history of which belongs to the subject
of diseases of the chest. Sometimes they are congenital ; at other times they are the
result of accidental circumstances which have modified the primitive conformation.
In some subjects the lateral exceeds the antero-posterior flattening, and the sternum
is prominent, as we habitually see it in the thorax of phthisical patients.
Many individual varieties of conformation of the thorax are the effect of frequently
repeated, or permanent compressions exercised on the bony cavity. I have seen infants
in whom the thorax was perfectly well formed at birth, but had been deformed and flat-
tened on the sides by pressure from the hands of the nurse. If there be, in fact, a time
when the slightest external pressure may be productive of permanent deformity, it is
during the first years of life. The effects of a strong and permanent constriction are
also manifest in a very evident manner, in the alterations of the form of the thorax con-
sequent upon the use of stays. This species of constriction affects principally the lower
part of the chest ; so that the fifth, sixth, seventh, eighth, ninth, and tenth ribs are press-
ed forward and inward, because the length and flexibility of their cartilages allow them
to yield readily ; and all the viscera which correspond to this species of girdle undergo
very marked alterations in their direction, and even in their figure and position. Thus
the liver, the spleen, and the stomach are forced upward and compress the lungs, which,
in their turn, are pushed to the upper part of the chest, and have a tendency to pass con-
siderably beyond the level of the first rib ; 2. The stomach becomes more oblique ; 3.
The transverse arch of the colon is often forced downward ; the pregnant uterus acquires
an oblique direction. In an old female, whose thorax was so contracted below as to
present the appearance of a barrel, and bore witness to the use of a very tight corset,
the cartilage of the seventh rib, on the right side, was in contact with that of the oppo-
site rib ; the xiphoid appendix was strongly depressed, and pushed behind the cartilages
of the seventh and eighth ribs, which touched each otlier. Some varieties of conforma-
tion depend upon deviations of the vertebral column ; they evidently belong to patholo-
gic2il anatomy, and need not occupy our attention. In the female, the chest resembles
a cone, with a larger base, but of less height than in the male.
There are certain varieties at different ages, which will be noticed in the history of
the general development of the thorax.
As the thorax does not form a regular cone, when we speak of its axis being directed
obhquely from above downward, and from behind forward, we only refer to its anterior
wall, the posterior and latereil being altogether devoid of this obliquity.
We shall now consider in detail the external and the internal surface of the thorax ;
the inferior circumference or base, and the superior circumference or summit, resulting
from its conical form.
External Surface of the Thorax.
On this surface we find an anterior, a posterior, and two lateral regions.
The anterior or sternal region, much wider below than above, forms a plane inclined
from above downward, and from behind forward, and more or less projecting according
to the general conformation of the thorax. It presents, 1. In the middle, the cutaneous
surface of the sternum; 2. On the sides, the series of articulations of the cartilages of
the ribs with the sternum ; 3. The costal cartilages, those being the longest which ap-
pertain to the lower ribs ; 4. Between the cartilages, certain intervals named intercostal
spaces ; 5. Externally to the cartilages, an oblique line running from above downward,
and from within outward, and marking the series of articulations of the costal cartilages
with the ribs ; 6. Still more externally, another oblique line, wliich has not been pointed
out, and which is formed by the anterior angles of the ribs ; it corresponds in obhquity
with the chondro-stemal Hne, and forms the boundary of the anterior region.
The posterior or vertebral region presents, in the median line, the series of dorsal spi-
nous processes ; on the sides, 1. The vertebral grooves ; 2. The series of dorsal trans-
verse processes ; 3. Their articulation with the tubercles of the ribs ; 4. A series of
surfaces, of which the lower are the largest, and which are comprised between the angle
and the tubercle of each rib ; 5. Lastly, an oblique line, running from above downward,
and from within outward, formed by the posterior angles of the ribs.
The lateral or costal regions resemble a sort of curved grate, more convex behind than
in front, and showing the series of ribs and intercostal spaces in the same manner as
the anterior and posterior regions. They increase in width from above downward, and
72 OSTEOLOGY,
form a sort of inclined plane, with a curved surface, and obliquely directed from above
downvi^ard, and from within outward. The first two intercostal spaces are both the
broadest and the shortest ; the third and fourth are broader in front than behind ; the
following are of almost uniform width through their whole extent : on the whole, tue
breadth of the spaces diminishes from above downward, or, as Bertin remarks, tlie edge?
of the lower ribs are almost in contact. The last two intercostal spaces form the onlj
exception, for they are nine lines in width, while those in the middle of the chest are
only about four. It should, moreover, be remarked, that the intercostal spaces are
broader in front than behind ; a fact which may be easily shown by comparing the dis- .
tance which separates the anterior extremities of the first and second ribs with that
which intervenes between their posterior terminations. The length of the intercostal
spaces increases from the first to the sixth ; it then diminishes to the last two, where it
is very small.
Internal Surface of the Thorax.
This surface, like the external, is divided into four regions. The anterior region ex-
actly resembles the anterior region of the external surface, with this difference only,
that it is concave instead of being convex.
• The -posterior region presents, 1. In the median line, the dorsal portion of the spinal
coliuntm, which, like an incomplete septum, forms a projection in the interior of the tho-
racic cavity, and divides it into two equal parts ; 2. On the sides, two deep grooves,
which are contracted above, but gradually enlarge towards the lower part. These
grooves, which lodge the posterior convex portions of the lungs, exist only in the human
subject ; they allow part of the weight of the body to be throwTi backward — an arrange-
ment which is very advantageous for preserving the equilibrium in standing, and is a
proof that man is destined to the erect posture.
The lateral regions form an inclined plane on the inside, resembling that which exists
on the outside, only they are concave instead of being convex.
Superior and Inferior Circumferences.
The superior circumference or summit is narrow in comparison with the inferior, and
slopes obliquely from above downward and forward ; it is wider transversely than in
the antero-posterior direction, and resembles the shape of a heart on playing cards. The
circumference of this opening is formed, in front, by the upper end of the sternum ; be-
hind, by the first dorsal vertebra ; on the sides, by the first ribs and their cartilages.
This opening, which is contracted in its dimensions by the clavicles, gives passage to
the following organs : the trachea, the oesophagus, the thoracic duct, the large arteries
and veins of the head, neck, and thoracic extremities, the apex of the lungs, and several
muscles of the neck.
The inferior circumference or hase is very wide, at least four times larger than the pre-
ceding, and, like it, broader transversely than from before backward. It presents, 1. In
front, a wide notch, the borders of which are formed by the cartilages of the seventh,
eighth, ninth, and tenth ribs, but are incomplete between the tenth and eleventh, as also
between the eleventh and twelfth ; at the apex of this notch is the ensiform cartilage.
2. Behind, we find on each side of the vertebral column a notch of much smaller dinien-
sions than that in front ; it is caused by the great obliquity of the twelfth rib, which
forms an acute angle with the spine. The inferior circumference of the thorax is con-
nected with muscles by numerous attachments.
The great mobility enjoyed by the lower aperture of the thorax, which, as we have seen,
is subjected to alternate movements of dilatation and contraction, contrasts remarkably
with the almost absolute immutability of the superior aperture. The lower opening pre-
sents certain varieties in dimension which are observed chiefly during inspiration, or are
occasioned by accidental causes of dilatation, such as pregnancy or the accumulation of
fluids in the abdominal cavity. This variability of its dimensions has reference to the
compressibility and dilatability of the abdominal viscera. Such an alteration at the upper
opening would have caused serious inconvenience by compressing the trachea and the
vessels.
General Development of the Thorax.
The shape and dimensions of the thorax vary considerably at different periods of Ufe ;
it is of great importance to be well acquainted with these, because they bear constant
relation to changes in the organs contained within the cavity.
One of the most remarkable characteristics of the fcetal thorax is the predominance of
the antero-posterior over the transverse diameter ; at this age we find the sternum very
far separated from the spine, and forming a considerable projection in front. This ar-
rangement coincides with the largely-developed state of the heart, and an organ denom-
inated the thymus gland, which are both situated in the middle of the thorax ; and also
with the small size of the lungs, which are situated laterally. Another marked feature
in the chest of the foetus is the absence, or, at least, the slight depth, of those grooves
which we have described as peculiar to man, and intended to lodge the posterior edge of
THE LIMBS. 73
the lungs. The absence of these pulmonary grooves produces, as a necessary conse-
quence, a want of those external projections on the back of the thorax, which we find in
the adult corresponding with the grooves on the interior. These two characteristics,
viz., the predominance of the antero-posterior diameter, and the absence of the grooves,
both depend on the same cause, viz., the shght degree of curvature of the ribs in the foetus.
At a more advanced period the curvatures increase, the posterior grooves are gradu-
ally developed, the antero-posterior diameter is diminished, and the transverse propor-
tionally increased, so that there is less difference in the absolute capacity of the thorax
than would at first sight appear, for the differences we have noticed are in a great measure
referrible to the comparative predominance of one or other diameter. We should also
remark, that in the foetus, the vertical diameter, particularly at the sides, is much shorter^
on account of the unexpanded state of the lungs, and the elevation of the diaphragm by
the abdomind viscera.
The two circumferences likewise present remarkable differences. In the foetus, the
superior opening has a greater extent from before backward than transversely, which is
precisely the opposite of what is observed in the adult. The inferior aperture is ex-
tremely wide in every direction ; and this accords with the large size of many of the
abdominal viscera at this age, and particularly of the Uver.
At birth there is a sudden enlargement of the chest, because the access of air increases
the lungs to a double or threefold extent, which, up to this period, were much contract-
ed. At puberty, the thorax participates in the great development which the respiratory
apparatus undergoes. It is at this time, eiIso, that malformations of this cavity most fre-
quently become obvious. In adult age, the thorax still grows, but in an sdmost insen-
sible manner.
In the aged, the different pieces of the sternum become united by osseous union : the
cartilages are ossified ; the thorax has a tendency, in some degree, to form only one
piece, which does not permit the different parts to move upon one another.
THE LIMBS.
The vertebral column alone, in many animals, is the organ of locomotion, and the jaws
the organ of prehension ; but all animals so constituted either live in water or crawl on
the earth. The vertebral column, however, in man, and in those animals which live in
the air, is not constructed in such a way as to allow of the performance of a complete
locomotion, and thence the necessity of limbs, which are only connected to the trunk by
their superior extremities, and which, along the rest of their length, are completely iso-
lated from the body. They are also denominated extremities, because they are the parts
which are most distant from the centre of the body. They are four in number : two supe-
rior, or thoracic, so called because they are directly connected with the thorax ; and two in-
ferior, or abdominal, because they are continuous with the abdominal cavity. These last
are intended to support the weight of the body like two pillars, and to transport it from
place to place : the thoracic hmbs are intended to seize objects or to repel them. The
extremities present in their structure certain general circumstances which are essen-
tially characteristic. We shaU particularly notice the following :
1. As regards their form. The bones of the extremities differ in many respects both
from those of the trunk and those of the head. They generally have the appearance of
cylindrical and elongated levers, superimposed so as to form a column, the parts of
which are movable upon each other.
2. The continuity of the extremities with the trunk is established by means of osseous
zones or girdles, viz., the shoulder for the thoracic limbs, the pelvis for the abdominal.
3. The bones of the extremities diminish in size and length from the proximal to the
distal, or free end.
4. The nimiber of the bones in the limbs augments as we proceed towards their free
extremity.
5. As a necessary consequence of the augmented number of bones, and of their pro-
gressively diminished size, the articulations become more numerous and smaller towards
the distal end of the limb.
The thoracic and abdominal extremities being constructed upon the same fundamental
type, we should never forget, in describing them, that they have numerous analogies,
while, at the same time, we notice the differences in each which are connected with its
peculiar ofiice.
THE SUPERIOR OR THORACIC EXTREMITIES.
The Shoulder. — Clavicle. — Scapula. — The Shoulder in general. — Development. — Humerm.
— Ulna. — Radius. — The Hand. — The Carpus and Carpal Bones. — The Metacarpus an4
Metacarpal Bones. — The Fingers. — General Development of the Superior Extremities.
;, The thoracic extremities arQ divided into four parts, which, proceeding from the central
Dwards the distal end, are, 1. The shoulder ; 2. The arm ; 3. The fore-ann ; 4. The hand
K
'i4 OSTEOLOGY.
■;„*?r":t The Shoulder. ^mfiX- • ^^ .,» ..J ;..'
The shoulder, situated at the posterior and lateral part of the chest, is composed of
two bones, which form by their union a sort of angular lever with a horizontal and a ver-
<ical arm. The horizontal arm is represented by the clavicle ; the vertical, by the scapula.
The Clavicle {fig. 41).
The clavicle performs so important an office in the mechanism of the thoracic extrem-
Fig.M. ity, that, upon its presence in a certain number of an-
imals, and its absence in others, the extremely im-
portant distinction between claviculated and non-cla-
viculated animals has been founded.
The clavicle, so called from its supposed resem-
blance to a key, occupies the superior and anterior part of the thorax, and forms the an-
terior portion of the shoulder. It is placed horizontally between the sternum, which is
its fulcrum, and the scapula, the movements of which it follows. Its length varies in
different individuals, and more particularly in the different sexes ; in the female it is
generally longer than in the male. It is a long bone, and forms one of a pair, and is
consequently asymmetrical ; its inner end (,e,fig. 41), which is the larger, is rounded ;
its outer end (d) is flattened from above downward, and it enlarges progressively from
without inward like a cone. Its direction should be carefully studied. Proceeding
from its outer end, which is very thin, we find it describing a curve with the concavity
forward (d a) ; it then changes its direction, and describes a much larger curve with the
concavity looking backward {a c). The clavicle, therefore, has two alternate curvatures,
resembling an italic S, an arrangement which has the advantage of giving strength to
the bone, since each curve becomes the seat of a decomposition of forces, which greatly
diminishes the violence of shocks directed against it from without inward.
The clavicle may be divided into a body and extremities.
The body (a) presents two surfaces, one superior and one inferior ; and two borders,
an anterior and a posterior.
The superior surface (a) of the body is placed almost immediately under the skin, and
offers an extensive and ill-protected surface to the action of foreign bodies ; this is one
of the causes of the great frequency of fractures of this bone. This surface is covered
by the skin, the platysma myoides muscle, and numerous filaments of the cervical plexus
of nerves.* Hence, direct blows upon the clavicle are accompanied with severe pain,
on account of the compression of the nerves of this plexus. We find on this surface,
near its inner end, a tubercle for the insertion of the sterno-mastoid muscle ; it has also
some inequalities for muscular attachments on the outside.
The inferior surface, broad externally, and narrow internally, like the preceding, is
marked by a groove, running longitudinally, and lodges the subclavian muscle. Near the
inner extremity of this surface there is sometimes a facette, which articulates with the
first rib, and, on its inferior surface, inequalities for the insertion of the costo-clavicular
ligament. Near the outer end there is a very rough tuberosity, and an irregular hne,
directed obliquely from within outward and from behind forward : they are both intended
for the insertion of strong ligaments which unite the clavicle and the scapula, the coraco-
clavicular ligaments. The internal third of this surface corresponds to the first rib,
which it embraces and crosses at a very acute angle. The middle third corresponds to
the first intercostal space, from which it is separated by the brachial plexus and the ax-
illary vessels ; the external third is in relation to the coracoid process and the articula-
tion of the shoulder with the arm.
The anterior border (b), which is thin externally, becomes expanded into a surface to-
wards the inner end ; its external third is concave, the two internal thirds are convex.
This convexity dlows the clavicle to resist, like an arch, any violence applied directly
from before backward. The external third of this border, where it gives insertion to
the deltoid muscle, is rough, but the two internal thirds are less uneven.
The posterior border (c) is concave in its four inner fifths, and convex and rough in its
external fifth, for the insertion of the Trapezius muscle. Its relations are very impor-
tant ; the subclavian vein runs along it, and it also corresponds to the subclavian artery
and the brachial plexus. From this it may be conceived how dangerous fractures of
the clavicle might become, if the sharp end of the fragments should penetrate among
the nerves or the vessels ; it may also be imagined how depression of the clavicle, by
compressing the vessels which are distributed to the upper extremity, may suspend the
circulation there ; and, lastly, we can understand how it is easy to apply a hgature to
the subclavian artery, by cutting along the middle of the clavicle. There still remains
one important relation to be noticed, viz., the propinquity of the apex of the lungs, from
which circumstance it becomes possible to ascertain the sonorousness of this portion of
the lungs by percussion on the clavicle.
Extremities. — The external or acromial end (d) of the clavicle is thin, and flattened from
* It is uot uncommon to find the body of the clavicle itself traversed by a nerve of the cervical plexus.
THE SCAPULA.
ire downward ; it presents a very narrow elliptical facette, whicli looks downward
and outward, and articulates with a corresponding surface on the scapula. This is the
weakest part of the bone ; it lies almost immediately below the skin, and is much expo-
sed to external violence, by which it is sometimes broken.
The internal or sternal end (e), on the contrary, is the thickest and strongest part of
the bone, and might with propriety be named the head of the clavicle ; it" articulates
- with the sternum, projecting beyond the concave articular surface of that bone in all di-
Tections, a circumstance which renders displacement much more difficult.
There are many varieties both of size and direction in the body and ends of the clav-
icle. By inspection of the inner or outer ends of the clavicle, even in the living body,
we may judge at once whether the individual has been engaged in a laborious manual
employment. I have been able, from the simple circumstance of a marked preponder-
ance of size in the inner end of the left clavicle, to declare a priori, and correctly, that
the individual on whom I observed it was left-handed. In some clavicles the inner half
resembles a quadrangular pyramid. In the female the clavicle is much more slender,
and the curvatures are less pronounced, than in the male : the strength and degree of
curvature of this bone are proportionate to the laborious and continued exercise of the
upper extremity. It may, therefore, be easily conceived how much importance should
be attached in forensic medicine to the characters of a bone, the examination of which
would of itself be sufficient to determine whether the body to which it belonged were
male or female, and whether the person had been engaged in a laborious manual occu-
"'pation, or the contrary.
' Cannexions. — The clavicle articulates with three bones, the sternum, the scapula, and
often with the first rib.
Internal Structure. — With regard to its structure, the clavicle appears to hold a middle
place between the long bones and the ribs ; like the first, in fact, it possesses a medul-
lary canal ; but it approaches the structure of the ribs in the contracted dimensions of
this canal, and the spongy nature of its ends. In examining many clavicles belonging
to the collections of the Faculty of Medicine, I was never able to meet with one that had
traces of a medullary canal extending throughout its entire length.
Development. — The clavicle makes its appearance at a very early period, about the
thirtieth or thirty-fifth day ; its dimensions, compared with those of the other bones of
the thoracic extremities, present considerable variations at different ages. In the sec-
ond month of foetal life, the clavicle has already acquired nearly three lines in length ; at
this time it is at least four times the length of the humerus and femur. After the com-
mencement of the third month it is not more than half as long again as these bones.
At the end of the third month it is still longer than the humerus, which does not exceed
it until the fourth month. Lastly, in the foetus at the full period the humerus does not
exceed the clavicle in length by more than a fourth, while in the adult it becomes twice
as long.
The clavicle has only one primitive osseous point ; from the age of fifteen to twenty-
eight years, a complementary or epiphysary point is developed, under the form of a very
thin plate, at the anterior part of the sternal end.
The Scapula {Jig. 42).
The scapula, or shoulder blade, forms in man the back part of the shoulder ; in a great
number of animals it constitutes the entire shoulder. Placed pig. 42.
like a sort of shield upon the back part of the thorax, for which
it serves as a means of protection against extern2d violence, this
bone corresponds with the lateral part of the spine, which it ap-
proaches or quits according to the different movements of the
upper extremity, to which it affords a movable point of attach-
ment.
The scapula is proportionally larger in man than in the lower
animals. It is an asjonmetrical bone, broad, thin, and triangu-
lar, presenting two surfaces, three borders, and three angles.
The anterior or costal surface is moulded, as it were, upon
the thorax ; it is concave ; the concavity being named the sub-
scapular fossa, is occupied by the sub-scapular muscle. In this
we observe ridges directed obliquely from above downward, and
from without inward, which receive the insertion of those apo-
neurotic layers which divide the substance of the muscle.* In
a well-formed subject, this surface should be exactly fitted to
the surface of the thorax ; but when the chest is contracted, as
m phthisical patients, the scapula does not participate in an equal degree in this alter-
* The direction of these ridges is not parallel with that of the back part of the ribs, but crosses them at an
angle ; proving, in opposition to the opinion of some of the older anatomists, that the ridgres, and t^e depres-
sions which separate them, are not the result of pressure exercised bj; the ribs on the antenor surtace of tM
scapula.
5^ OSTEOLOGY.
ation, and there is, consequently, a disproportion and change of relative position, to such
a degree that the scapulae fonn a projection behind, and are in some measure detached
from the ribs like wings : hence the expression of scapula data, applied to the external
aspect of the shoulder-blades in phthisical persons.
The posterior or superficial surface {fig. 42) is divided into two distinct parts by a tri-
angular eminence named the spine of the scapula (a). This spine, situated at the junc-
tion of the upper with the three lower fourths of the bone, arises from the posterior sur-
face by a thick edge, which traverses the entire breadth of the scapula ; the spine is
then directed horizontally backward, outward, and a little upward, and presents for our
notice an upper and a lower surface, which form part of the supra-spinous and the infra-
spinous fossae ; an external border (c), short, concave, thick, and smooth ; and a posterior
border (a), very thick and sinuous, which has at its inner end a triangular smooth sur-
face {d), over which the trapezius muscle glides. This border is placed almost imme-
diately under the skin, and may be easily traced in the living subject, even in very cor-
pulent individuals. It gives attachment below to the deltoid muscle, and above to the
trapezius, which is inserted into nearly the whole of its thickness.
Instead of uniting so as to form an angle, the external and the posterior borders of
the spine are continued into a process named acromion (c), (from aKpoQ, the summit, and
u^of ), because this process forms the highest point of the shoulder. The acromion then
forms a continuation of the spine, which appears to be its root. At the place where the
spine is continuous with the acromion, there is a contraction, a sort of pedicle, above
which the acromion enlarges, and becomes curved into a triangular arch presenting an
anterior and a posterior surface, a superior and an inferior edge, a base and a smiunit.
The posterior surface of the acromion is convex and rough, and is separated from the
skin by fibrous tissue and a synovial bursa. It gives attachment to the trapezius mus-
cle, and to acromio-clavicular Ugament. The anterior surface is concave and smooth, and
corresponds to the shoulder-joint. The upper edge has a facette, which articulates with
a corresponding surface on the clavicle ; the lower edge is convex and rough ; the sutrv-
mit forms the highest point of the shoulder; the base is continuous with the spine ; the
narrowness of this base or pedicle of the acromion explains the possibility of fractures
at this point.
The whole of the posterior surface of the scapula, above the scapular spine, forms the
supra-spinmis fossa (/), which is narrow at it its outer part, and a little enlarged and
shallower at the inner, and is filled by the supra-spinatus muscle. All that is below the
spine forms the infra-spinous fossa {g), which is occupied by the infra-spinatus muscle.
Towards the outer part, this fossa presents a vertical ridge, which marks off a narrow
surface, elongated from above downward, and itself divided by an obUque ridge into two
smaller surfaces, the superior (A) of which gives attacliment to the teres minor muscle,
and the inferior (i) to the teres major.
Of the three borders or costa of the scapula, the internal, which is also called the base,
posterior costa, vertebral or spinal border (k d I), is the longest of the three in the human
subject ; in the lower animals it is the shortest. It is thin, slopes from without inward
in the upper fourth of its extent, and from within outward in the three inferior fourths,
which gives it an angular form. The spine of the scapula meets the base at this angle {d).
The superior or cervical border, or superior costa (k r), the shortest and thinnest ; we
observe on it a notch (r) of variable size, which is converted into a foramen by means of
a ligament, and gives passage to the supra-scapular nerve ; rarely to the vessels of that
name.
The external or axillary border, or inferior costa {s I), is the thickest part of the scap-
ula. It is separated from the thorax by an interval, the extent of which determines the
depth of the cavity of the axiUa. Its thickness increases from the lower to the upper part,
where it terminates in the glenoid cavity. There is a depression (s) from which the
long head of the triceps muscle arises.
Angles. — Two of the three angles of the scapula are intended for the attaclmient of
the principal muscles belonging to this bone ; the third enters into the formation of the
shoulder-joint. ,
The internal angle {k) is that which approaches most to a right angle. In robust subjects
it presents a marked impression for the insertion of the levator anguli scapulae muscle.
The inferior angle (JL) is very acute, and is marked internally by inequalities for the at-
tachment of the serratus magnus. This angle is only covered by the skin and the latis-
simus dorsi muscle, and is, consequently, more liable than the other two to fracture from
external violence.
The external or glenoid angle (m) is the thickest part of the scapula ; it is hollowed into
an oval cavity, the long diameter of which is vertical, and the small end of the oval up-
permost. This cavity, called the glenoid cavity (m) of the scapula, belongs to the shoul-
der-joint ; it is supported by a contracted portion (?0 called tlie neck of the scapula, and
is surmounted by a strong process (o) named coracoul, from a fancied resemblance to the
bill of a raven. This process is directed outward ami forward like a finger in a state of
semiflexion ; its lower surface, which looks oiitwanl, lo confmve and smooth,' and is
THE SHOULDER IN GENERAL. 77
curved to correspond with the head of the humerus ; its upper surface is convex and
rough, and articulates with the clavicle. Its summit is rough, and affords attachment
to muscles. The coraco-acromial ligament is attached to its posterior border, the fecto-
ralis minor muscle and the anterior fibres of the coraco-clavicular ligaments to its ante-
rior, while the short head of the biceps and the coraco-brachialis muscles united arise
from its summit.
Connexions. — The scapula is articulated with the clavicle and the humerus.
Internal Structure. — There is very little spongy substance in the composition of the
scapula, as may be well observed in the supra and infra spinous fossae, where we can
scarcely make use of a file, without breaking through the very thin lamina of compact tis-
sue of which the bone is composed at these points. The spongy tissue occupies the ax-
illary border, the spine, the articular angle, the acromion, and the coracoid process.
Devclopimnt. — The scapula is developed from six points : one primitive for the body
of the bone, and five epiphysary or complementary, viz., one for the coracoid process,
two for the acromion, one for the posterior border, and one for the inferior angle.
The osseous point of the body appears towards the end of the second month of utero-
gestation, in the infra-spinous fossa, under the form of an irregularly quadrilateral plate
of bone, on the surface of which we cannot perceive any vestige of the scapular spine.
It is not until the third month that this process becomes apparent ; and at that period
the ossification has made so little progress towards the upper part of the bone, that the
spine, which subsequently is situated below the upper fourth of the scapula, is then suffi-
ciently elevated to project beyond the upper part of that bone. The spine is never devel-
oped from a separate point, but sprouts, as it were, from the posterior surface of the bone.
The osseous point of the coracoid process appears sometimes at birth, but generally
during the first year.
The osseous germ of the base of the acromion process, which has a rounded form, is
developed before the fifteenth year. That of the summit of the acromion does not be-
come visible until from the fifteenth to the sixteenth year ; that is the time at which the
coracoid process is united to the body of the bone. It is very variable in its shape, be-
ing sometimes like a narrow band, sometimes forming, by itself, the greatest part of the
process.
The osseous point of the inferior angle of the scapula is developed during the course
of the fifteenth year.
The osseous point of the vertebral border extends along the whole posterior costa as
a long marginal epiphysis, analogous to that which we shall afterward describe as exist-
ing on the haunch bone. It is not formed till the seventeenth or eighteenth year.
The union of these different osseous points does not commence until the fifteenth
year, at which time the coracoid process becomes joined to the body of the bone. The
other points unite at various periods, which have not yet been determined with much
exactness. The osseous point of the vertebral border remains the longest separate of
all. The union of all these points is not completed until the time when the growth of
the body is terminated.
The Shoulder in general.
Considered as forming only one piece, the shoulder represents a bony girdle intended
to serve as a fulcrum to the upper extremities. This girdle is incomplete in front oppo-
site the sternum, and behind in the region of the vertebral column. From this it follows,
that the two shoulders are independent in their motions, while the pelvis, which forms an
analogous structure for the lower extremities, is a continuous whole, the different parts
of which cannot move upon each other. The shoulders are fixed upon the upper part of
the thorax, and so greatly increase its apparent dimensions, that the chest, when they
are attached, resembles a cone with the base upward, while in its true shape it is a cone
with the base below. The shoulder is moulded exactly upon the thorax in front and be-
hind ; on the outside it is separated from it by an interval which forms the apex of the
axilla.
The circumstance which principally determines the transverse breadth of the shoul-
ders in the female is the length of the clavicle ; in the male, it is the breadth of the
scapula. The length of the clavicle and the width of the chest in front and at the upper
part, in the female, are evidently connected with the large size of the mammae ; and the
greater development of the scapulae in the male evidently corresponds with his greater
muscular power.
General Development of the Shoulder.
The development of the shoulder is remarkable for its precocity. For, on the one
hand, the considerable length, the well-defined form, and the double curvature of the
fcetal claAdcle, at a time when all the long bones are still straight, prove the rapidity with
which this part of the skeleton is developed. On the other hand, the size of the scapula,
which is already considerable, and the very advanced state of ossification of the part that
sustains the glenoid cavity, which enables it very soon to afford a sufficient resistance to
OSTEOLOGY.
the movements of the humerus, equally concur in demonstrating the same fact. This
rapid development cannot be attributed to the near vicinity of the heart and great vessels,
because the sternum and the cervical vertebrae, which are still more closely approximated
to the centre of the circulation, are proportionally much slower in their ossification.
The Arm.
The Humerus {Jig. 43).
The humerus, or bone of the arm, is situated between the shoulder and the forearm, at
-^ ^ the side of the thorax. It is the longest and the strongest of all the
/*'■ ■ bones of the upper extremity. It is proportionally shorter in individuals
"'^^ ^ of the Caucasian or white races than in the Ethiopian, which in them,
^t in this respect, presents some analogy to the ape tribes. Its direction
is vertical, that is, parallel to the axis of the trunk, but with some de-
gree of obhquity downward and inward. This obliquity is much great-
er in the femur, the bone of the lower extremity which corresponds
with the humerus. The distance between the humeri is much greater
in man than in quadrupeds, corresponding with the different shape of
the thorax, which, as we have before observed, is flattened from before
backward in the human subject, and laterally in quadrupeds. The hu-
merus is not, like the femur, curved as regards its axis, but it presents
a very marked curvature of torsion, which gives rise to a remarkable
groove, that lodges the deep artery and the radial nerve, as they turn
round the bone in a part of their course.
The humerus is a long, asymmetrical bone, presenting for examina-
tion a body (a) and two extremities {b c) ; the upper of these is rounded,
and is called the head (b).
The lower half of the body of the humerus is prismatic and triangular ;
the upper is cylindrical. It has three surfaces, an external, an internal,
and a posterior ; and three edges, an external, an internal, and an anterior.
The external surface {d e) presents, 1. A remarkable muscular impres-
sion, shaped like the letter V, with the point turned downward ; this is
the deltoid impression {d), and is generally situated below the upper third
of the bone, but sometimes at the middle ; 2. The groove of torsion (/),
directed obliquely downward and forward, the depth of which is always
proportional to the prominence of the deltoid impression, immediately
below which it is placed. Below the groove, the external surface (c)
looks forward, and is slightly concave, to allow of the origin of the
I { brachialis inter nus muscle.
The internal surface (a) is an oblique plane, looking forward and in-
ward ; the brachial artery runs along it, and therefore it is of impor-
tance to he well acquainted with the obliquity of the surface, in order that, when it is
necessary to compress the vessel, force may be applied in the proper direction. Its up-
per part, which looks forward, is broader than the lower, which is turned inward. On
this surface we observe, 1. The bicipital groove (g), which will be particularly noticed af-
terward ; 2. The principal nutritious foramen {v) of the humerus, which passes down-
ward into the interior ;* 3. An obscurely-marked impression for the coraco-brachialis
muscle.
The posterior surface is smooth, round, and much broader below than above ; it is cov-
ered by the triceps.
Of the three edges, the anterior (h i) is a rough ridge, round and blunt below, bifurcated
above, so as to form the two borders of the bicipital groove (g), which is one of the lar-
gest and deepest of all the tendinous grooves in the body, and lodges the tendon of the
long head of the biceps. The two borders of this groove, the external (h) and the inter-
nal {k), are very prominent and rough, and afford attachment to powerful muscles ; the
former to the peetoralis major, and the latter to the latissimus dorsi and teres major. It
should be remarked, that the anterior branch of the V represented by the deltoid impres-
sion is blended with the anterior edge of the bicipital groove, and greatly increases its
prominence.
The other two edges of the humerus, viz., the external {d I) and the internal (v r), are
olunt, and scarcely distinguishable in their upper two thirds, but sharp and prominent at
iheir lower parts, especially the external edge, which curves forward and gives attach-
ment to a great number of muscleig. This edge is also interrupted in its course by the
groove of torsion.
The lower or cubital extremity (c) of the humerus is flattened from before backward,
with a transverse diameter four times longer than the antero-posterior. It presents a
series of eminences and depressions arranged in the same transverse line, viz., counting
* There are some varieties in the situation of the nutritious foramen. I have seen it on the external, or
even posterior surface of the bone.
THE ULNA. 7g^
Irom without inward, 1. An exteriml tuberosity (I), called eptcondyle by Chaussier, which
forms a continuation of the outer border, and gives insertion to almost all the muscles
on the back of the forearm ; 2. The small head (m) of the humerus {humeral condyle of
Chaussier), a rounded eminence, bent forward and oblong from before backward. The
small head articulates with the radius, and is surmounted in front by a superficial de-
pression, intended to receive the rim of the shallow, cup-like cavity on the top of the
radius ; 3. An articular furrow (n), extending obliquely from behind forward, and from
without inward, and separating the small head from 4. The trochlea (c), or articulur pulley
of the humerus, which is also directed from behind forward, and from without inward, ia
excavated like the groove of a pulley in its long diameter, and the inner border of which
descends much lower than the outer. This trochlea articulates with a corresponding
surface on the ulna, and is surmounted in front by a small cavity named coronoid (o), and
behind by a much larger depression, the olecranoid cavity. These two cavities, the ante-
rior of which receives the coronoid process of the ulna during flexion of the forearm, and
the posterior, the olecranon, during its extension, are only separated from each other by
a very thin, translucent lamina of bone, which is sometimes perforated, so that they
communicate with each other ; 5. The internal tuberosity or epitrochlea (r),* which is bent
inward, is much more prominent than the external, forming a projection which can be
easily felt under the skin, and gives attachment to almost all the muscles situated on
the anterior aspect of the forearm.
The superior or scapular extremity of the humerus, much larger than the inferior, pre-
sents, 1. The head (i), a sphenoidzil eminence, forming about one third of a sphere. It
articulates with the glenoid cavity of the scapula, and is bounded in the two upper thirds
of its circumference by a circular furrow. The constriction resulting from this furrow
has been improperly called the anatomical neck of the humerus (*). The only part which
could possibly be considered as the neck, is a portion of the bone which projects on the
inner side, and appears to support the head. It is of importance not to confound the
circular constriction, which we have mentioned as being called the anatomical neck,
with what is denominated the surgical neck (at k), which is nothing more than that slight-
ly contracted portion of the bone which supports the whole of its upper extremity. The
presence of the anatomical neck of the humerus, and the inclination of the articular sur-
face, cause the axis of this surface to form an obtuse angle with the axis of the rest of
the bone. 2. Two other eminences, named greater {t) and lesser (u) tuberosities {trochiter
and trochin of Chaussier), and which might be called the great and small trochanters of the
humerus : they are separated by the bicipital groove. The smaller, which is in front,
gives attachment to the sub-scapular muscle ; the larger, which is external, presents
three surfaces, each of which gives attachment to a muscle, viz., to the supra spinatus,
infra spinatus, and teres minor.
Connexions. — The humerus articulates with the scapula, the radius, and the ulna.
Internal Structure. — The two extremities of the humerus are cellular ; the middle is
compact. It has a very large medullary canal.
Development. — The humerus is developed from seven points ; one for the body, two
for the upper end, and four for the lower.
The first osseous point appears in the middle of the bone from the thirtieth to the for-
tieth day, in form of a small solid cylinder, which progressively extends towards both
extremities. At birth, and during the course of the first year, the extremities are still
cartilaginous. The ossific point of the head of the humerus appears at the commence-
ment of the second year ; and that of the great tuberosity from the twenty-fourth to the
thirtieth month. It has not, in my opinion, been proved that there is any special point for
the lesser tuberosity. The ossification of the lower end of the bone commences after that
of the upper. At two years and a half, an osseous point is developed, corresponding to
the small head or condyle of the humerus ; at seven years, another nodule appears in the
epitrochlea ; at twelve years, a third point, which forms the inner edge of the trochlea ;
and, lastly, at sixteen years, a fourth point for the epicondyle.
The two points of ossification of the upper end of the bone unite from the eighth to
the ninth year. The four points of the lower end are joined together in the following
order : in the twelfth year, the two points of the trochlea ; in the sixteenth year, the troch-
lea, the epicondyle, and the small head. The two extremities are united to the shaft
from the eighteenth to the twentieth year. The union of the lower end always precedes
that of the upper by one year, although the latter first becomes ossified.
The Forearm.
The Ulna (jig. 44-).
The ulna, or cubitus, so called because it forms the elbow, is situated between the hu-
merus and the carpus, on the inner side of the radius, with which it articulates above
and below, but from which it is separated in the middle. It is the longer and the lar-
ger of the bones of the forearm. When the whole limb is in the vertical position, this
* Epitrochlea, from M, upon, and rpox'^'O) apuHey. Epicondyle, from ini, upon, and KivSv^oi, an eminence.
OSTEOLOGY.
Fig 44.
H
bone slants a little from above downward and outward. It is a long and
asymmetrical bone, much larger above than below, prismatic, triangular, and
slightly twisted upon itself: it is divided into a shaft and extremities.
The body or shaft (o) of the bone is larger above than below, is slightly curv-
ed forward, and has three surfaces and three edges.
The anterior surface (a) is broad above, and becomes gradually narrower to-
wards the lower part. On it we observe the nutritious foramen (above a),
which penetrates from below upward, i. e., in precisely the opposite direction
of the nutritious canal in the humerus. This surface is slightly grooved, and
gives origin to the flexor profundus muscle.
The posterior surface {d) is slightly convex, and is divided longitudinally by
a prominent vertical line into two portions, the inner of which is the broader.
A second oblique line placed at the upper part forms a triangular space occu-
pied by the anconeus muscle. The internal surface is very broad above, and
much smaller at its lowef end, which is immediately subcutaneous. It is
smooth throughout its whole extent. Of the three edges, the external (e) is
the sharpest, especially in the middle ; it commences above, below a small ar-
ticular surface, the lesser sigmoid cavity, and is effaced at the lower part of the
bone. It gives attachment to the interosseous ligament, a sort of fibrous mem-
brane stretched between the radius and ulna. The anterior edge {n fm) is blunt,
and is intended for muscular insertions ; towards its lower part it bends slight-
ly forward, becomes rough, and terminates in front of a pointed eminence
called the styloid process (m) : it commences above by a very marked projec-
tion (w) on the inside of an eminence named the coronoid process of the ulna.
The posterior edge commences below the olecranon by a bifurcated extremity ;
it terminates insensibly towards the lower fourth of the bone ; this edge may be felt be-
neath the skin throughout its whole extent.
The superior or humeral extremity (J) of the ulna presents a considerable enlargement ;
it is hollowed in front into a hook-hke cavity, which articulates with the trochlea of the
humerus, to the shape of which it is adapted. This cavity, which forms almost half the
circumference of a circle, is called the great sigmoid cavity (fi g h) of the ulna, because it
has been compared to the letter sigma of the Greek alphabet. It has a vertical branch,
which forms the olecranon process (6), and a horizontal one named the coronoid process (/«).
There is a sort of constriction at the place (g) where these two branches meet ; this is
the weakest point of the upper end of the ulna, and is, consequently, the almost invariable
seat of fractures of the olecranon. The olecranon (i), so named from uMvrj, the elbow,
and Kpuvov, the head, because it constitutes the most prominent part, or head of the elbow,
presents, 1. A posterior surface, smooth above, and rough and irregular below, where it
gives insertion to the triceps ; 2. An anterior or articular surface, concave, divided by a
vertical ridge into two lateral parts of unequal magnitude ; this is articulated to the troch-
lear surface of the humerus ; 3. Two borders, more or less rough in different subjects,
which afford attachments to the triceps muscle ; 4. A base, with the constriction we have
before described ; 5. The summit, having the form of a curved beak, which is received into
the olecranal cavity of the humerus during extension of the forearm.
The horizontal branch of the sigmoid cavity, or the coronoid process Qi), presents, 1. A
rough inferior surface (i), on which the brachiahs anticus muscle is inserted ; 2. A supe-
rior surface divided into two unequal parts by a ridge, which is a continuation of that
which divides the articular surface of the olecranon ; 3. An internal rough edge (n), bent
inward, and giving insertion to the internal lateral ligament of the elbow-joint ; 4. An
external edge marked by a smaU cavity, which is oblong from before backward, and
slightly concave in the same direction, and is called the lesser sigmoid cavity (Jc) of the
ulna, to which the head of the radius is articulated ; below this small cavity is a rough,
triangular, and deeply excavated surface, to which the supinator brevis muscle is attach-
ed ; 5. An anterior sinuous edge, with a projection or beak, which is received into the
coronoid cavity of the humerus during flexion of the forearm.
The lower extremity of the ulna presents a small rounded enlargement (c), which has
been called the head of the ulna. We observe on the outside an articular facette (Z), con-
-vex, and elongated from before backward, which is received into a corresponding con-
cave surface on the lower extremity of the radius. On the inner side of this head a
vertical cylindrical process arises, called styloid process of the ulna (m), the point of which
gives attachment to the internal lateral ligament of the wrist-joint. The head of the
ulna presents below a smooth surface, which articulates with the cuneiform bone, a
movable fibro-cartilage being interposed ; it is separated from the styloid process behind
by a groove for the passage of a tendon, and on the inside by a sUght, irregular depres-
sion, to which the triangular fibro-cartilage is attached.
Connexions. — The ulna articulates with the humerus, the radius, and the cuneiform
bone.
Internal Structure. — The shaft of the ulna is compact ; the two extremities are cellu-
lar, especially the upper, the olecranon process of which resembles a short bone, both
THE RADIUS. 81
in form and stmctuvo. Sometimes, even, as Rosenmullcr has observed, this process
constitutes really a short bone, entirely separated from the ulna.
Development. — The ulna is developed from three points ; one for the shaft, and one for
each extremity. The osseous point of the body appears first from the thirty-fifth to the
fortieth day, or a little later than that of the humeiiis. At birth, the extremities are
entirely cartilaginous ; they do not begin to ossify untQ the sixth year, the lower one
having the priority. The coronoid process is formed by extension of the ossific point
of the shaft. The nodule of the olecranon appears about the seventh or eighth year.
The upper extremity is united to the shaft from the fifteenth to the sixteenth year ; the
lower, from the eighteenth to the twentieth year.
The Radius {fig. 45).
The raiius, so named because it has been compared to the spoke of a wheel, is situa-
ted between the hiunerus and the carpus, on the outside of the ulna, to which ^^ ^j
it is contiguous above and below, and from which it is separated in the mid- ' „|
die by the interosseous space. It is somewhat smaller and shorter than the
ulna, and has a vertical direction. It is a long and asyiiunetrical bone, pris-
matic and triangular in its shape ; its lower end is the larger, and its shaft is
slightly curved ; it consists of a shaft and extremities.
The shaft (o), smaller above than below, presents a slight curvature with
the concavity looking inward : this circumstance increases the distance be-
tween the radius and ulna, i. e., the interosseous space. It has three surfa-
ces, an anterior, a posterior, and an external, and three edges. The anterior
surface (o), narrow above and broad below, presents (above o) the orifice of
the nutritious canal, which, like that of the ulna, runs upward, or in an oppo-
site direction to that of the humerus. It is somewhat grooved, and gives at-
tachment to the flexor longus pollicis, and below to the pronator quadratus mus-
cles. The posterior surface, also slightly hollowed, gives attachment to sev-
eral of the deep-seated muscles on the back of the forearm. The external
surface, convex and rounded, is of equal breadth in almost its whole extent,
and presents near the middle a rough surface for the insertion of the prona-
tor teres.
Of the three edges, one is anterior, the other posterior, and the third inter-
nal : the anterior edge (t r s) is blunt superiorly ; it commences below a marked
projection, named the bicipit£d tuberosity, or tubercle of the radius {t) ; from
this point it passes obliquely outward, and terminates below, in front of an-
other eminence c£dled the styloid process (s) of the radius. The posterior edge, less
prominent than the anterior, forms a scarcely perceptible demarcation between the two
surfaces which it separates ; it is pretty well marked in the middle of the bone, but
hardly distinguishable above and below. The internal edge {t g) is sharp, and has the
appearance of a ridge ; it commences below the bicipital tuberosity, and extends to a
small articular cavity (^), on the inner side of the lower end of the bone. This edge
gives attachment to the interosseous ligament in its whole extent.
The superior or humeral extremity (m), called also the head of the radius, expands in
form of a shallow but regularly-shaped cup, the cavity corresponding with the small head
of the humerus, which it partially receives. It is bounded by a circular border with a ver-
tical articular surface (»), varying in breadth in different points, being nearly three lines
broad on the inside, where it is in contact with the lesser sigmoid cavity of the ulna. The
head of the radius is supported by a constricted portion, or neck {w), of a cylindrical
form, and five or six lines in length, which is obhquely directed from above downward,
and from without inward. At the junction of the neck and body of the radius, on the
inside, we see a very marked process, called bicipital tuberosity (t). Its posterior half is
rough, where it gives attachment to the tendon of the biceps ; the anterior is smooth,
and the tendon of the biceps glides over it before reaching its point of insertion.
The inferior or carpal extremity {x), which is the largest part of the radius, is irregu-
larly quadrilateral. Its lower surface is articular, smooth, concave, irregularly triangu-
lar, and divided by a small antero-posterior ridge into two parts : an internal, which ar-
ticulates with the semilunar bone of the Avrist, and an external, which articulates with
the scaphoid. In the outside of this surface we observe a pyramidal, triangular pro-
cess, slightly bent outward ; this is the styloid process (s) of the radius, shorter and much
thicker than the styloid process of the ulna, and, like it, giving attachment to one of the
lateral ligaments of the wrist-joint. The circumference of this end of the bone exhibits
in front some inequcdities, to which the anterior ligament of the wrist is attached ; Se-
hind and on th« outside, it is marked by the following tendinous grooves, viz., proceed-
ing from without inward, 1. An oblique groove on the external surface of the styloid pro-
cess, which shows the trace of a longitudinal division marking out two secondary fur-
rows. 2. A groove bounded by projecting edges, and subdivided into two secondary
ones by a longitudinal ridge, less elevated than the lateral border. 3. A somewhat deep-
Li
6s OSTEOLOGY.
er groove, also divided into two secondary furrows of unequal dimensions by a ver3f
prominent line.*
On the inside (g-), the lower end of the radius is slightly excavated, to articulate witii
the carpal extremity of the ulna.
Connexion. — ^The radius articulates with the humerus, the ulna, the scaphoid, and
semilunar bones.
Internal Structure. — The two extremities of the radius are cellular, and are covered by
a very brittle layer of compact tissue : this is more remarkably the case at the lowei
part of the bone, where fractures most usually occur. The shaft is almost entirely form-
ed of compact tissue, and has a very narrow medullary canal.
Development. — The radius is developed from three points, one for the body, and oi «j
for each extremity. The osseous point of the body appears some days before that of
the ulna : the lower extremity is developed about the second year ; the upper, at nine
years. The upper extremity, which is last in beginning to ossify, becomes united to the
body of the bone about the twelfth year, while the lower extremity is not joined until
from the eighteenth to the twentieth year.
The Hand {fig. 46).
The hand is the last part of the upper extremity. Accustomed as we are to admire
jvo- 46. the beautiful and perfect organization of the different parts
of the animal body, we are impressed with the most profound
admiration when examining the mechanism of the hand.
The organ of touch and prehension, perfoiining functions the
most opposite ; those demanding great force, and those re-
quiring the greatest delicacy. To enable it to fulfil at the
same time functions so different, great solidity and great mo-
bility were essential ; and to secure these conditions, it was
necessary that it should be formed of a great number of
bones. It is composed of twenty-seven bones, exclusive of
the sesamoid bones. The hand exists only in man and in
the ape ; and its importance is so great, that it has been con-
sidered by naturalists as establishing a fundamental charac-
ter of the species. Man alone constitutes the class of bima-
na ; the apes form the class quadrumana : but in the hand
of the ape, compared with that of man, we find great infe-
riority. Let us, then, study with the attention it merits this
chef-d'auvre of mechanism, which some of the philosophers
of antiquity regarded as the distinctive character of man,
and even as the source of his intellectual superiority.
"Fae hand, considered as part of the skeleton, is composed of five series of small col-
umns. Each series consists of four pieces, excepting the outer one, which has three
only. The five series of colmnns converge so as to unite with a bony mass, composed
of eight bones (a to i) articulated together, and forming by their junction the base of the
hand or the wrist. This bony mass is called the carpus. The five columns {k k), next
the carpus, have received the name of metacarpal bones ; by their union they form the
metacarpus, which corresponds with the palm of the hand : lastly, the columns which
succeed to the metacarpus form appendages which are entirely isolated and independent
of each other ; these are the fingers, which are distinguished by numerical names of
first, second, third, fourth, and fifth, counting from without inward, the hand being su-
pine, and the palm turned forward ; they are also known by the following appellations :
thumb, index or indicator, middle, ring, and auricular or little finger. Each finger is composed
of three small bones, called phalanges {I m n), distinguished also successively, from above
downward, by the numerical names of first, second, and third. The third bears also the
name of ungual, because it supports the nail ; the thumb has only two phalanges {I n) ;
it is also distinguished from the other fingers, by being on a plane anterior to them.
The form of the hand leads us to consider separately a dorsal, convex surface, the
haah of the hand ; an anterior or palmar surface, the palm {fig. 46) ; an external or radial
edge {a n), formed by the thumb ; an internal or ulnar edge (c n), formed by the little
finger ; a superior, carpal, or anti-brachial extremity ; and an inferior or digital extrem •
ity, composed by the ends of the fingers, which, from their unequal length, form a curve
wifcli the convexity downward.
The natural attitude of the hand is that of pronation, i. e., the attitude in which it is
placed when the bones of the forearm, instead of being parallel as in supination, are
crossed in. puch a manner that the lower part of the radius is in front of the ulna. The
* In.the descriptiqa of the muscles, we shall point out the tendon which occupies each of there primitive
and secondary grooves. All enumerations of this kind, the advantages of which we do not dispute, when the
bones and muscles are already known, will find a place in the table at the end of the part devoted to myology.
We have noticed liere the muscular insertions, because, instead of burdening the memory, they are useful in
fixing the attention uppn tie objects described.
THE CARPUS. 83
hand is in this position when laying hold of anything, or exercising ihe sense of touch
It is only for the convenience of description that we shall suppose the hand to be in the
state of supination, and the palm turned forward. We shall be obliged to return to pro-
nation, when we draw a parallel between the hand and the foot.
The axis of the hand is ahnost the same as that of the fore2irm.
The Carpus {a to f, Jig. 46.)
The carpus (from Kapirdc, wrist, Kup-KSLv, to lay hold of) constitutes the bony structure
of the wrist ; it is of an oblong form, and almost elliptical transversely. The anterior
surface {fig. 46) is concave, and forms a deep groove, in which the tendons of the flexor
muscles are lodged. The posterior surface is convex, and in contact with the extensor
tendons. They are both traversed by waved lines, which indicate the numerous artic-
ulations of the component bones. The upper border is convex, and articulates with the
radius and ulna ; the lower is irregular and sinuous, and articulates with the metacarpal
hones.
At each of the two extremities of the ellipse represented by the carpus, we observe
two eminences, which form a projection on the anterior aspect, and contribute to aug-
ment the depth of the groove which it forms. The two which occupy the outer edge of
the wrist are much smaller than those which are situated on its inner border.
The structure of the carpus is remarkable in this respect ; that in proportion to its
size, it presents in a given space a much greater number of bones than any other part
of the skeleton. It consists, in fact, of eight bones, and is scarcely one inch in height,
and two inches and a half in breadth. These eight bones are arranged in two series, or
rows ; an upper proximal or anti-hrachial {ah c d), and a lotcer distal or metacarpal {e i g f).
Each of these ranges is composed of four bones ; counting from the external or radial
edge towards the internal or ulnar, they are, in the first row, the scaphoid {a), the semi-
lunar (i), the cuneiform (c), (or pyramidal), and the pisiform {d) ; in the second row, tra-
pezium (e), the trapezoid {i), the os magnum (g), and the unciforme (/).
I shall not occupy time in describing successively the six surfaces on each of these
bones. By simply explaining the law which regulates their configuration, I shall have
the double advantage of avoiding prolixity, and of enabhng the student to understand
more correctly both their forms and relations.
Bones of the first or Anti-brachial Range.
What I have just said of these bones does not apply to the pisiform, which is distin-
guished from all the others by particular characters, and merits a special notice. With
regard to the rest,* viz., the scaphoid {a), the semilunar {h), and the cuneiform (c), it may
be remarked, 1. That they articulate by their upper surfaces with the forearm, forming
a sort of interrupted condyle, i. e., one consisting of several pieces, which is received
into the cavity formed by the lower end of the radius and ulna. Each of the bones con-
tributes to form this condyle, by means of a convex surface ; consequently, the superior
surface of the bones of the first rank is articular and convex. 2. They articulate by their
lower surfaces with the bones of the second rank, which on the inside oppose to them a
large head formed by the os magnum and unciform, and on the outside a shallow con-
cavity, which corresponds to the trapezium and the trapezoid. In accordance with this,
the lower surface of the first row presents on the one hand a concavity, which receives
the head, and on the other a convexity, which corresponds to the cavity.
Three surfaces, belonging to the scaphoid, the semilunar, and the cuneiform, unite to
form the cavity, which receives the head belonging to the second row. There is, there-
fore, a broken cavity, i. e., one formed of several pieces. The scaphoid being the largest
of the bones of the first row, and corresponding by itself to the most convex part of the
head of the second row, is more deeply excavated than the two other bones ; this has
given it the form of a boat, whence the name of scaphoid (<7«a0^, a boat). The semilu-
nar, which corresponds to the summit of the head, presents from before backward a con-
cavity, which has given it its name ; the cuneiform, on the contrary, corresponds to the
least convex part of the articular head, and has an almost plane surface. »
One bone only, the scaphoid, answers to the concavity formed by the trapezium and
trapezoides, and it accordingly presents a convex surface at the point of union. There-
fore the lower surfaces of the bones of the first row are concave, and the lower surface of the
scaphoid is partly concave and partly convex.
3. The bones of the first row of the carpus unite with each other by plane surfaces ;
those of the scaphoid and semilunar, which join, are very small ; the contiguous surfa-
ces of the semilunar and the cuneiform are much larger.
The semilunar and the cuneiform, which occupy the middle of the row, articulate not
only with each other, but also with the scaphoid and the pisiform ; and each, therefore, has
two lateral surfaces, so that the two middle bones of the row have four artitular facettes.
* It is neces.sary, in order to follow this description, and obtain from it all the advantage wkich it can afford,
to study at the same time an articulated carpus, especially one in which the joints are exposed behind, soma
ligaments remaining in front.
"^
OSTEOLOGY.
The scaphoid, which is the outer bone of the first row, articulates internally witn th(6
semilunar, but externally it has a projecting process, which may be easily felt under the
skin, and which increases the depth of the anterior groove of the carpus. This eminence
constitutes the external superior process of the carpus. 4. The bones of the first row
forming part of the concavity in front, and of the convexity behind, have their anterior
surfaces much smaller than their posterior ; both are rough, and serve for the insertion
of ligaments.
The pisiform (d) is not in the same rank, and has only one articular surface, which
unites with the corresponding surface on the cuneiform. The whole of the rest of its
surface is intended for the insertion of ligaments and tendons. Its name is derived from
its irregularly rounded form. It is placed on a plane anterior to that of the other bones of
the first row, and forms the internal superior process, which is the most prominent and
the most superficial of aU the processes of the carpus. The pisiform receives above the
insertion of the flexor carpi ulnari^ and below allows of the origin of the abductor minimi
digiti. It might with propriety be considered as a sesamoid bone.
Bones of the Second or Metacarpal Row.
The bones of the second row are much larger than those of the first ; they form, in
fact, the support of the metacarpus. In the first row, the outer bone, namely, the sca-
phoid, is the larger ; in the second, the two inner bones, viz., the os magnum (g) and
unciform (f).
Superior Surfaces. — We have already stated, that the surface of the second row, which
articulates with the first, presents a head and a cavity. The head is formed almost en-
tirely by a spheroidal eminence, named head of the os magnum ; this is supported by a
(Constricted portion, or neck, below which is the body, the largest part of the bone ; this
head of the os magnum is truncated at its inner part, and appears to be completed by a
portion of the os unciforme. The concavity presented by the bones of the second row
is constituted by two bones, the trapezium (c), situated on the outside of the carpus, and
the trapezoid (i), placed between the trapezium and os magnum.
The inferior surfaces correspond to the bones of the metacarpus. Taken together,
these surfaces form a sinuous and angular line, which by itself would seem to prove the
impossibility of dislocation of the metacarpus. The trapezium supports the first meta-
carpal bone ; the trapezoid the second ; the os magnum the third ; and the os unciforme
the fourth and fifth metacarpal bones.
The posterior surfaces of the bones of the second row form part of the convexity of the
carpus ; the anterior surfaces are narrower, and correspond with its concavity. There
is a process on the anterior aspect at each extremity of the second row ; the internal be-
longs to the unciform bone, and resembles a hook, the concavity of which looks outward,
and corresponds with the flexor tendons ; the external belongs to the trapezium, and
forms a much less prominent hook than that of the unciform ; on its inside there is a
deep oblique groove for the passage of the tendon of the flexor carpi radialis, and it forms
the external inferior process of the carpus.
Lateral Surfaces. — The bones of the second row are joined together by broad plane
surfaces, partly articular and partly non-articular. The two middle bones, viz., the tra-
pezoid and the os magnum, have each two lateral articular surfaces, inasmuch as they
are articulated with each other, and since the os magnum is united to the unciform, and
the trapezoid to the trapezium. The extreme bones of this row have only one side ar-
ticular. Each of the middle bones, therefore, has four articular surfaces, a superior, an in-
ferior, and two lateral ; each of the extreme bones a superior, an inferior, and one lateral
Development of the Carpal Bones.
All the bones of the carpus, without exception, are developed from single points. The
ossific points appear very slowly ; all the bones are cartilaginous at birth. Towards the
end of the first year, the cartilages of the os magnum and the unciform show a bony
point in the centre. The osseous point of the cuneiform appears from the third to the
fourth year ; those of the trapezium and semilunar, from the fourth to the fifth ; and
those of the scaphoid and the trapezoid, from the eighth to the ninth year. The pisiform
does not become ossified until from the twelfth to the fifteenth year ; in fact, it is the
latest to ossify of all the bones of the skeleton.
The Metacarpus (k k\ Jig. 46).
The five bony columns which rest upon the carpus form the metacarpus ; they are long
bones placed parallel to each other, and constructed on the same model, with very slight
differences. Together they form a sort of square grating, the intervals of which are
larger, on account of the disproportion existing between the size of the middle part and
the ends of these bones. These intervals are denominated interosseous spaces, and are
occupied by muscles.
The metacarpal bones are five in number, distinguished by the names of first, second,
&c. They are not perfectly uniform, either in situation, length, or shape. The meta-
GENERAL CHARACTERS OF THE METACARPAL BONES. 86
carpal bone of the thumb, for instance, is situated upon a plane anterior to that which
the others occupy ; instead of being parallel, it is directed obliquely outward and do\vn-
ward, and hence the interosseous space between it and the second metacarpal bone is
triangular.
This arrangement is connected with the movement of opposition, which is the char-
acteristic feature of the hand. The metacarpus presents a palmar or anterior surface.
concave transversely, and slightly so from above downward, which corresponds with the
falm. of the hand ; a dorsal convex surface, the hack of the hand ; an external or radial edo-e,
which is short, obliquely directed outward and downward, and corresponds to the thumb ;
an ulnar edge, short and straight, which corresponds with the little finger ; a superior'or
carpal extremity, which presents a very sinuous articular line, to fit the opposite surface of
the carpus ; and an inferior or digital extremity, formed by five heads, or, rather, condyles,
flattened on the sides, and intended to articulate with the corresponding fingers : this
lower d^tremity forms a broken articular line ; it is curved, with the convexity doAvn-
ward, and the first metacarpal bone does not appear to belong to it.
General Characters of the Metacarpal Bones.
The metacarpal bones belong to the class of long bones, having the same form and
structure ; each consists of a hody and two extremities.
The hody is prismatic and triangular, and slightly curved, so as to present a concavity
on the palmar, and a convexity on the dorsal aspect. Of the three surfaces of the body,
two are lateral, and correspond to the interosseous spaces ; the third is on the back of
the hand, and is covered by the tendons of the extensor muscles. Of the edges, two are
lateral ; the third is anterior, and corresponds with the palm of the hand.
The upper or carpal extremity is large, and has five surfaces, an anterior and a poste-
rior, for ligamentous insertions, and three articular ; of the three articular surfaces, one
is at the end of the bone, and unites with a corresponding surface on a carpal bone ; the
two others occupy the sides of the extremity, and unite with corresponding surfaces of
the adjoining metacarpal bones. In some metacarpal bones, the lateral facettes are
double on each side. It is necessary to distinguish such of these lateral facettes as are
intended to unite with bones of the carpus, between which one of the metacarpal bones
is, as it were, wedged, from those which are exclusively intended for the articulation of
the metacarpal bones with each other.
The lower or digital extremity resembles a head flattened on the sides, or a condyle ob-
long from before backward, with an articular surface of greater extent on the palmar
than on the dorsal aspect, i. c, admitting of greater flexion than extension ; it is marked
both internally and externally by a depression, behind which is a rough projection for
the attachment of lateral hgaments.
Are there any peculiar characters by which the different metacarpal bones may be
distinguished 1 This question we shall now examine.
Differential Characters of the Metacarpal Bones.
The first metacarpal bone (t) is distinguished from the others by the following char-
acters : it is the shortest and the largest ; its body is flattened in front and behind
like the phalanges ; so that at times it has been looked upon as one of those bones.
We shall regard it as belonging to the metacarpus, because it is not only united to the
other metacarpal bones by the interosseous muscles, but its inferior or digital extremity
also has an exact resemblance. At the same time, we must acknowledge that there is
a circumstance in its development which tends to establish its analogy with the pha-
fanges. The carpal extremity of the first metacarpal bone has a particular form ; it is
concave from before backward, and convex transversely, for articulation with the cor-
responding surface on the trapezium. The characteristic marks, then, by which the first
metacarpal bone may be recognised, are, its shortness, its greater size, the antero-postenor
flattening of the hody, the upper articular surface concave and convex in opposite directions.
and the absence of lateral articular facettes.
There are many distinguishing characters of the second, third, and fourth metacarpal
bones. I shall content myself with saying, that the second and third are known by
their greater length, for they exceed the fourth by the whole of their lower extremity ;
they are also about a third larger, and heavier.
The third metacarpal bone is distinguished from the second by its greater size, and,
accordingly, it gives attachment to one of the most powerful muscles of the hand, the
adductor pollicis ; it is also known by having two lateral facettes on its upper extremity,
while the second has only one.
The fifth metacarpal bone (k) is the shortest of all, excepting the first, from which it
is distinguished by its smaller size. It differs from the fourth, which it most resembles,
1. By its shortness. 2. By the presence of an articular facette only on one side of its
carpal extremity. 3. By the existence of a very projecting eminence on its inner side,
for the insertion of the extensor carpi ulnaris muscle.
m
OSTEOLOGY.
Connexions. — The metacarpal bones articulate with each other, with the bones of the
carpus, and with the first phalanges of the corresponding fingers.
Internal Structure. — They have the same structure as other long bones : their extrem-
ities are cellular, and the shafts compact, with a small medullary canal.
Development. — Each metacarpal bone is developed from two points ; one for the body
and superior extremity, and one for the lower or distal extremity. The first metacarpal
bone, which in many respects resembles the phalanges, is similar also in its mode of
development. One of its two points appears in the shaft ; the other in the upper or
carpal extremity, which is the reverse of what takes place in the other bones of the
same denomination, and is analogous to that of the phjdanges. The ossific point of the
body of the metacarpal bone appears from the fortieth to the fiftieth day of fcetal life.
At birth the body is almost completely ossified, but the extremities are still cartilaginous.
The bony points of the lower ends of the last four metacarpal bones, and of the upper
end of the first, do not make their appearance until the third or fourth year. In general,
the upper ends of the last four bones, and the lower end of the first, are ossified by an
extension of the shaft ; but I have occasionally seen separate germs for each of these,
so that every metacarpal bone had three osseous nodules. The union of the lower ex-
tremities with the bodies of the four metacarpal bones does not take place until the
eighteenth or twentieth year ; and the same is the case with the ossific point of the up-
per end of the first metacarpal bone. In those cases where the lower end of the first
metacarpal, and the upper ends of the others, are formed from special points, their union
takes place at a much earlier period.
The Fingers {I m n, and I' n'yjig. 46).
The fingers are the essential organs of prehension, and for this purpose have a length
thickness, and mobility that are very remarkable, when we compare them with the toes,
which represent them in the lower extremity. Each finger forms a pyramid, composed
of three columns placed upon each other ; the base of the pyramid corresponds to the
metacarpus, and there are two enlargements or knots at the places where the columns
(named phalanges) unite together. The three columns which compose each finger suc-
cessively decrease in size, and are known by the numerical appellations of first, second,
and third. The first, which articulates with the metacarpus, is also called the metacarpal
phalanx (Z I') ; the second, the middle phalanx (m) ; and the third, which supports the nail,
the ungual phalanx {n n'). The thumb alone has only two phalanges, an ixngual and a
metacarpal. Chaussier has named the phalanges phalange, phalangine, and phalangette,
counting from the base to the ends of the fingers. These denominations he has found
very serviceable in the methodical designation of the muscles of the fingers.
The First Phalanx {I I').
The first phalanx belongs to the class of long bones, and presents to our notice, 1. A
body resembling a half cylinder, cut along its axis, and slightly curved upon itself, so as
to present a concavity in front ; the dorsal surface is cylindrical, and covered by the
tendons of the extensor muscles ; the anterior surface is slightly channelled for the par-
tial lodgment of the tendons of the flexor muscles ; its edges are sharp, and give attach
ment to a tendinous sheath, which converts the channel above mentioned into an osteo-
fibrous canal for the flexor tendons of the fingers. 2. An upper or mxtacarpal end, trans
versely oblong, and presenting a small glenoid cavity for the head of the corresponding
metacarpal bone. 3. A lower end, forming an articular pulley.
Such are the general characters of the first phalanx, but they are modified in each
finger. Thus, the phalanx of the middle finger is the longest ; those of the index and
ring finger come next. The first phalanx of the thiunb is the largest in proportion to its
length ; the first phalanx of the little finger is the most slender ; it is also the shortest,
excepting that of the thumb.
The Second Phalanx (m).
The second phalanx differs from the first by its smaller size and the shape of its up
per end, which forms two concave articular facettes, separated from each other by a
projecting line, which runs from before backward ; these are fitted to the trochlea on the
lower end of the first phalanx. The edges of this phalanx are thick and rough above,
where they give insertion to the tendon of the superficial flexor of the fingers.
The thumb has no second phalanx.
The Third Phalanx (n «').
This bone, to which so much importance has been attached in natural history,* sup-
ports the horny part with which the ends of the digits in animals are armed, and the
nails in man. It is shaped thus : the upper end is transversely oblong, exactly resem*
* See the interesting memoir of M. Dum6ril, entitled Dissertation sur la demiire Phalange dans Us Mam
ndfe.res ; the ungual phalanx presenting different forms, suited to the difterent instincts of the animal. Thi»
is BO remarkable, that, from its examination, the family to which the animal belonged may be ascertained.
THE PELVIS. gP
bling the upper end of the second phalanx ; from this part it contracts like a cone ; sifter-
ward it becomes much enlarged and flattened from before backward, and ends with the
shape of a horse-shoe, rough in front, where it supports the pulp of the finger, smooth
behind, and indented on the edges. The ungual phalanx of the thumb is much larger
than that of the other fingers ; that of the middle one is the next in size ; those of the
index and ring finger are almost equal, and that of the little finger is the smallest. It is
very difficult to distinguish the phalanges of the right from those of the left hand.
Development of the Phalanges.
The phalanges are developed from two points : one for the body and lower end, and
one for the upper end. This mode of development is common to the first, second, and
third phalanges. The osseous point of the body appears successively in the first, sec-
ond, and third phalanges, from the fortieth to the fiftieth day. The order of succession
is not subjected to any certain rules. Bony points are found at the same time in the
ungual and metacarpal phalanges, and prior to those of the middle phalanges. The os-
sific points of the upper ends of the phalanges appear successively in the first, second,
and third phalanges some time after birth, from the third to the seventh year. The
epiphysary point of the third phalanx is generally developed before that of the second.
The epiphyses do not join the bodies of the bones until from the eighteenth to the twen-
tieth year.
General Development of the Superior Extremity.
The thoracic limb in the foetus and the infant is remarkable for its dimensions, which
are proportionally much greater than in the adult. This early development and size are
particularly evident when compared with the slow development of the lower limb ; the
resulting disproportion is in an inverse ratio of the age, that is, it is greatest in early life.
The thoracic limb of the foetus differs from that of the adult in many other respects be-
sides dimensions. Thus, the two extremities of the humerus are proportionally much
larger, and altogether cartilaginous, though the difference does not appear to me so great
as has been imagined. The lower end of the bone is especially remarkable for the size
of the small head, which forms a very marked protuberance in front, and projects con-
siderably beyond the pulley or trochlea. In the forearm, the upper end of the radius is
situated much farther forward than in the adult, which agrees with the position of the
small head of the humerus. This circumstance merits careful notice, because it is one
of the predisposing causes of dislocation of the head of the radius forward, the ligament
which keeps it back being scarcely able to overcome its tendency in that direction. For
the same reason, displacements of the head of the radius are much more frequent in the
infant than in the adult.
The carpus, almost completely unossified at birth, is composed of the same number
of cartilages as there are bones afterward. The metacarpus, on the contrary, is ossified
long before birth, but this rapid development, common to the whole thoracic extremity,
is most remarkable in the phalanges.
Bichat appears to me to have greatly exaggerated the changes which take place in
these bones during the progress of age. I am certain that the torsion of the humerus,
and the curvatures of the radius and ulna, and also the interosseous space, exist equally
in the new-born infant as in the adult, and in almost the same proportions.
THE INFERIOR OR ABDOMINAL EXTREMITIES.
The Haunch. — Os Coxce. — The Pelvis. — Development. — Femur. — Patella. — Tibia. — Fibula.
— The Foot. — The Tarsus and Tarsal Bones. — The Metatarsus and Metatarsal Bones. —
The Toes. — Development of the Lower Extremities. — Comparison of the Upper and Lower
Extremities. — Os Hyoides.
The inferior or abdominal extremity is divided, like the superior, into four parts, viz.,
the haunch, the thigh, the leg, and the foot.
Of the Pelvis.
We have seen bony arches growing out from the sides of the dorsal portion of the ver-
tebral column, to form the thorax. In the same way there grows out from the sacral
portion of the column two large bones, which form the walls of the pelvic cavity. These
are the ossa innominata or haunch bones. The pelvis forms an appendix to the abdominal
cavity, and lodges and protects a number of important organs, viz., a portion of the or-
gans of digestion and of the urinary apparatus, and the whole of the internal organs of
generation, together with important vessels and nerves. The pelvis transmits to the
inferior extremities the weight it receives from the vertebral column. It is formed by
four bones, two of which placed behind on the median line, the sacrum and the coccyx,
we have already described ; the two placed on the sides, and extending forward to be
united on the median line before, the ossa innominata, we shall now examine.
88
OSTEOLOGY.
The Os Coxce, or Os Innominatum {figs. 47 and 48).
The haunch hone, called also os coxce, from coxa, the haunch, occupies the lateral and
anterior parts of the pelvis. It is the largest of all the broad bones of the skeleton. It
is asymmetrical, very irregular in its figure, and twisted upon itself, so that it appears to
be composed of two portions ; one superior, triangular, shaped like a wing, and flattened
from without inward ; the other inferior, and flattened from before backward. These
two parts are united by a contracted portion. On this bone we have for consideration
an external or femoral surface, which corresponds with the thigh, an internal or pehic
surface, and a circumference.
On the femoral surface (fig. 47) we observe the following parts : On the contracted
Fig. 47. portion, which unites the upper and the lower
half of the os coxae, is the cotyloid cavity {a. Jigs.
47, 48) (from Korvlrj, a cup), or acetabulum,
which receives the head of the femur. This is
of a hemispherical shape, and is the deepest of
\v all the articular cavities ; it looks obliquely
downward, outward, and a little forward, and
has a considerable depression (b, fig. 47) at the
bottom, on its inner aspect. The margin (c) of
this cavity is sharp and sinuous, and presents
three notches, or, rather, one notch and two slight
depressions, one of which is superior, and the
other inferior, and somewhat external. The
notch (d) is situated below and on the inside ; it
is very deep, and converted into a foramen by a
ligament, and gives passage to the vessels which
penetrate into the cotyloid cavity. Above and
below the acetabulum are two horizontal
grooves ; the upper one is superficial, and gives attachment to a fibrous expansion, one
of the origins of the rectus femoris ; the lower is deeper, and gives passage to the tendon
of the obturator externus. Above the cotyloid cavity, the os coxse presents a broad tri-
angular surface, improperly called external iliac fossa (c). On it we observe, proceeding
from behind forward, 1. A convexity : 2. A concavity, occupying about two thirds of the
fossa, and on which the principal nutritious foramina are situated : 3. A second convex-
ity : 4. A slight concavity.
The external iliac fossa is traversed by two curved lines for muscular insertions ; one
posterior, called the superior semicircular line (/) ; the other anterior, and much more
extensive, the inferior semicircular line (g). All the whole surface behind the former
gives attachment to the gluteus maximus : the portion comprised between the two lines
gives attachment to the gluteus medius.
Below the acetabulum we observe proceeding from without inward, 1. The obturator
foramen (h, figs. 47 and 48), improperly so called ; it is placed more internally than the
acetabulum, and has an oval form in the male (hence its name, foramen ovale) : in the
female it is smaller, and triangular. Its longest diameter is vertical, and it slopes a lit-
tle downward and outward. At its upper part is the obturator groove {i,fig. 48), directed
obliquely from behind forward and inward. It gives passage to vessels and nerves, and
has two lips : an anterior, which is continuous with the outer half of the circumference
of the foramen ; and a posterior, which is continuous with the internal half; for the two
halves of the circumference of the obturator foramen, instead of being united in front,
pass in different directions, the internal backward, and the external forward, leaving be-
tween them an interval which constitutes the groove. 2. On the inside of the obturator
foramen is a square surface (k, figs. 47 and 48), broader above than below, oblong in a
vertical direction, and rough for the insertion of several muscles of the thigh. This is
continuous below with another surface (/, fig. 47), broader inferiorly than above, which
extends obliquely downward and outward, then curves upward, and terminates below
the cotyloid cavity. This surface, which bounds the obturator foramen below, is intend-
ed for muscular insertions.
The internal or pelvic surface (fig. 48) of the os coxse is concave. It is divided into
two parts : a superior, w^hich looks upward, and an inferior, which looks backward, by a
prominent horizontal ridge (m n o, fig. 48), which forms the lower boundary of the in-
ternal iliac fossa. Above this ridge, which we shall afterward see forms the greatest
part of the inlet of the pelvis, we find, proceeding from behind forward, 1. A very prom-
inent and rough tuberosity (r), intended for several ligamentous attachments. 2. An ir-
regular eirticuiar surface, broader above than below, and called the auricular surface (s)
of the OS coxae, from a supposed resemblance to the concha of the ear ; it looks down-
ward and inward, and articulates with a corresponding surface on the sacrum. 3. More
anteriorly, and on a higher plane, a deep and regular excavation, correctly denominated
tne internal iliac fossa (t). This fossa, which is broad and smooth, is occupied by the
THE PELVIS. 89
iliacus muscle. At its lower part there is a nutritious foramen, which does not corre-
spond with that on the outside of the bone.
Below the horizontal ridge, which divides the internal surface of the os coxa; into two
halves, we observe, proceeding from without inward, and from behind forward, l.-A
smooth quadrilateral surface, broader above than below, slightly concave, and sloping
from above downward, inward, and forward : the front of this surface corresponds to the
depression at the bottom of the cotyloid cavity. 2. Behind this surface, a large notch,
which will be noticed when describing the circumference of the bone. 3. In front, the
inner opening of the obturator foramen, at the upper part of which is the commence-
ment of the groove already described. 4. Inside the foramen, a quadrilateral surface,
narrower below than above, where it forms a plane, sloping downward and backward,
which corresponds to the bladder. 5. Below the same foramen, a smooth surface.
The circumference of the os coxae is very irregular, and consists of a series of alter-
nate projections and notches. We shall describe four borders in this circumference ; a
superior, an inferior, an anterior, and a posterior.
The superior border or crest of the ilium {u v, figs. 47 and 48) is curved like the italic
letter iS ; it is directed from before backward, is rough, thick, and convex ; we shall de-
scribe it as having two lips and an interstice, that Ave may be able to point out with
precision the numerous muscular insertions of which it is the seat. It is not equally
thick in its whole extent ; the anterior extremity is thick, it is then contracted a little ;
about two inches behind this extremity it is considerably enlarged ; and still more pos-
teriorly there is a second enlargement even greater than the former. The inferior bar-
ber (w X y, fig. 47), which looks inward, is the shortest ; it commences at the most slo-
ping part of the os coxae by a large rough tuberosity, called tuberosity of the ischium (w x),
which gives attachment to almost all the muscles on the back of the thigh ; the weight
of the body rests upon it in the sitting posture. Proceeding from this tuberosity towards
the inner part of the os coxa3 (x y), tlie lower border becomes flexuous, irregular, and
shghtly twisted upon itself; it passes obliquely inward and upward, and contributes to
form the pubic arch (z y x, fig. 48). Above this oblique portion the border presents a
vertical elliptic surface, which unites with the corresponding surface on the opposite
bone, and forms the symphysis pubis (y y", figs. 47, 48). The lower border of tlie os coxae
consists, therefore, of two portions ; an oblique, which forms part of the arch, and a ver-
tical, which forms part of the symphysis.
The anterior border (u y', figs. 47, 48) commences at the anterior extremity of the crest
of the ilium by an eminence for muscular insertion, which can be always easily felt un-
der the skin ; it is the anterior superior spinous process of the ilium (m). Below is a notch
(m u'), which separates this process from another eminence for the insertion of the rec-
tus femoris ; it is caUed anterior inferior spinous process of the ilium {u'). Below this last
process is a notch or angular groove {uf n), over which the iliac muscle glides : on this
situation the anterior border changes its direction, and, from being vertical, becomes
horizontal. The horizontal portion of the anterior border presents then a smooth con-
cave surface inclined forward, and shaped like a triangle, with the base outward. This
triangular surface, which is covered by the pectineus muscle, presents, 1. An anterior
edge (*, fig. 48), continuous with the anterior lip of the obturator foramen. 2. A poste-
rior sharp edge, called crest of the pubes (**, figs. 47 and 48), a continuation of the hori-
zontal ridge, which we have described as forming the lower boundary of the internal
iliac fossa. 3. A base, presenting the cmincntia ileo-pectinea {n n), which corresponds to
the femoral artery, and upon which this vessel should be compressed, care being taken
to direct the force obliquely downward and backward, that is, perpendicularly to the sur-
face of the bone. 4. The summit of the triangle has a sharp eminence, which, in ema
ciated subjects, forms a marked projection under the skin. This eminence, called spine
of the pubes (o), gives attachment to the rectus abdominis, and must be distinguished
from the angle of the pubes (y'), which is a right angle formed by the meeting of the an-
terior and inferior borders.
The posterior border (v w, fig. 48) of the os coxaj commences at the posterior extremi-
ty of the crest of the ilium by a sharp eminence, named posterior and superior spinous
process of the ilium {v, figs. 47, 48) ; below is a notch, which separates it from another
eminence, the posterior inferior spinous process of the ilium {v'). Below this is a very
large notch, the sciatic notch of the coxa (v z, fig. 47), which contributes to form the great
sciatic notch, which we shall notice in the general description of the pelvis. This notch
is terminated below by a sharp ridge, called the sciatic spine (z) ; as this spine some-
times projects inward, can it, as some have imagined, press upon the foetal head when
it is clearing the lower outlet of the pelvis ] Between this spine and the tuberosity of
the ischium (r w ) is a small but well-marked groove, over which the tendon of the ob-
turator internus passes.
Internal Structure. — Like all broad bones, the haunch bone is composed of spongy sub-
stance contained between two laminae of compact tissue ; at the bottom of the acetabu-
lum, and in the double concavity of the iliac fossae, it is thin and semi-transparent ; it
is thick at the circumference, the crest of the ilium, the upper and back part of the ace»
M
dP OSTEOLOGY.
tabulum, the articular portion of the pubes, and more particularly at the tuberosity of
the ischium.
Cminr.xions. — The OS coxae unites with its fellow of the opposite side, with the sa-
crum, and with the femiir.
Development. — The os coxae is developed from three primitive, and five secondary
points of ossification. The three primitive points remain distinct until a very advanced
period, and therefore botli ancient and modern anatomists have incorrectly described
them as separate bones, under the names of ilium, ischium, and pubes. The ilium (1,
/iff. 48) comprehends the upper part of the acetabulum, and the broad, curved, and trian-
gular surface above it. The pubes (2) comprises, 1. The inner part of the acetabulimi.
2. The horizontal, prismatic, and triangular column that bounds the obturator foramen
above, and which is called the body of the pubes (/). 3. The vertical descending branch,
flattened in front and behind, which bounds the same foramen on the inside, and is call-
ed the descending ramus of the pubes (k, jigs. 47, 48).
The ischium (3, fig. 48) comprises, 1. The lower part of the acetabulum. 2. A verti-
cal column, very thick, prismatic, and triangular, which forms the tuberosity below, and
bounds the obturator foramen on the outside : this is the body of the ischium (/, figs. 47
and 48). 3. An ascending branch, sloping inward, flattened in front and behind, which
bounds the foramen below and on the inside, and joins the descending ramus of the
pubes ; this is the ascending ramus of the ischium (e, fig. 48). The limits of these three
pieces are marked before complete development by three cartilaginous hnes, united like
the letter Y, at the bottom of the cotyloid cavity (see fig. 48), which is the place where
the three primitive osseous points meet ; and this fact has contributed, in no small de-
gree, to establish that law of osteogeny which we noticed in our general remarks, viz.,
that when an articular cavity exists upon the surface of a bone which is developed from
several points, these points always unite in that cavity.
The following are the complementary points : 1. One at the bottom of the acetabulum,
pointed out by M. Serres,* and shaped like the letter Y ; 2. The marginal epiphysis,
which occupies and forms the entire length of the crest of the ilium ; 3. The epiphysis
of the tuberosity of the ischium, which stretches along the ascending ramus ; 4 and 5.
Two epiphyses, which do not seem constant ; one occupies the anterior and inferior spi-
nous process of the ilium ; the other, still more rare, occupies the angle of the pubes.
The ossification of the os coxae commences first in the ilium, in the ischium next, and
in the pubes last. The osseous germ of the ilium appears on the fiftieth day, that of the
iscliium at the end of the third month, and that of the pubes at the end of the fifth month.
At birth, the ossification of the os coxae is not far advanced ; the acetabulum is in a great
measure cartilaginous. The ascending ramus of the ischium, the descending ramus of
the pubes, and the entire circumference of the ilium, are also cartilaginous. These three
pieces are imited together from the thirteenth to the fifteenth year. At the same time,
the secondary points of ossification appear, and successively unite with the primitive.
This union is completed from the tenth to the twentieth year ; the epiphysis of the crest
of the ilium alone remains separate until the age of twenty-two, twenty-four, or even
twenty-five years.
The Pelvis in general.
The sacrum, the coccyx, and the haunch bones having now been described, we are
enabled to study the bony cavity which they concur in forming. It is called the pelvis
(fig. 48), and forms for the lower extremities an osseous girdle, analogous to that which
the shoulders form for the upper extremities. The pelvis or basin, so named because it
has been compared to a vase, is a large, irregular, bony cavity, open above and below,
which supports the vertebral column behind, and is itself supported by the thigh bones
on the sides and in front. In an adult of ordinary stature, tlie pelvis divides the body
into two equal parts. In the foetus the part of the body above the pelvis is much longer
than that below ; in adults of large stature, on the other hand, the part below is consid-
erably longer than that above.
The pelvis is symmetrical, but of a very irregular figure ; we may say, upon the whole,
that it forms a truncated cone, presenting, 1. An upper part or great pelvis, oval trans-
versely, much expanded on each side, and notched in front ; 2. A sort of contracted canal,
below this upper part, which is called the little pelvis. When the pelvis is examined in
the skeleton, it has not the horizontal position which it presents when resting on the
tuberosities of the ischium and the extremity of the coccyx. It is inclined with regard
to the axis of the body. The obliquity of the pelvis is not the same throughout, and we
have therefore to consider two axes, one for the great and one for the little pelvis. The
axis of the great pelvis is directed obliquely downward and backward, and is represented
by a line passing from the umbilicus towards the lower part of the curvature of the sa-
crum ; the axis of the little pelvis, on the contrary, is directed downward and forward,
* This point of ossification has been regarded as the vestige of a bone peculiar to marsupial animals, and
named marsupial bone ; but this view is incorrect, for, according to Cuvier, this fourth piece is found in mar-
supials themselves at the bottom of the cotyloid cavity, whereas the marsupial bone is a superadded portion
of the skeleton, which supports the pouch in these animals.
THE PELVIS IN GENERAL. 9t
and is represented by a line passing from the upper part of the curvatuie of the sacrum
through the centre of the lower opening or outlet of the pelvis. From the direction of
these two axes, it follows that the line of direction of the pelvis is a curve with the con-
cavity forward, and which is pretty correctly represented by the curvature of the ante-
rior surface of the sacrum. This sort of incurvation of the pelvis is an anatomical fact
of the greatest consequence, not only on account of the important office which this part
of the skeleton performs in the mechanism of standing, but also because, without an ac-
quaintance with it, it is impossible to understand the mechanism of natural labour, the
curved canal of the pelvis being the path which the infant has to traverse in passing out
of the cavity.
The obliquity of the pelvis varies at different ages and in different individuals : it is
pretty exactly measured by the prominence of the sacro-vertebral angle.
In the infant the pelvis deviates greatly from the horizontal direction ; its upper aper-
ture looks almost directly forward : in the adult it looks much more upward ; and in the
aged it again looks forward, as in the infant, but from a very different cause. In the
foetus the superior aperture is turned forward, even when the body is upright : at this
age the obliquity of the pelvis is inherent in its form ; but in the aged the pelvis looks
forward, because the trunk is curved in the same direction, and tends towards a hori-
zontal position as in quadrupeds. Thus in the foetus the pelvis has an obliquity which
depends on form ; in the aged the obliquity depends upon attitude.
The human pelvis is much larger than that of any other animal ; and this larger size
is connected with the important office it performs in maintaining the erect posture of
the trunk.
There is no part of the skeleton the form and dimensions of which so readily discrim-
inate the sex of the individual ; in the male the height predominates ; in the female the
breadth. By comparing the distance between the crests and the anterior and the pos-
terior spinous processes of the ilia, and between the obturator foramina, in the two sex-
es, we find that the transverse dimensions are much greater in the female ; the same is
observed in the antero-posterior dimensions, which may be easily proved by measuring
the distance between the symphysis pubis and the sacro-vertebral angle, and the dis-
tance between each obturator foramen and the sacro-iliac symphysis on the opposite
side. We shoidd add that, in the female, 1. The iliac fossae are larger, and turned more
outward than in the male ; hence the prominence of the hips. 2. The crest of the ilium
is not so much twisted in form of the italic S. 3. The interval between the symphysis
pubis and the acetabulum is greater ; this is partly the cause of the great prominence of
the trochanters, and the separation of the femora, which gives the female a peculiar gait
in walking. 4. The superior strait or brim is wider in every direction. 5. The tuber-
osities of the ischia are more separated, and the symphysis pubis is not so deep. 6. The
obturator foramen is triangular. 7. The arch of the pubis is rounded, wider, and more
curved, while in the male it is triangular and narrower. 8. The inner edges of the ascend-
ing rami of the ischia are prominent, and look less directly downward than in the male.
Such are the differences of the pelvis as regards sex ; we see that, for the most part,
they may be comprehended in the following proposition :
The female pelvis exceeds the male in its horizontal diameters ; the male pelvis exceeds the
femxde in its vertical diameters.
Regions of the Pelvis.
Under this title we shall examine in succession the external and internal surface of
the pelvis, the upper circumference or base, and the lower circumference or summit.
The external surface of the pelvis must be examined in front, behind, and on the sides.
Anterior Region. — 1. In the median line we observe the symphysis pubis (y y,Jig. 48),
varying from fifteen to eighteen or twenty pig. 49.
lines in length, always longer in the male,
and resembling a vertical column. It is ob-
liquely directed downward and backward,
which direction is peculiar to man; in all
other animals, as Cuvier has remarked, it is
placed horizontally. 2. On each side we find
the descending ramus of the pubes (k), which
is irregularly quadrilateral, and gives attach-
ment to several muscles. 3. Outside the pu-
bic column there is, on each side, the obtu-
rator foramen (A).
Posterior Region. — On this we observe, 1,
the ridge of the sacnim in the median line ;
2, and on each side the sacral grooves into
which the posterior sacral foramina open ; they are much deepened above, because the
back part of the ilium projects behind the sacrum : we find here, also, two ranges of
eminences, corresponding to the articular and transverse processes, and likewise the
back of the sacro-iliac articulation.
«g OSTEOLOGY.
Each lateral region is formed by the external iliac fossa, the acetabulum, and a con-
siderable portion of the body of the ischium below this cavity.
The internal surface of the pelvis is divided into two parts : an upper, which is much
expanded, and constitutes the great or false pelvis ; and a lower, more contracted, named
the small or true pelvis. These two portions of the same cavity are separated by a cir-
cular prominence, formed in a great measure by the horizontal ridge (m n o), which we
have described as constituting the lower boundary of the internal iliac fossae. The
whole space circumscribed by this line has been named the brim, superior orifice, or supe-
rior strait of the pelvis.
The great pelvis presents, 1. In front, an extensive notch (m y' u) ; 2. Behind, the sacro-
vertehral angle ox promontory of the sacrum (below d) ; 3. And on the sides, the internal iliac
fossae (1 and t), which form an inclined plane on each side, fitted to direct the weight
of the viscera which rest upon them, inward and forward.
The small pelvis is a cavity, the apertures of which are contracted, and therefore na-
med straits, and the middle portion is expanded, and called excavation.
We shall, therefore, examine separately its superior opening or upper strait, its infe-
rior opening or lower strait, and its middle portion or excavation.
The superior strait or brim is irregularly circular, and has been compared to an oval,
an ellipse, or a curvilinear triangle ; but none of these descriptions can give any correct
idea of its shape. The circumference, commencing behind, at the articulation between
the sacrum and the fifth lumbar vertebra, is formed by the projection of the anterior
edge {g d) of the base of the sacrum, by the horizontal ridge (m n),'on the inner surface
of the iliac bones, by the pectineal line (w o), and terminates in the spine of the pubes (o).
The superior strait has four diameters, an antero-posterior, a transverse, and two oblique.
The antero-posterior or sacro-pubic diameter (d y) is generally four inches in length ; the
transverse (m m), which is the longest, is five inches ; and the two oblique {n g), which
are measured from the eminentia ilio-pectinea on one side, to the sacro-iliac symphysis
on the other, are four inches and a half These measures are taken from a well-form-
ed female pelvis, and it is chiefly in the female that they are important, on account of
their reference to the process of parturition. In the male, all the diameters of the upper
strait are smaller.
The inferior or perineal strait, inferior orifice or outlet of the small pelvis, presents three
deep notches separated by three eminences, so that when the pelvis is placed upon a
horizontal plane, it appears to rest, as it were, upon three feet. Of these notches, one is
anterior, viz., the arch of the pubes {x y x); the others are lateral, and somewhat poste-
rior ; they are the ischiatic notches («' z, fig. 47). The arch of the pubes is angular in the
male, but rounded in the female, forming a true arch, which receives the occipital bone
of the foetus in the great majority of labours ; it is formed on each side by the ascend-
ing ramus of the ischium, the edge of which is somewhat everted, so that the head of
the foetus when passing under the arch glides over a sort of inclined plane, instead of
being in contact with the edge of the bone. The transverse diameter of the pubic arch
near the upper part has been calculated at one inch ; that of the lower part {x x, fig. 48),
at three inches. The two lateral notches are formed behind by the sacrum and the
cocc)rx ; in front, by the sciatic notch of the os innominatum ; they are therefore called
also the sacro-sciatic notches. They are very deep, and reach almost to the superior
strait of the small pelvis. Of the three emineiwes which separate the notches, the poste-
rior is formed by the coccyx, and the two anterior by the tuberosities of the ischia, which
are situated on a lower plane than the first ; from this peculiar arrangement, the whole
weight of the body, in the sitting posture, rests upon the tuberosities of the ischia, and
not at all upon the point of the coccyx. The diameters of the lower aperture of the
pelvis are, in reference to parturition, of equal importance with those of the upper, and
have been accurately determined. The antero-posterior diameter, or cocci-pubic, so called
because it extends from the symphysis pubis to the point of the coccyx, is four inches,
but may be increased to four inches and a half by depression of the coccyx. The trans-
verse or bisciatic diameter, which stretches between the tuberosities of the ischia, is four
inches, which is invariable ; and, lastly, the two oblique diameters, which extend from the
middle of the sacro-sciatic ligament on one side to the tuberosity of the ischium on the
other, are also four inches each. These dimensions, which are taken from a well-formed
female pelvis, are greater than in the male.
Excavation. — The excavation or cavity of the true pelvis is formed, 1 . Behind, by the
sacrum and coccyx, the concavity of which varies in different individuals, but is gener-
ally shallower in the female than in the male. The height of these two bones is four
inches and a half; the greatest depth of their concavity from ten to twelve lines. 2. In
front, by the symphysis and back part of the pubes, forming a plane inclined downward
and backward ; outside the pubes is the inner opening of the obturator foramen. 3. On
the sides, the excavation is formed by two smooth planes inclined downward and in-
ward ; they are about three inches and a half in height, and are bounded behind by the
sciatic notch.
It is of great consequence to notice these two inclined planes, because they perform
THE FEMUR. ffj
an importcint part in the mechanism of parturition. The diameters of the excavation
being of little value in an anatomical point of view, the student is referred to works on
midwifery for an account of them.
The superior circumference or base of the pelvis looks forward, and is formed behind by
the sacro- vertebral angle ; on each side by the upper border of the ilium, and in front by
the anterior border of the same bone. It presents, 1 . In front, a vast notch {u u, fig. 48),
in which we observe in the median line the upper part of the symphysis pubis («') ; on
each side, proceeding from within outward, the spine of the pubes (o), the pectineal sur-
face (o n), the ilio-pectineal eminence (« w), and the angular groove for the psoas and
iliacus muscles (n u"). In all this extent the notch is horizontal, but beyond the groove
it slants obliquely upward and outward, to the anterior superior spinous process of the
ilium (u), where it terminates. 2. Behind, the great circumference of the pelvis presents
the sacro-vertebral angle, and on each side a small notch between the vertebral column
and the back of the crest of the ilium. 3. Laterally, we observe the crest of the ilium
(m v), bent much more outward in the female than in the male.
The dimensions of the upper circmnference of the pelvis, measured in a well-formea
female, are the following : 1. Between the anterior superior spines of the ilia, from eight
to nine inches. 2. From the middle of the crest of one ilium to that of the other, from
nine to ten inches.
The inferior circumference of the pelvis forms the lower strait, which has been already
described.
General Development of the Pelvis.
The pelvis in the first periods of life participates in the slow development of the lower
extremities. Its dimensions, especially in the foetus and in infancy, are so small, that
it is unable to receive into its cavity many of the organs which are afterward contained
in it ; this is one of the principal causes of the prominence of the abdomen of the foetus.
The smaller capacity of the pelvis results also from the absence of the iliac fossae, for
these bones are neither twisted nor excavated, but straight and flat. Nevertheless, the
upper or iliac portion of the pelvis is proportionally more developed than the lower or
cotyloid, doubtless because this latter part belongs especially to the lower extremities,
and also serves as a protection to the genital organs, both of which are in a rudimentary
state in the foetus. If we examine in detail the differences in size, considered only
with reference to the various diameters, we shall find that the transverse are very small,
because in front the cotyloid cavities are scarcely developed, and all the pubic region is
contracted ; and behind, the iliac bones are more closely approximated to each other, on
account of the small size of the sacrum. The antero-posterior diameters appear longer,
on account of the shortness of the transverse. But the most characteristic feature of
the pelvis in the early periods of life is its much greater inclination than in the adult.
In the latter, indeed, a horizontal line drawn from the upper part of the symphysis pubis
would fall only a few lines below the base of the sacrum, while in the foetus a similar
horizontal hue would fall nearer the lower than the upper part of the sacrum. This, as
well as the small capacity of the pelvis, is the cause of the forward position of the blad-
der, bringing the whole of its anterior surface to correspond with the parietes of the ab-
domen, and, consequently, rendering it more easily accessible to instruments introduced
above the pubes.
We have already remarked, that the obliquity of the pelvis in the aged is not of the
same kind as that in the foetus ; and we should add here, that there is no change in the
relative position of the bladder, which, as in the adult, corresponds to the back of the os
pubis.
The Thigh.
The Femur {fgs. 49 and 50).
The femur, or thigh bone, situated between the pelvis and the leg, is the longest and
largest bone of the skeleton. It is proportionally larger in man than in any other ani-
mal ; this is connected with the ofiice which it performs, of supporting, by itself alone,
the weight of the body in standing, and transmitting it to the leg. It is obliquely di-
rected downward and inward. This obliquity is greater in the female than in the male,
on account of the greater distance between the acetabula. Too great an obliquity is in-
jurious both in standing and walking, and constitutes a well-known deformity.
The femur describes a curve in front and behind, the convexity of which looks for-
ward, and leaves a sort of excavation behind, which is occupied by the numerous pow-
erful muscles which bend the leg upon the thigh. This curvature, of which the siun-
mit is in the middle of the bone, explains why fractures generally occur here. It is
generally very great in subjects affected with rickets. Independently of tliis antero-
posterior curvature, the femur is slightly twisted upon itself This curvature of torsion
seems to me to be connected with the course of the femoral artery, which passes round
the shaft of the bone from one surface to the other. Lastly, at its upper part it presents
an angular curve, which we shall notice presently.
94
OSTEOLOGY.
Like all other long bones, the femur is divided into a body and extremities.
Of the Body. — ^The body or shaft is prismatic and triangular, with three surfaces and
three edges.
The anterior surface (a, fig. 50) is rounded, and has a cylindrical aspect ; it is broader
below than above.
The internal surface {h, fig. 49) is flat, it becomes much wider below, and then looks
backward. The femoral artery corresponds to this surface, and may be compressed
upon it towards the middle third of the thigh.
The external surface (c) is much narrower than the internal, and is slightly excavated
throughout its extent.
Of the three edges, the internal and the external are rounded, and scarcely distinguish-
Fig. 49.
Fig. 50.
able from the surfaces which they separate.
The posterior edge {e df), on the contrary,
is very rough and prominent, and has, there-
fore, been called the linca aspera : it is di-
vided into tico lips and an interspace, for the
sake of facilitating the description of the
numerous muscles to which it gives attach-
ment. It is more rough above than below,
and is bifurcated at both ends. Of the two
branches of the upper bifurcation, the exter-
nal (e), extremely rough, is occasionally sur-
mounted by a considerable eminence, and
prolonged to the large process called great
trochanter. The internal branch is less pro-
jecting, and terminates on the inside in a
smaller eminence called lesser trochanter.
The outer branch (/) of the lower bifurca-
tion runs towards the outside of the lower
extremity of the femur, and terminates in
an eminence, below which is a small de-
pression, to which the external head of
the gastrocnemius is attached. The in-
ner branch (g) is nearly effaced at the part
where the femoral artery passes over it :
below this it appears again, and, like the
outer branch, terminates in a well-marked
prominence, to which the adductor magnus
is attached, and, below it, the inner head
of the gastrocnemius. The triangular in-
terval, included between the two branches
of the bifurcation, corresponds to the popli-
teal artery and vein. The nutritious fora-
men (Ji) is situated in the linea aspera ; it passes from below upward.
The superior extremity of the femur forms an obtuse angle with the body, and presents
a head, a neck, and two unequal eminences, named trochanters, the greater and lesser.
The head (i, figs. 49 and 50) is the most regularly spheroidal of all the eminences in
the skeleton, and forms nearly two thirds of a sphere. In the middle of it we observe a
rough depression (k) of variable dimensions, which gives attachment to the round Uga-
ment. The neck (/), so called because it supports the head of the bone, is obliquely di-
rected upward and inward ; it forms an obtuse angle with the body of the femur {angle
of the femur), retiring on the inside and projecting on the outside, the degree of which
varies in different individuals, at different ages, and in the two sexes. In fact, it is
sometimes a very obtuse and sometimes a right angle : this last is most common in the
female, and is one of the causes of the prominence in her of the great trochanter. The
neck, which varies in length in different subjects, is flattened in fi-ont and behind, so
that its verticed diameter is double the antero-posterior ; hence it has more power in
resisting force applied from above downward than from before backward, which is a
great advantage, since the causes which would produce fractures are almost always ap-
plied in the former direction. The anterior surface of the neck is much shorter than
the posterior, which is also slightly concave. The upper edge is very short, and pre-
sents a great many nutritious foramina ; the lower edge is about double the length of
the upper. The base of the neck is marked by a number of nutritious foramina ; it is
bounded in front by some inequaUties ; behind by the great trochanter above, and the
lesser trochanter below ; and in the interval between these two, by a projecting ridge,
which unites them, and which is called the inter-trochanteric line. Behind, at the root
of the great trochanter, there is a deep pit, which weakens the neck of the bone in this
situation, fiom which circumstance fractures most generally occur at that point.
The great trochanter (m) is situated a little behind, at the outer and upper part of the
THE FEMUR, THE PATELLA. TO
lemur. It is on a lower level than the head, and nearly in the same axis as the shaft,
which it prolongs upward. It is of considerable size, and forms a very marked promi-
nence under the skin. It should be carefully studied in its relations, 1. With the crest
of the ilium, beyond which it projects on the outside ; 2. With the external condyle of
the femur ; 3. With the external malleolus, because these relations constantly serve as
a guide, both in the diagnosis, and the reduction of dislocations of the femur, and of frac-
tures of the neck or shaft of that bone. The great trochanter, which is intended solely
for muscular insertions, is of a quadrilateral figure, flattened from without inward, and
presents, 1. An external surface, which is convex, and terminates below in a projecting
ridge for the vastus externus, and is traversed by an oblique line running downward and
backward, to which the gluteus medius is attached ; 2. An internal surface, on which we
find a depression called digital, or trochanteric cavity, where the tendon of the obturator
externus is inserted ; 3. A superior border, to which the gluteus minimus, the pyramidalis,
and obturator internus are inserted ; 4. An anterior border, which is often surmounted by
a large tubercle, gives attachment to the vastus externus ; and, 5. A posterior border, which
gives attachment to the quadratus femoris.
The lesser trochanter (n) is situated on the inside, behind, and below the base of the
neck of the femur ; it is a sort of conoid tubercle, and gives attachment to the common
tendon of the psoas and iliacus muscles.
The lower end of the shaft of the femur is of considerable size ; it is broad, transverse-
ly flattened in front and behind, and divided into two convex articular processes, called
internal (r) and external (*) condyles of the femur. The external condyle is in the same
line as the shaft of the femur. The internal condyle projects on the inside of the axis
of the bone, and below the external condyle, so that when both condyles rest on the
same horizontal plane, the femur is directed obliquely downward and inward. The two
condyles are separated behind by a deep notch, called inter-condyloid notch (o, fig. 49) ; in
front their union forms a sort of pulley, the femoral trochlea {t, fig. 50), on which the pa-
tella rests. That portion of the trochlea which belongs to the external condyle is larger,
more prominent, and higher than that which belongs to the internal. Each condyle has
three surfaces : 1. The lower surface, articular, convex, and rounder behind than in front,
is in contact with the tibia and the patella ; the lower surface of the internal condyle is
more prominent behind than that of the external. 2. The internal surface of the external
condyle, and the external surface of the internal condyle, are deeply excavated, and give
insertion to the crucial ligaments. 3. The internal surface of the internal condyle and the
external surface of the external condyle present two enlargements, called tuberosities of
the femur.
The internal tuberosity (v) is the larger, and has behind a depression situated above the
tubercle for the adductor magnus, already described. The external tuberosity {w) is less
prominent, and presents two depressions separated by a tubercle, which may be easily
felt under the skin in emaciated subjects. The inferior groove is distinctly marked, and
gives origin to the tendon of the popliteus muscle.
Connexions. — The femur articulates with the innominatum, which transmits to it the
weight of the body, and with the tibia upon which it rests, and is in contact with the
patella.
Internal Structure. — Like all long bones, the femur is compact in its shaft and spongy
at the extremities ; its medullary canal is the type of canals of that kind.
Development. — The femur is developed from five points : of these, three are primitive,
viz., one for the shaft, and one for each extremity ; two are epiphysary, one being for each
trochanter. A bony point first appears in the shaft, from the thirtieth to the fortieth day ;
the osseous germ of the lower extremity is visible in the centre of the cartilage, during
the last fifteen days of foetal life. The constancy of the appearance of this point is of
great importance in forensic medicine, because its existence proves at once that the
foetus has reached the full term. The third point is seen in the head of the femur, at the
end of the first year after birth. The neck has no separate osseous centre ; it is formed
by an extension of the shaft. The nodule of the great trochanter is developed from three
to four years after birth ; that of the lesser trochanter, from the thirteenth to the four-
teenth year.
The order of union of these parts does not coincide with that of their appearance ; it
commences after puberty, and does not terminate until after the growth of the body is
completed. The lesser trochanter, the great trochanter, and the head, are successively
attached to the bone about the eighteenth year. The lower extremity, which appeared
first, does not join the shaft until the twentieth year. In old age the spongy tissue is
frequently so delicate, that the interior of the neck becomes filled with an adipose tissae
Uke the body of the long bones. This explains the frequency of fractures in this situa-
tion in advanced age.
The Patella {jig. 51).
The patella or rotula, so named from its rounded shape, resembhng a wheel, is, both
from its size, and the functions which it performs, the most important of those bones
96 OSTEOLOGY.
which have been called sesamoid (from aijadfiT]), on account of their resemblance to the
sesamum seed, and which are found in the neighbourhood of various articulations that
are subjected to much pressure. It is situated in front of the knee, and is movable
when the leg is extended ; but fixed and very prominent when the leg is flexed upon the
thigh. Its mobility allows it to escape the injurious effect of external blows, to which
it would be subject were it united to the tibia like the olecranon process to the ulna.
It is the most variable of all the bones, both in its absolute size, and in the proportion of
its different dimensions. It is flattened in front and behind, and presents an interior and
a posterior surface, and a circumference.
The anterior or subcutaneous surface {i,fig. 51) is convex, and covered by a very thick
layer of fibrous tissue, intimately adherent to the bone.
The -posterior ox femoral surface (2, fig.' 51) corresponds exactly to the pulley on the
lower extremity of the femur. We observe on it, 1. An articular ridge (x) sloping down-
ward and inward, and corresponding to the groove of the trochlea, which presents the
same obliquity. 2. On each side of this ridge, a concave articular surface, which is mould-
ed upon the corresponding condyle of the femur ; and as the external condyle of the
femur is the larger, the external articular surface (y) of the patella is much greater than
the internal. From this inequality, it is easy at once to distinguish the right from the
left patella.
The circumference of the patella resembles a curvilinear triangle ; its thick base, di-
rected upward, gives attachment to the tendon of the rectus femoris and to the tendons
of the extensor muscles of the leg ; and its apex (z), turned downward, and somewhat
pointed, gives attachment to the ligamentum patellae. Its sides are thin, and give at-
tachment to some aponeurotic fibres ; so that, excepting its posterior surface, wliich is
articular, the whole patella is enveloped in fibrous tissue ; a circumstance which is in ac-
cordance with its peculiar mode of development, and has an important influence over its
reunion when fractured.
Internal Structure. — Tlie patella is entirely composed of spongy tissue, covered in
front by a thin layer of compact substance, which renders it very liable to fracture, and
which forms a very remarkable exception to the generality of short bones, in presenting
well-marked parallel verticcd fibres. Between these fibres are numerous vascular open-
ings.
Development. — The patella is developed from one point only. In a few rare cases, as
Rudolphi has observed, there are several points. The ossification of the patella com-
mences about the age of two years and a half
The Leg.
The Tibia (fig. 52).
The tibia, the larger of the two bones of the leg, is situated between the femur, which
rests upon its upper end, and the foot on which it is supported. Next to the femur, it
is the largest and longest bone of the skeleton. Its upper extremity is expanded ; the
shaft is narrower, and of a triangular prismatic form. The lower extremity is also ex-
panded, but to a much less degree than the upper. The smallest part of the tibia does
not exactly correspond with the middle of the shaft as in the femur, but at the junction
of the lower with the two upper thirds ; and in this place fractures, produced by centre-
coup, are most frequent. The direction of the tibia is vertical, contrasting thus with the
femur, which, as we have seen, slants obliquely downward and inward. In individuals
whose thigh bones are very oblique, the tibife have a direction downward and outward.
In a well-formed skeleton, the two tibiae are parallel.
With regard to its axis, the tibia presents a double inflection, so that the upper end is
turned outward and the lower slightly inward. When this last inclination is excessive,
it gives rise to bowed legs. Lastly, it is slightly twisted at its lower part.* Like all
long bones, it is divided into a body and extremities.
The body or shaft has the figure of a triangular prism ; and this form, which is observ-
ed in ahnost all long bones, is in none so marked as in the tibia. We have, therefore,
to consider three surfaces and three edges.
The internal surface (a, fig. 53) is covered at the upper part by the internal lateral lig-
ament, and by an aponeurotic expansion (called patte d^oie,f or goose'' s foot) : in the rest
of its extent it is immediately under the skin. This superficial situation of the internal
surface partly explains the facility with which this bone may be broken by direct violence,
and also the frequency of caries, exostoses, and necrosis. It is broad above, and grad-
ually diminishes towards the lower part. Its three superior fourths look inward and
fo'^ward ; its lower fourth looks directly inward.
The external surface {b) presents in a great part of its extent, but especially above, a
longitudinal excavation, the depth of which corresponds to the size of the tibialis an-
* The absence of an antero-posterior curvature and the lateral curves in opposite directions, together with
its slight torsion, explains the great solidity of this bone.
t [This patte d'oie consists of the expansion formed by the tendons of the sartorius, gracilis, and semitendi-
nogus muscles.]
THE TIBIA.
97
ticus, to which it gii'es attachment. Inferiorly, the external surface Fig.5i. Fig.sz.
of the tibia turns forward (d), and this deviation corresponds with the
altered direction of several tendons, which are placed at first on the
outside of the bone, and afterward pass in front of it. There is, in
fact, a constant reciprocity between alterations in the direction of
bones, and changes in the course of neighbouring tendons.
The posterior surface is also broad above, and progressively dimin-
ishes downward. On it we oh- 1 ve near the upper part, I. An irreg-
ular line, running obliquely downward and inward ; to this line many
of the deep-seated muscles on the back of the leg are attached. 2.
Above this line a triangular surface covered by the popliteus muscle,
which separates it from the popliteal artery. 3. Below the same
line, the orifice of the nutritious canal, which runs downward. Into
this nutritious canal, which is, perhaps, the largest of any in the long
bones, I have seen a nervous twig enter, accompanying the nutri-
tious artery. 4. From the oblique line to the lower end of the tibia,
the posterior surface of this bone is smooth, of almost uniform di-
ameter, and divided throughout its length by a more or less marked
vertical line.
The anterior edge (c c) is placed immediately under the skin, beneath
which it may be readily felt ;* its lower fourth is round and blunt, the
upper three fourths are sharp, and hence it has been called the crest of
the tibia. Its upper part inchnes somewhat outward, its lower part in-
ward.
The external edge (g k) gives attachment to the interosseous liga-
ment ; it is bifurcated below, and thus forms the two boundaries of an
articular cavity, which we shall notice in describing the lower end of the tibia. The «j-
ternal border {f I), much less sharp than the others, affords insertion to several muscles.
The upper or femoral extremity (/ g) of the tibia is at least double tlie size of the lower,
and is larger in a transverse direction than from before backward ; on it we observe
two concave articular surfaces, of an oval shape, with their long diameter directed from
behind forward. They have been improperly denominated condyles; a more correct
name would be glenoid cavities of the tibia. These surfaces, which articulate with the con-
dyles of the femur, are not perfectly alike ; the internal is longer, narrower, and deeper
than the external. They are separated by a pyramidal eminence surmounted by two
sharp tubercles. This eminence, which is called the spine of the tibia (e), is nearer the
posterior than the anterior part of the bone. In front and behind this spine are two
rough depressions, which give attachment to the crucial ligaments. The glenoid cavi-
ties are supported by two considerable enlargements, called tuberosities of the tibia.
The internal tuberosity (/), larger than the external, presents behind a horizontal
groove, into which one of the divisions of the tendon of the semi-membranosus is in-
serted. The external tuberosity (g), smaller, but more prominent behind than the internal,
presents at its back part a small, almost circular facette, which articulates with a corre-
sponding surface on the fibula. The two tuberosities of the tibia are separated behind by a
considerable excavation. In front they are separated by a triangular surface, pierced by
vascular foramina, and terminating below in an eminence, called anterior tuberosity of the
tibia (A). This tuberosity, below which the crest of the bone commences, is rough and
prominent below, where it gives attachment to the tendon of the extensor muscles of
the leg, ligamentum patellcB,i and smooth above, where it is separated from the same ten-
don by a synovial bursa. A projecting line runs outward from this tuberosity, and ter-
minates above in a tubercle, which is very prominent in some individuals, and may be
easily felt under the skin. It gives origin to part of the tibialis anticus.
The lower or tarsal extremity (Z k) of the tibia is almost square, having, like the upper,
its greatest diameter transversely. We observe on it a quadrilateral articular cavity (i),
transversely oblong, broader on the outside than on the inside, and divided by an antero-
posterior ridge, into two unequal parts. It articulates wth the astragalus. The circum-
ference of this extremity presents, 1. In front, a convex surface (rf), with some inequalities
for the insertion of ligaments ; it is in contact with the extensor tendons of the toes. 2.
Behind, an almost plane surface, having a shallow depression, which is hardly visible in
some subjects, forthe tendon of the long flexor of the great toe, and which must not be con-
founded with an oblique groove, situated on the inner side, and which will be described
with the internal malleolus. 3. On the outside, a triangular cavity (k), broad and smooth
below, narrow and rough in its two upper thirds, which articulates with the fibula. 4. On
* The superficial sitnation of the antenor edge of the tibia renders it a good guide to surgeons in the diagiuv
sis and coaptation of fractures of the leg. It also greatly exposes the bone to injury from external violence.
It is not uncommon to find it broken, or, as it were, notched, by a gun-shot.
t t have seen this tuberosity so large that several practitioners, not familiar in such anatomical variettM,
believed it to be an exostosis, and had placed the patient, a lad of 14 years of age, under a course of mercozial
frictions.
N
90 OSTEOLOGY.
the inside, a thick quadrilateral process, flattened on the outside and the inside, and call-
ed the internal malleolus (I). This eminence, which bends inward, forms a marked prom-
inence at the lower and inner part of the tibia. When the posterior surface of the tibia
is laid upon a horizontal plane, the two tuberosities of the upper end of the bone rest
upon that plane, while the internal malleolus advances considerably forward ; it is there-
fore upon a plane anterior to that of the internal tuberosity of the tibia : this depends
upon the torsion of the lower part of the bone. The internal surface (l) of the malleolus
is convex, and is placed immediately under the skin : its external surface forms part of
the inferior articular cavity of the tibia. Its anterior edge is rough, and gives attachment
to ligamentous fibres ; its posterior edge, which is thicker than the anterior, presents a
groove running obliquely downward and inward, and sometimes double, along which the
tendons of the tibialis posticus and flexor longus digitorum pass. The base of the mal-
leolus, very thick, is united to the shaft of the bone. The summit, which is truncated
and slightly notched, gives attachment to the internal lateral ligament of the ankle-joint.
Connexions. — The tibia articulates with the femur, the astragalus, and the fibula ; it
articulates also with the patella, but indirectly by means of the ligamentum patellae.
Internal Structure. — The shaft consists of compact tissue, and has a large medullary
canal. The two extremities are spongy, and are pierced by a great number of vascular
foramina.
Development;. — The tibia is developed from three points ; one for the body, and two for
the extremities. Sometimes there are four. Beclard once saw the internal malleolus
developed firom a separate point. The ossific point of the shaft is the first to make its
appearance ; it commences between the thirty-fifth and fortieth day, almost at the same
time as that of the body of the femur ; sometimes it is even earlier, as in one case ob-
served by myself The bony germ of the upper extremity makes its appearance gen-
erally towards the end of the first year after birth. I have never seen it before birth.
The ossification of the lower extremity commences during the second year. The inter-
nal malleolus is formed by a prolongation of this extremity. The union of all the parts
of the bone is not finished until the period of complete development of the body, that is,
from the eighteenth to the twenty-fifth year ; it always commences with the lower ex-
tremity, which is the last to become bony. It is of importance to remark, that the su-
perior epiphysis of the tibia does not form the whole of the upper end of the bone, but
only a sort of horizontal plate which supports the articular cavities ; and the same is
true of almost all articular extremities. It should also be observed, that the anterior tu-
berosity of the tibia is formed by a vertical prolongation of the plate which forms the su-
perior epiphysis. It would oppear, that in some subjects this anterior tuberosity has a
distinct centre of development.
The Fibula (fig. 53).
The fibula or perone (from irepovri) is so named because, according to Sabatier, it has
been compared to a sort of clasp or brace in use among the ancients.
In order to understand the description of this bone, it is necessary to place it exactly
in the position which it occupies in the skeleton.* It is situated on the outside of the
tibia below, on the outside and to the back of the same bone above. It is as long as the
tibia, but is extremely slender ; it is> indeed, the most slender of all the long bones, and
may be at once recognised by this character. Its direction is vertical, with a slight in-
chnation outward at its lower part. It is the most twisted on itself of all the long bones,
and is a remarkable exemplification of that law of osteology, viz., that the torsion of
bones is always connected with the changes of direction of tendons, or vessels. It is divided
into a body and two extremities.
The body has the form of a triangular prism. In order rightly to comprehend its
shape, it is necessary to be aware that the muscles which are placed on its external
surface above turn round to the posterior aspect below, from which it is easy to under-
stand how the four upper fifths of the external surface look outward, and the lower fifth
backward.
The external surface (n) is marked by a deep groove which runs along it, and gives at-
tachment to the peroneus longus, and pcroneus brevis. The lower part, which is turned back-
ward, is smooth. The internal surface is divided into two unequal parts by a longitudi-
nal ridge, to which the interosseous ligament is attached. The portion of the surface in
front of the ridge is narrower than the other, being in some subjects not more than two
lines in breadth ; it gives attachment to the muscles on the fore part of the leg : the por-
tion beliind the ridge is larger, and gives attaclunent to the tibialis posticus. This sur-
face becomes anterior at its lower part (o).
* We have hitherto deemed it unnecessary to indicate the position in which each bone should be studied,
Decause a glance at an articulated skeleton would suffice to enable the student at once to place the bones
aright. The fibula, however, forms an exception, on account of its remarkable torsion. In order, then, to
8t:5y this bone conectly, it is necessary to place the flattened end (u ») downward, taking care that the artic-
ular surface on that part be turned inward, and that the thin edge (u) of the eminence which forms this Jow-
"r end should look forward.
v >^^' •
THE FOOT.
99
The posterior surface of the fibula is narrow above, and expanded below, where it
looks inward, and terminates by a rough part, to which ligaments that unite it to the tibia
are attached. The whole of this surface gives attachment to muscles. We observe on
it the principal nutritious canal, which passes obliquely downward. This canal is some-
times placed on the internal surface of the bone.
The three edges participate in the deviations of the surfaces. Thus, the miter edge (r)
becomes posterior below ; the anterior edge (s) becomes external, and is bifurcated ; the
internal edge becomes anterior, and after being thus changed, forms the continuation of
the ridge for the interosseous ligament, which we noticed upon the inner surface.
All the edges give attachment to muscles and aponeurotic processes, and are remark-
able for their prominence.
The superior extremity or head (t) of the fibula presents an articular facette (near t\
slightly concave, which unites with a corresponding surface on the tibia : on the outside
are some irregular impressions for the insertion of the biceps muscle, and the externa!
lateral Ugament of the knee. At the back part of this head we observe the styloid pro*
cess of the fibula (below t) for the tendon of the biceps.
The lower extremity or external malleolus (w v) passes much below the inferior articu-
lar surface of the tibia ; it is longer and thicker than the internal malleolus. It is flat-
tened on the outside and the inside, and presents, 1. An external surface (uv), convex
and sub-cutaneous. 2. An inlerTial surface, which articulates with the astragalus hy
means of a facette, which completes on the outside the sort of mortise fgrjneci by tha
union of the lower ends of the tibia and fibula ; below and behind this ^urfeioc is a, deep,
rough excavation, which gives attachment to a ligament. .3.^Aji aut^erion ^ige (u) for the
insertion of a Ugament. 4. A posterior edge (c), thicker, ■jrarlied by a superficial -groovG
for the passage of the tendons of the peronei muscles. t&. A summit, which gives airaclj
ment to one of the external lateral ligaments of the ankle-jciu*^.
Connexions. — The fibula forms the outer part of rh*? le?, and a^liculr.tes with the tibia
and the astragalus. ' - > ^
Internal Structure. — The shaft is compact, and has a very small medullary canal, and
the extremities are spongy.
Development. — The fibiSa is developed from three points : one for the body, and one for
each extremity. The osseous point of the body appears a little after that of the shaft of
the tibia, from the fortieth to the fiftieth day. At birth, the two extremities are still car-
tilaginous. An osseous point appears in the lower end during the second year ; that of
the upper end about the fifth. The extremities are united to the shaft of the bone when
the development is completed, viz., from twenty to twenty-five years : the lower end is
the first to become joined.
The Foot {figs. 54, 55, and 56).
The foot is the part of the lower extremity which is analogous to the hand in the up
per. They are both but varieties of the same type of organization, with certain differ-
ences which have reference to their respective uses. In the foot, for example, which is
intended to support the body, the conditions necessary for solidity are principally mani-
fest, while the hand is chiefly remarkable for the mobility of its parts.
The foot is composed of twenty-six bones, which, by their imion, form three distinct
parts, viz., 1. The tarsus (c if, fig. 54), a bony
mass, consisting of seven pieces closely articu-
lated ; 2. The metatarsus, composed of five sep-
arate columns {m m", figs. 54 and 55) ; and, 3.
The toes, formed each of three columns (n o r),
excepting the first, or most internal, which has
only two {71" r").
The size of the foot varies in different indi-
viduals. It exceeds the hand in thickness and
length, but is not so broad. Its direction is
horizontal from before backward, and it forms
a right angle with the leg, differing much in
this respect from the hand, which is in the
same line as the forearm. It is flattened from
above downward, is hollow below {fig. 56), nar-
row behind, where it is of considerable height,
and thinner and broader in front, at which part
jilso it is digitated. It presents, 1 . A superior
or dorsal surface, which is convex, dorsum pedis,
( fig. 54) ; 2. An inferior or plantar surface, which
is concave transversely, and likewise in the an-
tero-posterior direction, sole of the foot {fig. 55) ;
3. An internal or tibial edge {fig. 56), which is
very thick, and corresponds to the great toe ; 4. An external or fibular edge, which corre-
100 OSTEOLOGY.
sponds to the little toe ; 5. A ■posterior extremity or heel ; 6. An anterxar or digital exttemity.
We shall describe in succession the tarsus, the metatarsus, and the '.oes.
The Tarsus {figs. 54, 55, and 56).
The tarsus is an analogous structure to the carpus, but differs from it in forming the
Pig^ 56. posterior half of the foot, while the carpus
only constitutes about a sixth of the hand.
Its antero-posterior diameter surpasses by
more than double its transverse, precisely
the opposite of what obtains in the carpus.
It resembles a vaulted arch, the convexity
of which (c a j, fig. 56) looks upward, and
which is excavated below {d i) both trans-
versely and from before backward. The
weight of the leg falls upon the smnmit of this arch. This form of the foot is not de-
signed merely for securing the advantages derived from the mechanism of arches, but is
especially intended to afford a protecting excavation for the organs which could not with
impunity be compressed in standing and progression. The posterior and free extremity
of the tarsus is narrow, and progressively enlarges forward.
The tarsus is composed of seven bones, disposed in two rows. The/r«^ or tibial raw
iS formed b/'twp bones only, the os calcis (c) and the astragalus (a) ; the second or meta-
tarsal row cenoists Qffiv& bones, viz., the scaphoid (g), the cuboid (/), and the three cune-
iform bones (i j I). The bo|ies. of the first row, instead of being placed in the same trans-
verse line, like those of the, flust, row of the carpus, rest one upon the other. The astrag-
iilus'is the oniy JJipne /)f the tarsus which enters into the formation of the ankle-joint.
' ' ' ■ " "'■'^o .Fiiist ,cri 'J!iJ)ial Row of the Tarsus.
" " ■ ♦ The Astragalus [a).
The astragalus is placed below the tibia, above the os calcis, on the inside of the mal-
leolar extremity of the fibula, and behind the scaphoid ; it is irregularly cuboid in its fig-
ure, is the second largest bone of the tarsus, and heis six surfaces : 1. The superior oi
tibial surface (a, fig. 54) is articular, and shaped like a trochlea or pulley, which fits ex-
actly to the lower surface of the tibia. In front and behind the trochlea are inequalities
for the attachment of ligaments. 2. The inferior or calcaneal surface (a, fig. 55) presents
two facettes, separated by a very deep furrow, running obliquely backward and inward,
and broadest in front, which gives insertion to a ligament. The facette behind the
groove is the larger ; it is concave and oblong in the same direction as the groove. The
facette in front is flat, and often divided into two smaller surfaces. Both articulate with
the OS calcis. 3. The internal lateral surface {fig. 56) is articular for a considerable por-
tion of its upper part, and corresponds to the internal malleolus ; below, there is a rough
depression, which gives attachment to the internal lateral ligament of the ankle-joint.
4. The exterTud lateral surface is triangular, like the corresponding surface of the external
malleolus, with which it articulates. It should be remarked, that both the lateral articu-
lar surfaces of the astragalus are continuous with the trochlea or upper surface, without
mterruption. 5. The anterior or scaphoid surface is convex, and has been called the head
of the astragalus ; it is articular, and continuous, below, with the anterior facette of the
lower surface of the bone already described. This head is supported by a contracted
portion, or neck (i, fig. 54 and 56), to which ligaments are attached. 6. The posterior
surface is very small ; it consists simply of a groove, slanting downward and inward,
along which the tendon of the flexor longus poUicis pedis glides.
The Os Calcis (c).
The OS calcis, or calcaneum, situated below the astragalus, and at the lower and back
part of the foot, is the largest bone of the tarsus. Its form is irregularly cuboid, with
the greatest diameter from before backward ; it is flattened transversely. Its size and
its length have reference to the double ofl5ce which it serves, of transmitting the weight
of the body to the ground, and of acting as a lever for the extensor muscles of the foot.
I should remark, that its large posterior extremity forms the heel (d, figs. 55, 56), the
horizontal direction of which, in man, is one of the most advantageous arrangements for
the vertical position of the body.
The OS calcis has six surfaces : 1. The superior surface {fig. 54) presents, in front, two,
or often three, articular facettes, which correspond with those on the lower surface ol
the astragalus. The posterior facette is the larger, convex, and separated from the an
terior by a groove, which is shallower than the corresponding one of the astragalus, but
follows the same direction backward and inward. The whole of the non-articular por-
tion of this surface projects behind the astragalus ; it is flattened on the sides, and slight-
ly concave from before backward. Its length varies in different individuals, and is tho
cause of the varieties in the projection of the heel. 2. Tlie lower oi plantar surface {fig
THE CUBOID AND SCAPHOID BONES. 101
55) is rather an edge than a true surface ; it is directed obliquely upward and forward.
We observe here, at the back part, two tuberosities, the internal of which is much larger
than the external ; both serve as places of insertion for muscles, but their principal use
is to support the weight of the body behind, and they essentially constitute the heel (d.
Jig. 56) in the human subject. 3. The external surface is superficial, which accounts for
the frequency of injuries of this bone on its outside, and explains, also, the ])ossibility of
reaching it with surgical instruments. It is convex, and narrow in front, where it pre-
sents two superficial grooves separated by a tubercle (s, figs. 54 and 55). These grooves
afford a passage to the tendons of the peroneus longus and brevis. On the anterior and
superior part of this surface we find, also,'tinother tubercle, which is a guide to the sur-
geon in the partial amputation of the foot recommended by Chopart. 4. The internal sur-
face {fig. 56) is deeply grooved for the passage of several tendons, and also for the
nerves and vessels which are distributed to the sole of the foot. It presents, in front
and above, a projecting eminence, like a blunt hook, in a shallow groove, below which
the tendon of the flexor longus pollicis pedis glides. This eminence has been called
the small process of the os calcis (e, fig. 56), also sustentaculum tali, because the anterior
and internal articular surface, which supports the astragalus, is on its upper part. 5.
The anterior or cuboid surface is the smallest. It is concave from above downward, and
articulates with the cuboid. It is surmounted on the inside by a short projection, direct-
ed horizontally forward,* above which the third articular surface for the astragalus is
situated when it exists. The whole portion of the os calcis which supports the anterior
or cuboid surface bears the name of great process of the os calcis {t,figs. 54 and 55). 6.
The posterior surface is shaped like a triangle, with the base downward ; its lower part
is rough and irregular, and gives attachment to the tendo Achillis, the upper part, over
which the same tendon glides, being smooth and polished like ivory.
Second Row of the Tarsus.
The bones of the second row are five in number : on the outside it is formed by the
cuboid alone, but on the inside it is subdivided into two secondary rows ; a posterior,
formed by the scaphoid ; and an anterior, composed of the three cuneiform bones. This
subdivision of the inner portion of the tarsus, by multiplying the articulations, has the
effect of diminishing the violence of shocks, or of pressure upon the foot, especially on
the inner side, to which they are principally applied.
The Cuboid Bone [ffigs. 54 and 55).
Tho cuboid, which ranks £is the third bone of the tarsus in point of size, is situated at the
outside of the foot, and appears like-a continuation of the great process of the os calcis. It
is more regularly cuboid than any of the other tarsal bones, and has six surfaces : 1. The
upper or dorsal surface {fig. 54) is covered by the extensor brevis digitorum pedis, and
looks somewhat outward. 2. The lower or plantar surface {fig. 55) presents on its fore part
a deep groove (/), running obliquely inward and forward, for the tendon of the peroneous
longus. Behind this groove, the posterior lip of which is very prominent, are impres-
sions for the ligament which connects the cuboid and the os calcis. 3. The posterior or
calcaneal surface is sinuous, directed obliquely inward and backward, and adapted to the
OS calcis in such a way that there is a mutual reception of the surfaces of the two bones.
At the inside of this surface, we observe a process which is directed inward and back-
ward, and strengthens the union with the os calcis. It occasionally becomes an obstacle
to the disarticulation of the foot, after Chopart's method. 4. The anterior or metatarsal
surface looks obhquely inward and forward ; it articulates with the fourth and fifth meta
tarsal bones. 5. The internal surface articulates with the third cuneiform bone, and fre-
quently also with the scaphoid ; it presents, besides, some impressions for the insertiop.
of ligaments. 6. The external surface is rather an edge; its extent from before back-
ward scarcely equals half the length of the internal surface. We observe on it the com-
mencement of the groove for the tendon of the peroneus longus.
The Scaphoid {g,Jigs. 54, 55, and 56).
The scaphoid or navicular hone, so named from its supposed resemblance to a boat, is
situated on the inner side of the tarsus ; it is flattened from before backward, and is
thicker above than below, irregularly elliptical, with the long diameter placed transverse-
ly. It has two surfaces and a circumference : 1. The posterior surface is concave, and
receives, thougn incompletely, the head of the astragalus. 2. The anterior surface pre-
sents three articular facettes, which correspond to the three cuneiform bones. 3. The
circumference is convex above, inclined inward, and rough for ligamentous insertions. It
is much smaller below, where also it gives attachment to ligaments. On the i?iside it
presents, at its lower part, a large process, process of the scaphoid (at g), which may be
easily felt under the skin, and serves as a guide in performing Chopart's amputation.
This process gives attachment to the tendon of the tibialis posticus. It is frequently
* This small prolongation, which might be called imaZi anterior process of the os calcis, in contradistinction
to the one on the internal surface already mentioned, merits notice in the performance of Chopart's operation.
102 OSTEOLOGY.
very large, and may, and, indeed, has been mistaken for an exostosis of the bone. On
the outside the circumference is irregular, gives attachment to some hgamentous fibres,
and often presents a small surface which articulates with the cuboid : this surface is
continuous with the facettes for the three cuneiform bones.
The Three Cuneiform Bones.
These bones, so named from their shape, are three in number: they are called ^rsf,
second, and third, counting from the inside of the foot. Tliey are also distinguished by
their size, into the great, middle-sized, and small.*
The First Cuneiform Bone (t, figs. 54, 55, and 56).
The first or internal cuneiform bone is the largest. It is placed on the inside of the
others, in front of the scaphoid, and behind the first metatarsal bone. It is shaped like
a wedge with the base below, which is precisely contrary to what obtains with the other
two. We observe oa it, 1. An internal surface {fig. 56), which is subcutaneous, and
forms part of the inner edge of the foot. 2. An external surface, which presents an an-
gular articular facette for union with the second cuneiform bone behind, and the second
metatarsal bone before ; the non-articular portion of the external surface of the first
cuneiform bone is rough, and gives attachment to ligaments. 3. A posterior surface,
which is concave, and articulates with the most internal and largest facette on the an-
terior surface of the scaphoid. 4. An anterior or metatarsal surface, which is plane, or,
rather, shghtly convex, of a semilunar form, the convexity being to the inside, and the
greatest diameter vertical ; it is broad below and narrow above, and articulates with
, the first metatarsal bone. 5. An inferior surface {fig. 55), which forms the base of the
wedge ; it is rough, with a tubercle behind for the attachment of the tibialis anticus. 6.
An upper part {fig. 54), which forms the point of the wedge ; it is an angular border,
running forward and upward, and thicker in front than behind, where it contributes to
form the convexity of the foot.
The Second or Middle Cuneiform Bone {j,fig. 54, 55, and 56).
The second coneiform bone is the smallest of the three : it ^ placed between the two
others, and corresponds to the scaphoid behind, and the second metatarsal bone in front.
The wedge wliich it represents has the base turned upward ; its length from behind for-
ward is very inconsiderable. It presents, 1. An internal surface, which is triangular, and
articulates with the first cuneiform bone : 2. An external surface, which articulates with
the third or external cuneiform bone : 3. A posterior or scaphoid surface, which is concave,
and articulates with the middle facette on the anterior surface of the scaphoid : 4. An
anterior or metatarsal surface, which is triangular, and nan'ower than the posterior ; it
articulates with the second metatarsal bone : 5. A superior surface {fig. 54), or lase of
the wedge, which is irregularly square, and rough for the attachment of ligamentous
fibres : 6. An apex {fig. 55), which is very thin, and gives attachment to some hgaments.
The Third or External Cuneiform Bone {I, figs. 64 and 55).
This bone, which is the third as regards position, and the second in point of size, has,
like the preceding, the form of a wedge with the base turned upward. Its internal sur-
face articulates behind with a corresponding surface on the preceding bone, and in front
with the second metatarsal. This last portion completes the kind of recess or mortise
into which the head of the second metatarsal bone is received ; its inner side being
formed by the first cuneiform bone, and the bottom by the second. The external surface
articulates with the cuboid : the posterior surface is continuous with the two lateral ones,
and articulates with the most external of the three facettes on the scaphoid : the ante-
rior surface is triangular, and articulates with the end of the third metatarsal bone : the
base {fig. 54) is rough, and forms part of the convexity of the foot : the apex {fig. 55) is
more obtuse than the same part of the second cuneiform bone, and passes considerably
below it.
Structure of the Banes of the Tarsus. — The bones of the tarsus present the structure
common to all short bones, viz., a mass of spongy tissue surrounded by a layer of com-
pact substance. I have remarked, that in some cases of white swelling of the ankle-
joint, the OS calcis contained in its interior a cavity analogous to the medullary canal of
long bones. This cavity, however, must be looked upon as Edtogether abnormal.
Development of the Tarsal Bones. — ^With the exception of the os calcis, which has two
osseous germs, all the bones of the tarsus are developed from single points. The os
calcis first becomes ossified. A bony nodule appears in the centre of its cartilage, about
the middle of the sixth month of foetal life, according to most osteogonists ; in the fifth,
or even the fourth month, according to others. It is placed much nearer the anterior
than the posterior extremity of the future bone. Another osseous germ is formed in the
posterior extremity of the os calcis, from the eighth to the tenth year, and is much
thicker at its lower than at its upper part. The astragalus is developed from one point,
* Also, by position, into internal, middle, and external.
THE METATARSUS. 103
which appeara from the fifth to the sixth month of intra-uterine life. According to Bfe-
clard, the cuboid is not ossified until some months after birth ; I have observed the pro-
cess to be already commenced in a foetus at the full term. Meckel says that it begins
after the eighth month of foetal life. Blumenbach, on the contrary, makes the time of
its ossification a year and a half, or two years after birth ; and Albinus, who has been
followed in this respect by the generality of anatomists, affirms that in the foetus at the
full period, all the bones of the tarsus, excepting the os calcis and the astragalus, still re-
main cartilaginous.
The cuneiform bones are developed in the following order : The first is ossified to
wards the end of the first year ; the second and the third appear almost simultaneously
about the fourth year ; the os calcis being the only bone of the tarsus which has more
than one point of ossification, is also the only bone in which we have to examine the or
der of union. The two points which form it are not united until the fifteenth year.
The Metatarsus {m m'^figs. 54, 55, and 56).
The metatarsus forms the second portion of the foot. Like the metacarpus, its anal
ogous part in the hand, it consists of five long bones, parallel to each other, forming a
sort of quadrilateral grating, the intervals of which, called interosseous spaces, are in-
creased by the disproportion between the ends and the shafts of the bones. The meta-
tarsus presents, 1. An inferior or plantar surface {fig. 55), with a marked transverse con-
cavity ; 2. A superior or dorsal surface {fig. 54), which is convex^ and answers to the
back of the foot ; 3. An internal or tibial edge (m', fig. 56), which is very thick, and cor-
responds to the great toe ; 4. An external or fibular edge, which is thin, and corresponds
to the little toe ; 5. A posterior or tarsal extremity, which presents a waved articular line ;
6. An anterior or digital extremity, presenting five heads flattened on the sides, which as-
sist in forming five separate articulations. The bones of the metatarsus have certain
characters which distinguish them from all others, besides some peculiar marks by which
they may be known from each other, and from the metacarpal bones, with which they
have many analogies.
General Characters of the Metatarsal Bones.
The metatarsal bones belong to the class of long bones, both in shape and structure.
Each consists of a body and two extremities. The body is prismatic and triangular, and
sUghtly curved, with the concavity below. Two of its surfaces are lateral, and corre-
spond to the interosseous spaces ; the third, so narrow that it resembles an edge, is on
the dorsum of the foot. Two of the edges are lateral ; the third is below, on the plantar
aspect of the foot.
The posterior or tarsal extremity is much expanded, and presents five surfaces, two of
which are non-articular, and three articular. Of the two non-articular surfaces, one is su-
perior, and the other inferior ; both give attachment to ligaments. Of the three articu-
lar surfaces, one is posterior, that is, on the extremity of the bone ; in general it is tri-
angular, and articulates with a corresponding surface on one of the tarsal bones. The
other two are lateral, partly articular, and partly non-articular. The articular surfaces
are small, and often consist of more than one ; they join the contiguous metatarsal bones.
The tarsal extremity is wedge-shaped ; the upper or dorsal surface being very broad,
represents the base of the wedge ; the lower surface, being narrow, forms the point.
The anterior or digital extremity presents a head or condyle, flattened on the sides, and
oblong from above downward ; the articular surface extends much farther on the lower
aspect, or in the direction of flexion, than on the upper, or the direction of extension.
On the inside and outside of the condyle there is a depression, and a projection behind
it for the lateral ligament of the joint.
Characters of the different Metatarsal Bones.
The first or metatarsal bone of the great toe (m', figs. 54, 55, 56) is remarkable for its
great size. It is the only one which, in this respect, resembles the tarsus ; its body is
shaped like a triangular prism ; its digital extremity is marked on the plantar aspect by
a double furrow for two sesamoid bones (*, fig. 56). (Vide Articulation of the Foot.) Its
tarsaL extremity presents a semilunar concave surface, with its greatest diameter verti-
cal, which articulates with the internal cuneiform bone. There is no articular surface
on the circumference of the first metatarsal bone. In this point it resembles the first
metacarpal bone, and by this and its great size it is distinguished from all the others.
The fifth metatarsal bone (m, fig. 54, 55) is the shortest after the first ; it has only one
lateral articular face on its tarsal extremity. On the opposite side of this extremity,
viz., on the outside, we observe a large process, process of the fifth inetatarsal bone, shaped
like a triangular pyramid, and directed obliquely backward and outward, into which the
peroneus brevis is inserted. This process may be easily felt under the skin, and serves
as a guide in the partial amputation of the foot at the tarso-metatarsal articulation.
Another charact^iristic of the fifth metatarsal bone is the great obliquity outward and
backward of the %rticular face on its posterior extremity.
104 OSTEOLOGY.
The second, third, and fourth metatarsal bones are distinguished from each other by
the following characters.
The second is the longest, and also the largest after the first ; it articulates with the
three cuneiform bones by its posterior extremity, which is dovetailed with them. The
third and the fourth metatarsal bones are of almost equal length ; their apparent difference
in an articulated foot depends chiefly on the fact that the articulation of the fourth with
the cuboid is on a plane posterior to that of the third with the external cuneiform bone.
Lastly, they may be known from each other by the presence of two surfaces, on the in-
side of the posterior extremity of the fourth metatarsal ; one being for the external cu-
neiform bone, and the other for the third metatarsal bone.
Development. — The metatarsal bones are developed from two points ; one for the body,
and one for the anterior or digital extremity. The first metatarsal bone is the only ex-
ception to this rule, for its epiphysary point is situated at the posterior extremity.* The
osseous point of the body appears first during the third month, according to the majority
of authors, but about the forty-fifth day, according to the observations of Blumenbach and
Beclard. It is completely developed in the foetus at the full period. The epiphysary
point makes its appearance during the second year. The union of these parts does not
take place until the eighteenth or nineteenth year, and is not simultaneous in all the
bones of the metatarsus. The epiphysis of the first metatarsal bone is the first to unite
with the body. An interval of a year sometimes intervenes between the union of this
epiphysis and those of the other four metatarsal bones.
The Toes [n o r, n r, Jigs. 54, 55).
The resemblance between the phalanges of the fingers and those of the toes is so com-
plete, that we cannot do better than refer to the description already given of the former
for details respecting the latter. At the same time, it should be remarked, that the pha-
langes of the toes appear, as it were, atrophied, or stinted in growth, when compared
with those of the fingers, excepting the great toe, which, in all its parts, preserves the
large dimensions of the inner side of the foot.
The first or metatarsal phalanx {n to n') resembles closely the metacarpal phalanx of
the fingers. The middle phalanx (o) is remarkably small and short ; it would almost ap-
pear to consist of the extremities alone, the body being absent. At first sight it might
be t£iken for a pisiform bone, or, rather, for one of the pieces of the coccyx ; but the
presence of anterior and posterior articular faces is sufficient to mark the distinction.
The ungual phalanges (r r') of the toes resemble in form, but are much smaller than
the corresponding parts of the fingers. This remark, however, only applies to the last
four, for the ungual phalanx of the great toe is in size at least double that of the thumb.
I cannot conclude this description without remarking, that the articular surface of the
posterior extremity of the metatarsal phalanges, as well as of the anterior extremity of
the metatarsal bones, is prolonged farther upward than the corresponding surfaces on
the metacarpal bones and phalanges of the fingers ; this arrangement allows a greater
extension of the toes, and is an important element in the mechanism of progression.
Development. — The first, second, and third phalanges are developed from two points
of ossification ; one for the body, and one for the metatarsal extremity. The epiphysary
points of the second and third phalanges are so small, that their existence has been
doubted by many anatomists. The osseous points of the bodies of the first phalanges
are much later in appearing than those of the metatarsal bones, not being visible, in
general, until from the second to the fourth month ; the first phalanx of the great toe is
an exception, its ossification concmiencihg from the fiftieth to the sixtieth day. The
epiphysary point of the first phalanges does not appear until the fourth year. The bodies
of the second phalanges are ossified almost at the same time as those of the first ; the
epiphysary point of their posterior extremity is not visible until from the sixth to the sev-
enth year. The bodies of the third phalanges are ossified before those of the second and
the first ; an osseous point appears in them about the forty-fifth day, excepting in the lit-
tle toe, where it is much later. The ungual phalanx of the great toe is remarkable as be-
ing ossified before all the other phalanges of the toes. It is developed from a point which
does not occupy the centre, but the summit of the phalanx. The epiphysary point of the
posterior extremity appears about the fifth year in the great toe, and about the sixth year
in the othei four. The epiphysary points of the phalanges are not united to the bodies
until the age of seventeen or eighteen years.
General Development of the Inferior Extremity.
The most characteristic feature of the lower extremity in the foetus is the comparative
Sateness of its development, which is most remarkable at the early periods. We have
* This exception corresponds entirely with that observed in the hand, and renders the analogy between the
metatarsal bone of the great toe and the metacarpal of the thumb extremely close ; for the same reason, both
of these bones resemble tke first phalanges of the fingers. I may add, that, in some subjects, it has appeared
to me that there was a very thin epiphysary point at the digital extremity of this bone, which soon united tn
the body
COMPARISON Oi' THE EXTREMITIES. 106
already stated the periods at which each point of ossification appears in the diiferent
bones, and the times at which they are united, and it now only remains for us to point
out some peculiarities of development which have not been included in the description
of the bones.
From the observations of Bichat, it is generally admitted that the neck of the femur
in the foetus and the newly-born infant is proportionally shorter than in the adult, and
forms ahnost a right angle with the shaft of the bone ; that the body of the femur is al-
most straight ; and that its extremities are proportionally much larger than they become
subsequently. As we before observed with regard to the upper extremities, all these
assertions are at variance with the results of our observations. The same reflections
apply equally to the bones of the leg, the torsion of which we believe to exist to the same
degree in the foetus and in the new-bom infant as in the adult.
After birth, the development of the lower limbs proceeds more rapidly than that of the
upper, and the final proportions are not attained until the age of puberty. In the aged,
the phalanges of the toes are often anchylosed ; but this union, like the dislocations of
the toes, and some deformities of the tarsus and metatarsus, are the results of pressure
upon the foot occasioned by tight shoes, and the more or less complete immobility in
which the parts are maintained.*
Comparison of the Superior and Inferior Extremities.
We have hitherto omitted the applications of that species of comparative anatomy by
which different organs of the same animal are compared with one another. Those anal-
ogies which exist between the various parts that compose the trunk could not, with pro-
priety, be included in a work on descriptive anatomy. But we do not deem it proper to
apply the same rule to the parallel between the upper and lower extremities ; for that is
founded on such numerous and striking points of analogy, and has become so much a
subject of instruction, that we should consider it a serious omission did we here neglect
giving a brief notice of it.
The upper and the lower extremities are evidently constructed after the same type,
but present certain modifications corresponding to the difference of their functions. I
should remark in this place, that some of these analogies are very manifest and satis-
factory, and greatly facilitate the remembrance of important anatomical details ; while
others are far-fetched, and wholly destitute of useful application : these will be passed
over with a simple notice. We shall now compare in succession the shoulder and the
haunch, the humerus and the femur, the forearm and the leg, the hand and the foot.
Comparison of the Shoulder and the Pelvis.
Before the time of Vicq-d'Azyr, anatomists were in the habit of considermg the clavi-
cle and the scapula among the bones of the upper extremity, but regarded the os innom-
inatum or haunch as belonging to the trunk ; and yet the most simple reflection is suf-
ficient to establish the analogy between the shoulder and the haunch. In order the
more readily to appreciate the points of resemblance and difference between these parts,
it is advisable to follow the method adopted by Vicq-d'Azyr, of studying the shoulder
reversed ; or, what is the same thing, to compare the aspect of the shoulder which cor-
responds to the head, with that of the pelvis which answers to the coccyx ; remember-
ing, at the same time, that, for a long period after birth, the haimch bone is formed of
three distinct pieces, the ilium, the ischium, and the pubes.
1. The shoulders form an osseous girdle, intended to form a point of support for the
upper extremities, in the same manner as the haunch does for the lower extremities.
The girdle formed by the shoulders is interrupted in front in the situation of the sternum,
and behind, opposite the vertebral column ; hence there are two shoulders, while the
haunch bones constitute one united whole. The shoulder, therefore, and, consequently,
the arm of one side, are completely independent of those of the other, but the two lower
extremities have a sohd bond of union.
2. The second point of difference relates to the comparative dimensions of the pelvis
and the shoulder. The great size of the pelvis, the thickness of its edges, the depth of
its notches, and the prominence of its eminences, contrast strongly with the slender
construction of the shoulder, and the thin edges of the scapula, and are in harmony with
the uses of the lower extremities.
3. The broad portion of the scapula is analogous to the iliac portion of the os innom-
inatum ; the internal iliac fossa is analogous to the subscapular fossa.
4. The supra and infra-spinous fossae correspond to the external iliac fossa ; but the
iliimi has no part analogous to the spine of the scapula.
5. The axillary border of the scapula answers to the anterior edge of the os innomi-
natum. The spinal border is analogous to the crest of the ilium. The superior border
* On thi» subject the reader may consult a very curious memoir, by Camper, on the inconveniences arising
from tight shoes, to which he attributes, 1. The shortening of the second toe ; 2. The partial luxation of some
of the tarsal bones. To this vie may add the luxation, outward, of the first phalanx of the great toe ; and the
luxation, inward, of the first phalanx of the second, and sometimes of the third toe.
o
106 OSTEOLOGY.
of the scapula corresponds to the posterior border of the os innominatuin ; and the cora^
coid notch on this border, with the coracoid hgament which converts it into a foramen,
are analogous to the sciatic notch, and the sacro-sciatic ligaments.
6. The glenoid cavity is evidently analogous to the acetabulum ; according to Vicq-
d'Azyr, the coracoid and the acromion processes are represented by the tuberosity of
the ischium and the pubes, with this remarkable difference only, that the two processes
of the shoulder are separated from each other by the large acromio-coracoid notch, while
in the pelvis the iscliium and the pubes are united, and, instead of including a notch,
form the circumference of a foramen, the obturator. This analogy is not universally
admitted ; for the ischium, being intended to sustain the weight of the body when sit-
ting, bears no resemblance in this respect to the shoulder. One of the most striking
analogies between the shoulder and the pelvis is that of the clavicle and the horizontiS
portion of the pubes ; with this difference, that the clavicle is articulated with the scap-
ula, while the pubes is united by bone to the ilium. Without forcing an analogy, we
may trace a similitude between the symphysis pubis, and the union of the clavicles by
means of the interclavicular ligament.
Comparison of the Arm Bone and the Thigh.
In order to make the parallel exact, we must remember the relative situation of the&o
two bones, and compare the right femur with the left humerus ; and the side of flexion,
that is, the posterior aspect of the first, with the side of flexion, or the anterior aspect of
the second. This being determined, we must place the linea aspera of the femur in front,
and the himierus in its natural position. The humerus is much smaller than the femur,
being about a third shorter, and only half the weight and bulk. The humerus is placed
vertically, and almost parallel to the axis of the trunk ; in this it contrasts with the
marked obliquity of the thigh bones, which touch each other at their lower ends. The
humeri are separated from each other by a greater distance than the femora ; this differ-
ence depends on the conformation of the human thorax, which is flattened in front and
behind, while in quadrupeds it is flattened on the sides, and permits the approximation
of the humeri, which serve as pillars of support to the fore part of the trunk.
The humerus is not curved like the femur, but, on the other hand, it is much more
twisted, and presents an oblique groove, which does not exist in the femur. We shall
compare in succession the shafts and the extremities of these bones.
1. Comparison of the Shafts. — -The posterior surface of the humerus exactly corresponds
to the anterior surface of the femur, being, like it, smooth and rounded. The external
surface resembles the external plane of the femur, with some differences ; the impres-
sion for the gluteus maximus is evidently analogous to the deltoid impression. The in-
ternal surface is in contact with the brachial artery, as is the internal surface of the
femur with the femoral artery. The anterior edge is a sort of linea aspera, analogous
to that of the femur, and, like it, terminating by a bifurcation at its upper part.
2. Comparison of the Loicer Ends of the Bones. — Although the differences between
these parts are very marked, we can yet detect, in the one bone, traces of all the more
important points of structure observed in the other. Thus, the internal and external
tuberosities of the humerus evidently resemble those of the femur, and they are both
intended for the insertion of muscles and ligaments. The trochlea of the humerus re-
sembles that of the femur, with this difference, that, in the femur, the two borders of
the pulley diverge from each other behind, while in the humerus they are parallel through-
out. In front and behind the femoral trochlea, we find depressions, wliich are manifestly
analogous to the coronoid and olecranal fossae of the humeral trochlea. Lastly, without
admitting any fundamental difference, we may explain the existence of the small head
of the humerus, for which there is no representative in the femur, by a reference to the
fact, that both bones of the forearm unite with the humerus, while only one bone of the
leg articulates with the femur.
Comparison of the Upper Ends. — As in the femur, we find in the humerus a segment
of a spheroid, or a head, supported by a neck, of which, however, there is only a trace ;
and two tuberosities, which are analogous to the trochanters, and, like them, give at-
tachment to the rotator muscles of the Umb. In the humerus, however, the two pro-
cesses are much more closely approximated, being only separated by the bicipital groove.
Lastly, the great tuberosity of the humerus causes the prominence of the shoulder, in
the same manner as the great trochanter causes the prominence of the hip.
Comparison of the Leg and Forearm.
The forearm is that portion of the upper extremity which is represented by the leg in
the lower. Each is composed of two bones ; but while the leg is essentially constitu-
ted by the tibia, which alone enters into the formation of the knee-joint, and the greater
part of the ankle-joint, both the radius and the ulna contribute, almost in an equal degree,
to that of the forearm ; and although the ulna forms the greater part of the elbow-joint,
the radius, by a sort of compensation, is the chief bone of the wrist-joint.
Although the general analogy between the forearm and leg is sufficiently striking, it js
COMPARISON OP THE EXTREMITIES. 107
not so easy to trace the corresponding parts in detail. Anatomists are much at variance
on this subject, particularly as to which bone of the forearm corresponds to the tibia.
Vicq-d'Azyr, from a consideration of the elbow and the knee joints, came to the con-
clusion that the ulna is analogous to the tibia, and the radius to the fibula. M. de Blain-
Tille, on the contrary, reflecting on the relations between the leg and foot, and the fore
arm and hand, and considering that the tibia is placed on the same line with the great toe,
and the radius with the thumb, and also that in the forearm the radius constitutes the
chief part of the wrist-joint, and that in the leg the tibia is most concerned in the ankle-
joint, is of opinion that the tibia and the radius are analogous parts.
We shall adopt what is true in either opinion, and reject what appears to us too un
conditionally stated or incorrect ; and, therefore, considering, 1. That neither of the bones
of the leg resembles, by itself, one of the bones of the foreann ; 2. That each bone of the
leg has some characters, both of the ulna and of the radius ; 3. That the natural position
of the forearm being that of pronation, and that the leg being in a state of constant pro-
nation, it is incorrect to compare the forearm when supinated with the leg when in the
opposite position ; 4. That comparative anatomy has shown, in ruminating animals, the
upper extremity of the ulna to be blended with the radius, and a slender process on the
external aspect of the forearm resembUng the fibula, we are inclined to believe that the
upper end of the tibia is represented by the upper lialf of the ulna, and the lower half of
the tibia by the lower half of the radius ; while the fibula is represented by the upper part
of the radius and the lower part of the ulna. If we enter into details, we shaU see how
plausible this comparison is in reality.
Comparison of the Upper Half of the Ulna and the Upper Half of the Tibia.
The horizontal portion of the great sigmoid cavity of the ulna is represented by the
upper end of the tibia, and the crest which separates the two surfaces of the cavity is
analogous to the spine of the tibia. The patella and the olecranon are constructed after
the same type ; the mobility of the first, and the fixture of the last, are not essential dif-
ferences. The body of the ulna is prismatic and triangular, like that of the tibia ; its in-
ternal surface is superficial and almost subcutaneous, like the anterior surface of the
tibia ; its posterior edge (crest of the ulna) is prominent, and represents the crest of the
tibia ; it is equally superficial, and serves as a guide in the diagnosis and coaptation of
fractures. As in the tibia, the crest of the ulna is continuous with a triangular tuberosity,
which may be called the posterior tuberosity of the ulna, and is analogous to the anterior
tuberosity of the tibia.
Comparison of the Lower Part of the Radius and the Lower Part of the Tibia.
The quadrangular lower end of the radius corresponds to the equally quadrangulai
lower extremity of the tibia. The inferior articular surface of both is divided into two
parts, by an antero-posterior ridge. The ulnar side of the lower end of the radius is
hollowed into an articular cavity, in the same way as the fibular side of the lower end
of the tibia. The styloid process of the radius answers to the internal malleolus of the
tibia. Both extremities exhibit furrows for the passage of tendons.
Comparison of the Hand and Foot.
The back of the foot corresponds with the back of the hand, the sole with the palm, the
tibial edge of the one with the radial edge of the other ; the fibular and the ulnar borders
are analogous ; the tarsal extremity of the foot corresponds with the carpal extremity of
the hand, and each has a digital extremity. But amid these features of resemblance,
which are sufficient to establish the old adage, pes altera manus, we find also great dif-
ferences. Thus the foot exceeds the hand both in size and weight, being longer and
thicker, though it is narrower : this excess of volume does not affect the toes, which are
mcomparably smaller than the fingers ; nor the metatarsus, but is confined to the tarsus,
of which the carpus seems little more than a vestige. A second characteristic differ-
ence is the absence of the power of opposition in the great toe. As far as regards func-
tion, indeed, it may be truly said, that the want of this power constitutes a foot, and the
Eossession of it a hand. A third difference results from the mode of articulation of the
jg with the foot, for the leg does not articulate with the posterior extremity of the tar-
sus, but Avith its upper surface, so that a part of the tarsus projects behind the joint, and
the axis of the foot forms a right angle with that of the leg. These remarks will suffice
to show the general differences between the hand and the foot.
Comparison of the Bones of the Carpus and Tarsus.
While the carpus scarcely forms the eighth part of the hand, the tarsus constitutes
half the foot. Its antero-posterior diameter, which is five or six inches, is three times
greater than the transverse diameter, precisely contrary to what is the case in the hand.
The tarsus resembles a vault, concave below, both in the antero-posterior and transverse
directions, and receives the leg upon its summit. The carpus is nothing more than a
groove for tendons. It is manifest that the carpus is only the rudiment of the tarsus,
which is not surprising, if we consider that the former is truly the fundamental part of
lOS OSTEOLOGY.
the foot, and the basis of support to the whole body. We shall examine in detail the
analogies and the differences of these two constituent parts of the foot and the hand.
They differ in the following respects : 1. There are eight bones in the carpus : there are
only seven in the tarsus. 2. Each of the two rows of the carpus is composed of four
bones : the first row of the tarsus consists of two bones, and the second of five ; 3. The
bones of the first row of the tarsus are placed one above the other, not arranged side by
side as in the first row of the carpus. 4. One tarsal bone only enters into the formation
of the ankle-joint, while three of the carpal bones are concerned in the wrist-joint : last-
ly, the second row of the tarsus is subdivided into two secondary rows on the inside, a
posterior, formed by the scaphoid, and an interior, formed by the three cuneiform bones.
We shall now compare the bones of these two regions, and for the want of their re-
semblance in shape, we shall have recourse to that of their mode of connexion — a meth-
od which is, perhaps, more constant and important than that which is founded upon a
character so variable as figure.
Comparison of the Metatarsal Row of the Tarsus with the Metacarpal Row of the Carpus.
The metatarsal and the metacarpal rows are evidently more analogous to each other
than the first rows of each region, and have, therefore, been chosen for the purpose of
establishing the parallel.
1. The cuboid is manifestly analogous to the os unciforme ; their relative positions
are the same ; their forms are, in a great measure, similar ; and while the cuboid is at-
tached to the last two metatarsal bones, the os unciforme articulates with the last two
metacarpal. This analogy being admitted, we shall find in the three cuneiform bones
the representatives of the three other bones of the second row of the carpus, viz., the
trapezium, the trapezoid, and the os magnum.
2. We must admit here that the analogies now become much less evident. Never-
theless, the third cuneiform bone, which, from being in contact with the cuboid, should
represent the os magnum, which is contiguous to the os unciforme, does so far agree,
that it articulates with the third metatarsal bone, as the os magnum does with the third
metacarpal ; and, what is sufficiently remarkable, the third cuneiform has a slight con-
nexion with the second metatarsal, as the os magnum has with the second metacarpal.
Although, therefore, we do not find in the third cuneiform bone anything approaching
to the size of the os magnum, or resembling the remarkable head of that bone, we should
not, on that account, hastily conclude that they have no analogy. We shall explain af-
terward how this fact should be interpreted : we only wish it to be admitted in this
place, that the base or metacarpal portion of the os magnum is represented by the third
cuneiform bone.
3. The second cuneiform bone, which corresponds to the trapezoid, supports the sec-
ond metatarsal, as the trapezoid supports the second metacarpal.
4. The first cuneiform bone, which supports the first metatarsal, corresponds to the
trapezium, which supports the first bone of the metacarpus. All these analogies, it must
be confessed, are very imperfect, and founded rather upon the connexions than the forms
of the different bones. In fact, what resemblance is there between the three large cu-
neiform bones all cut into facette-like wedges, and all so like each other in shape, and
the bones of the carpus, to which we have compared them 1 Above all, what compari-
son can be established between the third cuneiform, which exactly resembles a wedge,
and the os magnum, which has a rounded head 1 There is nothing in the metatarsal
range of the tarsus which represents the rounded head which belongs to the metacarpal
row of the carpus ; but the following considerations, which did not escape the notice of
Vicq-d'Azyr, will serve to solve the difficulty.
1. It is an observation which apphes with sufficient generality to the whole skeleton,
that when two bones move upon each other, one being provided with a head, and the
other with a cavity, the head moves upon the cavity, not the cavity on the head. Thus,
the femur moves upon the os innominatum ; the humerus upon the scapula. 2. The hand,
in the performance of its functions, almost always moves upon the forearm. In the move-
ments of the hand, the metacarpal row of the carpus moves upon the first row, and
therefore the metacarpal row presents the head. On the contrary, in the movements of
the bones of the tarsus during progression, the bones of the first row always move upon
those of the second or metatarsal row ; and consequently, instead of finding a rounded
head in the second row, we meet with it in the first.
Proceeding thus by the method of exclusion, it now only remains for us to establish
the analogy between the bones of the first row of the carpus on the one hand, and the
scaphoid, the os calcis, and astragalus on the other. The analogies here are very equiv
ocal, and are not agreed upon among anatomists.
Comparison of the First Row of the Tarsus with the First Rmo of the Carpus.
As there are only three bones in the posterior row of Uie tarsus which correspond to
the antibrachial or superior row of the carpus, it might be supposed, d priori, that one of
these would correspond to two of the bones of the first row of the carpus. A verv slight
COMPARISON OP THE EXTREMITIES. 109
examination of the tarsus and the carpus in a quadruped will show at once that the
pisiform bone is represented by that part of the os calcis which projects behind the as-
tragalus. The OS calcis is the only bone of the tarsus which is developed from two
points ; and this establishes a strong presumption in favour of the opinion that it repre-
sents two bones. If we admit the analogy of the back part of the os calcis with the pi-
siform bone, the anterior portion of this bone would represent the cuneiform or pyram-
idal bone of the carpus ; and as this last articulates with the os unciforme, so the an-
terior portion of the os calcis unites with its representative, the cuboid. The os calcis,
then, may be considered as representing the cuneiform and the pisiform bones blended
together, and much augmented in size.
It remains, then, to establish the analogy between the scaphoid and semilunar bones of
the hand, and the astragalus and scaphoid of the foot.
The scaphoid of the hand resembles the scaphoid of the foot, both in form and con-
nexions. The similarity of shape has led to the identity of name ; and, with regard to
connexions, we find that the scaphoid of the foot is attached to the three cuneiform
bones, and that of the hand to the trapezium, the trapezoid, and the os magnum, which
represent the three cuneiform bones ; and, lastly, we observe that the scaphoid bone of
the foot is placed on the same side as the great toe, and that the scaphoid bone of the
hand is placed on the same side as the thumb. There is, however, one remarkable dif-
ference between them, viz., that the scaphoid bone of the hand articulates with the fore-
arm, while that of the foot has no connexion with the leg.
"We have now only to discover in the tarsus the representative of the semilunar bone.
All the rest of the bones being now excluded, we can only conclude, with Vicq-d'Azyr,
that the astragalus is its counterpart, with the mere addition of a rounded head.
Comparison of the Metacarpus and the Metatarsus.
Five small long bones, arranged parallel to eacli other, form both the metacarpus and
the metatarsus. In both there are four interosseous spaces : these are larger in the
hand than in the foot, because there is a greater disproportion between tlie bulk of the
extremities and shafts of the metacarpal than of the metatarsal bones : the metacarpus,
from being shorter, appears broader than the metatarsus. The most distinguishing char-
acter of the metacarpus is the fact, that the metacarpal bone of the thumb is the short-
est of the whole, and is situated on a plane anterior to the others, and that its direction
is oblique, aU which circumstances bear reference to the movement of opposition, which
is peculiar to the hand. The characteristic mark of the inetatarsus is the size of the
first metatarsal bone, which greatly exceeds that of all the others. The great size of
the tarsus is continued in this bone and the great toe, on account of the important part
they perform in the mechanism of standing. There is so great a resemblance between
the other metacarpal and metatarsal bones, that some attention is necessary in order to
distinguish between them. 1. The metatarsal bones gradually diminish in size from
their tarsal to their digited extremities ; the metacarpal bones, on the contrary, are most
expanded at their digital ends. The metacarpal are shorter and thicker ; the metatar-
sal longer and more slender. The shaft of the metacarpal bones is pretty regularly pris-
matic and triangular ; that of the metatarsal, on the contrary, is compressed or flatten-
ed on the sides. 2. There are no well-marked differences between the carpal extremi-
ties of the metacarpal bones and the tarsal extremities of the metatarsal ; but the lat-
ter are larger than the former, which agrees with the greater dimensions of the tarsus.
3. The tarsal extremities are more regularly cuneiform than the corresponding ends of
the metacarpal bones.
The most characteristic differences, however, of these two series of bones are found
in the digital extremities, which are incomparably larger in the metacarpus than in the
metatarsus, the fingers being the chief part of the hand, while the tarsus is the principal
portion of the foot. We should also remark, that the convex articular surfaces of the
digital ends of the metatarsal bones are prolonged farther on the dorsal aspect than the
corresponding surfaces of the metacarpal bones.
Comparison of the Phalanges of the Fingers and Toes.
The fingers, being the essential organs of prehension and the fundamental part of the
hand, greatly exceed the toes both in length and thickness, and the latter may be looked
upon as representing in rudhnent the former, being precisely analogous in structure.
The phalanges of the toes may, therefore, be regarded as phalanges of the fingers in
a state of atrophy ; but the great toe forms a remarkable exception to this rule, for its
phalanges are much larger in proportion to the other toes than the phalanges of the
thumb are to the other fingers. This magnitude of the great toe corresponds to the size
of its metatarsal bone, and accords with its destination, as constituting the principal sup-
■^rt for the weight of the body in front. The first phalanx of the toes exactly resembles
the first phalanx of the fingers in all things but volume. The middle phalanx of the toes
can scarcely be recognised, from its diminutive size : it may be said to want the shaft al-
together, the extremities being in contact. As we have already^remarked, it might at
110 OSTEOLOGY.
first sight be confounded with a pisiform, or a sesamoid bone, or still more readily with
a piece of the coccyx.
Comparison of the Upper and Lower Extremities with regard to Development.
The development of the lower extremities is proportionally less rapid than that of the
upper. The clavicle and the scapula are ossified before the os innominatum. The os-
sification of the skeleton commences in the clavicle ; in this bone, the osseous nodule is
visible from the twenty-fifth to the thirtieth day ; it appears in the scapula about the for-
tieth day. The osseous point of the ilium is visible about the forty-fifth day, that of the
ischium in the third month, and that of the pubes in the fifth month. The scapula is
completely ossified at the age of twenty years ; the marginal process of the crest of the
ilium is scarcely united until the twenty-fifth year. The bony centres of the shafts of
the femur and humerus are almost simultaneous in their appearance. The germ of the
lower end of the femur always exists at birth ; that of the lower end of the humerus does
not appear until the end of the first year ; but this latter unites with the bone at eighteen
years, while the former is still separate at twenty years. The tibia is ossified a little be-
fore the bones of the forearm, the fibula a little after them. The ossification of the leg
and the forearm is completed almost about the same time. The ossification of the bones
of the tarsus precedes that of the carpus by a considerable period. Thus, at from foui
and a half to five months of foetal life, a bony point is visible in the os calcis, and some
days after in the astragalus ; the os magnum and os cuneiforme (which, however, ar«
not the representatives of the preceding) do not show ossific points until a year after
birth. The pisiform bone is not ossified until the twelfth year ; while the latest of the
tarsal bones, the scaphoid, is converted into bone at the fifth year. Nevertheless, the
epiphysary point of the os calcis (which we have shown to be analogous to the pisiform
bone) does not become visible until the tenth year ; this fact strengthens the analogy
between the pisiform bone and the epiphysary lamina of the os calcis.
The metatarsal bones are developed in exactly the same manner as the metacarpal,
only at a somewhat later period. The union of the epiphyses takes place a little earlier
in the metatarsus than in the metacarpus. The toes are ossified at a later period than
the fingers ; especicdly the ungual and the second phalanges, which are much later than
those of the fingers.
It is, no doubt, impossible to state the precise reason for these differences ; but it is
sufficient to find a positive relation between the rate of development of these parts, and
the offices they are intended to fulfil.
The Os Hyoides, or the Hyoid Apparatus* (fig. 57).
The OS hyoides has a parabolic form, resembling the upsilon of the Greeks, whence its
name. It is the only bone which is detached from the rest or
Fig. 57. ^ the skeleton ; it is connected only by ligaments and muscles, and
is situated between the base of the tongue and the larynx. It is
larger in the male than in the female. It is placed almost hori-
zontally, the concavity of its curve looking backward, and the
convexity forward.
This bone is divided into five parts ; viz., a body or middle
part (a), ani four cornua, two large (J) and two small (c). This
multiplicity of parts, which is much greater in some animals, es-
pecially fishes, justifies the name of " hyoid apparatus," which
we have adopted.!
The body of the os hyoides (a) is quadrilateral, elongated, and curved, with the cavity
behind. Its anterior surface looks upward, and presents a crucial projection, the vestige
of a process which in many animals is prolonged into the substance of the tongue. This
projection gives attachment to several muscles, the insertions of which are marked by
transverse lines, interrupted by tubercles. The posterior surface, more or less excavated
in different individucds, is sometimes connected with a yellow ceUular tissue, which sep-
arates it from the epiglottis, and is sometimes covered by a synovial membrane. Its ex-
cavation, which is never very great in man, is the vestige of the enormous cavity which
exists in the hyoid of the Howler monkey. The lower edge gives attachment to the thy-
ro-hyoid muscle only. The upper edge gives insertion to a yeUow membrane, a sort ol
ligament which stretches into the tongue ; and also to the yeUow thyro-hyoid ligament,
which has been incorrectly stated to be inserted into the lower edge of the bone. The
extremities of the body of the os hyoides are covered by cartilage for articulation with
the great cornua.
The great cornua or rami {b) are much longer than the body, and flattened above and
below, while the body is compressed from before backward. They are expanded at the
place where they articulate with the body, pass backward, and, after being contracted
* I have introduced the description of the os hyoides into this place, because, although chiefly belonging to
the tongue, it gives attachment to several muscles, and, therefore, should be previously knovfn to the student
t Vide M QeofFroy Saint-Hilaire, on the anterior bones of the chest. — {Philos. Anat., vol. i., p. 139.)
THE ARTICULAR CARTILAGES. HI
and flattened, terminate in a rounded tubercle, which is sometimes surmounted by an
epiphysis. ♦
The little comua (c) are called also styloid cornua, because they are connected with the
styloid process by means of a ligament. They are two pisiform nodules at the point of
junction of the great comua with the body of the hyoid {ossa pisiformia lingualia of
Soemmering). They surmount the upper edge of the bone, and are directed upward and
outward ; their length is very variable. In the lower animals, the prolongations which
correspond to these httle cornua are much longer than the great cornua in man. They
articulate by their lower end with the body and the great cornua. Their upper part gives
attachment to a ligament, which unites it with the styloid process. This ligament
which is sometimes ossified in man, is always a bony connexion in the lower animals.*
Internal Structure. — The hyoid bone is composed chiefly of compact tissue ; but there
is a small quantity of spongy tissue in the thick parts of the body and the great cornua.
Development. — The os hyoides is developed from five points ; one for the body, two for
the great comua, and two for the little cornua.. Some anatomists admit two points for
the body, and make the whole number six.
The ossification of the great cornua precedes that of the body, which becomes bony
soon afl;er birth ; the little cornua are not ossified until some months afl;er. All the pie-
ces are at first separated by considerable portions of cartilage, afterward by a very thin
layer, which sometimes remains during life, and gives the different parts of the bone a
great degree of mobility.
THE ARTICULATIONS, OR ARTHROLOGY.
General Observations. — Articular Cartilages. — Ligaments. — Synovial Membranes. — Classi-
fication of the Joints. — Diarthroses. — Synarthroses. — Amphiarthroses, or Symphyses.
The bones are united together by the joiTits or articulations. The study of these parts
is the object of syndesmology, or, more properly, of arthrology {apdpov, a joint). In exam-
ining each joint, it is necessary to consider, 1. The contiguous surfaces of the bones, or
the articular surfaces ; 2. The uniting medium, or the ligaments ; 3. The means or condi-
tions which facilitate the motion of the parts, the syiwvial membranes ; and, 4. The move-
ments of which the joint is capable, t
It is impossible to insist too much upon the importance of a careful study of the artic-
ulations. There is no part of anatomy a thorough knowledge of which is more indis-
pensable both to the physiologist and the surgeon ; without it the former cannot form a
correct idea of the animal mechanism, nor can the latter appreciate the nature of those
numerous injuries and diseases of which the articulations are the seat.
Before describing the forms and the motions of the different joints, it is necessary to
give a general idea of the articular cartilages, the synovial membranes, the hgaments,
&c. ; in short, of all the means which contribute to secure the solidity and mobility of
the articulations.
The Articular Cartilages.
It has been observed,t that when two osseous surfaces in immediate contact rub upon
each other, they are gradually absorbed in such a manner as to render the movements
between them diflicult and painful. In order to avoid these injurious effects in the joints,
the contiguous surfaces of the bones are covered by a layer of cartilage (the incrusting
or articular cartilage), a substance which unites in itself the qualities of solidity, pliability,
and elasticity in a high degree, yielding when compressed, and returning to its former
state when the pressure is removed. These articular cartilages exist in all the mova-
ble joints. The extent of surface which they cover is generally proportioned to the ex-
tent of motion in the joints. Their thickness is generally greatest when the bones
which they cover are most movable,' and most subjected to pressure. An articular car-
tilage is not of uniform thickness throughout. Thus, on convex surfaces, the cartilagi-
nous layer is thicker in the centre than at the circumference ; and, on the other hand, the
cartilages of articular cavities are thickest at the circumference. The most perfect co-
aptation results from this arrangement. It should also be remarked, that the most vio-
lent shocks are applied to the centre of the heads of the bones, and to the circumference
of the cavities.
The articular cartilages present, 1. A free surface, perfectly smooth and polished, which
is in the interior of the articulation ; 2. An adherent surface, which is so closely attached
* In the lower animals, the styloid process is detached from the cranium, and forms one of the hyoid chain
of bones, which is composed, 1. Of the five pieces of the os hyoides ; 2. Of the bones which supply the place
of the styloid ligaments ; 3. Of the styloid processes, or, rather, bones : nine pieces in all.
t Three of these, viz., the configuration of the articular surfaces, the ligaments, and the niovements of the
joint, are essentially related to each other; so that we may deduce, <i priori, the means of union, and the
movements of any joint, from the shape of the articular surfaces, and vice verscL.
% Absorption of the cartilages is a frequent disease of the joints, and obliges the individuals affected by h
to maintain constant rest
112 ARTHROLOOy.
to the tissue of the bone, that it is impossible to separate it excepting in cases of disease.
In some cases of white swelling, I have been able to remove the articular cartilages with
great facility, and in these it appeared that the adherent surface of the cartilage was
very irregular, and that the fibres of the bone were implanted in it by innumerable small
prolongations.
Tliere is another kind of cartilage existing in certain joints, in the form of thin plates,
having both surfaces free, and being interposed between two articulating bones. These
are generally found in such joints as are exposed to the most violent shocks, and sub-
jected to the most frequent movements ; they are known by the name of inter-articular
cartilages. Their use is to adjust the contact of the surfaces on the bones, to moderate
the intensity of the shocks to which they may be submitted, to increase in some cases
the depth of the articular cavities, and to impart solidity to the joints. They are almost
always bi-concave, from which circumstance the name of meniscus is sometimes applied
to them (from iirjvrj, lund) ; they are thick at the circimiference, and very thin in the cen-
tre, which is sometimes perforated.
These two kinds of cartilage are found only in those joints the surfaces of which are
simply in contact.
The articulations of continuous surfaces are provided with cartilages very different
from the above, and which should be looked upon as non-ossified portions of the original
cartilage of ossification. The progress of ossification always encroaches upon them,
while the regular articular cartilages are never affected in this way. It will be seer
afterward that the articular cartilages are inorganic, like the enamel of the teeth, anc
the horny tissues, which are worn away by attrition, and are not susceptible of any le
sions, excepting such as arise from mechanical injury or chemical action.*
The Articular Ligaments.^
The ligaments constitute a very important division of the fibrous tissue, which is met
with in all parts where great resistance and great flexibility are required, and in no part
of the body are these requisites more necessary than in the joints. They consist of
bundles of flexible and inextensible fibres of a pearly- white lustre, sometimes parallel
and sometimes interlaced. Sometimes tliey are placed between the osseous surfaces^
and are then named interosseous ; sometimes, on the contrary, they occupy the circum-
ference of the surfaces, and are then called peripheral or capsular. The peripheral liga-
ments present two surfaces : a deep surface, lined by the synovial membrane, which is
intimately united to it, and which is so delicate that were it not from its development in
disease, its existence here might be doubted ; and a superficial, which is in contact with
the muscles, tendons, nerves, vessels, and cellular tissue, in a word, to all the structures
which surround the articulations ; and also tico extremities, which are attached to the
bones, at a greater or less distance from the cartilage. The adhesion of these parts is
so intimate, that it is easier to break either the ligament or the bone than to separate
them at the precise place of their union.
The ligaments may be classed under two very distinct heads : 1. The fasciculated, or
those which exist in bundles ; and, 2. The membranous or capsular. The ligaments,
properly so called, belong to the first class ; the fibrous capsules belong to the second.
We may admit a third form, which consists of scattered fibres, too far separated to
form fasciculated ligaments, and too few in number to constitute articular capsules. We
should include, also, in the class of articular ligaments, two very remarkable modifica-
tions of the fibrous tissue: 1. The articular borders; these are circlets of fibres which
sunnountthe margins of articular cavities, belonging to that class of joints denominated
enarthroses ; they augment the depth of the cavities, and act as a kind of pad to break
the force of impulsion of the articular head against the brim of the cavity, and prevent
this edge from breaking. 2. The yellow or elastic ligaments, which are characterized by
their yellow colour, extensibility, and elasticity ; hence the name of yellow elastic tissue
has been given to them, on account of their colour and chief property.
The Synovial Membranes^ or Capsules.
In every part of the body where fibres move, they are surrounded by cellular tissue,
which secretes a lubricating fluid to facilitate their motions ; and, where surfaces move
upon each other, they are covered by a membrane which exudes a fluid, varying in its
nature according as the motions are confined to simple gliding, or are accompanied by a
certain amount of friction. In the first case, the membranes secrete a watery or serous
fluid, and are, consequently, denominated serous membranes ; in the second, the liquid is
of an unctuous nature, resembling white of egg ; it is called synovia (avv, with, and u6v,
an egg), and the membrane synovial membrane. All the movable articulations are pra
* [Though the articular cartilages may be non-vascular, it is scarcely correct to say that they are unor-
ganized.]
t The word ligament, ovvlea/ios of the Greeks, copula or vinculum of the Latins, is applied, in anatomy, to
any structure which serves to unite different parts to each other. In this sense we speak of the broad and the
round ligaments of the uterus, the ligaments of the bladder and of the liver. Taken in its most limited aeamtt
this name applies exclusively to the articular ligaments.
CLASSIFICATION OF THE JOINTS. 113
Tided with a synovial membrane or capsule, by means of which the parts are constantly
lubricated with a viscid, unctuous fluid, that favours the exact adaptation of the articular
surfaces, obviates the effects of friction, and maintains them in contact. This is the
cause of the noise or cracking which results from the sudden separation of the articulai
surfaces.
The synovial capsules, which have been well described by Monro, are thin, transparent
membranes, forming shut sacs, which cover the heads of the bones without admitting
them into the interior of the cavity. In fact, it is their external surface which adheres
more or less intimately to the ligaments and other parts which surround the joint, while
their internal surfaces are in contact with each other, and are constantly lubricated by
the synovia. It is a question among anatomists whether the synovial membrane covers
also the articular cartilages. It can only be traced by the knife as far as the circumfer-
ence of these cartilages, and if it exists on them, which analogy would lead us to be-
lieve, it is so completely modified as not to be recognisable. Without admitting or de-
nying the fact, for the sake of facility in description, we shall assume the continuity of
this membrane over the cartilages. In many joints the synovial membrane is raised
from the surface of the parts by a subjacent cushion of fat, which projects into the joint,
and which Clopton Havers imagined to be a gland for secreting the s)Tiovia. I believe
that this, which may be called synovial fatty tissue, is only intended to fill up the spaces
which would otherwise be formed in many articulations during the performance of cer-
tain movements. The synovial fringes, described by the same author as the excretory
ducts of these glands, are nothing more than folds of the membrane.
Classification of the Joints.
The multiphcity of the articulations, and the analogies and differences which they
present, have induced anatomists to arrange them in a determinate number of groups,
having well-marked characteristics. The shape of the articulating surfaces in each
joint, the arrangement of the uniting media, and the variety and extent of motions, being
necessarily correlative, either of these three circumstances may be taken as the basis of
classification. Most of the older anatomists, attending specially to the means of union,
divided the articulations into four classes : 1 . Synchondroses {avv, with, and x6v6po(, a car-
tilage), when the bones are united by means of cartilage ; 2. Syneuroses {avv, with, and
vtvpov, a nerve, the synonyme of ligament among the ancients), when the connexion is
established by ligaments ; 3. Syssarcoses {avv, with, and aup^, flesh or muscle), those
joints in which muscles form the uniting medium ; 4. Meningoscs {fi^viy^, a membrane),
when membranes serve as ligaments, as in the bones of the cranium in infants. This
classification can only be regarded as a rough sketch.
Bichat, fixing his attention entirely upon the movements, has divided the movable
joints according to the variety of motions of which they are capable. There are four
kinds of motion : 1 . Gliding ; 2. The movement of opposition, when a bone is alternately
moved in opposite directions, as in flexion and extension ; 3. The movement of circum-
duction, when the bone which is in motion describes a. cone, the apex of which is at the
joint, and the base is traced by the opposite end of the bone ;* 4. The movement ofrotor
tion, in which a bone rolls on its axis without changing its place.
Proceeding on this classification of the movements, Bichat arranged the articulations
in two great classes, the movable and the immovable. The latter he divided accord-
ing to the nature of the articular surfaces, the former according to the number of mo-
tions, in the following order : 1st class, those joints which are capable of every kind of
motion, viz., gliding, opposition, rotation, and circumduction ; 2d class, those joints which
are capable of all the motions, excepting rotation ; 3d class, those joints which are only
capable of opposition, or alternate motions in the same plane ; ith class, those joints
which admit only of rotation ; 5th class, those joints which are only capable of a gliding
motion. We should observe that gliding occurs in all the preceding forms of articulation.
This classification, which is almost exclusively founded upon a consideration of the
movements, is eminently physiological. For this reason we shall reject it, because, in
the study of anatomy, the consideration of functions is of secondary importance, com-
pared to that of structure. The motions of a joint are also evidently the consequence
of the shape of its articular surfaces.
The classification now genercilly adopted is that of Galen, with some modifications.
Taking the presence or absence of mobility as the primary ground of division, the artic-
ulations are divided into the movable or diarthroses, and the immovable or synarthroses.
To these two great divisions Winslow has added a third, under the name of mixed artic-
ulations, or amphiarthroses {uji^u, both), because they partake of the characters of both,,
viz., mobility, and continuity of surfaces. +
For the determination of the secondary divisions, regard h£is been had both to tha
shape of the articular surfaces, and to the movements of which the joint is capable.
* All the joints which possess the four movements of opposition necessarily possess those of etrcumcvuctton;
t This kind of articulation was known to Galen, and named by him neuter, or doubtful articulation
P
1 14 ARTHROLOGY.
Thus, the diarthroses hare been subdivided iiito, 1. Enarthroses, when the head of one
bone is received into the cavity of another ; 2. Arthrodia, when the articular surfaces are
plane, or nearly so ; 3. Ginglymus, when the joint is only capable of opposition, that is,
of alternate movements in opposite directions in the same plane. This latter class is
again subdivided into (a) angular ginglymus or hinge-joints, when the movements are an-
gular, as in flexion or extension : the angular ginglymus is said to be perfect, when these
movements alone are possible, as in the elbow ; and imperfect, when a slight degree of
later2d motion may take place, as in the knee : (Jb) lateral ginglymus (or diarthrosis tro-
choides), when rotation is the only possible movement. It also is subdivided into simple^
when the bones touch only by one point ; and double, when they have two points of contact.
The synarthroses, or immovable joints, have been divided, according to the nature ot
their articular surfaces, into, 1. Suture, when they are furnished with teeth, by means ol
which they are locked together, as in the squamous suture ; 2. Harmonia, when the sur-
faces are nearly smooth, and are merely in juxtaposition ; 3. Gomphosis, when one part
is implanted in another, as the teeth in the alveoli ; 4. Schindylesis, when a plate of one
bone is received into a groove of another : in this way the osseous projection of the an-
terior edge of the palate bone is attached to the opening of the maxillary sinus.*
There are many advantages in the abov& classification, but many imperfections also.
I would characterize, as especially objectionable, the class arthrodia, which comprises
the most dissimilar articulations, as the shoulder-joint, the articulations of the lower
jaw, of the wrist, of the bones of the carpus, and of those of the tarsus. We should als9
notice, as another cause of imperfection, the want of imity in the basis of the classifi-
cation, which is sometimes founded upon the shape of the surfaces, sometimes on the
motions.
By adopting the shape of the articular surfaces alone as a basis, we shall find the ar-
rangement of the ligaments and the motions to be in some measure dependant upon this.
On this principle, we shall divide all the joints into three classes : 1. The diarthroses
{diapdpovj), or those which are formed by bones the surfaces of which are contiguous,
but free ; 2. Synarthroses {avv, with), or all the joints whose surfaces are continuous ;
3. Amphiarthroses, or symphyses (an<pu, both), or those joints whose surfaces are partly
contiguous, and partly continuous by means of fibrous tissue.
I. Diarthroses.
Characters. — Contiguous or free articular surfaces, shaped so as to fit exactly upon
each other, and each provided, 1. With an incrusting layer of cartilage ; 2. With syno-
vial membranes ; 3. With peripheral ligaments ; joints always movable. This class is
divided into six subdivisions :
1. Enarthrosis.
Characters. — A head, or portion of a sphere, more or less completely received into a
cavity. Examples : hip and shoulder joints (fig. 76, and^«. 69 and 70).
Ligaments. — A fibrous capsule.
Motions. — In every direction ; viz., flexion, extension, abduction, adduction, circumr
duetion, and rotation.
2. Articulation by mutual Reception.
Characters. — Articular surfaces, concave in one direction, convex in the direction per-
pendicular to the first, and so fitted as to embrace each other reciprocally. Example ;
articulation of the trapezium with the first metacarpal bone {m,fig. 75). J
Ligaments. — Two or four ligaments, or, rather, an orbicular or capsular ligament.
Motions. — In all directions, like the enarthroses, excepting rotation.
3. Articulation by Condyles, or Condylarthrosis.
Characters. — An elongated head, or condyle, received into an elliptical cavity. Ex-
amples : articulation of the forearm and hand {fig. 75), of the lower jaw and the temporal
bone {fig. 65).
Ligaments. — Two or four ligaments.
Motions. — In four directions ; viz., flexion, extension, abduction, and circumduction,
but no rotation. There are always two principal movements in these joints, and, con-
sequently, two which are limited.
4. Trochlear Articulation, or Ginglymus.
Characters. — A mutual reception of the articular surfaces. The pulley or trochlea
belongs to this mode of articulation. Examples : the elbow {figs. 71 and 72), the knee
{fig. 78), the joints of the phalanges {figs. 73 and 74).
* [The rostrum of the sphenoid, and the descending plate of the ethmoid, are united in this manner to the
vomer, and afford, perhaps, a better example.]
+ The particle Ita always signifies separation.
i The cervical vrrtebrae of the swan present a beautiful specimen of this kind of articulation. This girei
to the movements of the neck of these birds that elegance and grace for which they are so remarkable.
ARTICULATIONS OF THE VERTEBRAL COLUMN. Il6
Ligaments. — ^Two lateral ligaments generally placed nearer the side of flexion than
that of extension. Sometimes there are likewise anterior and posterior ligaments, but
they are always weak, and are often replaced by tendons.
Motions. — Two motions in opposite directions.
5. Trochoid Articulations.*
Characters. — An axis received into a ring, which is partly osseous and partly fibrous.
Examples : articulation of the atlas and axis (c, fig. 64), of the radium and ulna {figs. 71
and 72).
Ligaments. — ^An annular hgament.
Motions. — Rotation.
6. Arthrodia.
Characters. — Articular surfaces, plane, or nearly so.t Examples: articulations of the
carpal and tarsal bones {figs. 75 and 84), and of the articular processes of the vertebrae {g,figs.
61 and 63).
Ligaments. — Fibres placed irregularly round the joint.
Motions. — Gliding.
II. Synarthroses.
Characters. — Articular surfaces armed with teeth or other inequalities, which are mu
tually dovetailed, and from which the name of suture is derived. Examples : articular
tions of the bones of the cranium {figs. 21, 22, and 23).
Means of Union. — Remnant of the cartilage of ossification, which is gradually en-
croached on during the progress of age.J
There are no incrusting cartUages, synovial membranes, ligaments, nor motions.
Monro enumerates seven kinds of sutures, and these might still be multiplied, if we
regarded all the varieties presented by the articular surfaces. Three kinds may be ad-
mitted with propriety: 1. Indented sutures; 2. Squamous sutures; and, 3. Harmonic sv^
tares ; the distinctions depending upon the articular surfaces being provided with teeth,
or overlapping like scales, or being simply rough and in juxtaposition. These even are
only unimportant varieties. Monro added the schindylesis, or ploughshare articulation
of Keil. We shall content ourselves with simply mentioning it ; and we also omit the
division gomphosis {yofK^oQ, a nail), which is appropriated to the mode of implantation of
the teeth ; because the teeth are not bones, and are lodged in the jaw, not articulated
with it.
III. ^mphiarthroses, or Symphyses.
Characters. — Flat, or nearly flat, articular surfaces, which are partly in contact, and
are partly continuous, by means of fibrous tissue. Examples : articulation of the bodies
of the vertebra {b, fig. 58), symphysis pubis {e, fig. 77), sacro-iliac symphysis {b, fig. 76).
Means of Union. — Interosseous and peripheral ligaments.
Motion. — Very slight, gliding ; an arthrodia is a necessary element of an amphiarthro-
»is. Thus, in the symphysis pubis the bones are partly in contact, partly continuous.
ARTICULATIONS OF THE VERTEBRAL COLUMN.
Articulations of the Vertebrae with each other. — Those peculiar to certain Vertebra:. — Sacro-
vertebral, Sacro-coccygeal, and Coccygeal Articulations. — Articulations of the Cranium —
Of the Face — Of the Thorax.
The articulations of the vertebral column {figs. 58, 59, and 60) are divided into the
extrinsic and the intrinsic. The first comprise the articulations of the vertebral column
with the head, the ribs, and the ossa innominata. The intrinsic comprise the articula-
tions of the vertebrae with each other. These last are also divided into those which are
common to all the vertebrae, and those which are peculiar to some. We shall describe
each in succession.
Articulations of the Vertebrcs with each other.
Mode of Preparation. — Remove completely all the soft parts which surround the ver-
tebral column ; saw ofl!" vertic2illy all that part of the head which is in front of the column,
and separate the bodies of the vertebra from the posterior arches by dividing the pedi-
cles. When the section reaches the axis, carry the instrument behind the superior ar-
* The trochoid (rpfx<u, to turn), or pivot-joint, corresponds to the simple or double lateral ginglymu* of'
modem anatomists, or the rotatory diarthrosis of the ancients.
t These articular surfaces are very variable in the arthrodial articulations. Sometimes they are angular,
sometimes spheroidal. As respects the ligaments, they are sometimes loose, sometimes firm.
t Some anatomists have rejected this kind of articulation, adopting the opinion of Columbus, who affirms
that there can be no joint whe'e there is no motion.
116
ARTHROLOGY.
licular processes of this vertebra, and of the atlas, and behind the condyles of the occipi-
tal cone : remove the spinal marrow^ and its membranes. In this way the vertebral col-
umn will be divided into two parts : an anterior, formed by the series of the bodies of the
vertebra;, on which we find the anterior and posterior common ligaments, and the interver-
tebral substances ; and a posterior, formed by the series of laminae, and the articular and
sj)inous processes. The intervertebral substances require a special preparation, which
consists in making vertical and horizontal sections of a portion of the column, or which
may be more simply effected by maceration in diluted nitric acid, which allows the
bodies of the vertebra; to be removed without injuring the intervertebral substance.
The vertebrae are united, 1 . By their bodies ; 2. By their articular processes ; 3. By their
laminae ; and, 4. By their spinous processes.
Articulation of the Bodies of the Vertebra.
The bodies of the vertebrae are united together by amphiarthrosis. The arthrodial por-
tion, or the contiguous surface, is represented by the articular processes.
The articular surfaces are the upper and under surfaces of the body of each vertebra.
It follows, from the concavity of these surfaces, that, instead of fitting each other exact-
ly, they leave considerable lenticular spaces between them ; these appear to berfhe ves-
tiges of the biconical cavity between the vertebrae of fishes. The depth of these spaces
is not the same throughout the entire column ; it exactly measures the thickness of the
intervertebral substance. By measurement, I have afecertained that the height of the in-
tervertebral substance in the loins is one half of that of the bodies of the vertebra, in the
back one third, and in the neck a little more than the half From the size of the bodies
of the vertebra, it follows that the interval between the bodies is largest in the lumbar re-
gion. The articular surfaces of the bodies of the vertebra are covered by a very thin
layer of cartilage intermediate between the bones and the fibrous tissues.
The means of union are of two kinds, as in all the amphiarthroses : 1. They surround
the joint ; 2. They proceed from one articular surface to the other : in one word, some
are peripheral, and the others interosseous.
1. Peripheral Ligaments. — The most general idea which can be formed of these liga-
ments is that of a fibrous sheath, surrounding the column formed by the bodies of the
vertebrae, and uniting in one whole the different pieces of which it is composed. The
part of the sheath which covers the anterior aspect of the bones is called the anterior
common ligament of the vertebra ; and that which covers the posterior surface is called
the posterior common ligament of the vertebra.
The anterior common vertebral ligament (a, figs. 58, 60) presents the appearance of a
Fig. 58. white pearly-looking membrane stretched from the axis to the
upper part of the sacrum. This ligament, which is thicker in the
dorsal region than in the neck or the loins, is composed of three
very distinct parts : a thick one in the middle, and two lateral,
which are separated from it by a series of openings that give pas-
sage to some vessels (see fig. 58). Its anterior surface is in con-
tact with the organs of the neck, the thorax, and the abdomen,
and united with them by very loose cellular tissue. The tendons
of the longi colli and anterior recti muscles, and the pillars of the
diaphragm, mix their fibres with this ligament. The psoae mus-
cles correspond to its lateral portions below. Its posterior surface
adheres more closely to the intervertebral substances, and to the
projecting rims of the bodies of the vertebrae, than to the trans-
verse grooves of the bodies. This ligament is composed of sev-
eral planes of fibres, of which the most superficial are the longest.
The deepest pass from one vertebra to the next, and are lost on
the periosteum. The superficial stretch over four or five vertebrae.
Posterior common vertebral ligament (a, fig. 59). This is thicker than the anterior, but
(Fig. 59.)
has the same white pearly appearance. It commences at the oc-
cipital bone, and terminates at the sacrum. It resembles a fibrous
band, which expands at the intervertebral substances, and is con-
tracted over the bodies of the vertebrae ; hence it has a regular fes-
tooned appearance. Its posterior surface is united to the dura mater
at its upper part, but is separated from it by a dehcate cellular tis-
sue throughout the rest of its extent. Its anterior surface adheres
intimately to the intervertebral substances ; it is separated from
the middle of the bodies of the vertebra by the veins, which pass
from the interior of the bone into the vertebral venous sinuses
which run along the edges of the ligament. Like the anterior com-
mon vertebral ligament, it is composed of several planes of fibres,
the posterior of which are the longest. It is formed of more com-
pact tissue than the anterior.
2. The intervertebral substance or interosseous hgament {b, figs. 58,
ARTICULATIONS OP THE VERTEBRAL COLUMN. 117
59, 60, and 68) consists of a kind of disc, which fills up the lenticular space between the
bodies of the vertebrae, and might, with propriety, be called mtervertehrd. disc.
Each disc has the form of a double convex lens, and is so closely united by its upper
and under surfaces to the corresponding vertebra;, that it is easier to break the bones than
to destroy this connexion. Its circumference adheres to the anterior and posterior com-
mon ligaments, and contributes to form the intervertebral foramina. In the dorsal region
it also forms part of the angular facette which articulates with the ribs. The thickness
of the intervertebral substance is not the same in all the regions of the spinal column, be-
ing greatest at the lower parts. The proportion between the thickness of the discs and
the bodies of the vertebrae is exactly measured by that of the intervertebral space, and is
not the same in all the regions. In the lumbar region the thickness of the disc is half
that of the corresponding vertebrae ; in the dorsal region it is a third ; and in the cervi-
cal region it is a little more than a half*
The intervertebral substance is not equally thick throughout. From its lenticular form,
it must be thicker at the centre than at the circumference ; in the neck and in the loins
it is thicker in front than behind ; in the back the opposite prevails, and by this inequality
the discs concur in producing the alternate curves of the vertebral column. Abnormal
curvatures are in a great measure caused by unequal thickness of these dies, and I have
often had opportunities to convince myself that compression of this substance on the side
towards which the inclination takes place is the most common origin of the deformity.
The thickness of the discs varies in different circumstances. Thus, after prolonged
standing in the erect posture, the height of the body becomes diminished from eight to
ten lines, which is owing to compression of the intervertebral substances.
Each disc is composed of concentric layers (figs. 60 and 68) closely pressed together
at the circumference, but more separate towards the centre, where we find a soft spongy
substance, moistened by a viscid fluid resembling synovia. This soft substance is nearer
the posterior than the anterior aspect of the body of the vertebra ; it escapes, and forms,
as it were, a hernia, when the parts are cut either horizontally or vertically. It varies
much at different ages. It is moist, soft, spongy, and white in the infant and in youth,
which accords with the suppleness of the vertebral column at that period of life. Where
this substance is situated, we may inflate an irregular cellular cavity in it, which may be
regarded as the rudiment of the large synovial cavity which these parts exhibit in fishes.
M. Pailloux believes that this cavity is lined by a synovial membrane. In old age it be-
comes dry, friable, and yellowish, or brown. Monro attributes the elasticity of the ver-
tebral column to the displacement of this soft central substance in the different move-
ments ; for, according to his theory, the movements of the bodies of the vertebrae take
place upon it as upon a movable pivot or a Uquid fulcrum.
The intervertebral substance is called a cartilaginous ligament by Vesalius ; by others,
a cartilage ; and by Bichat, a Jibro-cartilage ; but they evidently belong to the fibrous tis-
sues. This may be shown by macerating a portion of the spinal column for some days,
or even by rubbing the surface with a rough cloth. It will then appear that this pretend-
ed fibro-cartilage is nothing more than a series of concentric fibrous layers, strongly com-
pressed together ; that each layer is formed of parallel fibres, directed very obliquely
from the lower surface of the vertebra above to the upper surface of the vertebra below,
and regularly crossing with the fibres of the next layer {¥, fig. 58). This regular cross-
ing, which we shall meet with in other parts, is evidently very conducive to solidity.
Union of the Articular Processes.
These articulations are arthrodice.
Articular Surfaces. — The corresponding surfaces are covered by a thin layer of cartilage.
The means of union consist of some irregular ligamentous fibres {d d, fig. 60), which sur-
round the outside of the joint, and are more numerous in the dorsal and cervical regions
than in the loins, the internal side of the articulation being occupied by the yellow liga-
ment. These articulations are provided with synovial membranes of greater extent in
the cervical than in the other regions.
Union of the LamincB. ^_ 60.
The spaces between the vertebral laminae are occupied by ligaments of
a particular description, which are called yellow ligaments, ligamenta suh-
flava, on account of their colour. They are composed of two halves uni-
ted at an angle like the laminae (c c,fig. 60). Their lower edge is implanted
upon the upper edge of the laminae below, and their upper edge is attached
to the anterior surf£ice of the corresponding laminae. From this it fol-
lows, that the height of the ligamenta subflava is much greater than would
be necessary to reach from one lamina to another ; it is almost equal
to that ol the corresponding vertebral lamina.
Their length is measured by that of the laminae, and is, consequently,
* A curious preparation may be made by taking away all the bodies of the vertebrae in a
spine softeced by nitric acid. A column then remains, formed by the series of discs, which
may be compared with a column formed by the bodies of the vertebra;.
118 ARTHROLOGY.
greater in the neck than in the back and loins. They are of greater thickness in the
loins than in the back and the neck, and the thickest part corresponds to the base of the
spinous process. There are also some re-enforcing bundles, which constitute a sort of
median yeUow ligament. Their anterior surface is separated from the dura mater by cel-
lular tissue, and by veins. It is remarkable for its smooth and polished appearance.
Their posterior surfaces are in contact with the vertebral laminae, which cover them al-
most completely, except in the cervical region, where they may be seen between the lam-
inae, when the head is slightly inclined forward ; this circumstance renders it possible
lor a penetrating instrument to enter between the cervical laminae, while it is almost
impossible in the dorsal and lumbar regions.
Structure. — These ligaments are composed of parallel vertical fibres very closely ar-
ranged. They are extensible, and, when stretched, immediately recover themselves, and
are therefore very elastic. They are as strong as ordinary ligaments. Their extensi-
bility is brought into action during flexion of the vertebral column, and their elasticity
during extension. They have great effect in maintaining the erect posture, which would
otherwise have required a constant expenditure of muscular power.
Union of the Spinous Processes.
The spinous processes are united by the supra-spinous and the inter-spinous ligaments.
The supra-spinous ligament {d d, figs. 58 and 59) is a fibrous cord, which extends from the
seventh cervical vertebra to the sacrum, along the summit of the spinous processes of
the dorsal and lumbar vertebrae. This ligament can be only distinguished from the
aponeurotic fibres, which are inserted into the spinous processes, by the longitudinal di-
rection of its fibres. It is larger in the lumbar than in the dorsal region. It is expand-
ed, and becomes even sometimes cartilaginous in the interval between the processes.
It is inextensible. I regard a fibrous cord which extends from the seventh cervical ver-
tebra to the external occipital protuberance as a continuation of the supra-spinous liga-
ment ; it appears to be the vestige of the posterior cervical ligament of quadrupeds, and is
of considerable size in some subjects ; from its anterior surface, prolongations a\^ given
off to the spinous processes of all the cervical vertebrae, excepting the first.*
The inter-spinous ligaments (e e, Jig. 58) do not exist in the neck, where their place is
suppUed by small muscles ; they are very thin in the back, where each has the form of a
triangle with the base looking backward. They are thick and quadrilateral in the loins.
Their upper and lower edges are attached to the corresponding spinous processes. Their
surfaces are in contact with the muscles of the vertebral grooves. M. Mayer speaks of
synovial capsules, which he has met with between the lumbar spinous processes, and
especially between the third and the fourth in this region ; these membranes are by no
means constant.
Articulations peculiar to certain Vertebra (Jigs. 61 to 64).
Although the articulations of the atlas and of the axis, with the occipital bone, do not
properly belong to the articulations of the vertebral column, yet the connexion between
these articulations and that of the atlas with the axis is so intimate, that it is impossi-
ble to separate them. We shall describe these three articulations in succession ; first
noticing the articulation of the atlas with the occipital bone {occipito-atlantoid articulation).
Occipito-atlantoid Articulation.
Preparation. — Remove the part of the scull which is in front of the vertebral column,
taking care to leave the basilar process. The muscles which surround the joint, being
closely applied to the ligaments, should be very carefully detached.
The atlas unites with the occipital bone, 1 . By its anterior arch ; 2. By its posterior
arch ; 3. By the base of its transverse processes ; 4. By its two articular surfaces.
1. The anterior arch of the atlas is united to the circumference of the foramen mag-
„. g. num by two anterior occipito-atlantal ligaments. One
*^' ■ of these, the superficial (a, figs. 61 and 64), is a very
strong cylindrical cord situated in the median line,
where it forms a very marked projection, and stretches
from the basilar process of the occipital bone to the an-
terior tubercle of the atlas. The other (i, fig- 61),
which is deep-seated, is pretty thick, consists of several
layers, and extends from the upper edge of the anterior
arch of the atlas to the occipital bone.
2. Most anatomists admit the existence of a liga
ment stretching from the posterior part of the foramen
magnum to the upper edge of the posterior arch of the
atlas, the posterior occipito-atlantal ligament (b, figs. 62
* This ligament is the result of the intersection of the aponeuroses, of the trapezius, splenius, &c. I shall
»fer more particularly to this point in myology, when on the subject of the posterior cervical apoueiirosis
ARTICULATIONS OF THE VERTEBRAL COLUMN.
119
and 64). But it can scarcely be distinguished, con- Fig. 62.
sisting only of a {ew ligamentous fibres among the
fat of this region.
3. Lateral Occipito-atlantal Ligaments (c, jig. 61).
— A fibrous cord passes from the base of the trans-
verse process of the atlas to the jugular process of
the occipital bone. In connexion with a similar bun-
dle from the pars petrosa, it forms a very remark-
able fibrous canal, which gives passage to the in-
ternal jugular vein, the internal carotid artery, the
hypoglossal, pneumogastric, glosso-pharyngeal, and
accessory nerves.
4. The union of the condyles of the occipital bone with the superior articular surfaces
of the atlas is a double candy laid articulation. The articular surfaces of the occipital bone
are the two condyles, convex, oblong, looking downward and outward, and directed for-
ward and inward, so that their axes, if prolonged, would meet in front of the basilar
process. The articular surfaces of the atlas are concave and oblong, and look upward
and a little inward, so as to fit exactly upon the convexity of the condyles. Both are
covered by a thin layer of cartilage. The ligaments are vertical fibres which surround the
joint, but are most numerous in front and on the outside, for they scarcely exist on the
mside and behind. There is also a very loose synovial membrane which passes beyond
^he articular surfaces on all sides, but especially to the outside.
Atlanto-axoid Articulation.
Preparation. — After having studied the superficial ligaments, remove the laminae of the
axis, the posterior arch of the atlas, and the back part of the foramen magnum. Detach
with care that portion of the dura mater which corresponds to the first two vertebrae and
the foramen magnum, and turn it upward. Lastly, in order to obtain a good view of the
articulation of the odontoid process with the atlas, disarticulate the occipital bone.
This articulation is formed between, 1. The odontoid process of the axis, and the an-
terior arch of the atlas ; 2. Between the superior articulating processes of the axis and
the inferior articulating processes of the atlas ; 3. In addition, the anterior and posterior
arches of the atlas are united to the Jixis by two hgaments — the anterior and the poste-
rior atlanto-axoid ligaments.
The anterior atlanto-axoid ligament {b,figs. 61 and 64) is a thick vertical bundle com-
posed of several layers, which extends from the tubercle and the lower edge of the an-
terior arch of the atlas in front of the base of the odontoid process of the body of the axis.
It is continuous below with the anterior common ligament.
The posterior atlanto-axoid ligament (c,figs. 62 and 64) is a very loose and thin mem-
brane, extending from the posterior arch of the atlas to the upper edge of the laminae of
the axis ; it is a little thicker in the median hue than at the sides, and represents the
ligamenta subflava in a rudimentary state.
Articulation of the Odontoid Process with the Atlas. — This is aywof joint, the odontoid pro-
cess being received into a ring formed in front by the anterior arch of the atlas, on the
sides by the lateral masses of the same bone, and behind by the transverse ligament.
We have, therefore, to consider, 1. The articulation of the anterior arch of the atlas with
the odontoid process (atlanto-odontoid articulation) ; 2. The articulation of this same pro-
cess with the transverse ligament (syndesmo-odontoid articulation).
1. Atlanto-odontoid Articulation (e, fig. 64). — The articular surfaces are an oval and
slightly concave facette on the posterior surface of the anterior arch of the atlas (1);
and a slightly convex, vertically oblong facette, on the fore part of the odontoid process
(2). Both surfaces are incrusted with cartilage, and there is also a very loose synovial
membrane with subjacent adipose tissue. The joint is strengthened by some hgament-
ous fibres, arranged in the form of a capsule.
2. Syndesmo-odontoid Articulation. — ^This joint is formed by means of the transverse or
Fig. 63.
annular ligament (/, figs. 63 and 64), a very thick and
compact bundle of fibres, flattened before and behind,
and stretched transversely between the lateral masses
of the atlas, passing behind the odontoid process, and
closely embracing it like a half ring. The anterior sur-
face of this hgament is concave, and polished like car-
tilage ; it is in contact with the posterior surface of
the odontoid process (2, fig. 64), which is covered with
cartilage, and is almost always furrowed transversely,
i. e., in the direction of its movements. There is a very
loose synovial membrane in this joint, which is prolonged on the sides of the odontoid
process, as far as the odontoid ligaments. The posterior surface is covered by the pos-
terior occipito-axoid ligaments* (o, fig 64 ; see figs. 63 and 64). From its upper edge a
* If the student is only provided with one preparation for the examination of all these joints, it is necessary
«o study these ligament* before dividing them, in order to expose the transverse lig-aiuenls.
120 ARTHROLOGY.
fibrous band is detached, which is fixed to the occipital bone, in front of the occipito-ax-
oid ligament, by a narrow extremity. Another fibrous band (see jigs. 63 and 64), of
greater length than breadth, proceeds from its lower edge, and is attached to the postenor
surface of the axis ; hence the name crucial has been given to the annular ligament by
some authors. The extremities are inserted into two tubercles on the inside of the
lateral masses of the atlas.
There is a very remarkable circumstance connected with this ligament, viz., that its
lower circumference belongs to a smaller circle than its iipper, so that the odontoid process
is very firmly retained in the ring which this ligament contributes to form, and this ar-
rangement accords with a sort of constriction at the base of the odontoid process.
Union of the Articular Processes of the Atla^ and the Axis.
This is a double arthrodia. The articular stirfaces of the atlas are plane, circular, and
horizontal, but looking slightly inward ; those of the axis are also plane and horizontal,
looking slightly outward, and of greater extent than the preceding. They are retained
in their place by a fibrous capsule ig,figs. 61 and 63), which is very strong, especially in
front, and sufficiently loose to permit the extensive motions which take place at this
joint : it is formed of vertical and parallel fibres. The synovial ca-psule is very loose, and
projects beyond the surfaces of the bones in every direction, but particularly in front. It
almost always communicates with the synovial membrane of the joint between the
transverse ligament and the odontoid process.
Union of the Occipital Bone and the Axis.
Although the occipital bone and the axis are nowhere contiguous, and are not, there-
fore, articulated, yet they are united very firmly by means of strong ligaments, extending
from the occipital bone to the body of the axis, and also to the odontoid process.
Preparation. — Remove with care that portion of the dura mater which corresponds to
the first two vertebrae ; the occipito-axoid ligaments lie under it. Then detach the
transverse ligaments, remove the anterior arch and lateral masses of the atlas, so that
nothing remains excepting the occipital bone and the axis.
1. The occipito-axoid ligaments are three in number, a middle and two lateral. The
Ftg. 64. middle occipito-axoid ligament (o, fig. 64) is thick, and forms
at its upper part a single band, the fibres of which are sep-
arated below into three very distinct layers. The most
posterior of these is continuous with the posterior common
ligament ; the second is attached to the posterior surface
of the body of the axis ; and the deepest, which is very
thin, and shaped like a tongue pointed above, is that which
we described with the transverse ligament. The lateral
occipito-axoid ligaments (r, fig. 64) arise from the sides of
the basilar groove by a broad extremity, and are attached
to the posterior surface of the axis by a pointed end. They
correspond in front with the odontoid and transverse ligaments, and behind with the
dura mater.
2. The odontoid ligaments are three in number, a middle and two lateral. The middle
(I, fig. 64) consists of ligamentous fibres, which extend from the apex of the odontoid
process to the fore part of the foramen magnum, between the condyles ; the two lateral
(I, fig. 63) are two bundles of fibres, very strong, short, and cylindrical, which stretch
between the sides of the apex of the odontoid process, and two small fossae on the inside
of the condyles ; their direction is horizontal, so that they represent the horizontal limbs
of the letter T, of which the odontoid process forms the vertical portion ; they are almost
always united by a bundle, which passes above the odontoid process without adhering to
it, so that, at first sight, they might be declared to be one and the same ligament.
Sacro'Vertebral, Sacro-coccygeal, and Coccygeal Articulations.
Sacro-vertebral Articulation. — This resembles in every point the articulations of the
other vertebra;. We shall only remark, 1 . The great thickness of the intervertebral sub-
stance, particularly in front, a vertical section of it resembling a hatchet with the broad
part turned forward ; 2. The sacro-vertebral ligament {a, fig. 76), which is proper to this
articulation, a very short, thick, and strong bundle stretched obliquely from the trans-
verse process of the fifth lumbar vertebra to the base of the sacrum, where it crosses
with some ligamentous fibres of the sacro-iliac articulation.
Sacro-coccygeal Articulation. — This is an amphiarthrosis, or symphysis, analogous in
every repect to that of the bodies of the vertebrae ; a fibrous disc resembling the inter-
vertebral substances, but of a more loose texture, unites the corresponding articular sur-
faces. In some subjects the coccjrx is very movable, and there is a synovial capsule in
the centre of the disc. The other means of union are, 1. The anterior sacro-coccygeal lig-
ament {a fig. 77), composed of parallel fibres extending from the anterior surface of the
sacrum to the anterior surface of the coccyx, and often divided into two lateral bundles ;
MECHANISM OF THE VERTEBRAL COLUMN. 121
2. The posterior sacro-coccygeal ligament, which is fixed above to the edges of the notch
which terminates the sacral canal, and is prolonged upon the posterior surface of the
coccyx. This ligament, which completes the sacral canal, gives attachment to the glu-
taei maximi muscles by its posterior surface. It is composed of several layers, the most
superficial of which reach the apex of the coccyx, while the deepest extend only to the
first piece of that bone.
The coccygeal articulations are also amphiarthroses, which become synarthroses during
the progress of life. The articulation of the first with the second piece is the only one
. which remains to an advanced age. It is sometimes extremely movable.*
Mechanism of the Vertebral Column.
The vertebral column being at once an enclosing and protecting cylinder for the spi-
nal marrow, a column for transmitting the weight of the trunk and the upper extremi-
ties to the legs, and an organ of locomotion, its anatomical structure must be examined
in reference to these three uses.
The Vertebral Column considered as the Protecting Cylinder of the Spinal Cord.
The vertebral column performs the office of a protecting cylinder, by virtue of its so-
lidity, ensured by the bodies of the vertebrae in front, by the projection of the spinous
processes behind, which ward off, so to speak, all external objects, and by the promi-
nence of the transverse processes at the sides. By means of these arrangements, the
spinal cord is inaccessible, excepting by a sharp instrument, which might penetrate ei-
ther in front through the intervertebral substances, or on the sides through the interver-
tebral foramina, or, lastly, behind through the intervals between the spinous processes,
and between the laminae. Another condition of solidity, in so far as this can be obtain-
ed with mobility, is provided by the number of pieces of which the vertebral column is
formed. For, in all cases where the column is subjected to shocks, each articulation
becomes the seat of a decomposition of the force ; a part is employed in producing a
slight displacement of the articular surfaces, and is therefore entirely lost, as far as re-
gards the transmission of the shock. If, on the contrary, the vertebral column had been
formed of one single piece, the transmission of shocks would have been unbroken, and
thus the frequent cause of concussion and fracture. Lastly, the breadth of the articular
surfaces by which the bodies are united, the strength and pliability of the intervertebral
substances, the vertical direction of the articular processes, contrasted with the horizon-
tal direction of the articular surfaces of the body, and the species of dovetailing which
results from it, are also most favourable conditions for the protection of the spinal mar-
row. Indeed, I do not see how, in our system of organization, the protection to the spi-
nal cord could be increased.
• The Vertebral Column considered as an Organ for transmitting the Weight of the Trunk
The anatomical arrangements adapted to this purpose are the following :
1. The progressive increase in size of the vertebral column, from the apex to the base.
This disposition is particularly observable in the first two pieces of the sacrum, which
are proportionally much larger in man than in the lower animals.
2. The articulation of the vertebral column with the posterior part of the pelvis, by
which the centre of gravity of the trunk is carried backward, and the maintenance of
the equilibrium is aided, by counterbalancing the weight of the thoracic and abdominal
viscera, which, instead of uniformly surrounding the column, are all placed in front.
3. The alternate inflections of the vertebral column, which allow more extensive os-
cillations of the centre of gravity of the column than would have been practicable held
its direction been altogether rectilinear, and which also augment its power of resistance
in the vertical direction.
4. The length of the spinous processes, which thus afford a more favourable, because
a longer lever to the extensor muscles, which maintain the column erect. The absence
of these processes in infancy is one of the causes of the difficulty of standing at that period.
5. The existence of the soft matter in the centre of the intervertebral discs, which
prevents compression of the column by affording a liquid, and therefore almost incom-
pressible point d'appui, as Monro has remarked ; the truth of this may be proved by sub-
mitting a portion to powerful compression. We have before remarked that this soft
matter is not placed in the centre, between the bodies of the vertebra, but nearer to the
posterior border, and, consequently, it occupies the centre of their movements. It di-
minishes the violence of shocks, changes its position as we change our attitudes, and fills
up the vacancies resulting from the approach of the bodies on one side, and their separa-
tion on the other. It is generally believed, it is true, that the diminution of height which
follows upon prolonged standing or walking is the result of mechanical compression of
the intervertebral discs, and an absolute diminution of their thickness ; but it appears
* I have met with an instance in which this joint was very movable : there was a synovial membrane ana
a fibrous capsule. The extent of the motion was so great, that the two pieces could be made to form a, ngut
angle with the cavity looking backward.
Q
122 ARTHROLOGY.
more conformable to the laws of physics to admit that the diminution in the height of
the vertebral column depends upon the increase of the curvatures, unless we admit Mon-
ro's hypothesis of the absorption of part of the hquid contained within the discs.
6. The presence of the yellow ligaments, which, by their elasticity, continually oppose
the causes which tend to bend the body forward, and which are for each of the vertebrae
what the posterior cervical ligament is for the head.
7. The existence of the vertebral canal, which has the same advantage as the cylinder
of long bones, of increasing the strength without increasing the weight.
8. The mode of articulation of the vertebral column with the head, which is doubly ad-
vantageous, both as regards the place occupied by the articular surfaces, and their di-
rection: 1. The articular surfaces correspond to the point of junction of the posterior
with the two anterior thirds of the head. The posterior third of the head contains a
large portion of the encephalic mass, while the two anterior thirds are chiefly formed by
the face, which, in comparison to its size, is of little weight. From this it follows, that
the weight of the posterior third almost counterbalances that of the two anterior thirds
of the head. 2. The almost horizontal direction of the condyles in the human subject
permits the head to rest upon the summit of the vertebral column, without having a
necessary tendency, or at least a very slight one, to incline forward, as invariably takes
place in animeds whose occipital condyles are vertical, and situated entirely on the back
of the head. Yet, notwithstanding these advantageous conditions of the atlantal artic-
ulation, the part in front of the condyles is somewhat heavier than that behind ; and this
difference, though slight, is sufficient to cause flexion of the head, when left to itself,
either during sleep or after death. Indeed, in spite of all the arrangements above re-
ferred to, considerable efforts are required to maintain the biped position ; and to secure
this, we have the vertebral grooves filled up with powerful muscles. In the human sub-
ject, the muscles which occupy the cervical portion of the column, and which are des-
tined to support the head, are not nearly so strong as the corresponding muscles in the
quadruped, while those of the loins are proportionally much stronger. Standing in the
erect position is, therefore, very far from being a state of rest, and requires a constant
muscular effort to sustain it.
The Vertebral Column considered as an Organ of Locomotion.
The vertebrae perform upon each other certain oscillatory or balancing movements in
all directions, by means of the pliability of the intervertebral substances ;* but they are
so obscure, that their existence can scarcely be recognised, or their character examined
on a small portion of the column. In order to understand them, the entire spine must
be examined.
Movements of the entire Column. — These are, 1. Flexion, or the movement forward. 2.
Extension. 3. Lateral inclination. 4. Circumduction, in which the column describes a
cone, of which the apex is below, and the base above. 5. Rotation on its axis, or tor-
sion of the vertebral column.
In the analysis of the motions of the column, it is necessary to distinguish carefully
between the actual and the apparent motions ; the first are much less extensive than
would be imagined at first sight, the greater part of the apparent movements taking place
at the articulations of the pelvis with the thighs. In these movements of the whole, the
column represents a lever of the third order, an elastic arch in which the resistance is at
the upper extremity, the fulcrum at the lower end, and the power applied in the middle.
Each vertebra, on the contrary, represents a lever of the first order, in which the pow-
er and the resistance are at the anterior and posterior extremities of the bone, and the
fulcrum in the middle.
1. In the movement of flexion, which is the most extensive of all, the anterior common
ligament is relaxed ; the anterior part of the intervertebral substances is compressed ;
the soft central portion is pushed backward ; the posterior fibres of the discs are shght-
ly stretched, as are also the posterior common ligament, the supra-spinous, inter-spi-
nous, and yellow ligaments. The inferior articular processes of each vertebra move up-
ward upon the superior articular processes of the vertebra below. The laminae are sep-
arated, so that the rachidian canal, especially in the cervical region, becomes accessible
to penetrating instruments.
2. In extension, the anterior common ligament and the anterior fibres of the intei ver-
tebral discs are stretched ; the posterior fibres of the disc are relaxed ; the soft central
matter is pushed forward ; the yellow, supra-spinous, and inter-spinous ligaments are
relaxed. The lower articular processes glide downward upon the superior articular pro.
cesses of the vertebra below. This motion is not extensive ; it is limited by the ante-
rior common ligament, and the meeting of the spinous processes.
3. In the movements of lateral inclination, the discs are compressed on the side to
which the inclination takes place, and the central pulp is forced to the other side. These
motions are limited, not only by the meeting of the transverse processes, but even be
* Tbns the uniting media of the vertebrse serve also as means of Icomotion.
MECHANISM OF THE VERTEBRAL COLUMN. "HSl
fore these touch, by the resistance of the intervertebral substances, and of the lateral
bundles of the anterior common ligament.
4. Circumduction. — This motion, the centre of which is in the lumbar region, appears
at first sight very extensive, because a portion of the movement at the hip-joint is gen-
erally ascribed to it. In reahty, it is very limited, and results from a succession of the
preceding motions.
5. The movement of rotation is effected by the twisting of the intervertebral sub-
stances. Although the motion of each disc is very slight, yet the simultaneous twisting
of them all produces a general movement, by which the anterior surface of the column
is turned slightly to the sides. It is, however, upon the whole, very limited ; and al-
though in the erect posture the trunk of the body can describe a semicircle, the greater
part of this motion takes place at the hip-joint.
All the regions of the vertebral column do not equally participate in these general mo-
tions. They are most extensive in the cervical region, where we observe, 1. Flexion,
which may be carried so far as to make the chin touch the upper part of the sternum ;
2. Extension, so that the neck may be turned backward ; 3. Lateral inclination, until the
head nearly touches the shoulder ; 4. Rotation, which is greater here than in any of the
other regions, notwithstanding the presence of the lateral hook-like processes or ridges.*
Tliese motions may be to such an extent as to cause luxation, which can only take place,
without fracture, in the cervical region, on accoimt of the ahnost horizontal direction of
the articular processes.
The general movements are most limited in the dorsal region. 1. Flexion is rendered
impossible by the presence of the sternum. The presence of this bone in the different
species of animals attests the immobility of the dorsal portion of the column, in the same
manner as its absence is an indication of its mobility. 2. Extension is prevented by the
meeting of the spinous processes, which are longer and more closely imbricated in this
than in any other of the regions. 3. Lateral movements are rendered impossible by the
ribs, which would be forced against each other if this motion took place. 4. As aU the
preceding motions are the elements of circumduction, it may be easily conceived that
this can scarcely take place. 5. The same obstacles oppose the movement of rotation,
which is also prevented by the position of the articular processes, which are directed ver-
tically, and whose surfaces on the right and left sides are not upon the same plane. The
thinness of the intervertebral substances in the dorsal region accords with all these
arrangements in limiting mobility.
What has been said regarding the immobility of the dorsal region applies only to the
upper part of this region. The dispositions at the lower part are more favourable to mo-
bihty. We know that the last two dorsal vertebrae are remarkable for the shortness of
their spinous and transverse processes ; and that the ribs with which they articulate are
very movable, and could not oppose the motions of the vertebras in any degree.
The lumbar region participates much more in the general motions than the dorsal.
The articular processes in this region are much more advantageously adapted for rota-
tion than in either the dorsal or cervical, for the lower pair of each vertebra forms a solid
cylinder, which is received into the hollow surface of the superior articulating processes
of the vertebra below. This arrangement permits a motion resembhng that of the hinges
of a door.
It should be remarked, that in all the regions the lower articular processes of each
vertebra are placed behind the superior articular processes of the succeeding vertebra,
ftnd form a sort of imbrication. Each vertebra, then, is retained in its place by a species
of dovetailing, so that it cannot be dislocated forward without breaking the superior ar-
ticular processes of the vertebra below, nor backward, without breaking the inferior ar-
ticular processes of the vertebra above. This remark does not apply rigorously to the
cervical region, the articular processes of which are oblique, and can permit dislocation
■without fracture.
Mechanism of the Articulations of the Vertebral Column and the Head.
The movements of the head upon the vertebral column are shared between two artic-
ulations : viz., 1. The occipito-atlantal, to which edl the motions of flexion, extension,
lateral inclination, and circumduction belong ; 2. The atlanto-axoid, which only performs
one movement, viz., rotation.
Mechanism of the Occipito-atlantal Articulation.
The movements of flexion and extension of the head upon the atlas are very limited ;
when the head is decidedly bent or inclined, the effect is produced by motion of the
whole cervical region. It is possible to distinguish flexion at the occipito-atlantal artic-
ulation from that which is produced by the entire cervical region. In the first case, the
chin approaches the vertebral column, and the skin on the upper part of the neck is
* We should form an incorrect notion of the obstacle resulting from the lateral ridges on the bodies of tne
Tcrtebrse, in the pcrfiinnanre of rotation, if we were to study them only on the disarticulated skeleton. In the
recent subject they scarcely (ouch the vertebra above, on account of the intervertebral disc.
124 ARTHROLOGY. '''''^'
wrinkled transversely ; in the latter, the spine bends at the same time as the head, con-
sequently the interval between it and the chin remains the same, and there are no trans-
verse viTinkles of the skin.
During flexion the condyles glide backward ; the odontoid, the occipito-axoid, and the
posterior ligaments are stretched, but in extension the gliding takes place in an oppo-
site direction.
The occipito-atlantal articulation is deprived of the power of rotation by the direction
of the condyles, which mutually obstruct this movement. In birds, which have only one
condyle, the articulation of the head admits of very extensive rotation. In the human
subject there is a slight movement of rotation at this joint, when the head is previously
ioclined upon one of the condyles, which then serves as a pivot.
Mechanism of the Atlanto-axoid Articulation.
In the movements of this articulation, we should regard the atlas and the head as
forming only one piece. There are no movements either of flexion or extension. The
inclusion of the odontoid process in the syndesmo-atlantal ring prevents even the slight-
est motion of the atlas, either forward or backward ; for in the forward motion, or flex-
ion, the atlas is fixed by the transverse ligament, which presses upon the odontoid pro-
cess ; and in the backward motion, or extension, the atlas is fixed by its own anterior
arch, which is brought in contact with the same obstacle. There is, moreover, no lat-
eral inclination at this joint, for this is prevented by the odontoid ligaments. Rotation
is, therefore, the only movement which remains. In this motion, in which the head de-
scribes the arc of a large circle upon the vertebral column, the syndesmo-atlantal ring
turns upon the axis as a wheel upon its axle. Of the two plane surfaces of this joint,
one glides forward, and the other backward ; one of the odontoid ligaments is stretched,
and the other relaxed. These ligaments, it should be observed, limit the extent of rota-
tion, which explains the necessity for their great strength ; but, great as this is, their
resistance is occasionally insufficient, and the odontoid process breaking one of them,
slips below the transverse ligament, and occasions death by compressing the spinal cord,
Luxation, therefore, of this articulation is to be dreaded, not merely for the same rea-
sons as other dislocations, but as being a cause of compression of the spinal marrow.
The entire movement by which the face is turned to either side should not be attrib-
uted to this articulation alone, for it extends to the fourth of a circle on each side, and
such a degree of motion would dislocate the articular surfaces of the atlas and the axis.
Articulations of the Cranium.
All the bones of the cranium are united together by synarthroses. We have here to
examine, as in all other articulations, 1. The articular surfaces ; 2. The means of union.
As the bones of the cranium form a complete cavity, closed in every direction, they unite
by their entire circumferences or by their edges ; and as the solidity of joints is in a di-
rect ratio to the extent of the articular surfaces, the bones of the cranium, which are
only in contact by their edges, would have been very slightly connected, had it not been
for the following provisions : 1. The cranial bones are generally thicker at the circum-
ference than in the centre ; 2. They are almost all provided with marginal denticulations
that multiply three or four fold the points of contact; 3. The edges, instead of being cut
perpendicularly, are bevelled so as to overlap each other, and thereby present much more
extensive corresponding surfaces ; 4. We should observe, also, the number of projecting
and retreating angles that are formed by these bones ; and, 5. The sinuous arrangement
of their edges, all of which arrangements are most favourable to the increase of solidity.
We should remark, however, that these different modes of ensuring solidity are not
employed indiscriminately over the whole scull. In the vault of the cranium, for exam-
ple, firmness is attained by the mutual adaptation of the serrated margins of the bones
at the upper and at the back parts, and by their overlapping at the sides ; in the base, on
the contrary, the sohdity chiefly depends upon the breadth of the contiguous surfaces,
and upon the reception of projecting into corresponding retreating angles. Examples of
this double arrangement may be seen in the articulation of the occipital and sphenoid
bones, which is accomplished by means of broad surfaces, and in the articulation of the
projecting angle formed by the petrous portion of the temporal bone with the retreating
angle formed by the occipital bone behind and the sphenoid in front.
This description will suffice to give a general idea of the mode of union between the
bones of the cranium. It would evidently exceed the limits of this work to dilate upon
the form of each of the sutures, and to follow Monro in distinguishing fourteen or fifteen
different kinds. Nevertheless, we do not think a few words regarding the principal
forms of the indentations will be out of place. We would therefore observe, that the
tooth-like projections are sometimes four or five lines in length, and are themselves in-
dented on their edges, secondary denticulations being thus formed. They are generally
straight, but are sometimes alternately bent towards the external and the internal sur-
face. Some of the teeth are, as it were, pediculated, and are enclosed between the others,
thus holding a middle place between the Wormian bones and the ordinarj' denticulations
MECHANISM OF THE CRANIUM. 125
We should remark that the name suture, piopurly speaking, belongs more especially
to those sutures in which the bones are dovetailed ; that those sutures, the uniting sur-
faces of which are broad and oblique, are generally called squamous ; and that the sutu
ra harmonia are those in which the indentations are scarcely perceptible. We must
also observe, 1. With regard to the sutures, that their indentations are much deeper on
the external than on the internal surface of the bones of the cranium ; 2. With regard to
those sutures which are bevelled, that they often present alternate oblique sections, hav-
ing opposite directions, so that of two bones, the one that overlaps the other at one part
of the suture is, at another part, itself overlapped : of this we have an example in the
fronto-parietal suture.
Means of Union of the Bones of the Cranium.
We have remarked, in speaking of the development of the bones, that those which
are subsequently united by immovable articulations are formed in a piece of cartilage
that is common to them all. Portions of this cartilage, not yet encroached upon by os-
sification, serve as the uniting media. It is evident, therefore, that these cartilages of
the sutures are broader when the amount of ossification is less, viz., in the earher periods
of life. The pericranium, on tlie outside, and the dura mater, on the inside, although
they adhere more firmly to the bones along the lines of the sutures, cannot to any con-
siderable extent contribute to strengthen the union of the bones of the cranium.
Mechanism of the Cranium.
While the vertebral column performs four offices, 1. A cylinder or canal of protection ;
3. A column of support ; 3. The central lever of locomotion ; and, 4. An organ movable
on itself in its different parts, the cranium only performs two : 1. An organ of locomotion ;
2. An organ of protection. As an organ of locomotion we have already fully studied it,
when examining the movements of the vertebral column, and, consequently, it only re-
mains for us to examine its mechanism as protecting the nervous mass which it encloses.
The cranium is nothing more than a bony envelope added to the fibrous one which en-
closes the brain, and is exactly moulded, on its inner surface, to the external surface of
the organ it encloses. Before its complete ossification, the cranium may experience an
enlargement or diminution in size in proportion as the organ it contains is enlarged or
diminished in volume ; but so soon as its ossification has been completed, its capacity is
independent of the volume of the brain. If that organ is atrophied, the vacancy is fiUed
up by serous fluid ; if hypertrophied, a fatal pressure is the consequence. The state-
ments which have been made by some, that the capacity of the interior of the cranium
increases in men of genius, and that the head of Napoleon increased wonderfully in size
during the progress of his reign, we consider as mere vagaries of the imagination. As
the cranium encloses the brain, it is evident that any motion between the bones which
form this case would be attended with fatal consequences. They are, therefore, im-
movably articulated to each other. It might be supposed that this solidity could have
been better secured, had the brain-case been formed of one instead of a number of bones.
But, independently of the other important objects obtained by its being made up of a
number of separate pieces, its power to resist fractures is increased by this arrangement,
seeing that forces applied to it, in being transmitted through its different articulations,
are weakened, and operate much less violently than they would have done without this
arrangement.
What has been said above of the immobility of the bones of the cranium is not equally
true at all periods of life. During foetal existence, and the first few years after birth, the
intervals between the bones of the cranium are occupied by a flexible, cartilaginous sub-
stance, which permits those of the roof to move pretty extensively upon each other.
Since, therefore, the conditions of solidity are not the same at this period as in the adult,
we must examine the mechanism of the cranium both in the foetus and in the adult.
1. In the foetus, the conditions of solidity must be studied both in the roof and in the
base of the cranium.
In the roof of the cranium, the incomplete ossification allows the bones to move upon
each other, and in this respect the encephalon is imperfectly protected. But, on the
other hand, the presence of these cartilaginous intervals diminishes the momentum of a
violent force applied to the cranium, and thus prevents, in some degree, both fractures
of the cranium and concussions of the brain. The mobility of the bones is principally
displayed at birth, in their overlapping, when the head of the foetus is passing through
the pelvis. The base of the cranium is incompressible at the same period, and the bones
are immovable, because ossification has so far advanced that they are only separated by
very thin layers of cartilage. Tliis arrangement is well adapted for the protection of the
most important parts of the encephalon, which are in the vicinity of the base of the cranium.
2. In the adult, the roof and the base of the cranium form one piece. The roof being
most exposed to violence, we shall examine the mechanism of resistance in the cranium
to blows directed vertically upon the top of the head ; and it will be easy to apply what
is said in explanation of the effects of a force so directed, to cases in which violence is
applied in other directions.
tm
ARTHROLOGY.
The effects which may be presumed to follow a violent blow on the top of the scull,
are, 1. Concussion of its bony parietes, succeeded by their elastic reaction ; 2. Disjunc-
tion of the pieces entering into the formation of the scull ; and, 3. Fracture of those
pieces. We shall examine the method in which these results may be produced.
1. Concussion and Compression of the Cranium without Fracture. — The cranium may be
looked upon as a hollow sphere, endowed with a certain degree of elasticity, depending
partly upon the osseous tissue itself, and partly upon the cartilaginous laminae which
separate the bones ; and it cannot, therefore, be doubted that, from pressure, or violent
blows on the top of the head, the scuU may undergo a flattening, and then recover its
original condition, like a hollow baU of ivory when struck vertically. The truth of this
explanation may be shown at once by projecting a scull against a resisting surface, when
it wiU be found to rebound like an elastic ball. However sUght this flattening may be,
and the recovery which follows it, the known laws of physics will not aUow us to deny
its possibility.
2. Tendency to Disjunction of the Bones of the Cranium. — This separation has never been
observed as the consequence of external blows. The following is the manner in which
displacement is prevented in cases of blows on the top of the head. It is evident that
violence applied in this direction would have a tendency to depress the upper edge of
the parietal bones ; but this cannot take place without forcing the lower edge outward ;
and as, from the peculiar formation of the squamous suture, the parietal bones are over-
lapped by the temporal and the sphenoid, this edge cannot be driven outward without
giving the temporal bones such a motion as will tighten the articulations of the base of
the cranium. All these articulations are remarkable in this respect, that the projecting
angles of some of the bones are received into the retiring angles of others. This is ex-
emplified in the articulation of the petrous portion of the temporal bone with the sphenoid
and the occipital bone, and in the basilar process of the occipital bone with the two tem-
porals and the sphenoid. The residt of all these arrangements is, that blows upon the
top of the head, instead of separating the bones of the cranium, tend to render their union
still closer.
3. Another effect of blows on the top of the head may be fracture of the cranial bones ;
and it will be impossible to comprehend the nature of many of these fractures, without
a knowledge of the following points of structure : 1 . The cranium is of unequal thickness
in different parts. This circumstance explains how a round body, striking the cranium
in a spot of sufficient strength to resist the impulse, may cause a fracture of a more or
less distant part, where the parietes are thinner, and consequently weaker. It may be
conceived that this kind of fracture may take place either in the bone struck, or in other
bones, and that it may affect the internal table only, the external remaining uninjured.
2. The cranium is so constructed, that a shock impressed upon the top is concentrated at
the base, being propagated on the sides to the temporal bones and their petrous portions,
as well as to the great wings of the sphenoid and the body of that bone ; behind, by the
occipital bone to the basilar process and the body of the sphenoid ; and in front, by the
fiontal bone and the roof of the orbits, to the smaller wings and body of the sphenoid.
It will thus be seen how blows upon various parts of the scull may concentrate their ef-
fects upon the base of the cranium ; and this explains the production of fractures at the
base, in consequence of violence inflicted on the roof of the scull. 3. Most of the cranial
bones are bent and angular. This disposition, which is observed at the union of the or-
bital and frontal portions of the frontal bone, and at the junction of the squamous and
petrous portions of the temporal bone, explains how these bones may be broken by the
transmission of shocks from the roof For we may conceive, when violence is applied
to a bone which is bent at an angle, that this angle will be the seat of a decomposition
of the force, one portion of which is transmitted to the part of the bone below the angle,
while the remaining portion acts against the angle itself in the original direction, and
may thus determine a fracture of that part of the bone.
Although the roof of the cranium is most exposed to injury, yet some parts of the base
may be reached by penetrating weapons, as the roof of the orbits and the cribriform plate
of the ethmoid. It should be remarked, also, that these are the thinnest parts of the scull.
Articulations of the Face.
The articulations of the face comprise those of the upper and of the lower jaw.
Articulations of the Bones of the Superior Maxilla with each other, and with the Cranium.
All these articulations are sutures, but they have not such large indentations as the
bones of the cranium ; almost all are united by harmonia or juxtaposition. At the same
time, it should be remarked that a true dovetailing exists in these articulations, as may
be seen in the junction of the superior maxillary bones (the fundamental articulation of
the face), which is effected by means of thick furrowed surfaces, mutually and firmly
adapted to each other.
No suture in the whole scull is stronger than that between the malar and the maxil-
lary bones ; indented sutures are most common on the sides of the face. The manner
ARTICULATIONS OF THE FACE. 127
in which the vertical portion of the palate bone is received into the furrow in the open-
ing of the maxillary sinus, afFords an illustration of the suture by reception. There are
some well-marked indentations in the articulations of the bones of the face with those
of the cranium ; as in the articulation of the nasal bones ; of the ascending processes of
the superior maxillae ; and of the malar bones with the frontal ; in that of the sphenoid
with the malar bones ; and of the latter with the zygomatic processes of the temporal
bones. Simple juxtaposition is met with in the junction of the ethmoid with the roof of
the orbit ; of the palate bone with the pterygoid processes ; and of the vomer with the eth-
moid ; but there is a mutual reception in the articulation of the vomer with the sphenoid.
With regard to the means of union, in addition to the firm union resulting from the
configuration of the articular surfaces, there is also a thin layer of cartilage, continuous
with that which formed the matrix of the bones, and which is itself afterward obhterated
during the progress of ossification.
Mechanism of the Articulations of the Upper Jaw.
As the mechanism of the face is adapted both to resist force applied from below through
the medium of the lower jaw, and also the effects of external violence, it is necessary to
analyze the conditions of solidity resulting from the configuration of the upper jaw ; and
in order to appreciate these correctly, we must analyze the framework of the face.
The upper jaw, considered as a whole, forms inferiorly a sort of parabola, circumscri
bed by the alveolar border, which is the strongest part of the bone, and receives the di-
rect impulse of the lower jaw ; it curves backward, and forms the roof of the palate,
which gradually diminishes in thickness ; and, not receiving the impulse of the lower jaw
directly, its construction is not so solid as the alveolar border. The upper jaw becomes
broader and flattened above, and separates into different parts or prolongations, which,
after enclosing certain openings, unite with the cranium by means of several processes,
that form, as it were, so many columns for resisting any impulses transmitted from below.
These columns are, 1. The fronto-nasal, constituted on each side by the ascending pro-
cess of the superior maxillary bone. These columns, which correspond to the canine
teeth, are remarkably strong in carnivorous tribes ; and to their great size may be attrib-
uted the lateral position of the orbits in these animals. The interval between these
columns is occupied above by the nasal bones ; but an opening is left between them, be-
low, shaped like a heart on playing cards. The whole of that portion of the alveolar
edge situated beneath this opening is weaker ; but it should be remarked, that it corre-
sponds to the incisor teeth, which, being adapted for cutting, divide instead of bruising
or tearing the food, and are, consequently, not subject to such powerful efforts as the
canine and molar teeth.
2. The second pair of columns is formed by the malar eminences, which are contin-
uous with the alveolar border, by the vertical ridge separating the canine from the zygo-
matic fossa. These columns, which correspond to the second great molar teeth, may
be called the zygomato-jugal, because they are subdivided into two other secondary col-
umns, the vertical, malar, or jugal, and the horizontal or zygomatic. The jugal columns
are much stronger than the fronto-nasal, and are continuous with the external orbital
processes of the frontal bone, and with the anterior thick and indented edges of the
great wings of the sphenoid : the second, or horizontal, articulate with the zygomatic
processes of the temporal bones, and with them constitute the zygomatic arches. From
this arrangement, it may be understood how effectually the bevelling of the end of the
zygomatic process that rests upon the malar bone is adapted for resisting impulses com-
municated from below. The zygomatic arches, also, form props that oppose all trans-
verse displacements. The mode of. articulation of the zygomatic processes with the
malar bones is such, that the zygomatic arches, although horizontal, are well C8dculated
to resist any force from below. In carnivora, where there are no jugal columns, the
zygomatic arches are enormously large.
The fourth pair of columns are the pterygoid,, intended to support the face in the antero-
posterior direction, being articulated with the maxillary bones through the medium of
the palate bor.es ; these also oppose any displacement upward, and, moreover, serve to
support the back part of the alveolar border.
There are, therefore, four pairs of columns, vi»., Vae fronto-nasal, the jugal, the zygo-
matic arches, and the pterygoid columns. They are almost entirely composed of compact
tissue. The principal columns are situated immediately above the first great molares,
where the jugal, zygomatic, and pterygoid columns are concentred, and where the most
violent impulses are received. The fronto-nasal columns correspond to the canine teeth ;
their strength is proportioned to that of these teeth, and hence, in carnivorous animals,
the ascending processes of the superior maxillae are very large and thick. The fronto-
nasal and jugal columns are near each other below, and only leave a small space be-
tween them, which is occupied by the two small molares ; but they are separated to a
considerable distance above, and enclose the orbital fossae.
In this manner the deep fossae in the face are formed without being prejudicial to its
strength. Even the maxillary sinus does not much diminish the solidity of the face.
128 ARTHROLOGY.
because it is situated in the interval between the columns, and because only a small
portion of it corresponds to the alveolar border.
These details wiU suffice to show that the upper jaw has been framed to resist ex-
ternal impulses, but especially forces communicated from below by the lower jaw ; that
the alveolar border, being intended to receive the impulse directly, is most strongly con-
structed ; that the whole force applied to the upper jaw is transmitted by the fronto-nasal
columns to the internal orbital processes, by the malar columns, partly to the external
orbital processes, and partly to tlie zygomatic arches, and by the palate bone to the ptery-
goid columns of the sphenaid ; that the vomer transmits little or nothing either to the
ethmoid or the sphenoid ; and that the cranium, on its part, opposes very imyielding
structures to the sustaining pillars of the face. To forces directed from before back-
ward, the zygomatic arches and the pterygoid processes offer great resistance ; against
lateral violence each malar bone resists like an arch, and transmits the impulse it has
received to the superior maxillary bone, the frontal and the sphenoid. \ The greatest
part of the impulses communicated to the face are then ultimately tranbtiitted to the
cranium ; and were it not for the multiplicity of its constituent parts, and the great num-
ber of articulations which absort) part of the force, the brain contained within it would
be frequently exposed to dangerous violence. The upper jaw is concerned in the pro-
cess of mastication merely as a means of support ; for though it may be raised when the
mouth is opened, and depressed when the mouth is shut, these movements belong to
the entire head, and result from the action of its extensor muscles, which thus become
powerful auxiliaries of mastication in the carnivorous animals.
Temporo-maxillary Articulation (figs. 65, 66, and 67).
This joint, the centre of all the movements of the lower jaw, is a double condyloid ar-
ticulation. The articular surfaces are, 1. The two condyles of the lower jaw, transverse-
ly oblong, and directed somewhat obliquely inward and backward, so that their axis, if
prolonged, would intersect behind : 2. The glenoid cavity of each temporal bone, and the
transverse root of its zygomatic process. These surfaces are covered with cartilage.
The glenoid cavity is remarkable both for its depth and its capacity. Its depth is in-
creased by several eminences on its borders : viz., on the inside, by the spine of the
sphenoid ; and behind, by the styloid and the vaginal processes, the latter of which is
nothing more than the anterior lamina of the auditory meatus. The capacity of the
glenoid cavity is no less remarkable, being double or triple that which would be neces-
sary to receive the condyle ; moreover, the whole of this cavity is not articular, the part
situated behind the glenoidal fissure being extraneous to the joint. This disproportion
between thp cavity and the condyle is only observed in man and in ruminantia : in ro-
dentia and carnivora, the one is exactly proportioned to the other. The portion of the
glenoid cavity posterior to the fissure affords an example of those supplementary cavities
that, in certain circumstances, increase or replace the principal cavity. All that part of
the glenoid cavity situated anteriorly to the fissure belongs to the joint, and is, there-
fore, covered with cartilage.*
The transverse root of the zygoma, convex from before backward, and concave trans-
versely, is also articular, and covered by a cartilage, which is a continuation of that lining
the glenoid cavity. This articulation presents the only example in the body of two con-
vex surfaces moving upon each other.
The means by which motion is facilitated and union maintained in this articulation
are an inter-articular cartilage, an external lateral ligament, and two synovial mem-
branes ; the internal lateral ligament of some authors, and the stylo-maxillary ligament,
do not belong to this joint.
1. Inter-articular Cartilage {a, fig. 65). — This cartilage is interposed between the artic-
Pig, 65. ular surfaces ; it is thick at the circumference, and some-
times perforated at the centre, and resembles a bi-con-
cave lens, with this peculiarity, that its upper surface
is alternately convex and concave, to correspond with
the glenoid cavity and the transverse root of the zygoma ;
while the lower surface is concave, and adapted to the
condyle. Its circumference is free, excepting on the out-
side, whfere it adheres to the external lateral ligament,
and on the inside, where it gives attachment to some
fibres of the external pterygoid muscle. This circum-
stance is of great importance in regard to the mechanism
of the joint. The existence of an inter-articular cartilage in a joint which is subjected
to such considerable pressure, and is so often put in motion, agrees with the general
law already pointed out. (Vide The Akticulations in general).
* The study of the condyle and the glenoid cavity is of very great importance in comparative anatomy ; for
by the characters which they present, we may easily recognise the head of one of the rodentia, carnivora, or
ruminantia. 1. In carnivora, the condyles are transversely oblong, the long axes of both being in the same
line ; they are received into very deep cavities. 2. In rodentia, on the contrary, the long ditinietiy of the con-
dyles is directed from before backward. 3. In ruminantia, the glenoid cavity is flat, as well as the head of
the condyle, while the transverse root of the zygoma is scarcely discernible.
ARTICULATIONS OF THE FACE.
129
Fig. 66.
2. External Lateral Ligament (J, fig. 66). — This ligament extends from the tubercle sit-
uated at the junction of the two roots of the zygoma to
the outside of the neck of the condyle : it is directed
obliquely downward and backward, and forms a thick
band covering the whole of the outside of the articu-
lation : it is in contact with the skin externally, and in-
ternally with the two synovial capsules, and the inter-
articular cartilage.
Anatomists have described, under the name of the
internal lateral or spheno-maxillary ligament (c, fig. 67),
an aponeurotic band, which, neither as regards its po-
sition or its use, can be considered as properly belong-
ing to the joint ; it is extended from the spinous process of the sphenoid to the spine sit-
uated on the inside of the orifice of the inferior dent2il canal. It is a very thin band,
which covers the inferior dental vessels and nerves, and pig^ 67.
separates them from the pterygoid muscles. Since the band
just described has no effect in giving strength to the joint,
it may be wondered that there is only one ligament for the ^g^^ TMHilllBUmK
articulation ; but it should be observed that, as the lower ^* VrnWiillilfri
jaw is articulated in the same manner at both its extrem-
ities, the external lateral ligament of the one exactly per-
forms the functions of an internal lateral ligament to the
other.
The stylo-maxillary ligament (d, figs. 65, 66, and 67) ap-
pears to me to hold the same place as the preceding ; it is a fibrous band extending from
the styloid process to the angle of the inferior maxUla. It has no relation to the union of
the articular surfaces. Its use appears to be that of giving attachment to the stylo-
glossus muscle. Meckel calls it the stylo-mylo-hyoid ligament.
3. There are two synovial capsules in this joint, one on the upper and the other on
the lower surface of the inter-articular cartilage (see fig. 65). Sometimes they commu-
nicate by an opening in the cartilage ; the superior is looser than the inferior ; and thus
the articular cartilage is more closely united to the condyle of the lower jaw than to the
glenoid cavity.
These two synovial capsules are in contact on the outside with the external lateral
ligament, and elsewhere with a thin layer of fibrous tissue.
Mechanism of the Temporo-maxillary Articulation.
In considering the action of this joint, the lower maxilla may be regarded as a ham-
mer which strikes against the anvil represented by the upper jaw ; it is a double angu-
lar lever, the axis of its motion being represented by a horizontal line that would pass
through the middle of the rami. This articulation, which belongs to the class of condy-
loid joints, has been ranged among the angular ginglymi, on account of the great extent
of its movements in two opposite directions, during its elevation and its depression ; but
it differs from them in being so constructed as to admit of slight lateral movements. It
can also be moved forward and backward.
1. Depression. — In this movement each condyle rolls forward in its glenoid cavity, and
then passes upon the transverse root of the zygoma, with a sudden jerk, which may be
easily felt by placing the finger on the condyle while the mouth is being opened ; at the
same time the angle of the jaw is moved backward. The condyle carries with it the
inter-articular cartilage ; for the union of these two parts is of such a nature that, even
in dislocation of the jaw, they are never separated. This depends not only upon the
comparative tightness of the lower synovial capsule, but also on the mode of insertion
of the external pterygoid muscle, which, being attached both to the neck of the condyle
and the inter-articular cartilage, acts simultaneously upon them. The other parts of the
joint are affected in the following manner : During depression of the lower jaw, the ex-
ternal lateral ligament is stretched ; the upper synovial capsule is distended behind, but
readily yields on account of its laxity. The spheno-maxillary band, or internal lateral
ligament, which is inserted at an almost equal distance from the condyle, which is car-
ried forward, and from the angle of the jaw, which is carried backward, remains unal-
tered, being neither stretched ner relaxed.
When the depression is carried too far, either from the effect of a blow upon the bone,
or during a convulsive yawn, the condyle is dislocated into the zygomatic fossa;, tearing
the superior synovial capsule, and carrying with it the inter-articular cartilage.* Thi^
mode of displacement is impossible in the infant ; for, from the obliquity of the ascend-
ing ramus of tlie jaw, the upper part of the condyle looks backward, and, in order to be
* This luxalion-would be much more common were it not for the inter-articular cartilage, which, by al-
ways iiiri.mpji. ying the condyle, presents a smooth surface, oTer which the latter may glide in returning^ into
R
130 ARTHROLOGY.
luxated forward, would have to traverse a much larger space than it does even when
the mouth is opened to the greatest possible extent.
2. In elevation, the condyle rolls backward, upon the transverse process, into the gle-
noid cavity. The external lateral ligament is relaxed. The obstacles to too great an
elevation are, 1. The meeting of the dental arches. 2. The presence of the vaginal
process and the anterior wall of the auditory meatus ; and it is very probable that the
extensive movements of the jaw in the old subject, when the teeth are lost, are permit-
ted by the size of the glenoid cavities. Without that portion of the glenoid cavity which
is behind the fissure of Glasserus, the toothless alveolar edges of the aged could never
be brought in contact.
The forward motion is not, like the preceding, the motion of a lever in which the jaw
turns upon its axis ; it is a horizontal movement, in which the condyle is brought under
the transverse root of the zygoma. A preliminary and indispensable condition to this
movement is a slight depression of the whole of the lower maxilla. In this movement
all the ligaments are stretched ; if it were carried too far, the coronoid process would
strike against the bone in the zygomatic fossa, and this circumstance would prevent the
possibility of luxation of the condyle.
The backward motion requires no special remark.
The lateral movements differ from the preceding in the mechanism by which they are
effected. In the first place, the whole bone does not move from its place. One of the
condyles alone escapes from its socket, while the other remains in the glenoid cavity.
The bone, therefore, turns upon one of the condyles as on a pivot.
The external lateral ligament of that articulation in which the condyle moves is much
stretched.
The lateral motions would have been much more extensive had not the two condyles
mutually obstructed each other in all movements but that of depression, by reason of
their opposite directions. This may be shown by sawing a maxilla through the middle,
and moving each of the halves. Moreover, the styloid and vaginal processes, and the
spine of the sphenoid, prevent displacement inward.
Articulations of the Thorax.
The articulations of the thorax comprehend, 1. The costo-verteDral articulations ; 2.
The chondro-sternal ; 3. The articulations of the cartilages of the ribs with each other ;
4. The junction of the cartilages and the ribs.
The Costo-vcrtebral Articulations {figs. 58 to 60, and 68).
Preparation. — Saw the ribs across at their posterior angles. Remove with care the
pleura and the subjacent cellular tissue in front, and the muscles of the vertebral grooves
behind. After having studied the superficial ligaments, expose, 1. The costo-transverse
interosseous ligament by a horizontal section of the rib, and the transverse process to
which it is attached ; 2. The costo-vertebral interosseous ligament by a similar horizon-
tal section, including one vertebra and one rib, and passing above the angular part of the
joint. This last ligament may be also exposed by a vertical section of the rib and the
two vertebrae with which it is connected. The costo-vertebral articulations have some
characters which are common to them all, and others that are peculiar to a few.
General Characters of the Costo-vertebral Articulations.
Articular Surfaces. — In this joint, the head of the rib is applied to the angular surface
formed by the two half facettes (//, fig. 58) upon the sides of the bodies of the dorsal
vertebraj, so that each rib is articulated with two vertebrae {costo-vertebral articulation,
properly so called) ; and, in addition, the tubercle of the rib is applied to the facette {g,figs.
58, 60, and 68) on the fore part of the transverse process {costo-transverse articulation).
With regard to the costo-vertebral articulation, it is to be remarked, 1 . That it affords
an example of a projecting angular facette received into a retreating angular facette,
which has giver, rise to the mistaken notion that this joint is an angular ginglymus ; and,
2. That in each articulation the lower hcdf facette is twice as large as the upper.
The surfaces of the costo-transverse articulation are, a convex facette belonging to the
tubercle of the rib, and a concave one belonging to the tranverse process. Sabatier af-
firms that the articular surfaces of the transverse processes look forward and upward in
the upper vertebrae, and forward and downward in the lower, and directly forward in
those which occupy the middle of the column. This arrangement has been referred to
in explanation of the mechanism of the dilatation of the thorax, by depression of the low-
er, and elevation of the upper ribs ; but this explanation is unfounded.
In addition to the costo-vertebral and costo-tran verse articulations, the neck of the rib
{c,fig. 68), without being in immediate contact with the tranverse process, is, in some
degree, united with it by symphysis.
Means of Union. — These joints are examples both of symphysis and arthrodia. Some
of the ligaments are external to the articulation, the remainder are interosseous.
The ligaments external to the articulation are, the anterior costo-vertebral or stellate lig-
ARTICULATIONS OF THE THORAX. 131
ament, the superior and the inferior ligsiments, the posterior costo-transverse, and the
superior costo-transverse.
1. The anterior costo-vertebral, or stellate ligament {I, fig. 58), arises from the two verte-
brae with which the rib is connected, and from the corresponding intervertebral substance.
From these points its fibres converge, and are inserted in front of the extremity of the rib.
2 and 3. Besides the stellate ligament there are two small ligamentous bundles, a su-
perior and an inferior, which extend from each of the vertebrae, concurring to form the
articulation, to the extremity of the rib.
4. The posterior costo-transverse ligament {m,fig. 59 : transverse ligament of Boyer, poste-
rior costo-transverse ligament of Bichat) is a fibrous band stretched from the apex of the
transverse process, in an oblique direction, to the non-articular portion of the tubercle of
the rib.
5. The superior costo-transverse ligament (n, figs. 58, 59 : costo-transverse of Boyer, infe-
rior costo-transverse of Bichat) consists of a band, which arises from the lower edge of
each transverse process, passes obhquely, and is inserted, not into the rib, which articu-
lates with that process, but into the upper edge of the neck of the rib below. At the
place of this insertion, we always find a crest or spine. This ligament is sometimes di-
vided into two or three bundles ; it forms the continuation of a thin aponeurosis, which
covers the external intercostal muscle, and completes the externjd wall of the opening
through which the posterior branches of the intercostal vessels and nerves are transmit-
ted. This ligament is interposed between the anterior and posterior branches of these
vessels and nerves.
The interosseous ligaments are two in number. 1. A costo-vertebral interosseous ; 2.
A costo-transverse interosseous.
1. The costo-vertebral interosseous ligamervt (o,fig. 58) is a small bundle of fibres, very
short and very thin, extending horizontally from the projecting angle on the head of the
rib to the retreating angle of the vertebral facette, where it is continuous with the inter-
vertebral substance.
2. The costo-transverse interosseous ligament (a, fig. 68) is formed by some ligamentous
bundles intermixed with reddish adipose tissue, which stretch jYg-. 68.
from the anterior surface of the transverse process to the pos-
terior surface of the neck of the rib. An idea of the strength
of this ligament may be formed by attempting to separate the
rib from the transverse process, after the anterior costo-ver-
tebral and the posterior costo-transverse ligaments have been
divided.
There are three synovial capsules in the articulations of the
ribs with the vertebrae : one between the tuberosity and the
transverse process, and two small ones for the two surfaces which are separated by the
costo-vertebral interosseous ligament.
Characters peculiar to certain Costo-vertebral Articulations.
The articulations of the first, eleventh, and twelfth ribs alone present peculiarities.
1. Costo-vertebral Articulation of the First Rib. — The rounded head of the first rib is re-
ceived into a cavity on the side of the body of the first dorsal vertebra ; the articulation
is, therefore, a species of enarthrosis ; there is neither a costo-vertebral interosseous lig-
ament, nor a superior costo-transverse ligament ; the synovial membrane is much looser
than in the corresponding articulations.
2. The costo-vertebral articulations of the eleventh and twelfth ribs present the same char-
acters as the preceding in this respect, that the articular cavity for the head of the bone
is situated upon one vertebra alone. The head of the rib is flattened, or very slightly
convex, and there is no interosseous costo-vertebral ligament. The superior costo-trans-
verse ligament is much broader and stronger than in the other articulations. As the
eleventh and twelfth ribs have no tuberosities, and the transverse processes of the cor-
responding vertebrse are but little developed,* it follows that there is no costo-transverse
articulation ; but yet there is a costo-transverse interosseous ligament. All these liga-
ments are much more loose than in the other articulations.
Tlie Chondro-sternal Articulations (Jig. 69).
There are §even in number on each side, formed by the internal angular end of the
cartilages, which are received into the angular cavities on the side of the sternum. The
means of union are, 1. A radiated or anterior chondro-sternal ligament {a, fig. 69), which is
tolerably strong : it crosses in the median line with the corresponding ligament of the
opposite side, and is blended both with the periosteum and the aponeurotic insertions of
the greater pectoral muscles, in the thick fibrous layer which covers the sternum ; 2.
Two small ligaments, a superior and an inferior ; 3. A radiated or posterior chondro-sternal
ligament, much weaker than the anterior. The existence of a synovial membrane is
* Sometimes, however, the transverse process of the eleventh dorsal vertebra is enlarged, and articulated
to the eleventh rib.
132 ARTHEOLOGY.
merely inferred from analogy, for it cannot be demonstrated. {Vide Articulations in
GBNERAL.)
The first, second, sixth, and seventh chondro-stemal articulations present some pe-
culiarities. 1. The cartilage of the first rib is sometimes continuous with the sternum,
and is sometimes articulated like the cartilages of the other ribs. I found in one sub-
ject the first rib excessively movable, because its cartilage, instead of being continuous
with the sternum, had its upper edge applied to the side of that bone to which it was
united by ligaments, and was ultimately articulated by a narrow extremity immediately
above the second rib. 2. The second cartilage (ft) is much more angular at its inner ex-
tremity than any of the others ; it is received into the retreating angle formed by the
union of the first two pieces of the sternum. Sometimes there is an interosseous liga-
ment in this joint, running from the angle of the cartilage to the bottom of the cavity,
and there are then two synovial capsules : in other cases there is only one (c), but it is
always more marked than in the other joints. 3. The articulations of the sixth and sev-
enth cartilages, besides the anterior ligaments, have also a chondro-xiphoid ligament more
or less strong, which crosses with the ligament of the opposite side in front of the ensi-
form cartilage and the lower end of the sternum. Sometimes this ligament only exists
for the seventh cartilage ; it is intended not only to strengthen the chondro-stemal ar-
ticulations, but also to maintain the xiphoid appendix in its place.
The Chondro-costal Articulations.
The cartilages are immovably united to the ribs ; the anterior extremity of the rib is
hollowed to receive the external end of the cartilage : there is no ligament. The perios-
teum is the only bond of union between the costal cartilage and the rib, as in the articu-
lations of the cranial bones.
The Artiadations of the Costal Cartilages.
The first, second, third, fourth, and fifth costal cartilages do not articulate together,
unless the aponeurotic laminae, sometimes very strong, which form the continuation of
the external intercostal muscles, and occupy the whole length of the cartilages, be con-
sidered as uniting media.
The sixth, seventh, and eighth cartilages, frequently the fifth, and sometimes the ninth,
present true articulations. Some cartilaginous processes arise from the neighbouring
edges, and come in contact with each other : there are sometimes two articular facettes
between the sixth and the seventh cartilages. The means of union are some vertical
fibres united in bundles so as to form two ligaments, the one anterior and thicker, the
other posterior and thinner. There is a much more distinct synovial membrane than in
the chondro-stemal articulations. The seventh, eighth, and tenth cartilages have not
always articular facettes, but are simply united by vertical ligaments.
Mechanism of the Thorax.
As the thorax performs the double oflice of protecting the organs which it encloses, and
el assisting by its movements in the function of respiration, we must consider its mecha-
nism with reference to both these ends.
Mechanism of the Thorax for the Protection of the contained Organs.
1. The following is the mechanism by which the thorax is enabled to resist pressure
or violent blows directed from before backward. The sternum is supported by the four-
teen ribs, which, like buttresses, oppose their united strength to any causes of displace-
ment or fracture ; it is therefore very rare to find the sternum driven backward, and all
the ribs broken, however great the violence may have been. The elasticity of the car-
tilages and of the ribs, and the number of articulations which exist in the thorax, are all
circumstances most favourable to strength, because they diminish the intensity of exter-
nal blows by neutralizing a certain amount of impulse : yet I have met with one case in
which all the sternal ribs were broken by a fall, as completely as if the anterior wall of
the thorax had been divided for an anatomical preparation. I should remark, also, that
the flexibility of the ribs and their cartilages permits great depression of the sternum
without fracture ; and this explains the possibility of contusion, and even rapture of the
heart, lungs, or great vessels, without fracture of the bones of the thorax. The degree
of resistance of the anterior wall of the thorax may be also considerably varied by the
state of relaxation or contraction of the muscles, which should be considered as active
and contractile supports to the arch, of which the stemum forms the key-stone.
2. In the case of lateral pressure or blows, the thorax resists, like an arch, the vault
of which is represented by the convexity of the twelve ribs, and its pillars by the ster-
num in front and the vertebrae behind. External violence cannot act upon the whole
side of the chest at once, as it does upon the front, and therefore the ribs ofltr a more
partial resistance laterally, and are accordingly much more easily broken by direct blows
In this case, also, as in the former, when the elevator muscles of the ribs are in action,
the resistance is considerably increased ; and individuals have been then able to beai
ARTICULATIONS OF THE RIBS. 133
giiorttious •WTei^ts, which would, in all probability, have fractured the ribs, had the raus>
cles been relaxed.
What has been said above of the manner in which the ribs withstand violence is not
however, applicable to the false ribs, which, having no fixed point on the stemui.l are
depressed into the abdominal cavity.
Mechanism of the Thorax with reference to Mobility.
The thorax is not equally movable throughout. The middle portion, which corresponds
to the heart, and which is formed by the sternum and vertebral column, has a very limit-
ed degree of mobility, vvhile the sides which correspond to the lungs are endowed with
the power of extensive motion.
The movements of the thorax consist of alternate dilatations and contractions, from
which its mechanism has been compared to that of a pair of bellows. They result from
the motions which take place at the costo-vertebral and chondro-sternal articulations,
and at the articulations of the cartilages with each other. We cannot explain the move-
ments of each rib, and of the entire thorcix, without first analyzing the motions at each
of the above joints.
Movements of the Costo-vertebral Articulations.
These articulations permit only very limited gliding motions. In these movements,
each rib represents a lever, which moves upon the fulcrum afforded by the vertebral col-
umn. It may describe the movements, 1. Of elevation; 2. Of depression ; 3. It may be
carried inward ; 4. It may be carried outward ; 5. It may perform a revolving motion
around the cord of the arc which it represents. These different movements, which are
very obscure in the immediate neighbourhood of the joint, are more evident the gieater
the distance is from the posterior end of the rib. The means of union between the ribs
and vertebrae are so strong, that luxation of the ribs is impossible ; and the causes which
would tend to produce it would break the neck of the rib.
Each rib is capable of performing all these motions ; but, as they vary in degree in the
different ribs, we must examine them comparatively in the series of costo-vertebral ar-
ticulations. The eleventh and the twelfth ribs possess the most extensive power of
motion. They owe this, 1. To the circumstance of their being scarcely at aU united to
the very small transverse processes ; 2. To the loose state of their ligaments ; and, 3.
To the almost perfect flatness of their articulated surfaces. The extent of their move-
ments inward and outward should also be noticed. We shall find these movements
but less pronounced, in the eighth, ninth, and tenth ribs, they scarcely exist in the first
seven ribs.
The shape of the head of the first rib is undoubtedly favourable to mobility, and has
suggested the idea that it is the most movable of all the ribs ; but the articulation of
its tubercle with the transverse process of the first dorsal vertebra, and the tightness
of its ligaments, suflSiciently explain why this opinion is erroneous.
The movements which take place in the second, third, fourth, filth, sixth, and seventh
costo-vertebral articulations do not differ sufficiently to require any special mention.
Movements of the Chondro-sternal Articulations.
In these articulations there is even less gUding than in the preceding. The anterior
extremity of the first rib, or, rather, of the cartilage which forms its continuation, is the
least movable of all ; more commonly, it is completely fixed on account of its continu-
ity with the sternum, a circumstance which neutralizes the favourable conditions for
mobility presented by its posterior extremity. The eleventh and twelfth ribs, whose
anterior extremities are connected only to soft parts, are the most movable. The mo-
bility of the ribs in front decreases from the lower to the upper part of the thorax ; to
this rule the second rib is an exception, chiefly on account of tlie two synovial mem-
branes at its chondro-sternal articulation, which permit of greater motion. This, how-
ever, is variable, depending as it does on the absence or presence of an articulation be-
tween the first and second bones of the sternum, and upon the more or less variable
mode in which these two pieces are articulated.
Movements of the Cartilages upon each other.
The movements of this kind are restricted to the sixth, seventh, eighth, ninth, and
tenth ribs, the cartilages of which alone are articulated to each other. They are simple,
gliding motions, and this gliding is proportionate to the looseness of the ligaments.
Hence it follows, that the ribs wliich I have just mentioned are always moved simul-
taneously as they gUde slightly upon each other ; whereas the superior ribs are inde-
pendent in their movements. This independence, however, is not as great as it might
appear at first sight, on account of the interosseous aponeuroses, the interosseous mus-
cles, and the superior transverso-costal ligament, which is very narrow above, and forms
below large and shining aponeurotic laminae.
It results, from the facts above stated, that the most movable ribs are the twelfth
and the eleventh, which may be moved upward and downward, and, at the same time,
134 ARTHROLOGY.
enjoy, in the highest degree, the movements of projection inward and outward ; that
the first rib is the least movable of all ; that the superior ribs may be moved isolatedly ;
that the inferior ribs are moved all together.
Movements of the entire Rib.
Since we now know all the elements of which the movement of the ribs is composed,
we shall easily comprehend the play of each of those bones isolatedly, and the play of
the whole thorax.
The movements of the entire rib are composed, 1. Of those which take place at the
sternal and vertebral articulations ; and, 2. Of those which result from its own flexibility
and elasticity. We shall endeavour to reduce the subject to its most simple elements.
Let us suppose, then, that the ribs are straight, inflexible levers : from their oblique po-
sition in reference to the vertical axis of the spinal column, their elevation will increase
the width of the intercostal spaces ; for it is a law of physics, that lines which are ob-
lique with regard to another line, and parallel to each other, become farther separated
when they are placed perpendicularly to that line. Hence it follows, that the contact or
the overlapping of the ribs is impossible during the movement upward of these bones. A
second effect of the elevation of this oblique lever is the advancement of the anterior
extremity of the rib, which movement increases proportionately to the length of the le-
ver ; hence results an increase of the antero-posterior diameter of the thorax. But as
the ribs are curved levers, and not rectilinear, in assuming the horizontal position, their
concavity must come to be directed perpendicularly to the median plane formed by the
mediastinum. It may be shown, geometrically, that the concavity of an arc which falls
perpendicularly upon a plane, includes a greater space than when it falls obliquely. From
the elevation of the ribs results, therefore, an increase of the transverse diameter of the
thorax.*
The arcs of the ribs, however, have not all the same curvature : each rib has its own
peculiar perimeter, and it may be proved that the more curved the rib, the greater is the
projection outward which it forms when elevated. Lastly, as in some ribs the upper
border forms the segment of a smaller circle than the lower, the movement of projection
outward is proportionally greater in these than in the other ribs. This assertion may
be experimentally proved by imitating the movements of elevation and depression on
the second rib. I- The greater the disproportion between the curvature of the superior
and that of the inferior border, the more marked will be the projection gjitward. This
is the reason why the elevation of the second and third ribs, when they are bent at once,
both by their faces and their borders, produce such a remarkable increase of the thoracic
capacity.
If the ribs and their cartilages were inflexit)le levers, the movements of elevation
would be much restrained ; but, by a mechanism, of which we find no instance elsewhere,
the flexibility of these levers introduces into the problem a power which is most impor-
tant and very variable, so that their movements are much more marked than would arise
from the mobility of the articular surfaces. These movements cannot be determined by
calculation. Now this flexibility, whence results a movement of torsion in the rib, or
of rotation round an axis, represented by the cord of the arc which the rib forms, is in a
direct ratio to the length of the ribs and their cartilages, and the flexibility of either.
Indeed, the movements of the ribs are much more considerable in children and women
than in old men ; and the deficiency of mechanical power in regard to breathing, which
corresponds to the smallness of the power of locomotion in old men, explains the sever-
ity which characterizes asthma and all the diseases of the lungs at this age.
We shall now examine the movements of the thorax in genercil.
Movements of the Thorax in general.
The general movements of the thorax, which result from those partial motions we
have been engaged in considering, are, 1. A movement of dilatation, corresponding with
the act of inspiration ; 2. A movement of contraction, corresponding with that of expi-
ration.
1 . The dilatation of the thorax is caused by the elevation of the ribs. By this move-
ment, the anterior extremity of each rib is carried forward, and the antero-posterior di-
ameter of the thorax is thus increased ; the most eccentric portion of the rib is carried
outward, and the transverse diameter of the thorax is thereby augmented. There is a
sort of antagonism between the upper and lower part of the thorax, with regard to the
direction in which the increase of its capacity is effected : in the upper part the trans-
verse diameter is most augmented ; in the lower, the antero-posterior diameter.
The most movable point in the superior ribs is at the centre of the curvature ; the
most movable point of the inferior ribs is at the junction of the ribs and the cartilages
But the columns to which the extremities of the ribs are attached are not equ£iUy mo-
* BoreUi, t. ii., p. 177.
t From measurements taken by Haller, it appears that the second rib is the most elevated during inspira-
tion ; and if this may be doubted, it cannot be denied that its eccentric movement is greater than that of ant
»f the other ribs.
ARTICULATIONS OF THE SHOULDER. 135
vable : if the posterior extremity is fixed, the anterior extremity may be moved from its
place. This circimistance does not oppose the transverse enlargement being produced
by the elevation of the arcs of the ribs, though it introduces a new condition into the
problem, to wit, the elevation of the anterior column or the sternum. So long as the
movement of elevation of the ribs is limited to the costo-vertebrcd articulations and a
slight flexibility of the ribs and their cartilages, the sternum scarcely participates in the
motion ; but when the elevation is carried beyond a certain point, when all the powers
of inspiration are in activity, when there is an integral movement of the thorax, which
has not been sufficiently distinguished from the partijd movement, then the sternum is
carried upward with the ribs, then the first two ribs, which we have represented as the
essential props of the sternum, are themselves elevated, and this elevation must be the
Scune as that of all the other ribs, and must, therefore, be proportionately more consider-
able. Does the sternum perform an angular motion during its elevation, as Haller ima-
gined 1 On placing the thorax between two parallel planes, and on executing a forci-
ble movement of inspiration, we feel at the inferior portion a pressure, which seems to
indicate, in this inferior portion, a movement of projection forward. The lever formed
by the inferior ribs being longer, it seems, indeed, as though there ought to be an angular
motion ; but it will be observed that there is no pression tending to diminish the curve
which is described by the ribs ; that therefore the two halves of the arc which the curves
represent do not recede from each other, and that the powers of elevation simply draw
all the anterior extremities of the ribs upward ; indeed, the sternum is simply elevated
near the cervic£d region, retaining; its primitive direction, as Borelli had previously well
pointed out ; considering the flexibility of the cartilages, the angular motion is almost
impossible.
The enlargement of the thorax is effected by the elevation of the ribs, and takes place
either transversely forward or backward. The enlargement of the thorax in a vertical
direction is produced by a totally different mechanism, the contraction of the diaphragm,
of which we shall speak hereafter.
2. Let us now speak of the contraction of the thortix. This contraction is effected by
the depression of the ribs. In the first stage, the contraction is passive, because it re-
sults from the elasticity of the cartilages, which, on account of the relaxing of the eleva-
tor muscles, cease to be maintained in a state of torsion, and therefore react and restore
the rib to its primitive position, so that the rib and cartilage, according to the ingenious
remark of Haller, are alternately the cause of their respective movements. It ought to
be remarked, that the movement of depression is much more limited than the movement
of elevation ; and I may justly regard the superior transverso-costal hgament as being
destined to impose particular limits to that depression, during which the intercostal
spaces are narrowed. We may regard as a powerful auxiliary of the depression and the
contraction of the thorax the movement of projection inward, especially in the last five
ribs, which are in certain respects depending upon each other. This movement of pro-
jection inward is opposed to the transverse dilatation or the movement of projection out-
ward, which takes place especially at the superior portion, as has been seen above, and
as is shown every day by the use of the corsets. Afterward we shall see that the great
inspiratory powers, or powers of elevation, occupy the superior portion of the thorax, as
the great expiratory powers occupy the inferior portion. To the integral elevation of
the thorax, in the most considerable degree of contraction, corresponds an integral de-
pression, and this depression of the ribs is directly produced by muscles which bear the
name of expiratory muscles.
ARTICULATIONS OF THE SUPERIOR OR THORACIC EXTREMITIES.
Articvlaiions of the Shoulder. — Scapulo-humeral, — ■Humero-cuhital. — Radio-cubital. — Radio-
carpal.— Of the Carpus and Metacarpus. — Of the Fingers.
Articulations of the Shoulder.
The two bones of the shoulder are articulated together ; the clavicle is also united
with the sternum and the first rib. There are, therefore, two orders of articulations : 1
The intrinsic articulations of the shoulder, viz., the acromio- and coraco-clavicular artic-
ulations ; 2. The extrinsic, or the sterno- and costo-clavicular.
The Acromio- and Coraco-clavicular Articulations.
The clavicle is articulated, 1. With the acromion by its external extremity, the acro-
mio-clavicular articulation ; 2. With the coracoid process by its lower surface, the coraco-
clavicular articulation.
Preparation. — Remove the skin, the cellular tissue, and the muscles which surround
the joints ; separate the acromion from the spine of the scapula ; remove, in succession,
the different layers of the superior acromio-clavicular ligament, so as to be able to judge
of its thickness. Make a vertical section of the acromio-clavicular articulation, so as to
be able to observe the thickness of the ligaments and articular cartilages.
136 ARTHROLOGY.
Aeromio-clavicular Articulation {fig- 69).
Articular Surfaces. — ^The clavicle and the acromion process oppose to each other a
plane, elliptical surface, with its greatest diameter directed from before backward. The
articular surface of the clavicle looks somewhat obliquely downward and outward, the
acromial facette looks obliquely upward and inward. The extent of these surfaces va-
ries greatly in individued cases, dependant on the degree of exercise to which the joint
is subjected.*
Means of Union and Promsion for facilitating Motion. — These are, 1. An intcr-articidar
cartilage, first pointed out by Weitbrecht ; it is by no means constant, and, when it does
exist, occupies only the upper half of the articulation. 2. An orbicular fibrous capsule {d,
fig. 69), which is very thick above and behind, and very thin below. It is composed of
distinct bundles, which are much longer behind than in front, and are strengthened by
some fibres belonging to the aponeurosis of the trapezius muscle ; it is not only attached
to the upper edge of the articular surface, but also to some inequalities upon the upper
surface of the acromion. It is composed of several layers, the deepest being the shortest.
3. A synovial membrane, of a very simple construction, supported below by adipose tissue.
Coraco-clavicular Articulation {fig. 69).
There can be no doubt concerning the existence of an articulation, where two surfaces
are contiguous, and capable of a gliding motion on each other ; one of them, the coracoid,
being almost always covered with carti-
lage and a synovial membrane ; and the
other, the clavicular, presenting some-
times a considerable process for this ar-
ticulation.
The means of union are two ligaments,
or, rather, two distinct ligamentous bun-
dles, a posterior and an anterior : they
are called coraco-clavicular.
1. The posterior ligament, named also
the conoid or radiated (c, fig. 69), is trian-
gular, and directed vertically ; it com-
mences by a narrow extremity, at the
base of the coracoid process, and is inserted into a series of tubercles on the posterior
edge of the clavicle, near its outer extremity.
2. The anterior ligament (/) {trapezoid ligament of Boyer) arises from the internal edge
of the coracoid process, and from the whole extent of the rough projection on the base
of this process ; from this it proceeds very obliquely to the ridge on the lower surface,
near the external end of the clavicle.
The two coraco-clavicular ligaments are continuous, and can only be distinguished by
the direction of their fibres.
We might with propriety range among the means of union of this joint an aponeurotic
lamina, to which much importance has been attached in surgical anatomy, and which is
known by the name of the costo-clavicular aponeurosis, or costo-coracoid ligament. It
may be easily felt under the pectoralis major in emaciated individuals : it extends from
the inner edge of the coracoid process to the lower surface of the clavicle, and converts
the groove for the subclavius muscle into a canal.
Mechanism of the Acromio- and Coraco-clavicular Articulations.
The acromio- and coraco-clavicular articulations perform well-marked gliding move-
ments ; and, in addition, the scapula rotates forward and backward upon the clavicle to a
considerable extent. In order to have a correct idea of these motions and their mecha-
nism, it is necessary to procure a shoulder with the ligaments still attached, and to ro-
tate the scapula backward and forward. It will be then seen that the scapula turns round
an imaginary axis passing through its middle. The looseness of the posterior half of the
orbicular and of the coraco-clavicular ligaments permits this rotatory motion ; of the two
coraco-clavicular ligaments, one limits the rotation forward, while the other, which, as
we have observed, runs in an opposite direction, hmits the rotation backward. Although
these motions are pretty extensive, they never give rise to dislocation, which can only
be produced by falls on the top of the shoulder, the coraco-clavicular ligaments being
lacerated if the luxation be complete. Incomplete luxations may, however, take place
without laceration of these ligaments.
The Sterno-clavicular Articulation {fig. 69).
The articulation of the inner end of the clavicle is composed of the sterna-clavicular
and the costo-clavicular articulations.
Preparation. — Saw through the clavicles vertically at their middle, and also the first
ribs at corresponding points ; and meet these two sections by a horizontal division of the
* In indiyiduals who have excrciscil the upper extremities very much, these surfaces are uneven, and
unequally incrusted '"•th np^lv-fonned cartilage.
ARTICULATIONS OF THE SHOULDER. 1^7
Sternum. In order to see the interior of the sterno-clavicular joint, open the fibrous cap-
sule along the edge of the sternum above, or, rather, make a horizontal cut, which will
divide it into two parts, an upper and an under.
In order to examine the costo-clavicular articulation, open the synovial membrane be-
hind.
The sterno-clavicular articulation belongs to those which are formed by rmitual reception.
Articular Surfaces. — The articular surface of the sternum is transversely oblong con-
cave in the same direction, and convex from before backward ; it looks obliquely upward
and outward, and is situated on the side of the notch on the upper part of the sternum.
1. The articular surface of the clavicle is oblong from before backward, slightly concave
in the same direction, and convex transversely. From the respective configuration of
these surfaces a mutual jointing results, and the short diameter of the one corresponds to
the long diameter of the other ; so that the end of the clavicle overlaps the surface of the
sternum in front and behind, and the surface of the sternum projects beyond that of the
clavicle on the inside and the outside.*
2. There is an inter-articular lamina of cartilage (i. Jig. 69) between the articular sur-
faces, which is moulded upon them, and is very tliick, especially at the edges. It is
sometimes perforated in the centre. + It is so closely united by its circumference to the
orbicular Hgament that it is impossible to separate them : it adheres below to the carti-
lage of the first rib, and above and behind to the clavicle.
Means of Union. — These are, 1. The orbicular ligament {I, fig. 69). This name may be
given to the fibrous capsule which surrounds the joint in all directions. The fibres which
compose it have been regarded as forming two distinct bundles, known by the name of
anterior and posterior ligaments ; but it is impossible to distinguish between them. Fi-
bres proceed from all parts of the circumference of the articular surface of the clavicle,
obliquely downward and inward, to the circumference of the articular surface of the ster-
num. The capsule is not of equal thickness throughout ; it is thinner, and somewhat
looser, in front than behind, which may partly account for the more frequent luxations
of the clavicle forward than backward.
2. The inter-clavicular ligament (wi, Jig. 69), consisting of a very distinct bundle stretch
ing horizontally above the fourchette of the sternum, from the upper part of the innei
end of one clavicle to the inner end of the other. This ligament, which is much nearer
the posterior than the anterior part of the joint, establishes a sort of continuity between
the clavicles. It is the only direct means of union between the two shoulders.
3. There are two synovial capsules in this joint. That which is between the sternum
and the inter-articular cartilage is more loose than that between the cartilage and the
clavicle.
The Costo-clavicular Articulation {Jig. 69).
The articulation between the clavicle and the cartilage of the first rib is an arthrodia.
It is formed between an articular surface, which almost always exists on the lower sur-
face of the clavicle, and a corresponding facette on the upper surface of the inner end
of the first rib, at its junction with the cartilage. There is, in this articulation, a syno-
vial membrane, which is loose, especially behind. There is only one ligament, the cos-
to-clavicular {g, Jig. 66), a thick, strong bundle of fibres, quite distinct from the tendon of
the subclavius muscle, which is placed in front of it. It is fixed to the inner part of the
first costal cartilage, and is directed very obliquely upward and outward, to be inserted
into the under surface of the clavicle, to the inner side of the articular facette.
Mechanism of the Sterno-clavicular Articulation.
This articulation is the movable centre of the motions of the shoulder and of the
whole upper extremity ; and hence the utility of an inter-articular cartilage, to obviate
tte effects of blows or pressure : hence, also, the wearing away of this cartilage, the de-
formity and wasting of the articular surfaces, the depression of the right sternal facette,
and, lastly, the difference in the size of the sternal extremities of the right and left
clavicles.
This articuation, like all those effected by mutual reception, admits of motions in
every direction : viz., upward, downward, forward, backward ; and of circumduction,
resulting from the preceding, but not of rotation.
1. Movement of Elevation. — In this the sternal facette of the clavicle glides downward
upon the corresponding surface of the sternum ; the inter-clavicular ligament is relaxed ;
the cartilage of the first rib comes in contact with the inner extremity of the clavicle,
limits the degree of elevation, and prevents displacement.
2. Movement of Depression. — In this the sternal end of the clavicle glides in the oppo
site direction ; the articular surfaces of the costo-clavicular articulation press strongly
* Bichat considers that this arrangement of the articular surfaces predisposes to luxation ; it appears to ma
to have a precisely opposite effect, as it permits tho surfaces to move upon each other to a considerable extent
without being separated. i,- i, i,
t In a great number of cases this ligament is found partially wasted by the continued pressure to which the
joint is subjected.
s
138
ARTHBOLOGY.
against each other, and limit the extent of this movement. It should be remarked, that
in this movement the subclavian artery is compressed betvi^een the clavicle and the first
rib, sometimes so completely as to arrest the circulation in the limb.
3. In the movement of the shoulder backward, the inner end of the clavicle glides for-
ward upon the surface of the sternum ; the anterior part of the orbicular capsule is
stretched ; and if the movement is carried beyond a certain point, the capsule is torn,
and the clavicle dislocated forward.
4. In the foricard movement of the shoulder, the inner end of the clavicle glides back-
ward. The anterior part of the orbicular ligament is relaxed, and the posterior part
stretched ; as, also, the inter-clavicular ligament, which, as we have seen, is nearer the
back than the front of the joint. In this motion luxation may take place backward. It
may be remarked that, of all the movements of the shoulder, the one described, in which
the clavicle is likely to be dislocated backward, is the most uncommon.
The movement of circumduction is more extensive forward and upward than backward.
The motions at the sterno-clavicular articulation are very circumscribed in themselves ,
but when transmitted by the lever of the clavicle, they become very considerable at the
apex of the shoulder.
Mechanism of the Costo-clavicular Articulation.
This articulation, which may be regarded as a dependance of the sterno-clavicular,
admits of very limited motions, subordinate to those of the joint last described.
The Scapulo-humeeal Articulation {figs. 69 and 70).
Preparation. — Separate the upper extremity from the trunk, either by disarticulating
the clavicle at its sternal end, or by dividing it through the middle ; 2. Detach the del-
toid from its origin ; 3. Detach the supra and infra spinati muscles, the teres minor and
subscapularis, proceeding from the scapula to the humerus ; 4. Observe the adhesion of
the tendons of these muscles to the capsular ligament ; 5. Divide the capsule trans-
versely, after having studied its external aspect.
The scapulo-humeral articulation belongs to the class of enarthroses.
Articular Surfaces. — These are the glenoid cavity of the scapula, slightly concave, of
an oval form, with the large end downward, and looking directly outward ; and the head
of the humerus, consisting of about a third of a sphere, and presenting a surface three or
four times more extensive than the glenoid cavity. The axis of the head of the hume-
rus forms a very obtuse angle with that of the shaft of the bone.*
These two surfaces are covered by a layer of cartilage, which, on the head of the hu-
merus, is thicker at the centre than at the circumference ; while the reverse obtains in
the glenoid cavity.
Glenoid Ligament (a, fig. 70). — This is a fibrous circle, which surrounds the margin of
Fig. 70. the glenoid cavity, and appears to be formed by the bifur-
cation of the tendon of the long head of the biceps ; but it
is also partly composed of fibres proper to itself, which
stretch along the margin, arising from one point and ter-
minating in another. Notwithstanding this addition, the
head of the humerus is still too large to be received into
the cavity, so that a portion of it is always in contact with
the capsular ligament ; an inconvenience that is obviated,
in some measure, by the existence of a supplementary
cavity, as we shall presently see. The scapulo-humeral ar-
ticulation is therefore one formed by juxtaposition, and not
by reception ; from which arrangement it has lately been
classed among the arthrodial articulations.
Means of Union. — Like all enarthroses, there is here a fibrous capsule, or capsular lig-
ament (r, figs. 69 and 70), a sac with two openings, which extends from the margin of
the glenoid cavity to the anatomical neck of the humerus, t This capsule is remarkable
for its laxity. In fact, it is so capacious that it could lodge a head twice as large as that
of the humerus, and is so long that it will allow the articular surfaces to be separated
for more than an inch ; the only example of so great a separation without laceration of
the ligament.t
There is this peculiarity in the fibrous capsule of the shoulder-joint, that it is incom-
plete in one part, its place being there supplied by the tendons of the surrounding mus-
cles. In no joints, in fact, have the muscles and tendons more effect in strengthening
the articulation : they are, in a manner, identified with it. There are a great many varie-
.ies in this respect. The fibrous capsule is so much stronger, as it is less adherent to the
* Such is the shortness of the neck of the humerus, that its head, which looks upward and inward, would
6e almost entirely included between the prolonged planes of the body of the humerus.
t It should be remarked, however, that the fibrous capsule does not terminate directly at the anatomical
neck of the humerus, but is prolonged a little downward, and becomes blended with the insertions of the ten-
dons of the supra and infra spinati and subscapularis.
i In paralysis of the deltoid, the head of the humerus is so far separated from the glenoid cavity thai two
fingers may be inserted betweeu the articular surfaces.
AKTICULATtONS OF THE SHOULDER. 189
surrounding tendons. The following are the relations of the capsule : 1. Below, in the
variable space between the subscapularis and teres minor, it corresponds to the cellular
tissue of the axilla, or, rather, to the thin edges of the muscles just mentioned : the head
of the humerus may, therefore, be easily felt by the fingers introduced deeply into the
axilla. 2. Above and on the outside, it is in contact with the tendon of the supra-spi-
natus, from which it is difficult to separate it, and is also in relation, though not immedi-
ately, with the arch formed by the acromion and clavicle with the deltoid muscle. 3. In
front, it corresponds to the subscapular muscle, from which it may be easily separated.
4. Behind, it corresponds to the tendons of the supra and infra spinatus, which are more
or less adherent to it, and the teres minor, which does not adhere to it. As to its struc-
ture, it is composed of fibres stretched irregularly from the neck of the humerus to the
circumference of the glenoid cavity. Its thickness is not great, nor is it equal through-
out, being most considerable below and in front ; but the capsule is strengthened above
by a considerable bundle of fibres (s, fig. 69), called the coracoid ligament, coraco-humeral
ligament, or accessory ligament of the fibrous capsule, which arises from the anterior edge
of the coracoid process, and spreads out on the capsule. This capsule always presents
an opening or an interruption above and before,* on a level with the superior border of
the subscapularis, which covers the opening in part ; or, rather, between this border
and the coracoid process. This opening is of an oval form ; its greatest diameter is
horizontal ; its large extremity is turned outward, and its small extremity inward. The
circumference of this opening, which is large enough to admit the point of the index fin- ,
ger, is perfectly smooth, thick, and looks like mother-of-pearl, especially in its inferior
half. This opening is traversed by a considerable prolongation of the synovial mem-
brane, which reaches the basis of the coracoid process, and then extends between the
tendon of the subscapularis and the cavity which bears the same name. This cone-
shaped prolongation is variable with respect to its extent, and appears to have no other
object except to facilitate the gliding of the tendon of the subscapularis under the cora-
coid arch and against the border of the glenoid cavity. By distending the articular cap-
sule in several subjects, Mr. Bonamy has demonstrated this disposition to my perfect
satisfaction. I have been able to see that the synovial prolongation is sometimes divi-
ded into several cells by incomplete walls, by which this distended prolongation acquires
a crimpled aspect. Sometimes several of these cells are totally distinct from the syno-
vial membrane.
Inter-articular Ligament. — This name may, with propriety, be applied to the tendon (t,
fig. 70) of the long head of the biceps, which, arising from the upper part of the glenoid
cavity, turns like a cord over the head of the humerus, and passes along the bicipital
groove. It acts by keeping the head of the humerus applied to the glenoid cavity, and
forms a sort of arch that supports the bone when it is forced upward. In two subjects,
I found this tendon terminating by a strong adhesion in the bicipital groove, and thus
justifying the name of inter-articular ligament, which I have applied to it : the tendon
for the long head of the biceps took its origin from the same groove. I consider this
division of the tendon to have been accidental, for the bicipital groove was depressed,
and the inter-articular ligament flattened, and, as it were, lacerated.
The synovial capsule is the simplest of all in regard to its disposition. It lines the
fibrous capsule and the tendons which replace it, and is reflected, on one side, on the
neck of the humerus, and, on the other, upon the border of the glenoid cavity, to be lost
upon the circumference of the articular cartilages. It is remarkable, inasmuch as, 1. It
forms a fold round the tendon of the biceps, which is prolonged into the bicipital groove,
and terminates below by a cul-de-sac or circular fold, which prevents the effusion of the
synovia ; 2. It is open in one or two points,+ and presents two prolongations communi-
cating with the synovial bursse of the subscapularis and infra-spinatus.
Supplementary Cavity. — ^We may regard as a dependance of the scapulo-humeral artic-
ulation the vaulted arch formed by the coracoid and acromion processes, and the liga-
ment which unites them. In shape it corresponds to the head of the humerus, and is so
constructed that the coracoid process prevents displacement inward ; the acromion pre-
vents it upward and outward ; and the ligament between them opposes dislocation di-
rectly upward. This provision evidently compensates for the incomplete reception of
the head of the humerus in the glenoid cavity. A circumstance which proves the use
fulness of this vault, and the frequent contacts which it must have with the humerus, is
the presence of a synovial capsule, situated between the coraco-acromion vault on one
* I have seen this opening divided into two unequal portions by a fibrous bundle, strong, looking like mother-
of-pearl, and resemliling a little tendon. Often 1 have met a second interruption of the fibrous capsule on a
level with the concave border of the acromion process, which concave border acts as a real retum-puHey for
the infra-spinatus muscle, and is analogous to the return-pulley presented by the basis of the coracoid process
to the subscapularis muscle. When the capsule is perforated at this point, the synovial membrane gives oflf a
prolongation, which serves as a gliding capsule for the tendon of the infra-spinatus.
t [Although the synovial capsule of the shoulder-joint is thus occasionally prolonged into the bursoe mucosal
connected with the tendons of these muscles, it must not, therefore, be supposed that it is an exception to the
general rule that membranes of this nature always form shut sacs ; in such cases, the three structures consti-
tute one coiitiiiuuus cavity.]
140 - " • . ARTHROLOGY.
side, and, on the other, the tendon of the infra-spinatus and the great trochanter of the
humerus. The study of the coraco-acromion vault cannot, therefore, be separated from
the study of the scapulo-humeral articulation, either under an anatomical and physiolo-
gical or surgical point of view.
The Coraco-acromial Ligament.
This ligament (m, figs. 69 and 70) forms part of the vault we have described : it is a
triangular bundle of radiating fibres, which extends from the apex of the acromion to the
A^hole length of the posterior edge of the coracoid process. Its external edge becomes
Ainner, and is continued into an aponeurotic lamina below the deltoid muscle, and sep-
arating that muscle from the joint. Its anterior and its posterior bundles are very thick,
folded upon each other, and look like mother-of-pearl ; its middle bundles are much less
thick. It is lined below by a synovial membrane, and is separated from the clavicle by
fatty tissue.*
Mechanism of the Scapulo-humeral Articulation.
The scapulo-humeral articulation admits of the most extensive movements of any
joint in the body : it is capable of every kind of motion, viz., forward and backward, and
also those of adduction, abduction, circumduction, and rotation.
Forward and Backward Motions. — In these the head of the humerus rolls upon the gle-
noid cavity, and moves round the axis of the neck of the humerus, while the lower extrem-
ity of the bone describes the arc of a circle, of which the centre is at the joint, the radius
being represented by the humerus.! The forward movement is very extensive, and may
be carried so far that the humerus may take a vertical direction exactly opposite to the
natural one. The motion backward is produced by the same mechanism ; the head of
the humerus turns upon its axis. This movement is limited by the contact of the head
of the humerus with the coracoid process, without which dislocation forward would be
very easily produced. It should be remarked that, in any considerable movement of the
humerus forward, the scapula is also moved, performing that sort of rotation which we
spoke of when considering the mechanism of the shoulder. And this combination of the
movement forward of the arm and the movement of rotation of the shoulder renders
every kind of displacement extremely difficult in exercising the movements of the arm
forward.
The movement outward, or abduction, is the most remarkable. It belongs exclusively
to animals possessed of a clavicle. In it the head of the humerus does not turn upon an
axis ; it glides downward upon the glenoid cavity, and presses upon the lower part of
the capsule. The shape of the glenoid cavity, which has its long diameter vertical, and
its broad part below, is advantageous as regards this motion. When abduction is car-
ried so far that the humerus forms a right angle with the axis of the trunk, a great part
of the head of the bone is below the glenoid cavity. If, while in this condition, the arm
be moved forward or backward, the great tuberosity of the humerus rubs against the
coraco-acromial arch, and forms with it a sort of supplementary articulation, lubricated
by the bursa situated between the coraco-acromion vault and this great trochanter.^
The movement of abduction may be carried so far as to allow the arm to touch the head
without dislocation ; for the capsular ligament is sufficiently loose, especially below, to
receive almost the whole head of the bone without being torn. It should be remarked,
that during abduction the scapula is fixed, which explains the frequency of luxations of
the humerus downward.
Adduction is limited by the arm meeting with the thorax. When it is combined with
the forward motion, the upper and back part of the capsule, and the muscles which cover
it, are considerably stretched. The scapula does not participate in this movement, du-
ring which luxation can be occasioned only by a very strong impulse on the arm upward
and backward.
Circumduction is nothing more than the transition of the humerus from one to another
of these motions. The cone which it describes is much more extensive in front than
behind, a circumstance tending greatly to facilitate the prehension of external objects,
which is the chief purpose of the upper extremities. This predominance of the forward
motions has been already noticed in the sterno-clavicular articulation, and will be found
also in many others.
* [This is the ligamentum proprium anterius of authors ; but the author has taken no notice of another liga-
ment proper to the scapula, viz., the ligamentvm proprium posterius, a thin band of fibres stretched across the
notch at the base of the coracoid process, which it thus converts into a foramen. The supra-scapular nerve
generally passes below, and the artery above it.]
t It is through this ingenious and simple mechanism, of which we shall soon see another example in the
articulation of the femur with the os innominatnm, that the movement forward of the humerus maybe carried
far enough to describe a demi-circle, without the bone being displaced.
X If theory has led us to believe that the coraco-acromion vault contributed to luxation, by offering a point
of support to the lever represented by the humerus abducted from the body, a more careful observation, on the
contrary, has demonstrated that this supporting of the humerus was impossible, as the anterior border of the
coraco-acromion ligament is alone pressing against the humerus in the forcible abduction, and luxation is al-
ways produced in a middle abduction of the urni.
ARTICULATIONS OF THE ELBOW.
141
Fig.n.
Fig. 72.
Rotation. — In this movement the humerus does not turn upon its own, but upon an
imaginary axis, directed from the head of the humerus to the epi-trochlea, parallel to the
bone. The manner in which the rotatory muscles embrace the head of the humerus is
highly favourable to this motion, by compensating for the shortness of the neck, which
serves as a lever for the rotatory movements.
The Humero-cubital Articulation, or Elbow-joint {figs. 71 and 72).
Preparation. — 1. Remove carefully the brachialis anticus muscle ; 2. Detach the ten-
don of the triceps from above downward, without opening the synovial capsule ; 3. Re-
move the muscles which are attached to the internal and external tuberosities, keeping
in mind that the lateral ligaments are intimately connected with the tendons of these
muscles. This articulation belongs to the class of trochlear joints (angular ginglymi).
Articular Surfaces. — On the humerus we find, 1. An almost perfect trochlea or puUey
presenting two edges, of which the internal is the more
prominent, so that, when the end of the bone rests upon
a horizontal plane, its shaft is directed very obliquely
from above downward and inward ; 2. The small head,
or articidar condyle, separated from the trochlea by a
furrow, which is also articular ; 3. Two cavities, a pos-
terior, which is very deep, and is intended to receive
the olecranon process, and an anterior, which is shal-
lower, and receives the coronoid.
The articular surfaces of the forearm are, 1. The
greater sigmoid cavity of the ulna, which exactly em-
braces the trochlea ;* 2. The glenoid cavity of the ra-
dius, which receives the small head of the humerus.
The means of union consist of four ligaments, two
lateral, an anterior, and a posterior. 1. The external
lateral ligament (a, Jigs. 71, 72) is blended with the ten-
don of the supinator brevis ; it is of a triangular form,
and stretches from the external tuberosity of the hu-
merus to the annular ligament, with which it becomes
continuous, and which seems to be in part formed by
it. Some fibres of this ligament are also inserted into
the outer part of the sigmoid cavity of the ulna. This
connexion of the lateral with the annular ligament is
of great importance with reference to the production
of luxations of the upper end of the radius, t
2. The internal lateral ligaments are two in number ;
one internal, properly so called, or humero-cormioidian ;
the other internal and posterior, humero-olecranian.
The former, or humero-coronoidian, which is partly
confounded with the aponeurotic tendon of the superficial flexor muscle of the fingers,
is a thick, rounded bundle, which arises below the internal tuberosity of the humerus,
and is inserted into the whole internal side of the coracoid process, and more especially
in its tubercle.
The second, or humero-olecranian, which might be described as a posterior ligament
of the articulation, is thin and radiating ; it arises from the posterior portion of the epi-
trochlea, and irradiates to be inserted into the whole extent of the internal border of the
olecranon ; the inferior bundles are the strongest, and come in part from the humero-
coronoidian ligament. The superior bundles are thin and slender, and reach beyond the
olecranon, in order to expand over the synovial membrane.
3. The anterior ligament (c) is a very thin layer, in which, however, three orders of
fibres can be recognised. The first, directed vertically, fonn a bundle which extends
from the upper part of the coronoid cavity to the lower part of the coronoid process ; the
second are transverse, and intersect the first at right angles ; and, lastly, the third are
obliquely directed downward and outward to the annular ligament, t We shall see,
hereafter, that the brachialis anticus renders an anterior resisting ligament entirely use-
less ; moreover, the most inferior and deepest fibres of this muscle are directly inserted
in this anterior hgament.
* Tbere is here, indeed, a hinge : it is the most remarkable example of a hin?e in the system ; it is the
most perfect angular ginglymoid. The two articular surfaces present a sinuous surface, wliich is alternately
concave and convex, a sort of catching which is seen nowhere else.
t These relations between the annular ligament and the external lateral ligament are so intimate that these
two ligaments are seldom torn independently of each other ; hence the consecutive dislocation "f the radius
.pon the cubitus in the luxations of the elbow ; hence, also, the luxations of the radius upon the humerus,
the ulna remaining in its place. (See an example of the luxation backward of the radius upon the humerus,
the ulna remaining in its place, Anat. Pathol., with plates, 8th number.)
t It should be remarked, that none of these ligaments of the elbow-joint are attached directly to the radius,
but that the fibres which are- directed towards this bone join the annular ligament. This arrangement allows
the radius to rotate with perfect freedom within its ring, which would have been impossible had the fibr>^
been directly inserted into the bone.
142 ARTHROLOGY.
4. The posterior ligament {d,fig. 72). The place of the posterior Hgament is occupied
by the olecranon and the tendon of the triceps. There are some fibres, however, which
sxtend from the external to the internal tuberosity of the humerus, which are in relation
with the synovial membrane in front, and the tendon of the triceps behind. The princi-
pal posterior ligamentous fibres are those which seem to arise from the humero-olecra-
nian hgament.
The synovial membrane covers the posterior surface of the anterior ligament ; from
this it is reflected upon the coronoid cavity, covers the olecranon cavity behind, and is
prolonged a little between the tendon of the triceps and the back of the humerus. In
this place it is widest and most loose. Below, it forms a prolongation, which extends
into the radio-cubital articulation, covering the whole inner surface of the annular liga-
ment, and forming a circular cul-de-sac below it, which prevents the effusion of the sy-
novia.* There is some synovial adipose tissue round the points of reflection, and also
at the margin of the coronoid and olecranon cavities.
Mechanism of the Humero-cuhital Articulation.
Extension and flexion, the only motions performed by this joint, are executed by it with
remarkable precision and rapidity. The precision of these movements depends, 1 . Upon
the exact fitting of the articular surfaces ; 2. Upon the great extent of the transverse di-
ameter, round which the movements of flexion and extension are performed as round an
axis ; 3. Upon the shortness of the antero-posterior diameter of the inferior extremity of
the humerus, and, consequently, on the smallness of the circle to which the curve of the
humeral trochlea belongs.
1. Flexion. — In this motion, which is very extensive, the radius and ulna move as a sin-
gle bone from behind forward, on the small head and trochlea of the humerus. It should
be observed that, in this movement, the obliquity of the trochlea from behind forward, and
from without inward, throws the forearm, when bent, in front of the thorax, and the hand
in front of the mouth. This motion is limited by the meeting of the coronoid process
with the coronoid cavity. When this motion is carried to the greatest extent, the upper
end of the olecranon descends to the level of the lowest part of the trochlea, and is, con-
sequently, below the line which passes through the two tuberosities, or condyles, of the
humerus. In this motion, the back part of the trochlea and the olecranal fossa are cov-
ered only by the tendon of the triceps, so that instruments can readily enter the joint at
this place. The flexion of the elbow, which constitutes a fundamental movement in pre-
hension of bodies, may be carried as far as possible, even so far as to cause the forearm
to meet the arm, without any risk of luxation, as any sort of dislocation here is impossi
ble, however extensive this movement may be.
2. Extension. — In this movement, the radius and ulna roll backward upon the humerus.
This motion can only be carried so far that the forearm and the arm form a right line,
for then the upper part of the olecranon comes in contact with the bottom of the olecra
nal fossa. The anterior ligament and the anterior and middle bundles of the internal lat-
eral hgament are put on the stretch, and thus concur in limiting the movement of exten-
sion, which is already limited by the olecranon coming in contact with the bottom of the
olecranon cavity. There is no appreciable lateral motion of this joint, the exact fitting
of the articular surfaces effectually preventing it.+
The Radio-cubital Articulations {figs. 71 to 75).
In these articulations, the radius and the ulna are united, 1. By their upper ends {supe-
rior radio-cubital articulation) ; 2. By their lower ends {inferior radio-cubital articulation) ;
3. By the interosseous ligament through a great part of their extent.
Superior Radio-cubital Articulation.
Preparation. — Remove with care the anconeus and the supinator brevis, and separate
the forearm from the arm.
The articular surfaces are the edge of the head of the radius, which is of unequal height
in different parts, and the lesser sigmoid cavity of the ulna, which is oblong from before
backward, broader in the middle than at the ends, and which forms the bony portion of
the osteo-fibrous ring in which the head of the radius rolls.
The means of union consist of the annular ligament of the radius {e, figs. 71 and 72)
* [According to the common opinion, the articular surfaces of the radius and ulna are, of course, also cov-
ered by the synovial membrane.]
t A glance at the articulation of the elbow, surrounded by its ligaments, is sufficient to convince us of the
facility with which the dislocation of the humerus forward takes place, favoured as it is by the smallness of
the antero-posterior diameter of the articulation, and by the deficiency in the resistance of the anterior liga-
ment. This dislocation is, next to that of the humerus, the most frequent, notwithstanding the resistance of
the brachialis anticus, which, being an active ligament, supports the anterior portion of the articulation, with
which it is so closely identified, that, in this dislocation, it is always torn, at least incompletely. This dislo-
cation forward is, moreover, favoured in the movement of extension by the point of the olecranon meeting the
bottom of the olecranon cavity of the humerus. In a fall upon the wrist, the forearm being extended, the hu-
merus becomes a lever of the first kind, whose point of support is represented by the- olecranon cavity of the
humerus strongly pressed against by the point of the olecranon ; the lever of power is represented by the whole
length of the humerus ; the lever of resistance, by the short portion of the humerus below the olecranon cavity
RADIO-CUBITAL ARTICULATIONS. 143
This ligament is a band forming three fourths of a ring, which is completed by the lesser
sigmoid cavity of the ulna ; it is attached, by its two ends, to the fore and back part of
this cavity. Its internal surface, which is smooth and shining like mother-of-pearl, is in
contact with the articular border of the head of the radius. The external lateral ligament
is attached to its outer surface, and evidently becomes continuous with its posterior half.
This arrangement has doubtless given rise to the assertion, that the external lateral lig-
ament is attached to the ulna. Those fibres of the anterior ligament which are directed
obliquely downward and outward are also inserted into the annular ligament. All these
ligamentous attachments retain the annular ligament in its proper position ; when they
are divided, it is manifestly retracted towards the neck of the radius, and exposes the ar-
ticular edge of the bone. The breadth of the annular ligament is from three to four lines,
and its upper circumference is wider than the lower, which construction tends to main-
tain the head of the radius in its situation more accurately. With regard to its structure,
I would observe, that it is much thicker behind, where it receives the insertion of the ex-
ternal lateral ligament, than in front, where it may be much more easily ruptured ; and
I am persuaded that, in luxation of the elbow, it is not the external lateral ligament
which is most commonly torn, but rather the anterior portion of the annular.
The synovial capsule is a sort of diverticulum from that of the elbow-joint, which is
prolonged upon the inner surface of the annular ligament, and is reflected upward from
its lower margin, so as to form a sort of cul-de-sac below it.
Inferior Radio-cubital Articulation.
Preparation. — 1. Remove the muscles on both aspects of the forearm. 2. Separate the
hand from the forearm so as to expose the lower surface of the triangular ligament, or
fibro-cartilage. 3. In order to examine the interior of the joint, saw through the middle
of the forearm ; divide the anterior and posterior ligaments ; separate the two bones of
the forearm ; cut through the triangular ligament at its insertion into the ulna.
The articular surfaces are a small sigmoid cavity on the radius, analogous to that which
we have described at the upper end of the ulna, and the external two thirds of the cir-
cumference of the head of the ulna. This articulation, therefore, is precisely the re-
verse of the upper, since in this the ulna furnishes tl\e head, and the radius the sigmoid
cavity, while a precisely opposite arrangement obtains in the upper joint.
The means of union are, 1. Some fibres stretched in front and behind the joint, and call-
ed anterior (/, Jigs. 71 and 75) and posterior (ff, Jigs. 72 and 74) ligaments. They form a
very imperfect annular ligament. They extend from the anterior and posterior margins
of the sigmoid cavity of the radius to the anterior and posterior surfaces of the little head
of the ulna, in the neighbourhood of its styloid process.
2. The triangular ligament, or, rather, cartilage* {i,Jigs. 7i and 73). This is a triangu-
lar lamina of cartilage, the apex of which is fixed into the angle formed by the head and
styloid process of the ulna, and its base into the lower edge of the sigmoid cavity of the
radius. It is thin at the base and the centre, and thick at the apex and the circumfer-
ence. It concurs in maintaining the union of the radius and ulna, and performs the office
of those inter-articular cartilages which we have noticed as peculiar to such joints as are
most exposed to shocks and friction ; and, above all, it restores the level of the inferior
radio-cubital surface by filling up the vacancy caused by the projection of the radius be-
low the ulna.
There is a separate synovial membrane for this joint (see above, i. Jig. 75), (often called
membrana sacciformis). It covers the upper surface of the triangular ligament, and the
sort of incomplete ring which circumscribes the head of the ulna. It forms very loose
folds at the places of reflection, which admit of very extensive rotation. This synovial
membrane is common to the articulation of the ulna with the radius, and to the articula-
tion of the ulna with the inter-articular cartilage ; it is entirely independent of the syno-
\ial membrane of the wrist-joint.
Middle Radio-cubital Articulation, or Interosseous Ligament.
The interosseous ligament {I, figs. 71, 72), improperly so called, is an aponeurosis which
occupies the interval between the radius and ulna, and which appears to serve princi-
pally for the insertion of muscles. It is broader in the middle than at the ends, and does
not reach the extremities of the interosseous space, for there is an interval above and
below, which serves the purpose of giving passage to nerves and vessels, and also per-
mits more free motion between the two bones. The fibres which compose it are direct-
ed obhquely downward and inward, i. e., from the radius to the ulna. We generally ob-
serve on its anterior aspect several bundles running downward and outward ; the supe-
* This is the only example in the system of an inter-articulary cartilage serving as a means of union be-
tween the bones. Can its principal use be to prevent the dislocation of the ulna in the movements of rotation 1
The following experiment will show that this cartilage does not oppose the forcible movements of pronation
and supination : Saw the bones of the forearm at their middle line, separate the forearm from the wrist, ro-
tate with the utmost force the radius upon the ulna, and it will be sedn that, during these movements, the in-
ter-articular cartilage remains unstrained in all its points. This cartilage is attached to the groove of the sty
loid process of the ulna by fibrous tissue ; what it called the summit of the triangular cartilage is, therefore
Dothing else than a very short and strong little ligament, by which the cartilage is attached to the ulna.
144 ARTHEOLOGY.
rior and the strongest of these is called the round ligament, or the ligamentous cord of
Weitbrecht (m, Jig. 71). It extends obliquely downward and outward, from the outside
of the coronoid process of the ulna to the lower part of the bicipital tuberosity of the ra-
dius. Its direction is, therefore, precisely the inverse of that of the fibres of the inter-
osseous ligament.
Mechanism of the Radio-cubital Articulations.
These articulations, like all trochlear joints, only admit of one kind of motion, viz.,
rotation, which is here called by a peculiar name. Rotation forward is denominated
■pronation. ; rotation backward is called sjipination. We must examine these in both the
upper and the lower radio-cubital articulations.
Mechanism of the Superior Radio-cubital Articulations.
Pronation. — In this movement, the inner part of the head of the radius rolls backward
upon the lesser sigmoid cavity of the ulna, and may be carried so far that the radius may
describe half a circle upon its axis. Notwithstanding the obstacles to displacement re-
sulting from the strength of the back part of the annular ligaments, and the presence of
the two little hooks, one in front and the other behind the lesser sigmoid cavity of the
ulna, and, lastly, notwithstanding the advantage produced by the reception of the small
head of the humerus in the cup-like cavity of the upper end of the radius, in violent pro-
nation the head of the radius is frequently luxated backward. Perhaps no dislocation is
more common in infancy than the incomplete luxation backward of the upper end of the
radius, on account of the greater looseness of the annular ligament, and the less com-
plete reception of the small head of the humerus in the cupula of the radius. The cause
occasioning this displacement is forced pronation, so frequent when infants are held by
the hand, in attempting to save them from falling.
In supination, the head of the radius turns upon its axis in a different direction, i. e.,
its inner part ghdes forward upon the lesser sigmoid cavity of the ulna. If it be carried
too far, dislocation forward may be the consequence.*
Mechanism of the Inferior Radio-cubital Articulations.
The movements of pronation and supination, at the lower radio-cubital articulation,
are produced by a mechanism which is precisely the inverse of the former ; for the ra-
dius, instead of rotating upon its own axis, turns round the head of the ulna by a move-
ment of circumduction. This difference results partly from the curvature of the radius,
and partly from the great transverse diameter of its lower end, which forms the radius
of the arc of the circle which it describes round the ulna. In pronation, the little sig-
moid cavity roUs forward on the articular edge of the head of the ulna ; in supination, it
glides in the opposite direction, that is, backward. We see, then, that in the lower ar-
ticulation, a concave surface moves upon a convex, while the contrary takes place at
the upper. •
Does the inter-articular cartilage limit these motions, as it has been asserted 1 The
experiment which I have indicated above shows that this cartilage is in the same con-
ditions in regard to the articular surfaces, both in pronation and supination, and that the
small ligament which attaches it to the groove of the styloid process of the ulna, expe-
riences neither tension nor relaxation. The anterior and posterior ligaments alone are
able to limit the movements of rotation by their resistance ; but, in forcible pronation,
these may be broken, and the head of the ulna dislocated backward ; in forcible supina-
tion, it may be dislocated forward. It should be remarked that, in cases of luxation of
the ulna, the head of this bone does not lacerate the capsule, but the capsule is torn upon
it ; for, as we shall afterward see, the ulna is immovable at the cubito-carpal joint, and
takes no share in the partial motions of the forearm.
Mechanism of the Radio-cubital Articulations, considered with reference to the Bodies of the
two Bones.
In the movement of pronation, the radius crosses the ulna at an acute angle, so that
its lower part is carried in front of the ulna, while the upper remains on the outside.
The movement of supination consists in the return of the radius to its state of parallel-
ism with the ulna. In pronation, the interosseous ligament is relaxed ; in supination, it
is stretched : its absence at the upper part of the forearm, where its place is supphed by
the ligament of Weitbrecht, allows more extensive rotatory movements, t
* This displacement is very uncommon, on account of the hook-like projection at the anterior extremity of
the sigmoid cavity, and doubtless, also, because forcible supination is very rjjre. Professor Dng^es informs me
that he has seen an instance of this dislocation of the radius, and proved its existence by inspection after
death. I have myself recMitly met with a case of an incomplete dislocation forward in a child ; a slight pres-
sure from before backward upon the superior extremity of the radius was sufficient to reduce the dislocation,
which took place on a sudden, while the child was being dressed.
t If the interosseous ligament, the fibres of which pass downward from the radius to the ulna, had besn
prolonged to the upper part of the interosseous space, it would have much impeded the motions of supination,
l)y limiting the movements of the bicipital tuberosity, into which one of the supinator muscles of the forearm,
viz., the biceps, is inserted ; but the round ligament being inserted below the bicipital tuberosity, and passing
dojwQward from the ulna to the radius, can have no effect in limiting the extent of rotation
RADIO-CARPAL ARTICULATION. 145
The existence of the interosseous space is an indispensable condition for the peiform-
ance of pronation and supination ; and, therefore, every curative plan for the treatment
of fractures of the forearm which does not provide for the preservation of this space
should at once be rejected.
In the explanation we have given of the mechanism of the radio-cubital articulations
the ulna has been considered as an immovable axis, round which the radius executes
below certain movements of circumduction ; but many authors have maintained the
opinion that the ulna also takes part in these motions. Without discussing the different
theories which have been successively proposed on this subject, we shall mention an
experiment which is at once decisive of the question. If all the articulations of the arm
be exposed from the shoulder to the hand, and the humerus be immovably fixed in a
vice, it will be seen that, when the forearm is pronated or supinated, the radius moves
upon the ulna, which remains altogether imdisturbed ; and, also, that any lateral motion
of the ulna is absolutely impossible, from its perfect jointing with the humerus at the
elbow. When the humerus is not completely fixed, it also rotates in conjunction with
the bones of the forearm.
Lastly, it should be observed that, when the radius is rotated during semiflexion of
the forearm, the motion is accompanied by slight degrees of flexion and extension at the
elbow-joint.
Radio-carpal Articulation {figs. 73 to 75).
Preparation. — Divide the fibrous sheaths of the flexor and extensor tendons, and care-
fully remove those tendons ; bearing in mind the fact that the fibrous sheaths closely ad-
here to the ligaments, or, rather, are identified with them, and may be considered as an
appurtenance of the ligamentous apparatus of the joint.
This articulation belongs to the class of condylarthroses.
The articular surfaces (fig. 73) are those of the scaphoid, the semilunar, and the cunei-
form, which together form a condyle, oblong transversely, and covered by articular car-
tilages, which are prolonged farther on the posterior than on the anterior aspect of the
bones, and the transversely oblong concave, articular surface, formed by the lower ends
of the radius and ulna. The radius, which forms by itself two thirds of the surface, cor-
responds to the scaphoid and semilunar, and presents an antero-posterior ridge, and a
slight contraction from before backward, opposite the interval between these two bones.
The ulna corresponds to the cuneiform bone, with the intervention of an inter-articular
cartilage, viz., the triangular cartilage already described, which performs the part both of
a hgament and an inter-articular cartilage. The concave surface presented by the lower
part of the forearm is completed at the sides by the styloid processes of the radius and ulna.
Means of Union. — There are for this joint an external lateral hgament, an internal lat-
eral, two anterior, and one posterior hgament.
The external lateral ligament {a, figs. 73, 74, 75) stretches from the summit, and forms
the neighbouring parts of the styloid process of the radius to the outer part of the scapho-
id, where it is inserted by a broad attachment immediately on the outside of the radial ar-
ticular surface of that bone. This ligament, which is not very thick, is continuous with
the anterior and the posterior ligament, without any line of demarcation being perceived.
The internal lateral ligament. It is uncovered immediately after the tendinous sheath
of the extensor carpi ulnaris has been divided. It is lined by the synovial membrane of
this sheath. It is a cylindrical chord, commencing at the styloid process, of which it
seems to be a continuation, and dividing inferiorly into two fasciculi, one of which is at-
tached to the pisiform, the other, which is more considerable, to the posterior surface of
the cuneiform bone. This chord first appears very thick ; but, on dividing it, it is seen
perforated by a cavity communicating inferiorly with the radio-carpal articulation, and its
superior extremity is not attached to the summit of the styloid process of the ulna, but to
the middle point of this process, in the form of a demi-capsule. The summit of this pro-
cess is articular, and surrounded with a thick layer of cartilage ; it is farther contained
in the synovial membrane of the wrist, and is in direct relation with the cuneiform bone.
The styloid process of the ulna is therefore the only portion of this bone which enters di-
rectly into the wrist-joint.
The anterior ligaments are two in number, one radial, the other ulnar.
The radio-carpal hgament forms a broad layer resembling mother-of-pearl, which ap-
pears as soon as the flexor tendons have been removed. It is composed of bundles, which
are often separated by adipose cellular tissue and vessels, so that I considered it neces-
sary, in the former edition of this work, to describe three anterior radial bundles, an ex-
ternal, a middle, and an internal ; I have abandoned this distinction, because it does not
appear of any use. This ligament arises from the whole breadth of the anterior border of
the inferior extremity of the radius around the articular surface ; it also arises from the
anterior border of the styloid process of this bone. Hence its fibres stretch from above
downward, and from without inward, approximating to a horizontal position, in proportion
as they are more elevated. The most external fibres go to the os unciforme and the os
magnum ; those which come next are inserted into the scaphoid bone ; others, again, into
T
146 ARTHEOLOGY.
the cuneiform and the pisiform bones. The most elevated fibres, which ire the most in-
ternal, seem to be continuous with the anterior ligament of the inferior "adio-cubital ar-
ticulation. The most external bundles of this ligament are tl e thickest. This ligament
is composed of several layers of fibres, the most superficial cf which are the longest.
The ulnar-carpal ligament has probably been conjfounded by authors with the internal
lateral Ugament ; or perhaps it may have escaped their notice altogether, on account of
its being deeply seated. This ligament arises, by a narrow extremity, from the groove
which separates the styloid process from the little head of the ulna, in front of the small
ligament which forms the summit of the inter-articular cartilage ; thence it goes down-
ward and outward, passes under a few fibres of the anterior radio-carpal ligament, and ■
lost by irradiating. The horizontal superior fibres describe a curve beneath the head o-
the idna, and are inserted into the anterior border of the radius, where they are confound-
ed with the fibres of the radio-carpal ligament ; the inferior fibres descend almost verti-
cally downward, externally to the pisiform bone, and terminate in the os cuneiforme.
The posterior ligament cannot possibly be separated from the fibrous sheath of the ex-
tensor and radial tendons, with which it is continuous. There is but one posterior liga-
ment ; it is much weaker and narrower than the anterior radio-carpal ligament, and
stretches obhquely from the posterior border of the radius to the posterior faces of the
cuneiform and the semilunar bones. The bundle which goes to the cuneiform is the
stronger. This ligament covers about the third portion of the joint, while the radio-car-
pal ligament covers the whole of the anterior surface. It should be observed, that there
is a marked predominance of the anterior over the posterior ligaments, both in the artic-
ulation of the hand with the forearm, and in the articulations of the carpus.
With regard to the anterior and posterior ligaments of the radio-carpal articulation, I
shall make an observation which may be of some interest : it is, that all these ligaments,
with the exception of the cubito-carpal, come from the radius, and closely unite the inferior
extremity of that bone to the first range of the carpus, and, consequently, to the hand.
The synovial membrane (see Jig. 73) is loose behind, where it is only partially covered
by the ligaments we have described ; throughout the whole of the remaining circumfer-
ence of the joint it is strengthened by scattered ligamentous fibres, which some anato-
mists have described as a capsular ligament. This synovial membrane sometimes com-
municates with that of the lower radio-cubital articulation, by an opening at the place o
union of the triangular cartilage with the lower edge of the sigmoid cavity of the radius.
It also sometimes communicates with the general synovial membrane of the carpus, by
the interosseous spaces which separate the bones of the first carpal row.
Besides the means of union which we have described, the flexor tendons in front, and the
extensor tendons behind, should be noticed, as serving to increase the strength of the joint.
Mechanism of the Radio-carpal Articulation.
This articulation belongs to the condyloid class, and has, therefore, four motions, viz.,
flexion, extension, abduction, and adduction, and by passing from one of these to the
other, it can perform circumduction.
1. Flexion. — In this motion, the condyle formed by the first row of the carpus glides
Ibackward upon the lower end of the forearm. The posterior ligaments and the exten-
:Sor tendons are put on the stretch. When the movement of flexion is carried too far,
luxation may take place by laceration of the posterior ligament, and then the lower end
of the two bones of the forearm pass in front of the articular surface of the bones of the
first row of the carpus. The possibility of dislocation of this joint has been doubted ;
but I have seen two instances of this kind of dislocation, which were incontestable.
2. In extension, the condyle formed by the carpus roUs forward upon the lower end of
the forearm ; and as the articular surface of the carpus reaches farther on the back than
in .front, it follows that extension may be carried farther than flexion: it is limited by
the strong anterior ligaments, and also by the lateral ligaments, which, as is generally
observed, are attached nearer to the side- of flexion than to that of extension.
It should also be remarked, that extension is the easiest motion of the hand upon the
forearm : this may be readily understood from the great power which the hand possess-
es when it forms a right angle behind with the forearm.*
3. In abduction, the condyle formed by the carpus rolls in the direction of its length,
t. c, transversely and from without inward, while the radial edge of the hand is inchned
towards the radial edge of the forearm : this motion is limited by the mutual meeting of
the styloid process of the radius, and the external process of the scaphoid.
4. In adduction, the ulnar edge of the hand is bent towards the ulnar edge of the fore-
; arm ; the motion is limited by the meeting of the summit of the styloid process of the
ulna and the cuneiform bone, and also by the tension of the external lateral ligamsnt.
It may be easily conceived, that in the lateral movements, which are performed in
* We should observe that it is almost impossible to separate the mechanism of the carpal articulations
irom that of the radio-carpal joint ; the latter is noticed here by itself only in order to conform with the ana
toicical divisions.
ARTICULATIONS OF THE CARPUS. 147
the direction of the long diameter of the articular surfaces, dislocation must be very dif
ficult, and that, when it does occur, it must be incomplete.
The movement of circumduction is nothing more than a succession of the different m»
tions which have been already pointed out. The hand describes a cone, of greater ex
tent behind, that is, in the direction of extension, than in front, or in the direction o»
flexion. It is also still more restricted in adduction and abduction.
Articulations of the Carpus (figs. 73 to 75).
These articulations comprise, 1. The articulations of the bones of each row together
and, 2. The articulations of the two rows.
Articulations of the Bones of each Row.
Preparation. — 1. Remove the extensor and the flexor tendons ; 2. Separate the hand
from the forearm, then the first row from the second, and, lastly, the bones of both rows
from each other, examining their means of union before completing the separation.
Articular Surfaces. — The articulations of the bones of each row are amphi-arthroses,
and, consequently, present one part continuous and another contiguous. The bones of
the first row correspond to each other by oblique surfaces, those of the second row by
vertical and more extensive surfaces.
Means of Union. — Two classes of ligaments belong to these joints : the one is extend-
ed between the corresponding surfaces, the interosseous ligaments; the other set are
peripheral, and are divided into palmar and dorsal.
The palmar and dorsal ligaments are fibrous bundles, stretched transversely or oblique-
ly from each of the bones of the carpus to those which are contiguous to it. The dorsal
are much thinner than the palmar.
The interosseous ligaments are not disposed in an exactly similar manner in the two
rows, and we shall, therefore, examine them separate- ^ 73
ly. 1 . The interosseous Ugaments of the first row (e e,
fig. 73) occupy only the upper part of the corresponding u
facettes ; they are nothing more than small fibrous bun- \'
dies, one extending from the scaphoid (1) to the semi-
lunar (2) ; the other from the semilunar to the cunei-
form (3) ; they are sometimes partially interrupted, and
present openings, which establish a communication be-
tween the general synovial membrane of the carpus
and that of the radio-carpal articulation. These inter-
osseous ligaments are reddish, scarcely fascicidated,
very loose, so as to admit of pretty extensive gliding
motions. 2. The interosseous ligaments {d d d) of the
second row are much thicker than those of the first ;
the whole non-articular portion of the corresponding
facettes gives insertion to these Ugaments, which are
very compact, and of a much more dry and close tex-
ture than the reddish tissue connecting together the bones of the fii-st row. It follows,
therefore, that the bones of the second row are more firmly united than those of the first,
whose interosseous ligaments are loose, and permit a certain degree of mobility. The
articulation of the pisiform bone with the cuneiform merits a special description.
Articulation of the Pisiform and Cuneiform Bodies.
For this articulation, the pisiform bone presents a single articular surface, which
unites with the auterior facette of the cuneiform bone. There are four ligaments in
this little joint, which is nothing else but a loose arthrodia : 1. Two inferior {e,fig. 75),
which are very strong, viz., an external, stretched obliquely from the pisiform to the
hook-like process of the unciform bone ; and an internal, vertical, which is inserted into
the upper end of the fifth metacarpal bone. These two ligaments appear partly to re-
sult from the bifurcation of the tendon of the flexor carpi ulnaris, this tendon being in
the place of the superior ligament, which is wanting. The internal lateral ligament of
the radio-carpal articulation may also be considered as entering into the structure of the
superior ligament. 2. An anterior and a posterior ligament, thin and radiating, which
strengthen the synovial capsule in front and behind.
The synovial capsule is, most commonly, a small isolated pouch ; and sometimes it is
a prolongation of the radio-carpal synovial membrane. This capsule is ver>' loose, and
the ligaments are not very tight ; hence the great mobility of the articulation.
Articulation of the two Rows of Carpus together.
The articulation of the two rows of the carpus together presents an enarthrosis in the
middle, and an arthrodia on each side.
The articular surfaces consist of a head or spherical eminence received into a cavity,
constituting the enarthrosis, and of plane surfaces on the inside and the outside, whick
form a double arthrodia. The head is formed by the os magnum (6<fig ^^^ ^"^ ^■he su-
148 ARTHROLOGY.
perior process of the os unciforme (7) : the cavity is constituted by tne inferior surfaces
of the scaphoid (1), the semilunar (2), and the cuneiform (3) bones. This cavity, which
is deeply notched in front and behind, is completed in these situations by two ligaments,
an anterior and a posterior, which might be called glenoid ligaments, considering their po-
sition on the edge of a cavity, and their use in increasing its depth.
The posterior glenoid ligament is composed of transverse fibres, which are inserted into
the first row, closing up the posterior notch.
The anterior glenoid ligament, much stronger than the other, belongs to the second
row ; it is confounded with the anterior ligaments of the articulation, between the two
rows, and extends transversely from the os unciforme to the trapezium, passing in front
of the neck and the head of the os magnum. Besides these ligaments, we also find, 1
An anterior ligament (i, fig. 75), which is very thick, and stretches from the anterior sur-
face of the OS magnum, by diverging rays, to those three bones of the first row that form
the enarthrodial cavity, in which the head of the os magnum is received, viz., the sca-
phoid, the semilunar, and the cuneiform. 2. A posterior ligament (i, fig. 74), which con-
sists merely of some fibres extending obliquely from the bones of the first row to those
of the second.
On the inside and the outside of this carpal enarthrosis we find an arthrodia. On the
tnside is the articulation of the cuneiform (3, fig. 73) with the unciform (7) bone, consti-
tuted by plane surfaces, and strengthened by a very thin posterior ligament, an anterior
ligament, much thicker than the preceding, and an internal lateral ligament (c). On the
outside is the articulation of the scaphoid with the trapezium and the trapezoid. The ar-
ticular surface of the scaphoid (1) is a sort of head or elongated convexity, and those of
the trapezium (4) and the trapezoid (5) are two facettes, that unite in forming a concavity,
into which the convexity of the scaphoid is received. This small articulation is strength-
ened by two anterior ligaments, both of which proceed from the scaphoid, and are connected
one to the trapezium, and the other to the trapezoid ; and two posterior, arranged in a sim-
ilar manner with the preceding, but much thinner.
A single synovial capsule (see fig. 73), very loose, especially behind, covers the corre-
sponding articular surfaces of the two rows. But it is also provided with small culs-de-
sac, which penetrate into the intervals between the bones of each row, there being tliree
below and two above.
Mechanism of the Carpus.
The mechanism of the carpus must be considered as providing both for strength and
mobility. The conditions favourable to strength are, 1. The number of bones in the car-
pus ; 2. The reciprocal dovetailing of the two rows, the anti-brachial row joining in this
fashion the metacarpal, and vice versa ; 3. The numerous ligaments connecting the bones
of each row together. The carpus, therefore, has power to resist the most violent shocks,
chiefly on account of the expenditure offeree at each of its numerous articulations. With
regard to mobility, the movements between the bones of each row must be distinguished
from those which take place between the two rows. 1. The partial movement between
the component bones of each row is scarcely appreciable, and requires no consideration.
2. The mobility of the two rows upon each other is, however, more marked. The enar-
throdial articulation of the head of the Os magnum can only perform forward and backward
motions, for the arthrodial joints on each side prevent any lateral movements.
Mechanism of the Carpal Enarthrosis. — The movement of extension is very limited, on ac-
count of the resistance of the anterior ligaments. The movement of flexion, on the con-
trary, is much more considerable : it may be carried sufficiently far to cause luxation of
the head of the os magnum backward. The slight structure and the looseness of the pos-
terior hgaments, and also the looseness of the synovial membrane behind, explain the fa-
cility which this articulation enjoys in the movements of flexion. It is of importance to
remark, that the carpal enarthrosis performs a more active part in the flexion of the hand
than even the radio-carpal articulation ; a circumstance of the highest interest in relation
to the mechanism of the carpus.
Metacaep.vl Articulations.
The metacarpal bones are united at their extremities, but separated along their shafts.
We shall examine the articulations, 1. Of their carpal ; and, 2. Of their digital extremities.
1. Articulations of the Carpal Ends of the Metacarpal Bones.
These are symphyses or amphi-arthroses. The articular surfaces {see fig. 73) occupy the
sides of the carpal ends of the metacarpal bones, and are partly contiguous and partly con-
tinuous. The contiguous portion consists of a facette covered with cartilage, and is, in
fact, an extension of the surface that articulates with the carpus. The part intended to
become continuous is rough.
The means of union are the interosseous, the dorsal, and the palmar ligaments. The inter-
osseous ligaments (//, fig. 73) are short, close, and very strong bundles of fibres, interposed
between the rough portions of the lateral facettes of two neighbouring metacarpal bones.
They constitute the principal means of uniting these bones, as may be seen by attemptinfl
METACARPAL ARTICULATIONS.
149
Fig 74.
to separate them after dividing the dorsal and pahnai
ligaments.
The dorsal {I, fig. 74) and palmar ligaments (m, fig. 75)
consist of fibrous bundles, stretched transversely from
one metacarpal bone to another. The palmar ligaments
are much larger than the dorsal.
2. Articulation of the Digital Ends of the Metacarpal
Bones.
Although the digital extremities of the metacarpal
bones are not, prop-
erly speaking, artic-
ulated together, yet
as they are contigu-
ous, and move upon
each other,their sur-
faces are covered
by a synovial mem-
brane, which facil-
itates their move-
ments ; moreover, a
palmar ligament (n.
Jigs. 74, 75) is stret-
ched transversely
in front of these ex-
tremities, and unites them loosely together. This lig-
ament (called also transverse) is common to the last
four metacarpal bones, but it does not reach the met-
acarpal bone of the thumb. It may be considered as
formed by the union of all the anterior ligaments ot
the metacarpo-phalangal articulations, and as being
destined to render these ligaments continuous. In
order to expose this ligament, and to study with atten-
tion its connexions with the anterior ligaments of the
metacarpo-phalangal articulation, it is sufficient to
open the fibrous sheaths of the flexor tendons of the fingers, and to remove the smalllura-
bricales muscles, together with the nerves and vessels of the fingers.
We may consider the interosseous palmar aponeurOsity as representing, in respect to
the shafts of the metacarpal bones, the aponeurosis called the interosseous ligament in
the forearm. Strictly speaking, the thickened inferior border of the dorsal interosseous
aponeurosis, which is continuous with the tendons of the extensor muscles, might be con-
sidered as a dorsal transverse ligament, much weaker than the preceding.
The interosseous muscles, as we shall afterward see, complete the means of union of
the metacarpal bones.
Carpo-metacarpal Articulations.
The articular surfaces are the inferior facettes on the bones of the second row of the
carpus, and the facettes on the upper ends of the metacarpal bones. We may consider
all the carpo-metacarpal articulations as forming only one joint with a broken surface.
The articulation of the trapezium with the metacarpal bone of the thumb, and that of the
fifth metacarpal bone with the os unciforme, require each a special description.
Articulations of the Second, Third, and Fourth Metacarpal Bones with the Carpus.
Articular Surfaces {see fig. 73). — ^The articulation of the second, third, and fourth met-
acarpal bones with the carpus presents a sinuous line, which might, perhaps, be sub-
jected to certain rules of disarticulation, if this disarticulation seemed to be of the least
use. It constitutes a tight arthrodia, with an angular surface. Proceeding from within
outward, the fourth and third metacarpal bones form a regular curve, with the concavity
looking upward ; but the second, which unites by three facettes with the trapezium, the
trapezoid, and os magnum, presents an angular surface. The second metacarpal bone
is jointed, by its transversely concave surface, Avith a facette on the trapezoid, which is
concave, but in the opposite direction, and by two lateral facettes, with the os magnum
and the trapezium, so that it enters, as it were, into the carpus by two angular projec-
tions, which are received into the intervals between the three bones with which it is
articulated. From this it follows, that the carpo-metacarpal articulations present not
only concave and convex surfaces, favourable to mobility, but also angular surfaces thai
evince the immobility of these joints.
Means of Union. — Some ligaments, distinguished as dorsal and palmar, both very
strong, short, and compact, retain the articular surfaces as immovably in contact as if
the joints we-e symphyses.
150 ARTHEOLOGY.
The dorsal ligaments are much stronger than the palmar, and are composed of several
layers, the deepest being the shortest. There are three dorsal ligaments for the second
metacarpal bone : a median (o, fig. 74), stretched to it from the trapezoid bone ; an exter-
nal (p), which comes from the trapezium, and covers the insertion of the extensor carpi
radialis longior ; and an internal, arising from the os magnum : the first of these is ver-
tical, tlie last two are oblique. There are two dorsal ligaments in the articulation of the
third metacarpal bone : a vertical, which comes from the os magnum ; and an oblique (r),
from the OS unciforme.
In the articulation of the fourth metacarpal bone there is one dorsal ligament, longer
and looser than the preceding.
The palmar ligainents are much less marked than the preceding ; contrasting thus with
the palmar ligaments of the carpus. There is none for the second metacarpal bone ; the
tendon of the flexor carpi radialis appears to supply the place of this ligament. There
are three ligaments for the third metacarpal bone : an external, which comes from the
trapezium ; a middle, proceeding from the os magnum ; and an internal, from the os unci
forme. Lastly, for the articulation of the fourth metacarpal bone, there is one palmar
ligament from the os unciforme.
The synovial membrane (see fig. ""rQ) of the carpo-metacarpal articulations is a continu
ation of the synovial membrane of the carpus, and is prolonged between the upper ends
of the metacarpal bones ; and, as the synovial membrane of the carpus communicates
also with the radio-carpal joint, it can be conceived what ravages may be produced by
inflammation attacking any one of these parts. I must here point out an interosseous, or
lateral ligament (I, fig. 73), which arises from the os magnum, and slightly, also, from
the OS unciforme, and is attached to the inner side of the third metacarpal bone. It al-
most completely isolates the articulations of the last two metacarpal bones. This liga-
ment being attached to the third metacarpal bone, which is already provided with very
strong ligaments, increases in a remarkable manner the strength of the joint.
Carpo-metacarpal Articulation of the Thumb.- — This joint {m,fig. 73), which is very dis-
tinct and completely separated from all the others, is remarkable, also, for the arrange-
ment of the articular surfaces. There is a mutual jointing between the trapezium, which
is concave transversely, and convex from behind forward ; and the first metacarpal bone,
which is concave and convex in precisely opposite directions. It is the type of all ar-
ticulations by mutual reception.
The m£ans of union consist of a capsular ligament {s, figs. 74 and 75), imperfect on the
outside, where its place is occupied occasionally by the tendon of the abductor longus
pollicis (extensor ossis metacarpi poUicis) : it is much thicker behind than in front, and
is sufficiently loose to permit extensive motions in all directions. There is a separate
synovial membrane for this joint, which is remarkable in respect of its relations : viz., 1.
Behind, with the extensor muscles of the thumb ; 2. On the outside, with the expanded
tendon of the abductor pollicis ; 3. On the inside, with the interosseous muscles and the
radial artery, where that vessel penetrates into the palm of the hand, to form the deep
palmar arch ; and, 4. In front, with the muscles of the baU of the thumb.
Carpo-metacarpal Articulation of the fifth Metacarpal Bone {see fig- 73). — The articulation
of the fifth metacarpal bone with the os unciforme is, in many respects, analogous to the
preceding ; for there is here, also, a sort of mutual reception between their correspond-
ing articular surfaces. There is, also, a kind of capsular ligament {t, fig. 74), very strong
in front and thin behind, and incomplete on the outside, on account of the presence of
the fourth metacarpal bone : it is rather loose, and maintains the relation of the articular
surfaces. The tendon of the extensor carpi ulnaris strengthens this joint behind, in the
same manner as the tendon of the long abductor of the thumb strengthens the articula-
tion of the trapezium and the first metacarpal bone.
The synovial membrane of this joint belongs also to the fourth metacarpal bone. The
fourth and fifth metacarpal bones may, indeed, be strictly considered as forming only one
joint, and the lateral interosseous ligament as completing the capsular ligament. On
the other hand, the second and third metacarpal bones form a very distinct articulation
with the OS magnum, the trapezoid, and a small facette upon the trapezium ; lastly, there
is another joint peculiar to the first metacarpal bone and the trapezium. There are thus
three distinct joints (see fig. 73) in the carpo-metacarpal articulation, in one of which
the articular surfaces are simple, while in the two others they are broken.
Mechanism of the Carpo-metacarpal Articulations.
The mechanism of the carpo-metacarpal articulations should be studied, both as re-
gards strength and mobility.
I. With regard to strength, the metacarpal bones mutually support each other, and resist
in common the action of external agents : they can only be broken, therefore, by violence
suflicient to fracture several at the same time. In order that any one should be broken
alone, the violence must be applied directly to it. In this manner I have seen the third
metacarpal bone fractured by the stick of a rocket.
The great strength of the metacarpus depends not only on the simultaneous resistance
ARTICULATIONS OP THE FINGERS. '1^1
ot its component parts, but also on the intervening articulations, each of which becomes
the seat of a certain expenditure of force ; for part of this being employed in moving the
articular surfaces upon each other, is necessarUy lost as far as its direct transmission is
concerned.
With regard to mobility, these articulations, which might be called tight angular arthro-
dias, are only possessed of slight gUding motions, on account of the angular disposition
of the articular facettes, the sinuosity of the common articular line, and the strength and
shortness of both the external and the interosseous ligaments. At the same time the
mobility of all the metacarpal bones is not equal. Thus, the articulation of the trape-
zium with the first metacarpal bone holds the first rank ; it is in some degree different
from the others in this respect as well as in position, and merits particular description.
The articulation of the fifth metacarpal bone holds the second place, and that of the
fourth the third. The articulations of the second and third metacarpal bones are as im-
movable as symphyses.
Mechanism of the Articulation of the Trapezium and the first Metacarpal Bone. — From the
mutual reception of the articular surfaces, this articulation permits four motions, viz., flex-
ion, extension, abduction, and adduction, and, as a consequence of these, circumduction.
Flexion is not performed directly, but obliquely inward and forward. This obhque mo-
tion produces the inovement of opposition, which characterizes the hand ; it is very exten-
sive, and, when carried too far, may produce luxation backward with the greater facility,
because the capsular hgament is very thin in that direction. Extension may be carried
so far that the first metacarpal bone may form a right angle with the radius. It is con-
ceivable that luxation forward might be produced by this motion ; but there are very few
causes that would tend to increase extension to such a degree, and, moreover, the ante-
rior part of the capsular ligament is extremely strong, so that no example of this luxa-
tion has ever been recorded.
Abduction is very extensive ; when carried beyond a certain point, it may give rise to
dislocation inward, for the trapezium, being situated on a plane anterior to the root of the
metacarpus, the neighbouring metacarpal bones offer no obstacle to such a displacement.
Lastly, direct adduction is limited by the meeting with the second metacarpal bone.
Mechanism of the Articulation of the fifth Metacarpal Bone with the Cuneiform. — This ar-
ticulation in some degree resembles the preceding, and, like the last, it would be liable
to dislocation, were it not for its intimate connexions with the other metacarpal bones,
so that the same cause that would tend to displace the fifth metacarpal bone would also
tend to displace the fourth.
Articulations of the Fingers (.figs. 74 and 75).
These comprise, 1. The articulations of the fingers with the metacarpal bones. 2. The
articulations of the phalanges together.
Metacarpo-phalangal Articulations.
These belong to the class of condyloid articulations.
The articular surfaces in each are formed by the head of the metacarpal bone, flattened
from side to side, increasing in breadth from the dorsal to the palmar aspect, and pro-
longed much farther in the latter direction, where it presents the trace of a division into
two condyles ; and by the shallow glenoid cavity of the first phalanx, which is trans-
versely oblong, and, consequently, has its long diameter at right angles to tliat of the head
of the metacarpal bone, which is oblong from before backward. We see, then, that an
articular head, elongated from before backward, is adapted to a transversely oblong cav-
ity. This arrangement favours the movements of flexion and extension, as well as the
lateral motions, which are as extensive as they would have been had all the diameters
of the articular surfaces been equal to those which are actually the longest.
It is on account of the lateral flattening of the heads of the metacarpal bones that, in
amputations at these joints, surgeons make choice of lateral, in preference to antero-
posterior flaps.
Means of Union. — On account of the disproportion just noticed as existing between
the articular surfaces of this joint, the glenoid cavity of the first phalanx not being equal
to more than one half of the articular surface on the metacarpal bone, this cavity is pro-
vided with a ligament called the anterior ligament {u,f.g. 75), which was confounded by
the older anatomists with the fibrous sheaths of the flexor tendons. This ligament I
have called the glenoid ligament, and its use is to complete the cavity of reception ol
the metacarpal condyle. It is situated on the palmer aspect of the joint, and is grooved
anteriorly, to correspond with the flexor tendons. It is concave, forming, so to say, a
demi-capsule behind, to correspond with the metacarpal condyle. By its edges it is con-
tinuous not only with the transverse metacarpal ligament, which is one ol' its appurte-
nances, but also with the sheath of the flexor tendons, and with the lateral ligaments of
the joint. By its superior border this ligament is continuous with the palmar interos-
seous aponeurosis, and with the digital bands of the palmar aponeurosis. By its lower
edge it is finnly fixed to the anterior part of the margin of the first phalangal articular
152 ARTHROLOGY.
surface ; its upper edge is loosely connected by some ligamentous fibres to the contract
ed neck which supports the head of the metacarpus, and is accurately adapted to that
neck. The anterior or capsular ligament is very thick, unyielding, formed of fibres that
cross each other, and look like mother-of-pearl, and is as compact as cartilage. Several
times I have found a sesamoid bone in the substance of the anterior ligament of the in-
dex and the middle finger. The whole tendinous sheath of the tendons of the flexor
muscles may be considered as making part of this anterior ligament, and we ought not
to overlook these tendons in estimating the solidity of the joint with regard to flexion.
This joint has two lateral ligaments, which are extremely unyielding, an internal and an
external ; they are inserted into a marked tubercle existing posteriorly on each side of
the lower extremities of the metacarpal bones, and into a very remarkable depression
below and before this tubercle ; hence these ligaments extend very obliquely from be-
hind forward and from above downward, in the shape of a strong and flat band, looking
like mother-of-pearl, which continually expands and irradiates, and finally terminates, 1 .
In a tubercle existing anteriorly, and on each side of the margin of the upper end of the
first phalangal bone. 2. By its superior fibres into the borders of the anterior ligament.
These lateral ligaments extend, therefore, obUquely from the posterior tubercle of the
lower end of the metacarpus to the anterior tubercle of the upper end of the first phalan-
gal bone ; they are stretched by flexion, which cannot be extended beyond the right
angle without the ligaments being torn ; and they are relaxed by extension, except that
portion of these ligaments which goes to the anterior ligament, and which limits the ex-
tension by its resistance. It may be interesting to remark, that the external lateral lig-
ament is much stronger than the internal ; the former of these ligaments is inserted not
only into the tubercle, but also into the whole extent of the subjacent depression.
There is no dorsal ligament properly so called ; its place is evidently supplied by the
corresponding extensor tendon (lo, fig. 74). This extensor tendon, after having reach-
ed the level of the joint, becomes nan-ow, and contracts, as it were, upon itself, in order
to form a thick and extremely compact cord. From each edge of this ligament an apo-
neurotic expansion arises, which is inserted into the sides of the joint.
The synodal capsule is extremely loose, especially on the aspect of extension ; it does
not adhere to the tendon, but is folded upon itself during extension, and is stretched du-
ring flexion : it lines the inner surface of the lateral ligaments, and is reflected upon the
articular cartilages.
Metacarpal-phalangal Articulation of the Thumb. — Two sesamoid bones (x, figs. 73 and
75) are annexed to this articulation in front, and are constantly found in the glenoid lig-
ament ; they aflJbrd insertion to the lateral ligaments and to aU the short muscles of the
thmnb.
If we examine these articulations in connexion, we shall find that they are disposed
in a curved line, with the convexity looking downward. This curvature is slightly in-
terrupted at the articulation of the fourth metacarpal bone, which is not on a level with
those of the index and the middle fingers.
Mechanism of the Metacarpo-phalangal Articulations.
We shall take as an example the metacarpo-phalangal articulation of the middle fin-
ger. From the arrangement of the articular surfaces, it is evident that this articulation
can execute movements in four principal directions, and, consequently, those of circum-
duction also. From a simple inspection of the surfaces, it might be inferred that the
movement of flexion must be very extensive, while that of extension (or flexion back-
ward) and the lateral motions of abduction and adduction are exceedingly limited. The
arrangement of the ligaments amply confirms these suppositions. It should be noticed,
as a rare exception, that in the movements executed by this joint, it is not the head that
moves upon the cavity, but the cavity that moves upon the head.
In flexion, the first phalanx glides forward upon the head of the corresponding metacar-
pal bone ; the extensor tendon and the back of the synovial capsule are stretched by the
projecting head of this bone : the posterior fibres of the lateral ligaments are also stretch-
ed ; they limit the movement of flexion, allowing it only to proceed so far that the pha-
lanx forms a right angle with the metacarpal bone. Lastly, flexion can be carried some-
what farther by the thumb, the ring, and the little fingers, than by the others. In ex-
tension, the phalanx glides backward upon the head of the metacarpal bone supporting it :
this head corresponds almost entirely with the anterior ligament, which, as we have seen,
is disposed in the shape of a fibrous demi-capsule. The posterior fibres of the lateral
ligaments are relaxed, and the anterior stretched. The motion is evidently limited by
the anterior or capsular ligament, and by the anterior fibres of the lateral ligaments,
which are inserted into this anterior ligament. I may remark, that the upper border of
this anterior ligament forms a sort of ring or collar, which surrounds ahnost entirely the
neck of the corresponding metacarpal bone, without adhering to it.
According to the relative size of this ring, and the comparative looseness of the glenoid
ligament, will the movement of extension be more or loss considerable. In all persons
\t may be carried so far as to form *n obtuse angle behind ; in some, until a right anglo
ARTICULATIONS OF THE FINGERS. 153
is formed ; and in a few, even so far as to produce an incomplete luxation, reducible by
the sliglitest muscular effort. If extension be carried beyond these limits (for which,
however, considerable violence is necessary), the head of the metacarpal bone will escape
from the kind of collar formed by the superior border of the capsular ligament and the
anterior fibres of the lateral ligaments, sometimes by extensively lacerating it, but at
others only by stretching it very much ; in both cases the first phalanx is dislocated back-
ward, or the metacarpal bone forward. When the collar is not torn, reduction is al-
most impossible, because the glenoid hgament is always interposed between the articular
surfaces. It should be remarked, that the metacarpo-phalangal articulation of the thumb
is the only one which is not capable of flexion backward. This is probably owing to
the want of looseness in its aaterior or capsular ligament. In this joint, the movement
of extension does not go beyond the straight line ; in this respect it resembles the ar-
ticulations which the phalanges form with each other.*
Adduction and abduction consist of simple latered glidings, limited by the meeting of
the other fingers.
Articulations of the Phalanges of the Fingers.
These are pulley-like joints, or perfect angular ginglymi. There are two articulations
of this kind in each finger, but only one in the thumb.
Articular Surfaces. — The lower end of the first phalanx, flattened from before back-
ward, presents a trochlea, broader on the pahnar than on the dorsal aspect, and prolonged
much farther in front than behind. The trochlea of the phalanx resembles the lower
end of the femur, with tjiis difference, that its two condyles are not separated from each
other. The upper end of the second phalanx, also flattened from before backward, pre-
sents two small glenoid cavities, separated by an antero-posterior ridge. The ridge cor-
responds to the groove of the pulley, and the glenoid cavities to the two condyles.
Means of Union. — 1. An anterior ligament {,y,fig. 74), grooved anteriorly, to serve the
tendon as a sheath, and exactly resembling what exists in the metacarpo-phalangal ar-
ticulations, and performing the same office of deepening the glenoid cavity, which by it-
self only imperfectly receives the pulley of the first phalanx. 2. Two lateral ligaments,
an internal {z) and an external {z'), arranged precisely in the same manner as the lateral
ligEiments of the metacarpo-phalangal articulations. They are attached to tubercles
situated behind the lateral depressions, on the lower end of the first phalanx, and pass
obliquely forward, to be inserted both into the glenoid ligament and the second phalanx.
There is no posterior ligament, its place being supplied by the extensor tendon. This
tendon is disposed in a peculiar manner : it gives off constantly a prolongation (w) from
its anterior aspect, which is inserted into the upper end of the second phalanx, so that
this bone presents a somewhat similar arrangement behind, as it does in front, with the
flexor tendon. This prolongation has a cartilaginous aspect.
The synovial capsule is precisely similar to that of the metacarpo-phalangal joints.
The foregoing description applies equally well to the articulation of the second with the
third phalanx. There is often a sesamoid bone in the substance of the glenoid ligament
of the two phalangal joints of the thumb.
Mechanism of the Phalanges.
The fingers are essentially the organs of prehension and of touch. In the mechanism
of touch, the fingers are moved over the surfaces of bodies, and are moulded upon even
their slightest inequalities, sometimes acting together, sometimes separately, seizing and
moving between them, as between the blades of sentient forceps, even the most delicate
objects. For the performance of this function, great mobility must be conjoined with
great precision of movement. On the other hand, for the purpose of seizing bodies, of
retaining, repulsing, or breaking them, as well as of acting as the means of attack and
defence, considerable power is required ; all which qualities are united in the mechanism
of the hand. Observe the number of the fingers and their complete isolation, so that
they can act either together or separately, and even in opposite directions. Notice the
number of the phalanges, their successive decrease in size, and the facility with which
they can be separated or made to approach each other, so as to be apphed around spher-
ical bodies. Note, also, the inequality of the fingers in length and power, enabling each
to act a determinate part in prehension ; and, above all, remark the shortness of the thumb,
which only reaches the base of the first phalanx of the index finger ; but which, placed
as it is upon a plane anterior to the rest, and endowed with a greater degree of mobili-
ty, can be opposed to all the fingers together, to each finger separately, and to every pha-
lanx of each, thus constituting the principal blade of the sentient forceps represented by
the hand ; for, being more strongly constructed, and provided with more powerful mus-
cles than the other fingers, it in some degree counterbalances them all.
* This is, I believe, the anatomical reason why a reduction of the dislocations forward of the n^tacarpo-
phalan^l articulations of the thumb and the other fingers is difficult, and sometimes impossible The most
skilful practitioners have sometimes failed in this reduction, and especially in dislocations of the thumb; ^n-
grene and death have often taken place in consequence of the violent attempts at reduction. I am certain that
the vertical section of the anterior ligament wotfld obviate the difficultj' at once.
u
-'IM ARTHROLOGY.
.;' ... ^.rxbT^aXw^ Meckanism of the Phtdangal Articulations.
f^i From the shape of the articular surfaces, which form a miniatiire representation o£
*the knee, it is evident that the only motions of which these joints are capable are flex-
ion and extension. The flexion of the second upon the first phalanx is as extensive as
it could possibly be, for it is only limited by the meeting of the anterior surfaces of these
bones. The amount oi flexion of the third phalanx upon the second is less considerable.
The extension of the second phalanx upon the first, and that of the third upon the second,
are limited, as in the metacarpo-phalangal joints, by the anterior glenoid and the lateral
ligaments. This motion of the phalanges is extremely slight ; I have never seen them
carried farther back than to form a straight line.
From what has been observed, it follows that, as regards its movements, each finger
'represents a shortened or miniature limb ; that, at its articulation with the metacarpus,
it is capable of motions in every direction, and also of circumduction ; that, from the
joints between the phalanges, it is endowed with the power of strong, extensive, and
accurate flexion ; and that, from the double bending of the second upon the first, and the
third upon the second phalanges, the fingers represent a true hook for seizing and cling
ing to external objects.
ARTICULATIONS OF THE INFERIOR OR ABDOMINAL EXTREMITIES.
Articulations of the Pelvis. — Coxo-femoral. — Knee-joint. — Peroneo-tibial. — Ankle-joint.—
Of the Tarsus. — Tarso-metatarsal. — Of the Toes.
Articulations of the Pelvis {figs. 76, 77).
The articulations of the pelvis are, 1. The sacro-iliac symphysis ; 2. The symphysis
pubis ; and, 3. The sacro-coccygeal articulation. The last has been already described with
the other articulations of the vertebral column.
Sacro-iliac Symphysis.
Preparation. — 1. Detach the pelvis from the rest of the trunk ; 2. Saw through the hor-
izontal ramus and arch of the pubes at the distance of about eighteen lines on each side
of the symphysis ; 3. Dislocate the os innominatum of one side ; 4. Dissect the anterior
ligaments of the sacro-iliac symphysis upon the other ; 5. Then make a horizontal section
of that articulation, dividing it into an upper and a lower half
The sacro-iliac articulation belongs to the class of symphyses or amphi-arthroses.
The articular surfaces are formed on the sacrum and os innominatum, and are partly
contiguous and partly continuous. The contiguous surfaces of these two boneS are an-
terior to the others, and are shaped like an ear, with the convex edge turned forward ;
hence they are called the auricular surfaces. The parts which are rendered continuous
by means of ligamentous fibres consist of the entire space comprised between the auric-
ular portion and the posterior border of the os innominatum, and of all the lateral sur-
face of the sacrum not occupied by the auricular facette. The continuous portions are
both marked with very rugged eminences and depressions. These articular surfaces are
also remarkable from being sinuous and alternately concave and convex, and from their
presenting a well-marked obliquity in two directions, viz., from above downward, and from
before backward and inward, so that the sacrum is, as it were, wedged between the ossa
innominata both in a vertical and an antero-posterior direction.
Means of Union. — The auricular surfaces are covered with cartilage, which is thicker
Fig. 76. upon the sacrum than on the os innominatum,
and is remarkable for the roughness of its
surface, which contrasts with the smooth ap-
pearance of other articular cartilages. There
is a distinct synovial membrane in this joint
in the infant and pregnant female, but it can
scarcely be detected in the adult and the
aged. The ligaments are, 1. An anterior sa-
cro-iliac ligament (b, figs. 76, 77), a very thin
layer which passes in front of this articula-
tion, and composed of fibres stretched trans-
versely from the sacrum to the ilium. 2. A
superior sacro-iliac ligament ii,fig- 52), a very
thick bundle, extending transversely from
the base of the sacrum to the contiguous
portion of the ilium. 3. An interosseous lig-
_^ ament, which forms the strongest bond of
onion in this joint, composed of a great number of ligamentous fibres, stretched horizon-
tally from the ilium to the sacrum, crossing each other, and filling up almost the whole of
the deep excavation comprised between the two bones ; these fibres leave small inter-
ARTlCUL'A*'nroN^'^bF *rHE PELVIS. 155
vals between them, which are occupied by fat, and traversed by numerous small veins.
One of these bundles merits a special description : it consists of a long and strong band
extending almost vertically from the posterior superior spinous process of the ilium to a
thick tubercle on the third sacral vertebra ; it may be caUed the posterior vertical sacra-iliac
ligament. 4. The ilia-lumbar ligament {c,figs. 76, 77) maybe considered as belonging to
this joint ; it extends from the summit of the transverse process of the fifth lumbar ver-
tebra to the thickest part of the crest of the ilium, that is, to the enlargement situated
about two inches in front of the posterior superior iliac spine. It is a thick and very
strong triangular bundle.
Symphysis Pubis.
Preparatian. — This requires no special direction : only, in order to become acquainted
with the respective extent of the contiguous and continuous portions, it is necessary to
make two sections, a horizontal section, and also a vertical one from before backward.
The articular surfaces {e,fig. 77) are oval, having their longest diameters directed ver-
tically ; they are flat, and obliquely cut from behind forward and outward. Tliey are,
therefore, separated by a triangular interval, the base of which is directed forward, and
the apex backward. We should observe, concerning this articulation, that there are many
varieties in the respective extent of the contiguous and continuous portions of the artic-
ular surfaces. Sometimes they are almost wholly continuous ; at other times, on the
contrary, they are nearly altogether contiguous. I have observed this latter disposition
in a very remarkable degree in the symphysis of a young woman who died in the sixth
month of pregnancy.
The means ofuruon are the following : 1. Aii anterior pubic ligament {d,fig. 76), a very
thin fibrous layer, the posterior portion of which is blended with the interosseous liga-
, ment : it is composed of fibres extending from the spine of each os pubis obliquely to the
anterior surface of the opposite pubic bone ; those from the left side pass in front of those
from the right. 2. A posterior pubic ligament, extremely thin, and covering the prominence
formed by the ossa pubis behind, at the place of their articulation. This prominence,
which is very marked in old subjects, seems to be produced by a jutting out of the poste-
rior table of the bone backward, apparently caused by the pressure of one articular sur-
face upon the other ; these surfaces being, as we have described, in contact behind, but
separate in front. In a female who died of peritonitis soon after delivery, I found this
posterior prominence of the pubes fonning a sort of spine of some lines in diameter from
before backward. 3. A superior pubic ligament {e,fig. 76), very thick, and continuous on
each side, with a fibrous cord, that covers the upper edge of the os pubis, and effaces its
irregularities. 4. An inferior pubic or triangular ligament (/, fig. 76), which is exceed-
ingly strong ; it forms a continuation of the anterior and interosseous ligaments, and is
composed of interlacing fibres : this ligament renders the angle formed by the ossa pubis
obtuse, and gives to the arch of the pubes that regular curve presented by it to the head
of the foetus during labour. 5. An interosseous ligament (e, fig. 77), which occupies the
whole non-contiguous portion of the articular surfaces, and varies greatly in thickness in
different individuals. This hgament forms the principal means of union between the
bones of the pubes ; it fills up the vacant space of a line and a half to two lines, which
exists between the articular surfaces, and is composed of fibres, which cross each other
like those of the intervertebral substances.*
Of the Sub-pubic or Obturator Membrane, and the Sacro-sciatic Ligament.
We place the description of the obturator and sacro-sciatic ligaments next to that of
the articulations of the pelvis, simply remarking that they can scarcely be considered
true ligaments, but rather aponeuroses, which serve to complete the parietes of the pel-
vis, without contributing anything to the strength of the pelvic articijations. In trying
to account for the great obturator foramen and the great sciatic notch, I have asked my-
self the question whether these great openings, independently of their transmitting ves-
sels, nerves, and muscles, did not result from that law of osteology, by means of which
the bones, the levers of the muscular power, are formed with the least possible weight
and volume. How much heavier would the pelvis have been, if the obturator foramen
and the great sciatic notch had been filled with osseous tissue. It would have been use-
less, for the strength of the pelvis would not have been increased in any way by such an
arrangement. Perhaps these strong but flexible membranes are also useful during the
progress of labour, by diminishing the pressure of the soft parts of the mother between
the head of the child and the bones of the pelvis.
* From analogy, we may infer aa identical disjjosition in the pubic and vertebral symphysis. Thus it will be
seen that the articular surfaces in these two articulations are not fitted to each other. In the syniphyis pubis,
however, we discover an additional degree of mobility ; the articular surfaces are contiguous to a greater ex-
tent, and the synovial membrane is so perfect that no anatomist has yet doubted it. The symphysis pubis
might, therefore, be regarded as the transition between the movable aiticulations and the rai.ved or symphy-
ses. The obliquity in an inverse direction of the articular surfiices is the cause why the syraphysis pubis is
much larger in front than behind ; hence, in symphyseotomy or a section of the symphysis, the knife must be ap-
plied to the anterior portion of the symphysis, so tjiat the articulation may be entered into with more safety.
It is clear that a trocar could not be thrust into the bladder through the symphysis, on accojnt of Us bemj too
narrow behind to admit of its passage.
166 ARTHROLOGY.
Sub-pubic or Obturator Membrane {g, figs. 76, 77). — This membrane closes the obtura-
tor (sub-pubic) foramen, excepting at its upper part, where we find a notch, by which the
groove for the obturator vessels and nerves is converted into a canal. The external
half of its circumference is attached to the corresponding margin of the obturator fora-
men, and the internal half to the posterior surface of the ascending ramus of the ischi-
um ; its two surfaces give attachment to the obturator muscles. The obturator mem-
brane is composed of aponeurotic bundles, which look like mother-of-pearl, and are in-
terlaced in every direction. An interesting point of its structure is its being formed of
several layers of fibres, and small bristle-shaped collections of fibres arising constantly
from the internal half of the margin of the obturator foramen, which expand upon the
anterior surface of the membrane, and afterward intermingle with the periosteum.
There is also to be found a very strong parcel arising from a sort of spine upon the mar-
gin of the obturator foramen, immediately above the level of the great cotylo d notch.
Sacro-sciatic Ligaments. — These are divided into the great and the S7nah . ^'e apply
the term ligaments to them rather on account of their fasciculated shape than fron» their
use, which scarcely has reference to the union of the bones of the pelvis.
The great sacro-sciatic ligament {I, figs. 76, 77) arises from a ridge situated on the in-
ternal hp of the tuberosity of the ischium, and also from the ascending ramus of the
same bone, by a curved margin of considerable extent, having its concavity directed up-
ward, which, with the inner surface of the tuberosity of the bone, forms a groove for the
protection of the internal pubic vessels and nerves. The most superficial fibres of this
ligament are partly continuous with the common tendon of the biceps and the semi-ten-
dinosus. Immediately after its origin, from its fibres being collected together, it be-
comes very narrow and thick, and is directed upward and inward ; it then expands con-
siderably, and is inserted into the edges of the sacrum and coccyx, and more slightly
into the posterior part of the crest of the ilium, as far as the posterior and superior spi-
nous process of this bone. Its upper edge, or, rather, its external, is vertical, and is
continuous with the aponeurosis, extending over the pyriformis muscle. Its internal
edge, which forms a curve, and which is almost horizontal, makes part of the inferior
circumference of the small pelvis ; it fines the small sacro-sciatic ligament, to which it
adheres at its insertion into the coccyx, and from which it is separated externally by a
triangular space, where it is in relation with the internal obturator muscle ; it is covered
by the gluteus maximus, to which it furnishes a great number of aponeurotic insertions.
This disposition increases the thickness of this ligament considerably, and gives to its
posterior surface the rugged, rough, and, as it were, lacerated aspect, which is a char-
acteristic of that surface. The great sacro-sciatic ligament is composed of bundles, sev-
eral of which, on a level with the narrowest portion of this ligament, are interlaced in
the shape of the letter X. Several of these ligaments, which are external at their sci-
atic insertion, become internal at their insertion into the coccyx, and vice versa. The
great sacro-sciatic ligament and the posterior and superior sacro-iliac ligaments consti-
tute a fibrous plane in the shape of bundles, arising from the superior posterior spinous
process of the ilium, and extending in various directions.
fVg.. 77, The small sacro-sciatic ligament {m,figs. 76, 77), placed in
front of the preceding, and extremely thin, arises from the
summit of the spine of the ischiimi, passes inward, and,
becoming thinner, is lost upon the anterior surface of the
great sacro-sciatic ligament. The two sacro-sciatic liga-
ments divide the great sacro-sciatic notch into two distinct
foramina : the upper (n, fig. 77) is very large, and shaped
like a triangle with the angles rounded off, and is in a great
measure filled up by the coccygeus and pyriformis muscles ;
it gives passage also to the great and small sciatic nerves,
to the ischiatic vessels, and to the gluteal and internal pu-
dic vessels and nerves, and to a large quantity of cellular
tissue. That form of hernia which is called sciatic takes
place through this foramen. The lower {o,fig. 77) is much
smaller ; it is situated between the spine and tuberosity of
the ischium, and gives passage to the obturator intemus
muscle, and to the internal pudic vessels and nerves.
Mechanism of the Pelvis.
The mechanism of the pelvis should be regarded in four distinct points of view : 1.
As affording protection to the contained viscera ; 2. In relation to the part which it per-
forms in the mechanism of standing and progression ; 3. In connexion with the phenom
ena of part mtion ; and, 4. In reference to the motions which take place at its articula
tions with other bones, and those between its own component parts.
I. Mechanism of the Pelvis considered as a Protecting Structure. — The following are the
conditions in the structure of the pelvis, having reference to its ofiice as a protector of
the contained viscera : 1. Behind ; the presence of the sacrum, which is itself pi-otected.
ARTICULATIONS OP THE PELVIS. ISV
as well as the nerves that pass through it, by the great prominence of the posterior iliao
tuberosities, which project considerably beyond it ; 2. On the sides, by the crest of the
ilium, and the prominence of the trochanters, which so often preserve the pelvis from ex-
ternal violence. With regard to the large notch in front, which leaves the viscera situ-
ated on a level with it, unprotected, it may be remarked, that the viscera contained in the
small pelvis, being liable to considerable changes of volume, require to leave the osseous
and unyielding space which contains them when empty, in order that they may extend
into a cavity the walls of which are soft, and may be dilated almost indefinitely ; 3. In
front the means of protection are much less efficacious, in consequence of the vast notch
which is situated in this region.
The partial absence of the bony parietes in front has reference to the great variation?
in size which the viscera of the pelvis can undergo, and which would have been incom-
patible with the existence of an osseous cincture, incapable of dilatation. The absence
of bony walls in the situation of the three great notches, presented by the outlet of the
pelvis, is also unfavourable to its solidity ; but it has many other important uses, partic-
ularly in the mechanism of labour. The pelvis, especially at its upper part, where it is
most exposed to injury, is enabled to resist external violence by virtue of its vaulted con
struction. Part of the impulse, also, is lost in producing the slight degree of gliding mo
tion permitted at the symphysis pubis. "Where, however, the power of resistance pos-
sessed by the pelvis is overcome, it will be seen at once that the parts most liable to
fracture are the ascending rami of the ischia at their junction with the descending rami
of the ossa pubis.
2. Mechanism of the Pelvis with regard to Standing and Progression. — The part perform-
ed by the pelvis in standing is connected with the transmission of the weight of tlie trunk
to the lower extremities ; this is efFi>cted by means of "the sacrum, which rests upon the
ossa innominata. We should add, that a small portion of the weight is directly trans-
mitted to the femurs by the iliac bones, which support the viscera of the abdomen.
TQbe following arrangements should be noted, as being concerned in the transmission of
the weight by means of the sacrum : 1. The great size of that bone, affording evidence
of the destination of man for the erect posture. 2. The obtuse angle at which the sacrum
unites with the vertebral column, peculiar to the human species, and which becomes the
seat of a decomposition of the force transmitted by the spine. Part of the momentum
acting in the direction of the axis of the column has no other effect than that of increas-
ing the sacro- vertebral angle, at the expense of the flexibility of the inter-articular car-
tilage ; the rest is transmitted to the sacrum, and then to the lower extremities. 3. The
double wedge shape of the sacrum itself. In order to understand the advantage arising
from this form, it is necessary to remark, first, that the weight of the trunk is transmit-
ted in the axis of the upper half of the sacrum, and, consequently, in the direction of a
line sloping downward and backward ; from this it follows, that the sacrum must have
a tendency to be displaced either downward or backward, but the displacement downr
ward is prevented by the position of the ossa innominata, which are nearer to each other
below than above. The displacement backward is obviated by the oblique direction of
the articular surfaces of the same bones backward and inward, while the obliquity of the
sacrum itself is in the opposite direction, for it is broader in front than behind.* 4. The
distance intervening between the sacro-iliac and the coxo-femoral articulations. The
articulation of the vertebral column with the pelvis being situated at the back part of that
cavity, while those of the femurs are situated towards the front and the side, the distance
between them increases the space in which the centre of gravity can oscillate, without
being carried so far forward as to pass beyond the perpendicular let fall from the coxo-
femoral articulation to the base of support. In man alone is found a large pelvian basis
of support, and thus the erect posture has been rendered possible in him, without an ex-
cessive extension in front.
In quadrupeds, the antero-posterior diameter of the bones of the ilium is rather short,
and their haunch bones are elongated behind, and placed in almost the same plane as
the vertebral column. The foetus and new-born infant somewhat resemble the lower
animals in this respect, and, therefore, in the human subject there is a great tendency
to assume the attitude of a quadruped during the first year of existence.
The weight received by the sacrum and transmitted to the haunch bones is divided,
sometimes equally and sometimes unequally, between the sacro-iliac symphyses. One
portion of the impulse calls into action the mobility of the symphyses, and the remainder
is transmitted to the cotyloid cavities. It should be remarked, that this transmission is
effected along the triangular prismatic columns, which form the sides of the inlet of the
pelvis, and are the thickest and strongest parts of that structure. At the foot oi these
* Without admitting- that the influences to which the sacrum is subjected have a tendency to force it back-
ward as well as downward, it is impossible to explain either the use of its being- shaped like a wedge, with
the base turned forward, or of that powerful apparatus of posterior ligaments which can oidy resist its disloca-
tion backward. The idea that these forces tend to press it forward is manifestly at variance with the naturt
of the uniting media ; for the sacro-iliac symphyses are only maintained in front by a very thin ligamentous
layer, and the breadth of the space between the iliac bones is also greater in front than behind; ciicumstaa-
ces that ■\\ould evidently facilitate displacement forward.
ARTHROLOGY.
columns, which form cmres, we find, dug, as it were, into their substances, the cotyloid
cavities, to which the weight of the trunk is transmitted. During the sitting posture, the
weight of the body is transmitted to the tuberosities of the ischia, which, from their great
size, are well fitted to support it. As these processes are a little anterior to the cotyloid
cavities, and, therefore, situated in a plane very near the front of the pelvis, the centre
of gravity of the trunk has a tendency to fall behind the basis of support represented by
them ; and, therefore, it is easy to push an individual backward when in the sitting pos-
ture, inasmuch as in front the basis for the support of the pelvis is increased by the length
of tlie femurs and the length of the foot while man is seated on a chair, and the whole
length of the abdominal extremity while he is seated on a horizontal plane. The mode
in which the pelvis resists violence appUed to the tuberosities of the ischia in falls, is some-
what connected with its mechanism as adapted to the sitting posture. The shock is, in
these cases, transmitted directly upward in the dh-ection of the acetabula, the lower hem-
ispheres of which offer resistance like two arches : from the acetabula the impulse is
communicated backward, by the thick columns extending from behind these cavities, to
the sacro-iliac symphyses ; and forward, to the symphysis pubis ; so that falls upon the
tuberosities are dmost always accompanied with painful concussion both of the sacro-
iliac and pubic symphyses.
In order to complete our account of the mechanism of the pelvis in standing, we must
examine its mode of resistance in falls upon the knees or soles of the feet. In this case,
the shock is communicated from below upward to the upper halves of the cotyloid cavi-
ties, wliich are supported by the prismatic columns already described. The anterior
part of each acetabulum presents a large notch, and is altogether unconcerned in the
transmission of these shocks ; so, also, is the very thin lamina constituting the bottom or
inner wall of the cavity, which can only suffer compression in falls upon the great tro-
chanter. The great difference existing between a fall upon the knees and the tuberosi-
ties of the ischia, and the fall upon the points of the feet, with regard to a commotion of
the brain and the spinal marrow, may be easily conceived. While standing on one 4»ot
the weight of the trunk is transmitted to the femur by the sacro-iliac symphyses, and by
the curve-shaped column of the side which bears upon the ground. In this position a
fall readily takes place, on account of the facihty with which the centre of gravity passes
the basis of support.
During progression, the pelvis affords to each thigh alternately a solid fulcrum, and re-
ceives itself a fixed point of support from the femur of that leg which rests upon the
ground. While onp side of the pelvis is thus supported upon one of the thigh bones, the
other side is projected forward. These alternate movements of projection of either side
of the pelvis take place at the coxo-femoral articulation of the extremity which rests
upon the ground. The alternate movements of projection increase in proportion to the
breadth of the pelvis. It is for this reason that women, in walking, move the hips more
than men. The remark of a witty author, that " running is the only thing which women
are unable to do gracefully," is an allusion to this rather awkward motion of the pelvis.
We may form a correct idea of the share which the pelvis takes in the act of walking by
studying the mode of progression of persons with wooden legs. In these unfortunate
beings the lateral inclinations of the pelvis are sufficient for progression by transporting
the centre of gravity alternately to the two inflexible columns substituted for the lower
extremities.
3. Mechanism of the Pelvis with regard to Parturition. — The art of midwifery depends,
in a great measure, upon the study of the pelvis ; it is impossible to form a true concep-
tion of the mechanism of natural labour without being acquainted with the axes of the
pelvis, its dimensions as compared with the size of the foetus, the sacro- vertebral angle,
the inclined planes of the true pelvis, the diameters of the brim and the outlet, and the
malformations to which it is liable. Any lengthened details upon these points would be
out of place here. I shall only remark, I. That the existence of the arch of the pubes
is pecidiar to the human species ; and, 2. That the sciatic notches and the obturator
foramina are not only useful from economizing weight, but also because, corresponding
as they do to the oblique diameters of the head of the foetus during parturition, they ren-
der less painful the pressure attendant upon that process ; 3. That the pyramidales, the
mtemal obturators, and the psoae and iliaci muscles perform, so to speak, the office of mat-
tresses in the pelvic cavity ; 4. That parturition, consisting in the expulsion of the foetus
along the line of the pelvis, natural parturition, provided the expulsive power exists in
its normal conditions, depends partly on a true conformation of the pelvis, and partly on
a true conformation and position of the foetus ; 5. That a general idea of all the defects
which may occur in the conformation of the pelvis may be expressed by stating, that
this cavity is liable to all the malformations which may result from a pressure upon its
whole brim or only a part of it, from above downward, from below upward, from before
backward, or from side to side.
4. Mechanism of the Pelvis with regard to its own Movements. — The intrinsic movements
of the pelvis are very obscure, being confined to mere gliding or swinging motions, the
production of which destroys part of the momentum from any external violence. By
COXO-FEMOEAL AETICULATION. 159i
some admirable contrivance, the mobility of the intrinsic articulations of the pelvis is
considerably increased during the latter periods of pregnancy, so that the coccyx may be
pressed backward, causing an increase of five or six lines in the antero-posterior diam-
eter of the outlet ; wliile the symphysis pubis* becomes susceptible of a slight separa-
tion, which increases (in a very slight degree, it is true, but sufficiently to merit notice)
the dimensions of the brim of this cavity. This mobiUty, which is especially remarkable
in a narrow pelvis, favours the process of labour in a singular degree. The natural mobil-
ity of the symphysis pubis has suggested the operation of symphyseotomy, by which the
diameters of the pelvis, however, are but little increased, unless the severing of the
bones of the pubes should be carried far enough to result in a separation of the sacro-
iliac symphysis. A relaxation taking place in the symphysis of the pelvis may give rise
to strange errors in diagnosis.
The extrinsic movements of the pelvis are those of flexion, extension, lateral inclina-
tion, and rotation : these motions, which are all very hmited, have been indicated in
describing the mechanism of the vertebral column. The motions of the pelvis upon the
thighs are very considerable : they will be examined with the mechanism of the hip-joint.
CoxO-FEMOEAL ARTICULATION {fig. 76).
Preparation. — Remove with care all the muscles that surround the joint, preserving
the reflected tendon of the rectus femoris. The psoas and iliacus muscles, the synovial
capsule of which so often communicates with the articular synovial membrane, must be
removed with particular care. After the fibrous capsule has been studied upon its exter-
nal surface, a circular division should be made round its middle portion, for the purpose
of uncovering the deep-situated parts. This articulation is the type of the order enar-
throsis, being a true ball and socket joint.
The articular surfaces are the globular head of the femur, and the cotyloid cavity of the
OS innominatum. There is a striking difference between this joint and that of the shoul-
der, as far as regards the size of the articular head and the depth of the articular cavity.
While the head of the humerus and the glenoid cavity are simply in juxtaposition with-
out any reception of the former into the latter, so that the scapulo-humeral articulation
has for a long time been, and is now considered as an arthrodia, there is a deep and com-
plete fitting of the head of the femur into the cotyloid cavity, which we have pronoun-
ced to be the deepest articular cavity of the body. Both of the surfaces above named
are covered with cartilage, with the exception of two depressions, one of which is situa-
ted on the head of the femur, the other at the bottom of the cotyloid cavity : the latter
is filled with a reddish adipose tissue, improperly called the cotyloid gland. It is analo-
gous to the adipose tissue found in the neighbourhood of all the joints ; its use is not
well known. I have often asked myself the question, Why should there be this poste-
rior cotyloid cavity ! On submitting the joint to an antero-posterior vertical section,
shghtly encroaching on the margin of the posterior cotyloid cavity, it will be seen that
the object of this cavity is to protect the round ligament in all the possible positions of
the head of the femur ; and that, without this cavity, the round ligament could not have
existed \vithout its being compressed between the articular surfaces. Now, as the intra-
articular vessels enter this cavity, and go to the head of the femur along the round lig-
ament, it is not impossible but that the exclusive use of this posterior cotyloid cavity
should be to protect the vessels destined to the head of the femur, and that the round
hgament itself should have no other use than to support these vessels, and to transmit
them to the head of the femur. The cotyloid adipose tissue does not seem to have any
other object, except to fill the empty space of this posterior cavity.
It appears to me that the round ligament of the coxo-femoral articulation of the poste-
rior cotyloid cavity serves the same purpose as the space between the condyles of the
lower end of the femur and the crucial ligaments of the knee-joint.
Means of Union. — The cotyloid ligament {n, fig. 76). This band, improperly called co-
tyloid ligament, is attached to the margin of the acetabulum, which it, as it were, com-
pletes ; it augments the depth of the cavity, and renders smooth its sinuous and notched
circumference. It is of greater size at the notches than in any other part : by its means
the irregularities of the edge of the acetabulum are effaced, and the deep- notch in front
and below is converted into a foramen for the passage of vessels to the fatty tissue, the
inter-artiailar ligament, and the head of the femur.
The cotyloid band is much thicker above and behind than below and in front, and it
is precisely against the first two points that the head of the femur constantly presses.
It is also remarkable, in this respect, that the diameter of its free borders is smaller than
that by which it is attached ; and this circumstance assists, in some degree, in retaining
the head of the femur in the cotyloid cavity, t It consists of fibres which arise succes-
* In a female seventy-nine years of age, the mother of nineteen children, I found the symphysis pubis ex-
tremely movable : the two articular surfaces of the pubes were contiguous ; the interosseous ligament had
disappeared ; and a very thick, fibrous capsule, of recent formation, surrounded the articular surfaces in front,
above and below, being inserted at some distance from them. It was a symphysis changed to a loose arthrodia.
t I have never seen this disposition better exhibited than in a subject in which the cotyloid band was OSM-
fied in its whole extent, except at the place on a level with the anterior and inferior notch. The head of thfl
160 ARTHROLOGY.
sively from all points of the circumference of the acetabulum, and interlace at very acute
angles. This interlacement is especially visible in the situation of tlie great anterior
notch, where the fibres may be seen arising from each side of the notch, and passing
across each other.
The orUcular ligament, or Jibrous capsule (p, Jig. 76). This represents a fibrous sac,
having two openings, by one of which it embraces the acetabulum, outside the cotyloid
ligament, while the other surrounds the neck of the femur. The femoral insertion of
the capsular ligament requires to be carefully studied, for the purpose of explaining the
difference between fractures within, and fractures beyond, the capsule. This insertion
is so arranged, that at the upper part and in front of the joint it corresponds with the
base of the neck of the femur, while beneath and behind it is situated at the junction of
the external wich the two internal thirds of the neck. The insertion of the capsule in
front takes place not only at the base of the neck of the femur, but also internally to this
base, to the extent of several lines, as may be ascertained by an incision being made
along this insertion in the direction of the axis of the neck. The length of tlie orbicular
ligament is exactly equal to the distance between its insertions, excepting at the inner
part, where it is much more loose. Hence the extent of the motion of abduction, which
is so remarkable in some jugglers, that they are able to separate their legs until they
form right angles with the body, without producing dislocation.
The thickness of this ligament is not equal throughout : it is greatest above and on
the outside, where the reflected tendon of the rectus muscle is situated ; it is yet very
considerable in front and above ; it is less thick behind, and still thinner on the inside.
In some subjects the thickness of the superior part of the capsule is to that of the inferi-
or as five to one. In front, the capsule is strengthened by a bundle of fibres stretched
Dbliquely, like a sling, from the anterior inferior spinous process of the ilium to the inside
of the base of the neck of the femur. It is called by Bertin the anterior and superior lig-
ament (r, fig. 76). This band, which serves as a re-enforcement to the capsule, lies un-
der that portion of the iliacus muscle which arises from the anterior spinous process of
the ilium, and follows the direction of this muscle ; it is composed of pardlel fibres, and
closely adheres to the capsule, without adhering in the least to the muscle. Within this
bundle the capsule is often imperfect, and permits a communication between the synovial
membrane of the joint and the bursa of the psoas and iliacus muscles. This last syno-
vial membrane may be considered as a prolongation of the articular synovial membrane ;
this prolongation is analogous to the one which we have described at the scapulo-hume-
ral articulation for the subscapularis muscle. In one subject that I dissected, the com-
municating orifice was so large, that the common tendon of these muscles was in imme-
diate contact with a considerable portion of the head ofthe femur ; the tendon itself be-
ing split into several bands, some of which had been lacerated, and, as it were, worn
away by friction.
The external surface of the capsular ligament is in relation with the psoas and iliacus
muscles in front, being separated from them by a bursa at the upper part, in those cases
where the fibrous capsule is not interrupted, and giving insertion to many of their fibres
below. On the inside, it is in relation with the obturator externus and the pectineus ;
on the outside, with the gluteus minimus ; behind, with the quadratus femoris, the ge-
melli, the pyi-iformis, and the obturator intemus. Several of these muscles send fortify-
ing bundles of fibres to the capsule. I may point out an aponeurotic expansion coming
from the gluteus minimus, which establishes a close connexion between this muscle and
the capsule ; a second expansion, furnished by the pyriformis and the gemelli ; and a third,
which is furnished to the capsule by the tendon of the vastus externus. The internal
surface is lined by the synovial membrane.
The orbicular ligament ofthe hip-joint differs from the generality of such structures
in being of a dull white instead of a pearly white colour, and in being composed of ir-
regularly interlaced fibres, except the superficial fibres, which are disposed in parallel
lines. I have also observed a very remarkable fact, apparently overlooked by anatomists,
viz., that it is extremely thin at its inferior orifice, but especially behind ; and that near
this insertion it is strengthened by some circular fibres which embrace the neck of the
bone like a collar, but without adhering to it ; and that in its different movements this
sort of collar rolls round the neck, but is retained in its place by small bundles of fibres,
reflected from the capsule upon the neck of the bone, which raise the synovial mem-
brane from the surface.
The intcr-articular, which is improperly called round ligament (t, fig. 76). This ligament
arises, under the form of a fibrous band, folded backward upon itself, from the depression
on the head of the femur, which depression is not entirely filled by it. It is twisted
around this head, and is divided into three bands, one of which, after having again been
subdivided, traverses the adipose tissue and is fixed into the bottom of the cotyloid cav-
ity, while the two others are attached to the two edges ofthe cotyloid notch, below the
cotyloid band, by which this insertion, with which it is often continuous, is concealed.
femur wis mechanically and solidly retained in the acetabulum, whose bottom, being partly worn out ani]
pressed inward, fonned a prominence in the interior face of the pelvis.
COXO-FEMORAL ARTICULATION. 161
In one case a prolongation of this ligament traversed the cotyloid notch, and was at-
tached to the part nearest the capsule. The thickness and the strength of this inter-ar
ticular ligament are extremely variable : sometimes it is extremely strong, sometimes very
weak ; sometimes it adheres to one edge only of the notch ; sometimes it consists mere-
ly of a few ligamentous fibres, contained within the substance of the reflected synovial
membrane ; sometimes in its place is found a fold of that membrane, which may be torn
by the slightest force ; and, lastly, it is not uncommon to find that it is altogether wanting.
The synovial membrane lines the whole internal surface of the capsular ligament the
two non-adhering surfaces of the cotyloid ligament, and that part of the neck of the fe-
mur contained within the joint ; it embraces the round ligament, and sends off a pro-
longation from it to a quantity of fatty matter at the bottom of the acetabulum;* an ar-
rangement which led the older anatomists to believe that the round ligament was in-
serted into the bottom of the cotyloid cavity.
Mechanism, of the Coxo-femoral Articulation.
Like all enarthroses, the coxo-femoral articulation can execute movements of flexion,
extension, abduction, adduction, circumduction, and rotation.
1. Inflexion, the head of the femur roUs in the cotyloid cavity around an imaginary
axis corresponding with that of the neck of the bone, while the lower end of the femur
is carried from behind forward, and describes the segment of a circle, whose radius is
represented by the shaft of the bone. In the mechanism of this movement, the neck of
the femur has the effect of substituting a rotatory motion of the head of that bone upon
a fixed point, without changing the relation of the head with the acetabulum, and, con-
sequently, without any tendency to displacement, for a very extensive movement back-
ward and forward, which would otherwise have been necessary, and in which the sur-
faces would have been liable to separation from each other. We can, indeed, scarcely
believe that luxation would be possible during this motion, although it can be carried so
far that the front of the thigh and the fore part of the abdomen may be brought in contact
2. Extension is effected by the same mechanism, the head and the neck of the femur
rolling upon themselves from behind forward, while large arcs of a circle, from before
backward, are described by the body of the bone ; but such is the obliquity of the acetab-
ulum, which looks both forward, outward, and downward, that when the femur is in the
vertical direction, the head projects and carries forward the fibrous capsule. The anterior
re-enforcing bundle is stretched. The psoas and iliacus muscles perform the office of an
active ligament. Luxations of the femur forward are not common, for the movement of
extension is limited by the meeting of the edge of the acetabulum and the back part of the
neck of the femur ; and the ligament and muscles above named also tend to counteract it.
3 and 4. The mechanism of adduction and abduction is altogether different from that
of the preceding movements, where the articulation forms the centre of a circle descri-
bed by the femur, the radius of which is measured by a line stretched from the head of
the bone to the space between the condyles. In abduction, the head of the femur presses
against the inner part of the capsular ligament ; and, on account of the looseness of this
ligament, the obliquity of the acetabulum, and the arrangement of the inter-articular lig-
ament, this movement may be carried very far without displacement, and is only limited
by the meeting of the upper edge of the neck of the femur with the rim of the cotyloid
cavity. But this very niceting may itself become the cause of luxation, and then the
edge of the cotyloid cavity may be regarded as the fulcrum of a lever of the first order
with unequal arms, the whole length of the femur being the arm, to which the power is
applied, and the neck of the bone, that by which the resistance acts.
In adduction, the femur moves in precisely the opposite direction : this motion is lim-
ited by the mutual contact of the two thighs, but, by means of slight flexion, it may be
carried so far as to throw one over the other. The great depth of the upper and exter-
nal part of the cotyloid cavity, and the strength of the capsular ligament in the same di-
rections, would seem to oppose all displacement. But it should be observed, that falls
upon the knees almost always happen during adduction of the thighs, for this is an in-
stinctive movement of preservation. However slight the adduction may be, the inter-
articular ligament is of necessity stretched ; and from this it follows, as my colleague,
M. Gerdy, has ingeniously remarked, that the head of the femur is detached from the
bottom of the cavity by a kind of rolling of the round ligament upon it, and comes to
press against the fibrous capsule. The rupture of the inter-articular ligament is not al-
ways necessary in luxation. I have seen several instances of a so-called incomplete lux-
ation inward, without this hgament being torn.
5. Circumduction consists in the transition from one of these motions to another. The
* The synovial membrane is often seen, being interposed and descending- between the adipose substance
and the posterior cotyloid cavity. I may also point out semilunar folds, which are often formed by tne syno
rial membrane round the neck of the femur. These folds are supported by some detached fibres of the cap-
Bule, so that the neck, on a level with those fibres, is lined with synovial membrane only in the neighbour
hood of the head of the femur. The synovial folds appear to me destined to conduct vessels to the margin of
the head of the femur. Round the head of the femur, at its point of union with the neck, are constants
found very small adipose bundles. v • - • •
X
162 ' "' ' ■ ARTHROLOGY.
femur circumscribes a cone, of which the apex is in the joint, while the base is described
by the lower end of that bone. The axis of the cone is represented by aline drawn
from the head of the femur to the interval between the condyles ; and the length of the
femur accounts for movements which are scarcely felt at the coxo-femoral articulation,
being so considerable at the lower end of the bone.
6. Independently of the movements above described, the coxo-femoral articulation per-
forms motions of rotation, arising by no means from its enarthrodial shape, but from the
presence of the neck of the femur. Generally no movement appears to require a greater
expenditure of power on the part of nature than the rotatory movements, and these move-
ments are not always regulated by the same mechanism. We have already seen an ex-
ample of this movement in the atlo-axoidian articulation, where a cylinder forme 1 by tho
odontoid process rolls in the partly osseous and partly fibrous ring of the atlas, as an axle
tree in a wheel. Here the arrangement is quite different ; the rotatory movement is ob
tained simply by the lever being bent like an elbow in such a manner as to make the rota
tory movements of the femur upon its axis result from the movements forward or backward
of the bent portion. This movement should be studied both at the upper and at the lower
part of the femur. At the upper part it is a motion of horizontal displacement, the radi-
us being represented by the head and neck of the bone ; at the lower part it is a rotatory
motion of the femur, not precisely upon itself, but upon an imaginary axis placed on the
inside of, and parallel to, the shaft. It follows that there can be no rotation in cases of
fracture of the neck of the bone, and this is one of the diagnostic signs of that accident
Lastly, it may be observed that rotation is perfonned from without inward, or from within
outward : the latter is the more extensive and more natural movement ; it is produced by
a great number of muscles, and, therefore, during repose, the point of the foot is slightly
inclined outward.
The Knee-joint (Jigs. 78 to 81).
Preparation. — 1. Make a crucied incision in front of the knee and dissect back the flaps.
2. Detach the aponeurosis of the thigh, preserving the fibrous band, which forms the con-
tinuation of the tensor vagina femoris, and which forms, as it were, a superficial ligament.
3. Remove the aponeurosis of the triceps on the sides of the patella, taking care to avoid
opening the synovial capsule. 4. Remove the tendon of the biceps, and turn downward
the tendons of the sartorius, gracilis, and semitendinosus. 5. Remove the popliteal ves-
sels and nerves behind, and also the gastrocnemii. 6. After having studied the ligaments
situated around the synovial capsule, isolate the latter as much as possible by dissecting
off the lateral ligaments, and the ligamentum patellae. 7. Open the synovial capsule
above the palate. 8. Make a horizontal section of the femur immediately above the con-
dyles, and a vertical section from before backward between the condyles These two
sections are intended to expose the crucial ligaments.
The articulation of the knee belongs to the class of angular ginglymi ; it is the largest
and most complicated joint in the human body ; it is, perhaps, the most important, both
in regard to the part which it plays in the mechanism of the animal economy, and the fre-
quency and the gravity of the maladies which it is liable to.
Articular Surfaces. — The lower end of the femur and the upper end of the tibia are the
essential constituents of this joint, which is completed in front by the patella. The ar-
ticular surface of the femur is formed in front by the trochlea, and behind by the two
condyles, separated by the intercondyloid fossa ; the articular surface of the tibia con-
sists of the glenoid cavities, separated by the spine of the til)ia, in front of and behind
which are some irregular projections. The patella presents two concave surfaces, sep-
arated from each other by a vertical ridge corresponding to the groove of the trochlea.
These surfaces are aU covered with a thick layer of cartilage. It should be remarked,
with regard to the knee-joint, 1. That the articular surfaces are rather placed in juxta-
position than jointed together ; 2. That the articulation is in some measure double, since
two very distinct condyles correspond to two equally distinct cavities. These two con-
dyles being turned in opposite directions, viz., the external backward and outward, the
internal backward and inward, they are opposed to each other ; like the articulation oi
the two condyles of the occipital bone with the atlas, which are opposed both to the lat-
eral and the rotatory motions, and, in regard to these motions, constitutes an angulai
ginglymus, so in the case in the knee, its two condyles constituting, as it were, a double
condylian articulation, transformed into an angular ginglymus.
Inter-articular Cartilages. — Like all joints that are exposed to much pressure, the knee
is provided with inter-articular cartilages. They are two in number, and are named,
from their figure, semilunar or falciform cartilages (a, b, fig. 78). Their upper surfaces,
corresponding to the convexity of the condyles, are concave ; their external circumfer-
ence is very thick, and the internal sharp and thin : they therefore assist in deepening
the concave surfaces of the tibia. The section of tlicse cartilages forms an elongated
isoscele triangle, with its base outward. The external inter-articular cartilage (a) gov
ers almost the whole of the external glenoid cavity of the tibia, fonning nearly a com-
plete circle ; while the internal cartilage (4), which is, indeed, semilunar, leaves a great
ARTICULATIONS OP THE KNEE-JOINT.
'-.H^'UnMt* .
1^.78.
part of the corresponding cavity uncovered.* In this respect
the inter-articular cartilages of the knee differ from all others
of the S2uiie kind, for they do not establish a complete separ-
ation of the articular surfaces, between which they are placed.
« hese falciform cartilages are inserted into the tibia by means
of ligaments, which deserve a particular description.
Ligaments of the External Semilunar Cartilage. — These are
two : the one anterior, and the other posterior ; both of them
are very strong. The anterior is inserted in front of the spine
of the tibia, outside of the anterior crucial ligament, into a
deep depression situated near the external glenoid cavity of
the tibia. This anterior ligament of the external semilunar
cartilage sends off a bundle which intermingles with the ante-
rior crucial ligament. The posterior is inserted into the spine
of the tibia, in the unequally-divided interval situated between
the two prominences of the spine. The posterior ligament
sends off a considerable bundle of fibres to be inserted into the
posterior crucial ligament. The circular form of the external
semilunar cartilage is owing to the insertions of the two an-
teiior and posterior ligaments being separated from each other
only by a few lines.
Ligaments of the Internal Semilunar Cartilage. — These are much weaker than the foi-
mer. The anterior is inserted a good deal before its fellow, the anterior ligament of
the external semilunar cartilage, and the posterior is inserted a good deal behind the
corresponding ligament of the externed semilunar cartilage ; hence the semilunar shape
of the internal semilunar cartilage, which does not send off any fibrous prolongation to
the anterior or posterior crucial ligaments. The ligaments of the inter-articular cartila-
ges being inserted into the tibia, these cartilages follow the tibia throughout its course
Means of Union of the Knee-joint are two lateral hgaments, a posterior and an anterior,
two crucial ligaments, and a synovial capsule.
1. Lateral Ligaments. — The external lateral ligament {a, figs. 79 and 80) appears as a
rounded cord ; it is inserted into the exter-
nal tuberosity of the femur, at the point of
union of the five anterior sixths with the first
posterior, on the prolongation of the line of
the fibula ; the precise point of this insertion
is a small eminence surmounting a depression
which is destined to the tendon of the popli-
teus muscle, and is situated in front of an- al
other depression destined to the external ge- A
meUus ; thence this ligament descends, in a '^
vertical line, to be inserted into the external
face of the head of the fibula. This ligament
has the appearance of a tendon ; it extends
along the anterior border of the tendon of the
biceps, with which it may be readily con-
founded.
We should have but an incomplete idea of
the means of union which the knee-joint pos-
sesses on the outside, if we did not add to the
number of its ligaments the tendon of the bi-
ceps, which unites in some sort its inferior
insertions with those of the external lateral
ligament, and the small band of the fascia
lata inserted into the anterior tubercle of the
tibia, and sending to the external edge of the
rotula an expansion, which unites with the
tendon of the vastus externus.
The internal lateral ligament (J c, figs. 79
and 80), which is much longer than the exter-
nal, has the shape of a broad, thin, pearly-
coloured band, arising from the posterior part
Fig. 79.
Fig. 80.
* On asking- myself the question why there should be
this difference between the two semilunar cartilages, I
have come to the conclusion that the external condyle of
the femur, pressing much more upon the tiliia than the
internal, on account of the external following the axis
of the femur, while the internal is turned away from it , t. »»■ l f ♦
to the inside, the externa! inter-articular cartilage had to protect a greater portion of the articular «unace ol
thti tibia
164 ARTHROLOGY.
of the internal tuberosity of the femur, on a level with the external lateral ligament, im-
mediately below the tubercle into which the third adductor muscle is inserted ; it is
turned downward, and a little outward ; it widens in its course, and is inserted, by a
broad surface, into the internal border and the anterior surface of the tibia : at this in-
sertion, which is at least an inch wide, it is covered by the tendons of the sartorius^
gracilis, and semitendinosus muscles, which glide over this ligament by means of an in
tervening synovial bursa.
Its deep surface is applied to the anterior or reflected tendon of the semi-membrano
sus, to the internal semilunar cartilage, to which it intimately adheres, and to the inter
nal inferior articular vessels, which are protected by it.
When the layers of this ligament are removed in succession, it will be seen that the
deepest fibres are attached to the superior part of the internal tuberosity of the tibia,
and adhere to the synovial membrane. The lateral ligaments are situated much nearer
to the flexing or the back part, than to the extending or the fore part of the joint, so
that they are stretched during extension, and assist in limiting that motion, but are re-
laxed during flexion, to the performance of which they offer no obstacle.
The posterior ligament, or ligament of Winslow (c, figs. 79 and 81), is much complicated,
and is composed, 1. Of a fibrous capsule for each condyle ; 2. Of a median posterior hg-
ament, the only one which has been described by authors.
1. Fibrous Capsule of the Cmidyles. — Each condyle is enveloped with a fibrous husk ,
that of the external condyle is covered by the external origin of the gemellus, and thai
of the internal condyle by the internal. The fibrous capsule of the internal condyle is
completed by the internal origin of the gemellus turning around the highest and most in-
ternal portion of this condyle. The semi-membranosus muscle sends a fibrous expansion
from above downward to this same internal capsule ; the external head of the gemellus
is still much more than the internal identified wath the corresponding fibrous capsule,
which furnishes a great number of insertions to that muscle. When there is a sesa-
moid bone in the external gemellus, it is found in the substance of the external capsule.
2. The Median Posterior Ligament. — It is composed of several sets of fibres : 1. Some
pass obliquely upward and outward, being formed by a considerable expansion of the
semi-membranosus ; 2. Others proceed from the tendons of the popliteus and the ge-
melli ; and, lastly, 3. Some fibrous bundles, partly vertical and partly oblique, arise from
above the condyles of the femur, and are attached to the tibia. Frotn this collection of
fibres running in different directions, there results an irregularly-interwoven ligament,
perforated by foramina that transmit the ramifications of tlie middle articular artery ;
several of the most deeply-seated ligamentous bundles are inserted into the edges of
the inter-articular cartilages.
3. Anterior Ligament, or Ligamentum Patellm {d,figs. 80 and 81). — This name is given
to that portion of the tendon of the extensor muscles which ex-
tends from the patella to the tibia. This ligament has the thape
of a very broad, thick, almost triangular band. Its fibres arise
by a broad insertion, of from five to six lines, from the apex of
the patella and from the anterior surface of this bone ; they are
parallel, pearly-white, and become nearer to each other as they
approach the most prominent and lower portion of the anterior
tuberosity of the tibia, to which tuberosity they are attached. It
should be remarked, tliat this ligament is by no means inserted
into the rugged projections which are found on the back part of
the apex of the patella. Behind this ligament is a considerable
mass of adipose tissue {e,fig. 81), which separates the hgament
from the articular synovial capsule , a synovial bursa if, fig. 81)
separates it from the anterior portion of the tuberosity over
which it glides. This synovial bursa sometimes communicates
with the articular synovial capsule, and sometimes is totally dis-
tinct from it.*
Crucial or Interosseous Ligaments. — In the interior of the knee-
* I should remark that this bursa extends partly over the ligament, which it covers from side to side, ana
partly over the anterior tuberosity of the tibia, vfhich is at this point completely deprived of inter-articular car.
tilage , so that the facility with which the synovial membrane of the tibia is removed contrasts with the diffi-
culty which is experienced in dissecting the synovial membrane which covers the inter-articular cartilages,
provided it exists there. The ligamentum patella; forms only a part of the anterior ligament of the knee-joint ,
this anterior ligament is completed by the rotula and by the united tendons of the rectus femoris, the vastus
mtemus and extemus, of which united tendons the ligamentum patellae is evidently a continuation. We see
here a very remarkable application of this law, by mea>is of which the articular ligaments are fortified by ten
dons, and sometimes completely replaced by ftem ; and I have taken care to observe that it is generally the
trochlear joints which exhibit examples of this replacing of ligaments by tendons in regard to extension, be-
cause, in the movement of extension, a ligament, being a purely passive means of union, was not sufficient.
What would take place if an ordinary ligament were to be substituted for the tendon of the extensor muscles t
In the first place, this ligament would have to be extremely long to permit flexion ; but in case it should be
long enough for flexion, what would become of it in the movement of extension ? Unless it were endowed
witn the extensibility and the elasticity of the yellow ligaments, it would become folded, and would thrust
itself between the articular surfaces. It is for this reason that a ligament was required which might be short
ARTICULATIONS OF THE KNEE-JOINT. Ifffe
joint there are two interosseous ligaments {g i,fig- 78), so arranged as to admit of the
most extensive flexion, but to limit the movement of extension. They are called cniciaU
because they cross each other like the letter X. They are situated in the deep inter-
condyloid fossa, whose sole destination appears to be that of protecting them. The an-
terior {g,Jigs. 78 and 81) arises from the external condyle, and passes to the fore part of
the spine of the tibia. The •posterior (t, fig. 78) arises from the internal condyle, and is
fixed to the back part of the spine. Both are continuous, by a distinct bundle, with the
external inter-articular cartilage ; never with the internal. The names anterior and
posterior have been given these ligaments, from their inferior insertion ; for superiorly
they arise on the same level. Here follows a more minute description of their inser-
tions above and below, and of their direction.
The anterior crucial ligament arises, as a little band flattened from side to side, from
the semilunar depression, which is concave superiorly, and is situated on the internal or
median surface of the external condyle ; thence it extends from above downward, from
without inward, and from behind forward, flattens from before backward, and is inserted
in front of the spine of the tibia, upon which spine it encroaches a little by means of some
insertions which it takes between the two articular projections constituting the spine.
From the external edge of this ligament a few fibres are given off, which extend into the
external part of the semilunar cartilage.
The posterior crucial ligament arises from the external or median surface of the inter-
nal condyle in a semilunar depression, entirely similar to the one which is destined to the
anterior crucial ligament ; like the latter, it presents a threefold obliquity from above down-
ward, from before backward, and from within outward ; it sends a considerable expan-
sion to the external inter-articular cartilage, and is inserted back of the spine of the tibia.
Thence it follows that the crucial ligaments present a double crossing : 1. A crossing
in an antero-posterior direction, and this alone has been observed with attention ; 2. A
crossing in a transverse direction ; when the tibia is rotated from within outward, the
crossing of these two ligaments increases to such an extent that these two ligaments,
strongly pressed against each other, limit the motion ; in the movement of rotation from
without inward, on the contrary, as the crossing diminishes, they become relaxed and
parallel ; both are stretched during extension, and relaxed during flexion ; there is an
exception for the most anterior fibres of the anterior crucial ligament, which are relaxed
in the middle state of extension, and stretched during flexion ; but when the extension
is considerable, the anterior crucial ligament is also stretched in its anterior fibres, which,
being pressed by the condyles, describe a curve anteriorly concave.
The synovial capsule of this joint is the largest and the most complicated of all that ex-
ist in the body. In tracing it from the upper edge of the patella, we find, behind the ten-
don of the extensor muscles, a large cul-de-sac {s,fig. 81), sometimes replaced by a dis-
tinct synovial capsule, interposed between that tendon and the surface of the femur. In
many subjects, this bursa communicates with the synovial capsule of the knee-joint by
a more or less considerable opening, and in such cases a circular constriction forms the
only trace of separation. On each side of the patella the synovial membrane extends
beneath the two vasti, and is sometimes elevated from one and a half to two inches
above the articular surfaces ; the prolongation under the vastus externus is much more
considerable than that under the vastus internus. The existence of these two prolonga-
tions affords an explanation of the sweUings observed at the sides of the knee in dropsy
of this joint ; and the greater extent of the external prolongation explains, also, the great-
er size of the prominence on the outside. In the inter-condyloid notch the synovial mem-
brane envelops the crucial ligaments ; then it is reflected upon the posterior ligament,
the lateral ligaments, the semilunar cartilages, the articular surfaces of the tibia, and,
lastly, the back of the ligamentum pateUae ; it next sends off a prolongation, containing
a few ligamentous fibres, and extending from the lower border of the patella to the front
of the inter-condyloid notch. This fold has been incorrectly termed the adipose ligament
ened or elongated as might be necessary, a tendon being the continuation of a muscle, that is, of an organ at
once capable of extension, contraction, and endowed with elasticity. Besides this, a bone was required that
might complete the articulation on the outside, that might fill the large space which, during the movement
of flexion, would have remained empty between the articular surfaces, and might glide without injury ovor
osseous surfaces, and facilitate, at the same time, standing upon the knees. This threefold object has been
attained by the patella, a sesamoid bone, which is developed in the substance of the tendon of the extensor
muscle of the leg, viz., of the triceps femoris, whose parallelism, at its insertion into the rotula, is destroyed
by this bone.
Independently of the anterior ligament, the knee-joint exhibits a large aponeurotic surface, formed by the
femoral aponeurosis, by an aponeurotic expansion of the. fascia lata, and by another aponeurotic expansion fur-
nished by the tendons of the sartorius, gracilis, and semi-tendinosus muscles ; to this latter expansion is joined
a fibrous lamina, given off by the tendon of the vastus externus and internus, which is attached to the libia.
This large anterior aponeurotic surface exhibits, on a level with the tendon of the triceps, a saltier-shaped in-
terlacing, which closely adheres to this tendon, and seems destined to serve it as a bridle ; on a level with the
patella it exhibits a thin layer, which is sometimes interrupt- 3, and, so to say, lacerated, in consequence of
the sub-cutaneous synovial capsule being present ; and on a level with the ligamentum patelte it exhibits
fibres running obliquely from above downward and from without inward.
Finally, I shall point out as appendages of the anterior ligament two proper ligaments of the patella, one m
temal, the other external, extending from the edges of the patella to the posterior part of each tuberosity
these ligaments are broad and thin, and strongly adliere to the synovial capsule.
166 ARTHROLOGY.
(ligamentum mucosum, t,figs. 78 and 81). After having furnished this fold, the syno-
vial membrane lines the posterior surface of the patella, and becomes continuous with
the cul-de-sac behind the extensor tendon. Sometimes the prolongation, known as the
adipose ligament, does not exist ; at other times there is more than one. I have seen
a fold of the same nature extending from that part of the synovial membrane which lines
the extensor tendon to the surface of the femur above the trochlea. No other synovial
membrane in the body is provided with so large a number of villous prolongations, which,
in some subjects, may be said to give it a shaggy appearance ; they are especially met
with around the patella* and the semilunar cartilages. To these prolongations Clopton
Havers has given the name of synovial fringes. Some deep fibres of the triceps cruris
have been regarded as a special tensor muscle of the synovial capsule. (Vide Trice fs
Cruris, Myology.)
Sub-synovial Adipose Tissue. — From the abundance of this tissue in the knee-joint, its
disposition requires some special notice. It is chiefly met with behind the ligamentum
patellae {_e,fig. 81), where it forms a very thick layer, filling up the interval between the
patella and the synovial membrane. This adipose mass, which raises the ligamentum
patellae in the extension of the knee, and which, during flexion, fills the empty space
which the movement of flexion produces between the condyles of the femur and the tibia,
is situated to the outside of the joint, between the ligamentum patellae and the synovial
capsule, which is raised by the mtiss. This mass, on being examined on the side which
is contiguous to the joint, exhibits several prolongations, which are somewhat similar to
the fatty appendages of the epiploon. These appendages are all lined by a fold of the
synovial capsule ; one of these appendages, supported by a fibrous bundle, is attached
to the inter-condyloid space, under the name of ligamentum mucosum patellas, which hg-
ament is sometimes multiple, and has no other object except to draw to it the fatty mat-
ter between the tibia and the femur during flexion of the knee, and to keep that matter
in its place during the movement of extension. A large quantity of fatty matter is also
found behind the tendon of the triceps above the condyles, where that matter fills the in-
terval between this tendon and the corresponding part of the femur. Bundles of fatty
matter are, lastly, foimd all around the condyles, as well as in the inter-condyloid notch,
and around the insertions of the crucial ligaments. This fat, which may be observed
even in individuals in a state of marasmus, except that, under those circumstances, it is
more serous and infiltrated, is nowhere more evidently than in the knee-joint, destined to
fill the intervals produced between the articular surfaces by certain attitudes.
Mechanism of the Femoro-tibial Articulation.
1 . With regard to Strength. — The strength of articulations is generally in direct pro-
portion to the extent of the articular surfaces, and there is no joint more advantageously
constructed in this respect than the one we have been examining. The reception of the
spine of the tibia into the inter-condyloid fossa also tends greatly to increase the strength
of the joint, although it forms but an imperfect kind of dovetailing. A third and last con-
dition conducive to strength is, the multiplicity of the ligaments, and of the tendons, sup-
plying, in some respects, the deficiencies in the fitting.
2. With regard to Mobility. — The knee, being a hinge-joint, has two principal move-
ments, in opposite directions, \iz., flexion and extension; but, as the mutual reception of
the surfaces is very imperfect, it is also capable of some slight rotatory motions.
In flexion, the surfaces of the tibia, defended by their inter-articular cartilages, glide
backward upon the condyles of the femur ; and, from the great extent of the articular
surfaces of the last bone in that direction, the movement can be carried so far as to per-
mit the leg and thigh to touch. In this movement, the lateral, the posterior, and the cru-
cial ligaments are relaxed, except the anterior fibres of the crucial ligament, which are
stretched ; the ligamentum patellae is stretched ; the patella is firmly applied to the front
of the joint, and can neither be moved to the right nor to the left, as may be done during
extension. In the position of flexion, the patella fills up, as it were, the great hiatus then
existing at the front of the joint between the femur and the tibia. Luxation is impossible
during this movement, which is only limited by the mutual contact of the leg and the thigh.
In extension, the tibia and the inter-articular cartilages glide in the opposite direc-
tion. The movement is arrested when the leg is in the same line as the thigh, and
whatever muscular feffort be then made, the leg never will pass that limit, excepting
trom malformation of the parts. A greater amount of extension is rendered impossible,
both by the shape of the articular surfaces, and by the stretching of all the ligaments, ex-
cepting that of the patella, which is completely relaxed, and permits of a great mobility
of that bone in all directions. One circumstance in the shape of the articular surfaces,
which appears to be opposed to any extension beyond the straight line, is the small extent
of the trochlea in front ; for, could such extension take place, the glenoid cavities of the
tibia would then be applied to a portion of the trochlea, much smaller than themselves.
The crucial ligaments are especially intended to limit the movement of extension, as the
* [Two slight folds of the membrane formed at the sides of the patella have been particularly described
inder the very inappropriate name of the alar ligaments.^
PERONEO-TIBIAL ARTICULATIONS. J67
following experiment will at once demonstrate. Divide all the external ligaments of
the joint ; the crucial ligaments will then alone remain ; then endeavour to extend the
leg beyond the ordinary limits ; this wiU be found impossible until these ligaments are
divided. That both the crucial hgaments oppose the extension of the limb beyond a cer-
tain limit, is proven by dividing these ligaments separately. So long as one remains, no
matter which, the extension is limited. An analogous experiment, in which all the hga-
ments of the joint (even including the crucial) are divided, excepting the lateral, proves
that these are not only opposed to lateral movements, but also limit extension with much
force ; this they are enabled to do from being situated nearer to the back than to the
front of the joint. Complete luxation can only be effected after laceration of all the hga-
ments which hmit extension. An interesting remark, which has been suggested to me
by'M. Martin, is, that the crucial hgaments are not only destined to limit the movement
of extension, but also — and this is, perhaps, their principal object — to prevent the articu-
lar surfaces from leaving each other in the anterior posterior direction during a forcible
extension. Thus, the anterior crucial ligament will prevent, in a movement of exten-
sion, both the displacement of the tibia backward, and that of the femur forward, and the
posterior crucial ligament will prevent both the displacement of the tibia forward, and
that of the femur backward. It is also important to remark, that while standing upon the
feet, the ham-strings being stretched, these extensor muscles of the leg, which are situa-
ted upon the thigh, the rectus femoris, and the vastus externus and intemus, are entirely
inactive, as is prgved both by the extreme mobility of the patella and the relaxed state of
these muscles in a standing position, and by the absence of all sensation of lassitude in
these muscles after the vertical position upon the feet has been continued for a long
time. The extension of the knee, therefore, takes place without any co-operation on
the part of the muscles, simply through the articular surfaces being juxtaposed in all
their breadth, and by the tension of the lateral and crucial ligaments, which keeps the
articular surfaces mechanically upon each other.*
In all these motions the patella is fixed ; it is the femoral trochlea which glides upward
or downward upon the posterior surface of that bone. This almost invariable position
of the patella depends on the inextensibility of its ligament. The existence of the patella
has no effect in limiting the movements of extension ; its only uses, as far as the joint
is concerned, are to protect it in front, and to prevent painful pressure in the kneeling
posture. Its other and chief uses are connected with the functions of the triceps ex-
tensor muscle, in the tendon of which it is developed ; it removes the axis of the muscle
from the parallel direction of the lever which it is destined to move. It is movable and
depressed during extension of the leg, but during flexion it becomes prominent and fixed, t
Rotation. — When the leg is semi-flexed upon the thigh, it can be very slightly rotated
mward and outward. These movements are performed, not upon the external, but upon
the internal condyle as a pivot, so that the external part of the head of the tibia glides
forward during rotation inward, and backward during rotation outward. The difference
in the part performed by the two condyles in the movement of rotation does not depend
upon any peculiarity of structure in the joint, but exclusively upon the arrangement of
the acting forces, as we shall see when treating of the muscles. Rotation inward is limited
by the mutual contact of the crucial ligaments, whose decussation is increased during this
movement. Rotation outward is more extensive, because in this movement the liga-
ments are uncrossed, and become parallel. We shall see hereafter that the biceps is the
agent of rotation outward, and the popliteus of rotation inward.
Peeoneo-tibial Articulations {figs. 79 and 80).
Preparation. — 1. Remove carefully the muscles of the anterior and posterior regions
of the leg, which will expose the interosseous ligament, and the anterior and posterior
ligaments of these joints. 2. In order to see the interior of the articulations, saw through
the two bones in the middle, and then separate them. 3. To gain an idea of the interosseous
* M. Robert, one of our most distinguished young surgeons, has observed a fact which sustains these ideas,
■which had already been demonstrated by the artificial legs of M. Martin. An individual in whom the patella
was fractured, had recovered with a distance of about ten centimeters. The movement of extension by mus-
cular contraction was impossible ; but when the limb was extended, it maintained itself in that position with
the same force as the limb upon the healthy side. The patient had succeeded, by a sort of artifice, in exe-
cuting spontaneously the movement of extension ; he brought the trunk and the pelvis forcibly forward : the
femur followed the pelvis, and extension being once effected, this inferior limb, being very strong and immo-
vable, assisted in the standing position just as much as the healthy limb.
t It is during flexion of the leg, and, consequently, when the patella is most immovable, that this bone
may be displaced in consequence of some external violence, and in this case, the displacement always takes
place to the outside. However, one should suppose that the external condyle of the femur, being much more
prominent than the internal, would be opposed to the luxation outward, and favour the luxation inward, "ut
we may remark, that the patella, when displaced inward, cannot remain in this position, in which nothing
maintains it, and from which the oblique direction of the triceps tends, on the contrary, to bring it back to its
natural place ; whereas, when the patella is displaced outward, the prominence of the extorual condyle op-
Tjoses the reduction of the patella, which can only be effected by artificial means. It should be remarked, that
ttie obliquity downward and inward of the femoral trochlea gives a tendency to the patella of being continuaUj
drawn outward by the tendon of the extensor muscles, which is slightly oblique in the same direction as the
trochlea. This is so true, that in white swellings of the knee-joiut, the spontaneous displacement of the pa-
tella always takes place outward.
168 ARTHROLOGY.
ligament of the inferior articulation, saw perpendicularly through the lower endc of thp
bones of the leg, so as to divide them into an anterior and a posterior portion.
The tibia and the fibula, which are contiguous at their extremities, are separated iVoir
each other along their shafts, the interval being occupied by an aponeurosis, improperly
called the interosseous ligament. We have, then, a superior and an inferior peroneo-tibiai
articulation, and an interosseous ligament or aponeurosis.
1. Superior Peroneo-tibial Articulation.
Tliis articulation is an arthrodia. The articular facette of the tibia, looking downward
and outward, is situated behind its external tuberosity. I'he facette of the fibula looks
upward and inward ; it occupies the inner part of the upper end of the bone. The means
of union are two ligaments : an anterior {g, Jig. 80) and p. posterior {d, Jig. 79). They
are composed of parallel fibres, directed obliquely downward and outward from the exter-
nal condyle of the tibia to the heaji of the fibula. There is generally a distinct synovial
membrane for this joint, but sometimes it is a prolongation from the capsule of the knee.
This communication frequently existing between the synovial capsule of the knee and
the peroneo-tibial articulation, should condemn, in an amputation of the leg, the practice
of extirpating the superior extremity of the fibula. The formidable accidents which
might be consequent upon such an extirpation may readily be conceived, and should for-
bid the operation, although it has been accomplished without any accident. Its only ob-
ject is to prevent the fibula from pressing upon the soft parts.
2. Inferior Peroneo-tibial Articulation.
This articulation is an amphi-arthrosis, that is, it is formed between surfaces that are
partly contiguous and partly continuous. The former consists of two articular facettes,
narrow from above downward, and oblong from before backward ; of these, one is con-
vex, and situated upon the internal surface of the lower end of the fibula above the mal-
leolus ; the other is concave, and continuous with the inferior or tarsal articular surface
of the tibia. They are both covered with cartilage. The continuous surfaces are rough,
and much more extensive ; they are triangular in shape, having their bases directed down-
ward : the one situated upon the fibula is convex, that upon the tibia is slightly concave.
The means of union are, two ligaments external to the joint, and an interosseous liga-
ment connecting the two triangular surfaces just mentioned. Of the two external liga-
ments, one is anterior (i. Jig. 80) and the other posterior {e, Jig. 79). They are both very
strong, and composed of thick, shining, parallel fibres, which pass obliquely downward
and outward from the tibia to the fibula. They are almost always divided into two dis-
tinct bundles. They are both remarkable from descending beyond the articular surfa-
ces, so that they increase the depth of the cavity for the reception of the astragalus.
The sijnovial membrane of this articulation is a prolongation from that of the ankle-joint
The interosseous ligament consists of fibrous bundles, mixed with adipose tissue, which
unite the two triangular surfaces so firmly that the fibula is sometimes fractured in at-
tempting to rupture the ligaments.
3. Interosseous Aponeurosis.
The name of interosseous ligament is given to an aponeurotic septum {b,figs. 79 and
80) placed between the muscles of the anterior and those of the posterior aspect of the
leg ; it should rather be regarded as serving to multiply the points of insertion for fibres
of those muscles, than as a means of union between the bones of the leg. It is narrow-
er below than above, and is composed of fibres running obliquely downward and outward
from the outer edge of the tibia to the longitudinal crest on the inner surface of the
fibula. As in the interosseous ligament of the forearm, we find some other fibres cross-
ing the former at an acute angle. The septum thus formed is interrupted above and be-
low for the passage of the tibial vessels ; the peroneal artery and veins traverse the low-
er opening ; the anterior tibial artery and veins pass through the upper.
Mechanism of the Peroneo-tibial Articulations.
The fibula is only capable of almost imperceptible gliding movements upon the tibia.
This arrangement is directly connected with the mechanism of the ankle-joint.
Ankle, or Tibio-taksal Joint (Jigs. 79 and 80).*
Preparation. — Cut and turn back the tendons that are reflected round the joint, and
remove tl\e sheaths of those tendons by which most of the ligaments are covered. The
peroneo-calcanean ligament is seen after the tendons of the peroneal muscles have been
removed ; the synovial membrane of these tendons only covers it. The peroneo-astra-
galian ligament is the most difficult to uncover, on account of its being deeply seated,
and separated from the sheath of the muscles of the posterior region by a large quantity
of adipose tissue. The internal lateral ligament is seen immediately beneath the sheaths
of the tibialis posticus, the common flexor tendon of the toes, and the proper flexor of the
* We should remark th&t, in order to study this as well as all the other articulations efficiently, it is a great
ijvantage to be provided with two joints, of which one is opened, while the other has its ligaments untouched
ARTICULATIONS OF THE ANKLE-JOINT. 169
great toe. In order to see the deep layer of this ligament, the superficial laj ers must
be removed one after the other.
The tibio-tarsal articulation belongs to the class of angular ginglymt.
Articular Surfaces. — Both bones of the leg participate in this joint, their 1 >wer extrem-
ities being united to form a transversely oblong socket, of which the tibia constitutes by
far the greater part. On this articular surface there is an antero-posterior ridge, corre-
sponding to the groove of the trochlea on the astragalus, and separating two shallow cav-
ities. The socket is bounded by the malleoli on each side. The internal or tibial mal-
leolus corresponds to the internal lateral articular surface of the astragalus ; and the ex-
ternal or fibular malleolus, to the external lateral facette of the same bone. The tibio-
peroneal cavity is completed forward and backward by the lower part of the anterior and
posterior peroneo-tibial ligaments. The superior articular surface of the astragalus is
a trochlea ; it is oblong from before backward, thus contrasting with the cavity on the
lower extremity of the leg,* which is transversely oblong. This trochlea presents a
shallow depression, running from before backward, and having an external and an internal
edge, the external being the more elevated of the two. The pulley of the astragalus is
continuous with its lateral articular surfaces, of which the external is by far the larger.
The means of union are three external lateral ligaments, two internal lateral ligaments,
an anterior {r,Jig. 80) and a posterior {s,fig. 79) ligament, and a synovial capsule.
The external lateral or. peroneo-tarsal ligaments are three in number; they all proceed
from the fibula, either to the astragalus or the os calcis.
1. The external lateral ligament, properly so called (ligamentum fibulae medium vel per-
pendiculare, m,.figs. 79 and 80), is situated beneath the sheath of the peroneus longus
and brevis. It arises from the summit of the external malleolus, is directed downward
and shghtly backward, to be attached to the outside of the os calcis. It is rounded, and
composed of parallel fibres.
2. The anterior external lateral ligament (ligamentum fibulae anterius, n, fig. 80) arises
from the anterior edge of the externed malleolus, and proceeding downward and forward,
is fixed to the astragalus in front of its external malleolar facette. It is very short, and
broader below than above : it forms one of the two anterior hgaments described by Bi-
chat in this joint.
3. The posterior lateral ligament (ligamentum fibulae posterius, o,fig. 79) is very deeply
seated behind ; it extends from the excavation on the inside and behind the external
malleolus to the posterior border of the astragalus, immediately above the pulley of this
bone. It is directed almost horizontally, or in a slight degree obliquely downward and
inward, and is almost parallel to the posterior ligament of the lower peroneo-tibial ar-
ticulation. It is composed of very distinct parallel fibres, which are arranged in several
layers, the deepest of which are attached to the astragalus behind the facette of the ex-
ternal malleolus. The posterior peroneo-astraglagean ligament is very strong. Bichat
calls it the posterior ligament of the joint.
The interTwl lateral ligament is much stronger than the three external ligaments taken
together. It is composed of two very distinct layers : 1. A superficial layer, consistiiig of
fibres stretched from the apex and the anterior and posterior borders of the internal mal-
leolus to the OS calcis, and the upper edge of the lower calcaneo-scaphoid ligament, which
it maintains in a state of constant tension. The fibres are long and slightly divergent,
but still sufficiently so to have given origin to its name of the deltoid ligament {p,figs. 79
and 80). The fibres which are most anterior pass directly forward to the neck of the
astragalus, and to the scaphoid ; they form a very thin layer, which has been improper-
ly called the anterior ligament of the ankle-joint. 2. Below the above is a deep layer of
much greater extent, composed of sliort and strong bundles, passing downward and out-
ward from the sununit and sides of the internal malleolus, to the inner surface of the as-
tragalus, below the articular facette. +
Synovial Capsule. — The external surface of this membrane is brought into view in
front and behind by removing the tendons and their sheaths ; and if the external and in-
ternal lateral ligaments be divided, it will be seen to extend into the inferior peroneo-
tibial articulation. It will also be observed that it is tense at the sides, but very loose
behind, and more particularly so in front. A great quantity of adipose tissue covers its
external surface in these situations.
Mechanism of the Ankle-joint.
This articulation not only constitutes the point at which the weight of the body is
* Hence, the longest diameter of the astraglagean cavity is from before backwaril ; the longest diametei
of the tibio-peroneal cavity is transversely. The extent of the movements of flexion and extension ol '"« '9°'
depends upon the disproportion between the antero-posterior diameter of the pulley of the astragalus ana me
socket of the leg. , „„„._„„,
t [The author has omitted, perhaps intentionally, to give a special description of the anterior anu posienor
ligaments of the ankle-joint, already alluded to by him. The former extends from the anterior margin oi tne
articular surface of the tibia to the corresponding border of the astragalus, a id is called the wno-iarsai itg-
ament ; it is very thin, and covered by the tendons of the extensor muscles. The posterior can scarcely De
said to exist as a distinct ligament.]
15»
ARTHROLOGY.
transmitted to the foot, but also performs a very active part in the movements of pro-
gression ; it is therefore so constructed as to unite great strength with the capability of
tolerably extensive motion.
With regard to strength, the following arrangements should be noticed as especially ad-
vantageous : 1. The leg being articulated with the foot at a right angle, transmits the
weight of the body directly to it, and this transmission being effected in the perpendicular
direction, i. c, in a direction in which the articular surfaces mutually oppose each other,
has no tendency either to produce fatigue or to rupture the ligaments. The perpendic-
ular position of the leg upon the foot during standing is worthy of notice, because of it-
self it proves that man was intended for the erect posture, since in this attitude alone
does the entire inferior surface of the foot rest upon the ground. It should be also re-
marked, that there is no other articulation, excepting that of the head upon the verte-
bral column, in which the parts united are habitually perpendicular to each other. 2.
The dovetailing effected at this joint, by the reception of the astragalus into the socket,
formed by the bones of the leg, is also highly conducive to its strength. This dovetail-
ing results both from the pulley-like surface of the astragalus, and from the angular form
of the tibio-fibular socket ; and it should be observed, that this latter condition is, as it
were, peculiar to the ankle-joint, for in no other do we meet with such abrupt angles.
With regard to mobility, the tibio-tarsal articulation admits of flexion and extension.
There is no lateral motion, the movements of the foot in this direction being almost ex-
clusively performed at the tarsal joints.
Inflexion, the astragalus gUdes backward upon the tibia and fibula, and the back part
of the pulley projects behind. Luxation, from an excess of this movement, is almost
impossible, for it is limited by the meeting of the neck of the astragalus and the anterior
edge of the tibio-fibular sockets. In this movement, the posterior extern2d lateral liga-
ment, and the middle and posterior fibres of the internal lateral ligament, are put upon
the stretch.
In extension, on the contrary, the trochlea of the astragalus glides forward upon the
corresponding surface ; the synovial membrane is borne upward in front ; the anterior
external lateral ligament, and the anterior and middle fibres of the internal lateral liga-
ment, are stretched. Luxation is possible during this motion, but is very rare.
Lateral Movements. — Although the shape of the joint is opposed to movements of this
kind, yet it cannot be doubted that the elasticity of the fibula, by allowing the external
malleolus to yield a little, may permit them in a slight degree. Nevertheless, the fibula
must be fractured, if any force, exerted by the astragalus against the external malleolus,
be carried so far as to thrust it much outward.
Articulations of the Tarsus {figs. 80, 82, 83, 84).
The intrinsic articulations of the tarsus comprise, L The articulations of the compo--
nent bones of each row. 2. The articulation of the tv/o rows together.
Preparation. — 1. Remove the tendons situated upon the dor-
sum of the foot, and also the extensor brevis digitorum mus-
cle. 2. Remove all the muscles of the plantar region. 3. Rub
off, by means of a rough cloth, the adipose tissue covering the
ligaments (a subject much infiltrated with serum is best adapted
for this purpose). 4. In order to gain a clear comprehension of
the articulation of the two rows together, remove the astrag-
alus from the sort of box in which it is contained, by divi-
ding the interosseous ligament which unites it to the os calcis.
5. For the examination of the interosseous ligaments, it is ne-
cessary to separate the bones by laceration or section of those
ligaments ; the resistance experienced in doing this, and the
portions of the ligaments remaining attached to the bones, will
give a good idea of their strength and situation. 6. In order
to obtain a correct notion of all the ligaments together, it is
necessary, while studying each, at the same time to examine
a foot in which all the joints have been opened above, while
the bones are still retained in their situations by means of the
plantar ligaments.
Articulation of the Component Bones of the First Row, or Articula-
tion of the Astragalus with the Os Calcis.
This is a double arthrodia, in which each of the bones pre-
sents two articular facettes, separated by a furrow deeper on
the outer than on the inner side. Tlie posterior surface of the
astragalus (1, fig. 84) is concave, that of tlie os calcis (2) is
convex ; in front (1) the opposite obtains, so that there is a mu-
tual reception of parts. The means of union, properly speak
ing, consist only of an extremely strong interosseous ligament (a,
Fig.SZ.
ARTICULATIONS OF THE TARSUS.
171
/Jg'. 84) formed by ligamentous bundles, of which some are vertical, and others oblique ,
they are mixed with fat, and occupy the considerable interval formed by the grooves of
the two bones, and which is larger towards the outer end. To form a complete idea of
this ligament, it is necessary to make a vertical section from before backward, through
the middle of the astragalus and os calcis (as in^^. 84). A loose synovial membrane
lines the posterior articulation, which is strengthened on the inside by the fibrous sheaths
of the tendons of the tibialis posticus, the flexor longus digitorum, and the flexor longus
poUicis. There are also about this joint two very small fibrous bundles, one of which
is posterior {t, fig. 80 ; a, fig. 83), and the other external {Jb, fig. 83) : some anatomists
have described them by the names of posterior and external ligaments. The anterior por-
tion of this articulation is often double, from the division of the anterior articular sur-
faces into two smaller facettes : it forms part of the astragalo-scaphoid articulation, with
which it will be described.
Articulations of the Component Bones of the Second Row.
All these joints are very compact, for the five bones which constitute this row act as
one only in the movements perfonned by the foot at its tarsal pig, 93.
articulations. They present for the most part angular facettes ;
they have also interosseous ligaments, and are true symphyses
or amphiarthroses.
Articulations of the Cuneiform Bones with each other.
Articular Surfaces. — The corresponding surfaces of the first
and second cuneiform bones present contiguous as well as con-
tinuous portions. The contiguous portions are square, and sit-
uated at the upper and back part of each surface. The con-
tinuous portions are placed in front of the preceding. The
corresponding articular surfaces of the second and third cunei-
form bones are smooth and contiguous behind, but rough and
irregular in front.
Means of Union. — 1. By dorsal ligaments {c c, fig. 83). This
name is given to some very compact fibrous bands stretching
transversely from one bone to the other. By their upper sur-
faces, on which the longest fibres may be seen, they are in re-
lation with the extensor brevis digitorum and with the tendons
of the other extensor muscles. Their lower surfaces, the
fibres of which are shorter, correspond to the articulations, and
to the periosteum of the cuneiform bones, with which they in-
terlace. 2. By plantar ligaments. This name may be given
to some of the fibres of the interosseous ligaments. 3. By in-
terosseous ligaments. These, which are very strong, consti-
tute the principal means of union of these joints, and occupy
all the rough portions of the corresponding facettes. They
so closely unite the bones, that, even when the dorsal liga-
ments are removed, it is not easy to open the joints.
The synovial membrane is merely a portion of the general sjrnovial membrane of the
tarsus.
Articulations of the Scaphoid vnth the Cuneiform Bones.
Articular Surfaces. — The scaphoid presents the only example in the body of a single
articular surface being divided into three facettes by well-marked ridges. Each of these
facettes is triangular, and corresponds to a surface of the same form on one of the cunei-
form bones. The base of the triangular facette for the first cuneiform bone is below ;
the bases of the other two are above (3, fig. 80).
Means of Union. — 1 . Dorsal ligaments. There are two for the first cuneiform bone, a
superior (d, fig. 83), and an internal (c, figs. 83 and 84) ; and only one for each of the oth-
ers (//, fig. 83). The dorsal ligaments of the first cuneiform bone pass directly back-
ward ; those of the other two are stretched obliquely for^vard and outward. 2. Plantar
ligaments. A very strong plantar ligament (a, fig. 82) extends from the tubercle of the
scaphoid to the corresponding tubercle of the first cuneiform bone ; it is blended with the
tendon of the tibialis posticus, which furnishes a considerable expansion that crosses the
direction of the tendon of the peroneus longus, and extends to the third cuneiform, and
the corresponding metatarsal bone ; it may be considered as an inferior ligament of the
tarsus. The name of plantar ligaments can scarcely be given to some irregular fibres
{h,fig. 82) passing from the lower surface of the scaphoid to the second and third cunei-
form bones.
A synovial membrane, common to the three articulations, is continuous with that of the
three cuneiform bones.
)J|S ARTHROLOGY.
Articulation of the Third Cuneiform Bone with the Cuboid.
This articulation resembles in every respect those of the cuneiform bones. The means
of union are a dorsal ligament {g, fig. 83), consisting of a very strong transverse bundle ;
an interosseous ligament, which occupies the entire non-articular portion of the correspond-
ing surfaces ; and an ill-defined plantar ligament, consisting of some irregular transverse
fibres. The synovial membrane communicates with that of the cuneo-scaphoid articulations.
Articulation of the Scaphoid with the Cuboid.
The scaphoid and the cuboid often unite by a small facette. The means of union are
an oblique dorsal ligament {i, fig. 83), a very strong interosseous ligament, occupying the
whole of the corresponding surfaces of the bones, excepting the small portions which
are contiguous ; and a very thick transverse plantar ligament, extending somewhat ob-
liquely from the tuberosity of the scaphoid to the cuboid. These ligaments exist even
when there are no articular facettes.
Articulation between the two Rows of the Tarsal Bones.
The articulation between the two rows consists of the articulation of the astragalus
with the scaphoid and os calcis, the articulation of the os calcis with the cuboid, and,
lastly, the union of the os calcis to the scaphoid by means of several ligaments.
1 . Articulation of the Astragalus with the Scaphoid.
The articular surface on the head of the astragalus {.I, fig. 84), elongated from without
jPt^. 84. inward, and from above down-
ward, is larger than the glenoid
cavity of the scaphoid (3), and pro-
jects considerably below it, where
it articulates with the anterior fa-
cette, or the two anterior semi-
facettes of the os calcis. The
cavity of reception is completed
by a ligament called the inferior
calcaneo-scaphoid {b), which occu-
pies the triangular interval be-
tween the small tuberosity of the
os calcis and the scaphoid, and
y forms by itself the inner side of
the cavity of reception. In order to obtain a good view of this ligament, it is advisable
to remove the astragalus by cutting and tearing the interosseous ligament that unites it
to the OS calcis ; it will then be seen that the ligament we are describing is very strong
and triangular, and that it covers not only the lower, but the inner part also of the head
of the astragalus. It is often divided into two parts : one being external, narrow, and
shaped like a band ; the other internal, much broader and thicker, in relation below with
the sesamoid bone of the tendon of the tibialis posticus, and presenting a cartilaginous
thickening at the corresponding point.
Another ligament, called the superior calcaneo-scaphoid {I, fig. 83), must also be regard
ed as contributing to wedge in the astragalus ; it extends from the inside of the anterior
extremity of the os calcis to the outside of the scaphoid. It is situated upon the dorsum
of the foot, in the deep hollow occupied by fat, on the outer side of the astragalus.
These two ligaments (the inferior and superior calcaneo-scaphoid) constitute the means
of union between the os calcis and the scaphoid. These bones are in no part contigu-
ous ; but occasionally we find the os calcis continued into the scaphoid, through the me
dium of an osseous lamina, which replaces the lower calcaneo-scaphoid ligament.*
The OS calcis being very securely articulated with the astragalus, and at the same
time very firmly connected with the scaphoid, it follows that the articulation between the
scaphoid and astragalus possesses great strength, although the ligaments directly uniting
them are by no means powerful ; just as the atlas, which is but slightly connected with
the occipital bone by means of its own ligaments, is very firmly fixed by the ligaments
stretching from the occipital bone to the axis. Nevertheless, the absence of any very
strong and direct means of union between these bones renders it possible for the astrag-
alus to be forced by externeil violence out of the sort of osseo-fibrous socket in which
it is placed.
The superior astragalo-scaphoid ligament {s,fig. 80 ; m,figs. 83 and 84) is the only one
proper to this joint ; it is semicircular in form, and extends somewhat obliquely forward
and outward, from the neck of the astragalus to the margin of the facette on the sca-
phoid. It is thin in texture, and consists of parallel fibres ; it is covered by the ex
tensor brevis digitorum above, and is lined below by the synovial membrane of the articu-
lation between the scaphoid and the astragalus.
* I have represented a case of this nature (vide Anat. Pathol, avec Planches, liv. ii., pi. v.).
ARTICULATIONS OF THE TARSUS. l73
2. Calcaneo-cuhoid Arliculahon.
This articulation is upon the same line as the astragalo-scaphoid ; an anatomical fact
which has suggested the ingenious idea of a partial amputation of the foot between the
two rows. It belongs to the class we have designated articulations by mutual reception,
and of which we have found examples in the sterno-clavicular joint, and the carpo-meta-
carpal articulation of the thumb.
Articular Surfaces (2, fig. 80). — The facette of the os calcis is concave from above
downward, while the surface of the cuboid is concave transversely, that is, in a direc-
tion at right angles to that of the former. At the lower part of the facette of the os cal-
cis there is a horizontal projection, which sometimes stops the knife during the disartic-
ulation of the two rows.
The means of union consist of three ligaments : an inferior or plantar, an internal, and
a superior. The inferior -plantar, or calcatieo-cuboid ligament (ligamentum longum plantae,
c d,figs. 82 and 84), is the strongest of all the tarsal ligaments, forming a broad band of
pearly- white fibres, directed from before backward. These fibres constitute a very thick
bundle, and extend from all the under surface of the os calcis, excepting the posterior
tuberosities, to the posterior margin of the groove of the cuboid. If the fibres of this
ligament be removed layer by layer, we soon arrive at a more deeply-seated ligament,
separated from the first by some fatty tissue : it extends obliquely inward, from a tuber-
osity at the forepart of the under surface of the os calcis, to all that portion of the infe-
rior surface of the cuboid, situated behind its groove. There are, therefore, two inferior
calcaneo-cuboid ligaments : a deep (c) and a superficial {d).
The internal calcaneo-cuhoid ligament {n, fig. 83) is short, narrow, quadrilateral, and
very strong ; it is placed at the side of the superior calcaneo-scaphoid ligament, in the
deep excavation between the astragalus and the os calcis. These two ligaments are
separated in front, but blended together behind, so as to resemble the letter Y. They
may be considered as in some measure forming the key of the articulation of the two
rows of tarsal bones ; for, during disarticulation, the articular surfaces are easily separ-
ated as soon as they are divided.
The superior calcaneo-cuboid ligament (o, fig 83) is only a very thin, small band of fibres,
extending directly forward, from the os calcis to the cuboid.
Mechanism of the Tarsal Articulations.
We should examine the mechanism of the tarsal articulations both as regards their
strength and their mobility.
With regard to Strength. — The tarsus forms the fiindamental part of the foot ; one
might, in fact, consider the metatarsus and the toes as superadded structures, for, even
when they are removed, the foot fulfils its office as a basis of support very efficiently.
Surgeons avail themselves of this fact in performing partial amputations of the foot at
the tarsal and tarso-metatarsal articulations.
The construction of the tarsus is, in every respect, adapted to ensure strength ; the
number of its pieces, the breadth of the articular surfaces, the strength of the interosse-
ous ligaments, and even the mobility of its component bones, all conduce to this end.
Suppose, for example, that a single bone had occupied the place of the seven bones in
the tarsus, how liable would this long and cancellated lever have been to fractures from
the violent shocks to which it is constantly exposed, or from the influence of muscular
contraction 1 The tarsus is narrow behind, but enlarged before, so as to increase the
transverse extent of the supporting base in that direction ; it is articulated with the leg
at a right angle, and, therefore, receives directly the weight of the body, and as directly
transmits it to the ground. In order to provide the arm of a lever for the power which
raises the weight of the body, it pirojects behind the leg ; indeed, the fitness of an indi-
vidual for running and leaping may be, in some degree, calculated from the length of his
heel, or, what is the same thing, from the prominence of the tendo Achilles. In stand-
ing upon the sole of the foot, the weight of the body is transmitted by the tibia to the
astragalus, and from thence to the os calcis. Part of the momentum is lost at the artic-
ulation between these bones, and it is easy to comprehend why they are super-imposed,
and not arranged in mere juxtaposition. But the astragalus is not placed horizontally
above the os calcis, for it inclines inward, downward, and forward ; and from this cir-
cumstance, even in standing upon the soles of the feet, the weight of the body is distrib-
uted between the os calcis and the anterior range of the tarsus, which is itself subdivi-
ded into two rows, but only on the inside, because it is there chiefly that the weight of
the body is transmitted by the astragalus. In one attitude, this weight is communicated
by the astralagus exclusively to the front row, viz., in standing upon the point of the
foot ; and it is then that the division of the tarsus into several bones is especially useful
in preventing the injurious effects of shocks transmitted from belOw. There is an im-
.nense difference, also, as regards their effects on the system, between falls upon the
heels and those upon the points of the feet.
The mechanism of the tarsal articulations with respect to mobility should be first studi
ed in the two ranges separately, and afterward in the articulation of the two rows to-
gether.
tT4 ARTHROLOGY.
1. The bones of the first range, viz., the astragalus and the os calcis, glide upon each
other from before backward and from side to side. The lateral glidings assist in the
torsion of the foot, which, however, is chiefly performed at the articulation between the
two rows. The antero-posterior glidings take place under the following circumstances :
when the weight of the body presses upon the upper part of the astragalus this bone slips
a little forward, and the foot has a tendency to become elongated, or flattened from above
downward, as Camper has remarked. "WTien the pressure ceases, the astragalus returns
to its original position. The truth of the assertion, that the foot is an elastic arch, is
chiefly established by reference to the nature of the astragalo-calcanian joint.
2. The bones of the second row are capable of such very slight gliding movements,
that they may be considered as forming but a siilgle piece. However, the articulation
between the scaphoid and the cuneiform bones is somewhat more movable than those
of the cuneiform bones with each other-and with the cuboid.
3. The chief movements of the tarsus take place between the two rows, and the ar-
ticular surfaces are there very favourable to mobility ; for there is in one part a head re-
ceived into a cavity (at the astragalo-scaphoid articulation), and in another a mutual re-
ception (at the calcaneo-cuboid articulation). These movements consist of a sort of tor-
sion or rotation, by means of which the sole of the foot is carried either inward or out-
ward. Assisted by slight lateral motions of the astragalo-calcanian joint, they consti-
tute what is called adduction and abduction of the foot. They are generally attributed to
the ankle-joint ; but, as we have seen, that articulation is limited to flexion and exten-
sion ; the sprains, therefore, which result from too extensive movements, either outward
or inward, take place at the articulation of the two tarsal ranges, and not at the ankle-
joint. When the movement of torsion is carried too far, the external malleolus is forced
somewhat outward ; slight gliding motions occur at the tibio-fibular articulations ; the
elasticity of the fibula is called into play ; and, if the violence be immoderate, the fibula
is fractured.
Tarso-mktatarbal Articulations {Jigs. 82 to 84).
, In the formation of these joints, the wedge-shaped tarsal extremity of each metatarsal
bone is opposed to one of the bones of the tarsus, the corresponding surfaces being plane
and triangular. The first metatarsal bone articulates with the first cuneiform ; the sec-
ond metatarsal with the second, and shghtly with the first and the third cuneiform bones ;
the third metatarsal with the third cuneiform ; the fourth and fifth metatarsal with the
cuboid. From this there results an angular articular line, commencing on the outside, at
the projection formed by the tuberosity of the fifth metatarsal bone. This line is directed
obliquely forward and inward ; it forms an angle at the third, and again more particularly
at the second metatarsal bone, because the third cuneiform bone projects, and is wedged
in between the second and fourth metatarsal bones, while the second metatarsal bone
projects into the tarsus between the first and the third cuneiform bones. The articular
surfaces are held together by dorsal, plantar, and interosseous ligaments. We shall now
study each of these articulations separately.
Articulation of the First Metatarsal Bone with the Tarsus. — ^There are two semilunar
facettes in this articulation, one belonging to the first metatarsal, the other to the first
cuneiform bone ; the long diameter of these surfaces is directed vertically. The strength
of the joint is maintained by a very strong plantar {ffigs. 82 and 84), and a thinner dor-
sal {p,fig- 83, and e,fig. 84) ligament. Both these consist of bands directed from before
backward. There is a distinct synovial membrane for this joint. We may include
among the ligaments of this articulation the aponeurotic expansion given off by the pe-
roneus longus to the first cuneiform bone, and also that derived from the tibialis anticus,
and attached to the first metatarsal bone.
The articulation of the second metatarsal hone with the tarsus is effected by the reception
of the posterior extremity of that bone within the recess formed by the three cuneiform
bones. We met with a similar arrangement, though less perfectly developed, in the
carpo-metacarpal articulation of the second metacarpal bone. It is the strongest of all
the joints of this kind, and is provided with, 1. Three dorsal ligaments, as in the corre-
sponding articulation in the hand ; one median (r, fig. 83), broad, and constantly divided
into two bands, which proceed from the second cuneiform bone ; a very strong internal
ligament, extending from the first cuneiform bone, the third being external, thin, and at-
tached to the third cuneiform bone. 2. With two plantar ligaments, one of which {g, fig.
82) is very strong, extends obliquely from the first cuneiform to the second metatarsal
bone, and is prolonged upward, so as to become interosseous ; the other is very small,
and proceeds from the sharp edge of the second cuneiform to the second metatarsal bone.
3. With an interosseous or lateral ligament, extending from the external lateral surface of
the first cimeiform bone to the internal lateral surface of the second metatarsal bone.
The articulation of the third metatarsal hone with the tarsus is maintained by a dorsal liga-
ment {s, fig. 82) from the third cuneiform bone. There is no plantar ligament, properly
so called, unless an oblique bundle of fibres from the first cuneiform bone be considered
as such ; but the fibrous layer, which, after forming the sheath of the tendon of the pe-
ARTICULATIONS OP THE METATARSUS. ITII
roneus longus, is prolonged to the third metatarsal bone, appears to me to act as a plantar
ligament. There is also an external lateral or interosseous ligament, which separates the
articulations of the third and fourth metatarsal bones.
The fourth and fifth metatarsal bones together present a slightly concave surface, which
articulates with the convex surface of the cuboid. The means of union consist of a
dorsal ligament (t, fig. 83) for the fourth, and an oblique ligament (u), running outward and
forward, for the fifth metatarsal bone : they are both loose, but especially the latter.
There is no plantar hgament, excepting the sheath of the tendon of the peroneus longus,
and a very strong tendinous expansion of the tibialis posticus. The tendon of the pe-
roneus brevis acts as an external lateral ligament ; and, besides this tendon, there ex-
ists a very strong fibrous band, derived from the external plantar aponeurosis, which
extends from the os caleis to the process of the fifth metatarsal bone ; and, moreover,
an expansion of the tendon of the peroneus longus, given off as it passes over the cuboid.
The articulation of the fifth metatarsal bone is very loose. There is a very strong in-
terossemis ligament, stretched from the external lateral facette of the third cuneiform
bone to the internal lateral facette of the fourth, and the external lateral facette of the
third metatarsal bones. This ligament is analogous to one that separates the articula-
tion of the fourth and fifth metacarpal bones from the other carpo-metacarpal articula-
tions, and it fulfils a similar purpose here ; so that there are three distinct articulations
between the tarsus and the metatarsus, and, therefore, three separate synovial mem-
branes ; one for the fourth and fifth metatarsal bones, one for the second and third, and
another for the first.
Articulations of the Tarsal Extremities of the Metatarsal Bones. — These are true amphi-
arthroses. The corresponding surfaces are partly contiguous and partly continuous. The
contiguous part is nearer to the tarsus ; it is flat, and presents on each bone two small
secondary facettes. Contrary to what obtains in the metacarpus, the continuous por-
tions are larger than the articular surfaces. There are interosseous, dorsal, and plantar
ligaments. The interosseous consist of very strong, short, and compact bundles of fibres,
which extend between the rough surfaces of two neighbouring metatarsal bones. The
dorsal {b, fig. 83) and plantar {i, fig. 82) pass transversely from one metatarsal bone to
another, the plantar being much the larger.
Articulations of the Digital Extremities of the Metatarsal Bones. — ^Although the digital
ends of these bones do not articulate together, yet, as they are in contact and move upon
each other, a synovial membrane covers the continuous surfaces and facilitates their
movements ; a ligament, also, the transverse ligament of the metatarsus (x, figs. 82 and
83), is stretched transversely in front, and unites them loosely together. This ligament
is conamon to the five metatarsal bones ; it is formed by the junction of all the anterior
ligaments of the metatarso-phalangal articulations, by means of small bundles passing
from one to another. It is exposed by opening the sheaths of the flexor tendons.
Mechanism of the Metatarsal Articulations.
With regard to Strength. — 1. The five component bones of the metatarsus are so strong-
ly united that it is very uncommon for one of them to be broken by itself; the metatar-
sus, therefore, can be only fractured by violence sufficient to crush it. 2. The slight
■ mobility of the bones also concurs in increasing the strength of this part of the foot, by
permitting it to yield slightly to external impulse. 3. The metatarsus is not uniformly
strong throughout ; the first of its bones is the strongest, and upon it a great portion of
the weight of the body rests during standing.
The mobility possessed by the tarsal and the digital extremities of the metatarsal
bones requires to be separately noticed.
1. In the tarsal extremities, the a'ngular arrangement, the mutual wedging of the tar-
sus and the metatarsus, as well as the strength and shortness of the external and inter-
osseous ligaments, admit of only very obscure gliding movements ; a proof of which ex-
ists in the fact, that no example of the luxation of these bones upon the tarsus has, per-
haps, ever been recorded. 2. Obscure, however, as these movements may be, they give
rise to considerable motions in the digital ends of the bones, where the mobility is fa-
voured by the looseness of the transverse metatarsal ligament, and the presence of a sy-
novial membrane between the heads of the bones. The first metatarsal bone is not
more movable than the others, contrasting remarkably in this respect with the first met
acarpal bone.
Articulations op the Toes {figs. 82 to 84).
Metatarso-phalangal Articulations.
These articulations belong to the class condyloid, and offer a nearly perfect similarity
to the metacarpo-phalangal joints.
Articular Surfaces. — The head of each metatarsal bone is flattened on the sides, and
elongated from above downward, so that it forms a condyle. Each i)halanx presents 3
shallow cavity, the greatest diameter of which, contrary to that of the metatarsal surface
is transverse.
J 76 ARTHROLOGY.
Means of Union. — 1. There is an inferior or glenoid ligament (I, Jig. 82), situated on the
plantar aspect of the joint ; it is very thick, of the density of cartilage, and consists of
interlacing fibres : its edges are continuous, partly with the sheath of the flexor tendons,
partly with the transverse metatarsal ligament, but especially with the lateral ligaments
of the joint. It is grooved below for the flexor tendons, concave above, to correspond
with the convexity of the head of the metatarsal bone, and completes the cavity in which
that head is received. Its anterior edge is very firmly fixed to the plantar border of the
cavity of the phalanx, of which it seems a continuation ; its posterior edge is free, or,
rather, is loosely connected by some ligamentous fibres to the inequalities behind the
head of the metatarsal bone, upon the contracted neck of which it is moulded very ex-
actly, so that, while protecting the lower part of the joint, it serves also to increase the
extent of the surfaces included in the articulation. 2. There are two very strong lateral
ligaments (y, figs. 82 and 83), an internal and an external, inserted, not into the depres-
sions on each side of the head of the metatarsal bone, but into tubercles situated behind
them ; from this origin they proceed very obliquely forward and downward, like flat
bands, spreading out as they advance, and terminating partly in the inferior ligament,
and partly on the sides of the phalanx. There is no dorsal ligament, properly so called,
but the corresponding extensor tendon evidently occupies its place. It is not uncommon
to observe a prolongation from the anterior surface of this tendon united to the metatar-
sal end of the first phalanx.
Synovial Capsule. — ^Under the extensor tendon we find a very loose synovial capsule ;
it covers the internal surface of the ligaments as well as the articular cartilages.
The metatarso-phalangal articulation of the first metatarsal bone presents some peculiar-
ities which merit special description. 1. The articular surfaces are much larger than in
the other similar joints. 2. The head of the first metatarsal bone presents two pulleys
on its plantar aspect, separated from each other by a prominent ridge directed from be-
fore backward. This construction is connected with the presence of two sesamoid bones
{g, fig. 84), developed in the substance of the inferior ligament, which is three or four
times thicker than in the other joints. The lateral ligaments are almost exclusively
fixed into these sesamoid bones. This joint has also a sort of fibrous ring surmounting
the border of the glenoid cavity of the phalanx.
Articulations of the Phalanges of the Toes.
These are perfect angular ginglymi. Each toe has two such joints, with the excep-
tion of the great toe, which has only one.
Articular Surfaces. — The anterior extremity of the first phalanx, flattened from above
downward, presents a trochlea, which is broader, and prolonged farther on the plantar
than on the dorsal surface. On the second phalanx there are two small glenoid cavities
separated by a ridge, the cavities corresponding to the sm£dl condyles, and the ridge to
the groove of the trochlea just described.
Ligaments. — 1. As the articular pulley of the first phalanx projects considerably below
the second, it is covered in this direction by an inferior or glenoid ligament (m, fig. 82),
exactly resembling those of the metatarso-phalangal joints, and perfoming the same
functions. 2. The two lateral ligaments (y, figs. 82 and 83) are fixed precisely like the
corresponding ligaments of the metatarso-phalangal joints, viz., into the tubercle above
the lateral hollow on the anterior extremity of the first phalanx ; and they extend ob-
liquely forward to the glenoid ligament and the second phalanx. 3. There is no superior
ligament, its place being supplied by the extensor tendon. This tendon is arranged in a
particular manner, for it frequently sends off a prolongation (z, fig. 83) from its anterior
surface, which is attached to the upper end of the second phalanx. 4. The synovial cap-
sule is arranged as in the metatarso-phalangal articulations. There is often a sesamoid
bone in the inferior ligament of the phalangal articulation of the great toe.
Mechanism of the Metatarso-phalangal Articulations.
Like all condyloid joints, these admit of movements in four principal directions, and,
therefore, are also capable of circumduction. Extension or flexion backward can be car-
ried much farther than in any other similar joints. The lateral movements of abduction
and adduction are very hmited. Let us examine what takes place during each of these
movements, in which the glenoid cavity of the first phalanx glides upon the head of the
corresponding metatarsal bone. Inflexion, the first phalanx glides downward upon the
head of the metatarsal bone ; the extensor tendon and the upper part of the synovial
capsule are stretched by the projecting head ; the upper fibres of the laterad ligaments
are also stretched ; these fibres then limit the motion, which, nevertheless, may be car-
ried so far that the phalanx may make a right angle with the metatarsal bones. In
extension, the phalanx glides upward upon the head of the corresponding metatarsal
bone ; the superior fibres of the lateral ligaments are relaxed, while the inferior are
stretched : these latter and the inferior ligament evidently limit the motion. In all sub-
jects it maybe carried so far as to make an obtuse angle behind ; in some so as even to
form a right angle. The movements of abduction and adduction are limited by the meet-
ing of the toes.
ODONTOLOGY. 177
Mechanism of the Phdangal Articulations.
As the mechanism of these joints is in every respect identical with that of the fingers,
we shall refer to what has been said upon that subject, merely remarking that, eithei
from original construction, or from the continued confinement of the toes in tight shoes,
their movements, which consist exclusively of flexion and extension, are much more
limited than those of the fingers.
Note on Artkrology. — [It has been considered advisable to include in a single note the following observation*
on the general anatomy of the several tissues that enter into the construction of the articulations :
Cartilages (p. 111). — The substance of the articular cartilages, in many joints, appears to be arr'mged in
masses placed side by side, and perpendicularly to the surface of the bone ; and hence the fibrous character
presented by them alter slight maceration: nevertheless, they are composed of pure cartilage, unmixed with
fibrous tissue. When viewed under the microscope, cartilage is found to consist of a transparent substance,
in which are imbedded numerous corpuscles, either placed singly or aggregated in groups. The interme-
diate substance is homogeneous in youth, but becomes more or less laminated as age advances. The corpuscles,
which are, in fact, metamorphosed primitive cells, are of irregular forms, contain nuclei and nucleoli, and are
somewhat flattened near the surface of the cartilage. Occasionally, several are seen occupying a distinct
cavity in the intermediate substance. Their average size is tsVs*^ °^ '"^ '"'^'^ '" length, by^ iAj-jth in
breadth. Neither nerves, bloodvessels, nor lymphatics are found in the articular cartilages, which, al-
though non-vascular, can scarcely be considered unorganized. Cartilage contains 66 per cent, of water ; its
principal solid constituent is an animal matter, resolved by boiling into a peculiar variety of gelatin, called
chondrin ; it also contains salts of soda, lime, magnesia, and potash.
The inter-articular cartilages having free surfaces (as those of the knee-joint), are composed of true carti-
lage interwoven with fibrous tissue, which particularly abounds at their attached margins. The inter-verte-
bral substances, and all other interosseous cartilages, have a similar structure, but contain a greater propor-
tion of fibrous tissue. From the two anatomical elements of which these structures consist, they are called
ftbro-cartilages.
The articular borders surrounding the glenoid and cotyloid cavities, generally described with the ligaments,
are also composed of fibro-cartilaginous tissue.
Ligaments (p. 112). — The articular ligaments consist entirelyof fibrous tissue, the obvious component fibres
of which are divisible into parallel microscopic filaments, exactly similar to those of cellular tissue (see note
on Aponeurologt, infra). They are supplied with but very few vessels and nerves ; they contain 62 per
cent, of water, the remainder being almost entirely converted into gelatin by boiling.
The yellow elastic tissue, of which the ligamenta subflava are composed, differs in minute, as well as in ob-
vious characters, from the white fibrous tissue of ordinary ligaments, it consists chiefly of peculiar filaments,
intermixed with a few of those of cellular tissue. The proper elastic filaments, examined with the micro-
scope, are yellowish and transparent, have a bright aspect and dark outline (very unlike the delicate appesir-
ance of the cellular filaments), and are usually curved or bent at their torn extremities. The peculiar char-
acter of dividing and uniting again, often assigned to them, is thought to be rather apparent than real, and to
depend on an imperfect separation of the larger into their component filaments. The elastic is more vascular
than the fibrous tissue. It contains less water (only 29 per cent.), and yields much less gelatin when boiled ;
the insoluble residua somewhat resembles coagulated albumen.
Synovial Membranes (p. 112). — The basis of an articular synovial membrane is cellular tissue, which be-
comes more and more condensed towards the free surface of the membrane. The smoothness of this surface is
due to a covering of flattened scales (metamorphosed primitive cells) lying upon it, and constituting what is
termed an epithelium. The recent discovery of this epithelium upon the surface of the articular cartilages is
suflScient to establish the continuity of the synovial membrane over them; a fact which, though doubted by
many, is assumed by M. Cruveilhier upon ansilogical grounds. No nerves have been traced into these mem-
branes, and the vessels existing in the sub-synovial tissue cease at the margin of the cartilage. The synovia
secreted by these membranes is an aqueous solution of albumen and saline matters. It contains more albu-
men than the fluid of serous cavities, the lining membranes of which (as we shall hereafter notice) have a
similar structure to those just described.
Besides the articular synovial membranes, two other kinds are usually mentioned, viz., the bursal, including
the various bursae, erroneously called bursae mucosae ; and the vaginal, examples of which are met with in th«
sheaths of tendons. These two forms will be again referred to in the note on Aponeurology, infra.
Adipose Tissue. — The constant occurrence, especially in the larger articulations, of masses of fat beneath
the synovial membranes, affords an opportunity of jdluding in this place to the minute anatomy of the adipose
tissue generally. It may be briefly stated to consist of an aggregation of distinct spherical or oval vesicles,
containing the adipose substance, and having numerous vessels ramifying on their transparent and homoge
neous parietes. They are held together by the branches of those vessels, and by cellular tissue. In man, the
adipose substance is liquid during life, but separates, when obtained in any quantity, into an oily fluid caUed
•la'ine, and a solid residue, consisting of two fatty substances, stearine and margarine.]
ODONTOLOGY.
Circumstances in which the Teeth differ from Bones. — Number. — Position. — Exterrud Confot
mation. — General Characters. — Classification — Incisor — Canine — Molar. — Structure. —
Development.
The teeth, the immediate instruments of mastication, are those ossiform concretions
which surmount the edges, and are implanted in the substance of both jaws. The teeth
are not bones, though, from possessing an apparent analogy to them, they have long
been considered as such. They differ from bones in many respects.
1. With regard to position. The teeth are naked and visible at the surface, while the
bones, and tliis is one of their most important characters, are covered by periosteum.
2. In anatomical characters. The teeth consist of a bulb or thick papilla, surrounded
by a calcareous envelope, composed of two substances, the enamel and the ivory. This
calcareous envelope is not traversed by vessels, nor can any trace of cellular tissue be
discovered in it.
3. In regard to their mode of development. In the teeth, the formation of the hard or
ossiform matter takes place by successive depositions, from the circumference to the cen-
Z
178 ODONTOLOGY.
Ire ; while bones are developed in a precisely opposite direction. No nutritive changes
are carried on in the teeth as in bones. Moreover, the teeth are renewed by means of
the second dentition ; but there is no analogous phenomenon in the development of bone.
4. In physiological relations. The teeth do not participate in the diseases of bone,
being susceptible only of chemical and physical alterations ; nor is the period of their
existence, like that of the bones, of equal duration with the life of the individual.
5. In regard to chemical composition. They contain a much larger proportion of saline
matters, and the enamel is entirely destitute of gelatine.
All these circumstances prove that the teeth are not bones. We shall now show that
they belong to the epidermoid system, and are analogous to the nails and hair.
1. When examined in the lower animals, they are found to present an uninterrupted
series, from such as closely resemble horns or nails to such as present the most perfect-
ly characteristic appearances of bone. 2. They have a lamellated structure, hke the nails
and hair : in some animals this is very manifest, but is rendered obscure in others from
the abundance of calcareous deposite. 3. They are developed in the same manner as
horns, nails, and hair. 4. Like them, they present no nutritive phenomena ; they are
formed layer after layer, and undergo no renewal of their constituent parts ; they are*
inorganic bodies, the products of transudation. 5. According to M. Geoffrey St. Hilaire,
the beak of birds, which is evidently a horny structure, belongs to the dental system.
Number. — In young subjects, at the period of the first dentition, there are twenty teeth,
ten in each jaw : in the adult there are thirty-two, sixteen in each jaw. Man, therefore,
during the course of his life, has fifty-two teeth, twenty temporary, and thirty-two per-
manent.
The varieties in the number of the teeth are either the result of a deficiency or an excess.
The varieties from deficiency consist, 1 . In the absence of all teeth, examples 6f which
have been recorded by Fox and Sabatier ; 2. In the absence of a great number of teeth,
as occurred in an individual who had only the four incisors in each jaw. These deficien-
cies are chiefly observed to affect the posterior molares, and frequently they are merely
apparent in them from the teeth remaining concealed within the alveoli for a much longer
period than usual. Besides, Fox remarks, that there is no tooth which has not occa-
sionally been observed to be wanting, either alone or in conjunction with others.
The varieties /rom excess are observed in the existence of supernumerary teeth, which
may or may not range wth the ordinary teeth. The supernumerary teeth either exist in
distinct alveoli, or are blended with some other teeth. There are two varieties of this
latter condition ; for the supernumerary tooth may either appear to grow upon a primitive
or parent tooth {^dens prolifcr of Bartholin), or several teeth may seem as if united into one.
Position. — The teeth are arranged in two parabolic curves, constituting the dental
arches, and corresponding to the alveolar arches, which support them. Into these arches
the teeth are fixed, not by articulation, but by the implantation of their roots into the al-
veoli, which are moulded exactly upon them. This arrangement induced those anato-
mists who regarded the teeth as true bones to admit a peculiar mode of articulation for
them, called gomphosis (yd/z^of, a nail).
The teeth are mechanically fixed in their alveoli ; but yet we must consider the gums
and the alveolo-dental periosteum as also forming uniting media. The importance of the
latter will be acknowledged, if we consider the effects of scurvy in loosening the teeth,
and the ease with which they drop out from the skeleton.
Each dental arch forms a regular, uninterrupted curve, an aiTangement peculiar to man,
for in the lower animals the teeth are of unequal length, and the dental arches have irreg-
ular edges ; moreover, instead of their teeth being uninterruptedly contiguous, very con-
siderable intervals, at some points at least, are left between them. Each dental arch
presents an anterior convex, and a posterior concave surface ; an adherent or alveolar bor-
der, which is regularly scalloped ; and a free edge, thin and cutting at the middle, thick
and tubercular at the sides ; in the latter situations it has two lips, of which the external
is sharper in the upper teeth, and the internal in the lower. The free edge is so arran-
ged that all the teeth are upon a level.
As the superior dental arch forms a greater curve than the inferior, it necessarily fol-
lows that the two arches meet hke the blades of a pair of scissors ; but the mode in
which they meet is not the same in the middle region, occupied by the incisor teeth, as
on the sides, where the molares are placed. Thus, the upper incisors pass in front of
the lower, while the external tubercles of the superior molares pass to the outside of the
external tubercles of the inferior molares, so that these latter tubercles are applied to the
furrow formed between the two rows of tubercles of the upper molares.
The teeth of the upper jaw, with the exception of the great molaies, are larger, in gen-
eral, than those of the lower. I should also remark, that no tooth is placed quite per-
pendicularly to its fellow in the other jaw ; for the summit of a tooth in one jaw always
corresponds to the interval between the summits of two in the other ; so that the two
rows of teeth are not simply in contact, but are really locked together.
* See note, p. 183.
THE INCISOR TEETH. 179
External Conformation. — ^The teeth, considered in reference to their form or configura-
tion, present some general characters which distinguish them from all other organs of the
body ; and also certain specific characters, by which one tooth may be distinguished from
another.
General Characters {figs. 85 to 92). — Each tooth is composed of two very distinct
parts : a free portion, projecting beyond the alveolus, named the crown or body {a, figs.
85, &c.), and a portion implanted in the bone called the root ox fang (i), the constricted
portion between these two constituting the neck (c). The rim of the alveolus or socket
does not exactly correspond to the neck of the tooth, but rather to the root, at some dis-
tance from the neck, the intervening space being occupied by the gam.
The axis of the teeth is vertical. This direction is peculiar to the human species. The
projection of the teeth forward gives a disagreeable aspect to the countenance, and is al-
most invariably connected with a diminution of the facial angle. The axis of all the teeth
is slightly inchned, so as to converge somewhat towards the centre of the alveolar curve.
The length of the teeth (that is, of their crowns) is very nearly uniform. The advan-
tage of this arrangement, in preventing one tooth from projecting beyond another, is very
obvious. Wlien the teeth are not equal in length, mastication is evidently imperfect ;
and therefore the principal object, in cases of fracture of the lower jaw, is to prevent the
inconvenience that would arise from irregularity of the dental edge, and which is actu-
ally observed when the fragments unite in a wrong position.
The teeth are only separated from each other by very small triangular intervals, so
that they are almost contiguous. When the intervcds are very considerable, mastica-
tion is imperfect.
The general form of the teeth is that of a sUghtly elongated cone, flattened in opposite
directions, the base of which is formed by the crown and turned towards the free edge
of the dental arch, while the summit, formed by the simple or compound root, presents
an opening that penetrates into the cavity of the tooth. The conical form of the root,
and the accuracy with which the alveolus is moulded upon it, have a twofold result, viz.,
that the effort of mastication is disseminated over all points of the socket, and that no
pressure is ever experienced at the extremity which receives the vessels and nerves.
The differences presented by the teetfi, more especially in the crown, have led to their
arrangement into three classes, viz., incisors, canine, and molars: the latter have been
subdivided into the great and small molars.
The crown of the incisor teeth {figs. 85, 86) resembles a wedge with the sharp border
shaped like a chisel ; as their name implies, they serve the purpose of cutting the food.
The crown of a canine tooth {figs. 87, 88) forms a cone with a free pointed apex ; these
teeth serve to tear the food, whence their name of laniaires : Hunter called them cu'spi-
dati, from their having only one point. The crown of a molar tooth {figs. 89 to 92) is
cuboidal, the free extremity being provided with tubercles or points, intended to bruise
the food as in a mill. The smjdl molars, which have only two tubercles, are called by
Hunter bicuspides {figs. 89 and 90). Man alone, of the entire animal series, is possessed
of the three kinds of teeth in an almost equal state of development.
The Incisor Teeth {jigs. 85 and 86).
These are eight in number, four in either jaw. They occupy the middle of the dental
arches, and, consequently, the anterior extremity of the lever of the third order, repre-
sented by each half of the jaw. Their position is unfavourable, and, consequently, they
are intended only to divide substances that offer but little resistance. This class of teeth
attain their utmost development in rodentia ; as in the rabbit, beaver, &c.
General Characters. — The crotcn (a) is wedge-shaped ; its anterior surface {fig. 85) is
convex, and the posterior concave ; its sides {fi,g. 86) are triangular ; its e-- 85 K 86
base is thick and continuous with the root, and its free edge sharp, some- '^'
what broader than the base, and cut obUquely upward and backward in , „r"
the upper teeth, and downward and forward in the lower. This obliqui-
ty of the surfaces, by which the incisors of the two jaws correspond, is
the result of their constant friction upon each other, for they cross like
the blades of scissors. The cutting edge of an incisor tooth, before it is
worn down, is marked by three small denticulations. The root {b) has
the form of a cone flattened on the sides ; the anterior border is thicker
than the posterior. A small vertical furrow (see fig. 86) occasionally ex-
ists on each side, appearing to indicate an original division ; and some-
times the point of the root is bifid. Two curved lines, having their concavities directed
downward, and united on the sides of the tooth, separate the root from the crown.*
Differential Characters. — The upper incisors are distinguished from the lowor by their
nmch greater size, the fonner being almost twice as large as the latter. In the upper
jaw, the middle are distinguished from the lateral incisors, also, by their well-marked su-
* [It maybe well to observe, that the illustrations arc all taken from teeth of the upper jaw, in which tha
general characters of each class are more strongly marked than in those of the lower.!
ODONTOLOGY.
periority in size. In the lower jaw, on the contrary, the lateral incisors are the larger,
though the difference is but shght.
The Canine Teeth {fgs. 87, 88).
These are four in number, two in each jaw. They are situated on either side exter-
nally to the incisors, and therefore are nearer to the fulcrum, so that they can overcome
a greater resistance. These teeth are most completely developed in the camivora. The
tusks of the boar and of the elephant are also canine teeth.
General Characters. — They are the longest of all the teeth, both in the crown and in
Fig. 87. Fig. 88. the root ; they therefore project a little beyond the incisors, particu-
larly in the upper jaw. Their crown (a) is thick and irregularly conoid ;
it is somewhat enlarged immediately above the neck, and terminates
in a blunt point cut obliquely at the sides (see^^. 88), and grooved be-
hind. The anterior surface (fig. 87) is convex, the posterior concave.
The canine teeth have much longer and larger roots (ft) than any oth-
er, and their alveoli are remarkably prominent. The root is flattened
on the sides, each of which presents a vertical groove traversing its
entire length (see^^. 88).
Differential Characters. — The superior canine teeth are distinguished
from the inferior by their greater length and thickness. The roots cor-
respond to the ascending process of the superior maxilla, and in some
subjects are prolonged to the base of that process. The length of their root explains the
difficulty of extracting them, and the accidents by which this operation is sometimes fol-
lowed. There are several preparations in the museum of the Faculty of Medicine, in
which the canine teeth are seen developed in the substance of the ascending process,
and reversed, so that the crown is turned upward and the root downward.
The Molar Teeth {fgs. 89 to 92).
The molar teeth are twenty in number, ten in each jaw. They occupy the last five
alveoli on either side, and, consequently, are nearer to the fulcrum than all the other teeth :
they are, therefore, most advantageously placed for exercising a powerful pressure upon
any substances we may desire to break between the teeth. The instinctive motion by
which, in order to crush a very hard body, we place it between the molars, is evidently
connected with this arrangement. These teeth are most highly developed in herbivora.
The general characters which belong to all the molars are the following : 1. The great
extent of their grinding surfaces, which far exceed those of the incisors and canine ;
2. The absence of all obliquity at their summit, the anterior and posterior surfaces be-
ing parallel, instead of approaching each other, so as to form a cutting or angular bor-
der : this character is evidently connected with the preceding one ; 3. The inequalities
of their grinding surfaces, which are marked by eminences and depressions ; 4. The round
or even cubical form of the crown ; 5. The shortness of the vertical dimneter of the crown ;
6. The multiplicity of roots.
The molars are divided into two classes, according to their difference in size, and the
number of tubercles upon their grinding surfaces. The smaller are called small molars,
or bicuspides ; the larger, great molars, or multicuspides. It should be remarked, that in
the first dentition, all the molars, without exception, are multicuspides.
The small molars or biscuspides {figs. 89 and 90) are eight in number ; four in each
jaw, two on the right, and two on the left side. They are distinguished by the names
first, second, &,c. They are situated between the canine teeth and the great molars.
The small molars of the upper jaw correspond to the canine fossae.
General Characters. — The crown (a) is irregularly cyhndrical, flattened from before
Fig. 89. Fig. 90 backward, with its long diameter directed transversely. The anterior
and posterior surfaces, which correspond to the two neighbouring
teeth, are plain (see fig. 90). The internal and external {fig. 89) sur-
faces are convex ; the free or grinding surface is armed with two tu-
bercles or points, separated from each other by a furrow. Of the two
tubercles the external is the larger. The crown of the small molars
has been compared to that of two small canine teeth united. The root
(b) is generally simple, but sometimes double or bifid. When simple,
it has a deep vertical groove upon each side ; when it is bifid, the sep-
aration is never so deep as in the great molars.
Differential Characters. — The lower bicuspides are distinguished from the upper by
their smaller size, by a slight projection of the crown inward, and by the external tuber-
cle being worn down. In the upper bicuspides, the two tubercles are separated by a
deep furrow ; in the lower, on the contrary, the furrow is more shallow, and the tuber-
cles are sometimes united by a ridge. The second upper bicuspid has generally two
roots {figs. 89 and 90), by which it is distinguished from the others. Tlie first lower
bicuspid, somewhat smaller than the second, has most commonly but one tubercle, viz
the external. This gives it more resemblance to a canine tooth.
STRUCTURE OF THE TEETH.
181
The great molars or multicuspides (figs. 91 and 92) are twelve in number ; six in each
jaw, three on one side, and three on the other. They are named pig_ gj, pig 93
nmnerically, proceeding from before backward, first, second, and ^ „ <'
third. The last is also called de-ns sapicntia, on account of its
tardy appearance. They occupy the most remote part of the
alveolar border.
General Characters. — The crown (a) is pretty regularly cuboid.
The anterior and posterior surfaces (see fig. 92), by which these 4 ]
teeth correspond, are flat ; the external and internal surfaces
(fi,g. 91) are rounded. The grinding surface is armed with four
tubercles (dcntes guadricuspides), separated by a crucial furrow,
which is occasionally replaced by small depressions. lu some teeth a fifth tubercle may
be found. In almost all the tubercles are of unequal size, and cut into facettes. The
crown of the great molars resembles two small molars united. The root (b) is always
compound ; it is most commonly double or triple, and, in this case, one of the roots has
a longitudinal furrow. Sometimes it is divided into four or five parts, variable both in
length and direction. The roots are either divergent or parallel ; and occasionally, after
separating, they approach each other again, curving like hooks, so as to embrace a more
or less considerable portion of the jaw bone. Such teeth (which are called dents harries)
it is impossible to extract without pulling away the included portion of the jaw also.
Each root of these teeth exactly resembles the single roots of the teeth already descri-
bed, with the exception of being smaller.
Differential Characters of the Upper compared with the Loicer Molars. — I . Contrary to
what was observed with regard to the other teeth, the crowns of the lower great molars
are a little larger than those of the upper. 2. They are slightly bent inward, while those
of the upper great molars are quite vertical. 3. The lower great molars have only two
roots, an anterior and a posterior. These roots are very strong and broad, flattened from
before backward, deeply grooved longitudinally, and bifurcated at the points. The upper
great molars have at least three roots {figs. 91 and 92), one internal and two external.
It is very easy, then, to distinguish between the molar teeth of the two jaws.
Individual Characters of the Great Molars. — 1 . The first great molar is distinguished
from the other two by its size, in which it generally exceeds them. 2. The third great
molar, or wisdom tooth, is distinguished from the first and second by its evidently
smaller size ; by its crown having only three tubercles, two external and one internal ;
by its shortness ; and by its roots being, in certain cases, more or less completely joined
together. However, even where the roots of these teeth are united, we always find the
trace of the characters proper to the series of molar teeth to which they belong ; i. e.,
the vestige of three roots, an internal and two external for the upper wisdom teeth, and
of two roots, an interior and a posterior for the lower.
No teeth present so many varieties as the last molares, which occasionally even remain
buried in the substance of the maxillary tuberosity.
Structure of the Teeth.
The crown of each tooth contains a cavity {d, figs. 93, 94) corre^onding with it m
shape. This cavity is prolonged with contracted dimensions into ^^ gg y. g^_
the centre of the root, and opens by an orifice of variable size at w- •
the apex of the simple or compound cone, represented by the fang.
The dimensions of this cavity are in an inverse proportion to the
age of the tooth ; so that it is largest at the earliest periods, but
during the progress of years it becomes entirely obliterated. It
contains a soft substance constituting the dental pulp. A tooth, i;||
therefore, is composed of two substances, an external hard or c<w-
ftcai porhoTi, which is unorganized,* and an internal organized pulp.
The dental pulp, contained in tfte cavity of the tooth as in a
mould, has the same form as the tooth to which it belongs. This
pulp is cormected with the dental vessels and nerves by means of
a nervous and vascular pedicle, which, after penetrating the dental cavity through the
orifice in the apex of the root, and traversing the small canal, becomes continuous with
it. From analogies, the accuracy of which will be seen in studying the development of
the teeth, the pulp may be regarded as a bulb or large papilla, and appears to consist of
a nervous expansion traversed by a great number of vessels. Its arteries are derived
from the internal maxillary ; the nerves belong to the superior and inferior maxillary
branches of the fifth pair. A membrane, rather difficult of demonstration on account of
its tenuity, envelops the pulp, which is extremely sensitive, is the seat of toothache,
and to it alone must be referred all that has been said regarding the vitality and sensi-
bility of the teeth.
The hard or cortical portion is composed of two substances, one of which covers th«>
* Sfie note, p. 183.
|S2 ODONTOLOGY.
crown, and has been called the enamel (e, figs. 93 and 94), from a comparison with the
vitreous layer or glaze of porcelain ; the other, constituting the entire root and the in-
terior of the crown, is the ivory (/), improperly designated the bony •portion of the tooth.
The enamel is thickest on the grinding surface of the tooth ; it diminishes in thickness
as it approaches the neck, at which part it terminates abruptly. The prominence of the
curved line, indicating the termination of the enamel, gives rise to the constriction call-
ed the neck.
By comparing, and, in some degree, contrasting the peculiar characters of the enamel
and the ivory, we shall be better able to assign to each their respective properties.
1. The enamel is of a bluish- white, milky colour, and semi-transparent ; the ivory is
yellowish-white, and has an appearance like satin.
2. The enamel, examined in fragments of the crown, exhibits fibres perpendicularly
implanted upon the ivory, and pressed closely to each other. The ivory, on the contra-
ry, is formed of concentric layers,* the fibres of which are generally parallel to the long
diameter of the tooth.
3. Both substances are excessively hard ; but in this respect the enamel is superior
to the ivory, for it will strike fire with steel, and is much less easily worn down by use ;
it can even turn the edge of a file. This excessive hardness, a principal element of im-
mutability, explains how the teeth are preserved uninjured as long as the enamel re-
mains entire, and, on the other hand, the facility with which they decay when once it
has been removed. The great brittleness of the enamel, which is one of its most char-
acteristic properties, is also owing to this extreme hardness.
4. In chemical composition, the enamel and ivory present important diflferences, indi-
cated in the following tables :
Ivory.
Enamel.
Phosphate of lime ...
61-95
Phosphate of lime ...
85-3
Fluate of lime ....
210
Fluate of lime ....
3-2
Carbonate of lime ...
5.30
Carbonate of lime
8-0
Phosphate of magnesia - -
1-25
Phosphate of magnesia
1-5
Soda and chloride of sodium
1-40
Membranes, soda and water
2-0
Cartilage and water ...
28-00
It follows, therefore, that the principal chemical distinction between these substances
depends on the existence of cartilage, that is, of an animal matter in the ivory, and on
its absence in the enamel. The presence of cartilage in ivory forms a trace of resem-
blance between this substance and bone ; and this is farther strengthened by the result
of the action of heat, by which both are similarly aifected. Between the true bones and
the ivory there is, however, all that diflference by which a living tissue is distinguished
from a solidified product of secretion. I admit, then, a complete want of vitality both in
the ivory and the enamel of the tooth ; nevertheless, there are some phenomena which
appear to contradict such an opinion.
1. The cortical substance of the tooth affords a much more perfect sensation of such
bodies as come in contact with it than either the nails or hair.
3. Weak acids, particularly vegetable acids, cause a peculiar sensation when they are
applied to the teeth, rendering the shghtest touch extremely painful ; a sensation gener-
ally expressed by saying that the teeth are set on edge.
But if, on the other hand, we reflect that the substance of the teeth is never affected
by inflammation, that it never becomes the seat of any tumour or diseased product, and
that it is worn away by rubbing and by the file, in the same way as an inorganic body,
without any attempt at reparation or any evidence of the existence of a nutritive pro-
cess, we must be led to admit the absence of vitality in these organs, and to explain the
foregoing facts as dependant simply upon transmission.
Lastly, the hardness, fragility, and mutability of the enamel and ivoiy vary in differ-
ent individuals ; hence the difference in the durability of the teeth, and their liability to
change. It must not be imagined that the ivory, when exposed, is susceptible of caries
or necrosis ; its changes are entirely of a chemical nature. The contrary opinion pre-
vailed only so long as the teeth were considered true bones, and yet it has exercised an
influence over the language of surgery which is not yet removed ; thus, we are in the
habit of speaking of a carious or necrosed tooth, and to describe them as affected with
exostosis, and even with spina ventosa.
It follows, from all that has been said, that the human teeth are simple, i. e., formed
by one centre of ivory covered with one layer of enamel. Compound teeth exist only in
herbivora, in which animals mastication consists of a most extensive grinding move-
ment ; nor are they met with except among the molar teeth. The characteristic feature
of a compound tooth is the division of the crown into a greater or smaller number of
lesser crowns, each of which consists of a centre of ivory covered by a layer of enamel.
All these crowns are united into one by a third substance, called the cement or crusta pe-
trosa, of which the tartar of the human teeth will afford a sufficiently good idea.t
* See not«, infra.
t tRecent researches into the structure of the teeth have brought so many interesting facts to light, that It
la necessary to notice the result of these discoveries.
DEVELOPMENT OF THE TEETH.
183
Development of the Teeth, or Odontogeny.
The study of the development of the teeth is one of the most interesting parts ol
their history. It embraces the description of the phenomena that precede, accompany,
and follow the eruption of the first and second sets of teeth.
First, Temporary, or Provisional Teeth.
Phenomena which precede their Eruption* — If the jaws of a foetus of two or three
months be examined, it will be seen that they are marked by a broad and deep groove,
divided by very thin septa into so many distinct sockets for the reception of the dental
germs. The alveolar groove is closed at its free border by the membrane of the gum,
which is stretched over a sort of thin, and, as it were, indented crest. This crest is
formed by a tissue to which some anatomists have given the name of dental cartilage ;
it is a pale, very strong fibrous tissue, and does not extend either upon the anterior or
posterior surface of the bone, which are only covered by the mucous membrane, the gum
being as yet confined to the alveolar border. The gingivjd fibrous tissue sends a pro-
longation into each alveolus (alveola-dental periosteum), that forms a fibro-mucous sac upon
Three different structures at least enter into the formation of the human teeth, viz., the ivory, the enamel,
and the cortical substance.
The ivory {a. Jig. 95) consists of a hard, transparent substance, traversed by numerous tubes, about -r^-^th
of a hne in diameter, which commence by open orifices at the cavity of the pulp, and extend in an undulating,
but nearly parallel direction, towards the surface of the ivory. In this course the tubes fig. 95.
present secondary and smaller undulations, undergo a dichotomous division, diminish in
size, at first gradually, then rapidly, give off numerous lateral twigs, and, finally, divide
into extremely minute ramifications, of which some anastomose together, others commu-
nicate with small irregular dilatations called calcigerous cells, situated in the transparent
inter-tubular substance, while the remainder appear to be lost at or near the surface of the
ivory. The cells and tubes both contain calcareous matter, and seem to be analogous to
the corpuscles of bone and the ramified lines radiating from them. In human teeth the
cells are very minute ; but in those of many animals they are much more distinct, and
present a striking analogfy to the osseous corpuscles.
The hard inter-tubular substance is not homogeneous, but, as may be clearly seen in
young and growing teeth, is comjxjsed of fibres arranged parallel to the tubes, which ap-
pear to have distinct parietes. It consists of animal tissue, combined with a large
amount of calcareous salts ; and it is the scat of by far the greater proportion of the
earthy matter contained in tlie ivory of the tooth.
The enamel {b,fig. 95) is composed of hexagonal and transversely striated fibres, about
x^th of aline in diameter, arranged parallel to each other, and applied by their internal
extremities to numerous corresponding depressions on the surface of the ivory, a delicate
intervening membrane serving to connect the two structures. Near the neck of the
tooth, the enamel fibres rest almost perpendicularly, near the apex of the cro\vn, more
or less obliquely upon the surface of the ivory ; moreover, they are often slightly waved
or curved. Previously to the eruption of the tooth, each fibre contains an appreciable
quantity of organic matter, which, at later periods, almost entirely disappears.
The cortical substance (c,fig. 95) consists of a thin osseous layer developed on the ex-
ternal surface of the fangs, and, as life advances, extending even into their interior, and
encroaching upon the cavity of the pulp. It differs in no essential particular from true
bone, containing the characteristic corpuscles, and anastomosing tubuli of that tissue.
It has been found, also, on the fangs of the teeth of most mammalia, and of a few reptiles
and fishes ; in some instances, direct communications have been discovered between the tubes of the ivory
and the cells and tubuli of the cortical substance. The cement, or crusta petrosa, existing on the crowns of
the compound teeth of the lower animals, also contains corpuscles and tubuli like those of bone, and may, per-
haps, be regarded as an analogous deposite to the preceding, differing from it only in situation.
From a perusal of the preceding summary, it will be seen that not only has much additional knowledge
been acquired regarding the structure of the teeth, but that many of the statements of M. Cruveilhier must
now undergo considerable modification. Thus, 1. The crusta petrosa bears no resemblance to the tartar of the
teeth, which is merely a deposite from the saliva. 2. Even simple teeth contain a third element in their struc-
ture, besides the ivory and enamel. 3. Instead of being inorganic Iwdies, the teeth are possessed of a complex
organization, which, we may add, is uniform throughout each species, and often sufficiently characteristic to
be of the highest utility to the zoologist, &c. 4. A remarkable affinity has been established between the
teeth and bone, as far as regards the structure of the cortical substance and the ivory.]
* [The earliest stage in the development of the teeth, described in the text, is that in which the dental pulps
are situated at the bottom of closed sacs ; it has long been familiar to anatomists, and is now called the saccu-
lar stage. A. condition antecedent to this, in which the future sacs are as yet open follicles, was first described
by Arnold, but we are indebted to Mr. Goodsir (Edin. Med. and Surg. Journ., No. cxxxviii.) for the following
connected history of the origin of the pulps and sacs of the temporary and permanent teeth :
Origin of the Pulps and Sacs of the Temporary Teeth. — In the upper jaw of a foetus, about the sixth week,
between the lip and a semicircular lobe constituting the early condition of the palate, is situated a denression of
the form of a horseshoe. During the seventh week, this begins to be divided by a ridge (commencing from
behind) into two grooves, of which the outer forms the recess between the lip andithe future external alveolar
process, while the inner constitutes the primitive dental groove. The mucous membrane along the floor of this
groove is then thickened, and from it a single papiUa is developed, and subsequently four others arise from the
external lip of the groove, in either half of the jaw. In the mean time, membranous laminie projecting from the
external lip, and at first only partially surrounding the papills, unite with similar but smaller processes from
the internal lip, so that each papilla (p, 3, Jig. 97) becomes enclosed in a separate follicle {/, S,Jig. 97), com
municating with the cavity of the mouth, and lined by its mucous membrane. The papilla now increase in
size, and gradually assuming the form of the future temporary teeih, sink within the yet open follicles. At
this period, the edges of the latter appear to be developed into opercula (0, 4, Jig- 97), which differ in number
and arrangement according to the shape of the crowns of the different teeth, there being two for the incisors,
three lur the canine, and four or five for the molars. The formation of the bony alveoli, by the development
of an external and internal alveolar process, and of inter-alveolar septa, closely follows the jireceding changes
in the soft parts.
The order and time of appearance of these ten papil';K in the upper jaw are as follow : F rst, those of the
184
ODONTOLOGY.
each follicle, perforated at the bottom of the socket for the passage of the dental vessels
and nerves. As these prolongations or sacs are intimately connected to the gingival
{Fig. 96, magnified three diameters.)
anterior temporary molars during the seventh week ; of the
canine teeth at the eighth ; of the central, and then of the lat-
eral incisors, about the ninth ; and in the tenth week those of
the posterior molars. The formation of the inter- follicular sep-
ta, and the other changes in the papillae, follicles, and alveolar
borders described above, proceed in the same order, and are
completed about the thirteenth week. The condition of the
tipper jaw at that period, constituting the end of the follicular
stage in the development of the temporary teeth, is seen in
Jig. 96, in which the follicles are shown as if held open ; the
diagrams 1 to 5 in_^g'. 97, representing perpendicular sections
across the jaw, may serve to illustrate the successive changes
in the mucous membrane, from the commencement of the
groove to the completion of the follicles.
During the fourteenth week, a small crescentic depression
(c, 5, Jig. 97) is formed immediately behind each of the folli-
cles, the mouths of which are now closed by their opercula,
but without adhesion ; the lips of the groove, -which at this time is called the secondary dental groove, are now
applied to each other (6, fig. 97). With the exception of the ten depressions just mentioned, and a small por-
tion situated beyond the posterior temporary molar follicle, adhesion of every part of the groove now takes
place, proceeding from before backward. The follicles are thus converted by the fifteenth week into shut
sacs is, T,fig. 97), while the enlarged papilla constitute the dental pulps (p, 7). The relation of the parts in
this, the saccular, stage in the development of the temporary teeth, is represented at 7, fig. 97.
Independently of a few subordinate differences, the changes in the lower jaw are similar, and occur in the
same order, each step in the process being somewhat later than the corresponding one in the upper.
Origin of the Pulps and Sacs of the Permanent Teeth.— It has been stated above, that during the general
adhesion of the dental groove occurring at the fifteenth week, the part posterior to the second temporary molar
follicle (in either half of the j-iw) still remains open ; in this situation, a papilla, sunk in an open follicle, ap-
pears'during the sixteenth week. At the twentieth, the fundus of this follicle is converted into a sac, and
the papilla into the pulp of the anterior permanent molar tooth, which is thus the earhest to appear of those
of the second set, and is farther characterized by being developed (like the papillae of the temporary teeth)
from the primitive dental groove, and on the same level with them. At the end of this week the hitherto open
portion of the groove is entirely closed by adhesion of its lips, but its walls still remain disunited, and a cavity
is thus formed, situated between the sac of the anterior permanent molar and the surface of the gum ; this is
the posterior cavity of reserve, from which the pulps and sacs of the second and third molars are subsequently
developed.
The ten depressions (c, 6) formed behind the follicles of the temporary teeth during the secondary condi-
f^W
i^
tion of the dental groove (6, fig. 97), in consequence of their escaping the general adhesion of its lips and sides,
Fig. 98. Fig. 98.*
are converted into as laany c#rities, called the anterior cav-
ities of reserve (c, 7), whfch gradually elongate and recede
into the substance of the gum. Pulps and folds (analogous
to the opercula of the temporary follicles) are developed
within them, appearing first in the anterior cavities ; and
they eventually become the sacs of the ten anterior perma-
nent teeth, assuming a position behind and above those of
the miUc teeth in the upper, and behind and below them in the lower jaw (see? to \%fig- 97 ; aXso fig. 98, and
a, figs. 101, 102), each occupying corresponding recesses {a, fig- 102) in the alveolar border.
At this time, owing to the great relative increase in the size of the dental sans, that of the anterior perma-
nent molar (a, i,fig- 98*) is forced backward and upward into the maxillary tuberosity of the upper, and intc
the coronoid process of the lower jaw (a 2) ; and the large posterior cavity of reserve (6 2) is drawn in the same
direction. At birth, the length of the alveolar border increases relatively, and this sac again sinks to a level
with those of the temporary teeth (o 3). The cavity of reserve (6 3), having now resumed its former poaitioc
DEVELOPMENT OP THE TEETH. 185
membrane, by pulling gently upon the latter we can raise the follicles from their recep-
tacles, and completely lay bare the alveoli.
The follicle or dental germ consists essentially of a membraiie, containing a sort of pe-
diculated papilla, known as the bulb or dental pulp.
1. The membrane of the follicle, after having clothed the sac just described as lining the
alveolus, is reflected upon the vessels and nerves which form the pedicle of the bulb, and
appears to be prolonged upon the bulb itself : this, however, has not yet been demon-
strated. The membrane of the follicle, therefore, resembles the serous membranes in
forming a shut sac, the inner surface of which is free and smooth, and the outer adhe-
rent. A transparent viscid fluid occupies the space between the bulb and the alveolar
portion of the membrane.
The following is the order in which the follicles of the first set of teeth appear. To-
wards the middle of the third month of foetal life there are four distinct follicles in each
jaw ; at the end of the third month a third follicle appears in each h£ilf of the jaw, and
a fourth and a fifth towards the end of the fourth month.
2. Of the dental bulb. In the earliest stages the membrane of the dental follicle only
contains a fluid, which is at first reddish, and afterward yellowish-white ; but towards the
third month a small body makes its appearance, rising as a papilla from the bottom of
the alveolus.* This papilla is abundantly suppUed with vessels and nerves, and pro-
gressively increases in firmness and in size. A very thin pedicle, consisting of the den-
tal vessels and nerves, affords attachment to it, so that it is suspended like a grape.
This papilla, dental bulb, or pulp, gradually acquires the characteristic form of some par-
ticular tooth, of which it presents an exact model, constituting the nucleus around which
the tooth itself is deposited. The first part developed upon this papilla is the crown of
the tooth, on which we already find indications of the various eminences and depressions
subsequently exhibited by it.
The development of the hard portion commences towards the middle of pregnancy.
The production of the ossiform matter upon the surface of the bulb is eflfected by a pro-
cess of secretion ;+ it begins by the deposition of some small laminae, or very delicate
scales {I, Jig. 99), upon each projection of the pulp : they are at first pUable and elastic,
but gradually become more consistent. These laminae or scales constitute so many
formative points for the tooth, and have been compared to the points of ossification in
bones. The incisor and canine teeth have only one scale ; the bicuspides have two,
and the great molares as many as there are tubercles. These small scales so intimate-
ly embrace the pulp upon which they are moulded, that it requires some force to detach
them ; and yet their inner surface, as well as the outer, is very smooth. It should be
remarked, that the pulp has a much more vividly red colour at the points covered by the
scales. The scales are visible in the lower jaw at an earlier period than in the upper.
The following is the order in which they appear : the middle incisors are visible from
the fourth to the fifth month ; they are soon followed, 1 . By the lateral incisors. 2. By
the first or anterior molar, which appears from the fifth to the sixth month. 3. At a short
and shape, elongates backward, and a pulp is developed in its fundus, -whicli is converted before the fourth
year into the sac of the second permanent molar. About the sixth or seventh year, the remaining part of the
cavity once more elongates backward, and forms the pulp and sac of the third permanent molar, or wisdom
tooth. Each of these sacs undergoes changes in its relative position in the jaws, similar to those experienced
by the anterior permanent molar, at first receding backward and upward, and then descending behind, and on
a level with the sac immediately anterior to it.
From the preceding observations, it follows that the palps and sacs of both the temporary and permanent
teeth have a common origin from the gastro-intestinal mucous membrane ; that a papilla is first formed, after-
ward surrounded by and sunk into a follicle, which latter is then converted into a closed sac ; and hence the
origin of the terms papillary follicular, and saccular, applied to these several conditions.
It moreover appears that all the temporary teeth, and also the anterior permanent molar, originate from the
primitive dental groove ; and that all the permanent teeth, except the anterior molar, are developed from cav-
ities of resen-e commenced during its secondary condition.
For an account of the changes occurring in the pulps aud sacs of the two sets of teeth during the saccular
and eruptive stages, the reader may now refer to the text, remembering, however, that the term follicle is there
applied to the entire dental germ in its saccular condition, consisting of a closed sac and its contained pulp.]
* [The papilla of a temporary tooth appears even before the formation of the open follicle, and therefore
long prior to its conversion into a shut sac. (See note, p. 183.)]
t [The ivory is no longer regarded, by the best authorities, as a secretion from the surface of the dental
pulp, nor the enamel as a similar product from the parietal layer of the lining membrane of the sac. A micro-
scopic examination of these two structures in their perfect condition is, indeed, alone sufficient to throw con-
siderable doubt on the old opinion adopted in the text. The researches of Schwann into their mode of devel-
op-oient have again elucidated the subject. It has been observed that the globules in the centre of the dental
pulp are primitive nucleated cells, analogous to those found in the early condition of all organic tissues ; that
at the surface of the pulp these cells assuro« a cylindrical form and a perpendicular arrangement, but still con-
tain nuclei ; that they adhere in places to the ossified scales, and correspond in size (not to the tubuli) but, to
the fibres of the inter-tubular substance in a growing tooth. From these facts Schwann concludes that th«
formation of the ivory, likethat of all other organized tissues, is effected by a metamorphosis of primitive nu
cleated cells ; in other words, that it is developed by a progressive transformation and ossification of the superfi-
cial cells of the dental pulp — a theory which recent observations in Great Britain would seem to have confirmed.
Similar evidence is advanced by him to prove that the enamel is formed in a similar manner from the pulp^y
enamel membrane, occupying the upper portion of the sac. The hexagonal fibres, of which the surface of this
membrane consists, are, in fact, prismatic, nucleated cells, resting perpendicularly on a tissue, in which are
other cells of a vesicular form. The hexagonal fibres correspond, therefore, both in form and direction, with
those of the perfect enamel ; and, moreover, they are found to agree in size with the membranous remains of
the enamel fibres of a growing tooth, after the removal of their earthy matter by means of a dilute acid.]
Aa
186
ODONTOLOGY.
interval from each other, by the canine and the second molar : the scales of all the teeth
of the first set have made their appearance by the seventh month, according to the ob-
servations of Meckel ; but at the eighth month, according to Blake.
As development advances the scales enlarge, and gradually uniting (2, fig. 99), form a
sheath or shell of ivory, which, during its growth, encloses the pulp, and, by degrees, ex-
tends to the vascular and nervous pedicle at the part where it penetrates the alveolus.*
The outermost sheath being formed, a second is deposited within it, then a third within
that, and so on. The external surface of the bulb secretes the ivory. The enamel is
formed from the parietal or alveolar layer of the follicular membrane : at the commence-
ment of its formation it is so soft that, in a foetus at the full time, it can be very easily
separated from the ivory. It has been asserted by some that the enamel, as well as the
ivory, is the product of a secretion from the bulb, from which it has transuded in a liquid
state through the different layers of the ivory, and has then solidified upon its surface ;
others affirm that the enamel is a sort of crystalline deposite from the fluid surrounding
the tooth ; but the greater number of anatomists admit, with Hunter, that the enamel is
a product of secretion from the parietal layer,! as the ivory is from the layer of the fol-
licular membrane, reflected upon the bulb. This opinion appears to me the more proba-
ble, because, on examining with attention the parietal layer, we find on its inner sur-
face, near the crown of the tooth, a sort of pulp, or very evident enlargement, particular-
ly in the follicles of the molar teeth. This external pulp becomes atrophied as soon as
the enamel is formed ; and hence the fang is not covered with enamel, although, after
the eruption of the tooth, that part occupies the former position of the crown. This ex-
ternal pulp does not exist in some of the dental follicles of certain animals, and we can-
not, therefore, be astonished that such teeth have no enamel. Lastly, when this ex-
ternal pulp remains after the eruption of the teeth, the secretion of the enamel also con-
tinues, like that of the ivory. This is the case with the incisors of the rabbit and the
beaver. In these animals the enamel occupies only the anterior surface of the tooth ;
consequently, the edge alw&ys remains sharp, from the unequal wearing of the anterior
and posterior surfaces.
From what has been said concerning the phenomena of the formation of the pro vision-
ary teeth before their eruption, we may draw the following conclusions : 1 . Of the two
constituent parts of a tooth, viz., the corticle or hard portion, and the medullary portion
or pulp, the latter is first developed ; and of the two distinct elements of the hard por-
tion, viz., the ivory and the enamel, the formation of the ivory is first commenced. 2.
The deposition of the cortical substance of the tooth begins at the crown ; the roots are
not formed until a subsequent period. 3. The bulb being enclosed within the solidified
products which it has furnished, diminishes gradually in size as these press upon it.
Phenomena which accompany the Eru-ption of the First or Temporary Teeth. — At the time
of birth all the teeth are still contained within their alveoli. Exceptions to this rule
have been met with in cases where infants have been born with one or two teeth. If
the anterior wall of the alveoli be removed at this time, the teeth will already be found
considerably, but unequally developed, none having yet reached the bottom of the socket.
But after birth, and at periods to be presently indicated, the extremity of the root having
reached the bottom of the alveolus, and the farther growth of the tooth in that direction
being impossible, it is effected in the direction of the gum, which is compressed, becomes
inflamed, and is perforated ; this perforation, however, is not exclusively the result of
distension, for the gum is but very slightly stretched when it opens ; and in other cases
where it is greatly distended, as by polypi or other tumours, it is not lacerated at all.
The tooth gradually rises, and the gum moulds itself successively upon the different
portions of the crown, and, lastly, upon the neck of the tooth. The division of the gum
is a severe process, but still it cannot altogether explain those serious symptoms which
frequently accompany the first dentition.
The eruption of the teeth does not take place simultaneously, but in succession, and
in a regular order that admits of but few exceptions. 1. The teeth of the same kind ap-
pear in pairs, one on the right side, the other on the left ; 2. The teeth of the lower jaw
* [The vascular pulp of either a temporary or permanent tooth having more than one fang is, after tho
formation of the crown, divided into as many processes by the advancement into it of the gray membrane of
the sac. The dental substance still continuing to be produced on every part of the surface of the divided pulp.,
abridge of ivory is thus formed across the area of the cavity of the tooth between each process (3, 4,jf^. 99),
(Ft^. 99.)
around which separate fangs are subsequently developed (5, 6, 7), in the same mannpr ns that around the niK
divided pulp of an incisor tooth.] ■• See note, p. 184.
DEVELOPMENT OF THE 'JEETH.
precede those of the upper in their appearance ;* 3. The middle incisors are cut before
the lateral, these before the first molars ; after these come the canine, and then the sec-
ond molars. The eruption of the first set of teeth commences towards the sixth month
after birth, and terminates at the end of the third or the commencement of the fourth
year. The middle lower incisors appear from the fourth to the tenth month, and, soon
afterward, the upper middle incisors ; the inferior lateral incisors appear from the eighth
to the sixteenth month, and then the superior lateral incisors. The first lower molars
are cut from the fifteenth to the twenty-fourth month ; the lower canine from the twen-
tieth to the thirtieth ; and the upper first molars and canine soon afterward. In some
cases the eruption of the canine and the first molar teeth takes place simultaneously ;
sometimes even the canine teeth take the precedence. The second great molars appear
from the twenty-eighth to the fortieth month, and thus complete the twenty teeth of the
first set.
Second or Permanent Teeth.
Phenomena which precede the Eruption.i — The second dentition consists of the eruption
of the teeth called permanent, to distinguish them from the temporary teeth. They are
thirty-two in number, so that there are twelve additional teeth in the second set. In
this dentition, as in the former, we have to study the phenomena which precede, ac-
company, and follow the eruption of the teeth.
The follicles or germs of the second set of teeth correspond to the row of teeth already
formed, bony septa intervening between them. They have the following relations with
the follicles of the provisionary teeth : 1. The follicles of the additional teeth in the sec-
ond set, viz., the last three molars, are situated in the same curve as the milk teeth, but
they occupy, of necessity, the lateral extremities of these curves {Jig. 100). 2. The fol-
licles of those teeth of the second set that replace others of the first are, on the contrary,
situated precisely behind the teeth to which they correspond {a, Jigs. 100, 101, 102).
These follicles are at first contained in the same alveoli as the temporary teeth ; but.
after a certain time, septa are grad- Fig. lOO.
ually formed between them, pro- _.^— -—f
ceeding from the bottom of each
alveolus towards its orifice (Jigs.
101, 102). Nevertheless, for a long
time after the formation of these
septa, the temporary (a"" a", Jig. 102)
and the permanent ("b ^b) alveoli
communicate by tolerably large or-
ifices (c' c',Jigs. 101, 102), through
which proceed the cords (c. Jig.
102) connecting the two teeth. The
follicles of the permanent teeth do not sensibly difier in their mode of development from
those of the provisionary teeth, only the increase of the vascular system of the former
coincides with the progressive atrophy of the vessels of the latter.
Phenomena which accompany their Eruption. — As long as the development of the per-
manent teeth can be efiected in a direction towards the bottom of their sockets, the tem-
porary teeth remain uninjured ; but when the growth of the permanent teeth influences
their upper edges, the alveoli of the first set are compressed, and afterward destroyed at
the parts corresponding to the crowns of the permanent teeth Fig. 101.
(see^^. 101). After this time the alveoli of the first and sec-
ond sets form common cavities : the roots of the milk teeth
being compressed by the crown of the permanent teeth, under-
go a loss of substance, become loosened, and may be detached
by the slightest effort, each tooth being retained in its place
only by the sort of ring formed by the gum around its neck.
The shedding of the milk teeth is not always effected in the
way we have described, viz., by a previous destruction of their
root. Sometimes, in fact, the permanent tooth does not pen-
etrate into the alveolus of the corresponding milk tooth ; but
this alveolus is gradually wasted away by the constantly in-
creasing development of the neighbouring permanent socket,
teeth may fall without destruction of their roots, which, however, are then almost always
slender, and, as it were, atrophied. Some compression, either exercised upon the pa-
rieties of the temporary sockets, or upon the roots of the milk teeth, is almost indispen-
sable for their expulsion. When, in fact, the permanent tooth deviates from its natural
direfction, and, consequently, does not press upon the milk tooth, this latter remains, and
forms a supernumerary tooth. We cannot, then, doubt the influence of this compression
upon the fall of the milk teeth ; but anatomists are not agreed as to the immediate cause
of the destruction of the temporary alveoli, and of the roots of the teeth contained within
* [Although the papillae, it wiU be rememliered, appear earlier in the upper jaw.] t See note, p. 183,
In this case, the milk
188
ODONTOLOGY.
them. How does this compression act 1 Does it produce the fall of the milk teeth in a
purely mechanical manner, or does it effect this indirectly by the destruction of the den-
tal vessels and nerves 1 One author believes the latter to be the principal cause ; but
what we have already said regarding the want of vitality in the teeth will abundantly
prove that the wearing away of the alveolus and the milk tooth is the result of mechan-
ical pressure.
At the same time it should be observed, that, since the destruction of the roots of the
milk teeth leaves no debris, a process of absorption must, therefore, be performed, the ex-
citing cause of which is, undoubtedly, the compression above alluded to. It is not neces-
sary, as some authors have believed, to assume the existence of a peculiar absorbent ap-
paratus, appropriated to this office.
The teeth of the first dentition are shed in the space comprised between the sixth and
j^ JQ2 the eighth year, the fall of each tooth
taking place in the same order as its ap-
Kr'i^N ' ^1^ /\ pearance. Blake was the first to point
out the existence of a cord (c. Jig. 102)
passing from the follicle of the perma-
nent tooth, along a small, long canal (c'
c'), behind the alveolus of the milk tooth,
and becoming continuous with the gum.
It has been supposed that the canal, and
the cord placed within it, were intended
to direct the tooth during the progress
of its eruption. Hence the name of iter
dentis given to the canal, and guhernac-
ulum dentis applied to the cord, which
has been ingeniously compared by M.
Serres to the gubernaculum testis. This
cord appears to me to be solid,* not hollow ; it is very well marked in the incisor teeth,
but forms a mere thread in the molars. Upon the whole, the influence exerted by the
iter dentis and gubernaculum upon the direction of the permanent teeth during its erup-
tion is by no means constant.
Order of Eruption. — The first permanent teeth which appear are the first great molars ;
they precede the other permanent teeth by a considerable interval, and immediately suc-
ceed the milk teeth, coexisting with them for some time ; they have been, therefore, im-
properly classed among the first set of teeth in some anatomical treatises. The first
great molars are known by the vulgar name of seven years' teeth. The eruption of the
permanent teeth takes place in the same order as that of the milk teeth. Below are sta-
ted the periods at which each pair are protruded :
Middle lower incisors from
Middle upper incisors .... . . "
Lateral incisors . •. "
First small molar "
Canine teeth "
Second small molar "
Second great molar "
Third great molar "
The greatest irregularity exists in the eruption of this last molar tooth, which is often
wanting, and frequently remains, during the whole of life, either partially or entirely en-
closed within the substance of the jaw.
The incisor and canine teeth of the second set are much larger than the corresponding
milk teeth. The opposite is the case with regard to the first two permanent molars, viz.,
the small molars, or bicuspides. It was ascertained by the inquiries of Hunter, that, in
this way, there is such a compensation, that the twenty teeth of the first set occupy pre-
cisely the same space as the twenty corresponding teeth of the second. This is not a
purely speculative question, but one of singular interest in relation to the practice of ex-
tracting the milk teeth. The truth of Hunter's assertion may be confirmed by measuring
with a thread the space occupied by the twenty temporary teeth, and comparing it with
the space occupied by the corresponding teeth of the second set. M. Delabarre has
done this upon the same individual at the period of the two dentitions.
Plienomena which follow the Eruption of the Permanent Teeth. — These relate, 1. To their
growth ; 2. To their decadence.
1. Growth of the Teeth. — ^The teeth of man are not, like those of some animals, the ro-
dentia in particular, susceptible of unlimited growth. The enamel of the crown wears
away without ever being reproduced. All the facts brought forward in support of the idea
of its reproduction are either erroneous observations, or may be interpreted in a different
manner. Nevertheless, some changes take place in the interior of the tooth which are
worthy of notice. New layers of ivory continue to be secreted; &nO the cavity of the
* [Arising from the adhesion of the sides of the elongated part of the cavity of resene.l
6 to
8 years
7 "
9
8 "
10
9 "
11
10 "
12
11 "
13
12 "
14
28 "
30
DEVELOPMENT OF THE TEETH. 199
tooth is gradually encroached upon, and finally obliterated. Thus the teeth of the aged
have neither pulp nor dental cavity.
2. Decadence of the Teeth. — The fall of the teeth in aged persons is the effect of a con-
traction of the alveoli, produced in the following manner : The teeth are dependances of
the buccal mucous membrane, and are, as it were, only accidentally placed in the alveo-
lar borders, which, from the tonicity or elasticity of their bony tissue, have a constant ten-
dency to displace them. In one word, the tooth is to the alveolus like a foreign body, of
which it is incessantly tending to free itself This tendency to contract on the part of
the alveolus is effectually resisted, so long as the root of the tooth has a tendency to in-
crease towards the bottom of the socket ; but it acts with full force when this resistance
ceases in consequence of atrophy of the pulp. Then the alveolus, shrinking upon it-
self, expels the tooth by a mechanism similar to that by which, during the progress of
syphilitic affections, the most healthy-looking teeth are displaced, solely in consequence
of the vitality of the pulp being destroyed by the influence of the virus.
The fall of the teeth in the aged is regulated by no law, either as regards the time or
the order in which it is effected.
Differences between the First and Second Sets of Teeth. — The teeth of the first dentition
are distinguished from those of the second by the following characters : 1 . Their colour,
instead of being white, like ivory, or clear yellow, is of a bluish or azure white hue. 2.
The temporary incisor and canine teeth are always distinguished from the corresponding
permanent teeth by their smaller size and the shortness of their roots. 3. The two mo-
lars of the first set differ from the two small permanent molars or bicuspids which take
their place, and approach nearer in character to the great molars ; from these, however,
they are distinguished, by the shortness of their crowns, and by the number of tubercles
on them, viz., five ; three on the outside, and two on the inside. 4. Comparative chem-
ical analyses of the teeth of the two sets have shown that the milk teeth contain some-
what less phosphate of lime than the permanent, and to this circumstance their greater
susceptibility of change is due.
General Observations. — From the description we have given of the teeth, it will be seen
that these organs should be looked upon merely as large vascular and nervous papillae,
covered by an unorganized calcareous sheath, which is formed by a species of crystalli-
zation.* The diseases of the teeth offer nothing incompatible with this theory, for, with
the exception of toothache, and the sensation of being set on edge, which are evidently
seated in the pulp, the other alterations of which the teeth are susceptible are either me-
chanical lesions, such as splitting, cracking, wearing, &c., or chemical changes, as the
dry or moist caries, or, lastly, alterations appearing to have their seat in the hard sub-
stance of the tooth, but which are really situated elsewhere. Of this nature are the in-
crustations with tartar, the product of a vitiated secretion, attributed by several anato-
mists, and especially by M. Serres, to some small follicles, the function of which, before
the eruption of the teeth, is to produce a fluid to soften the gum preparatory to its perfo-
ration by the teeth. Again, exostosis and spina ventosa of the teeth evidently depend
upon irregular secretion of the enamel and ivory. The consolidation of fractures of the
teeth is explained by the formation of new layers, resembling those which have been
seen surrounding bullets in the substance of an elephant's tusk. Lastly, the coloration
of the teeth, from the action of madder, is only observed in the layers deposited during
its use, and therefore does not prove the existence of any nutritive process in these or-
gans, such as takes place in bone.
With regard to the evolution of the teeth in two distinct sets, it may be inquired what
is the object of such an arrangement. Without entering here into the discussion of final
causes, it cannot be denied that the second set of teeth would not accord with the com-
paratively small size of the jaws in the foetus.
Use. — 1. The teeth are the immediate agents of mastication. The incisors cut, the
canine tear, and the molars grind the food, the position of each being regulated by the
resistance they have to overcome. 2. The teeth form a kind of elevated border, which
prevents the constant escape of saliva from the mouth. 3. They assist in rendering
sounds articulate, by affording a fixed point to the tongue in the pronunciation of certain
consonants, called by grammarians dental. 4. The teeth furnish important characters
for zoological classifications. Indeed, as they bear a necessary relation to the mode of
feeding in different animals, a circumstance that exercises so great an influence over
their entire organization, it may easily be conceived that the fonn of the teeth is, to a
certain extent, one of the characters by which a summary idea is conveyed of the nature
of that organization. At the same time, it is necessary to guard against the evidently
erroneous conclusions which some philosophers have delighted in deducing from the ar-
rangement of the dental apparatus in man with regard to his fitness for a purely animal
or exclusively vegetable diet. Above all, it should be remembered that the mechanical
mgenuity of mankind must always form an indispensable element in the solution of every
problem of this nature.
* [It is necessary, in some degree, to modify this definition of the hard portion of the teeth, which, though
extra-vascular, and, on that account, probably subject neither to interstitial absorption nor nutrition, cannot
be regarded with propriety as unorganized or crystalline bodies.
190 MYOLOGY.
MYOLOGY.
The Muscles in general. — Nomenclature. — Number. — Volume and Substance. — Figure. — Di-
rection.— Relations. — Attachments. — Structure. — Uses. — Preparation. — Order of Descrip-
tion.
The active organs of locomotion are called muscles.* They are composed of bundles
of red or reddish fibres, consisting of fibrin as their basis, and possessing the essential
property of contractility, that is, the power of contracting or shortening upon the applica-
tion of a stimulus, t
JVomenclature of Muscles
The names applied to the various muscles have not been founded upon uniform prin-
ciple. Before the time of Sylvius the muscles of any region (of the thigh, for example)
were designated numerically, first, second, &c., in the order of their super-position or of
their uses. Sylvius first gave particular names to the greater number of the muscles ;
and he was followed by almost all succeeding anatomists, especially by Riolanus. In
this nomenclature, which is still generally adopted, the names of the muscles are deri-
ved, 1. From their situation, as radialis, ulnaris, peroneus, &c. ; 2. From their size, as
glutaeus maximus, minimus ; palmaris longus, brevis, &c. ; 3. From their direction, £is
rectus abdominis, obliqui capitis ; 4. From their shape, which is generally an imperfect
representation, either of certain geometric figures, as rhomboideus, pyramidalis, and sca-
lenus, or of well-known objects, as deltoideus, lumbrici, and soleus (from solca, the sole
fish) ; 5. From their divisions or complications, as digastricus (from having two bellies),
triceps (from having three heads), biceps, complexus, &c. ; 6. From their insertions, as
stemo-hyoid, stemo-thyroid, &c. ; 7. From their uses, as flexors, abductors, &c.
In modem times many attempts have been made to substitute in the place of these
vague and generally arbitrary denominations, a uniform nomenclature, derived from the
most important consideration, viz., the attachment of the muscles. The nomenclature
of Chaussier, however, which is undoubtedly superior to all others, has not been adopt-
ed ; first, because a knowledge of the old names cannot be neglected, since they are the
only ones employed in a great number of works on medicine and surgery ; and, second-
ly, because even the most imperfect denominations, when they have been long in use,
are, from this circumstance edone, preferable to any new appellations.
JVumber of the Muscles.
Upon this point, likewise, authors are but little agreed. According to most, the num-
ber of muscles is four hundred. Chaussier reduced it to three hundred. These differ-
ences arise partly from the fact that the natural limits of the different muscles are not
so well marked as those of the bones, for example, and partly because the grounds of de-
marcation between the various muscles have not been sufficiently established. The fol-
lowing rules may be adopted with advantage : 1. When a number of fasciculi unite, and
form a mass, which is isolated both in its body and at its extremities, and fulfils distinct
and determinate uses, such a collection should be considered a separate muscle. 2. A
muscle should also be regarded as distinct when it is separated from others at one por-
tion only of its body, and at the most movable of its attachments. On the whole, what-
ever be the mode of demarcation adopted, it will be seen that the number of the muscles
greatly exceeds that of the bones ; the reason of this is, that each bone acts as a lever
in a great variety of movements, while each muscle acts only in a very limited number
of motions.
Volume and Substance of the Muscular System.
Of all the systems of organs in the body, the muscular is predominant both in substance
and in volume. This great mass of muscular apparatus is a necessary consequence of
the unfavourable position of most of the levers represented by the bones. There is very
great variety in different individuals, as regards both the volume and substance of the
muscular system. Compare, in this respect, the glutaeus maximus of a robust man, and
the same muscle in a thin, nervous individual, much emaciated, but yet in perfect health,
for still greater differences are produced by disease : size and strength of the muscular
system may also be natural or acquired, partial or general. Partial preponderance is
most usuEdly acquired, and is commonly the result of exercise. To be convinced of this,
it is only necessary to inspect the muscles of certain regions, in individuals whose em-
ployment requires the special exercise of those parts. The preponderance of the mus-
cles on the right side is produced solely by the habit of using this side more than the
other ; it is not, as has been alleged, the result of congenital difference.
Lastly, the size of one or the other region of the muscular system, in different anim£ils,
* From nvi)V, a muscle, or /itij, a mouse.
t It will be seen that, in constructing this definition, the only object has been to distinguish the muscles gen
erally from other orgaas, by pointing out their two characteristic properties, viz., their fibrinous comnosition
■ad their contractility.
FIGURE AND DIRECTION OF THE MUSCLES. 191
is in relation either with their instinctive propensities, their mode of feeding, or their
natural attitude, or with some other important peculiarity in their organization. Hence
we find, 1. In the lion, the tiger, and other carnivorous animals that tear their prey in
pieces, the muscles connected with the inferior maxiUa, the most highly developed ; 2.
In the bear, which is a climbing animal, the muscles of the back ; 3. In the hare, whose
mode of progression is by successive leaps, the muscles of the hind limbs ; 4. The mus
cles of the wing in birds ; and, 5. Those of the lower extremities and the vertebral grooves
in man, to whom the erect position is peculiar
Figure of the Muscles.
The figure of the muscles is determined upon the foUoviing data : 1. From a compari-
son of them with geometric figures or with famihar objects. 2. From the respective ar-
rangement of their surfaces, edges, and angles. 3. From their being symmetrical or
otherwise. In this latter respect there is a remarkable difference between the osseous
and the muscular systems : many bones are symmetrical, or azygos, while almost all the
muscles, on the contrary, are asymmetrical, and arranged in pairs. 4. From the relative
proportion between their three dimensions ; from this latter consideration, muscles have
been divided into three classes, viz., long, broad, and short, concerning each of which we
shall make some general remarks.
The long muscles are chiefly met with in the limbs. Their length is sometimes con-
siderable ; and the longest are always most superficial. Very long muscles generally
pass over several articulations, and can therefore assist in moving them all. This great
length of certain muscles has also another advantage, viz., that it enables them to obtain
a fixed point of attachment upon a less movable part, as the trunk, from which they can
then act upon the more mobile parts : such is the case with the muscles that move the
thigh or the leg. Long muscles are either simple or divided. Sometimes the division
occurs at the more movable attachment ; sometimes at that which is habitually fixed.
The broad muscles occupy the pjirietes of cavities ; they are quadrilateral when all their
points of attachment are on the trunk, and triangular when they extend from the trunk
to the extremities. When several broad muscles are super-imposed, the fibres of one
always cross those of another at an angle ; and this arrangement, by forming a sort of
interweaving, greatly augments the strength of the parietes which they assist in forming.
This is particularly well shown in the broad muscles of the abdomen.
The short muscles are generally met with in the same situations as the short bones.
It is not the shortness of its fibres, but of its fleshy body that characterizes a short mus-
cle. It is important to notice, with regard to these muscles, that a number of them are
often arranged in succession, so as to resemble a long muscle. Of this we shall find
many examples in the muscles of the vertebral grooves.
Direction of the Muscles.
The direction of the muscles is one of the most important points in their history, since,
without a knowledge of this, it is impossible to appreciate their uses. Each muscle has
an axis or middle line, in which the general action of its fibres takes effect. Few mus-
cles are altogether rectilinear ; most are angular or curved ; and almost all undergo cer-
tain deviations or reflections in passing round the joints : some, indeed, take a direction
at right angles to their primitive course, when they pass over pulleys or hook-like pro-
cesses. In muscles of this kind the action is in the direction of the reflected portion.
The direction of muscles must be studied with reference to the axis of the body, but
especially to the axis of the limb or lever, in relation to which they represent the moving
power. Many muscles are almost parallel to the axis of the lever upon which they act ;
but it should also be remarked that, in certain positions, these same muscles form great-
er or smaller angles with their corresponding levers, and may even become perpendicu-
lar to them. In this respect the direction of the muscles is not absolute, but is subordi-
nate to the position of the levers.
Some muscles are constantly perpendicular to the levers upon which they act.
The angles of incidence of the muscles upon their points of attachments are very va-
riable, but generally they are more nearly parallel than perpendicular to those points.
As the axis of a muscle is not the same as that of its component fibres, it is necessary to
study, in each muscle, not only the direction of the fleshy beUy, but that of the fibres also.
Relations or Connexions of the Muscles.
In reference to surgery, the relations or connexions of the muscles are among the
most important circumstances in their history.
Relations of the Muscles to the Skin. — Those muscles only which are called cutaneous
are immediately connected with the skin ; the remainder are separated from it by apo-
neuroses of greater or less density, so that the skin does not participate in the move-
ments of the m.uscles, and vice versa. Nevertheless, the changes produced in the form
and size of the muscles during their contraction are so decided, that those which lie
near the surface are more or less defined through the integuments ; but the projections
192 MYOLOGY.
corresponding to the bodies of the muscles and the depressions at their attachments
are, in a measure, obliterated by adipose tissue, the quantity of which varies in the two
sexes and in different individuals. To this latter circumstance are due the differences
in the outward characters of the muscular system of the female, as compared with the
male ; and of a fat individual, as compared with the one who is emaciated.
Relations of the Muscles to the Bancs. — In the limbs where the muscles form several par-
allel layers around the bones, the belly or thickest part of the muscle always corresponds
with the shaft or most slender portion of the bone ; while the ends of the muscle, where
it is thinnest, correspond with the expanded extremities of the bone. The relations of
the bones with the muscles vary, according as the latter are deep-seated or superficial.
The superficial are only in contact with the bones by their extremities or their tendons
the deep-seated muscles alone correspond to the bones by their entire length.
Relations of the Muscles to each other. — The muscles are arranged upon each other in
successive layers ; each muscle is covered by a sort of fibro-cellular sheath ; and a loose
and moist cellular tissue is interposed between the different sheaths, so as to facilitate
the gliding movement and independent contraction of each muscle. This isolation of
the muscles does not exist throughout their entire length ; several are often blended
together in one conunon insertion, from which they proceed as from a centre, afterward
separating from each other. This community of attachment is principally observed in
those muscles that perform analogous offices, or that, usually at least, act simultaneously.
Most muscles are enclosed in a separate fibrous sheath, which isolates them in their
actions, and also in their diseases. Of this we shall find remarkable examples in the
rectus abdominis and sartorius. With regard to the relations of their edges, the muscles
are sometimes contiguous throughout their entire course, and sometimes separated by
intervals, generally of a triangular figure ; and principally important in surgical anatomy,
because incisions, for the exposure of vessels, are almost always made in such intervals.
Relations of Muscles to the Vessels and Nerves. — The muscles serve to protect the ves-
sels and nerves, not only in consequence of the thickness of the layers which they form
in front of them, but also by the resistance they oppose during their contraction to ex-
ternal violence. Near the centre of a limb there is generally a considerable cellular in-
terval between the muscular layers, which is intended for the principal vessels and nerves.
The existence of such spaces prevents the injury which these vital parts would sustain
from compression during the contraction of the muscles. It is also worthy of notice,
that whenever a vessel passes through the body of a muscle, we find an aponeurotic arch
or ring, which is non-contractile, and in some degree, therefore, obviates the danger of
compression during the action of the muscular fibres. I say in some degree, because,
in order to render compression of the vessels impossible, the muscular fibres attached to
these rings must have proceeded from them as from a centre, diverging in all directions.
In this case, the action 5f the muscles would not change the form of the rings, but would
tend to increase their diameters in every direction. It is found, however, that they are
invariably elongated in one direction and diminished in another, when the fibres of the
muscle contract. Bernouilli, indeed, has shown that it is impossible to change the form
of a circle, by making one of its diameters greater than the others, without, at the same
time, diminishing its capacity ; because, within a given periphery, the most regular fig-
ures have the greatest capacity, and the circle is more regular than either the oval or
the ellipse. On the whole, however, it must be understood that the contraction of the
fibrous rings does not, in any material degree, impede the circulation.
It should also be remarked, that a distinct fibrous sheath surrounds the vessels and
the nerves, serving to isolate and protect them amid the various muscles by which they
are surrounded.
Most of the arteries have accompanying muscles, which may be called their respective
satellites : thus, the sartorius is the satellite muscle of the femoral artery, the biceps of
the brachial, the stemo-mastoid of the carotid, &c.
Attachments or Insertions of Muscles.
The attachments or insertions of muscles constitute one of the most important points in
their history, and one which requires to be studied with the greatest care, because the
uses of a muscle can be determined from a knowledge of its insertions alone. These
insertions should be considered in two points of view : 1. As to the direct insertion of
the muscular fibres into the tendons, aponeuroses, or other structures ; 2. As to the in-
sertion of the tendons and aponeuroses into the levers represented by the osseous system.
The muscular fibres themselves are attached, 1. To the skin, of which mode there are
numerous examples in the muscles of the face ; 2. To other muscular fibres, as in many
muscles of the face and of the tongue ; 3. To cartilages, as in several of the muscles of
the chest and larynx ; 4. To aponeuroses, of which they act as tensors, and whose power
of resistance they thereby increase; lastly, to tendons or aponeuroses,* that are them-
selves attached to the bones.
The fleshy fibres are inserted into, or become continuous with, the tendons and apo-
* [The tendons afford examples of the fascicular form of fibrous tissue, for a notice of which see note, tn/jd.)
ATTACHMENTS AND STRUCTURE OF MUSCLES. 193
neuroses in the following manner : Tlie tendon is prolonged under the form of a mem-
brane, either upon the surface or in the substance of the muscle. The results of this
arrangement are, 1 . An increase of surface for the attachment of the muscular fibres,
which the tendon gathers up, as it were, in order to concentrate their efforts upon one
point ; 2. An obliquity in the insertion of the fibres, in reference to the axis of the entire
muscle, by which the direction of the power is represented. It may easily be conceiv-
ed that this obliquity is of the greatest interest as regards the dynamic relations or ac-
tive property of the muscles.*
One of the most curious circumstances respecting the continuity of a tendon or an
aponeurosis with a muscle is the very intimate union between the muscular and fibrous
tissues, which is so complete that they are scarcely ever separated by external violence,
which, moreover, tends to lacerate the muscle rather than the tendinous fibres.
It is a fact worthy of notice, and one which we have already had frequent occasion to
remark, that the adhesion of any two organic tissues is stronger than the respective co-
hesion of each ; so that the tissues themselves will sooner break than admit of separa-
tion from one another.
Insertion of the Aponeuroses and Tendons into the Bones. — A tendon or an aponeurosis
forms a species of ligament, by means of which the action of a very large muscle is
transmitted to the lever intended to be moved, by a fibrous cord or aponeurotic lamina
of small size. A great advantage arises from this mode of economizing the extent of
bony surface required for muscular attachments ; for, notwithstanding the extent of
surface afforded by the expanded ends of the bones, and by the eminences and ridges
with which they are covered, it would be evidently insufficient, were the muscular fibres
to be directly attached.
The existence of tendons and aponeuroses produces also this remarkable result, viz.,
that the muscular insertions are much stronger than they would otherwise have been.
The aponeurotic tissue acts as a transition structure, being in some points of its organi-
zation analogous to bone, and in others approaching that of muscle. The analogy be-
tween the bony and fibrous tissues is confirmed by the frequent occurrence of ossifica-
tion in the latter, even under normal conditions, as may be observed in the formation of
the sesamoid bones, and also in the mode by which tendons are attached. It has been
observed, in fact, that at the point of junction of the tendons with the bones there is a
sort of mutual fusion of the tissues, from which so intimate a connexion results, that the
proper substance of the tendons always gives way before they can be separated from the
bones, their attachments to which even maceration will scarcely destroy.
Of the different bones with which a muscle is connected, some remain immovable du-
ring its contraction, while others are put in motion ; hence the distinction between Jixed
and movable attachments. But this eminently useful distinction must not be taken in an
absolute sense ; it is only rigorously true of a very small number of muscles, which, like
some of those found in the face, being connected by one extremity with the skin, and
by the other with the bones, can give rise to movements only at their cutaneous at-
tachments. In the greater number of muscles, on the contrary, although one of the at-
taclunents is most commonly fixed and the other movable, yet their relative condition
may be changed, and they may become alternately fixed and movable ; it is therefore
necessary, in explaining the action of a muscle, carefully to notice the supposed mobility
or fixedness of the different attachments at the time.
In comparing such attachments as are habitually fixed with those that are constantly
movable, we shall observe that the former are either numerous or spread out by means
of aponeuroses, whereas the latter consist of very accurately-circumscribed tendons.
The figurative expressions of head and tail, given to the §nds of a muscle, refer to this
arrangement. The fixed attachment of a muscle is usually blended with those of several
others, while the movable one is distinct.! In order to facilitate our description, we
shall invariably designate the fixed attachment of a muscle, its origin, and the movable
attachment, its termination or insertion.
Structure of Muscles.
Muscles are composed of two kinds of fibres : 1. Of red or contractile fibres, wYiich form
the muscular tissue properly so called ; 2. Of white, strong, and non-contractile fibres, con-
stituting the tendons and aponeuroses. In speaking of the ligaments, we mentioned the
general properties of tendons and aponeuroses as belonging to the fibrous tissues ; we
shall now make a few remarks on the peculiar characters of muscular tissue.
1. Colour. — Muscular tissue is of a reddish colour, the intensity of which varies in dif-
ferent muscles and in different individuals. This colour is not an essential character
even in the human subject, for the contractile fibres of the intestinal canal are very
* In fact, as the tendon, and the aponeuroses by which it is continued into the muscle, represent the direc-
tion of the power, the fleshy fibres must necessarily be attached to it more or les.s obliquely. It is not our in-
tention to examine here the great loss of power which this arrangement involves.
t [This assertion must be taken with some limitation. We shall find many exceptions to this general rule,
(S we proceed in the description of the muscles.]
Bb
194 MYOLOGY.
pale ;* still less is it so in the lower animals, some of which have the entire muscular
system perfectly colourless. The red colour of the muscular fibre is independent of the
blood contained within the vessels of the muscle.
2. Consistence. — The consistence of the muscular fibres varies in different subjects .
in some it is soft and easily torn ; in others it is firmer and more resisting, and retains
for some time after death a degree of rigidity which yields with difficulty to forcible ex-
tension.
Structure. — The muscles may be divided into bundles or fasciculi of different orders,
and these, again, into distinct fibres, which are visible to the naked eye, and rendered
more apparent, either by dissection, or by the action of alcohol, of diluted nitric acid, or
even of boiling water. They are of a variable shape, resembling prisms of three, four,
five, or six surfaces, but are never cylindrical. Their length also varies in different
muscles, in but a few of which do they extend parallel to each other tliroughout the en-
tire length of the fleshy belly.
Each muscle is surrounded by a sheath of cellular tissue, which also penetrates into
its substance, and surrounds both the fasciculi and fibres. This cellular tissue permits
the free motion of the different fasciculi upon one another, while it serves, at the same
time, to isolate each and combine the whole. +
The chemical analysis of muscular tissue shows that it is composed of a small quan-
tity of free lactic acid (Berzelius) ; gelatin ; some salts ; osmazome in greater or less
quantity, according to the more or less advanced age of the individual ; and leucine, a
substance extracted from this tissue by the process described by M. Braconnot. {Ann.
de Chim. et de Phys., tom. viii.)t
In addition to the tendinous and fleshy fibres, vessels, nerves, and cellular tissue also
enter into the composition of muscles. We have already described the disposition of
the cellular tissue contained in these organs ; the mode of distribution of their vessels and
nerves will be more appropriately alluded to in the description of the vascular and ner-
vous systems.^
Uses of Muscles.
The muscles are the active organs of motion, constituting the source of the power
* [The involuntary muscular tissue, of which the above-named fibres afford examples, are, v»ith the excep-
tion of the heart, of a much paler colour than the voluntary muscles, to which this division of the present
work exclusively refers.]
t [In reference to the microscopic structure of the voluntary muscles, or those of animal life, it has been
ascertained that the smallest fasciculi (corresponding with the prismatic fibres of our author, and with the
secondary fasciculi of Miiller), the size of which varies in different muscles, are divisible into transversely-slri-
ated fibres (the primitive fasciculi of Miiller), having a uniform diameter in all muscles in the same species,
and being themselves composed of still smaller elementary parts named _/t?amcn<* (the primitive fibres of Miil-
ler). All these elements of the muscular tissue extend parallel to each other, from one tendinous attachment
to another, never having been seen to bifurcate or coalesce.
In man the fibres vary from y^o^th to -g-^Tfth of an inch in diameter ; the transverse striae upon them are
parallel, generally straight, but occasionally slightly waved or curved ; they are situated at intervals of from
The filaments are varicose or beaded, i. e., alternately enlarged and contracted ; their diameter is from
_ ' th to y-f^^nTr''^ °f *" inch. According to the general opinion, they are held together in each fibre by
means of a glutinous substance, which latter, according to Skey, constitutes the entire centre of the fibre, the
circumference alone being occupied by the filaments. In the larvae of insects, a delicate membranous sheath,
sometimes observed projecting beyond the filaments, has been described by Schwann as forming a proper in-
vestment of the fibre ; and, by analogy, this is also presumed to exist in man and the other vertebrata. Be this
as it may, it is certain that the fibres have no separate sheaths of cellular tissue derived from the common
sheath of the muscle, the prolongations of which appear to extend only so far as to enclose the smallest fasciculi.
The cause of the striated appearance has, perhaps, not been quite satisfactorily ascertained ; but since the
enlargements on the varicose filaments are darker than the constricted portions, and since they are situated
at intervals precisely similar to those between the transverse strios of the corresponding fibre, and from some
other additional considerations, it has been supposed, with great probability, to result from the enlarged and
dark portions of the filaments being arranged side by side.
For an account of the microscopic characters of the involuntary or organic muscular fibres, see the notes ot
the structure of the several viscera, &c., in which they are found, viz., the alimentary canal, trachea, genito-
urinary organs, and iris. We may remark here, that the muscular fibres of the heart and of the upper part
of the oesophagus are striated, and approach very closely in character to those of animal life.]
X [The following analysis of the muscles of the ox is on the authority of Berzelius ;
Water 77-17
Fibrin (with vessels and nerves) 15.8
Cellular tissue convertible into gelatin 1 '9
Albumen and colouring matter 2'2
Alcoholic extract, or ozmazome, with lactic acid and lactates 1 '8
Watery extract, with phosphate of soda 1'05
Phosphate of lime -08
100-
The inadvertent omission, on the part of M. Cruveilhier, oi fibrin as one of the proximate principles of mus-
cle, will serve to impress on the mind of the reader its importance as a constituent of that tissue, in which it
exists in greater abundance than in any other.
The substance called leucine, mentioned in the text, is a product resulting from the action of concentrated
sulphuric acid on muscular fibre, and therefore must not be regarded as previously existing in it.]
^ As it is our intention to introduce, after Myology, an account of the Aponeuroses, we shall be content at
present with the general ideas that have been already stated regarding this important division of the fibrous
tissues.
USES OF MUSCLES.
195
that is applied to the various levers represented by the component parts of the skeleton.
The movements produced are the result of that peculiar property possessed by the mus-
cles of shortening themselves, which is called muscular contractihiy {myotiliti). The
shortening of a muscle is termed its contraction, and the opposite state its relaxation.
Phenomena of Muscular Contraction. — During contraction the muscular fibres become
folded in a zigzag manner throughout their entire length ; the muscle itself becomes
hardened, and broader and thicker in proportion to the amount of shortening. There is
no oscillation in a muscular fibre during a normal contraction.*
The aponeuroses and the tendons take no part in the contraction ; they are entirely
passive. The degree of shortening of which the muscular fibre is susceptible cannot
be precisely determined ; as far as we know, the shortening, and, consequently, the ex-
tent of the resulting movement, is proportional to the length of the fibre. A distinction
should be drawn between the force and the velocity or rapidity of muscular contraction.
Again, the velocity is very different from the extent of motion : the latter depends upon
the length of the fibres ; the former has no connexion with it, but varies according to the
constitution of the individual, and is probably dependant on a more or less rapid influx
of nervous influence.
The muscular force is composed of a great number of elements. According to Borel-
li, an intrinsic and an effective farce may be distinguished in each muscle. The in-
trinsic force is that power which the muscular fibres would exert if they were in the
most favourable position for contraction : the effective force is measured by the result.
The estimation of the force of a muscle presupposes a knowledge, 1 . Of the number of
its fibres. 2. Of ther quality or constitution. 3. Of the nature of the lever upon which
it acts. 4. Of the angle of incidence of the muscle upon that lever ; and, 5. Of the angle
of incidence of the fibres with respect to the imaginary axis of the muscle.
1. Each muscular fibre, being distinct from those around it, may be considered as a
small power ; it may, therefore, be eeisily conceived that the greater the number of fibres
in any muscle, the more energetic will be its contraction.
2. The quality and constitution of the fibre, and the intensity of the stimulus, have no
less an influence upon the contractile force of a muscle than the number of its fibres. To
be convinced of this, it is sufficient to compare the energy of movement in an individual
excited by anger with that in one who is C2ilm.
3. The determination of the kind of levert represented by the bone upon which the
muscle acts, is a fundeimental point in studying muscular action. It is a law in mechan-
ics, that the power acts with greater effect in proportion as its arm of the lever exceeds
in length that of the resistance. The most common lever in the human body is that of
the third order, in which the power, being applied between the fulcrum and the weight,
is therefore most disadvantageously situated for action.
4. As far as regards energy of movement, the lever to which the power is applied is
as unfavourable as possible, because the muscles are generally inserted near the fulcrum.
* The observations of Rogerus tend to show that rapid contractions and relaxations are cotutantly takiiig
place in muscles, especially during their contraction. — (TV.)
" Be Peri)etua Fibrarum Muscularium Palpitatione," 1760. Fig. 103.
t A lever, in mechanics, signifies an inflexible rod capable of turning
round a point. The point upon which the lever turns is called the /ui-
crum if, figs- 103, 104, 105) ; the cause of motion is called the power (p) ;
and the obstacle to be surmounted is the resistance (r) ; the space be-
tween the fulcrum and the power is the power-arm of the lever ; the space
between the fulcrum and the weight is the resistance-arm of the lever.
There are three kinds of levers, distinguished by the respective arrange-
ment of the three parts : 1. A lever of the first order {fig. 103) has the ful-
crum between the power and the resistance. 2. A lever of the second or-
der (fig. 104) has the resistance between the fulcrum and the power. 3.
A lever of tlte third order {fig. 105) has the power between the resistance
and the fulcrum
Fig.lOi.
196 MiULoGV,
But, as a sort of compensation, an advantage peculiar to animal mechanics, the motions
gain in velocity and extent what they lose in force, which, however, may still be obtain-
ed by an increase in the number of muscles, and of the fleshy fibres of each muscle.
Nevertheless, levers of the most favourable construction, and of the most advantageous
position, are met with in situations where considerable force is required ; as in the ar-
ticulation of the foot with the leg, presenting an example of a lever of the second order ; and
in the articulation of the head with the vertebral column, forming a lever of the first order.
The angle of incidence most favourable to the power is the right angle ; but in the hu-
man body, as the muscles are arranged in layers upon the bones which they are intend-
ed to move, they are for the most part inserted at very acute angles. Their incidence
would be still more unfavourable were it not for the enlargement of the articular ex-
tremities of the bones, which disturb the parallelism of the muscles. Besides, in certain
cases, the angle of incidence more or less approaches, or even attains to a right angle,
and is combined with an extremely advantageous lever, when such an arrangement is
required : a& in the articulation of the foot with the leg.
It is of importance to notice, in determining the action of a muscle, that its incidence
upon the bone varies at different periods during its action ; so that a muscle which is
eilmost parallel to the lever when it begins to contract, becomes perpendicular to it at a
given moment during that process. It maybe said that the momentum of a muscle occurs
at that period of its action when its perpendicular incidence gives it the utmost energy
of which it is capable : thus, the momentum of the action of the biceps femoris takes
place when the leg forms a right angle with the thigh. In a certain number of muscles
the momentum coincides with the commencement of action, such as the gastrocnemii
and the solei. In some muscles the angle of incidence remains the same throughout the
whole time of their action, and, consequently, they have no momentum : this is the case
with the deltoid.
The angle of incidence of the muscular fibres, with regard to the imaginary axis of
the muscle or the terminating tendon, involves a loss of power proportional to the amount
of the angle. In some muscles the aponeuroses form a continuation of the fleshy fibres ;
in others, the angle of incidence of the muscular fibre is so acute that it may be left out
of consideration.
Estimation of the Action or Uses of the Muscles. — Since the contraction of a muscle con-
sists in its shortening, it follows that its action may be determined, a priori, from a
knowledge merely of its attachments and direction. It may also be ascertained experi-
mentally, by placing a limb in such a position that the muscfe in question shall be per-
fectly relaxed. As the same muscle generally performs several uses, it is necessary to
place the limb in several different positions, so as to determine those in which the mus-
cle becomes relaxed. Let us take, for example, the glutaeus maximus. If we desire to
relax this muscle completely, it is necessary, 1. To extend the thigh upon the pelvis.
2. To abduct it. 3. To rotate it outward : hence it follows that the glutaeus maximus
is at once an extensor, an abductor, and a rotator outward of the thigh. As a counter-
proof, the limb must be placed in such a condition that the muscle becomes completely
stretched. The successive positions in which a muscle becomes stretched will be the
very reverse of those which the limb assumes during the contraction of the muscle.
Thus, the glutaeus maximus is slightly stretched by rotation inward, more so by adduc-
tion, and most completly by flexion of the thigh upon the pelvis.
In determining the action of a muscle that is reflected over any angle of a bone, it is
necessary to put out of consideration all that portion of the muscle intervening between
its origin and its angle of reflection, and to suppose the power to operate directly from
the latter points.
The action of sphincter muscles is to close the orifices around which they are placed.
A curvilinear muscle assumes a rectilinear direction at the very commencement of its
action.
The insertions of a muscle are neither equally fixed nor equally movable. The fixed
• point of a muscle is that extremity which remains immovable during contraction ; but, in
certain cases, the fixed may become the movable point : this must be taken into consider-
ation in determining the action of a muscle. The fixed point is most commonly that
which is nearest to the trunk. But, with few exceptions, it is never completely station-
ary ; and since a muscle would lose much of its power when acting between a movable
and an imperfectly fixed point, it is necessary that the latter should be kept as immova-
ble as possible by the contraction of other muscles. These consecutive contractions are
often very extensive, and should be familiar both to the physician and the physiologist.
When a muscle passes over several articulations, it moves them all in succession,
commencing with the one nearest to the movable insertion.
Those muscles which concur in producing the same motion are called congenerous ;
those which execute opposite movements are termed antagonists : thus all the flexor
muscles of any region are congenerous, and they are antagonists to the extensors.
Two muscles may be congenerous at one time, and act as antagonists at another :
when they contract simultaneously, their individual and opposite effects are destroyed.
PREPARATION, ETC., OP MUSCLES. 197
and a common and intermediate effect results ; thus, when the flexor carpi ulnaris, which
is both an adductor and a flexor, acts in conjunction with the extensor carpi ulnaris,
which is an adductor and extensor, the hand is neither flexed nor extended, but is mere-
ly adducted. We shall constantly have occasion to notice this arrangement, which ap-
pears to me calculated to give much greater precision of motion than if two perfectly
congenerous muscles had been employed.
There are also certain compound motions, which are, as it were, the results of two
different movements ; thus, when the flexors and the adductors of the thigh act simul-
taneously, the femur passes in the intermediate direction. It is from this kind of com-
bination that the movement of circumduction is produced by the action of the four orders
of muscles situated at the extremities of the antero-posterior and transverse diameters
of the joint. These four orders of muscles are known by the names oijlexors, extensors,
adductors, and abductors.
Lastly, muscles may contract without producing any motions, as when antagonist
muscles act with equal energy. The result of such a simultaneous contraction is an
active immobility or tonic movement, as the older WTiters termed it, which is of very great
importance.
Preparation of Muscles.
Dissection. — The end to be attained in the dissection of a muscle is to isolate it accu-
rately from all the surrounding parts, leaving only those connexions which are compat-
ible with that object. Since, however, it is sometimes impossible to preserve the rela-
tions, and at the same time isolate the muscle, it then becomes necessary to be provided
with two preparations for the demonstration or study of the same muscle.
In order to isolate a muscle, the surrounding cellular tissue, which often forms a very
adherent sheath, must be removed ; and to do this completely, 1. Make a section of the
skin parallel to the fibres of the muscle, deep enough to reach the muscle through the
sheath; 2. As soon as the flap of skin can be grasped by the hand, stretch and separ-
ate it from the muscle by cutting with the scalpel in the angle formed by these two
parts ; 3. When the superficial surface is exposed, proceed to separate the deep surface,
preserving as much as possible all its important relations ; 4. Then dissect the extrem-
ities, marking out their limits with the greatest care.
In the study of the muscular system, great importance should be attached to the choice
of subjects. Robust and tolerably fat subjects are best adapted for this purpose.
Preservation of Muscles in Liquids. — Alcohol, oil of turpentine, a mixture of equal parts
of these, or solutions of the bichloride of mercury, or persulphate of iron, may be em-
ployed for the preservation of muscles, though they alter many of their properties, such
as their colour, consistence, &.c.
Preparations by Desiccation. — As this kind of preparation requires a peculiar method,
we refer to the special treatises upon anatomical preparations for an account of them.
(Vide the works of MM. Marjolin arid Louth.)
Order of Description of the Muscles.
Before passing to the description of the particular muscles, it is necessary to deter-
mine in what order they shall be studied. Galen divided the body for this purpose into
regions, and described the muscles of each in their order of super-imposition. In place
of this arrangement, which is purely topographical, Vesalius substituted a physiological
one, founded upon a consideration of the uses of the muscles. This order was adopted
by Winslow, who named the different muscular regions in the following manner : 3fus-
cles which move the shoulder upon the trunk ; muscles which move the arm upon the scapula,
&c. Albinus revived the method pursued by Galen, and divided the muscles into forty-
eight regions in the male and forty-six in the female. He was followed by Sabatier, and
by Vicq-d'Azyr, who brought the arrangement to perfection by establishing some sub-
divisions in the groups formed by Albinus. Thus modified, it has been adopted by most
modem anatomists. It is evidently preferable in many respects, since it is essentially
anatomical, and is best calculated to exhibit the relations of the different muscles and
regions. In regard, also, to economy of subjects and facility of dissection, it has many
advantages over the physiological order, with which, however, in many regions it may
be made to coincide. We shall, therefore, adopt this arrangement, modifying it so far
as to permit all the muscles to be dissected upon one subject ; and, aft;er having descri-
bed all the muscles according to their topographical relations, we shall give a table in
which they will be grouped in a physiological order.
198
MYOLOGY.
MUSCLES OF THE POSTERIOR REGION OF THE TRUNK.
TTie Trapezius. — Latissimus Dorsi and Teres Major. — Rhomboideus. — Levator AnguR
Scapula. — Serrati Postici. — Splenius. — Posterior Spinal Muscles. — Complexus. — Iriter-
spinalis Colli. — Recti Capitis Postici, Major et Minor. — Obliqui Capitis, Major et Minor,
— General View and Action of the Posterior Spinal Muscles.
The muscles situated on the posterior region of the trunk form several layers, which,
proceeding from the skin to the bones, consist, on either side, of the trapezius, the latis-
simus dorsi and teres major, the rhomboideus and levator anguli scapulae, the serrati
postici, superior and inferior, the splenius, the long muscles of the back, viz., the sacro-
lumbalis and longissimus dorsi ; the transversalis colli and the complexus (which I re-
gard as two series of accessory fasciculi to the longissimus dorsi) ; the complexus ma-
jor, the inter-spinales colli, the recti capitis postici, major et minor, and the obliqui
.capitis, major et minor.*
The Trapezius.
Dissection. — 1. Render the muscle tense by placing a block under the chest ; 2. Make
an incision through the skin from the occipital protuberance to the twelfth dorsal verte-
bra, and another horizontally from the seventh cervical vertebra to the external end of
the clavicle ; 3. Reflect the two flaps, together with the cellular membrane adhering in-
timately to the muscle ; 4. Dissect very carefully the insertions into the occipital bone,
which consist of a very thin aponeurosis closely united to the skin.
The trapezius (cucuUaris, Alhinus, a, figs. 106, 113), the most superficial muscle on the
Fig. 106. posterior region of the trunk, covers
the nape of the neck and the back.
It is a broad triangular, rather than
trapezoid muscle, thick in the mid-
dle, thin and elongated at its supe-
rior and inferior angles.
Attachments. — It arises from the
spinous processes of all the dorsal
and the seventh cervical vertebrae,
from the corresponding supra-spi-
nous ligaments, from the posterior
cervical ligament (ligamentum nu-
chae;, and from the internal third of
the superior occipital line, and is in-
serted into the entire length of the
spine of the scapula, into the poste-
rior border of the acromion, and into
the external third of the posterior
border of the clavicle. The fixed
attachments or origins of this mus-
cle present, 1. A broad, semi-ellipti-
cal aponeurosis, which, when united
to the one on the opposite side, forms
an ellipse, occupying the space be-
tween the sixth cervical and the
third dorsal vertebrae ; 2. A very thin
fibrous lamina, not having the ordi-
nary shining appearance of an apo-
neurosis, which is firmly adherent to
the skin, and forms the truncated
occipital angle of the muscle ; 3. A
great number of tendinous fibres,
constituting all those attachments
to the vertebrae that are independ-
ent of the two preceding aponeuro-
ses. From these origins all the fleshy
fibres proceed outward, the inferior fibres from below upward, the superior from above
downward, and from behind forward, and the middle ones horizontally. They terminate
in the following manner : the lower or ascending fibres are collected together, and at-
tached to a triangular aponeurosis, which, gliding over the small facette at the internal
extremity of the spine of the scapula, is inserted into the tubercle immediately connect-
ed with it ; the middle or horizontal fibres terminate at the posterior border of the spine
of the scapula, by tendinous fibres which are very distinct, especially towards the acro-
* [The transverso-spinalis muscle includes the semi-spinalis colli, the semi-spinalis tlorsi, and the multifidiu
iminse of Alhinus.]
THE LATISSIMUS DORSI AND TERES MAJOR. 189
mion ; the upper or descending fibres are inserted into the convex portion of the posterior
border of the clavicle, many of them being also attached to the upper surface of that bone.
Relations. — The trapezius is covered by the skin, from which it is separated by an
aponeurotic lamina, except at the upper part, where the muscle and integuments are
intimately adherent. It covers the complexus, splenius, rhomboideus, and levator an-
guli scapulae, in the neck ; and the serratus posticus superior, the supra-spinatus, the pos-
terior spinal muscles, and the latissimus dorsi, in the back. The most important rela-
tions of this muscle are those of its superior and external or occipito-clavicular margin :
tms forms the posterior boundary of the supra-clavicular triangle, which is limited in
front by the stemo-mastoid muscle, and below by the clavicle. It should be observed
in reference to the indications regarding the supra-clavicular space, furnished by this
margin of the trapezius, that it sometimes advances as far as the middle of the clavicle, and
has even been observed to become blended with the posterior edge of the stemo-mastoid.
Action. — 1. The upper or descending portion elevates the clavicle, and, consequently,
the apex of the shoulder ; but if the shoulder be fixed, this portion of the muscle inclines
the head to one side and extends it, and, moreover, rotates it, so that the face is turned
to the opposite side. 2. The middle or horizontal portion carries the shoulder back-
ward, but, from the obliquity of the spine of the scapula, it also rotates that bone, so that
the apex of the shoulder is carried upward. 3. The lower or ascending portion draws
the posterior costa of the scapula inward and downward ; and, by a species of rotation,
which was alluded to when treating of the scapulo-clavicular articulations, also elevates
the apex of the shoulder. 4. When the whole of the muscle contracts at once, the scap-
ula is drawn inward, and the apex of the shoulder is raised.
The Latissimus Dorsi and Teres Major.
Dissection. — 1. Render the latissimus dorsi tense by the same means as were employ-
ed for the trapezius, and also by withdrawing the arm from the side. 2. Make an incis>-
ion in the median line from the tenth dorsal vertebra to the sacrum, and another trans-
versely from the same vertebra to the posterior border of the axilla, dividing in the lat-
ter incision a fibro-cellular membrane, which adheres very firmly to the fleshy fibres.
3. Dissect the humeral insertion very carefully, and at the same time prepare the teres
major, which is very intimately related to this extremity.
The Latissimus Dorsi.
The latissimus dorsi (b,fig. 106, p,figs. 109, 110) occupies the lumbar and part of the
dorsal region, and the posterior border of the axilla. It is the broadest of aU the mus-
cles, and shaped like a triangle, having its inferior angle truncated, and its upper and
external angles considerably elongated.
Attachments. — It arises from the spinous processes of the last six or seven dorsal, of
all the lumbar, and of the sacred vertebrae, from the posterior third of the crest of the
ilium, and from the last four ribs, and is inserted into the bottom of the bicipital groove
of the humerus, not into its posterior border.
Its origin from the crest of the ilium and from the vertebrae is effected through the
medium of a triangular aponeurosis, narrow and thin above, broad and very strong be
low, where it is blended with the aponeuroses of the serratus posticus inferior and ob
liquus intemus abdominis, and with the posterior layer of the aponeurosis of the trans-
versus abdominis. This aponeurosis assists in forming the sheath of the sacro-lumbalis,
longissimus dorsi, and trans verso-spinalis. The costal origins consist of fleshy tongues
or digitations, which are interposed between similar processes of the external oblique.
From this threefold origin the fleshy fibres proceed in the following manner : the upper
pass horizontally, the middle are directed obliquely, and the lower vertically upward ;
they all converge, so as to form a thick fasciculus, directed towards the inferior angle
of the scapula, from which it often receives some accessory fibres. The muscle is then
twisted upon itself, so that the inferior or vertical fibres become first anterior and then
superior, while the superior or horizontal fibres become first posterior and then inferior.
This torsion may perhaps be intended to prevent displacement of the fibres. They all
terminate in a flat quadrilateral tendon, which is inserted into the bottom of the bicip-
ital groove, above the insertion of the tendon of the pectoralis major. This tendon fur-
nishes a fibrous expansion continuous with the fascia of the arm, and also a band which
extends to the lesser tuberosity of the humerus.
Relations. — This muscle is covered by the skin (from which it is separated by a close-
ly-adherent fibro-cellular sheath), and by the inferior angle of the trapezius. It covers
the posterior spinal muscles, the serratus posticus inferior, the external intercostals, the
serratus magnus, the lower angle of the scapula, the rhomboideus, and, lastly, the teres
major, by which muscle it is itself covered in its turn. Its external margin is in relation
with the posterior border of the external oblique, from which it is separated below by a
small triangular interval. The upper part of the external margin, together with the teres
major, forms the posterior border of the axilla ; and from the same margin a muscular fasci-
culus occasionally extends beneath the axilla to the lower edge of the pectoralis major.
mtfO MYOLOGY.
The Teres Major.
This muscle (c c,Jig. 106), which, both in its uses and its anatomical arrangements,
should be considered an accessory to the latissimus dorsi, is situated behind the shoulder.
Attachments.— It arises from the quadrilateral surface, situated at the inferior angle of
the scapula, to the outer side of the infra-spinous fossa, and is inserted into the josterior
border of the bicipital groove. The scapular attachment consists of short tendinous
fibres, some of which are fixed directly to the bone, and some into the fasciae, which
separate this muscle from those of the infra-spinous and subscapular fossae. The fleshy
fibres arising from these different attachments form a thick fasciculus, flattened from be-
fore backward, not cylindrical, and about two or three fingers in bieadth, which is direct-
ed outward and upward, and becomes slightly twisted, so as to be inserted by a broad
and flat tendon into the posterior border of the bicipital groove.
Relations. — The latissimus dorsi at first covers its scapular extremity, and then, turn-
ing round its lower edge, becomes anterior to it. The tendon of the latissimus dorsi is,
therefore, applied to the anterior surface of the tendon of the teres major ; but since the
former is attached to the bottom, and sometimes even to the anterior border of the bi-
cipital groove, and the latter to the posterior border of the same groove, they are separ-
ated at their insertions by an interval, in which there is almost always a synovial mem-
brane, and which forms a true cul-de-sac below, for the lower margins of the two tendons
are blended together.
The posterior surface of the teres major is covered by the skin, from which it is sep
arated on the inside by the latissimus dorsi, and externally by the long head of the tri-
ceps. Its anterior surface is in relation with the subscapularis, the coraco-brachialis,
the short head of the biceps, the brachial plexus, the axillary vessels, and the cellular
tissue of the axilla. Its upper margin is at first in contact with the teres minor, from
which it is separated above by the long head of the triceps ; its lower margin forms, in
conjunction with the latissimus dorsi, the posterior border of the axilla.
Action of the Latissimus Dorsi and Teres Major. — The latissimus dorsi adducts the
arm, rotates it inward, and at the same time draws it backward (hence its name, ant
scalptor). When only the upper or horizontal fibres contract, the arm is carried inward
and backward ; when the lower fibres act alone, it is carried downward.
The uses of the teres major are precisely similar to those of the latissimus dorsi, to
which it is congenerous and accessory, and with which it is always associated in ac-
tion, drawing the humerus inward, backward, and downward. When the humerus is
the fixed point, the latissimus dorsi raises the trunk, and with the greater facility, be-
cause it is attached to the ribs, the spine, and the pelvis. In consequence of its costal
attachments, the latissimus dorsi is a muscle of inspiration ; and it should be observed,
that the direction of its fibres, which is almost perpendicular to the ribs, enables it to
act with great power.
The Rhomboideus.
Dissection. — Divide the trapezius by an incision extending from the third dorsal ver-
tebra to the lower angle of the scapula ; dissect back the flaps, taking care to remove a
fibro-cellular layer which adheres closely to the trapezius.
The rhomboideus {d d, fig. 106), situated in the dorsal region, on the posterior aspect
of the trunk, approaches closely to the form of a rhomboid or lozenge ; it is broad and
thin, but thicker below than above, and is almost always divided into two parts.
Attachments. — It arises from the bottom of the ligamentum nuchae, from the spinous
processes of the seventh cervical and five superior dorsal vertebrae, and from the corre-
sponding interspinous ligaments, and is inserted into all that part of the posterior costa
of the scapula situated below its spine. The spinal or internal attachments consist of
tendinous fibres, the most inferior of which are the longest. From these points the
fleshy fibres proceed, parallel to each other, downward and outward, to a very thin ten-
don, which runs along the posterior costa of the scapula, but only adheres to it above
and below : the greater number of fibres are inserted into the lower angle of the scapula
by a very strong tendon, which forms the principal attachment of the muscle, and to
wliich the tendon mentioned above is merely subordinate. The upper part of this mus-
cle {e,fig. 103), which arises from the hgamentum nuchae and the seventh cervical ver-
tebra, is inserted by itself opposite the spine of the scapula. It is distinct from the re-
mainder of the muscle, and from this fact Vesalius, Albinus, and Scemmering gave it
the name of rhomboideus minor or superior.
Relations. — This muscle is covered by the trapezius, the latissimus dorsi, and the
skin. It covers the serratus posticus superior, part of the posterior spinal muscles, the
ribs, and the intercostal muscles.
Action. — ^The rhomboid raises the scapula and draws it inward. As it acts principal-
ly upon the lower angle of that bone, it rotates it in such a manner that the anterior
angle, and, consequently, the apex of the shoulder, is depressed. It assists the trape-
zius in carrying the entire shoulder inward, and is also associated with the upper fibres
THE SERRATI POSTICI. 201
of the same muscle in raising that part ; hut, on the other hand, it antagonizes the tra-
pezius by depressing the apex of the shoulder.
The Levator Anguli Scapulcs.
Dissection. — Detach the trapezius from the spine of the scapula with care ; divide the
upper part of the sterno-mastoid, so as to expose the transverse processes of the three
or four superior cervical vertebrae.
The levator anguli scapula (levator scapulae, Alhinus, f,figs. 106, 110, 113, 114), situ-
ated at the posterior and lateral part of the neck, is an elongated bundle, having its up-
per portion flattened from without inward, and divided into three or four fasciculi, while
the lower part is flattened from behind forward.
Attachments. — It arises from the posterior tubercles of the transverse processes of the
three or four superior cervical vertebrae, externally to the splenius, and behind the sca-
lenus posticus ; it is inserted into the superior angle of the scapula (whence its name),
and into all that portion of its internal costa situated above the spine.
The cervical attachments of this muscle consist of four tendons, to which succeed an
equal number of fleshy fasciculi, at first distinct, but afterward united into one bundle,
which proceeds downward, backward, and outward, and spreads out to be inserted into
the scapula by short aponeurotic fibres.
Relations. — It is covered by the trapezius, the sterno-mastoid, and the skin ; and it
lies superficially to the splenius, the sacro-lumbalis, the transversalis colli, and the ser-
ratis posticus superior.
Action. — When its upper attachment is fixed, this muscle carries the posterior angle
of the scapula upward and forward, and, consequently, rotates that bone, so as to depress
the apex of the shoulder. It conspires with the rhomboid and the trapezius in elevating
the entire shoulder, and with the rhomboid in depressing its apex, in this respect acting
as an antagonist to the trapezius. When the fixed point is below, which must be very
rarely, it inclines the neck backward and to its own side.
The Serrati Postici.
These are two in number, a superior and an inferior.
Dissection. — 1. To expose the superior muscle, divide and reflect the trapezius and the
rhomboid, and draw the scapula forward ; 2. To display the inferior, raise the latissimus
dorsi with great care, as its deep aponeurosis is blended with that of the serratus posticus
inferior ; 3. Preserve the thin aponeurosis extending between the two serrati muscles.*
1. The serratus posticus superior is situated at the upper and back part of the thorax,
and is of an irregularly-quadrilateral figure.
Attachments. — It arises from the ligamentum nuchae and the spinous processes of the
seventh cervical and of the two or three upper dorsal vertebrae, and is inserted into the
upper borders of the second, third, fourth, and fifth ribs. The vertebral attachment con-
sists of a very thin aponeurosis, the fibres of which are parallel, and inclined downward
and outward. From this aponeurosis, which constitutes at least the inner half of the
muscle, the fleshy fibres proceed in the same direction, and almost immediately divide
into four digitations, which are inserted into the ribs by means of short tendinous fibres.
The superior digitation is attached near the angle of the corresponding rib, and each of
the others at successively greater distances from it.
2. The serratus posticus inferior (lumbo-costalis, Chaussier, g, fig. 106) is also of an ir-
regularly-quadrilateral form, and is situated at the lower part of the back and the upper
part of the loins. It arises from the spinous processes of the two lower dorsal and three
upper lumbar vertebrae, and is inserted into the inferior borders of the last four ribs. The
vertebral or internal attachment consists of an aponeurosis similar to that of the prece-
ding muscle, but its fibres have an inverse direction, i. e., obliquely outward and upward.
From this aponeurosis, which forms the internal half of the muscle, the fleshy fibres pro-
ceed in the same direction, and divide into four flat digitations, progressively decreasing
in size from above downward, which are inserted into the ribs by means of tendinous
laminae, the superior digitation near the angle of its corresponding rib, and the others,
successively, farther beyond it.
Relations. — These two muscles have certain relations in common, and there am some
peculiar to each. They both cover the longissimus dorsi, the sacro-lumbalis, the trans-
verso-spinalis, the ribs, and the corresponding intercostal muscles. The superior is cov-
ered by the rhomboideus, the trapezius, and the serratus magnus, and covers the splenius
and transversalis colli. The inferior is covered by the latissimus dorsi, with the apo-
neurosis of which muscle its own aponeurotic lamina is so closely united that it is impos-
sible to separate them completely ; and it covers the posterior layer of the aponeurosis
of the transversalis.
Action. — Besides certain common uses, each muscle has its own peculiar action. One
* [This exceedingly thia and semi-transparent lamella has received the name of the vertebral aponewrotit
Sep A.P0NEUK0I.0OY.]
Cc
202 MYOLOGY.
impoitant common use is, to retain in the vertebral groove those muscles of the back
which, from their extreme length, are the most liable to displacement. This effect is
produced by their fleshy portions rendering tense their aponeurotic expansions.
With regard to the actions proper to each, 1. The superior elevates those ribs into
which it is inserted, and is, consequently, a muscle of inspiration ; 2. The inferior, on
the other hand, is a depressor of the ribs, and, therefore, a muscle of expiration.
The Splenius.
Dissection. — Merely remove the trapezius, the rhomboid, and the serratus posticus su-
perior.
The splenius {i,Jigs. 106, 113, 114), so named because it has been compared to the
spleen {a■!T^v), is situated at the posterior part of the neck and upper part of the back. It
is a broad muscle, terminating in a point below, and dividing into two portions above.
Attachments. — It arises from the spinous processes of the four or five superior dorsal
and the seventh cervical vertebra, from the corresponding supra-spinous ligaments, and
also from the ligamentum nuchae, between the seventh and the third cervical vertebrae ;
it is inserted, 1. Into the transverse processes of the first, second, and often the third cer-
vical vertebrae ; 2. Into the external surface and posterior border of the mastoid process,
and the external third of the rough space beneath the superior semicircular line of the
occipital bone. The spinal attachments consist of tendinous fibres, the most inferior of
which are the longest. From these the fleshy fibres proceed obliquely upward and out-
ward, the lower being longer and more vertical, and form a broad, flat muscle, which is
much thicker externSly, and soon becomes divided into two portions : one smaller, infe-
rior and external ; the other much larger, superior and internal. The former is called
the splenius colli ; it is sometimes distinct, even from its origin, and soon subdivides
into two or three fasciculi, which terminate in as many tendinous processes, that are in-
serted into the atlas, the axis, and often into the third cervical vertebra. The fascicu-
lus proceeding to the atlas is usually the largest. The second, or the upper and internal
portion of the muscle, is connected with the head, and is called the splenius capitis.
Relations. — The splenius is covered by the trapezius (the rhomboid and the serratus
posticus superior intervening below), by the sterno-mastoid, and by the levator anguli
scapulae. It covers the complexus, the longissimus dorsi, the transversalis colli, and
the trachelo-mastoid. The levator anguli scapulae is in contact with its outer border,
and rests upon it above, the cervical insertions of the two muscles being blended togeth-
er ; below they are separated by the transversalis colli and sacro-lurabalis. The inter-
nal edge is very thin, and separated from the muscle of the opposite side by a triangu-
lar interval, in which the complexi are visible.
Actions. — The splenius extends the head, inclines it to its own side, and rotates it so
that the face is turned to the same*ide. This action of the splenius depends on its at-
tachments to the occipital bone, the mastoid process, and the atlas. By its insertions
into the second and third cervical vertebrae it tends to rotate these in the same direction.
When the two muscles act together, the head is drawn directly backward. The splenius
is therefore an extensor and rotator of the head and of the neck ; it assists in supporting
the head in the erect position, and prevents it from inclining forward in obedience to the
force of gravity.
The Posterior Spinal Muscles.
As these muscles are arranged in a peculiar manner, we shall adopt a method of de-
scription in some measure different from that which we have elsewhere employed.
The posterior spinal, or long muscles of the back (see Jig. 107), are three in number,
viz., the sacro-lumbalis, the longissimus dorsi, and the transverso-spinalis muscle.
These three muscles, which extend the entire length of the spine, form a very large
muscular mass, completely filling up the corresponding vertebral groove. This mass is
small at the lower part of the sacral groove, becomes much enlarged in the loins, then
diminishes in the back, and again acquires a considerable size in the neck. Chaussier
has given a description of them under the collective name of the sacrospinal muscle ;
and they have also been denominated the erector spina.
I shall describe the three muscles together ; but, in order to adopt some arrangement
in a matter so complicated, I shall divide them into three portions, viz., a lumbro-sacral,
a thoracic, and a cervical.
Ltimhro-sacral Portion of the Posterior Spinal Muscles.
Dissection. — 1. Render this portion of the muscle tense, by placing a block under the
abdomen. 2. Divide by a vertical incision the trapezius, splenius, rhomboideus, latis-
simus dorsi, and serrati postici ; reflect the divided portions inward and outward. A
young subject, from ten to twelve years of age, is best adapted for the study of these
muscles, from the facility with which the different fasciculi may be separated. For the
same reason, one that is much infiltrated with serum is preferable to one in which the
parts are dry. i -
THE POSTERIOE SPINAL MUSCLES.
203
The lumbo-sacral portion is usually called the common m/iss of the sacro-lumbalis and
longissimus dorsi. It forms the fleshy part of the loins, and is called the fdlet in the low-
er animals : it is the most highly developed in man, in whom it exerts a constant and
powerful action during the erect posture : it appears to be the coimnon origin of the pos-
terior spinal muscles, whence the name of common mass : it fills up entirely the lumbo-
sacral groove, and even projects backward and laterally in robust subjects.
It is of small size in the sacral region, is much enlarged at the middle of the lumbar
region, at the upper part of which it again diminishes, so as to resemble two cones uni-
ted by their bases.
Attachments. — The common mass arises from the whole extent of the sacro-iliac
groove, and from the anterior surface and external border of an extremely strong apo-
neurosis, formed of parallel vertical fibres, and strengthened by a superficial layer direct-
ed obliquely. This aponeurosis of origin for the posterior spinal muscles {d,fig. 107) is in-
serted on the inside to the sacral ridge, to the summits of the spinous processes of the
lumbar and three lower dorsal vertebrae, and to the corresponding supra-spinous liga-
ments : on the outside, to the series of eminences representing the transverse processes
of the sacral vertebrae, and to the back part of the crest of the ilium : it gives attach-
ment to many of the fibres of the glutaeus maximus. It is short on the outside, and very
long on the inside, reaching in the latter direction to the middle of the dorsal region, un-
der the form of parallel and regular bands {d,fig. 107).
Arising from these different origins, the coiimion mass appears at first extremely sim
pie in its composition, consisting of fibres passing vertically upward. But if the aponeu-
rosis be detached from its spinal insertions, and turned outward, it will be seen that the
common mass is essentially composed of two portions : one internal and anterior, the
lumbosacral portion of the transverso-spinalis ; and the other external and posterior, the
lumio sacral portion of the sacro-lumbalis and longissimus dorsi.
1. The lumbosacral portion of the transverso-spinalis* occupies all the sacral groove, and
that part of the lumbar groove situated within the articular processes. It is perfectly
distinct in the loins, being separated from the common mass by loose cellular tissue trav-
ersed by vessels and nerves. It arises from the articular processes of the lumbar verte-
brae by flat tendons, directed obliquely inward and upward, and terminating upon the pos-
terior surface of the muscle : by the imion of their contiguous edges an aponeurosis is
formed, which is itself blended along one of its borders with the deep surface of the com-
mon aponeurosis of origin. From these tendons the
fleshy fibres arise, and having united into bundles,
terminate by other tendons at the spinous processes
of the vertebrae above. In the sacral region this
portion of the transverso-spinaUs is less distinct, but
it may be easily seen that it occupies the whole of
the sacral groove, and that the corresponding por-
tion of the aponeurosis of origin affords attachments
fo it alone.
2. The external and posterior portion of the com-
mon mass, or lumbosacral portion of the sacro-lumbalis
and longissimus dorsi, is entirely without the sacral
groove, but occupies that part of the lumbar groove
situated on the outer side of the articular processes.
It arises, 1. From all the lumbar portion of the com-
mon aponeurosis. 2. From an extremely strong ten-
don, which is attached to the posterior superior spi-
nous process of the ilium. 3. From the posterior s~
fourth of the crest of the ilium, internally by tendi-
nous, and externally by muscular fibres. The thick
fleshy mass proceeding from these different origins
is disposed of in the following manner : the greater
part of the fibres pass directly upward to the dorsal
region, forming the proper commencement of the
sacro-lumbalis (a a, fig. 107). The remaining fibres
are directed forward, and are arranged into two sets
of bundles, one of which is inserted into the summits
of the transverse processes, forming the external or
transverse fasciculi ; and the other into the tubercles
of the articular processes, forming the internal or ar-
ticular fasciculi. These two sets of fibres constitute
the proper origin of the longissimus dorsi (d d, fig.
107).
Relations. — The common mass is covered behind
Fiff. 107.
[This corresponds to the inferior or lumbo-sacral fasciculi of the multifidus spinte,]
204 MYOLOGY.
by the united aponeuroses of the latissimus dorsi and serratus posticus inferior, and by
the posterior layer of the aponeurosis of the transversalis ; in front, it corresponds to
the lumbar groove, the inter-transversales muscles of the loins, and the middle layer of
the aponeurosis of the transversalis, which separates it from the quadratus lumborum ;
on the inside, it corresponds to the spinous processes ; and on the outside, to the angle
of union between the posterior and middle layers of the aponeurosis of the transversalis.
In this way it is completely enclosed in an osteo-fibrous sheath.
Thoracic Portion of the Posterior Spinal Muscles.
The transverso-spinalis muscle may be completely isolated from the others in this
region. We have seen the distinction between the sacro-lumbalis and longissimus dorsi
commenced at the upper part of the lumbar region ; in the back they are completely sep-
arated by some loose cellular tissue and the posterior branches of the dorsal nerves and
vessels.
The thoracic portion of the sacro-lurnbalis (6 V, fig. 107) consists of a continuation of the
vertical or external fibres of the common mass ; as it proceeds upward it becomes more
and more slender, and is divided into a series of fasciculi, which are inserted succes.sive-
iy into the angles of the ribs, by means of tendinous prolongations, that extend for a
considerable distance upon the posterior surface of the muscle. It was the existence of
these aponeurotic processes, the contiguous edges of which are often united, that in-
duced Winslow to compare the muscle to a palm leaf In this manner the muscular
fasciculi are soon expended, terminating at about the sixth rib, but the muscle itself is
continued into the neck by means of accessory fibres, which may be exposed by turning
the muscle outward, sifter separating it from the longissimus dorsi (as at h') : twelve
long, thin tendons will then be seen to arise from the upper portion of the angles of the
twelve ribs, and to pass outward and upward : to these succeed fleshy fasciculi, which
terminate in aponeurotic processes, situated on their posterior surfaces, and having pre-
cisely the opposite direction. These accessory bundles (c c',Jig. 107; i,fig. 108) have
been very well described by Diemerbroek under the name ofcervicales descendens, and by
Steno under that of musculus accessorius ad sacro-lumbalem ; the four or five superior bun-
dles form the transversaire grele of Winslow, and the cervicalis descendens of Albinus.
The thoracic portion of the longissimus dorsi (e e', fig. 107) is larger than the preceding
muscle, to the inner side of which it is situated : it diminishes much less rapidly, because
the common aponeurosis {d) is extended in the form of bands upon its posterior aspect,
which afford attachment to additional fleshy fibres. This muscle is a continuation of the
internal or articular, and the external or transverse fasciculi, described as existing in
the lumbar region, and is itself divided into three orders of fasciculi, one external and two
internal. 1. The external or costal fasciculi form the continuation of the transverse bun-
dles of the lumbar portion of the muscle, and are inserted by very thin tendons into the
space between the angles of the ribs and the summits of the dorsal transverse processes
(e',fig. 107). 2. The first set of internal, or the spinous fasciculi, are inserted into the spi-
nous processes of the five or six superior dorsal vertebrae ; and as they arise from tendi-
nous bands attached to the summits of the spinous processes of the lower dorsal vertebrae,
and of that of the first lumbar vertebra, Winslow considered them as forming a separate
muscle, which he called le long epineux du dos (spinalis dorsi, /,^o'. 107). 3. The second
set of internal, or the transverse fasciculi, are a continuation of the articular fasciculi of the
lumbar region ; they constituie the principal termination of the longissimus dorsi, and
are attached by very long and thin tendons to the transverse processes of the dorsal
vertebrae.
The thoracic portion of the transverso-spinalis* (partly seen in^^. 108) is reduced to a
very narrow band, concealed by the longissimus dorsi : it arises by very long and delicate
tendons from the lower dors^ transverse processes, and is inserted by others equally
sinailar, long and slender, into the summits of the superior dorsal spinous processes,
some pale fleshy fibres connecting the two series of tendons.
Connexions. — The dorsal portion of the posterior spinal muscles entirely fills the dor-
sal groove, limited on the outer side of the angles of the ribs. They are covered by
several muscular layers, the nearest of which is formed by the two serrati postici and
their connecting aponeurosis, which completes the sheath enclosing the long muscles of
the back : they are, moreover, separated from the skin by the rhomboid, trapezius, and
latfssimus dorsi.
The Cervical Portion of the Posterior Spinal Muscles, the Transversalis Colli, and the
Trachelo-mastoidcus.
Cervical portion of the sacro-lumbalis, or cervicalis descendens. The sacro-lumbalis,
whose original fibres are found to terminate at and upon the sixth rib, is continued, by
means of its accessory fasciculi (c c',fig. 107), up to the transverse processes of the four
or five inferior cervical vertebrae (i,fig. 108), into the summits of which it is inserted by
very slender tendons. The number of these terminating fasciculi varies in a remarkable
* [This corresponds to the semi-spinalis do.rs-, and to the dorsal portion of the multifidus spinsn of Albinus ■•
THE POSTERIOR SPINAL AND COMPI.EXUS MUSCLES. 205
manner. Indeed, the splenius, the transverscdis colli, the sacro-lumbalis, and even the
levator anguli scapulas, are so closely connected, that, upon examining their cervical in-
sertions only, these might all be ascribed to a single muscle. The cervical portion of
the sacro-lumbalis is covered by the levator anguli scapulae, and can only be exposed by
turning this muscle outward.
The cervical portion of the longissimus dorsi, or the transverscdis colli, and the tra-
chelo-mastoid. The extent of the longissimus dorsi is limited to the back ; its highest
internal or spinous fasciculus seldom reaches the spinous process of the first dorsal ver-
tebra : its highest external or costal fasciculus is attached to the second, sometimes even
to the fourth rib, and its highest transverse fasciculus is inserted into the transverse
process of the first dorsal vertebra. In some very rare cases, a few internal fasciculi
reach the cervical vertebrae : I have seen one of them terminate by becoming attached
both to the transverse process of the third cervical vertebra and to the complexus. The
longissimus dorsi is, however, prolonged by accessory fasciculi as far as the third cervi-
cal vertebra. These fasciculi can only be identified by their direction (for they can never
be completely separated from this muscle) : they form a distinct muscle, known as the
transverscdis colli (transversalis cervicis, Albinus, g g,fig. 107).
By reflecting outward the upper part of the longissimus dorsi, they may be exposed,
varying in number, and arising from the summits of the transverse processes of the third,
fourth, fifth, sixth, and sometimes seventh and eighth dorsal vertebrae, by long, thin ten-
dons, and inserted by other tendons into the posterior tubercles of the transverse pro-
cesses of the five inferior cervical vertebras {I, fig. 108) : the transversalis colli is covered
by the longissimus dorsi, the splenius, and levator anguli scapulae, and rests upon the
trachelo-mastoid and complexus.
The trachelo-vtastoideus (complexus minor, i i, fig. 107) may be regarded as another
accessory muscle to the longissimus dorsi, which it continues up to the head. In order
to expose its origin, the transversalis colli must be reflected outward (as in fig. 107).
It arises from the angles between the transverse and articular processes of the four in-
ferior cervical vertebrae, by four small tendons, or sometimes by a continuous aponeu-
rotic plane. From thence the fibres proceed upward, and form a small muscle, which is
inserted into the mastoid process, in a small furrow to the inside of the digastric groove.
This small muscle is almost always interrupted by a tendinous intersection near its
mastoid insertion.
The cervical portion of the transverso-spinalis.* While the preceding muscles present
only a few fasciculi in the neck, the transverso-spinalist undergoes an enlargement in
this region, so as to occupy the entire cervical groove (a and b,fig. 108). In camivora,
this portion of the muscle is enormously developed (much more so than in man), in con-
sequence of those animals using the head and neck in seizing or struggling with prey.
In mammalia, as in man, the dorsal portion of the transverso-spinalis is, as it were, but
a rudiment in the lumbo-sacral region ; the muscle is larger in man than in other animals,
on account of his erect posture. Albinus described the enlarged cervical portion as a
separate muscle, viz., the spinalis cervicis.
In the neck, as in the other regions, the transverso-spinalis is a collection of super-
imposed fasciculi, which arise from the transverse processes of the five or six upper
dorsal, and from the articular processes of the five lower cervical vertebrae, and are in-
serted into the spinous processes of the six lower cervical vertebrae : the highest and the
largest fasciculus is attached to the axis. This muscle, which would have been much
better named articvio-spinalis, is composed of several layers of fasciculi, placed one above
the other, and extending from the whole length of the articular processes and laminae
of the vertebrae below to the whole length of the spinous processes and laminae of the
vertebrae above. The length of these layers diminishes progressively from the more
superficial {a, fig. 108) to the deep-seated ones (6) ; the latter extend only from one ver-
tebral lamina to another, and might be considered as proper muscles of the laminae, and
not as a part of the transverso-spinalis muscle. The most superficial layer is composed
of radiating fasciculi, diverging from one articular process to the summits of several of
the spinous processes.
The Complexus.
Dissection. — ^Divide the splenius perpendicularly to the direction of its fibres, and re-
flect the two parts upward and downward ; turn outward the upper portions of the lon-
gissimus dorsi, the transversalis colli, and the trachelo-mastoid {see fig. 107).
The complexus {I, fig. 107) is situated beneath the splenius at the posterior part of the
neck and upper part of the back. It is a flat muscle, broad above, but terminating in a
point below.
Attachments. — It arises, 1. From the transverse processes of the five or six superior
* If we were to follow the order of super-imposition rigorously, the complexus should be described before
this muscle, which cannot be brought into view until the former is removed.
t [This portion of the transverso-spinalis corresponds to the semi-spinalis colli (a, fig. 108), and the cervj
cal fasciculi (6) of the niultifidus spins of Albinus. 1
206 MYOLOGY.
dorsal vertebrae ; 2. From the articular tubercles and the angular depression formed be-
tween them and the transverse processes of the four inferior cervical vertebrae ; 3. Some-
times from the spinous processes of the seventh cervical and two upper dorsal vertebrae :
it is inserted upon the side of the external occipitd crest into the inner half of the rough
space comprised between the two semicircular lines. The origins of this muscle con-
sist of tendons, from which the inferior fleshy fibres pass vertically upward, the superior
ones obliquely inward and upward, becoming graduaUy shorter and more nearly horizon-
tal. The muscular fibres are interrupted by some very remarkable tendinous intersec-
tions. Thus, on the inside, the fleshy fasciculus arising from the sixth, fifth, and fourth
dorsal vertebrae, gives origin to a tendon, which proceeds along the inner edge of the
muscle, and, at the distance of an inch and a half or two inches, becomes the origin of
another fleshy fasciculus, which is attached to the side of the occipital crest ; hence the
name of biventer cervicis, given by Eustachius to the whole complexus, and by Albinus to
this inner portion only (m, fig. 107). More externally, there is another flat tendon ex-
tending along the posterior surface of the muscle, from the outer edge of which an apo-
neurotic intersection passes in a zigzag course obliquely outward and upward. It is not
uncommon to find another small digastric fasciculus with a separate tendon, on the an-
terior surface of the muscle.
Relations. — The complexus is covered by the trapezius, splenius, longissimus dorsi,
transversalis colli, and trachelo-mastoid, and covers the transverso-spinalis and the recti
and obliqui capitis. Its inner edge is separated from the muscle of the opposite side by
a considerable quantity of adipose tissue, and by a prolongation of the ligamentum nuchae.
The Inter-spinales Colli.
The inter-spinales muscles are distinct in the neck oidy. It is generally admitted that
there are five pairs, the first of which extends between the axis and the third cervical
vertebra, and the last between the seventh cervical and first dorsal vertebras. They are
small quadilateral muscles, extending from one of the borders of the groove in the spinous
process below to the corresponding lip of the next process above. Externally, they are
in relation with the transverso-spinalis, and are separated from each other internally by
cellular tissue and an aponeurotic lamina.
Fig. 108. The Recti Capitis Posticiy Major and Minor.
The rectus capitis posticus major {e,fi^. 108) may be regarded as an
axoido-occipital, and the rectus minor (d) as an atloido-occipital inter-spi-
ndis muscle. They both arise tendinous, the smaller from the tubercle
on the posterior arch of the atlas, and the greater from the superior
tubercle of the spinous process of the axis (2) ; and, increasing in size,
they both pass obliquely upward and outward. The rectus major,
^h which is much the larger and more oblique, is inserted to the outer
side of the inequalities situated below the inferior semicircular line
of the occipital bone ; the rectus minor is inserted to their inner side.
The name of recti is not, therefore, very appropriate, for both of them
(but more especially the larger one) are directed obliquely ; but they
are so called in contradistinction to two neighbouring muscles which
are much more oblique. The obliquity of these muscles (by increas-
ing their length) allows of more extended movements, and, at the
same time, enables them to assist in rotating the head.
Tht Ohliquus Capitis Major or Inferior^ and Obliquus Minor or Superior.
The ohliquus major or inferior (/, fig. 108), as far as its insertions are concerned, may
be called the axoido-atloid spino-transversalis ; it resembles, in fact, a thick fasciculus of
the longissimus dorsi. The obliquus minor or superior {g) may, for the same reason, be
called the atloido-occipital transverso-spinalis, resembling a thick fasciculus of that mus-
cle. The ohliquus major arises from the apex of the spinous process of the axis, on the
outer side of the rectus major (c), and above the transverso-spinalis (i. c, the semi-spi-
nalis colli and multifidus spinas conjoined, a and h) ; it forms a thick, cyhndriccd bundle,
passes almost horizontally outward, and is inserted behind and below the transverse
process of the atlas, which is excavated for this purpose. It is the axoido-atloideus of
Chaussier. The ohliquus minor (atloido-sub-mastoideus) arises by some very long tendi-
nous fibres from the upper part of the transverse process of the atlas, proceeds at an
angle of about 45° towards the occipital bone, into which it is inserted not far from the
mastoid process, by some tendinous fibres, less distinctly marked than those of its origin.
From this difference of direction, it follows that the rectus major and the two obliqui
form on each side an equilateral triangle ; in the interval between the two triangles a
considerable part of the recti minores is seen.
Relations. — The recti and obliqui capitis are covered behind by the complexus, from
which they are separated by a very strong aponeurotic lamina and much cellular tissue ;
THE POSTERIOR SPINAL MUSCLES. 20T
they cover tlie posterior arch of the atlas, with the posterior ligaments of the atloido-oc-
cipital and atloido-axoid articulations.
General View of the Posterior Spinal Muscles.
After the preceding description, it will now be easy to comprehend the general guiding
principles in the arrangement of the innumerable, and, at first sight, inextricable fasci-
cuh which constitute the fleshy mass known by the general name of the posterior spinal
muscles. We shall first recall to mind, that the levers to which all these muscles are
ultimately attached are, 1. The row of spinous processes ; 2. The row of articular pro-
cesses ; and, 3. The row formed by the transverse processes and the ribs, which, for
many reasons, may be regarded as extensions of those processes.
We shall suppose these three series of levers, and therefore the several points of in-
sertion, to be represented by three vertical lines.
We must remember, also, that the dorsal transverse processes are upon the same line
as the lumbar and cervical articular processes, and that the ribs are upon the same line
as the lumbar transverse processes and the anterior roots of the cervical transverse pro-
cesses. (See Osteology, p. 5.) These data being admitted, we can now reduce all
the posterior spinal muscles into the four following orders of fasciculi, two being vertical
and two oblique.
1. The internal vertical or spinous muscles, comprising the spinalis dorsi (i. e., the in-
ternal and superficial portion of the longissimus dorsi), the inter-spinalis of the neck, and
the recti postici of the head. 2. The external vertical lateral, or transverse muscles, con-
nected with the transverse or costiform processes. They comprise the sacro-lumbalis
and the inter-transversales, among which the quadratus lumborum may be included. 3.
The spino-transverse and spino-articular* oblique muscles, including the longissimus dorsi,
with its accessories, the transversalis colli and trachelo-mastoid, the splenius and th6
obliquus major. 4. The transverso-spinous and articulo- spinous* oblique muscles, viz.,
the transverso-spinalis, the complexus, and the obliquus capitis minor.
Action of the Posterior Spinal Muscles.
Having once established the general principles according to which the posterior spinal
muscles are arranged, it is very easy to determine the mode of action of each, and to re-
duce to very simple elements a mechanism to all appearance so complicated.
1. The long and short spinous fasciculi being vertical, directly extend the vertebrcil
column ; such is the action of the spinalis dorsi and inter-spinalis colli ; the recti capitis,
at the same time that they extend the head, rotate it also to the side on which the mus-
cles are acting. When the recti muscles of both sides act simultaneously, the head is
drawn directly backward.
2. The fasciculi of the sacro-lumbalis being vertical and lateral, erect the vertebral
column, and incline it to one side, when only one set of muscles acts ; when both sets
act together, they extend it directly backward.
3. As the fasciculi of the longissimus dorsi, belonging to the spino-transverse and spi-
no-articular group, have their fulcra upon the spine, and are inserted into the articular
and the transverse processes or ribs, they conspire in erecting the vertebral column, and
keeping it in that position. But, from their obUquity, they produce a slight movement of
rotation, those fibres which are attached to the articular processes having less effect than
those connected with the transverse processes. In this movement, the front of the body
is turned to the side on which the muscles are situated. When the muscles of both
sides act together, the spine is extended directly backward. The splenius, which is the
representative of the longissimus dorsi for the neck and head, acts in the same way, but
with greater effect. Thus, by the contraction of the left splenius, the face is turned to
the left side, and the head is drawn backward and to the right side. The obliquus infe-
rior jilso acts in the sEune direction. When the two splenii and the two inferior oblique
act together, the head is inclined directly backward.
4. The fixed insertions of the transverso-spinalis being at the articular or transverse
processes, and their movable points at the spinous processes, besides the common effect
of erecting the vertebral column, they are also able to rotate it, so that the anterior re-
gion of the trunk is turned to the opposite side. From its obliquity, this muscle is the
principal rotator of the vertebral column. The complexus, which is its representative
in the neck, acts upon the head in the same manner, but in a more remarkable degree.
Thus, by the contraction of the complexus of the left side, the face is turned to the right
side, and the head is inclined backward upon the left side, so that, in rotation, it acts in
a precisely opposite direction to the splenius. When all these muscles act together, the
trunk is simply drawn erect. The superior oblique assists the complexus in the move-
ments of the head.
Lastly, we may now understand the successive actions which take place along the
* [The terms spino-transverse and spino-articular are applied to fasciculi passing upward from the spinous
to the transverse and articular processes ; transverso-spinous and articulo-spiuous, to such as proceed upward
from the transverse and articular to the spinous processes.]
208
MYOLOGY.
whole extent of the posterior spinal muscles. The sacrum and the iliac bones furnish a
fulcrum for the fasciculi which move the lumbar region : this latter being fixed, then be-
comes the fulcrum for those that move the dorsal region, and so on to the head, which
alone has independent muscles. It is impossible to extend backward the dorsal region,
and the lower part of the cervical, without at the same time erecting the lumbar region;
but the head may be moved at will, independently of the vertebral column.
The posterior spinal muscles maintain in equilibrium the weight of the whole trunk ;
hence the lassitude experienced in the back, but especially in the loins, by long-contin-
ued standing, walking, or even sitting without a support to the back ; and hence the re-
lief afforded by the recumbent posture.
Rotation, we have seen, scarcely exists in the loins, the back, or the lower part of the
neck ; but at the upper part of the neck it is very extensive, and here the rotator mus-
cles are proportionally strong, and directed very obliquely.
MUSCLES OF THE ANTERIOR ABDOMINAL REGION.
The Obliquus Externus Abdominis. — Obliquus Internus and Cremaster. — Transversalis Ab-
dominis . — Rectus Abdominis. — Pyramidalis .
The muscles of the anterior abdominal region are, the external oblique, the internal
oblique, the transversalis, the rectus, and, occasionally, the pyramidalis ; being ten in the
whole, five on each side.
The Obliquus Externus Abdominis.
Dissection. — 1. Make an incision through the skin of the abdomen extending from the
cartilage of the eighth rib obliquely downward and inward, dividing, at the same time,
the very firm layer of cellular tissue which immediately covers the muscle. 2. During
the preparation of this, as well as 2ill the other abdominal muscles, place a block under
the loins, and in the dissection follow exactly the direction of the muscular fibres.
The great or external oblique muscle of the abdomen {o,fig. 106, and a, fig. 109), so call-
ed from the direction of its fibres (ob-
liquus descendens), forms the most su-
perficial muscular layer of the abdom-
inal parietes, on the sides and front of
which it is situated : it is very broad,
quadrilateral, and curved upon itself.
Attachments. — It arises from the ex-
ternal surfaces and lower borders of
the seven or eight inferior ribs, and is
inserted into the anterior half of the ex-
ternal lip of the crest of the ilium, into
the external edge of the anterior ab-
dominal aponeurosis, and by it into the
linea alba. The upper or costal attach-
ments consist of seven or eight angu-
lar tongues, or digitations, fleshy and
tendinous in their structure, and arran-
ged in an oblique line, running down-
ward and backward.
These digitations increase in size
from above downward, as far as the
eighth rib, and then diminish to the
twelfth. The four or five superior di-
gitations are interposed, like the fingers
of the two hands (whence the name),
between similar prolongations of the
serratus magnus. The three or foui
lower digitations between those of the
latissimus dorsi, by which they are
covered. This series of costal attach-
ments constituting the upper edge of
the muscle, represents a serrated curv-
ed line, the convexity of which is di-
rected upward and backward.
The first digitation is attached close
to the cartilage of the corresponding
rib, the succeeding ones are farther
and farther removed from the first, and the last is inserted into the apex of the cartilage
of the last rib.
THE OBLiaUUS INTEENUS.
20d
From these attachments the fleshy fibres proceed in different directions : the poste-
rior pass nearly vertically downward, the middle obliquely downward and inward, and
the upper almost horizontally inward ; the posterior terminate by short tendinous fibres
at the crest of the ilium ; the anterior at the external concave edge of a broad aponeu-
rosis, which forms the superficial layer of the anterior abdominal aponeurosis, and, by
interlacing with the corresponding structure of the opposite side, concurs in forming the
linea alba, and is folded upon itself below, to form the crural arch, or Poupart's ligament.
(See Aponeurolggy.)
It should be remarked, that the fibres of the external oblique follow exactly the me
direction as those of the external intercostal muscles.
Relations. — The external oblique is covered by the skin, a considerable quantity o*
adipose tissue, and behind by a small portion of the latissimus dorsi. It covers the in-
ternal oblique, the anterior extremities, and the cartilages of the seven or eight inferior
rib's, together with the corresponding external intercostal muscles. The most remark-
able relation is that of its posterior border with the outer edge of the latissimus dorsi.
Most commonly this border is covered by the latissimus dorsi ; but sometimes a trian-
gular space exists between them, which has been much noticed since Petit described a
hernial protrusion in it, which he called lumbar hernia.
Action. — The external oblique performs a threefold action: 1. It compresses the ab-
dominal viscera during any exertion, or in expulsion of the faeces, in labour, &c. ; 2. It
depresses the ribs, and thus indirectly flexes the vertebral column ; 3. From its obliquity,
it rotates the vertebral column, through the medium of the ribs, so that the fore part of
the trunk is turned to the opposite side. When the two muscles act together, the tho-
rax is inclined directly forward. Hitherto we have supposed that the movable point of
the muscle is at the ribs ; if, on the contrary, the thorax be fixed, it then draws the pel-
vis upward, and rotates the vertebral column, so that the fore part of the pelvis is turn-
ed to the same side as the contracting muscle.
The Obliquus Internus, and the Cremaster.
Dissection. — Divide the external oblique across the direction of its fibres, i. e., down-
ward and backward.
The small or internal oblique of the abdomen (obliquus ascendens, p,Jig: 106, and a, Jig.
110) is a broad, irregularly-quadrilateral mus- Fig.llO.
cle, much broader in front than behind, and
smaller and thinner than the preceding. It
occupies the anterior, lateral, and posterior
parts of the abdomen.
Attachments. — It arises from the spinous
processes of the lumbar vertebrae, from the
anterior three fourths of the interval between
the borders of the iliac crest, and from the
crural arch (Poupart's ligaments). It is in-
serted into the lower edges of the cartilages
of the ninth, tenth, eleventh, and twelfth ribs,
and into the linea alba by means of the mid-
dle layer of the anterior abdominal aponeu-
rosis. The spinal fibres take their origin
through the medium of the posterior abdomi-
nal aponeurosis : they are few in nmnber.
The iliac portion of them arise by very short
tendinous fibres, and those which proceed
from the crural arch arise from the sort of
groove situated on its upper surface. From
this threefold origin the fibres proceed in dif-
ferent directions : the posterior almost verti-
cally upward ; those which arise from the
crest of the ilium obliquely upward and in-
ward, becoming longer and more oblique an-
teriorly ; those which proceed from near the
anterior superior spinous process of the ilium
are horizontal ; and, lastly, those which arise
from the crural arch pass obliquely downward
and inward. The posterior fibres terminate
at the lower edge of the cartilages of the four
inferior ribs, and are continuous with the in-
ternal intercostal muscles, in the intervals
between the tenth and eleventh and eleventh and twelfth ribs, indicating the analogy
between these muscles. I have often observed the insertion into the last rib to be
wanting. The middle fibres, which are the most numerous, terminate at the external
Dd
210 MYOLOGY.
edge of the middle layer of the anterior abdominal aponeurosis. The fibres arising from
the crural arch are few in number, pale, and fasciculated ; some terminate at the pubes,
passing behind the inguinal or external abdominal ring ; others proceeding from the
ring, in the male, form the cremaster muscle.
Relations. — It is covered by the external oblique, and behind by a small portion of the
latissimus dorsi ; and it lies superficially to the transversalis. The most important re-
lations are those of its inferior edge with the inguinal ring of the external oblique, which
it partly closes on the inner side, as Scarpa and Bichat have well pointed out, and with
the spermatic cord, which passes beneath it, and, during the descent of the testicle,
draws with it some of the lower fibres of the muscles ; and hence the looped arrange-
ment they assume.
The cremaster. The loops so well described by M. Jules Cloquet are very variable,
and do not always appear to me to constitute the entire muscle. According to this
anatomist, the cremaster is nothing more than the lower fibres of the internal oblique,
that had been entangled with the testicle during its descent, forming loops in front of the
cord, the concavity of which is directed upward, and which may be traced to the bottom
of the scrotum. But I have often been convinced, from the examination of subjects in
which the cremaster was much developed, that this muscle {b, Jigs. 109, 137) consists
principally of a longitudinal fasciculus, partly derived, it is true, from the lower fibres of
the internal oblique, but consisting partly, also, of proper fibres arising from the crural
arch, near the external pillar of the ring ; and that this fasciculus is lost upon the proper
sheath of the cord, to which it is intimately united. The oflSce of this muscle is to
raise the entire testicle. The slow vermicular motion observed in the scrotum during
the venereal orgasm, or from the action of cold, is not at all connected with it.
The actions of the internal oblique are, 1. Compression of the abdominal viscera; 2.
Depression of the ribs, and, consequently, flexion of the trunk ; 3. Rotation of the trunk,
so that the fore part of the body is turned to the same side. The right internal oblique,
therefore, co-operates with the left external oblique ; when it acts with its fellow, the
thorax is drawn directly towards the pelvis ; but if the chest is fijced, they move the pel-
vis upon the loins.
The Transversalis Abdominis.
Dissection. — 1. Make a horizontal section of the internal oblique ; 2. Dissect with care
the two flaps of this nmscle, following the direction of the fibres of the transversalis ; 3.
In order to obtain a good view of the costal attachments, open the abdomen and exam-
ine them on the inner surface of the ribs ; this may be omitted until the diaphragm is to
be inspected.
The transversalis abdominis, so named from the direction of its fibres, is situated more
deeply than the two preceding muscles, and, like them, is irregularly quadrilateral (b, fig.
110).
Attachments. — It arises from the six lower ribs, from the anterior three fourths of the
internal lip of the crest of the ilium, and from the spinous and transverse processes of
the lumbar vertebrae. It is inserted into the linea alba by means of the deep layer of
the anterior abdominal aponeurosis. The costal attachments consist of fleshy digita-
tions interposed between those of the diaphragm, the two muscles being actually contin-
uous at the two inferior intercostal spaces ; the vertebral attachments are efiected by
means of the posterior abdominal aponeurosis ; and from the ilium it arises by very
short tendinous fibres internally to the small obliqije. From these three origins the fleshy
fibres proceed parallel to each other and horizontally inward ; the lower ones alone are
slightly inclined downward and inward ; the middle fibres are the longest. They are all
inserted into the external convex edge of a tendinous expansion, which constitutes the
posterior layer of the anterior abdominal aponeurosis.
Relations. — The transversalis is covered by the internal oblique, and rests upon the
peritoneum, from which it is separated by a fibrous lamina, which is very distinct in
front, where it is named the fascia transversalis.
Actions. — 1. It acts more powerfully upon the abdominal viscera than any of the pre-
ceding muscles, compressing them strongly, like a girth, against the vertebral column,
and assisting greatly in the process of defecation. 2. It draws inward the rib to which
it is attached, and thus materially assists in expiration.
The Rectus Abdominis.
Dissection. — 1. The subject being laid upon its back, place a block under the loins ; 2.
After having removed the skin, make a vertical incision through the strong aponeurosis,
at about two fingers' breadth from the linea alba ; 3. Dissect off the two flaps inward and
: outward. The adhesions between this aponeurosis and the muscle are, however, so in-
'timate at many points, that it is impossible to separate them.
The rectus abdominis (c, fig. 110) is situated at the anterior and middle part of the ab-
domen on each side of the linea alba, and occupies the sp.^ce between the pubes and the
. cartilage of the fifth rib. It is flattened like a riband in front and behind ; it is about
THE RECTUS ABDOMINIS.
three or four fingers' breadth wide above, and only two below. Its breadth is generally
in an inverse proportion to its thickness.
Attdchmcnts. — It arises from the upper edge of the os pubis, in the space between the
spine and the symphysis ; and is inserted in front of and below the cartilage of the sev-
enth rib and costo-xiphoid ligament, to the cartilages of the fifth and sixth ribs, and
sometimes to the bone also.
The pubic attachment is a flat tendon, consisting of two very distinct portions, of
which the external is the larger. This tendon is continuous by its external border Avith
the fascia transversalis. It is separated from its fellow of the opposite side by a very
narrow and thick fibrous septum, which forms the lower part of the linea alba. Some-
times the internal tendinous fibres intersect with those of the opposite side in front of
the symphysis pubes ; and some fleshy fibres often arise from the sides of the linea alba.
The presence or absence of the pyramidalis affects the size of the lower part of this
muscle. From this tendinous origin the fleshy fibres proceed vertically upward (whence
the name oi rectus). At the upper part, where they are prolonged in an expanded form
upon the thorax, they are slightly oblique from within outv^ard, and divided into three
unequal portions : the internal, the smallest, is attached to the cartilage of the seventh
rib and to the costo-xiphoid ligament ; the middle, which is larger, is fixed to the carti-
lage of the sixth rib ; and the external, by far the largest, to the cartilage of the fifth rib.
Very often a small portion of the muscle is insertad into the base and edges of the xi-
phoid cartilage, thus justifying the name of stemo-puhien given to it by Chaussier. It is
not uncommon to find this muscle give off a fourth bundle to the fourth rib, and even an
aponeurotic expansion to the sterno-cleido-mastoid. The rectus is interrupted by two,
three, four, or five tendinous intersections, which pass transversely or obUquely across the
muscle in a flexuous or zigzag course, seldom occupying either the entire thickness or
width of the muscle, which they divide into so many smaller muscles. There are always
more intersections above than below the umbilicus.
Relations. — This muscle is contained in a very strong tendinous sheath, which is form-
ed by the anterior abdominal aponeurosis, is thicker in front than behind, much stronger
below than above, and completely isolates the muscle. Below and behind, this sheath
is deficient, in which situation the muscle (passing through the openings. Jig. 1 10, in the
aponeurosis of the transversalis) rests directly upon the peritoneum ; the upper and pos-
terior part of the sheath is also wanting, so that the muscle is in immediate contact
with the cartilages of the fifth, sixth, seventh, eighth, and ninth ribs, and with the cor-
responding intercostal muscles. The linea alba occupies the interval between the two
muscles, which is much larger above than below the umbilicus ; but the most important
of all the relations of the rectus is that of its posterior surface with the epigastric artery,
which we shall hereafter notice.
Actions. — This muscle, having its fixed point below, and its movable attachments di-
vided between the fifth, sixth, and seventh ribs, depresses the whole thorax, and, con-
sequently, the vertebral column. Few muscles are so favourably situated as the rectus,
which both acts upon a very long lever, and is inserted at right angles to the part to be
moved.
As the rectus forms a curve, the convexity of which is directed forward, and cannot
contract without becoming rectilinear, it follows that the first effect of its contraction is
the compression of the abdominal viscera; hence it assists in expelling the contents of
the bladder, rectum, and uterus ; it aids in expiration, by depressing the ribs, and, by
keeping them fixed when the thorax is dilated, it assists in the performance of any ef-
fort. \\Tien the fixed point is above, the rectus becomes a flexor of the pelvis.
What are the uses of the intersections 1 It is generally stated that their effect is to
increase the number of fibres, and thereby augment the force of the muscle ; and in sup-
port of this a principle is adduced, which is incontestable in itself, viz., that the power
of a muscle is in a direct ratio to the number of its fibres ; for if each fibre represent one
partial power, the more of these the greater must be the total power. But it has been
overlooked, that this law only applies to fibres arranged side by side, not to those which
are placed end to end. In fact, it may be experimentally shown that, when two equal
forces are applied to a lever, parallel to each other, they produce double the effect either
would have done separately ; but if one be made continuous with the other, and both are
then applied to the same lever, they only produce an effect equal to that of either per se.
These intersections, therefore, do not increase the power of the muscle ; nor do they
diminish the extent of motion, for the sum of the contractions of the small muscles into
which they divide the recti is equal to that of an undivided muscle. What, then, are
the uses of these intersections 1 Can it be intended, as Bertin has said, to associate
the obUque muscles with the recti by means of the intimate adhesions existing between
.them and the aponeuroses 1*
* Benin considers these adhesions as true points of attachment tor the muscles of the aiitlomeii, so that
when the rectus contracts, it acts :iot only upon tho pubes, but also upon the crests of tlie ilia, through the
medium of the abdominal aponeuroses. Professor Berard, who Irmgs forward this forgotten opinion of Ber-
tin iRipert. Gentr. dcs Sc. Med., art. Abdomen), correctly observes, that tho obliquus internus only adheres
to tho rectus. In the same aficle M. Biirard declares he is not satisfied that the intersections increMe the
, I \ver of the recti muscles.
SICI^
MYOLOGY.
;, v'-.r; wV^jtU-TSia The Pyramidalis. •:^^^^>^.^At.::<
The pyramidalis {d, fig. 1 10), a small triangular muscle which is often deficient, occu-
pies the lower part of the abdomen on each side of the linea alba. It arises from the
pubis and the anterior ligament of the symphysis by tendinous fibres, from which the
fleshy portion proceeds upward, the internal fibres vertically, the external obliquely up-
ward and inward, and terminates by a pointed extremity, which is attached to the hnea
alba, and forms the apex of the muscle, the base being at the os pubis. It is covered
by the aponeuroses of the obliqui and transversalis muscles, and rests upon the rectus.
The lower part of the rectus and the pyramidalis are united together. When the latter
is wanting, the lower end of the rectus is proportionally increased in size, and vice versa-
There are sometimes two pyramidales on one side, and one on the other ; sometimes the
two are of unequal size. In a negro I found them extending beyond the middle of the
space between the pubis and the umbilicus.
Action. — It is a tensor of the linea alba.
DIAPHRAGMATIC REGION.
T^e Diaphragm.
Dissection. — Description. — Attachments. — Relations. — Action.
Dissection. — In order to expose this muscle, it is necessary to open the abdomen and
remove all the abdominal viscera, taking great care in detaching the liver, stomach, and
Kidneys. Tie the oesophagus and vena cava where they pass through the diaphragm,
and cut them below the ligature. Raise the peritoneum with the fingers or forceps, and
tear it gently away ; thus exposing the lower surface of the muscle without using the
scalpel. All the insertions of the diaphragm are well seen on this surface. In order to
study the convex surface of the muscle, another subject should be provided, and the tho-
rax opened before the abdomen. This is the only method by which a good idea of it can
be obtained ; for when the abdomen has been previously opened, the muscle becomes
relaxed as soon as the thorax is cut into, and affords no idea of its naturally vaulted form.
The diaphragm (septum transversum, a a, fig. Ill), which exists in mammalia only
p^ jlj is, according to the expression of Haller, with the
exception of the heart, the most important muscle.
I in '\ f f \U\ of the body. It is a muscular septum, sitotticd ob-
liquely at the junction of the upper with the two
lower thirds of the trunk. It separates the thorax
-a from the abdomen, constituting the floor of the for-
mer and the roof of the latter. All other muscles
,^ are placed on the outside of, or around, the levers
which they are intended to move ; but the diaphragm
alone is situated within those levers, like the mus-
cles of animals having an external skeleton.
The diaphragm divides the body into two unequal
parts : an upper, or supra-diaphragjnatic ; and a lower,
or infra-diaphragmatic. It is placed on the median
line, but is not symmetrical. It is elliptical in form,
its longest diameter being from side to side, thin and
flattened, and resembles an arch, or, rather, a fan,
the broad and circular portion of which is horizon-
tal, while the narrow part is vertical, and at right
angles to the former. The older anatomists, there-
fore, divided it into two portions : the upper, or great
muscle of the diaphragm ; and the lower, or small m)is
cle of the diaphragm.
Attachments. — It arises partly from the lumbar re
gion of the vertebra, column, in front of the bodies and intervertebral substances of the
second, third, and fourth lumbar vertebra? ; partly from the posterior surface of the ster-
num and the base of the ensiform cartilage ; and partly from the posterior surface and
upper edge of the cartilages and contiguous bony portions of the seventh, eighth, ninth,
tenth, eleventh, and twelfth ribs. Sometimes it is attached also to the sixth rib.
The vertebral origin consists of two tendons, formed by several smaller vertical ten-
dons, situated in front of each other, which are blended with the anterior common liga-
ment of the spine. To these tendons two thick, fleshy bundles succeed, which pass ver-
tically upward, become gradually thicker and broader, give off" a fasciculus to each other, •
and are inserted into the posterior notch in the aponeurosis, having the form of a trefoil
leaf, which forms the centre of the muscle, and is therefore called the central aponeurosis
of the diaphragm {b, fig. 1 1 1), or cordiform tendon. These two fleshy bundles and their ten-
dons (c c) are named the pillars, crura, or appendices of the diaphragm. The right crus
THE DIAPHRAGM. 213
IS anterior, larger, and descends lower down than the left. Each pillar is occasionally
divided into two very distinct secondary pillars, and the trace of this division is always
visible in the opening which gives passage to the great splanchnic nerve. The two pil-
lars of the diaphragm leave between them an interval, divided into two portions or rings
by the fleshy fasciculi which they mutually give to each other. The communicating fas-
ciculus from the right pillar is anterior, and larger than that from the left. Of the two
openings (ir rings between the pillars of the diaphragm, the loxcer or aortic {d) is parabolic,
and gives passage to the aorta, the vena azygos, the thoracic duct, and sometimes, also.
to the left great sympathetic nerve. Like all orifices through which arteries pass, it is
aponeurotic in its structure, being formed by the tendons of the pillars of the diaphragm
at the sides, and above by a fibrous prolongation of those tendons, which arches over
and completes the ring : the upper or (Esophageal opening (e) gives passage to the oesoph-
agus and the pneumo-gastric nerves; it is elliptical, and altogether muscular. In one
subject, however, I found the upper part tendinous ; and in another, a small muscular
fasciculus proceeded from the edge of the orifice, and was lost upon the coats of the
oesophagus. Haller has twice observed the same peculiarity.
A fibrous prolongation proceeds outward from the tendon of each crus, and is fixed to
the base of the corresponding transverse process of the first lumbar vertebra, so as to
form an arch on each side (fig. Ill), under which the upper end of the psoas muscle pass-
es (ligamentum arcuatum proprium). Another aponeurotic arch, which has been improp-
erly called ligamentum arcuatum {ligament cintre du diaphragme), for it is nothing more
than the upper edge of the anterior layer of the aponeurosis of the transversalis muscle
folded upon itself, extends from the outer extremity of the preceding arch to the lower
border and apex of the last rib ; under it passes the superior portion of the quadratus
lumborum muscle {fig. 111). From both these arches muscular fibres pass forward, and
are inserted into the corresponding part of the cordiform tendon. Indeed, the five ten-
dinous arches which we have just described, viz., the aortic in the middle, and the two
on each side for the psoas and quadratus lumborum muscles, give origin to all the fleshy
fibres which terminate at the posterior notch of the central tendon of the diaphragm
The existence of these arches led Haller and Scemmering to reckon three or four crura
on each side. The cordiform tendon in which the preceding muscular fibres are insert-
ed serves, in its turn, as the origin of other fibres, which constitute the vault of the dia
phragm. This central aponeurosis (i), to which so much importance was attached by
the ancients, under the name of the phrenic centre, and which some modern anatomists
regard as the central point of the entire aponeurotic system of the human body, occupies
the middle of the vault of the diaphragm, immediately below the pericardium, with which
its circiunference is blended in adults, but from which it may be easily separated in young
subjects : it is a sort of aponeurotic island, surrounded on all sides by muscular fibres,
and converting the diaphragm into a true digastric muscle. In form, it resembles a tre-
foil leaf, with a notch in the situation of the pedicle ; each division is called a wing or
leaflet ; the middle leaflet is the largest, the right the next, and the left the smallest. Be-
tween the right and the middle le^et is an opening (/), sometimes converted into a ca-
nal for the inferior vena cava. This orifice is entirely tendinous, and of a quadrangular
shape when the vena cava is removed. It is bounded by four tendinous fasciculi, which
meet at right angles. The cordiform tendon is itself composed of several planes of fibres ;
the principal of which consists of a diverging series, running forward, and uniting into ir-
regular, straight, or curved bundles, which intersect each other at various angles ; an
arrangement that gives great strength to the tendon. The fleshy fibres are attached to
all points of the circumference of this tendon, and radiate from it in all directions. The
anterior, very short, and sometimes aponeurotic, proceed to the base of the ensiform car-
tilage, describing a slight curve, with the concavity directed downward. A triangular
interval, or else several small spaces, are often left between these fibres, establishing a
communication between the cellular tissue of the thorax and that of the abdomen.
Hence, diaphragmatic hernias occasionally occur ; and pus, formed in the neck or medi-
astinum, may ultimately point at the epigastrium. It is not uncommon to find the ster-
nal attachment of the diaphragm partially or entirely deficient. ^
The lateral muscular fibres, which are much longer than the anterior, describe very
well-marked curves, and form an arch, with the concavity downward, but more convex
and projecting on the right than the left side. They then divide into six or seven digi-
tations on each side, which are attached to the ribs, intersecting with the costal inser-
tions of the transversalis abdominis. It is not uncommon to find considerable intervals
between the digitations of this muscle, opposite which the pleura and peritoneum are in
contact ; this more especially occurs between the eleventh and twelfth ribs. The fas-
ciculus for the twelfth rib is sometimes deficient, its place being occupied by a tendon.
The direction of the fibres of the diaphragm is then radiated and curvilinear in the hori-
zontal portion, but radiated and rectilinear in the vertical portion.
Relations. — 1. The inferior or abdominal surface, concave in the middle, and much more
concave on the right side, where it corresponds to the convex upper surface of the liver,
than on the left, where it is in contact with the spleen and the large extremity of the
214 MYOLOGY.
Stomach, is covered by the peritoneum throughout the greater part of its exteiit, except-
ing at the situation of the coronary ligament of the liver, and also behind, where it is in
relation with the third portion of the duodenum, the pancreas, the kidneys, the supra-
renal capsules, and the solar plexus.
2. Thoracic, or upper surface. The middle portion is convex, and covered by the pleu-
ra and pericardium ; it is flat, and serves as a floor to support the heart, the inferior sur-
face of which rests upon it ; hence the pulsations of the heart felt in the epigastrium.
The lateral portions are convex, and contiguous to the lungs. The convexity is greater
on the right than on the left side : the highest point to which the right side reaches, in
the natural condition, is the level of the fourth rib ; the highest point which the left side
attains is opposite the fifth rib. Hence the surgical rule of operating for empyema high-
er on the right than on the left side.*
The height to which the diaphragm is raised varies remarkably ; it reaches very much
higher in the foetus than in the adult. Should the muscle be only slightly vaulted, it is
considered by medical jurists as one of the presumptive proofs that the infant has respired.
3. Circumference. — ^With the exception of the crura, the diaphragm is connected by its
circumference only with one muscle, viz., the transversalis, which presents exactly cor-
responding attachments, so that, indeed, these two muscles may be considered as form-
ing one contractile sac, interrupted by the costal insertions.
Action. — The diaphragm forms an active septum between the thorax and abdomen,
which affects the viscera of both cavities. The two pillars act like the long muscles ;
the body of the diaphragm after the manner of the hollow muscles. When the pillars
contract, they take their fixed point upon the lumbar vertebrae, and their movable point
upon the notch at the back of the cordiforra tendon, which is carried backward and down-
ward. This aponeurosis, in its turn, becomes a fixed point for all the other curved ra-
diated fibres that are attached to the ribs. The first effect of the contraction of a curved
fibre is its becoming straight ; and, in this process, the highest part of the curve is drawn
down towards a level with its extremities : the vertical diameter of the thorax is, there-
fore, increased, and that of the abdomen proportionally diminished ; but, during contrac-
tion, the fibres act equally upon both their points of insertion, and, as the cordiform ten-
don is fixed, and the costal attachments are movable, the ribs are drawn inward, and the
transverse diameter of the thoracico-abdominal cavity thereby diminished. The antero-
posterior diameter would be equally diminished, were it not for the inclination of the di-
aphragm downward and backward, in consequence of which the abdominal viscera are
pressed downward and forward. Some experimentalists, among whom we may men-
tion Haller and Fontana, have asserted that the diaphragm may become convex below
during a forced contraction, but I beheve this can only take place when air has been ad-
mitted into the cavity of the pleura.
We shall now consider the effects of the contraction of the diaphragm upon the open-
ings by which it is perforated.
The elliptical, or, rather, oval opening for the oesophagus, being entirely muscular, is
contracted during the action of the diaphragm, in the same manner as the mouth by that
of the orbicularis muscle : hence the oesophagus is compressed. From this it has been
concluded that vomiting cannot take place during inspiration, but experience proves the
contrary, vomiting being favoured by this compression.
It is generally said that the orifice for the vena cava is not affected by the contraction
of the diaphragm ; but if we draw upon the muscular fibres in the neighbourhood of this
opening, we see at once that it is diminished in size ; HaUer has even witnessed this in
a living animal during inspiration. The arch, or, rather, the parabolic canal, which gives
passage to the aorta, is also contracted, and the vessel slightly compressed ; hence,
doubtless, arises the frequency of aneurisms of tliis artery, where it passes through the
pillars of the diaphragm.
LUMBAR REGION.
The Psoas and Illiacus. — Psoas Parvus. —Quadratus iMmborum.
The lumbar region includes the psoas and iliacus, the psoas parvus (when it exists),
and the quadratus lumborum.
7'he Psoas and Iliacus.
I consider that, since the psoas and iliacus muscles have a common insertion, they
should be described as a single muscle, having a double origin, which we shall term the
psoas-iliac muscle.
Dissection. — Having opened the abdomen, tear away with the fingers the peritoneum
covering the iliac fossae and the lumbar regions. Remove, at the same time, the intes-
* This rule should be disregarded : the object of it is to open the thorax at the lowest part, so as to give a
more easy exit to the liquid ; but the lowest portion would be behind, in the deep groove formed by the dia-
phragm with the parietes of the thorax. It is of little importance to find the most depending part ; it is suf-
ficient to establish an outlet ; the fluid will always flow to it.
THE PSOAS ANDi,ILIACUS. 215
tines, the stomach, the pancreas, the kidney, the liver, and the spleen ; detach the iliac
fascia. In order to see the femoral insertion of this muscle, divide the crural arch
through the middle. Dissect with care the muscles at the anterior and superior part of
the thigh, especially the pectineus, with which this muscle is in immediate relation
Remove the adipose cellular tissue which surrounds the crural vessels and nerves.
The psoas-iliac muscle is deep-seated, and extends from the sides of the vertebral
column and front of the iliac fossa to the lesser trochanter of the femur. It arises above
by two very distinct muscular masses ; an internal, long, or lumbar portion '[lumbaris,
sive psoas, Riolanus), the great psoas of authors ; and an external, broad, or iliac portion,
constituting the iliacus (iliacus intemus, Albinus).
1, The lumbar portion (psoas magnus, from tpdai, the loins, g g, Jig. Ill) arises from
the sides of the bodies of the five lumbar and last dorsal vertebrae, and of the correspond-
ing inter- vertebral substances, and from the base of the transverse processes, by means
of aponeurotic fibres, united by tendinous arches, which correspond to the grooves on
the bodies of the lumbar vertebrae, so that the muscle is, in reality, only attached to the
upper and lower borders of the bodies of the vertebra, and to the inter-vertebral sub-
stances. From this double origin the fleshy fibres proceed in the form of a conoid bun-
dle, compressed on the sides, and directed obliquely downward and outward ; the sum-
mit of the cone is flattened, and embraced by the ligamentum arcuatum ; the body is
thicker and rounded, and diminishes in size inferiorly, as its constituent fibres are grad-
ually attached to a tendon, which, though at first concealed in its centre, afterward ad-
vances towards the anterior and external surface, receives the fibres of the iliacus, and
is inserted into the lesser trochanter of the femur. The great psoas, therefore, resem-
bles a double cone or spindle.
Its component fibres are not fasciculated, but are united by a very delicate cellular
tissue. The complete absence of fibrous tissue explains the weakness of this muscle,
which may be torn with the greatest facility, and perhaps, also, the frequency of its dis-
eases. Its tenderness in the ox causes it to be a favourite joint for the table, under the
name of short ribs (aloyau) : perhaps this delicacy of texture is connected with the pres-
ence of a large plexus of nerves in the substance of the muscle.
2. The iliac portion (iliacus muscle ; iliacus intemus, Alb., i i,fig. Ill) fills the internal
Uiac fossa. It arises from the whole of this fossa, from the crest of the ilium, the ilio-
lumbar ligament, and the base of the sacnun, and from the anterior superior iliac spine,
the notch below, the anterior inferior iliac spine, and even the capsular ligament of the
hip-joint. The fleshy fibres converge, and are immediately attached to the external
edge of the common tendon, which we have described as originating in the substance of
the psoas. This tendon, which receives on its inner side all the fibres of the psoas, and
even those fibres of the iliacus which arise from the brim of the pelvis, runs along the
side of the brim, diminishing its transverse diameter, and emerges from the pelvis under
the crur£d arch, passing through a remarkable groove between the anterior inferior spi-
nous process of the ilimn, and the eminentia ilio-pectinea. In this situation all the fibres
of the psoas terminate ; those that remain of the iliacus are successively attached to
the outside of the tendon, like the barbs of a feather to the shaft, and form a triangular
fleshy bundle, which inmiediately changes its direction, passes backward, inward, and
downward among the muscles of the thigh, turns slightly round, so that its anterior sur-
face looks somewhat inward, and its posterior surface outward, and is inserted into the
lesser trochanter, which it embraces on every side, even to its base. It is not uncom-
mon to find the fasciculus which comes from the anterior inferior spinous process of the
iUum and the capsular ligament forming a very distinct muscle, which has been often
described separately, under the name of the ilio-capsulo-trochantericus ; it is inserted
separately below the lesser trochanter into the oblique line which extends from this pro-
cess to the linea aspera.
Relations. — 1. The lumbar portion (psoas magnus) is in relation anteriorly with the
diaphragm, the kidney, the ascending colon on the right side, the descending colon on
the left, the peritoneum, and the psoas parvus, when it exists. The external Uiac artery
and vein run along the anterior surface. On the inside it corresponds to the bodies of
the lumbar vertebrae and the lumbar vessels ; behind, to the transverse processes of the
lumbar vertebrae and the quadratus lumborum. The lumbar plexus is situated posterior-
ly in the substance of the psoas magnus ; this explains the violent pain in the loins ex-
perienced during repeated contractions of this muscle, and, during pregnancy, from the
pressure of the gravid uterus. 2. The iliac portion lines the iliac fossa ; it is covered
by the peritoneum, the caecum, and the end of the small intestines on the right side, and
by the sigmoid flexure of the colon on the left. These two muscles form a projection on
the inside, which reduces the transverse diameter of the brim of the pelvis from five
inches to four and a half 3. The psoas and iliacus exactly fill that portion of the crural
arch in which they are placed, so that hernias never take place in this situation. 4. In
the thigh, the common tendon is separated anteriorly from the cellular tissue of the
groin by the deep femoral fascia ; it is in relation with the crural nerve, which passes
out of the pelvis in the same sheath as, but below, the psoas, in a groove between the
iJ16 MYOLOGY.
latter and the iliacus, between which parts it forms the only separation. Behind, it is in
contact with the anterior border of the os coxae and the hip-joint, a large bursa inter-
vening, which often communicates with the synovial capsule of the joint, by an opening
of variable size.* The inner edge of the psoas-iliac muscle is in relation with the outer
edge of the pectineus, and with the femoral artery, which it sometimes covers. The
external edge is at first in relation with the sartorius, and afterward with the rectus
femoris. The psoas-iliac is also covered by the lumbo-iliac fascia {fascia iliaca), which
will be described hereafter. (Vide Aponeurology.)
Actions. — The psoas-iliac muscle flexes the thigh upon the pelvis ; this action is the
more energetic from the fact of the fixed points of insertion being both on the vertebral
column, and on the iliac fossa. The two portions of the muscle do not act in the same
direction ; but when they contract simultaneously, the opposite forces are destroyed, and
the traction upon the common tendon becomes direct. This muscle affords a remark-
able example of the reflection of a muscle over a pulley, which greatly increases the
power, by changing the direction of insertion nearly to the perpendicular. The action
of this muscle, therefore, must only be calculated from the point of reflection, i. e., the
anterior edge of the ilium. It is in semiflexion that the muscle becomes perpendicular
to the femur, and acts with the greatest power ; and, therefore, the Tnomentum of the
muscle occurs at that period. The psoas-iliac is at the same time a rotator outward of the
femur, on account of the obliquity of its insertion at the inner and back part of that bone.
When the femur is fixed, as in standing, it draws the lumbar portion of the spine and the
pelvis forward ; and its iliac portion rotates the pelvis so as to turn the front to the opposite
side. When the muscles of each side act together, the trunk is inclined directly forward.
The Psoas Parvus.
This muscle (Z I, fig. Ill) lies in front of the preceding ; it arises from the twelfth dor-
sal vertebra, the first and sometimes the second lumbar vertebrae, and the corresponding
inter-vertebral substances. It forms a small, flat bundle, at first appearing to be a de-
pendance of the psoas magnus, but soon becoming isolated ; it terminates in a broad,
shining tendon, which crosses the psoas magnus at a very acute angle, and is inserted
into the upper part of the ilio-pectineal eminence, and the corresponding portion of the
brim of the pelvis. This small muscle receives the lumbo-iliac aponeurosis (fascia ili-
aca) on its outer edge. It is often absent ; we have sometimes seen it double. Its use
is evidently to render the iliac fascia tense, and to tie down and prevent displacement
of the lumbar portion of the psoas magnus. It may assist in flexing the pelvis upon the
thorax, as in climbing ; in the recumbent and supine position, if one muscle acts alone,
it inclines the pelvis to its own side ; but if its fixed point be below, it inclines the trunk
to the same side.
The Quadratus Lumborum.
Dissection. — Expose the posterior surface, by carefully detaching the common mass Oi
the posterior spinal muscles ; and to view the anterior, open the abdomen and remove
the viscera. This muscle is enclosed in a sheath formed by the anterior and middle lay-
ers of the posterior aponeurosis of the transversalis abdominis ; divide this sheath, and
the muscle will be completely laid bare.
The quadratus lumborum (m m, fig. Ill) is quadrilateral in shape, and broader below
than above ; it is situated in the lumbar region, on the sides of the vertebral column, be-
tween the crest of the ilium and the last rib.
Attachments and Direction. — It arises from the ilio-lumbar ligament, and from about
two inches of the adjacent part of the iliac crest, by aponeurotic fibres, which, on the
outer side especially, are very long. These fibres are bound down by others, crossing
them at right angles, and give origin to the fleshy part of the muscles, which proceeds
upward and a little inward, in the following manner : 1 . Some of the fibres pass verti
cally upward, and are inserted into the last rib, to an extent wliich varies in different in
dividuals. 2. Others are directed very obliquely inward, and divide into four fleshy bun-
dles, inserted, by means of a similar number of tendons, into the summits of the transverse
processes of the four superior lumbar vertebrae. 3. There is most commonly a third
plane, anterior to the preceding, and consisting of fibres, which arise from the summits
of the transverse processes of the third, fourth, and fifth lumbar vertebrse, and are in-
serted into the lower edge of the last rib.
Connexions. — The quadratus lumborum somewhat resembles the rectus abdominis, in
being enclosed and bound down in a very strong tendinous sheath ; it has, therefore, no
direct relations. In front are the kidney, the colon, the psoas, and the diaphragm ; be-
hind is the common mass of the spinal muscles, beyond which its outer border some-
what projects, especially below. Its most important relations are with the kidney and
the colon. It is the guide for the necessary incisions in operations performed in this re-
gion, particularly in nephrotomy.
* See note. p. 296.
INTEK-TRANSVERSALES, RECTUS CAPITIS LATERALIS, AND 8CALENI. 217
Action. — ^With its fixed point at the crest of the ilium, this muscle depresses the last
rib, by means of its costal insertions, thus acting as a muscle of expiration ; and it in-
clines the spine to its own side, through the medium of its vertebral attachment. With
its fixed point above, it inclines the pelvis to its ow^n side.
LATERAL VERTEBRAL REGION.
The Inter-traTisversales and Rectus Capitis Lateralis. — Scaleni.
The lateral muscles of the vertebral column are the inter-transversales of the neck
and loins, the rectus capitis lateralis, and the scaleni. The quadratus lumborum, already
described, belongs also to this region.
The Inter-transversales and Rectus Capitis Lateralis.
The inter-transversales muscles exist only in the neck and the loins ; in the back
they are represented by the intercostals, an additional proof of the analogy between the
ribs and the cervical and lumbar transverse processes. Many celebrated anatomists, how-
ever, admit the existence of inter-transverse muscles in the back, but they are nothing
more than deep-seated fasciculi of the transverso-spinalis.
1. Inter-transversales of the Neck {a to a, fig. 112). — There are two of these muscles in
each inter-transverse space, an interior and a posterior. They are small quadrilateral
muscles, one arising from the anterior, the other from the posterior margin of the groove
on the transverse process below : from these origins the fibres proceed vertically upward,
and are inserted into the transverse process of the vertebra above.
They are separated from each other by the anterior branches of
the cervical nerves and by the vertebral artery, the canal for
which they serve to complete. Behind, they are in relation Avith
the posterior spinal muscles, the splenius, the levator anguli
scapulas, the transversdis colli, and the cervicalis descendens ;
and in part with the rectus capitis anticus major.
2. Rectus Capitis Lateralis {h,fig. 112). — This muscle may be
regarded as the first posterior inter-transversalis of the neck, and
the rectus capitis anticus minor, which we shall presently de-
scribe as the first anterior inter-transversalis. The comparative
size of the rectus lateralis is not opposed to this view, for it is
connected with the increased development of the corresponding
cranial vertebra. It arises from the transverse process of the
atlas, and proceeds directly upward, to be inserted into the jugu-
lar surface of the occipital bone, immediately behind the fossa of that name. This mus-
cle separates the jugular vein, with which it is in contact in front, from the vertebral
artery, to which it is contiguous behind.
3. Inter-transversalis of the Loins. — The absence of any groove upon the lumbar trans-
verse processes would lead us at once to infer that in this region there must be only one
muscle in each inter-transverse space. There are, therefore, five on each side. The
first extends from the transverse process of the last dorsal to that of the first lumbar ver-
tebra ; and the last from the transverse process of the fourth to that of the fifth lumbar
vertebra.
Action. — These little muscles, by drawing the transverse processes towards each oth-
er, incline that portion of the vertebral column with which they are connected towards
their own side ; that is, the cervical muscles with the rectus lateralis incline the head
and neck, and those of the lumbar region act upon the loins.
The Scaleni.
Dissection. — These muscles are, in a great measure, displayed in the ordinary dissec-
tion of the anterior and posterior cervical regions. In order specially to expose them
upon an entire subject, it is sufficient to dissect off the skin on the sides of the neck, and
to remove the omo-hyoid, the nerves, the cellular tissue, and the sub-clavicular lymphat-
ic glands. But in order to demonstrate the inferior attachments of these muscles, the
upper limb must be scarified by disarticulating the clavicle at its sternal end, or, still bet-
ter, by sawing the clavicle through the middle, dividing the great and small pectoral mus-
cles, raising the stemo-cleido-mastoid, detaching the serratus magnus, and drawing the
apex of the shoulder forcibly backward.
The scaleni occupy the sides and lower part of the neck, extending from the two up-
per ribs to the six lower cervical vertebrae, sometimes to the atlas also. They are, there-
fore, fasciculated like all the other vertebral muscles. Anatomists are not agreed con-
cerning their number. Albinus enumerated five on each side ; Sabatier reduced these
to three •, but we agree with M. Boyer, and modern anatomists, in admitting the exist-
ence of two only, an anterior and a posterior. M. Chaussier has followed the example of ♦
Riolanus, in describing only one, which he calls costo-trachelien.
E E
•gJ8 MYOLOGY.
1. The scalenus anticus {c,figs. 112, 113, and 114) might be termed the anterior lorig in-
ter-transversalis colli. Its name sufficiently indicates its triangular shape, though it rathei
resembles a cone with the base below and the apex above.
Aitachments and Direction. — It arises from the inner margin and upper surface of the
first rib, near its middle, the point of attachment being indicated by a tubercle, with which
it is highly important that we should be acquainted, because it serves as a guide in pla-
cing a ligature upon the subclavian artery, which passes over the upper surface of the
first rib. It arises by means of a tendon that expands into an aponeurotic cone, from the
interior of which the fleshy fibres take their origin. These unite, form the body of the
muscle, and proceed upward and inward, to be inserted by so many separate tendons into
the anterior tubercles of the transverse processes of the sixth, fifth, fourth, and third cer-
vical vertebrae, and more especially into the notches between the two tubercles at the ex-
tremities of these processes. It is not unconmfion to find one or two fasciculi inserted
into the posterior tubercles.
Relations. — In front and on the outside, this muscle is in relation with the clavicle, from
which it is separated by the subclavian muscle and vein ; higher up, with the stemo-
mastoid, the omo-hyoid, the phrenic nerve, and the transverse and ascending cervical
arteries. Behind, it is separated from the posterior scalenus by a triangular space, which
is wide below to receive the subclavian artery, and narrow above, where it corresponds
to the brachial plexus of nerves, by the first two branches of which the muscle is some-
times perforated. On the inside, it is separated from the vertebral artery by the longus
colli. The relations of the scalenus anticus to the subclavian vein and artery are of the
highest importance to the surgeon, and, in order to impress them upon the memory, I
propose to designate it the muscle of the subclavian artery. I have seen both the artery
and vein placed in front of this muscle.
The scalenus posticus {d,figs. 112, 113, and 114) may be termed the posterior long inter-
transversalis colli. It is situated behind the preceding muscle, is of the same shape, but
somewhat larger.
Attachments and Direction. — It has two perfectly distinct origins : one, anterior and
larger, from all that part of the first rib intervening between the depression for the sub-
clavian artery and the tubercle ; and another, posterior, from the upper edge of the sec-
ond rib. The latter attachment is sometimes wanting. Proceeding from this double
origin, the fleshy fibres form two small muscular bodies, which either remain distinct, or
become blended together, and pass upward and inward, to be inserted by six separate
tendons into the posterior tubercles of the transverse processes of the six inferior cer-
vical vertebrae. It is not uncommon to find a fasciculus extending from the second rib
to the atlas.
Relations. — It is separated from the anterior scalenus by the subclavian artery and
brachial plexus ; and is in relation, behind, with the cervicaJis descendens, transversalis
colli, splenius, and levator anguli scapulae : on the outside, with the serratus magnus,
the transverse cervical artery, and the stemo-mastoideus : on the inside, with the first
intercostal, the first rib, the inter-transversales of the neck, and the cervical vertebrae.
Action. — The scaleni are powerful flexors of the neck, when their fixed points are be-
low ; but when their upper attachments are fixed, they tend to elevate the first rib, and
in a slight degree the second also.
DEEP ANTERIOR CERVICAL, OR PREVERTEBRAL REGION.
The Recti Capitis Antici, Major et Minor. — Longus Colli. — Action of these Muscles.
This region includes three pairs of muscles placed immediately in front of the cervical
and three superior dorsal vertebrae, viz., the rectus capitis anticus major, the rectus capi-
tis anticus minor, and the longus colli. Their arrangement is extremely complicated and
very difficult of elucidation, unless we consider them in the same general manner al-
ready adopted with regard to the disposition of the posterior spinal muscles. Let us
suppose, then, that there exists in the median line of the basilar process of the occipital
bone and the anterior surface of the bodies of the cervical vertebrae a series of spinous
processes (a supposition which is realized in some animals) ; then the rectus capitis an-
ticus major would be a transverso-spinalis, the rectus minor an anterior inter-transversalis
between the occipital bone and the atlas, and the longus colli would be a compound mus-
cle, its lower fibres forming a spino-transversalis, its upper fibres a transverso-spinalis,
and its internal fibres a spinalis. All this wiU be rendered apparent from the following
description.
Dissection. — Remove the face and all the parts which cover the cervical portion of the
spine by the vertical section, called the section of the pharynx, because it is also employed
in demonstrating that part. In order to separate the face from the cranium, remove the
roof of the scull by a horizontal section, and then make a vertical cut either from above
or from below ; if we cut from above, we may adopt the usual plan of directing the saw
transversely, so as to emerge immediately in front of the auditorj' meatus : in doing this,
THE RECTUS CAPITIS ANTICUS MAJOR, ETC. "!?t1)
however, we are in danger of injuring the superior attachments of the recti, or of cutting
into the pharynx. We prefer, therefore, the following method : make two sections with
the saw obliquely forward and inward in the course of the occipito-mastoid and petro-
occipital sutures, and having arrived at the basilar process, cut it across with a chisel,
a little in front of the anterior condyloid foramina. In separating the face from the cra-
nium from below upward, a great number of muscles must be scarified : the preceding
section is therefore preferable, although it is somewhat more difficult.
The Rectus Capitis Anticus Major.
This muscle {e,figs. 112 and 114), the transverso-spinalis anterior (rectus capitis in-
temus major, Alb.), is the most external of those in the prevertebral region.
Attachments and Direction. — It arises from the anterior tubercles of the transverse pro-
cesses of the sixth, fifth, fourth, and third cervical vertebrae, by small tendons, to which
as many fleshy fasciculi succeed ; these pass obliquely upward and inward, overlying
and blending with each other, and terminate on the posterior surface and edges of a shi-
ning aponeurosis, that occupies almost entirely the anterior aspect of the muscle. This
aponeurosis itself becomes a surface of origin, dividing into two lamina;, from the bor-
ders of and interval between which a fleshy bundle ascends, to be inserted into the basi-
lar process in front of the foramen magnum. The fasciculus arising from the third cer-
vical vertebra does not join the common insertion, but is attached directly, and in a very
distinct manner, to the basilar process within and behind the common fasciculus. The
muscle must be turned outward in order to display this structure.
Relations. — It is covered by the pharynx, the internal carotid artery and jugular vein,
the superior cervical ganglion and trunk of the great sympathetic nerve, and the par va-
gum, being separated from all these parts by some loose cellular tissue and the preverte-
bral aponeurosis. It covers the corresponding vertebrae, the articulation of the occipital
bone with the atlas, and that of the atlas with the axis, a portion of the longus colli, and
also of the rectus minor.
The Rectus Capitis Anticus Minor.
This muscle {f,fig- 112), the inter-transversalis anterior (re^ctus capitis internus mi-
nor, Alh.), extends from the base of the transverse process and from the adjacent part
of the lateral mass of the atlas, to the basilar process of the occipital bone. It is partial-
ly covered by the rectus major, which is nearer the mesial plane : the superior cervical
ganglion of the sympathetic rests upon it, and it covers the atloido-occipital articulation.
It may be regarded as an anterior inter-transversalis between the occipitcd bone and the
atlas, the rectus laterahs constituting the posterior inter-transversalis.
The Longus Colli.
Attachments, Direction, and Relations. — The longus coUi {g,g,figs. 112 and 114), as be-
fore stated, is composed of three very distinct sets of fasciculi : 1. The transverso-spina-
lis, which, arising by flat tendons from the anterior tubercles of the transverse processes
of the fifth, fourth, and third cervical vertebra;, unite so as to form a considerable fleshy
bundle directed upward and inward, occupy the hollow on each side of the median line
of the axis, and are inserted into the anterior tubercle of the atlas, which may be regard-
ed as the representative of an anterior spinous process : 2. The anterior spino-transver-
salis, the least numerous of all, arise from the bodies of the three superior dorsal verte-
brae by very slight tendinous expansions, proceed upward and outward, and are inserted
into the anterior tubercles of the transverse processes of the fourth and third cervical
vertebrae : 3. The spinalis which arise, to the inner side of the preceding fasciculi, from
the bodies of the three upper dorsal and four lower cervical vertebrae, and from the in-
termediate ligaments, and having described a slight curve, are inserted into the crest of
the axis and into the third cervical vertebra. The longus colli is elongated and fusiform
in shape ; it supports the pharynx, the oesophagus, the internal carotid artery, the inter-
nal jugular vein, and the pneumogastric and great sympathetic nerves : it covers the
vertebrae to which it is attached.
Action of the Muscles of the deep Anterior Cervical Region.
When the head is thrown back, these muscles restore it to its original position. The
rectus anticus major tends to flex the head, and from its obliquity to rotate it, so as to
turn the face to its own side. The rectus minor inclines the head to its own side. The
longus colli flexes the atlas upon the axis, and rotates it so as to turn the face to its own
Bide. '^I'he same muscle also rotates the lower part of the neck, so as to turn the face
to the opposite side • and, lastly, it is a direct flexor of the cervical region.
MYOLOGY.
THORACIC REGION
The Pectoralis Major. — Pectoralis Minor. — Subclavius. — Serratus Magnus. — Intcrcostales
— Supra-costales. — Infra-costales. — Triangularis Sterni.
The Pectoralis Major.
Dissection. — Separate the arm from the side. Make a horizontal incision from the top
of the sternum to the front of the arm on a level with the lower border of the axilla, in-
cluding in this incision a fascia which adheres closely to the fleshy fibres. Reflect one
of the flaps upward and the other downward, by dissecting parallel to the fibres, i. e.,
transversely to the axis of the body.
The ■pectoralis major (c c, fig. 109) is a broad, thick, triangular muscle, situated at the
upper and fore part of the thorax and axilla. It arises from the anterior border of the
clavicle and anterior surface of the sternum, from the cartilages of the second, third,
fourth, and more particularly those of the fifth and sixth ribs, from the osseous portion
of the last-mentioned rib, and from the abdominal aponeurosis : it \s inserted into the an-
terior margin of the bicipital groove of the humerus.
The clavicular origin consists of short tendinous fibres attached to the entire breadth
of the anterior border of the clavicle, for about the inferior third, or half of its extent.
The sternal attachment consists of aponeurotic fibres, which, intersecting with those of
the opposite muscle, form, in front of the sternum, a very thick fibrous layer, sometimes
ahnost completely covered by the muscular fibres, which, in certain individuals, advance
nearly to the median line.
The costal origins consist of very thin tendinous laminae, and the attachment to the
abdominal aponeurosis is blended with that of the rectus abdominis.
From these different origins the fleshy fibres proceed outward in different directions ;
the upper fibres obliquely downward, the middle transversely, and the lower fibres oblique-
ly. These last are folded backward, so as to form a sort of groove, which embraces the
lower border of the pectoralis minor. It appears, then, that the pectoralis major is com-
posed of three very distinct portions, which are sometimes separated by a greater or
less quantity of cellular tissue. These three portions, in converging, are so disposed that
the upper overlaps the middle, and this, again, the lower portion, the fibres of which are
twisted upon themselves, so that the lowest in front become the highest behind, and vice
versa.* They are all inserted into the anterior lip of the bicipital groove by means of a
flat tendon, about fifteen lines in breadth, which is continuous with the anterior edge of
the tendon of the deltoid. The structure of this tendon commands particular attention,
and can only be examined after having divided the muscle across, and turned the exter-
nal half outward. It will then be seen that it is composed of two laminae, placed one be-
fore the other, sometimes blended together, but generally distinct, or united only by
their lower edges, so that they form a groove opening upward. The anterior lamina is
the thicker, and receives the clavicular and middle portions of the muscle ; the deep lay-
er affords attachment to the lower portion. It is not uncommon to find the two laminae
separated by the tendon of the long head of the biceps, the groove for which they then
contribute to form. The entire tendon is broader and thicker below than above, and
gives off, both forward and backward, an aponeurotic expansion, constituting one of the
chief origins of the fascia of the arm.t
Relations. — It is covered by the platysma myoides, the mammary gland, and the skin.
Its deep relations are of the greatest importance. On the thorax it covers the sternum,
the ribs and their cartilages, the pectoralis minor, the subclavius nauscle, the serratus
m£ignus, and the intercostals. It forms the anterior wall of the axilla, and is in relation
with the brachial plexus and axillary vessels, and with the cellular tissue and lymphatic
glands of that region. Its external border is nearly parallel to the anterior edge of the
deltoid, being separated from the latter by a linear or triangular cellular interval, in
which are situated the cephalic vein and acromial artery. Its lower border is thin towards
the median line, thick and tendinous externally ; it forms the anterior border of the ax-
illa, and gives rise to a projection under the skin, proportionate to the development of the
muscle. Its inner border intersects in the median line with the muscle of the opposite
side, and is continuous below with the linea alba.
Uses. — The pectoralis major is essentially an addTictor of the arm ; at the same time it
rotates it inward, and draws it forward. It is by the action of this muscle that the fore-
arms are crossed, and that one hand is placed on the opposite shoulder. Its upper or
clavicular portion conspires with the anterior fibres of the deltoid and with the coraco-
brachialis in elevating the humerus, and carrying it forward.
* I believe that this overlapping and folding of the muscular fibres tend, reciprocally, to prevent the dis-
placement of any individual portion of the muscle.
t I have once observed a very slender muscular fasciculus, arising' from the abdominal aponeurosis, proceed
along the inferior border of the pectoralis major, from which it was perfectly distinct, and terminate in a small
tendon opposite the humeral insertion of that muscle. This tendon was continued along- the inner side of the
arm, adhered to the aponeurotic inter-muscular septum, from which it received a small fleshy fasciculus, and
was ultimately inserted into the epitrochlea
IHB FECTORALIS MINOR, SUBCLAVIUS, AND SERRATUS MAGNUS. 2l2t
If the arm be at a moderate distance from the side and its lower extremity be fixed,
as is the case in falling on the elbow when the arm is directed outward, this muscle acts
upon the humerus as upon a lever of the third order, of which the fulcrum is below, the pow-
er in the middle, and the resistance above ; and it then tends to dislocate the bead of the
humerus •with great force, because in this position its insertion is perpendicular to the lever.
When the humerus is fixed, the pectoralis major acts upon the ribs, the sternum, and
the clavicle, and raises the trunk upon the arm. It is, therefore, one of the chief agents
in climbing. Its action upon the ribs renders it an important auxiliary in cases of la-
borious inspiration. Hence the attitude of an asthmatic patient, who always nlaces him-
self so as to keep the humeri fixed.
The Pectoralis Minor.
Dissection. — Detach the clavicular insertion of the pectoralis major, and divide that
muscle in the middle by a verticle incision ; reflect the two flaps, taking care to remove,
at the same time, the loose cellular tissue which invests its deep surface.
The pectoralis minor {t,fi.g. 110) is a thin, flat, triangular muscle, having its internal
edge serrated (serratus anticus, Albinus), and occupying the anterior and upper part of
the thorax and shoulder. It arises from the third, fourth, and fifth ribs, by three delicate,
shining, tendinous prolongations, lying superficially to the intercostal muscles ; to these
succeed three fleshy fasciculi, which unite and converge, so as to be inserted by a flat
tendon into the anterior margin of the coracoid process, near its summit.
Relations. — It is covered by the pectoralis major, from which it is separated by the tho-
racic vessels and nerves : its posterior surface is in relation with the ribs, the intercos-
tal muscles, the serratus magnus, the cavity of the axilla, and, therefore, with the axillary
vessels and nerves. This last relation is of great importance, and sometimes renders
the section of this muscle necessary for the ligature of the axillary artery. Attention
should also be directed, 1 . To its upper border, which is separated from the clavicle by
a triangular interval, broad on the inside and narrow on the outside, in which the same
artery may be tied ; and, 2. The lower border of the muscle extends downward beyond
the pectoralis major.
Action. — Most commonly it acts upon the scapula (musculus qui scapulam antrorsum
agit, Vesalius). With its fixed point at the ribs, it evidently draws the scapula forward
and downward, and forcibly depresses the apex of the shoulder. As a depressor of the
shoulder, it acts in conjunction with the levator anguli scapulae and rhomboideus, but an-
tagonizes those muscles considered as elevators of the entire scapula : it is also opposed
to the rhomboideus when moving the scapula forward. With its fixed point at the scapu-
la, this muscle elevates the ribs to which it is attached.
The Subclavius.
Dissection. — Raise the clavicle by carrying the apex of the shoulder upward ; divide
the pectoralis minor, and remove the fibrous membrane, descending from the clavicle,
and immeidiately investing the muscle. In order to expose its external or clavicular in-
sertion, saw through the clavicle in the middle, divide the muscle at the same point, and
reflect the external half with the corresponding portion of the clavicle.
The subclavius (g,fig. 110) is a long, thin, fusiform muscle, applied to the lower sur-
face of the clavicle, by which it is concealed (musculus qui sub clavicula occultatur, Fa-
bricius Hildanus). It arises from the cartilage of the first rib, and is inserted into the in-
ferior and external surface of the clavicle. Its costal attachment consists of a cervical
tendon, from which the fleshy fibres proceed outward, backward, and upward, and are in-
serted into the clavicle by short, tendinous fibres.
Relations. — It is covered above by the clavicle, which is grooved beneath for its recep-
tion ; it is in relation below with the first rib, being separated from it by the axillary ves-
sels and the brachial flexus ; in front, it is enveloped by a very strong aponeurosis, com-
pleting the osteo-fibrous canal in which it is included. Its relation with the brachial
plexus and axillary vessels prevents the direct compression to which these parts would
have been otherwise exposed between the clavicle and the first rib.
Action. — ^When its fixed point is at the first rib, it depresses the clavicle, and is, there-
fore, a depressor of the shoulder ; it tends also to press the inner end of the clavicle for-
cibly against the sternum ; so, also, in fracture of the clavicle, it occasions the external
fragment to ride upon the internal. When its fixed point is at the clavicle, it assists in
elevating the first rib, and is, therefore, arranged among the muscles that act in impeded
inspiration.
The Serratus Magnus.
Dissection. — Having removed the two pectorals, saw through the clavicle at its mid-
dle ; press the scapula backward, directing its axillary edge outward ; remove with care
the cellular tissue occupying the axilla, especially that against the axillary vessels and
nerves, and near the intercostal attachments of the muscle itself, in order to see the in-
ternal surface of which the subject must be turned, and the vertebral eosta of the scap-
ula drawn outward.
222 XM.i* - MYOLOGY.
The serratus magnus [u,fig. 106, d, 109, and I, 110), very broad, quadrilateral, and ser-
rated along one of its borders, occupies the side of the thorax, and extends, hke a mus-
cular girth, from the ten upper ribs to the vertebral costa of the scapula. Its costal at-
tachments consist of nine or ten digitations arranged in a curve, having its concavity di-
rected backward. The first digitation, which is very large, arises both from the first
and second ribs, and from an aponeurotic arch between them ; from thence tlie fibres
proceed upward, outward, and backward, and are inserted into the inner surface of the
posterior and superior angle of the scapula, near the levator anguli. This digitation is
the narrowest part of the muscle ; it differs in direction from the remainder, and is sep-
arated from them by a cellular interval ; hence it has been termed the superior portion
of the serratus magnus. The second, third, and fourth digitations arise in an oblique
line, running downward and forward from the second, third, and fourth ribs. These are
the largest and the thinnest of all the digitations ; they proceed horizontally backward,
and are inserted separately, by short tendinous fibres, into the entire length of the verte-
bral costa of the scapula, anterior to the rhomboid ; they are distinguished from the re-
maining digitations both by their direction and by an intervening cellular space ; they
form the middle portion of the serratus magnus.
The fifth, sixth, seventh, eighth, ninth, and tenth digitations arise from the outer sur-
face of the corresponding ribs along oblique lines, resembling the fingers crossed, and
are interposed between corresponding prolongations of the external oblique. These di-
gitations are at first tendinous ; they soon become fleshy, and, converging towards each
other, form a radiated fasciculus, which passes upward, outward, and backward, to be
inserted into the internal surface of the inferior angle of the scapula. This is the infe-
rior portion of the serratus magnus.
Relations. — The serratus rnagnus is partially covered by the two pectorals before, by
the subscapularis behind, and above by the axillary vessels and nerves ; its deep surface
rests upon the ribs and the intercostal spaces, all these parts being united by a quantity
of loose cellular tissue. A considerable portion of the lower part of the muscle is sub-
cutaneous, and, therefore, the inferior digitations are important studies for the painter
and the sculptor, and sometimes even for the surgeon, as indications of the arrangement
of the corresponding ribs.
Action. — From the disposition of its different fasciculi, the serratus magnus occasions
a compound movement of the scapula, which it will be well to analyze. The upper por-
tion depresses and brings forward the apex of the shoulder ; the middle portion draws
the entire scapula directly forward ; while the lower portion depresses it, and, more-
over, rotates it, so that the apex of the shoulder is carried upward. As the lower part
of the muscle is composed of six or seven of the converging fasciculi, which act with
greater energy than the others, it follows that their action predominates even when the
whole muscle contracts. The serratus magnus is, then, a depressor of the entire shoulder,
and an elevator of its apex. It is more especially concerned than any other muscle in
supporting a burden upon the shoulder.
In order that the action of the serratus may be directed upon the scapula, its costal
attachments must be fixed : this requires the simultaneous contraction of the oblique
muscles of the abdomen to maintain the ribs in a depressed position, and of the dia-
phragm and transversalis to prevent their projection outward. This simultaneous con-
traction occurs during all great efforts.
When the fixed point of the serratus magnus is at the scapula, its upper portion be
comes a muscle of inspiration, its middle one of expiration, and its lower one of inspira
tion. The greater power of the latter has been the cause of the antagonizing action of
the middle portion being overlooked ; and the serratus magnus is, with great justice, re
garded as the most powerful accessory muscle of inspiration : hence the various atti-
tudes of asthmatic persons, who instinctively take a position which fixes the scapula,
either by seizing a cord suspended from the top of the bed, or by bending forward, anc"
leaning on their elbows and forearms, or by resting their upper extremities on two lat
eral supports.
The Inter-costales, Externi and Interni ; the Supra-costdles and the Infra
costales.
Dissection. — In order to examine the extemeil intercostals and the supra-costales (le
vatores costarum), the scapula and all the muscles which cover the thorax must be re
moved ; to expose the internal inter-costales and the infra-costales, it is necessary to
saw through the middle of the dorsal vertebrae and the sternum in a vertical direction,
and to tear off the pleura from one side of the thorax, which may be very easily accom
plished by the fingers.
The intercostal muscles, as their name implies, occupy the intervals between the ribs
there are two in each intercostal space, and, therefore, as many pairs as there are spaces.
They are divided into external and internal. They represent two very tliin muscular
layers, of exactly the same width as the spaces to which they belong ; taken together.
THE INTER-COSTALES, SUPRA-COSTALES, AND INFRA-COSTALES. 223
they also occupy the entire length of those spaces, but not separately, for the external
intercostals extend only from the costo-vertebral articulations to the commencement of
the cartilages of the ribs, while the internal intercostals commence at the angles of the
ribs behind, and extend forward to the sternum. A very thin aponeurosis is prolonged
from the free margin of the one forward and of the other backward to the end of the in-
tercostal space. The external muscles, which I have generally found thicker than the
internal, arise from the lip of the groove on the lower border of one rib, and the internal
from the inner hp of the same groove, as well as from the corresponding costal carti-
leige ; they are both inserted into the upper border of the rib below. The superior at
tachments consist of fleshy and tendinous fibres and lamellae, all of which proceed down-
ward to the rib below ; those of the external layer obliquely forward, and those of the
internal layer much l6ss obliquely backward. The inferior attachments are similar in
structure. The tendinous fibres of the intercostal muscles are very long, and much
more numerous than the fleshy fibres : hence the intercostal spaces possess consider-
able strength, to which the crossing of the two layers also contributes.
Relations. — The external intercostals are covered by the two pectorals, the serratus
magnus, the serrati postici, the latissimus dorsi, the sacro-lumbalis, and the external ob-
lique ; they are superficial to the internal intercostals, and are separated from them by the
intercostal vessels and nerves, and by a very thin fibrous layer. The internal intercostala
are covered by the external and by the aponeurotic layer continuous with them anterior-
ly. Internally they are in relation with the pleura, which, from the angles to the tuber-
osities of the ribs, is in apposition with the external muscles.
The infracostal muscles of Verheyen consist of small muscular and aponeurotic tongues,
variable in number and length, which extend from the inner surface of one rib to the in-
ner surface of the next, and sometimes, also, to the second or third rib below. They are
sometimes vertical, but often oblique, like the internal intercostals, of which they may
be regarded as portions.
Supra-costales (levatores breviores costarum of Alhinus, o to o,fig. 107). These are
small triangular muscles, situated at the back part of the intercostal spaces. They are
accessories of the external intercostals, resemble them in being half tendinous and half
fleshy, and appear to form a continuation of them. There are twelve on either side.
Each arises from the summit of the transverse process of a vertebra, and proceeds in a
radiated manner downward, to be inserted into the back part of the upper border and ex-
ternal surface of the rib below.
The fibres of these muscles have the same direction as those of the external intercos-
tals, but they are more obhque, especially on the outside. The first arises from the trans-
verse process of the seventh cervical vertebra, the last from that of the eleventh dorseil.
Some of these muscles have two digitations, one disposed in the ordinary manner, the
other attached to the next rib below. The latter, called the long supra-costals (levatores
longiores, Albinus and Haller), form a transition between the levatores breviores and the
serrati. Morgagni met with all the levatores united together, so as to form a very reg-
ular serrated muscle. They are covered by the longissimus dorsi and sacro-lumbaUs,
and they cover the external intercostals.
Action. — The contraction of the intercostal muscles tends to approximate the ribs ;
and, according as the upper or the lower ribs are fixed, they act as muscles of inspira-
tion or of expiration. It has never been denied that the external intercostals are mus-
cles of inspiration, but the crossing of the tAvo muscidar layers has given rise to the opin-
ion that they oppose each other in action ; and hence arose the celebrated dispute be-
tween Bamberger and Haller. It is easy to understand that the slight difference exist-
ing between their attachments, with regard to their distance from the fulcrum, could not
counterbalance the effect of a difference in the relative fixedness of the ribs, and that the
intercrossing of these muscles has no other object than to increase the strength of the
parietes of the thorax.
As the first rib is much more fixed than the last, it follows that it must serve as a fixed
point for the first intercostal muscle, which will consequently raise the second rib ; this
will then become the fixed point for the third rib, and so on. The scaleni off^en take their
fixed point upon the vertebrae, and then assist in elevating the first rib. The quadratus
lumborum depresses the last rib, which may then serve as a fixed point for the others
during expiration.
The levatores act very effectually in raising the ribs ; for, being attached so near to
the fulcrum, the slightest movement produced in the posterior extremity of the rib be-
comes very sensible at the other end. I agree with Borelli {De Motu Animal., torn, ii-,
p. 158), that the intercostals act even during the most easy respiration. This can be
observed upon our own persons, and also in individuals in deep sleep. The ribs will
be seen distinctly carried outward, and the sternum raised.
The Triangularis Sterni, or small Jlnterior Serratus.
Dissection. — Divide the ribs vertically at their junction with the cartilages, and tear
off" the plenra with the fingers.
224 .i/.(K. :v -'^X- ^" MYOLOGY. '""^
The triangularis sterni represents the levatores costarum in front, or, rather, the ser-
rati postici, with this difference, that it occupies the internal instead of the external sur-
face of the thorax. Like them, it is sen-ated. It arises from the sides of the posterior
surface of the sternum, from the ensiform cartilage and the inner ends of the cartilages
■ of the ribs. From this origin the fleshy fibres proceed, dividing into three, four, five, and
sometimes six digitations, which are inserted by tendinous fibres into the posterior sur-
face and borders of the sixth, fifth, fourth, third, sometimes of the second, and even of
the first costal cartilages. The lower fibres pass horizontally and parallel to the upper
fibres of the transvcrsalis, with which they are continuous. The succeeding fibres are
directed upward and outward, proceeding more and more obliquely upward : hence the
triangular shape of the muscle, to which its name refers.
Relations. — It is covered by the sternum, the internal intercostal muscles, and the cos-
tal cartilages, from which it is separated by the manunary vessels and some lymphatic
glands ; it is lined internally by the pleura, and rests upon the diaphragm below.
Its use is evidently to depress the costal cartilages, into which it is inserted, or to op-
pose their elevation.
Remarks concerning the Intercostal Muscles. — The muscles we have just described, viz.,
the intercostals and" their accessories, are essential elements in the construction of the
chest ; they are found in all animals possessed of a thorax. Their use is to dilate and
contract this cavity in its antero-posterior and transverse diameters. The first rib, be-
ing Itxed by the contraction of the scaleni, serves as a fulcrum for the agents of inspira-
tion ; and the last rib, when fixed by the quadratus lumborum, serves the same purpose
for those of expiration ; so that these muscles, whose most common action is to incline
to one side the neck and the loins, do not, on that account, act the less u^jon the ribs.
I cannot, by any means, agree with Winslow, who denies that the scaleni have any ac-
tion upon the ribs, and maintains that the articulation of the first rib with the first dor-
sal vertebra is intended for the movement of the vertebra on the rib, not for that of the
rib on the vertebra. (Winslow, Expos. Anat., t. ii., p. 360.)
SUPERFICIAL ANTERIOR CERVICAL REGION.
TAe Platysma Myoides. — Sterno-cleido-mastoideus.
The Platysma Myoides.
Dissection. — Stretch the muscle by inclining the head backward and placing a block
under the shoulders of the subject ; make a horizontal incision through the skin from the
angle of the jaw to the symphysis menti, another from the symphysis to the inner end
of the clavicle, and a third along the clavicle. These incisions should be very super-
ficial, scarcely dividing the entire thickness of the skin. The muscle must be very cau-
tiously dissected by taking care to commence at its upper part, to turn the edge of the
scalpel towards the skin, and to follow exactly the direction of the fleshy fibres which
pass obliquely downward and outward.
The platysma myoides (e, fig. 109), called le pcaucier by Winslow, latissimus colli by AI-
binus, is a broad, very thin, and irregularly-quadrilateral muscle lining the skin at the
fore part of the neck, and adhering to it like the cutaneous muscles of the lower animals.
It extends from the skin covering the anterior and upper part of the thorax to the side '
of the face, where it terminates thus : at the base of the lower jaw, at the commissure
of the lips, upon the masseter muscle, and at the skin of the face. From its lower at-
tachment, which is almost always prolonged as far as the shoulder, and loses itself in
the subcutaneous cellular tissue, the fibres proceed obliquely upward and inward ; the
pale muscular fasciculi which they form are separated from each other, and sometimes
strengthened by additional fasciculi to the posterior border of the muscle : they terminate
in the following manner above : the posterior fibres are lost under the skin of the face
near the masseter muscle, the lower end of which they cover ; those next in front are
partly continuous with the triangularis oris, and partly with the quadratus menti ; the
anterior fibres terminate at the external oblique line of the lower jaw, and the most in-
ternal intersect with those of the opposite side. The posterior fibres, which are lost
upon the skin of the face, are the rudiments of a remarkable fasciculus, an accessory of
the platysma found in some subjects. It is directed obliquely downward, from the re-
gion of the parotid gland to the angle of the lips. Santorini described it under the name
ofrisorius novus.
Relations. — These two muscles occupy the whole anterior region of the neck, except-
ing the median line, where they leave a triangular interval, having its base below, and
occupied by a very dense fibrous tissue, forming a species of raph(5, which is found in the
median line throughout the body. This is the linea alba of the neck, from which the dif-
ferent component layers of the cervical fascia take their origin.
The platysma is intimately connected with the skin, but it does not adhere equally
throughout ; it is united closely below, but much more loosely above, where the inter
THE STERNO-CLEIDO-MASTOIDEUS.
225
▼enmg cellular tissue is always adipose, and capable of containing a large quantity of
fat, as we find in individuals who have what is called a double chin. There are no lym-
phatic glands between this muscle and the skin ; they are all situated beneath the mus-
cle. The relations of the deep surface of the platysma are very numerous. It covers
the supra and sub-hyoid, and the supra-clavicular regions, being separated from all the
structures beneath it by the cervical fascia, to which it is united by loose cellular tissue,
seldom containing any fat. If we examine these relations in detail, we find, proceeding
from below upward, that it covers, 1. The clavicle, the pectoralis major, and the deltoid ;
2. In the neck, the external jugular vein, and also the anterior jugulars where they ex-
ist, the superficial cervical plexus, the sterno-mastoid, the omo-hyoid, the sterno or cle-
ido hyoid, the digrastic, and the mylo-hyoid muscles, the sub-maxillary gland, and the
lymphatic glands at the base of the jaw. In front of the sterno-mastoid, it covers the
common carotid artery, the internal jugular vein, and the pneumogastric nerve ; behind
the sterno-mastoid, it covers the scaleni muscles, the nerves of the brachial plexus, and
some of the lower nerves of the cervical plexus. 3. In the face, it covers the external
maxillary or facial artery, the masseter and buccinator muscles, the parotid gland, &c.
Action. — The platysma is the most distinctly marked vestige in the human body of the
panniculus carnosus of animals ; and it can produce slight wrinkles in the skin of the
neck. Its anterior border, especially at its insertion near the symphysis menti, is the
thickest part of the muscle, and therefore projects slightly during its contraction. It is
one of the depressors of the lower jaw ; it also depresses the lower lip, and, slightly, the
commissure of the lips. It therefore assists in the expression of melancholy feelings,
but it is antagonized by the accessory portion, which draws the angle of the lips upward
and a little outward, and thus concurs in the expression of pleasurable emotions ; hence
its name, risorius.
The Sterno-cleido-mastoideus.
Dissection. — Divide the skin and the platysma from the mastoid process to thewtop of
the sternum, in an oblique line, running downward and forward ; reflect the two flaps,
one forward and the other backward, taking care to remove at the same time the strong
fascia which covers the muscle. In order to obtain a good view of the superior attach-
ments, make a horizontal incision along the superior semicircular line of the occipital bone.
The sterno-cleido-Tnastoid {b, Jig. 113) occupies the anterior and lateral regions of the
neck. It is a thick muscle, bifid below, and narrower in the middle than at either end.
It arises, by two very distinct masses, from the inner end of the clavicle, and from the
top of the sternum in front of the fourchette, and is inserted into the mastoid process
and the superior semicircular line of the occipital bone. The sternal origin consists of
a tendon prolonged for a considerable distance in front of the fleshy fibres. The clavic-
ular origin consists of very distinct parallel ten- pig. 113.
dinous fibres, attached to the^ inner side of the
anterior edge and upper surface of the clavicle,
to a very variable extent, an important fact in
surgical anatomy. There is often a considerable
cellular interval between these two origins ;
sometimes this interval scarcely exists, but, in
all cases, the two portions of the muscle can be
readily separated. From this double origin the
fleshy fibres proceed, forming two large bundles,
which rfimain distinct for some time. Many
anatomists, therefore, Albinus in particular, have
considered it as consisting of two separate mus-
cles, which they describe as the sterno-mastoid
and the cleido-mastoid ; a division that is sanc-
tioned by the comparative anatomy of this mus-
cle. The sternal portion of the muscle is the
larger, and passes upward and outward ; the cla-
vicular portion proceeds almost vertically upward,
behind the other, and is entirely concealed by it
at the middle of the neck ; the two portions still
remain separate, although approximated ; ulti-
mately they become united, and are inserted into
the apex and anterior surface of the mastoid pro-
cess by a very strong tendon, which runs for
some distance along the anterior border of the
muscle, and also into the two external thirds of
he superior semicircular line of the occipital bone, by a thin aponeurosis. The direction-
or axis of the sterno-mastoid passes obliquely upward, backward, and outward.
The relations of this muscle are very important. Its superficial or external surface is
covered bv the skin and platysma, from which it is separated by the external jugulai'
Fy
226 MYOLOGY.
vein, and the branches of nerves, constituting what is improperly termed the superficial
cervical plexus. Its deep or internal surface covers, 1. The sterno-clavicular articulation ;
2. All the muscles of the sub-hyoid region, and also the splenius, the levator anguli scap-
ulae, the digastricus, and the scaleni ; 3. The accessory nerve of Willis, which crosses
beneath its superior third, the pneumo-gastric nerve, the great sympathetic, the loop of
the hypoglossal nerve, and the cervical nerves ; 4. The internal jugular vein ; 5. The
lower portion of the common carotid artery. Its anterior border produces a ridge under
the skin, which it is important to study, because the first incisions for hgature of the
common carotid, and for oesophagotomy, should be made along it. The parotid gland
rests upon the upper part of this border, which is separated from the corresponding bor-
der of the muscle of the opposite side by a triangular interval, of which the apex is be-
low and the base above. Its posterior border forms the anterior limits of the lateral tri-
angle of the neck, which is bounded behind by the external margin of the trapezius, and
below by the clavicle.
Action. — When the sterno-cleido-mastoid of one side acts alone, it flexes the head, in-
clines it to its own side, and rotates it so that the face is turned to the opposite side. It
is, therefore, both a flexor and a rotator of the head. When both muscles act together,
they flex the head directly upon the neck, and the neck upon the chest. Their action is
particularly manifested in an attempt to raise the head while lying upon the back. Still,
there is a position in which this muscle may become an extensor of the head, viz., when
it is thrown very far backward ; and this effect is owing to the nature of the upper inser-
tion, which is situated somewhat behind the fulcrum of the lever represented by the head.
This muscle affords one of the most remarkable examples of the co-operation or si-
multaneous action of several muscles, in order to give effect to the action of one. Thus,
in order that the sterno-cleido-mastoid may act most advantageously upon the head, it
becomes necessary that the sternum, being the fixed point, should be maintained as im-
movable as possible, and this can only be effected by the contraction of the recti muscles
of the abdomen. These latter, in their turn, require a fixed point at the pelvis, and this
renders necessary the contraction of the glutaei, the semi-tendinosus, the semi-mem-
branosus, and biceps femoris on either side ; and, lastly, for the action of these, the legs
require to be fixed by means of their extensor muscles.
This remarkable simultaneous contraction of so many muscles, necessary for the ac-
tion of but one, has been extremely well illustrated by Winslow. It has many impor-
tant results both in physiology and in pathology.
MUSCLES OF THE INFRA-HYOID REGION.
The Stcrno-hyoideus. — Scapula- or Omo-hyoideus. — Sterno-thyroideus. — Thyro-hyoideus.
The muscles of the infra-hyoid region are four in number«on each side, viz., the sterno,
or, rather, cleido-hyoid, the omo-hyoid, and the sterno-thyroid, which is continuous above
witli the fourth muscle, viz., the thyro-hyoid.
The Sterno-hyoideus.
Dissection. — This is extremely easy, and is the same for all the muscles of this region.
Tlie only caution necessary is, that the clavicular and sternal attachments of these mus-
cles should be studied from their posterior aspect only, and that the trapezius must be
removed in order to expose the scapular attachments of the omo-hyoid.
The sterno-hyoid [I, figs. 113 and 114) is a flat, thin, riband-like muscle, which is some-
times double on each side. It arises from the inner end of the clavicle, and is inserted
into the os hyoides. Its inferior attachment is liable to some variations ; most conmion-
ly it is connected with the back part of the inner extremity of the clavicle and with the
inter-articular cartilage ; sometimes with the outer side of that extremity ; and sometimes
with the circumference of the clavicular surface of the sternum. From this origin the
fleshy fibres proceed parallel to each other, upward and inward, to be inserted by short
tendinous fibres into the lower edge of the body of the os hyoides on the side of the
median line, and to the inside of the omo-hyoid, with which it is often blended. Imme-
diately above the clavicle this muscle is often divided by an aponeurotic intersection,
which is united to that of the opposite side, and forms, as it were, a transverse bridle.
Relations. — It is covered by the platysma, the stemo-mastoid, and the cervical fascia.
It covers the deep-seated muscles, the thyroid body, the crico-thyroid and thjTO-hyoid
membranes, from which it is often separated by a bursa mucosa, the crico-thyroid mus-
cle, and the superior thyroid artery. The inner edges of the two sterno-hyoid muscles
are generally separated by a fibrous raphe, but they are sometimes blended together, and
thus render the operation of tracheotomy more difficult. This impediment may, how-
ever, be overcome by keeping accurately in the median line.
The Scapulo- or Omo-hyoideua.
This muscle (coraco-hyoideus, Albinus, m m, figs. 113 and 114) is longer and more
THE STERNO-THYROIDEUS AND THYRO-HYOIDEUS. 227
slender than the preceding ; it is a digastric reflected muscle, composed of two small
fleshy bellies, united by an intermediate tendon. It arises from the superior border of
the scapula behind the coracoid notch, over an extent varying from a few lines to an
inch, and is inserted into the lower part of the body of the os hyoides, externally to the
sterno-hyoid. From its origin, which is sometimes tendinous, it proceeds for a variable
distance behind and parallel to the clavicle, and is then reflected upward and inward, at
an obtuse angle. At the point of reflection it becomes entirely or partially tendinous,
and gives origin to another fleshy bundle larger than the former, which is inserted into
the OS hyoides.
The angular direction of this muscle is maintained by means of an aponeurosis, first
described by Soemmering, which extends between the inner borders of the two muscles,
and is fixed to the clavicle : it is one of the layers of the cervical fascia, an important
structure, to be again alluded to hereafter, and of which the omo-hyoid muscles are ten-
sors. These muscles eire occasionally wanting ; sometimes they are double. In one
case of this kind the accessory muscle was larger than the normal one, and arose from
the upper and internal angle of the scapula.
Relations. — This small muscle, before reaching the sub-hyoid region, traverses two
others, the supra-clavicular and the stemo-mastoid. It is covered by the trapezius, the
subclavius, the clavicle, the platysma, the stemo-mastoid, and the skin ; it covers the
scaleni, the brachial plexus, the internal jugular vein, and the common carotid artery,
and it is in contact with the outer border of the sterno-hyoid muscle.
The Sterno-thyroideus.
The sterno-thyroid (w. Jig. 1 14) closely corresponds with the sterno-hyoid, from which
it differs only in being shorter and broader. It extends from the posterior surface of the
sternum to the thyroid cartilage. It arises from the sternum opposite the first rib ; it is
often blended with its fellow, so that their origins form a line reaching the entire breadth of
the sternum, and often to the edges and posterior surface of the cartilage of the first rib.
From this origin the fleshy fibres proceed directly upward parallel to each other, and
are inserted into the thyroid cartilage by a tendinous arch running obliquely downward
and inward, which embraces the thyro-hyoid muscle, and is attached by its extremities
to two very prominent tubercles on the external surface of the cartilage. It is some-
times continued as far as the os hyoides by a small lateral prolongation, and at other
times it is continuous with the thyro-hyoid. The sterno-thyroid is interrupted by a ten-
dinous intersection analogous to those of the rectus abdominis. It is not uncommon to
find the two sterno-thyroid muscles united together by an intervening aponeurosis shaped
like the letter V, opening upward, and corresponding to the fourchette of the sternum.
Relations. — It is covered by the sterno-hyoid and omo-hyoid muscles, and it covers the
trachea, the lower part of the subclavian and internal jugular veins, the common carotid
artery, and the arteria innominata on the right side, the thyroid body and the thyroid
vessels. The middle thyroid vein runs along its inner border, an important relation in
regard to the operation of tracheotomy.
The Thyro-hyoideus.
This is a small quadrilateral muscle (hyo-thyroideus, Albinus), which may be consider-
ed a continuation of the stemo-thjToid (^o,figs. 113 and 114). It arises from the oblique
line, and the tubercles of the thyroid cartilage, where it is embraced by the tendinous
arch of the preceding muscle, passes vertically upward, and is inserted into the posterioi
surface of the body and part of the great cornu of the os hyoides.
Relations. — It is covered by the two muscles of the superficial layer, and covers the
thyroid cartilage, and the th3TO-hyoid membrane.
Action of the Muscles of the Sub-hyoid Region. — These muscles are the most simple,
both in structure and in action : they all concur in depressing the lower jaw ; but if the
lower jaw is ficxed, they produce flexion of the head. The fixed points of all are below,
viz., at the sternum on the inside, at the clavicle in the middle, and at the scapula on the
outside. This arrangement not only bestows particular uses upon each, but renders the
common action of all more certain. Thus, the omo-hyoid, at the same time that it de-
presses the 03 hyoides, carries it backward and towards its own side. Wliere the two
omo-hyoid muscles act together, the os hyoides is directly depressed, and forced back-
ward against the vertebral column. The sterno-hyoid and the sterno-thyroid, prolonged by
the thyro-hyoid, draw the os hyoides directly downward. The principal use of the thyro-
hyoid is, to move the os hyoides upon the thyroid cartilage, in which movements the upper
part of the cartilage is carried behind the os hyoides, the curve described by which is al-
ways greater than that formed by the cartilage. The muscles of the sub-hyoid region nev-
er eissume as their movable point 3 either their sternal, clavicular, or scapular attachments
^'P^^^IP^'^F*^
228
MYOLOGY.
MUSCLES OF THE SUPRA-HYOID REGION.
The Digastricus. — Stylo-hyoideus. — Mylo-hyoideus. — Genio-hyoideus. — Their Action.
The muscles of this region, taken in the order of super-imposition, are the digastric,
the stylo-hyoid, the mylo-hyoid, and the genio-hyoid.
The Digastricus.
Distection. Remove the platysma, reflect the mastoid insertion of the stemo-mastoid ;
Pig^ 114. detach and raise the sub-maxillary
and the lower extremity of the pa-
rotid gland.
The digastric muscle (biventer
mjixillae inferioris, Albinus,p p,figs.
113 and 114), so named because it
consists of two fleshy bellies, united
by an intermediate tendon, reaches
the whole extent of the supra-hyoid
region, from behind forward. It is,
in some respects, the type of digas-
tric muscles. It is curved upon it-
self, forming the arc of a circle, with
the concavity directed upward.
It arises from the digastric groove
in the mastoid process, and from the
anterior edge of that process, in front
of the sterno-mastoid ; it it inserted
into the side of the symphysis menti,
below the sub-mental tubercles, into
the whole extent of the digastric fos-
sa. It is also attached to the os hy-
oides by means of an aponeurotic ex-
pansion.
Its origin from the mastoid pro-
cess is partly fleshy and partly ten-
dinous, the tendon being prolonged
for some distance upon the upper border of the muscle. The fusiform fleshy belly pro-
duced in this manner passes forward, inward, and downward, into the interior of a sort
of fibrous cone, forming the commencement of the intermediate tendon. This tendon,
which is about two inches in length, follows at first the direction of the muscle, almost
always perforates the stylo-hyoid muscle, and is then received into a fibrous ring attach-
ed to the OS hyoides, and lined by a synovial capsule. This fibrous ring is often wanting.
A broad aponeurotic expansion proceeds from the intermediate tendon, and is fixed to the
OS hyoides. When this is united to the corresponding structure on the opposite side,
they form a very strong, triangular aponeurosis, called the supra-hyoid aponeurosis, which
occupies the interval between the two muscles, and serves as a kind of floor for the other
muscles of the supra-hyoid region. After having passed through the fibrous ring, the ten-
don changes its direction, and is reflected at an obtuse angle upward and forward, to ter-
minate in another tendinous cone. From the interior of this cone the fleshy fibres of the
anterior belly take their origin. This belly is not so strong as the posterior, and is insert-
ed by separate tendons, sometimes intersecting those of the opposite side, into the whole
extent of the digastric fossa, below the sub-mental tubercles. Some fibres are often
blended with those of the mylo-hyoid. It is not uncommon to see a small fasciculus
arising from the os hyoides, and strengthening the anterior belly. The two anterior bel-
lies are sometimes united by a raphe, and by a small transverse fibrous bundle.
Relations. — It is covered by the platysma and sterno-mastoid, the parotid and the sub-
maxillary glands, the latter of which it embraces by the concavity of its upper border : it
covers the muscles which arise from the styloid process, the mylo-hyoid muscle, the in-
ternal jugular vein, the external carotid artery, and its labial and lingual branches, the
mternal carotid, and the hypo-glossal nerve, which lies parallel with, and beneath the
intermediate tendon of the muscle.
Its action is very complicated : when the posterior belly contracts alone, the os hyoides
is carried backward and upward ; the anterior belly carries it forward, and also upward.
When the two bodies of the muscle contract at the same time, these opposite effects are
destroyed, and the os hyoides is carried directly upward. In all these motions, the low-
er jaw must be fixed. If the os hyoides is fixed, the posterior belly becomes a depressoi
of the jaw, on account of the reflection of the muscle ; the anterior and the posterior bel-
lies can incline the head backward, but this inclination of the head backward during mas-
tication, and when the jaws are separated, depends on the action of the posterior exten-
THE STYLO, MYLO, AND GENIO HYOIDES. 229
BOr muscles of the neck ; leistly, the anterior belly of the digastric is the tensor of the
supra-hyoid fascia.
The Stylo-hyoideus.
Dissection. — Detach the posterior belly of the digastric. This is a small and very thin
muscle {q,fig. 114 ; ^ q,fig^- ^^'^ ^^^ ^^'^), like all those which are attached to the sty-
loid process.
It arises from the back of the styloid process, at a short distance from the apex, and oppo-
site the insertion of the stylo-maxillary ligament. This origin consists of a small tendon,
which terminates in a fibrous cone, from the interior of which the fleshy fibres commence.
These proceed downward, forward, and inward, and form a bundle, which is almost al-
ways perforated by the tendon of the digastric. Occasionally the fibres pass only in front
of that tendon. They are iiiserted into the body of the os hyoides, at a short distance
from the median line. Sometimes the tendon of insertion is reflected upon itself, and
forms the pulley for the digastric.
Relations. — It is covered by the posterior belly of the digastric, and has the same re-
lations as that muscle. It is not uncommon to find a second stylo-hyoid muscle, ex-
tending from the styloid process to the little cornu of the os hyoides. This muscle takes
the place of the stylo-maxillary ligament ; it was described by Santorini under the name
of the stylo-hyoideus iwvus, and was noticed also by Albinus.*
The Mylo-hyoideus.
Dissection. — Detach the anterior belly of the digastric at its maxillary insertion ; dis-
sect the sub-maxillary gland, and turn it outward.
This muscle {r, figs. 113 and 114), situated immediately below, i. e., deeper (as re-
gards the surface) than the anterior belly of the digastric, is thin and quadrilateral. It
arises from the whole extent of the mylo-hyoid line, from opposite the last molar to the
symphysis menti, by short aponeurotic fibres. The fleshy fibres arising from these pass
in different directions : the internal (or anterior), very short, proceed inward to a median
fibrous raphe, which traverses the whole supra-hyoid region ; the external (or posterior)
pass much less obliquely to the upper part of the body of the os hyoides. The median
raphe is sometimes wanting, and the muscular fibres of the opposite sides are continuous
with each other. Some of the fibres are often lost in the digastric, and are even contin-
uous with the sterno-hyoid. The two mylo-hyoid muscles may, with great propriety, be
regarded as a single muscle, divided by a tendinous intersection in the median line.
Relations. — It is covered by the anterior belly of the digastric, the supra-hyoid fascia,
the platysma, and the sub-maxillary gland ; and it covers the genio-hyoid, the hyo-glos-
sus, and stylo-glossus muscles, the lingual and hypo-glossal nerves, the Whartonian
duct, the sublingual gland, and the buccal mucous membrane.
The Genio-hyoideus.
This muscle {s,fig. 114, 143, 147) is situated below, i. e., deeper than the preceding,
which must be divided very carefully, in order to avoid raising the two together. It is a
small, round, fleshy bundle, described by anatomists as consisting of two very minute
muscles, separated from each other by an extremely delicate cellular tissue. Sometimes
it is impossible to separate them; at other times the two bundles are very distinct
They arise from the inferior sub-mental tubercle, and proceed downward and backward,
to be inserted into the upper part of the os hyoides.
Relations. — ^They are covered by the mylo-hyoids, and cover the hyo-glossal muscles.
Actions of the Muscles of the Supra-hyoid Region.
These are of two kinds, relating to the depression of the lower jaw, and to the eleva-
tion of the OS hyoides.
The OS hyoides being fixed by the muscles of the sub-hyoid region, all the supra-hyoid
muscles, with the exception of the stylo-hyoids, depress the lower jaw ; and it should
be observed that they are situated in the most favourable manner for this purpose ; for,
on the one hand, they are almost perpendicular to the lever, and, on the other, they are
attached as far as possible from the fulcrum. The obliquity of their direction has also
this advantage, that the lower jaw is carried backward as well as depressed, and thus
the orifice of the mouth is greatly increased in size.
But the most important action of these muscles relates to the elevation of the os hy-
oides. This elevation is an indispensable element in the act of deglutition, and also in
the protrusion of the tongue. Thus, the os hyoides is carried upward and backward by
the stylo-hyoid muscles and by the posterior belly of the digastric, upward and forward
by the anterior belly of the digastric and by the mylo- and genio-hyoids, and directly up-
ward by the combined action of all these muscles. The base of the tongue, of which
the os hyoides constitutes, in some degree, the framework, is associated with it in all
* Albinus termed it stylo-hyoideus alter.
MYOLOGY.
these movements, which take place at different periods of deglutition : thus, the move-
ment upward and forward is effected during the period when the alimentary mass is
driven from the cavity of the mouth into the pharynx, which enlarges for its reception.
The direct elevation takes place when the mass is passing, and the movement upward
and backward occurs after it has passed, so as to prevent its return into the mouth.
When the lower jaw is fixed against the upper, and the os hyoides is also fixed by the
sub-hyoid muscles, the muscles of the supra-hyoid region assist in flexing the head.
Lastly, the os hyoides is elevated during the production of acute, and depressed during
that of grave, vocal tones.
MUSCLES OF THE CRANIAL REGION.
Occipito-froTttalis . — A uricular Muscles .
The muscles of the cranial region are the occipito-frontalis and the auricular muscles.
The Occipito-frontalis.
Dissection. — Shave the head, and make a horizontal incision above the superciliary
arch ; make a second incision in a vertical direction from before backward, and reaching
from the former to the superior semicircular line of the occipital bone ; be very careful
not to dissect away the epicranial aponeurosis, nor the fibres of the muscle ; commence
the dissection at the fleshy fibres, which adhere less intimately to the skin than the
aponeurosis.
The occipito-frontalis (epicranius, Albinus, a' a', jig. 113) is sometimes regarded as one
muscle with two bellies ; sometimes as a combination of two separate muscles, the oc-
cipital and the frontal. It covers the roof of the scull. We shall describe the occipital and
frontal portions only ; the aponeurosis will be elsewhere noticed. (Vide Aponeurology.)
1. The occipital portion, or occipital muscle, covers a great part of the occipital bone,
and is situated over the superior occipital protuberance. It is thin and quadrilateral.
It arises from the two external thirds of the superior semicircular line, and from the
neighbouring part of the mastoid process of the temporal bone, and is inserted into the
posterior border of the cranial aponeurosis, of which it may be regarded as the tensor.
The occipital attachment is composed of tendinous fibres, the fleshy fibres proceeding
from which pass upward in a parallel direction, and, after a short course, terminate in
the aponeurosis.
2. The frontal portion, or frontal muscle, is placed at the front of the cranium ; it is
thin, and irregularly quadrilateral, like the preceding. It is attached above to the cranial
aponeurosis, and terminates below in the following manner : 1. The internal or median
fibres are prolonged into a fleshy band, which constitutes the pyramidalis nasi ; 2. The
fibres next on the outside are continuous with those of another muscle, viz., the levator
labii superioris alaeque nasi — ^to the outside of these fibres, the muscle is attached to the
internal orbital process ; 3. The greater number of the fibres are blended with those of
the orbicularis palpebrarum. The upper border of the muscle, which is attached to the
aponeurosis, forms a semicircular line, that, in many individu^^, causes a projection un-
der the skin.
Relations. — Tlie occipito-frontalis covers the roof of the scull ; hence the name of epi-
cranius (Albinus). It rests upon the pericranium (the periosteum of the cranial bones),
being separated from it by a quantity of moist cellular tissue, which admits of a consid-
erable degree of mobility of the integuments, and is so elastic that it returns to its origi-
nal situation after being displaced by any movements of the hairy scalp. The super-
ficial surface of this muscle is covered by the skin, and is united to it by a very dense,
almost fibrous cellular tissue, in which are ramified the numerous vessels and nerves of
the cranial integuments.
Action. — The occipital portion is a tensor of the epicranial aponeurosis, which, when
stretched, affords a fixed point for the frontal portion. This latter raises the upper half
of the orbicularis palpebrarum, elevates the eyebrows and the skin over the root of the
nose, and has a great effect in the expression of emotions of delight. This muscle pro-
duces the transverse wrinkles on the forehead, which give to the countenance of indi-
viduals who are habitually gay a peculiar expression, that is often imitated by painters.
These transverse wrinkles do not extend over the triangular interval, which separates
the two fleshy bellies of the muscle in the centre of the forehead.
The occipito-frontalis must be regarded as an elevator of the upper eyelids ; it is blend-
ed with the orbicularis palpebrarum in the same manner as the labial muscles with the
orbicularis oris. In this respect the occipito-frontalis is assisted by the levator palpe-
hrse superioris, and antagonized by the corrugator supercilii and orbicularis palpebrarum.
Can this muscle erect the hairs on the head 1 It is certain that it can move the entire
hairy scalp, for many individuals are able to do this at will ; but it appears to me that
the expression, the hairs stand on end, as regards man, is merely figurative, and is de-
rived from what occurs in the lower animals, in which this erection of the hair is very
THE AURICULAR MUSCLES, ETC. 1281
manifest. Perhaps, however, the skin itself may produce this effect by the same mech-
anism as that which gives rise to goose skin.
The Auricular Muscles.
Dissection. — Be very careful in dissecting the superior and anterior auricular muscles,
which are extremely thin, and consist only of a few colourless fibres. To render them
as tense and prominent as possible, it is necessary to draw the ear away from the mus-
cle to De examined.
All these muscles are rudimentary in man, in whom the external ear is almost im-
movable. They may all be considered as dilators of the auditory meatus, to which there
is no constrictor or sphincter in the human subject : certain animals, however, possess-
ing a very delicate sense of hearing, have constrictor muscles, which draw together and
move the different pieces forming the cartilaginous portion of this canal.
The auricular muscles are three in number : a superior, an anterior, jmd a posterior.
The Auricularis Superior.
This muscle, which is extremely thin and of a triangular form (b',Jig. 1 13), oocupies the
temporal fossa. It arises from the external border of the epicranial aponeurosis, of which
it seems to be a dependance , from this origin its fibres converge, and are inserted into the
upper part of the concha. It is covered by the skin, and lies upon the temporal fascia.
Action. — To raise the ear (attollens auriculam, Albinus).
The Auricularis Anterior.
This muscle (c'. Jig. 1 13) is still thinner and less marked than the preceding, with
which it is continuous. It is also triangular, and arises from the outer edge of the oc-
cipito-frontalis and the cellular tissue covering the zygomatic region ; the fibres con-
verge from their origin, and are inserted into the front of the helix. It is covered by the
skin, and lies upon the temporal fascia, from which it is separated by the temporal artery
and vein.
Action. — To draw the auricle forward and upward (anterior auriculae, Albinus).
The Auricularis Posterior.
This muscle {d',fig. 113) is much more decidely marked than the preceding, and is
composed of two or three distinct fleshy fasciculi (tres retrahentes auriculam, Albinus),
which extend from the base of the mastoid process, and sometimes also from the occipi-
tal bone to the lower part of the concha.
Action. — To draw the aiu-icle backward.
MUSCLES OF THE FACE.
All the muscles of the face are arranged in groups around its several openings, and
may be classed either as dilators or constrictors. The nostrils alone have no constrictors.
The eyelids must be opened and closed entire, without the production of any folds ;
the nostrils must remain constantly open, for the skin around these orifices has within it
a corresponding lamina of cartilage, which gives it the necessary tension, strength, and
elasticity, and into which the muscles are inserted. There is no such arrangement at
the orifice of the mouth, the muscles being there inserted into other muscles.
From the three openings around which the muscles of the face are grouped, these may
be arranged into three distinct regions, viz., the palpebral, the nasal, and the buccal.
MCSCLES OF THE PALPEBRAL ReGION.
Orbicularis Palpebrarum. — Super ciliaris. — Levator Palpebra Superioris.
The muscles of the eyelids are divided into constrictors and dilators. There is one
constrictor, viz., the orbicularis palpebrarum, to which the corrugator supercilii is an ac-
cessory ; there is also one elevator, viz., the levator palpebrae superioris.
The Orbicularis Palpebrarum.
Dissection. — ^Make an elliptical incision through the skin round the base of the orbit ;
dissect successively the upper and lower half of the muscle, proceeding from the adhe-
rent towards the free border of each eyelid. It is of more importance here than in any
other situation to dissect the skin parallel to the fleshy fibres. When the external sur-
face of the muscle has been studied, detach it carefully from the subjacent parts, and re-
flect it inward.
The orbicularis palpebrarum {e',fig. 113) forms an elliptical zone of variable size round
the eyelids, and also an extremely thin layer upon them. It is a sphincter, and, like all
muscles of this kind, is composed of circular fibres ; but, as a special exception, it is also
provided with a remarkable tendon of origin, named the straight tendon of the orbicularis ;
this is about two hues in length and half a line in breadth, arises from the ascending pro-
cess of the superior maxilla, anteriorly to the lachrymal groove, and passes in front of
2JK5 MYOLOGY.
the lachrymal sac, where it divides into two unequal parts, an upper and smaller, and a
lower more capacious ; sometimes it corresponds entirely to the upper part of the sac.
At first it is flattened from before backward, but is then twisted upon itself, so as to pre-
sent one surface upward and another downward. Opposite the inner angle of the eye-
lids, this tendon, which is also called the palpebral ligament, becomes bifurcated, and
each division is attached to the inner end of the corresponding tarsal cartilage ; from the
posterior surface of the tendon a very strong aponeurotic lamina is given off, and forms
the outer wall of the lachrymal sac : this is the reflected tendon of the orbicularis palpebra-
rum. Fleshy fibres proceed from the anterior and posterior surfaces, and from the bor-
ders of the straight tendon, and also from the anterior border of the reflected tendon ;
but the greater number arise by well-marked tendinous prolongations from the external
orbital process of the frontal bone, from the ascending process of the superior maxilla,
and from the internal and lower third of the base of the orbit. From these origins the
fleshy fibres pass outward, dividing into two halves, an upper, which describes concen-
tric curves with the concavity directed downward, and a lower, also describing concen-
tric curves, but with the concavity directed upward (duo palpebrarum musculi, Vcsalius).
Each of these halves is subdivided into two sets of fibres : an external set, surrounding
the base of the orbit ; and an internal or palpebral, belonging to each eyelid : hence the
distinction drawn by Riolanus between the orbicularis and the ciliaris or palpebralis mus-
cles. The external fibres (forming the orbicular portion) describe a complete ellipse. I
have never met with the fibrous intersection at the outer part of the eye, mentioned by
some anatomists. The palpebral or ciliary fibres, forming the proper palpebral portion,
arise from the bifurcation of the tendon, and describe concentric arcs, which are united
on the outside at an acute angle to a cellular raphe.
Relations. — The orbicular portion is closely united to the skin by means of a fibrous
and adipose tissue, which is very compact over the upper, and loose over the lower por-
tion of the muscle ; it is connected with the skin of the eyelids by a serous cellular tis-
sue, remarkably susceptible of infiltration. It covers the lachrymal sac, the corrugator
supercilii muscle, the orbited arch, the maxillary bone, the temporal muscle, and the su-
perior attachments of the zygomaticus major, of the levator labii superioris alaeque nasi,
and of the levator labii superioris.
It is separated from the conjunctiva by a fibrous membrane and the tarsal cartilages.
Its circumference is blended with the pyramidalis nasi on the inside, with the occipito-
frontalis and corrugator above, but is free below ; occasionally it gives off a few fibres
from its outer border, some of which form the zygomaticus minor, and others of a pailer
colour terminate in the skin.
Actions. — ^The orbicularis acts in the same manner as £ill other sphincters, that is to
say, the circular fibres of which it is composed contract towards the centre ; but, as the
fleshy fibres have their fixed point at the straight tendon, and still more at the internal
insertions, it follows that, during the contraction of this muscle, it is thrown in some
measure inward, and by it the integuments of the forehead, the temple, and the cheek
are drawn towards the inner angle of the eye. The intimate adhesion between the skin
and the upper half of the muscle explains why, during its contraction, that part is ren-
dered more apparent beneath the skin than the lower. The palpebral portion contracts
independently of the orbicular, a fact that confirms the distinction made by Riolanus.
Nor is this all : the contraction of this palpebral portion, or palpebralis muscle, properly so
called, is habitually involuntary, while the contraction of the orbicular portion is subject
to the will. The palpebral fibres are pale, and resemble the muscular fibres of the ali-
mentary organs ;* the orbicular fibres are red, like those of the muscles of animal life.
When the palpebral fibres contract, they do not produce the occlusion of the eye, by a
concentric approximation of the fibres, but by bringing together the free edges of the eye-
lids, the only method permitted by the tarsal cartilages. The curve described by the
rnuscular fibres of the lower being smaller than that formed by those of the upper eye-
lid, it follows that the closing of the eyes depends principally upon the latter.
The Super ciliaris.
Dissection. — Make a vertical incision in the median line between the frontal muscles ;
ttim back carefully the frontal and the orbicularis muscles from within outward.
The superciliaris (corrugator supercilii, Albinus, a', Jig. 114) is a narrow and tolerably
thick fasciculus, generally of a deeper red than the orbicularis, and situated along the
superciliary arch, with the direction of which it corresponds. It arises by one, often by
two or three portions, from the internal portion of this arch ; proceeds upward and out-
ward, describing a slight curve, having its concavity downward, and is blended with the
orbicularis palpebrarum at about the middle of the arch of the orbit. From this arrange-
ment, Albinus described it as a root of the orbicularis. According to some authors, it
terminates in the skin of the eyebrow (cutaneo-surcilier, Dumas) ; but I have always
found it attached to the deep layer of the orbicularis muscle.
* See note *, p. 238.
THE LEVATOR PALPEBE^ SUPERIORIS, ETC. 2SSt
Relations. — It is covered by the pjrramidalis nasi, the orbicularis palpebrarum, and the
occipito-frontalis, and it covers the os frontis, the supra-orbital and frontal arteries, and
the frontal branch of tlie ophthalmic nerve.
Action. — This muscle corrugates the eyebrow, and dravrs it downward and inward. It
is, therefore, regarded as the principal agent in the expression of grief The repeated
contraction of these muscles in irascible individuals gives a character of severity to the
countenance, from the constant approximation of the eyebrows, and the permanence of
the vertical wrinkles formed between them.
The Levator Palpebrce Supreioris.
Dissection. — Remove the roof of the orbit by two cuts with a saw, meeting at an acute
angle opposite the foramen opticum ; detach the bone with care, so as to leave the peri-
osteum untouched ; cut the periosteum from before backward, and separate the frontal
nerve which passes above and parallel to the muscle, which may then be separated care-
fully from the superior rectus muscle of the eye.
The levator palpebro'. superioris (see description of the eyelids) is an elongated, flat,
triangular, and very thin muscle, placed in the orbital cavity, directed horizontally from
behind forward, and curved at its anterior extremity, sa as to form a concavity directed
downward. It arises from the inferior surface of the lesser wing of the sphenoid, im-
mediately above the optic foramen, and from the sheath of the optic nerve, and is insert-
ed into the upper border of the tarsal cartilage. Its sphenoidal origin consists of a small
tendon, and its attachment to the sheath of the optic nerve is a fibrous ring common to
aU the muscles of the eye. From these points the fleshy fibres proceed forward, form-
ing a broad, thin bundle, increasing in width and diminishing in thickness towards its
tarsal insertion, which is effected by means of a broad aponeurosis.
Relations. — Covered by the periosteum of the orbit, from which it is separated by the
frontal branch of the ophthalmic nerve ; covered, also, by some adipose tissue and by the
fibrous membrane of the upper eyelid, it covers the superior rectus of the eye and the
conjunctiva.
Action. — It raises the upper eyelid. Its reflection over the globe of the eye explains
that peculiar motion of the eyelid by which its upper edge is buried below the orbital
arch. The relaxation of this muscle suffices for the depression of the upper eyelid in
passive closure of the eyes, while the active occlusion depends on the contraction of the
orbicularis.
There is no analogous muscle for the lower eyelid, which scarcely concurs either in
opening or shutting the eyes.
NASAL REGION.
The Pyramidalis Nasi. — Levator Labii Superioris Alceque Nasi. — Tranaver salts, or Trian-
gularis Nasi. — Depressor Ala. Nasi. — Naso-labialis.
The muscles of this region are the pyramidalis nasi, the levator labii superioris alae-
que nasi, the transversalis or triangularis nasi, the depressor alae nasi, or myrtiformis,
and the naso-labialis of Albinus.
The Pyramidalis Jfasi.
Dissection. — ^Trace doiwn upon the dorsum of the nose the internal fibres of the occip-
ito-frontalis, directing the scalpel parallel to these fibres, which have a vertical course.
The pyramidalis nasi (/, fig. 113) is a prolongation of the internal fibres of the occipito-
frontalis, of which it may be regarded as a prolongation (frontahs pars per dorsum nasi
ducta, Eustachius). It lies upon the bridge of the nose on each side of the median line.
It is separated from the muscle of the opposite side by a thin layer of cellular tissue. It
is narrower at its origin than at its termination, which takes place in the aponeurosis of
the transverse muscle of the nose.
Relations. — It is covered by the skin, to which it closely adheres, especially below, and
it covers the nasal bones and lateral cartilages.
Action. — This small muscle has been regarded as an elevator of the ala. and, conse-
quently, a dilator of the nose ; but I believe it rather acts in depressing the inner angle
of the eyebrow, and the skin between the eyebrows. In this respect it has considerable
influence upon the expression of the countenance.
The Levator Labii Superioris AlcRque JSTasi.
Dissection. — Make a vertical or somewhat oblique incision from the ascending process
of the superior maxilla to the upper lip. Reflect outward the inner and lower part of the
orbicularis muscle.
This muscle (^, fig. 113) is thin, triangular, and divided into two portions below. It
extends from the ascending process of the superior maxilla to the ala of the nose and the
^upper lip. It arises by a narrow extremity from the internal orbital process of the frontal
bone, immediately below the tendon of the orbicularis palpebrarum, passes obliquely
Go
234 T ,? >7, MYOLOGY.
downward and outward, becomes much broader, and is inserted partly into the cartilage
of the ala of the nose, or, rather, into the very dense skin which covers it, and partly into
the orbicularis oris, or, rather, into the skin of the upper lip. The cutaneous portion of
this muscle is distinguished by its paleness, compared with the red colour of the rest.
Relations. — It is covered by the skin, and a small portion of the orbicularis palpebrarum ;
and it covers the ascending process of the superior maxilla, and the transverse muscle of
the nose.
Action. — It elevates both the ala of the nose and the upper lip. I consider it the most
important of all the muscles of the nose, because the elevation of the alae dilates the nos-
trils, and thus aids most essentially in cases of impeded respiration. It is a respiratory
muscle of the face, and has, also, great influence over the countenance, producing the
expression of contempt. Its action upon the upper lip is of much less importance than
that upon the nose.
The Transversalis, or Triangularis JVasi.
Dissection. — Remove with great care the skin covering the ala of the nose, and then fol-
low this muscle below the inner edge of the common elevator ; or, what is better, remove
all the soft parts covering the ala of the nose, and dissect the muscle from its deep surface.
The transversalis vusi (compressor narium, h',figs. 113, 114), which I regard as a de-
pendance of the muscle next to be described, is a small and very thin triangular muscle,
stretching from the inner part of the canine fossa to the bridge of the nose. It arises by
a narrow extremity from the canine fossa, passes forward, enlarging as it proceeds along
the ala of the nose, and terminates by a very thin aponeurosis, which is blended in the
median line with that of the opposite side, and with the pyramidalis. It is covered by
the skin, to which it closely adheres, and by the common elevator ; and it covers the car-
tilage of the ala, and a small part of the superior lateral cartilage of the nose.
Action. — The action of this small muscle is not yet weU determined. Some have
agreed with Riolanus in considering it a dilator (qui alam naris diktat sine elevatione
nasi, Riolanus) ; others think, with Spigelius and Albinus, that it is a constrictor of the
nose (primi paris constringentium alas, Spigelius ; compressor naris, Albinus). It is prob-
able that its action varies according to the shape of the ala : if this be concave outward,
it is a dilator ; if convex outward, it is a constrictor. Its action is very slight.
The Depressor Alee JVasi, or Myrtiformis.
Dissection. — Evert the upper lip, and remove the mucous membrane on each side of
the fraenum. The two myrtiformes may then be separated by a vertical incision in the
median line. It will be apparent that the myrtiformis and transversalis form only one
muscle, which arises from the alveolar border near the lateral incisor, the canine and the
anterior bicuspid teeth, and is distributed to the orbicularis oris, the alae, and the septum
of the nose.
This muscle {if, fig- 114) is short and radiated, and arises by a narrow extremity from
the incisive or myrtiform fossa of the superior maxilla, opposite the canine and two in-
cisor teeth (incisif moyen, Winslow). Its fibres diverge upward and outward, and are in-
serted thus : the lower, or descending, behind and in the substance of the orbicularis oris ;
and the upper or ascending, into the ala and septum of the nose. Its upper border is
not distinct from the lower border of the transversalis. Chaussier, on account of its
termination in the upper lip, regarded it as one of the origins of the orbicularis oris.
Relations. — It is covered by the buccal mucous membrane, by the orbicularis oris, and
the common elevator, and it lies upon the maxillary bone. It is continuous, without any
line of demarcation with the transversalis nasi. The inner border of the muscle of one
side is separated from that of the other by an interval, corresponding to the fraenum of
the upper lip.
Action. — It depresses the ala of the nose, and has also been considered a depressor of
the upper lip (depressor labii superioris,* Cowper). I regard it rather as an elevator of
that lip.
The J^aso-labialis of Albinus.
This consists of a fasciculus which it is difficult to demonstrate in many subjects. It
arises from the anterior extremity of the septum of the nose, passes horizontally back
ward, is then reflected downward, and terminates like the preceding in the orbicularis,
of which it may be considered a root.
MUSCLES OF THE LABIAL REGION.
rhe Orbicularis Oris. — Buccinator. — Levator Labii Superioris. — Caninus. — Zygomatict,
Major et Minor. — Triangularis. — Quadratus Menti. — Levator Labii Superioris. — Move-
ments of the Lips and those of the Face.
No region has so many muscles as the orifice of the mouth : seventeen, nineteen, and
* Depressor labii superioris aliBque nasi of other writers.
THE ORBICULARIS ORIS AND THE BUCCINATOR. 4)85
often twenty-one muscles, are grouped round it, viz., the orbicularis oris, the common
elevators of the alae and lip already described, the proper elevators of the lip, the great zy-
gomatics, the canine, the buccinators, the triangulares,the quadrati or the levatores menti ;
and often two muscles on each side, viz., the risorius of Santorini, and the small zygomatic.
The Orbicularis Oris.
Dissection. — Make an elliptical incision round the opening of the mouth, and dissect
back the skin with great care, the mouth being previously distended by the introduction
of tow between the lips and alveolar borders.
The orbicularis oris (J,' I', figs. 113 and 114) is the sphincter of the orifice of the mouth ;
it is essentially the constituent muscle of the lips, occupying the entire space betweeii
the free edge of the upper lip and the nose, and the free edge of the lower lip and the
transverse furrow above the chin.
We shall consider, with Winslow, the orbicularis to be composed of two halves, each
constituted by a demi-zone, of semi-elliptical concentric fibres, terminating on either side
at the commissures of the lips. These fibres, which are all fleshy, do not become con-
tinuous opposite the commissures of the lips, but only intersect each other, those of the
upper half being continuous with the lower fibres of the buccinator, and those of the low-
er half with the upper fibres of the same muscle.
The thickness of the two halves varies in different individuals, particularly around the
free borders of the lips, where the fasciculi of the muscle are somewhat everted. In
the negro this is very remarkable. The thickness of the lips depending upon this cir-
cumstance must be distinguished from that which is the effect of a scrofulous habit.
Relations. — These muscles are covered by the skin, to which they adhere intimately,
and hence the facility of bringing together the entire depth of the surface of wounds in
the lips, by retentive applications to the skin only. They cover the mucous membrane
but are separated from it by the labial glands, the coronary vessels, and a great number
of nervous filaments. Their outer circumference receives all the extrinsic muscles of
the lips, which terminate in these as in a conmion centre. Their inner circumference
circumscribes the opening of the mouth. The differences in the dimensions of this open-
ing occasion the varieties observed in the size of the mouth, but the capacity of the buc-
cal cavity is in no way influenced by these variations.
Actions. — These are exceedingly various, and may be studied as connected with the
closing of the mouth, with the prehension of aliments by suction, with the playing upon
wind instruments, and with the expression of the countenance. I shall here only notice
the shutting of the mouth.
This may be accomplished simply by the approximation of the jaws, which is followed
by a corresponding motion of the lips. In active occlusion, or that dependant on the
orbicularis, two things may happen : either the lips may be closely drawn against the
teeth, and their free edges applied to each other, or they may be pushed forward and
puckered ; in the latter case, the buccal opening, which is usually represented by a trans-
verse line, resembles a circular, or, rather, a lozenge-shaped orifice.
The Buccinator.
Dissection. — Distend the cheeks by stuffing the mouth with tow ; make a transverse
incision through the skin, from the commissure of the lips to the masseter muscle, and
dissect back the flaps': in order to gain a good view of the posterior border of the mus-
cle, turn downward the zygomatic arch and the masseter, and then divide with the saw
the inferior maxilla in front of the ramus.
The buccinator (fig. 113, and b,figs. 114 and 147) is the proper muscle of the cheek;
it is broad, thin, and irregularly quadrilateral. It is attached above to the external sur-
face of the superior alveolar arch, along the space between the first great molar and the
tuberosity of the maxilla ; below, to the external surface of the inferior alveolar arch,
or, rather, to that part of the external oblique line of the lower jaw which corresponds
with the last two great molars ; and behind, to an aponeurosis existing between this
muscle and the superior constrictor of the pharynx (see fig. 147). This aponeurosis, to
which the name of buccinato-pharyngeal has been given {ptery go-maxillary ligament), ex-
tends from the apex of the internal pterygoid process to the posterior extremity of the
internal oblique line of the lower jaw. From these different origins the fleshy fibres
proceed forward, the upper somewhat obliquely downward, the lower obliquely upward,
and the middle fibres horizontally. In consequence of this arrangement, the fibres inter-
sect each other opposite the commissure of the lips, from which points the lower fibres
of the muscle proceed to terminate in the upper half of the orbicularis, while the upper
fibres end in the lower half of the same muscle.
Relations. — It is situated deeply behind, where it is covered by the ramus of the lower
jaw, the masseter, and a small part of the temporal muscle ; from all these parts, how-
ever, it is separated by a considerable quantity of adipose tissue, and by a mass of fat
which exists even in the most emaciated individuals. More anteriorly it is covered by
■-■■'•.■"■~,Trrr"''" "
236 MYOLOGY.
the zygomaticus major and the zygomaticus minor, and the risonus jf Santorini, where
the two latter exist ; and at the commissure it is covered by the canine muscle {levator
angnli oris) and the triangularis. The Stenonian duct runs along this muscle before
passing through it ; the buccal nerves and the branches of the transverse facial artery
lie parallel to its fibres; the external maxillary (i. e., the facial) artery and vein pass
perpenaicularly across it, near the commissure. A peculiar aponeurosis, called the buc-
cal fascia, is closely united to it, and intervenes between it and all these parts. It cov-
ers the mucous membrane of the cheek, from which it is separated by a dense layer of
the buccal mucous glands.
Action. — It is the most direct antagonist of the orbicularis. When the cheeks are not
distended, its contraction elongates the opening of the mouth transversely, and, conse-
quently, renders the hps tense, and produces a vertical fold upon the skin of the cheek.
This fold becomes permanent in the aged, and constitutes one of their most prominent
wrinkles.
When the cheeks are distended by air, or any other substance, the buccinator becomes
curved instead of flat, and acquires all the properties of the former class of nmscles.
Thus the first effect of its contraction is, that its fibres become straight, or have a ten-
dency to become so ; gaseous, liquid, or solid bodies, are then expelled from the mouth,
rapidly if the orbicularis offer no obstacle, and gradually should that muscle contract.
The buccinator, therefore, fulfils an important ofiice in performances upon wind instru-
ments, and hence its name {buccinare, to sound the trumpet). la mastication it is of no
less importance, since it pushes the food between the teeth, and expels it from the sort
of groove existing between the cheeks and the alveolar arches.
The Levator Labii Superioris.
Dissection. — Reflect the lower half of the orbicularis palpebrarum upward, and dissect
with care the lower extremity of the muscle about to be described, which adheres close-
ly to the skin. It can be best studied from the inner surface.
This muscle (c', fig. 1 14) is thin and quadrilateral. It is situated upon the same plane
as the common elevator, of which it appears to be a continuation, and extends from the
base of the orbit to the skin of the upper lip.
It arises from the inner half of the lower edge of the base of the orbit, on the outei
side of the common elevator : from this origin, which is sometimes bifid, the fibres con-
verge dovraward and inward, and are inserted successively into the skin, probably into
the bulbs of the hairs, as in animals which have mustaches ; so that this muscle would
deserve the name of mustachie, which is given by some anatomists to the naso-labial of
Albinus.
Relations. — Its two upper thirds are deeply seated ; its lower third adheres closely to
the skin. It is worthy of notice, that almost all the muscles of the face are deeply
seated at one of their extremities, and terminate by the other in the skin. It is covered
by the orbicularis palpebrarum and the skin, and it covers the infra-orbital vessels and
nerves, as they escape from the infra-orbital canal. It is also in relation with the ca-
nine muscle, from which it is separated by a quantity of adipose tissue, with the trans-
versalis nasi, and with the orbicularis oris, being interposed between the latter muscle
and the skin.
Action. — It raises the upper lip, and draws it a little outward.
The Caninus.
Dissection. — Merely reflect the levator labii superioris.
The canine muscle (levator anguli oris, Albinus, d,fig. 114), so named from its origin,
arises from the canine fossa by a broad attachment, from which it proceeds downward
and a little outward, diminishing in size, and becoming gradually more superficial, to
the commissure of the lips, where it terminates by uniting with the zygomaticus major,
and becoming continuous with the triangularis oris. We often find some accessory
fibres arising from this muscle, and attached to the skin opposite the commissure.
Relations. — Above, it is concealed by the levator labii superioris and the infra-orbitary
vessels and nerves ; below, it is quite superficial, being only covered by the skin. It
covers the superior maxilla, the buccinator, and the buccal mucous membrane.
Action. — It raises the angle of the mouth, and, from its oblique position, draws it inward.
The Zygomatici Major et Minor.
Dissection. — Make an oblique incision from the malar bone to the commissure of the
lip, and remove carefully, from the great zygomatic, the fatty tissue which surrounds it.
The Zygomaticus Major.
This muscle {m',fig. 113) is a cylindrical, fleshy fasciculus, extending from the malar
bone to the conunissure of the hp. It arises, by tendinous fibres, from the entire length
of a horizontal furrow, situated above the lower edge of the malar bone. The fleshy
fibres approach each other so as to form a fasciculus, which passes obliquely downward
THE TRIANGULARIS, ETC. 237
and inward towards the commissure, where it is closely united to the canine muscle,
and, like it, is continuous with the triangularis or depressor anguli oris.
Relations. — It is covered by the skin, from which it is separated above by the orbicu-
laris palpebrarum, and below by a large quantity of adipose tissue ; it covers the malar
bone, the masseter and buccinator muscles, a great collection of fat, and the labial vein.
Action. — It draws the angle of the mouth upward and outward ; by carrying the com-
missure upward, it assists the canine muscle, but in drawing it outward, it antagonizes the
same. When the zygomatic and canine contract together, the commissure is drawn di-
rectly upward.
The Zygomaticus Minor. •
This small muscle {n',fig. 113), which is often wanting, maybe regarded as a depend-
ance of the proper elevator of the upper lip. It arises from the malar bone, above the
great zygomatic, passes downward and inward to the outer border of the levator labii su-
perioris, with which it is blended. It is not uncommon to find this muscle enlarged by
fasciculi given off from the outer and lower circumference of the orbicularis muscle of
the eyelids. It is covered by the skin and the orbicularis palpebrarum ; and it covers
the canine muscle and the labial vein.
Action. — It assists the common elevator in raising the upper lip and drawing it some-
what outward.
The Triangularis, or Depressor Anguli Oris.
Dissection. — Make a vertical incision of the skin, from the commissure of the lips to the
base of the jaw ; then follow the course of the muscidar fibres as they are successively
exposed.
This muscle {o',fig. 113) is of a triangular shape, as its name implies, and belongs to
the inferior maxillary region. It arises, by a broad base within, from the lower border of
the inferior maxilla on the side of the median line, and sometimes from the median line
itself; and without, from the external oblique line : from these points the fibres pass in
different directions, the external almost vertically upward, the internal obliquely upward
and outward (the obliquity increasing as we proceed inward), and describing a curve with
the concavity looking inward. All these fibres are concentrated into a narrow and thick
fasciculus, which terminates at the commissure, on a plane anterior to the fibres of the
buccinator and the orbicular oris, being evidently continuous with the canine and the
great zygomatic.
Relations. — It is covered by the skin, beneath which it is clearly discernible, and it cov-
ers the quadratus menti, the platysma, and the buccinator. Some colourless fibres, which
intersect those of the quadratus at a right angle, and, moreover, follow the same direc-
tion as those of the triangularis, may be regarded as a dependance of that muscle, to the
inside of which they are situated. They terminate in the skin, like those of the quadratus.
Action. — It depresses the angle of the mouth, thus antagonizing the canine muscle and
the great zygomatic, with which it is continuous. The continuity of these muscles is so
manifest, that they may be regarded as constituting a single muscle, broad and triangu-
lar below ; bifid above, to form the canine and zygomatic ; and narrow in the middle,
where it corresponds to the commissure. The internal fibres of the triangularis, from
their oblique direction, are directly opposed to those of the canine muscle ; but its exter-
nal fibres have not a similar relation to those of the zygomaticus major.
The Quadratus Menti, or Depressor Labii Inferioris.
Dissection. — Dissect back the skin covering this muscle, cutting obliquely downward
and outward.
The quadratus menti {-p'tfig. 113 ; q',fig. 114), situated to the inside of the preceding, is
of a square, or, rather, lozenge shape. It arises from the external oblique line of the low-
er jaw, and is in a great measure continuous with the platysma, the fibres of wliich pass
behind, and sometimes through the triangularis. From this origin it proceeds obliquely
upward and inward, therefore in an opposite direction to the triangularis, and is inserted
into the skin of the lower lip, on a plane anterior to the corresponding half of the orbicu-
laris oris. It is closely united to the skin, and covers the lower jaw, the mental nerve
and vessels, the lower half of the orbicularis oris, and the muscle next to be described,
with which it is intimately connected. It is separated from the muscle of the opposite
side by the prominence of the chin below, but is blended with it above.
Action. — It depresses the lower lip : from the obliquity of this muscle, it also draws out-
ward and downward each half of the lower lip, which is therefore stretched transversely.
The Levator Labii Inferioris.
Dissection. — Evert the lower lip ; divide the mucous membrane at its reflection upon
the lip from the lower jaw, so as to expose the origin of the muscle. In order to show
its cutaneous insertion, carefully dissect off the skin covering the chin. As the muscles
of each side are blended in the median line, it is necessary to make a vertical incision
from before backward, opposite the symphysis, in order to separate them.
2^ MYOLOGY.
This muscle (levator menti, Alb., r',Jig. 114) is a small conoid fasciculus, which forma,
in a great measure, the prominence of the chin. It arises from the facette on the side of
the symphysis menti, opposite the incisor teeth, whence the name incisif inferieur, Wins-
low, which is also given to this muscle. From this point the fibres expand like a tuft,
downward and forward, to be inserted into the skin. It is red and fasciculated at its or-
igin above, but pale, intermixed with fat, and not fasciculated below, where it is blended
on the inside with the opposite muscle, and on the outside with the quadratus menti.
Its upper fibres form a concavity above, which partially embraces the great circumfer-
ence of the lower half of the orbicularis oris.
Action. — It raises and wrinktes the skin of the chin, and, consequently, raises the low-
er lip, and projects it forward. It appears somewhat singular at first that an elevator of
the lip should be situated below it.
General Considerations regai-ding the Movements of the Lips, and those of the
Face in general.
If we take a general view of the muscles of the face, we shall observe, 1. That no re-
gion is provided with so great a number of muscles ; 2. That all these muscles are at-
tached to a bone by one extremity, while the other is implanted into the skin, or into
other muscles ; 3. That the cutaneous portion of these muscles is colourless and non-
fjisciculated, presenting all the characteristics of involuntary muscles ;* 4. That those
portions which are attached either to the bone or to other muscles have, on the contrary,
aH the characters of the voluntary muscles.
All these muscles are arranged around the several openings of the face, and, conse-
quently, they are either constrictors or dilators ; the orifice of the mouth, however, is
peculiar! in having the greater number of the muscles of the face specially intended for
it. Indeed, the orbicularis oris, or sphincter of the mouth, is antagonized by the bucci-
nators or transverse dilators ; by the proper elevators of the upper lip, and the common
elevators of that and the alae of the nose ; by the depressors of the lower lip, or quadrati ;
by the elevators of the angle of the mouth, viz., the canine muscles, the zygomatici ma-
jores, and, where they exist, the zygomatici minores, and the two risorii of Santorini ;
and, lEistly, by the depressors of the commissure, or triangulares oris.
The lips fulfil a great number of uses, all requiring a considerable degree of mobility. •
They serve for the prehension of aliments, for suction, and for the articulation of soundsj *'
whence the name labial given to consonants specially produced by the action of the lips, '
as b, p, m : they modify the state of the expired air so as to produce in it vibrations of a
peculiar character, constituting the act of whistling ; and, in this respect, they illustrate
the mechanism of the glottis : they assist in mastication, by retaining the food and con-
stantly forcing it between the teeth : they are also employed, during performances upon
wind instruments, in regulating the volume of the column of air which strikes upon the
body to be thrown into vibrations. The mechanism of their action varies according to
the kind of instrument : sometimes, for example, they assist in graduating the rapidity
of the column of air, by influencing the orifice through which it issues, as occurs in play-
ing upon the flute ; and sometimes they represent vibrating cords situated at the mouth
of an instrument, and determining the different tones by their various degrees of ten-
sion. In this case, the lips themselves become the vibrating bodies, and propagate their
oscillations to other bodies with which they are in contact, independently of the effect
produced in the instrument from the passage of a column of air. Examples of this are
observed in playing on the horn, trumpet, &c.
If we examine the muscles of the face in connexion with their influence in producing
emotional expressions, we shall find that they are often almost completely removed from
the influence of the will, as, for example, where those emotions are not simulated ; but
that sometimes, on the contrary, their contraction is altogether voluntary, as in those
individuals who, either by profession or habit, are accustomed to imitate feelings which
they do not really experience. Nevertheless, it should be remarked that, although the
outward expression of every passion may be produced at will upon the face, yet there is
always a great difference between the natural emotion and the fictitious representation.
On the whole, the general expressions of the countenance may be regarded as varie-
ties of two great types, viz., those of the cheerful and those of the melancholy emotions.
* This similarity is limited, however, to the colour and general aspect of the two kinds of muscles ; for
even the palest muscular fasciculi of the face are found to consist of striated fibres, precisely similar to those
of the other voluntary muscles ; but the fasciculi into which they are collected are neither so evident nor so large.-
t Man greatly exceeds all animals in the number of muscles attached to his lips. The ape, which is ni'"^
markable for the great mobility of its physiognomy, has, properly speaking, only one muscle for the entire face,
which is a dependance of the platysma (or cutaneous muscle) ; therefore, the play of its countenance is con-
fined to a grimace, which is always the same, only differing in intensity, and which does not permit it to ex
press different and even opposite passions, such as are often depicted upon the human countenance.*
* £The platysma myoides in monkeys is certainly extended, as a single muscle, over the entire cheek, and
forms a muscular layer, covering the lateral pouches appended to the mouth in some of that tribe of animals.
In addition to this, however, monkeys have precisely the same number of muscles attached to their lips as in
the human subject : they possess, indeed, all the facial muscles found in man ; and, like him, they appear to
be capal)le of expressing, by changes in their features, a variety of internal emotions.]
THE MASSETER. 239
The cheerful emotions are expressed by the expansion of the features, i. e., their retrac-
tion from the median line, a movement that is due to the occipito-frontalis, the levatores
palpebrarum, and especially to the great zygomatic muscles. The melancholy passions,
on the contrary, are expressed by the approach or concentration of the features towards
the median line, which is chiefly effected on either side of the face by the corrugator
supercilii, the depressor anguli oris, the common and proper elevators of the upper lip,
the levator labii inferioris, and the quadratus menti.
On account of the intimate connexion between the skin of the face and the facial mus-
cles, which, from the nature of their insertions, are in some measure identified with it,
the frequently-repeated contraction of one or more of these muscles occasions folds oi
wrinkles of the skin that remain during the intervals of those contractions, and aftei
they have entirely ceased. And thus the continual experience of grave or cheerful emo-
tions, with their characteristic expressions of countenance, at length impresses a pecu-
liar and permanent stamp upon the features, so that those who are in the habit of close
ly observing such circumstances may in some degree judge of the disposition of an indi
vidual from an examination of his physiognomy. This is the only foundation of the sys
tern of Lavater.
MUSCLES OF THE TEMPORO-MAXILLARY REGION.
The Masseter and Temporalis.
The muscles of this region are four in niunber ; two on each side, viz., the massetei
and the temporal.
The Masseter.
Dissection. — ^Make a horizontal incision along the zygoma, and a vertical one from the
middle of this to the base of the jaw ; dissect back the flaps, taking care not to divide
the Stenonian duct, which passes over the muscle. In order to see the deep surface, saw
through the zygoma in two places, and turn it outward.
The masseter {s,Jig. 113) is a short and very thick muscle, of an irregularly-quadrilat-
eral form, situated upon the side of the face.
Attachments. — It arises from the lower edge of the zygoma, and is inserted into the
outer surface of the angle and ramus of the lower jaw. Its origin from the zygoma
consists of a very thick aponeurosis, which embraces the anterior borders of the mus-
cles, and is composed of several planes of super-imposed fibres, which are prolonged
upon its surface and in its substance for a considerable distance. Tlie fleshy fibres pro-
ceed from the inferior surface and the borders of this aponeurosis, obliquely downward
and backward, and are inserted into the angle of the jaw either directly or by means of
very strong tendinous fibres. Not unfrequently a small triangular fasciculus is detached
forward to the inferior border of the body of the bone. The fleshy fibres arising from
the posterior portion of the zygoma constitute a short, small, and almost entirely fleshy
bundle, which passes vertically downward, and is inserted behind the preceding into the
external surface of the ramus of the jaw. Lastly, the zygomatic arch being reversed,
we see a still smaller fleshy fasciculus, arising directly from its internal surface, and
T^assmg forward, to be inserted into the outer surface of the coronoid process, and into
the tendon of the temporal muscle.
Relations. — It is covered by the skin, from which it is separated by a small fascia, and
sometimes by a prolongation of the platysma ; behind, it is covered by the parotid gland,
and by the orbicularis palpebrarum and zygomaticus major above. It is crossed at right
angles by the divisions of the facial nerve, the transverse artery of the face, and the
Stenonian duct. It covers the ramus of the jaw, the temporal and the buccinator mus-
cles, from the latter of which it is separated by a collection of fat. Its anterior edge,
which is prominent beneath the skin, has an important relation below to the facial ar-
tery, which may be compressed against the bone immediately in front of it. The parot-
id gland embraces its posterior border.
Action. — The action of this muscle is very powerful. Its strength in different animals
may be in some degree measured by the size of the zygomatic arclu and by the promi-
nence of tiie lines and projections on the angle of the jaw.
Its momentum, i. e., its period of most powerful action, occurs when the jaws are
slightly separated, because its angle of incidence with regard to the lever is then nearly
perpendicular. The general direction of the fibres of the masseter muscles, obliquely
downward and backward, is highly advantageous as regards the trituration of the food,
for during the contraction of the two muscles the lower jaw is moved upward and for-
ward. This same obliquity explains the action of the muscle in producing luxation of
the jaw ; for as its insertion is farther back than it would have been had the fibres been
vertical, it follows that, however slightly the jaws may be separated, the condyle is
placed in front of the axis, to which all the fibres of the masseter may be referred ; and
when this muscle contracts, it increases the peculiar movement performed by the con-
dyle in becoming dislocated forward.
240
MYOIiOGY.
The Temporalis.
Dissection. — Having sawn through and turned back the zygoma, remove the fascia
covering the temporal region, and the fat surrounding the insertion of the muscle into
the coronoid process. In order to gain a view of the deep surface, detach the muscle,
either from above downward, by scraping the periosteum from the temporal fossa, or
from below upward, after having sawn through the base of the coronoid process.
The temporal muscle {e', fig. 114), or crotaphyte, so named because it occupies the
whole of the temporal fossa {Kporacjioc, the temple), is a broad, radiated muscle, resem-
bling a triangle with the base turned upward.
Attachments. — It arises from the whole extent of the temporal fossa, and from the in-
ner surface of the superficial temporal fascia, and is inserted into the edges and summit
of the coronoid process. The fleshy fibres all arise directly, either from the temporal
fossa, or from the inner surface of the fascia, which, being attached above to the entire
length of the temporal semicircular line, and below to the upper edge of the zygomatic
arch, is very tense, and thus affords a solid and very strong surface of origin. From
these two parts the fleshy fibres converge, and proceeding downward, the anterior ob-
liquely backward, the posterior obliquely forward, and the middle vertically, form a fleshy
mass, which gradually increases in thickness until its fibres are attached, partly to the
external, but chiefly to the internal surface and borders of the terminal aponeurosis.
The fibres of this aponeurosis, which are very strong, and radiated at its comm'ince -
ment, are collected into the form of a very thick tendon, inserted into the coronoid pro-
cess, and called the coronoid tendon. The temporal muscle, in its course from the tem-
poral fossa to the coronoid process, undergoes a sort of reflection over the groove at the
base of the zygoma. I have often seen a very strong muscular fasciculus arising from
the lower part of the temporal fossa and the ridge bounding it below, and inserted by a
separate tendon into the internal border of the anterior surface of the ramus of the jaw.
Relations. — It is covered by the skin, the aponeurosis of the occipito-frontalis, the an-
terior and superior auricular muscles, the superficial temporal arteries, veins, and nerves,
and more immediately by the superficial temporal aponeurosis, the zygomatic arch, and
the masseter. It covers the temporal fossa, the external pterygoid muscle, a small
part of the buccinator, the internal maxillary artery, and the deep temporal vessels. Its
thickness is in proportion to the depth of the temporal fossa and the strength of the
coronoid process.
Action. — The strength of the temporal muscle, therefore, may be in some degree
measured by the depth of the temporal fossa and the size of the coronoid process. This
fact may be demonstrated by an examination of these regions in the skeletons of carniv-
orous animals, in which the elevators of the lower jaw are most highly developed. The
use of the temporal muscle, like that of the masseter, is to elevate the lower jaw, but
the mechanism of its action is diflerent. In fact, the masseter raises the jaw by a direct
action ; the temporal muscle, on the contrary, raises it by a sort of swing motion, acting
principally upon the back part of the coronoid process. In a word, the temporal muscle
acts upon the vertical arm of the bent lever represented by the maxillary bone, while
the masseter, on the contrary, acts upon its horizontal arm, the movement depending on
the action of the temporal muscle : the lower jaw resembles the curved lever represent-
ed by the hammer of a beU.
THE PTERYGO-MAXILLARY REGION.
The Pterygoideus Internus. — The Plerygoideus Externus.
The muscles of this region are the external and the internal pterygoids.
Fig. 115
The Pterygoideus Internus vel Magnus
Dissection. — Separate the face and that part of
the cranium which is situated anterior to the ver-
tebral column from the remainder of the scull,
and divide the face into two lateral halves by an
antero-posterior section.
' This muscle may also be dissected in the fol-
lowing manner : saw through the lower jaw ver-
tically at the junction of the body and ramus ; re-
move the zygomatic arch ; cut through the base
of the coronoid process and the neck of the con-
dyle, and then disarticulate the latter.
The internal pterygoid {a, fig. 115) is deeply
seated m the zygomatic fossa, along the inner
surface of the ramus of the jaw(tertius nmsculus
qui in ore latitat, Vesalius). It is thick and quad-
THE PTERYGOIDEttS EXTERNUS, ETC.
iilateral, and in its form, structure, and direction, bears a remarkable reselrtBlarice to the
masseter ; hence Winslow called it the internal masseter.
Attachments. — It arises from the pterygoid fossa, from the hamular process, at the apex
of the internal pterygoid plate, and from the lower surface of the pyramidal process of
the palate bone ; and is inserted into the inner surface of the angle of the lower jaw
Its origin consists of a tendon resembling that of the msisseter, prolonged upon the in-
ternal surface, and into the substance of the muscle. From this the fleshy fibres pro-
ceed downward, outward, and backward, to be inserted, by very strong tendinous laminae,
into the lower jaw.
Relations. — On the inside it is in relation with the external peristaphyhne muscle
{tensor palcti), and with the pharynx, a triangular interval existing between it and the
latter, occupied by a considerable quantity of cellular tissue, vessels, nerves, and the
sub-maxillary gland : on the outside it corresponds with the ramus of the lower jaw,
from which it is separated above by the dental and lingual nerves, the inferior dental
vessels, and the so-called internal lateral ligament of the temporo-maxillary articulation.
Action. — As this muscle is inserted almost perpendicularly into the lever upon which
it acts, it has very great power. Most of the remarks already made concerning the mas-
setor apply to this muscle, which is a true internal masseter. It has only this peculiar-
ity, that as its origin is nearer the median line than that of the external masseter, it
assists in producing a slight lateral movement of the jaw, which is very useful in bruis-
ing the food.
The Pierygoideus Externus vet Parvus.
Dissection. — This, like the preceding muscle, may be exposed by two opposite methods.
The external pterygoid {b,fig. 115) is very short, thick, and conoid, smaller than the
preceding, and situated in the zygomatic fossa, extending horizontally from the outer
surface of the external pterygoid plate to the neck of the condyle of the lower jaw. It
arises from the whole outer surface of the external plate of the pterygoid process, and
from the facette of the palatine process, at which it terminates below, from the ridge
separating the temporal and zygomatic fossae, and from a spinous process at the extrem-
ity of this ridge, which appears to me worthy of notice. It is inserted into the fossa in
front of the neck of the condyle of the lower jaw, and into the border of the interarticu-
lar cartilage. Its origin consists of a strong tendon, prolonged into the substance of
the muscle. From this the fleshy fibres proceed horizontally outward and backward,
forming, at first, two distinct portions, between which the internal maxillary artery often
pjisses : these two portions then converge, are blended together, and terminate by some
small tendinous fibres, which form the truncated summit of the cone represented by the
muscle, and are attached to the neck of the condyle and to the inter-articular cartilage.
Relations. — This muscle is deeply situated, and is in relation on the outside with the
ramus of the lower jaw, the temporal muscle, and the internal mcixillary artery ; on the
inside with the internal pterygoid, and above with the upper wall of the zygomatic fossa.
Action. — The axis of the external pterygoid being directed outward and backward,
and its origin being at the pterygoid process, it may be readily imagined that its con-
traction will produce a horizontal motion in two directions, viz., forward and to the op-
posite side from that on which the muscle is acting. When the two external pterygoids
act together, the jaw is carried directly forward. From the insertion of this muscle into
the inter-articular cartilage, the latter is never separated from the condyle during these
several movements. It is principally this muscle which causes displacement of the con-
dyle in cases of fracture of the neck of the bone, and it is also the chief agent in bruis
ing the food.
MUSCLES OF THE UPPER EXTREMITIES
The muscles of the upper extremities may be divided into those of the shoulder, oi
the ann, of the forearm, and of the hand.
MUSCLES OF THE SHOULDER
The Deltoidexis. — Supra-spinatus. — Infraspinatus and Teres Minor. — Subscapularis.
The muscles of the shoulder are the deltoid, the supra-spinatus, the infra-spinatus
and teres minor (which I regard as only one muscle), and the subscapularis. The teres
major, generally arranged among the muscles of this region, has already been described
with the latissimus dorsi, of which it may be regarded as an accessory.
The Deltoideus.
Dissection. — Make a horizontal incision through the skin, round the summit of the
•houlder, extending from the external third of the clavicle to the most distant point of
the spine of the scapula : from the middle of this incision let another be made, descend-
Hh
242 MYOLOGY.
mg vertically half way down the humerus ; dissect back the two flaps, taking care tc
raise at the same time a very thin aponeurosis, which is closely applied to the fibres.
The deltoid {I, figs. 106, 109), so named from its resemblance to the Greek delta, A, re-
versed, is a thick, radiated, triangular muscle, bent in such a way as to embrace the
scapulo-humeral articulation before, on the outer side and behind. It is the muscle of
the top of the shoulder.
Attachments. — It arises from the entire length of the posterior border of the spine of
the scapula, from the external border of the acromion, and from the external third, i. e.,
from the concave part of the anterior border of the clavicle : it is inserted into the del-
toid impression on the humerus. The scapulo-clavicular origin of the deltoid corre-
sponds exactly to the inferior attachment or the insertion of the trapezius, so that these
two muscles, although separate and distinct in man, appear to form a single muscle di-
vided by an intersection : a view that is perfectly confirmed by a reference to compara-
tive anatomy. The origin consists of tendinous fibres ; of these the posterior are the
longest, and are blended with the infra-spinous aponeurosis, which also gives origin to
some of the fibres of the deltoid. Three or four principal tendinous laminae, attached at
regular intervals to the clavicle and the acromion, penetrate into the substance of the
muscle, and give origin to a great number of fleshy fibres. The largest of these laminae
extends from the summit of the acromion, and its situation is sometimes indicated by a
prominence of the skin, particularly during contraction of the muscle. From this very
extensive origin the fleshy fibres proceed downward, the middle vertically, the anterior
backward, and the posterior forward : they form a thick, broad mass, moulded over the
top of the shoulder, and, gradually converging, are at length inserted into the deltoid
impression of the humerus by three evry distinct tendons, the two principal of which,
the anterior and posterior, are attached to the bifurcations of that V-shaped impression.
Not unfrequently some fibres of the pectoralis major are connected with the front of this
tendon.
Relations. — It is covered by the skin, the platysma intervening between them, by
some supra-acromial nerves, and by a thin fascia extending from the infra-spinous apo-
neurosis, the spine of the scapula and the clavicle, and becoming continuous with the
fascia of the arm. It covers the shoulder-joint, from which it is separated by a tendi-
nous layer continued from the infra-spinous and coraco-acromial ligaments, and which
terminates on the sheaths of the coraco-brachialis and biceps muscles. Between this
lamina and the greater tuberosity of the humerus there is a quantity of filamentous cel-
lular tissue, and frequently a synovial bursa. The deltoid, therefore, is enclosed in a
proper fibrous sheath, and glides over the articulation. It also covers the upper third
of the humerus, the coracoid process, the tendons of the pectorales, coraco-brachialis,
biceps, supra-spinatus, infra-spinatus and teres minor, teres major, and biceps muscles,
also the circumflex vessels and nerves. The anterior border of the deltoid, directed ob-
liquely downward and outward, is separated from the external margin of the pectoralis
major by a cellular interval, but is frequently in contact with it. The cephalic vein and
a small artery define the limits of the two muscles. The posterior border is thin above,
where it is applied to the infra-spinatus muscle, and becomes thick and free below. The
inferior angle of the deltoid is embraced by the brachialis anticus. Issues are generally
established over this situation.
Remark. — The structure of this muscle has been patiently investigated by some anat-
omists, who have counted the exact number of its component fasciculi. Tliese are sep-
arated by fibro-cellular prolongations, like the fasciculi of the glutaeus maximus ; some-
times, even, the muscle is divided into three distinct portions above, viz., a clavicular,
an acromial, and a spinal. Eighteen or twenty small penniform fasciculi, the bases of
which are generally turned upward, are collected into a small space by mutually over-
lapping each other, and are united by their terminating tendons. Albinus admits ten
of these bundles, which he has described separately.
Action. — The deltoid elevates the shoulder (elevator, attollens humerum). From the
threefold direction of its fibres, it has a different action, according to the particular set of
fibres employed. The middle fibres raise the humerus directly, the anterior raise and
carry it forward, the posterior raise and carry it backward. When the arm is raised,
Bichat states that the anterior and posterior fibres can depress it ; but I do not think
this possible. There has been no example recorded of luxation from the over-action of
this muscle. When the arm is fixed, as in the act of climbing, the aJioulder is moved
upon the head of the humerus. The trapezius must be regarded as the most powerful
antagonist of the deltoid, since the scapulo-clavicular attachments of both muscles are
the same. Thus, we have seen that the diaphragm and the transversalis abdominis are
separated only by their costal insertions. The most complete antagonism follows from
such an arrangement, for then one fibre is, as it were, opposed to another, having ex-
actly an opposite direction.
The action of the deltoid is, however, less powerfnl than might have been supposed
from its size ; it is, in fact, parallel to the lever on which it acts. While almost all other
muscles have a mmnentum, occurring at the period when their fibres are inserted at the
THE SUPRA AND INFRA S>ilJiATUS AND TERES MINOR. S48
most favourable angle, the deltoid, pioperly speaking, has none ; it is parallel to the lever
during the entire period of its action. This is the reason vthy the elevation of the arm
is so feeble a movement, and why contraction of the deltoid is always accompanied by
considerable fatigue.
The Supra-spinatus.
Dissectimi. — Take off the trapezius, and, in order to see the whole extent of the mus-
cle, remove the clavicle, and saw through the base of the acromion.
The supra-spinatus {r,fig. 106) is a thick, triangular muscle, broad on the inside, nar-
row without, occupying the supra-spinous fossa, and retained therein by a strong apo-
neurosis, which completes the osteo-fibrous sheath in which the muscle is enclosed.
Attachments. — It arises from the internal two thirds of the supra-spinous fossa, and is
inserted into the highest of the three facettes on the greater tuberosity of the humerus
Its origin from the supra-spinous fossa is partly tendinous and partly fleshy, and sora„
fibres arise from its aponeurotic investments. From these points the fleshy fibres con-
verge to a tendon, which is found among them where the muscle reaches the upper part
of the joint, and which is slightly reflected over the head of the humerus before reaching
its insertion. This has not the shining appearance of other tendons, but has the dull
aspect of many ligaments ; it is blended with the fibrous articular capsule, from which
it cannot be separated near its insertion. It may even be regarded as forming the upper
part of the capsular ligament.
Relations. — It is covered by the trapezius, the clavicle, the coraco-acromion ligament,
and the deltoid ; and it covers the supra-spinous fossa, the supra-scapular vessels and
nerves,* and the upper part of the shoulder-joint. Its tendon is often blended with that
of the. infra-spinatus, and is separated from that of the sub-scapularis by the long head
of the biceps, and the accessory ligament of the capsule.
Action. — It raises the humerus, and therefore assists the deltoid. Notwithstanding
the nmnber of its fibres, and its perpendicular insertion into its lever, it has very little
power, on account of the proximity of that insertion to the fulcrum. Its principal action
appears to me to have reference to the joint, affording a support to it above, and forming
a sort of active arch, the resisting power of which is in proportion to the force tending
to thrust the humerus upward against the osteo-fibrous arch, composed of the acromion
and coracoid processes and their connecting ligament. There is no muscle, then, to
which the name of articular can be more correctly applied. The use of the deep fibres
in preventing the folding of the fibrous and synovial capsules, and their compression be-
tween the two articular surfaces, though much insisted on by Winslow, appears to me
very problematical.
The Infra-spinatus and Teres Minor.
Dissection. — ^Detach the scapular origin of the deltoid, and saw through the base of the
acromion.
The infraspinatus (s) and teres minor {t, Jig. 106) constitute a single, thick, triangular
aiuscle, broad on the inside and narrow externally, and occupying the infra-spinous fossa,
in •rt'hich it is retained by an aponeurosis, exactly resembling that of the supra-spinatus
uiuscle.
It aiises from the internal two thirds of the infra-spinous fossa, from a very strong
fascia interposed between it and the teres major and long head of the triceps, and by a
'ew fibres from the infra-spinous aponeurosis : it is inserted into the middle and inferior
'acettes on the greater tuberosity of the humerus, below the insertion of the supra-spi-
natus. It arises from the infra-spinous fossa, directly by fleshy fibres, and also by means
uf tendinous fibres attached along the ridges of that fossa. One of these laminae is con-
stantly found attached to the ridge situated on the outer side of the infra-spinous groove :
ihis has doubtless given rise to the division of the muscle into two parts, called the in-
fra-spinatus and the teres minor. From these origins the fleshy fibres proceed, the su-
perior horizontally, the next obliquely, and the inferior almost vertically outward : they
form a thick, triangular, fleshy body, and become attached to the anterior surface and
margins of a flat tendon, which glides upon the concave humeral border of the spine of
th,3 scapula, to be inserted into the humerus. Not unfrequently we find the lower fibres
of the portion called the teres minor, arising from the posterior surface of the tendon of
the triceps, becoming applied to the imder part of the capsular ligament, and inserted
into the humerus immediately below the great tuberosity.
Relations. — These two united muscles are covered by the deltoid, the trapezius, the.
Jatissimus dorsi, and the skin ; and they cover the infra-spinous fossa, from which they
are separated by the supra- scapular nerves and vessels ; they also cover the capsular
ligament of the joint, and a small portion of the long head of the triceps. Their lower
or external border corresponds internally or inferiorly with the teres major, an aponett-
rotic septum intervening between them, and externally or superiorly with the long head
jf the triceps.
* The supra-scapular nerve generally passes through the coracoid notch by itself, and the supra-scapulat
lery above the ligament.
244 • ?:'.»,«r^ ' MYOLOGY
Action. — This muscle rotates the humerus t,atward and a little backward. When the
arm is raised, it assists in keeping it in this position, and carries it backward. But an
important use of this muscle is that of retainmg the head of the humerus in its place, pre-
venting its displacement backward, and protecting the posterior part of the articulation.
The Sub-scapularis.
Dissection. — Detach the upper extremity, including the shoulder, from the trunk of the
body ; remove from the inner surface of the muscle the cellular tissue, the lymphatic
glands, the brachial plexus, the axillary vessels, and the serratus magnus ; and dissect
off, with care, the thin fascia which invests it.
The sub-scapularis (a, figs. 110, 116) is a thick triangular muscle, occupying the whole
of the sub-scapular fossa, beneath the axillary border of which it passes : by itself it rep-
resents the supra and infra spinatus and teres minor, upon the posterior scapular region.
We not unfrequently meet with tendinous laminae dividing it into three parts, which cor-
respond to those three muscles.
Attachments. — It arises from the internal two thirds of the sub-scapular fossa, by ten-
dinous laminae attached to the oblique ridges already described as existing on that part
of the scapula ; also from the anterior lip of the axillary border of the scapula by an apo-
neurosis, which separates this muscle from the teres major and the long head of the tri-
ceps. Very frequently the lowest fibres arise from the anterior surface of this head of
the triceps, just as we have seen that the lower fibres of the teres minor take their ori-
gin from the posterior surface of the same head of that muscle. From these different
origins the fleshy fibres all proceed outward, the upper horizontally, and the lower ob-
liquely, gradually approaching more and more to the vertical direction. The muscle,
therefore, becomes progressively narrower and thicker, until its fibres are attached to
the two surfaces and borders of a tendon which is inserted into the entire surface of
the lesser tuberosity of the humerus. Some of the muscular fibres are inserted below
the tuberosity ; and I have seen the inferior fibres of the muscle attached for a certain
extent to a fibrous prolongation that completes the bicipital groove behind.
Relations. — The posterior surface of this muscle lines the sub-scapular fossa, which it
entirely fills, and from which it is separated at the outer third by some cellular tissue
and the sub-scapular vessels and nerves ; more externally, it covers the upper and anterior
part of the capsular ligament of the shoulder-joint, turning around it, and becoming iden-
tified with it at its insertion. Its anterior surface is in relation with the serratus magnus,
the sub-scapular fascia, and some very loose cellular tissue intervening between them ;
also with the axillary vessels and nerves, and with the coraco-brachialis and deltoid
muscles. The upper border of its tendon glides in the hollow of the coracoid process,
which serves as a pulley, and forms with the coraco-brachialis and the short head of the
biceps a sort of ring, partly bony and partly muscular, in which the tendon is retained.
Between this tendon and the coracoid process there is also a synovial bursa, which some-
times extends over the tendons of the biceps and coraco-brachialis, and always commu-
nicates with the synovial capsule of the shoulder-joint.*
Action. — It is essentially a rotator inward of the humerus. In proof of this, we find
that the muscie is stretched when the arm is rotated outward, and relaxed when it is ro-
tated inward. The movement of rotation is much more considerable than the length of
the neck of the humerus would lead us to imagine, and this arises from the muscle turn-
ing round the head of the bone. As a rotator muscle, then, it is congenerous with the
latissimus dorsi. When the humerus is raised, the sub-scapularis tends to draw it down-
ward. And farther, this muscle, as well as the supra-spinatus, infra-spinatus, and teres
minor, is essentially an articular muscle, and is sometimes completely identified with the
anterior part of the fibrous capsule : in all cases it offers an active resistance to displace-
ment forward, and is, therefore, always torn in this kind of dislocation.
MUSCLES OF THE ARM.
The Biceps. — Brachialis Anticus. — Coraco-brachialis. — Triceps Extensor Cubiti.
The muscles of the arm have been divided into those of the anterior region, viz., the
biceps, the coraco-brachialis, and the brachialis-anticus ; and those of the posterior region,
which constitute the single muscle called the triceps.
Anterior Brachial Region.
The Biceps.
Dissection. — Make a vertical incision through the skin from the middle of the clavicle
to the middle of the bend of the elbow ; dissect back the flaps, and divide longitudinally
the brachial fascia, which is united to the biceps by very loose cellular tissue ; preserve
the vessels and nerves which lie along the inner border of the muscle. Expose the up-
per part of the muscle by detaching the pectoralis major and deltoid from their clavicu-
* See note, p. 22.
THE BICEPS.
Fig. 116.
tax origins, and turning them inward and outward. In order to trace the whole extent
of the long head of the biceps, open the capsular ligament above ; and to see the radial
insertion of the muscle, flex the forearm to a right angle upon the arm, and supinate it
forcibly ; it is better, however, to wait until the muscles of the anterior region of the fore-
arm are dissected.
The biceps flexor cubiti (a, flg. 116) is along muscle forming the superficial layer of the
anterior region of the arm ; it is divided above into a short and
long head ;* and hence its name biceps.
Attachmcjits. — It arises by its short head from the apex of the
coracoid process, and by its long head from the top of the glenoid
cavity ; and is inserted into the bicipital tuberosity of the radius.
The origin of the short or coracoid head {b,fig. 116) consists
of a flat and very thick tendon, common to it and the coraco-
brachialis, and terminating in front of this part of the muscle in
an aponeurosis, from which is given off a tendinous septum, be-
tween the biceps and the coraco-brachialis. The long, glenoid,
or reflected head arises by a tendon apparently forming a contin-
uation of the glenoid articular border, which penetrates into the
interior of the joint, turns over the head of the humerus, upon
which it is reflected, and thus reaches the bicipital groove. It
is retained in this groove by a sort of fibrous bridge or canal,
traverses the whole of its extent, and ends in a sort of tendinous
cone open behind, from the interior of which the fleshy fibres
take their origin. These fibres are collected into a rounded belly,
which, about the middle of the arm, is applied to the muscular
belly of the short portion, equally rounded and of variable size,
and ultimately becomes identified with it. The single muscle
(fl, fig. 116) thus formed is very thick, flattened from before
backward, and directed vertically like the two original fasciculi.
Its fibres are attached to the surfaces and edges of an aponeuro-
sis, which gradually becomes narrower and thicker, until it emerges in the form of a free
tendon opposite the lower end of the humerus, a little nearer to the outer than the inner
side. This flattened tendon sinks downward and backward into the triangular space be-
tween the supinator longus and the pronator teres, and is then so folded and twisted upon
itself that its anterior surface becomes posterior, its internal margin becomes anterior,
and its external margin at first posterior and then superior. This folding and torsion are
of extreme utility in preventing displacement of the muscle, which thus fastens down it-
self The tendon of insertion having given off from its anterior surface and external
margin a broad aponeurosis, constituting the principal origin of the fascia of the fore-
arm, glides over the bicipital tuberosity of the radius, from which it is separated by a
bursa, and is inserted into the posterior part of that process.
Relations. — The upper third of the two heads of the biceps, as well as the coraco-brach-
ialis, and the axillary vessels and nerves, are contained in the cavity of the axilla, be
tween the pectoralis major and the deltoid in front, and the latissimus dorsi and teres
major behind. In this part of its course, the short head of the biceps is in relation Witt
the coraco-brachialis on the inside, and behind with the sub-scapularis, which separates
it from the shoulder-joint ; a bursa intervenes between these two muscles. The tendon
of the long head is in contact with the head of the humerus, and surrounded by the sy-
novial membrane, which isolates it from the cavity of the joint, and accompanies it, for
a greater or less distance, along the bicipital groove. Below the axilla the biceps is sub-
cutaneous in front, the brachial fascia intervening between it and the skin, through which
it is very clearly defined ; behind, it is in relation with the musculo-cutaneous nerve, and
the coraco-brachialis and brachialis anticus muscles ; on the inside, with the brachial ar-
tery and its accompanying veins, and with the median nerve, all of which lie along its in-
ternal border, by the projection of which they are protected. The tendon is embraced at
its insertion by the supinator brevis, and it is separated from that of the brachialis anti-
cus by a bursa. Great attention should be paid to the relation of this muscle to the brach-
ial artery. I am accustomed, when speaking of the surgical anatomy of these parts,
to call the biceps the satellite muscle of the brachial artery. It is worthy of remark, that
the relative positions of the long and the short head are altered as the humerus is rota-
ted inward or outward ; in rotation inward, the long head is placed behind the other, or
even crosses to the inner side of it ; but in rotation outward, the interval between the
two heads is considerably increased.
Action. — The biceps flexes the forearm upon the arm, and at the same time supinates it.
This last effect results from the insertion of the muscle into the inner and back part of
the bicipital tubercle of the radius. The momentum of the biceps occurs during seini-
* Not unfrequently the biceps is trifid above. The supernumerary head is internal, and arises from the in-
ner border of the humerus, below the coraco-brachialis, which may be regarded as the continuation of this
head, for they correspond in size. This supernumerary portion is attached to the inner edge and posterior
surface of the lower tendon of the biceps. 1 have twice seen this disposition of parts.
246 MYOLOGY.
flexion of the forearm • its insertion being at that period perpendicular to tiie lever, the
disadvantage arising from its proximity to the fulcrum is then counteracted. The length
of Its fibres explains the extent of the movement of flexion. By means of its scapular
attachments, the biceps acts upon the arm, either secondarily, after bending the forearm,
or primarily, when the forearm is extended. By means of both its heads, it carries the
arm forward, and thus co-operates with the anterior fibres of the deltoid and coraco-brach-
ialis. The two heads also assist in strengthening the shoulder-joint. The long head
forms a sort of fibrous arch, which supports the head of the humerus, and retains it in the
glenoid cavity. The short head, together with the coraco-brachialis, forms a continuation
of the hook of the coracoid process, and protects the anterior and inner part of the joint.
The biceps is, as Winslow first showed, one of the principal supinators of the forearm ;
and it is in this movement that the tendon glides over the bicipital tuberosity of the ra-
dius by means of the intervening bursa. This tuberosity is almost entirely intended for
the tendon to glide over ; it is, therefore, incrusted with cartilage. Dense and reddish
granulations, as pointed out by Haller, are found upon the synovial bursa of the tendon.
When the forearm is fixed, as in climbing, the biceps flexes the arm upon the fore-
arm, and the scapula upon the arm. Lastly, it is a tensor of the fascia of the forearm,
upon which the internal fibres of the muscle often terminate.
The Brachialis Anticus.
Dissection. — Cut the biceps across, opposite the insertion of the deltoid, and turn down
the lower part upon the forearm.
The brachialis anticus (brachialis internus, Alb., d d,fig. 116; d,fig. 117) is a thick,
prismatic, and triangular muscle, situated behind the preceding. It arises from the hu-
merus, below the insertion of the deltoid, which it embraces by a well-marked bifurca-
tion ; and since the point of insertion of the deltoid is not always the same, it follows that
this origin of the brachialis anticus is eilso variable ; it also arises from the internal and
external surfaces, and from the three borders of the humerus, and from the external and
internal inter-muscular septa. It is inserted into the rough surface on the fore part of the
coronoid process of the ulna. The different origins from the humerus are fleshy, the
fibres being of very various lengths, and proceeding in different directions ; the middle
pass vertically downward, the external somewhat obliquely inward, and the internal out-
ward ; they all terminate on the posterior surface of an aponeurosis, which is broad and
thin above, and thick below, especially on the outer side, where it turns round so as to
embrace the outer border of the muscle, and forms a deep aponeurotic lamina. The
fleshy fibres, therefore, are received into a semi-cone of tendinous substance, open on
Che inside, the fibres of which are collected together, and finally inserted into an oblique
line, running downward and outward, below the coronoid process of the ulna.
Relations. — The anterior surface of the brachialis anticus is in relation with the biceps,
the musculo-cutaneous nerve, the brachial fascia, the brachial artery and veins, and the
median nerve ; its internal surface, with the pronator teres muscle, the ulnar nerve, and
the triceps, from which it is only separated by the internal inter-muscular septum ; its
external surface, with the supinator longus and the extensor carpi radialis longior, which
are received into a sort of groove presented by it, the radial nerve establishing the limit
between these two muscles and the brachialis anticus. The posterior surface embraces
the internal and external surfaces of the humerus, to which it is attached ; below, it em-
braces, and effectually protects the front of the elbow-joint, into the anterior ligament of
which many of its fibres are inserted.
Action. — The brachialis anticus flexes the forearm upon the arm, and, reciprocally, the
arm upon the forearm. Its momentum takes place, like that of the biceps, during semi-
flexion. It is worthy of remark, that this muscle acts with greater precision than the bi-
ceps upon the forearm, because it arises from the humerus only, and, besides that, it be-
longs more especially than that muscle to the elbow-joint. I have already said that it
may be regarded as the active anterior ligament of this articulation. In fact, it so com-
pletely hmits the movement of extension, that we cannot imagine the possibility of lux-
ation of the forearm backward without rupture of this muscle. From the insertion of
the biceps into the radius, and of the brachialis anticus into the ulna, it follows that the
flexor muscles of the forearm are divided between the two bones, in the same manner
as those of the leg are distributed to the tibia and fibula Thus, the contraction of the
brachialis anticus has a tendency to carry the forearm outward as well as to flex it,
while that of the biceps tends to draw it inward. When the two muscles contract si-
multaneously, direct flexion is the result.
The Coraco-brachialis.
Dissection. — The upper part is exposed as soon as the deltoid is detached ; the middle
is situated between the pectoralis major and the latissimus dorsi ; and the lower part is
seen upon the mner surface of the humerus, near the tendon of the deltoid.
The coraco-brachialis {e,figs. 116, 117) is the smallest muscle of the arm. It is situa-
ted at the inner and upper part of the arm, and was confounded by most of the oldei
THE TRICEPS EXTENSOR CUBITI.
«4T
anatomists with the short head of the biceps, with which, indeed, it is intimately united
at its upper part.
Attachments. — It arises from the apex of the coracoid process, and is inserted towards
the middle of the internal surface and border of the humerus. It arises from between
two tendinous layers, the most superficial of which is common to it and the short head
of the biceps, and also from the septum between these two muscles. From this origin
the fleshy fibres proceed, forming an elongated, thin, and flat bundle, the size of which is
always in an inverse ratio to that of the short head of the biceps ; this bundle passes
downward, backward, and a little outward, to be inserted into the humerus, between the
brachialis anticus and the triceps. Its insertion is effected by means of a flat tendon,
which receives the fleshy fibres successively upon its edges and external surface, and is
accompanied by them even to its attachment to the bone. The precise situation of the
attachment varies like that of the deltoid, and hence the different statements of authors
regarding this point. According to Winslow, the coraco-brachialis is inserted at the up-
per part of the middle third of the humerus ; according to M. Boyer, in the middle of the
bone ; and according to Bichat, a little above its middle. I have found it inserted at
the junction of the lower with the two upper thirds.
Relations. — It is covered by the deltoid, the pectoralis major, and the biceps, and it
covers the sub-scapularis, the latissimus dorsi, and the teres major. Its relations to the
axillary and brachial arteries, and the median and musculo-cutaneous nerves, are the
most important. Above, it covers these parts, and then it is in relation with the outer
side of the brachial artery and median nerve, so that its tendon alone separates the ves-
sel from the bone. The musculo-cutaneous nerve passes through it ; hence the name
of -perf mains Casserii has been given to this muscle. It is also very frequently perfora-
ted by one of the branches of origin or roots of the median nerve.
Action. — It cames the arm forward and inward, and, at the same time, elevates it
It co-operates with the anterior fibres of the deltoid, and the superior fibres of the pecto-
ralis major. If the arm be fixed, it depresses the top of the shoulder ; when the arm is
carried backward and turned inward, it draws it forward again, and rotates it outward.*
Posterior Brachial Region.
The Triceps Extensor Cubiti.
Dissection. — It is exposed by simply removing the skin and the fascia from the back
of the arm, by removing the deltoid, or turning it upward, and by tracing the long head
of the muscle between the teres major and minor to the axillary border of the scapula.
In order to render it tense, and thus facilitate the dissection, the forearm must be flexed
and the humerus abducted.
The triceps extensor cubiti {ifg,fig. 117) is a very large muscle, divided above into three
portions, named the external, internal, and middle, or
long heads. It constitutes by itself the entire muscular
apparatus of the posterior region of the arm.
Attachments. — It arises, 1. By its long head, from the low-
er part of the glenoid cavity of the scapula, and from a
rough, triangular depression existing on the contiguous
portion of its axillary border ; 2. By its external head
(vastus extemus), from all that portion of the posterior
surface of the humerus which is above the groove for the
radial nerve, from the external border of that bone, and
from the external inter-muscular septum ; 3. By its inter-
nal head (vastus intemus), from the whole of the poste-
rior surface of the humerus below the groove for the ra-
dial nerve, from the internal border of the bone, and from
the internal inter-muscular septum. It is inserted into
the back of the olecranon.
The origin of the middle or long head (which we shall
find to be analogous to the rectus cruris)t consists of a
tendon that is blended with the glenoid ligament, nearly
in the same manner as the long tendon of the biceps.
This tendon is flattened from before backward, and soon
splits into two layers, united by their outer edges, the
posterior of which is thin and short, while the anterior
is very thick, especially at its outer edge, and prolonged
to the middle of the muscle. The head of the humerus,
therefore, is bound by the long head of the triceps below,
in the same manner as by the long tendon of the biceps
* I have seen a small supernumerary coraco-brachialis extending from the base of the corait't ."v**.^
below the lesser tuberosity of the humerus, immediately beneath the insertion of the sub-scapularis : the same
arrangement existed on both sides. This small muscle described a curve in front of the sub-soapularis.
t The older anatomists regarded this long portion as a separate muscle : longus [Riolanus Albirms), cubitum
Rxtendentium primus (Yesalius), le grand ancone (Winslow).
248 a!Y'):,'|(;y.
above. The fleshy fibres arise from between the two layers above mea^.o.icu, and form
a bundle flattened in front and behind, which irnmediately turns upon itself, so that its
anterior surface becomes posterior, and vice versa. From this sort of torsion the strong-
est layer of the tendon, which was originally in front, eventually occupies the posterior
surface of the muscle. The fleshy fibres arising from between the two layers, and es-
pecially from the anterior surface and borders of the now posterior tendon, pass down-
ward and a little outward, to be inserted, some into the anterior, but the greater number
into the posterior surface of an aponeurotic expaosion, the external border of which is
continuous with a similar structure belonging to the external division of the muscle.
The aponeurotic fibres are collected together into a very thick tendon, which is folded
into a semi-cone, within which the fleshy fibres terminate ; the tendon itself is inserted
by a thick mass into the inner and back part of the olecranon, on the outer side of the
internal portion of the muscle, and closely united with the posterior aponeurosis of the
external portion. A synovial capsule intervenes between this tendon and the olecranon.
The origins of the external and internal portions from the humerus divide between
themselves, so to speak, the posterior surface of that bone, to which the long head has
no attachments.
The external head {f,figs. 116, 117), which is larger than the internal, and, from analo-
gy, may be termed the vastus externus of the triceps brachii (cubitum extendentium secun-
dus, Vesalius ; ancon6 externe, Winslow), arises partly by fleshy and partly by tendinous
fibres. They are bounded above by a rough line, which is very well marked in powerful
individuals, extending obliquely from the lower part of the head of the humerus to its
external border. From these different origins the fleshy fibres proceed dovnward and
inward, become partly blended with the internal head, and are almost all attached to the
anterior surface of the terminal aponeurosis of the long head, and to the anterior sur-
face and external edge of a very broad and strong tendon, which occupies the posterior
aspect of the muscle. This latter tendon is united internally with the tendon of the long
head, is folded upon itself, and receives the fleshy fibres as far as its insertion into the
olecranon, on the outside of the long head. The inferior fleshy fibres of this portion of
the muscle are very short and horizontal, and seem to be continued by the anconeus.
The internal head of the triceps (tertius cubitum extendentium, Vesalius ; ancone in-
terne, Winslow, g, figs. 116, 117), which we denominate the vastus internus of the triceps
brachii, might be called the deep and internal portion of this muscle, for, as we find with
regard to the vastus internus of the thigh, it is almost entirely covered by the other two
portions. Its origins are partly fleshy and partly tendinous. The fibres pass in differ-
ent directions, the external downward and inward, a few to the anterior surface of the
aponeurosis of the external head, by which they are concealed, but the greater number
directly to the olecranon, in front of the insertion of the other portions. The internal
pass downward and outward, and terminate, some upon the inner edge and anterior sur-
face of the tendon of the long head, but the greater number directly upon the olecranon,
to the inside of that tendon. The lowest of these fibres are almost horizontal. Somt
of the deepest fasciculi are generally given off from the body of the muscle, to be insert-
ed into the synovial capsule of the elbow-joint.
Relations. — It is covered through nearly its whole extent by the brachial fascia, and
separated by it from the skin, through which it is distinctly defined ; it covers the poste-
rior surface of the humerus, the back of the elbow-joint, the radial nerve, and the deep
humeral artery. It is separated from the muscles of the anterior region of the arm by
the external and internal inter-muscular septa. Its long or scapular portion is in relation
with the deltoid and the teres minor behind, and with the sub-scapularis, the teres major,
and the latissimus dorsi in front.
Action. — The triceps extends the forearm upon the arm, but in order that its long head
may act with effect, the scapula must be fixed by other muscles. The power of this
muscle is not so great as its size and the number of its fibres would indicate, on account
of its disadvantageous insertion near the fulcrum. It is true that here, as in the case
of the triceps femoris, nature has, as much as possible, counterbalanced this disadvan-
tage by inserting the muscle, not into the apex, but into the back part of the olecranon.
We even find, as we have said, a synovial bursa between the tendon and that part of the
olecranon with which it is in contact. It would appear, at first sight, that the momentum
of this muscle would occur during semi-flexion, but a little consideration would show
that, like the triceps femoris, it has, properly speaking, no momentum ; and that the ole-
cranon, which may be regarded as the ossified tendon of the muscle, always has the same
relation to the ulna, whatever be the position of the forearm. It should also be observ-
ed, that this muscle has not nearly so much power during semi-flexion as during exten-
sion, because, in the former case, it is opposed by the flexor muscles, which, in that po-
sition, act with the greatest possible effect ; while in the latter, when the arm and fore-
arm form an obtuse angle, the extensor muscle has the advantage. Lastly, the predom-
inance of the extensor over the flexors is less marked in the arm than in the thigh ; and
even supposing the extensor to possess more intrinsic power, it has less active force,
in consequence of the insertions of the flexors being much more favourable, both as
THE PRONATOR TERES.
349
legards their distance from the fulcrum, and their nearer approach to a perpendicular
direction. Thus flexion evidently predominates at the elbow, and extension at the knee.
This, indeed, ought to be the case, for in the upper extremities the flexion of the elbow
is the movement of attraction and prehension ; while in the lower extremities, the ex-
tension of the knee is an essential position in standing, walking, running, and leaping.
We might suppose the possibility of rupture of the olecranon at its junction with the
coronoid process, during violent extension o{ the forearm, an accident that would be anal-
ogous to fracture of the patella, or rupture of its ligament. The long head of the tricepa
assists in drawing the humerus backward, and slightly adducts the arm. By means oi
its tendon of origin from the scapula, and especially by the outer edge of that tendon,
which is thick, and, £is it were, arched, so as to fit the head of the humerus, the long
head also forms a cord which supports the bone during abduction, and tends to prevent
its displacement ; but, as the glenoid cavity is directed forward, and as its inferior ex-
tremity is situated almost at the junction of the two anterior thirds with the posterior
third of the cavity, it follows that this tendon is well calculated to prevent dislocation
backward, but offers no resistance to displacement forward. Sometimes the lower ex
tremity of the triceps becomes its fixed point, and then it extends the arm upon the fore-
arm, and the shoulder upon the arm.
MUSCLES OF THE FOREARM.
Fig 118.
The Pronator Teres. — Flexor Carpi Radialis. — Palmaris Longus. — Flexor Carpi Ulnaris.
— Flexor Sublimis Digitorum. — Flexor Profundus Digitorum. — Lumbricalcs. — Flexor
Longus Poinds. — Pronator Quadratus. — Supinator Longus. — Extensores Carpi Radia-
lis, Longior et Brevior. — Supinator Brevis. — Extensor Communis Digitorum. — Extensor
Digiti Minimi. — Extensor Carpi Ulnaris. — Anconeus. — Abductor Longus Pollicis. — Ex-
tensor Brevis Pollicis. — Extensor Proprius Indicis.
The muscles of the forearm are divided into those of the anterior, the external, and
the posterior regions.
Muscles of the Anteeior Region.
These muscles form four very distinct layers. The first consists of the pronator teres,
the flexor carpi radialis, the palmaris longus, and the flexor carpi ulnaris ; the second is
formed by the flexor sublimis digitorum ; the third by the flexor profundus digitorum and
the flexor longus pollicis ; and the fourth by the pronator quadratus.
The Pronator Teres.
Dissection. — This muscle is exposed when the inner and anterior part of the fascia of
the forearm is removed. Its origin should be carefully studied.
The pronator teres, or rotundus {a, fig. 118), the most superficial mus-
cle on the anterior and inner aspect of the forearm, forms an oblique
ridge under the skin, upon the inner side of the bend of the elbow.
It is attached above to the inner condyle of the humerus, or epitroch-
lea (a, fig. 1 19), and is inserted below into the middle of the radius (a')-
It arises from the lower part of the inner border of the humerus, from
the inner condyle, from a large inter-muscular septum, separating it
from the flexor carpi radialis and the flexor sublimis, and from the
coronoid process of the ulna on the inner side of the brachialis anti-
cus, by means of a tendinous and fleshy bundle, which is separated
from the rest of the muscle by the median nerve. From these ori-
gins the fleshy fibres proceed obliquely downward and outward (pro-
nateur oblique, Winsl.), surrounding a flat tendon, which appears first
on the anterior surface of the muscle, and then turns over the ante-
rior and external surfaces of the radius, to be inserted at the middle
of that bone. The muscle, therefore, turns spirally around the radius,
but not so completely as the supinator brevis. Its insertion may take
place opposite any point in the middle third of the bone.
Relations. — It is covered by the fascia of the forearm, by the su-
pinator longus and extensor carpi radialis, and by the radial artery
and musculo-spiral nerve : it covers the brachialis anticus and flexor
sublimis, the median nerve by which it is first perforated, and the
ulnar artery.
Action. — The greater the amount of supination of the forearm, the
more effectual is the action of this muscle as a pronator, because
then it is much more completely rolled around the radius. I may
remark that, on account of its obliquity, it is inserted into the radius
at an angle of 45" ; and that, consequently, the direction in which it
operates is rather favourable. It acts with greater advantage in pro-
portion as it is mserted nearer to the upper end of the radius ; and, for this reason, it»
Ii
250 MYOLOGY.
power must vary considerably in different individuals. When pronation is carried asj
as possible, the muscle then becomes a flexor of the forearm. After the preceding i
amination of this muscle, we need no longer be surprised at the great energy of the mo^
ment of pronation, which is much more powerful than that of supination ; nor yet that
is the most natural position of the forearm, for the pronator teres can more than coui
teract the two supinators taken together. In fracture of the bones of the forearm, tb.
muscle tends to obliterate the interosseous space.
The Flexor Carpi Radialis.
Dissection. — It is sufficient to divide and dissect off the anterior part of the fsiscia o!
the forearm, in order to expose this muscle, which may be recognised by the followinj
description :
The flexor carpi radialis (radialis intemus, Albinus, I, fig. 118) is situated immediatelj
within the pronator teres, occupying the superficial layer of the anterior aspect of tht
forearm, and being, as far as its tendon is concerned, the most superficial of all these
muscles. It arises from the lower part of the internal border and from the inner con-
dyle of the humerus {b,fig. 119), and is inserted {h') into the second metacarpal bone.
Its origin consists of a tendon common to it and to the pronator quadratus, palmaris
longus, flexor sublimis, and flexor carpi ulnaris. The fleshy fibres immediately arise
from within a sort of pyramidal aponeurosis given off by this common tendon, and from
the body of the muscle, at first slender, then increasing in size, and again tapering to-
wards its attachment to the two surfaces and edges of a tendon, which forms the lower
two thirds of the muscle, and passes obliquely outward and downward to the level of the
OS scaphoides ; it there penetrates into a groove formed by the scaphoid and the trape
zium, is reflected inward along this oblique groove, and terminates upon the second met-
acarpal bone, spreading out so as to embrace its upper extremity ; it also gives off a ten-
dinous expansion to the trapezium, and sometimes one to the third metacarpal bone.
Relations. — It is covered by the fascia and the skin, through which it is very clearly de-
fined : it is in relation behind with the flexor sublimis ; on the outside, with the tendon
of the flexor pollicis, over which it passes at an acute angle, so as to bind it down ; and
lower down, with the wrist-joint. A very strong tendinous sheath, concealed by the ab-
ductor brevis and opponens pollicis, completes the groove formed by the scaphoid and
trapezium for its tendon, the movements of which are facilitated by a well-marked sy-
novial membrane.* Its most important relation is that of the external border of its ten-
don with the radial artery. The superficial position of the tendon prevents our feeling
the artery when the muscle is contracted.
Action. — It flexes the second row of the carpus upon the first, and this, again, upon the
forearm. Moreover, on account of its reflection, it is a pronator, and, according to
Winslow, it is a more powerful supinator than the supinator longus. Its obliquity down-
ward and outward explains why it inclines the hand to the radial border of the forearm,
and thus acts as an abductor.
The Palmaris Longus.
Although this small muscle is rather a tensor of the palmar fascia than a flexor of the
hand, I have yet judged it proper to describe it in this place, in connexion with the flexor
carpi radialis, which, in contradistinction to this muscle {le petit palmaire), has also been
called le grand palmaire {Bichat). It is a small fusiform, slender, fleshy bundle {c,fig.
118), of about four inches in length, arising {c,fig. 119) from the inner condyle of the
humerus to the inner side of the preceding muscle, and from a small tendinous cone,
which isolates it from that muscle, the flexor sublimis, and the flexor carpi ulnaris. The
fleshy fibres terminate around a flat tendon, which constitutes the lower two thirds of
the muscle (whence the name palmaris longus), proceeds vertically downward and a little
outward, and terminates by expanding in front of the anterior annular ligament {g, figs.
118, 119) of the wrist, and becoming continuous with the middle palmar fascia (c', fig. 118).
This muscle is subject to a great many varieties, and is often wanting ; its fleshy belly
is sometimes very long, and occasionally occupies the middle of the muscle.
Relations. — The same as those of the preceding muscle {flexor carpi radialis) ; its ten-
don is very superficial. It is separated from the neighbouring muscles by a very strong
sheath.
Action. — It is a tensor of the palmar fascia. When this effect has been produced, it
flexes the hand upon the forearm. According to Winslow, it would assist the flexor
carpi radialis in pronation.
The Flexor Carpi Ulnaris.
Dissection — Remove the superficial layer of the fascia covering the inside of the 'ire-
arm, taking care, in dissecting this as well as the other muscles of the forearm, to stop
at the points where that fascia adheres intimately to the fleshy fibres.
* See note, p. 296.
THE FLEXOR SUBLIMIS DIGITORUM.
251
This is the most deep-seated of all the muscles of the superficial layer of the forearm
(ulnaris internus, Alhinus ; cubital interne, Winslow, d,figs. 118, 119, 121, 122).
It arises from the inner condyle of the humerus and from the inner edge of the ole-
cranon, these two origins forming an arch under which the ulnar nerve passes. It also
arises sometimes, though slightly, from the coronoid process of the ulna, from the upper
half of the posterior border of the ulna, through the medium of the fascia of the forearm,
and from the septum between itself and the flexor sublimis. It is inserted into the pisi-
form bone. The origin from the ridge on the ulna is remarkable ; it consists, indeed, of
the fascia of the forearm, which becomes thickened and divided into two layers, one
deep and very thin, the other superficial and very thick ; in the interval between these
the fleshy fibres arise. These fibres are attached to the surfaces and edges of a very strong
tendon, which then appears upon the anterior border of the muscle, and continues to re-
ceive the fleshy fibres on its posterior edge until its insertion into the pisiform bone.
This takes place upon the anterior surface of the bone, like those of the triceps muscles
of the arm and thigh into the olecranon and pateUa. The tendon then becomes continu-
ous with the inferior vertical ligament of the articulation between the pisiform and cunei-
form bones, so that the muscle may, in fact, be regarded as inserted into the fifth meta-
carpal bone.
Relations. — It is covered by the fascia, and is intimately united with it for a consider-
able extent : it covers the ulnar artery and nerve, the flexor sublimis, the flexor profun-
dus, and the pronator quadratus. The most important of all its relations is that with the
ulnar artery, which is at first under it, and then lies along the external edge of its ten-
don, which protects the artery, and serves as a guide in the application of a ligature to it.
I have, therefore, been in the habit of calling this muscle the satellite of the ulnar artery.
Action. — This muscle acts as if it were inserted into the upper extremity of the fifth
metacarpal bone. Were it not for the peculiar mode of its attachment to the pisiform
bone, it would have been inserted parallel to its lever ; whereas it is really inserted at
an angle of about 45°. It flexes the second row of the carpus upon the first, and this
upon the forearm ; at the same time it inchnes the hand towards its ulnar side. Its vio-
mentum, as well as that of the preceding muscle, occurs during semi-flexion of the hand
upon the forearm.
The Flexor Sublimis Digitorum.
Dissection. — ^The portion of this muscle, situated in the forearm, is exposed by cutting
across the middle, and turning aside the pronator teres, the flexor carpi radialis, and the
pahnaris longus, which form a superficial layer in front of it. With a little care, the ori-
gin of this muscle may be separated as far as the inner condyle of the humerus. In re-
moving the pronator teres, it is necessary to be extremely careful to avoid dividing the
radial origin of the flexor sublimis, which forms a very thin prolongation under the pro-
nator. The dissection of the palmar and digital portions of the mus-
cle is the same as that of the flexor profundus.
Divide the anterior annular ligament of the carpus vertically, and
remove the palmar fascia ; examine the disposition of this structure
opposite the heads of the metacarpal bones, and also the relations
of the tendons of the flexor sublimis and flexor profundus in the
palm of the hand ; then dissect the digital sheaths, which must be
divided in order to display the singular manner in which the ten-
dons of the flexor sublimis bifurcate and turn round, so as to em-
brace the corresponding tendons of the flexor profundus.
The flexor superficialis, sublimis, ox perforatus (e e,fig. 118 ; e,jig.
119), is a broad, flat, thick muscle, divided into four portions below.
It arises from the internal condyle or epitrochlea of the humerus,
and from the ulnar and radius, and is inserted into the second pha-
langes of the fingers. It arises from the epitrochlea by the common
tendon, from a rough surface on the fore part of the inner side of
the coronoid process of the ulna, and also from about two inches
of the radius. This latter origin consists of tendinous fibres attach-
ed to that obUque portion of the anterior border of the bone which
extends inward towards the bicipital tuberosity, and from which
arise the supinator brevis above, the flexor longus pollicis below,
and the muscle we are now describing in the middle. A great
number of fibres also arise from the broad aponeurotic septa which
divide this muscle from the flexor carpi ulnaris, and from the other
muscles of the superficial layer, viz., the pronator teres, the flexor
carpi radialis, and the palmaris longus.
From these diflferent origins the fleshy fibres proceed vertically
downward, forming a broad and thick belly, which is almost imme-
diately divided into four portions. These at first are in juxtaposi-
tion, but soon become arranged in two layers, like the tendons of
Fig. 119.
252
MYOLOGY.
the extensor communis, viz., one anterior and larger, consisting of the divisions for the
median and ring fingers (the latter not being so strong as the former), and another pos-
terior, formed by the divisions for the index and little finger. Each division is, indeed,
a small muscle, having its own particular tendon, around which the fleshy fibres are ar-
ranged, at first regularly, and afterward on one side only : they are thus semi-penniform
muscles. The two posterior divisions are not so distinct as the anterior, and have a pe-
culiar arrangement : they generally constitute two small digastric muscles ; that is to
say, a fleshy belly terminates upon a flat tendon, which, becoming enlarged, gives origin,
in its turn, to a new fleshy belly. The four tendons, after emerging from the fleshy fibres,
pass together under the annular ligament {g) of the carpus, in conjunction with the me-
dian nerve, which lies on their outer side, and is often mistaken for a tendon, and with
the tendons of the flexor profundus digitorum and the flexor longus pollicis. This thick
bundle of tendons having reached the palm of the hand, is then distributed in a manner
to be noticed after the description of the flexor profundus, with the tendons of which
those of the flexor sublimis are intimately connected.
Relations. — It is covered by the pronator teres, the flexor carpi radialis, the palmaris
longus, the flexor carpi ulnaris, and the fascia of the forearm ; and it covers the flexor
profundus digitorum, from which it is separated by the ulnar vessels and nerves ; it also
covers the median nerve and the flexor longus pollicis, to- which it generally sends a
tendinous and fleshy prolongation.
The Flexor Profundus Digitorum.
Dissection. — This muscle is exposed by cutting across the flexor sublimis and the flex-
or carpi ulnaris.
The flexor profundus or perforans (i, fl.gs. 119, 120) is situated under the superficial flex-
Fig. 120. °^' which it exceeds in size, but resembles it in being divided below
into four portions.
Attachments. — It arises from the upper three fourths of the internal
and anterior surfaces of the ulna, from a well-marked cavity situated
on the inner side of the coronoid process behind the rough eminence
which gives attachment to the internal lateral ligament of the elbow,
from the inner two thirds of the interosseous ligament, from that part
of the fascia of the forearm which covers the inner surface of the ulna,
and, lastly, by a few fibres, from within and below the bicipital tuber-
osity of the radius. It is inserted into the front of the bases of the last
phalanges of the fingers ii,figs. 119, 120).
The fleshy fibres arise directly from these numerous origins, and
proceed vertically downward, the internal fibres alone being directed
somewhat obliquely forward and outward. The belly of the muscle
thus formed continues to increase in size, and is then divided into four
unequal portions, each constituting a semi-penniform muscle. These
four small muscles are in juxtaposition, and terminate in as many flat
tendons, which occupy the lower two thirds of the anterior surface of
the entire muscle, and are remarkable for being divided into very reg-
ular and closely-united parallel bands of a nearly white colour. The
four tendons emerging from the fleshy fibres at various heights, but
always above the anterior annular ligament of the carpus, pass under
this ligament conjointly with the tendons of the flexor sublimis, the
flexor pollicis longus, and the median nerve. In this situation they
are placed behind the tendons of the flexor sublimis, which are ar-
ranged in two layers, as we have already seen. The tendons of the
flexor profundus are always in juxtaposition, and, moreover, are united
together by means of dense cellular tissue and tendinous bands pass-
ing from one to the other : the fasciculus for the index finger alone remains distinct ;
and, therefore, the flexion of this finger is almost as independent of that of the others as
its extension, for which latter movement it receives a special muscle. Immediately below
the annular ligament the tendons separate from each other ; the two anterior tendons
of the flexor sublimis no longer cover the two posterior, but all four become situated in
front of the corresponding tendons of the flexor profundus, and arrive together at the
metacarpo-phalangal articulations : here they are received, at first, into a very strong
fibrous sheath, resulting from the division of the palmar fascia, and afterward into an-
other sheath {s,figs. 118, 119), which converts the groove in front of the phalanges into
a canal. If we divide any of these digital sheaths, we find the tendon of the superficial
flexor becoming flattened and hollowed underneath, as it were, into a groove, which is
exactly moulded upon the tendon of the deep flexor. About the middle of the first pha-
lanx the tendon of the sublimis ie,fl.g. 119) bifurcates, and gives passage to that of the
profundus, which it embraces by turning round it like the thread of a screw, and be-
coming posterior instead of anterior, as it was before. The two halves of the tendon
then reunite to form a groove having its concavity directed forward, and again separate
THE LUMBEICALES AND THE FLEXOR LONGUS POLLICIS. '253
to be inserted into the rough edge of the groove on the second phalanx. The tendon of
the flexor profundus (i' i', figs. 119, 120), on the contrary, passes directly through the
sheath formed by that of the flexor sublimis, and is inserted into the third phalanx. The
tendons of the flexor profundus, moreover, present in their whole course very slightly
apparent traces of division. From the relation of the tendons of the two flexors to each
other, the superficial muscle has been called the perforatus, and the deep one the perforans.
Relations. — These should be examined in the forearm, in the palm of the hand, and
along the fingers.
In the forearm the flexor profundus is covered by the flexor sublimis, from which it is
separated by an incomplete tendinous septum, and by the median nerve. It covers the
ulna, the interosseous ligament, and the pronator quadratus ; it corresponds within to
the flexor carpi ulnaris, and without to the flexor longus pollicis. The ulnar vessels
and nerves are at first situated between this muscle and the flexor sublimis, and after-
ward separate it from the flexor carpi ulnaris.
In the palm its tendons are subjacent to those of the flexor sublimis, and cov^r the
interosseous muscles and the adductor pollicis. The lumbricales muscles take their
origin from them.
Along the fingers its tendons are in relation behind with the grooves of the phalanges,
and with the metacarpo-phalangal and phalangal articulations, and in front with the
tendons of the sublimis and the fibrous sheaths of the fingers. <
Action of the two Flexors. — These muscles flex the third phalanx upon the second, the
second on the first, this, again, upon the corresponding metacarpal bone, and, lastly, the
hand upon the forearm. The flexor sublimis has no action upon the third phalanges.
Its origin from the internal condyle of the humerus enables it to act upon the forearm,
and to assist in flexing it upon the arm. It is scarcely necessary to say that the bifur-
cation of the tendons of the flexor sublimis is intended to afford a sheath to, and bind
down, those of the flexor profundus. The flexor profundus flexes the third phalanx upon
the second, the second upon the first, the first upon the corresponding metacarpal bone,
and, lastly, the hand upon the forearm.
The Lumbricales.
The lumbricales (x,figs. 119, 120) are small fleshy tongues, which may be regarded as
accessories of the flexor profundus. They are four in number, distinguished as the first,
second, &c., counting from without inward. They extend from the tendons of the flexor
profundus to the first phalanges of three or four fingers. They arise from the tendons
after these have passed through the annular ligament : the first and the second in front
of the tendons for the index and middle fingers, the third in the interval between those
for the middle and ring fingers, and the fourth in the interval between those for the ring
and little fingers. From these origins they proceed, those near the median hue verti-
cally, and those at either side obliquely downward to the outer side of the metacarpo-
phalangal articulations of the corresponding fingers, where they terminate by a broad
tendinous expansion inserted into the edges of the extensor tendons, and completing the
sheath which those tendons form on the back of the first phalanges. The tendon of the
third lumbricalis appears to me to be almost always inserted, not into the outer side of
the ring finger, but into the inner side of the middle finger : an arrangement that cannot
well be accounted for. It is not uncommon to find this third lumbricalis bifurcated, and
attached, not only to the inner side of the middle, but to the outer side of the ring finger.
Relations. — They are placed between and upon the tendons of the flexor profundus,
and have, therefore, the same relations as those tendons in the palm of the hand ; they
are also in relation with the sides of the metacarpo-phalangal articulations, and the ten-
dons of the interosseous muscles.
Action. — It is difficult to determine their actions precisely. Vesalius has described
them as adductors, and Spigelius as flexors. I agree with Riolanus in regarding them
as specially intended to keep the extensor tendons closely applied to the phalanges, and
to serve instead of a proper sheath. They are of use also in binding together the ex-
tensor and flexor tendons, and preventing the displacement of either.
The Flexor Longus Pollicis.
Dissection. — ^The same as that of the flexor profundus.
The flexor longus pollicis {I, figs. 119, 120) is situated upon the same plane as the flex
or profundus digitorum, of which it may be considered a division ; it is thick, elongated,
and penniform.
Attachments. — It arises from the upper three fourths of the radius, from the contiguous
portion of the interosseous ligament, from the anterior border of the radius, and not un-
frequently by a prolongation, tendinous at its extremities and fleshy in the middle, from
the flexor sublimis digitorum. It is inserted into the upper end of the second phalanx
of the thumb. The fleshy fibres arise directly from these origins, pass vertically down-
ward, and are attached to the posterior surface of a flat tendon, which forms a continu-
ation of the series of tendons of the flexor profundus on the outside, and, like them, is
254 MYOLOGY.
divided into bands. The fleshy fibres accompany the tendon as far as the anterior an-
nular hgament of the carpus ; it then passes beneath this ligament, is reflected over the
inside of the trapezium, and proceeds obhquely outward along the first metacarpal bone.
When it reaches the metacarpo-phalangal articulation of the thumb, it is received in an
osteo-fibrous sheath, resembling in every respect that of the tendons of the other fingers,
and, like them, is inserted in front of the upper extremity of the ungual phalanx of its
corresponding finger (Z, ^g-. 120).
Relations. — It is covered by the flexor sublimis, the flexor carpi radialis, the supinator
longus, and the radial artery ; it covers the radius and the interosseous ligament, from
which it is separated above by the interosseous vessels and nerves, and below by the
pronator quadratus. Its tendon is the most external of those which pass under the an-
terior annular ligament of the carpus, after leaving which it is received into a deep mus-
cular groove formed by the muscles of the ball of the thumb, and is ultimately enclosed
in its own osteo-fibrous sheath.
Action. — It flexes the last phalanx of the thumb upon the first, this upon the first met-
acarpal bone, and then the hand upon the forearm. In order to understand its action
precisely, we must suppose the muscular force to be concentrated upon the upper end of
the reflected portion ; it is then easy to see that it draws the phalanges inward, while
flexing them. It is, therefore, an opponens muscle.
The Pronator Quadratus.
Dissection. — Cut across all the tendons occupying the lower part of the anterior region
of the forearm, and this muscle will be exposed.
This small muscle (le petit pronateur, Bichat, m,figs. 119, 120) is situated at the low-
er part of the anterior region of the forearm, and forms the deepest layer of this region.
It is regularly quadrilateral, and thicker than at first sight it appears to be.
Attachments. — It arises firom the lower fourth of the internal border of the ulna, which
is directed so decidedly backward inferiorly, that the muscle is rolled round the bone ;
also, from an aponeurotic layer much thicker below than above, directed obliquely up-
ward and outward, and occupying the inner third of the muscle, upon which it terminates
in a number of elegant intersections ; lastly, from all that portion of the anterior surface
of the ulna upon which it lies. From these origins the fibres proceed horizontally out-
ward (le pronateur transverse, Winslow), becoming longer as they are more superficial, to
the lower fourth of the external border, anterior surface, and internal border of the radius.
Relations. — It is covered by the flexor profundus digitorum, the flexor longus poUicis,
the flexor carpi radialis, and the radial and ulnar arteries, and it partially covers the two
bones of the forearm and the interosseous ligament.
Action. — ^The pronator quadratus tends to approximate the two bones of the forearm ;
but as it is rolled around the ulna, which is immovable, it causes the radius to turn upon
that bone, and is therefore a pronator. Its action is much more energetic than would
at first sight appear : this depends on the number of its fleshy fibres, which are arranged
in several layers, the most superficial being the longest.
The Muscles of the External Region of the Forearm.
The muscles of this region are, the supinator longus, the extensores carpi radiales,
longior and brevior, and the supinator brevis.
The Supinator Longus.
Dissection. — The brachial portion of this muscle is exposed in the dissection of the
brachialis anticus and the triceps, and the portion situated in the forearm, by removing
the fascia from the outer and anterior aspect of the muscles of this region.
The 'supinator longus (/, Jigs. 118, 121), which is the most superficial muscle of the ex-
ternal and anterior aspect of the forearm, belongs both to the arm and the forearm (bra-
chio-radialis, Soemmering), and constitutes, in a great measure, the oblique ridge forming
the external boundary of the bend of the elbow. It is a long, flat muscle, fleshy in its
upper two thirds, and tendinous in its lower third.
Attachments. — It arises from the outer border of the humerus, and from the external
inter-muscular septum of the arm ; the extent of its humeral attachment varies from the
lower fourth to the lower third of that bone, and is limited above by the groove for the
musculo-spiral nerve. It is inserted into the base of the styloid process of the radius.
The fleshy fibres proceed from their origins downward, forward, and a little inward, to
form a fleshy belly, which is flattened from without inward, and is applied to the brachi-
alis anticus. After reaching the lower end of the humerus, the fleshy belly becomes
flattened from before backward, and passes vertically downward. At first it is thick, but,
during its progress, it expands, and becomes thin, until its fibres terminate successively
upon the anterior surface of an aponeurosis, which becomes entirely free from fleshy
fibres above the middle of the forearm, and is gradually contracted into a flat tendon,
that is inserted into the styloid process of the radius.
Relations. — It is covered bv the fascise of the arm and forearm : in the arm it is en-
THE EXTENSORES CARPI EADIALES, LONGIOR ET BREVIOR. 255
closed in the same sheath with the brachialis anticus, from which it is separated by the
radial or musculo-spiral nerve ; in the forearm it has a sheath proper to itself: it is in
relation with the brachialis anticus, which is at first within, and afterward behind it ;
then with the extensor carpi radialis longior, the tendon of the biceps, the supinator bre-
vis, the pronator teres, the flexor carpi radialis, the flexor digitorum sublimis, the flexor
longus pollicis, the radial artery and veins, and the radial nerve. Its inner border limits
the bend of the elbow on the outside : the radial artery emerges from beneath this bor-
der, and then lies parallel to it. Its outer border is separated from the extensor carpi
radialis longior by cellular tissue, and, inferiorly, is in contact with the dorsal branch of
the radial nerve, which, at first, was situated beneath it. The most important of all
these relations is that with the radial artery, of which the long supinator may be consid-
ered the satellite muscle, and might be designated the muscle of the radial artery.
Action. — It might be asked, Why does the supinator longus form an exception to the
general rule, in being inserted into the lower end of the lever which it is intended to
move 1 for, while the forearm is in a state of supination, the axis of the muscle is verti-
cal, and its action appears limited to that of flexing the forearm ; but if the limb be pro-
nated, the direction of the muscle becomes oblique from without inward, and, therefore,
supination is the result of its contraction. After this effect has been produced, if the
muscle still continues to act, the forearm is flexed upon the arm. It is needless to state
that the distance of its insertion from the fulcrum gives the muscle great power, not-
withstanding its disadvantageous angle of incidence.
The Extensor Carpi Radialis Longior.
Dissection. — This muscle, as well as the succeeding one, will be exposed at the same
time as the supinator longus, beneath which it is placed. The lower end of its tendon
occupies the dorsum of the wrist, and should also be exposed.
The extensor carpi radialis longior (le premier ou long radial exteme ; radiahs externus
longior, Albinus, n,figs. 119, 121) is situated on the external and posterior aspect of the
forearm, below the supinator longus, of which it seems to be a continuation at its origin
from the humerus : like that muscle, it is flattened from within outward in the arm, and
from before backward in the forearm : it is fleshy in its upper third, and tendinous in its
lower two thirds.
Attachments. — It arises from the rough triangular impression terminating the external
border of the humerus, from the external inter-muscular septum, and from the anterior
surface of the common tendon. It is inserted into the back of the upper end of the sec-
ond metacarpal bone. The fleshy fibres arising directly from the parts mentioned con-
stitute a bundle, at first flattened on the sides, and forming a continuation of the supina-
tor longus, from which it is often difficult to separate it : it afterward becomes flattened
from before backward. The fibres pass vertically downward, and are attached to the
anterior surface of a tendon, a little beyond the upper third of the forearm. The tendon
then becomes narrower and thicker, proceeds along the outer border of the radius, pass-
es under the tendons of the abductor longus and extensor brevis pollicis, which cross it
obliquely, and turns a little outward, and then backward, to arrive at a groove common
to it and the extensor carpi radialis brevier ; it is then crossed at an acute angle by the
tendon of the extensor longus pollicis, and is finally inserted, by an expanded termina-
tion, into the second metacarpal bone {n',fig. 121).
Relations. — It is covered by the supinator longus and the fascia of the forearm ; on the
outside of the forearm, it is covered and crossed obliquely by the abductor longus and ex-
tensor brevis pollicis. and in the wrist by the tendon of the extensor longus pollicis. It
covers the elbow-joint, the extensor carpi radialis brevier, and the back of the wrist-joint.
The Extensor Carpi Radialis Brevior,
The extensor carpi radialis brevior (le second ou court radial exteme ; radialis externus
brevior, Albinus, o,figs. 119, 121, 122) is thicker, but shorter, than the preceding, below
which it is placed. It arises from the external condyle or epicondyle of the humerus, by
a tendon common to it and the extensor muscles of the fingers ; also, from a very strong
aponeurosis, situated upon its posterior surface ; and from another tendinous septum,
which divides it from the extensor communis digitorum. It is inserted into the back part
of the upper end of the third metacarpal bone. The fleshy fibres, thus arising from the
external condyle by means of an aponeurotic pyramid, are attached to the posterior sur-
face of a tendon, which becomes gradually narrower and thicker as it receives them.
The fibres themselves terminate about the middle of the forearm, and then the flat ten-
don passes backward into the same groove on the radius as that of the last-named mus-
cle, the two tendons being retained in it by the same fibrous sheath, and lubricated by
tne same synovial membranes, but separated from each other by a small vertical ridge
of bone. After leaving the common sheath, the tendon of the short separates from that
of the long radial extensor, passes still more posteriorly, and is inserted into the third
metacarpal bone (o', Tf^s. 121, 122).
RelatioDis. — It is covered by the preceding muscle, and, like it, is crossed obliquely on
256 MYOLOGY.
the outside by the long abductor, the short, and then the long extensor muscles of the
thumb : it covers the external surface of the radius, from which it is separated by the
supinator brevis above, and the pronator teres in the middle. Its tendon covers and
protects the back of the wrist. In consequence of the different length of their fleshy
fibres, the supinator longus and the two radial extensors of the carpus are arranged one
above the other, the highest being the supinator longus, and the lowest the extensor
carpi radialis brevior.
Action of the two Radial Extensors. — These two muscles, which, from their insertions
might be called the posterior radials, extend the second row of the carpus upon the firs
and this upon the forearm ; they are also abductors of the hand, for they incline it to-
wards the radial side of the forearm. The extensor carpi radialis longior being attach-
ed to the humerus, can assist in flexing the forearm.
The Supinator Brevis.
Dissection. — Pronate the forearm forcibly. In order to expose this muscle completely,
divide the two radial extensors of the carpus, and even some of the muscles of the su-
perficial layer, on the back of the forearm.
The supinator brevis (p,figs. 119, 120, 122) is a broad muscle curved into the form of a
hollow cylinder, and rolled round the upper third of the radius : it forms by itself the deep
layer of the external region of the forearm.
Attachments. — It arises from the external lateral Ugament of the elbow, with which it
is blended, and by this means from the external condyle ; from the annular ligament of
the radius ; from the external border of the ulna, which is provided with a projecting
ridge for this purpose ; from a deep triangular excavation, in front of this ridge, arid below
the lesser sigmoid cavity of the ulna ; and, lastly, from the deep surface of an expansion of
its tendon of origin and the external lateral ligament, which covers the greater part of
the muscle. From these different origins {fig. 122) the fleshy fibres pass round the ra-
dius, into the posterior, external, and anterior surfaces of which bone they are inserted,
embracing in front the bicipital tubercle and the tendon of the biceps {figs. 119, 120). I
have seen a fleshy prolongation of this muscle, covering the anterior half of the annular
ligament of the radius, of which it might be regarded an extensor.
Relations. — The supinator brevis is covered by the radial extensors, the supinator lon-
gus, the pronator teres, the extensor communis digitorum, the extensor digiti minimi,
the extensor carpi ulnaris, the anconeus, and the radial artery and vein : it covers the
upper third of the radius, and also its annular ligament, the elbow-joint, and the inter-
osseous ligament. It is perforated by the deep branch of the radial nerve, which is dis-
tributed to all the muscles on the back of the forearm.
Action. — No muscle in the body is so completely rolled around the lever that it is in-
tended to move, for it forms five sixths of a cylinder ; it is, therefore, the chief agent in
supination, and the supinator longus can only be regarded as an accessory.
Muscles of the Posterior Region of the Forearm.
The muscles of the posterior region of the forearm constitute two very distinct layers :
one superficial, comprising the extensor communis digitorum, the extensor digiti minimi,
and the extensor carpi ulnaris ; the other deep, comprising the abductor pollicis longus, the
extensor brevis and extensor longus pollicis, and the extensor indicis
Muscles of the Superficial Layer.
One mode of dissection is common to all these muscles. Make a circular mcision
through the skin at the lower part of the arm ; pronate the arm, arifl make a perpendic-
ular incision from the external condyle of the humerus to the third metacarpal bone,
entirely dividing the sub-cutaneous cellular tissue down to the fascia ; remove this fascia
by careful dissection, except where it is very adherent. Trace the tendons of the ex-
tensor muscles along the back of the fingers.
The Extensor Communis Digitorum.
The extensor communis digitorum {b,fig. 121), situated at the back of the forearm, sim-
ple above and divided into four portions below, arises from the external condyle of the
humerus, and is inserted into the second and third phalanges of the four fingers. Its ori-
gin consists of a tendon common to it, and to the extensor carpi radialis brevior, exten-
sor digiti minimi, and extensor carpi ulnaris. This tendon consists of a four-sided pjrra-
raid, and is formed by the fascia of the forearm, by a lamina separating this muscle from
the extensor carpi radialis longior, by another lamina separating it from the extensor
digiti minimi and the extensor carpi ulnaris, and, lastly, by another situated between it
and the supinator brevis. The fleshy fibres arising from the interior of this pyramid form
at first a thin, but afterward a much larger muscle, which becomes flattened from before
backward, and soon divides into four fasciculi. The two middle fasciculi, intended for
the middle and the ring fingers, are stronger than those destined for the index and little
fingers, i. e., the two extreme fasciculi, which, lower down, become placed in front of
THE EXTENSOR DIGITI MINIMI.
257
the middle fasciculi. In this manner they all pass under the dor- Fig. 191.
sal ligament (r,fig. 121) of the carpus in a proper sheath. After
leaving this sheath, in which they are provided with a synovial
capsule,* extending both above and below the dorsal ligament, the
four tendons become situated on the same plane, and diverge from
each other ; the two middle tendons proceed along the backs of the
corresponding metacarpal bones ; the external and internal ten-
dons {b' h',Jig. 121) correspond to the interosseous spaces, which
they cross obliquely, in order to assume a position behind the heads
of the metacarpal bones, to which they belong. Having reached
the metacarpo-phalangal articulations, the tendons become nar-
rower and thickened, and give oif on each side a fibrous expansion,
attached to the sides of the joint ; they then enlarge again so as to
cover the dorsal surface of the first phalanges, receive and are re-
enforced by the tendons of the lumbricales, and opposite the ar-
ticulation of the first with the second phalanx, they divide into
three portions, one median, which is implanted upon the upper end
of the second phalanx, and two lateral, which pass 2dong the sides
of the second phalanx, approach each other at the lower half of the
dorsal surface of the second phalanx, unite by their neighbouring
edges, and are inserted into the upper end of the third phalanx.
Opposite the metacarpal bones they sometimes split into two or
three small juxtaposed tendons, and at the lower end of these
bones the tendons for the little, ring, and middle fingers commu-
nicate with each other by expansions of variable size, and some-
times by a true bifurcation (see fig. 121). The tendon for the in-
dex finger is alone free. The communication of the tendon of the
little with that of the ring finger takes place opposite the metacar-
po-phalangal articulation, by means of a transverse band, which
forms a projection under the skin. Lastly, we not unconmionly
see a tendinous prolongation arising from the anterior surface of these tendons, and in-
serted into the upper end of the first phalanx.
Relations. — The extensor communis digitorum is covered by the fascia of the forearm,
from which a great number of its fibres arise superiorly, by the dorsal ligament of the
carpus and the dorsal fascia of the metacarpus, which separate it from the skin : it cov-
ers the supinator brevis, the three long muscles of the thumb, the extensor proprius in-
dicis, the lower radio-cubital articulation, the carpus, the metacarpus, and the fingers.
Action. — ^This muscle extends the third phalanx upon the second, the second upon the
first, the first upon the corresponding metcarpal bone, then the carpus, and, lastly, the
radio-cubital articulation. It is necessary for me to mention the independence of the
muscular fasciculi proceeding to each finger : this is peculiar to man, and is much more
remarkable in some individuals than in others. By continual exercise, the faculty of
extending one finger without the others may be acquired. The tendon for the index is
generally the only one not united to the others, and therefore the movements of this
finger are by far the most independent.
The Extensor Digiti Minimi.
This is a very slender muscle (extensor proprius auricularis, Albinus, c, fig. 121) placed
on the inner side of the common extensor, to which it appears to be an appendix. It is
difficult to trace its origin as far as the common tendon, with which it is connected only
by an aponeurotic prolongation. Its fleshy fibres arise from this prolongation, and from
a fibrous pyramid which separates it from the muscles of the deep layer, from the exten-
sor communis digitorum externally, and internally from the extensor carpi ulnaris, and
is completed superficially by the fascia of the forearm. The fibres constitute a small,
fusiform, fleshy belly, which accompanies the tendon (at least on one side) as far as the
head of the ulna ; there the tendon enters a special fibrous sheath formed behind the
head of that bone ; it is then reflected inward to the fifth metacarpal bone, behind which
it is retained in a thinner sheath, which, like the preceding, is lined by a synovial mem-
brane.t The tendon then spUts into two bands, of which the external (or radial) re-
ceives the inner bifurcation of the extensor communis. The three tendinous prolonga-
tions becoming united, envelop, as in a sheath, the dorsal aspect of the first phalanx of
this finger ; having reached the articulation of the first with the second phalanx, they
divide into three portions, which are attached precisely in the same manner as the ten-
dons of the extensor communis.
Action. — As its name indicates, this muscle extends the little finger. It might at first
sight be imagined that this finger might be moved independently, since it receives a sep-
arate muscle ; but the connexion of its tendon with that of the extensor communis ren-
See note, p. 296.
Kk
t See note, p. 296.
t,58 MYOLOGY.
ders any such independent action as difficult as in the other fingers, and much more so
than in the index finger.
The Extensor Carpi Ulnaris.
The extensor carpi ulnaris (c, fig. 121), the most superficial and the most internal* of the
muscles on the back of the forearm, arises from the external tuberosity of the humerus ;
from the posterior surface of the ulna, which is a little excavated for this purpose ; from
the middle third of the posterior border of that bone ; and from the anterior surface of
an aponeurosis covering the muscle behind. It is inserted behind the upper end of the
fifth metacarpal bone. Its origin is effected by means of a fibrous pyramid, the apex of
which is attached to the outer tuberosity of the humerus. From the interior of this pyr-
amid, and from the other origins above mentioned, the fleshy fibres proceed to a tendon,
which, by a very uncommon arrangement, extends through the substance of the muscle,
even from its superior attachment, without commencing in the form of an aponeurosis.
At the lower third of the forearm, this tendon appears on the posterior border of the then
semi-penniform muscle, and continues to receive fleshy fibres on its anterior edge until
it enters the groove intended for it on the ulna. This oblique groove is continued as far
Fig. 182. as the insertion of the tendon into the metacarpal bone, by means of a
long, fibrous sheath, and is lined throughout by a synovial membrane.
Relations. — The extensor carpi ulnaris is covered by the fascia of
the forearm : it covers the ulna, the supinator brevis, and the mus-
cles of the deep layer.
Action. — It extends the second row of the carpus upon the first, and
this upon the forearm. It is, at the same time, an adductor of the
_g hand, which it inclines towards the ulnar border of the forearm.
The Anconeus.
The anconeus (brevis anconeus, Eustachius ; le petit ancone, Wins-
low, ff, figs. 121, 122) is a short, triangular muscle, so named from
its situation {uyKuv, the prominence of the elbow). It appears to be
a continuation of the external portion of the triceps, from which it is
only separated by a very slight cellular interval.
Attachments. — It arises from the back part of the outer tuberosity
of the humerus, and is inserted into the outer side of the olecranon,
and a triangular surface bounded internally by the posterior border of
the ulna. Its origin from the condyle consists of a tendon quite dis-
tinct from that common to the muscles on the back part of the fore-
arm. This tendon splits into two diverging bands. The fleshy fibres
arising from these proceed inward, the upper horizontally, the lower
obliquely downward, and are inserted directly into the outer side of
the olecranon, so as to be continuous with the triceps, and into the
surface of the ulna.
Relations. — It is covered by a prolongation from the fascia of the
triceps, and it covers the radio-humeral articulation, the annular lig-
ament of the radius, the ulna, and a small portion of the supinator
brevis.
Action. — ^It extends the forearm upon the arm, and vice versa ; from its oblique direc-
tion, it can also rotate it inward.
Muscles of the Deep Layer.
Dissection. — This is the same for all the muscles of the deep layer of the forearm, and
consists in removing the muscles of the superficial layer, especially the extensor com-
munis digitorum and the extensor digiti minimi.
The Mductor Longus Pollicis.
The abductor longus pollicis (extensor ossis metacarpi pollicis, i,figs. 121, 122) is the
broadest, thickest, and most external muscle of the deep layer (le grand abducteur, Bichat).
Attachments. — It arises from the ulna below the origin of the supinator brevis, from
the interosseous hgament, from the radius, and from a tendinous septum between it and
the extensor longus pollicis. It is inserted into the upper end of the first metacarpal
bone. From the above-mentioned origins the fleshy fibres proceed obUquely downward
and outward, constitute a flattened fusiform belly, and are successively attached to the
posterior surface of an aponeurosis, which becomes condensed into a flat tendon ; this
tendon turns round the radius, crossing over the radial extensors of the carpus, and, at
the same time, ceasing to receive any fleshy fibres ; it is then received into the outer
groove on the lower end of the radius, conjointly with the tendon of the extensor brevis
* It is needless to remark that this internal situation presupposes the supination of the forearm. In prona-
tion, this muscle may be correctly termed ulnaris externus, and le cubital externe, according to Albinus and
Witulow.
THE EXTENSOR BREVIS POLMCIS, ETC. 254
pollicis, a small fibrous septum intervening between them, and, finally, is inserted into
the first metacarpal bone. This tendon is almost always divided longitudinally into two
equal parts, and not unfrequently the division extends up to the fleshy portion. Of these
two divisions, one is inserted into the first metacarpal bone, the other furnishes attach-
ments to the abductor brevis pollicis.
Relations. — It is covered by the extensor communis digitorum and extensor digiti min-
imi : it lies immediately under the fascia, from the outer side of the radius to its termi-
nation. It covers the interosseous ligament, the radius, the tendons of the radial exten-
sors of the carpus, and the outer side of the wrist-joint, where it may be easily distin-
guished under the skin.
Action. — It extends and abducts the first metacarpal bone : for a long time it was
called the extensor of the thumb ; but its chief use is, as Albinus first remarked, in ab-
duction. Winslow observes that, from its obliquity, it can act as a supinator ; lastly, it
assists in extending the hand.
The Extensor Brevis Pollicis.
This muscle (extensor primi intemodii pollicis, I, figs. 121, 122) is situated internally
to the preceding, which it exactly resembles- in figure and direction, and with which it
was for a long time confounded (partie du premier extenseur du pouce, Winslow). It is,
however, shorter and mpre slender (petit extenseur du pouce, Bichat).
It arises from the radius, occasionally from the ulna, and from the interosseous liga-
ment ; and is inserted into the upper end of the first phalanx of the thumb. Its origin
consists of short, tendinous fibres, the fleshy fibres proceeding from which constitute a
slender fasciculus, having a similar arrangement to that of the preceding muscle ; its
tendon is received into the same fibrous sheath, but is divided from the other by a small
septum, and passes on, to be inserted into the first phalanx.
Relations. — The same as those of the abductor longus.
Action. — It extends the first phalanx upon the first metacarpzil bone, and then becomes
an abductor and extensor of the metacarpal bone of the thumb.
The Extensor Longus Pollicis.
This muscle (extensor secundi internodii pollicis, m,figs. 121, 122) is much larger than
the extensor brevis, within and parallel to which it is situated. It arises from a consid-
erable extent of the ulna, from the interosseous ligament, and from the tendinous septa,
dividing it from the extensor carpi ulnaris, and the extensor proprius indicis : it is insert-
ed into the upper end of the second phalanx of the thumb. The fleshy fibres form a flat
fusiform bundle, directed obliquely like the preceding muscle ; they terminate in succes-
sion around a tendon, which emerges from them at the carpal extremity of the ulna, en-
ters a special osteo-fibrous sheath, and crosses obliquely over the tendons of the two ra-
dial extensors, being separated from the tendons of the abductor longus and extensor
brevis pollicis by an intervjil which may be readily distinguished through the integu-
ments, and gives rise to the hollow on the outer side of the wrist, commonly called the
salt-cellar. The tendon next crosses obliquely over the first interosseous space, gains the
inner edge of the first metacarpal bone, and then that of the first phalanx, upon which it is
expanded, and proceeds to be inserted into the second or ungual phalanx of the thumb.
Relations. — Its general relations are the same as those of the preceding muscle.
Action. — Its uses are also the same ; but it acts in a special manner upon the second
phalanx of the thumb, which it extends upon the first before exerting any influence upon
this last-mentioned bone. It has less power in abduction than the preceding muscles.
The Extensor Proprius Indicis.
This is an elongated fusiform muscle (indicator, Albinus, r, fig. 122) like the preceding,
below and parallel to which it is situated. It arises from the ulna, the interosseous liga
ment, and a septum intervening between it and the extensor longus pollicis : it is insert-
ed into the last two phalanges of the index finger. The fleshy fibres proceed obliquely
from their origins and terminate around a tendon, which they accompany as far as the
sheath of the extensor communis digitorum : into this sheath the tendOn enters, and.
having escaped from it, crosses obliquely over the carpus and the second interosseous
space, becomes situated on the inside of the tendon given off to the index finger by the
extensor conununis, unites intimately with that tendon opposite the lower end of the
metacarpus, and terminates with it in the manner already indicated. Its relations are
the same as those of the preceding muscles.
Action. — It enables the index finger to be extended independently of the others, and
hence, without doubt, arises the particular use of that finger. I should add, that the union
of its tendon with the one furnished by the common extensor is so intimate, that its in-
dependence of action would have been much less, had not the fleshy fasciculus of the
common extensor destined for it been itself almost isolated.
260 MYOLOGY.
MUSCLES OF THE HAND.
Tlie AbdiMor Brevis Pollicis. — Opponejis Pollicis. — Flexor Brevis Pollicis. — Adductor Pol-
lids. — Palmaris Brevis. — Abductor Digiti Minimi. — Flexor Brevis Digiti Minimi. — Op-
ponens Digiti Minimi. — The Interosseous Muscles, Dorsal and Palmar.
The muscles of the hand occupy the entire palmar region. They are divided into
those situated on the outer side, viz., the muscles of the thenar eminence, or ball of the
thumb ; those on the inner side, viz., the muscles of the hypothenar eminence, or of the
little finger ; and those which occupy the interosseous spaces.
All the muscles of the thenar eminence belong to the thumb ; they are, in the order
of their superposition, the abductor brevis, the opponens, the flexor brevis, and the ad-
ductor pollicis. Those of the hypothenar eminence all belong to the little finger, and
are the abductor, the flexor brevis, and the opponens. The palmaris brevis may be in-
cluded in this region.
The interosseous muscles are seven in number — four dorsal and three palmar. The
lumbricales, vi^hich belong to this region, have been already described with the tendons
of the flexors of the fingers.
Muscles of the Thenar Eminence, or Muscles belonging to the Thumb
I divide these into three muscles inserted into the outer side of the first phalanx of
the thumb, or into the first metacarpal bone, and a single muscle inserted into the inner
side. The former are the abductor brevis, the opponens, and the flexor brevis ; the lat-
ter consists of the adductor, in which I include a part of the flexor brevis of authors
generally.
Muscles inserted into the Outer Side of the First Phalanx of the Thumb, or
into the First Metacarpal Bone.
Dissection. — Make an oblique incision from the middle of the annular ligament of the
carpus to the outer side of the first phalanx of the thumb, and a circular incision round
the wrist ; detach the flaps, raise the external and middle palmar fasciae, and then cau-
tiously separate the muscles of this region, which are recognised by the following char-
acters.
The Abductor Brevis Pollicis.
This is the most superficial of the muscles constituting the ball of the thumb {q, fig.
119). It arises by tendinous and fleshy fibres from the os scaphoides, from the upper,
anterior, and external part of the anterior annular ligament of the carpus, and almost
always from an expansion of the tendon of the abductor longus pollicis. It is a small,
•hin, flat muscle, passing outward and downward, and inserted by a flat tendon into the
outer side of the first phalanx of the thumb. A very narrow cellular line separates it on
the inside from the flexor brevis, which is situated on the same plane. It is covered by
the external palmar fascia, and it covers the opponens muscle, from which it is distin-
guished by the direction of its fibres, and by a thin intervening aponeurosis.
Action. — It draws the thumb forward and inward, and therefore might be termed the
superficial opponens. From its attachments, it might be called scaphoido-phalangal.
The Opponens Pollicis.
The opponens pollicis (r, figs. 119, 120), a small triangular muscle, arises from the trape-
zium, and the anterior and external part of the anterior annular ligament of the carpus,
in front of the sheath of the flexor carpi radialis. From these origins, which are partly
fleshy and partly tendinous, the fleshy fibres radiate downward and outward, the highest
being the shortest and the most horizontal. They are inserted into the entire length of
the outer border of the first metacarpal bone.
This muscle is covered by the abductor brevis, which projects a little beyond it on the
outside, and from which it is separated by a more or less distinct aponeurosis. It cov-
ers the first metacarpal bone, and its articulation with the trapezium.
Action. — It draws the first metacarpal bone inward and forward, thus opposing it to the
others, as its name indicates. From its attachments, it may be called trapezio-metacarpal.
The Flexor Brevis Pollicis.
It is difficult to point out the limits of this muscle, or, rather, they have hitherto been
quite arbitrary. Its inferior attachment has been usually divided between the external
and the internal sesamoid bones (Boyer, Traitl d' Anatomic, torn, ii., p. 307 ; Bichat, Ana-
tomic Descriptive, torn, ii., p. 272) ; but we shall consider that portion only whioli is at-
tached to the external sesamoid bone as belonging to this muscle, referring tlie entire
fleshy mass that is inserted into the internal sesamoid bone to the adductor pollicis.*
' The arrangement I have adopted is founded upon the inferior attachments of the musr les, for at their
origins they are so blended that their division is more or less arbitrary. I divide the muscular fasciculi con-
nected witu the thumb, therefore, into two sets, viz., those proceeding from the carpus to tlie first metacan>al
THE ADDUCTOR P0LLICI8, ETC. 26^1
This division is, moreover, established by the tendon (I, fig. 120) of the flexor longns
pollicis. Proceeding then from below upward, in the dissection of the flexor brevis {t.
iigs. 119, 120), we shall see that it is triangular, much larger than the preceding two
muscles, bifid above, and channelled in front. It arises by tendinous and fleshy fibres
from a process on the trapezium, from the lower edge of the annular ligament, from all
the reflected portion of that ligament forming the sheath of the flexor carpi radialis, and
extending as far as the os magnum, and from the os magnum itself by a portion which
is usually distinct. From these different origins the fleshy fibres proceed downward and
outward, the intem£d being the most oblique ; and, converging so as to form a thick fas-
ciculus, are inserted, through the medium of the external sesamoid bone, into the first
phalanx.
Relations. — It is covered by the external pahnar fascia, which is prolonged in front of it :
it covers the tendon of the flexor longus pollicis, and more internally those of the common
flexor. It also covers a small portion of the outer border of the adductor pollicis, and
the tendon of the flexor carpi radialis. Its outer border, or, rather, side, is in relation
with the short abductor, from which it is easily separated, and with the opponens, some-
times being continuous with it. Its inner border is distinct from the adductor below,
but is confounded with it at its origin. Its tendon of insertion into the phalanx is cov-
ered by that of the short abductor, which lies externally to it. From its attachments, it
might be called trapezio-phalangal, and, from its uses and position, the opponens internus.
Action. — It is evidently not a flexor pollicis, but, like the preceding muscles, it draws
the thumb forward and inward, and it acts more decidedly in producing the latter effect.
because it is inserted in a more favourable manner than the other muscles. This, there-
fore, is also an opponens muscle.
Muscle inserted into the Inner Side of the First Phalanx of the Thumb.
The Adductor Pollicis.
This is the largest of all the muscles of the thumb (m, figs. 119, 120) ; it is very ir-
regularly triangular, and arises from the entire extent of the anterior border of the third
metacarpal bone, from the anterior surface of the os magnum, from the anterior and up-
per part of the trapezoides, from the anterior part of the trapezium by a tendinous and
fleshy fasciculus, and from the palmar interosseous fascia, near the third metacarpal
bone. From these different origins the fleshy fibres proceed, the lower horizontally, the
rest more and more obliquely outward ; they all converge to form a thick fleshy bundle,
which is inserted through the medium of the internal sesamoid bone into the first pha-
lanx of the thumb.
Relations. — Its inner two thirds are deeply situated, and covered by the tendons of the
flexor profundus digitorum, by the lumhricales, and by an aponeurosis, which, becoming
continuous with the deep interosseous fascia, constitutes the sheath of the muscle. It
is sub-cutaneous near its lower border. It covers the first two interosseous spaces, from
which it is separated by a very strong aponeurosis. It is again sub-cutaneous behind,
also along its lower border, which may be easily felt under the fold of skin, extending
from the thimib to the index finger.
Action. — It is an adductor ; it draws the thumb towards the median line or axis of tho
hand, represented by the third metacarpal bone.
Muscles of the Hypothenar Eminence, or Muscles belonging to the Little Finger.
These muscles correspond exactly to those of the thumb : the reason that three only
are described is, that the one which represents the adductor of the thumb is situated in
the fourth interosseous space, and is, therefore, classed with the interosseous muscles,
to be hereafter described. All the muscles of the hypothenar eminence are inserted into
the inner side of the first phalairx of the little finger, or into the third metacarpal bone
We find also a cutaneous muscle in this region, viz., the palmaris brevis.
The Palmaris Brevis.
This is a very thin square muscle (caro quaedam quadrata, J, fig. 1 18), situated in the
adipose tissue covering the hypothenar eminence. It arises from the anterior annular
ligament of the carpus, and the inner edge of the middle palmar fascia, by very distinct
tendinous fasciculi, succeeded by equally distinct fleshy bundles, which pass horizontally
inward, and terminate in the skin.
Relations. — It is covered by the skin, to which it adheres intimately, especially by its
inner extremity (le pahnaire cutane, Winslow ) ; it covers the muscles of the hypothenar
bone and to the outer side of the first phalanx of the thumb, and those extending from the carpus to the inner
side of the same phalanx. The first set, which might be regarded as a single muscle, comprises the abductor
brevis, the opponens, and the flexor brevis ; the other constitutes the abductor pollicis, which I regard as the
first palmar interosseous muscle. The action of the first set is common, viz., to carry the thumb forward and
inward ; they are, therefore, all muscles of opposition (perhaps no muscles are so badly named as those of the
thenar eminence) ; the muscle formeJ !jy the second set is really an adductor, as its name implies, and so are
all the palmar interossci. ;im0Qg .., a :i it ^l (Uld be included.
262 MYOLOGY.
eminence and the ulnar artery and nerve, from all of which it is separated by the inter-
nal palmar fascia.
Action. — It corrugates the skin over the hypothenar eminence.
The Abductor Digiti Minimi.
It arises from the pisiform bone, and from an expansion of the flexor carpi ulnans,
by tendinous fibres ; these are succeeded by a fusiform fleshy belly {v,fig. 119), which
passes vertically along the internal (or ulnar) surface of the fifth metacarpal bone, and is
inserted by a flat tendon into the inner side of the first phalanx of the little finger.
Relations. — It is covered by the external palmar fascia, and covers the opponens digiti
minimi.
Action. — As it name denotes, it abducts the little finger from the axis of the hand.
The Flexor Brevis Digiti Minimi.
This muscle {w,fig. 119) is situated on the outer or radial border of the precedmg,
from which it is distinguished by arising from the unciform bone. ■ The two muscles are
separated by the ulnar vessels and nerves, which pass between them, in order to penetrate
into the deep palmar region. In other respects, as in direction, insertions, and relations,
the muscles resemble each other ; they have accordingly been described by Chaussier as
a single muscle, under the name of Ze carpo-phalangien du petit doigt. This muscle is often
wanting, but the fleshy fibres which usuaUy constitute it are then always found in some
measure blended with the other muscles.
Action. — It produces slight flexion of the little finger.
The Opponens Digiti Minimi.
This muscle {y,fig. 119) is generally distinct from the preceding, and is the represent-
ative of the opponens pollicis. It arises from the hooklike process of the unciform bone,
and from the contiguous part of the annular ligament : from these points the fibres pro-
ceed downward and inward (i. e., towards the ulnar border of the hand), the highest be-
ing the shortest and the most horizontal : they are i-nserted into the whole length of the
inner or ulnar margin of the fifth metacarpal bone.
Relations. — It is covered by the preceding muscles and by the internal palmar fascia :
it covers the fifth metacarpal bone, the corresponding interosseous muscle, and the ten-
don of the superficial flexor proceeding to the little finger.
Action. — It opposes the little finger to the thumb by drawing it forward and outward.
The Interosseous Muscles.
Dissection. — Remove the tendons of the extensor muscles behind, and those of the flexor
muscles in front, together with the lumbricales, preserving, at the same time, the digital
inseiiions of these small muscles. Dissect and study the deep palmar fascia, a fibrous
layer covering the interosseous muscles in the palm of the hand, which sends prolonga-
tions between the two kinds of these muscles, and is inserted into the anterior borders
of the metacarpal bones, enclosing each interosseous muscle in a proper sheath. After
having studied the palmar and dorsal fascia, separate the bones of the metacarpus by
tearing their connecting ligaments, and the interossei will then be completely exposed.
The interossei, so named from their position, and distmguished from each other by the
numerical appellations first, second, third, &c., are divided into palmar (p p p, Jig. 123)
and dorsal {ddd d), according as they are situated nearer to the palm or to the back of
the hand. They are also distinguished into adductors and abductors of the fingers.
There are two in each interosseous space, one occupying its dorsal, the other its pal-
mar aspect ; and, as there are four interosseous spaces, it would seem that there should
be eight interosseous muscles ; nevertheless, seven only are admitted by modern anat-
omists, in consequence of the first palmar interosseous muscle, which belongs to the
thumb, being separately described as the adductor pollicis. This separation is founded
upon the peculiar arrangement presented by that muscle, which is not attached from the
first to the second, but extends from the first to the third metacarpal bone ; an importjuit
fact, that explains the great extent to which the thumb can be adducted.
A minute description of the interosseous muscles would be both useless and tedious.
I shall content myself with pointing out their genereil conformation, and the law which
regulates their arrangement.
In taking a general view of the interosseous muscles, they must be considered with
regard to the adduction or abduction of the fingers ; but these terms must not be under-
stood in reference to the axis of the skeleton, but to the axis of the hand, which is rep-
resented by a line passing through the third metacarpal bone and the middle finger. This
being admitted, all the dorsal interossei will be found to be abductors, and all the palmar
interossei adductors.
Thus, the first dorsal interosseous muscle proceeds from the first and second meta-
carpal bones to the outer or radial side of the first phalanx of the index finger : it is there-
fore an abductor of that finger. The second extends ft-om the second and third meta-
THE DORSAL INTEROSSEI. 263
carpal bones to the outer or radial side of the first phalanx of the middle finger, and is an
abductor of that finger. The third extends from the third and fourth metacarpal bones
to the inner or ulnar side of the phalanx of the middle fingers, and is also
an abductor of the same, because it separates it firom the supposed axis of
the hand. The fourth extends from the fourth and fifth metacarpal bones
to the inner or ulnar side of the first phalanx of the fourth finger, and it again
is an abductor of that finger from the axis of the hand, although, as well as
the preceding muscle, it is an adductor as regards the axis of the body. In
order to render this view more intelligible, I have been accustomed to rep-
resent the five fingers by five lines (see diagram d), to prolong the middle
line for the axis of the hand, and then to draw other lines (the four fine lines)
representing the axes of the muscles ; the demonstration is thus rendered
complete.
In the same manner, all the palmar interossei are adductors as regards the axis of the
hand. Thus the first, which is represented by the adductor pollicis, and extends from
the third metacarpal bone to the inner or ulnar side of the first phalanx of the thumb, is
an adductor as regards the axis of the hand as well as that of the body ; the second, ex-
tending from the second metacarpal bone to the inner or ulnar side of the first phalanx
of the index finger, is an adductor both as regards the axis of the hand and that of the
body ; the third, extending from the fourth metacarpal bone to the outer or radial side
of the first phalanx of the ring finger, is an adductor as regards the axis of
the hand ; and, lastly, the fourth, extending from the fifth metacarpal bone to
the outer or radial side of the first phalanx of the little finger, is an adductor
as regards the axis of the hand, but an abductor in reference to the axis of
the body. A similarly-constructed figure, as that employed for the dorsal
interossei, wiU always keep this arrangement in the memory (see diagram
p ; the four fine lines represent the axes of the pahnar muscles). The gen-
eral disposition of the interossei may be summed up in the following very
simple law : All the dorsal interossei have their fixed attachments farther
from the axis of the hand than their movable one ; all the palmar interossei
have their fixed attaclmients nearer to the axis of the hand than their movable one.
We may now consider the general arrangement of these little muscles.
The Dorsal Interossei.
These are short, prismatic, and triangular muscles (d to d. Jig. 123), extending from
the two metacarpal bones, between which they are placed, to fHg. 123.
the first phalanx and the extensor tendon of one of the corre-
spending fingers. They arise by a double origin, between
which the perforating arteries pass. But while one of these
origins is limited to the back part of the lateral surface of one
of the metacarpal bones, the other occupies the whole length
of the corresponding lateral surface of the other metacarpEd
bone. From this double origin the fleshy fibres pass obliquely
forward round a tendon, which only emerges from them near
the metacarpo-phalangal articulation ; it then expands, and is
inserted partly to the upper end of the first phalanx and partly
to the outer edge of the corresponding extensor tendon.
Relations. — The dorsal interossei correspond behind with the
dorsal surface of the hand and the extensor tendons, from which they are separated by
a very thin aponeurosis ; in front, they are visible in the palm of the hand by the sides of
the palmar interossei, and, like the latter, are covered by the muscles and tendons of the
palmar region, being separated from those parts by the deep pahnar fascia. A distinct
cellular line, or, rather, an aponeurotic septum, intervenes between one of their lateral
surfaces and the corresponding palmar interosseous muscle ; the other lateral surface is
in relation, through its entire length, with the metacarpal bone on which it is implanted.
Action. — These muscles are evidently abductors of the first phalanges of the fingers,
the axis of the hand being taken as the point of departure. Their insertion into the ex-
tensor tendons explains why previous extension of the fingers is necessary to the move-
ment of abduction.
The first dorsal interosseous muscle merits a special description. It is larger than the
others, on account of the greater size of the space occupied by it ; it is flat and triangu-
lar, and arises by two origins, separated, not by a perforating branch, but by the radial
artery itself A fibrous arch completes the half ring formed by the interval between the
first two metacarpal bones for the passage of this artery. The external head of the
muscle arises from the upper half of the inner border of the first metacarpal bone ; the
internal from the entire length of the external surface of the second metacarpal bone,
and from the hgaments which unite it to the trapezium. From these points the fleshy
fibres proceed, forming two thick bundles, which are perfectly distinct above, and con-
verge to a tendon that is attached to the outer side of the first phalanx of the index finger.
264
BIYOLOGY.
Relations. — It is covered behind by the skin ; it corresponds in front to the adductoi
and flexor brevis pollicis, excepting below, where it is sub-cutaneous. Its lower edge,
directed obliquely downward and inward, is immediately sub-cutaneous, and crosses the
corresponding edge of the adductor pollicis at a very acute angle.
The Palmar Interossei.
These, like the preceding, are short, prismatic, triangular, and penniform muscles.
They are three in number (p p p, fig. 123) according to most authors, but four if we in-
clude the adductor pollicis. They all occupy the palm of the hand, as their name indi-
cates, and extend from the entire length of one of the metacarpal bones bounding the
interosseous space in which they are situated to the first phalanx of one of the corre-
sponding fingers, and to its extensor tendon.
They arise from about the anterior two thirds of the lateral surface of only one meta-
carpal bone ; they are, therefore, covered behind by the dorsal interossei, wliich, being
attached to the entire lateral surface of the other metacarpal bone, project equally into
the palm. Lastly, their insertions into the phalanges and their extensor tendons corre-
spond precisely with those of the dorsal interossei.
Relations. — They are covered by the flexor tendons and by the muscles of the palmar
region : each is in relation behind with a dorsal interosseous muscle ; on one side with
the dorsal muscle of the corresponding finger, and on the other with the metacarpal bone
from which it arises.
Action. — They are evidently adductors, as regards the axis of the hand, and, like the
dorsal interossei, they bind down the extensor tendons ; they can only act effectuall)
when the fingers have been previously extended.
MUSCLES OF THE LOWER EXTREMITIES.
The muscles of the lower extremities may be arranged in four groups, viz., those ol
the pelvis, of the thigh, of the leg, and of the foot.
MUSCLES OF THE PELVIS.
The Glutcei, Maximus, Medius, et Minimus. — Pyriformis. — Obturator Internus. — Gcmelb,
Superior et Inferior. — Quadratus Femoris. — Obturator Externus. — Action of these Muscles
fig, 1S4, The muscles of the pelvis are divided into those occupy
ing the posterior and those occupying the anterior region.
The former are very numerous, consisting of the three glutaei,
maximus, medius, and minimus, the pyriformis, the obturatoi
internus, the gemelli, the quadratus femoris, and the obtura-
tor externus.
The iliacus, which may with propriety be considered as be-
longing to the pelvis, and as forming its anterior vregion, hsis
been already described, together with the psoas, under the
name of the psoas-iliac muscle.
The GlutcBUs Maximus.
Dissection. — Having placed the subject on its face, raise the
pelvis by a block, flex the leg forcibly, and rotate it inward ;
then make an oblique incision along the middle of the but-
tock, from the sacrum towards the great trochanter, dividing
both the skin and fascia covering the muscle : dissect up the
tw(( "aps, one from below upward, the other from above down-
wani, following the direction of the muscular fibres.
The idutaus maximus {a, fig. 124) is the most superficial of
the muscles on the posterior aspect of the pelvis ; it is broad,
thick, and pretty regidarly quadrilateral ; it is the largest mus-
cle of the human body, in this respect coinciding with the
great size of the pelvis and femur in man ; it causes the prom-
inence of the buttocks. Its great size is one of the most dis-
tinctive characters of the muscular system of man, and has
reference to his biped position.
Attachments (see a, fig. 125). — It arises from the posterior
semicircular line of the ilium, and the portion of the bone be-
hind that line ; from the vertical sacro-iliac ligament, and the
outer margin of the common aponeurosis of the posterior spi-
nal muscles ; from the crest of the sacrum, sometimes only
from the tubercles which form a continuation of the trans-
verse processes of the vertebrae on the outside of the posteiior
THE GLUTiEUS MEDIUS. 265
sacral foramina ; from the edges of the coccyx, and the notch terminating the crest of the
sacrum below, this origin being often effected by means of a tendinous arch, under which
the last posterior sacral nerves pass ; from the posterior surface of the great sacro-sci-
atic ligament ; and, lastly, from the posterior surface of the aponeurosis of the glutseus
medius. It is inserted {a, fig. 125) into the rough line leading from the great trochanter
to the linea aspera of the femur.
The fleshy fibres arise either directly or by short tendinous fibres, and proceeding par-
allel to each other outward, and a little downward, unite into large distinct fasciculi, ca-
pable of being separated through their entire length, and constituting an extremely thick,
quadrilateral, and very regular muscle, which, having reached the outside of the thigh,
terminates by tendinous fibres. These are received between two layers of the fascia
lata, which is here very thick ; in passing downward they converge, escape from the
fascia lata, curve round the base of the great trochanter, or, rather, the tendon of the vas-
tus externus, from which they are separated by a synovial bursa, and are successively
inserted by so many large fasciculi into the series of tubercles and depressions, extend-
ing from the great trochanter to the linea aspera, and from the external bifurcation of
that line. The lower fleshy fibres are attached directly to the linea aspera, and a cer-
tain number are inserted merely into the fascia lata. In order to obtain a good view of
the femoral insertions of this muscle, its tendon must be separated from the fascia lata.
Relations. — It is covered by a large quantity of fat, being separated from it by an ex-
pansion from the aponeurosis of the glutaeus medius, from which are given off the cellu-
lar prolongations that divide the muscle into thick, parallel, and easily separable fasciculi.
It covers the glutaeus medius, the pyriformis, the gemelli, the obturator internus, the
quadratus femoris, the great sciatic notch, and the tuberosity of the ischium, together
with the muscles attached to it, viz., the semi-tendinosus, the semi-membranosus, and
the long head of the biceps. It covers also the great trochanter, the adductor magnus,
and the triceps femoris, the glutaeal, ischiatic, and internal pudic vessels and nerves, and
the great sciatic nerves. Its upper border is very thin, and rests upon the glutaeus me-
dius ; its lower border forms a very marked prominence beneath the skin, that affords
the surgeon very precise indications, both in the diagnosis of many diseases of the hip-
joint ; in operations performed for the purpose of reaching the tuberosity of the ischium,
when it is either carious or necrosed ; in those for the relief of sciatic hernia ; or, lastly,
in searching for the sciatic nerve, whenever it becomes necessary to operate upon it.
Several bursae mucosae, which have been well described by Monro, separate the glutaeus
maximus from the eminences which are covered by it. One of these separates it from
the great trochanter, and is almost always multi-locular : I have seen it filled with a san-
guineous synovia. A second exists over the tuberosity of the ischium, but is often want-
ing ; and a third between the tendon of this muscle and the vastus externus.*
Action. — The glutaeus maximus is an extensor, an abductor, and a rotator of the thigh
outward. When the femur is fixed, as in standing, it acts upon the pelvis, which it draws
backward and to its own side, and rotates so that the anterior surface of the trunk is
turned to the opposite side. Besides this, it is easy to see that the lower fibres can act
as adductors. By its connexions with the fascia lata, it is one of the principal tensors of
this structure ; by its attachment to the coccyx, it tends to prevent that bone from being
thrown backward, forward, or to one side.
The Glut (BUS Medius.
Dissection. — Make a vertical incision through the middle of the glutaeus maximus, or
detach that muscle from the pelvis ; remove the adipose tissue from the sub-cutaneous
portion of the muscle, and also the fascia lata ; dissect the tensor vaginae femoris, which
covers the anterior fibres of this muscle.
The glutaus medius (b,figs. 124 to 127) is intermediate to the other two glutaei, both as
regards size and position ; it is a broad, thick, radiated muscle, situated more deeply
than the preceding, beyond which it projects upward and forward (^fig. 124). The glu-
taeus maximus is attached to a small portion only of the iliac fossa : the glutaei medius
and minimus share almost the whole of it between them.
Attachments. — It arises from the whole extent of the curved triangular surface included
between the superior semicircular line behind, the anterior three fourths of the crest of
the ilium above, and the inferior semicircular line below ; from the anterior superior
spine of the ilium and the notch immediately below it ; from the deep surface of a dense
aponeurosis, which is inserted into the outer lip of the crest of the ilium, covers all the
upper portion of the muscle, and becomes continuous with the fascia lata : opposite the
junction of the anterior with the middle third of the crest of the ilium, at which point a
large tubercle exists upon the bone, this aponeurosis is so dense as to resemble a tendon.
The muscle also arises from a deep aponeurosis, extending from the anterior part of the
inferior semicircular line, and giving attachment, on its external surface, to a great num
her of fleshy fibres ; and, lastly, from the fascia lata internally to the tensor vaginae femo
ris. It is inserted into the external surface of the great trochanter {figs. 125, 127)
* See note, p. 296.
L L
k
266 MYOLOGY.
From these numerous origins the fleshy fibres proceed in different directions ; the pos-
terior forward, the middle vertically, and the anterior backward, becoming more and more
horizontal in front. They all terminate upon the two surfaces and edges of a radiated
aponeurosis, the fibres of which are gradually concentrated, and folded upon themselves,
so as to form a flat tendon, inserted, not into the upper border, as it is generally said, but
into the external surface of the great trochanter, along an oblique line running downward
and forward, so that the anterior fibres of the muscle are inserted into the anterior ex-
tremity of the lower border of the great trochanter, and the posterior fibres into the back
part of the upper border ; at this latter point a well-marked projection sometimes exists,
the size of which generjdly indicates the power of the glutaeus medius. A synovial bursa
intervenes between the tendon and that part of the great trochanter over which it passes.*
Relations. — It is covered by the glutaeus maximus, the tensor vaginas femoris, and the
skin : it covers the glutaeus minimus, with which its outer border is blended, and the
glutaeal vessels and nerves. Its lower border is parallel with the pyriformis {fig. 125).
Action. — The glutaeus medius is both an extensor and an abductor of the thigh. More-
over, the anterior fibres rotate the femur inward, and the posterior outward ; but the for •
mer have the greater power, for they are more numerous, the muscle being twice or
thrice as thick in front as behind ; it is, therefore, an extensor, an abductor, and a rotator
inward of the thigh. Winslow denies that it is an extensor, and considers it only as an
abductor ; this is only true in the position of standing upon both feet. In the sitting pos-
ture, again, this muscle in some degree loses its power as an extensor and abductor,
and acts merely as a rotator. When the femur is fixed, as in standing, the glutaeus
medius extends the pelvis, draws it to its own side, and rotates it> so that the front of
the trunk is turned towards the same side. It co-operates with the glutaeus maxunus in
the first two motions, but antagonizes it in the last. Finally, its anterior fibres appear
to me calculated to flex the thigh upon the pelvis, especiaUy when the flexion has been
already contmienced by other muscles.
The Glutce.us Minimus.
The glutaus minimus (c,fig. 127) is exposed by simply cutting across the preceding
muscle, beneath which it lies ; it is thinner, and more regularly radiated. It arises from
the anterior part of the crest of the ilium, below the glutaeus medius, from the outside of
the sciatic notch, and from all that part of the external iliac fossa situated below the in-
ferior semicircular line : from these points the fibres converge, the middle passing ver-
tically, the posterior forward, and the anterior backward, to the deep surface of a radia-
ted aponeurosis, the fibres of which are collected together into bands, that are inserted
separately into the anterior border and anterior half of the upper border of the great tro-
chanter. Most commonly the posterior band is intimately attached to the tendon of the
pyriformis.
Relations. — It is covered by the glutaeus medius, with which its anterior fibres are
blended ; it covers the external iliac fossa, the reflected tendon of the rectus femoris,
and the upper part of the hip-joint, from which it is separated by some fatty cellular tissue.
Action. — It is much more directly an abductor than the preceding muscles. Its ante-
rior half rotates the thigh inward, and its posterior half outward. If the femur be fixed,
it extends the pelvis, inclines it to its own side, and turns the anterior aspect of the
trunk to the same side ; by its anterior fibres it assists slightly in producing flexion.
General Remarks upon the Action of the Glutcei. — The three muscles we have just ex-
amined generally have their fixed points upon the pelvis ; and, in this point of view, are
of the greatest importance in the standing posture. By their means the pelvis, firmly
held down from behind, is enabled to resist the effects of the weight of the trunk, which
tends to throw it forward : hence the enormous development of these muscles in man,
evidently proving his destination for the erect position. These same muscles are the
principal agents in the position of standing upon one foot, inclining the pelvis to their
own side, and balancing the entire weight of the opposite side of the trunk. They also
rotate the trunk when the individual is standing upon one foot. They are all extensors
and abductors ; the glutaeus maximus is a rotator outward ; the other two are rotators
inward. Hence we may understand how the thigh can be so powerfully rotated inward,
although there are no direct muscles for that purpose ; while a great number are spe-
cially intended to produce rotation outward, which movement, indeed, is performed
much more energetically than rotation inward.
The Pyriformis.
Dissection. — Detach the glutaeus maximus, and separate the pyriformis from the lowei
border of the glutaeus medius, to which it is parallel. In order to see the sacral attach-
ments of the muscle, make an antero-posterior section of the pelvis.
The pyriformis or pyramidalis {d, fig. 125) is sometimes double : it is a flat muscle, of
a p5Tifonn, or, rather, pyramidal shape, lying almost horizontally along the lower margin
of the glutaeus medius, with which it seems to be continuous, and is sometimes intimately
* See note, p. 296.
THE OBTURATOR INTERNUS. 267
united : it is partly situated in the cavity of the pelvis, and assists in filling up the sciat-
ic notch.
Attachments. — It arises from the anterior surface of the sacrum (p,^. Ill), in the in-
tervals between the grooves forming the continuations of the anterior sacral foramina,
and also opposite those grooves, by three or four digitations, which are sometimes trav-
ersed by the great sciatic nerve : these origins are sometimes concentrated into a small
space around the second and third anterior sacral foramina. It also arises from the an-
terior surface of the great sacro-sciatic ligament, and from the upper part of the sciatic
notch. It is inserted into the back part of the upper edge of the great trochanter. The
fleshy fibres pass irom their origins almost horizontally outward and a little backward,
and form a muscle which fills up the upper part of the great sciatic notch, and, becoming
much narrower immediately after emerging from the pelvis, from the convergence of its
fibres, terminates on the posterior surface and edges of an aponeurosis, which is after-
ward converted into a round tendon, and is fixed to the upper border of the great tro-
chanter, behind the glutaeus minimus, and above the gemelU and obturator internus, with
which it is almost always intimately connected.
Relations. — Its anterior surface is in relation with the rectum, the sciatic plexus, and
the hypogastric vessels within the pelvis, and with the hip-joint outside that cavity ; its
posterior surface, with the sacrum and the glutaeus maximus ; its upper margin, with the
glutaeal vessels and nerves, which separate it from the glutaeus medius ; its lower mar-
gin, with the ischiatic vessels, and with the great and small sciatic nerves. Sciatic her-
niae take place between the upper margin of this muscle and the sciatic notch. Some-
times the muscle reaches the summit of the notch ; occasionally, a considerable interval
exists between them ; in such cases, there is a predisposition to this species of hemiae.
The Obturator Internus.
The oUurator internus {e,fig. 125) is a triangular reflected muscle, extending from the
inner surface of the margin of the obturator foramen to the digital cavity of the great
trochanter. Its course and direction are alike remarkable.
Attachments. — It arises from the posterior surface of the obturator ligament, from the
pelvic fascia lining the inner surface of this muscle, and from the tendinous arch which
converts the sub-jmbic groove into a canal ; also, from the entire circumference of the ob-
turator foramen, viz., from the internal surface of the descending ramus of the pubes and
the ascending ramus of the ischium, and from the whole extent of the quadrilateral sur-
face situated between the obturator foramen and the sciatic notch ; and, lastly, by a few
fibres from the brim of the pelvis. It is inserted into the digital cavity of the great tro-
chanter. The fleshy fibres arise directly from this extensive surface, and, converging
downward and outward, pass out of the pelvis through a triangular opening formed by the
spine of the ischium and lesser sacro-sciatic ligament above, by the great sacro-sciatic
ligament on the inside, and by the body of the ischium on the outside. At its exit from
the pelvis the muscle becomes much narrower, is reflected at a right angle over the body
of the ischium as over a pulley, is next received into a groove formed for it by the gemelli,
and proceeds horizontally outward, to be inserted into the digital cavity of the great tro-
chanter below the pyriformis. In order to obtain a good view of the structure of this
muscle, it must be detached from its insertion and turned inward. We shall then per-
ceive that the tendon divides into four or five diverging portions upon the deep surface
of the muscle, which are lost in its interior. A well-marked synovial membrane* inter-
venes between the tendon and the trochlear surface on the body of the ischium, which
is covered with cartilage that is streaked, as it were, in the direction of the movements.
Cowper and Douglas alluded to the presence of this bursa when they named the muscle
marsupialis vel bursalis.
Relations. — In the pelvis the obturator internus is in relation with the obturator liga-
ment and the circumference of the obturator foramen, by its anterior surface ; and with
the pelvic fascia and levator ani muscle, which separates it from the bladder, by its pos-
terior surface. During its passage through the orifice I have described, it is in relation
with the internal pudic vessels and nerves ; externally to the pelvis, it is covered by the
great sciatic nerve and the glutaeus maximus, and it covers the hip-joint.
From the great extent of the pelvic origins of this muscle, almost the whole of the an-
terior and lateral parietes of the pelvis are covered internally by a layer of muscular tis-
sue ; the posterior wall is also in a great measure covered by the pyriformis.
The origin' of the muscular fibres from the tendinous arch of the obturator ligament
are so arranged, that the contraction of the muscle can have no effect in diminishing the
size of the sub-pubic foramen intended for the passage of vessels and nerves. There
are sometimes two small tendinous arches ; one for the nerve, the other for the artery
and vein.
The Gemelli, Superior et Inferior.
The gemelli (gemini, Albinus ; les petits jumeaux, Winslaw, f and g, Jig. 135), two small
1 See note, p. 295.
268 MYOLOGY.
fleshy fasciculi, accessories to the obturator intemus, are generally distinguished by anat-
omists into the superior (/) and the inferior (g) ; they are separated from each other by
the tendon of the obturator intemus, for the reception of which they form a groove.
Above and below this groove they take their origin ; the superior from the spine of the
ischium, and the inferior, which is the larger, from the tuberosity of that bone, immedi-
ately above the attachment of the great sacro-sciatic ligament, and even slightly from
the ligament itself They both pass horizontally outward, are sometimes united either
behind or in front of the tendon of the obturator intemus, which they then completely
embrace, and with which they are entirely or partially blended, being inserted with it into
the digital cavity of the great trochanter.
Their relations are the same as those of the reflected portion of the obturator intemus.
The gemellus superior is often wanting, and the inferior is frequently double. I have
several times seen the superior terminate in the tendon of the pyriformis, and the in-
ferior in the tendon of the obturator intemus.
Actimi. — They rotate the thigh outward. Their relations with the synovial capsule of
the obturator intemus led to their being designated marsupiales by Cowper, and by Portal,
le muscle capsulaire de la capsule du tendon de I'obturateur interne.
The Quadratus Femoris.
This muscle (i, fig. 125), shaped like a parallelogram, is situated immediately below
the gemellus inferior. It arises from the external border of the tuberosity of the ischium,
in front of the semi-membranosus, from which it is separated by adipose tissue. From
this point the fibres proceed horizontally outward, parallel to each other, and are inserted
into " an oblong ridge* projecting partly from the back of the root of the great trochan-
ter, and partly from the femur immediately below it ;" but above the attachment of the
adductor magnus, with which, at first, it appears to be continuous, but from which it is
always separated by the internal circumflex vessels.
This muscle is sometimes wanting ; but very frequently its pelvic attachments are pro-
longed as far as the ascending ramus of the ischium ; in which cases it is twisted inferi-
orly upon itself, so as to oppose a surface, not a border, to the adductor magnus. Its re-
lations behind are the same as those of the preceding muscles ; in front, it covers the
obturator externus and the lesser trochanter, from which it is often separated by a sy-
novial capsule.
The Obturator Externus.
Dissection. — The lower or horizontal portion of the obturator externus is exposed, by
dividing the quadratus femoris into two equal parts by a vertical incision. In order to
see the upper or pelvic portion, it is necessary to detach the gracilis, pectineus, psoas, ili-
acus, and adductor brevis.
This is a triangular, flat muscle (e, fig. 127), of the same shape, but thinner and smallei
than the obturator intemus, and, like it, reflected, though at an obtuse angle. It arises
from the circumference of the obturator foramen, from the obturator ligament, and from
the tendinous arch which completes the sub-pubic canal for the vessels and nerve. It
is inserted into the deepest and lowest part of the digital cavity of the great trochanter.
The fleshy fibres arise directly, the lower ones proceed horizontally outward, and the
upper obliquely downward, backward, and outward ; thus converging, they form a fleshy
belly, which turns round the neck of the femur, and terminates in a tendon that passes
horizontally outward, to be inserted into the digital cavity, below the gemelli and the ob-
turator intemus.
Relations. — Its outer and anterior surface is in relation with the pectineus, the adduc-
tors, the psoas and iliacus muscles, and more externally with the neck of the femur and
the lower part of the capsular ligament of the hip-joint. Its inner and posterior surface
is in contact with the obturator foramen and the quadratus muscle.
Action of the preceding Muscles.
The last six muscles are evidently rotators of the thigh outward. The pyriformis, the
gemelli, and the obturator internus, which are almost always united at their insertions,
would deserve the name of quadri-gemini, given by the older anatomists to the gemeUi,
the pyriformis, and the quadratus. When they take their fixed point upon the femur, as,
for example, in standing upon one foot, they become rotators of the pelvis, and turn the
anterior surface of the trunk to the opposite side. They are only rotators when tlie limb
is extended ; in the sitting posture, they become abductors. Winslow, who first demon-
strated their use in abduction in the semiflexed position, attached great importance to
the connexion of so many of these muscles with the capsular ligament, which he believed
prevented pinching of the capsule during the different movements of the joint.
The insertion of these muscles is exceedingly favourable. Moreover, we shall find,
that besides the glutaeus maximus and the posterior fibres of the glutaeus medius and
* [M. Cruveilhier states the insertion of the quadratus femoris to be into the inter-trochanteric line. Tba
description in the text, copied from Albinus, gives a more accurate idea of the insertion of this muscle.]
THE BICEPS CRURIS.
minimus, they have many other muscles as accessories in rotation. The effects pro-
duced by the contraction of the two obturators can be easily understood, if we bear in
mind that the action of a reflected muscle is to be calculated from the point of reflection,
leaving the rest of the muscle out of consideration. Thus, with regard to the obturator
internus, the sciatic notch acts as a pulley, and may be regarded as the fixed point.
MUSCLES OF THE THIGH.
The Biceps Cruris. — Semi-tendinosus. — Semi-memhranosus. — Tensor Vagina. Femoris. —
Sartorius. — Triceps Extensor Cruris. — Gracilis. — Adductor Muscles of the Thigh.
The muscles of the thigh are divided into those of the posterior region, viz., the biceps,
the semi-tendinosus, and the semi-membranosus ; those of the external region, viz., the
tensor vaginae femoris and the vastus externus ; those of the anterior region, viz., the
sartorius, the rectus, and the triceps extensor cruris of authors ; and, lastly, those of the
internal region, viz., the gracilis, the pectineus, and the three adductors.
Posterior Region.
The Biceps Cruris.
Dissection. — This is the same for the biceps, the semi-tendinosus, and the semi-mem-
branosus. Place the subject upon its face, with a block under the pelvis, and allow the
leg to hang over one side of the table. Make an incision from the middle of the space
between the tuberosity of the ischium and the great trochanter to the interval between
the two condyles of the femur. Both the skin and the fascia of the thigh must be di-
vided in this incision. Cautiously remove the cellular and adipose tissue surrounding
the subjacent muscles, the relations of which with the popliteal vessels and nerves must
be carefully studied. In preparing the superior attachments of these muscles, the glu
iaeus maxiraus must be divided in the middle, perpendicularly to its fibres.
The biceps femoris (biceps cruris, Albinus, I, figs. 124, 125), so named because it con-
sists of two fleshy bodies or heads above, is a long, large muscle, situated on the poste-
rior and external aspect of the thigh.
Attachments. — It arises from the tuberosity of the ischium and the linea aspera of the
femur, and is inserted into the head of the fibula, and slightly jp^. 125.
into the external tuberosity of the tibia. Its origin from the
ischium {I, fig. 125) is common to it and the semi-tendinosus ; -;; ■; ^^f ;
it takes place, not from the tuberosity properly so called, but
from the highest and most external part of the tuberosity,
above and behind the adductor magnus, and immediately be-
low the gemellus inferior. It arises by a tendon which is sel-
dom completely free from muscular fibres. This tendon, at
first very thick, and separated from the tuberosity of the
ischium by a synovial bursa, expands into an aponeurosis,
which gives origin to the fleshy fibres of the biceps by its ex-
ternal edge and posterior surface, and to those of the semi-
tendinosus by its internal surface. Up to this point the biceps
and semi-tendinosus are blended together so as to form a single
fleshy belly, which, after extending from two to four inches, is
divided into two portions : one posterior and external, consti-
tuting the long head, or ischiatic portion of the biceps ; the other
anterior, forming the origin of the semi-tendinosus, which we
shall next describe. Arising thus in succession, the fleshy
fibres of the long head of the biceps form a fusiform belly
passing obliquely downward and a little outward, and termina-
ting on the anterior surface of an aponeurosis, which extends
for a considerable distance on the posterior surface of the
muscle, and which gradually becomes contracted, so as to
form the terminal tendon. Just where these fleshy fibres are
about to terminate {l,Jig. 125), the aponeurosis receives upon
its anterior surface and external edge the fleshy fibres of the
short head, or femoral porticm of the biceps. This portion of
the muscle {I', fig. 125) arises from the greater part of the in-
terval between the two margins of the linea aspera, and the
posterior surface of the external inter-muscular septum of the
thigh ; it passes downward, inward, and backward, to be at-
'.ached to the common tendon, almost as far as its insertion.
This insertion is not confined to the head of the fibula, but extends also to the external
tuberosity of the tibia by means of a strong division of the tendon, which, at the same
time, gives ofF^n expansion to the fascia of the leg. The insertion into the fibula is ef-
2^0 MYOLOGY.
fected on the outer side, in front of and behind the extemzd lateral ligament of the knee-
joint, which ligament it embraces in a bifurcation.
Relations. — The biceps is covered by the glutaeus maximus and the femoral fascia. It
covers the semi-tendinosus, semi-membranosus, and vastus externus. It is in relation,
also, with the great sciatic nerve, which is placed at first externally, then in front, and,
lastly, on the inside of the muscle ; finally, its short head is in relation with the popliteal
vessels.
The biceps forms the external border of the popliteal space ; near its termination it
is in relation with the outer head of the gastrocnemius and with the plantaris longus
muscle.
Action. — The biceps flexes the leg upon the thigh. When this movement is com-
pleted, its long portion extends the thigh upon the pelvis. From its obliquity downward
and outward, it rotates the leg outward during semi-flexion ; but this rotation is impos-
sible when the leg is extended, in consequence of the tension of the crucial ligaments.
The fixed point of this muscle is as often below as above, and it then performs an im-
portant part in the mechanism of standing ; for it tends to prevent the individual from
ialhng forward, because it holds back the pelvis. When the pelvis is thrown quite back-
ward, this muscle can then flex the thigh upon the leg.
The Semi-tendinosus.
The semi-tendinosus {m,figs. 124, 125), so named on account of the great lengta of its
tendon, is situated on the posterior and internal aspect of the thigh.
AttcLchments. — It arises from the tuberosity of the ischium, and is inserted into the an-
terior tuberosity of the tibia. Its origin (m, fig. 125) consists of a tendon common to it
and the long head of the biceps, which is prolonged in the form of an aponeurosis, upon
the external (or popliteal) border of the muscle. Some of the fleshy fibres are attached
directly to the tuberosity of the ischium. Having arisen in this manner, it enlarges and
constitutes a fusiform bundle, which passes at first vertically downward, and then ob-
liquely inward. About four or five fingers' breadth above the knee-joint it terminates in
a long, thin tendon, which turns round the internal tuberosity of the tibia, describing a
curve having its concavity directed forward, and is then reflected horizontally forward,
to be inserted into the anterior teberosity of that bone, behind the tendon of the sarto-
rius, and parallel with the lower edge of that of the gracilis, to which it is united. The
union of these three tendons constitutes the patte d'oie (goose's foot).
The length of its tendon of insertion is the most characteristic feature of the muscle ;
and hence its name, semi-nervosus (Spigelius), and le demi-nerveux ( Winslow), for which
the term semi-tendinous has now been substituted. The structure oi this muscle is re-
markable. The fleshy fibres are interrupted across the middle by a tendinous intersec-
tion, analogous to that of the great complexus, which gives origin to new fleshy fibres.
Relations. — It is covered by the glutaeus maximus and the femoral fascia, and it cov-
ers the semi-membranosus and part of the upper portion of the adductor magnus. Its
tendon is first placed behind the semi-membranosus, and then, before it turns round the
internal tuberosity of the tibia, between the tendon of that muscle and the inner head of
the gastrocnemius.
Action. — ^The same as that of the biceps. It is a very powerful flexor, on account of
the reflection of its tendon. Its oblique direction enables it to rotate the tibia inward du
ring semi-flexion of the leg. It is, therefore, a congener of the popliteus.
The Semi-membranosus.
The semi-membranosus {n,figs. 124, 125) is situated upon the posterior aspect of the
thigh, thin and aponeurotic above, thick and fleshy below.
Attachments. — It arises from the upper and outermost part of the tuberosity of the is-
chium, in front of the biceps and semi-tendinosus ; and is inserted into the internal tuber
osity of the tibia, and also, by an expansion of its tendon, into the femur. It arises by
means of a very thick tendon, which becomes wider immediately after its origin. From
its inner border is given off" an aponeurotic lamina, that splits into two layers, from the in-
terval between which the superior fleshy fibres arise. Lower down, the muscular fibres
proceed directly from the tendon itself, which runs along the outer (or popliteal) border
of the muscle, as far as the lower fourth of the thigh, but is afterward buried in its sub-
stance. The union of all these fibres constitutes a very thick, four-sided, fleshy belly,
which is received into a tendinous semi-cone, open on its outer side, and soon becoming
converted into a thick tendon, which, after a passage of a few lines, separates into three
divisions, terminating in the following manner : the posterior division passes inward and
upward, forms the chief part of the posterior ligament of the knee-joint, and is inserted
into the femur ; the middle division is attached to the back of the internal tuberosity of
the tibia, below the articular surface ; the third is horizontal, and turns round the inter-
nal tuberosity of that bone in the horizontal furrow existing there, and is inserted on the
inner side of the tuberosity. A synovial bursa intervenes between it and the bone.
Relations. — The semi-membranosus is covered by the glutaeus maximus, the semi-ten-
THE TENSOR VAGINA FEMORIS. THE SARTORIUS. 271
dinosus, the biceps, and the femoral fascia : it covers the quadratus femoris, the adduc-
tor niagnus, and the inner head of the gastrocnemius. A synovial membrane separates
it from the knee-joint. It also covers the popliteal artery and vein, which soon come
into relation with its outer or popliteal border. The sciatic nerve lies parallel with its
outer border through the whole of its extent ; the gracilis is in contact with its inner
border. I shall remark here, that the biceps on the outside, and the semi-membranosus
and semi-tendinosus on the inside, constitute the lateral boundaries of a cellular interval
which extends along the whole of the back of the thigh, and is continuous with the pop-
liteal space. This large cellular interval communicates above with the cellular tissue
of the pelvis at the sciatic notch, and below with the fossa of the ham. It is in this di-
rection that purulent matter so readily escapes from the pelvis. The greater part of
this interval is destined for the great sciatic nerve, which, however, is soon accompani-
ed by the popliteal vessels.
Action. — Precisely similar in nature to that of the preceding muscle, but much more
powerful. The momentum of all these flexor muscles occurs, on the one hand, during
semi-flexion of the leg upon the thigh ; and, on the other (i. e., when their lower attach-
ments are fixed), during semi-flexion of the thigh upon the pelvis.
External Region.
The Tensor Vagince Femoris.
Dissection. — In order to expose this muscle, it is sufficient to make a vertical incision
through the thick, tendinous layer given off from the anterior portion of the crest of the
ilimn, and to dissect back the two flaps of that aponeurosis.
The tensor vagina femoris (le muscle du fascia lata, o,fig. 126) is the largest of all the
extensor muscles of aponeuroses : it is a short, flat, quadrilateral muscle, contained within
the substance of the fascia lata, and occupying the upper third of the external region of
the thigh. It arises from the anterior part of the outer margin of the crest of the ilium,
and from the outer border of the anterior superior spinous process of the ilium, between
the sartorius and the glutasus medius, by means of a tendon, which also furnishes some
points of attachment to the anterior fibres of the last-named muscle. From these points
the fleshy fibres proceed downward and a little backward, and, at about the upper fourth
or third of the thigh, terminate in a series of small tendinous bundles, the anterior of
which become continuous with the fascia lata, while the posterior cross obliquely over
the vertical fibres of the fascia, with which they are very soon blended.
Relations. — It lies between two layers of the fascia lata, the external layer being much
thicker than the internal. It is covered by the skin, and it covers the glutaeus medius,
the rectus, and the vastus extemus. Its anterior border is in contact with the outer
edge of the sartorius, but is soon separated from it by a triangular space, in which the
rectus femoris may be seen. '
Action. — It is a tensor, not only of the entire femoral fascia, but particularly of the very
dense portion or band of the fascia lata, which, being continuous with it, may be regard-
ed as an aponeurotic tendon to this muscle (muscle aponeurotique de la bande large,
Winslow), and which is inserted into the outer tubercle of the anterior tuberosity of the
tibia, and into the adjacent part of its external tuberosity. When the tensor vaginae is
in action, this band compresses the vastus extemus, which has so great a tendency to
displacement ; by means of this band, also, the muscle acts upon and extends the leg.
Lastly, on account of its slight obliquity downward and backward, it may be regarded as
a rotator of the thigh inward ; it is but little concerned, however, in the production of
this movement, which, as I have already said, is chiefly effected by the anterior fibres
of the glutaei medius and minimus.
Anterior Region.
The Sartorius.
Dissection. — This is common to all the muscles of the anterior and inner regions ol
the thigh. Make a horizontal incision along the fem.oral arch, and another perpendicu-
larly from the middle of that to the anterior tuberosity of the tibia. Dissect the fascia
of the thigh with care. As all the muscles of the anterior and inner region are separa-
ted from each other by distinct sheaths, their dissection consists simply in opening these
sheaths successively, and removing the cellular tissue that fills up the inter-muscular spa-
ces. It is necessary to preserve the vessels, in order to obtain a good view of their rela-
tions : avoid opening the vena saphena, as it generally contains a large quantity of blood,
the escape of which will impede the dissection. If the vein should be opened, it must be
tied above and below the orifice, and then cut across. When the superficial muscles
have been studied, they must be divided in the middle, in Order to expose the muscles
of the deep layers.
The sartorius {p, fig. 126), so named on account of its uses, crosses diagonally over the
anterior, and then the inner part of the thigh, to the top of the leg. It is the longest mus-
cle in the body, both as regards its total length, and more especially in reference to the
«72
MYOLOGY.
Fig- 126. length of its fibres ; whence the name of longus, given to it by
Riolanus. This is the case even although it be nneasured by a
line stretched directly between its two extremities.
Attachments. — It arises from the anterior superior spinous pro-
cess of the ilium, from the upper half of the notch below that pro-
cess, and from a tendinous septum between the muscle and the
fascia lata. It is inserted into the inner margin of the crest of the
tibia, situated beneath the ligamentum patellae. Its origin con-
sists of some tendinous fibres, which are more marked beb md and
on the outer side than in front and within. The fleshy fibres
commence almost immediately, and form a flat, riband-like mus-
cle (fascialis, Spigelius), which in reality is prismatic and trian-
gular, as well as the tendinous sheath in which it is enclosed.
The muscle increases in breadth as far as the lower third of the
thigh, and passes obliquely downward, inward, and a little back-
ward ; it becomes internal and vertical at the lower third (p, Jigs.
124, 125), and reaches the back part of the inner condyle of the
femur, to turn round the knee-joint, tendinous fibres having al-
ready conmienced on the anterior edge of the muscle. The fleshy
fibres terminate precisely where the muscle changes its direction
to pass forward. The flat tendon by which they are succeeded is
at first narrow, but becomes considerably expanded, to be inserted
into the crest of the tibia, in front of the tendons of the semi-ten-
dinosus and gracilis muscles, with which it is united, so as to
form what is called the patte d'oie (goose's foot). A synovial
membrane separates it from the tendons of these muscles. A
considerable tendinous expansion is given off from its lower edge,
and contributes to form the inner part of the fascia of the leg.
Relations. — ^The sartorius is the most superficial muscle in the
anterior aspect of the thigh ; it lies beneath the femoral fascia,
and covers the psoas and iliacus, the rectus, the vastus internus,
the adductor longus, the gracilis, the adductor magnus, and the
internal lateral ligament of the knee-joint. The borders of this
muscle deserve particular attention, because incisions for ligature
of the femoral artery must be made along them. Its most important relation, indeed, is
with the femoral artery and vein ; it is the satellite muscle of the femoral artery. Thus,
in the upper third of the thigh, it forms, with the adductor longus and femoral arch, an
isosceles triangle, having its base turned upward, and the femoral artery represents a
perpendicular drawn from the apex to the base of the triangle. In the middle third of
the thigh, the artery is in relation, first, with the inner border, then with the posterior
surface, and, lastly, with the outer border of the muscle. In the lower third, the sarto-
rius occupies a deep groove, formed by the gracilis and vastus internus ; from the latter
muscle it is separated below by an interval containing adipose tissue, of which circum-
stance advantage may be taken in the application of issues. It also covers the saphenus
nerve (a deep branch of the anterior crured), which emerges from beneath its anterior bor-
der, opposite the lowermost point of insertion of the adductor magnus. Near the knee-
joint, the saphena vein is in relation with the posterior border of the muscle.
The structure of the sartorius is very simple. The fleshy and tendinous fibres are all
parallel, and the former correspond exactly with the length of the muscle.
Action. — The sartorius flexes the leg upon the thigh, which it draws inward, so as to
cross one leg over the other. When this movement is produced, it flexes the thigh upon
the pelvis. If the fixed point of the muscle be at the leg, it then flexes the pelvis upon
the thigh, and rotates it, so that the anterior surface of the trunk is directed to the op-
posite side.
The Rectus Femoris and Triceps Extensor Cruris, or the Triceps Femoralis.
I have included under the name triceps femoralis the two muscles, or, rather, the two
parts of the same muscle, which are described separately in most anatomical works.
The reasons for this arrangement will be understood after the following description of
the muscle :
I shall consider the triceps femoralis as composed of three portions, viz., a middle or
long portion, the rectus femoris of authors ; an external and an internal portion, which
constitute together the triceps cruris of authors ; for these I shall retain the names of
vastus internus and externus, including in the former the middle portion or crureus, prop-
erly so called, of most anatomists.
The long portion of the triceps femoralis, or the rectus femoris (r, fig. 126), is situated in
the anterior region of the thigh, extending from the anterior inferior spinous process of
the ilium to the patella : it is vertical in its direction, thick and broad in the middle, and
narrowei at its extremities in..-;-r
THE RECTUS FEMORIS AND TRICEPS EXTENSOR CRURIS. 273
It arises by a very strong tendon (r, fig. 127), which embraces the anterior inferior
spinous process of the ihum, and is proportioned to the power of the muscle. This ten-
don receives on its outer side another flat tendon, arising from a groove upon the rim
of the cotyloid cavity, and following its curvature ; this is the rejected tendon, which is
blended with and strengthens the straight tendon. It then expands into a broad aponeu-
rosis, the outer portion of which is very thin and prolonged over the anterior surface of
the muscle as far as the middle, while the inner portion is very thick, and penetrates
into its substance nearly as far as its insertion. The fleshy fibres arise from the poste-
rior surface and edges, and also from the anterior surface of the inner portion of this
aponeurosis ; they all pass downward and backward, the internal inward and the exter-
nal outward, and form a fleshy belly, which increases as it proceeds downward, and then
terminates on the anterior surface of a broad, thick, and shining aponeurosis, occupying
the lower two thirds of the posterior surface of the muscle, and soon becoming contract-
ed into a flat tendon, which receives upon its inner edge the superficial fibres of the
vastus intemus, again expands, and is finally blended with the common tendon of the
two vasti.
Triceps Femoris of Authors, or Vastus Internus and, Externus. — This is a voluminous
mass of muscular tissue, situated behind the preceding muscle, and extending from the
three surfaces of the shaft of the femur to the patella and tibia. It is commonly but er-
roneously considered to be divided above into three heads, which are described under
the names of vastus internus, vastus externus, and crureus. I have searched in vain for
the middle portion, but have never been able to find more than two separate parts : one
external, very large and superficial, viz., the vastus externus; the other internal, anteri-
or, and even external, viz., the vastus internus ; it is much smaller than the vastus ex-
ternus, and is partly covered by it and by the rectus.
The external portion, or vastus externus {s, figs. 124 to 127). This is the largest portion
of the triceps femoralis. It arises from a projecting border or horizontal crest, situated
at the base of the great trochanter, and from a vertical edge in front of that trochanter,
which forms a continuation of its anterior border, and sometimes presents a very prom-
inent tubercle : in the angle formed by these two attachments is situated tlie tendon of
the glutseus medius. It also arises along a line running from the great trochanter to the
linea aspera, and from the whole extent of the external lip of the linea aspera itself
All the preceding origins are effected by means of a broad aponeurosis which covers the
superior three fourths of the muscle, and from the deep surface of which almost all the
fleshy fibres proceed. Lastly, some of these arise from the tendon of the gluta?us max-
imus, and from the tendinous septum intervening between the vastus externus and the
short head of the biceps. From these origins the fleshy fibres proceed, some vertically
downward, the others somewhat obliquely downward and forward, the lowest being the
shortest and the most oblique ; they form a large bundle, which partially covers the an-
terior portion of the vastus intemus, but is separated from it by vessels, nerves, and cel-
lular tissue. After a course of variable length, some of the fleshy fibres are attached to
the deep, but the greater number to the superficial surface of another equally strong apo-
neurosis : this becomes thickened and contracted into a flat tendon, which is sometimes
divided into thick parallel bands, emerges from the fleshy fibres at the external margin
of the rectus, and is inserted into the outer half of the upper border of the patella, being
blended on the inner side with the rectus and the vastus intemus. The lower fleshy
fibres which arise from the inter-muscular septum are attached directly to the outer bor-
der of the patella.*
The internal or anterior portion, vastus internus {t and u,fig. 127), is much smaller than
the external, and surrounds the femur. Its inner portion lies immediately under the fas-
cia, and is the only part which is generally described as the vastus internus {t,figs. 126, 127).
Its anterior portion is covered by the rectus, or long portion, and is usually called the
crureus (cmralis, Alb., u,fig. 127). Its outer portion is covered by the vastus externus,
with which many of its fibres are blended ; but they may always be separated by cutting
along the outer margin' of the middle aponeurosis. Thus defined, the vastus internus
arises from a rough oblique line, extending from the front of the neck of the femur to the
linea aspera, and from the internal lip of the linea aspera itself, in front of the adductor
muscles : both of these origins are effected by means of an aponeurosis, which is weaker
and smaller than that of the vastus externus, and is blended with that of the adductors,
concurring w ith it in the formation of a canal for the femoral artery. It also arises from
almost the whole of the internal, anterior, and external surfaces, and from the two ante-
rior borders of the femur ; lastly, the lower fibres arise from the internal inter-muscular
septum. From these different origins the fleshy fibres pass in various directions ; the
external inward, the middle vertically, and the internal, which are the most numerous,
downward, forward, and outward ; they thus form a fleshy belly, thicker below and with-
in than above and without, and are successively attached to both surfaces, and espe-
cially to the posterior surface of a broad aponeurosis, which is covered by the tendon of
* Tke anterior border of this tendon is free, and perfectly distinct from the tendon of the rectus, which is
lined by it ; and also from the expanded tendon of the vastus internus.
Mm
2T4 MYOLOGY.
the vastus externus, but can be easily separated from it. The uiner fibres are attached
to the anterior surface of the aponeurosis, and terminate very regularly opposite a verti-
cal line, running parallel to the inner margin of the rectus femoris.
The aponeurosis extends over the anterior surface of the middle portion of the mus-
cle, which lies behind the rectus : this fact has, doubtless, given rise to its division into
two parts, viz., a middle, or the crureus, and an internal, called the vastus internus. The
superficial layer of the interna! fleshy fibres is attached below to the inner margin of the
rectus, or long portion of the triceps femoralis : the lowest of these fibres, which arise
from the inner and inferior bifurcation of the linea aspera, and from the corresponding
inter-muscular septum, are almost horizontal, and accompany the tendon as far as its in-
sertion into the inner border of the patella. Lastly, the terminating aponeurosis is pro-
longed inward to the internal tuberosity of the tibia, below which it is inserted, being
covered by the tendons of the semi-tendinosus, semi-membranosus, and gracilis muscles,
on the inner side of the internal lateral ligament of the knee. This very strong aponeu-
rotic insertion represents the fascia lata on this aspect of the limb, and forms an acces-
sory internal lateral ligament.
From the above description, it follows that the triceps femoralis is composed of three
muscles and three tendons, super-imposed upon each other, viz., the rectus femoris, the
vastus externus, and the vastus internus.
Relations. — The long portion of the triceps, or the rectus femoris, is covered by the
fascia lata in its lower three fourths. Its upper part is covered by the sartorius, by the
anterior fibres of the glutajus medius, and by the psoas and iliacus. It covers the hip-
joint, the anterior circumflex vessels, and the two vasti muscles. The vasti surround
the femur as in a muscular sheath, and have relations with all the muscles of the thigh.
They are superficial in a great part of their extent : in front, they are in relation with
the psoas and iliacus, the rectus femoris, and the sartorius, and they lie immediately
under the fascia, in the triangular spaces left between these muscles : behind, they are
in relation with the biceps and semi-membranosus ; on the inside, with the adductors,
with the femoral artery, the sheath of which the vastus internus contributes to form,
and with the sartorius ; on the outside, with the glutaeus maximus, which glides over
the upper end of the vastus externus, and is separated from it by a synovial bursa ; and,
lastly, with the tensor vaginae femoris, and the fascia lata. It is necessary to allude
here to a small fleshy bundle, formed by the deepest and lowest fibres of the vastus in-
ternus, which is always distinct from the rest of the muscle, and is inserted into the up-
per part of the synovial membrane of the knee. This bundle has been regarded by Wins-
low as an articular muscle, intended to prevent the synovial membrane from being
pinched between the surfaces of the joint.
Action. — This muscle extends the leg upon the thigh ; its action is facilitated by the
existence of the patella, which serves to increase the angle of insertion, and which we
have described as a sesamoid bone, developed in the substance of the tendon. We must,
therefore, regard the triceps as inserted into the anterior tuberosity of the tibia, or, rath-
er, into tiie lower part of that tuberosity. It should be observed, that the tendon is in-
serted into the patella, in front of its base, and not into the base itself, in the same man-
ner as the ligameutum patellae is attached to the anterior surface of that bone, and not
to the rough mark on its posterior surface : this important arrangement increases the
angle at which the moving power operates. The triceps femoralis is the most powerful
muscle in the body, no other having such large surfaces of origin, and, consequently, so
great a number of fibres. By itself it supports, in a state of equilibrium, tlie entire
weight of the body in standing, and may be adduced as a striking example of the pre-
dominance of the extensors over the flexors ; it is also this muscle which raises the
whole trunk in progression and in the act of leaping. We cannot, therefore, be astonish-
ed at rupture of the patella, of its ligament, or of the common tendon, during a violent
contraction of this muscle, notwithstanding its disadvantageous insertion so near to the
fulcrum. The rectus necessarily acts with the two vasti, but it can also flex the thigh
upon the pelvis. The somewhat oblique direction of the tendon of the triceps down-
ward and iawar^, and of the ligameutum patelljff downward and outward, so that Siey
form an obtuse angle, open to the outside {see Jig. 126), and more especially Jliejjjfedom-
inance of the vastus externus over the vastus internus, sufficiently account for the oc-
currence of luxation of the patella>Qulw.aj:d,taiid (dr the impossibility of its beiifig dislo-
cated inward.
When the patella is forced inward by external violence, the contraction of the vastus
externus draws it back into its original position : on the other hand, the action of this
muscle has a tendency to displace it outward ; and when this is accomplished, the same
muscle keeps it in its abnormal position. Luxations of the patella, therefore, if not al-
together irreducible, can only be temporarily replaced ; whenever the hand ceases to re-
tain tlie bone in its proper place, the contraction of this muscle again dislocates it. Pro-
fessor Ant. Dubois has informed me of an individual whose knees were bent very much
inward, who could not contract the triceps femoralis with any force without dislocating
the patella outward.
THK GRACILIS, ETC.
iM
Internal Region of the Thigh.
The muscles of the internal region of the thigh are the gracilis and the adductors,
among which I include the pectineus.
The Gracilis.
The gracilis (le grele interne, ou droit interne, Winslow, v,figs. 124, 125, 126) is a long,
straight, and slender muscle, and the most superficial of those situated on the inside of
.he thigh.
Attachments. — It arises from the symphysis pubis, between the pubic spine and the
ascending ramus of the ischium, and is inserted into the spine of the tibia. It arises by
some long, shining, and parallel tendinous fibres, which bind down a perpendicular fibrous
bundle that lies on the inner side of the line of attachment. The fleshy fibres succeed-
ing to these are at first parallel, and "form a broad, thin bundle ; they then converge to-
wards each other, so that the entire muscle resembles a much elongated isosceles tri-
angle. It is rounded below, and terminates in a long, thin tendon, which runs for a con-
siderable distance upon its posterior border, and receives all the fleshy fibres in succes-
sion. This tendon becomes free immediately above the knee-joint, is then situated be-
hind the internal condyle of the femur, turns round this process and the corresponding
tuberosity of the tibia, and is inserted into the spine of the last-mentioned bone, behind
the tendon of the sartorius, and above that of the semi-tendinosus, with both of which it
is united so as to form the trifid aponeurotic interlacement, denominated la patte d'aie
(goose's foot).
Relations. — The gracilis is covered by the femoral fascia, and slightly by the sartorius
at its lower part : it covers the three adductors, the inside of the knee-joint, and the in-
ternal lateral ligament, from which it is separated by a synovial bursa common to it and
the semi-tendinosus : the vena saphena interna crosses the inner surface of this muscle
obliquely, near its lower extremity.
Action. — It flexes the leg, and carries it slightly inward, at the same time, by means of
its reflection round the knee ; in this part of its action it assists the sartorius ; it also ad-
ducts the thigh. In the position of standing, its movable point is at the pelvis.
The Mductor Muscles of the Thigh.
There are three muscles on the inner aspect of the thigh which are called adductors ;
with these the older anatomists were acquainted under the collective name of the triceps
adductor. Modern viTiters, however, describe them either in the order of their super-
imposition, as the fo-st, seco7id, and third (Boyer) ; or in the order of their size, as the mid-
dle, small, and great adductors (Bichat). These vague denominations are the source of
much confusion, for the one which occupies the middle place as regards size is the first
as regards its position. I have therefore thought it right to modify these names, and
have, at the same time, included the pectineus among the adductor muscles. I consider,
therefore, that there are four adductors, which I shall divide into superficial and deep ;
the two superficial are the pectineus and the first or long adductor ; these I shall term
the first and second.
Superficial Adductors. — The two deep are the short and the great adductors, which I
shall denominate the small deep adductor and the great deep adductor. Strictly speaking, we
could only admit the existence of two adductors, one superficial, the other deep ; and this
mode of division would perhaps be preferable.
Dissection. — This is common to all the adductors. Abduct the thigh so as to render
these muscles tense. Make an incision through the integuments from the middle of the
femoral arch to the patella, and a semicircular incision at either end of this ; preserve
the vessels and nerves, in order to examine their relations ; tie and cut across the vena
sephena where it enters the femoral vein ; divide the fascia lata, and dissect the mus-
cles, which will then be brought into view.
The First Superficial Adductor, or Pectineus.
Tiie pectineus {pecten, the pubes) is a square muscle {w, fig. 126) situated at the upper
anterior and inner aspect of the thigh, on the inner side of the psoas and iliacus (c).
Attachments. — It arises (w, fig. 127) from the spine and crest of the pubes, from the trian-
gular surface in front of this crest, and from the lower surface of a very strong tendinous
and arched prolongation of Gimbernat's ligament, which is attached to the crest of the pu-
bes, and is continuous with the fascia covering the muscle. It is inserted (w, fig- 127)
below the lesser trochanter, into the ridge extending from that process to the linea as-
pera. With the exception of the spine of the pubes, where there are always some well-
marked tendinous attachments, the fleshy fibres commence directly from the several ori-
gins : they proceed downward, backward, and outward, and constitute a bundle, which is
at first flattened from before backward, and afterward from without inward .- the fibres of
this after a short course converge, and are inserted into the internal bifurcation of the
linea aspera, in part directly, and partly through the medium of an aponeurosis which oc-
cupies the anterior surface of the muscle.
MYOLOGY.
Tig. 127.
Relations. — The pectineus is covered by the deep layer of
the femoral fascia, and by the femoral vessels. It covers the
capsular ligament of the joint, the small deep adductor, and
the obturator externus, from which it is separated by the ob-
turator vessels and nerves. Its outer border is parallel with
the inner border of the conjoined portions of the psoas and
iliacus, and is separated from them by a cellular interval, over
which the femoral artery passes ; so that, were it not for the
projection of this outer border, this vessel would be in imme-
diate contact with the bone. Its inner border is in relation
with the second superficial adductor, and is sometimes blend-
ed with it, except below, where it is separated by an interval
in which the small deep adductor may be seen. It has an im-
portant relation with the anterior orifice of the sub-pubic canal,
which corresponds with the posterior surface of the muscle.
When hernial protrusions, therefore, take place at the fora-
men ovale, the displaced parts are always covered by the pec-
tineus muscle.
The Second Superficial Adductor^ or Mductor
Longus.
The adductor longus of Albinus (le premier adducteur, Ba-
yer; le moyen adducteur, Bichat, x,fig. 126) is a flat, triangu-
lar muscle, situated on the same plane as the pectineus, of
which it seems to be a continuation, and with which it is often
blended above. For this reason, Vesalius made of these two
muscles his eighth pair of muscles of the thigh, under the
name of pars octava femur moventium. It is certain that there
is a sort of consolidation between these two muscles, and that
a small pectineus is always observed in conjunction with a
large adductor longus.
Attachments. — It arises {x, Jig. 127) from the spine of the
pubes, and is inserted {x) into the middle third of the linea as-
pera of the femur. Its origin consists of a narrow, flat ten-
don, which expands anteriorly, and gives origin to a thick and
broad fleshy belly ; this passes downward, backward, and out-
ward, and is inserted into the middle third of the linea aspera
of the femur, between the triceps femoralis in front, and the great deep adductor behind :
with the latter of these muscles it becomes blended at its insertions. It is attached to
the bone by means of two tendinous layers, between which the fleshy fibres are receiv-
ed. A number of foramina, intended for the perforating arteries, are observed in the neigh-
bourhood of this attachment.
Relations. — Its upper part lies immediately under the fascia, and it becomes gradually
deeper as it passes downward. It is in relation with the sartorius, from which it is sep-
arated by the femoral artery and veins. This relation is one of great importance, as I
shall hereafter have occasion to point out.
The Small Deep Adductor, or Adductor Brevis.
The adductor brevis o{ Albinus (le seconde of Boyer ; le petit of Bichat, y,fig. 127) is
of the same form as the preceding muscle, and is the second in the order of super-im-
position, but the smallest in size. It arises below the spine of the pubes on the outer
side of the gracilis and the inner side of the obturator externus, from a variable extent
of surface. The fibres proceed outward, downward, and a little backward, and form a
thick bundle, at first flattened from within outward, and then from before backward,
which increases in breadth, and terminates at the middle of the linea aspera of the femur,
in front of the great deep adductor, and behind the two superficial adductors, with which
it is blended at its insertion.
Relations. — It is covered by the superficial adductors, and it covers the great deep ad-
ductor, or adductor magnus. Its outer border has a relation with the obturator externus,
and the conjoined psoas and iliacus muscles ; its inner border is at first in contact with
the gracilis, and is then applied to the adductor magnus, from which it is sometimes
difficult to separate it.
The Great Deep Adductor, or Adductor Magnus.
Dissection. — In order to obtain a good view of this muscle, it is not suflicient to study
its anterior surface only, which is exposed after the preceding muscles have been divi-
ded ; its posterior surface must also be examined ; and for this purpose it is necessary
to remove the three muscles of the posterior region of the thigh, viz., the biceps, the
semi-tendinosus, and the semi-membranosus.
THE ADDUCTOR MAGNUS, ETC. 277
The adductor magnus of Alhimis (le troisi^me of Boyer ; le grand of Bir.hat, z, z', figs.
124 to 127) is a very large, triangular muscle, extremely thick internally, where it con-
stitutes almost the entire substance of the inside of the thigh {fig. 127). It arises from
the whole extent of the ascending ramus of the ischium, from a small part of the de-
scending ramus of the pubes, and from the apex, i. c, the lowest portion, of the tuberos-
ity of the ischium. It is inserted into the whole extent of the interval between the two
lips of the linea aspera, and into a very prominent tubercle upon the inner condyle of the
femur, above the depression for the insertion of the tendon of the inner head of the gas-
trocnemius. Its origins, especially those from the ischium, which are the principal, can
only be seen on the posterior surface of the muscle (see fig. 125). They consist of ten-
dinous bundles, giving origin immediately to fleshy fibres, which form an extremely thick
mass, directed downward and outward, and presenting coarse bundles, almost as large
and as easily separable as those of the glutasus maximus. The muscle soon divides
into two portions, or, rather, into two distinct muscles, an internal and an external.
The internal portion {z,figs. 125, 127) forms the inner border of the adductor magnus,
the original course of which it follows. About the lower third of the thigh, its fibres
are received into a tendinous semi-cone, open on the outside, and terminating in a shi-
ning tendon, which is inserted into a well-marked tubercle on the upper and back part of
the internal condyle of the femur. Throughout its whole course, this tendon lies close
to the aponeurosis of the vastus internus.
The external portion (z',^^. 125), abandoning the primitive direction of the muscle, is
directed outward, and separates into thick bundles, which are inserted into the whole
extent of the interval between the lips of the linea aspera by means of a very large
aponeurosis, which is intimately united to the tendons of the other adductors, and forms
a series of arches (see fig. 125) for the passage of the perforating arteries.
These two divisions of the adductor magnus are separated below by the femoral ar-
tery and veins and their sheath, and are generally distinct for a considerable extent, and
sometimes entirely so. I have met with a case of this kind. That portion of the mus-
cle which was inserted into the internal condyle arose entirely from the apex of the tu-
berosity of the ischium ; while the origin of that portion which was attached to the linea
aspera took place from a prominence situated on the external side of that tuberosity,
and projecting outward from it, and also from the ascending ramus of the ischium, and
the descending ramus of the pubes, externally to the gracilis muscle. The superior
fibres {fig. 125) are horizontal, and, forming a distinct, and, as it were, a radiated bundle,
turn in front of the succeeding fibres, and are inserted into the line leading from the
great trochanter to the linea aspera, internally to the glutaeus maximus.
Relations. — The adductor magnus is covered by the superficial adductors and by the
small deep adductor : it covers the semi-tendinosus, the biceps, the semi-membranosus,
and the glutaeus maximus. Its inner border is bounded by the gracilis above, and by the
sartorius below: its upper border is in contact with the obturator externus ie,fig. 127)
on the inside, and with the quadratus femoris (i, fig. 125) more externally. Its most
important relation is that with the femoral artery and vein, which pass through it before
reaching the popliteal space. At the place where this periforation occurs we observe a
tendinous arch, or, rather, canal, into which the fleshy fibres are inserted ; and so, also,
where the perforating arteries pass through this muscle.
Action of the Adductor Muscles. — ^The muscles we have just described are both flexors
and rotators outward ; but their principal office, as their name indicates, is to perform
adduction, a very energetic movement, as might be anticipated from the strength of the
muscles concerned in its production. We have seen, indeed, that the line of origin ex-
tends from the ilio-pectineal eminence as far as and including the tuberosity of the ischi-
um, and that the insertions occupy the entire length of the linea aspera, the two branch-
es of its superior bifurcation, and the inner condyle of the femur. These muscles are
powerfully exerted during equestrian exercise ; it is by their means that the horse is
firmly grasped between the knees. The two superficial adductors and the adductor bre-
vis are also flexors, because their insertions are posterior to their origins. All the ad-
ductors are, as it were, rolled around the femur during rotation inward.
MUSCLES OF THE LEG.
The Tibialis Anticus. — Extensor Communis Digitorum. — Extensor Proprius Pollicis. — Pe-
roneus Longus and Brevis. — Gastrocnemius, Plantarus, and Soleus. — Popliteus. — Titia-
lis Posticus. — Flexor Longus Pollicis.
The muscles of the leg may be divided into those of the anterior, those of the exter-
nal, and those of the posterior regions.
Muscles of the Anterior Region of the Leg.
The muscles of the anterior region of the leg are the tibialis, the extensor communis
digitorum. and the extensor proprius pollicis pedis. The anterior peroneus, or peroneus
ms
MYOLOGY.
tertius, wlien it exists, is nothing more than an accessory fasciculus of the extensor
communis.
The Tibialis Anticus.
Dissection. — ^Make a vertical incision through the skin from the anterior tuberosity of
Fig.l^
the tibia to the middle of the inner border of the foot ; dissect
back the two flaps of skin, and expose the fascia of the leg ; di-
vide this fascia vertically, commencing from the middle of the
leg, and terminating at the lower end of the tibia, taking care to
preserve the annular ligament ; prolong the dissection and sep-
aration of the fascia as far upward as possible ; lastly, remove
the fascia on the dorsum of the foot, which covers inferiorly the
tendon of the tibialis anticus.
The tibialis anticus {a, fig. 128) is a long, thick, prismatic, and
triangular muscle, placed superficially along the outer side of the
tibia.
Attachments. — It arises from the crest which bounds the ante-
rior tuberosity of the tibia on the outside, and from the tubercle
terminating this crest above ; from the external tuberosity of the
tibia, and the superior two thirds of its external surface, which
presents a depression proportioned to the strength of the muscle ;
from all that portion of the interosseous ligament situated to the
inner side of the anterior tibial vessels and nerves ; from the
deep surface of the fascia of the leg ; and, lastly, from a tendi-
nous septum intervening between this muscle and the extensor
communis digitorum. It is inserted into the tubercle on the first
or internal cuneiform bone, and sends oflT a tendinous expansion
to the first metatarsal bone.
It arises from the internal surface of an osteo-fibrous quadran-
gular pyramid formed by the tibia, the fascia of the leg, the inter-
osseous ligament, and the inter-muscular septum ; from these
points the fleshy fibres proceed vertically downward, and termi-
nate around a tendon which commences in the substance of the
muscle above its middle third ; the anterior fibres cease at the
lower third of the muscle, the posterior accompany the tendon
to the point where it passes under the dorsal ligament of tlie in-
step (seen in fig. 128). As soon as the tendon appears on the
anterior border of the muscle, it is deflected forward in a similar
manner to the external surface of the tibia, and follows the same
oblique course, after having left the common sheath of all the
muscles of the anterior region of the leg. Another sheath, which
is nothing more than the condensed dorsal fascia of the foot, re-
ceives the tendon at the point where it passes vertically downward, to be inserted into
the tubercle of the first cuneiform bone.
Relations. — The tibialis anticus is covered by the fascia of the leg asad the dorsal fascia
of the foot ; on the inside it is in relation with the external surface of the tibia ; on the
outside, at first with the extensor communis digitorum, and then with the extensor pro-
prius pollicis, from which it is separated behind by the anterior tibial vessels and nerves.
Action. — It flexes the foot upon the leg ; and, from tlie obliquity of its tendon, it raises
the internal border of the foot, and, consequently, produces that sort of rotation inward
at the articulation of the two rows of the tarsus which we have already alluded to. It
tends, also, to adduct the ankle-joint, and is, consequently, opposed to dislocation out-
ward. The absence of a proper sheath for this muscle explains the considerable pro-
jection formed by its tendon during contraction, which may serve as a guide to the pre-
liminary incisions in ligature of the dorsal artery of the foot. Spigelius called this mus-
cle the musculus catencE, because fetters applied around the ankles of criminals press
chiefly upon the projection formed by its tendon.
The Extensor Longus Digitorum Pedis, and the Peroneus Tertius vel Anticus.
Dissection. — Remove the fascia of the leg and the dorsal fascia of the foot.
This is an elongated, semi-penniforra, and reflected muscle {b c, fig. 128), flattened
from within outward, single above, and divided into four or five tendons below.
Attachments. — It arises from the external tuberosity of the tibia, on the outer side of
the tibialis anticus ; from the whole of the internal surface of the fibula in front of the
interosseous ligament, and slightly from that ligament ; from the upper part of the fascia
of the leg, and from the tendinous septa interposed between this muscle and the tibialis
anticus within, and the peroneus longus and brevis without. It is inserted into the sec-
ond and third phalanges of the last four toes.
From these numerous origins the fleshy fibres proceed in different directions ; the su-
THE EXTENSOR PEOPRIUS POLLICIS. "^9
perior vertically downward, the rest obliquely downward and forward, the lowest being
the most oblique ; they all terminate around a tendon, which appears upon the anterior
border of the muscle below the upper third of the leg. This tendon soon divides into
two portions : one internal, and itself subdivided into three tendons for the second, third,
and fourth toes ; the other external, and generally split into two tendons, one of which
is intended for the fifth toe, while the other is fixed to the posterior extremity of the cor-
responding metatarsal bone. This last subdivision is often wanting : it is but imperfect-
ly separated from the fasciculus belonging to the fifth toe, to which it almost edways
sends off an accessory tendon : it has been generally described as a separate muscle,
under the name of the peroneus tertius or anticus {c,Jig. 128). I have thought it right,
however, to connect this muscle with the extensor longus digitorum (i), from which it
can be so imperfectly separated that it has been designated by Cowper, pars extensoris
digitorum pedis longi ; and by Morgagni, quintus tendo extensoris longi digitormn pedis.
The extensor communis is directed vertically as far as the ankle-joint, where it enters
a sheath conmion to it and the flexor proprius poUicis, is next reflected under this sheath,
becomes horizontal, passes obliquely inward and opposite the tarsus, is received into a
much stronger proper sheath, after leaving which the five tendons separate so as to cov-
er the dorsd surface of the metatarsal bone of the toes, to which they correspond. In
this course they cross the extensor brevis digitorum at a very acute angle, reach the
dorsal surface of the metatarsal phalangal articulations, apply themselves to the inner
edges of the corresponding tendons of the extensor brevis, receive some expansions from
the interossei and lumbricales, and are arranged in precisely the same manner as the ex-
tensor tendons of the fingers, forming a fibrous sheath on the dorsal surface of the first
phalanx of the toes ; and like these, having arrived at the articulations of the first with
the second phalanges, each divides into three portions : one median, attached to the pos-
terior extremity of the second phalanx ; and two lateral, which unite upon the dorsal sur-
face of the second phalanx, to be inserted into the posterior extremity of the third.
Relations. — Internally this muscle is in relation with the tibialis anticus, from which
it is soon separated by the extensor proprius pollicis, and externally with the peroneus
longus and brevis. It is covered by the fascia of the leg and foot, and it covers the fibula,
the interosseous ligament, the ankle-joint, the extensor brevis digitorum, which separ-
ates it from the tarsus and metatarsus ; lastly, it covers the toes.
Action. — As in all reflected muscles, we must suppose the power to be exerted imrne-
diately after its reflection, and in the direction of the reflected portion : in this way, it will
be seen that it extends the third phalanges upon the second, and the second upon the
first ; and having produced this effect, it flexes the foot upon the leg. From its obliqui-
ty, it also draws the toes outward, and turns the sole of the foot inward.
The Extensor Proprius Pollicis.
The extensor proprius pollicis {d,fig. 128) is an elongated, thin, flat muscle, placed in
front of the leg, betwisen the extensor longus digitorum and the tibialis anticus.
Attachments. — It arises from the interned surface of the fibula, and slightly from the
adjacent part of the interosseous ligament, within and behind the extensor communis
This origin is situated at variable heights, but commonly not above the middle third
of the leg. It is inserted into the posterior extremity of the second phalanx of the great
toe. The fleshy fibres arise directly from the fibula and the interosseous ligeiment, and
proceed at first vertically around, and then obliquely behind a tendon, which occupies the
anterior border of the muscle, and to which the fleshy fibres are all attached in a sloping
manner, like the barbs of a feather, as far down as below the proper sheath formed for
it at the tarsus. From thence the tendon is reflected at a right angle, proceeds oblique-
ly and horizontally forward and inward upon the dorsum of the foot, passes along the
dorsal surface of the first metatarsal bone and first phalanx of the great toe, to the latter
of which it gives off a prolongation on each side, and is then inserted into the second
phalanx.
Relations. — Internally, it is in relation with the tibialis anticus, from which it is sep
arated behind by the anterior tibial nerve and vessels ; and externally, with the extensor
longus digitorum. Its anterior border, at first concealed between the preceding muscles,
is soon situated immediately beneath the fascia, and during its contraction forms a pro-
jection, which it is important to know, because it serves as a guide in searching for the
dorsal artery of the foot, which will always be found on the outer margin of the tendon :
it may be called the muscle of the arteria dorsalis pedis. In the foot it crosses superfi-
cially to the extensor brevis digitorum.
Action. — It extends the second phalanx of the great toe upon the first, and that upon
the metatarsus ; when this is accomplished, it flexes the foot upon the leg. In conse-
quence of its obliquity, it tends, like the preceding muscle, to turn the toes outward, and
slightly to elevate the inner border of the foot.
External Region of the Leg.
In this region are found the peroneus longus and peroneus brevis muscles.
9^ MYOLOGY.
The Peroneus Longus. «k-«.'i
Dissection. — This is common to both muscles. Remove the skin on the outer side of
the leg ; make a vertical incision through the fascia ; reflect the two flaps, in order to ar-
rive at the tendinous septa dividing the peronei from the muscles of both the anterior
and posterior regions of the leg. To expose these muscles in the foot, remove the outer
portion of its dorsal fascia, and divide obliquely inward and forward all the muscles of
the pkntar region, from the groove of the cuboid to the posterior extremity of the first
metatarsal bone.
The peroneus longus {e,figs. 128 to 130) is a long, thick muscle, prismatic and trian-
gular at its upper part, and superficially situated on the outer side of the leg (peroneus
primus, Spigelius).
Attachments. — It arises externally from the outer and anterior part of the head of the
fibula ; from a small portion of the contiguous part of the external tuberosity of the tibia ;
from the upper third of the external surface of the fibula ; and from the anterior and pos-
terior borders of that bone, by means of very strong tendinous septa, interposed between
it and the anterior and posterior muscles of the leg ; lastly, from the fascia of the leg
superiorly. It is imerted into the posterior extremity of the first metatarsal bone, on the
outer side of which a process exists for this purpose.
From these very numerous origins, the fleshy fibres proceed vertically and form a bun-
dle {e,fig. 130), thick above, thin and flat below, and terminating in a tendon which is at
first concealed in the substance of the muscle, but appears in the form of a band on its
outer side, a little above the middle of the fibula, and becomes narrower and thicker as it
proceeds. Tlie tendon soon leaves the fleshy fibres, and accompanies the external sur-
face of the fibula as it turns backward (peroneus posticus, Riol), then passes behind the
external malleolus in a groove common to it and to the peroneus brevis, and is reflected
forward and downward to the outer side of the os calcis, upon which it is held by a sep-
arate sheath. Having reached the outer side of the cuboid bone, it is again reflected,
enters a groove running obliquely inward and forward upon the lower surface of that
bone {e,figs. 132, 133), where it is retained by a very strong and compact sheath, and
continues its oblique course, without any deviation, along the lower surface of the tarsal
bones ; as far as the posterior extremity of the first metatarsal bone. In this way the
tendon of the peroneus longus undergoes a double reflection : first, behind the external
malleolus, in which situation a thickening or knot is often seen ; and, secondly, at the
cuboid bone, opposite which a sesamoid bone almost always exists. There are also
three? fibrous sheaths, and three synovial membranes belonging to this tendon, one be-
hind the external malleolus, one upon the outside of the os calcis, and a third under the
cuboid bone.
Relatioiis. — In the leg, the peroneus longus is covered by the skin and the fascia of the
leg : it covers the peroneus brevis. In front, a tendinous septum intervenes between it
and the extensor longus digitorum : behind, another inter-muscular septum exists between
it and the soleus above, and the flexor proprius below. On the outside of the foot, its
tendon corresponds to the skin externally, and to the os calcis internally. In the plantar
region, it is covered below by the entire thickness of the soft parts, and corresponds
above to the inferior tarsal ligaments.
Action. — As we have already so frequently observed, a reflected muscle acts as if the
power were applied at the point of reflection. In this way, by transferring the power to
the outer end of the groove on the cuboid bone, we shall find that the foot is abducted,
or, rather, rotated outward by this muscle ; by next supposing the power to act from the
other point of reflection, i. e., from behind the external malleolus, we may observe that
the foot is extended upon the leg, and its outer border turned upward. In this move-
ment, the lower end of the external articular surface of the astragalus tends to carry the
external malleolus outward, and to increase the curvature of the fibula, which is some-
times fractured in consequence. It may be easily conceived that if the fibula be frac-
tured, the contraction of this muscle will no longer be counteracted, and accordingly
will turn the sole of the foot outward, and may luxate the astragalus inward. This is
the mechanism of luxation of the foot occurring after fracture of the fibula, the only
species of lateral dislocation of this part which has ever been observed.*
The Peroneus Brevis.
The peroneus brevis o{ Albinus (peroneus secundus, Spigel ; le petit peronier, Wins-
tmB,f,figs. 129, 130) is a flat, penniform, and reflected muscle, smaller and shorter than
the preceding, beneath which it lies.
Attachments. — It arises from the lower half, sometimes from the lower two thirds of
the external surface of the fibula, which is more or less excavated for this purpose ; from
the anterior and posterior borders of the same bone, and from the tendinous septa exist-
ing between this muscle and those of the anterior and posterior regions of the leg.
It is inserted into the posterior extremity of the fifth metatarsal bone, and sometimes
* See the admirable memoir by M. Dupuytren, on fracture of the fibula.
THE GASTROCNEMIUS.
2B1
CYcn, by a tendinous expansion, into the fourth metatarsal bone ; it often gives off a pro-
longation to the extensor tendon of the httle toe.
The fleshy fibres proceed successively from their different origins to the internal sur-
face and edges of a tendon, situated upon the outer surface of the muscle ; the bundle
which they form gradually increases in size, and then diminishes, is at first penniform,
and afterward semi-penniform, and accompanies the tendon as far as the fibrous sheath
behind the external malleolus : after leaving the sheath, the tendon enters another, prop-
er to itself, upon the outer side of the os calcis, above that for the tendon of the peroneus
longus, and passes somewhat obliquely downward and forward, to be inserted into the
base of the fifth metatarsal bone.
Relations. — It is covered by the peroneus longus, and covers the fibula and the outer
side of the os calcis. It is, therefore, only in comparison with the peroneus longus that
Riolanus and others have called this muscle the anterior peroneus.
Action. — The same as that of the peroneus longus, with the exception of that of its
subtarsal portion. Thus, supposing the power to be applied at the external malleolus,
we have extension of the fifth metatarsal bone upon the cuboid ; extension and rotation
inward of the second row of the tarsus upon the first ; rotation of the calcaneum upon
the astragalus ; extension, and a tendency to abduction of the entire foot, which is
therefore considerably everted when the fibula is fractured.
PosTEKioK Region.
There are two layers in this region : one superficial, formed by the gastrocnemius and
soleus (or triceps suralis) and the plantaris ; the other deep, consisting of the popliteus,
the tibialis posticus, the flexor longus digitorum, and the flexor longus pollicis.
The Gastrocnemius and Soleus, or Triceps Suralis, and the Plantaris.
Dissection. — Make a vertical incision from the upper part of the popliteal space to the
heel ; at right angles to this, above, make another horizontal and semicircular incision,
embracing the back part of the thigh ; divide and dissect the fascia of the leg. The gas-
trocnemii will then be exposed, and must be dissected very carefully at their origins. In
order to study the structure and attachments of these muscles properly, they must be
cut transversely in the middle, and the superior half turned upward. In dividing the
outer head of the gastrocnemius, be careful not to cut the plantaris, which seems to be
merely a small fasciculus detached from that muscle. The soleus is exposed by simply
removing the gastrocnemius ; but, in order to study its structure and attachments, it
must be divided vertically from behind forward at the side of a
median tendinous raph^, and the fibres which conceal this median
aponeurotic lamina of the muscle must be scraped away. From
this division we have a fibular and a tibial portion of the soleus.
The gastrocnemius (g g) and the soleus (i i',Jig. 129) together
constitute a very powerful triceps muscle (musculus surae. Seem.),
which, by itself, forms the fleshy part of the leg, commonly called
the calf The great development of these muscles is one of the most
marked characteristics of the muscular apparatus of the human sub-
ject, and is connected with his destination for the erect position.
The three portions of the triceps suralis are united together below
in a common tendinous insertion, constituting the tendo Achillis {t,
Jig. 129), but are divided above into two very distinct planes : one,
anterior or deep, formed by the soleus ; the other, posterior or su-
perficial, consisting of the two heads of the gastrocnemius. We
shall describe these in succession.
Gastrocnemius.
The gastrocnemius, from yaarrip, a belly, and Kv^firj, the leg (ge-
mellus, Albinus ; primus pedem moventium, cum secundo, Vcsalt-
us), is the most superficial muscle on the back of the leg : it con-
sists of two heads above {g g',fig. 129), but forms a single fleshy
belly, which is thick and flattened from before backward.
It arises from the condyle of the femur by two perfectly distinct
but similar heads, viz., an outer or smaller, called the gemellus ex-
ternus {g), and an inner or larger, named the gemellus internus (g-')-
They take their origin from the bone, by two very strong and flat
tendons, which are attached on the outer side, and behind the con-
dyle of the femur, to two well-marked digital impressions, that for
the outer head being situated above a much deeper impression foi
the popliteus muscle, and that for the inner head inmiediately be
hind the tubercle into which the adductor magnus is inserted, so
that the inner head is situated upon a plane a little posterior to that
of the outer head. They also arise, by tendinous fasciculi, from
Nn
Fig. 139.
S82 MYOLOGY.
the rough triangular surfaces surrounding the digital impression, and terminating at the
inferior bifurcation of the linea aspera. Each tendon of origin (that for the inner being
much larger than that for the outer head) expands into an aponeurosis upon the posteri-
or surface of that portion of the muscle to which it belongs. The aponeurotic expansion
of the inner head is, moreover, thicker and longer than the other, and embraces the inner
border of that part of the muscle, like a tendinous semi-cone. The fleshy fibres arise
from the anterior surface of these tendinous expansions, and are disposed in the follow-
ing manner : those in the middle, which are few in number, are strengthened by fleshy
fibres proceeding from the rough projections of the bifurcation of the linea aspera, pass
inward and downward, and are united together like the limbs of the letter V opening up-
ward, upon a median raphe, which consists either of a simple thickening of the termina-
ting aponeurosis, or of a small tendinous septum : the other fibres, constituting almost
the entire muscle, arise from the anterior surface of the tendons of origin, and from the
aponeurosis in which they terminate, and proceed vertically downward to the back of an-
other very dense aponeurotic expansion, which covers the whole anterior surface of the
muscle. This last aponeurosis commences above by two very distinct portions ; at first
it is of equal breadth with the muscle, then becomes narrower and thickened, and, finally,
closely united with the terminal tendon of the soleus. At the lower part of the calf the
fleshy fibres terminate suddenly upon the posterior surface of this aponeurosis, forming
a V opening downward. Although the two portions of the gastrocnemius become inti-
mately united shortly after their origin, they are not confounded together, and the inter-
nal portion forms on the inside of the tibia the greatest part of the fleshy mass called the
calf of the leg.
Relations. — The gastrocnemius is covered by the fascia of the leg, and it covers and
adheres intimately to the capsular ligament, which envelops the back part of the con-
dyles of the femur. It is also in relation with the popliteus and the soleus.
The tendon of the inner head corresponds to the posterior surface of the internal con-
dyle ; that of the outer head to the outer side of the external condyle. We often find
at the upper part of the tendon of each head, but most commonly in the substance of
that of the outer head, a sesamoid bone, that glides upon the back of the condyle, and
belongs to the sort of fibrous capsule or hood by which the back of each condyle is cov-
ered. (Vide Syndesmology, Articulation of the Knee.)
The Plantaris.
This little muscle (le plantaire grele, 1 1', Jig. 129) should be regarded as an accessory
of the outer head of the gastrocnemius, or, rather, as a rudimentary muscle in the hu-
man subject. Its small fusiform, fleshy belly, varying much in size, is found beneath the
outer head of the gastrocnemius.
It arises {I) from the fibrous capsule covering the external condyle, and sometimes from
the lower part of the external bifurcation of the linea aspera. From these points, it pass-
es obUquely downward and inward, and after a course of from two inches and a half to
three inches, ends in a long, flat, and slender tendon, which is at first situated between
the gastrocnemius and soleus, and afterward (/') lies parallel with the inner edge of the
tendo Achillis, and is inserted into the os calcis, either at the side, or in front of that ten-
don. Sometimes, however, it is lost in the sub-cutaneous adipose tissue. This muscle,
which is often wanting, is occasionally double.*
The Soleus.
The soleus (partly seen at i i',fig. 129) is so called because it has been compared to
the fish called a sole, or to the sole of a shoe.
Attachments. — It arises from the fibula and tibia, and is inserted into the os calcis. Its
fibular origins (i) consist, first, of a tendon attached behind, and on the inner side of the
head of that bone ; this tendon is extremely strong, especially on the inside, opposite a
process existing on the fibula for its attachment ; it is prolonged within the substance,
Snd along the anterior surface of the muscle : and, secondly, of some tendinous fibres
attached to the upper half of the external border of the fibula, and the upper third of the
posterior surface of the same bone.
The tibial origins {i') take place from the oblique line on the posterior surface of the
tibia below the popliteus, and from the contiguous portion of the aponeurotic expansion
of that muscle ; from an aponeurosis which arises from the middle third of the inner
border of the tibia, and is prolonged upon the anterior surface, within the substance of
the muscle ; and, lastly, by a few fleshy fibres from a tendinous arch extending between
the head of the fibula and the oblique line on the posterior surface of the tibia. From
these diflferent origins, the fleshy fibres pass in different directions to the anterior sur-
face and edge of an aponeurosis, which covers the posterior surface of the muscle, be-
comes narrower and thickened as it proceeds downward, unites with the terminal ten-
don of the gastrocnemius about the middle third of the leg, and is soon blended with it
to form the tendo Achiljis.
* Fourcroy, in his sixth memoir upon the liursce mucosa;, states that the plantaris, whose tendon, according
to Albinus, is received into a groove along^ the inner border of the tendo Achillis, is the tensor muscle of the
synovial capsule of that tendon. This is an error.
THE POPHTEUS.
In order to study accurately the structure of the soleus, divide it longitudinally at the
aide of tlie raphes or tendinous septum existing in the middle of the lower half of this
muscle, and then, by scraping off some of the fleshy fibres, it will be seen that a dense,
fibrous septum given off by the terminal aponeurosis, separates the muscle into two equal
halves, and forms with that aponeurosis two tendinous semi-cones, in the interior of
which the fleshy fibres are received. It will now be understood why Douglas, who had
designated the gastrocnemius the two external and superficial heads of the great extensor
of the tarsus, should call the soleus the two internal and deep heads of the same muscle
There are, in fact, two principal aponeuroses of origin, and two hollow tendons of insei-
tion ; each aponeurosis of origin covers almost the entire anterior surface of tlie corre-
sponding half of the muscle.
Relations. — It is covered by the gastrocnemius, which projects beyond it on both sides,
but especially on the inner side, and from which it is separated by the plantaris. It is
thickest immediately below the largest part or belly of the inner portion of the gastroc-
nemius, and, consequently, it prolongs the swelling of the calf downward. It covers the
muscles of the deep layer, viz., the flexor communis digitorum, the flexor proprius polli-
cis, and the tibialis posticus ; it also covers the posterior tibial and the fibular vessels
and nerves.
The Tendo Achillis. — ^The tendo Achillis {I, figs. 129, 130) results from the union of the
tendons of the gastrocnemius, plantaris, and soleus. It is formed in the following man-
ner : the terminal aponeurosis of the gastrocnemius, shortly after leaving the Ik f<liy
fibres, is intimately united to that of the soleus, which still continues to receive fleshy
fibres upon its anterior surface and its edges, and gradually becoming narrower, is soon
joined by the antero-posterior septum of this muscle. All these tendinous fibres are col-
lected together to form the strongest and largest tendon in the body, known by the name
of the tendo Achillis, which, after a course of about an inch and a half or two inches,
glides over the smooth surface presented by the superior two thirds of the back of the
OS calcis, with the intervention of a synovial bursa, and is expanded a little, in order to
be inserted into the rough surface on the lower part of the same bone.
Action of the Gacirocnemius and Soleus. — These muscles extend the foot upon the leg.
In no other part of the body do we find so advantageous an arrangement for an immense
development of power. 1. These muscles are very large, and particularly remarkable for
the number of their fleshy fibres, in which respect they exceed all other muscles in the
body. 2. The mode of insertion is nowhere else so favourable, for it is absolutely per-
pendicular. 3. We have here a lever of the second order, in which the fulcrum is at the
ball of the toes, the resistance in the middle of the foot, being represented by the weight
of the body resting upon the ankle-joint, and the _power at the extremity of the heel (see
fig. 104). The length of that portion of the lever which projects behind the joint varies
much in different individuals ; it scarcely exists in the peculiar malformation denominated
flat-foot. These muscles are the principal agents in walking and leaping ; they raise
the weight of the whole body, even when loaded with heavy burdens. Hence it is not
surprising, that occasionally an energetic contraction of these muscles may rupture the
tendo Achillis, or fracture the os calcis. Frequent exercise appears to be necessary for
these muscles ; for when they remain inactive, they become atrophied, and are speedily
affected with fatty degeneration. The action of the soleus, which reaches only from the
leg to the heel, is limited to extension of the foot ; but the gastrocnemius, which is at-
tached to the femur, after having extended the foot, can flex the leg upon the thigh ; but,
from its proximity to the fulcrum, this last action is very slight. When the foot is fixed,
as, for example, in standing, the soleus acts upon the leg, and tends to prevent one from
falling forward, to which there is a constant tendency from the weight of the body ; the
action of the gastrocnemius, on the contrary, is to flex the thigh, and in this respect it
is altogether independent of the soleus.
The plantaris can only be regarded as rudimentary in man ; in the lower animals it
is a tensor of the plantar fascia ; it has been, as it were, cut short in man, in conse-
quence of his destination for the erect position. Sometimes, as we have already stated,
it is lost upon the fatty tissue covering the os calcis.
The Popliteus.
This is a small, triangular, and very thin muscle {m,fig. 130), situated in the poplitea?
space.
It arises from a deep fossa, resembling a groove running from behind forward, on the
back of the external condyle of the femur, below the origin of the outer head of the gas-
trocnemius. It is inserted into the entire extent of the triangular surface, on the upper
part of the posterior aspect of the tibia.
It arises by a very strong tendon, which bears no proportion to the diminutive size
of the muscle. This tendon, at first concealed by the external lateral ligament, contain-
ed, as it were, in the cavity of the joint, and completely enveloped by the synovial mem-
brane, passes obliquely behind the articulation, and, after extending for about one inch,
284
MYOLOGY.
divides, like the tendon of the obturator internus, into four or five small diverging bun-
IHg. 130. dl^s, which soon surround the fleshy fibres on all sides. The lat-
ter then become attached in succession to the triangular surface
of the tibia, the lowest being the longest and the most oblique.
The superficial fibres are inserted into a tendinous expansion from
the semi-membranosus, which covers the posterior surface of the
popliteus muscle, and forms a very strong sheath for it.
Relations. — It is covered by the gastrocnemius and the plantaris,
from which it is separated by the popliteal vessels, and the inter-
nal popliteal branch of the sciatic nerve. It covers the tibio-fibu-
lar articulations and the back of the tibia.
Action. — It flexes the leg upon the thigh, and, at the same time,
rotates it inward (oblique movens tibiam, Spigelius). In this last
respect it antagonizes the biceps.
The Tibialis Posticus.
Dissection. — Remove the gastrocnemius and soleus ; separate
the tibialis posticus from the flexor longus digitorum, which par-
tially covers it ; carefully remove from the posterior surface of the
tibialis posticus a very broad aponeurosis, together with a portion
of the long flexor of the toes, which arises from the posterior sur-
face of that aponeurosis ; completely separate the tibialis posticus
from the interosseous ligament, and the adjacent portions of the
tibia and fibula ; lastly, be careful to preserve the tendinous expan-
sions always given oflT by this muscle to the fourth and fifth meta-
tarsal bones.
The tibialis jposticus {n,fig. 130) is the most deeply seated of all
the muscles on the back of the leg ; it is very thick, and occupies
the whole depth of the excavation between the tibia, fibula, and
interosseous ligament.
Attachments. — It arises from the tibia, the fibula, and the interos-
seous ligament, and is inserted into the scaphoid bone. Its tibial
and fibular origins form a bifurcation for the passage of the poste-
rior tibicd artery. Its tibial attachment takes place on the oblique
line situated below the popliteus, soieus, and flexor longus digitorum. Its fibular origin
is from the inner border of that bone, below the soleus, and from all that portion of its
inner surface which is behind the interosseous ligament. It also arises from the entire
posterior surface of this ligament. Lastly, a few fibres take their origin from the deep
surface of an aponeurosis which separates the deep from the superficial layer of muscles,
and from the tendinous septa interposed between this muscle itself and the flexor lon-
gus digitorum on the inside, and the flexor proprius pollicis on the outside. From these
numerous origins the fleshy fibres proceed vertically downward, around a tendon which
may be distinguished near the upper extremity of the muscle, under the form of a ten-
dinous sheaf, which afterward appears along its posterior border, and receives the fleshy
fibres on its anterior surface, like the barbs of a feather upon the shaft. This tendon,
however, is nothing more than the thickened posterior edge of an aponeurosis occupy-
ing the entire substance of the muscle from before backward, and receiving the fleshy
fibres upon its two lateral surfaces as far down as opposite the internal malleolus. The
thick tendon resulting from the union of these aponeurotic fibres then becomes free, and
enters a proper sheath on the outer side of that belonging to the tendon of the flexor longus
digitorum, in front of which it then passes behind the internal malleolus, where it is also
enclosed in a separate sheath {n,fig. 129). On the inner side of the internal lateral lig-
ament of the ankle, and below the lower calcaneo-scaphoid ligament, it enters another
sheath, and is finally inserted {n,fig. 133) into the tubercle of the scaphoid bone, a very
thick sesamoid bone existing near its insertion. In some subjects this sesamoid bone
is found at the point of insertion ; in others it is situated opposite the calcaneo-scaphoid
ligament. Besides this, the tendon of the tibialis posticus gives off a very strong ex-
pansion to the first cuneiform bone, and on the outside an oblique expansion to the sec-
ond and third cuneiform bones, and even to the third or fourth metatarsal bones.
Relations. — It is covered by the flexor longus digitorum, slightly by the flexor proprius
pollicis, and entirely by the soleus : it covers the interosseous ligament and the adjacent
parts of the tibia and fibula.
Action. — The tibialis posticus extends the foot upon the leg. As it is a reflected mus-
cle, all the fibres must be considered as acting from the point of reflection that is be-
hind the inner ankle. It is evident, then, that this muscle extends the foot, both by its
action upon the astragalo-scaphoid articulation, and also by that upon the ankle-joint.
It also tends to turn the sole of the foot inward ; and, consequently, it co-operates with
the tibialis anticus in this respect, and antagonizes the peroneus longus and brevis. It
may also be understood why some persons, in whom the tendo Achillis has been cut oi
THE FLEXOR LONGUS POLLICIS. 2l8^'
ruptured, are yet capable of walking, and why the foot can in all cases be extended after
this accident ; but under these circumstances the lever formed by the foot is changed,
and the power represented by the tibialis posticus is applied between the fulcrum and
the resistance ; so that we have, then, a lever of the third, not of the second order, as
when the tendo Achillis is uninjured.
The Flexor Longus Digitorum Pedis.
This is a penniform, elongated, and reflected muscle {o,figs. 130, 132), situated along
the posterior surface of the tibia and in the sole of the foot ; it is the most internal mus-
cle of the deep layer, is flattened from before backward, and terminates below in four
tendons.
Attachments. — It arises from the tibia, and is inserted into the last phalanges of the last
four toes. It arises from the oblique line of the tibia, below the popliteus and the sole-
us, and from the middle three fifths of the posterior surface of the same bone. Some
fibres also proceed from the tendinous septum intervening between it and the tibialis
posticus. From these different origins the fleshy fibres proceed obliquely backward
and downward, to the anterior surface and edges of a tendon which commences near
the upper end of the muscle, and gradually disengages itself from the fleshy fibres, being
accompanied by them anteriorly as far as the internal malleolus. It passes behind this
projection in the same sheath as the tendon of the tibialis posticus, from which it is sep-
arated by a fibrous septum ; it soon leaves that tendon, passing to its outer or fibular
side (o, fig. 129), and is then reflected at an obtuse angle upon the internal malleolus.
It now becomes horizontal, and is buried under the astragalus and the small anterior
tubercle of the os calcis, where it is contained in a proper sheath. Having thus reached
the sole of the foot (o, figs. 131, 132), it passes obliquely outward and forward, crosses
under the tendon of the flexor longus pollicis at a very acute angle, receives from it a
strong tendinous communication, and at the same time becoming expanded, is joined by
its accessory muscle, and finally divides into four tendons for the last four toes. The
tendon for the second toe proceeds directly forward. The tendons for the other toes in
succession pass more and more obliquely. Having reached the metatarso-phalangal ar-
ticulations, these tendons are received, together with those of the flexor brevis digitorum,
into the sheaths upon the first and second phalanges ; and they have precisely the same
relations to the tendons of the last-mentioned muscle as the flexor profundus is observed
to have with regard to the flexor sublimis digitorum in the hand ; and hence the name
of jperforans given by Spigelius to the long flexor of the toes. The tendons are finally
inserted into the posterior extremities of the third phalanges. The tendinous parts of
this muscle are lubricated by synovial membranes where they pass through the different
sheaths.
Relations. — It is covered by the soleus, the posterior tibial vessels and nerves, and it
covers the tibia and the tibialis posticus. In the foot, it is covered below by the flexor
brevis digitorum and the adductor pollicis.
Action. — It flexes the third phalanges upon the second, the second upon the first, and
the first upon the corresponding metatarsal bones. When these movements have heen
accomplished, it extends the foot upon the leg. From the obliquity of its reflected por-
tion, it would turn the toes and the sole of tue foot slightly inward, if the accessory mus-
cle did not, as it were, rectify its action, as well as co-operate with it. In standing, it op-
poses flexion of the leg forward.
The Flexor Longus Pollicis.
The flexor longus pollicis is the most external and the largest muscle in the deep re-
gion of the leg : it is prismatic and quadrangular, vertical and fleshy in the leg {p, figs.
129, 130), tendinous and horizontal in the foot {p,figs. 131, 132).
Attachments. — It arises from the fibula, and is inserted into the last phalanx of the great
toe. Some of the fibres arise directly from the inferior two thirds, and from the internal
and external borders of the fibula ; others arise from the fascia covering the tibialis pos-
ticus (its origin from the fibula, and that from the fascia of the tibialis muscle, are sep-
arated from each other by the peroneal vessels) ; from a tendinous septum between it
and the peroneus longus and brevis ; and from a small portion of the lower part of the
interosseous ligament. From these numerous points of origin the fleshy fibres pass ob-
fiquely downward and backward, around a tendon which occupies the entire length of
the muscle, and may be seen at the lower part of the leg, through a thin layer of muscu-
lar fibres. These fibres terminate abruptly behind the ankle-joint, at the oblique groove
on the astragalus, in which the tendon is lodged ; it then turns into a groove on the os
cedcis, forming a continuation of the preceding (^fig. 133), and situated below that for the
tendon of the flexor longus digitorum, and dips into the sole of the foot. It is retained
in these two grooves, which run obliquely downward, inward, and forward, by a very
strong and continuous sheath (fig. 132). In the sole of the foot, the tendon is deeply
situated (p, fig. 131), passes forward, and crosses (p, fig. 132) at an acute angle above
the tendon of the flexor longus digitorum, to which it gives off" a considerable fibrous
^relf MYOLOGY.
prolongation. It is then received in a groove formed between the flexor brevis digito-
rum and the oblique adductor of the great toe, passes below the anterior glenoid liga-
ment of the metatarso-phalangal articulation of that toe, between the two sesamoid
bones, and is received into the osteo-fibrous sheath of the first phalanx, to be inserted
into the posterior extremity of the second.
Relations. — It is covered by the soleus, being separated from it by a fascia, which in-
creases in thickness as it passes downward ; it is also covered by the tendo Achillis ; it
covers the fibula, the tibialis posticus, the peroneal artery, and the lower part of the in-
terosseous ligament. Externally, it is in relation with the peroneus longus and brevis ;
internally, with the flexor longus digitorum.
Action. — It flexes the second phalanx of the great toe upon the first, and this upon the
first metatarsal bone ; having produced these movements, it then extends the foot upon
he leg. From the obliquity of its fleshy belly, it has a tendency to turn the great toe
and the foot outward. In this respect it antagonizes the flexor longus digitorum and the
tibialis posticus. The very strong tendinous expansion which unites it to the long flexor,
of the toes consolidates the two muscles ; in fact, it is very uncommon to find either of
them acting independently.
MUSCLES OF THE FOOT.
The Extensor Brevis Digitorum. — Abductor Pollicis Pedis. — Flexor Brevis Pollicis Pedis. —
Adductor Pollicis Pedis. — Transversus Pollicis Pedis. — Abductor Minimi Digiti. — Flexor
Brevis Minimi Digiti. — Flexor Brevis Digitorum. — Flexor Accessorius. — Lumbricales. —
Interossei.
The muscles of the foot are divided into those of the dorsal and plantar aspects and
the interossei. The muscles of the plantar aspect may be again subdivided into three
regions, viz., those of the middle plantar region, those of the internal plantar region, and
those of the external plantar region. A single muscle occupies the dorsum of the foot,
viz., the extensor brevis digitorum. The muscles of the internal plantar region are four
in number, viz., the abductor, the flexor brevis, and the oblique and transverse adduc-
tors of the great toe. The last two muscles may be regarded as forming part of the
middle plantar region.
The muscles of the external plantar region are the abductor and the flexor brevis of
the little toe.
The muscles of the middle region are the flexor brevis digitorum, the flexor accesso-
rms, and the lumbricales.
The interosseous muscles are seven in number, and are divided into the dorsal and
plantar.
Dorsal Region.
The Extensor Brevis Digitorum.
DissectKm. — ^Remove the dorsal fascia of the foot, and the tendons of the muscles of
the anterior region of the leg.
The extensor brevis digitorum (q, fig. 128) is a thin, flat, quadrilateral muscle, situated
on the dorsum of the foot ; it is divided into four portions anteriorly, and is an accessor}'
of the extensor longus digitorum. It arises from the os calcis, and is inserted into the
first four toes.
It arises, by a rounded extremity, from a small excavation on the outside of the foot,
formed by the os calcis and the astragalus {the astragalo-calcanean fossa), and from the os
calcis, in front of that excavation. Its origin from these parts is both fleshy and tendi-
nous. The muscle then passes forward and inward, and soon divides into four fleshy
fascicuh, each representing a little penniform muscle, and terminating quickly in a small
tendon, the size of which is proportioned to the strength of the fasciculus. The inter-
nal tendon is the largest, because it is intended for the great toe ; it is situated below
the tendon of the extensor proprius pollicis, which it crosses at a very acute angle, and
is inserted into the dorsal surface of the proximal end of the last phalanx. The second,
third, and fourth tendons, intended for the second, third, and fourth toes, are subjacent
to the corresponding tendons of the extensor longus digitorum, which they cross at a
very acute angle. Having reached the metatarso-phalangal articulations, the tendons of
the short extensor are situated to the outside of those of the extensor longus, and are
blended with them, so as to complete the fibrous sheath on the dorsal surface of the first-
phalanx, and to terminate in a similar manner.
Relations. — It is covered by the dorsal fascia of the foot, by the tendons of the exten-
sor longus digitorum and extensor proprius pollicis ; it covers the second row of the tar-
sal bones, the metatarsus, and a small portion of the interosseous muscles and the pha-
langes. The arteria dorsalis pedis runs at first along the inner border of this muscle,
which overlaps the artery, where the latter perforates the first interosseous space, in
order to reach the sole of the foot.
THE FLEXOR BREVIS POLLICIS PEDIS.
28T
Action. — It extends the first four toes ; it acts upon the first phalanx only of the great
toe. Its obliquity enables it to correct the contrary oblique movement communicated to
the toes by the contraction of the extensor longus digitorum ; so that the opposite ac-
tions of these two muscles are mutually destroyed, and the foot is extended directly.
Not uncommonly, the extensor brevis presents a fifth fasciculus, which is lost upon
some one of the metatarso-phalangal articulations.
Internal Plantar Region.
The muscles of the ball of the great toe may be divided, like those of the thumb, into
two orders, viz., those which pass from the tarsus to the inner side of the first phalanx,
and those which pass from the tarsus to the outer side of the same phalanx. Here, as
wifli the muscles of the thumb, the tendon of the flexor longus divides the flexor brevis
poUicis pedes of authors into two parts : one internal, forming the flexor brevis of the
great toe, properly so called ; the other external, which is found to be connected with
the oblique adductor of this toe.
Muscles inserted into the Inner Side of the First Phalanx of the Great Toe.
Dissection. — In order to expose the abductor brevis, it is sufficient to remove the in-
ternal plantar fascia ; the flexor brevis will be found under, i. e., deeper than the tendon
of the abductor brevis.
The muscles inserted into the inner side of the first phalanx of the great toe are the
abductor brevis and the flexor brevis. They are distinct at their origins, but are often
blended at their insertions ; so that Winslow united them together under the name of
le thenar du pied.
The Abductor PoUicis Pedis.
This muscle (le court adducteur,* Cruveilhier, r,fig. 131) is
the most superficial in the internal plantar region ; it arises
on the inside, from the internal posterior tuberosity of the os
calcis ; from the internal annular ligament under which the
posterior tibial vessels and nerves pass ; from the upper sur-
face of the internal plantar fascia ; and from the lower sur-
face of a tendinous expansion, which occupies the entire ex-
tent of the deep or superior surface of the muscle. From
these points the fleshy fibres proceed to the circumference of
a tendon (r, figs. 132, 133), which emerges from them infe-
riorly near the first cuneiform bone, but is often accompanied
by them superiorly as far as its insertion into the internal ses-
amoid bone, opposite the first phalanx of the great toe.
Relafio7is. — It is covered below by the internal plantar fas-
cia, and is divided from the muscles of the middle plantar re-
gion by a tendinous septum, which gives attachment to some
of its fleshy fibres. It is superficial to the flexor brevis poUi-
cis, the flexor accessorius, the tendons of the flexor longus
digitorum, and that of the flexor longus poUicis, the tarsal in-
sertions of the tibialis anticus and posticus, the plantar vessels
and nerves, and the internal articulations of the tarsus.
Action. — It is, properly speaking, a flexor of the great toe.
The Flexor Brevis PoUicis Pedis.
Adopting a similar plan in the definition of this muscle as in that of the short flexor
of the thumb, I shaU describe as the short flexor of the great toe that portion {s,fig. 133)
only of the flexor brevis of authors which extends from the second row of the tarsus to
the internal sesamoid bone of the metatarso-phalangal articulation of the great toe, and
sliall refer to the oblique adductor that portion (t) which is attached to the external ses-
imoid bone. This change appears to be warranted by the rule already laid down for the
distinction of muscles. Community of tlje fixed points of origin is not sufficient to es-
tablish the unity of two muscles, provided their movable insertions are distinct. A cel-
lular interval and the tendon of the flexor longus poUicis establish anteriorly the line of
demarcation between the flexor brevis and the adductor obliquus poUicis.
According to this view, the flexor brevis poUicis (s, figs. 131, 132, 133) arises from
the second row of the tarsus, particularly from the cuboid and the third cuneiform bones,
by some tendinous fibres which are formed by a continuation of the inferior ligaments of
the tarsus, and are common to this muscle and the internal portion (t) of the obliqne ad-
ductor of the great toe. The tendon of the tibialis posticus {n,fig. 133), or, rather, the
prolongation which this tendon gives off to the fourth metatarsal bone, also furnishes
Bome points of origin. The fleshy fibres proceeding from these different attachments
form a bundle that gradually increases in size, becomes separated from the oblique ad-
* See note, next page.
MYOLOGY.
ductor, and terminates in a tendon which is inserted into the external sesamoid bone,
and also into the glenoid ligament of the metatarso-phalangal articulation. Not unfre-
quently the greater number of the fleshy fibres are attached to the tendon of the abduc-
tor brevis, and thus constitute the short head of a biceps muscle.
Relations. — The flexor brevis pollicis is in relation below with the internal plantar fas-
cia, and with the tendon of the abductor brevis pollicis, being moulded upon it, and usu-
ally separated from it by a tendinous sheath, except in those cases where the two mus-
cles are blended together. Observe that, at the point where the fleshy belly of the ab-
ductor terminates, the flexor brevis is in relation above with the tendon of the peroneus
longus {e,fig. 133) and the first metatarsal bone. ^
Action. — The same as that of the preceding muscle, but it is much less powerful, ajid
less extensive.
Muscles inserted into the External Side of the First Phalanx of the Great Toe.
These are the oblique and transverse adductors.*
Dissection. — They are exposed by cutting across, and turning forward the flexor brevis
digitorum, the tendons of the flexor longus digitorum, and the flexor accessorius : par-
ticular care should be taken, when the dissection has extended as far as the heads of the
metatarsal bones, to avoid cutting the small transverse adductor.
The jJdductor Pollicis Pedis.
This (I'abducteur oblique, Cruveilhier, tt',fig. 133) is the largest of all the plantar mus-
cles ; it is prismatic and triangular, and occupies the great hollow formed by the last four
metatarsal bones, and is bounded by the first metatarsal bone on the inner side. It ex-
tends from the second row of the tarsus to the external sesamoid bone of the great toe.
It arises by two very distinct portions : the smaller {t,figs. 131, 132, 133), common to it
and to the flexor brevis, proceeds from the cuboid bone ; the other (f ) is mucli larger,
and arises Irom the slieath of the tendon of the peroneus longus (e), from the posterior
extremities of the tiiird, foiu-th, and fifth metatarsal bones, and from the transverse lig-
aments by which they are united. From these different origins the fleshy fibres pass
more or less obli<juely inward, and are inserted by a tendinous bundle into the external
sr-yaiiHiid bone of the metatarso-phalangal articulation of the great toe, and into the pos-
terior edge of the glenoid ligament of the same joint.
Relations. — Its inferior surface is in relation with the long and short flexors of the toes,
with tlie flexor accessorius, the lumbricales, and the plantar fascia ; its superior surface,
with the interosseous muscles and the external plantar artery ; audits inner surface, with
the first metatarsal bone, the tendon of the peroneus longus, and with the flexor brevis
pollicis.
Action. — It is a powerful adductor and flexor of the great toe.
The Transversus Pollicis Pedis.
This small transverse bundle (I'abducteur transverse, Cruveilhier, u, fig. 133) forms an
appendage of the preceding muscle, and is represented in the hand by the transverse
fibres of the adductor pollicis ; it extends from the fifth metatarsal bone to the external
sesamoid bone of the metatarso-phalangal articulation of the great toe.
This muscle, which is of variable size, arises externally from beneath the head of the
fifth metatarsal bone, by a tendinous and fleshy tongue, which is directed transversely
inward, is strengthened by other fibres arising from the anterior transverse ligament of
the metatarsus, and from the interosseous aponeurosis, and is inserted into the outer side
of the first phalanx of the great toe, where it is often blended with the attachment of the
oblique adductor.
Relations. — It is in relation below with the tendons of the long and short flexors of the
toes and with the lumbricalis, and above with the interosseous muscles. It is lodged ia
the anterior part of the deep concavity of the metatarsus, and is provided with a proper
sheath.
Actions. — It adducts the great toe, and draws the head of the metatarsal bones towards
each other.
* [The terms adductor and abductor arc applied by M. Cruveilhier to the muscles of the great toe, from their
respective actions upon it, in reference to the axis of the body ; the muscle attached to the inner side of that toe
being called its adductor, and those to the outer side its abductors. In the translation, however, the nomen-
clature of Albinus has been adopted, in which the terms adductor and abductor have reference to the axis of
the limb : first, because it is followed by the majority of authors ; and, secondly, because it is in accordance
with the principle observed by M. Cruveilhier himself, in describing not only all the muscles of the hand, but
some even of those of the foot, viz., the interossei, which are classed by him as abductors or adductors, accord
iug as they draw the several toes from or towards an imaginary axis passing through the second toe. By this
change much risk of perplexity will be avoided, and a uniform principle of nomenclature preserved as regards
all the muscles of the hand and foot.
In the description of each muscle of the great toe, the synonymes of Cruveilhier are given between brack
ets ; but in all instances, both here and hereafter, where these muscles have incidentally to be mentioned, the
names adopted from Albinus will be strictly adhered to.
It is vcarccly necessary to observe that the abductor of the little toe will still retain its name, j
THE ABDUCTOR DIGITI MINIMI, ETC.
m
External Plantar Region.
The Abductor Digiti Minimi.
Dissection. — This is common to the abductor and the flexor brevis. The first is ex-
posed by simply removing the external plantar fascia, and the second by removing or re-
flecting down the first.
The abductor digiti minimi (,v,fig. 131) is of the same form, the saune structure, and al-
most the same size as the abductor pollicis, and extends from the os calcis to the first
phalanx of the little toe. It arises by tendinous and fleshy fibres from the external pos-
terior tuberosity of the os calcis, from the outer side of the internal posterior tuberosity,
and from an aponeurosis occupying the upper surface of the muscle. The fleshy fibres
having arisen in succession from these different points, proceed obliquely round a tendon,
from which they emerge, opposite the posterior extremity of the fifth metatarsal bone.
The fleshy belly of the muscle appears to end at this point, but it is continued by other
fibres, arising from the upper surface of the externd plantar fascia, and inserted either
into the common tendon, or separately, by the side of this tendon, into the outer part of
the first phalanx of the little toe. A small fleshy bundle is frequently detached from the
body of the muscle, and implanted into the posterior extremity of the fifth metatarsal
bone, together with a prolongation of the external plantar fascia, which serves as a ten-
don for it.
Action. — It is an abductor and flexor of the little toe.
The Flexor Brevis Digiti Minimi. ^s- 133.
This is a small fleshy fasciculus {x,figs. 131, 132, 133), situ-
ated along the external border of the fifth metatarsal bone, and
forming a continuation of the series of interosseous muscles,
with which it was for a long time confounded (interosseus,
Spigelius) : it extends from the second row of the tarsus, and
from the fifth metatarsal bone, to the first phalanx of the little
toe. It arises from the ligamentous layer covering the plantai
surface of the metatarsal row of the tarsal bones, and from the
posterior extremity of the fifth metatarsal bone ; it is inserted
into the outer side of the first phalanx of the little toe, or, more
correctly, into the posterior edge of the glenoid ligament of the
metatarso-phalangal articulation of that toe. Some of the
fleshy fibres will be found attached to the entire length of the
externjd border of the fifth metatarsal bone ; and these some-
times form a small and very distinct muscle, representing the
opponens digiti minimi of the hand.
Relations. — It is covered below by the plantar fascia, which
is here very thin, and also by the tendon of the abductor digiti
minimi ; it is in relation above with the fifth metatarsal bone
and the first plantar interosseous muscle.
Action. — The same as that of the preceding muscle with re-
gard to flexion, but its action is less powerful and less exten-
sive.
Middle Plantar Region.
The Flexor Brevis Digitorum.
Dissection. — Remove the plantar fascia, which is intimately united to this muscle pos-
teriorly.
The flexor brevis digitorum {y,fig. 131) is a short, thick muscle, narrow behind, and'
divided into four tendons in front. It arises from the inside of the external tuberosity
of the OS calcis, from the upper surface of the middle plantar fascia, from a special ten-
dinous expansion occupying the lower surface of the muscle, and appearing to be a de-
pendance of the plantar fascia ; and, lastly, from an aponeurotic septum, situated between
Ti. and the muscles of the external plantar region. It forms a fleshy belly, which is nar-
row and thick behind, passes directly forward, increases in breadth, and soon divides
into four, sometimes only into three fasciculi, constituting as many small and perfectly
distinct penniform muscles, the long and delicate tendons of which emerge from the
fleshy fibres before reaching the metatarso-phalangal articulations, become flattened, and
are then situated below and in the same sheath with the tendons of the flexor longus.
Opposite the first phalanx each tendon of the short flexor bifurcates, to allow the passage
of the corresponding tendon of the flexor longus, is formed into a groove, becomes re-
united above the latter tendon, and once more bifurcates, in order to be inserted along
the borders of the second phalanx (hence it was named perforatus by Spigelius, and le
perfore du pied by Winslow). The short flexor of the toes is, therefore, analogous to the
superficial flexor of the fingers.
Relations. — It is covered below by the plantar fascia and the skin ; it is in relation
Oo
;20O MYOLOGY.
above with the plantar vessels and nprves, with the tendon of the flexor longus digitorum,
and with the flexor accessorius and the lumbricales, from which it is separated by a tendi-
nous lamina. On its outer and inner side it is completely isolated from all the adjacent
muscles by prolongations of the plantar fascia.
Action. — It flexes the second phalanges of the last four toes upon the first phalanges,
and these upon the corresponding metatarsal bones.
The Flexor Accessorius.
This is a flat, quadrilateral muscle, forming a considerable fleshy mass (massa carnea,
Jacobi Sylvii, z,fig. 132) ; it arises, by a bifurcated extremity, from the lower part of the
groove of the os calcis, and a small part of the calcaneo-scaphoid ligament by fleshy
fibres, and by means of a tendon from the lower surface of the same bone, this tendon
sometimes extending as far as the external posterior tuberosity of the os calcis. From
these points the fleshy fibres pass directly forward, and terminate in the following man-
ner : the lower fibres become inserted into the outer margin, and a small portion of the
inferior surface of the tendon of the flexor longus digitorum ; while the upper are inserted
into several small fibrous bundles, which unite together, receive a considerable expan-
sion from the tendon of the flexor longus poUicis, and are ultimately blended with, and
increase the size of the divided tendon of the flexor longus digitorum.
Relations. — This muscle is in relation below with the flexor longus digitorum and the
plantar vessels and nerves, and abme with the os calcis and the inferior calcaneo-cuboid
ligaments.
Action. — It is a muscle of re-enforcement, and assists in flexing the toes ; from its obli-
quity, it rectifies the oblique action of the flexor longus digitorum in the opposite direction.
The Lumbricales.
The lumbricales Q, I, figs. 131, 132), which form a second class of accessory muscles
belonging to the flexor longus digitorum, exactly resemble the lumbricales of the fingers ;
they consist of four small fleshy tongues, decreasing in size from within outward, the two
outer of which are not unfrequently atrophied ; they extend from the angles formed by
the division of the tendons of the flexor longus to the inner or tibial borders of the first
phalanges of the last four toes, and to the corresponding margins of the extensor tendons.
They are distinguished by the numerical names of first, second, third, and fourth. The
first is situated parallel with the flexor tendon of the second toe.
Relations. — They are covered below by the flexor brevis digitorum ; they emerge from
beneath the plantar fascia, in the interval between the sheaths furnished by it to the
flexor tendons, gain the inner side of the corresponding metatarso-phalangal articulation,
and terminate upon the first phalanx and inner margin of the tendons of the extensor
longus digitorum. They have the same action as the lumbricales of the hand.
Interosseous Region.
The Interossei.
The interosseous muscles of the foot correspond exactly with those of the hand, and
require the same consideration.
They arise from the lateral surfaces of the interosseous spaces in which they are
placed ; and are inserted into the sides of the first phalanges and the corresponding mar-
j^. 133. gins of the tendons of the extensor muscles. They are seven in
number, viz., four dorsal (three of which are seen at d d d, fig.
133), and three plantar {p j) p); to the latter, however, the ob-
lique adductor of the great toe may be added, for it is nothing
more than a very large plantar interosseous muscle.
As in the hand, the dorsal interossei are abductors, their origins
being situated externally to the axis of the foot ; the plantar inter-
ossei, again, are adductors ; but the axis of the foot must be suppo-
sed to extend through the second, and not through the middle toe.
As we observed in the hand, the dorsal interossei project into the
plantar region, by the side of the plantar muscles ; and so narrow
are the interosseous spaces in the foot, that these dorsal muscles
are much more completely situated in tlie plantar than those of the
hand in the palmar region. The palmar interossei correspond-
ing to the fourth and fifth toes, arise not only from the lower two
thirds of the internal or tibial side of the corresponding metatar-
7" sal bone, but also from the lower surface of the posterior extrem-
ity of the same bone. It follows, therefore, that the interosseous
muscles, viewed from below, appear one continuous muscle, in
which it would be difficult to separate the muscles of each space,
if the interosseous plantar fascia did not give off prolongations
between them ; elsewhere, a cellular line defines the limit be-
tween each plantar and dorsal muscle.
PHYSIOLOGICAL ARRANGEMENT OF THE MUSCLES.
Again, as in the hand, the dorsal interossei arise from two corresponding metatarsal
bi)nes at once, but more especially from the lateral surface of that metatarsal bone which
is directed/rota the axis of the foot : as in the hand, also, their posterior extremities are
perforated by the posterior perforating arteries, the first being perforated by the arteria
dorsalis pedis. The plantar interossei arise from only one of the metatarsal bofnes, and
from the lateral surface that is directed towards the imaginary axis of the foot ; moreover,
they do not arise from the entire thickness of the bone, but only from its inferior two
thirds, since the upper third is covered by the dorsal muscle.
The following are the general relations of the interossei : they are separated above
from the tendons of the extensors by a layer of fibrous tissue, and by the dorsal inter-
osseous fascia ; and below from the proper muscles of the foot, by the deep plantar in-
terosseous fascia, which is much stronger than the corresponding structure in the hand,
and gives off septa between the different pairs of interosseous muscles.
PHYSIOLOGICAL ARRANGEMENT OF THE MUSCLES.
However important it may be to become acquainted with the order of super-imposi-
tion, or the topographical arrangement of the muscles, it is no less necessary to study
the retrospective uses, in other words, the physiological arrangement of these organs*
In order to obtain, as much as possible, the advantages of each of these two methods,
having already described each muscle in its topographical order, I shall now give a table
of the muscles, arranged according to their physiological relations. It is important to
observe that the terms muscles of the arm, of the thigh, <fc., have not the same accepta-
tion in the two arrangements. Thus, by the term muscles of the £irm, in the topographi
ical order, we mean the muscles which occupy the region of the arm, as the deltoid, bi-
ceps, &c. ; but, in the physiological arrangement, the same term is applied to the mus-
cles which move the arm, viz., the pectoralis major, latissimus dorsi, &c.
Muscles of the Vertebro-cranial Column.
These are divided into the extensors, the flexors, and the lateral muscles or lateral
flexors, which incline the vertebral column to one side or the other. There are no rota-
tors, for rotation is performed by the extensor muscles.
Extensors. — These occupy the posterior region of the vertebral column. They con-
sist, on each side, of, 1. The posterior spinal, or long muscles of the back, divided into
the sacro-lumbalis, longissimus dorsi, and transverso-spinalis ; 2. Of the transversalis
colli and the trachelo-mastoideus, which may be regarded as accessory fasciculi to the
longissimus dorsi ; 3. Of the splenius, or representative of the longissimus dorsi of the
neck and head ; 4. Of the complexus, or transverso-spinalis of the head ; 5. Of the m-
ter-spinales, in which the two recti postici of the head may be included ; 6. Of the ob-
liquus major, or spino-transversalis of the atlas ; 7. Of the obliquus minor, or transverse
spinalis of the head.
Flexors. — These are situated on the anterior region of the vertebro-cranial column.
The most important of these muscles are carried forward, and attached to the sternum,
and to those long transverse processes called the ribs. They are on each side, 1. The
rectus abdominis ; 2. The stemo-cleido-mastoideus. The other muscles that co-operate
in flexion occupy the deep anterior cervical region, viz., 1. The rectus capitis auticus
major ; 2. The rectus capitis anticus minor ; 3. The longus colli.
Lateral Muscles. — These are, 1. The inter-transversales oCthe neck and loins, among
which I include the rectus capitis lateralis ; 2. The scaleni anticus et posticus ; 3. The
quadratus lumborum.
Muscles of the Ribs, or of the Thoracico-abdominal Parietes.
These are, 1. The inter-costales, externi and intemi, which are both elevators and
depressors; 2. The small accessory muscles, viz., the infra-costales of Verheyen and
the supra-costales, or levatores costarum, the latter being always elevators ; 3. The ser-
rati postici superiores, which are elevators ; 4. The serrati postici inferiores, depressors ;
5. The triangularis stemi, or small anterior serratus, also a depressor ; 6. The diaphragm,
a muscular septum, the contraction of which increases the vertical diameter of the tho-
riix, and draws the ribs inward. Tlie muscles of the abdominal parietes are so intimate-
ly connected in action with those of the thorax, that the description of the former nat-
urally follows that of the latter. The abdominal muscles, then, may be regarded as mus-
cles of expiration, and are all depressors of the ribs. There are, 1. The obliqims exter-
* Custom, rather thtn conviction, has induced me to prefer the topographical to the physiological arrange-
ment. The only objection which can be nrped against the latter is, that it does not permit all the muscles
to be dissected upon the same subject ; but this objection applies only to a few regions ; and as these regions
exist in pairs, the superficial muscles on one side might surely be sacrificed. Moreover, there is no reason
why the examination of the deep-seated muscles should not be postponed until the superficial ones have been
studied. I therefore direct students to dissect these parts sometimes according- to their topographical, and
at others after their physiological order
fSffSt MYOLOGY.
nus, which is nothing more than a large external intercostal muscle, extending between
the ribs and the pelvis ; 2. The obliquus internus, which may be regarded as a large
internal intercostal muscle, of which the cremaster is a dependance ; 3. The trai sversa-
lis, which we may consider as forming with the diaphragm a single muscle, intermpted
by its costal attachments.
Muscles which move the Lower Jaw.
As the bones of the upper jaw are immovably articulated together and to the cranium,
they have no proper muscles. The muscles of the face do not belong to them, but are
true cutaneous muscles, attached to the different bones only for the purpose of having
fixed origins. The lower jaw, on the contrary, is provided with two principal orders of
muscles, elevators and depressors, to which are added diductors (from diduco, to draw aside).
The elevators and diductors preponderate ; the only office of the depressors is to bring
down the jaw into a position from which it may then be raised.
1. Elevators. — These are the masseters, the temporales, and the pterygoidei interni.
2. Diductors, viz., the pterygoidei extemi.
3. Depressors, consisting of the muscles of the supra- and infra-hyoid regions, and
more particularly of the two digastrici.
Muscles which move the Os Hyoides.
These are divined into elevators and depressors.
All the elevators belong to the supra-hyoid region, and are, 1. The stylo-hyoidei ; 2.
The mylo-hyoidei ; 3. The genio-hyoidei.
The depressors consist of the muscles of the infra-hyoid region, viz., 1. The sterno-
hyoidei ; 2. The stemo-thyroidei ; 3. The thyro-hyoidei ; 4. The omo-hyoidei.
Muscles which move the Pelvis.
There are no muscles proper to the pelvis. The ischio-coccygeus is the only intrinsic
muscle. The extrinsic muscles attached to the pelvis do not belong to its cavity, but
merely take their fixed points from its parietes. It is only under particular circumstan-
ces that the pelvis changes its usual office, and becomes the movable point ; for exam-
ple, in the horizontal position, in the action of climbing, and in the reversed attitude of
a tumbler, the pelvis is moved upon the vertebral column on the one hand, and upon the
femur on the other.
Muscles which move the Shoulder.
Tlie muscles of each shoulder are divided into elevators and depressors, both of which
are also rotators. The elevators are, 1. The trapezius ; 2. The rhomboideus ; 3. The
levator anguli scapulae. The depressors are, 1. The pectoralis minor ; 2. The subclavius ;
3. The serratus magnus. The elevators and depressors of the entire shoulder must be
carefully distinguished from those which raise' or depress its apex.
Muscles which move the Thigh upon the Pelvis.
Tliese muscles are divided into extensors, flexors, adductors, abductors, and rotators
The extensors and abductors are the same, viz., the three glutaei.
The conjoined psoas magnus, iliacus, and psoas parvus constitute the only_^xor.
Adduction is performed by four muscles, viz., the pectineus and the three adductors.
Rotation outward is performed by six muscles, viz., the pyriformis, the two gemelli, the
obturator internus, the quaflratus femoris, and the obturator externus.
Rotation inward is performed by the tensor vaginae femoris, and especially by the an
terior fibres of the glutaei, medius et minimus.
Muscles which move the .Mrm upon the Shoulder.
These muscles are divided into abductors, which are at the same iivae flexors, and into
adductors and rotators. There are no proper muscles for the movement forward or flexion,
nor for the movement backward or extension, both of which motions are effected by the
adductors and abductors.
The abductors are, 1. The deltoideus ; 2. The coraco-brachialis ; 3. The supra-spi-
natus.
The adductors are, 1. The pectoralis major ; 2. The latissimus dorsi ; 3. The teres
major.
The rotators are, 1. The external, viz., the infra-spinatus and the teres minor ; 2. The
internal, viz., the sub-scapularis.
Muscles which move the Leg upon the Thigh.
These are divided into flexors and extensors. The flexors are, 1. The biceps femoris ;
2. The semi-tendinosus ; 3. The semi-membranosus ; 4. The popliteus ; 5. The sarto-
rius ; 6. The gracihs.
Extension is performed by one muscle only, viz., the triceps femoralis, the long head
PHYSIOLOGICAL ARRANGEMENT OF THE MUSCLES.
of which is fonned by the rectus femoris, and the other two heads by the triceps cruris
of authors, viz., the vastus externus and vastus internus, including the crureus.
I should remark, that all these muscles which arise from the pelvis perform the double
function of moving the leg upon the thigh, and the thigh upon the pelvis.
Muscles which move the Forearm upon the Arm.
These are divided into flexors and extensors. The flexors are the biceps and the
brachialis anticus. The extensors are, 1. The triceps (of which the long head resembles
the rectus femoris) ; 2. The anconeus.
Muscles which move the Radius upon the Ulna.
These are rotators inward, or pronators, viz., 1. The pronator teres ; 2. The pronator
quadratus; and rotators outward, or supinators, viz., 1. The supinator longus ; 2. The
supinator brevis. The pronators occupy the anterior region, the supinators the poste-
rior region of the forearm.
Muscles which move the Hand upon the Forearm.
These are divided into flexors and extensors. The flexors are, 1. The flexor carpi
radialis ; 2. The palmaris longus ; 3. The flexor carpi ulnaris. The extensors are, 1.
The extensores carpi radiales, longior et brevior ; 2. The extensor carpi ulnaris.
Adduction and abduction are also performed by these muscles.
Muscles which move the Fingers.
These are divided into extensors, flexors, adductors, and abductors. The extensors
are, 1. The extensor communis digitorum; 2. The extensor digiti minimi; 3. The ab-
ductor longus pollicis ; 4 and 5. The extensor brevis and extensor longus pollicis ; 6.
The extensor proprius indicis.
The flexors are, 1. The flexor sublimis digitorum ; 2. The flexor profundus digitorum,
and its accessories, the lumbricales ; 3. The flexor longus pollicis.
The extensors and the flexors of the fingers are all situated in the forearm ; the ad-
ductors and abductors belong to the hand : they consist of the interossei, which are seven
in number, four dorsal, constituting the abductors, and three palmar, which are adductors.
Other muscles are also superadded to the thumb and the little finger; The muscles
superadded to the thumb are, 1. Those which constitute the thenar eminence (ball of
the thumb), viz., the abductor brevis, the opponens, and the flexor brevis ; 2. The ad-
ductor pollicis, which is nothing more than a palmar interosseous muscle. The mus-
cles su|)eradded to the little finger constitute the hypothenar eminence (ball of the little
finger), and form, as it were, a repetition of those of the thenar eminence, viz., the ab-
ductor brevis, the flexor brevis, and opponens. But although three only are thus de-
scribed, it is because the palmar interosseous muscle of the little finger, which repre-
sents the adductor poUicia, presents no peculiarities, and is, therefore, classed with the
other palmar interossei.
Muscles which move the Foot upon the Leg.
These are divided into flexors and extensors : the same muscles also produce, at the
articulation of the two rows of the tarsal bones, movements of rotation, which corre-
spond to adduction and abduction.
The extensors are, 1. The gastrocnemius and soleus, or the triceps suralis, with which
we describe a small rudimentary muscle, the plantaris. 2. The tibialis posticus. 3. The
peroneus longus et brevis.
There is only one flexor, viz., the tibialis anticus. The peroneus tertius, when it ex-
ists, is merely a dependance of the extensor longus digitorum.
There are no muscles in the leg analogous to the pronators and supinators of the fore-
arm.
Muscles which move the Toes.
These are divided into extensors and flexors.
The extensors are, 1. The conjoined extensor longus digitorum and peroneus tertius.
2. The extensor proprius pollicis. 3. The extensor brevis digitorum. The flexors are, 1.
The flexor longus digitorum, and its accessories, the lumbricales. 2. The flexor brevis
digitorum ; the flexor longus pollicis.
Contrary to what we have seen with regard to the fingers, many of the flexors and ex-
tensors of the toes form part of the intrinsic muscles of the foot. As in the hand, the ad-
ductors and abductors of the toes occupy the thenar, hypothenar, and interosseous regions.
The interosseous muscles are adductors and abductors of the toes ; they are seven in
number, four dorsal, being the abductors, and three plantar, acting as adductors.
The superadded muscles of the great toe are, 1. The muscles of the thenar eminence,
viz., the abductor brevis and the flexor brevis. 2. The adductor obliquus, and the ad-
ductor transversus. The muscles superadded to the little toe are the muscles of the hy-
pothenar eminence, viz., the abductor and the flexor brevis.
APONEUROLOGY.
Cutaneous Muscles,
These muscles, which are inserted into the skin by one of their ecxtremities at least,
are in the human subject concentrated round the openings in the face, with a single ex-
ception, viz., the palmaris brevis.
The cutaneous muscles of the ear belong to the orifice of the external auditory meatus,
and are £ill rudimentary in man. They form the three auricular muscles.
The muscles of the eyelids, on either side of the face, are divided into constrictors and
dilators. There is only one constrictor, the orbicularis palpebrarum, of which the comi-
gator supercihi may be considered an accessory.
There are two dilators, viz., the levator palpebrae superioris and the occipito-frontalis.
The cutaneous muscles of the nose consist of four or five pairs, i. e., on each side of the
face, of the pyramidalis nasi, the levator labii superioris alaeque nasi, the transversalis
nasi, the depressor alae nasi or myrtiformis, and the naso-labialis of Albinus.
The cutaneous muscles of the lips are, 1. A constrictor, viz., the orbicularis oris. 2.
Nine pairs of dilators, consisting, on each side, of the levator labii superioris alaeque nasi
already mentioned, the levator labii superioris, the zygomaticus major, the caninus, the
buccinator, the triangularis oris, the quadratus menti, the levator labii inferioris, the pla
tysma myoides ; and often of two accessory muscles, viz., the risorius of Santorini, and
the zygomaticus minor.
APONEUROLOGY.
General Observations on the Aponeuroses. — Structure. — Uses.
The aponeuroses are fibrous membranes, arranged in the form of inextensible textures,
which constitute sheaths for the muscles, and, at the same time, afford them broad sur-
faces for attachment. The aponeuroses are generally known, at the present day, by the
name oi fascia {fascia, a band), an expression which was at first appUed exclusively to
the strong, broad aponeurotic band, forming the termination of the tensor vaginae femoris,
and part of the fascia lata of the thigh.
The aponeuroses constitute important adjuncts to the system of locomotion. They
were for a long time neglected, or, rather, studied independently of each other, and then
only partially, until Bichat gave a general view of them, in his division of the fibrous sys-
tem, including the membranous forms of that tissue, of which the aponeuroses form the
greatest part.
As the aponeuroses have now become the object of numerous researches, and even
the subject of some special treatises,* I have considered that it would be useful to offer
a description of all the aponeuroses of the human body under the head of Aponeurology.
This grouping together of analogous parts will have the double advantage of simplifying
the description of the particular aponeuroses, by making them elucidate each other, and
of bringing into prominent notice a system of organs, the study of which is generally neg-
lected in anatomical lectures.
General Observations. — The aponeuroses are divided by Bichat into two distinct class-
es, one serving for the insertion of muscles, viz., the aponeuroses of insertion ; the other
for investing or containing the muscles, called the investing or confining aponeuroses.
Many aponeuroses serve both these purposes at the same time ; but, in general, one or
the other function predominates in each.
The aponeuroses of insertion^ are subdivided into those formed by the expanded con-
tinuations of tendons, and those which do not originate in tendons. The aponeuroses
of the gastrocnemius and soleus belong to the first class ; those of the broad muscles of
the abdomen are examples of the second : in the latter case, the aponeuroses serve both
for the insertion and investment of the muscles. Sometimes the aponeurosis occupies
the middle of a muscle ; as, for example, the cordiform tendon of the diaphragm, and the
aponeuroses of the occipito-frontalis. The use of the aponeuroses of insertion evident-
ly has reference to the great number of muscular fibres, all of which could not have been
attached to the limited superficies of the skeleton.
The investing aponeuroses occasionally form a sheath for the entire limb, sometimes
for only a single muscle, and at others for several muscles. The first set are called gen-
eral, the other two partial aponeuroses.
The aponeuroses are found not only in the extremities where they perform such im-
portant offices, but also in the trunk. As a general rule, wherever there exists a muscle
fulfilling any special purpose, and susceptible of displacement during its contraction, we
find an aponeurosis, or, rather, an aponeurotic sheath ; and the thickness of this sheath
is proportioned to the length and strength of the muscle, and especially to its tendency
to displacement.
* Godman, of Philadelphia, published in 1824 a special work upon the fascise ; and Paillard a treatise upOB
the aponeuroses of the human body in 1827. t See note, p. 296.
GENERAL REMARKS UPON THE APONEUROSES. 295
Each aponeurosis presents for our consideration an external and an iTitemal surface, a
superior border or circumference, sometimes termed its origin, and an inferior border or
circumference, sometimes called its termination.
1. The external surface of the general investing aponeuroses is in contact with the sub-
cutaneous cellular tissue, from which it is separated by the superficial veins, lymphatics,
and nerves. The skin is therefore movable upon these aponeuroses, excepting in some
situations, as in the palms of the hands and soles of the feet, where it is intimately uni-
ted to the fasciae by prolongations from the inner surface of the cutis. What, indeed,
would be the consequences with regard to the sense of touch, or in the attitude of stand-
ing, if the skin over those regions were as movable as it is upon the thigh 1 The same
adhesion is also observed between the hairy sc£dp and the subjacent aponeurosis.
The mobility of the skin upon the aponeuroses depends upon the following contrivance :
From the inner surface of the skin are given off a great number of prolongations, which,
having intercepted the areolae containing the adipose tissue, unite together, and expand
into a membrane, which glides over the aponeuroses and the superficial vessels and
nerves : the sub-cutaneous membrane thus formed bears, the name of the fascia superfici-
alis : it is only distinctly seen in regions that are traversed by superficial vessels and
nerves, as in the lower part of the abdomen, and on the extremities.
2. The deep surface of a general investing aponeurosis presents fibrous prolongations
passing between the different layers of muscles, and even between the muscles of which
these layers are composed. Moreover, this surface and its several prolongations some-
times afford attachments to the superficial muscles, and sometimes it glides over the mus-
cles and their tendons by means of a very loose filamentous cellular tissue — an arrange-
ment that prevails throughout the greater part of the extent of this surface. Lastly,
amid aU these sheaths for the muscles, there exists a proper sheath for the principal
vessels of the extremities.
These aponeurotic sheaths are not so exactly moulded upon the muscles as not to ad-
mit of the accumulation of a certain quantity of fat in their interior ; nevertheless, their
capacity is so far proportioned to the size of the muscles, that the latter, during their
contraction, experience a degree of pressure from them which is highly favourable to
their action, at the same time that it prevents all displacement.
In emaciated individuals, these sheaths are no longer filled by their respective mus-
cles ; and, without doubt, the want of a due compression upon the muscles has some in-
fluence in producing the weakness experienced by convalescents, or by those wasted by
some chronic disease.
3. The borders or circumferences of aponeuroses, incorrectly named their origin and ter-
mination, are either continuous with the aponeuroses of the adjacent regions, or are at-
tached to the processes on the articular extremities of the bones, or result, in part, from
the expansion of tendons.
The aponeuroses are perforated by vessels and nerves, which, in such cases, are gui-
ded and protected by arches, rings, or canals of fibrous tissue : of this nature are the
sheaths of the femoral artery and vein, and of the brachial artery and veins, the femoral
arch, the canal and arch of the adductor muscles of the thigh, the arch of the obturator
foramen, and the aortic arch of the diaphragm ; these canals and arches tend to prevent
any injury to the vessels and nerves by which they are traversed during the contraction
of the muscles. We must not suppose, however, that the vessels are exempt from all
pressure ; for experience has proved that arteries are particularly liable to become affect-
ed with aneurism in the neighbourhood of such arches ; as, for example, the popliteal and
femoral arteries and the aorta. The muscular fibres, in fact, are not attached to these
arches in such a manner as to dilate them in all directions during their contraction, but
rather in such a way as to elongate them in one direction and contract them in another.
All the aponeuroses, whether of insertion or investment, have their tensor muscle.
With regard to the aponeuroses of insertion, this requires no proof; for the action of the
muscle or muscles to which they afford attachment must necessarily render them tense.
It is no less true, however, of the investing aponeuroses, some of which have even a sep-
arate muscle for this purpose. Thus, the occipital and frontal muscles are tensors of the
occipito-frontal aponeurosis. The fascia lata is rendered tense by the tensor vaginae fe-
moris, the palmar fascia by the palmaris longus, &c.
The aponeuroses of both kinds are inextensible, resisting, and insensible membranes,
their thickness and strength being exactly proportioned to the resisting power and strength
of the muscles which are invested by them, or to which they afford the means of inser
tion. Thus, the fascia of the thigh is very much stronger than that of the arm : the thick-
ness of the aponeuroses increases from the upper to the lower part of the limbs ; and,
again, the powerful vastus externus is provided with a much stronger sheath than the
muscles of the posterior, or of the internal region of the thigh. We may, then, consider
it as a general law, without exception, that the aponeurotic system invariably presents a
corresponding degree of development to that of the muscular system. "VVe should, there
fore, study the aponeuroses, as well as the muscles, upon robust subjects ; their pearly
aspect is destroyed in individuals wasted by chronic diseases. The aponeurotic and
296 APONEUROLOGY.
muscular systems are both most fully developed in carnivora, in which class of animals
the pearly appearance is peculiarly well marked, and the cellular tissue is often replaced
by a fibrous texture ; a transformation which proves the analogy of the cellular and fibrous
tissues in organization, vitality, and function.*
The thinner fasciae are composed of a single layer of parallel fibres, which have be-
tween them intervals of different sizes : stronger aponeuroses are composed of several
planes, the fibres of which intersect each other at various angles. The vessels and
nerves of the aponeuroses are little known ; but I believe that I have traced nerves into
them. I have certainly done so with regard to the dura mater.*
I shall include among the aponeuroses the fibrous sheaths of tendons,* which are some-
times presented under the form of imperfect rings, or canals of different lengths, which
retain the tendons in contact with the bones. They serve to confine the tendons, to
keep them applied against the bones, and to favour their reflection.
The periosteum* must also be annexed to the aponeurotic system ; it is a tnie aponeu-
rosis, covering every part of the bones, and constituting a fibrous sheath for them. We
may consider the periosteum as the central point of the aponeurotic system, proceeding
from which, we find either tendons expanding upon the surface or in the substance of
muscles, and constituting the aponeuroses of insertion ; or else those fibrous cones or pyr-
amids, from the interior of which the fleshy fibres take their origin. From the perioste-
um, or, rather, from the ridges or clefts by which the surfaces of bones are marked, both
the partial and general investing aponeuroses arise. In this way the muscles of the ex-
tremities are situated between two fibrous layers ; the deep layer consisting of the peri-
osteum, the superficial layer of the general investing fascia : numerous septa pass from
one to the other, and divide the limb into a number of compartments, intended to isolate,
confine, and protect the different muscles.
Use of the Aponeuroses. — Forming, as they do, an important division of the fibrous tex-
tures, they partake of the physical, chemical, anatomical, physiological, and pathological
properties of that tissue.
1. From their great strength, they are enabled to resist the powerful traction and dis-
tension exercised upon them by the muscular fibres. Their division or destruction is
accompanied by displacement of the parts which they are intended to bind down. Be-
tween the different layers of the regions of the body they establish very precise limits, a
knowledge of which is of the greatest importance, in enabling us accurately to accoxmt
for many morbid phenomena, and in guiding us in the performance of surgical operations.
2. They are inextensible ; hence the resistance which they oppose to the development
of subjacent parts, and the tension produced by inflammation of organs situated beneath
them. They yield to gradual distension, but then become thinner and weaker, and can
only imperfectly fulfil their proper offices.
3. They are totally inelastic, and, therefore, when distended beyond a certain point,
never return to their original dimensions. Of this we have an example in the condition
of the abdominal parietes after utero-gestation, or ascites.
4. The low degree of vitality they possess explains why they are so slightly involved
in inflammation or other morbid conditions of the adjacent structures, and also the fact
of their establishing limits beyond which these diseases seldom pass. They are insen-
sible to all ordinary stimuli, but become painful when they are violently overstretched
The plantar fascia, under such circumstances, becomes extremely sensitive.
Having made these general remarks, we shaU now describe, in succession, the prin-
cipal aponeuroses of the human body.f
• See note, infra.
t Note on Aponeurology. — [The analogy existing' between the cellular and aponeurotic investments of various
organs renders it advantageous to consider in this place the general a.n-Atomy of the cellular and fibrous tissues.
The ultimate elements of both these kinds of tissue are precisely similar, though somewhat differently ar-
ranged in each ; they consist of delicate transparent filaments, varying in diameter from ^^j-^ ^^^ th to yj^Tj-g^th
of an inch, and having a peculiar sinuous or undulating direction ; they are insoluble in cold water, but by
long-continued boiling are almost entirely converted into gelatine.
In cellular tissue these undulating filaments are arranged side by side, either into larger compound and flei-
uous fasciculi, or into thin, transparent lamina, which cross and intersect one another in all directions, so as
to lesve interstitial cavities or areolie, freely communicating with each other, and moistened by an albuminous
fluid. The tissue thus formed, more properly called areolar, or filamentous, is of a grayish aspect, and highly
elastic ; the latter property depending not on any innate elasticity in the ultimate filaments, but on the sinuous
disposition of those filaments, and of the fasciculi into which they are collected. But few vessels, and still
fewer nerves, are believed to terminate in this tissue. It is continuous over the whole body ; hence the great
extent to which it may be affected with diffuse inflammation; it also invests and isolates parts, forms the ma-
trix of nearly all organs, and the basis of many membrane* ; and is called, according to its position, investing,
intermediate, penetrating, parenchymatous, or sub-membranous. The characters above described are most
strongly marked in the loose cellular tissue, examples of which are met with in the axilla, under the sub-scap-
ular muscle, between the free surfaces of muscles and their sheaths, behind the kidneys, &c. In other situ-
ations it is more condensed, as in the sub-serous, sub-mucous, and snb-cutaneoiis cellular tissues ; in the latter
of these, or the superficial fascia, and also in the cutis itself, it approaches to the fibrous tissue both in density
and in the mode of arrangement of its elementary filaments, and is therefore termed fibro-cellular tissue.
From this variety the transition is natural to the fibrous tissues, properly so called.
\n fibrous tissue the undulating primitive filaments are also arranged side by side into fasciculi, which diflTer
from those of cellular tissue in being much larger, more dense and more opaque, and in being straight in-
stead of flezuous. They are white, shining, strong, and almost inelastic, qualities depending on the compact
SUPERFICIAL FASCIA. 297
PARTICULAR APONEUROSES.
Superficial Fascia. — Aponeuroses of the Cranium — of the Face — of the Neck — of the Thorax
— of the Abdomen — of the Pelvis — of the Thigh, Leg, and. Foot — of the Shoulder, Arm,
Forearm, and Hand.
The Superficial Aponeurosis, or Superficial Fascia.
From every point of the deep surface of the skin fibrous cellular lamellae arise, which
intersect each other in various directions, so as to form meshes or areolae, containing
adipose tissue in ordinary circumstances, and a serous fluid in cedema.* The cutaneous
muscle (panniculus carnosus) of the lower animals is developed in these laminae ; and
among them are situated the sub-cutaneous vessels and nerves, and the l)TTiphatic glands.
The name oi fascia superficialis has been of late applied to this assemblage of lamellae.
It was pointed out in a particular manner by Ghsson, who described it under the name
of the general investment of the muscles, proceeding from the spine, and covering the
whole body; Camper, Cowper, Scarpa, Hesselbach, Lawrence, J. Cloquet, &c., have
described it upon the abdomen, in its relation with herniae ; Godman has spoken of its
existence over the entire surface of the body : M. Paillard, in his inaugural dissertation,
traced it with still greater exactness ; MM. Velpeau and Blandin, in their Traites d^Ana-
tomie Chirurgicale, consider it as existing in almost all regions of the body.
But if the word aponeurosis be employed in its ordinary acceptation, it will be found
that a fascia superficifilis, consisting of a fibrous texture capable of anatomical demon-
stration, exists only in two kinds of situations, viz., in those where the skin is extreme-
ly movable, and in those where there is a layer of sub-cutaneous vessels and nerves : in
both these cases the fibrous prolongations from the skin are expanded into a thin lamina,
constituting a superficial covering for these vessels and nerves, and separated from the
fibrous investment of the muscles by a layer of cellular and adipose tissue, of variable
thickness. In all other parts, the fibro-cellular prolongations of the skin become contin-
uous either with the investing aponeuroses, or with the proper fibro-cellular sheaths of
the muscles, or are lost in the sub-cutaneous cellular tissue. So true is this, that this
thin areolar layer, which can with difficulty be separated from the skin in emaciated
persons, disappears altogether in those whose cellular tissue is distended by fat or se-
rous effusion.
Having made these remarks, I shall describe the superficial fascia in those regions
only where it can be easily demonstrated, viz., in the lower part of the abdomen, and in
the extremities. «
The Superficial Fascia of the Abdomen.
This aponeurosis, from its constituting the first sub-cutaneous covering of herniae, has
particularly engaged the attention of authors who have specially treated of the patho-
logical anatomy of those diseases.
It becomes evident in the neighbourhood of the umbilical region, but is much more dis-
tinct at the fold of the groin, where it divides into two layers, one of which is attached
to the femoral arch, and the other is prolonged upon the lower extremity. It is bound-
ed on the inside by the median line, and on the outside by another line, extending per-
pendicularly upward from the anterior superior spinous process of the ilium. It is pro-
longed over the inguinal ring, and over the spermatic cord in the male subject.
parallel disposition of the component filaments, and the slight amount of elasticily in particular on the ab-
sence of sinuosity in the compound fasciculi. According to the manner in which tliese fasciculi or fibres (as
they are termed) are arranged and combined, wo have either the membranous or the fascicular form of fibrous
tissues.
In the membranous form there are some which closely resemble the fibro-cellular memliranes already allu-
ded to, and consist of the shining fibres crossing each other in all directions (without anastomosis), and inter-*
mixed with more or less condensed cellular tissue ; for example, the thinner investing aponeurosis, the capsu-
lar ligaments, the pericardium, tunica albuginea, periosteum, and dura mater. In others, again, the fibres are
more parallel, though still intersected, and combined with cellular tissue, as in the fascia lata of the thigh,
and in other strong investing aponeuroses. In the aponeuroses of insertion of the broad muscles, and in the
expanded terminations of tendons, there is scarcely any cellular tissue, while the parallel arrangement is yet
more perfect ; and, finally, the latter attains its utmost perfection in the round ligaments, and in tendons,
which constitute the fascicular form of fibrous tissue, and the type of the tissue itself.
These textures contain but few nenes and vessels. The distribution of a branch of the fourth cranial nerve
to the dura mater, alluded to in the text, has been confirmed by other anatomists. Bloodvessels abound in the
periosteum, but they merely divide in that membrane, so as to enter the bone at a great numlier of points.
The sheaths of tendons (classed among the fibrous tissues by M. Cruveilhier) display a tendency to become
fibro-cartilaginous, especially at and near their attachments to the bones. They have fiitherto been described
(ex. gr., p. 250, 257) as if lined by vaginal synovial membranes (note, p. 177). According to Dr. Ifenl6, how-
ever, their interior is not covered by an epithelium. The bursa, or so-called bursal synovial membranes, formed
between the tendons of muscles (p. 265), between tendons and bones (p. 265, 266, 267), and between the skin
and projecting parts of bones, as over the patella, the olecranon, <&c., according to the same authority, are also
destitute of epithelium. It would appear, therefore, that although these cavities resemble in function the
true synovial membranes, they differ anatomically from them, and consist merely of shut sacs formed in the
Bfeneral cellular texture of the liody. Such bursie, however, as communicate with the synovial capsules of
oints (p. 216. 244), are probably lined by an epithelium.]
* [AdipoKc tissue is never deposited m the suli-cutaneous tissue of the eyelids, nor in the male onjan of tfcn-
«raliou. These lart", however, m-'V liecoine much distended from serous infiltration.]
Pp
APONEUROLOGY.
It has been said that in the foetus, before the descent of the testicle, the superficial fas
cia dips into the inguinal canal, and forms an infundibuliform prolongation, reaching up
to the lower part of that gland ; and the dartos has been supposed to result from the ex-
pansion of this fascia — a description which can be regarded only as an ingenious specu-
lation, which has not been confirmed by actual dissection.
Lastly, the external surface of the superficial fascia of the abdomen is in relation with
the skin, separated from it, however, by a layer of adipose tissue of variable thickness,
in which the sub-cutaneous vessels and nerves are situated. Its deep surface corre-
sponds with the aponeurosis of the external oblique muscle, and with a portion of its
fleshy fibres : from these parts it is separated by a layer of serous cellular tissue, which
enables it to be moved easily upon this muscle and the sub-cutaneous vessels and nerves.
The Superficial Fascia of the Upper and Lower Extremities.
These are thin fibrous sheaths, separated from the skin by a greater or less quantity
of adipose tissue, and from the investing aooneurosis of the muscles by the sub-cutaneous
vessels and nerves. It does not exist around the joints, nor in the palms of the hands
and soles of the feet, for in these places the skin adheres to the subjacent aponeuroses
The Aponeuroses of the Cranium.
The Occipito-frorUal or Epi-cranial Aponeurosis.
This is a sort of tendinous or cutaneous cap {galea capitis), stretched between the two
frontal and two occipital muscles. Its superficial surface is intimately adherent to the
skin by means of very short and strong fibrous prolongations, between which the fatty
matter is deposited : the frontal, occipital, temporal, and auricular vessels and nerves
traverse this adipose tissue. Its deep surface glides upon the periosteum of the scull
(pericranium) by the intervention of a very delicate cellular tissue, in which fat is never
found. Its anterior margin receives the fibres of the frontal muscles, forming a trian-
gular point between them ; its posterior margin receives the fibres of the occipital mus-
cles, and also occupies the interval between them. These two muscles act as tensors
of the aponeurosis. Its outer margin gives attachment to the superior and anterior-
auricular muscles. It is composed behind of shining fibres, which seem to form a ten-
don of insertion to the occipitalis muscle, but it soon loses its pearly appearance, and
becomes more adherent to the skin : it is thick and strong at the upper part of the head,
but thin and almost cellular at the sides : it may be regarded as a dependance of the su-
perficial fascia. It gives rise to the tension which is so common and so dangerous in
inflammations of this region. Its adhesion to the skin explains the shallow character
of ulcers, and the flatness of the small abscesses occurring in these parts.
The Temporal Aponeurosis.
Besides the tendinous origin of the temporal muscle, which has been already descri-
bed, there is also a very strong investing aponeurosis, arising from the upper border of
the zygomatic arch, and inserted into the curved line bounding the temporal fossa above.
This aponeurosis completes the sort of case in which the muscle is contained ; and the
space between it and the temporal fossa corresponds with the thickness of the muscle.
It differs from the epicranial aponeurosis, which is more superficial and covers it su-
periorly, in not adhering to the skin, which glides very easily upon it. Its deep surface
adheres to the upper part of the muscle, and furnishes it with numerous points of at-
tachment ; below it becomes free, and is separated from the fleshy fibres by a consider-
able quantity of fat ; hence the depression formed in this situation in emaciated persons.
It increases in thickness from above downward ; it divides below into two layers : one
superficial and thinner, inserted into the outer edge of the upper border of the zj^goma ;
.the other deep and thicker, attached to the inner surface of that process. In tolerably
stout persons, a considerable quantity of fat is situated between these two layers, and a
remarkable branch of the temporal artery also occupies the same situation. This fat
must not be confounded with the larger mass which lies beneath the aponeuroses. The
resistance of this fascia explains the reason why abscesses in the temporal fossa never
point outward, but rather tend downward into the zygomatic fossa.
The Aponeuroses of the Face.
The Parotid Aponeurosis.
This is a sheath of great thickness, especially that part which covers the outer surface
of the gland ; it is continuous below with the cervical fascia. It belongs especially to
the gland, for which it forms a framework by means of fibrous prolongations from its
deep surface. The density of this sheath explains both the pain caused by inflammation of
the gland, and the difliculty with which pus makes its way from within it to the surface.
The Masseteric Aponeurosis.
This is a thin tendinous layer covering the masseter muscle, and continuous below
with the cervical fascia ; it appears to divide behind into two layers, one of which con-
THE CERVICAJ. FASCIA, ETC. ^99^
Stitntes the parotid fascia, and the other penetrates between that gland and the tiasse-
ter ; above and anteriorly, it becomes merged into the cellular tissue. Purulent matter
situated beneath this fascia tends downward into the neck, but when situated superfi-
cially to it, points towards the skin.
The Buccinator Aponeurosis.
The buccinator is covered by a closely adherent fibrous layer, which is regarded as tne
expansion of the fibrous sheath of the Stenonian duct ; it is thickest behind, where it is
termed the buccinato-pharyngeal aponeurosis, because it gives attachment behind to the
superior constrictor of the pharynx, and to the buccinator in front. This aponeurosis
prevents superficial abscesses from opening into the mouth, and is also opposed to the
extension outward of diseases attacking the mucous membrane.
The Cervical Aponeurosis, or Cervical Fascia.
In the cervical region we find, 1. The cervical fascia ; 2. The prevertebral aponeurosis
The Cervical Fascia.
The cervical aponeurosis covers the whole anterior region of the neck ; it extends
from the base of the lower jaw to the sternum and clavicles, and is insensibly lost on
either side in the sub-cutaneous cellular tissue. It is thick in the median line, and forms
a sort of cervical lima alba. From this linea alba two layers proceed in the supra-hyoid
region, and four in the infra-hyoid region, which are arranged in the following manner
1. The superficial layer, or the superficial cervical fascia, covers the whole anterior and
lateral regions of the neck, is prolonged downward in front of the clavicle, to become
continuous with the proper aponeurosis of the pectoralis major, is attached above to the
masseteric and parotid fasciae, and, internally to the masseter muscle, is fixed to the
base of the lower jaw.
It fills up the interval between the two platysmata, and is prolonged behind these mus-
cles to form the anterior layer of the sheath of the stemo-mastoid. The external jugu-
lar vein is superficial to this layer in the sub-hyoid, and lies beneath it in the supra-hyoid
region.
2. The deep layer passes beneath the stemo-mastoid, on the outer border of which it
unites with the preceding layer, and completes the sheath for that muscle. It covers
the internal jugular vein, the common carotid artery, the pneumogastric nerve, the great
sympathetic, and its cervical ganglia. Its upper margin is attached to the base of the
lower jaw ; its lower margin to the posterior surface of the clavicle, and to the posterior
edge of the fourchette of the sternum. It is necessary to examine this deep layer, both
in the supra and sub hyoid region.
In the supra-hyoid region its middle portion is very strong, and occupies the triangu-
lar space between the anterior bellies of the digastric muscles ; it is fixed by its lower
margin to the os hyoides, and on each side to the tendon of the digastricus. The lat-
eral portions of this aponeurosis pass beneath the sub-maxillary glands, and are attached
to the rami of the lower jaw. Externally to these glands they join the parotid aponeu-
roses, and form a tolerably thick septum between the sub-maxillary and parotid glands of
either side.
In the sub-hyoid region this deep layer is divided into three very distinct parts, a mid-
dle and two lateral. The middle is the stronger ; it occupies the triangular space be-
tween the two omo-hyoid muscles, and becomes continuous with their median tendons :
the muscles may, therefore, be regarded as the tensors of this facia. It binds down the
muscles of the infra-hyoid region : its arrangement explains why abscesses situated in
front of it discharge their contents through the skin, and not into the thorax, as those do
that are subjacent to it. The lateral parts of the aponeurosis constitute the supra-clavic-
ular fascia, a very strong layer, in which the superficial layer already described, and the
two which yet remain to be noticed, all terminate. It occupies the whole triangular
space between the trapezius and the stemo-mastoid, is continuous with the fibro-cellular
sheath of the former muscle, and adheres below to the clavicle. The latter circumstance
is of great importance in relation to surgical anatomy.
The superficial and deep layers which we have now described are common to both
the supra and sub hyoid regions. In the sub-hyoid region there are two other aponeurotic
layers : one, very thin, separating the superficial from the deep muscles, i. c, the omo
and sterno hyoidei from the sterno-thyroidei and thyro-hyoidei ; the other, thicker, pass-
ing between the sterno-thyroidei and the trachea. The latter is the fourth layer, which
Godman incorrectly describes as continuous with the pericardium.
The Prevertebral Aponeurosis.
This aponeurosis covers the muscles of the prevertebral region, viz., the longi colli,
and the great and small anterior recti : it is prolonged on each side upon the scaleni, the
levator anguli scapula;, and the brachial plexus ; and is attached to the upper border of
the scapula, and to the outer half of the posterior border of the clavicle. It completely
^&b APONEUROLOGY.
separates the axilla from the neck, and is perforated by several vessels. It prevents
large abscesses of the neck from opening into the axilla ; and, in caries of the cervical
vertebrae, it retains the pus poured out against it, so as to form abscesses by accumulation.
The Thoracic Aponeuroses.
The Intercostal Aponeurosis.
Independently of the semi-tendinous structure of the intercostal muscles, we find sev-
eral fibrous layers in each intercostal space : one layer in front, continuous with the ex-
ternal intercostal muscle ; another behind, continuous with the internal intercostal mus-
cles ; and, situated within these muscles, a third layer, which lines them and separates
them from the pleura. The existence of this sub-serous aponeurosis accounts for the
rare occurrence of the bursting of an external abscess of the chest into the cavity of the
pleura ; and, on the other hand, of the escape of collections in the pleura by external
openings.
The Aponeurosis of the Serrati Postici.
In the dorsal region of the trunk, we find a very thin fibrous layer (sometiriies called
the vertebral aponeurosis), extending between the two serrati postici. It is of a quadri-
lateral form ; its inner margin is attached to the summits of the dorsal spinous process-
es ; its outer margin to the angles of the ribs, and its lower margin to the upper border
of the serratus posticus inferior ; it seldom terminates at the lower border of the serratus
posticus superior, but generally passes beneath it, and becomes the investing aponeuro-
sis of the splenius. The use of this aponeurosis is evidently to confine the posterior spi-
nal or long muscles of the back.
The Abdomistal Aponeuroses.
The parietes of the abdomen are partly muscular and partly aponeurotic : the muscu-
lar portions are situated at the sides of the abdomen. The aponeurotic portions occupy
the anterior and posterior regions, and form the anterior and posterior abdominal aponeu-
roses. The extensibility, elasticity, and, above all, the contractility of the abdominal pa-
rietes, depend on the three intersecting muscular layers ; while to the aponeuroses must
be attributed their capability of resistance and want of extensibility.
The Anterior Abdominal Aponeurosis.
The anterior abdominal aponeurosis forms the greater part of the anterior wall of the
abdomen. It consists, 1. Of a fibrous column, which is continuous with the osseous col-
umn of the sternum ; and, 2. Of two perfectly corresponding halves, one right, the other
left. These two halves are united in the linea alba, which may be regarded as their com-
mon origin.
The Linea Alba.
The linea alba {i,figs. 109, 110) is a tendinous raphe, extending from the ensiform
cartilage to the symphysis pubis ; it constitutes the anterior median line of the abdomen.
In a theoretical point of view it may be regarded as a continuation of the sternum, which,
in some animals, is prolonged as far as the pubes.*
Anatomists are not agreed as to the acceptation of the term linea alba. According
to some, it is a mathematical line produced by the intersection of the aponeuroses of
one side with those of the other : according to others — and this njeaning appears to me
preferable — it consists of the tendinous band comprised between the inner borders of the
recti.
Thus defined, the breadth of the linea alba corresponds to the interval between these
muscles, and, as they are directed somewhat obliquely upward and outward, it follows
that the upper or supra-umbilical portion of the linea alba is broader than that portion
which is below the umbilicus. This remarkable arrangement, by which the strength of
the lower part of the abdomen is secured, affords an explanation of the uniform occur-
rence of hernias through the linea alba above, not below, the umbilicus. It should also
be observed that, during exertion, the viscera are chiefly forced against the lower part of
the abdominal parietes, and also that the gravid uterus rests upon it.
The sub-umbihcal portion of the linea alba forms a mere line, while the supra-umbili-
cal is about a quarter of an inch in breadth. Its transverse dimensions are much in-
creased in persons whose abdomen has been greatly distended. Thus, during and after
pregnancy and certain dropsies, it in some cases acquires a considerable breadth, and
does not return to its original size, even after the distension has ceased to exist. In a
female who died a short time after delivery, I found the linea alba three inches across
at the umbilicus, and fifteen lines in the narrowest part. In cases of this kind, the linea
alba forms a sort of long pouch, which receives the intestines, and becomes very prom-
inent during the contraction of the recti.
The linea alba presents several elliptical openings for the passage of nerves and ves-
* The anal.ip.v has pveu bpen cnrried so far, that the tendinous intersections of the recti have been C«a»
JtarecJ to the ri'.is, Tt tht>y seeiii to ciime off from the linea alba like abdominal ribs.
THE ANTERIOR ABDOMINAL APONEUROSIS. 301
sels. In these foramina, round masses of fat are developed, which dilate them, and draw
down the peritoneum into them, or are absorbed in consequence of emaciation, and thus
open an easy way for the production of hernia of the linea alba. Of all these orifices,
the most remarkable is the umbikcal ring, which gives passage to the umbilical vessels in
the foetus, but becomes cicatrized after birth, at least in the majority of subjects.*
The situation of the umbilicus varies at different ages. The middle point of the length
of the body is situated above the umbilicus before the sixth month of foetal existence,
and corresponds with it after that period. In the adult it is situated below the umbil-
icus. Its situation with regard to the abdomen varies in different individuals. Thus,
the umbilical cicatrix, which is generally a little below the middle of the abdomen, is
sometimes exactly in the middle. I have even seen it at the/ point of junction of the
lower with the upper two thirds.
This cicatrix, moreover, is much stronger than the neighbouring parts. Thus, an
umbilical hernia, which, in a new-born infant, always occupies the navel itself, in an
adult is almost invariably situated a little above the umbilicus. Still it occasionally
yields, either in cases of dropsy or of hernia ; and I have records of several instances of
hernia in the adult, that have occurred through the umbilical ring.
The linea alba is in relation, in front, with the skin, which adheres more closely to it
than to the neighbouring parts, especially opposite the umbilicus. In the, male, it is sep-
arated from the skin below by th,e suspensory ligament of the penis, which sometimes
extends as far as the middle of the space between the pubes and the umbilicus : behind,
it is in relation with the peritoneum, separated from it, however, by the remains of the
urachus, and by the bladder itself, when that viscus is distended. It is, then, through
the linea alba that the bladder is punctured in cases of retention of urine, and that the
incision is made in the high operation of lithotomy. The peritoneum does not adhere
more closely to the umbilicus than to the other parts of the abdomen, and therefore um-
bilical hemiae, like all others, are invariably provided with a proper sac.
The upper extremity of the linea alba is attached to the ensiform appendix, a flexible,
elastic, cartilaginous body, constituting, as it were, a transitional structure between the
sternum and the part we are now describing.
The lower extremity corresponds to the symphysis pubis.
If we examine the structure of the linea alba, we shall see that it is formed by the in-
tersection of the layers of the anterior abdominal aponeuroses. One remarkable circum-
stance is, that the intersecting fibres do not stop at the median line, but pass from one
side to the other ; so that the tendinous fibres of the external oblique of the right side
become the tendinous fibres of the internal oblique of the left ; and, again, that the inter-
section occurs not only from side to side, but also from before backward. Below the
umbilicus the point of intersection is elevated by some longitudinal fibres, constituting
a small and very distinct cord, which appears to form a septum between the recti mus-
cles ; it increases in thickness as it proceeds downward from the umbilicus to the sym-
physis, and may be easily felt under the skin in emaciated individuals. We may add,
that the fibres of the linea alba have no resemblance to the yellow elastic tissue ; they
are neither extensible nor elastic, at least in the human subject. Its uses entirely re-
fer to its capability of offering resistance.
The pyramidales are its tensor muscles.
The Four Layers of the Anterior Abdominal Aponeurosis.
From each side of the linea alba {a, Jig. 134, a diagram representing a horizontal sec-
tion of the abdominal parietes) two fibrous layers proceed Fig. 134.
out'vard, one anteriorly, the other posteriorly, to the rec-
tus muscle (r).
The anterior layer (b), having arrived near the outer bor-
der of the muscle, subdivides into two other layers : one
superficial, constituting the aponeurosis of the external ob-
lique (d) ; the other deep, forming the anterior layer of the
aponeurosis of the internal oblique (e). The posterior lay-
er (c) is also simple as far as the outer border of the rec-
tus, and then separates likewise into two layers : one an-
terior, which becomes united with the aponeurosis of the
internal oblique (e), and is regarded as the posterior layer
of that aponeurosis ; the other posterior, which continues
its course outward from the rectus, and forms the aponeu-
rosis of the transversaUs muscle (/). We shall describe
these different parts in succession.
The Aponeurosis of the External Oblique. — This is the most superficial layer, and is
)f a quadrilateral figure {a, fig. 109) ; it is broad below, where it corresponds to the in-
* Some cases are on record of the persistence of the umbilical vein, and, consequently, of the umbilical ring.
I have nariated a case where a sub-cutaneous abdominal vein, prodigiously developed, became continuous with
the vena cava, which was also very large. — {Anat. Path., 1. xvi., pi. 6.)
APONEUROLOGY.
terval between the anterior superior spinous process of the ilium and the linea alba, be-
comes narrower immediately above, and again expands at the upper part, but to a less
extent than below.
It is covered by the skin and the superficial fascia, and it covers the aponeurosis and
the anterior portion of the fleshy fibres of the internal oblique. It adheres intimately to
the aponeurosis of the internal oblique, as far as the vicinity of the outer border of the
rectus, excepting below, where the two fasciae are perfectly distinct, and can be easily
separated throughout their entire extent.
Its external margin, slightly concave and denticulated, presents irregular prolongations,
with which the fleshy fibres become continuous. A line extending from the anterior
superior spinous process of the ilium to the extremity of the cartilage of the eighth rib,
will indicate with tolerable accuracy the direction of this margin, which appears to be
divided into two layers, one superficial, very thin, and continuous with the proper cel-
lulo-fibrous sheath of the muscle ; the other deep, and giving origin to fleshy fibres.
Its upper margin is narrow, and cannot be exactly defined ; it often gives attachment
to some fibres of the pectoralis major.
Its lower margin consists of two very distinct portions : one, extending from the ante-
rior superior spinous process of the ilium to the spine of the os pubis, is called the fem-
oral arch (p p',figs. 136, 137) ; the other, stretching between the spine and the symphy-
sis pubis, offers for consideration the pillars and the cutaneous orifice of the inguinal
canal (m, figs. 109, 136, 137).
The aponeurosis of the external oblique is composed of tendinous fasciculi, directed
obliquely downward and inward, like the fleshy fibres with which they are continuous.
It is also perforated, especially in the neighbourhood of the linea alba, by a considerable
number of bloodvessels and nerves. Not unfrequently the component fasciculi have
between them, especially near the femoral arch, linear or triangular spaces of variable
size, through which the fibres of the internal oblique are visible. The component fas-
ciculi are also intersected at right angles, and, as it were, bound down by other tendi-
nous fibres, which are more or less developed in different individuals, and are most usu-
ally situated in the neighbourhood of the femoral arch.
Having made these preliminary observations, we shall now describe in detail, 1. The
lower margin of the aponeurosis of the external oblique, or the femoral arch; and, 2. The
inguinal ring and canal.
Th& Femoral or Crural Arch. — ^When the aponeurosis of the external oblique has ar-
Fig. 136. rived opposite a line extending from
the anterior superior spinous pro-
cess of the ilium to the spine of the
pubes, it suddenly terminates, be-
comes thickened, and is reflected
(a a', fig. 137) from before back-
ward upon itself The reflected
border {pp',figs. 136, 137) has been
variously denominated the femoral
or crural arch, the reflected margin
of the teiidon of the external oblique,
PouparVs ligament, and the ligament
of Fallopius. , This arch, which is
stretched like a cord, corresponds
to the fold of the groin, and defines
the limits of the abdomen and the
lower extremity : it forms the ar
terior border of a considerable tri-
angular space, which is completed
by the ilium (I, fig. 136) on the out-
side, and by the os pubis (2) behind.
This space establishes a communi-
cation between the lower extremi-
ty and the abdomen, and is occupied (proceeding from without inward) by the psoas and
aiacus muscle (» to i), the crural nerve (n), the femoral artery (a) and vein {v), and the
pectineus muscle.*
The crural arch is directed somewhat obliquely downward and inward ; and as its out-
er third is more oblique than the inner two thirds, it describes externally a slight curve,
having its concavity directed upward. Its lower or reflected border is continuous with
the fascia of the thigh. This adhesion occasions the tension of the arch, as may be
shown by cutting the femoral fascia at the point of its junction with the arch : hence
the precept of Scarpa, who recommended incisions to be made in this situation, in order
to relieve the constriction in femoral hernise.
The free margin of the reflected portion of the aponeurosis, of which the femoral arch
* This is not represented in the woodcut.
^^
THE CRURAL ARCH. 303
consists, is continued backward into the iliac fascia («') externally ; and internally, into
the fascia transversalis (t).
Externally near the psoas and iliacus (beyond a', fig. 137), the posterior or reflected
portion of the arch is closely blended with its anterior or direct portion, as well as with
the iliac fascia and the fascia of the thigh, so that, in this situation, there is a thickening
rather than an actual reflection of the aponeurosis. Internally to the psoas and iliacus,
however (at a), the direct and reflected portions are perfectly distinct, and form a groove
with its concavity upward, which we shall find to assist in the formation of the inguinal
canal. These two separate portions of the inner part of the femoral arch require a spe-
cial description.
The direct portion (part of which is shown turned downward at d, fig. 137) passes on
to be attached to the spine of the pubes (p,figs. 136, 137), becoming more and more
prominent, so that it can be easily felt under the skin, especially when the thigh is ex-
tended upon the pelvis. The reflected portion, externally, is narrow, and, as it were,
folded ; but internally it becomes expanded, from its fibres slightly changing their direc-
tion, and diverging, so as to be inserted into the spine of the pubes behind the direct
portion, and also into the pecten or crest of the pubes.
This reflected and expanded portion, described even in the oldest anatomical works,
has become celebrated in recent times under the improper name of Gimbernat's ligament
{g,fig. 136), from a Spanish surgeon, who pointed out its importance as the seat of stric-
ture in femoral hernia. It is triangular in shape ; its anterior margin corresponds to the
crural arch ; its posterior margin to the crest of the pubes ; its outer margin is free, con-
cave, tense, and sharp, and forms the inner part of the circumference of the crural ring
(r). This concavity, against which the protruded intestine becomes strangulated, has
obtained for the ligament the name of the falciform ligament or fold.* Its strength is
very considerable ; but, occasionally, intervfds are left between its fibres, through which
hernial protrusions may take placet
From the lower surface of Gimbernat's ligament a fibrous prolongation is given off,
which sometimes represents a second arch below the femoral arch, and assists in form-
ing the superficial layer of the fascia lata of the thigh. This tendinous expansion has a
great effect in rendering the arch tense. We may add, that there is considerable vari-
ation in different subjects, both in the strength and development of Gimbernat's liga-
ment ; varieties that must have great influence on the position of crural herniae, and on
the seat of strangulation in that disease. Behind the femoral arch, on the outer side of
Gimbernat's Ugament, is an opening (a to r,fig. 136) or rkig, intended to give passage to
the femoral artery (a) and vein (v), and to a great number of lymphatic vessels and glands :
this is the crurcU ring.X The sub-peritoneal cellular tissue sometimes acquires great
strength opposite this ring, and constitutes what is called the crural septum (situated at r).
The form of the crural ring is that of an isosceles triangle, the base of which is very
long, and formed by the cniral arch, the inner border by the pectineus, and the outer by
the psoas and iliacus muscles. Of the three angles, the internal is rounded, and corre-
sponds to the concave margin of Gimbernat's ligament ; the external angle, opposite
which the epigastric artery is situated, is very acute, and corresponds to the point at
which the femoral arch separates from the iliac fascia ; the posterior angle is very ob-
tuse, and corresponds to the ilio-pectineal eminence {d).
The femoral vein is in relation with the inner or pectineal border of this triangular
space ; the femoral artery with the ilio-pectineal eminence and the outer border. The
crural nerve («) lies behind and externally to the artery, being separated from it only by
the iliac fascia («')• Crural herniae descend through the inner portion of the crural ring.^
The femoral arch is formed by proper fibres, arising from the anterior superior spinous
process of the ilium ; and also by those fibres of the aponeurosis of the external oblique,
which, after having arrived at the arch, change their direction, become reflected inward,
and are collected together, so as to form a strong and tense cord.
The Inguinal Ring and Canal. — On the inner side of the spine of the os pubis, between
the spine and the symphysis, the aponeurosis of the external oblique divides into two
almost parallel, or at least very slightly diverging, bands, which leave between them an
opening for the passage of the spermatic cord in the male, and of the round ligament in
the female. This opening is the inguinal ring {m,figs. 109, 136, 137), and the bands
which form its limits are called the pillars (o p, figs. 136, 137). The inguinal ring is oval
or triangular ; its greatest diameter has the same direction as the fibres of the external
obUque, viz., obliquely downward and inward. Its base corresponds to the interval be-
* tTnis term is now generally applied (after Bums) to the external margin of the saphenous opening {n,Jig.
137) in the fascia lata.]
t M. Laugier has lately recorded a case of hernia through the fibres of Gimbernat's ligament. I have since
had an opportunity of seeing, in an old woman at the Salptr^iere, two hernial sacs near each other, one of
which protruded through the crural ring, and the other internally to the ring; the necks of these sacs wer«
separated by a fibrous band, which appeared to me to be formed by the external fibres of Gimbernat's ligament.
X [The term " crural ring," it must be remembered, is limited by British anatomists and surgeons to the
small space (r), bounded internally by the free margin of Gimbernat's ligament, and externally by the femora]
vein. It is through this space, and therefore through the internal portion only of the " crural ring" of M
CrUTcilhier, that crural hemiEB descend.] I) See note, supa.
304
APONEUftOLOGY.
Fig. IS". tween the spine and
symphysis pubis. Its
apex is not always
well defined, and is
generally truncated
by fibres which pass
at right angles to its
pillars. From the up-
per part of the margin
of the ring a tendi-
nous prolongation is
given off, which ac-
companies the sper-
matic cord in the
male, and the round
ligament in the fe-
male.
Of the pillars, one
is external or inferior,
the other internal or
superior. The external
pillar (p) is attached,
not to the spine of the
OS pubis, but into the fore part of the symphysis : this pillar is nothing more than the in-
ternal extremity of the direct portion of the femoral arch. Moreover, some anatomists
consider Gimbemat's ligament as the reflected portion of the external pillar. The internal
pillar (o) is broader than the external, and intersects the corresponding structure of the
opposite side in front of the symphysis, not unfrequently some fibres of the right internal
pillar intersecting those of the left external pillar.
Inguinal Canal or Passage. — The inguinal ring^ {m) is the anterior or cutaneous orifice
of an oblique passage, formed in the substance of the lower edge of the inferior parietes
of the abdomen opposite the crural arch, and destined to transmit the cord (s) of the
spermatic vessels in the male, and the round ligament of the uterus in the female. This
passage, which modern writers only have correctly described, has been styled by them
the inguinal canal (i c wi). Its length varies from an inch and a half to two inches and a
half; it is directed obliquely downward, forward, and inward.
The inguinal canal is formed, in reality, by the groove resulting from the reflection
backward of the aponeurosis of the external oblique (at a), the posterior border of which
groove is continuous with the fascia transversalis, and its anterior border with the apo-
neurosis of the external oblique itself We may, then, consider this passage as having
an inferior concave wall (at a) formed by the groove of reflection ; an anterior wall, formed
by the aponeurosis of the external oblique (shown turned downward at d) ; and a posterior
wall, formed by the fascia transversalis (c). There is no superior wall, or, rather, it is sup-
plied by the lower margins of the internal oblique (c) and transversalis (/) muscles,
which occupy the groove of the crural arch, and receive from it externally numerous
points of attachment. Internally the margins of these muscles are separated from the
groove by the spermatic cord, or the round ligament. It has been supposed that this
canal is lined by a funnel-shaped prolongation of the fascia transversalis. The peritoneal
or interrml orifice (t, figs. 110, 137) of the inguinal canal is much less accurately defined
than the external, or, rather, its inner border alone is well defined, consisting of a concave
fibrous edge fonned by the fascia transversalis, and somewhat analogous to the concave
edge of Gimbemat's ligament. The strangulation of the intestine in inguinal hernia
sometimes occurs against this edge. The peritoneal orifice of the inguinal canal is closed
by the peritoneum, and the epigastric artery runs aloug its inner border.
The testicle, which is originally situated within the abdomen, descends through the
inguinal canal ; so, also, do those herniae, commonly called oblique inguinal hemis, in
order to distinguish them from the direct or internal inguinal herniae.
The Anterior Aponeurosis of the Obliquus Internus and Transversalis. — The aponeurosis
of the internal oblique commences at the linea alba, and immediately divides in its upper
three fourths into two layers, one of which passes in front, and the other behind the rectus
(r, fig. 1 34). The lower fourth passes entirely in front of the same muscle without division
(as shown in^^. 135). The anterior layer is very closely united with the aponeurosis of
the external oblique (at b), from which it can be distinguished only by the direction of
its fibres. In some parts there is even a true interlacement between the tendinous fibres
of these two muscles ; the lower or undivided portion of the aponeurosis of the internal
oblique may, on the contrary, be easily separated from that of the external oblique. The
posterior layer of the aponeurosis of the internal oblique is no less intimately blended with
that of the transversalis (at c), from which, also, it is to be distinguished by the direction
of its fibres only. At the outer border of the rectus muscle the anterior layer of the apo-
THE FASCIA TRANSVERSALIS, ETC. 305
aeuroFis of the internal oblique separates from that of the external oblique, and the pos-
terior .ayer from that of the transversalis, and then immediately unite together, and give
origin to the fleshy fibres. The outer margin, therefore, of the aponeurosis of the internal
oblique exactly corresponds to the outer border of the rectus, and is directed vertically.
The aponeurosis of the transversalis (/, Jigs. 134, 135) is the deepest layer of the an-
terior abdominal aponeurosis : it is very narrow above, increases in breadth as far down
as opposite the crest of the ilium, and then progressively diminishes towards its lower
portion. It commences at the linea alba, and is divided into two portions : one inferior
(below s,Jig. 110), consisting only of the lower fourth of the aponeuroses, and passing in
front of the rectus (as in Jig. 135) ; the other superior (above s, Jig. 110), which passes
behind the rectus (as in^^. 134), and is formed by the upper three fourths of the apo-
neurosis. Its external margin is convex, and gives origin to the fleshy fibres of the
muscle. Its anterior surface is closely united to the aponeurosis of the internal oblique,
beyond which it passes on the outside : its posterior surface is loosely connected with
the peritoneum, excepting in its lower fourth, which, as already stated, passes in front
of the rectus muscle. The tendinous fibres of the transversalis, which have the same
direction as its fleshy fibres, are occasionally found not to terminate abruptly behind the
lower part of the rectus ; but the aponeurosis merely becomes thinner, and its fasciculi
separated from each other.
The Fascia Transversalis and Sub-peritoneal Aponeurosis,
In order to complete the description of t"he anterior abdominal aponeurosis, it only re
mains for me to describe the fascia transversalis, which I regard as a thickened portion
of the sub-peritoneal fascia.
The fascia transversalis (seen at a' and c,Jig. 137) was first pointed out by Sir Astley
Cooper, but has been more correctly described by Lawrence and J. Cloquet : it com-
mences below at the reflected border (a a') of the crural arch, so that it may be regard-
ed as a thin prolongation of the reflected portion of the tendon of the external oblique.
It also frequently arises from the brim of the pelvis, as well as from the crural arch.
From these points it passes upward, becoming more and more attenuated as it approach
es the umbilicus, at which point it cannot be distinguished from the sub-peritoneal apo-
neurosis.
The fascia transversalis is situated between the abdominal muscles and the peri-
toneum. Its internal margin is continuous with the outer border of the rectus muscle ;
and its external margin, which gradually becomes thinner, is blended with the sub-peri-
toneal aponeurosis. The only part deserving a special description is that portion which
lies between the outer border of the rectus muscle and the abdominal opening of the in-
guinal canal. In this situation it assists in strengthening the parietes of the abdomen,
which are here remarkably weak ; and it is to the existence of this fascia that we may
attribute the extreme rarity of direct inguinal hemiae*, which, in fact, can only result
from a congenital weakness, or a relaxation of this fascia.
A very interesting portion of the fascia transversalis is an infundibuliform prolonga-
tion, given off from it to the spermatic cord. It is impossible, indeed, to conceive the
descent of the testicle to occur without its pushing before it a portion of the fascia,
which then constitutes the immediate investment of the cord upon which the cremaster
muscle {b,Jig. 137) is spread out. The peritoneal orifice of the inguinal canal is, there-
fore, the superior opening of the infundibuliform process, furnished by the fascia trans-
versalis to the testicle and its cord.
The Sub-peritoneal Aponeurosis.
The peritoneum, throughout the whole extent of the abdominal parietes, is strength-
ened on its outer surface by a very thin tendinous layer, the existence of which may
serve to explain why abscesses, formed in the parietes of the abdomen, so seldom open
into the cavity of the peritoneimi ; and, on the other hand, why collections within the
peritoneal cavity so seldom open externally.
The Posterior Abdominal Aponeurosis.
The posterior abdominal aponeurosis is much smaller and of less importance than the
anterior : it consists of three layers, one anterior (Ji, in diagram,/^. 134), and very thin,
which commences at the base of the transverse processes of the lumbar vertebrae, and
passes in front of the quadratus lumborum {q) ; another, middle («), and much stronger,
commencing at the summits of the same transverse processes, and passing behind the
quadratus lumborum ; and a third, posterior (k), which arises from the summits of the
lumbar spinous processes, and passes behind the sacro-lumbalis, longissimus dorsi, and
transverso-spinalis muscles («). This last-mentioned layer is connected both with the
internal oblique (e) and with the transversalis muscle (/), and is blended with the apo-
neuroses of the serratus posticus inferior, and of the latissimus dorsi (/). The two an-
* [/. e., herniiE occurring directty downward and forward throagh the inguinal ring {.rn,jig. J 37), and not
descending along the inguinal canal.l
Qq
306 APONEUROLOGY.
terior layers are connected with the transversalis only. The posterior abdominal apo-
neurosis has, therefore, nearly the same relation to the quadratus lumborum and the
common mass of the sacro-lumbalis, longissimus dorsi, and transverso-spinalis muscles,
that the anterior aponeurosis has to the rectus muscle.
The Lumho-iliac Aponeurosis.
The lumbo-iliac aponeurosis, or fascia iliaca of modem authors, forms the tendinous
sheaths of the abdominal portion of the psoas and ihacus muscles, and is, therefore, bi-
furcated at its upper part. That portion which invests the psoas commences at the ten
dinous arch of the diaphragm, already described as embracing the upper end of this mus-
cle. The iliac portion arises from the whole extent of the inner border of the crest of the
ilium. The circumflex ilii artery is situated in the substance of this iliac portion, at its
origin. The internal margin of the fascia iliaca is attached to the sides of the lumbar
vertebrae, and, lower down, to the brim of the pelvis ; it is arranged in arches, which
give passage to the lumbar vessels and to the nervous cords, establishing a communica-
tion between the lumbar plexus and the lumbar ganglia of the sympathetic nerve. The
centre of each arch is opposite to the groove on one of the bodies of the lumbar verte-
brae, the intervals between the arches corresponding with the intervertebral substance.
The largest arch extends from the last lumbar vertebra to the brim of the pelvis, and is
opposite to the base of the sacrum. The obturator and lumbo-sacral nerves pass under it.
Opposite the femoral arch, the fascia iliaca adheres intimately to the outer part of
Poupart's ligament ; but towards the median line it separates from that ligament, passes
behind the femoral vessels, and forms the posterior half {s,Jig. 136) of the crural ring.
Below the femoral arch, the fascia is prolonged upon the thigh ; on the outside («') it
completes the sheath of the psoas and iliacus, accompanies them as far as the lessei
trochanter, and becomes continuous with the iliac portion {g, fig. 137) of the femoral
fascia ; on the inside, it forms the posterior wall (s, fig. 136) of the canal for the femoral
vessels, and forms the deep layer or pubic portion {h,fig. 137) of the femoral fascia.
Relations. — It lies beneath the peritoneum, to which it is united by a very loose cellu-
lar tissue ; it covers the psoas and iliacus, but is not adherent to them, in consequence
of the interposition of some equally delicate cellular tissue. All the nerves from the
lumbar plexus are subjacent to this fascia, excepting one very small cord, which perfo-
rates it at the side of the sacrum, and becomes situated in the sub-peritoneal cellulai
tissue. The femoral vessels are situated on the inner side of the fascia, and are separ-
ated by it from the crural nerve, which lies on its outer side, and underneath it.
Structure. — The upper part of the fascia is extremely thin, but it increases in thick-
ness as it approaches the femoral arch. It is formed of well-marked transverse fasci-
culi, intersected perpendicularly by the tendon of the psoas parvus, when that muscle
exists. This tendon is blended with the fascia, and is distinguished from it only by the
different direction of its fibres ; it is inserted by spreading out, at the side of the pelvic
brim, into a tendinous arch which lines this brim, and with which the psoas parvus and
the iliac fascia are continuous above, and the pelvic fascia below.
Few aponeuroses are more deserving the attention of anatomists than this, on account
of the practical consequences resulting from its arrangement. In fact, notwithstanding
its tenuity, it forms a boundary between the sub-peritoneal and sub-aponeurotic cellular
tissue, which is very rarely passed by inflammatory action. When inflammation termi-
nates in suppuration, the pus, whether it be beneath the peritoneum or beneath this fas-
cia, descends towards the femoral arch ; but if the inflammation be sub-peritoneal, the
femoral vessels lie behind the purulent collection ; and should it be sub-aponeurotic, the
vessels will be in front of it. The latter is especially the case in abscesses following
caries of the vertebrae.
The Aponeuroses of the Pelvis.
The aponeuroses of the pelvis should be distinguished into the pelvic, properly so called,
and the perineal : the former constitute essential parts of the pelvis, and are deeply seat-
ed. The others belong to that part of the floor of the pelvis which is called the perineum.
I shall commence with the description of the latter.
The Aponeuroses of the Perineum.
These are two in number ; one superficial, the other deep.
The Superficial Perineal Fascia.*
Dissection. — Remove tne sub-cutaneous adipose tissue very cautiously, layer by layer,
commencing the dissection along the edges of the pubic arch.
This aponeurosis (which is very distinct from the fibrous laminae, intercepting spaces
filled by fat, and forming what is called the fascia superficialis) is of a triangular shape,
and consists of well-marked transverse fibres. The outer margin of each half of the fas-
cia is attached to the descending ramus of the os pubis and the ascending ramus of the
ischium : its inner margin is lost at the raphe, along the median line : its posterior maX'
* M Bouvier, in his thesis, and M. Blandin, in his Traiie d'Anaiomie Chirurgicale, first described this fascia
THE DEEP PERINEAL APONEUROSIS.
807
Fig. 138.
^a IS bounded by a line extending from the tuberosity of the ischium to the anus ; it cor-
responds with the posterior edge of the transversus perinei muscle, and appears to be
reflected behind it, so as to line the corresponding perineal or ischio-rectal fossa.*
Relations. — It is covered by a prolongation of the dartos, to a greater extent in the me-
dian line than on each side ; also by the sub-cutaneous adipose tissue, which is thicker
behind than in front, and by the sphincter ani, above which it terminates in the median
line : it covers the transversus, the bulbo-cavernosus, and the ischio-cavernosus mus-
cles, the fibrous sheaths of which may even be regarded a^ a prolongation of this aponeu-
rosis. It also covers the superficial perineal vessels and nerves, which are sometimes
lodged within its substance. The existence of this membrane explains why, in cases
of perforation of the urethra, the urine is infiltrated forward, and very rarely backward.
The Deep Perineal Aponeurosis.
Dissection. — Remove with great care the ischio- and bulbo-cavernosus and the trans-
versus perinei muscles.
This aponeurosis, which was well described by M. Carcassone under the name ofpe.
rineal ligament, and called by
modern writers the middle pe-
rineal fascia, appears to me
perfectly distinct from the
aponeuroses of the pelvis. It
is an extremely strong trian-
gular layer {b a, fig. 138t), oc-
cupying the pubic arch, and
apparently forming a continu-
ation of the sub-pubic ligament
(jb). It is vertical near the
arch, as far as the ball of the
urethra, below which it be-
comes horizontal, or, rather,
oblique, from before back-
ward. Its lateral margins are
attached to the descending ra-
mi of the ossa pubis, and the
ascending rami of the ischia
{d, d), above the attachment of
the ischio-cavernosi muscles. Its posterior margin becomes blended with the posterior
margin of the superficial perineal fascia, behind the transversi muscles, in front of the
perineal fossse, of which it forms the anterior boundary.
Relations. — Its lower surface is in relation with the ischio- and bulbo-cavernosus mus-
cles, and gives off, in the median line, a fibrous septum, which passes between these
muscles, and affords them points of attachment. Its upper surface is in relation with
the artery or arteries (e e) of the bulb, which are sometimes contained within its sub-
stance : it is also in contact with a very remarkable plexus of large veins, with which it
is very closely united, so that, when divided, they remain open : these veins are also fre-
quently enclosed within its substance. It is also in relation with the levator ani.
There constantly exists another transverse muscle, very distinct from the transversus
perinei generally described, which is situated farther behind. This muscle (transversus
perinei alter. Alb.) is applied to the lower surface of the perineal fascia, and passes trans-
versely inward to the bulbous portion of the urethra.
The deep fascia of the perineum is perforated (at c) by the posterior part of the bulb
of the urethra, or, rather, by the point of union (c, fig. 181) between its bulbous and
membranous portions : it gives off prolongations upon the sides of the bulb, and serves
to support the membranous portion of the urethra : whence the name, triangular liga-
ment of the urethra, given to it by CoUes. It is also perforated, beneath the arch of the
pubes, by a great number of veins, and by some arteries.
Uses. — This remarkable aponeurosis evidently supports the canal of the urethra. It
has been correctly regarded as an obstacle to the introduction of the catheter, the point
of which strikes against it, however slightly it may deviate from the direction of the ca-
nal. The prostate gland is situated above it.
The Pelvic Jlponeuroses.
From the sides of the pelvis, and from the entire circumference of the brim (which, as
* Sec note, p. 309.
t [The triangular liganfient consists of two layers, which approach each other more ne.irly above tliati below .
m^g- 138, the anterior layer has been removed. Between the two layers are situated the sub-pubic ligamoa
(A), perforated by the vena dorsales penis, the pudic arteries (//), the arteries of the bulb (e e), the g^eat
part of the membranous portion of the urethra, with its comjjressor muscle, to be described hertaftiir, an.
lastly, Cowper's glands (g g). In the female, the triingular ligament is perforated by the vagina, as wel
bv the urethra.]
308 APONEUROLOGY.
we have seen, is covered and rendered smooth by a thick layer of fibrous tissue, that
forms a hmit to the lumbo-iliac aponeurosis), a tendinous lamina is given off, which pass-
es into and lines the pelvis, and is soon divided into two distinct layers : one external,
the lateral pelvic or obturator fascia, which continues to line the sides of the pelvis, and
covers the obturator intemus muscle ; the other internal, or superior, which passes in-
ward upon the side of the prostate gland, bladder, and rectum, in the male, and of the
bladder, vagina, and rectum, in the female, in order to form the floor of the pelvis. This
IS the superior pelvic aponeurosis, with the description of which we shall commence.
The Superior Pelvic Aponeurosis, or Recto-vesical Fascia.
Dissection. — This aponeurosis must be studied both from the cavity of the pelvis and
from the perineum. It is exposed in the pelvis by removing the peritoneum, and the
loose cellular tissue beneath that membrane : this should be done without any cutting
instiument. To view this fascia from the perineum, it is necessary to take away the
adipose tissue that occupies the perineal fossae, and also the levator ani muscle.
The superior pelvic aponeurosis forms a complete floor for the pelvis. Anteriorly it is
remarkable for its strength and shortness ; in fact, it does not reach the inlet in this sit-
uation, but arises on each side from the symphysis pubis, presenting the appearance of
bands or columns, which are more or less separated from each other, and become at-
tached to the front of the neck of the bladder, whence the name of anterior ligament of
the bladder, which the older anatomists gave to this part of the aponeurosis. More exter-
nally, it forms a strong arch (the sub-pubic arch), which completes the posterior orifice of
the obturator or sub-pubic canal (i, fig. 48). This arch is not unfrequently double, and
then one of the foramina gives passage to vessels, and the other to nerves.
Still more externally, it is attached to the brim of the pelvis, in the manner I have al-
ready pointed out.
Posteriorly it is extremely thin, passes in front of the sciatic plexus, and is lost upon
the sacrum. Sometimes it appears to be divided into two lamina, the posterior of which
passes in front of the sciatic plexus, and the anterior in front of the internal ihac vessels,
to which it would seem to furnish sheaths.
Relations. — Its upper surface is concave, and connected with the peritoneum by loose
cellular tissue, containing more or less fat. Its lower surface is convex, and covered by
the levator ani : it forms part of the great perineal excavation, and is in relation with
the pjTiformis and obturator intemus mucles, with the sacral plexus, &c.
This aponeurosis is perforated by a great number of openings : in the male it is pierced
by the prostate {i,fiff. 181) and the bladder (h), on the sides of which it is prolonged, and
reflected on to the rectum, whence the name of the recto-vesical aponeurosis, given to it by
M. Carcassone. In the female it is also perforated by the vagina. On each side of the
bladder and prostate it is strengthened by two tendinous bands, which run from before
backward. These are sometimes very strong ; they extend from the symphysis pubis
(6) to the spine of the ischium (e), pass along the bladder and the prostate, and are re-
flected upon their sides.
In front, it has some openings for the vesical and prostatic vessels.
Behind it presents a considerable opening, which corresponds to the outlet of the pel-
vis, and gives passage to the lumbo-sacral nerve and the gluteal vessels. The extrem-
ity of the arch formed by it corresponds to the anterior border of the sciatic notch. It
is through this opening that sciatic herniae protrude.
We not uncommonly find larger or smaller openings in this fascia, of an oblong or cir-
cular shape, leading into conical culs-de-sac, which are filled with fat. Lastly, it is per-
forated behind by the ischiatic and internal pudic vessels. It does not appear to be in-
tended for the passage of the vessels which are distributed in the interior of the pelvis,
for it seems to invest these in fibrous sheaths.
Uses. — The superior pelvic aponeurosis forms the floor of the pelvis ; it is pushed
downward by the action of the diaphragm and abdominal muscles, and tends to prevent
the occurrence of perineal herniae, which otherwise would be extremely common : it
forms a boundary between the sub-peritoneal and the perineal cellular tissue, and also
limits the progress of inflammation and infiltrations. Infiltration of urine above the fas-
cia can only be caused by rupture of the bladder itself The prostate {i,fig. 181) is al-
most entirely below the fascia, and therefore, in the lateral operation for stone, in which
this gland is the principal structure to be divided, inflammation and infiltration of the
cellular tissue are extremely rare. When they do occur, the section or laceration must
have been prolonged into the body of the bladder.
The Lateral Pelvic Aponeurosis, or Fascia of the Obturator Muscle.
Dissection. — ^This aponeurosis is more advantageously studied, at least in its most impor-
tant part, from the perineum, than from the cavity of the pelvis : it is exposed on either
side by removing the adipose tissue, which fills up the perineal fossa. This aponeurosis,
which is quite distinct from the obturator ligament, commences at the upper part of the
circumference of the obturator foramen, and at the brim of the pelvis, in connexion with
THE FEMORAL APONEUROSIS. 30P
the superior pelvic aponeurosis, which it soon leaves, and is applied to the obturator in-
temus muscle : it then unites below with the reflected portion of the great sacro-sciatic
ligament, and is prolonged upon that portion of the anterior surface of the glutaeus max-
imus which projects beyond the ligament, and also upon the coccygeus muscle.
Relations. — On the inner side and above, it is only separated from the superior pelvic
aponeurosis by the levator ani, which is applied to that aponeurosis ; lower down, the
two aponeuroses are separated by a considerable interval, which is occupied by fat : this
interval forms the perineal fossa. On the outside it is in contact with the obturator in-
ternus, and lower down with the internal pudic vessels and nerves.
Uses. — It binds down the obturator internus muscle, and protects the internal pudic
vessels and nerves, which are, therefore, rarely cut in operations in the perineum. It
forms the external boundary of the perineal fossa.
TTie Perineal Fosscb. — Situated between the superior pelvic aponeurosis (which is lined
below by the levator ani) and the lateral pelvic aponeurosis, there is found on each side
of the anus a conical space, the base of which is directed downward, and corresponds
to the skin : it is formed behind by the lower border of the glutaeus maximus ; in front,
by the transversus perinei muscle ; on the inside, by the levator ani and the superior pel-
vic aponeurosis ; and on the outside, by the tuberosity of the ischium.* Each of these
fossae is filled by a large quantity of fat, and traversed by fibrous laminae, some of which
extend vertically from the apex to the base, and divide the contained adipose ceUular
tissue into several distinct portions. When an abscess occurs in either of these fossae,
it may be easily conceived how difficult it is for the inner surface of its parietes to come
into opposition : hence the pathology of fistulae, and the modes of cure which are adopted.
The Aponeuroses of the Lower Extremity.
The aponeuroses of the lower extremity comprise the femoral fascia ; the fascia of the
leg ; the annular ligaments, which bind down the tendons of the muscles of the leg, as
they are passing upon the dorsal or plantar surface of the foot ; the plantar and dorsal
fascia of the foot ; and, lastly, the fibrous sheaths, which maintain the tendons in con-
tact with the phalanges of the toes. We shall describe these in succession.
The Femoral Aponeurosis, or Fascia Lata.
After the remarks which we have already made upon the aponeuroses generally, it
may be easily conceived that the muscles of the thigh, which are so numerous, of such
great length, and so loOsely united together, and almost all of which are reflected to a
greater or less amount over the knee, require to be kept in close contact with each oth-
er and with the bones ; hence the necessity for the femoral' aponeurosis, consisting of a
large fibrous sheath, that confines without compressing the muscles, and the strength of
which is directly proportioned to the force of the muscles, and their tendency to dis-
placement. Its superficial or sub-cutaneous surface {g h,fig. 137) is separated from the
skin by a very thin fibrous layer, the fascia superficialis (not shown in fig. 137), which
can be more easily demonstrated immediately below the femoral arch, and along the sa-
phenous vein. Between the femoral aponeurosis or fascia lata and this superficial fas-
cia, which results from the union of the fibrous prolongations given off by the deep sur-
face of the skin, the sub-cutaneous vessels and nerves take their course, and communi-
cate with the deep vessels and nerves, either by simple openings or by fibrous canals, of
variable length. Under this fascia, also, are situated the superficial lymphatic vessels
and glands of the groin.
A great number of the superficial nerves of the thigh have special sheaths, which are
hollowed out, as it were, in the substance of this aponeurosis.
The femoral aponeurosis is perforated with a great number of foramina opposite the
femoral vessels, from Poupart's ligament to the entrance of the vena saphena {x) into
the femoral vein (y). These foramina, which occupy a triangular space, of which the
base is above and the apex below, are intended for the ' passage of a great number of
lymphatic vessels, which pass through it to join the deep set. This has been called the
sieve-like portion of the fascia lata, or the fascia cribriformis (v) : it has been said by some,
that the aponeurosis is altogether wanting in this situation.! We not unfrequently find
a lymphatic gland occupying one of the foramina.
* [These spaces are the ischio-recial fossie of Velpeau ; they are described by him as if lined by an aponeu-
rosis (the ischio-rectal) composed of two layers, one external or ischiatic, corresponding to the lateral pelvic
aponeurosis of M. Cruveilhier, and another internal or rectal, which covers the lower surface of the levator
ani from the coccyx to the posterior border of the transversus perinei, and unites with the other layer before,
above, and behind. This latter layer is very thin, and continuous with the united margins of the superficial
perineal fascia and the triangular ligament, behind the transverse muscle, and is alluded to by M. Cruveilhier
(p. 307) as a reflection of the superficial fascia. 1
t [And then the cribriform fascia is regarded, not as belonging to the fascia lata, but as formed by a deep
layer of the superficial fascia, situated beneath the sub-cutaneous vessels, adherent to the borders of the saphe-
nous opening in the fascia lata, and perforated by those vessels. The saphenous opening is, according to this
view, not the foramen (t) through which that vein passes, but the aperture (n) left between the iliac (g) and
pubic (A) portions of the fascia lata, and is bounded externally by the crescentic margin of the iliac portion
or the falciform process of Bums (see the left side of Jiff. 137, where the cribriform fascia has been enlirelj
removed).]
310 APONEUROLOGY.
The most remarkable of all these openings is undoubtedly that (i) for the vena saphena
interna, where that vessel enters the femoral vein, at the upper part of the thigh, eight
or ten lines below Poupart's ligament. The margin of this opening, which has been
improperly called the inferior orifice of the crural canal, can only be demonstrated in its low-
er half, on account of the almost complete absence of the aponeurosis above it : this is
the reason of the semilunar form of the portion of the fascia over which the vein passes.
The deep surface of the fascia lata gives off a great number of prolongations, which
pass between the muscles, and form their proper investments or sheaths.
The largest of these prolongations form two lateral septa, called the inter-muscular sep-
ta, which extend from the fascia to the linea aspera ; each has the form of a triangle,
having its base directed downward and its apex upward ; they are extremely thick, es-
pecially below.
The Inter-muscular Septa of the Femoral Aponeurosis.
Of these there are two, one internal and the other external.
The Internal Inter-muscular Septum. — This serves at once as a septum, an aponeurosis
of insertion, and a sheath for the vastus intemus : it extends from the anterior inter-
trochanteric line to the inner condyle of the femur.
Its anterior surface affords attachments to the vastus intemus throughout its whole
extent : its posterior surface is in opposition with the adductors, and is intimately uni-
ted to their aponeuroses. Its outer margin is attached to the Unea aspera : its inner
margin is very thick, and prominent below, where it is strengthened by the inferior ten-
don of the adductor magnus, and may be felt under the skin like a cord. It appears to
become continuous below with the internal later£il ligament of the knee.
It is composed of very strong vertical fasciculi, passing somewhat obliquely down-
ward and inward. These fasciculi are bound together above the inner condyle by oth-
ers passing transversely, and are crossed almost at right angles by the tendinous fibres
of the adductors.
Lastly, the internal septimi is perforated, near the linea aspera, by a number of orifices
destined for the passage of vessels, and forming communications between the anterior
and the internal sheath of the muscles of the thigh.
The External Inter-muscular Septum. — This serves as a septum, an aponeurosis of in
sertion, and as a sheath for the vastus extemus.
It extends from the great trochanter to the external condyle, above which it forms a
projecting cord : it affords attachments to the vastus extemus in front, and to the short
head of the biceps behind. . Its inner margin is attached to the linea aspera : its outer
margin forms a prominent cord, especially below.
It consists of fibres directed vertically, or somewhat obliquely outward, and strength-
ened by transverse fibres above the condyle. Like the internal septum, it is perforated,
especially above and below : above, for the passage of the circumflex vessels ; below,
for the passage of the articular vessels of the knee.
We shall now examine the different sheaths fiirnished by the femoral aponeurosis.
One of the most important of these is, as it were, hollowed out of the sides of the others,
and belongs to the femoral vessels.
The Sheath of the Femoral Vessels.
The femoral artery (z,fig. 137) and vein (y) are enclosed in a prismatic and triangular
tendinous canal, which protects them in their course amid the muscles of the thigh.
The portion of the canal (laid open in fig. 137) included between the femoral arch and
the point where the vena saphena opens into the femoral vein, has received the name
of the crural canal, a term to which I have always objected, since it was first introduced
into anatomical nomenclature, because it establishes a false analogy between the ingui-
nal canal and this upper portion of the sheath of the femoral vessels ; for, while an
oblique inguinal hernia traverses the entire length of the inguinal canal, crural herniae,
as far, at least, as my own observation extends, never protrude through the saphenous
opening, but escape inunediately below the femoral arch, and lift up the cribriform por-
tion of the fascia lata.*
The anterior wall of the sheath of the femoral vessels is formed above by the cribri-
form portion of the femoral fascia (g',fig. 137), then by the fascia itself, and, lastly, by
the posterior layer of the sheath of the sartorius, in which place it is thin and transparent.
Tlie internal wall is formed above by the very strong layer covering the pectineus ; be-
low, by the weaker layer investing the adductors.
The external wall consists of the very strong sheath {s',fig: 136) of the psoas and ilia-
cus : externally to this wall is situated the crural nerve, a branch of which perforates
* [The tenn "crural ring" is, in this country, commonly limited to the space (r,fig. 136) situated internal-
ly to the femoral vein. By the term " crural canal" is generally understood that portion only of the canal de-
scribed by M. Cruveilhier as the " craral canal," which is situated on the inner side of the femoral vein, and
is occupied by cellular tissue, lymphatic vessels, and sometimes by a lymphatic gland. If the term crural ca-
nal be thus defined, if the cribriform fascia be regarded as a part of the superficial fascia, and the saphenous
aperture as the space between the iliac and pubic portions of the fascia lata (see note, p. 309), the analogy be-
tween the crural and inguinal canals will not be so very remote.]
THE FEMORAL APONEUROSIS. 81 J
the sheath and joins the vessels. Lower down, the external wall is formed by the apo
neurosis of the vastus internus.
The three great Muscular Sheaths of the Femoral Aponeurosis.
By means of the internal and external inter-muscular septa, the muscles of the ante-
rior region of the thigh are separated from those of the posterior and internal regions ;
a weaker septum than the preceding intervenes between the muscles of the internal
and posterior regions. It foUows, then, that the femoral aponeurosis presents three
great tendinous sheaths : an anterior, an internal, and a posterior.
The great posterior sheath is undivided : it is common to the biceps, the semi-tendino-
sus, and the semi-membranosus.
The great anterior and internal sheaths are subdivided into a number of secondary
uheaths, in most cases corresponding with the number of the muscles.
The great Anterior Sheath. — The sartorius has a proper sheath, remarkable for its pris-
matic and triangular form. The rectus femoris, or long head of the triceps, is separated
from the two vasti by a tendinous layer, very thin below, but strong above, and com-
posed of vertical fibres.
The tensor vaginae femoris is contained in the strongest sheath in the human body,
for it is formed by the fascia lata itself The deep layer of this sheath is much thinner
than the superficial ; it commences at the anterior inferior spinous process of the ilium,
below the rectus, and may be regarded eis the deep origin of the ^road band in which
the tensor vaginae femoris terminates : it is composed of verticed fibres, prolonged be-
tween the rectus and the vastus externus. Lastly, above and on the outside, we find
the sheath of the psoas and iliacus {s',fig. 136), which forms a continuation of the lum-
bo-iliac aponeurosis, or fascia iliaca.
The great internal sheath furnishes a number of tendinous lamellae, which separate the
different muscles of this region. Thus, there is a proper sheath for the gracilis, a com-
mon one for the pectineus and the adductor longus, one for the adductor brevis, and an-
other for the adductor magnus. The sheath of the obturator externus is continuous
with that of the adductor brevis ; it commences by a very strong fibrous lamina or arch,
which arises from the anterior edge of the pubes, and is directed obhquely outward to
the fibrous capsule of the hip-joint. This arch conceals the anterior orifice of the obtu-
rator canal, and protects the obturator vessels and nerves.
Lastly, the two vasti, which extend into all the regions of the thigh, have sheaths
formed by the femoral fascia, where they are superficial, and by the internal and exter-
nal inter-muscular septa, and the posterior laminae of the other sheaths in their more
deeply-situated portions.
In the midst of the sheaths of the anterior and internal regions we find the sheath of
the femoral vessels already described.
The Superior Circumference of the Femxiral Aponeurosis.
In front the femoral aponeurosis arises from the femoral arch, with which it is so pei-
fectly continuous as to render the arch tense : hence the plan, already mentioned as
proposed by Scarpa, of endeavouring to remove the constriction in cases of strangulated
crural hernia, by puncturing the femoral aponeurosis.
But the mode of origin and continuity of this fascia with the femoral arch is not the
same on the inner and outer sides. On the outside, the iliac portion of the femoral apo
neurosis (g, fig. 137) arises by a single very thick layer ; more internally, in the situation
of the femoral vessels, it arises by two layers, one superficial, thin, and perforated by
foramina (the cribriform portion, v) ; the other deep, called its pubic portion (A), which is
continuous with the fascia iUaca (s,fig. 136), covers the pectineus, and sends off a pro-
longation between that muscle and the psoas. This deep layer forms the posterior wall
of the canal of the femoral vessels.
On the inside of the thigh, the femoral aponeurosis arises from the body of the os pu-
bis and the ascending ramus of the ischium.
On the outside and behind, it arises from the crest of the ilium by very numerous ver-
tical fibres, which are strengthened, especially behind, by other horizontal fibres. Be-
tween the posterior superior spine of the ilium and the crest of the sacrum there is a
tendinous arch, which is common to the femoral fascia and the aponeurosis of the long
muscles of the back.
The Glutceal Aponeurosis.
The glutaeal aponeurosis forms the upper and back part of the femoral fascia. It cov-
ers the glutaeus medius, in which situation it is extremely thick, and is continuous with
the broad band of the tensor vaginae femoris. Having reached the upper border of the
glutaeus maximus, it is divided into two layers : one superficial and very thin, which
covers the outer surface of the gluta;us maximus, becomes thinner below, and continu-
ous with the femoral fascia ; the other deep and thicker, especially above and behind,
where it affords attachment to the glutaeus maximus, and is blended with the great sa-
cro-sciatic ligament. It becomes ver}' thin whe: e it separates the gluta3us maxirau?
312 APONEUROLOGY.
from the deep-seated muscles. A synovial capsule intervenes between this fascia and
the great trochanter, and another between it and the tuberosity of the ischium.
It presents a very remarkable opening called the glutaal arch, for the passage of the
glutseal vessels and nerves. Lastly, over that portion of the glutaeus maximus which
enters into the formation of the corresponding perineal fossa, it acquires a great degree
of thickness, and, at the lower border of the muscle, is blended with the superficial layer
of the gluteal fascia.
The Inferior Circumference of the Femoral Aponeurosis.
The femoral aponeurosis terminates below, around the knee-joint, where it becomes
continuous, partly with the fascia of the leg, and partly with the fibrous structures cov-
ering this articulation. Concerning the arrangement of these fibrous laminae we shall
offer a few remarks.
Behind, the femoral aponeurosis passes over the popliteal space, and is continuous
with the fascia of the leg.
In front, it is prolonged over the patella, from which it is separated by a synovial bur-
sa; it is very thin, and is continued in front of the ligament of the patella, upon which
it forms a thin layer of transverse fibres.
071 the inside, it is at first blended with the sheath of the sartorius, and then with the
horizontal portion of the tendon of this muscle ; it crosses the fibres of that portion per-
pendicularly, and becomes continuous with the fascia of the leg.
Under this layer of fibrous tissue we find, on the inside of the knee, another very dense
layer, formed by vertical tendinous fibres derived from the vastus internus, and inserted
into the upper part of the inner surface of the tibia, beneath the tendon of the sartorius.
This fibrous layer, which may be regarded as the lower or tibial insertion of the vastus
extemus, occupies the interval between the internal lateral ligament of the knee-joint
and the patella. Its vertical fibres are crossed by others at right angles, extending from
tne internal tuberosity of the femur to the corresponding margin of the patella.
Lastly, under this we find another very thin layer, belonging to the synovial capsule.
On the outside, the femoral aponeurosis is blended with the broad band of the tensor
vaginae femoris, from which it can be distinguished only by the horizontal direction of
its fibres.
Beneath this very thick layer we find a thin one, composed of fibres stretching from
the external tuberosity of the femur to the patella ; and, lastly, another thin layer be-
longing to the synovial membrane.
Structure of the Femoral Aponeurosis.
It is thin behind and on the inside, thicker in front, and extremely thick on the out-
side of the thigh, where, indeed, it may be said to exceed all other fibrous membranes in
thickness and in strength. This thickened portion is bounded in front by a line extend-
ing vertically downward from the anterior superior spinous process of the ilium. Its lim-
its behind are no less distinctly defined ; hence the name given to it of the broad hand
{fascia lata).
This great density is owing to some very strong vertical fibres, arising from the front
of the crest of the ilium. It is connected with the great force and tendency to displace-
ment of the vastus externus.
We may add, that the femoral aponeurosis is composed of horizontal fibres, sometimes
regularly parallel, as in its thinnest portions, and sometimes intersecting each other.
These horizontal fibres are even seen opposite the broad band on the outer side, from
which they are distinguished by their direction.
There is a very beautiful preparation of this aponeurosis in the Museum of the Facul-
ty of Medicine : similar preparations should be made by those who wish to obtain a good
idea of the tendinous sheaths, and the shape of the muscles of the thigh. It is to be
made by removing all the muscles from their sheaths by means of longitudinal incisions,
and substituting for them a quantity of tow, which must be taken out when the aponeu-
roses are completely dried. The form of the sheaths exactly represents that of the cor-
responding muscles. A tolerably accurate idea of these sheaths may also be obtained
by cutting across each sheath and the muscle which it contains, in a fresh subject. The
circumference of the section of the portion of the sheath that becomes visible after the
retraction of the muscle will give an excellent idea of the figure of the different sheaths,
which are all angular and polyhedral like the muscles, but never rounded : during health
they are completely filled by the muscles, which in emaciated persons, on the contrary,
do not occupy more than a half, a third, or a sixth of the area of their sheaths.
Such is the femoral fascia. Its tensor muscles consist of the tensor vaginae femoris and
the glutaeus maximus, the tendon of which is received between two layers of this fascia.
Aponeuroses of the Leg and Foot.
Aponeurosis of the Leg.
The aponeurosis of the leg forms a strong general investment for the whole leg, except-
ANNULAR LIGAMENTS OF THE TARSUS. 313
mg the internal surface of the tibia, which is covered by it only at its lower part, a little
above the malleoli.
Its external surface is separated from the skin by the superficial vessels and nerves,
several of which perforate it, either directly, or after having run for a short distance in its
substance. The external saphenous vein and nerve receive from it a complete sheath.
Its internal surface covers all the muscles of the leg, and does not adhere to them ex-
cepting above and in front, where it gives attachment to the tibialis anticus and the ex-
tensor communis digitorum. From the internal surface there proceeds on the outer side
of the leg two principal tendinous septa, one situated between the muscles of the ante-
rior tibial region and the peronei, the otlier between the peronei and the muscles of the
posterior region of the leg. There are, therefore, three principal sheaths in the leg, an
anterior, an internal, and a posterior. The latter is subdivided into two other sheaths
by a very strong transverse lamina, becoming still stronger below, which separates the
muscles of the deep posterior layer and the posterior tibial and peroneal vessels and
nerves from the superficial layer of muscles, or the triceps suralis. Lastly, some tendi-
nous laminae, more or less complete, are interposed between the different muscles of
each region. Thus, a tendinous layer separates the tibialis anticus, at first from the ex-
tensor communis digitorum, and then from the extensor proprius pollicis : this layer dis-
appears in the middle of the leg. Another very strong tendinous lamina separates the
tibialis posticus from the flexor longus digitorum on the one hand, and from the flexor
longus pollicis on the other.
Superior Circumference. — If we now examine the manner in which the aponeurosis
of the leg becomes continuous with that of the thigh, we shall find that, posteriorly, the
femoral fascia is prolonged directly upon the leg, in order to form the posterior part
of its aponeurosis, which, in this situation, also receives an expansion from the ten-
dons of the biceps, sartorius, gracilis, and semi-tendinosus, and from the broad band of
the fascia of the thigh. Anteriorly the fascia of the leg is continous with that of the
thigh over the patella, and appears also to arise directly from the outer edge of the ante-
rior tuberosity of the tibia, from the head of the fibula, and from the tendon of the biceps,
which, as we have already seen, gives off an aponeurotic expansion backward.
By its lower circumference this fascia is continuous with the annular ligaments of the
ankle, which we shall presently describe.
Structure. — On examining the direction of the fibres and the thickness of the fascia of
the leg, it is found that it is much thicker in front than on the outer side of the leg, and
still more so than behind ; that, in the first situation, in the ujpper three fourths of its ex-
tent, it is composed of obliquely interlaced fibres, some of which descend from the spine
of the tibia, and others from the anterior angular surface of the fibula ; and that in the
lower fourth of the anterior region of the leg, and in the whole extent of the posterior re-
gion, it is composed of circular fibres.
At the point where the muscles of the leg become tendinous, and are reflected over
the ankle, they require very strong sheaths to keep them in contact with the joint ; the
fascia of the leg, therefore, forms, opposite this part, the anterior, internal, and external
annular ligaments.
The Annular Ligaments of the Tarsus.
The annular ligaments of the tarsus are three in number : an anterior or dorsal, an in-
ternal, and an external.
The dorsal annular ligament of the tarsus. The aponeurosis of the leg is thicker at the
lower and anterior part of the leg, and binds down the corresponding portion of the mus-
cles in that region. But there is, in addition to this, a dorsal annular ligament of the
tarsus (see fig. 128), which arises, by a narrow but thick extremity, in front of the as-
tragalo-calcanean fossa, becomes broader as it extends inward, and is divided into two
bands. The superior band passes upward and inward above the internal malleolus, and
is split into two layers, in such a way as to form two complete sheaths : one internal,
for the tibialis anticus ; the other external, for the extensor longus digitorum and the
peroneus tertius. Between these two complete sheaths, which are separated from the
synovial capsule of the joint by a layer of cellular tissue, we find an incomplete sheath
(for the annular ligament is not split into two layers in this situation), intended for the
extensor proprius pollicis and the anterior tibial vessels and nerves : the internal sheath is
the higher, and situated opposite the lower extremity of the tibia ; the external sheath
is lower, and corresponds to the ankle-joint. The inferior band, or the lower bifurcation
of the annular ligament, passes forward and inward to the front of the tarsus, and be-
comes continuous with the internal plantar aponeurosis. This lower band forms a sec-
ond annular ligament, which furnishes to each of the three preceding muscles, upon the
dorsum of the foot, a less powerful sheath than that afforded by the upper band : it keeps
the tendons closely applied to the bones.
The external and internal annular ligaments of the tarsus are two fibrous bands, contin-
uous with the fascia of the leg on the one hand, and with the plantar aponeurosis on the
other.
Rr
i
314 APONEUROLOGY.
The internal annular ugament arises from the borders and summit of the internal mal-
leolus, and proceeds in a radiating manner to the inner side of the os calcis, and the in-
ner margin of the internal plantar aponeurosis. Beneath this sheath, which is thick-
er below than above, and closes in the concavity on the inner surface of the os cal-
cis, proceed the posterior tibial vessels and nerves, and also the tendons of the tibialis
posticus, the flexor longus digitorum, and the flexor longus poUicis. For these several
parts there are four very distinct sheaths : the most superficial is that for the vessels
and the nerves ; two sheaths, placed one over the other (see Jig. 130), and behind the
internal malleolus, belong, the anterior to the tibialis posticus (w), and the posterior or
more superficial to the flexor longus digitorum (o). These two sheaths soon separate
as the two tendons diverge from each other towards their insertions : as the sheath of
the tibialis posticus is continued as far as the insertion of that muscle, the sheath of the
flexor longus digitorum accompanies it to where it gets beneath {i. e., deeper from the
surface than) the plantar fascia. The sheath of the flexor longus pollicis {p) is lower
than the preceding, and extends obliquely along the astragalus and os calcis, to be cov-
ered by the internal plantar fascia.
The external annular ligament forms a common sheath for the two peronei, longus et
brevis : it extends from the border of the external malleolus to the os calcis, and is
completed on the inside by the external lateral ligaments. It is at first single, but soon
becomes subdivided into two other sheaths, one of which is destined for the tendon of
the peroneus brevis, and the other for that of the peroneus longus.
The Aponeuroses of the Foot.
These are divided into the dorsal and plantar.
The Dorsal Aponeuroses of the Foot.
These comprise the dorsal aponeurosis, properly so called, the pedal aponeurosis (Vapo-
neurose pidieuse), and the dorsal interosseous aponeuroses.
Dorsal Aponeurosis of the Foot. — While the upper margin of the annular ligament is
blended with the fascia of the leg, which appears to be inserted upon it, the anterior
margin of the same ligament becomes continuous with the dorsal aponeurosis of the foot.
This dorsal aponeurosis is a thin layer, which forms a general sheath for all the tendons
situated upon the dorsum of the foot : it gradually disappears in front, opposite the an-
terior extremities of the metatarsal bones, and is attached at the sides to the borders
of the foot, becoming continuous with the plantar fascia. These tendons, again, are sep-
arated from the extensor brevis digitorum by another and still thinner layer, which in-
vests that muscle : this is the pedal aponeurosis ; lastly, upon the same surface of the
foot we find the four dorsal interosseous aponeuroses, viz., one for each interosseous space.
The Plantar Aponeuroses.
The plantar aponeuroses or fasciae are three in number : one middle, the other two
lateral.
The middle plantar aponeurosis is very strong, is attached to the inner of the posterior
tubercles of the calcaneum, becomes suddenly contracted, and afterward gradually ex-
pands without diminishing perceptibly in thickness. Opposite the anterior extremities
of the metatarsal bones, it divides into four bands, which are themselves bifurcated al-
most immediately, so as to embrace the flexor tendons of the four outer toes. Becom-
ing moulded on the sides of these tendons, they furnish those of each toe with an almost
complete sheath, which is attached to the upper and lateral borders of the anterior gle-
noid ligament of the corresponding metatarso-phalangal articulation, and becomes con-
tinuous with the tendinous sheath of the corresponding toe. These four sheaths are
separated by three arched openings, through which proceed the lumbricales and interos-
seous muscles, and the plantar vessels and nerves. There is a perfect analogy between
the middle plantar and the middle palmar aponeurosis ; but the former is by far the
stronger. It constitutes, indeed, a true ligament for the foot, offers a powerful resist-
ance to the forced extension of the phalanges upon the bones of the metatarsus, and sup-
ports the antero-posterior arch of the sole of the foot. I have known exceedingly vio-
lent pain to be produced by distension, and, probably, laceration of some of the fibres of
this aponeurosis. The margins of the middle plantar aponeurosis are curved upward,
so as to embrace the flexor brevis digitorum on each side ; they become continuous
with the external and internal plantar aponeuroses, and form septa between the muscles
of the middle and those of the external and internal plantar regions : in front these septa
are complete, but only partial behind. The upper surface of this fascia gives attach-
ment, posteriorly, to the short flexor of the toes : the proper tendinous expansion of this
muscle appears to be given otf from the upper surface of the plantar aponeurosis.
Some transverse fibres strengthen this fascia in front, and I shall also notice some
other transverse fibres, perfectly distinct from the preceding, which form a true trans-
verse ligament for the four outer toes : it is situated opposite the middle of the lower
surface of the first phalanges, and is admirably adapted for opposing their dislocation.
The External and Internal Plantar Aponeuroses. — The external plantar aponeurosis, very
THE APONEUROSES OF THE SHOULDER. 315
thick behind and thin in front, gives attachment by its upper surface to the abductor
muscle of the Httle toe, and is bifurcated at the posterior extremity of the fifth metatar-
sal bone. The external division of this bifurcation is very strong, is inserted into the
enlarged posterior extremity of the fifth metatarsfd bone, and may be regarded as a pow-
erful medium of connexion between that bone and the cuboid. The internal plantar apo-
neurosis is thin in comparison with the external ; it commences behind by an arch, ex-
tending from the inner malleolus to the os calcis ; its inner margin is attached to the
corresponding border of the tarsus, and is continuous with the dorsal annular ligament
and with the dorsal fascia of the foot ; its outer margin is blended with the middle plan-
tar fascia, or, rather, is reflected upward, to complete the sheath for the internal mus-
cles of the foot.
These three plantar fasciae just described form three sheaths, which are quite distinct
in their anterior five sixths, but communicate with each other behind.
The internal plantar sheath includes the abductor and the short flexor* of the great
toe, which are separated from each other by a layer of fibrous tissue ; it also contains
the internal plantar artery and nerves.
The external plantar sheath includes the abductor and the flexor of the little toe, Avhich
are also separated by a tendinous layer. Lastly, the middle plantar sheath includes the
short flexor of the toes, the tendon of the flexor longus digitorum, the flexor accesso-
rius, the lumbricales, the tendon of the flexor longus poUicis, the oblique adductor,! the
transversus pedis, and the external plantar vessels and nerves. The sheath of the
flexor brevis digitorum is completed above by an aponeurotic layer, which separates it
from the tendons of the long flexor and from the accessorius. A prope\' sheath exists
for the oblique adductor,+ and a subdivision of the same sheath for the transverse ad-
ductor. It is formed above by the interosseous aponeuroses, and below by a thin layer
attached to the circumference of the deep hollow in which the adductors are lodged.
Lastly, the inferior interosseous aponeurosis is remarkable for its thickness, and for the
septa which it gives off between the interosseous muscles.
The sheaths into which the flexor tendons of the toes are received opposite the pha-
langes resemble so exactly those of the fingers, that I shaU not anticipate what will be
said hereafter regarding the latter. We find the same system of synovial membranes,
and the same loose, membranous, and extensible cellular tissue for the flexor tendons
of the toes as for those of the fingers. In all sheaths that are partly osseous and partly
tendinous, we find a synovial membrane ;t but, on the other hand, there is nothing more
than a loose cellular tissue in situations where a tendon or muscle ghdes in the interior
of a confining aponeurosis.
The Aponeuroses of the Upper Extremity.
Tliese comprise the aponeuroses of the shoulder ; the brachial aponeurosis ; the apo-
neurosis of the forearm ; the dorsal and anterior annular ligaments of the carpus ; the
palmar aponeurosis ; and, lastly, the sheaths for the tendons of the flexor muscles of the
fingers.
The Aponeuroses of the Shoulder.
These are the supraspinous, the infror spinous, the sub-scapular, and the deltoid aponeu-
roses.
The supraspinous aponeurosis is a thick layer of fibrous tissue, attached to the entire
circumference of the supra-spinous fossa, and converting it into a sort of osteo-fibrous
case, that serves as a sheath for the supra-spinatus muscle, to which it also affords sev-
eral points of attachment. This tendinous layer is gradually lost, externally, under the
acromio-coracoid arch.
The infra-spinous aponeurosis is an equally dense and strong fibrous lamina, attached
to the entire margin of the infra-spinous fossa, and completing the osteo-fibrous sheath
of the infra-spinatus muscle : it is continuous on the outside with the brachial fascia, and
gives off from its anterior surface a thick septum intervening between the scapular at-
tachments of the teres major and those of the teres minor, and also some thinner septa
interposed between the teres minor and the infra-spinatus, and between the different
portions of the infra-spinatus muscle itself
The deltoid aponeurosis. The infra-spinous aponeurosis having reached the posterior
border of the deltoid muscle, splits into two layers : of these, the superficial layer invests
the deltoid, and terminates in the brachial aponeurosis ; the deep layer continues to cover
the tendon of the infra-spinatus, and becomes attached to the tendon of the short head
of the biceps. Some very loose cellular tissue, or even a synovial bursa, separates this
aponeurosis from the head of the humerus, and the tendons inserted around it.
The subscapular apo7icurosis is a very thin membrane, which completes the sheath of
the sub-scapularis, and gives the muscle some points of attachment. It is fixed to the
entire margin of the sub-scapular fossa.
* [/. e., the inner half of the flexor brevis pollicis of anatomists generally.]
t [Including the outer portion of the flexor brevis pollicis of most anatomists.]
t See note on ApoNE urology, p. 296.
I
APONEUROLOGY.
The Brachial Aponeurosis.
The brachial aponeurosis commences above at the clavicle, the acromion, and the spine
of the scapula, and is continuous with the infra-spinous aponeurosis : on the inner side
it arises from the tendons of the pectoralis major and the latissimus dorsi ; and, in the
interval between them, from the cellular tissue of the axilla ; it envelops the arm as far
down as the elbow, where it becomes continuous with the fascia of the forearm, and is
attached to the different bony projections presented by the surface of that joint. Its su-
■perficiaJ, surface is separated from the skin by vessels and nerves, to which it furnishes
sheaths of greater or less extent. We may admit the existence of a superficial fascia
between the vessels and the skin.
Its deep surface presents various septa, dividing its interior into a certain number of thin
sheaths for the several muscles. It is composed almost entirely of circular fibres, some
of which have a somewhat spiral direction : these fibres are intersected at right angles
by others passing vertically downward to the fascia of the forearm.
The brachial aponeurosis is so loose as to permit the free exercise of the muscles con-
tained within it, yet sufficiently tense to prevent their displacement.
It is slightly thickened on either side, along the outer and inner borders of the humerus,
and gives off in those situations two very strong inter-muscular septa : one external, the
other internal. These septa are in every respect analogous to those of the femoral
fascia, and divide the brachial sheath into two great compartments : an interior, contain-
ing the muscles on the anterior aspect of the arm, viz., the biceps, the brachialis anti-
cus, and the coraco-brachialis, also the upper or brachial portion of the supinator longus,
and the extensor carpi radialis longior ; the posterior compartment belongs to the triceps.
The external inter-muscular septum arises from the anterior border of the bicipital
groove, by a narrow and very thick extremity, blended with the posterior margin of the
tendon of the deltoid ; it reaches the outer border of the humerus, expands and becomes
somewhat thinner, and separates the anterior from the posterior muscles, more espe-
cially the triceps from the brachialis anticus, affording attachments to them both. It is
perforated very obliquely by the musculo-spiral or radial nerve, and the superior profunda
artery, which at first lie behind, but are afterward in front of it. The sheath of this
nerve and artery establish a free communication between the anterior and posterior com-
partments already alluded to.
The internal inter-muscular septum, broader and thicker than the preceding, but, like it,
of a triangular form, arises from the posterior border of the bicipital groove, below the
teres major, is continuous with the tendon of the coraco-brachialis, crossing it at a very
acute angle, and becoming partially united to and blended with it, proceeds along and
adheres closely to the inner border of the humerus, and terminates at the inner condyle
or epitrochlea of that bone. Both of these septa are formed by bands and fibres given
off in succession from the corresponding borders of the humerus, and they both afford
attachments to the brachialis anticus in front, and to the triceps behind. The ulnar
nerve is anterior to the internal septum in the upper part of the arm, but perforates it,
and remains in contact with its posterior surface, passing between the attachments ot
the triceps.
From these two great sheaths the proper sheaths of the muscles proceed. First, the
deltoid has its proper sheath : another thin aponeurotic layer, gradually becoming thicke?
from above downward, consisting almost entirely of vertical fibres, and forming one of
the origins of the aponeurosis of the forearm, separates the biceps from the brachialis
anticus ; again, the brachial vessels and the median nerve have a special sheath, which
also receives at its upper part the basilic vein, and the ulnar and internal cutaneou*
nerves ; this is the brachial canal, the counterpart of the femoral canal ; it establishes a
communication between the cellular tissue of the axilla, and that in the bend of the
elbow ; lastly, a tendinous layer separates the upper half of the long head of the triceps
from the other portions of that muscle : the sheath of the coraco-brachialis is given ofl
from the inner edge of the biceps.
We must consider as dependances of the common brachial investment the several
sheaths furnished by it to the cephalic, basilic, and median veins, to the branches of the
internal cutaneous nerve, and to the superficial ramifications of the musculo-cutaneous
nerve. When an artery or a vein previously situated under an aponeurosis becomes
sub-cutaneous, the perforation in the aponeurosis is almost always of an arched form.
The brachial aponeurosis has no muscle analogous to the tensor vaginae femoris ; the
pectoralis major and the latissimus dorsi are sufficient to effect its tension.
The Aponeurosis of the Fokeakm and Hand.
The Aponeurosis of the Forearm.
Dissection. — ^Make a circular incision through the skin, immediately above the elbow,
and from this let two vertical incisions be carried downward to the wrist, one in front
and the other behind ; let the incisions extend through to the fascia, without dividing it ;
then cautiously remove the skin, being careful to take Math it the sub-cutaneous adipose
THE APONEUROSIS OF THE FOREARM. 31*3
tissue ; the superficial veins and nerves may be preserved. The external surface of the
fascia may be studied first, and its several sheaths afterward opened in succession.
The aponeurosis, or fascia of the forearm, ■^orms a general sheath, entirely surrounding
or embracing that portion of the upper extremity, with the exception of the posterior
border of the ulna. It is semi-transparent, and hence can be seen to be traversed by
white lines, generally vertical in their direction, which indicate a corresponding number
of thickenings of the sheath, and inter-muscular septa given off from them.
It is separated from the skin by the superficial veins and nerves ; by its upper part it
gives numerous attachments to the subjacent muscles, and this renders the dissection
very difficult. By making a vertical incision, however, along the separate sheath which
it furnishes to each of the muscles, and then carefully removing the latter, a good idea
may be formed of the numerous angular compartments into which the common cavity
of the fascia is subdivided. In the first place, it will be seen that this fascia, like all
other investing aponeuroses, is composed of proper and superadded fibres ; that the
proper fibres are nearly or quite circular, are more or less oblique, and more or less in-
terlaced, but the superadded fibres are vertical. It will be found that it is twice as thick
upon the dorsal as upon the palmar surface of the forearm ; that its thickness and its
strength increase from above dowTiward ; and that it is strengthened by a great number
of superadded fasciculi, consisting of aponeurotic expansions from the tendons of the
adjacent muscles. Thus, the brachialis anticus on the outside, the biceps on the inside
and in front, and the triceps behind, give off tendinous expansions to this aponeurosis :
of these the most remarkable is, without doubt, that given off from the biceps, which
muscle may be regarded, indeed, as the tensor of the anterior portion of the fascia.
This expansion constitutes, in fact, one of the terminations of the biceps, with the ex-
ternal fasciculi of which it is continuous, and, moreover, arises from the outer edge and
the anterior surface of its tendon. This expansion, so important in consequence of its
relations with the brachial artery, passes obliquely inward and downward, and, as it ex-
pands, intersects at right angles the vertical fasciculi proceeding from the epithrochlea
and epicondyle of the humerus. These last-mentioned fasciculi also appear to me to be
supplementary ; they are continuous with the common tendons of origin of the external
and internal muscles of the forearm, and constitute the anterior walls of those two mul-
tilocular pyramids, of which one is on the inner, the other on the outer side of the fore-
arm, or of that series of trumpet-shaped cavities (cornets), as M. Gerdy calls them, from
each of which the muscles of these regions take their origin. I must not omit to men-
tion the thick tendinous band, which arises from the entire length of the posterior border
of the ulna, divides into two layers to give origin to the flexor carpi ulnaris, and by its
internal or deep surface affords attachment to the flexor sublimis.
In the fascia of the forearm there are numerous foramina for the passage of vessels
and nerves, but I shall direct attention to one very large orifice existing in front, at the
bend of the elbow, and bounded on the inside by the outer margin of the tendinous ex-
pansion of the biceps. This opening establishes a free communication between the sub-
cutaneous and the sub-aponeurotic cellular tissue at the bend of the elbow, and leads
into a sort of fossa, in which are found the tendon of the biceps, the brachial artery, the
commencement of the radial artery, and the median nerve. This fossa is lined by apo-
neurotic laminae : on the outside, by the layer which covers the inner surface of the supi-
nator longus, the radial extensors, and the flexor sublimis ; on the inside, by the layer
which completes the sheath of the pronator teres : it communicates above with the canal
of the brachial artery, and below with the canals through which the radial, ulnar, and
interosseous arteries and the median nerve proceed downward to the forearm.
From the internal surface of this fascia a number of laminaj are given off, to form the
following muscular sheaths :
In the anterior region of the forearm, a transverse septum, thicker below than above,
divides the superficial layer of muscles from the middle layer, consisting of the flexor
sublimis, and also from the deep layer, composed of the flexor profundus digitorum and
the flexor longus pollicis. Other septa, passing from before backward, divide the mus-
cles of the superficial layer from each other. Lower down the sheaths of the flexor carpi
radialis and palmaris longus, which are perfectly distinct from each other, are situated
in front of the remainder of the fascia ; and this has led to the statement of some anat-
omists, that the fascia is perforated by the tendons of these muscles, especially by that
of the palmaris longus. The radial artery has a special sheath throughout its whole ex-
tent ; the ulnar artery and nerve have a proper sheath only in the lower part of the forearm.
In the posterior region of the forearm, the fascia is much stronger than in the anterior.
A transverse layer separates the muscles of the superficial from those of the deep layer;
and septa, passing from behind forward, subdivide these common sheaths into several
smaller ones, corresponding in number to that of the muscles. Thus, we find a sheath
for the extensor communis digitorum, a second for the extensor digiti minimi, a third
for the extensor carpi ulnaris, and a fourth for the anconeus. The supinator longus and
the two radial extensors of the wrist appear to be in the same sheath ; but a more or
less distinct membrane surrounds the first of these muscles : the supinator brevis has
318 APONEUROLOGY.
also a proper sheath. We find a common sheath for the extensor longus poUicis and the
extensor proprius indicis. The abductor longus and the extensor brevis poUicis, which,
properly speaking, constitute but one muscle, have also a common sheath accompanying
them as far as the dorsal annular ligament of the wrist.
The Dorsal Annular Ligament of the Wrist, and the Dorsal Aponeurosis of
the Metacarpus.
The dorsal annular ligament of the wrist (r, Jig. 121) may be considered as a depend-
ence of the fascia of the forearm, which in this situation is strengthened by a great
number of fibres. It is a band of six or eight lines in width, passing obhquely inward
and downward over the extensor tendons of the hand, perforated by a number of open-
ings for the passage of vessels, and distinguishable from the fascia of the forearm
only by its somewhat greater thickness and by the parallel arrangement of its fascicuU.
It arises internally from the pisiform bone and the palmar fascia, passes first over the
ulnar side, and then the posterior surface of the carpus, is interrupted by the outer mar-
gin of the groove for the two radi2d extensor muscles, takes a fresh origin from that mar-
gin, covers the radial side of the wrist, and is inserted partly into the radius, and partly
into the fascia of the forearm. From the anterior surface of this thick fibrous band
arise several small prolongations, which are interposed between the numerous tendons
passing over the dorsal and radial aspects of the carpus, and convert the grooves upon
the lower extremities of the radius and ulna into canals. Thus, proceeding from with-
out inward, and from before backward, we find, 1 . A sheath for the united tendons of the
abductor longus and extensor brevis pollicis ; 2 and 3. Two distinct sheaths opposite
the radius : one for the two radial extensors of the carpus, the other for the extensor
longus pollicis, which sheaths become blended together lower down into a single com-
pletely fibrous sheath ; 4. A fourth sheath, stronger than the preceding, for the extensor
communis digitorum and the extensor proprius indicis ; 5. An entirely fibrous sheath for
the extensor digiti minimi ; 6. A very strong sheath for the extensor carpi ulnaris,
which is prolonged below the ulna, and accompanies the tendon as far as the fifth meta-
carpal bone. All these sheaths are lined by synovial membranes,* which extend some
distance above the dorsal annular ligament, and, on the other hand, accompany the ten-
dons very far down, sometimes even to their insertions.
The dorsal aponeurosis of the metacarpus is a continuation of the dorsal annular liga-
ment : it is composed of a very thin layer of transverse fibres, and separates the exten-
sor tendons from the sub-cutaneous vessels and nerves. A very loose, extensible, and
elastic cellular tissue takes the place of the synovial membranes over these tendons, and
greatly facilitates their movements.
The Anterior Annular Ligament of the Carpus.
The deep groove upon the anterior surface of the carpus is converted into a canal by
a very thick fibrous band, viz., the anterior ligament of the carpus {g,fig. 118). It com-
mences internally by two well-marked origins, separated from each other by the ulnar
nerve, one being from the pisiform bone and the tendon of the flexor carpi ulnaris, the
other from the unciform bone. The first bundle passes downward, the second trans-
versely, and their united fibres, some of which are transverse and others interlaced, ter-
minate at the trapezium and the scaphoid, giving off an expansion to the fascia cover-
ing the ball of the thumb, with which they are continuous. This ligament is continuous
above with the fascia of the forearm, which is much thickened in this situation : it re-
ceives in front the expanded tendon of the palmaris longus, and terminates below in the
palmar fascia. Its anterior surface gives attachment to most of the muscles of the the-
nar and hypothenar eminences. A small portion only of this ligament is generally seen
and described, viz., the free portion. If it is wished to obtain a perfect conception of it,
the muscles attached to its anterior surface should be carefully removed ; it will then be
seen that, on the outside, it describes a curve having its concavity, directed inward, in
order to be attached to the scaphoid and the trapezium, and that the sheath of the flexor
carpi radiahs is contained in its substance : this sheath is entirely fibrous above, and
partly fibrous and partly osseous below, where it converts into a canal the groove on the
trapezium.
While there are almost as many synovial membranes as there are sheaths under the
dorsal ligaments of the carpus, on the palmar aspect nine tendons with the median nerve
form but a single bundle, which is lubricated by one or two synovial membranes. This
synovial membrane* presents a curious arrangement, subject, moreover, to numerous
varieties. It lines the posterior surface of the anterior annular ligament of the carpus
is prolonged above and below that ligament, and is reflected (without passing between
the different tendons) upon the anterior surface of the bundle formed by them and by the
median nerve, which is to their outer side. In order to obtain an accurate idea of the
termination of this synovial membrane, cut across the tendons at the lower part of the
forearm, and turn them forward upon the palm of the hand : it will then be seen that the
* See note, p. 296.
THE PALMAR APONEUROSIS, ETC. 319
synovial membrane is reflected upon the ulnar border of the bundle of tendons ; that it
lines the posterior surface of this bundle, passing more or less between the tendons, and
separating them from each other in a rather irregular manner ; that it is reflected upon
the groove of the carpus, prolonged upward and downward much farther than it was in
front, and divided below into four small prolongations corresponding to the flexor ten-
dons of each finger. Nor is this all, for there is a special synovial membrane for the
flexor longus poUicis. In order to expose this, the synovial membrane must be cut
through where it is reflected, on its radial side, from the annular ligament on to the me-
dian nerve and the anterior surface of the bundle of tendons : a special and very exten-
sive synovial membrane will then be seen to pass high up along the tendon of the flexor
longus pollicis, and to be prolonged downward as far as the last phalanx of the thumb.
The Palmar Aponeurosis.
The palmar fascia (,c,fig. 118) forms a common sheath for all the muscles of the palm
of the hand, and is divided into three portions, a middle and two lateral.
The middle portion. This is the only part generally described as the palmar fascia ;
it is triangular and strong, but of variable thickness : it binds down the numerous sub-
jacent tendons. It arises from the anterior surface and lower margin of the anterior
annular Ugament of the carpus, and from the tendon of the palmaris longus, which may
be regarded as its tensor muscle. Between these two origins the ulnar artery pene-
trates into the palm of the hand. Not unfrequently the expanded tendon of the palma-
ris longus forms a fibrous layer in front of the proper palmar fascia. This fascia is nar-
row and thick at its origin, but expands as it proceeds from above downward, and, op-
posite the heads of the metacarpal bones, divides into eight prolongations for the four
inner fingers. At the seat of this division we find very strong transverse fibres binding
the prolongations together, and preventing disjunction of the fingers and laceration of
the fascia. By this arrangement four arches are formed, under which the tendons of
the flexor muscles pass : between these four arches there are three smaller ones, giving
passage to the collater£il vessels and nerves of the fingers, and to the lumbricales, so that al-
together there are seven arches. These arches are true fibrous canals. In order perfect-
ly to understand their structure, make a vertical incision through the palmar fascia ; it will
then be seen that, opposite the arches, tendinous prolongations or tongues are detached
from the deep surface of the fascia : these prolongations turn round the sides of the ten-
dons so as to embrace them, and become continuous with the anterior or glenoid liga-
ment of the metacarpo-phalangal articulations : the same arrangement obtains with re-
gard to the three small arches for the vessels and nerves situated between the four prin-
cipal tendinous arches. The palmar fascia is, moreover, intimately united to the skin
by very numerous prolongations : its deep surface covers the superficial palmar arch of
the arteries of the hand, the median and ulnar nerves, and the flexor tendons ; a very
loose and extensible cellular tissue separates it from these parts, and facilitates the move-
ments of the tendons. From its inner margin is given off a very strong layer, which
becomes continuous with the interosseous aponeurosis, and separates the middle from
the internal palmar region ; a thinner layer proceeds from its outer margin, and passes
down between the muscles of the thenar eminence and the first lumbricalis muscle.
This small muscle, called the palmaris brevis (Jb,fig. 118), arises from the inner margin of
the middle palmar fascia, and is merely a cutaneous muscle.
The external and internal palmar fascia, or the thenar and hypothenar aponeuroses.
These consist of two rather thin fibrous layers, forming the sheaths of the muscles of
the ball of the thumb and those of the little finger : they are both continuous with the
middle palmar fascia : the external appears to consist, in a great measure, of an expan-
sion from the tendon of the abductor longus pollicis ; and the internal, of an expansion
from that of the flexor carpi ulnaris. At the limits between these aponeuroses and the
middle fascia are formed two septa, passing from before backward, and dividing the palm
of the hand into three distinct sheaths : one median, completed by the interosseous apo-
neurosis, and intended for all the flexor tendons and the principal vessels and nerves of
the hand ; the other two placed on either side, and binding down the muscles of the the
nar and hypothenar eminences.
The Sheaths of the Flexor Tendons of the Fingers, and their Synovial Mem-
branes.
After leaving the arches, or, rather, the curious sheaths, formed by the palmar fascia
immediately above the corresponding metacarpo-phalangal articulation, each pair of flex
or tendons is received into a special sheath, by which they are accompanied down to
the last phalanx. It will be remembered that the anterior surfaces of the first and sec-
ond phalanges are marked by a longitudinal groove ; to the two borders of this groove is
attached a very regular semi-canal of fibrous tissue, which is exactly large enough to
contain the two flexor tendons. This very strong sheath preserves its shape when the
tendons have been removed ; and a correct idea of its importance may be obtained by
observing the effects of contraction of the flexor muscles after it has been divided. This
320 SPLANCHNOLOGY.
sheath is formed of parallel semicircular laminae, placed one above the other, densely ag-
gregated over the bodies of the phalanges, and, for the most part, forming a continuous
sheath, but becoming more and more separated, and sometimes even completely disap-
pearing opposite the articulations and the articulating extremities of the bones. It ap-
pears to me that, in the movements of flexion, these articular rings are pushed into each
other. The sheath ceases altogether above the articulation of the second with the ter-
minal phalanx.
A very remarkable synovial membrane,* which is prolonged upward beyond the arch-
es formed by the palmar fascia, lines the whole lenth of each osteo-fibrous sheath on the
one hand, and on the other is reflected upon the two flexor tendons, affording each of them
a sheath, and forms two, often three or four triangular folds, having their bases directed
upward, and being perfectly analogous to the so-called adipose ligament of the knee-
joint. Of these folds, the superior is situated opposite the upper extremity of the first
phalanx, and extends from the tendon of the flexor sublimus to that of the flexor pro-
fundus ; the inferior fold passes from the bifurcation of the superficial tendon to the deep
tendon ; the others are intermediate, and proceed from the phalanx to the two tendons.
These synovial folds can be very well seen by raising and separating the flexor tendons
from the phalanges. Not unfrequently the synovial membrane forms a hernia between
two of these tendinous rings, either opposite the body of a phalanx, or, still more com-
monly, over one of the articulations. We may add, that these synovial folds are proba-
bly intended to support the nutritious vessels of the tendons, and not to connect these
tendons together.
SPLANCHNOLOGY.
General Observations on the Viscera. — External Conformation. — Structure. — Development.
— Functions. — Dissection.
Splanchnology (from crcTMyxvov, viscus) is that division of anatomy which treats of
organs more or less compound in their structure. Some of these are contained within
the three great visceral cavities (_the viscera), while others are situated without these
cavities {organs, properly so called), t
The brain, the spinal cord, the heart, and the organs of the senses, are generally in-
cluded in this division. I have thought it advisable, however, to confine myself here to
the description of the digestive, respiratory, and genito-urinary apparatus. The organs
of the senses, the brain, and the spinal cord will be studied more advantageously in con-
nexion with the rest of the nervous system, and the heart with the other organs of the
circulation.
As the organs we are about to examine have few relations with each other, they do
not admit of such extended and important general remarks as those which preceded the
osteological and myological divisions. I shall content myself with explaining briefly the
method in which the description of each organ should be pursued.
Every organ presents for consideration its external conformation, its internal confor-
mation or its structure, its development, and its functions.
The External Conformation of Organs.
The description of the external conformation of organs includes that of their nomen-
clature, number, situation, direction, size, shape, and relations.
Nomenclature. — The nomenclature of organs has not been subjected to so many chan-
ges as that of the bones and muscles : the names adopted by the oldest authors have
been retained in modern science, and are even used in common language.
The names of organs are derived, 1. From their uses, as the asophagus (from olu, I
convey, and (^ayo), I eat) ; also, the lachrymal and the salivary glands. 2. From their
length, as the duodenum. 3. From their direction, as the rectum. 4. From their shape,
as the amygdala (the tonsils). 5. From their structure, as the ovaries. 6. From the
name of the authors who have best described them, as the Schneiderian membrane, the
FaUopian tubes. Lastly, they are conventional words ; for example,the tongue, the liver, &c.
Number. — Some organs are single ; others exist in pairs. Varieties in number are
very common, both by excess and by defect. Thus, three kidneys have been found in
the same individual, and there is often only one. Examples have been recorded of in-
dividuals having three testicles ; one is uncommon. Lastly, varieties by excess almost
always result from the division, and those by defect, from the union or fusion of organs.
Situation. — This must be considered with regard to the region of the body occupied by
an organ, i. e., its general or absolute situation; and also with regard to its relations with
neighbouring organs, i. e., its relative situation. Thus, when it is stated that the stom-
* See note, p. 298.
t All the viscera are organs, but all the organs are not viscera. The word viscus is probably derived from
veacor, I eat, because a great number of the viscera are eng:aged in the functions of nutritioi .
STRUCTURE AND DEVELOPMENT OF ORGANS. 321
ach occupies the left hypochondrium and the epigastrium, its absolute or general situa-
tion is indicated ; but when it is added that this viscus is situated between the oesopha-
gus and duodenum, below the diaphragm, and above the transverse mesocolon, its relative
situation is implied.
Many of the organs are subject to varieties of position ; and this constitutes an im-
portant point in their history. These varieties of position depend upon congenital oi
upon accidental displacement, either affecting the particular organ only, or consequent
upon displacement of the neighbouring organs ; or they may result from a change in the
size of the organ itself
Size. — The absolute size of an organ is determined by linear measurements, by the
quantity of water which it displaces, and by its weight ; its relative size, by comparison
with bodies of a known size, or with other organs.
The size of organs is subject to a great number of varieties. These depend either on
age, as in the liver, testicles, and thymus gland ; on sex, temperament, or on individual
peculiarities ; also on the state in which an organ is found : for example, the uterus, pe-
nis, and spleen. Lastly, there are some pathological variations, which shoxild not be
omitted in a treatise upon descriptive anatomy.
Figure. — The figure of the organs treated of in splanchnology appears to follow these
rules. The double organs do not exactly resemble each other on the right and left sides
of the body. The single organs, occupying the median line, are symmetrical ; but most
of those which are removed from that line are not symmetrical. Nevertheless, symme-
try is not so completely wanting in the viscera belonging to nutritive life, as stated by Bi-
chat, for the stomach and the small and great intestines may be divided into two equal
halves.
In regard to their forms, organs are compared, in general, either with familiar objects,
or with geometric figures. Thus, a kidney is said to resemble a kidney-bean, and either
lung, a cone. In very irregular organs, we merely describe the surfaces and the borders.
We shall not find in the viscera the same constancy of form as exists in the organs of
relation.
Direction. — The direction of an organ is determined in the same manner as that of the
bones and muscles, viz., by its relations with the imaginary planes surrounding the body,
or with the mesial plane.
Relations. — The figure of an organ being determined, its surface is then divided into
regions, the relations of which are accurately ascertained. These regions are generally
termed surfaces and borders. As the situation of many organs is subject to great varie-
ties, their relations must also vary. Too much cannot be said of the value of an accu-
rate knowledge of these relations, from which a number of the most important practical
inferences may be derived.
The Internal Conformation &r Structure of Organs.
The surface of an organ being well understood, we next proceed to the study of its
structure, comprising its colour, its consistence, and its anatomical elements.
Colour. — The colour both of the surface and the substance of an organ requires to be
studied. All variations of colour should be very carefully noted. Age and disease have
much influence over it ; and it is often difficult to distinguish positively between its
physiological and pathological condition.
Consistence. — The consistence, density, and fragility of organs are connected with their
structure. The specific gravity or density of a single organ only, the lung, has been ac-
curately studied, and that in a medico-legal pomt of view. In estimating the con^^isience
and fragility of organs, we can only approximate the truth. It is desirable that some more
methodical and accurate means should be devised for the estimation of these qualities.
Anatomical Elements. — The determination of the immediate anatomical elements, or
tissues, which enter into the composition of an organ, together with their proportions
and their arrangement, constitutes the knowledge of its structure. Every organ has
either a cellular, fibrous, cartilaginous, or bony framework. Some organs are provided
with muscular fibres, or even with distinct muscles ; they all contain the several kinds
of vessels, viz., arteries, veins, and lymphatics ; and they edl possess nerves. The glan-
dular organs have excretory ducts.
In explaining the structure of organs, we shall, generally, confine ourselves to a brief
enumemtion of their constituent parts, referring to works on the anatomy of textures for
details which would be misplaced in an elementary treatise.
Tkt Devdopment of Organs.
The study of the development of organs, and the changes which they undergo at the
different periods of intra- and extra-uterine life, is of the greatest interest, at least as re-
gards some among them. The formation of the soft parts, however, is not nearly so weL
understood as that of the hard tissues, because the most important phenomena of devel-
opment occur during the first weeks after conception. The remarks upon this subject
will, therefore, generally point out some hiatus to be filled up.
Ss
822 SPLANCHNOLOGY.
The Functions of Organs.
The functions or uses of organs flow so naturally from their anatomical description,
that we shall follow the example of the greater number of anatomists, in adding to such
description a short account of the functions of an organ. We shall only notice particu-
larly those uses of organs which depend immediately upon their structure, referring to
physiological works for the details and discussions of yet disputed points in the science
of functions. No part of anatomy excites so much curiosity and interest as splanchnol-
ogy, in consequence of the importance of the organs of which it treats. Without a
knowledge of this department of anatomy, it is impossible to understand the mechanism
of functions the most indispensable to life ; and as the organs themselves are the seat
of the greater part of the lesions which are assigned to the physician, as well as of many
of those which fall under the care of the surgeon, most of the fundamental questions of
the heeding art require a profound knowledge of these organs.
The Dissection of the Viscera.
The dissection of organs does not consist in merely isolating them from surrounding
parts, which, as far as regards those contained in the visceral cavities, is done by sim-
ply laying open the latter, but in the separation of their anatomical elements or tissues.
For this purpose, injections of the most delicate kind, maceration, boiling, preservation
in alcohol, desiccation, the action of acids, in short, aS\. the resources of his art, are em-
ployed by the anatomist.
Having made these preliminary observations, we shall now describe in succession the
organs of digestion, the organs of respiration, and the genito-urinary apparatus.
THE ORGANS OF DIGESTION AND THEIR APPENDAGES,
ALIMENTARY OR DIGESTIVE CANAL.
General Observations. — Division. — Mouth and its Appendages. — Lips. — Cheeks. — Hard and
Soft Palate. — Tonsils. — Tongue. — Salivary Glands. — Buccal Mucous Membrane. — Pha-
rynx.— (Esophagus. — Stomach. — Small Intestine. — Large Intestine. — Muscles of the Pe-
rineum.— Development of the Intestinal Canal.
The organs of digestion form a long canal, the alimentary or digestive canal, extending
from the mouth to the anus, which receives alimentary substances, induces in them a
series of changes, by which they are rendered fit to repair the losses incurred by the
body, and, moreover, presents a vast absorbent surface for the action of the lacteal ves-
sels. The entire series of these organs constitutes the digestive apparatus.
Tlie existence of an alimentary canal is one of the essential characters of an animal.
In consequence of possessing it, animals may be detached from the soil, so as to move
from place to place. In the lowest species, the entire animal is nothing more than an
alimentary sac, having a single opening, and formed by a reflection of the skin ; so that,
according to the beautiful observation of Trembley, when polypes are turned inside out,
the digestive process is performed as well by their external as by their internal surface.
Ascending in the scale of animals, the canal soon presents two openings, acquires larger
dimensions, becomes more or less convoluted, and is distinct from other systems of or-
gans. A skeleton clothed by muscles is interposed between it and the skin. It becomes
more and more voluminous, in proportion as the nutritive materials and the textures of
the body differ more widely in their chemical composition. What a difference there is,
in this respect, between certain fishes, in which the alimentary canal is not nearly so
long as the animal, and some herbivora ; the ram, for example, in which it is twenty-
seven times the length of the body. Carnivorous animals, again, have a short and nar-
row alimentary canal. Man, being destined to live both upon animal and vegetable sub-
stances, occupies, as it were, a middle station between the herbivora and carnivora.
General Situation. — The digestive canal is situated in front of the vertebral column,
with the direction of which the straight portion of the canal accurately corresponds,
while its tortuous part is distant from, though invariably connected with it by means of
membranous attachments. It commences at the lower part of the face, traverses the
neck and the thorax, penetrates into the abdominal cavity, which is almost exclusively
intended for it, and the dimensions and mechanism of which bear strict relation to the
functions of the alimentary canal ; and it terminates at the outlet of the pelvis, anterior
to the coccyx, by the anal orifice. Its upper part is in immediate relation with the or
gans of respiration ; its lower, with the genito-urinary apparatus.
Dimensions. — The length of the digestive canal has been calculated to be seven oi
eight times that of the body of the individual. Its diameter is not equal through its
whole extent ; and its alternate expansions and contractions establish very distinct lim-
its between its several portions. The largest portion is, undoubtedly, that which re-
ceives the name of the stomach ; the narrowest parts are the cervical portion of the
oesophagus, the pyloric opening of the stomac-h, and the ileo-caecal orifice. It is impor-
GENERAL REMARKS.
tant to remark, that the transverse dimensions of an alimentary canal have, to a certain
extent, an inverse ratio to its length. Thus, a very wide intestinal canal is generally
less remarkable for length. This remark is illustrated by comparative anatomy in the
fact that, in the horse, an herbivorous animal, the intestinal canal is shorter, but, at the
same time, of a much greater calibre than in the ruminantia, which are also herbivorous.
Direction. — The upper or supra-diaphragmatic portion of the alimentary canal, through
which the food merely passes, is straight ; the sub-diaphrjigmatic portion is very much
convoluted upon itself, but again becomes straight before its termination.
General Form. — The digestive apparatus forms a cylindrical continuous canal, in which
we have to consider an external and generally free serous surface, and an internal mu-
cous surface.
Struclure. — The digestive canal is composed of four membranes or tunics : 1 . The
most external is the serous or peritoneal coat, also named the common tunic, because it is
conunon to almost all the organs in the abdominal cavity. This membrane, which may
be regarded as an accessory tunic, is often incomplete, and even entirely wanting through-
out the supra-diaphragmatic portion of the digestive canal. At the same time that it
constitutes the external covering of this canal, it separates it from the neighbouring parts,
facilitates its movements, and forms certain bands, which maintain the several portions
of the canal more or less fixedly in their proper situations. The serous membranes, of
which this external tunic is only a dependance, are shut sacs, which, on the one hand,
line the walls of the cavities to which they belong, and, on the other, are reflected upon
the organs contained therein,* without, however, including them within their ovm prop-
er cavity.
A serous membrane may be compared to a balloon, or, rather, to a double nightcap ;
its internal surface is free, smooth, always moistened with serosity, and its parietal and
visceral portions are in contact with each other : its external surface is adherent, t
2. Beneath the serous coat is situated the muscular coat, consisting of two layers : one su-
perficial, composed of longitudineil fibres ; the other deep, and composed of circular fibres.
These fibres are colourless, like almost all the muscles of nutritive or organic life. J
3. The fibrous coat, interposed between the muscular and mucous coats, may be regard-
ed as constituting the framework of the alimentary canal. It consists of dense areolar
cellular tissue.^
4. The mucous coat or membrane forms the internal lining of the digestive canal. Ev-
ery cavity having a communication with the exterior is hned by a mucous membrane,
so called on account of the mucus with which it is constantly lubricated.
In mucous membranes generally, we find, 1. A dermis or chorion, 2. Papilla or villosi-
ties, which give them a velvety appearance ; hence the designation papillary, villous, or
velvety membrane frequently given to them. 3. On the outer surface of the dermis we
find a very dense network of capillary vessels, which may be completely injected from the
veins, but less easily and less completely from the arteries. 4. Either follicles or small
closed sacs are seen here and there in the substance of mucous membranes ; but they
are not essential, as the name follicular, given to these membranes by Chaussier and
some other anatomists, would seem to indicate.
* [Hence the terms parietal and visceral, applied to these two portions of a serous membrane (see Jig, of
the testis, letters p and v).
In consequence of the existence of an aperture in the free extremity of each Fallopian tube, the peritoneal
cavity in the female is an exception to the general rule, that serous membranes form shut sacs, not communi-
cating with the external medium.]
t [Serous membranes are transparent, colourless, extremely thin, and highly distensible and elastic. They
are composed of a basis of cellular tissue, loose and connected to the adjacent tissues externally, more or less
condensed towards the inner and free surface of the membrane, and covered with an extra- vascular epithelium,
consisting of a single layer of nucleated cells, Ilattened into the form of scales, and arranged parallel to that
surface. Cilia have been detected on many serous membranes, as on the peritoneum and pericardium of the
frog ; on the same parts, and also on the pleura and lining membrane of the ventricles of the brain in certain
mammalia ; and in the latter situation in man. Bloodvessels ramify in the sub-serous cellular tissue, but do
not penetrate far towards the free surface, where they are entirely wanting. Lymphatics also exist in the
sub-serous tissues, but have not been found in the membranes themselves ; nor have nerves been traced into
them. The fluid secretion found in serous cavities appears to be of an albuminous nature.]
t [The involuntary muscular fibres of the alimentary canal (according to Dr. VV. Baly) consist of bands, va-
rying from o^j'g-jjth to , A ^ th of an inch in diameter, apparently formed of flattened tubes, in the parietes of
which are seen, at irregular intervals, numerous transparent oval or linear bodies, sometimes very difiicult of
detection : they are believed to be the nuclei of the primitive cells, from which the fibre itself is developed.
These fibres contain no varicose filaments, nor do they present any transverse striK, like those of animal life
(see p. 194). Moreover, although they have a parallel arrangement in the fasciculi into which they are col-
lected, the fasciculi themselves are irregularly interlaced, at the same time that they all pursue a common
direction.
The muscular coat of nearly the entire alimentary canal consists essentially of these involuntary or organic
muscular fibres ; but at the commencement and termination of the canal, where the muscular systems of ani-
mal and organic life come into relation with each other, this tunic appears also to consist of fibres resembling
those of the voluntary muscles. Thus, at the upper part of the (Esophagus, fibres containing varicose filaments,
and possessing the cross stri<e, were detected by Schwann ; and it has been shown by Valentin and Ficinns,
that these exist all along the oesophagus, and that indistinctly striated fibres are found even at the cardiac end
of the stomachs of many mammalia, and of man. Similar fibres were observed by Ficinus in the rectum, near
the sphincter ani.]
I) [It is frequently called the cellular coat ; and, from its white appearance, has been termed (like all othei
white textures) the nervous tunic]
SPLANCHNOLOGY.
All mucous membranes are covered by an extremely delicate pellicle, which may be
readily detected by means of a simple lens. Injections made by the arteries and veins
never penetrate it, nor is it reddened by inflammation. I have accidentally injected it,
hovirever, by means of a tube containing mercury, used for injecting the lymphatics by
pricking the mucous membrane in different places as superficially as possible. The vas-
cular network, thus injected, is exceedingly delicate ; the small globules of mercury
traversing it in all directions, so as to form rapidly a silvery areolar layer. I have seen
this in the mucous membrane of the nose ; on the conjunctiva, both over the sclerotic
and over the cornea ; on the mucous membrane of the vagina, of the tongue, and of the
cheeks. It is very remarkable that the mercury never passes from this network ei-
ther into the veins or the arteries ; and, moreover, that if the tube pierces a little too
deeply, the veins are injected, but not the epidermic capillary network. It is evident,
therefore, that this network has no communication either with the arteries or the veins.
It probably belongs to the lymphatic system, although I have never observed the lymphat-
ic vessels filled from it.*
Vessels and Nerves. — Vessels and nerves also enter into the formation of the aliment-
Fig. 139. ary canal : for example, we find a very abundant supply of
branches from the adjacent arterial trunks ; an immense num-
ber of veins, of which those from the sub-diaphragmatic por-
tion of the canal terminate in the vena portae ; absorbent ves-
sels, divided into lymphatics and lacteals ; and, lastly, nerves,
almost all of which proceed from the ganglionic system, ex-
cepting the pneumogastric and glosso-pharyngeal nerves.
Division of the Digestive Canal. — The digestive canal has
been divided into several parts, from differences both in their
anatomical characters and their functions. One principal di-
vision, which deserves to be retained, is into a supra-diaphrag-
matic and a sub-diaphragmatic portion. The supra-diaphragmat-
ic portion comprehends the mouth, the pharynx, and the asoph-
agus. The infra-diaphragmatic portion includes the stomach
(a h, fig. 139), the small intesti7ie, subdivided into the duodenum
(b c), and the jejunum and ileum (c d) ; and the large intestine,
somewhat arbitrarily divided into the ceecum {d e), the colon {d
h), and the rectum (h i). The appendages of the digestive ca-
nal consist of the salivary glands, connected with the mouth ;
of the liver and the pancreas, connected with the duodenum ;
and of the spleen, which may be regards'^ .^s an appendage of the liver.
The Mouth and its Appendages.
The mouthy is a cavity situated at the entrance of the digestive passages. It occu-
pies the lower part of the face, and is situated between the two jaws, below the nasal
* [The lining membrane of the digestive apparatus, forming part of the gastro-pulmonary system of the
mncou.s membranes, extends not only throughout the entire alimentary canal, but also along the ducts of the
various glands which pour their secretions into it.
Structure m general. — Mucous membranes are usually soft, pulpy, incapable of great distension, easily la-
cerated, soraevfhat opaque, and when free from blood, of a pale grayish or ashy hue. The dermis or chorion
(analogous to that of the skin) is a basis of cellular tissue, of very variable thickness ; its attached surface is
connected to the subjacent textures, either immovably, as in the nasal cavities and on the tongue, or loosely,
as in the gullet and stomach. The pellicle or epithehum with which its surface is always covered (correspond-
ing to the epidermis of the skin) adso varies much in thickness in different situations ; it consists of transpa-
rent nurJeated cells, according to the form and arrangement of which it receives its name. Thus, in the
squamous epithelium, there are generally (as in the mouth and gullet) several layers of cells ; of these the
deepest are vesicular, and contain a comparatively large nucleus ; those im the surface are flattened out into
polygonal scales, from the centrj of which the nucleus has nearly disappeared, while the intermediate cells
present intermediate transitional forms. The nucleated cells of the columnar epithelium (found, for example,
in the stomach and intestines) are developed into oblong cylinders, arranged in a single scries, like basaltic
columns, perpendicularly to the surface of the dermis. In some situations, as in the nasal cavities and air
passages, cilia are attached to the free extremities of the cylinders of the columnar epithelium, but no cilia
have been detected in any part of the alimentary canal of man, or the warm-blooded animals : the superficial
cells of the epithelium of mucous membranes are continually being thrown off by a process of desquamation.
The different mucous membranes differ in vascularity ; the network of capillary vessels in the dermis becomes
closer or denser near its surface ; the lymphatic vessels also form a network in the same situation; but the
epithelium, though organized, is, as stated in the text, perfectly extra-vascular.
Mucous membranes are also more or less abundantly supplied with nerves.
When boiled they yield no gelatine, or, rather, only as much as would proceed from the cellular tissue and
vessels they contain. The fluid secreted by them, or mucus, is viscid, transparent, and colourless, miscible
with, but not soluble in water, and not coagulated by heat. It contains, besides the desquamated epithelium
scales, proper granular globules, yjg-ff '"•''^ '" diameter, and having a very close resemblance to the globules
of pus. According to Berzelius, mucus consists of water, a few salts, albumen, and a peculiar animal sub-
stance, which he calls mucous matter. This latter, when dried, swells on being placed in water, but, like-
fresh mucus, is insoluble in that fluid, either hot or cold; it is shghtly soluble in dilute acetic and nitric acids,
and in caustic alkalies.
The peculiarities presented by particular portions of the mucous membranes, and the structure of the pa-
pillae, villi, follicles, &c., found in some parts of them, will be separately noticed, as ojiportunity offers.)
t The meaning of the word mouth, in anatomy, differs from the ordinary acceptation of the term, which is
•sually applied, not to the buccal cavity, but to its orifice.
THE LIPS. 32d
fossffi, between the cheeks, behind the lips, and in front of the pharynx. It constitutes
a very complicated apparatus, in which are per- p^g j4q
formed the several acts of mastication, tasting,
and insalivation, the commencement of the act of
deglutition, and the articulation of sounds.
The dimensions of the buccal cavity are great-
er than those of the succeeding portion of the ali-
mentary canal ; hence bodies may be introduced
into it which are too large to pass through the
constricted parts of that canal.* The size of the
mouth presents every intermediate degree be-
tween complete closure with the jaws in contact
and leaving no interval between them, and ex-
treme expansion, when the buccal cavity repre-
sents a quadrangular pyramid, the base of which
is directed forward, and the apex backward. Au
increase in the capacity of the mouth may also
be effected in the transverse direction by the dis-
tension of the cheeks, and in the antero-posterior
direction by a projection of the lips fiJrward.
In studying the relative proportions of the sev-
eral diameters of the buccal cavity, it is found
that none of them predominates in man, while,
in the lower animals, the antero-posterior is by
far the longest : this depends partly on the great size of their nasal cavities, and partly
on the length of their jaws. In connexion with this subject, we may remark, that in
the animal series there is an inverse ratio between the size of the cavity of the cranium
and that of the gustatory and olfactory cavities.
In man, the direction or axis of the mouth is horizontal — an arrangement which is con-
nected with his destination for the biped position. If man assumed the attitude of a
quadruped, the axis of his mouth would be vertical ; whereas, in the lower animals, it is
directed obliquely to the horizon.
Form. — The mouth {Jig. 140) represents a perfectly symmetrical oval cavity, the great
extremity of which is in front. It has an upper wall, viz., the arch of the palate (a) ; a
lower wall, consisting principally of the tongue (i) ; a posterior icall, formed by the velum
palati (c) ; an anterior wall, composed of the lips {d) on one plane, and of the alveolar
arches and the teeth (e) on another ; and two lateral walls, formed by the same arches,
by the teeth, and by the cheeks. It lias two openings : one anterior (m), constituting the
orifice of the mouth ; the other posterior {2, Jigs. 140, 141), establishing a communication
between the buccal cavity and the pharynx, and, on account of its narrowness, called the
isthmus of the fauces .
We shall now describe these parts in succession, excepting the maxillary bones and
the teeth, which have been already treated of The salivary glands, which pour their
secretions into the buccal cavity, will be described as appendages to it.
The Lips.
The lips, forming the anterior wall of the mouth, are two movable, extensible, and
contractile curtains, which circumscribe its orifice. They are distinguished into upper
and lower. Their direction is vertical, like that of the alveolar and dental arches, upon
which they are applied. This direction is peculiar to the human species, and is more
marked in the Caucasian race; lips projecting forward, like those of the lower animals,
and not placed upon the same vertical plane, give a mean expression to the physiogno-
my. The depth of the lips is measured by that of the alveolar and dental arches. The
upper is deeper than the lower lip.
The two lips offer for our consideration an anterior or cutaneous surface, a posterior
or mucous surface, an attached and a free border, and two commissures.
The Anterior Surface. — In the upper lip this surface presents along the median line a ver-
tical furrow, the sub-nasal groove, commencing at the septum of the nose, and termina-
ting belovi^ in a tubercle, which is more or less prominent in different individuals. This
furrow is the vestige of a division in the lip, natural to many mammalia. The malfor-
mation, termed single hare-lip, always occupies one of the edges of this groove ; in double
hare-lip both of them are affected. On each side, the upper lip is convex, and covered
with a slight down in the female, and before puberty in the male, but after that period
with long and stiff hairs directed obliquely outward. The aspect of the anterior surface
of the lower lip is inclined a little downward ; the middle portion only of this lip, which
presents no median depression, is covered with hairs.
* As a peneral rule, the proportion between the different parts of the alimentary canal is such, that the up-
per portion will not admit bodies too Urge for the lower ; and though the buccal cavity forms an exception to
the rule, it is because the food, while it remains in that situation, is under the influence ot the will.
326 SPLANCHNOLOGY.
The Posterior Surface. — Each lip is free behind, excepting in the median h'ne, where
we find a small fold of mucous membrane called the frcenum labii : it is more marked m
the upper than in the lower lip. This surface is always moist, and is in contact -with
the alveolar and dental arches. The complete independence of the lips, as regards the
maxillary bones, explains the extreme mobility of these membranous organs.*
Adherent Borders of the Lips. — The lips are bounded at their posterior surface by the
reflection of the mucous membrane upon the jaw, so that there is a deep and very re-
markable furrow between the lips and the maxillary bones, which may be regarded as
an anterior buccal cavity, or the vestibule of the mouth. The upper lip is bounded in front
by the base of the nose ; on each side it is separated from the cheeks by the projection
of the inner margin of the levator labii superioris alaeque nasi ; the lower lip is bounded
in the median line by a transverse depression situated between it and the chin, called
the mento-labial furrow, which is remarkable for the perpendicular direction of the hairs
growing upon it ; on each side it is separated from the cheeks by the projecting inner
margin of the triangularis oris.
The hue or furrow which separates cm either side the lips from the cheek commences
at the ala of the nose, and is c£illed the naso-labial line .•+ it would be more appropriately
named the bucco-laJnal line or furrow.
The boundaries between the lips and the cheeks are, then, entirely artificial ; the two
lips, taken together, represent an ellipse, the longest diameter of which is transverse.
The Free Borders of the Lips. — ^The free borders of the lips are rounded, are covered
by a red integument, intermediate in character between skin and mucous membrane, and
are marked by folds or wrinkles directed at right angles to the length of the lips, and
produced by the contraction of the orbicularis oris muscle. These free borders, which
are, as it were, everted, especially that of the lower lip, present anteriorly a well-marked
line of separation between the skin and the mucous membrane ; they describe an undu-
lating line, which attracts the attention of the painter more than that of the anatomist.
The chief characters of the free margin of the upper lip are, a slight projection in the
middle hne, and a slight depression on either side : those of the free border of the lower
lip are a median depression and two lateral projections ; on meeting together, these bor-
ders come into accurate contact, and completely close the opening of the mouth. The
free margins of the lips are, moreover, their thickest part, and they are thicker in the
middle than at each extremity ; their thickness also varies greatly in different individ-
uals. In general, thick lips are regarded as indicating a scrofulous diathesis ; but in
forming an opinion upon this subject, it is necessary to distinguish carefully between
size resulting from hypertrophy of the muscular layer, and that which is caused by an
excess of skin and cellular tissue. In the Ethiopian race, the size of the lips is entirely
due to the great development of the muscles.
The Commissures. — The lateral extremities of the free margins of the lips are thin, and
by their union form the angles or commissures of the lips (from committo, to join together).
The Anterior Orifice of the Mouth. — The free edges of the lips intercept a transverse
fissure, viz., the anterior opening of the mouth. The variable size of this orifice in man
has given rise to the distinctions of middle-sized, large, and small mouths : the difference,
however, is confined to the opening, and does not at all affect the buccal cavity properly
so called. The anterior opening of the lips is also exceedingly dilatable, and, accord-
ingly, admits the introduction of very large bodies, and renders the exploration of every
part of the cavity of the mouth comparatively easy.
Structure of the Lips. — The lips are composed of two tegumentary layers, one cutane-
ous, the other mucous ; of a muscular layer ; of a series of glands ; and of vessels,
nerves, and cellular tissue.
The Cutaneous Layer. — This is remarkable for its density and thickness, for the size
of the hair follicles, which are partially situated beneath it, and for its intimate adhesion
to the muscular layer ; so that it is impossible to separate them by dissection without
encroaching upon one or the other. This layer may be regarded as the framework of
the lips. It is endowed with an exquisite sensibility, and, in many animals, possesses
so delicate a sense of touch, that the slightest movement of the extremities of the long
hairs with which it is provided at once warns the animal of the presence of approach-
ing objects.
The Mucous Layer. — This is remarkable from the existence of an epithelium upon it,
which can be very easily demonstrated. It covers the free edge of the hps, so that, by
a rare exception, a portion of this mucous membrane is habitually exposed to the exter-
nal air. It adheres more firmly at the free edge of the lip than elsewhere.t
The Glandular Layer. — This is a thick layer, situated between the mucous and the
* Mammalia alone have lips that are movable, independently of the jaws ; but this independence is still
more marked in man.
t Much importance is attached to this furrow in semeiology. It is termed the abdominal line, because it
becomes remarkably distinct in diseases of the abdomen.
t [The mucous membrane upon the free borders of the lip is provided with papillse. Its epithelium, and,
indeed, that of the entire mouth, is sqiuanous.l
THE LIPS. 327
..muscular layers, and causing an elevation of the former. It consists of small spheroida.
i^glands of unequal size, placed close to each other, but perfectly distinct ; when examined
with a lens, they resemble small salivary glands, each being provided with an excretory
duct, opening by a separate orifice upon the posterior siurface of the mucous membrane.*
These are true labial salivary glands, and not muciparous follicles.
The Muscular Layer. — This is composed essentially of a single proper muscle, the or-
bicularis oris, into which almost all the muscles of the face are inserted, viz., the levator
labii superioris alaeque nasi, the levator labii superioris, the depressor alae nasi, the naso-
labialis, and the zygomaticus minor (where it exists) for the upper lip ; the quadratus
menti and the levator labii inferioris for the lower lip ; the buccinator (which we have
regarded as forming the orbicularis by its bifurcation extending to both lips), and the
zygomaticus major, the triangularis oris, the levator anguli oris, and the risorius of San
torini (where it exists) to the commissures. Including the orbicularis oris, there are
twenty-five muscles. The differences presented by the free edges of the lips in differ-
ent individuals depend upon variations in the thiclcness of the corresponding portion of
the orbicularis.
No fibrous tissue enters into the composition of the lips and their commissures, which
are exclusively formed of fleshy fibres : hence they are extremely extensible, a circum-
stance of which the surgeon avails himself in operating upon parts situated in the buc-
cal cavity and pharynx.
Vessels, Nerves, and Cellular Tissue. — Few parts are so abundantly provided with vessels
and nerves as the Jips. The arteries of the lips are derived from two principal sources :
the coronary arteries arise from the facial ; the buccal, infra-orbital, and alveolar arteries
destined for the upper lip, and the mental artery for the lower lip, arise from the internal
maxillary. The sub-mental artery, a branch of the facial, and the transversalis faciei, a
branch of the temporal, also give off some ramifications to the lips. The veins bear the
same names, and follow the same direction as the arteries ; the lymphatic vessels, which
are little known, terminate in the glands at the base of the jaw. The nerves are derived
from two distinct sources, viz., from the fifth and the seventh pairs of cranial nerves.
The cellular tissue contained in the substance of the lips is essentially of a serous
nature. It is liable to a considerable amount of serous infiltration ; but even in the fat-
test individuals it contains only a very small quantity of adipose tissue.
Development. — According to Blumenbach and most modem anatomists, the upper lip
is originally developed from three points or three distinct parts : one median and two
lateral. Some have even gone farther, and have maintained that the median point itself
is originally formed of two lateral halves, which become united at a very early period.
This hypothesis is founded partly upon the nature of the divisions in simple and double
hare-lip, each of which has been assumed to be nothing more than an arrest of develop-
ment ; also, upon the mode of development of the superior maxillary bones, the alveolar
border of which, it is said, is composed of four pieces : two median or incisor, and two
lateral ; and, lastly, upon the permanent existence of these divisions in some animals.
In opposition to this view, however, we may state, first, the absence in the human foetus
of distinct bony pieces, corresponding to the ossa incisiva of the lower animals, for all
that can be distinguished is a fissure, the mere trace of a separation (see Development of
the Superior Maxilla, p. 51) ; and, secondly, that at no period of foetal life can we demon-
strate the existence of any division in the upper lip. This lip has always appeared to
me to consist of a single piece from the earliest period of its formation. The same
may be said of the lower lip, which, according to authors, is developed from two lateral
halves. At no period of foetal life can any such division be detected. + I do not even
know an example of malformation in which such an arrangement existed.
The length of the lips of the new-bom infant is well adapted for the act of sucking, and
depends upon the absence of the teeth. To the same cause, and to the wasting of the
alveolar borders, the length of the hps in advanced age must be referred.
Uses. — The lips, constituting the anterior wall of the mouth, form a sort of barrier in
front of the teeth and alveolar arches, by which the saliva is retained within that cavity.
So great is the importance of the lips in preventing a continual escape of the saliva, that
in cases where they have been destroyed, the constant draining away of that fluid may
become a cause of exhaustion, and even of death.J
They are employed, also, in drinking, sucking, and blowing ; in playing upon wind-in-
struments, and in uttering articulate sounds. They are also of great importance in the
expression of the passions, which, as we have seen, influence all the muscles of the face.
Pride, contempt, joy, grief, anger, and every possible gradation Of feeling, are depicted
in a striking manner upon the outline of the lips. The mouth is more particularly the
* When these orifices are obliterated, the dilated excretory ducts are transformed into salivary cysts, which
may acquire a very large size.
t The admirable researches of M. Velpeau upon embryology fully confirm the results at which 1 have ar-
rived.
t This use is principally confined to the lower lip, and it is remarkable that this lip is never affected by con-
genital fissure. Another singular, and also totally inexplicable fact, is, that cancer, which is so common a dis
ease, never affects the upper, but invariably the lower lip
\
328 SPLANCHNOLOGY.
seat of grimaces, which are nothing more than the expression of passions ridiculously
exaggerated.
The Cheeks.
The cheeks form the lateral walls of the mouth and the sides of the face. They are
bounded internally by the reflection of the mucous membrane upon the maxillary bones ;
externally their limits are much less defined, and are thus determined on each side of
the face ; in front, by the bucco-labial furrow, which separates them from the lips ; behind,
by the posterior border of the ramus of the lower jaw ; above, by the base of the orbit ;
and below, by the base of the lower jaw. The cheeks, then, comprise three very distinct
regions : the malar, the masseteric, and the buccal, properly so called. Each cheek is
quadrilateral in form, and presents, 1. An external or cutaneous surface, on which is ob-
served, above, tl)e projection of the cheek, called the malar eminence, and lower down, a
surface, which is convex and smooth in stout persons, but hollow and wrinkled in the
emaciated ; 2. An internal or mucous surface, free, and corresponding to the alveolar and
dental arches. On this surface is situated the orifice of the Stenonian duct, opposite the
interval which separates the first from the second upper large molar tooth.
Structure. — Each cheek, properly so called, is composed of the following parts : the
malar bone and the ramus of the lower jaw ; a cutaneous layer, increased in thickness
by a great quantity of fat ; a mucous, a glandular, a muscular, and an aponeurotic layer ;
some vessels and nerves, and an excretory duct. We shedl make a few remarks upon
these different layers, commencing with the skin.
The skin is remarkable for its firmness and vascularity over the cheek bone, and also
for the facility with which it is injected, or becomes pale under the influence of the moral
feelings ; it is covered with hair on the lower and back part in the adult male
The mucous membrane is a continuation of that of the lips, and presents the same char-
acters.
The glandular layer is formed by the buccal salivary glands, which exactly resemble the
labial glands, but are smaller, and, like them, cause projections of the mucous membrane,
upon which they open by distinct orifices. Two of these glands have obtained a partic-
ular appellation, because they are not subjacent to the mucous membrane, but are situ-
ated between the buccinator and the masseter muscles : they are called the molar glands.
Their excretory ducts open opposite the last molar tooth.
The muscular layer is formed, in the masseteric region, by the masseter and a part of
the platysma ; in the malar region, by the orbicularis palpebrarum ; in the buccal region,
properly so called, by the buccinator, and the two zygomatici.
The aponeurotic layer is formed by the aponeurosis of the buccinator muscle.
The adipose layer is thin in the malar and masseteric regions, and very thick in the
buccal region, properly so called. Bichat has, moreover, pointed out a mass of fat in the
substance of the cheek, between the buccinator and the masseter. It is highly devel-
oped in the infant, and vestiges of it are found even in the most emaciated individuals,
and in extreme old age.
The arteries of the cheeks come partly from the facial and the transverse artery of
the face, and partly from the internal maxillary : the branches from the internal maxil-
lary belong to the infra-orbital, the inferior dental, the buccal, the masseteric, and the
edveolar arteries.
The veins bear the same name, and follow the same course, as the arteries.
The lymphatic vessels pass into the cervical and parotid lymphatic glands.
The nerves of the cheeks, like those of the lips, are derived from two sources, viz.,
the buccal and malar nerves, from the portio dura of the seventh pair, and the buccal,
masseteric, infra-orbital, and mental branches of the fifth pair.
The cheek is perforated by the duct of Steno {s, fig. 144), which runs horizontally for-
ward, below the malar bone.
Development. — The absence of the teeth, the presence of a large quantity of fat (more
especially the great size of the mass above noticed), the want of height in the superior
maxilla from the non-development of the sinus, and, lastly, the obtuse angle of the lower
jaw, give to the cheek of the infant its characteristic fulness. The loss of the teeth,
and the wasting of the alveolar borders in the aged, diminish the inter-maxillary space ;
so that their emaciated cheeks become disproportionately long, and, consequently, dis-
play a looseness which forms one of the chief peculiarities in their physiognomy. At
puberty, the cheeks of the male are covered with hair.
Uses. — The cheeks form lateral active walls of the mouth, which, closely applying
themselves against the alveolar arches and teeth, force the food between the latter, and
thus assist in mastication. They are employed, also, in suction, in the articulation of
sounds, and in plapng upon wind-instruments. In the expression of the passions, they
assist rather by changes in their colour than by any distinct movements.
The cheeks and the lips constitute the outer wall of a supernumerary buccal cavity,
of which the inner wall is formed by the alveolar borders and the teeth. This cavity, a
sort of vestibule to the buccal cavity, properly so called, is very dilatable. It mav be
THE PALATINE ARCH AND THE GUMS. 329
tfuusidered as a kind of reservoir, in which the food is deposited, in Older to be submitted
in successive portions to the action of the masticatory organs. This vestibular buccal
cavity is provided with labial and buccal salivary glands. It is also interesting to find
that the parotid glands, the largest of all the salivary glands, pour their secretion into
this cavity.
The Palatine Arch and the Gums.
The palatine arch, or the hard palate (a, fig, 140), constitutes the Tipper wall of the buc-
cal cavity. It has the form of a parabolic arch, bounded in front and on either side by
the teeth, and behind by the velum palati, into which it is continued without any dis-
tinct line of demarcation. Upon it we observe, in the median line, an antero-posterior
raphe, at the anterior extremity of which is a tubercle corresponding to the lower orifice
of the anterior palatine canal. This tubercle has been incorrectly stated by physiolo-
gists to be endowed with a peculiar sensibility ; on each side and in front there are trans-
verse ridges, more or less marked in different individuals, which represent the still more
highly-developed ridges, bars, or calcareous concretions, which render the surface of the
roof of the palate in some animals so rugged. Posteriorly, the roof of the palate is per-
fectly smooth.
Structure. — The constituent parts of the palatine arch are an osseous framework, a
fibro-mucous membrane, a layer of glands, with vessels and nerves.
The framework consists of the bony palate already described : it is thicker in front
than behind, and is held up in the middle by the sort of column formed by the vomer and
the perpendicular plate of the ethmoid, and behind and on each side by the vertical por-
tions of the palate bones, and by the pterygoid processes. We have already noticed the
asperities which it presents, and which appear to have no other object than to secure
the intimate adhesion of the fibro-mucous membrane to the bones.
The Palatine and Gingival Membrane. — This mucous membrane is remarkable for its
whitish colour ; for the thickness of its epithelium, especially in front ; for the thickness
and density of its chorion, which even approaches to that of the corresponding tissue in
the skin ; for its close adhesion to the bones, into which the chorion sends off well-mark-
ed fibro-cellular prolongations ; and, lastly, for the great number of orifices with which
it is perforated, especially behind. This excessive thickness of the palatine membrane,
however, is observed only anteriorly, and most particularly so behind the incisor teeth.
The Glandular Layer. — In the median line the palatine membrane is blended with the
periosteum of the bones, but on each side it is separated from it by a very thick layer of
glands, which are sometimes arranged in regular rows along the antero-posterior groove
presented by the palatine arch. These palatine salivary glands are exactly similar to the
labial and buccal glands already described ; they are much more numerous behind than
in front, and open upon the membrane by a number of orifices visible to the naked eye.
There are often two openings mud more distinctly marked than the rest, situated one
on either side of the posterior extiemity of the median raphe.
The Gums. — The description of the peculiar tissue of the gums, to which some allusion
has been made in speaking of the teeth, naturally follows that of the palatine membrane.
The term gums {ovXa) is applied to those portions of the buccal mucous membrane which
surround the teeth. They are distinguished from the rest of that membrane by their
intimate adhesion to the periosteum, by their thickness, and especially by their almost
cartilaginous density, which enables them to resist the shocks of hard bodies during mas-
tication. In this latter respect, and in regard to their want of sensibility, the gums
closely resemble the contiguous portions of the palatine membrane. They commence
about a line from the base of the alveoli, their limits being marked by a scalloped ridge.
Having reached the free margins, i. e., the base of the alveoli, the gums continue their
course for the space of about a line beyond that point, as far as the neck of the teeth,
where they become reflected upon themselves. The point of reflection is a free border
of a semilunar shape, corresponding to the indented, and, as it were, festooned border
of each alveolus. The denticulations or longest portions of the gums correspond to the
intervals between the teeth, in which situation the processes of the gum, covering the
anterior and posterior surfaces of the alveoli, communicate with each other.
The reflected portion of the gum, though not adhering to, is in contact with, all that
portion of the root of the tooth which projects above the alveolus ; it then dips into the
cavity of the latter, so as to form the alveola-dental periosteum, which, as we have already
seen, is a powerful means of connecting the fang of the tooth to its socket. The tissue
of the gums appears to be provided with particular follicles for the secretion of the tar-
tar.* It varies much in different individuals, both in colour and in density. One of its
most peculiar characters is the singular effect produced on it by scurvy and by mercury,
under the influence of which agents it becomes softened and fungous, easily bleeds, and
furnishes a large quantity of tartar.* Another, but purely anatomical character, conbists
•'n its largely-developed openings or pores, which, in a particular light, an even vii^ible
* [These are nuutMis follicles : the tartar is now known to be merely a deposite from the saliva ; its inert ascc
amount during- 1..1 i\t.ri:il salivation is, therefore, readily accounted tor.l
Tt
3iro SPLANCHNOLOGY.
to the naked eye. The gums are almost insensible when divided by cutting instruments ;
but the pressure exerted upon them by the teeth, during the eruption of the latter, often
gives rise to the most serious affections.
Vessels and Nerves of the Roof of the Palate and the Gums. — The arteries arise, seme
from the internal maxillary, viz., the posterior palatine, the alveolar, the infra-orbital,
and the mental branches ; others from the facial, viz., the superior coronary for the
gums of the upper, and the sub-mental branches for those of the lower jaw ; the sub-lingual
artery also supplies the latter. The veins bear the same name. All the nerves proceed
from the fifth pair, viz., the palatine and the superior and inferior dental branches. The
naso-palatine nerve sends ramifications to the small median tubercle upon the roof of
the palate. Few parts have so little cellular tissue as the gums.
Development. — According to the best authorities, the bony and membranous portions
of the hard palate are developed from two lateral points, which unite along the me-
dian line, so that the malformation known by the name of harelip with cleft palate, is
said to be an arrest of development. The fissure may be either single or double in front.
If the cleft be double, that portion of the upper jaw which supports the incisor teeth is
separated on both sides from the rest of the bone. Such divisions always seem to me
to be absolutely departures from nature,* for at no period of its growth can such separa-
tions or clefts be detected in a naturally-formed foetus.
Uses of the Gums and Hard Palate. — The hard palate separates the buccal cavity from
the nasal fossa. It serves as a fulcrum for the tongue in the act of tasting, in mastica-
tio'n, deglutition, and the articulation of sounds. Before the eruption of the teeth, the
gums completely close the alveoli, and serve as the immediate instruments of mastication ;
and they become hard, and supply the place of the teeth after the loss of those organs.
The gums have great influence in fixing the teeth within their sockets, and hence the
loosening of the former from scurvy or from the abuse of mercury. We may consider the
gums as that portion of the mucous membrane in which the dental follicles are situated.
The Velum Palati and Isthmus Faucium.
Dissection. — The lower surface of the velum palati may be seen by forcibly depressing
the lower jaw, or still better by sawing it across in the median line, and separating the
two halves. In order to see its upper surface, the pharynx must be removed entire, and
its posterior wall divided vertically (as in_^^. 141). The dissection of the different lay-
ers which enter into the formation of the velum palati, and of its extrinsic and intrinsic
muscles, will be understood from the following descriptions :
External Conformation. — The velum palati, or soft palate (c, fig. 140), is a muscular and
membranous valve, which prolongs the palatine arch backward, and, therefore, might be
called the membranous palatine arch. It is a sort of incomplete septum (septum staphylin,
Chauss.), dividing the buccal cavity from the nasal fossae and the pharynx.
Its direction is curved : its upper portion is horizontal, but it soon becomes curved,
and passes almost directly downward (velum pendulum palati). In the act of degluti-
tion, the velum becomes horizontal during the passage of the alimentary mass, but im-
mediately afterward returns to its oblique and pendulous position, and thus tends to pre-
vent the return of the food into the mouth. In several pathological conditions the velum
is thrown backward and upward, and adheres to the posterior orifices of the nasal fossae.
AH these changes of direction affect the oblique, and not the horizontal portion of the
velum. The velum palati is broad, quadrilateral, and perfectly symmetrical. Its in-
ferior or buccal surface is concave, and continuous with the hard palate, without any line
of demarcation. This surface is very well seen when the mouth is opened, and is, there-
fore, easily accessible to the surgeon. In the median line it presents a white raphe,
which is a continuation of the median raphe of the hard palate ; it is formed by a small
fibrous cord, causing a projection under the mucous membrane.
The superior or nasal surface of the velum {fig. 141) is convex : it prolongs the floor
of the nasal fossae, and, from its obliquity, directs the mucus into the pharynx. This
surface presents a median projection produced above by the palato-staphylin muscles
(azygos uvulse, a), and below by a mass of glands. Congenital division of the velum is
always situated in the median line, and is followed by so great a retraction of its two
halves, that, in some cases, the entire absence of the velum has been suspected.
Its upper border is thick, and firmly united to the posterior border of the hard palate.
Its lower border is free, extremely thin and concave, and forms the upper boundary of
the isthmus {t,fig. 141) of the fauces : it presents, in the middle line, a sort of appendix
or prolongation, called the uvula (u,fig. 140) : this is of a conical shape, and of very va-
riable size and length ; it is capable of considerable elongation, and may then reach the
base of the tongue, but not, as has been supposed, the upper orifice of the larynx.t It
is not very uncommon to find it bifid, and sometimes it is entirely wanting.
* [/. c, not mere arrests of development.]
+ In consultation upon a case of chronic laryngitis, I was much surprised to hear the medical attendant
state that the disease was the result of irritation produced by the UTula upon the superior orifice of the 1*
rfnx. The position of the uvula is always a few lines in advance of the epiglottis.
THE VELUM PALATI. 331
The two lateral borders of the velum limit it on each side, and separate it from the
cheek. This boundary is indicated (on each side) by a prominent ridge (before /, fi^.
140), extending from the posterior extremity of the upper to the corresponding part of
the lower alveolar border. This prominence corresponds to the anterior margin of the
internal pterygoid muscle, and is formed, in a great measure, by a series of small, glan-
dular structures, which are collected behind the last great molar tooth of the lower jaw
into a considerable mass resembling a small gland.
The pillars of the velum palati. These are two lateral columns or pillars, having an
arched form, and distinguished into anteriw (behind /, fig. 140) and posterior {g), which
pass down on either side from the uvula. Each of the anterior pillars (the two forming
together the anterior arch of the fauces) proceeds from the base of the uvula outward,
and then vertically downward, describing a curve with its concavity directed inward,
and terminates at the sides of the tongue, opposite the anterior extremities of the V-
shaped series of papillae vallatae found upon that organ. Each of the posterior pillars
(which together form the posterior arch of the fauces) commences at the apex of the
uvula, and immediately curves into an arch, having a smaller diameter than that repre-
sented by the anterior pillar, and then passes obliquely downward, backward, and out-
ward, to its termination on the sides of the pharynx. The two posterior pillars consti-
tute the free margin of the velum. They project much farther inward than the anterior
pillars, so that when the base of the tongue is depressed in the living subject, both sets
of pillars can be seen at the same time, like double curtains, placed on different planes.
Each of these pillars represents a triangle, having its base below and its apex above.
ITie Amygdaloid Fossa. — From the direction of the anterior and posterior pillars, they
approach each other above, and are separated by a considerable interval below. This
interval, which is partly occupied by the tonsil (w), may be called the amygdaloid excava-
tion. In order to have a good idea of it, it is necessary to make a vertical section of the
head from before backward. A sort of recess will then be observed, narrow and shallow
above, but very broad and deep below, especially when the tonsil (n) is small. The base
of this fossa corresponds anteriorly to the base of the tongue (J), then to the epiglottis
(i), the larynx, and the walls of the pharynx : the bottom of the fossa corresponds to the
angle of the lower jaw and the lateral portion of the supra-hyoid region, where it is sep-
arated from the skin only by a thin layer of soft tissues. The dimensions of this fossa
always remain the same above, but are very variable below, according as the tongue is
retained in the mouth or protruded.
The Isthmus Faucium. — The posterior orifice of the buccal cavity is called the isthmus
faucium (2, figs. 140, 141). It is a sort of passage between the buccal and the pharyn-
geal cavities, bounded below by the base of the tongue, above by the free margin of the
velum palati, divided into two arches by the uvula in the middle, and the two pillars on
each side. This posterior orifice of the mouth, though very dilatable, is less so than the an-
terior opening of the same cavity. It may be contracted, and even completely closed, not
only from inflammation of the tonsils and arches of the fauces, but also from the contraction
of the muscles which enter into the formation of the velum and its pillars. This may be
seen by watching the movements of the isthmus of the fauces in a person who will sub-
mit to such an examination. These differences in the dimensions of the isthmus are con-
cerned not only in deglutition, but also in the modulations or articulations of the voice.
Structure. — In the velum palati we find an aponeurotic framework ; also certain mus-
cles by which it is moved, which are either extrinsic or intrinsic. The intrinsic mus-
cles are those constituting the azygos uvulae, viz., the palato-staphylini ; and the extrin-
sic muscles are four on each side, two descending, viz., the levator palati, and the cir-
ciunflexus or tensor palati, and two ascending, viz., the palato-glossus, and the palato-
pharyngeus. We also find in the soft palate a thick layer of glands, vessels, nerves, and
cellular tissue ; and, lastly, a covering of mucous membrane.
The Aponeurotic Portion. — The aponeurotic portion, or, rather, the principal aponeuro-
sis, is extremely dense, and continues the hard palate backward : it is generally regarded
as an expansion of the reflected tendons of the tensores palati, but it is, in a great measure,
formed of proper fibres continuous with the fibrous tissue, which prolongs backward the
septum narium, the outer borders of the posterior orifices of the nasal fossae, and the
fibrous portion of the Eustachian tube. Below this aponeurotic membrane there is an-
other fibrous lamella, continuous with the fibrous tissue found in the hard palate. The
framework of the upper half of the velum palati may, therefore, be said to be formed of
two fibrous layers, one superior, the other inferior, between which the glandular layer is
situated. Lastly, a small fibrous band extends from the nasal spine to the uvula, along
the median raphe, upon the lower surface of the velum, producing a slight elevation of
the mucous membrane. This little band sends off a prolongation between the glands of
the velum, which separates the right half of the soft palate from the left.
The Muscles of the Velum Palati.
Dissection. — This is common to all the muscles of the soft palate. It is merely neces-
sary to remove the mucous membranes and the subjacent glands, in order to study the
SPLANCHNOLOGY.
arrangement of these muscles, and to follow the ascending and descending fibres which
emerge from or enter into the velum.
The Azygos Uvidcs, or Palato-staphylini.
The palato-staphylini (a, fig. 141) are two small, fleshy, cylindrical bands placed in
Fig. 14L contact, one on each side of the median line, and extending
from the posterior nasal spine, or, rather, from the aponeuro-
sis continuous with it, to the base of the uvula. They are
covered by the mucous membrane of the nose, under which
they form a projection, and they cover the levatores palati.
The two muscles, from their juxtaposition, appear, at first
sight, to form a single rounded muscle, to which the names
azygos uvulcz, columellcB musculus teres, have been given.
Action. — To raise the uvula.
The Levator Palati, or Peristaphylinus Internus.
Dissection. — Remove the mucous membrane from a verti-
cal ridge which exists along the outer border of the posterior
orifice of one of the nasal fossae, behind the Eustachian tube ;
then remove the mucous membrane covering the upper sur-
face of the soft palate.
The vertical portion of the levator palati (le petro-salpin-
go staphylin, Winslow ; petro-staphylin, Chauss., c,figs. 141,
146) is situated upon the outer side of the posterior orifice of the corresponding nasal
fossa ; its horizontal portion is in the substance of the velum ; it is thick, narrow, and
rounded above, expanded and triangular below. It arises by short tendinous fibres from
the lower surface of the petrous portion of the temporal bone, near its apex, and from
the contiguous part of the cartilage of the Eustachian tube. From these points its fibres
pass obliquely downward and inward, turning round the outer side of the tube. At the
outer border of the velum palati the muscle becomes horizontal, and its fasciculated fibres
diverge, so as to cover the whole extent of the antero-posterior diameter of the velum.
The anterior fleshy fasciculi are inserted by short tendinous fibres into the posterior
border of the aponeurosis of the soft palate. The others also terminate by very short
tendinous fibres, which are blended in the median line with those of the opposite side,
immediately below the azygos uvulae.
Relations. — It is covered by the mucous membrane of the pharynx and soft palate ; its
vertical portion is in relation, on the outside, with the circumflexus palati and the supe-
rior constrictor muscles, and its horizontal portion with the palato-pharyngeus. It forms
the uppermost muscular layer of the soft palate.
Action. — It raises the velum (elevator palati mollis, Albin., Samm.). The length of its
fibres, its direction, and its shape, render it well fitted for this purpose. It should be re-
marked, that the tendinous portion of the velum scarcely participates in the movement
of elevation.
The Circumflexus or Tensor Palati, or the Peristaphylinus Externus.
This is a thin, flat, and reflected muscle (le pterygo or spheno salpingo staphylin,
Winsl. ; pterygo-staphylin, Chauss.), and is tendinous for a considerable part of its ex-
tent ; its vertical portion {d, fig. 141, 146) is situated* along the internal plate of the ptery-
goid process, to the inner side of the internal pterygoid muscle (b), and its horizontal
portion {d) in the substance of the velum.
Attachments. — It arises from the fossa navicularis, at the base of the internal pterygoid
plate, from the contiguous part of the great wing of the sphenoid, and from a small por-
tion of the cartilage of the Eustachian tube. From these points the muscle, which forms
a thin fasciculus, flattened at the side, passes vertically downward : near the hamular
process of the internal pterygoid plate it becomes a shining tendon, which changes its
direction, and is reflected at a right angle under that process : it is retained in this situ-
ation by a small ligament, and its motions are facilitated by a synovial membrane. The
tendon then passes horizontally inward, expands, and becomes blended with the aponeu-
rotic membrane.
Relations. — Its vertical portion is in relation on the outside with the internal pterygoid,
and on the inside with the levator palati, from which it is separated by the superior con-
strictor of the pharynx (g,fig. 141) and by the internal pterygoid plate. Its horizontal
or aponeurotic portion is anterior to the levator palati, and has the same relation as thp
aponeurotic portion of the velum.
Action. — It is a tensor of the aponeurotic portion (tensor palati), but does not otherwise
move the velum. As Haller has remarked, when its fixed point is below, it can dilate
the Eustachian tube.
The Palato-pharyngeus, or Pharyngo-staphylinus.
This muscle (thyro-staphylinus, Douglas, e e,fig. 141) is narrow and fasciculated in the
THE PALATO-GLOSSUa. 333
middle, where it is situated in the posterior pillar of the fauces, broad and membranous
at its extremities, one of which is in the velum and the other in the pharynx.
Attachments. — It arises from the whole extent of the posterior border of the thyroid
cartilage. From this point it passes vertically upward, and forms a broad and thin mus-
cular layer, the fibres of which are first collected into a fasciculus or muscular column,
which enters the posterior pillar of the fauces, and then, again expanding, ocaipy the
whole extent of the antero-posterior diameter of the velum, and unite in the median line
with the muscle of the opposite side, so as to form an arch. The anterior fibres are in-
serted into the posterior border of the aponeurosis of the velum.
RclatioTis. — It forms the lowest muscular stratum of the velum : it is separated from
the mucous membrane below by the layer of glands : it is in relation above with the
muscular layer formed by the expansion of the levator palati. In the posterior pillar it
is in relation with the mucous membrane, which covers it in all directions, excepting on
the outside. In the pharynx it forms the innermost muscular layer, i. c., it lies between
the constrictors and the mucous membrane.
Action. — The two palato-pharyngei draw the velum downward, and press it strongly
against the alimentary mass during deglutition ; they therefore form a constrictor of the
isthmus of the fauces. When they take their fixed points above, they raise the poste-
rior wall of the pharynx. They are important agents in deglutition.
The Palato-glossus, or Olosso-staphylinus.
This is a small fleshy bundle {o,jig. 141) situated in the anterior pillar of the fauces,
narrow in the middle, and broad at the extremities. Its lower extremity is expanded
upon the side of the tongue, and is united with the stylo-glossus. Its upper extremity
spreads out in the velum palati, and becomes blended with that of the palato-pharyngeus.
Its middle portion is very slender ; it forms the anterior pillar, and is visible through the
thin mucous membrane by which it is covered.
Action. — The two muscles depress the velum palati, and raise the edges of the base
of the tongue ; they consequently constrict the isthmus faucium.
The Glandular Layer of the Velum Palati. — Under the mucous membrane covering the
upper surface of the velum palati, there are some scattered glands, M'hich are more nu-
merous on the sides than along the middle ; but on the lower surface of the velum there
is a much more obvious collection of glands, particularly dense, opposite the aponeurotic
portion of the velum, and forming a contiouation of the glandular layer of the hard pal-
ate. Similar glands are found in the uvula, the size, and, in some measure, the form of
which they determine. These small glands in the velum exactly resemble the salivary
glands already described as existing in the lips, the cheeks, and the roof of the palate.
The Mucous Membrane. — Both surfaces of the velum are covered by mucous mem-
brane, which constitutes, as it were, its integuments. These two mucous layers are
remarkable, inasmuch as each presents the peculiar characters of the cavity to which it
belongs. Thus, the lower layer preserves the characters of the buccal mucous mem-
brane, and the upper layer those of the nasal.* The two layers are continuous with
each other along the free margin of the velum palati ; the fold of mucous membrane
forming this margin passes beyond' the other constituent tissues, so that, for the space
of half a line or a hne, the two mucous layers are in contact. The same occurs in the
uvula, the apex, and sometimes the lower half of which consists of a duplicature of mu-
cous membrane, containing some loose cellular tissue, which is very susceptible of infil-
tration. Either serous or sanguineous infiltration of the uvula produces an elongation of
this part, called relaxation of the uvula. I should not omit to mention the great differ-
ence, in regard to sensibility and liability to inflammation, that exists between the mu-
cous membrane of the free and adherent borders of the velum palati.
Vessels and Nerves. — These are very numerous in proportion to the size of the part.
The arteries arise from the palatine and the superior and in/erior pharyngeal. The veins
are similarly named, and follow the same course. The lymphatic vessels, which have
been little studied, enter the lymphatic glands at the angle of the jaw. The nerves are
derived from the palatine branches given off by Meckel's ganglion, and from the glosso
pharyngeus.
Development. — ^We have here again the question, whether the velum is formed origi-
nally from two halves, which afterward become united in the median line ; in favour of
this view we may adduce those cases in which the uvula and the velum are bifid, either
with or without fissure of the hard palate and lip. In the youngest embryos which I
have examined, I have always found the velum undivided.
Uses. — The velum palati is a contractile valve, which fulfils very important functions
in deglutition, in the utterance of articulate sounds, and in the modulation of the voice ;
it is capable of being elevated and depressed Elevation affects its muscular, but not its
* [According to the recent researches of Dr. IIenl6, the ciliated cohimnar epithelium (like that of the nasal
mucous membrane) is found upon the upper surface of the velum, only in the neighbourhood of, and a short
distance below, the expanded orifice of the Eustachian tube ; the remaininsr portion of the upper surface, as
well as the free border, and the whole of the lower surface, are covered with the squamous epithelium, simi
lar to that of the buccal mucous membrane.]
334 SPLANCHNOLOGY.
aponeurotic portion : this movement cannot be carried so far as to revert the velum up-
ward. Depression may be carried to such an extent as to close the isthmus faucium by
the approximation of the velum and the base of the tongue. The contraction of the pa-
lato-pharyngei, which are curved muscles, may be so complete as to bring the posterior
pillars of the fauces into contact, and thus close the isthmus in a transverse direction.
The uvula moves independently of the velum. When the aponeurosis of the velum pa-
lati is rendered tense, the velum itself is enabled to resist both elevation and depression.
The Tonsils, or Amygdal.*:.
The terms amygdala. (ufivySaMa, an almond), or tonsils, are applied to a group of mu-
cous follicles (n, fig. 140) which occupy the interval between the pillars of the fauces on
each side. They are placed there on account of the necessity of lubricating the isthmus
during the passage of the alimentary mass. Their form pretty nearly resembles that of
an almond ; they are directed obliquely downward and forward, and their size is exceed-
ingly subject to either congenital or accidental variation. In some subjects they can
scarcely be said to exist ; in others they fill up the whole amygdaloid fossa, and project
more or less into the isthmus of the fauces, so as to impede deglutition, o^ fcv^en respiration.
The compound tonsil results from its component follicles being collected into several
distinct masses.
The internal surface is free, and may be seen when the base of the tongue is depress-
ed ; it is perforated by foramina, like the ligneous shell of an almond. These foramina,
which vary in number and size, have been frequently mistaken for syphilitic ulcerations.
They lead into small cells, in which mucus sometimes collects, and is then ejected in
hard fetid lumps, which have been erroneously supposed to be pulmonary tubercles. Its
external surface is covered immediately by the aponeurosis of the pharynx,* and then by
the superior constrictor.
The tonsil corresponds to the angle of the lower jaw. Compression behind this an-
gle, therefore, affects it at once, and causes pain in cases where it is inflamed. It has an
important relation with the internal carotid artery, especially when that vessel, descri-
bing a curve with the convexity directed inward, touches the tonsil. In front the tonsil
is in relation with the anterior pillar of the fauces, and, therefore, with the palato-glossus
muscle ; behind, with the posterior pillar, and, accordingly, with the palato-pharyngeus
muscle.
Structure. — In structure the tonsils are intermediate between mucous follicles and
glands ; they consist of an agglomeration of follicles, continuous with those at the base
ot the tongue. Groups of these follicles open into small cells or lacunae, which again
open upon the internal surface of the tonsil by the foramina already described. The
mucous membrane covers the inner surface of the tonsil, and, penetrating through the
foramina, lines the interior of all the cells.
The arteries are very large, considering the size of the organ. They are derived from
the labial, the inferior pharyngeal, the lingual, and the superior and inferior palatine.
The veins form a plexus round this organ, called the tonsillar plexus ; it is a dependance
of the pharyngeal plexus. The lymphatic vessels terminate in the glands found near the
angle of the jaw ; hence the inflammation or enlargement of those glands in conse-
quence of inflammation of the tonsil. The lingual and glosso-pharyngeal nerves form a
plexus outside the tonsil, which gives off some branches to it.
The Tongue.
The tongue, the principal organ of taste, is situated within the buccal cavity, and, con-
sequently, at the commencement of the digestive passages (J, fig. 140) behind the lips,
which in many animals are organs of prehension ; also behind the teeth, the organs of
mastication, and below the organ of smell, which possesses the sense of taste in the
lower tribes, and is necessary in all animals for the perception of flavours. It is a mus-
cular organ, free and movable above, before, and on the sides. It is retained in its po-
sition by ligaments which attach it to the os hyoides ; and, by muscles connecting it to
the same bone, to the styloid processes and to the lower jaw ; so that it appears to me
anatomically impossible for persons to have been destroyed by swallowing their tongues,
as some historians have related. Nor do I believe, notwithstanding the authority of J
L. Petit, that division of the fraenum in infants may be followed by a similar accident.
The size of the tongue, though variable in different individuals, is always proportional
to the curve described by the lower jaw ; it is not large enough to fill the buccal cavity
completely when the jaws are closed. It has not been satisfactorily proved that too
large a tongue is the cause of certain defects in speech. However, a natural size is not
absolutely necessary for the exercise of its functions, for these are performed even when
considerable portions have been removed from its apex and sides.
Direction. — Its anterior portion is horizorttal ; behind, it slopes downward and back-
ward, and curves abruptly, so as to become vertical and reach the os hyoides, which in
some measure constitutes its base. This direction, which is maintained so long as the
♦ The existence of this aponeurosis explains why the tonsil always becomes enlarged internally, and also
why abscesses of this part never open externally.
THE TONGUE.
335
tongue is within the mouth, is somewhat altered when it is protruded, the tongue then
becoming horizontal, and the os hyoides raised.
Figure. — Examined without any anatomical preparation, the tongue appears of an oval
figure, having its great end behind. Its form is determined, and, as it were, measured,
by the parabolic curve of the lower jaw, by which it is circumscribed. When separated
from the neighbouring parts, it represents an ellipse, with its long diameter from before
backward. It is perfectly symmetrical, flattened above and below, narrow and thin in
front, and increasing in thickness and in breadth from before backward. Its figure,
which has itself become a term of comparison, does not appear to be essential for the
articulation of sounds, a function that would at first appear to be peculiarly connected
with this form.
The tongue presents for our consideration an upper and a
lower surface, two edges, a base, and an apex.
The Upper Surface or Dorsum of the Tongue. — This is free
in the whole of its extent, corresponds to the roof of the pal-
ate, and is divided into two lateral halves by a median furrow,
which often limits the progress of disease. It is covered by
innumerable eminences, which render it very rough ; these
should be distinguished into such as are perforated, viz., the
glandular eminences, and such as are entire, and have no ori-
fice, viz., the papilla {papilla, a nipple).
The perforated eminences, or lingual glands, improperly class-
ed among the papillae, and known under different names,, may
be distinguished by their circular openings, which are perfect- ,|
ly visible to the naked eye ; by their being situated only at the
base of the tongue ; by their rounded form, and their having
no pedicle ; by the arrangement of the mucous membrane,
which passes over without adhering to them ;* and, lastly, by
dissection, which most distinctly reveals their glandular na-
ture. These lingual glands, moreover, are not follicles, but
true glandular organs, analogous to the labial and buccal
glands. They form a V-shaped ridge, strongly marked in
some subjects, and bounded in front by the ridge (a a, fig.
142) of the same shape, formed by the caliciform papillae.
All the other eminences of the tongue are papillae, which we may describe as the large
and the small.
The large papillce are called caliciform : they are arranged in two lines (a a, fig. 142),
united like the limbs of a V, open in front. Their number varies from sixteen to twen-
ty, some of which are placed irregularly. Haller has seen them forming two rows on
each side. Their size is also variable, but they are larger than all the other papillae.
Each papilla forms a truncated and inverted cone, the base of which is free, and the
truncated apex adherent (papillae truncate, Haller ; papilles boutonnees ou a tete, Boyer).
They are placed in a sort of calyx or cup, or surrounded by a circular trench : hence the
name of papillae circumvallatae (papilles cahciformes, Cuvier). The border or rim of this
cup is itself a circular papilla, t
At the angle of union of the two rows of these glands is a blind opening (b), which is
frequently wanting, and generally known as the foramen caecum of Morgagni (lacune de
la langue, Chaussier). Several anatomists of the last century affirmed that certain sup-
posed salivary ducts, which were afterward shown to be merely veins, had their termi-
nation in this foramen ; it is now generally considered to be a cul-de-sac for the recep-
tion of the secretion from several follicles ; but it appears to me to be only the cavity
of a calyx, the papilla corresponding to which is very imperfectly developed. When the
papilla is more developed, or the calyx less deep than usual, the foramen caecum is said
to be wanting.
The Smull Papilla. — These occupy all that part of the dorsal surface of the tongue
which is in front of the V-shaped ridge, formed by the papilla circumvallatae ; they pre-
sent many varieties. Some of them are conical, others filiform ; some are pointed like
a reed, and others are lenticular or fungiform, that is, flattened at the top, and supported
by a narrow pedicle ; but the conical or filiform are evidently the most numerous, for
they occupy of themselves the anterior portion and the apex of the tongue, while all the
other varieties are disseminated between them. They are directed obliquely backward,
* ll. e., without being closely united to their outer surface, as it is to that of the papillse. The mucous
membrane, as in all glands, is really prolonged into their interior.]
t The want of a uniform nomenclature for the papilla: of the tongue has occasioned great obscurity. I do
not know two authors who agree in this respect. M. Boyer calls the lingual glands papilles lenticulaires ; the
caliciform papillse, papilles boutonnees ou a tile ; and applies the term papilles coniques to the papillse generally
known by that name. Gavard called the glands papilles muqueuses ; and the caliciform p.ipillffl, papilles fungi-
formes. M. H. Cloquet appears to have confounded both the glands and the caliciform papilla; under the name
of papilles lenticulaires ; the papilles fungiformes, according to him, are irregularly disseminated over the edges
and apex cfthe tongue. The use cif tile tenn conical papillse is the only point in which they are all agreed.
4
SPLANCHNOLOGY.
SO that, by rubbing the tongue sUghtly from behind forward, they may be brushed up,
and their exact sliape and length ascertained. This oblique direction is much more
marked in the lower animals than in man.
The conical papillae are sometimes arranged in regular or irregular lines, so as to give
the tongue a fissured appearance. Sometimes even several papillae are united in a line,
so as to form a jagged ridge. We may add, that there is very great variety both in the
shape and arrangement of the lingual papillae.*
The lower surface of the tongue is free only in its anterior third, the muscles which con-
nect the tongue to the neighbouring parts being attached to the posterior two thirds. On
the free portion, which we shall alone notice here, is observed a median furrow, more
distinct than that on the upper surface. At the posterior part of this furrow is a fold of
mucous membrane, called the franum lingua, which is sometimes prolonged to the apex
of the tongue, and prevents the movements of that organ, both in the act of sucking and
during articulation : hence the necessity for the operation known as the division of the
fracnum. On each side of this furrow are seen the ranine veins, on which the ancients
performed venesection ; also an antero-posterior projection formed by the lingual muscle.
The edges of the tongue are thick behind and thinner towards the point. The papiUae
are prolonged in a regular manner upon their upper half in a series of vertical and par-
allel lines.
The actual base is fixed to the os hyoides : the apparent base, which is seen at the
back of the dorsal surface, presents three glosso-epiglottid folds, of which the median
(above b,fig. 142) is much larger than the other two.
The apex is situated immediately behind the incisor teeth ; the median furrows of both
surfaces are prolonged upon it.
Having thus examined the peculiarities offered by the external surface of the tongue
without the aid of dissection, we shall now examine its structure.
Structure of the Tongue. — The tongue being the organ of one of the senses, and being,
also, capable of various movements, we must examine its structure with reference to
both these objects. But, after the example of Haller,+ we shall be principally occupied
here with its structure as a movable organ.
The tongue is essentially composed of muscular fibres, and, in this respect, the heart
is the only organ which can be compared to it. Its framework consists of the os hy-
oides, of a median cartilaginous lamina, and of its papillary membrane.
Framework of the Tongue. — The os hyoides, already described (seen in^^. 143), is tru-
ly the bone of the tongue : hence it has been called the lingual bone by some anatomists.
In man it is not prolonged by a process into the substance of the tongue, as in the lower
animals, but is united to it by the hyo-glossal membrane, which commences at the pos-
terior lip of the body of this bone ; and, again, since the os hyoides is united to the thy-
roid cartilage {t) by ligaments, it follows that all the movements of this bone are commu-
nicated both to the tongue and to the larynx, between which parts it is situated. From
the middle of this fibrous membrane, the median cartilaginous lamina of the tongue, de-
scribed by M. Blandin, proceeds. This lamina, which is perfectly distinct from the car-
tilage described by M. JBaur in the dog and the wolf,t is situated in the median line ; it
is directed vertically, and gives attachment to some muscular fibres by its two lateral
surfaces ; its upper edge is thin, and reaches the middle of the dorsal region of the tongue ,
its lower edge is seen between the genio-hyo-glossi, where it is either free or covered
by a few muscular fibres which interlace below it. It is thick behind, but thin in front,
where its fibres have a number of intervals between them, like those in the septum of
the corpora cavernosa penis.
I regard the papillary membrane as part of the framework of the tongue, on account of
Its density, which is so great that it is with difficulty cut by the scalpel. Moreover, a
great number of the muscular fibres terminate in it.
The Muscles of the Tongue.
These are either intrinsic or extrinsic.
The Intrinsic Muscles. — The ancients regarded the tongue as a single muscle, t*"
structure of which they did not attempt to unravel. Columbus was the first to conside?
this organ as composed of two juxtaposed muscles. If the texture of the tongue be ex-
amined by means of sections made in different directions, it will be found to be compo-
sed of an interlacement of muscular fibres, which will, indeed, appear to be inextricable.
Among these different sections, I would principally call attention to a vertical section,
made at right angles to the axis of the tongue. This section presents a pale muscular
* [All these kinds of papillae are extensions of the mucous membrane, and are, therefore, composed of simi-
lar elements. The papillae vallatae contain many loops of vessels, the papillae conicae, in general, only a few ;
all are abundantly supplied with nerves.]
t Hallcr treats of the muscles of the tongue when describing the organ of voice (lib. ix., sect, ii., p. 421),
and of the papillary membrane with the organs of the senses (lib. xiii., sect. )., p. 99).
t Ihe cartilage described by Baur is a fibrous cord, subjacent to the mucous membrane, and occnpying the
median line on the lower surface of the tongue. It extends from the apex of the latter, where it is very wel
marked, to \Ui: l^ise. where it terminates in a cellular rapht.
THE MUSCLES OF THE TONGUE. 337
tissue in the centre, in which successive layers of vertical and transverse fibres may be
distinguished. A soft, fatty substance, the lingual adipose tissue, is interposed between
these muscular fibres ; it is analogous to the fat formed at the base, or, sometimes, among
the fibres of the ventricles of the heart ; it increases in quantity towards the base of the
tongue, but is entirely wanting at the apex. Around this central part of the tongue,
whicli may with propriety be called, after M. Baur, the lingual nucleus (noyau lingual), we
find a very thin layer of red fibres situated above, a somewhat thicker layer on each side,
and a much thicker layer below ; the lateral and inferior layers belong to the extrinsic
muscles.
A transverse vertical section, therefore, demonstrates the presence of vertical and trans-
verse fibres in the tongue : an antero-posterior vertical section shows that there are fibres
running from one end of the organ to the other, and will also display the vertical fibres
already mentioned. Thus, by means of simple sections, we can demonstrate the exist-
ence of longitudinal fibres running from the base to the apex of the tongue ; of vertical
fibres passing from the upper to the lower suarface ; and of transverse fibres extending
from one side to the other ; and other dissections will confirm this statement. Though
Malpighi,* in a memoir of great interest, had very exactly described and figured the ar-
rangement of the three orders of fibres in the tongue of the calf ; though Steven proved
their existence in the human tongue, and Bidloo had carried his observations still far-
ther ; and although Massa had recommended that, to facilitate this investigation, the
tongue should be previously boiled, or should be examined after putrefaction had com-
menced ; still, almost all anatomists, including Haller, neglected this subject, until MM.
Baur, Gerdy, and Blandin directed attention to it almost at the same time. From the
examination of the boiled tongues of the ox, the sheep, and man, I have observed the
following facts :
1. Under the papillary membrane, which, as I have said before, has almost the density
of cartilage, there is a series of fibres running from before backward. These fibres ap-
pear to rise in succession from the papiUary membrane, and form a layer, which is thicker
in front, where the fibres are collected into a small space, than it is behind, where they are
scattered and pale. In the ox they traverse the yellowish glandular-looking substance
found at the base of the tongue. This thin layer is described by Malpighi, and has been
called the superior or superficial lingualis muscle.
2. On the lower surface of the tongue, between the genio-hyo-glossus and the hyo-
glossus, we find a longitudinal bundle, reaching from the base to the apex. This thick
bundle was first described by Douglas under the name of the lingualis muscle ; it might be
called the inferior lingualis. The lingual muscle of authors generallyt is a small mus-
cular fasciculus, situated on the lower surface of the tongue, between the stylo-glossus
(m, fig. 143) and the genio-hyo-glossus (a). It arises from the base of the tongue, in an
indistinct manner, amid an intricate mass of muscular fibres ; from thence it passes for-
ward, and terminates at the apex of the tongue, where it unites with the fibres of the
stylo-glossus. It shortens the tongue, and depresses its point.
3. On either side of the tongue we find two layers of oblique and very thin fibres, cross-
ing each other. The superficial layer consists of fibres passing forward and downward,
the deep layer of fibres running obliquely forward and upward. These two layers can
only be seen towards the base. They are more easily shown in the ox than in man.
We also find along each side some antero-posterior fibres, continuous both with the stylo-
glossus and the palato-glossus.
4. Lastly, the dissection of the lingual nucleus of a boiled tongue enables us most dis-
tinctly to separate the vertical and transverse fibres already noticed as being seen in the
different sections of the tongue. The transverse fibres form a slight concavity above :
the vertical fibres converge a little from above downward. In the substance of the lin-
gual nucleus, near the base of the tongue, a soft, liquid, adipose Fig. 143.
matter is interposed between the muscular fibres.
The Extrinsic Muscles. — The extrinsic muscles are three on
each side, viz., the stylo-glossus, the hyo-glossus, and the genio-
hyo-glossus.
The Stylo-glossus.
The stylo-glossus {u,figs. 114, 143, 146) is a small, slender mus-
cle, cylindrical above, thin, triangular, and bifid below. It arises
from the styloid process by some tendinous fibres surrounding the
lower half of that process, and slightly also from the stylo-maxil-
lary ligament. The fleshy fibres proceeding from these points
form a rounded fasciculus, which passes downward, inward, and
forward. At the margin of the tongue, opposite the anterior pillar
of the fauces, the muscle becomes flattened, expanded, and trian-
* It is notunwoithy of notice, that Malpighi commenced upon the tongue that series of researches into the
structure of organs which has made him, as it were, the founder of textural anatomy.
t [From this statement Albinus must be excepted ; the lingualis of that anatomist corresponds exactly witb-
Sie muscle described by Douglas.]
Ua
338 SPLANCHNOLOGY.
gular, and divides into two parts : one external, which runs along the corresponding
margin of the tongue, from the base to the apex ; the other internal, which passes be-
tween the two portions of the hyo-glossus, assumes a transverse direction, and is blend-
ed with the transverse fibres of the tongue.
Relations. — On the outside it is in relation, successively, with the parotid gland, the in-
ternal pterygoid muscle, the sub-lingual gland, the lingual branch of the fifth nerve, and
the mucous membrane of the tongue. On the inside it has relations with the stylo-
hyoid ligament, the tonsil, the superior constrictor of the pharynx, and the hyo-glossus
muscle.
Action. — ^The stylo-glossus draws the corresponding edge of the tongue, and, conse-
quently, the entire organ, upward, and to its own side. When the two stylo-glossi act
together, the tongue is increased in breadth, and carried upward and backward : it there-
fore assists in retraction of the tongue.
The Hyo-glossus.
This is a thin, quadrilateral muscle {t,figs. 113, 114, 146), arising from the os hyoides
by two very distinct origins : one from the body of the bone, near the great cornu ; the
other from the whole extent of the anterior border of the great cornu, and also from its
point.
From this double origin the fleshy fibres pass upward parallel to each other, forming
a quadrilateral muscle, which expands a little, in order to terminate upon the sides of the
tongue, between the stylo-glossus and the lingualis. There is an evident continuity be-
tween this muscle and the vertical fasciculi of the tongue.
The direction of this muscle varies according to the positions of the tongue. It is
vertical when the organ is contained in the buccal cavity, and is directed obliquely up-
ward and forward when the tongue is protruded.
The hyo-glossus is almost always divided into two portions corresponding to its double
origin, which are separated below by a cellular interval, and above by the posterior fas-
ciculus of the stylo-glossus. Albinus described them as two distinct muscles : the por-
tion arising from the body of the os hyoides, as the hasio-glossus ; and under the name of
the cerato-glossus, the portion arising from the great cornu. He also admitted a third
portion, under the name of the chondro-glossus, described as proceeding from the small
cornu. Haller, who considered this latter fasciculus a distinct muscle, states that he has
always been able to find it.
Relations. — On the outside it is in relation with the stylo-glossus, the mylo-hyoideus,
the digastricus, the sub-lingual gland, the hypo-glossal nerve, and lingual branch of the
fifth. On the inside, it corresponds to the lingual artery, which never passes between
the two portions of the muscle, to the genio-hyo-glossus, and to the middle constrictor of
the pharynx.
Action. — It depresses the corresponding edge of the tongue, and draws it towards the
OS hyoides. When the tongue has been protruded from the mouth, it assists in drawing
it backward. When the two muscles act together, the tongue is depressed and con-
tracted in its transverse diameter.
The Genio-hyo-glossus.
This is the largest of the extrinsic muscles of the tongue : it is thick, triangular, and,
as it were, radiated {a, Jig. 143). It arises from the superior genial process of the infe-
rior maxilla by a sort of tendinous tuft, from which the fleshy fibres immediately proceed
as from a centre, radiating backward in different directions. The posterior fibres are
attached to the os hyoides, either directly or through the medium of a membrane. They
constitute the superior genio-hyoideus of Ferrein. The more anterior fibres expand upon
the sides of the pharynx, occupy the interval between the os hyoides and the stylo-glos-
sus, and immediately cover the corresponding portion of the pharynx, or, rather, the
amygdaloid excavation. These fibres, which are very distinct (I was acquainted with
them before I was aware that they had been described by others), constitute the genio-
pharyngiens of Winslow. The fibres which are next in order, proceeding forward, all
belong to the tongue, and traverse the whole length of that organ. The most anterior
fibres, which are the shortest of all, having reached the lower surface of the tongue,
curve forward, and terminate near its point. All the others pass perpendicularly upward
and turn a little outward, so as to terminate in the papillary mucous membrane at the
side of the median line.
Relations. — On the inside it corresponds to its fellow, being separated from it by cel-
lular tissue frequently loaded with fat. The two muscles are perfectly distinct, and sep-
arable until they enter the substance of the tongue, beyond which point they cannot be
separated from each other. On the outside it is in relation with the sub-lingual gland,
the mylo-hyoideus, hyo-glossus, stylo-glossus, and lingualis muscle. The hypo-glossal
nerve perforates this muscle between its genio-pharyngeal and lingual portions. Its
lower margin corresponds to the genio-hyoideus, from which it is separated by a very
delicate layer of cellular tissue. Its upper margin is subjacent to the mucous membrane,
of which it occasions a prominence on each side of the fraenum.
THE MUSCLES OF THE TONGUE. 339
Action. — By its hyoid fibres it raises the os hyoides and carries it forward ; by it:.
pharyngeal fibres it draws the pharynx forward and compresses its sides ; by its poste-
rior lingual fibres, as well as the hyoid, it carries the base of the tongue, and, conse-
quently, the whole organ, forward. This is the muscle by which we are enabled to pro-
trude the tongue from the mouth. By means of its anterior or reflected fibres, the tongue,
when protruded, is drawn back into the mouth ; lastly, by its median lingual fibres, the
tongue is made into a groove ; when one muscle acts alone, it is protruded to the oppo-
site side.
Such, including the palato-glossus, already described, are the extrinsic muscles of the
tongue : I shall not include among them the mylo-glossus of the older anatomists, and
described, also, by Heister and Winslow, because it appears to be nothing more than
that portion of the superior constrictor of the pharynx which is inserted into the mylo-
hyoid ridge ; nor yet the glosso-epiglottideus, a very large muscle existing in the lower
animals, which has been described by Albinus in the human subject as a dependance of
the genio-hyo-glossus. After the most careful examinations, I have never been able to
meet with it.
Vessels, Nerves, and Cellular Tissue. — The cellular tissue of the tongue receives arter-
ies and veins, and from it issue both veins and lymphatics.
The arteries consist of the proper lingual, which are very large in comparison to the
size of the organ, the palatine, and the inferior pharyngeal.
The veins form two sets, as in the limbs, and for the same reason : a superficial set,
independent of the arteries ; and a deep set, accompanying those vessels.
^ The lymphatics enter the deep lymphatic glands of the supra-hyoid region.
The nerves are very large, and are derived from three sources, viz., from the ninth
pair, or hypo-glossal ; from the lingual branch of the fifth pair ; and from the glosso-pha-
ryngeal division of the eighth pair.*
The cellular tissue of the tongue is partly serous and partly adipose ; the serous por-
tion is chiefly situated in front, the other is more abundant behind.
The Tegumentary Membrane and Glands. — ^The tegumentary membrane of the tongue is
a continuation of the mucous membrane of the mouth. It is thin and slightly adherent
in almost all its non-papillary portion, and becomes very thick and strongly adherent
wherever the papillae exist. The edges of the tongue are occupied by numerous small
glands, continuous with the sub-lingual glands, and opening upon the lower wall of the
mouth by small excretory ducts.
Development. — The tongue is visible in the youngest embryos. Its early development
has reference to its functions, for it is an essential agent in suction, and is, consequently,
brought into use immediately after birth. The tongue is not double or bifid at first ; in
the earliest embryos it presents the appearance of a single tubercle.
Uses of the Tongue. — The tongue has two very distinct uses. It is the organ of taste,
and it is also a movable organ. In this place we shall consider it in the latter capacity
only. The movements of the tongue are concerned in the prehension of food, in suction,
in mastication, in tasting, in deglutition, in articulation, and in playing upon wind-
instnmients.
In order to fulfil such a variety of uses, it is organized so as to be capable of moving
in every direction. Its movements are either extrinsic or intrinsic. The extrinsic move-
ments, or those of the whole tongue, may be ascertained from our knowledge of the sin-
gle or combined actions of its extrinsic muscles. Thus, it may be protruded from the
mouth, drawn back into that cavity, inclined to the right or to the left side, directed up-
ward or downward, or carried into any intermediate position. In its intrinsic move-
ments it may be contracted transversely by the transverse fibres, diminished in length
by its longitudinal fibres, and contracted vertically and rendered concave by its vertical
fibres ; lastly, its apex can be carried upward by the superior, and downward by the
inferior longitudinal fibres.
By far the most varied, precise, and rapid motions of this organ are required in the ar-
ticulation of sounds, in which it is one of the chief agents. In consequence of this use,
which is by no means the result of a special conformation (for, by constant practice, an-
imals, whose tongues are very different from ours, may be taught to articulate), the
tongue is associated with, and becomes one of the principjd instruments of the mind. It
is the organ by which thought is most conamonly expressed. This use is peculiar to
man.
* The ninth nerve is distributed to the muscles, the lingual nerve to the mucous membrane of the anterior
part and sides, and the glosso-pharyngeal to that of the base of the tongue. (See Organ of Taste.)
I have lately seen a considerable branch of the facial nerve terminating in the tongue ; it was given oft
from the facial nerve at its exit from the stylo-mastoid foramen, crossed obliquely in front of the styloid pro-
cess with which it was in contact, passed in front of the stylo-pharyngeus muscle externally to the tonsil and
parallel to the glosso-pharyngeal nerve, which was situated behind it, communicated with that nerve by sev-
eral arches, and divided into two branches at the base of the tongue, one of which ran along the edge or that
organ, and the other anastomosed by a loop with the glosso-pharyngeal : from this loop some filaments passed
off, to be distributed in the usual manner.
The opposite side did not exhibit a corresponding arrangement.
SPLANCHNOLOGY.
. . - .ziki... - The Salivary Glands.
Besides the labial, buccal, and palatine glands found in the cavity of the mouth, which,
by most anatomists, have been confounded with the follicles or muciparous crypts, there
exists around this cavity a particular glandular apparatus, forming a sort of chain or col-
lar, symmetrically extended along the rami and body of the lower jaw. This chain is
interrupted so as to form six glandular masses, three on each side, named, from their sit-
uation, the parotid, sub-maxillary, and sub-lingual glands.*
The Parotid Gland.
The parotid gland {p, fig. 144), so called from being situated below and in front of
Fig. 144. the external auditory meatus {napa, near, ovc, wrof, the
ear), fills the parotid excavation. It is bounded in front
by the posterior edge of the ramus of the lower jaw ;
behind, by the external auditory meatus and the mas-
toid process ; above, by the zygomatic arch ; below, by
the angle of the lower jaw ; and on the inside, by the
styloid process and the muscles which proceed from
it. This gland has given its name to the region occu-
pied by it.
It is the largest of all the salivary glands, and even
exceeds all the rest put together. Its form is irregular,
and is determined by that of the surrounding parts, upon
which it is moulded like a piece of soft wax. Its su-
perficial portion is broad, but it suddenly becomes con-
tracted when it dips behind the ramus of the jaw.
In order to obtain a good idea of the size and shape
of this gland, it must be removed entire from the irreg-
ular mould in which it is lodged. It has been compared
to a pjTamid, of which the base is directed outward, and the apex inward.
Relations. — Its external surface, or base, is broad, oblong from above downward, irreg
tilarly quadrilateral, and lobulated at the edges ; it is sub-cutaneous, being separated from
the skin, however, by the parotid fascia and the risorius of Santorini, when that muscle
exists. +
Its anterior surface is grooved so as to embrace the posterior edge of the ramus of the low-
er jaw. A bursa, or some loose cellular tissue, facilitates the movements of these parts.
This surface is also in relation with the internal pterygoid muscle, the stylo-maxillary
ligament, and the masseter muscle, on the external surface of which it is prolonged to a
greater or less extent (see fig. 144) in different individuals, and is separated from it an-
teriorly by the ramifications of the facial nerve, by some loose cellular tissue, and by the
transverse artery of the face.
Its posterior surface is in relation %vith the cartilaginous portion of the external audito
ry canal, being moulded upon its convexity, and adhering to it by very dense cellular
tissue : it corresponds also to the mastoid process, the stemo-cleido-mastoid and digas-
tric muscles, and indirectly to the transverse process of the atlas. This surface is ex
tremely irregular, adheres by means of dense cellular tissue, and is dissected off with
great diflieulty in an attempt to remove the entire gland.
On the inside it is reduced to a mere border, which corresponds to the styloid process,
and the muscles and ligament connected with it. It sends off a considerable prolonga-
tion into the space which separates the styloid process and its muscles from the inter-
nal pterygoid : but the most important relation of this border is with the external carot-
id artery, for which it furnishes a groove, and sometimes, even, a complete canal.
Its upper extremity corresponds to the zygomatic arch and the temporo-maxillary ar-
ticulation.
Its lower extremity fills up the interval between the angle of the jaw and the sterno-
mastoid, and is separated from the sub-maxillary gland (m) by a very thick fibrous septum.
Besides the relations already indicated, the parotid has others with the vessels and
nerves which traverse it at different depths : these may be called its intrinsic or deep re-
lations. Thus, the external carotid artery almost always perforates the gland near its in-
ner side ; the temporal artery {see fig. 144), the transversalis faciei, and the anterior au-
ricular, which commence in the substance of the gland, also traverse it in various direc-
tions. We also find within it the temporal vein, which is a communicating branch be-
tween the external and internal jugulars ; the trunk of the facial nerve is at first placed
behind the gland, then penetrates it, and divides into two or three branches, which again
subdivide and traverse it in all directions. The auricular nerve, a branch of the cervi
* The continuity of this glandular chain, admitted by some anatomists, is only apparent. A fibrous septum
always intervenes between the sub-maxillary and the parotid glands.
t In a female in whom I dissected the parotid gland, the risorius arose from the superior semicircular
line of the occipital bone by two distinct fasciculi, which, passing downward and forward, united opposite the
apex of the mastoid process, and then proceeding horizontally, expanded upon the parotid gland. Some of the
fibres reached the commissure of the lips, but the greater number were lost upon the parotid fascia.
THE PAROTID GLAND. 341
cal plexus, also passes through it very superficially.* The parotid gland, by a remark-
able exception, always contains in its substance, a little below the surface, several lym-
phatic glands, which may be readily distinguished by their red colour from the proper
tissue of the gland. It may be imagined that a morbid development of these glands may
have often been mistaken for disease of the parotid itself
Structure. — A thick fibrous membrane covers the parotid glands, and sends prolonga-
tions into it which divide it into lobes, and these, again, into glandular lobules. The ac-
tual structure of the gland, therefore, depends upon the nature of these lobules ; and,
without entering into details which belong more properly to general anatomy, it may be
stated that it has been shown, by the aid of the simple microscope, that each lobule is a
porous, spongy body, something like the pith of the rush, and provided with afferent ves-
sels, viz., the arteries ; and efferent vessels, i. e., the veins and excretory ducts.^ The re-
lations of the nerves and lymphatic vessels with these granules have not been accurate-
ly determined.
The parotid arteries are very numerous ; some of them arise directly from the exter-
nal carotid ; others from its branches, more particularly from the superficial temporal,
the transversalis faciei, and the anterior and posterior auricular.
The veins have similar names, and follow the same direction as the arteries. There
is a parotid venous plexus.
The lymphatic vessels are little known : they terminate partly in the glands at the an-
gle of the jaw, and partly in those which lie in front of the auditory meatus. I have
already said that one or more lymphatic glands are always situated in the parotid gland,
a few hues below its surface.
The nerves are derived from the anterior auricular (a branch of the cervical plexus)
and from the facial nerve : they seem to be lost in the substance of the gland.
The Parotid Duct. — A small excretory duct (resulting from the union of its terminating
vesicles) proceeds from each lobule, and unites almost immediately, at a very acute an-
gle, with the ducts of the adjacent lobules. From the successive union of all these ducts
a single canal results, which emerges from about the middle of the anterior margin of
the gland : this is the parotid duct (s, fig. 144), called also the du^t of Steno, although it had
been previously described by Casserius. It passes horizontally forward, about five or
six lines beneath the zygomatic arch, across the masseter, and at right angles to its
fibres. At the anterior border of the masseter it changes its direction, curves in front
of a mass of fat situated there, dips perpendicularly into the fat of the cheek, perforates
the buccinator in the same direction, and glides obhquely, for the space of several lines,
between that muscle and the mucous membrane of the mouth, which it pierces opposite
the intervEd between the first and the second upper great molar teeth, almost on a level
with the middle of their crown.
The mode in which the Stenonian duct opens into the buccal cavity does not appear
to me to have been sufficiently well understood. It exactly resembles the manner in
which the ureters enter the bladder. Thus, it glides obliquely for a certain distance be-
neath the mucous membrane, a fact that may be easily determined by perforating the
cheek at the point where the duct passes through the buccinator, and then measuring
the interval between this perforation and the buccal orifice of the canal : this interval
varies from two to three lines in extent. Again, the buccal orifice is oblique, like the
vesical opening of the ureter, so that it is extremely easy to pass a fine probe into it.
The duct of Steno is often accompanied by an accessory glandt (glandula socia paroti-
dis, see fig. 144), situated between it and the zygomatic arch. The duct of this little
gland opens into the main canal. I have seen two small accessory glands situated above
the canal, one at the middle and the other at the anterior part of the masseter. Lastly,
as the parotid duct is passing through the buccinator, it is surrounded by a series of
glands continuous with those of the cheeks, called molar glands, the ducts of some of
which appear to open into the canal, and those of others directly into the mouth. Al-
though it is not flexuous, the canal, when separated from the surrounding parts, will be
found much longer than it appears at first sight.
Fig. 145.
* These relations prove the almost absolute impossibility of extirpating this gland
by a cutting instrument, and of compression after Desault's method, for the cure
of salivary fistulae. Compression, which is extremely painful, on acxjount of the
number of nerves passing through it, can only affect its superficial portion.
t [Weber has succeeded in distending with mercury the ducts {d,fig. 145) of the
parotid gland in the infant, and has shown that they terminate in closed vesicular
extremities (c) about - A ^j of an inch in diameter, three times that of the capillary
vessels ramifying upon them. See Mullet's Physiology, translated by Baly, p. 447 ;
and MuIUt on the Glands, translated by Solly, p. 69.— (Tr.)
In the early embryo of the sheep, this gland consists of a canal which opens into
the mouth by one extremity, but is closed at the other, and has numerous short
hollow branches projecting from it into a granular blastema : as development ad-
vances, the blastema is absorbed, and the ramified canal, increasing in length, be-
comes iitill more ramified, so as to form the ducts with their closed vesicular termi-
nations.] * Magnified fifty timcf.
t Desault found this gland very large in a subject where the corresponding parotid was atropmed.
m
SPLANCHNOLOGY.
Relations. — The Stenonian duct is sub-cutaneous and superficial where it passes orer
the masseter ; it is protected by a large quantity of fat, and, in front of the maisseter, by
the zygomaticus major. A considerable branch of the facial nerve, and some arteries
derived from the transversalis faciei, run along this canal.
Structure. — An exaggerated idea is generally entertained of the thickness of the duct
of Steno ; it is only thick at its anterior part, where it is strengthene(^ by an expansion
of the aponeurosis of the buccinator muscle. When freed from the surrounding fat, it
is not thicker than most other ducts, the ureters, for example. The notion that it is in-
extensible is also incorrect. It is true, however, that the diameter of its canal is not
in proportion to the size of the gland. It is formed by two membranes : one external,
the nature of which is not well known ; the other internal, consisting of a prolongation
of the mucous membrane of the mouth. Its arteries and veins are very large.
The Sub-maxillary Gland.
The sub-maxillary gland {m,fig. 144) is situated in the supra-hyoid region, and part-
ly behind the body of the lower jaw ; it is bounded by the reflected tendon of the digas-
tricus, below which it ahnost always projects.
Size and Figure. — It is much smaller than the parotid, but larger than the sub-lingual.
It is oblong from before backward, elliptical, irregular, and divided into two or three
lobes by some deep fissures.
Relati(ms. — On the outside and below, it corresponds to a depression on the inferior
maxillary bone, in which it is completely lodged when the jaw is depressed. When,
on the other hand, the head is bent backward upon the neck, the gland appears almost
entirely in the supra-hyoid region, and is in relation with the platysma, being separated
from it by the cervical fascia, to which it is united by cellular tissue of so loose a tex-
ture, that it may be called a synovial bursa. This surface of the gland is also in rela-
tion with the internal pterygoid muscle and the numerous lymphatic glands situated
£dong the base of the jaw. On the inside and above, it corresponds to the digastric, my-
lo-hyoid, and hyo-glossus muscles, and to the hypo-glossal and lingual nerves.
The sub-maxillary gland almost always forms a prolongation of variable size and shape
above the mylo-hyoideus. Sometimes the lobules of which it is composed are situated
in lines, so as to appear like the Whartonian duct, or, rather, a second canal running
parallel to it. Most commonly, this prolongation is of considerable size and irregular,
and forms, as it were, a second sub-maxillary gland.
The most important relation of the gland is to the facial artery (a), which runs in a
groove on its posterior border, and upon the contiguous part of its external surface.
Sometimes this groove is prolonged forward, and divides the gland into two unequal
parts. We cannot avoid seeing the great analogy between this arrangement and that
of the external carotid artery, with regard to the parotid gland.
Structure. — This is identical with that of the parotid. Its investing fibrous membrane
is weaker, and stiU more diflicult of demonstration. The arteries are numerous, and
arise from the facial and the lingual. The veins correspond to them. The b/mpkatic
vessels are little knovra, and enter the neighbouring glands. The nerves are derived
from the lingual and the myloid branch of the dental. I should remark, that all the nerves
proceeding from the sub-maxillary ganglion are destined for this gland.
The excretory duct of the sub-maxillary gland is called the Whartonian duct, although
it was really discovered by Van Home. It is formed by the successive union of all the
small ducts proceeding from the lobules ; it leaves the gland at the upper bifurcation of
its anterior extremity, and, consequently, above the mylo-hyoideus, and is directed ob-
liquely upward and inward, parallel to the great hypo-glossaJ and lingual nerves. It is
at first placed between the mylo-hyoid and hyo-glossus muscles, and then ghdes between
the genio-hyo-glossus and the sub-hngud gland, to the inner surface of which it is at-
tached.* I have never succeeded in determining whether it receives any excretory
duct or ducts from this gland. Having reached the side of the fraenum linguae, the duct,
which is sub-mucous in the whole of the portion corresponding to the sub-lingual gland,
changes its direction, passes forward, and opens by an extremely narrow orifice upon
the simimit of a prominent and movable papilla found behind the incisor teeth. This
orifice, which can scarcely be seen by the naked eye, was found to admit a hog's bristle
in a particular case presented to the Anatomical Society by M. Robert.t Bordeu has
correctly described the appearance of this orifice by the term ostiolum umbilicale.
The duct of Wharton is remarkable for the thinness of its coats, which are not thick-
er than those of a vein ; for its great calibre, which exceeds that of Steno's duct ; for
the extensibility of its coats, the canal sometimes acquiring an enormous size ; and, last-
ly, for its proximity to the mucous membrane of the mouth, which causes it, when much
dilated, to project into the buccal cavity.
* [See_^^. 146, in which the gland itself (m) hangs down, jesting upon the hyo-glossus ; the digastric and
mylo-hyoid muscles and half the lower jaw have been removed.]
t This was observed in a shoemaker ; the bristle had become the nucleus of a salivary calculus.
THE SUB-LINGUAL GLAND. 343
..-.^^.., .; ^^^^i . The Sub-lingual Gland.
The sub-lingual gland {I, fig. 146), which may be regarded as an agglomeration of small-
. cr glands analogous to those of the lips and palate, is sit-
. uated in the sub-lingual fossa of the lower jaw, at the side J^g. 146^
, of the symphysis menti : it is much smaller than the pre-
ceding gland, with which it is sometimes continuous. Its
shape 8 oblong, like that of an olive flattened at the sides.
The following are its relations : It is subjacent to the
mucous membrane, beneath which its upper edge forms
j^a prominent ridge, running from before backward along
,the sides of the fraenum ; its lower edge rests upon the
mylo-hyoid muscle ; its external surface corresponds
partly to the mucous membrane and partly to the sub-lin-
gued fossa ; its internal surface is in relation with the
mucous membrane, with the genio-hyo-glossus (from
which it is separated by the lingual nerve), with the Whar-
tonian duct (which, we have seen, closely adheres to it),
and with the ranine vein. Its anterior extremity touches
the gland of the opposite side. Its posterior extremity and its lower edge are embraced
by the lingual nerve, which gives numerous filaments to it. A small glandular prolonga-
tion also proceeds from its posterior extremity, and runs along the edge of the tongue.
Structure. — Precisely similar to that of the other salivary glands. Its arteries arise
.from the sub-mental and sub-lingual. Its veins bear the same name. Its nerves are
niunerous, and are derived from the lingual.
Its excretory ducts, called also the ducts of Rivinus, from their discoverer, are seven
or eight in number. They open along the sub-lingual crest : their orifices may be shown
by placing a coloured fluid in the mouth. Most anatomists state, that several of the
ducts of this gland open into the Whartonian duct.
General Characters of the Salivary Glands. — The salivary glands present the following
general characters :
1. They are situated around the lower jaw, extending along its body and rami, from
the condyles to the symphysis ; they are in relation, on the one hand, with the maxilla-
ry bone, and on the other with numerous muscles, so that they are subjected to consid-
erable compression during the movements of the lower jaw. 2. They all have direct
relations with large arteries, which communicate their pulsations to them. 3. They re-
ceive vessels from a great number of points, and the vessels themselves are very numer-
ous. 4. They are penetrated by many of the cerebro-spinal nerves, of which some only
pass through, but a certain number terminate in them. 5. In structure they resemble
the pancreas and the lachrymal glands ; they have no special fibrous investment to isolate
them completely from the surrounding parts ; they have no precise form, and they are
subdivided into lobes and lobules. 6. Their excretory ducts pour their secretion into the
mouth, i. e., the parotids between the cheeks and the teeth, the sub-maxillary and the
sub-lingual glands behind the lower incisors, on each side of the apex of the tongue.
This distribution of the means of insalivation between the two cavities into which the
mouth is divided deserves the attention of physiologists.
The Buccal Muccnis Membrane.
The buccal mucous membrane is continuous with the skin at the free edges of the lips ;
it lines their posterior surface, and is reflected from them upon each of the maxillary
bones, forming a cul-de-sac or trench, and in the median line a small fold, called the frae-
niun of the Ups. About a -line and a half or two lines from the free border of the lips,
it changes its character, and constitutes the gums, which are reflected upon themselves,
so as to become continuous with the fibro-mucous membrane, called the alveolo-dental
periosteum.
In the lower jaw the mucous membrane passes from the alveolar border to the lower
wall of the mouth, and from it to the under surface of the tongue. At the point of re-
flection in the median line, it forms the fraenum hnguae. From the under surface of the
tongue, the raucous membrane passes over its edges and upper surface, where it pre-
sents the peculiarities already described ; and in being reflected from the base of the
tongue to the epiglottis, it forms three folds, the glosso-epiglottid, so as to become con-
tinuous on the one hand with the mucous membrane of the larynx, and on the other with
that of the pharynx.
In the upper jaw it is extended from the upper alveolar border upon the roof of the pal-
ate, passing over the anterior and posterior palatine canals, which it closes, but does not
enter. From the roof of the palate it passes upon the velum, and is continuous with the
nasal mucous membrane at its free edge. On the sides it forms two large folds for the
pillars of the fauces, lines the amygdaloid excavation, covers the tonsil, and becomes
continuous with the mucous membrane of the base of the tongue and of the pharynx.
#44 SPLANCHNOLOGY.
At the sides of the buccal cavity the mucous membrane is reflected from both the alveo-
lar borders upon the inner surface of the cheeks, and thus forms two trenches. At the
anterior edge of the ramus of the jaw, behind the molar teeth, it is elevated by a saliva-
ry gland, which marks the limit between the cheeks and the pillars of the fauces. Inside
this prominence it forms a cul-de-sac.
The buccal mucous membrane sends off prolongations into the numerous canals which
open into the mouth. Thus, on the floor of the mouth there are two for the Whartonian
ducts, and several for the small ducts of the sub-lingual glands. Two others are seen on
the inner sides of the cheeks for the ducts of Steno ; and it is also clear that it must pen-
etrate into the thousands of other orifices with which the mouth is studded (those of the
buccal, labial, palatine, and other glands). But in all these prolongations its structure
is modified, and it becomes exceedingly thin. It has been proved that it lines not only
the larger ducts, but even their minutest subdivisions. Thus, there is a kind of parotitis,
which consists in inflanunation of the lining membrane of the excretory ducts of that
gland ; and then all the canals are filled with muco-puriform secretion, which escapes
by the buccal orifice when the gland is compressed. The numerous openings on the
surface of the tonsil are formed by the prolongations of this membrane into the cavities
situated in its interior.
Although the different parts of the buccal mucous membrane are continuous, they do
not all possess the same characters. Compare, for instance, in regard to their density,
thickness, and closeness of adhesion to the subjacent tissues, the mucous membrane of
the gums and palate with that of the lips and cheeks, or the membrane covering the low-
er with that upon the upper surface of the tongue, or the mucous membrane of the free
edge of the velum palati with that of the arches and the amygdaloid excavation.
The two principal characters of the buccal mucous membrane are the following : 1 .
The presence of an epidermis or epithelium* (as it is called in mucous membranes).
This can be distinctly demonstrated by maceration, or by the action of boiling water or
some acid ; by any of these means a pellicle is raised, having all the characters of an ep-
idermis. It is very thick upon the gums, the roof of the palate, and upon the tongue,
where it forms a horny sheath to each papilla. To the existence of this membrane, and
of the fluid with which it is constantly kept moist, we must attribute the possibility of
applying, or, rather, running, a red-hot iron over the surface of the tongue without burn-
ing the part. 2. The multiplicity of small subjacent glands, so near to each other in some
parts as to form a continuous layer. These glands should be carefully distinguished
from the muciparous follicles or crypts, with which many modern anatomists have
conunonly confounded them. To these two characteristics a third may be added, pe-
culiar to some portions of the buccal mucous membrane, viz., that it is supported by a
very dense fibrous tissue, with which it is completely united. This fibrous layer is per-
fectly distinct from the periosteum, and from its presence the mucous membrane should
be arranged among the fibro-mucous membranes.
The Pharynx.
The pharynx (^opvyf, the throat,t 1, 2, ^,fig. 140), long confounded with the cesopha-
gus, under the common name of gula or oesophagus, is a muscular and membranous semi-
canal, perfectly symmetrical, and situated in the median line : it is a sort of vestibule,
common to the digestive and the respiratory passages, intermediate between tlie buccal
and nasal cavities on the one hand, and between the cesophagus and larynx on the other.
It is situated deeply in front of the vertebtral column, extending from the basilar process
of the occipital bone to opposite the fourth or fifth cervical vertebra and the cricoid
cartilage. It therefore corresponds to the parotid, and partly to the supra-hyoid regions.
Its dimensions deserve particular attention. It is smaller than the mouth, but larger
than the oesophagus, which, compared to it, resembles the tube of a funnel. Hence it
follows, that foreign bodies, which have been able to pass along the mouth and pharynx,
may be arrested in the oesophagus.
In length it is from 4 to 4^ inches, which may be increased to 5^, or even 6^, by dis-
tension, and reduced to 2^ by the greatest possible contraction, which is limited only by
the contact of the base of the tongue with the velum palati rendered horizontal. The
length of the pharynx, therefore, may be made to vary about 4 inches.
The pharynx undergoes these extreme variations both in deglutition and in modula-
ting the voice ; in effecting which latter purpose, it acts in the same way as the tube of
a clarinet or flute. Thus considered, the entire length of the pharynx may be divided
into three parts, a nasal (1,/^. 140), a buccal or guttural (2), and a laryngeal (3) portion.
It may be easily seen that the variations in length affect almost exclusively the buccal
portion, into which the air is received after escaping from the larynx. Now these vari-
ations in the length of the pharynx have the same influence over the compass of the hu-
* [The existence of an epithelium is common to all mucous membranes ; that of the buccal cavity is of the
squamous variety.]
t The term pharynx had no well-defined meaning among the ancients : they sometimps used it to designate
•he phftrynz, properly so called ; sometimes the larynx.
THE PHARYNX. 345
man voice as the differences in the lengths of the tubes of wind-instruments h.iif ii.ori
the sounds produced by them.
The breadth of the upper or nasal portion of the pharynx is measured by the interval
between the posterior margins of the internal pterygoid plates : it is about one inch, and
is invariable. In the buccal portion the same diameter is measured by the interval be-
tween the posterior extremities of the alveolar borders, and is about two inches : it may
be diminished to one inch by the contraction of the constrictor muscles. The breadth
of the larj-ngeal portion is measured, first, by the interval between the summits of the
great cornua of the os hyoides, where it is about one inch and near two lines ; then by
the interval between the superior cornua of the thyroid cartilage, which is an inch and
two or three lines ; and, lastly, by the interval between the inferior cornua of the same
cartilage, about eleven or twelve lines. The contraction of this laryngeal portion may
be carried to complete obliteration of the cavity.
Both the buccal and laryngeal portions, therefore, are capable of contraction, and this
always takes place in deglutition, in order to force down and compress the alimentary
m£iss. Contraction of the buccal portion also takes place in the modulation of sounds :
it exerts the same influence over the compass of the human voice as the contraction of
the tubes of the flute or clarinet does over the notes of those instruments.
The antero-'posterior dimensions of the pharynx are not subject to the same variations as
the transverse and vertical, on account of the presence of the vertebral column. Its en-
largement in this direction is produced during that period in the act of deglutition when
the leuynx and os hyoides are carried forward and upward, and its diminution at the time
when the same parts are carried upward and backward. The antero-posterior diameter
of the pharynx depends upon the length of the basilar process of the occipital bone.
Figure. — The pharynx does not form a complete cavity with distinct and separate
walls, but, rather, hsdf or two thirds of a canal, which is completed in part by several or-
gans otherwise not belonging to it. Moreover, the pharynx, from its commencement
down to the larynx, is habitually open, and in a state of tension ; its walls are never in
apposition : an important circumstance in reference to the continual passage of air
through its nasal and buccal portions. This tension depends on its attachment to the
basilar process, and to the fixed points at its sides, and also upon the tendinous struc-
ture of its upper portion. Opposite the larynx the tension ceases to exist.
The pharynx, as well as all other hollow organs, presents an external and an internal
surface.
The External Surface. — ^This is in relation behind, by a plane surface, with the verte-
bral column (see fig. 140), from which it is separated by the long muscles of the neck
and the anterior recti of the head. It glides, by means of some very loose cellular tissue,
upon the fascia covering the muscles of that region ; and when, from the effect of in-
flammation, this cellular tissue becomes dense, the movements of deglutition cannot be
performed, and dysphagia is the result. The relation of the pharynx to the vertebral col-
lunn accounts for congestive abscesses of the neck sometimes opening into the pharynx.
At the sides the pharynx is separated from the internal pterygoid muscle by a triangular
space, broad below and narrow above, occupied by the internal carotid artery, the inter-
nal jugular vein, and the pneumogastric, glosso-pharyngeal, hypo-glossal, and spinal ac-
cessory nerves, all being surrounded by very loose cellular tissue. The sides of the
pharynx are also indirectly in relation with the parotid gland and the styloid muscles.
Lower down, the pharynx corresponds to a great number of lymphatic glands, and to the
external carotid artery and its branches.
The Internal Surface. — In order to examine this surface, it is necessary to open the
pharynx from behind by a vertical incision. We shall then perceive that this structure
only exists behind and at the sides, but that in front it presents a great number of open-
ings {see figs. 140, 141), the arrangement of which is of great interest.
Proceeding from above downward, we find, 1. The two posterior openings of the na-
sal fossa (I), quadrilateral in form, having their longest diameter vertical, and separated
from each other by the posterior edge of the septum. On looking into them, we see the
posterior extremities of the turbinated bones and the terminations of the several mea-
tuses. 2. The upper surface of the velum palati (c a), forming an inclined plane, which
directs the mucous secretions into the throat. 3. The isthmus of the fauces (2), of a sem-
icircular form, divided into two arches, and exhibiting the pillars, the amygdaloid ex-
cavation, and the prominence of the tonsils. 4. The superior opening of the larynx (3),
the plane of which is directed obliquely upward and forward {see fig. 140) ; the epiglottis
{i,fig. 140), which is ordinarily erect, closes this opening by becoming depressed like a
valve. 5. The posterior surface of the larynx, with its two lateral and triangular grooves,
broad above and narrow below, which have been regarded as specially intended for the
swallowing of liquids, which thus pass on each side of the laryngeal opening.
It is extremely curious and highly important to study all the objects displayed in the
complicated mechanism of the pharynx : by so doing, we learn how the air passes from
the nasal fossa and mouth into the pharynx, and thence into the larynx, into which it is
drawn by the active expansion of the thorax, without ever entering the (esophagus ;
Xx
1
a^ SPLANCHNOLOGY.
how the mucous secretions of the nose, or blood, can pass from the nose down into the
mouth and throat ; how instruments may be introduced from the nasal fossae and buccal
cavity into the oesophagus and larynx, or drawn from the nose into the mouth ; and,
lastly, how solids and liquids can pass into the oesophagus without entering the air-pas-
sages, or why they sometimes take this irregular course.
The posterior wall of the ■pharynx is broader in the buccal region than either above or
below : it may be partially seen through the isthmus of the fauces in the living subject.
There is no folding of the membrane upon any part of this wall : we only find a few
glands forming projections beneath the lining membrane.
On each lateral wall is seen the expanded orifice of the corresponding Eustachian tube
{A, fig. 140), and a groove leading from it downward and inward. This orifice corre-
sponds precisely to the posterior extremity of the lower turbinated bone : an important
relation, because it serves as a guide in the now common operation of introducing a
catheter into the Eustachian tube.
The roof of the pharynx corresponds to the basilar process : it may be reached by the
finger introduced into the mouth, if it be curved directly upward.
There is no very distinct line of demarcation, either internally or externally, between
the pharynx and the oesophagus (y, fig. 140). Their limits are established by a sudden
narrowing of the tube,* by a change of colour in the lining membrane, and by a change
in the direction and colour of the muscular fibres, which are red in the pharynx and
much paler in the oesophagus.
Structure of the Pharynx. — The pharynx is composed of an aponeurotic portion, of
muscles, of vessels and nerves, and of a lining mucous membrane.
The aponeurotic portion, or framework of the pharynx, is composed of the cephalo-pha-
ryngeal aponeurosis and of the petro-pharyngeal aponeurosis.
The cephalo-pharyngeal, or posterior aponeurosis of the pharynx, arises from the lower
surface of the basilar process, from the Eustachian tubes, and from the contiguous parts
of the petrous portions of each temporal bone : it is continuous above with the thick pe-
riosteum which covers the basilar process, is prolonged vertically downward, and, grad-
ually diminishing in thickness, is lost after extending about an inch and a half or two
inches. On this membrane the constrictor muscles of the pharynx terminate.
The petro-pharyngeal, or lateral aponeurosis of the pharynx, arises from the petrous
portion of the' temporal bone, internally to the inferior orifice of the carotid canal, by a
very thick tendinous bundle, continuous, at a right angle, with the cephedo-pharyngeal
aponeurosis ;i it then descends along the sides of the pharynx, and splits into bundles,
which are inserted into the pterygoid fossa between the internal pterygoid muscle and
the circumflexus palati, separating these muscles from each other. From thence it
gives off to the posterior extremity of the inferior alveolar border a fibrous prolongation,
to the front of which the buccinator muscle is attached. This aponeurosis covers the
tonsil, to which it is closely united. It is prolonged downward as far as the upper bor-
der of the OS hyoides, in order to form the framework of the side and lower part of the
pharynx.
Muscles of the Pharynx.
The muscles of the pharynx are divided into intrinsic and extrinsic.
The Intrinsic Muscles.
The intrinsic muscles have a membranous form, and are arranged in three successive
imbricated layers. Santorini described a great many muscles in the pharj'nx, on ac-
count of their numerous attachments ; but Albinus has reduced them to three on each
side, named constrictors, distinguished into an inferior, a middle, and a superior. Chaus-
sier united all the muscles which enter into the composition of the pharynx under the
collective name of les stylo-pharyngiena. The division of Albinus has been generally and
justly preferred.
^' !*'• The Inferior Constrictor.
This is a membranous muscle (w,figs. 141, 147), of a lozenge,
or, rather, a trapezoid shape, the most superficial and the thick-
est of all the muscles of the pharynx, and is situated at the low-
er part of that cavity. It is attached, on the one hand, to the cri-
coid and the thyroid cartilages, and, on the other, to the fibro-
cellular raphe, along the posterior median line of the pharynx
(crico-pharyngien and thyro-pharyngien, Valsalva, Winslow, and
Santorini). It might be called the crico-thyro-pharyngeus. It
-m arises upon the side of the cricoid cartilage, from a triangu-
lar space bounded in front by the crico-thyroideus (a, fig. 147),
* [This occurs exactly opposite the cricoid cartilage.]
+ The superior cervical ganglion of the sympathetic nerve lies upon the angle
formed by these two aponeuroses,
MUSCLES OP THE PHARYNX. 347
from which it often receives some fibres, and behind by the crico-arytenoideus posticus
(i,fig. 141).
Its thyroid origins are much more extensive, and take place from an imaginary ob-
lique line on the outer surface of that cartilage, from the two tubercles at the extremi-
ties of that line, and from the entire surface behind it ; also from the upper and poste-
rior borders, and from the corresponding inferior comu of the same cartilage. Having
thus arisen by two very distinct digitations, the fleshy fibres pass in different direc-
tions : the inferior fibres, short and horizontal, proceed directly inward ; the superior be-
come longer, and are directed more obliquely upward, in proportion as they approach
the upper part of the muscle : they terminate by an expanded border of much greater
extent than the outer border, and the upper extremity of which rarely extends above
the middle of the pharynx. The transverse direction and the shortness of the inferior
fibres have obtained for them the name of the (Esophageal muscle ( Wiiislow, Santorini).
Relations. — Covered by a dense cellular membrane, which surrounds the entire pha-
rynx, and which might be regarded as the proper sheath of its muscles, the inferior con-
strictor has the same relations posteriorly as the pharynx itself Externally it is cov-
ered by the sterno-thyroid muscle and the thyroid body. It covers the middle constric-
tor, the stylo-pharjmgeus, and palato-pharyngeus, and, for a great part of its extent, it is
in contact with the mucous membrane of the pharynx (see figs. 141, 147). The recur-
rent larjTigeal nerve passes undSr the lower margin of this muscle, near its cricoid at-
tachment, in order to enter the larynx. Its ufper margin is well defined from the other
constrictors by a tolerably distinct ridge, and by the passage of the superior laryngeal
nerve beneath it. Winslow states that he has seen some fibres of the muscle arise from
the thyroid body ; and Morgagni, that he has traced some from the first ring of the
trachea.
Action. — It is simply a constrictor in its lower portion : its upper fibres act as a con-
strictor, a depressor, and a tensor of the posterior wall of the pharynx ; it can also raise
the larynx, and carry it backward.
The Middle Constrictor.
This is a membranous triangular muscle {v, figs. 141, 147), situated in the middle of
the pharynx, upon a plane anterior to the preceding.
It arises from the os hyoides, and is inserted into the posterior median raphe {hyo-pha-
ryngeus). It arises from the os hyoides in the following manner : 1. From the whole ex-
tent of the upper surface of the great comu below the hyo-glossus {t), from which it is
separated by the lingual artery ; a great many fibres arise by a tendinous origin from the
apex of this comu. 2. From the lesser comu and the contiguous part of the stylo-hyoid
ligament. From these difTerent origins, which form the external truncated angle of the
muscle, the fleshy fibres diverge in various directions ; the inferior passing downward,
the middle transversely, and the superior upward : the latter are much more oblique and
more numerous than the others, and terminate in a pointed extremity, which never reach-
es as high as the basilar process.
Relations. — Its external surface is in a great measure superficial, and is in relation with
the muscles of the prae-vertebral region, through the medium of the cellular investment
of the pharynx. It is covered, in the rest of its extent, by the inferior constrictor and
the hyo-glossus. It covers the mucous membrane of the pharynx, the superior constric-
tor, the stylo-pharyngeus, and the palato-pharyngeus. Its upper margin may be dis-
tinguished from the superior constrictor by its projecting slightly behind that muscle, and
by the stylo-pharyngeus (r), which lifts up this border in penetrating into the pharynx.
Action. — It is a constrictor of the pharynx, and can draw the os hyoides upward and
backward.
The Superior Constrictor.
This is a quadrilateral muscle {g,figs. 141, 147), occupying the upper part of the pha-
rynx ; it arises from the pterygoid process, the mylo-hyoid ridge, and the base of the
tongue, and is inserted into the posterior median raphe {pterygo-pharyngeus, buccinato-
pharyngeus, mylo-pharyngeus, and glosso-pharyngeus, Santorini).
It arises, 1. By tendinous fibres, from the lower third of the margin of the internal
pterygoid plate and its hamular process. 2. From the contiguous portion of the palate
bone, and the reflected tendon of the circumflexus palati. 3. From the buccinato-pha-
ryngeal aponeurosis, which extends from the pterygoid process to the posterior extrem-
ity of the inferior alveolar arch.* 4. From the posterior extremity of the mylo-hyoid
line. 5. The fibres which are said to arise from the base of the tongue are nothing
more than those fibres of the genio-hyo-glossus, which Winslow has described as le ge-
nio-pharyngien. These are the same fibres, so difficult to demonstrate, which Valsalva
and Santorini have regarded as forming a particular muscle, denominated by them the
glosso-pharyngeus.
From these different origins the fleshy fibres curve backward, and then pass trans-
* As this same aponeurosis gives attachment to the buccinator, it may be conceived that the contruction ot
that muscle cannot be altogether without effect upon the pharynx.
^Ml SPLANCHXOLOGT.
versely inward ; the superior form a sort of arch, having its concavity directed upward
{see Jigs. 141, 147), and are inserted into the cephalo-pharyngeal aponeurosis : they form
the ccphalo-pharyngeus muscle of some authors, which is said to be continued from one
side to the other without any intermediate raphe. This muscle forms a very thin layer,
the fibres of which are paler and less distinct than those of the other constrictors.
Relations. — Its external surface is partly covered by the preceding muscle, and has be-
hind, and on the sides, the same relations as the pharynx. This muscle forms the inner
side of a triangular space already described (p. 345) (the maxillo-pharyngeal), the outer
side of which is formed by the ramus of the lower jaw and the internal pterygoid mus-
cle {b,fig. 141), and which is occupied by the internal carotid artery, the internal jugu-
lar vein, and the pneumogastric, h)T)0-glossal, and spinal accessory nerves.
Its internal surface (fig. 141) is in relation with the pharyngeal mucous membrane,
with the levator palati (c), which it separates from the circumflexus palati (d), and with
the palato-pharyngeus (c).
Action. — It is a constrictor.
Remarks. — From the preceding description, it follows, 1. That the constrictors of the
pharynx form three super-imposed or, rather, imbricated muscular layers. This imbrica-
tion, or overlapping, is so arranged that the projections (very slight, it is true) formed
by the upper margins of the constrictors are on the outer, not on the inner surface of
the pharynx ; and this has, perhaps, some relation to^he downward course of the ali-
mentary mass.* 2. That the thickest part of the muscular layer formed by the constric-
tors is opposite the buccal portion of the pharynx, where the lower and middle constric-
tors overlap ; and that the thinnest part is in the nasal portion, which is formed by the
superior constrictor alone. 3. That the pharyngeal insertions of all the constrictors are
upon a single line, the median raphe, while their points of origin are exceedingly nu-
merous, viz., commencing from below, the cricoid cartilage, the thyroid cartilage, the great
and lesser cornua of the os hyoides, the base of the tongue, the mylo-hyoid line, the buc-
cinato-pharyngeal aponeurosis, and, lastly, the pterygoid process.
The Extrinsic Muscles.
The extrinsic muscles of the pharynx are generally two in number, the stylo-pharyn-
geus and the palato-pharyngeus. The latter has been already described among the mus-
cles of the velum palati. It is by no means uncommon to find several supernumerary
muscles
The Stylo-pharyngeus.
This muscle (r, figs. 143, 147), which is round above and broad and thin below, arises
by tendinous and fleshy fibres from the inner side of the base of the styloid process, or,
rather, from the vaginal process surrounding that base. From this point it passes down-
ward and inward, becomes wider and flattened as it enters the pharynx between the
middle and superior constrictors, to spread out beneath the mucous membrane. Its up-
per fibres ascend, the middle are transverse, and the lower fibres descend to terminate
along the posterior border of the thyroid cartilage! (see jig. 143). These fibres, togeth-
er with those of the palato-pharyngeus, form the fourth muscular layer of the pharynx.
Relations. — Before entering the pharynx, the stylo-pharyngeus is in relation on the out-
side with the stylo-glossus muscle (u), the external carotid artery, and the parotid gland ;
on the inside, with the internal carotid and the internal jugular vein. Its most interest-
ing relation is with the glosso-pharyngeal nerve, which runs along its outer side. Some
branches of the nerve often pass through it. In the pharynx it is covered by the middle
constrictor, and it lies outside the superior constrictor, the palato-pharyngeus, and the
mucous membrane.
Actimi. — It raises the larynx and the pharynx.
Supernumerary Muscles of the Pharynx.
Among the supernumerary extrinsic muscles of the pharynx, I shall notice, 1. A fascicu-
lus pointed out by Albinus, which I have often met with : it arises from the petrous portion
of the temporal bone, and passes into the walls of the pharynx ; it is the petro-pharyn-
geus of some authors. 2. A very strong fasciculus, arising from the basilar process in
front of the foramen magnum, passing downward and inward, and interlacing with its
fellow of the opposite side in the median line : it may be called the occipito-pharyngeus.
3. A small muscle, which I have seen arising by well-marked tendinous fibres from the
summit of the hamular process of the internal pterygoid plate, passing obhquely inward
and downward, and expanding on the walls of the pharynx ; it may be called the extrin-
sic pterygo-pharyngeus. 4. Riolanus has described a spheno-pharyngeus arising from the
spinous process of the sphenoid, and Santorini and Winslow have noticed a salpingo-pha-
ryngeus arising from the cartilaginous portion of the Eustachian tube and the contiguous
bone, and blended in the pharynx with the palato-pharyngeus. »
* In the construction of pipes or tunnels for the conveyance of water, &c., each piece is received into that
below it ; an opposite arrangement would facilitate the blocking up of the pipe.
+ Some anatomists affirm that they have seen fibres from this muscle reaching the base of the tongue, the
epiglottis, and the os hyoides.
SUPERNUMERARY MUSCLES OF THE PHARYNX. 349
Such, then, are the muscles of the pharynx. They are all, as we have seen, constric-
tors, and at the same time elevators, in consequence of their fibres rising to a greater
height internally upon the median line than they do externally ; the stylo-pharyngeus
alone can be regarded as a dilator. Indeed, dilatation is chiefly effected by the muscles
of the OS hyoides, by the action of which the larynx is carried upward and forward ; we
may, therefore, with Haller, consider them as extrinsic muscles of the pharynx.
Pharyngeal Mucous Membrane. — The muscular semi-canal of the pharynx is lined by a
mucous membrane continuous with the buccal and nasal mucous membranes on the one
hand, and with those of the larynx and oesophagus on the other. This membrane, which
is of a reddish colour, presents some peculiarities at different parts of its extent. Above,
near the basilar process, it is thick, and, as it were, fungous, and closely united to the
periosteum, from which, indeed, it cannot be separated ; in this region it is very liable
to become the seat of fibrous polypi. Near the posterior orifices of the nasal fossae and
the openings of the Eustachian tubes, it is, in some respects, similar to the pituitary
membrane.* It forms a sort of rim around the trumpet-shaped orifice of the Eustachian
tube, into which it is prolonged in a remarkable manner, gradually becoming thinner,
and at length continuous with the lining membrane of the cavity of the tympanum. This
continuity of the mucous membrane of the pharynx and Eustachian tube explains the
close sympathy between these parts, and also the deafness which so frequently follows
chronic sore throats and coryzae, in consequence of the obstruction of these tubes.
In its buccal portion it exactly resembles the mucous membrane, upon the lower sur-
face of the velum palati : the part covering the posterior surface of the larynx is pale,
and forms several folds.
The mucous membrane of the pharynx adheres to the subjacent muscles only through
the medium of very loose cellular tissue, which is never loaded with fat, nor infiltrated
with serosity. It is ■still less intimately adherent to the posterior surface of the larynx.
Its surface is raised by a great number of small glands, chiefly occupying the upper
part of the pharynx, near the posterior nares : we shall divide them into agglomerated
and solitary. Two agglomerated glands are always situated around the orifices of the
Eustachian tube ; they open upon the mucous membrane, either separately or together.
These glands are sometimes arranged in a line, sometimes in several parallel rows.
Haller believes that the salpingo-pharyngeus of Santorini and Winslow is nothing more
than a series of these glands united together by fibrous tissue. The solitary glands are
scattered over the whole extent of the pharynx. Lastly, the pharyngeal mucous mem-
brane is provided with a thin epithelium,! which can be easily demonstrated by macer-
ation and the action of acids.
Vessels and Nerves. — The pharynx receives a principal artery on each side, viz., the
inferior pharyngeal, a branch of the internal carotid. The superior pharyngeal branch
of the internal maxillary, and some small twigs from the palatine and the superior thy-
roid, complete its arterial system.
Its veins form a very considerable plexus around it (the pharyngeal venous plexus), and
terminate in the internal jugular and superior thyroid. The lymphatiXhessels are little
known ; they pass into the glands lying along the internal jugular vein. Its nerves are
very numerous, and form a remarkable plexus — the pharyngeal, which I regard as one
of the largest in the body. They are derived from two sources : 1 . From the cerebro-
spinal axis, viz., the pharyngeal nerve, a branch of the pneumogastric, which appears to
be principally distributed to the muscular layer ; the glosso-pharyngeal, which appears to
be chiefly destined for the mucous membrane ; and, lastly, some branches of the supe-
rior laryngeal and the spinal accessory. 2. From the ganglionic system, several large,
gray, and soft branches being distributed to it from the superior cervical ganglion.
This abundance of nerves, and also the sources from which they are derived, will
serve to explain, 1. The great sensibility of the pharynx, to which part we refer the
feeling of thirst, which some have, therefore, proposed to term the pharyngeal sense ;
2. The part which it performs in the perception of certain flavours, for example, those
of acids ; 3. The sympathy between the pharynx, the base of the tongue, and the stom-
ach ; 4. The feeUngs of constriction and strangulation, so common in the pharynx ; 5
The spasms with which it is affected in tetanus and hydrophobia ; and, 6. The nature
of the globus hystericus, &c.t
Development. — The development of the pharynx offers no remarkable phenomena •,
still, it is an exception to the general law of bilateral development, laid down by some
anatomists.
Uses of the Pharynx. — ^The pharynx is one of the principal organs of deglutition. It
* See note, infra. .
t [According to Dr. Henl6, the upper part of the mucous membrane of the pharynx is covered with a <^U**
*ed columnar epithelium, as far down as a horizontal line extending from the lowei border of the atlas to the
floor of the nasal fossa ; below that line the epithelium assumes the squamous form, and is not cihated. In
the Eustachian tube it is also columnar, and provided with cilia ; but in the cavity of the tympanum it is
squamous, and destitute of those organs.] ,
i We cannot explain why the syphilitic virus has so serious a predilection for the mucous membrane ot the
pharynx.
SPLANCHNOLOGY.
serves also for the passage of air in respiration, and as a tube for modulating the voice.
The importance of the pharynx in this last point of view, and the influence which its dif-
ferent degrees of shortening and constriction exercise upon the compass of the voice,
do not appear to me to have sufficiently engaged the attention of physiologists.
The CEsophagus.
Tlie (esophagus {olau, I will convey, and ^ayw, I eat) is a musculo-membranous canal,
an organ of deglutition, intended to convey the food from the pharynx into the stomach.
It occupies the lower part of the cervical region and all the thoracic region, and perfo-
rates the diaphragm, in order to terminate in the stomach.
Directions. — It is situated in the median line, resting against the vertebral column ;
its general direction is straight, for the food does not remain in it ; nevertheless, it pre-
sents several slight curves ; at its commencement it is exactly in the middle line, but
inclines somewhat to the left side in the neck ; in the upper part of the thorax it deviates
slightly to the right side, then again becomes median, and, lastly, inclines to the left,
where it passes through the diaphragm. The general direction of the oesophagus per-
mits the introduction of straight probangs into the stomach. The inflection which it
undergoes at its entrance into the thorax explains the reason why these instruments
are sometimes arrested opposite the first rib.
Dimensions. — The length of the oesophagus corresponds to the interval between the
pharynx and the stomach, i. e., the space between the fifth cervical vertebra, or the cri-
coid cartilage, and the tenth dorsal vertebra. In regard to its calibre, or diameter, the
oesophagus is the narrowest part of the alimentary canal. Its diameter is not uniform
throughout, the cervical portion* being certainly the narrowest ; and, therefore, foreign
bodies which are too large to pass through the alimentary canal, are generally arrested
in the neck. The widest portion of the oesophagus is its lower end.
The oesophagus is capable of a certain degree of dilatation, as is proved by the passage
of large foreign bodies for a considerable distance through it (Mim. d'Hivin, Acad. Roy.
de Chirurgie), sometimes even aa far as the stomach. That this dilatability, however,
is very limited, may be inferred from the pain caused by swallowing too large a morsel,
and also from the stoppage of foreign bodies in the gullet. Nevertheless, in some CEises,
from external pressure upon, or from stricture of, some part of this canal, it becomes
greatly enlarged above the seat of obstruction, and forms a sort of ampulla or dilatation
resembling the crop in gedlinaceous birds. In one case I found a sort of pouch, or di-
verticulum, of the mucous membrane, of considerable size, protruding between the sep-
arated muscular fibres, and at first sight resembling the crop of gallinaceous birds. An
example has been recorded of dangerous suffocation occasioned by the pressure of ali-
mentary matters in a cavity of that kind.
Figure. — The oesophagus is cylindrical, and differs from the rest of the alimentary
canal in never containing any air, so that (when at rest) its parietes are always in con-
tact. It is somewhat flattened, and, as it were, compressed, at its upper part ; but be-
low it always pre|pnts the appearance of a solid cylinder, or a dense firm cord. This
appearance exists through its whole extent in some animals, the horse, for example.
Like all hollow organs, the oesophagus presents two surfaces, an external and an in-
ternal.
The external surface. In its long course the oesophagus has many relations, all ol
which are of great importance, and must be examined in the neck, in the thorax, and in
the abdomen.
In its cervical portion (y. Jigs. 1 14, 140), the oesophagus is in relation in front with the
membranous portion of the trachea {x), beyond which it projects a little on the left side.
The cellular tissue uniting these two canals is most condensed above. All that portion
which projects beyond the trachea comes into relation with the left sterno-thyroid muscle
(71, fig. 1 14), the thyroid body {z), the left recurrent laryngeal nerve, and the inferior thy-
roid vessels, which cross it at right angles. The relation of the oesophagus to the tra-
chea explains how foreign bodies arrested in the former passage may compress the tra-
chea, and impede or even prevent respiration. The deviation of the oesophagus to the
left is the reason for selecting that side for the performance of oesophagotomy. Behind,
it corresponds to the longi colli muscles and to the vertebral column, being united to
them by loose cellular tissue, so that it is enabled to execute those movements which
are necessary for the performance of its functions. Laterally, it corresponds to the thy-
roid body, the common carotid artery, and the internal jugular vein ; but these relations
are somewhat modified on each side, in consequence of the deviation of the oesophagus.
Thus, the relations of the oesophagus with the left common carotid are much more im-
mediate than those with the right. The left recurrent nerve lies in front of the oesopha-
gus, the right nerve a Uttle behind it.
Its thoracic portion (o, fig. 161) is situated in the posterior mediastinum, and is in rela-
tion in front, commencing from above, with the trachea, then with its bifurcation, and
slightly also with the left bronchus, which crosses it obliquely, and which may be com-
* [Opposite the cricoid cartilage.l
THE OESOPHAGUS. 351
pressed by it during the retention of a foreign body (an example of this accident has been
recorded by Habicot) ; lastly, it is situated opposite and behind the ascending portion of
the arch of the aorta, and the base and posterior surface of the heart, from which parts
it is separated by the pericardium. Behind, it is in relation with the longus colli and the
vertebral column, to which, however, it is not so closely applied as in the neck ; nor does
it follow the curvature of the spine in the dorsal region, but is separated from it by a
space filled with cellular tissue, lymphatic glands, the vena azygos, and the thoracic duct,
the latter being placed to its right side, at the lower part of the thorax, but passing be-
hind it above, so as to reach the left side. Below, at the point where the oesophagus
deviates to the left side, in order to gain the opening of the diaphragm, it lies in front of
the aorta. On each side it forms a projection along the wall of the mediastinum, which
is thus brought into relation with the corresponding lung ; it is much more prominent on
the right than on the left side. On the left side it is also in contact, in its entire extent,
with the thoracic aorta (h,fig. 161), which is situated a little behind it. Above, it has
immediate relations with the arch of the aorta, as that vessel is passing backward and
to the left side of the vertebral column. It is commonly, at this point, that aneurisms
of the aorta open into the oesophagus.
In all this region the oesophagus is enveloped by a serous cellular tissue, extremely
loose and very abundant ; it is surrounded by a great number ofljrmphatic glands, which
have been improperly named oesophageal. These glands, when enlarged, sometimes
compress the gullet so much as completely to arrest deglutition. Lastly, the two pneu-
mogastric nerves run along each side of the oesophagus ; inferiorly the left comes in front,
and the right retires behind the canal : they communicate with each other throughout
their course by loops or arches, which, perhaps, explains the pain caused by swallowing
too large a mass of food.
In its abdominal portion (if such can be said to exist), the oesophagus is in relation with
the oesophageal opening of the diaphragm, below which it is entirely covered by the
peritoneum. On the right side and in front it is embraced by the left extremity of the
liver ; behind, by the lobulus Spigelii. In some subjects the abdominal portion of the
oesophagus is an inch in length, but this, I think, is occasioned by descent of the stomach.
The internal surface is remarkable for its pale colour, which contrasts strongly with the
rosy hue of the stomach and the upper part of the pharynx, for the vsTinkling of its pa-
rietes and their contact with each other, and, lastly, for its longitudinal folds, which
seem to have reference to the necessity for its momentary distension during the mere
passage of the food through it.
Structure. — The oesophagus is essentially composed of two cyhndrical membranes, one
internal or mucous, the other external or muscular.
The muscular coat is remarkable for its thickness, which greatly exceeds that of any
other part of the alimentary canal, and is connected with the necessity for the rapid pas-
sage of the alimentary mass from the pharynx into the stomach. It is susceptible of hy-
pertrophy, as we find in cases of stricture of the lower part of the gullet. I have seen
it five or six lines thick. In all herbivorous animals in which the oesophagus is almost
incessantly in action, in those in which the food is carried upward in opposition to grav-
ity during the act of deglutition, in the horse and in ruminants, the muscular coat is still
more developed than in man.
The muscular coat is of a red colour immediately below the pharynx, and rosy through
the rest of its extent, but of a darker tint than in the succeeding portion of the aliment-
ary canal. It is of a vivid red in herbivora.*
This coat is composed of two very distinct layers, the external consisting of longitu-
dinal fibres regularly disposed upon all sides of the oesophagus ; the internal, of circular
fibres, in which we shall in vain seek for the spiral arrangement described by some anat-
omists as existing in animals and in man.t The longitudinal fibres seem to arise, at
least in part, from the posterior surface of the cricoid cartilage, in the median line, be-
tween the two posterior crico-arytenoid muscles ; they evidently become continuous be-
low with the longitudinal muscular fibres of the stomach. The first muscular ring of the
oesophagus appears to arise from the cricoid cartilage ; it has been designated the crico-
msophageus. There is no sphincter, as some anatomists have affirmed, round the lower
extremity of the oesophagus.
The Mucous Membrane. — As Bichat has remarked, the mucous membrane of the oesoph-
agus is, perhaps, next to the buccal, the thickest in the alimentary canal. By a remark-
able exception (also observed in the rectum), its outer surface is united to the adjacent
membrane by a very loose cellular tissue ; so that the whole mucous cylinder may be
removed entire from the sort of muscular sheath in which it is contained. It has even
been said that the muscular coat can force the mucous membrane downward by its con-
traction, so as to produce a projecting rim around the cardiac orifice of the stomach,
jmalogous to that which is formed at the anus in prolapsus. The longitudinal folds of
* [It consists of involuntary muscular fibres (note, p. 323), intermixed with fibres possessing transverse stnte.]
i [These fibres are obviously spiral in the ruminant, and many other mammalia ]
352
SPLANCHNOLOGY.
the mucous membrane are not caused by the contraction and elasticity of the circular
fibres of the muscular coat, but depend upon a peculiarity of structure. If the first hy-
pothesis be correct, why should not the mucous membrane also present transverse folds
from the action of the longitudinal fibres \ for the extremities of the oesophagus are not so
fixed, nor is its tension so great that it could not be shortened by the action of these fibres.
Besides the longitudinal folds, there are also in the oesophagus a number of wrinkles
analogous to those of the skin, and, therefore, irregular ; they appear to me to be caused
by the elasticity of the muscular fibres.
The mucous membrane of the oesophagus has a thick epithelium, which may be easily
shown by maceration and the action of acids, or even without preparation, and which
terminates at the cardiac orifice of the stomach by an irregularly fringed or festooned
border.*
When examined by the microscope, the free surface of the mucous membrane pre-
sents a number of small linear ridges, running vertically, and united together by other
oblique ridges, so that the whole surface has a reticulated aspect. These ridges are
formed by papillae or villosities, the arteries and veins of which have been accurately
figured by Bleuland.
The surface of the mucous membrane is raised in various places by small, oblong, and
flat glands found here and there over the entire oesophagus. They were first described
by Steno, and should be carefully distinguished from the oesophageal lymphatic glands :
the latter are external to the oesophagus, and, in certain animals, frequently contain small
entozoa : they have been supposed to open into the oesophagus, and to deposite within it
a fluid containing these animalcules, which some physiologists have regarded as the
chief agent in digestion. Any communication, however, between these lymphatic glands
and the cavity of the gullet is purely accidental. The true oesophageal glands are very
numerous.!
In the oesophagus, there is only a trace of the fibrous membrane, which forms the frame-
work of the alimentary canal ; it adheres to the muscular coat, and is, therefore, but
loosely attached to the mucous membrane.
There is no external serous membrane ; it would not have yielded to the instantane-
ous dilatation required in the cesophagus. The two laminse of the posterior mediasti.
num corresponding to its sides may be regarded as forming the rudiment of a serous coat.
Vessels and Nerves. — The (esophageal arteries are numerous, and arise from several
sources. They may be distinguished into the cervical, proceeding from the inferior thy-
roid ; the thoracic, given off either directly from the aorta or from the bronchial and in-
tercostal arteries, and sometimes from the internal manmiary ; and, lastly, the abdominal,
arising from the coronary artery of the stomach, and the inferior phrenic.
The vei7is terminate in the inferior thyroid, the superior cava, the azygos, the internal
manunary, the bronchial, the phrenic, and the coronary of the stomach.
The lymphatic vessels enter the numerous glands which surround the oesophagus.
The 7ierves are very numerous, and are derived from the pneumogastrics, which sur-
round the oesophagus with a series of loops ; these are joined by some branches from the
thoracic ganglia oi the sympathetic.
The development of the cesophagus presents nothing worthy of notice.
Functions. — The cesophagus is intended to convey the food rapidly from the pharynx
to the stomach. This function is performed by its longitudinal fibres shortening the pas-
sage, and by its circular fibres contracting it successively from above downward during
deglutition ; in vomiting or regurgitation, the contraction proceeds from below upward.
Fig. 148.
The Stomach.
The stomach {yaarfip, ventriculus), one of the princi-
pal organs of digestion, is that wide dilatation {s, fig.
139) of the ahmentary canal, intervening between the
cesophagus (a) and the duodenum (i c), in which the
food is collected and converted into chyme.
Situation. — It is situated at the junction of the upper
tenth with the lower nine tenths of the alimentary ca-
nal, between the organs of deglutition and those of
chylification. It occupies the upper part of the abdom-
inal cavity («, figs. 155, 161), almost entirely fills the
left hypochondrium, and advances into the epigastri-
um, as far as the limits of the right hypochondrium.i:
* [The epithelium is, in fact, continued on through the rest of
the alimentary canal, but becomes thinner, and assumes a different
character : in the cesophagus it is squamous.]
t [Especially around the lower extremity of the gullet.]
t [In order to facilitate the description of the viscera contained
in the abdominal cavity, anatomists have adopted the following ar-
tificial division of that cavity into several regions : The abdomen
is first divided into three zones by two horizontal lines, one (o a
THE STOMACH. 353
It is maintained in its place by the oesophagus and duodenum, and also by some folds
of the peritoneum, which connect it with the diaphragm, the hver, and the spleen. The
stomach is, therefore, less subject to displacement than most of the abdominal viscera.
It may even be generally stated, that almost all the changes in the relative situation ol
this organ are the results of displacements or alterations in the size of those organs
which are connected with it. I do not here refer to examples of complete transposition
of the viscera, nor to those cases of malformation of the diaphragm, in which the stom-
ach has been found in the thorax.
Direction. — The stomach is directed obliquely downward to the right side, and a little
forward ; this direction affords some explanation of the almost constant habit of lying
on the right side during sleep, and why the rest is disturbed and digestion rendered diffi-
cult in those who lie upon the left side. Changes in direction of the stomach depend
upon the same causes as changes in its situation. Thus, dragging produced by displace-
ment of the small intestine or the omentum, enlargements of the liver or spleen, or the
use of too tight stays,* must necessarily affect the direction of this organ. We not un-
frequently find stomachs having a vertical direction.
Number. — The stomach is single in the human subject as well as in the greater num-
ber of animals. The examples of double or triple stomachs in the human subject are
merely cases of single stomachs having one or more circular constrictions. t The es-
sential character of a double stomach is not an accidental or even a congenital contrac-
tion, but a difference in structure. Bilocular stomachs, indeed, are very common ; but
this form (resembling that of some kinds of calabash-gourds), though sometimes extreme-
ly well marked when the stomach is empty, disappears ahnost entirely when it is much
distended by inflation.
Size. — In all animals, the stomach is the most capacious part of the alimentary canal ;
so that, in many species, where its limits are not so clearly defined as in man, the ex-
istence of a stomach is determined only by the presence of a dilatation. It is of consid-
erable size in herbivora, but comparatively much smaller in camivora. The human
stomach is intermediate between these extremes — a fact which affords evidence of its
adaptation to both vegetable and aliment diet. The human stomach, however, presents
innumerable varieties in size, from a state of extreme contraction, in which it scarcely
exceeds the duodenum, to such an enormous degree of dilatation that it occupies a third,
a half, or even almost the whole, of the abdominal cavity. These differences depend
less upon original variations, than upon its peculiarly dilatable and elastic structure,
which enables it to contain a large quantity of food, and to contract more or less com-
pletely upon itself when empty. Thus, the stomach has a much greater capacity in those
who adopt the bad habit of eating only one very full meal in the twenty-four hours, than
in those who eat more frequently, but less abundantly. In some cases of stricture at the
pylorus, it becomes enormously distended. Long-continued abstinence occasions such
an amount of contraction, that it has even been asserted, that pain resulting from the
rubbing of its parietes together gives rise to the feeling of hunger ; but this completely
mechanical hypothesis should be rejected. In a great number of cholera patients, the
stomach was found to be exceedingly small. In a female, who died a month after hav-
ing voluntarily swallowed a small quantity of sulphuric acid, the contracted stomach was
not larger than a moderately-sized gall-bladder.
Figure. — The stomach resembles a flattened cone, curved upon itself backward and
upward, and having a rounded base ; it has been compared to the bladder of a bagpipe.
Sections made at right angles to its axis represent circles gradually decreasing in size
from the entrance of the oesophagus to the pylorus. We have to examine its external
and its internal surface.
The external surface. From the peculiar form of the stomach, we are enabled to con-
sider an anterior and a posterior surface, a convex border or great curvature, and a con-
cave border or lesser curvature, a great cul-de-sac or tuberosity, an oesophagal extremi-
ty, cuid a pyloric extremity.
The anterior surface (upper surface of some anatomists, s,Jig. 155) is directed forward,
and a little upward. When inflated in the dead body with the abdomen open, it is turn-
ed directly upward ; but such cannot take place, either in the living or dead subject,
fig. 148) extending between the most prominent points of the cartilages of the ribs, and the other {f> b) be-
tween the crests of the iliac bones. The superior zone is called the epigastric ; the middle, the umbilical ;
and the inferior, the hypogastric. These three zones are then subdivided by two vertical parallel lines drawn
from the cartilages of the eighth rib down to the centre of Poupart's ligament. The epigastric zone is thus
divided into two hypochondriac (1 Ij^and a middle epigastric region (2) ; the umbilical into two lumbar (3 3),
and a middle umbilical region (4) ; and the hypogastric into two iliac (5 5), and a middle hypogastric region (6).]
* It is impossible to insist too strongly upon the influence of too tight stays on the situation, and even the
form, of the viscera occupying the base of the thorax. Thus, changes in the situation and direction of the
stomach are much more frequent in females than in males. Soemmering observed, but without stating the
cause, that the stomach is more rounded in the male, and more oblong in the female.
t It may, strictly speaking, be stated that ruminants have only one stomach, the rennet or obomasum; and
that the iirst three, viz., the paunch, the reticulum, and the manypHes or omasum, are nothing more than dila-
tations of the oesophagus, in which the food undergoes a preparatory elaboration. The same observation ap-
plies to birds, in which the crop and the gizzard are not organs of chymification, the first being merely an or-
?ar of insalivation, the second one of trituration.
Yy
364 SPLANCHNOLOGY.
when the abdominal parietes are entire ; in which case the distended stomach passes in
the direction of the least resistance, i. e., forward and downward, and its anterior sur-
face cannot then be completely turned up.
This surface is in relation with the diaphragm, and is separated by it from the heart ;
with the liver, which is prolonged upon it to a greater or less extent ;* with the last six
ribs, being separated from them by the diaphragm ; and with the abdominal parietes in
the epigastrium : hence the name given to that region. It is not uncommon to find the
great omentum turned upward between the stomach and the liver. When distended,
the stomach has much more extensive relations with the epigastrium, or, rather, with
the abdominal parietes, both in a vertical and transverse direction.
All these relations are of the greatest importance ; and, with the exception of those
which concern the epigastrium, they are constant. In fact, it rarely happens that the
stomach precisely corresponds to the sub-sternal or xiphoid depression, which has been
called the pit of the stomach, or the scrobiculus cordis, but which belongs neither to the
heart nor the stomach. In exploring this depression, it is almost always the liver wliich
is felt ; the stomach lies lower down, and is generally below the ensiform appendix.
The posterior surface {inferior surface of some anatomists, seen turned up at s,fig. 154)
is directed downward and backwjurd, and is seen in the sac of the omentum, of which
it forms the anterior wall.
It has relations with the transverse mesocolon, which serves as a floor for it, and sep-
arates it from the convolutions of the small intestines ; with the third portion of the duo-
denum (e' to b), by some of the older anatomists called the pillow of the stomach {ven-
triculi pulvinar) ; and, lastly, with the pancreas (o). The duodenum, the pancreas, the
aorta (a), and the pillars of the diaphragm {d d), separate it from the vertebral column,
upon which it rests obUquely. These relations are modified by the emptiness or fulness
of the stomach.
The great curvature (the inferior or anterior border of some anatomists, cad, fig. 149)
Fig. 149. is convex, and directed almost vertically downward
in the empty condition of the organ, and almost di-
rectly forward when it is full ; it gives attachment
to the two anterior layers of the great omentum. It
is in relation with the abdominal parietes and the
cartilages of the lower ribs, and lies along the trans-
1^ verse arch of the colon (,t,Jlg. 155), in front of which
it advances when considerably distended ; hence it
was termed the colic border by Chaussier. In the
distended state its relations with the abdominal pa-
rietes become much more extensive ; but even then I
can scarcely believe the assertions of some, that the
pulsations of the gastro-epiploic arteries can be felt by the finger in emaciated individuals.
The lesser curvature (the superior or posterior border of some anatomists, o b p, fig. 149)
is concave, and extends from the oesophageal orifice to the pylorus ; it gives attachment
to the small or gastro-hepatic omentum ; it is directed upward when the viscus is empty,
upward and backward when it is full ; and it then embraces the vertebral column in its
curvature, being separated from it by the aorta and the pillars of the diaphragm (see^^.
154) ; it also embraces the small lobe of the liver or the lobulus Spigehi, the coeliac axis
(f), and the solar plexus of nerves.
The great extremity or great cul-de-sac of the stomach (the bottom or great tuberosity, from
c to the dotted line, fig. 149) comprises all that portion which is to the left of the car-
diac or cEsophageal opening ; it is a sort of semi-spheroid, applied to the base of the cone
formed by the rest of the stomach ; it is the highest and the largest portion of that or-
gan ; it is almost entirely absent in carnivora ; it is very large in herbivora, and of a
medium size in man. There are also many individual varieties in the size of this por-
tion of the stomach ; I have met with some instances in which it W2is not larger than it
is in carnivora.
It is in contact with the spleen {k, fig. 154) (hence it is called the splenic extremity by
Chaussier), with which it is connected by a fold of the peritoneum, called the gastro-
splenic omentum, and by the vasa brevia. When the stomach is distended it comes into
close contact with, and is, as it were, moulded upon, the spleen (see fig. 161). From this
relation a great number of physiological inferences may be deduced. t The great cul-
de-sac occupies the left hypochondrium, and corresponds also, in the greater part of its
* The relations of the anterior surface of the stomach with the liver are very variable in extent ; it some-
times reaches even to the gall-bladder. I have seen a case in vphich the gall-bladder adhered to the anterior
surface of the stomach, and, therefore, to the left of the pylorus, and communicated with it by an orifice, through
■which bile and biliary calculi were discharged.
t The great end of the stomach is so closely connected with the spleen, that it necessarily follows all dis-
placements of that organ. I have met with a case in which the spleen, three or four times its natural size,
■was situated in the umbilical region, and had dragged down the great end of the stomach with it. The left
extremity of the transverse colon, and the upper part of the descending colon, occupied the place of the great
extremity of the stomach. The patient had long suffered from indigestion, which had been attributed to chron-
ic gastritis.
THE STOMACH. 355
extent, to the left half of the diaphragm, which is in accurate contact with it, and separ-
ates it from the lungs above and from the last six ribs in front. It is more or less ele-
vated, according to the degree of distension of the stomach ; and from this we can easi-
ly understand that difficult respiration may be caused by too large a meal.
Lastly, it may be stated that the great extremity of the stomach has relations behind
with the pancreas, and with the left kidney and supra-renal capsule.
The (Esophageal extremity (o, Jig. 149). The oesophagus opens into the stomach at
different angles, according to the emptiness or fulness of that organ. The situation of
this opening, which is improperly denominated the cardia {cor, heart), is at the left ex-
tremity of the lesser curvature, to the right of the great cul-de-sac, and opposite the
(Esophageal opening in the diaphragm. It is embraced (c. Jig. 154) in front by the left
extremity of the liver, which sometimes forms a half circle round it, and behind by the
lobulus Spigelii. It is surrounded by a circle of vessels and some nerves. Examined
externally, the lower end of the oesophagus is continuous with the stomach, without any
other line of demarcation than that depending upon a difference in size and direction.
The peritoneum is directly reflected from the diaphragm upon the oesophagus and the
stomach, and forms the gastro-diaphragmatic fold (ligamentum phrenico-gastricum.
ScBJnmerifig).*
The pyloric extremity {pylorus, from ttCIt], a gate, and o^pof, a keeper, p,figs. 149, &c.)
iS situated at the right extremity of the stomach. It forms the apex of the cone, and
presents a circular constriction or strangulation, which exactly defines the limits between
the stomach and duodenum. About an inch from this constriction the stomach is much
curved, so as to form a decided bend, and presents a dilatation, on the side of the great
curvature corresponding to an internal excavation, called by Willis the antrum pylori, and
by others the srnall cul-de-sac of the stomach (from d to the dotted line e). Not uncom-
monly we find a second dilatation near the first, and a third, still smaller, on the side of
the lesser curvature, resulting from the bend formed by the stomach. The pyloric ex-
tremity of the stomach is directed to the right side, backward and upward, and some-
times even a little to the left, when the stomach is much distended.
The relations of the pyloric extremity with the abdominal parietes are very variable, for
the changes in the situation of the stomach chiefly affect this extremity. It corresponds
to the liaiit between the epigastrium and the right hypochondrium ; sometimes it is in
relation with the gall-bladder, and hence may become stained ; in some cases it passes
to the right of the gall-bladder, to the extent of an inch or an inch and a half. I have
seen it occupying the horizontal fissure of the hver, the edges of which were separated
for its reception. Very commonly we find the pylorus in the umbilical region. I have
seen it in the hypogastrium in a female who was affected vdth schirrus of the pylorus,
and I have also found it in the right iliac fossa. It is, therefore, extremely difficult to
determine the seat of an organic lesion of the pylorus from external examination.
The relations of the pylorus with the abdominal viscera are more constant : above, it
corresponds to the liver and the lesser omentum ; below, to the great omentum ; in front,
to the abdominal parietes ; and behind, to the pancreas. It is not uncommon to find it
adhering to the gall-bladder. #
The Internal Surface. — This presents the same regions as the external surface ; all its
peculiarities may be referred to the raucous membrane, which will be noticed when the
structure of the stomach is described. Besides these, however, we observe here the
two orifices of the stomach.
The oesophageal orifice (cardiac, left, or superior orifice, ostium iiitroitus, o, Jig. 150) is
remarkable for its radiated folds (ad steUae similitudi- pj UO
nem. Holler), which are effaced by distension ; for the ^,
irregularly fringed border and the change in colour ^ ,• , ? \
which mark the limits between the mucous membrane
of the oesophagus and of the stomach ; for its size and
its capabihty of dilatation ; and, lastly, for the total ab-
sence of any valve or sphincter.
The duodenal or pyloric orifice (right or anterior ori-
fice, janitor, sphinctor, ostium, exitus, p) is remarkable
for an internal rim, or circular valve, which in a distend-
ed and dried stomach forms a sort of diaphragm (in
speciem diaphragmatis, quedia sunt in tubis telescopicis, Morgagni) ; for the narrowness
of the passage, which, with difficulty, admits the little finger in most subjects ; for its slight
dilatability ; and, lastly, for the existence of a muscular ring, which may be regarded as
a true sphincter. It is of importance to remark, that this orifice, independently of ajiy
disease, presents a great number of varieties in its dimensions, and it is probable that
these congenital or acquired variations may have some influence upon its diseases.
The relative position of these two orifices is an important anatomical point. Upon
this we should observe, 1. That they are but little apart from each other, considering
* [Hence this extremity is comparatively fixed.]
356
SPLANCHNOLOGY.
the size of the stomach, and that the interval between them does not increase in propor-
tion to that size ; 2. That the oesophageal orifice is directed upward, the pyloric open-
ing backward and a little upward ; 3. That the two openings are not upon the same plane,
the oesophageal being higher and more posterior than the pyloric.
The Structure of the Stomach. — In order to study the structure of the stomach, it is
necessary, in the first place, to distend it. Two stomachs are indispensable for this pur-
pose, one to be dissected from without inward, and the other from within outward.
One of the stomachs should be everted, and then inflated.
The parietes of the stomach are formed by the super-position of four membranes or
coats, differing in texture and properties. These, proceeding from without inward, are
the serous, the muscular, the fibrous, and the mucous coats. We must also examine the
vessels, nerves, and cellular tissue, which enter into the composition of these parietes.
1. The serous or ■peritoneal coat. Like almost all the movable viscera of the abdomen,
the stomach receives a complete covering from the 'peritoneum {membrana communis of
the ancients ; la membrane capsulaire, Chauss.). It is formed in the following manner :
Two layers of the''peritoneum, in contact with each other, pass from the transverse fis-
sure of the liver to the lesser curvature of the stomach : there they separate, so as to
leave between them a triangular space, the base of which corresponds to the lesser curva-
ture ; the anterior layer then passes over the anterior surface of the stomach, and the pos-
terior covers it behind ; they again approach each other at the great curvature, along which
they form another triangular space, exactly resembling that which we have already de-
scribed as existing at the lesser curvature, and then unite so as to form the two ante-
rior layers of the great omentum (see description of Peritoneum). The same airange-
ment takes place at the great extremity of the stomach. Bloodvessels pass round the
stomach, along the line where the two layers of the peritoneum are applied to each oth-
er at its two curvatures.
The peritoneum, therefore, forms a complete covering for the stomach, excepting at
the curvatures, where we find triangular spaces, into which the stomach is forced during
its distension. I doubt whether these triangular spaces can afibrd sufficient space for
the stomach when greatly distended, and I believe that, in such cases, the two anterior
layers of the great omentum separate, and are applied upon that organ. It is evident,
besides, that distension of the stomach chiefly affects its great curvature.
The peritoneal coat does not adhere firmly to the subjacent tissues of the stomach, in
the neighbourhood of either curvature ; but it is closely united to them at the middle points
of both surfaces. The imperfect extensibility of the peritoneal coat requires such an ar-
rangement as exists along the curvatures. I have observed some small fibrous bands
in the sub-serous cellular tissue along the lesser curvature, which must be intended to
maintain the shape of that part. The uses of the peritoneal coat, in reference to the
stomach itself, are merely mechanical ; it strengthens, preserves the shape, and facili-
tates the movements of this organ.
The Muscular Coat. — This coat has engaged much of the attention of anatomists since
the time of Fallopius, who was the first to give a correct description of it ; and to whom
Morgagni {Advers. Anat., iii., p. 6) has^ttributed the honour of discovering it, in opposi-
tion to the claims of Willis. Helvetius made it the subject of a special work {Hist.
Acad. Roy. des Sciences, 1719).
We shall describe, in accordance with Haller (Elem. Phys., tom. vi., lib. xix., sect, i.,
Fig. 161.
p. 126), and the majority of anatomists, three layers of muscu-
lar fibres.
The superficial or longitudinal layer (1, fig: 151) is formed by a
continuation of the longitudinal fibres of the oesophagus, whioh
spread out in a radiated manner from the cardiac orifice of the
stomach. They are scattered thinly over its surfaces, the great
curvature, and the great extremity, but are collected into a band
along the lesser curvature, the shape of which they assist in
preserving. On account of this arrangement, they have re-
ceived the name of cravatc de Suisse.
These fibres form a continuous plane of considerable thick-
ness over the contracted portion of the stomach, near the pylo-
rus. In this situation they are stronger, and fasciculated, and
appear partly to terminate in the pyloric constriction, and part-
ly to be continued upon the duodenum.
The second or circular layer (2, fig. 151) is composed of fibres
which cross the axis of the stomach at right angles, so as to
form a succession of rings from the oesophagus to the pylorus.
They are few in number at the great extremity of the stomach,
but become much more numerous towards the pylorus, through-
out all the contracted portion of the stomach. At the pylorus
itself they form a thick ring, which forms a sort of rim, project-
ing in the interior. I have always found this more developed
THE STOMACH. 357
in old age than at any other period of life. It is a true sphincter, which, by its contrac-
tion, effectually opposes the passage of food and gas from the stomach into the duode-
num. It is not uncommon to find the whole of this ring, or a half, or two thirds of it, in-
creased to the thickness of three or four lines, independently of any organic lesion.
The older anatomists admitted also an oesophageal ring (or (esophageal sphincter), simi-
lar to that at the pylorus, and having the power of closing the oesophageal orifice. This,
however, does not exist ; the last circular fibres of the oesophagus do not form a thicker
layer than the others.
Lastly, the different rings formed by the circular fibres of the stomach intersect each
other obliquely at very acute angles. The spired arrangement admitted by Santorini
cannot be demonstrated.
The third muscular layer (3, fig. 151), which I have only been able to see distinctly upon
hypertrophied stomachs, is composed of looped or parabolic fibres, the middle portions of
which embrace the great end of the stomach, extending from the left side of the cardiac
orifice obliquely downward towards the great curvature, while their anterior and posterior
extremities are situated upon the corresponding surfaces of this viscus. The superior
loops reach the lesser curvature, the inferior the great curvature, and the intermediate
loops seem to be lost upon either surface, or, rather, to become blended with the circu-
lar fibres. This layer of fibres appears intended to compress the great extremity of the
stomach, and to push the food into the body of the organ, towards the pylorus.
From what has been stated, it follows that, excepting in the vicinity of the pylorus,
the muscular layers of the stomach do not form a continuous plane, but have an areolar
disposition : the areolae, or spaces between the different fibres, are of considerable size ;
hence the necessity for a strong membrane, like the fibrous coat, which, as we shall
find, constitutes the framework of the stomach.
The muscular fibres of the several layers are much paler than those of the oesopha-
gus.* They have a pearly appearance when seen through the peritoneal coat, which
has led to the supposition that they are tendinous. Hence the error of Helvetius, Wins-
low, and others, who regarded the two white lines running along the two surfaces of the
stomach, between the curvatures, as ligaments of the pylorus ; they are nothing more
than longitudinal muscular fibres. Other authors have merely admitted some tendinous
intersections of these fibres.
The muscular coat is not uniformly thick at all points. It is very thin at the great
cul-de-sac, and becomes much thicker towards the pylorus. It also presents many va-
rieties in different subjects ; it is but slightly developed in large stomachs, and much more
so when this organ is contracted. There is a physiological as well as a pathological hy-
pertrophy of the muscular coat. In the latter it has been found seven or eight lines thick.
The Fibrous Coat. — This coat, the existence of which has been alternately admitted
and denied, is situated between the muscular and the mucous coats, and is quite distinct
from both. It was known by the ancients as the membrana nervosa ,•+ it constitutes,
properly speaking, the frcmiework of the organ. In order to demonstrate this coat, it is
sufficient to remove the peritoneal and muscular tunics, and then to evert the stomach
and remove the mucous membrane. This experiment will also very clearly show the
great strength of the fibrous coat, which, even thus unsupported, can bear considerable
distension ; while, on the other hand, when this coat has been divided, the remaining
membrane or membranes burst through the opening thus made.
This coat should not be confounded with the dermis of the mucous membrane, for it
adheres much more strongly to the muscular coat, into which it sends numerous pro-
longations, than to the mucous membrane, with which it is connected only by loose cel-
lular tissue.
The fibres of this coat have not a parallel arrangement like those of aponeuroses and
fibrous sheaths, but they form a very dense network, the filaments or lamellae of which
can be separated by inflation or infiltration. It is concerned in a very important man-
ner in chronic diseases of the stomach ; it is very liable to hypertrophy ; and, in certain
cases, acquires a thickness of several lines.
The Mticous Membrane. — The history of this membrane is curious. It was for a long
time confounded with the mucus by which it is covered, being regarded as merely a dried
layer of that secretion.J It was pointed out by Fallopius, who applied to it the very ap-
propriate appellation of the velvet-like tunic ; but it was first described as a separate mem-
brane by Willis, under the title of the glandular tunic. The discovery was confirmed by
the beautiful injections of Ruysch, who gave it the name of epithelium ; to which term,
however, he did not attach the same meaning as modern authors. It was afterward re-
garded as an epidermic membrane, analogous to the epidermis of the skin,^ and capable
* [Thejr are principally of the involuntary class, but have a few striated fibres among- them (see note, p. 3 JJ
t [So called from its white appearance.]
X Riolanus states positively {Anthropol, 1. ii., c. xii., p. 171) that the stomach, like the intestines, is com-
posed of three coats, viz., a common external membrane, a nervous, and a muscular coat; and that a closely
adherent mucus, consisting of the thickest part of the chyle, lines it on the inside.
t) Such was the opinion of Ilaller, lib. xix. p. 132.
358 SPLANCHNOLOGY.
of being thrown off and renewed. In recent times it has been supposed to be concerned
tanquam omnium lerna malorum, and has become in the present day the object of a great
number of most interesting researches.
The mucous membrane of the stomach presents an adherent and a free surface. The
adherent surface is united to the fibrous coat by cellular tissue, so loose as to permit very
free motions. The free surface has the following characters : When the stomach is
strongly contracted, it forms a number of folds (see^^. 150), the principal of which are
longitudinal ; these folds disappear when the organ is distended, as may be shown in an
everted stomach. Their only use is to allow of the rapid distension of this organ, a con-
dition that could not have been attained in any other mode, in consequence of the slight
elasticity of the mucous coat.
These longitudinal and temporary folds, which are perfectly distinct from the perma-
nent folds observed in other parts of the alimentary canal, are most strongly marked
near the pyloris ; they are extremely regular, sometimes straight and sometimes flexu-
ous ; and they proceed parallel to each other from the cardiac towards the pyloric orifice
They are intersected more or less obliquely by other winding folds of different degrees,
which often give an areolar appearance to the internal surface of the stomach.
From this arrangement, it follows that dilatation of the stomach occurs principally in
a direction across its long axis ; the resources for dilatation in the direction of its axis
are much less numerous. Of all the folds of the mucous membrane, the most important
is undoubtedly that called the pyloric valve, which is often nothing more than a mere
elevation of the membrane by the sphincter muscle.* This cellular fold is equally op-
posed to the regurgitation of food from the duodenum into the stomach, and to its
passage from the stomach into the duodenum ; it is completely effaced by distension,
and it belongs as much to the duodenum as to the stomach. Its upper half has the
characters of the gastric ; the lower half offers those of the duodenal mucous membrane.
Diseases are sometimes observed to stop at the line of separation. We may add, that
the folds upon the internal surface of the stomach are formed by the mucous membrane
alone ; the fibrous coat does not enter into them.
Besides these folds, the mucous membrane presents numerous slight and tortuous
furrows, dividing it into small spaces or compartments, which are either lozenge-shaped,
hexagonal, polygonal, circular, oblong, or irregular.
Examined by the naked eye, the mucous membrane has a soft, spongy, tomentose, or
velvety appearance ; hence the name of villous or velvet-like membrane, by which it is still
generally known. It is covered by a layer of mucus of variable thickness, which may
be detached by friction with a coarse cloth. In order to avoid the inconveniences arising
from this method, which is more or less injurious to the texture of the membrane, I have
been accustomed to use a gentle stream of water, which, at the same time that it com-
pletely washes away the mucus, clearly displays the papillary structure of the surface
of the membrane.
There are some stomachs which might be called granular or glandjtlar, because the
mucous membrane has a granular appearance, so that at first sight it might be imagined
that some small glandular bodies (like the salivary glands) were scattered over the in-
ternal surface of the stomach ; but this glandular aspect is merely apparent, depending
upon the circular or semicircular direction of the furrows in the mucous membrane,
which give a spheroidal character to the kind of islets that are intercepted between them.
This gi'anular appearance is seldom observed over the entire stomach ; it rarely exists
at the great extremity. I have found it limited to the great curvature ; most frequently
it occurs in the vicinity of the pylorus ; sometimes it is observed over all that part of the
stomach which is to the right of the oesophagus. These granulations are particularly
developed in the stomach of the pig.
There is one remark upon which too much importance cannot be placed ; and that is,
the difference in the appearance of the mucous membrane of the great extremity of the
stomach, and of the part situated to the right of the oesophagus. Sometimes the line of
separation forms a perfect circle ; and this is a very remarkable fact, because in man,
who has a single stomach, it may be considered as a rudiment of the division into the
compound stomachs found in the lower animals ; for a multiple stomach results rather
from some difference in the structure of the mucous membrane, than from the existence
of different compartments or distinct cavities. It will not be uninteresting to connect
this remark with what has been already stated regarding bilocular stomachs.
We shall now examine the characters of the mucous membrane in the oesophageal and
in the pyloric portion of the stomach.
In the oesophageal portion it is thinner, softer, and more vascular, and can only be
separated in flakes from the subjacent parts. When the stomach contains any liquid
after death, this part is converted into a sort of pulp, which becomes of a blackish colour,
from the action of the acids in the gastric fluid upon the blood contained in the vessels
of the stomach. This is the pultaceous softening, which I regard as a post-mortem change,
* [It usually consists of the mucous membraue, the cellular coat, and the circular muscular fibres.]
THE STOMACH. 359
but which has been erroneously confounded with the gelatiniform softening. I'his second
portion of the mucous membrane, i. e., the part situated to the right of the oesophagus,
is thicker, stronger, and whiter, and may be separated entire from the other coats. Dis-
eases often observe the line of separation between the right and the left portions of the
stomach.
Modern pathologists having attached great importance to the condition of the gastric
mucous membrane, it has become highly interesting to determine its characters in the
healthy state ; these characters relate to its colour, its consistence, and its thickness.
Colour. — It is extremely difficult to determine what is the natural colour of this mucous
membrane. The opinion generally maintained by the best authorities, that it is either
primarily or secondarily affected in the majority of diseases, compels us to reject all ob-
servations made upon persons who have died from acute or chronic diseases, or even
from wounds or injuries of long standing. We are, therefore, obliged to have recourse
to cases of accidental death in persons previously in health. In such cases, for example,
in criminals who are executed while the stomach is empty, the mucous membrane is
found of a grayish-white colour, with a slight tint of yellow and pink.* When death has
occurred during digestion, the mucous membrane is found to vary from a delicate pink
to the most vivid red. After putrefaction has made some little progress, we find a red
or port wine colour, or a brownish black tint prevailing over the great extremity of the
stomach, and at the free edges of the folds or wrinkles to which the vessels correspond ;
again, it is often found marked with blackish patches, or marbled ; but these discolora-
tions are the result of post-mortem transudation.
In the pultaceous and blackish softening of the mucous membrane, the colour is owing
to the action of the acids in the gastric juice. Wlien the stomach contains bile, the mu-
cous membrane is tinged with yellow or green, and the stain sometimes remains after
the longest maceration.
If the mucous membrane be rubbed with a rough cloth, so long as the vessels contain
blood, we may produce a red punctuated appearance, which has been often mistaken for
a sign of inflammation. Lastly, in the aged we not unfrequently observe a slate gray
colour, either in points or in patches, or diffused over the surface. This colour occupies
the papillae, and may afford proof of some former irritation, but is certainly not due to any
diseased action during the later periods of life. These different discolorations of the
stomach must not be confounded with the alterations in its colour resulting from disease.
Thickness. — It is difficult to estimate the exact thickness of the gastric mucous mem-
brane. Like the muscular coat, it varies in different individuals ; in chronic inflamma-
tion it is twice or three times its natural thickness. In determining the thickness of this
membrane, it is important to bear in mind the difference in this particular between the
oesophageal and pyloric portions ; the former being extremely thin, and the latter twice
or three times as thick as that.
Consistence. — The same remarks apply to its consistence, for there are many individ-
ual varieties in this respect. The oesophageal portion may be torn with great ease ; but
the pyloric portion is so dense, that the back, and even the edge of a scalpel, may be
drawn over it with considerable force without wounding it. If there has been any liquid,
or even food in the stomach, in however small quantity, the mucous membrane of the
oesophageal portion, when macerated, is converted into a pulp ; moderate distension will
then rupture the weills of the stomach, which may be broken through by the point of the
finger.
From want of sufficient reflection upon this subject, men of great merit have commit-
ted serious errors in the appreciation of morbid lesions. In the gelatiniform softening,
the gastric mucous membrane, as well as the other coats of the stomach, become dis-
solved, and resemble a solution of gelatine. In many old people, and in some adults, I
have found the mucous membrane so thick and so strong, that it could be dissected off
entire, and removed in one piece. This condition coexisted with the slate colour, either
accompanied or not with chronic inflammation.
The PapillcB. — If we examine the mucous membrane of the stomach, placed under wa-
ter, and exposed to the direct rays of the sun by the aid of a powerful lens, we shall find
that its surface is very irregular, mammillated. Fig. 152. Fig. 153.
and furrowed, so as to present an appearance very
like the convolutions of the small intestine. The
eminences, which are much more distinct to-
wards the pylorus than near the oesophagus, are
studded with holes, or, rather, with small pits
resembling the cells of a honeycomb (figs. 152,
153). These alveolar depressions are well de-
scribed by Home, who states that they exist only r-im -tj^an— «
in the great cul-de-sac, while the viUi occupy the ""'il^fi J32 a.aB.rt^!' ^^S^S^toT
* In a great number of individuals who have died from acute or chronic diseases, the gastric mucous mem-
brane is found in the same state as in those who have died accidentally ; it is, therefore, not always affectedi
either primarily or secondarily, in disease
360 SPLANCHNOLOGY.
rest of the stomach. The truth is, that a precisely similar stmcture is observed ovei
the whole stomach. The alveoli, or pits, are separated from each other by small pro-
jections, or papilla {fig. 153), of vi^hich the papillae of the tongue convey an excellent idea.*
Should these papillae be distinguished from other projections that have been termed
villi, by Ruysch, for example, who called the entire membrane villoso-papillaris ? Aftei
the most minute examination, I have only detected one order of eminences,! viz., the
papilla, the existence of which I regard as the essential character of all tegumentary
membranes, whether mucous or cutaneous, which might all, therefore, be designated
papillary membranes. We shall return again to the structure of the papillse.
If we examine with a lens or simple microscope a perpendicular or oblique section
of the mucous membrane of the stomach, we shall perceive that it consists essentially of
a strong membrane, the mucous dermis, from which arise an immense number of small
eminences closely pressed together, and of unequal lengths, like the pile of velvet.
These eminences are the papillae ; they are liable to great enlargement in cases of hy-
pertrophy, and then the structure just described becomes very apparent.
The Follicles. — The follicles of the stomach can be very easily demonstrated in the
pigt and in the horse. In the last-mentioned animal, entozoa are frequently found in
the centre of these follicles, which then become developed into hard, and sometimes
very large tumours. It is so difficult to demonstrate them in the human subject, that,
with most anatomists, I, for a long time, doubted their existence. Haller only saw them
once or twice ;^ but in some individuals they are very distinct. I found them well
marked in a great number of cholera patients. II They are not situated in the sub-mucous
cellular tissue, as is generally stated, but in the substance of the membrane itself, so as
to form a projection on the inside of the stomach, but not on the outer surface. They
are rounded, flattened, and perforated by a central foramen, which is usually visible to
the naked eye. I have observed them upon all points of the mucous membrane, but they
appear to be most numerous near the oesophageal orifice, and along the lesser curvature. IT
The Vessels and Nerves of the Stomach. — The arteries are very large and numerous in
proportion to the size of the stomach ; they must, therefore, assist in the performance
of some function besides the mere nutrition of the organ ; this function is the secretion
of the gastric juice. They all arise from the cceliac axis, and are the coronary, the su-
perior pyloric and right gastro-epiploic branches of the hepatic, and the left gastro-epi-
ploic and vasa brevia, which are branches of the splenic artery. These arteries anas-
tomose, so as to form around the stomach a vascular zone, which is in close contact
with that organ during distension, but at some distance from it when empty. From this
arterial circle branches are given off, which at first lie between the peritoneal and the
muscular coats, but, after a certain number of divisions and anastomoses, perforate the
muscular and fibrous coats, and again subdivide and anastomose a great number of times
in the loose sub-mucous cellular tissue, until, having become capillary, they penetrate the
mucous membrane.
The veins bear the same name, and follow the same direction as the arteries ; they
contribute to form the vena portae. Schmiedel (Variet. Vasorum, No. xix., p. 26) has
seen the coronary vein of the stomach anastomose with the renal vein, the pyloric with
the vena azygos, and one of the venae breves with the phrenic vein.
The lymphatic vessels are very numerous, and terminate in the lymphatic glands, situ-
ated along the two curvatures of the stomach. The peculiar ducts, said to proceed from
the spleen to the stomach, and supposed by the ancients to be passages for the atra bilis,
are purely imaginary.
The nerves are of two kinds, some being derived from the eighth pair, and others from
the solar plexus.
The nerves of the eighth pair form a plexus around the cardiac orifice, the left nerve
being distributed upon the anterior, and the right upon the posterior surface of the stom-
* [The alveoli are from t^tt'^ '■° oTo*^ °^ ^^ inch, and, near the pylorus, y^n^th of an inch in diameter.
At the bottom of each alveolus is seen a group of minute apertures (fig. 152), which are the open mouths of
small tubes placed perpendicularly to the surface of the membrane, and closed at the other end. In a vertical
section of the membrane, these tubes, which average about -jijyth of an inch in diameter, are seen to rest upon
the sub-mucous tissue by their closed extremities. In the cardiac portion of the stomach they are short and
stiuight ; near the pyloric end they are longer, and convoluted, or irregularly dilated, and are sometimes bifur-
cated. Bloodvessels pass up between these tubes, and form a capillary network round the borders of the al-
veoli. The membranous projections sometimes found between the alveoli {fig. 153) form irregular fringes,
broader than the lingual papillae, and seem rather to be imperfectly developed villi (see note, p. 361), and are
usually so called. The epithelium covering the entire mucous membrane of the stomach consists of a single
layer of minute columnar cells ; it is very delicate, and invisible, except by a high magnifying power ; hence
its existence was formerly denied.]
t Upon this subject see the Memoir of Helvetius.— (/Tj'ii. Acad. Roy. des Sciences, 1720.)
t [In the pig these follicles appear to be nothing more than prolongations of the mucous membrane, or
small diverticula; so that, after having detached the mucous membrane, they may, by slight pressure, be
turned inside out.]
t> " Neque rejici debent, etsi non semper possint ostendi." — (Haller, 1. vi., lib. xix., p. 140.)
II Vide Anat. Path, avec planches, liv. xiv., pi. 1.
IT [In the neighbourhood of the (esophageal orifice there are also several small cgmpound glands, analogous
to Brunner's glands in the duodenum. — (W. S.)]
THE INTESTINES. 36]
ach. They may be followed as far as the muscular coat, where they seem to be lost ,
division of them paralyzes this coat. By means of the nerves of the eighth pair, the
stomach is connected with the oesophagus, the lungs, the pharynx, the larynx, and' the
heart. Through the nerves derived from the central epigastric plexus, and named after
the arteries that support them, the stomach is connected with the ganglionic system
and is brought into relation with the numerous viscera of the abdomen.
Lastly, a very delicate serous cellular tissue unites the different coats of the stomach.
There are three layers of this tissue, viz., one between the peritoneal and the muscular
coats, another between the muscular and the fibrous, and a third between the fibrous
and the mucous coats. The last of these is the most distinct ; it is liable to both serous
and sanguineous effusions, and may become the seat of diffuse inflammation. I have
lately seen it infiltrated with pus to a considerable extent, the mucous and the fibrous
coats being both perfectly healthy.
Develcypment of the Stomach. — The stomach of the foetus is remarkable on account of
its vertical position, which is due to the great development of the liver, especially of its
left lobe. An unnatural development of that lobe will also occasion a similar position
of the stomach in the adult. The relative smallness of the stomach, and the slight de-
velopment of its tuberosity, are also characteristic of its foetal condition.* Nevertheless,
from the first moment of its appearance, it is distinguished from the rest of the aliment-
ary canal by its greater size. The changes which the adult stomach undergoes, and
the variations in size which it presents, are, perhaps, less dependant upon congenital
differences than upon particular habits. The differences in the two sexes are manifest-
ly due to the pressure to which the stomach of the female is subject, either from the use
of stays or from the gravid uterus. I may here advert to the development of the mus-
cular ring of the pylorus, and of the neighbouring part of the stomach in aged persons.
Function. — The stomach is the organ of chymification, or of that process by which the
food is converted into a homogeneous gray pulp, called chyme. For that purpose it is
evidently necessary that the food should remain for some time in this organ, and the
elasticity of the muscular coat of the oesophagus and of the ring at the pylorus are suffi-
cient to prevent its regurgitation into the gullet, or its passage into the duodenum.
When the process is completed, however, the peristaltic contraction of the muscular
fibres of the stomach overcomes the resistance of the pylorus ; in eructation, regurgita-
tion, and vomiting, the same peristaltic movements are assisted by the contraction of
the diaphragm and the abdominal muscles.
Chymification is a chemical, or, at least, a molecular action, and is effected by means
of the gastric juice, mixed with the salivary and oesophageal secretions. These fluids
are acid.t
The influence of the nerves upon digestion has been ascertained by ingenious experi-
ments, the results of which, however, have been interpreted in various ways.
The Intestines in general.
The term intestine, in its widest signification, is applied to the whole alimentary ca-
nal ; but, in a more limited sense, it means that long and frequently-convoluted tube,
extending from the pylorus to the anus, and occupying almost the whole of the abdomi-
nal cavity. The intestines have been divided, according to their calibre, into the small
{b to d,Jig. 139) and the large (c to i) ; this distinction, which is applicable to most ani-
mals, is anatomically established in man by a difference in size, by the sacculated char-
acter of the large intestine, by a difference in direction, by the presence of a valve, by
the existence of a caecum and of a vermiform appendix, and, lastly, by a difference in
structure, especially in the muscular and mucous coats. Tlie same distinction is recog
nised in physiology, and upon equally good grounds, for the small intestine is essentid-
ly concerned in the formation and absorption of the chyle, while the large intestine is the
organ of defsecation.J These differences will be rendered more apparent from the de
scription of these two important parts of the alimentary canal.
The Small Intestine.
The small intestine includes all that part which is situated between the stomach and
the large intestine (i to d,fig. 139). According to Haller, Bichat, and their followers,
the upper portion, called the duodenum (b to c), should be abstracted from the small in-
testine, which, according to them, would commence at the termination of the duodenum.
It appears to me that the former definition should be adhered to, on account both of the
* [At early periods of foetal life, villi are found on the mucous membrane of the stomach g-enerally, after-
ward on the pyloric portion only ; and, subsequently to birth, the only traces of these are the irregular frmgcB
observed here and there between the alveoli.]
t [The saliva, though sometimes acid, is usually alkaline.]
i The division into a small and large intestine exists among all vertebrated animals ; but no animals, ex-
cepting the ourangs and the wombat, have both a ciecum and an appendix vermiformis. In some we find one
caecum, or several caeca ; in others, one or more vermiform appendices ; others have neither csecum nor appen-
dix, but a valvular fola arit a well-marked change in diameter indicate the limit between the small ana larf«
intestines. In some, again, the only difference consists in a change of diameter.
Zz
9m
SPLANCHNOLOGY.
absence of any real line of separation between the duodenum and the rest of the small
intestine, and of their similarity in structure and function.
The small intestine is divided into three parts, the duodenum, the jejunum, and the
ileum. The division between the duodenum and the rest of the small intestine is defi-
nite, but that between the jejunum and the ileum is altogether arbitrary ; so that we
shall follow the example of Haller, Scemmering, and others, in describing the jejunum
and ileum together (c to d), under the name of the small intestine, properly so called.
The Duodenum.
Dissection. — ^When the abdomen is opened, the first portion only of this intestine is
visible ; the second is hid by the ascending colon ; the third is seen in the cavity of the
omentum. The second is brought into view by turning aside the colon. The third por-
tion, which is the most difficult to demonstrate, may be exposed in two ways : either by
cutting through the inferior layer of the transverse mesocolon, or by turning the stomach
upward, after having divided the lavers of the grest omentum, which are attached along
its greater curvature.
Fig- 154. The duodenum {dudsKa
6uKTvXov, p b, Jig. 154), so
called by Herophilus (Ga-
len, Administr. Ariat., lib.
vi., c. 9) on account of its
being about equal in length
to the breadth of twelve fin-
gers, commences at the py-
lorus, and terminates, with-
out any precise line of de-
marcation, to the left of the
second lumbar vertebra, at
the point where the small
intestine enters into the
mesentery, or, rather, op-
posite the superior mesen-
teric artery (m) and vein,
which pass in front of it.
Its fixed position, its struc-
ture, and its curvatures,
have led to its being de-
scribed separately.*
It is difficult to determine its precise situation with regard to the abdominal parietes.
It is not exclusively confined to any one region, but occupies in succession the adjacent
borders of the right hypochondrium and the epigastrium, of the right lumbar and the um-
bilical regions, and of the epigastric and umbilical regions.
The duodenum is found more deeply situated in proportion as we recede from the py-
lorus, and hence the difficulty of exploring it through the parietes of the abdomen. It
is fixed firmly in its place by the peritoneum, by the mesenteric vessels and nerves,
which bind it down, and by the pancreas. This fixedness is one of its principal peculi-
arities, and is indispensable in consequence of its relations with the ductus communis
choledochus ; for had it been movable like the rest of the small intestine, incessant ob-
structions to the flow of the bile would have occurred. It follows, also, that the duode-
num can never form part of a hernia ; its first portion may, indeed, be displaced, for it
is less firmly fixed than the remainder, and is sometimes dragged out of its proper situ-
ation by the pyloric extremity of the stomach.
Dimensions. — It is eight or nine inches in length ; its calibre is somewhat greater than
that of the rest of the small intestine, but the difference is not so decided as to war-
rant the names of second stomach, or ventriculus sUccenturiatus, which have been given to
it. I have even met with subjects in whom the duodenum, when moderately distended,
was five inches, while the succeeding portion of small intestine was six inches in cir-
cumference. It has been supposed that this part is more dilatable than the rest of the
small intestine ; this has been attributed to the absence of the peritoneum. The fact
and the explanation are equally without foundation. It is the fibrous membrane, and
not the peritoneal coat, which is opposed to dilatation of the intestines.
Direction. — This is very remarkable. Commencing at the pylorus, the duodenum
passes upward to the right side and backward ; having reached the neck of the gall-
bladder, it suddenly changes its direction, and becomes vertical, forming an acute angle
■with the former portion ; this is its first curvature (e) : then, after proceeding vertically
through a variable space, it passes transversely from the right to the left side, and be-
comes continuous with the rest of the small intestine. This change in its direction
takes place at a right angle, and is, therefore, less abrupt than the former ; the point at
which it occurs is called the second curvatare (e').
* Glisson considered the insertion of the ductus communis chnlfidochm! "■••'"' ".-er limit of the duodtJiiuni.
THE INTESTINES.
363
It follows, then, that the duodenum describes a double curve, or, rather, one single
curve, of which the concavity is directed towards the left, and the convexity to the right
side. Haller has ingeniously- compared the course of the duodenum to two parallel
lines, intersected by a perpendicular. This double change in the direction of the duode-
num, which is probably intended to retard the passage of the food, enables us to consider
it as composed of three portions, distinguished as the first (p e), second (e e'), and third (e' d).
Relations. — These should be studied in each of the three portions.
Relations of the First Portion. — Above, with the liver (/', fig. 154*) and the gall-bladder
(g), to the neck of which it is united by a fold of the peritoneum. It is not uncommon
to see the gall-bladder and the duodenum closely adherent to each other, and to find an
opening through which biliary calculi have passed into the gut. Li front, with the gas-
tro-colic omentum and the abdominal parietes. Behind, with the hepatic vessels, and
the gastro-hepatic omentum. This portion of the duodenum, which may be denomi-
nated the hepatic, is about two inches in length.
Relations of the Second Portion. — In front, with the right extremity of the arch of the
colon (t,fig. 161, e being the duodenum), which crosses it at a right angle. Behind, with
the concave border of the right kidney, along which it descends to a greater or less dis-
tance, together with the vena cava inferior and the ductus communis choledochus. Some-
times this portion is not in relation with the kidney, but rather with the vertebral col-
umn. The ductus communis choledochus {c,fig. 169) and the pancreatic duct (m) enter
the intestine at the posterior and inner surface, and below the middle of this portion of
the duodenum. The relations of the duodenum behind are direct, i. c., without the in-
tervention of the peritoneum. On the right, this portion of the duodenum is in relation
with the ascending colon {a, fig. 161). On the left, with the pancreas {o,fig. 154), which
is closely united to it, and embraces it in a sort of half groove. This second portion is
two or three inches in length ; it may be called the renal portion.
Relations of the Third Portion. — The third portion is situated in the substance of the
adherent border of the transverse mesocolon. Below, it rests upon the lower border of
that fold. Above, it is bounded by the pancreas, which adheres closely to it. In front,
it corresponds to the stomach, from which it is separated by the layer of peritoneum
which lines the sac of the great omentum. Behind, it corresponds to the vertebral col-
lunn, from which it is separated by the aorta (a), the vena cava, and the pillars of the
diaphragm {d d).i
As the internal surface and the structure of the duodenum are very analogous to those
of the jejunum and ileum, I shall postpone the description until I have noticed the exter-
nal conformation of the rest of the small intestine.
Fig. 155.
The Small Intestine, or the Jejunnm and
Ileum.
The small intestine, properly so call-
ed (c d,fig. 139 ; i i i,fig. 155), or the
jejunum and ileum, consists of that por-
tion of the alimentary canal which fills
almost the whole of the abdomen, oc-
cupies the mnbilical, hypogastric, iliac,
and lumbar regions, and is surround-
ed, as it were, more or less complete-
ly, by the large intestine {efgh, fig.
139 ; a t d, fig. 155). Its upper ex-
tremity (/ fig. 161) is continuous,
without any hne of separation, with
the duodenum. The distinction be-
tween the two parts is established by
the angle which the mesentery forms
with the mesocolon, or, rather, by the
point where the superior mesenteric
vessels cross over the small intestine.
Its lower extremity {d,fig. 139 ; i,fig.
161) enters at a right angle into the
large intestine. The old division of
the small intestine into the jejunum
and ileum should be banished with oth-
er anatomical niceties, for it is found-
ed only upon trivial distinctions ; and
although the upper part of this intes-
tine differs in many respects from the
* In which figure the liver and stomach are turned upward.
t In one subject I found a fourth portion which passed upward, and was ahmit one inch ir len!?th, so that
the duodenum described a third curve, with its conc.avitv directed to the right.
364 SPLANCHNOLOGY.
lower, still the alteration takes place by imperceptible gradations.* So that Winslow,
unable to find any real difference, established a purely conventional distinction, by pro-
posing to call the upper two fifths the jejunum, and the lower three fifths the ileum.
No portion of the alimentary canal is so movable as the small intestine, properly so
called. It is exceedingly loosely attached, or, as it were, suspended from the vertebral
column, by a large fold of the peritoneum, called the mesentery (the attached portion of
which is seen at m,fig. 161), which, being broader in the middle than at either extrem-
ity, gives an unequal mobility to the different parts supported by it. The small intes-
tine is displaced with great facility.
The circular boundary described around it by the large intestine is only exact above,
where the mesocolon and the arch of the colon («, fig. 155) completely separate it from the
stomach («), the liver (Z), the spleen (k), and the duodenum. But below, between the
caecum {c,fig- 161) and the sigmoid flexure of the colon (/), it descends into the pelvis,
and, extending laterally, passes in front of the colon in both the right and left lumbar re-
gions.
This excessive mobility is one of the most characteristic and important facts regarding
the small intestine, which, in some measure, floats in the abdominal cavity, yielding to
the slightest impulse or concussion. Of all the viscera, it is the most frequently involv-
ed in hernia. It is liable to invagination, i. e., one portion may be received, as into a
sheath, into that immediately succeeding it. When any organ in the abdomen becomes
enlarged, the small intestine yields, and passes in the direction where there is least re-
sistance. It appears to partake of the mobility of fluids. It collects together, or spreads
out ; it moulds itself upon the adjacent parts, and fills up every space, so as to elude aU
causes of compression ; and, by means of this admirable contrivance, the abdomen ac-
commodates itself without inconvenience to the occasional enormous development, either
natural or diseased, of the organs contained within it.
Direction. — We have seen that the upper or supra-diaphragmatic portion of the diges-
tive canal is straight. The stomach presents one slight curve. The duodenum has two
decided curves, and the rest of the small intestine pursues a not less flexuous course.
The following is the direction of this intestine: commencing at the duodenum {j,fig-
161), it passes forward and to the left side ; it is then folded a great number of times
upon itself, and, at its lower part, it passes transversely from the left to the right side,
and a little upward, in order to enter at a right angle (i) into the great intestine.
The numerous foldings or turnings (gyri) of the small intestine upon itself have re-
ceived the name of convolutions ; they are moulded upon each other, without intermixing
or becoming entangled, so as to form a mass, which so closely resembles the surface of
the brain, that the term convolutions has also been applied to the winding eminences of
that organ.
Each convolution represents an almost complete circle. In the complexity presented
by the numerous windings of the small intestine, it appears to be very difficult to assign
to it any general direction ; nevertheless, if we consider that the small intestine com-
mences to the left of the second lumbar vertebra, and terminates in the right iliac fossa,
it will be seen that its general direction coincides with that of the membranous fold (m,
Jig. 161) which supports it ; that is, it may be expressed by an oblique line ruiming
downward from the left to the right side. If, however, we examine the particular di-
rection of the convolutions, we shall find that they all present a concavity towards the
mesentery, and a convexity towards the parietes of the abdomen, so that each resem-
bles the half of the figure 8. In consequence of this arrangement, the intestine may be-
come folded without much change in its position, either in advance or otherwise ; and
hence the great number of folds which can be placed between two points so near each
other as the left side of the second lumbar vertebra and the right iliac fossa, the distance
between which is not more than four inches.
Dimensions. — The determination of the length of the small intestine, properly so called,
has at all times been a subject of interest. Meckel says that it varies from thirteen to
twenty-seven feet, including the duodenum. According to my observations, it varies
from ten to twenty-five feet in the adult, t The length of the small intestine, compared
to that of the large intestine, is generally as five to one. The different results which
have been obtained by various authors may be explained partly by individual varieties
and partly by the mode in which the measurements were made. Thus, a more or less
perfect separation of the gut from the membranous folds which support it would lead to
different results. But another, and less understood cause of difference, is the influence
of the caliber of the intestine upon its length. The caliber and the length have always
an inverse ratio to each other. Of this we may be easily convinced, by strongly infla-
ting a portion of gut which has been previously measured. I have often been struck
* The upper part of the intestine is caWed jejunum, because it is generally found empty ; the second, ileum,
either because it has been supposed chiefly to occupy the iliac regions, or on account of its convoluted disposi-
tion, which, however, is common to it with the other (tiXtti', to turn, to twist).
t The average length of the small intestine, including the duodenum, is 20 feet. I have lately measured
several : in a female affected with chronic peritonitis, it was only 7 feet long ; in another, 14 ; in a third, 18 ;
in a fourth, 20 ; and in a fifth, 22.
THE INTESTINES. 365
with the shortness of the small intestine in cases of hernia, accompanied with retention
of the contents of the gut above the strangulation.
Some authors have attempted to establish a relation between the length of the intes-
tine and the stature of the individual ; and it has been affirmed that the former is four
or five times the height of the body. But differences in stature have not a uniform rela-
tion to the length of the alimentary canal.
Lastly, individual varieties in the length of the small intestine do not appear to h8T6
any influence upon the activity of the digestive process.
Caliber. — The cahber of the small intestine, properly so called, is not the same through-
out. It is greater at the commencement than at the termination of the intestine. When
moderately distended by inflation, I have found it six inches and four hnes in circum-
ference at its commencement, four inches and two lines at the middle, and three inches
and a half a little above its entrance into the large intestine ; but at the point of entrance
itself it is dilated to about four inches and a half
The small intestine, therefore, is funnel-shaped, a form which must facilitate the rapid
passage of its contents, by causing them to proceed from a wider into a narrower space.
Lastly, the caliber of the small intestine presents many varieties. When any obstruc-
tion occurs to the passage of its contents, it may attain the caliber of the large intestine.
In certain cases of marasmus, when it contains no gases, it becomes so contracted that
the tube is completely obliterated.
Figure and Relations. — The smaU intestine is cylindrical ; a section of it is almost cir-
cular. Its posterior harder, to which the mesentery is attached, is concave ; it is thrown
into shght folds, as every straight cylinder must be when it is bent into a curve. Its
anterior border is convex, free, and corresponds to the abdominal parietes, being separa-
ted from them by the great omentum,* which seems intended to contain the whole mass
of the intestinal convolutions. When the omentum is wanting, as in the foetus, or in
cases of displacement from its being rolled up into a cord, the small intestine is in im-
mediate contact with the parietes of the abdomen.
The lateral surfaces of the different convolutions of the small intestine are in contact
with each other. As these surfaces are convex, they intercept triangular spaces before
and after them, in which either effused blood, or serum, or pus, or false membranes, are
sometimes collected.
The small intestine corresponds to all the regions of the abdomen, excepting those of
the upper zone. Not uncommonly, we find it escaped from under the omentum, and sit-
uated between the hver and the abdominal parietes, or reaching into the left hypochon-
drium. It is immediately forced, as it were, in any direction in which there may be an
opening, t
More or less of the small intestine is always found in the pelvis ; in the male, between
the bladder and the rectum ; in the female, between the bladder and the uterus, and be-
tween the uterus and the rectum. In several persons who were emaciated from chronic
diseases, and in whom the vertebral column could be plainly felt through the parietes of
the abdomen, I have found almost the whole, and, in some cases, even the whole, of the
small intestine within the pelvis, contracted, and almost entirely void of air. When one
portion only of the small intestine is in the pelvis, it is invariably the lower part.
WTien any large mass is developed in the abdomen, as in pregnancy, or in encysted
dropsy of the ovarium, the small intestine passes upward and laterally, becomes diffu-
sed, fills up every space, and almost always escapes compression in the most remarka-
ble manner.
It is not uncommon to find, in the small intestine, appendices or diverticula, like the
fingers of a glove, which are sometimes two or three inches in length, and have been
found in the sacs of herniae. These diverticula are usually much nearer the lower than
the upper part of the small intestine. They are formed by all the coats of the bowel,
and are very different from mere protrusion of the mucous membrane through the mus-
cular coat, of which I have seen one example in the duodenum, and which I have often
met with in other parts of the small intestine. In a subject which I recently examined,
the small intestine presented about fifty spheroidal tumours of unequal size, all situated
along the mesenteric side of the gut, and formed by protrusions of the mucous membrane
through the muscular fibres.
Structure of the Small Iritesttne.
Dissection. — This structure must be studied upon a distended and moist portion of in-
testine, upon a distended and dried specimen, and also upon one inverted and distended.
It is also of importance to study the mucous membrane under water, with the assistance
of a strong lens. Injections thrown in first by the veins, and then by the arteries, are
also useful in developing its structure. t
* [Injig. 155, the great omentum has been removed.] . .
t The small intestine is found in diaphragmatic hernicc ; it constitutes perineal hernia ; and it is this por
ion of the bowels which escapes from the pelvis when the lower wall of that cavity is divided.
t The internal surface of the small intestine will be noticed with the mucous membrane.
1
i
366 SPLANCHNOLOGY.
The small intestine, as well as the stomach, is formed of four coats or membranes,
which, proceeding from without inward, are the serous, muscular, fibrous, and mucous coats.
The Serous Coat. — The arrangement of this coat upon the duodenum differs from that
upon the rest of the small intestine.
The peritoneum is apphed to the first portion of the duodenum in the same way as
upon the stomach, i. e., it covers it entirely, excepting in front and behind, where there
is a triangular space devoid of this coat. Like the stomach, this first portion gives at-
tachment to the great omentum in front, and to the small omentum behind. The fold
of peritoneum which passes from the liver to the duodenum has been improperly called
the hepatic ligament of the duodenum. The peritoneum merely passes over the front of
the second and third portions of the duodenum, so that the posterior surface of the in-
testine is in immediate contact with the parts with which it is in relation, and is very
perfectly fixed.
The peritoneum forms a complete sheath for the small intestine, properly so called, ex-
cepting along its concave border, where the two layers which constitute the mesentery
separate from each other, so as to include the bowel. In this situation we find a trian-
gular cellular space, exactly resembling those which we have already described along the
curvatures of the stomach, and performing a similar office, viz., that of remedying the
slight extensibility of the peritoneum, and permitting the intestine to undergo sudden
dilatation to a great extent. We should have a very incorrect notion of the dilatability
of the intestine if we imagined that it is limited by the triangular space along its con
cavity, for when the bowel is much distended, the mesentery itself becomes separatee
into its two layers to allow of such distension. Of this I am convinced from having
measured the antero-posterior diameter of the mesentery both before and after inflation
of the bowels.
The cellular tissue which unites the peritoneal to the muscular coat is extremely del-
icate, and its adhesion to the latter coat increases in proceeding from the concave to the
convex border of the intestine. Although the peritoneal coat is very thin, and so trans-
parent that the muscular fibres may be seen through it, yet it has considerable strength.
The muscular coat is composed of two layers of involuntary muscular fibres, one su-
perficial, the other deep. The superficial layer is the thinner ; it consists of longitudinal
fibres placed around the bowel in a very regular manner, and forming a continuous plane.
I have never found these fibres more numerous at the mesenteric than at the convex
border. This layer of fibres is almost always removed with the peritoneal coat, to which
it adheres very intimately. From their white colour and shining appearance under the
serous membrane, they have been supposed to be of a tendinous nature.
It is difficult, though by no means important, to determine exactly whether the same
fibres reach the whole length of the intestine, or whether they are interrupted at inter-
vals. It is generally admitted that they are interrupted, and that their extremities are
received in the spaces between other fibres.
The deep layer of muscular fibres is thicker than the preceding, and consists of circu-
lar fibres, either parallel or crossing each other at very acute angles. They appear to
me to describe complete circles, and to have their ends united. They have no tendinous
intersections.
The fibrous coat is intermediate between the muscular and mucous tunics, and presents
the same characters as in the stomach.
The Mucous or Papillary Membrane. — Its external surface adheres to the fibrous membrane
by a loose cellular tissue, which is liable to serous, sanguineous, and purulent infiltra-
tion. The emphysematous or cedematous condition may be imitated in the dead body,
by everting a portion of bowel and distending it either with air or water. The tenuity
of the mucous membrane displayed in these experiments has led to the opinion that this
coat is nothing more than an epithelium, a continuation of the epidermis of the skin, and
that the fibrous coat represents the cutaneous dermis. Its internal surface is free, and
is covered with more or less mucus ; it is remarkable for its duphcatures or valves, call-
ed valvules conniventes ; for its highly-developed papillee, and for the arrangement of its
follicles.
The ValvulcB Conniventes {Valvulce Intestinales).
Dissection. — Evert the small intestine, so that its external surface becomes internal, and
then plunge it in water ; or, what is better, lay open the bowel, and examine its internal
surface under water. Also study a portion of intestine inflated and dried.
Hitherto the mucous membrane of the alimentary canal has only presented to our no
tice certain folds which are intended to facilitate the dilatation of that canal, as in the
cesophagus and stomach, and which are completely effaced by distension. The folds of
the mucous membrane of the small intestine fulfil another purpose ; and although they
must, undoubtedly, in some measure assist in the elongation and dilatation of the bowel,
yet they are never entirely effaced, however far this extension in length or width maj
be carried. These folds deserve a special description. They are called valvulce conni-
ventes or the valves of Kerkringius, although Fallopius had given a complete description
THE INTESTINES. 367
of them before that anatomist. Kerkringius gave them the name of conniventes {con
niveo, to close partially). They commence in the duodenmn (see fig. 169), an inch, oi
sometimes two inches, from the pylorus ; and it is not unconunon to find them preceded
by some vertical folds. They are few and small at first, but become very numerous and
very large towards the end of the duodenum and the commencement of the small intestine,
properly so called. From the upper two fifths of that intestine they gradually diminish
in number, and become less regular and less marked towards the lower part of the small
intestine ; sometimes they are altogether wanting in the last two or three feet of the
bowel. In some rare cases, I have seen valvulae conniventes as far down as the ileo-
caecal valve ; in no part are they sufficiently numerous to have a true imbricated arrange-
ment. These valves are placed perpendicularly to the axis of the intestine, and describe
one half, two thirds, or three fourths of a circle ; but they seldom form a complete ring.
They are broader in the middle, being from two or three lines in width, than at their ex-
tremities, which are slender. In order to ascertain their dimensions, they must be
placed under water, or studied upon a fresh portion of intestine. They are generally
parallel, incline towards each other by their extremities, bifurcate, and send off smdj
verticular oblique prolongations. Sometimes we find small valves placed between the
larger ones. Some of them are suddenly interrupted, so that they might be supposed, at
first sight, to have undergone some loss of substance. Several of them are alternate,
and seem to be disposed in a spiral manner ; but there is no general rule in this respect ;
their free edge is sometimes directed towards the pylorus, and sometimes towards the
ileo-cffical valve. Their direction is very irregular ; they yield to any impulse that may
be conamunicated to them, and their free edge passes either upward or downward, ac-
cording to circumstances. When examined upon a dried specimen, they resemble very
much the diaphragms in optical instruments.
The valvulae conniventes are formed by folds of mucous membrane, within which we
find some loose cellular tissue, different kinds of vessels and nerves. Inflation, by rais-
ing the mucous membrane, completely effaces them. The fibrous coat presents a slight
thickening opposite the bases of these valves. The valves, notwithstanding the ease
with which they are moved, must in some manner retard the passage of the food, with-
out offering any decided resistance to it, for that would become a cause of obstruction,
and give rise to serious accidents. Their chief use, perhaps, is to increase the extent
of surface ; according to Fabricius, they double the surface of the intestine ; Fallopius
says they increase it three times, and Kew six times. Soemmering has given the some-
what conjectural opinion, that the surface of the intestinal mucous membrane is greater
than that of the entire skin (Corpor. Hum. Fabrica, t. vi., p. 295). Although not peculiar
to the human species, they are much more developed in man than in the lower animals.
Besides the valvulag conniventes, the mucous membrane of the small intestine presents
some irregular folds, which are effaced by distension.
The PapilloR, or Villi.
Preparation. — 1. Place the opened intestine in water, exposing it to a strong light, and
agitate the fluid. A stream of water previously received upon the membrane will re-
move the mucus, which sometimes forms a tenacious sheath around each papilla.* 2.
Roll up a portion of the detached mucous membrane, taking care to turn the adherent
surface inward. 3. Evert a loop of intestine, so that the peritoneal coat may be on the
inside : stretch it upon a cylinder, and then agitate it in a cylindrical vessel, so as to
float out the valves.
The papilla, or villi, are much more developed in the small intestine than in any other
part of the alimentary canal, with the exception of the tongue. Fallopius has the honour
of having discovered them. They were T,vell described by Helvetius, Hewson, and Lie-
berkuhn, but still more accurately of late by Albert Meckel. When examined by the
naked eye and under the microscope, the internal surface of the intestine appears to be
roughened by an inunense number of prominences or vilh {figs. 157, 159), resembling
very close, short grass, or a very hairy caterpillar. In some animals, as in the dog, and
especially in the bear, the villi are so numerous and so long, that they in some degree
resemble the filzmientous roots of plants. They are found through the whole length of
the small intestine, and cover the valvulae conniventes, as well as the intervals between
them. They vary in length : according to Lieberkuhn, they are one fifth of a line ; their
maximum length appears to be about four fifths of a line : and I have even found some
in the duodenum, which, when extended, were a line in length ; their number is very con-
siderable, and attempts havQ been made to determine it. Lieberkuhn computed them at
500,000. Several Germans have taken up the subject ; allowing 4000 to every square
inch, by a calculation, the exactness of which I have not verified, there would be a mill-
ion altogether. I have not observed any well-marked difference as regards the number
of the vilh, between the commencement and the termination of the small intestine. It
* A. Meckel recommends that the mucus should be removed by plunging the intestine first in an arsenical
solution, and then in water impregnated with sulphuretted hydrogen ; but the continued action of a stream of
water is far preferable.
368
SPLANCHNOLOGY.
appears to me that the number and length of the villi are much greater in carnivora than
in herbivora. The otter has been said to have the largest vilU of any animal. Their
form varies much. In the majority of animals which I have examined, as the dog, cat,
calf, and bear, they are fUiform. In the human subject they are all lamellar or foliaceous,
but with many varieties. In the duodenum they are curved upon themselves, presenting
the appearance of a calyx or corolla, and sometimes adhering to each other by their ex-
tremities. In the small intestine, properly so called {figs. 157, 159), they are rectilinear,
floating, cylindrical, conical, clubbed at the end, constricted, and sometimes bent in the
middle. In the neighbourhood of ulcerations, they are, as it were, cut oiF close or trun-
cated, without presenting any alteration in their structure.
Structure. — Brunner calls them membranous tubes ; Leeuwenhoek regarded them as
muscular organs ; Helvetius and Hewson considered them to be small valves, an idea
which has been revived and carried out more lately by Albert Meckel. This anatomist,
who has given representations of the villi in a great number of animals {Journ. Comple-
ment, t. vii., p. 209), regards them as formed of small Icunellae, sometimes twisted upon
their axes, like the first leaf of a germinating grain of wheat, and sometimes folded into
a semi-canal or groove ; but he considers that all these varieties m^y be referred to that
of a lamella, broad at the base and narrow at the apex ; a fundamental form, which may
always be demonstrated with the aid of a needle.*
Lieberkuhn states, that at the base of each villus there is an ampulla, which opens
upon the summit of the villus by a single orifice ; and he considers that both the ampul-
la and the orifice belong to the commencement of the lacteal vessels ; arteries and veins
ramify round the ampuUa ; and each villus has an afferent artery and an efferent vein.
According to Mascagni, the villi are composed of an interlacement of bloodvessels and
smEill lymphatics, and are covered by an extremely thin membrane, composed of lym-
phatics. The following are the results of my own observations : Having had occasion
to examine a subject in which the lymphatic vessels were filled with tubercular matter,
I was able to trace a lymphatic trunk into each villus (vide Anat. Path, avec planches,
liv. 2), which traversed its entire length. This perfectly agrees with Lieberkuhn's ac-
count. In another subject I injected mercury into one of the mesenteric veins, and then
above the mercury I forced in a coarse black injection. The mercury and a part of the
black injection passed into the cavity of the intestine, and a globule of mercury appear-
ed upon the summits of the villi, which were blackened from the injection. From this
I have concluded that the villi are perforated at their summits. I shall return to this
subject again. t
The Duodenal Glands and Follicles. Preparation. — Some intestines are not well adapt-
ed for the study of the follicles, which, indeed, seem to be entirely wanting in them.
Others, again, are very favourable for that purpose. The folhcles are rendered more
apparent by plunging the intestine into acidulated water. They must be examined from
the internal surface of the mucous membrane, and also from its external surface, by re-
moving the serous, muscular, and fibrous coats by which they are covered. In the study
of the duodenal glands, this last method of investigation is absolutely necessary.
The follicles are generally divided into two kinds, the simple or solitary, and the ag-
minated ; to these we shall add the duodenal glands.
The Duodenal Glands. — These, properly speaking, are the glands of Brunner. This anat-
omist, who had already made some curious experiments upon the pancreas, says that,
having partially boiled the duodenum, he observed upon its internal membrane some
granular bodies, which he has had figured, resembling the solitary follicles in the neigh-
bouring portion of intestine. To this collection of granules he gave the name of the sec-
ond pancreas. Farther observations have shown, that in the upper half, or upper two
* [Many of the villi are certainly cylindrical, and, therefore, not referrible to the fundamental form described
by Albert Meckel. In the fostus and young subject they are comparatively broader and flatter, and are con-
nected at their bases so as to form folds having irregular margins. In this stage of their development they re-
semble the rugiB in the intestines of birds and reptiles.]
t [The villi contain all the elements of the intestinal mucous membrane ; no nerves, however, have been ao-
toally demonstrated in them.
Fig. 156.
The bloodvessels are numerous, and form a very
Deautiful capillary network in each \';llu8 (3, Jig.
156).
Great differences of opinion have existed, and still
exist, as to the mode of origin of the lacteals in the in-
testinal villi ; the best authorities, however, agree in
stating that they do not commence by open orifices.
Rudolphi and A. Meckel considered that they arose by
a closed network. Dr. Ilenle found a single dilated
but closed lacteal in each viUosity ; and more recent-
ly, Krause observed that in each villus the lacteal
arose by several branches, some of which ended in
free but closed extremities, while others anastomosed
together (i,fig. 156). The villi, and, it may be ob-
served here, every portion of the intestinal mucous
membrane, are covered by a transparent, columnar epithelium, consisting of elongated prismatic nucleated cor-
puscules. The perpendicular arrangement of these upon the surface of a villus is shown in the diagram (1,
%. 156).]
THE INTESTINES.
thirds of the duodenum, there is a layer of flattened granular bodies, perfectly distinct
from each other, however close they may be. This layer must not be confounded with
the glanduliform arrangement of the duodenal villi ; it can only be well seen after hav-
ing removed the three outer coats. These granular bodies are nothing more than small
(compound) glands, which, when examined with a powerful lens, present all the charac
ters of the salivary glands. These glands do not cease abruptly, but become few and
scattered towards the lower end of the duodenum ; so that it is by no means inconsist-
ent to admit that the solitary folhcles of the rest of the intestinal canal may be of a simi-
lar nature.*
The solitary follicles, or glandula solitaries, are generally known in the present day ao
the glands of Brunner {Disput. de Gland Duoden., Heidelberg, 1687, 1715), although that
anatomist only described the glands or follicles of the duodenum, which he said dimin-
ished in number below that portion of the intestine, and disappeared adtogether in the je-
junum. It is, therefore, by an extension of the author's meaning that we speak of the
glands of Brunner as occupying the termination of the small intestine, the stomach, and
even the large intestine.
The glandulae solitariae present the appearance of small rounded granulations, like mil-
let seeds, projecting upon the internal surface of the mucous membrane, without any
distinct orifice, and covered with villi (fig. 157) ; they are found upon the valvulae con-
niventes, as well as in the spaces between them. Their number is very considerable ;
so that in certain diseases, where they become more prominent than usual, they might
be mistaken for a confluent eruption. It is a mistake to say that they diminish in num-
ber from the upper towards the lower part of the small intestine, the contrary being
nearer to the truth. When examined with the simple microscope, they have appeared
to me to be hollow, and filled with mucus. t
The agminated follicles, or glandular plexuses, are more generally knov^n as the glands
of Peyer, although both the solitary and agminated glands were described by that anato-
mist. Pechlin noticed them under the name of vesicularum agmina. Willis, Glisson,
Malpighi, Duvemey, and Wepfer have given more or less complete descriptions of them:
but Peyer (De Glandulis Intestinorum, J. C. Peyer, 1667, 1673), when still a young man,
and without any knowledge of the work of Pechlin, described and figured them under
the title oi glandula agminatce so accurately as to leave nothing to be desired.
These agminated glands are arranged in elliptical patches {fig. 158), the long diameter
of which corresponds with the direction of the intestine : —g.. 153.
they are pierced with holes, or small depressions, so that
they have a honeycombed appearance ; and hence has
arisen the name of plaques gaufries, under which I believe
I was the first to describe them : they are all situated on
the border opposite to that by which the mesentery is at-
tached to the intestine ; that is, along the convex border
of the intestine, and never along the concave border, nor
even upon either side. They are chiefly found towards the
end of the small intestine ; they become more and more
scattered as we approach the duodenum, in which, how-
ever, Peyer once met with a single patch. Their nuniber
varies considerably, twenty, thirty, and even more having
been counted. Are they ever entirely wanting 1 The dif-
ficulty of detecting them in some subjects has led to their
being rejected altogether, or considered as the results of
a pathological condition ; but this opinion is clearly at va-
riance with observation. Again, these patches are not
constant either in situation, form, or dimensions. Some-
times they assume the appearance of bands two or three
inches in length {fig. 158), and sometimes they form cir-
cular or irregular clusters. The largest are found near
the ileo-cffical valve. It is not rare to find the termina-
tion of the small intestine surrounded by a circular patch ;
in other cases, the patches termi-
nate some inches above the ileo-
■f!3cal valve, and their place is sup-
jjlied by simple follicles.
* [According to Dr. Boehra (He Gland. Intestm. Struct, penitiori), this is not tte
case, the compound glands of Brunner not existing below the commencement of the
jejunum.]
t iFig. 157 is a solitary gland magnified ; it is represented, after Boehm, as a
closed vesicle, filled with whitish matter, which contains granules smaller than
those of mucus. Villi are seen upon the free surface of its capsule, and it is sur-
rounded by the crypts of Lieberkuhn (the mouths of which are indicated by the ^aj^e'
spots), which have no communication with the vesicle itself (see also note, p 370J.1
A A A
Fig. 157.
370 SPLANCHNOLOGY.
These patches are generally contained in the substance of the mucous membrane, to
_p. j.g which they give a much greater density, so that, in
_ ■ ■ these situations, it will bear to be scraped. In some
f- < ^ ftases they appear to be imbedded in the fibrous coat.
pi; V,. They should be examined both from the external and
f' :rwmMfim internal surfaces of the mucous membrane.* When
y '.^millll they are filled with their secreted fluid, and are exam-
ined by transmitted light, they may be compared to the
vesicles in the skin of an orange : this observation may
be easily made in the day. They evidently consist of
collections of glands, exactly resembhng the solitary
glands {fig. 159). Each depression appears to be the
orifice of one of the follicles, which are quite independ-
ent of each other ; so that we sometimes find two or
three altered in the middle of a patch, which is other-
wise perfectly healthy. Lastly, viUi are found upon the
patches of the glandulse agminatae : they occupy the in-
tervals between the depressions.!
The Follicles or Corjruscules of Lieberkuhn. — Lieberkuhn speaks, also, of innumerable,
rounded, whitish foUicles, which are seen between the villi, and of corpuscules which are
visible between these follicles. He calculates that there are eighty follicles for eighteen
villi, and eight corpuscules for each follicle. I am disposed to think that these follicles
and corpuscules, which have never been seen excepting by the microscope, should be refer-
red to those globules which are reveededin all the tissues by the aid of a magnifying power. |
The Vessels and Nerves. — ^All the arteries of the small intestine, properly so called, are
branches of the superior mesenteric. They are very numerous. Those of the duodenum
arise from the hepatic. The branches from the superior mesenteric are remarkable for
the numerous anastomotic loops which they form before reaching the intestine, for their
flexuous course within its coats, and for the series of vascular layers formed by them
between the peritoneal and muscular, the muscular and fibrous, and the fibrous and mu-
cous coats. The last layer forms a very complicated network, from which the vessels
of the mucous membrane are derived. The veins are much larger than the arteries, and
present a similar arrangement, except in regard to the flexuous course, which is peculiar
to the arteries ; they constitute the superior mesenteric vein, which is one of the prin-
cipal branches that contribute to form the vena portae.
The lymphatic vessels are of two kinds, viz., lacteals and lymphatics, properly so called ;
they both enter the numerous lymphatic glands, situated in the mesentery ; those which
belong to the duodenum enter the glands above the pancreas.
The nerves are derived from the solar plexus.
The development of the small intestine will be noticed in conjunction with that of the
large intestine.
Uses. — Chylification, i. e., the transformation of the chyme into chyle, is effected in the
duodenal portion of the small intestine. The essential agents of this process are the
bile and the pancreatic fluid. In the remainder of the small intestine (the jejunum and
ileum), the absorption of the chyle takes place. The numerous convolutions, the valvu-
lae conniventes, and the villi, all tend to increase the extent of the absorbing surface.
The products of exhalation and of follicular secretion serve to complete the digestive
process. The contents of the bowels are forced along by the shortening of the longitu-
dinal, and the contraction of the circular fibres, the latter producing the vermicular mo-
tion of the intestines.
The Large Intestine.
The large intestine is that part of the alimentary canal which extends from the end oi
the small intestine {d,fig. 139) to the anus (i). It commences in the right iliac region
{c,fig. 161), and passes upward (a) as far as the right hypochondrium ; then, having
reached the liver, it makes a sharp flexure (the right or hepatic flexure), and proceeds
* [Their contents are sometimes transparent, and tliey are then very difficult of detection.]
filn fig. 169, representing part of a patch of Peyer's glands magnified, are seen some of the elevated white
bodies described by Boehra as resembling the solitary glands, except in not generally having any villi situated
directly upon them. Each is surrounded by a zone of dark points, the elongated openings of the crypts of
Lieberkuhn. Many of these crypts are also seen scattered irregularly between the numerous villi ; none of
them communicate vpith the interior of the whitish bodies, in which, whether solitary or agminated, Boehm
could discover no opening, at least, not in a healthy human intestine. He considers them, therefore, to be closed
vesicles, not follicles.
More recently, however, Krause has observed that, in the pig's intestine, they are occasionally open, independ-
ently of disease ; and Dr. Allen Thomson has lately made a similar obsen'ation in reference both to the pig
and to the human subject.]
i [The follicles or crypts of Lieberkuhn are tubes placed more or less perpendicularly to the surface of the
mucous membrane, like those in the stomach, but situated more widely apart ; their open mouths are seen
scattered over the whole surface of the membrane, or collected around the solitary and agminated glands (figt
157, 159). The corpuscules {corpora albicantia), described by the same observer as being situated in the bot-
tom of the crypts, are probably collections of desquamated epithelium within them.]
THE INTESTINES. 371
iransTersely (t) from the right to the left side {transverse arch of the colon) ; in the left
h3T)Ochondrium, below the spleen, it again makes a sharp bend and becomes vertical (d),
(left or splenic flexure). In the left iliac region (/) it is twice bent upon itself, hke the Ro-
man letter S {iliac or sigmoid flexure), and it then dips into the pelvis (r), and terminates
at the anus.
The large intestine, therefore, describes within the abdomen a nearly complete circle,
which surrounds the mass of convolutions of the small intestine ; and it occupies the
right and left iliac regions, the right and left lumbar, the base of each hypochondriac,
and the adjacent borders of the epigastric and umbilical regions. Although it is much
more firmly fixed in its place than the small intestine, and is, therefore, less liable to
displacement, yet it presents some varieties in length and curvature which have a con-
siderable influence over its position. The large intestine is more deeply situated than
the small in one part of its extent, but in another is at least quite as superficial.
From its long course, and from the different relations piesented by its diflferent parts,
it has been divided into the ccecum, the colon, which is itself subdivided into several
parts, and the rectum.
Dimensions. — The IcTigth of the large intestine is four or five feet, and, compared with
the small intestine, is as one to four ; but it varies considerably, rather, it would seem
to me, from the eflfects of repeated distension, than from any original conformation ; for
it may be easUy imagined that the bowel cannot be distended transversely without lo-
sing somewhat in length, and that, on returning to its former diameter, it must be elon-
gated in proportion to the distension it had previously undergone. The large intestine
has also generally appeared to me longer in persons advanced in age than in adults.
Its caliber or diameter usually exceeds that of the small intestine, but may become so
reduced that the gut resembles a hard cord, about the size of the little finger. In other
cases it is so large that it occupies the greatest part of the abdominal cavity : this is ob-
served in tympanitic distension of the large intestine. It is not of uniform caliber
throughout, as the following measurements will show. The circumference of the caecum,
moderately distended, and taken immediately below the ileo-caecal valve, was found to
be eleven inches and three lines in one subject, and nine inches and a half in another ;
the right colon in the loins and the right half of the arch were eight inches and nine
lines in the first, and five inches some lines in the second subject. The circumference
of the left half of the arch of the colon, and of the left lumbar colon, was six inches in
the first and five inches and a half in the second. The circumference of the sigmoid
flexure was five inches and a quarter ; that of the rectum was three inches until near
its termination, where it presented a dilatation four inches in circumference in one, and
five inches in the other subject.
It follows, therefore, that the large intestine, like the small, has an infiindibuliform
shape ; it resembles, indeed, two ftmnels, the base of the one corresponding to the
caecum, and its apex to the sigmoid flexure, while the base of the other is at the dilated
portion of the rectum, and its apex is apphed to that of the first. It is probable that this
infundibuliform arrangement has some reference to the passage of the faecal matters.
It also follows that there is no uniform relation between the diameters of the different
portions of the large intestine : thus, a very large caecum and ascending colon may co-
exist with a small descending colon In some cases we find in the large intestine con-
siderable dilatations, separated from each other by such constrictions that the caliber
of the corresponding part of the gut is obliterated. These strangulations from a con-
traction of the circular fibres are very different from those produced by organic diseases :
they probably take place during life, and may account for the affection known as the
windy colic. In some chronic diseases, accompanied with diarrhcea, the large intestine,
contracted and containing no gases, is not as large as the small intestine.
The CcEcum. — The caecum (e, fig. 139), so named because it resembles a cul-de-sac, is
the first part of the large intestine The existence of a caecum is one of the numerous
indications of the line of separation between the large and the small intestine. Its up-
per boundary is altogether arbitrary ; it is determined by a horizontal plane intersecting
it immediately above the insertion of the small intestine. It is single in the human sub-
ject, but is double in some species of animals. It is situated {c,fig. 161) in the right iliac
fossa, and occupies it almost entirely. It is one of the most fixed portions of the ali-
mentary canal, for the peritonemn merely passes in front of it, and binds it down into
the iliac fossa. It is not, however, so firmly fixed in all subjects ; it is often enveloped
by the peritoneum on all sides, and floats, as it were, in the region which it occupies, its
capability of motion depending on the looseness of the right lumbar mesocolon. This
arrangement of the peritoneum is not necessary, however, to explain the great amoun
of displacement which the caecum undergoes in certain cases. It is not uncommon to
find it in the cavity of the pelvis : it occasionally enters into the formation of herniae
and, what is somewhat remarkable, it has been at least as frequently found in hernia
upon the left as upon the right side.
Its direction, which is in general the same as that of the ascending colon, is not alway
vertical a.s may be seen by examining a moderately-distended intestine, but it pass*
379" SPLANCHNOLOGY.
obliquely upward and to the right side, so that it forms with the colon an obtuse angle
projecting on the right side ; and I have even seen it form a right angle with the colon.
This arrangement, connected with the obliquity of the plane of the iliac fossa, explains
why, when its attachments are relaxed, it has less tendency to be displaced towards the
right inguinal ring and femoral arch than to the same parts on the left side. In some
subjects, the caecum and its vermiform appendix are applied to the lower part of the
small intestine, so that the caecum and the neighbouring part of the colon describe a
curve, the concavity of which embraces the lower end of the ileum.
In size it is generally larger than the portion of the intestine which succeeds it : this,
perliaps, depends less upon its primitive conformation than upon the accumulation of
faecal matters resulting from the inclined position of this intestine, and from the direc-
tion in which its contents are moved. It may be said, as a general rule, that, next to
the stomach, the caecum is the largest part of the alimentary canal. There are many
individual varieties in the length and capacity of this intestine, in which the faecal mat-
ters are liable to be retained. These accumulations occasion great pain ; they have
been much studied lately, and have been often mistaken for inflammations. The caecum
is very shghtly developed in carnivora, but, on the other hand, it is very large in her-
bivora.
Figure. — ^The caecimi is a sort of rounded ampulla, all the diameters of which arc
nearly equal ; it is also sacculated like the rest of the large intestine. Upon it we ob-
serve the conamencement of the three longitudinal bands, which I have already noticed :
of these, the anterior is, in the caecum, twice as broad as either of the two posterior ;
some folds of peritoneum, loaded with fat, which are called fatty appendages {appendices
epiploica) ; and, lastly, some protuberances, separated by parallel depressions, an ar-
rangement which exists in the colon also, and is produced by the longitudinal bands.
Relations. — In front, the caecum is in relation with the abdominal parietes, through
which it can be felt when it is distended with gases or faecal matters. When the cae-
cum is collapsed, the small intestine is often interposed between it and the parietes of
the abdomen.
Behind, it rests upon the iliacus muscle, from which it is separated by the lumbo-iliac
fascia. The cellular tissue uniting it to this aponeurosis is extremely loose, and, there-
fore, offers no opposition to displacement of the intestine. When the peritoneum forms
a complete covering for the caecum, that intestine is, of course, in indirect relation with
the iliacus. The vermiform appendix is often turned back behind the caecum. On the
inside, the caecum receives the small intestine ; the angle at which they unite (the ileo-
csecal angle) varies much. Sometimes the small intestine is inserted at a right angle ;
most commonly the angle of incidence is obtuse above and acute below {fig. 160). Some-
times the ileum, instead of passing upward, is directed downward, and then the angle
of incidence is changed. A circular depression indicates the limit between the two in-
testines. Below, upon the free extremity or cul-de-sac of the caecum, is seen the \^r-
miform appendix {v), situated behind and on the left side, a few lines below the ileo-
caecal angle.
The arrangement of the internal or mucous surface of the caecum is in accordance with
that of its external surface : thus, three projecting ridges correspond with the three lon-
gitudinal bands ; some cavities or pouches with the protuberances ; and some transverse
projecting folds, forming incomplete septa, which are easily seen in a dried specimen,
correspond with the parallel depressions. Upon this surface, to the left and a little be-
hind, we also find the ileo-caecal valve (a b,fig. 160), and the orifice (o) of the vermiform
appendix (»).
The Ileo-caecal Valve. — This is also called the valve of Bauhin, from the name of the anat-
omist to whom its discovery is attributed, although it had been described before his time.
To obtain a perfect knowledge of it, it should be examined upon a fresh specimen under
water, and also upon an inflated and dried intestine.
In a fresh specimen, when viewed from the caecum, it presents the appearance of a
projecting cushion, oblong from before backward, and fissured in the same direction. It
is a membranous and movable cushion, and was incorrectly compared by Riolanus to the
pyloric ring. It has two lips and two commissures ; the two lips are in contact, except
during the passage of the contents of the bowels. Two folds, proceeding from the two
commissures, one of which is anterior and the other posterior, are lost upon the corre-
sponding surfaces of the intestine. The posterior fold is much longer than the anterior ;
Morgagni called them ihefrana of the valve. When viewed from the ileum, it presents
the appearance of a funnel-shaped cavity, directed upward and to the right side.
In a dried intestine, the ileo-caecal valve is seen to consist of two prominent valvular
segments, projecting into the caecum, so as to form an angular ridge. The upper, or ileo-
colic segment {b,fig. 160), is horizontal ; the lower, or ilco-ccecal (a), forms an inclined plane
of about 45°, and both are parabolic. The upper segment is fixe J by its adherent convex
border to the semicircular line, along which the upper part of the tube of the ileum is
united with the colon ; the adherent border of the lower segment, \^ hich is also convex,
is continuous with the semicircular hue of junction between the lower half of the ileum
THE INTESTINES. 373
and the caecum. The free borders of the segments are directed to-
wards the right side, and are semilunar ; they are united at their ex-
tremities, but in the middle leave between them (between a and h)
an opening like a buttonhole, which becomes narrower as the intes-
tine is more distended. The diameter of this opening is in proportion
to that of the small intestine. The free border of the lower segment
is more concave than that of the upper. When examined from the
ileum, the valve presents an angular excavation exactly correspond-
ing to the projecting edge found in the cavity of the large intestine.
The lower surface of the upper valvular segment is slightly concave ;
the corresponding surface of the lower segment is slightly convex.
This double ileo-caecal valve differs widely from the ring of the py-
lorus ; it offers no obstruction to the passage of the contents of the
small into the large intestine ; but in ordinary cases, it will not per- "
mit their regurgitation from the latter into the former. The lower or ileo-caecal segment
is elevated so as to prevent reflux from the caecum, and the ileo-colic segment becomes
depressed, and opposes any return of the contents of the colon. Still, from a great num-
ber of experiments which I have performed on this subject, I am satisfied that both wa-
ter and air injected into the large intestine most frequently overcome the resistance offer-
ed by this valve, though with different degrees of facility in different subjects. This re-
gurgitation, however, only takes place with gaseous or liquid matters ; such as have a
greater degree of consistence cannot pass back, and therefore the reflux of faecal matter
is impossible.*
Structure. — ^The structure of the ileo-caecal valve was perfectly demonstrated by Albi-
nus. If we follow his example, and remove the peritoneal coat from a distended intes-
tine, at the point where the ileum enters the large bowel, we shall at once perceive most
distinctly that the small intestine seems to sink in there ; and if, by means of careful and
gradual force, we attempt to disengage it from the large intestine, it may be drawn out,
as it were, from the colon to the length of an inch or an inch and a half; and then, on
inspecting the inside of the large intestine, we shall find that the valve has altogether
disappeared, and that the ileum communicates with the caecum and colon by a large ap-
erture.
The precise structure of the valve is as follows : it is composed of the circular muscu-
lar fibres of the ileum, which are prolonged as far as its free edge ;t of the fibrous coat,
and of the mucous membrane. A similar fact has been observed regarding this mucous
membrane to one we have already several times noticed in describing the alimentary ca-
nal, viz., a sudden change in its character opposite the free margin of the valve. That
portion of the membrane which lines the surface turned towards the large intestine has
all the characters of the mucous membrane of that bowel, while that lining the surface
directed towards the ileum has those of the mucous membrane of the small intestine.
The limit between them is generally observed in diseases.
The Appendix Vermiformis. — The appendix vermiformis {v,figs. 139, 160, 161), so na-
med from its resemblance to an earth-worm, commences at the posterior lower and left
portion of the caecum, of which it may be considered an appendage {the cacal appendix) ;
it resembles a small, hollow, and very narrow cord {duodecies jiascente colo angustior, says
Haller). In length and in direction, it presents much variation : its length is from one to
six inches. It is somewhat wider at its point of junction with the cascum than in any
other part, and is in general about the diameter of a goose-quill.
Its direction is sometimes vertically downward, sometimes upward, and often tortuous.
I have found it spiral, and at other times contained in the substance of the mesentery,
parallel to the ileum, and only free at its extremity. In some subjects it is funnel-sha-
ped, widening out to become continuous with the caecum, which, in such cases, is very
narrow. Its situation and relations are equally variable. Thus, most conmionly, it oc-
cupies the right iliac fossa, near the brim of the pelvis : it is attached to the caecum and
to the iliac fossa by a triangular or falciform fold of the peritoneum, which extends only
to one half of its length, and allows it a greater or less capability of movement. It is still
more movable when it is entirely surrounded by the peritoneum, and has no mesentery.
From this it may be conceived that it may enter into the formation of herniae, and may
be twisted around a knuckle of the small intestine, so as to cause strangulation. It is
* Nevertheless, if we consider that the large intestine must always be very much distended in order to pro-
duce a reflux of gases and liquids, it may be questioned whether the passage of gaseous or liquid matters from
the large to the small intestine can take place during life. I have been able to determine the mechani.sm of
the resistance oflfered by the valve from the effects of distension. The two segments are turned back, the
lower one upward, and the upper one downward ; their corresponding surfaces become convex, and they are
pressed together the more and more forcibly in proportion to the amount of distension. In some subjects dis-
tension may be carried so far as to rupture the longitudinal bands, and yet not overcome the obstacle. In
most cases, the free edge of the lower segment glides from right to left under the upper one, which remaina
immovable ; and the gas and liquids escape with more or less facility according to the degree of disturbance
in the parts.
t I The longitudinal muscular fibres and the peritoneal coat pass directly from the small to the large intes-
tine, without entering into the formation of the valve.]
374
SPLANCHNOLOGY.
often turned back behind the ascending colon between that intestine and the kidney : in
one case of this kind, I found the free extremity of the appendix in contact with the lower
surface of the liver. I have also once seen it turned up behind the lower end of the
-amall intestine, and, at another time, embracing that bowel in front. None of these dif-
* ferences, however, depend on the situation of its point of attachment to the csecum,
which is always on the left side, below and behind the cul-de-sac, at a short distance
from the ileo-caecal valve.
When divided lengthwise, the cavity within it is seen to be so narrow that the walls
are always in contact. A small quantity of mucus is found in it, and it often contains
small scybala ; cherry-stones and shot have also been found in it. The whole of its
internal surface has a honeycomb appearance, like that at the lower end of the small
intestine.* A valve of different size in different subjects, but never sufficiently large to
cover the orifice entirely, is found at the point (o. Jig. 160) where the appendix commu-
nicates with the caecum. The cavity of the appendix, like the caecum, terminates be-
low in a cul-de-sac ; and in this, which is extremely narrow, foreign bodies may be
lodged, and may then sometimes become the cause of those spontaneous perforations
which are occasionedly seen. The uses of this appendix are edtogether unknown ; in the
human subject, it is merely a vestige of an important part in many animals. Haller says
that he has twice seen the vermiform appendix obliterated, i. e., without any cavity. I
presume that this was the effect of morbid adhesion. Lastly, I once found this appendix
as large as the index finger, and two inches in length ; its cavity contained some thick,
transparent mucus. The orifice by which it should have conununicated with the caecum
was obliterated.
The Colon. — The colon {kuXvu, to impede, dfg h,fig. 139) constitutes almost the whole
of the large intestine. It extends from the caecum to the rectum, and, as we have al-
ready seen, there is no line of demarcation between these different parts. In the first
part of its course it ascends vertically, then becomes transverse, next descends vertical-
ly, and is then curved like the Roman letter S, and becomes continuous with the rectum.
From this long course, and also from its direction and numerous relations, the colon has
been divided into four portions, viz., the ascending or right lumbar colon, the transverse colon,
or arch of the colon, the descending or left lumbar colon, and the iliac colon, or sigmoid flexure.
Each of these parts requires a separate description, at least with regard to its relations.
Let us first point out the general form of the colon.
The colon presents a sacculated appearance throughout, which gives it some resem-
blance to a chemical apparatus, consisting of a long series of aludels. The sacculi of
the colon are arranged in three longitudinal rows, separated by three muscular bands.
Each of these rows presents a succession of enlargements and constrictions, or deep
grooves, placed across the length of the intestine. These enlargements and grooves
are produced by the longitudinal bands, which, bemg much shorter than the intestine,
cause it to be folded inward upon itself
at intervals. It follows, therefore, that
division of these bands by means of a
bistoury, or, rather, their rupture, from
great distension of the gut, should de-
stroy this sacculated appearance, and
such, indeed, is the result of the exper-
iment ; at the same time, the large in-
testine becomes twice or three times
as long as it was before, and forms a
regular cylinder, hke the small intes-
tine. An incontestable proof of the
relation between the cells of the colon
and the muscular bands, is the con-
current absence of both in a great num-
ber of animals. Lastly, the three rows
of sacculi vary much in different sub-
jects, and also in different parts of the
great intestine. The descending colon
and the sigmoid flexure have only two
rows of sacculi, and, consequently, two
intermediate bands. The sacculi al-
most entirely disappear in the sigmoid
flexure.
The Ascending or Right Lumbar Colon
(a, figs. 135, 161). — This portion of the
colon is bounded below by the caecmn,
* [Nevertheless, the structure of the mucouf
membrane in the two situations is very different
(see notes, p. 3T0, 379).]
.THE INTESTINES. 375
and above by the transverse arch, with which it forms a right angle, near the gall-blad-
der. It is more or less firmly held in its place by the peritoneum, which in some sub-
jects merely passes in front of it, and in others forms a fold or lumbar mesocolon. The
ascending and descending colon may be included among the most fixed portions of the
alimentary canal. In front of it are the parietes of the abdomen, from which, excepting
when greatly distended, it is separated by the convolutions of the small intestine. Be-
hind, it is in immediate relation with the quadratus lumborum and the right kidney, no
layer of peritoneum intervening. It is united to these parts externally by loose cellular
tissue. This relation accounts for the bursting of abscesses of the kidney into the colon,
and explains the possibility of reaching the colon in the lumbar region without wound-
ing the peritoneum. On the left side, advantage has been taken of this fact in attempt-
ing to form an artificial anus.
On the inside and on the outside it is in relation with the convolutions of the small intes-
tine ; and on the inside also with the psoas muscle, and with the second portion of the
duodenum.
The Transverse Colon, or Arch of the Colon. — This (<) is the longest portion of the large
intestine ; it extends from the ascending to the descending colon, from the right to the
left hypochondrium, and generally occupies the adjacent borders of the epigastric and
umbilical regions. It is not unfrequently found opposite the umbilicus, and even in the
hypogastrimn. Its right extremity corresponds to the gall-bladder {g), its left is below
the spleen {k). It describes a curve having its convexity directed forward, and its con-
cavity backward ; hence the name, arch of the colon. In some subjects it is two or three
times its ordinary length, and hence it presents various inflections. I have seen its
middle portion descending as low eis the umbilical or hypogastric region, and even reach-
ing the brim of the pelvis ; in other cases it descends parallel to, and on the inner side
of, the ascending colon, and then passes upward again, or it describes curves of different
extent. The arch of the colon is supported by a very remarkable fold of peritoneum,
called the transverse mesocolon, which forms a horizontal septum between the small in-
testine below, and the stomach, the liver, and the spleen above. The extent of this fold,
which is one of the largest of all those formed by the peritoneum, explains the great
freedom of the movements of the transverse colon, which, next to the small intestine,
is the part of the alimentary canal most frequently found in hernia.
Relations. — Above, it has relations with the liver (Z), which generally presents a shght
depression, corresponding to the angle formed by the ascending and transverse colon ;
with the gall-bladder (£), whence the discoloration of the right extremity of the arch
from the bile ; it is not rare to find the gall-bladder opening into the colon ; with the
stomach («), which projects in front of it when distended, but is separated from it by a
considerable interval when empty ; and, lastly, with the lower extremity of the spleen
{k). The two anterior layers of the great omentum, which proceed from the greater
curvature of the stomach, pass over the arch of the colon without adhering to it. I have
seen a large loop of the arch of the colon interposed between the liver and the diaphragm.
Below, the arch of the colon corresponds to the convolutions of the small intestine {fig.
155). In front, it corresponds to the parietes of the abdomen, beneath which it may
sometimes be felt when distended with gas. It is separated from them by the two an-
terior layers of the great omentum. The two posterior layers of the great omentum are
given off from the middle of its anterior border. Behind, it gives attachment to the
transverse mesocolon.
The Descending or Left Lumbar Colon. — The descending colon {d,figs. 155, 161) so close-
ly resembles the ascending portion, both in situation and relations, that we can only re-
fer to what has been already stated. We must observe, however, that it is more deeply
situated above than the ascending colon, and that it is of less size. Advantage has been
taken of its immediate relations behind, with the quadratus lumborum, in the operation
for artificial anus in cases of imperforate rectum. It is preferred, for this purpose, to
the ascending colon, simply from its proximity to the anus.
The Iliac Portion, or Sigmoid Flexure, of the Colon. — The sigmoid flexure of the co-
lon {f,Jlgs. 155, 161) is situated in the left iliac fossa, and is continuous below with the
rectum. The line of demarcation between it and the descending colon is determined by
the commencement of a fold of peritoneum, called the iliac mesocolon, or, rather, by the
change in the direction of the large intestine, as it appears to detach itself from the pa-
rietes of the abdomen, opposite the crest of the ilium. It is continuous with the rectum
at the point where it dips into the pelvis, opposite the left sacro-iliac symphysis. But, as
it often happens that the lower portion, or even the whole of the sigmoid flexure, is con-
tained in the cavity of the pelvis, it may be understood that such a definition is not precise.
It is retained in its place by a very loose fold of peritoneum, called the iliac mesocolon,
and therefore, in some measure, partakes of the mobility of the small intestine. It has
been found in almost all the regions of the abdomen, but especially in the sub-umbilical
zone. It has been seen in the umbilical region, its first curvature reaching even to the
liver. I have met with a case in which the sigmoid flexure extended upward, and the
arch of the colon downward to the umbilicus, so that they came in contact with each oth.
376 SPLANCHNOLOGY.
er ; the large intestine, therefore, corresponded with the whole anterior region of the
abdomen, the sigmoid flexure alone occupying the umbilical, the hypogastric, and the
left iliac region.
Should the following disposition, which I have met with several times, be regarded as
accidental or congenital 1 Commencing from the descending colon, the sigmoid flexure
passed transversely from the left to the right side, on a level with the brim of the pelvis
as far as the right iliac fossa, below the caecum, which it turned upward in one case, and
pushed in front of itself in another ; the sigmoid flexure then described its two curves
either in the right iliac fossa or in the pelvis. These cases, in which the sigmoid flex-
ure of the colon alone is transposed, must be carefully distinguished from general trans-
position of the viscera.
The most peculiar character of the sigmoid flexure is its direction. It passes at first
upward, in an opposite direction to the descending colon, then descends vertically, and
then, curving again, passes to the right or to the left, forward or backward, and becomes
continuous with the rectum (r), (the iliac flexure). These several flexures, however, vai7
exceedingly : I have seen them very shght ; but then the upper or free portion of the
rectum was found decidedly flexuous ; and, indeed, it is difficult to ascertain whether
such flexures belong to the rectum or to the displaced sigmoid flexure. • There can be
no doubt that this double curve of the colon is connected with its uses as a receptacle
for fajcal matters.
The size of the sigmoid flexure varies considerably. In a case of imperforate anus in
an infant, which lived twenty days, it became enormously distended. Retention of the
faeces in the adult seldom causes so proportionally great an accumulation in the sigmoid
flexure : the rectum is almost entirely the seat of the accumulation.
Relations. — The sigmoid flexure corresponds to the abdominal parietes in front. When
empty, its relations with the latter are indirect, in consequence of the interposition of
some convolutions of the small intestine ; when it is distended, they are inmiediate ;
and hence we are recommended to make an artificial anus in the sigmoid flexure of the
colon, in cases where the rectum is imperforate. It is in contact behind with the iliac
fossa, to which it is fiLxed by the mesocolon : hence it can be easily compressed and ex-
plored by the fingers, for the purpose of detecting hardened masses of faeces. In the
rest of its circumference it is in relation with the convolutions of the small intestine.
The Internal Surface of the Colon. — On the internal surface of the colon are seen three
longitudinal ridges, corresponding to the three muscular bands on its external surface ;
three intermediate rows of sacculi, the concavities of which agree exactly with the pro-
tuberances on the external surface ; and, lastly, numerous ridges or incomplete septa,
dividing the cells of each row from one another, and improperly called valves ; they cor-
respond to the grooves or depressions on the external surface. In order to comprehend
the arrangement of the cells and the intervening septa, we must examine the large in-
testine when moderately distended and dried. If the muscular bands have been previ-
ously divided, the cells and septa disappear.
The internal sacculi, as well as the external protuberances, vary much in different in-
dividuals, and even in diflerent parts of the same colon. Thus, there are generally only
two rows in the descending colon and the sigmoid flexure, because there are only two
muscular bands in those parts. Sometimes, indeed, there are no cells in the sigmoid
flexure. Lastly, the internal surface of the large intestine presents some irregular folds,
which are completely effaced by distension.
The Rectum. — The rectum (A i,fig. 139), so called from its direction, which is gener-
ally less flexuous than that of the rest of the intestinal canal, is the last portion of the
large intestine, and, consequently, of the digestive tube. It commences at the base of
the sacrum, and terminates at the anus. It is situated, in the true pelvis, in front of the
sacrum and coccyx {r,fig. 161 ; a o',fig. 181).
We see, then, that the alimentary canal, after having abandoned the vertebral column
in order to describe its numerous convolutions, is situated at its termination in front of
the lower part of that column, just as, at its commencement, it is applied to the upper
part of the same. It is firmly fixed, especially below, where it. is surrounded on all sides
by cellular tissue, and is also bound down by the superior pelvic fascia. This part of it
cannot, therefore, suffer such displacements as occur in hernia ; but, from its functions
as an organ of expulsion, the whole effort of the abdominal inusoles is concentrated upon
it, and it is, therefore, liable to displacements of a different kind, viz., to invagination
and eversion.
Its situation, which is in some degree constant, within a bony cavity, having unyield-
ing walls, and its relations with the pelvic fascia, place it in conditions altogether pecu-
liar to itself; for while the bladder and the uterus, which are also contained in the same
cavity, ascend into the abdomen when they are distended, the rectum, in which the fajces
are accumulated, dilates entirely within the pelvis, and undi^rfoes no change of position.
From this fixed condition of the rectum along the miildle of the pelvic cavity, it also
follows that, in cases where the gut is denuded by destmrtion of the surrounding cellu-
lar tissue, it remains separate from the walls of the pelvis : such is the nature of fistu-
f
THE INTESTINES. 377
lae ; and hence the necessity of cutting the rectum, in order to bring it in contact with
the walls of the pelvis.
Direction. — Particular attention should be paid to the direction of this bowel, as an
anatomical fact from which practicEd inductions of the greatest interest may be derived.
It is not straight, but is curved both in the antero-posterior and lateral directions.
In the antero-posterior direction it follows the curve of the sacrum and coccyx, to which
it is closely applied ; it is, therefore, concave in front and convex behind {see fig. 181).
Opposite the apex of the coccyx it bends slightly backward, so as to terminate about an
inch in front of that bone. By this very remarkable inflection, it is separated from the
ragina in the female, and from the urethra in the male.
T?ie Lateral Inclination. — On the left side of the base of the sacrum, and opposite the
sacro-iliac symphysis, the rectum passes downward, and to the right side, until it reaches
the median line opposite the third piece of the sacrum. It then passes forward, still in
the median line, and forms a slight curve with the preceding portion. It has been fre-
quently said that the lower part of the rectum does not occupy exactly the median hne,
but deviates a little to the right : this is not unfrequently the case at the lower part of
the sacrum, but it always regains its original position before its termination.
There are, however, some important varieties in the curvature described by the rec-
tum. Thus, it is not uncommon to see the upper part of the gut twisted like an italic <S
before reaching the median line ; and in this case, it is difficult to determine whether the
twisted portion belongs to the rectum or to the sigmoid flexure of the colon. In several
of the cases of unnatural position of the sigmoid flexure, which I have already mention-
ed, the rectum commenced on the right side of the base of the sacrum, and passed down-
ward, and towards the left side. In one case, where the sigmoid flexure was in its
natural position, the rectum passed almost transversely to the right side, as far as the
right sacro-iliac symphysis, and then proceeded very obliquely to the left side. The sit-
uation of the upper part of the rectum on the left of the median line has been often
quoted in explanation of the relative frequency of inclinations of the uterus to the right
side, and also of the greater or less amount of difficulty in parturition, according as the
occiput of the foetus is turned towards the right or the left.
Form and Size. — The rectum is cylindrical, not sacculated, and has no bands like those
observed in the other portions of the large intestine. Its external surface is covered
with a uniform layer of well-marked, fasciculated, longitudinal fibres, which give it some
resemblance to the oesophagus. At its commencement, its caliber is somewhat smaller
than that of the sigmoid flexure, but it gradually increases towards the lower end. Im-
mediately before its termination at the contracted orifice, called the anus, the rectum
presents a considerable dilatation, or ampulla, capable of acquiring an enormous size ; so
that, in certain cases of retention of the faeces, it has been found occupying the entire
cavity of the pelvis.
Relations. — Behind, the rectum corresponds with the left sacro-iliac sjmiphysis and the
curve of the sacrum and coccyx ; it is attached to the sacrum above by means of a fold
of peritoneum, called the meso-rectum, and is separated from the sacrum and the sacro-
iliac symphysis by the pyriformis muscle, the sacral plexus of nerves, and the hypogas-
tric vessels. Those portions of the rectum which project laterally beyond the coccyx
are in relation with the levator ani muscles, which form a sort of floor for it.
In front, the rectum is free in its upper portion, but is adherent below ; its relations
vary in the two sexes, and are of the greatest importance in a surgical point of view.
In the male its upper or free portion {o,fig. 181) corresponds to the posterior surface
of the bladder (A), from which it is separated, excepting in cases of retention of urine, or
of considerable dilatation of the rectum by convolutions of the small intestines. Its lower
or adherent portion is in immediate relation, in the middle line, with the inferior fundus
(bas-fond) of the bladder, at the triangular space intercepted between the vesicula; semi-
nales (s) ; on each side, it is separated from the bladder by these vesicles. The extent
to which it is in contact with this part of the bladder varies in different subjects, and ac-
cording as the bladder and rectum are full or empty.
We shall see in another place that the peritoneum {u u) forms a cul-de-sac of variable
depth between them. In some subjects the cul-de-sac extends as far as the prostate, so
that the whole of the inferior fundus of the bladder is covered by it.
In front of the inferior fundus of the bladder the rectum is intimately united to the
prostate {i). In some cases the prostate projects beyond the rectum, on one or both
sides ; in other cases the rectum projects beyond the prostate, on one or other, or both
sides, and receives the gland, as it were, in a groove.
The rectum has also relations with the membranous portion of the urethra (c), but, on
account of its inflection backward, it is separated from it by a triangular space, the base
of which is directed downward and forward, and the apex upward and backward.
The practical inferences to be drawn from these relations are these : that the bladder
projects into the rectum in cases of retention of urine ; that the bladder can be explored
from the rectum, and may be punctured and cut for the extraction of stone ; that the
finger passed into the rectum can assist in the introduction of the catheter, and in ex-
Bb B
378 SPLANCHNOLOGY.
amination of the prostate ; that the rectum must be emptied before performing the lateral
operation for stone ; and, lastly, that the membranous portion of the urethra may be
opened without injuring this bowel.
In the female, the free portion of the rectum corresponds with the broad ligament, the
left ovary and Fallopian tube, the uterus, and the vagina. The peritoneum forms a cul-
de-sac between the vagina and the rectum, analogous to that already described between
the bladder and the rectum in the male, and subject to the same varieties. When the
uterus and the rectum are empty, a certain number of convolutions of the small intestine
are always interposed between the rectum and the vagina ; and, therefore, in lacerations
of the posterior wall of the vagina, the small intestines escape through the wound.
The uterus and vagina are not unfrequently found deviating to the left side, while the
rectum deviates to the right, and then the free portion of the latter corresponds to the
right broad ligament and ovary. Lastly, in retroversion of the uterus, which is so com-
mon, the fundus of that organ rests upon the rectum.
The inferior or adherent portion of the rectum is intimately united to the vagina : hence
vaginal cancer frequently extends into the rectum ; below, on account of its inflection
backward, it is separated from the vagina in the same way as from the urethra in the
male, by a triangular space, the base of which is directed downward, and forms the
perineum of the female.
On the sides, the free portion of the rectum corresponds to the convolutions of the in-
testines ; the adherent portion is surrounded by adipose cellular tissue, which is nowhere
more clearly intended to fill up intermediate spaces ; the absorption or destruction of
this tissue is an important circumstance in diseases of the anus.
The internal surface of the rectum is remarkable for some longitudined folds, which are
obliterated by distension, and somewhat resemble the longitudinal folds of the cesophagus.
These folds, which have been inappropriately termed the columns of the rectum, are in-
tersected by other semicircular folds, also effaced by distension. This internal surface
presents, moreover, a dilatation corresponding to the enlargement seen from without,
immediately above the anus.
Structure of the Large Intestine. — The same number of coats exist in the large as in the
small intestine, but they present certain peculiarities in arrangement, of which some are
common to the whole bowel, while others exist only in particular parts.
The Peritoneal Coat. — The peritoneum does not, in general, form so complete a cover-
ing for the large as for the small intestine. Moreover, it forms a great number of dupli-
catures on the surface of the bowel, which usually contain fat, and are called the fatty
appendices {appendices epiploica). They are not constant, either in number, size, or
length, but are sometimes arranged in regular series. Some of them are so long that
they may form the contents of a hernial sac, or may even occasion strsmgulation, by
forming a ring around the intestines ;' they are seldom entirely absent. They become less-
ened when the gut is distended, and are elongated by its contraction. They are sometimes
loaded with an immense quantity of fat, of which they may be considered reservoirs. They
are found along the whole of the large intestine, including the free portion of the rectum.
The peritoneum often envelops the whole of the caecum ; at other times it does not
cover it behind. Most commonly it forms a fold, or mesentery, for the vermiform ap-
pendix. It only passes in front of the ascending and descending colon, which are al-
ways uncovered behind. It invests the whole of the transverse arch, excepting a trian-
gular space behind corresponding to the transverse mesocolon, and in another triangu-
lar space in front corresponding to the great omentum. It completely surrounds the sig-
moid flexure, excepting in a small space behind, corresponding to the iliac mesocolon.
Lastly, at the upper part of the rectum, it is arranged in a similar manner, and then
merely passes in front of that bowel, the lowest portion of which is entirely devoid of a
peritoneal covering, and is surrounded by a large quantity of adipose tissue.
From the arrangement of the peritoneum upon the large intestine, it follows that the
latter is more favourably circumstanced than the small intestine for assuming a large
size ; and, also, that it may be penetrated in many places without injuring the peritoneum.
The Muscular Coat. — As in the small intestine, this coat consists of a circular and a
longitudinal set of fibres.
The circular fibres form the deep layer, and are arranged as in the small intestine ; the
longitudinal fibres, which constitute the superficial layer, are not disposed equally around
the bowel, but are collected into three bands, which we have already noticed. These
bands have the pearly appearance of ligaments when seen through the peritoneal cover-
ing ;* they are continuous with the longitudinal fibres of the appendix vermiformis. The
anterior is the largest ; it becomes inferior along the arch of the colon, and again ante-
rior upon the descending colon and sigmoid flexure, spreading out upon the latter. Of
the posterior bands, which are narrower, one is external and the other internal ; they
become superior on the arch of the colon, and again posterior upon the descending colon
and sigmoid flexure, upon the latter of which they are often blended into one. I have
* [They are involuntary muscular fibres ; in the lower part of the rectum some transversely striated fibres
are found.]
THE INTESTINES. 379
already said that these bands, being not more than one third, or, at most, one half the
length of the large intestine, occasion its puckering, and arrangement into sacculi and
intervening depressions.
The muscular coat is remarkably modified in the rectum. In the sigmoid flexure the
longitudinal fibres become scattered, and at its termination surround the whole intestine ;
but this arrangement exists more particularly in the rectum, where they present the ap-
pearance of thick fasciculi, forming an uninterrupted covering (r,Jig. 161). The deep or
circular layer of the rectum is much thicker than that of any other part of the alimenta-
ry caucil, excepting the ossophagus ; it may be separated into distinct rings, the lowest
of which is so distinct that it has been described as a particular muscle, under the name
of the sphincter internus. It is arranged in precisely the same way as the corresponding
coat of the oesophagus, but is not so thick : this difference depends upon the uses of the
two canals, the oesophagus being intended to convey the food rapidly downward, while
the rectum is assisted by the abdominal muscles. When the rectum is empty, it contracts
upon itself like the oesophagus, and its walls are in contact.
The fibrous coat of the large intestine offers no peculiar characters.
The mucous coat of the large intestine has no valves : the semilunar crests, or ridges
which separate the cells of the colon, are formed by all the coats. The irregular folds
or wrinkles observed on this membrane are completely effaced by distension. The mu-
cous membrane is not unfrequently protruded through the muscular fibres, so as to form
small sacs having narrow necks, and containing masses of indurated faces. At first
sight such sacs resemble a varix. They are very conmion in the aged, and are probably
the result of habitual constipation.
When examined with the microscope and under water, in the same manner as the
mucous membrane of the small intestine, the inner surface of the large intestine is seen
to have no villi, but we find exactly the same appearance as in the mucous membrane
of the stomach, viz., an alveolar or honeycomb arrangement.* The openings or pores
of this mucous membrane are innumerable ; and, supposing that they assist both in ex-
halation and absorption, it may be conceived with what rapidity these processes must
be carried on in the large intestine. It is also studded with a number of follicles (tan-
quam stellae firmamenti, Peyer), which are depressed and perforated in the centre,* and
in a great number of subjects, especially in the old, have a black colour. These follicles
are never collected into patches, as in the smaU intestine, but are always solitary. They
are often inflamed, though the rest of the membrane is healthy.
It is easy, then, to distinguish the large from the small intestine, simply from the char-
acters of its mucous membrane. The hmit between the two is at the free margin of the
ileo-caecal valve ; aU preceding this has the characters of the mucous lining of the small,
all that comes after, of that of the large intestine.
We find dense patches of follicles in the vermiform appendix, the whole of which is
sometimes Mned with them.
The mucous membrane is more loosely united to the fibrous coat in the rectum than
in any other part of the large intestine. This looseness is most marked at its lower
part, and hence a protrusion of this membrane only may occur, as in the oesophagus ;
and this must be carefully distinguished from prolapsus of the entire rectum. I should
also remark, that the capillary veins are much developed at the lower part of the rectum,
and, when much larger than usual, constitute what are called hemorrhoidal tumours.
Vessels and Nerves. — The arteries of the caecum, the vermiform appendix, the ascend-
ing colon, and the right half of the arch, are supplied by the superior mesenteric ; the
rest of the colon and the rectum receive blood from the inferior mesenteric. The rec-
tum also receives a branch from the internal iliac, called the middle hemorrhoidal, and
a branch from the internal pudic, called the inferior hemorrhoidal. Some small ramifi-
cations are also furnished to the great intestine by the gastro-epiploic, splenic, capsular,
and spermatic arteries. The rectum exceeds all other parts of the large intestine in the
number and size of its arteries, and, therefore, operations upon the lower part of that
bowel are often followed by serious hemorrhage.
The veins, which bear the same name and follow the same course as the arteries, concur
in the formation of the great and small mesenteric or mesaraic veins, which terminate
in the vena portae. p. jgg
The lympliatic vessels are very numerous, and terminate in the
* [In the stomach this character is due to the presence of the alveoli, in the bot-
tom of which the perpendicular tubuli open. In the large intestine, however,
there are no pits ; but the alveolar appearance is produced by the openings of nu-
merous tubes, analogous in form and direction to the tubuli of the stomach, and to
the crypts of Lieburkuhn in the small intestine.
The follicles of the large intestine diifer from the solitary glands of the jejunum
and ileum, in being always open. Each follicle is much dilated below, but has a
narrow oriiice. lu Jig. 162, the upper drawing represents a vertical section of a
follicle (magnified), surrounded by the perpendicular tubes ; the lower is a magni-
fied superficial view, showing the depression and opening in the centre, and the _=__
orifices of the surrounding tubes. Magnified.
The epithelium of this mucous membrane is cylindrical or columnar.] r- ■■
380
SPLANCHNOLOGY.
glands situated along the attached border of the intestine ; the large intestine is also
possessed of lacteals, but they are less evident than in the small intestine.
The nerves are derived from the solar plexus, and form plexuses along the arteries ;
they all belong to the ganglionic system. The rectum alone receives additional nerves
from the cerebro-spinal system, viz., from the hypogastric and sacral plexuses. The
presence of these two sets of nerves has reference to the functions of the bowel, which
are partly involuntary and partly subject to the influence of the will.
The Anus. — The word anus, borrowed from the Latin, signifies the lower orifice of the
alimentary canal (the anal orifice) ; it is a narrow but dilatable opening, through which
the faeces are expelled.
It is situated in the median line, about an inch in front of the point of the coccyx, at
the back part of the perineum, between the tuberosities of the ischium, and at the bot-
tom of the fissure between the buttocks. The skin around the borders of this orifice,
wfiich is constantly closed, contains a great number of sebaceous follicles, and is cover-
ed with hair in the male ; it passes deeply into the orifice, to become continuous with
the mucous membrane, and presents a great number of radiated folds, which are effaced
during dilatation. The point at which it becomes continuous with the mucous mem-
brane is deserving of notice : it is within the rectum, at the distance of some lines from
the anus properly so called, and is marked by a waved line, which forms a series of
arches or festoons, having their concavities directed upward. Sometimes there are
small pouches in the situation of these arches, opening upward. From the angles at
which the arches unite, some mucous folds proceed, and small foreign bodies, detached
from the faeces, are often retained in the culs-de-sac, and become the causes of fistulae.
Structure of the Anus. — The anus, intended as it is to prevent the revolting inconve-
nience of a constant and involuntary escape of the faeces, consists essentially of a sphinc-
ter muscle, which is antagonized, not only by the proper dilator, viz., the levator ani, with
which I connect the ischio-coccygeus, but also by the diaphragm and the abdominal mus-
cles. The absence of a sphincter is the great evil of every artificial anus. A fourth
muscle, the transversalis perinei, must also be included among the muscles of the anus.
The skin and the mucous membrane which cover these muscles are remarkable for the
great development of the erectile tissue, which forms the basis of all tegumentary mem-
branes. The terminal branches of the hemorrhoidal arteries are extended upon this
portion of the skin and mucous membrane. From this erectile, and, therefore, vascular
tissue, arise a great number of winding, twisted, and plexiform veins, which form the
lowest roots of the vena portae. A considerable number of cerebro-spinal and ganglionic
nerves, derived from the sacral plexus and the hypogastric nervous centre, are distribu-
ted around this orifice. Lastly, there are mucous crypts, or, rather, glands, a vestige
of the highly-developed glandular organ found in some animals.
Muscles of the Anus. — We now proceed to the description of the muscles of the anus,
which are six in number, viz., two single muscles, the sphincter and the transversalis pe-
rinei ; and two pairs, the levatores ani and the ischio-coccygei, which, in fact, form but
one muscle. The sphincter intcmus of authors is nothing more than the last ring of the
circular fibres of the rectiun.
The Sphincter Ani.
Dissection. — Remove carefully the corrugated skin which covers the anal region ; pro-
long the dissection backward as far as the coccyx, and forward to the scrotum in the
male, and the vulva in the female. It is not sufficient to expose the lower ring of the
sphincter ; the adipose tissue, which surrounds the lower part of the rectum, should be
removed on each side. It is well to stuff the lower part of the rectum preparatory to
this dissection, as well as that of the muscles of the perineum.
The sphincter ani {a, fig. 163) is an orbicular muscle, situated around the lower end of
j^^. 163. the rectum. It is not a simple ring, but
a muscular zone of nearly an inch in
width. Its form is an ellipse, much elon-
gated from before backward, and tenni-
nating in a point in front and behind.
The fibres which constitute the lower-
most ring of the muscle arise from the
sub-cutaneous cellular tissue in front of
the coccyx, in the same manner as other
cutaneous muscles ; those which fonn
the upper rings arise from a sort of
fibrous tissue given off from the point
of the coccyx. From these points the
fleshy fibres proceed forward, and fonn
a semi-ellipse on each side, composed
of pa'rllel and superimposed muscular
rings, which terminate in front of the anus in the folldwing manner : The lower rings
THE INTESTINES. 381
in the sub-cutaneous cellular tissue, the upper rings in the sort of fibrous raph^, which
gives origin to the bulbo-cavemosus.
Relations. — The internal surface of the sphincter embraces the lower part of the rec-
tum, the lowest circular fibres of which are seen within the sphincter, and are distin-
guished from it by their paleness. They constitute the internal sphincter. Its external
surface is in relation with the adipose tissue of the pelvis. Its upper border is continu-
ous with the antero-posterior fibres of the levaotr ani ; so that it is very difficult to es-
tablish the limit between them.
Its inferior border projects a little below the lowest annular fibres of the rectum, and
only adheres to the skin by loose cellular tissue, which is continuous with the dartos.
Action. — It is a constrictor of the anus. The contraction of the body of the muscle
closes the lower part of the rectum ; the constriction produced by the inferior ring oc-
curs below that bowel.
The Transversus Perinei.
Dissection. — Remove with care the sub-cutaneous cellular tissue in front and upon the
sides of the anus.
The transversus perinei (b) is situated almost transversely in front of the anus. It
arises from the internal lip of the tuberosity of the ischium, immediately above the ischio-
cavemosus {erector penis), by a broad and thin tendon, which is soon succeeded by fleshy
fibres. These pass inward and a little forward, on to the anterior surface of the rectum,
where they are usually described as becoming blended with those of the opposite side
in a fibrous raphe, common both to the transversi, the sphincter, and the bulbo-cavernosi
{acceleratores urinoe). This does not appear to me to be the exact termination. I have
seen this muscle evidently continuous with that of the opposite side, after having trav-
ersed the anterior extremity of the sphincter. According to this, the two transversi
would constitute a single muscle, forming a half ring, the concavity of which, being di-
rected backward, would embrace the anterior part of the rectum, an arrangement well
calculated to assist in expulsion of the faeces.
Relations. — This muscle is placed at the boundary between the anal and perineal re-
gions. It forms the posterior side of a triangle, of which the outer side is formed by
the ischio-cavernosus (c), and the inner by the bulbo-cavemosus (d). It is sub-cutaneous,
excepting in the median line, and is in relation above with the levator ani.
Action. — It tends to compress and force the anterior against the posterior surface of
the rectum, which we shall see is pushed forward by the levator ani. It therefore as-
sists powerfully in defsDcation.
The Ischio-coccygeus and Levator Ani
Dissection. — These muscles must be studied both from the perineum and from the in-
terior of the pelvis. In the perineum : remove the adipose tissue, which occupies the
interval between the rectum and the obturator internus ; in order to expose the whole
of the ischio-coccygeus, cut the lower edge of the glutaeus maximus, and carefully divide
the great and small sacro-sciatic ligaments. In the pelvis : remove the peritoneum li-
ning the sides of that cavity ; remove the superior pelvic fascia which covers these mus-
cles, and trace them very carefully backward and upon the sides of the rectum, the blad-
der, and the prostate gland.
The ischio-coccygeus and the levator ani constitute the floor of the pelvis. They form
an uninterrupted muscular plane, from the lower border of the pyriformis muscle to the
arch of the pubes. The ischio-coccygeus includes that portion which is inserted into the
sides of the coccyx: the remainder is the levator ani.
The Ischio-coccygeus, or Coccygeus.
This is a flat, triangular, or, rather, a radiated muscle (o), situated at the lower part
of the pelvis, in front of the sacro-sciatic ligaments. It arises from the sides and sum-
mit of the spine of the ischium, from the anterior surface of the lesser sacro-sciatic lig-
ament, and often from the posterior part of the pelvic feiscia ; it passes in a radiated
manner to the border of the coccyx and the lower part of the border of the sacrum. All
these attachments are eflfected by aponeurotic fibres, to which the fleshy fibres succeed.
In this respect its structure has considerable analogy with that of the intercostal mus-
cles, the tendinous portion exceeding the muscular.
Relations. — Its upper surface {o,fig. Ill) is slightly concave, and corresponds to the
rectum ; its Zoicer surface {fig. 163) is slightly convex, and is in relation with the sacro-
sciatic ligaments and the glutaeus maximus ; its posterior margin is applied to the lower
border of the pyriformis ; its anterior margin is continuous, without any line of demar
cation, with the posterior margin of the levator ani (n), from which muscle it can be dis-
tinguished merely by its tendinous structure.
Action. — It assists in forming the floor of the pelvis. It tends to draw the coccyx to
its own side : when the muscles of both sides act together, the coccyx is fixed, and can-
not be thrown backward. It acts, therefore, in defalcation. The name levator coccygis,
which was given to it by Morgagni, is altogether inapolicable.
SS2 SPLANCHNOLOGY.
The Levator Ani. ' "''*•'
This muscle («), so called from one of its chief uses, is situated in the cavity of the
pelvis, and with its fellow forms a sort of muscular floor, which, in many respects, re-
sembles that formed by the diaphragm. It is thin, curved, and quadrilateral, narrow in
front, and broad behind.
It arises, by its fixed or upper attachments, in front, from the pubis, at the side of, and
sometimes even from the symphysis ; behind, from the anterior border of the spine of the
ischium, and in the interval between these extreme points from the upper part of the ob-
turator foramen, and from the brim of the pelvis.
Its movable attachments are to the side of the prostate, the bladder, and the rectum, to
the point of the coccyx, and to the fibrous raphe extending from that point to the sphinc-
ter. The fibres arising from the symphysis pubis are concealed by the pubio-prostatic
ligament ;* they are few in number, short, and directed inward, backward, and down-
ward, to form a bundle (the prostatic), which was described by Santorini as the levator
prostatcB, and by Winslow as le prostatique supirieur. The fibres arising from the spine
of the ischium are blended at their origin with those of the coccygeus, and pass trans-
versely inward to the point of the coccyx. The origins from the upper pai-t of the obtu-
rator foramen and from the brim of the pelvis take place by means of the pelvic apo-
neurosis, which divides and receives the muscle between its two layers (i. e., the supe-
rior pelvic and the obturator fasciae). These fibres, the hindermost of which are the
longest, all pass inward, describe a curve having its concavity directed upward, and are
divided into the vesical, anal, and pnz-coccygeal. The vesical fibres pass upon the sides
of the inferior fundus (bos-fond) of the bladder. I have never seen them terminate on
the vesiculae seminales. The anal fibres having reached the sides of the rectum, above
the sphincter, pass backward, and meet behind the bowel. They constitute a half ring
on each side, prolonging the sphincter upward, without any distinct line of demarcation.
The pra-coccygeal fibres are directed backward, and form a thick fleshy layer, occupying
the interval between the coccyx and the sphincter, and completing the lower wall or floor
of the pelvis. In the female there are also vaginal fibres.
Relations. — Its upper or internal surface is covered by the superior pelvic fascia, which
separates it from the peritoneum and the organs contained in the pelvis. The obturator
fascia intervenes between its lower or external surface and the internal obturator mus-
cle, from which it is separated below by a large triangular space, narrow above and broad
below, and filled with adipose tissue. Its posterior part is in relation with the glutaeus.
Action. — It serves as a muscular floor for the pelvis. It raises the prostate, the infe-
rior fundus of the bladder and the anus, and counteracts the effect of the diaphragm and
abdominal muscles during violent exertions. It assists powerfully in the expulsion of
the urine, the seminal fluid, and the faeces.
As the largest portion of the muscle occupies the sides and the back of the rectum, its
especial use is to expel the contents of that bowel : this is effected by the pree-coccygeal
fibres of both muscles elevating the rectum, and by their anal fibres drawing it forward
and upward, and compressing it on the sides.
Functions of the Large Intestine. — In the large intestine, the alimentary substances ac-
quire the odour and all the other characters of the faeces ; any remaining nutritious mat-
ter or chyle which they may contain is absorbed, and they become hardened and mould-
ed in the cells of the colon. Absorption is sufficiently active in the large intestine to
enable life to be supported for a considerable period by means of nutritive enemata, in
persons who cannot receive food into the stomach. The large intestine acts also as a
reservoir ; its long course, its curvatures, and its easily yielding character, enable it to
contain a great quantity of matter, and prevent the inconvenience of constant defaecation.
The appendix vermiformis has no use in man ; it is merely the trace of a largely-de-
veloped intestine in herbivorous animals.
The rectum is the final reservoir, and one of the agents in the expulsion of the faeces,
the presence of which gives rise to a sensation that informs us of the necessity for evac-
uating them. The sphincter, in general, opposes this evacuation, until it is determined
upon by the will. The expulsion is effected by the action of the rectum, assisted by the
diaphragm and the abdominal muscles.
Development of the Intestinal Canal.
The development of the intestinal canal offers two subjects for consideration, viz., the
relations existing between it and that portion of the foetal membranes called the vesicula
umbilicalis; and the development of the canal itself, independently of that vesicle.
In reference to the first point, the anatomy of the human foetus is still involved in much
obscurity, authorities being divided in opinion on the subject. Without entering here
into a discussion which belongs to a higher department of anatomy, I would observe, that
* [/. e., by the anterior folds of the Teeto-vesical fascia, from which the fibres in question partly arise, and
by which they are separated from the levator ani : the posterior layer of the triangular ligament is in relation
■with them in front.]
THE INTESTINES.
the principal arguments adduced by those who admit the communication between the
intestinal canal and the vesicula umbilicalis are drawn from analogy, and especially from
what occurs in oviparous animals, whose viteUine membrane is regarded as analogous
to the umbihcal vesicle, and in which the most evident communication exists at all sta-
ges of foetal existence.
I would observe, also, that these same anatomists are not agreed respecting the point
at which this communication occurs. According to Oken, it is at the junction of the
small with the large intestine :* according to Meckel, it is at the lower part of the small
intestine, and the diverticula so frequently observed in this place are vestiges of the ca-
nal of communication. The last-named anatomist, after having discussed all the argu-
ments on either side of the question, concludes thus : "I think, then, that we must at
present admit a continuity of substance between the umbilical vesicle and the intestinal
canal, without pretending to decide whether the cavities of these two organs open into
each other" {Manual d'Anatomie, torn, iii., p. 416, trad, par MM. jourdan et Breschet;
But the communication of the cavities is evidently the entire question.
The arguments of those who deny the existence of a communication in the human foetus
and mammalia are founded upon direct observation. I must say, with Emmert, Cuvier,
and others, that I have never detected this communication ; and though I am far from
denying it altogether, yet I consider that facts are still wanting to prove its existence.!
The development of the intestinal canal itself presents, besides some questions yet un-
determined, certain positive facts, concerning which there can be no dispute. One of
the undetermined questions relates to the mode in which the intestine is formed. Is the
digestive tube originally an oblong vesicle, which becomes elongated, at the same time,
at both its cephaUc and its coccygeal extremities, both being at first imperforate, but af-
terward opening so as to form the mouth and anus ] Does it at first resemble a groove
open in front, as Wolf has shown to be the case in birds ; or is it developed from two
lateral halves, subsequently united together, according to the opinion of M. SerresT Is
the intestinal caned formed from one, or from several centres of development 1 Is it de-
veloped from several pieces, which afterward meet each other, so to speak 1 and are any
grounds for this opinion afforded by the absence of different portions of the canal in
acephalous monsters, or the occasional existence of septa in different parts of its extent ]
I think not.
Upon the whole, these microscopical investigations into the first traces of the devel-
opment of organs are still involved in great obscurity ; and I must say that, whenever I
have been able to discern the intestinal canal, it has appeared to me to form a complete
cylinder, t Another question, which yet remains undetermined, relates to the situation
of the intestine in the early periods of intra-uterine existence. It is at first situated, as
some authors believe, in front of the vertebral column ; or, rather, as others imagine, in
that portion of the cord which is next the umbilicus.
Embryologists agree in stating that, in the earliest periods of its development, the in-
testinal canal is not contained in the abdominal cavity, but only its two extremities ; all
the intermediate part, i. e., almost the whole of the canal, is situated within the umbili-
cal cord, which at that time is very considerably enlarged. The whole intestinal canal is
not included in the cavity of the abdomen until towards the middle of the third month.
This fact is quoted in explanation of congenital umbilical hernia, which would be con-
sidered merely an arrest of development. I must here remark, that this situation of the
intestines, in a cavity formed within the umbiUcal cord, does not seem to me to have
been clearly established ; that there are a great number of cases where no such arrange-
ment exists ; that in other cases there is only a loop of the intestine in the substance of
the cord ; and, lastly, that the cases in which such an arrangement has been observed,
if not examples of actual disease, may at least be regarded as instances in which the de-
velopment of the anterior wall of the abdomen had been retarded.<J
Dimensions of the Intestinal Canal. — The earlier the period of development, the shorter
and narrower is the intestinal canal. Its length at first appears to correspond to that of
the vertebral column, a relation which is natural and permanent in a great number of the
lower animals. The canal soon becomes flexuous, and its windings become more nu-
merous in proportion as it increases in length. From the third to the fourth month, its
curves are analogous to those which it subsequently describes : at the sixth month, the
due proportion between the different parts of the canal is established. At the earlier
periods, the small intestine has a much greater caliber in proportion to the large intes-
tine than it afterward presents ; and, on the other hand, the large intestine is relatively
longer than at subsequent periods.
The division into the large and the small intestines does not exist at first. There is
* The Termiform appendix and the caecum are the remains of this communication, according to Oken.
t [The communication has been distinctly seen and described by Dr. Allen Thomson. — (Edin. Med. and
Surg. Journ., cxl., p. 132.)]
} [In the ovum, No. II., described by Dr. A. Thomson {loc. cit.), the future alimentary canal has the forn
of a groove.]
If [The presence of a portion of the intestinal canal within the umbilical cord, at some period of development
is constant not only in man, but in several quadrupeds, and cannot be merely accidental.]
SPLANCHNOLOGY.
no ileo-caecal valve, no caecum, and no appendix vermiformis ; but these three means of
distinction appear simultaneously from the second to the third month.* The caecum and
the vermiform appendix are not distinct from each other, but present the appearance of
a sort of funnel. The appendix, though at first small, is gradually developed, and be-
comes proportionally greater than it is afterward ; its caliber is nearly one half that of
the small intestine. If it be not quite correct to say, with Hallcr, that the caecum does
not exist in the foetus, yet it must be admitted that, at this period of existence, it is no-
thing more than the expanded base of the vermiform appendix ; and the development
which it acquires after birth may, to a certain degree, be regarded as the mechanical ef
feet of the weight of the faecal matters in dilating its cells. The anterior cells of the
ceecum, on account of its vertical position, undergo a relatively greater amount of dilata-
tion ; and from this the vermiform appendix, which corresponded at first to the centre
of the lower end of the caecum, is turned backward, inward, and to the left side, towards
the ileum. The caecum and the appendix do not occupy the right iliac fossa until the
fourth or fifth month ; before that time they are situated in the neighbourhood of the um-
bilicus. For the first four or five months of intra-uterine life, the large intestine is not
sacculated ; so that its external surface is exactly similar to that of the small intestine,
the only means of distinguishing one from the other being the situation of the vermiform
appendix. About the fifth month, according to Morgagni, the three longitudinal depres-
sions, and the transverse folds or depressions and intermediate protuberances, make
their appearance simultaneously. These characters are first observed in the transverse
arch of the colon.
The valvulae conniventes of the small intestine do not appear until about the seventh
month, and they are very slightly developed at birth. It is not uninteresting to remark,
that the condition of the foetus, in this respect, resembles that of animals, which never
have valvulae conniventes. The villi, however, can be observed as early as the third
month. Meckel considers that they are developed from folds of the mucous membrane,
the surfaces of which become notched. At the same period, according to that author,
villi are very apparent in the large intestine ; but, after the seventh month, they diminish
in number and size, while those of the small intestine remain, even if they do not increase.
At first it is impossible to distinguish the several coats of the intestine ; the serous and
the mucous membrane can alone be recognised. The intestine is perfectly transparent.
The great omentum first appears during the third month, along the convex edge of the
stomach, like a small and very thin border. Fat is never found within it before birth ;
nor are the appendices epiploicae developed until after that event.
At birth, the intestinal canal presents the same characters as it afterward possesses.
The small intestine is already provided with rudimentary valvulae conniventes, with well-
marked villi, and with very evident solitary and agminated glands. The large intestine,
which is much developed, is distended with meconium ; the caecum is shorter than it
afterward becomes, the vermiform appendix is larger, and the ileo-caecal valve has the
same appearance as in the adult. The mucous membrane of the large intestine is al-
ready characterized by its solitary follicles and alveolar appearance.
In the large intestine of the foetus, we find, instead of faecal matter, a thick, viscid in-
odorous, and dark-green substance, which fills the bowel more or less completely. This
is the meconium, so called from the Greek word /i^kuv, a poppy, because it bears some
resemblance in colour and consistence to the juice of that plant. Its quantity increases
towards the period of birth. The time at which it first appears has not been ascertained :
I have found it in foetuses of four or four and a half months, but then it only occupied the
rectum. From the seventh to the ninth month it is accumulated in the sigmoid flexure,
and diminishes in quantity towards the ileo-caecal valve. The vermiform appendix is
not unfrequently found distended with this matter. The small intestine also contains
a mucous substance ; but it is less abundant and less viscid, sometimes colourless, and
sometimes yellowish or greenish.
The changes which take place in the intestinal canal after birth, affecting its caliber,
its situation, and its length, appear to me to depend upon its being more or less distended
with gas and faecal matters, and on its being displaced in consequence of adhesions, in-
crease of size, or displacement of other organs. I have proved that in females who have
had children, the intestines present more varieties in situation than in males. We may
add, that these differences in position are much more frequently observed in the large
than in the small intestine.
APPENDAGES OF THE ALIMENTARY CANAL.
The Liver and its Excretory Apparatus. — The Pancreas. — The Spleen.
The appendages of the sub-diaphragmatic portion of the alimentary canal are the liver
and pancreas, two glandular organs which pour their secretions into the duodenum, and
the spleen, which may be regarded as an appendage of the liver.
* Haller, who, in this and many other passages, seems to have foreseen the law of unity of organization,
says, " Eadem primordialis hominis fere fabrica est quae quadrupedum." — (Lib. xxiv., D. 116.)
. THE LIVER.
•»i>j'> -A ■ ■ . . The Livee.
The liver {I I', figs. 155, 161) is a glandular organ, intended for the secretion of bile.
Moreover, it is to this organ that the blood of the abdominal venous system is carried in
the adult, and that of two systems of veins in the foetus.
It is situated near the duodenum, i. e., the portion of the intestinal canal into which the
bile is poured ; it occupies the whole of the right hjT)ochondrium, advances into the epi-
gastrium, and even slightly into the left hypochondrium. It is protected by the seven or
eight lower ribs on the right side, which defend it from external violence ; and it is separ-
ated from the thoracic organs by the diaphragm. It is supported by folds of the peri-
toneum connecting it with the diaphragm, and regarded as suspensory ligaments ; by
the stomach and intestines, which form a sort of elastic cushion for it ; and by the vena
cava, which is intimately adherent to it. These me^ns of support and attachment allow
of slight movements to and fro, and even of certain changes of position, not amounting
to displacement. Thus, it is depressed during inspiration, and projects a little below the
edges of the costdi cartilages ; it is raised during expiration ; it sinks slightly downward
during the erect posture, and backward, or in the direction in which its own weight
would drag it, according to the way in which the body lies during the horizontal posi-
tion ; it is pushed upward by tumours in the abdomen, and dovraward by effusions in the
chest. The disturbed sleep to which many individuals are subject when lying upon the
left side, is attributed to the pressure of the liver upon the stomach ; and to the dragging
of the liver upon the diaphragm has been eiscribed the sensation of hunger, as well as
the relief of that feeling produced by tying something tight around the abdomen. These
notions are, however, purely hypothetical ; and generally, in solving such questions, the
exact state of fulness of the abdomen, and of the mutual action and reaction of the ab-
dominal parietes and viscera, has not been sufficiently taken into account. True dis-
Dlacements of the liver are very rare, and hepatocele (hernia of the liver) is the result of
an imperfect development of the walls of the abdomen.
Size. — The liver is the largest and heaviest of all the organs of the body ; and, indeed,
in the human subject, it exceeds in weight and in size all the other glands together. It
is not true, as the ancients declared, that the liver is larger in man than in any other
animal. But the opinion maintained by many naturalists, that there is, in the animal
series, an inverse ratio between the size of the liver and the development of the respira-
tory organs, so that this organ is much larger in reptiles and fishes, whose respiration is
slight, than in birds and mammalia, which respire vigorously, is not altogether devoid of
loundation.
The liver weighs from three to four pounds, thus forming one thirty-sixth of the whole
weight of the body according to Bartholin, and one twenty-fifth according to others. Its
longest diameter, the transverse, is from ten to twelve inches ; its antero-posterior di-
ameter is from six to seven inches ; and its vertical diameter in the thickest part, from
four to five. These dimensions are extremely variable, but are always inversely pro-
portional to each other. In a great many livers the transverse diameter is the shorter,
and the vertical the longer.
Few organs present a greater variation in size and form in different individuals than
the liver. I am certain that the relative proportion between different livers may be as
much as one to three, in the absence of all disease. It is pretty generally believed that
a large liver occasions such modifications in the whole system as will give rise to a par-
ticular temperament. But it may be doubted whether there is any proof that the bilious
and melancholic temperaments are specially accompanied by a large liver, or that hypo-
chondriasis in particular is the result of a predominance of that organ.* AnatomicEil
evidence affords but little support to such ideas, which are rather the result of precon-
ceived notions respecting the functions of the liver and the influence of the bile, than the
fruit of positive observations.
It varies much in size according to the state of its circulation ; when its vessels, and
especially the ramifications of the vena portae, are empty, the tissue of the liver shrinks,
and its surface becomes, as it were, wrinkled. When, on the other hand, the hepatic
vessels are injected, the organ is in a state of turgescence. I have often been struck
with the increase in the size of the liver produced by an injection pushed forcibly and
continuously into the vena portffi.
The size of the liver, as influenced by age and disease, deserves particular attention.
I shall point out the influence of age under the head of development. We shall then
see that the liver is largest during intra-uterine life, and that it is proportionally larger
at periods nearer to that of conception : hence it arises that the greatest relative size
of the liver is coincident with the least amount of biliary secretion ; and we may there-
fore conclude that this organ has some other use besides that of secreting bile.
When diseased, the liver has been found to weigh from thirty to forty pounds ; but
the enormous size in these cases is almost invariably owing to the development of acci-
* Hippocrates sometimes gave the name of hypochondria to the liver, and hence, no doubt, the term hypo-
chondriac.
Ccc
386 SPLANCHNOLOGY.
dental tissues. Some cases, however, have been recorded of simple hypertrophe of the
liver without any organic disease, in which the size acquired was prodigious. In oppo-
sition to this, we must notice the state of atrophy* in which the liver is shrivelled, and
not more than a third, fourth, or even a sixth of the natural size. In one subject, in
which the umbihcal vein remained pervious, and the sub-cutaneous abdominal veins were
dilated and varicose, the liver weighed only about half a pound.
The specific gravity of the liver is, to that of water, as fifteen to ten
Figure. — The liver is a single and asymmetrictd organ, of such an irregular form as to
defy description. We shall compare it, with Glisson, to a segment of an ovoid, cut ob-
liquely lengthwise, thick at its right extremity, and progressively diminishing towards
the left, which terminates in a tongue. Its shape is represented by the sort of mould
formed by the right half of the diaphragm, and bounded below by an oblique plane di-
rected upward and to the left side {fig. 161).
No organ is more exactly moulded upon the surrounding parts, nor undergoes changes
in form with greater impunity, either from external pressure or from that exercised upon
it by other viscera ; it may even be said to be, as it were, ductile or malleable under the
influence of a slowly-exerted pressure. The injurious effects of very tight lacing are
chiefly experienced by the liver. A circular constriction and a fibrous thickening of this
organ opposite the base of the thorax sometimes afford evidence of this compression ;
its transverse and antero-posterior diameters become diminished, and its vertical diam-
eter is increased ; it projects more or less below the base of the thorax, descends as low
down as the right iliac fossa, and may even touch the brim of the pelvis without any
structural lesion. In these cases, its upper surface becomes anterior, and its lower sur-
face posterior.
There are but few female subjects without some deformity of the liver, and, therefore,
the type of the organ must be sought for in the male.t No practical conclusions, then,
can be derived from the shape of the liver ; and I am almost inclined to agree with Ve-
salius, in saying that it has no determinate form, but accommodates itself to the sur-
rounding parts. In a few rare exceptions, we find the human liver divided into lobules
by deep fissures, as it is in a great number of animals. The errors which have for a
long time existed upon this subject, even since the time of Vesalius, arise from a blind
respect for the assertions of older anatomists, who, having dissected few human sub-
jects, were accustomed to confound, in their descriptions, the structure found in animals
with that observed in man. ^
The liver presents for consideration a superior or convex surface, an inferior or plane
surface, an anterior and a posterior border, a base, and a summit.
The superior surface (pars gibba) is convex and smooth, and in contact with the dia-
phragm, which is moulded exactly upon it : this convexity is not regular, but much
greater on the right than on the left side, where the surface is almost flat {fig. 161).
This surface is divided into two unequal parts {I I') by a falciform fold of peritoneum (1
to 2), called the falciform or suspensory ligament of the liver, which seems to be principal-
ly intended to protect the umbilical vein, and which is never put upon the stretch during
the natural state of fulness of the abdomen. One or more fissures are not unfrequently
found running from before backward upon the upper surface of the liver ; and I am sure
that these fissures, in explanation of which Glisson and Fernel have advanced some
very singular opinions, are due, at least in some cases, to the pressure of projecting folds
of the diaphragm. The falciform ligament forms the line of separation between the
right {I') and the left (/) lobes, a purely nominal distinction, which results from the old
habit of admitting several lobes in the liver, and is retained here only for the sake of
conformity to custom. The portion of the liver situated to the left of the suspensory
ligament is always smaller than that upon the right.
The convex surface of the liver is bounded behind by the reflection of the peritoneum
upon it from the diaphragm. It is separated by the diaphragm from the heait, the ribs,
and the base of the right lung. Its relations with the base of the right lung are very ex-
tensive : the base of the lung and the convexity of the liver are exactly fitted to each
other ; this may be shown by making a vertical section from before backward, upon the
right side of the trunk, when the liver will be seen to be received, as it were, into a
deep excavation in the base of the lung. This relation explains why abscesses and
cysts of the liver may burst into the lung, and why abscesses of the lung point towards
the liver ; why the liver may increase in size in the direction of the thorax, and push up
the lung as far as the third or even the second rib ; and why effusions into the pleura
may force the liver downward in the abdomen ; and also why peritonitis, confined to the
region of the liver, is sometimes mistaken for pleurisy at the base of the thorax. The
relations of the liver with the seven or eight inferior ribs account for the impressions
which are often seen upon its surface ; and also explain the facts, that violent blows
upon the ribs may bruise this viscus ; that pointed instruments thrust into the intercos-
* We cannot admit the proposition of Soemmering, " Quo sanior homo, eo minus ejus hepar est."
+ Soemmering, without giving any reason, says, " In sexH masculo magit, minus in femineo coatis istit ter.
. turn latet."—(Corpor. Hum. Fabric, t. vi., p. 163.)
m
THE LIVER.
^ spaces on the right side may wound it ; and that abscesses of the liver point and
open between the ribs.
The relations of the convex surface of the liver Avith the abdominal parietes, which
are so extensive in the new-bom infant, and stiU more so in the foetus, are generally
confined in the adult to a variable extent of the epigastrium, and to a small space below
the edges of the ribs on the right side {fig. 155). In certain conformations of the liver
(almost always acquired), and in such diseases as are attended with an increased size
of the organ, these relations become much more extended; and, even in the absence of
any disease, the liver is not unfrequently found to extend into the neighbourhood of the
umbihcus, or even into the right iliac region. In the erect posture, the liver has a ten-
dency to project below the ribs ; and, therefore, the sitting posture, with the upper part
of the body inclining forward, and resting upon some object, is the most favourable one
for exploring this organ.* It is by no means rare to meet with accidental adhesions
between the liver and the diaphragm, consisting either of cellular filaments in the form
of bands, or of cellular tissue of a greater or less density.
The inferior or plane surface {pars sima, 1 1, fig. 154 and fig. 164). This is much more
complfeated than the upper surface, and upon it the hepatic vessels enter and make their
exit from the liver. Certain eminences and depressions, or fissures of variable depth,
are met with here, which have led to the division of the liver into several lobes ; but
that kind of division, which in animals appears to enable the organ to adapt itself to the
form of the viscera of the abdomen, and has probably some relation with the conforma-
tion of the heart, cannot be said to exist in man.t This lower surface is directed down-
ward and backward, and sometimes directly backward : it presents for our consideration,
in the first place, an antero-posterior fissure, or fissure of the umbilical vein, called also the
Fig. 16i.
longitudinal or horizontal fissure
(uh,fig. 164), which extends from
the anterior to the posterior bor-
der of the liver, and is divided by
the transverse fissure {dp), meet-
ing it at a right angle, into two
halves, one anterior, the other
posterior. The anterior half lodg-
es the umbilical vein in the foe-
tus,t or the fibrous cord {u), to
which it is reduced in the adult :
the posterior half lodges the duc-
tus venosus in the fcetus, or the
fibrous band {v), by which it is re-
placed after birth. The anterior
half of the longitudinal fissure is
much deeper than the posterior,
and is often converted into a com-
plete canal by a sort of bridge
formed by a prolongation of the substance of the liver : when incomplete, this bridge is
always situated near the transverse fissure : it often consists of a band of fibrous tissue.
Even when quite complete, it invariably presents a notch near the anterior border of the
liver. ^ The posterior half of the longitudinal fissure inclines more or less obliquely to
the left of the lobulus Spigelii (3), gives attachment, like the transverse fissure, to the gas-
tro-hepatic omentum, and communicates with the fissure for the vena cava superior (c),
behind the lobulus Spigelii.
The existence of this fissure has been the chief cause of the division of the liver into
the right or great lobe (1), and the left lobe (2), also termed the middle-sized lobe by those
anatomists who admit as a third lobe the small lobe, the lobule or the lobulus Spigelii (3).
This division of the liver into two lobes is also marked on the upper surface, as we have
already seen, by the suspensory ligament. Of these lobes, the right is much larger than
the left ; the former occupies the right hypochondrium, the latter the epigastrium and
left hypochondrium {fig. 161). The proportion between the right and the left lobe can-
not be precisely determined. The left lobe is sometimes reduced to a thin tongue, while,
at other times, it is almost half the size of the right lobe. Generally, the relative pro-
portion between them is as six to one. This, however, is of but little consequence ; for
as the distinction between the two lobes is quite imaginary, the substance of the left
* In an old woman, whose liver was deformed but healthy, and projected below the ribs, I was able to diag-
nosticate, by mediate percussion, the existence of a knuckle of intestine between the liver and the parietei
of the abdomen. Very lately I found a large loop of the transverse arch of the colon between the right lobe
and the abdominal parietes, and a loop of the small intestine between the left lobe and those parietes.
t The ancients admitted four lobes in the liver, which they distinguished by the singular names of mensa,
porta, gladius, and unguis.
t [The term umbilictil fissure is often restricted to this part of the longitudinal fissure ; the posterior half it
then called the fossa of the ductus venosus.]
0 [This bridge was purposely divided in the liver from which Jig. 164 was drawn.]
SPLANCHNOLOGY.
may, without any inconvenience, be included in the right, and vice versa. TKe transverie
fissure, or fissure of the vena ■porta {d p), is the true hilus of the liver, for through it the
hepatic vessels enter and pass out. It is a very broad, transverse fissure, from fifteen
to eighteen lines in length, occupying ahnost the middle of the lower surface of the liver,
a little nearer to the posterior than to the anterior border, and to the left than to the right
extremity. It is bounded on the left by the longitudinal fissure, with which it commu-
nicates ; to the right of the gall-bladder {g), it is prolonged obliquely forward by a deep
and narrow cleft. In the transverse fissure we find the vena portae, or the sinus (p) of
the vena portae, the hepatic artery (a), the roots of the hepatic duct (d), a great number
of lymphatic vessels and nerves, and a considerable quantity of cellular tissue. The
gastro-hepatic omentum is given off from this fissure. The transverse fissure is situa-
ted between two eminences, called by the ancients the pillars of the gate {portal eminen-
ces). All the peculiarities of the inferior surface of the liver may be referred to these
two fissures.
Thus, to the left of the longitudinal fissure we observe the inferior surface of the left
lobe, slightly concave behind, where it is applied to the lobulus Spigelii, from which it is
separated by the gastro-hepatic omentum ; concave in front, so as to be adapted to the
convexity of the stomach, upon which it is prolonged to a greater or less extent. This
relation of the liver with the stomach is of the utmost importance. Thus, when the
stomach is distended, it pushes the liver upward and backward in such a manner that
its lower surface is directed somewhat forward. In cases of chronic ulceration of the
stomach, the tissue of the liver is not unfrequently found supplying the place of the de-
stroyed coats of the stomach, and this to a considerable extent. The lower surface of
the left lobe is often in relation with the spleen, which it occasionally covers like a helmet.
To the right of the longitudinal fissure, and in front of the transverse fissure, we find,
upon the lower surface o'f the right lobe, the fossa for the gall-bladder, which is more or
less deep, oblong, and directed from before backward, upward, and to the left side, like
the gall-bladder (g) itself, for the reception of which it is intended. This fossa is not al-
ways prolonged as far as the anterior border of the liver. Between the fossa of the gall-
bladder and the longitudinal fissure is a square surface, the lobulus quadratus, anterior
portal eminence, or anterior lobule (4). This surface sometimes terminates behind in a dis-
tinct rounded prominence, which justifies the name of eminence applied to it ; at other
times, on the contrary, this portion of the liver is flattened.
Behind the transverse fissure we find the posterior portal eminence, or small lobe (pos-
terior lobule or lobule), also called the lobulus Spigelii (3), from the name of the anatomist
to whom its discovery has been attributed, although it was described, and even figured
before his time by Vesalius, Sylvius, and Eustachius. It varies much, both in size and
shape, and is situated between the transverse fissure and the posterior border of the liver,
and between the fissure of the ductus venosus (») on the left, and the fissure of the vena
cava inferior (c) on the right. It is situated to the right of the oesophageal orifice of the
stomach, opposite its lesser curvature, by which it is embraced ; its form is that of a
flattened semilunar tongue, convex upon its lower and free surface, which corresponds
to the upper border of the pancreas, and has a projection in the centre, surrounded by
an arterial circle, formed by the coronary artery of the stomach with the splenic and
hepatic arteries. This projection (above 3) is called by Haller major colliculus in magna
papilla similitudinem; and by Winslovv, r eminence triangulaire. From its posterior ex-
tremity a prolongation is given off opposite the posterior border of the liver, which con-
verts the fissure for the vena cava inferior into a canal that is sometimes complete.* A
prolongation or ridge (5) {the right prolongaiion of the lobule) passes from its anterior ex-
tremity to the right of the transverse fissure, and, proceeding obliquely forward, separ-
ates the renal (r) from the colic (o) depression. This prolongation was minutely descri-
bed by the older anatomists, and has been termed by Haller the colliculus caudatus.j At
its junction with the lobule, this prolongation is marked in front by a groove (the groove
of the vena porta), sufficiently deep to lodge the vena portae (p) and the hepatic artery (a) ;
and it is still more deeply excavated behind for the vena cava inferior (c) {the groove of
the vena cava inferior). Sometimes the right margin of the first-mentioned groove has a
papilla similar to that of the lobulus Spigelii ; and in this case it might be Sciid that there
are two lobes of Spigelius ; opposite this groove, the vena portae is separated from the
vena cava only by a very thin lamina.
The lobulus Spigelii presents much variety in its size ; but not such as to enable it to
be felt through the abdominal parietes, unless the enlargement is the consequence of
disease. Physicians who pretend to recognis.e by the touch obstruction or adhesion of
the lobulus Spigelii,t are certainly not anatomists.
To the right of the longitudinal fissure, the lower surface of the liver presents, behind,
* [This prolong-ation did not exist in the liver represented in fig. 1G4.]
+ [Now termed the lobulus caudatus.]
; Meckel and others consider that there is a right antero-posterior, or longitudinal fissure, formed by the
tossa for the gall-bladder and the groove of the vena cava inferior ; the latter groove being partly hollowed
t ut af the loCulus Spigelii, and partly out of the continguous portion of the right lobe, and then prolonged
upon the lower surface of the liver
THE LIVER.
au excavation of variable depth and extent in different subjects ; this is the renal im-
pression (r) : it corresponds to the kidney, upon which it is exactly moulded, and with
which it is loosely united, and also, though more loosely, with the supra-renal capsule.
Sometimes the impression for the capsule is distinct from that for the kidney. It may
be conceived that this impression must vary according as the liver corresponds to the
uj^er third, to the upper half, or to the whole of the right kidney. This impression is
always directed backward.
In front of the renal impression is a slight one, termed the colic depression (o), which
corresponds with the angle formed by the ascending and transverse colon with part of
the transverse colon itself, and sometimes, also, with the first portion of the duodenum.
Behind is the groove for the vena cava inferior (c), which advances slightly upon the
lower surface of the liver, on the inner side of the renal and capsular impression.
The accidental fissures sometimes observed upon the lower surface of the liver are
traces of the divisions which exist in a great number of mammalia.
To recapitulate the numerous objects seen upon the lower surface of the liver, we find
as follows : the antero-posterior or longitudinal fissure, intersected at right angles by the
transverse fissure ; on the left of the antero-posterior fissure is the lower surface of the
left lobe, presenting the depression for the lobulus Spigelii, the gastric impression, and
sometimes the splenic ; on the right and in front of the transverse fissure, are the fossa
of the gall-bladder, and the anterior portal eminence, or lobulus quadratus ; behind the
transverse fissure is the posterior portal eminence, or lobulus Spigelii, with its right
prolongation or lobulus caudatus, and the groove for the vena portae ; and still more to
the right are the renal and colic impressions, and the groove for the inferior vena cava.
The Circumference of the Liver. — The anterior border of the liver presents a very thin,
and, as it were, sharp edge, which is directed obliquely upward and to the *ft side, cor-
responding to the base of the thorax on the right side, and projecting below it, opposite
the sub-sternal notch (Jig. 155). Upon this edge there is invariably found a deep notch
(below 2, Jig. 161) for the umbilical vein ; and more to the right another notch, which is
often larger than the preceding, and corresponds to the base (g) of the gall-bladder.
Sometimes there is merely a trace of this notch, and sometimes it is altogether wanting.
In some subjects there is only one great notch, common to the gall-bladder and the um-
bilical vein, and the borders of it are sinuous, or cut into small notches. It is almost
always possible, when the parietes of the abdomen are relaxed, to insinuate the fingers
between the ribs and the liver.
The posterior border of the liver is very thick in all that part which corresponds to the
right side, and becomes gradually thinner as it approaches the left extremity. This
border, which is short, rounded, and curved, so as to fit the convexity of the vertebral
column, adheres intimately to the diaphragm by rather dense cellular tissue. The peri-
toneum is reflected, both above and below this border, from the diaphragm to the liver,
to form what is called the coronary ligament. The cellular interved between these two
layers of peritoneum is of irregular form, and taries in size. This border is divided into
two parts by a deep notch, which forms two thirds or three fourths of a canal for the re-
ception of the inferior vena cava {c,Jig. 164). This notch is converted into a complete
canal, sometimes by a sort of fibrous bridge, and sometimes by a prolongation fi-om the
posterior extremity of the lobulus Spigelii. In order to comprehend the arrangement of
the liver opposite this notch for the vena cava, that vein should be slit open, and we then
see at the bottom of a deep notch a large cavity, into which all the hepatic veins (Ji h)
open. We observe, also, that the antero-posterior fissure is continuous with the fissure
of the vena cava, behind the lobulus Spigelii. This lobule, viewed from behind, appears
like a tongue detached from the rest of the liver, by circumscribing fissures and grooves.
On the right side, the liver terminates in a thick, smooth extremity, forming the base
of the pyramid, to which this organ has been compared. A triangular fold of peritone-
um, caUed the right triangular ligament (/), is stretched from the middle of this thick ex-
tremity to the diaphragm.
On the left side, the liver terminates in an angular or obtuse tongue, more or less elon
gated, and sometimes reaching as far as the spleen, to which I have seen it adherent
This prolongation, which is attached to the diaphragm byatriangular fold of peritoneum,
called the left triangular ligament (3, fig. 161 ; I, fig. 164), is slightly notched behind for
the lower end of the oesophagus, which is bordered by it upon the left side. In one sub-
ject I saw this tongue completely separated from the rest of the liver, with the excep-
tion of a veiscular pedicle about four lines in length. This peculiarity was probably ow-
ing to traction exercised by the spleen, to which the prolongation from the Uver was in-
timately adherent.
Colour. — The liver is of a reddish-brown colour, the depth of which varies in different
individuals. Its surface, and also sections of it, resemble in appearance a granite com-
posed of two kinds of grains, the one deep brown, the other yellowish ; and hence has
arisen the distinction between the two substances of the Uver. In no tissue in the body
is there greater variety in colour than in that of the liver. Independently of the differ-
ent shades, which it is imoossible to describe, the liver is sometimes of a yellowish or
390 SPLANCHNOLOGY.
canary-yellow, or a chamois-yellow (hence the name cirrhosis given to a particular dis-
.ease of the liver) ; or it may be of a more or less deep olive-green hue, or of a slate
colour. These differences in colour, which have not, perhaps, been sufficiently investi-
gated, are connected with more or less decided alterations of texture. The chamois-
yellow colour almost always indicates the existence of fatty degeneration.
Fragility. — ^The fragility of the liver is one of the most important particulars in its de-
scription. It is compact and fragile, and cannot, therefore, be forcibly compressed with-
out suffering laceration ; hence the danger of contusions in the region of the liver, and
the rules laid down by accoucheurs for avoiding all compression of the abdomen of the
feet us during the manipulations required in protracted labours. The fragility and the
weight of the liver explain the occurrence of injuries of that organ by contre-coup, after
falls from an elevated height. In fatty degeneration of this organ, the liver retains the
impression of the finger, and its fragility is in a great measure lost. Olive-green and
slate-coloured livers are dense, their molecules are much more closely united, and they
are lacerated with difficulty.
Texture. — Before the admirable works of Glisson and Malpighi, anatomists were in the
habit of saying, with Erasistratus, that the liver, like all other organs of a complicated
structure, was a parenchyma ; a vague term, intended to imply the effusion of a particular
juice around a series of vessels. Malpighi showed, in opposition to the assertion of
Warthen, that the liver is a conglomerate gland : he examined the glandular granules
(the lobules of Kiernan), which Ruysch subsequently, by means of his beautiful injec-
tions, appeared to convert into vessels. Anatomists are still divided between the opin-
ions of these two eminent observers concerning the intimate structure of the liver, as
well as of all other glands, some believing it to be granular, others that it is vascular.
We have to' consider the coverings, and then the proper tissue of the liver.
The Coverings of the Liver. — These are two in number, viz., a peritoneal coat, and a
proper fibrous membrane.
The peritoneal coat forms an almost complete covering for the liver ; the posterior bor-
der, the transverse fissure, the groove for the vena cava, and the fossa for the gall-blad-
der, are the only parts that are destitute of this coat. The peritoneum, from being re-
flected upon the liver from the diaphragm, constitutes the several folds called the falci-
form, coronary, and triangular ligaments, of which we have already spoken. By means
of this membrane, which is always moist, the liver is enabled to glide upon the adjacent
parts without friction. We frequently find cellular adhesions between the liver and sur-
rounding structures, which do not positively impair its functions. The peritoneal coat
adheres intimately to the proper membrane.
The proper or fibrous membrane is very well seen over such portions of the liver as are not
covered by the peritoneum, and from these points it can be easily traced over the whole
of the remainder of the organ. It constitutes the immediate investment of the liver ; its
outer surface is adherent to the peritoneal coat, and its inner surface is connected with
the tissue of the liver by means of fibrous prolongations interposed between the granules
(lobules), affording to each a distinct covering.
It passes into and lines the transverse fissure, and is prolonged around the correspond-
ing divisions of the vena portae, the hepatic artery, and the biUary ducts, so as to form
cylindrical sheaths for those groups of vessels, and for all their farther divisions and sub-
divisions. These sheaths constitute the capsule of Glisson, which we must therefore re-
gard as a dependance of the proper fibrous coat. The internal surface of these sheaths
is united to the vessels only by a very loose cellular tissue. Their external surface ad-
heres intimately to the tissue of the liver by fibrous prolongations, which interlace in
every direction, and form distinct coverings for the deep-seated granules, analogous to
those which we have already stated are produced from the proper coat. The liver,
therefore, is traversed in all directions by very delicate fibro-cellular prolongations, form-
ing a vast network, in which the granules are contained. This proper coat, moreover,
is fibrous,* not muscular, as Glisson believed.
It may be said, with truth, to constitute the skeleton or framework of the liver, for it
affords a general covering for the organ ; it is prolonged around the vena portae, the he-
patic artery, and the biliary ducts, and it furnishes a fibrous or cellular covering for each
of the granules composing the proper tissue of the liver. The fibrous cells thus fonned
become very distinct in certain cases of hepatic disease. In fact, this fibrous tissue not
unfrequently becomes so much hypertrophied, that some of the glandular granules are
compressed and atrophied ; and then larger or smaller portions of the liver appear to be
converted into a reticulated fibrous tissue. The arrangement of the fibrous tissue is also
very manifest in cases of softening of the granules, which may then be easily scraped
out of their cells, and the surface of the section thus treated presents the appearance of
the cells in a honeycomb.
The Proper Tissue of the Liver. — The first thing that strikes an observer in examining
the structure of the liver, is the smoothness of its external surface, which does not pre-
sent any of the lobulated appearance of most other glands. If we attentively examine
* [It is composed of dense cellular or fibro-cellular tissue : for its use, see note, p. 393.1
THE LIVER. 391
this surface, either before or after the removal of its coverings, we find that it is most
distinctly composed of granules (lobules, Kieman) : the same is also rendered evident by
making sections of the organ, or by tearing it : the granular arrangement has, it is true,
been supposed to be the result of laceration.
From the mottled appearance of the liver (like granite), already noticed, anatomists
have admitted the existence of two substances, or, rather, two kinds of granules in this
organ, viz., reddish brown and yellow granules. This distinction was first made by Fer-
rein (Hist. Acad, des Sciences, 1735) ; it is now generally recognised, and has even served
as the basis of several more or less ingenious explanations. This anatomist called the
brown substance medullary, and the yellow cortical, names evidently derived from a rude
analogy between them and the medullary and cortical substances of the brain. Others
have reversed the meaning of these two words ; but that is of little consequence.
" These two substances," says Meckel, " are not arranged as in the brain, one exter-
nal and the other internal ; but alternately throughout the whole liver, the yellow sub-
stance forming the mass of the organ, and the brown substance occupying the intervals."
This distinction into two substances does not appear to me to be well founded. The
error has arisen from assuming as constant the existence of two colours, which, how-
ever, are far from being distinguishable in all subjects. The two colours, yellow and
brown, when they do exist, do not belong to two distinct granules, but rather to the same
granule, which is yellow in the centre, where the bile is found, and reddish brown at the
circumference, where the blood is collected.*
The granules of the human liver are so small, that, excepting when they become con-
siderably enlarged, it is not well adapted for examination. The liver of the pig, in which
the granules are naturally very large, appears to me the best suited for this purpose. I
have been accustomed to divide the liver in different directions, to slit up and remove
the veins which have been cut across, and afterward to examine the granules in the
semi-canals {g g,fig. 165 ; c c,fig. 166) which they then form. The granules (/ 1 1) may
thus be separated with the greatest facility ; they are small, ovoid, elliptical, or, rather,
polyhedral bodies, having five or six surfaces, and shaped so as to be moulded upon the
surface of the adjacent granules, without leaving any interval. It is evident, therefore,
that there is only one order of granules ; that these granules are not arranged in lobules,
as stated by Malpighi,+ but are merely in juxtaposition ; and that each has its proper cap-
sule, formed by prolongations of the fibrous coat. And as these granules can be isolated,
and detached from the capsules in which they are merely lodged, without adhering to
them, except at the points by which they receive and emit their vessels, it follows that
they are independent of each other, and that the most complete alteration of one or more
of them may take place, without the adjacent or intermediate granules being in any
way affected, or, at least, that such alteration would not be propagated by continuity of
tissue.
The size of the granules varies much in different individuals, and is quite independent
of the size of the liver itself Physicians who have paid much attention to pathological
anatomy have often mentioned their increased development, by the name of hepar aci-
nosum. This disease is characterized by the simultaneous occurrence of atrophy of the
entire organ, which is reduced to one half or one third its original size, and of hyper-
trophy of the granules themselves. In what is called cirrhosis, the greater number of the
granules are atrophied, t
The investigation of the structure of the liver is, then, reduced to the determination of
the arrangement of the granules with respect to each other, of the mode in which the
vessels are arranged, and of the structure of each granule.
1. The arrangement of the granules, with regard to each other, is revealed by the fol-
lowing fact : In the disease of the liver called ramollisement {Diet, de Med. et Chir. Pratiq.,
art. Maladies du Foie), in which that organ is reduced to a sort of pulp, as soon as the
investing membranes are torn, the tissue of the liver escapes like a brownish-yellow
pulp, which, as it is not fetid, cannot be supposed to be the result of gangrene. If this
pulp be placed in water, myriads of small and very distinct yellow granules will be seen,
resembling small raisin stones, and appended to the ramifications of the different kinds
of vessels by vascular pedicles.
This fact, which I have several times observed, is confirmed by the observations of
Harvey, who, in his work upon the generation of animals, says, that the tissue of the
liver is formed along the umbilical vessels like a grape on its footstalk, a bud on the end
of a twig, or an ear of corn springing from its stalk ; and also by reference to compara-
* See note, p. 395.
t [This statement illustrates the confusion that has prevailed from the terms lobule and acinus having' been
employed by anatomical writers in different senses to those attached to them by Malpighi ; the lobule of Mal-
pighi is, in fact, equivalent to the granule of M. Cruveilhier, and was described by him as consisting of a col-
lection of acini {see note, p. 395).]
t The ingenious explanation which has been given of cirrhosis is, then, destitute of foundation. In cirrhosis,
as I have shown in another place, there is neither atrophy of the red substance, nor hypertrophy of the yellow,
but rather atrophy of the greater number of granules, with hypertrophy and yellow discoloration of the re-
mainder.
392 SPLANCHNOLOGY,
tive anatomy, for M. Blainville has informed me that, in certain species of animals, the
liver is formed by rows of glandular granules attached aJong the vessels.*
2. The Vessels of the Liver. — The study of the vessels of the liver is one of the most
important points in the history of that organ. Besides the arteries and veins correspond-
ing to those of other parts of the body, the liver receives also a special system of veins,
viz., the system of the vena porta, which is distributed in its interior like an artery. It
presents also, in the adult, the remains of a venous system peculiar to the foetus, the sys-
tem of the umbilical vein ; and, lastly, it contains canals intended for the conveyance of
the bile, named the biliary ducts.
The special venous system of the liver, or the system of the vena porta, will be described
more particularly in another place. I shall only now observe, that the branches of ori-
gin of this system commence in all the abdominal organs concerned in the function of
digestion ; that the ventral venaportae, resulting from the union of these branches, reaches
the transverse fissure of the liver, and divides there into a right and left branch, which
constitute the hepatic vena portae {p, fig. 164) ; and that these branches subdivide and
spread into all parts of the liver, some forward and others backward, but all following a
transverse direction. The capsule of Glisson, as we have seen, is developed around this
vein ; so that, in sections of the liver, the branches of the vena portae can always be rec-
ognised by these two characters : a transverse direction, and the presence of the capsule.
Remmtis of the Umbilical Vein. — We can easily conceive the arrangement of these re-
Fig. 164.t mains, if we consider that, in the foetus, the umbilical
vein (m, fig. 164t), proceeds from the placenta to the
longitudinal fissure of the liver ; and at the point where
this is intersected by the transverse fissure, divides into
two branches, one of which, under the name of the duc-
tus venosus (d), passes directly to the vena cava (c), at
the point where it traverses the posterior border of the
liver ; while the other is continuous with the hepatic
vena portae (jf), which, as we have seen, occupies the
transverse fissure. The portion common to the umbil-
ical and portal veins remains pervious in the adult ; but
it then belongs exclusively to the vena portae. The ductus venosus then becomes a mere
fibrous cord {v, fig. 164t), as well as the trunk of the umbilical vein itself (m). It is not
rare to find the trunk of the umbilical vein persistent in the adult, from an abnormal com-
munication between it and the veins of the abdominal parietes. (See Anat. Path, avec
planches, liv. xvii., pi. 6.) No example has been recorded of a persistent ductus venosus.
Arteries. — The hepatic artery is a branch of the coeliac axis {t,fig. 154), which also
furnishes branches to the spleen and the stomach ; and although a difference in the ori-
gin of an artery dose not occasion any difference in the blood within it, yet this com-
munity of origin is not the less remarkable, for it seems to denote a community, a coinci-
dence, or a connexion of function. Moreover, as the nervous plexuses are supported
upon the arteries, it follows that the nerves of the spleen, stomach, and liver, are de-
rived from a common plexus, the cceMac. We frequently find a second hepatic artery
arising from the superior mesenteric.
I must not omit to mention the smaUness of the hepatic artery in comparison with the
size and mass of the liver. In this respect few organs present so great a disproportion :
compare, for example, the kidney and the renal artery, look at the muscles, and I may
almost say at the bones. The small caliber of the hepatic artery enables us to determine
d priori, that it cannot serve both for the nutrition of the organ and for the secretion of
the bile. Lastly, it exactly follows the r2unifications of the vena portae and the biliary
ducts, and the capsule of Glisson is common to it and to those two sets of vessels.
The Hepatic Veins. — The hepatic veins, the efferent vessels of the liver, are not pro
portion al to the size of the hepatic artery, but to that of the vena portae. Proceeding
from all points of the liver, and converging towards the fissure of the vena cava, the
hepatic veins {h h',fig. 164) empty themselves into that vein (c), especially near the pos-
terior border of the liver. It follows, therefore, that the direction of the hepatic veins
and of their divisions is from before backward, while that of the divisions of the vena
portae is transverse. t This direction, and the absence of the capsule of Glisson, on ac-
* Arrangement of the ioiuZe^.— [According to M. Kieman, from whose paper in the Phil Trans, for 1833
this and the succeeding notes on the structure of the liver are derived, the lobules (g^ranules, Cruveilhier) of
the human liver are many sided bodies, flattened on one surface, called the base, and forming- processes in
every other direction ; hence, in a longitudinal section they present a foliated, and in a transverse section a
polyhedral form. The bases of all the lobules (c c,fig. 166) rest on certain branches of the hepatic vein, call-
ed «u4-lobular veins (A h) ; while their other surfaces, surrounded by the capsular investments, are either in
contact with those of the adjacent lobules, or appear on the outer surface of the liver, or in the portal canals
^g gifig- '65). which contain the \4ka. portae, hepatic artery, and hep.atic duct, or in those fur the lars^er trunks
(h,fig. 166) of the hepatic vein. The intervals between the sides of the lobules are the inter-l(>bular/«s«r««,
and the points at which two or more of ihese meet are the inter-lobular spaces. The superficial lobules are
imperfect, or more or less flattened on their exposed side.]
t At least in the principal t'orVs ; for there are a great number of ramifications of the hepatic veins which
pass transversely.
THE LIVEE.
393
count of which the walls of these veins are directly adherent to the tissue of the liver,
so that the veins themselves remain patent, while the sections of the vena portae collapse,
are the two characters by which the divisions of the hepatic veins may be distinguished
from those of the vena portae, on simply inspecting a section of the liver. Do these
anatomical differences between the two kinds of veins produce any difference in the
mechanism of the circulation through them ] And is the want of immediate connexion
of the divisions of the vena portae to the tissue of the liver intended to permit them to
contract so as to propel the blood ] If we consider that the blood of the vena portae pro-
ceeds from the trunk towards the branches, as in the arteries, we may conceive the ad-
vantages which must result from an anatomical arrangement that would allow these
vessels to exert a direct pressure upon the blood.
Another point of difference between the branches of the hepatic vein and of the vena
portae is, that the walls of the former are perforated by a multitude of extremely small
openings or pores, which are the orifices of very small veins.
The Lymphatic Vessels. — The lymphatics of the liver are so numerous that these ves-
sels were first discovered in that organ ; indeed, it was for a long time regarded as the
origin of the lymphatic system, just as it had been originally considered the origin of the
veins. The lymphatics of the liver form a superjicicd and a deej> set. The superficial
lymphatics are arranged in an extremely close network under the peritoneal coat. Tlie
deep set, which are very large and numerous, pass out of the transverse fissure of the
liver, and terminate partly in lymphatic glands situated along the hepatic vessels, and
partly in the lumbar glands. They communicate directly and freely with the thoracic
duct, so that one of the best methods of injecting this duct consists in throwing the in-
jection into the lymphatics of the liver.
The Nerves. — These are very small, considering the size of the liver. They are deri-
ved from two sources, the cerebro-spinal and the ganglionic gystems. The former are
branches of the pneumogastric nerves ; the latter constitute the hepatic plexus, which
is an offset from the solar plexus. They are interlaced around the hepatic artery : some
of these nerves, however, by a special exception, accompany the vena portae. It is gen-
eredly admitted that a few filaments of the phrenic nerve are given to the liver.
The Biliary Ducts. — Wiiatever may be the origin of the biliary ducts, their radicles,
however small they may be, are always found in the capsule of Glisson, together with
the corresponding branches of the vena portae and hepatic artery. These radicles are
united like veins into smaller, and these into larger branches, which, at length, consti-
tute the hepatic duct (d,fig. 164). They can be readily distinguished from the other vas-
cular canals of the liver by their yellowish colour, by the fluid which they contain, and
by the appearance of their parietes.*
* Vessels. — [The first divisions ef the vena portae, hepatic artery, and hepat-
ic duct, are situated in the portal canals, which are tubular passages formed
in the tissue of the liver, commencing at the transverse fissure, and branching
through the Substance of the organ. The smallest divisions of the portal ca-
nals contain one principal branch of each of these vessels (P a d,fig. 165) :
from these proceed smaller branches, called vaginal, from their situation with-
in the capsule of Glisson. jf
In the larger canals, the vaginal veins (p" form a plexus in the substance
■p of the capsule, and then give off the tn(er-lobular veins (p p), which pass be-
tween the lobules opposite the inter-lobular spaces, ramify in the inter-lobular
fissures (p p,fig. 167), and, after freely anastomosing upon the capsular surfa-
ces of the lobules, divide into branches, which penetrate the lobules them-
selves. In the smaller portal canals, the vaginal venous plexuses are less ap-
parent, for many of the inter-lobular veins (i) arise at once from the principal
branch of the vena portae : where Fig. 166^
this occurs, the capsule of Glis-
son is very thin ; and, indeed, the
chief use of this structure, in oth-
er situations, appears to be to form a web, on which the vessels
may ramify, so as to enter the liver at a great number of points,
a use analogous to that of the pia mater and periosteum, in refer-
ence to the brain and bones.
The hepatic artery also forms vaginal plexuses in the portal
canals, wiiich give off inter-lobular hranches ; from these vessels
the proper capsule of the liver, the capsule of Glisson, the cap-
sules of the lobules, and the coats of the different vessels, derive
their nutrier.'. aT*«ries, which terminate in veins that enter the
vena portse. But few arterial branches enter the lobules them-
selves.
The hepatic duct, also, has its vaginal branches, but it is doubt-
ful whether they anastomose ; they are formed by the union of
the inter-lobular branches (d d,fig. 168), which do appear to anas-
tomose, and are derived from the biliary ducts, which pass out at
the surface of the lobules.
The several divisions of the hepatic veins are termed the he-
patic venous trunks, the su6-lobular veins, and the infra-lobular
veins. The inira-lobular veins (i,fig. 166 ; h,fig. 167), of which ,
but one, independent of the rest, emerges from the centre of the *
base of each lobule, open into the sub-lobular veins (A A), through - . •/ ■< r v
the thin walls of which can be seen the polyhedral bases of the lobules, and the central orifices (t t ) of Ul0
D n D
394 SPLANCHNOLOGY.
3. What is the structure of the gramdcs ? In examining a section of the liver of a pig
with the simple microscope, I have seen most distinctly that each granule has a porous
and spongy appearance, like the pith of the rush or elder, so that the proper tissue of the
liver resembles a sort of filter. This appearance was much more distinct in livers which
I had injected with walnut oil, either pure or coloured blue. The colouring matter thrown
into the vena portae was, as it were, infiltrated into the spongy tissue of the liver.
If we endeavour to ascertain the structure of the liver by means of injections, we shall
see what was observed by Soemmering, that whichever vessel be injected, whether the
hepatic artery, the duct, the vena portae, or the hepatic vein (provided only the injection
be thin, as, for example, coloured glue, size, or spirits of turpentine, or, better still, a
strong aqueous solution of gamboge), there will not be a single granule into which the
injection will not have penetrated ; and, moreover, that the liquid throvra into one ves-
sel will pass either into one, two, or all three of the others ; and the facility with which
this takes place proves that the different orders of vessels communicate with each other
directly, and not through the medium of cells or small cavities.*
In a foetus, or an infant that has died immediately after birth, an injection through the
umbilical vein gives similar results. I have never been able to force the liquid into the
l)Tnphatic vessels, at least without rupturing the tissue of the liver. Air driven into the
vessels penetrates more easily than liquids into the lymphatics, no doubt on account of
its greater subtilty.
It follows, then, that in each granule there is an arterial radicle, a radicle of the vena
portae, one of the hepatic vein, and one of the duct, probably some lymphatic vessels, and
a nervous filament. The aggregate has been represented by Soemmering as having
some resemblance to the arrangement of a Damask rose.f All the different vessels
communicate freely with each other.t
The manner in which these different vessels are arranged in each granule can only
be discovered by injecting them simultaneously, or, rather, successively, for it is nearly
impossible to inject all the vessels of the liver at the same time. I have accordingly in-
jected the vessels in the following order : the vena cava, and, consequently, the hepatic
veins, with wax coloured with Prussian blue — a certain quantity of walnut oil, also con-
taining Prussian blue, had been previously thrown into the same vein ; the vena portee
with a red injection ; the hepatic artery with the same ; and then the hepatic duct with
a yellow injection. These injections were made in the liver of a pig, the liver being
placed in warm water, and the injections pushed in with a gradually-increasing force.
During the injection of the vena cava and vena portae, the wrinkles of the liver disap-
peared, and the central depressions of the superficial granules became, on the contrary,
slightly prominent. It was therefore evident that each granule was hollow, and that
the space had been filled by the injected matter.
The liver thus injected and submitted to different chemical agents gave the following
results : The blue injection, or that which had been thrown into the vena cava, had pen-
etrated into the central part of each granule, which is generally called the yellow suh
stance of the liver. In the middle of the central part was the yellow injection from the
hepatic duct. Around tl\^ blue injection was found that coloured red, which had been
forced into the vena port* and the hepatic artery, and which occupied all the so-called
red substance of the liver. It follows, therefore, that each granule had a vascular appa-
ratus thus arranged : in the centre, a biliary duct ; farther removed from the centre, a
vascular circle formed by the ramifications of the hepatic vein ; and external to this
another vascular circle, formed by ramifications of the vena portae and hepatic artery.
As to the manner in which the vena portae and hepatic artery are arranged in relation to
each other, we shall find, if we trace them into the substance of the liver, that the ram-
ifications of the hepatic artery correspond exactly to those of the vena portae and biliary
duct, which, as we have already said, are all contained in the same sheath ; and that
they ramify and are lost upon the parietes of the vein and duct, almost in the same
manner as the bronchial arteries are distributed upon the divisions of the air tubes. I
must, therefore, conclude that the hepatic artery furnishes for the liver the nutritious
vessels (vasa vasorum) of the vena portae and hepatic ducts ; and this will explain the
disproportion between its cahber and the size of the Uver.
The subdivisions of the hepatic veins, which follow a separate course, present a sim
^ilar peculiarity to that observed in the splenic vein, viz., a multitude of pores or holes
inter-lobular veins. This appearance is peculiar to the sub-lobular veins, the canals for vehich alone are form-
ed by the bases (c c) of the lobules. The portal canals (g,fig- 165) are formed by their capsular surfaces, and
the openings (d), seen in the interior of the small divisions of the vena portae, correspond to the inter-lobular
spaces, not to the centres of the lobules. The sub-lobular veins anastomose with each other (this the divis-
ions of the vena portae never do), and unite to form the hepatic venous trunks (H,fig. 166), into which no in-
tra-lobular veins open, nor do tlie bases of any lobules rest upon them.]
* [From this statement the ducts must be excepted ; they do not communicate with the bloodvessels. — (See
note, p. 395.)] «
t " Quilibet acinus hepatis e glomeroso constat, vel e particulis arteriE, venae portarum, venie hepaticae, duc-
tus biliferi et vasorum absorbentium, cujus formam rosie sic dictie Damascenae imaginem pingere nobis licet,"
—(Corp. Hum. Fab., t. vi., p. 180.) t See note, p. 395.
THE LIVER. g§5
by which very small veins open directly into them. Their ramifications are much less
numerous than those of the vena portae.
The result of the injections described above also explains the difference in colour be-
tween the centre and the circumference of each granule ; it shows, moreover, that one
part of the granule is impermeable to injections ; and its spongy nature, resembhng that
of the pith of the rush or elder, is apparent even to the naked eye, in a section of a liver
thus injected, when viewed by a strong light.
To resume, then, it may be said that the liver is composed of ovoid, elliptical, or, rath-
er, polyhedral granules, moulded closely upon each other. Each granule has its proper
fibrous capsule ; and all the capsules are united together by prolongations, which also
connect them with the general cellular investment of the liver, and with that extension
of it called the capsule of GUsson. The granules are independent of each other. Each
of them consists of a spongy tissue, impermeable to injections ; of a biliary duct proceed-
ing from its centre ; of a venous network foimed by the hepatic veins ; of another ve-
nous network belonging to the vena portae ; and of a very delicate arterial network deri-
ved from the hepatic artery, which is ramified upon the parietes of the vena portae and
biliary ducts. Such is the structure of the hver.* It remains for me now to examine its
excretory apparatus.
The Excretory Apparatus of the Liver.
The excretory apparatus of the liver consists of the hepatic duct, of the cystic duct,
of the gall-bladder, and of the ductus communis choledochus.
The hepato-cystic canals, t admitted by some authors as constant or occasional in man,
can be easily shown in the lower animals, but do not exist in the human species.
TTie Hepatic Duct. — The hepatic duct arises in the granules of the liver by hepatic radr
KleSjt which, by uniting successively like veins, constitute small and then larger branch-
es. These latter all converge towards the transverse fissure of the liver, where they
terminate ultimately in two trunks of almost equal size, which join each other at a very
obtuse angle, and form the hepatic duct {d,fig. 164). The condition of the branches of
the hepatic duct in the transverse fissure is extremely variable : thus, sometimes the
trunk of the right side is larger than that of the left, and sometimes the opposite is the
case. Frequently several branches join the trunks late in the transverse fissure ; but,
whatever be the nature of these variations, the right trunk never corresponds exactly to
the right lobe of the liver, nor the left to the left lobe.
All the divisions and subdivisions of the hepatic duct^ are contained in the capsule of
Glisson, together with the ramifications of the vena portaj and hepatic artery, to which
* Structure of the Lobules. — [It appears from the preceding note, that while several branches of the vena
portae and hepatic artery enter, and several of those of the hepatic duct pass out at the capsular surface of
each lobule, only a single branch of the hepatic vein emerges from its base ; within the lobules, the following
is the arrangement of these vessels :
The branches from the inter-lobular (portal) veins Cp p p,Jig. 167) form in the outer portion of each lobule
a venous plexus {I I), consisting of branches radiating towards the centre, rv jg~
connected by others passing transversely ; these veins become capillary, e • ' •
ramify upon the biliary ducts, and terminating in the branches of the intra-
lobular (hepatic) vein (h), which correspond in number with the processes
on the surface of the lobule, ultimately unite to form the central vein that «:;>^^^Ji^^^/^}^^'^i^'^
passes out at its base.
The lobular arteries are few in number, and, according to Kieman, end in
branches of the vena portse, and not directly in those of the hepatic vein.
Miiller inclines to the more commonly received opinion, that the three kinds
of bloodvessels communicate with each other. No communication, how-
ever, exists, as stated by M. Cruveilhier, between the bloodvessels and the
biliary ducts, which, like the ducts of other glands, are an independent system of vessels. According to Mr.
Kieman, the ducts form a reticulated plexus, occupying principally the outer portion of each lobule (as shown
at 6 b, jig. 168, which is a diagram copied from Mr. Kieman's paper).
MUUer expresses doubts as to the anastomosis of the ducts, and thinks it
probable, from analogical observation, that they terminate in tufts of tubes
having blind extremities.
The islets formed between the radiating and transverse branches of the
lobular (portal) veins (I, fig. 167) correspond to the acini of Malpighi, and
contain the biliary ducts with their capillary bloodvessels, and also a pecu-
liar tissue, which occupies all the intervals between the several kinds of
vessels, and consists, according to Krause, of hexagonal, nucleated cells,
having several bright points in them, like globules of oily matter.
The appearance of two substances in the liver can now be explained ; it
does not depend on the biliary ducts being situated in the centre, and the '' ' '
veins nearer to the circumference of each lobule (sec p. 391, 394), but in a
partial congestion of either the portal or hepatic system of veins.
In portal congestion, the margins of the lobules are dark, and their centres pale ; it is very rare, and has
been seen only in children.
Of hepatic venous congestion there are two stages : in the first, the centre of each lobule is dark, and the
margin pale (fig. 166) ; it constitutes passive congestion, and is the common state of the liver after death : in
the second, the congestion extends to the portal veins in the iuter-lobular_/isiures, but not to those in the inter-
lobular spaces, or points at which those fissures meet, which spaces are then seen to occupy the centre of each
pale isolated spot : this is active congestion of the liver ; it occurs in diseases of the heart, and in acute dis-
eases of the lungs and pleura.]
+ [/. c, canals passing directly from the liver into the gall-bladder.] t See note, suprA
<) [Excepting those within the" lobules.]
396 SPLANCHNOLOGY.
they are connected by loose cellular tissue. The trunks of the hepatic duct lie at the
bottom of the transverse fissure, and are hid by the trunk of the vena portse and the
branches of the hepatic artery. The hepatic duct {t, fig. 169), thus formed by the union
of the two trunks which occupy the transverse fissure, passes downward and to the right
side for about an inch and a half, and then unites at a very acute angle with the cystic
duct (s), to form the ductus communis choledochus (c ; and x, fig. 154). In this course
the duct is contained in the gastro-hepatic omentum, together with the vena portas, which
is behind it, and the right branch of the hepatic artery, which is in front of it. A great
quantity of loose cellular tissue unites the duct to these vessels.
The Gail-Bladder. Dissection. — ^A gall-bladder filled with bile may be studied without
any preparation : if it is empty it must be distended, either with a fluid or vpith air. A
beautiful preparation of the gall-bladder may be made for preservation by drying it after
inflation, or by filling it with fat, which is afterward removed by oil of turpentine.
The gall-bladder {cystis fellea, g,fig. 164) is the reservoir of the bile. It is situated at
the lower surface of the right lobe of the liver, occupying a particular fossa (the fossa of
the gall-bladder) on the right of the longitudinal fissure, from which it is separated by the
lobulus quadratus. It is held in this place by the peritoneum, which, in the majority of
instances, merely passes below it, but, in others, almost entirely invests it, and thus at-
taches it to the liver by a sort of mesentery. In this latter case it is at some distance
from the liver, as in certain animals.
Its fcrrm. is that of a pear, or of a cone with a rounded base ; it is directed obliquely,
so that its great extremity (g,figs. 155, 161) looks forward, downward, and to the right ;
and its small extremity, backward, upward, and to the left side.
Size. — The small size of the gall-bladder corresponds with that of the rest of the ex-
cretory apparatus of the bile, and is strongly contrasted with the great bulk of the liver.
This difference becomes still more striking if we compare, on the one hand, the kidney
with the liver, and, on the other, the urinary bladder with the gall-bladder. It is true,
however, that all the urine must pass through the former, while a part only of the bile is
deposited in the latter.
The size of the gall-bladder, however, is subject to considerable variety ; it sometimes
acquires three, four, or even ten times its usual size from retention of the bile, in conse-
quence of obstruction in the ductus choledochus.* Cases have been recorded in which
it contained six, eight, or ten pounds of bile, but this I can scarcely credit. On the oth-
er hand, it is sometimes closely contracted round a small calculus, while the cystic duct
is completely obliterated, and reduced to a fibrous cord. It must undoubtedly have been
such cases as these that have been regarded as examples of congenital absence of the
gall-bladder.
Relations. — In order to facilitate our description, we shall consider the gall-bladder as
consisting of a body, a fundus, and a neck.
The body is conical, and has the following relations : below, where it is covered by the
peritoneum, it is in relation with the first portion of the duodenum, and the right extrem-
ity of the arch of the colon. It is not unfrequently found in contact with the pylorus, or
even with the pyloric end of the stomach. Sometimes it is united by accidental or nor-
mal adhesions to the duodenum and arch of the colon. These relations account for the
yellow or green discoloration which always takes place after death in those parts of the
alimentary canal that are in contact with the gall-bladder ; and also for the passage of
biliary calculi into the duodenum, the colon, and the stomach. It is not very rai-e to find
the gall-bladder applied by its whole length to the right kidney : this relation can only
occur after descent of the duodenum and transverse colon. Above, the body of the gall-
bladder adheres to the cystic fossa by a more or less loose cellular tissue,! and by ar-
teries and veins, but never in the human subject by biliary, i. e., hepato-cystic, ducts.
The fundus of the gall-bladder {g,fig. 161), entirely covered by the peritoneum, gen-
erally projects beyond the anterior margin of the liver, and comes into relation with the
abdominal parietes, opposite the outer border of the right rectus muscle, immediately
below the costal cartilages near the anterior extremity of the tenth rib. When distend-
ed with bile or calculi, the fundus of the gall-bladder becomes prominent, so as to raise
the abdominal parietes, through which it has been felt in emaciated individuals. It has
even been stated that the noise made by the calculi may be heard on percussion. This
relation explains the possibility of the occurrence of abdominal biliary fistulae, and why
calculi may escape through such openings : on it, also, is founded the scheme for ex-
tracting the calculi by an operation analogous to that performed for stone in the urinary
b adder, and which I should not have mentioned had it not been proposed by J. L. Petit.
The relations, as well as the size of the fundus of the gaU-bladder, present many vari-
* Anrf.her cause of enlargement of the gall-bladder is the obstruction of its neck by a calculus : but, in-
stead of bile, it then contains a limpid serum, and, in fact, is converted into a serous cyst. The tumour thus
formed may t)e compared to the lachrymal tumour in cases of obstruction of the lachrymal puncta or canals.
t This cellular tissue may become inflamed, and, if pus be formed, it may pass into the gall-bladder, while
the bile escapes into the cellular tissue, and hence death may ensue. I have observed, in a very short space
of time, three examples of this lesion, which, perhaps, has not been thoroughly examined ; and several cases
have been shown me under the name of gangrene of the gall-bladder.
THE LIVER. 3g7
eties. The fundus, or that part which projects beyond the Uver, is sometimes as large
as the body. I have seen this part of the gall-bladder turned back at a right angle upon
its body, and reaching the umbilicus. It may be conceived, that the differences in the
form and situation of the liver must greatly influence the situation of the fundus of the
gall-bladder, which I have found in the hypogastrium and in the right iliac fossa, either
with or without adhesion to the neighbouring parts.
The neck or apex of the gall-bladder is twice bent suddenly upon itself, like an italic S,
having its three portions in contact. It would appear, in some cases, that these two
curves resemble the thread of a screw. This double curvature may be easily elTaced by
removing the peritoneum with the subjacent cellular tissue. The limits between the
neck and the body of the gall-bladder on the one hand, and between the neck and the
cystic duct on the other, are marked externally by a constriction.
The internal surface of the gall-bladder is tinged either green or yellow, according to
the colour of the bile ; but this staining is the effect of transudation after death ; its nat-
ural colour is a whitish gray. Moreover, the internal surface is irregular, like shagreen,
and has some crests or prominences arranged upon it in polygons, and again subdivided
by smaller crests, like the reticulum in the stomach of ruminantia ; so that, when ex-
amined by a strong lens, it appears divided into a number of small and very distinct al-
veoli : some highly-developed papillae or villi, of a very irregular shape, are also found
upon it. As to the object of either the crests or the papillae, or whether they favour ab-
sorption by multiplying the surface, we are altogether unable to decide.
Opposite each of the two curves of the S, described by the neck of the gall-bladder,,
we find a very large valve. The two valves, which are in opposite directions, as well
as the curves, result from the alternate inflection of the neck itself, and are efl^aced by
straightening that part. The portion of the neck between the two valves is not unfre-
quently dilated into an ampulla. A calculus is often formed in this intermediate portion,
where it remains, as it were, encysted, and intercepts the course of the bile ; and that
the more easily, because the valves greatly contract the openings from the neck into the
body of the bladder, and into the cystic duct. Moreover, these valves are opposed nei-
ther to the entrance of the bile into, nor to its exit from, the bladder.
Structure. — Proceeding from without inward, we find that the gall-bladder is composed
of, 1. A peritoneal coat, which is reflected from the lower surface of the liver upon the
bladder, completely invests its fundus, forms a more or less incomplete covering for its
body and neck, and is continuous with the anterior layer of the gastro-hepatic omentum.
2. An areolar fibrous coat, which forms, as it were, the framework of the bladder, and pre-
vents its sudden distension, though it will yield to a long-continued distending force ;
but I have not been able to see the muscular fibres admitted by some authors, and which
can be so easily detaonstrated in the larger animals, the ox in particular. 3. An interned
mucous membrane, the principal characters of which I have noticed when speaking of the
internal surface of the gall-bladder : it presents some folds, which may be easily distin-
guished from the borders of the alveoh, because they are readily effaced by distension. Af-
ter the most attentive examination, I have been unable to recognise any crypts or follicles.
The gall-bladder receives one very considerable artery, the cystic branch of the hepatic.
The cystic vein terminates in the vena portae. The lymphatic vessels are very numerous,
and easily demonstrated ; they are sometimes tinged by the colouring matter of the bile.
Its nerves are derived from the hepatic plexus.
The Cystic Duct. — The cystic duct {,s,fig. 169), or excretory duct for the bile, is the
smallest of all the biliary canals : it is not unconunon, however, to find it of an equal or
even larger size than the others, in which case there has always been some obstacle to
the flow of the bile through the ductus communis choledochus (c). It conm[iences at the
neck of the gall-bladder, passes downward and to the left side for about an inch, and
unites at a very acute angle with the hepatic duct (t).
It is not straight, but inflected, and, as it were, sinuous.
Relatio-ns. — It is situated in the substance of the gastro-hepatic omentum, in front of
the vena cava, the cystic artery being on its left side. Its internal surface is remarkable
for its valves, which are indefinite in number ; according to Soemmering, there are from
nine to twenty, but this appears to me to be an exaggeration : I have counted from five
to twelve. These valves are concave at their free margins, irregular, alternate, oblique,
transverse, sometimes even vertical, and united together by small oblique valves. In
order to understand their structure, a cystic duct must be examined under water, or, rath-
er, an inflated and dried specimen. This alternate arrangement of the valves some-
times gives a spiral appearance to the inner surface of the cystic duct.* These valves,
which only exist in man, perhaps on account of the erect position peculiar to him, are
not effaced, like the valves in the neck of the gall-bladder, by such dissection as will al-
low of straightening of the duct. Small calculi are occasionally met with in the inter-
vals between the valves, giving to the cystic duct a nodulated appearance, and intercept-
ing the flow of the bile. Moreover, the valves of the cystic duct are not more opposed
to the descent than to the ascent of the bile. It is even probable that they facilitate the
* " Quae possint aliquam spiralis fabricse imagincm ferre." — {Holler, torn, vi., liv. xxiii., p. 530.)
398 SPLANCHNOLOGY.
ascent of the bile into the gall-bladder by supporting the column of liquid, like the valves
of the veins. Perhaps they are also intended to retard the course of the bile from the
gall-bladder towards the ductus choledochus. From their appearing sometimes to have
a spiral arrangement, M. Amussat has advanced a very ingenious opinion : that the as-
cent of the bile is effected by a contrivance like an Archimedes' screw. But an Archi-
medes' screw only causes the ascent of a liquid when a rotatory movement is communi-
cated to it, and how can such a movement be performed by the cystic duct 1*
The Ductus Communis Choledochus. — The ductus communis choledochus ( xo^, bile,
doxo^, containing ; c, c. Jig. 169), the last excretory canal of the bile, seems to be formed
Fig. 169. by the union of the hepatic (0 and the cystic
ducts («). Another, and, perhaps, more simple
manner of viewing the excretory cansils of the
liver, would be to consider the hepatic duct as
giving off to the right, after a certain course, the
cystic duct, which, after passing backward, di-
lates into an oval ampulla to form the gall-blad-
der ; and the ductus choledochus as nothing
more than the continuation of the hepatic duct.
The direction of the ductus choledochus is, in
fact, the same as that of the hepatic duct, i. e.,
obliquely downward, a little to the right, and
backward : there is no line of demarcation be-
tween these two ducts : in the natural state
there is no marked difference in their diame-
ters : the ductus choledochus, when collapsed, is
about as large as a moderately-sized goosequill.
't The same causes give rise to dilatation of the
ductus choledochus and of the hepatic duct. I have seen the former as large as the duo-
denum. {Anat. Pathol, avec planches.) Its length is from two to two inches and a half
Relations. — In the first part of its course, before it reaches the duodenum, the ductus
choledechus is included in the gastro-hepatic omentum, in front of the vena portae, and
below the hepatic artery, having the right gastro-epiploic artery along its left side, and
surrounded by loose cellular tissue, a great number of lymphatic vessels, and several
lymphatic glands. Having reached the duodenum, opposite the first flexure of that in-
testine, it passes behind and to the inner side of its second portion, and is there received
into a groove, or, more commonly, into a complete canal, formed for it by the pancreas.
Lastly, it penetrates very obliquely into the substance of the duodenum, about the mid-
dle of its second or vertical portion, perforates the muscular coat, passes between that
and the fibrous coat, then between the fibrous coat and the mucous membrane, elevating
the latter when distended with bile or by a probe, and after a course of about seven or
eight lines between the coats, opens into the duodenum, about the lower part of the sec-
ond portion, at the summit of a nipple-like eminence (above c), which is more or less
prominent in different subjects.
In this third portion of its course the ductus choledochus is in relation with the pan-
creatic duct (m), which is situated on its left. Opposite the base of the eminence above-
mentioned, the two ducts unite, or, rather, the pancreatic duct opens into the ductus
choledochus ; so that, at its termination, the latter may be regarded as a canal having a
triple origin, viz., an hepatic, a cystic, and a pancreatict
Internal Surface of the Ductus Hepaticus and Ductus Choledochus. — ^The internal surface
of both the hepatic duct and the ductus choledochus is characterized by the absence of
valves, though traces of valves are occasionally met with in the ductus choledochus ;
by the absence of the alveolar structure observed in the gall-bladder ; and by having a
niultitude of openings or well-marked pores, which are considered as belonging to mu-
ciparous follicles, and are apparently formed by an interlacement of fasciculi, having a
fibrous character, and intersecting each other at very acute angles. The ductus chole-
dochus and the hepatic duct are of uniform caliber throughout their whole length. The
ductus choledochus is contracted a little in its third or duodenal portion ; it dilates into
an olive-shaped ampulla, opposite the base of the papilla in the duodenum, and opens by
an extremely small orifice or mouth : hence the reason why biliary calculi are so fre-
quently arrested in the ampulla of the ductus choledochus.
From the narrowness of the duodenal orifice of the ductus choledochus, from the mo-
* Another opinion, founded upon the existence of the valves, is that of Bachius, who, believing that he had
shown that the valves prevent the ascent of the bile from the hepatic duct into the gaU-i)ladder, has advanced
very singular views concerning the formation and uses of the bile. The bile, according to him, is formed in
the gall-bladder, and carried l)y the cystic duct into the hepatic duct and the ductus choledochus. By his
theory, the bile which reaches the liver through the hepatic duct assists greatly in sanguification. This opin-
ion, altogether erroneous as it is, has perhaps exercised a great influence in science, by contributing to eradi-
cate the idea of the bile being an acrid, corrosive, and essentially injurious excrementitial fluid.
t Hence the definition of SoDminering : " Ductus choledochus, id est, ductus hepaticus, cysticus, et pancreatir
cus, in unum conflati," — ICorpor. Hum. Fabric, tom.\i., p. 186.)
THE LIVER.
▼able or yielding nature of the eminence upon which it opens, and from the oblique course
of the duct through the substance of the walls of the duodenum, it follows that the bile
and the pancreatic fluid may pass freely from the ductus choledochus into the duodenum,
but cannot regurgitate from the duodenum into the duct. On this subject I have made
several experiments. I have forcibly injected both water and air into the duodenum,
included between two ligatures, but nothing entered into the biliary canals : on the other
hand, I have injected the same fluids from the gall-bladder into the duodenum, which I
was thus able to distend at pleasure. But then, on compressing the bowel thus distend-
ed with great force, I have never been able to cause the slightest reflux into the biliary
caneils.*
At the union of the cystic and hepatic ducts there is a very long spur-shaped process,
formed by the hning membrane reflected upon itself At the junction of the ductus cho-
ledochus and the pancreatic duct there is also a similar process, which I have seen ex-
tending down to the duodenal orifice. In neither situation do these processes prevent
the fluid of one canal from passing into the other. Thus, the cystic bile might flow back
into the hepatic duct, the pancreatic fluid might regurgitate into the ductus choledochus,
and, on the other hand, the bile might enter the pancreatic duct, if these canals were not
habitually full. Moreover, the spur-shaped process between the ductus choledochus and
the pancreatic canal cannot arrest the flow, either of the bile or the pancreatic fluid, by
being applied to the orifice of the one or other duct.
Structure of the Biliary Ducts. — ^AU the biliary ducts have a similar structure : they
have an internal mucous membrane, continuous on the one hand with the lining mem-
brane of the gall-bladder, and on the other with that of the duodenum ; it is thin, and
provided with slightly-developed papillae ;t a. proper membrane, composed of a dense are-
olar tissue, generally regarded as fibrous, but which appears to me analogous to the tis-
sue of the dartos condensed ; a cellular layer connecting these canals to the surrounding
parts ; and, lastly, the peritoneimi, which forms a very incomplete accessory tunic for
them.
Thus constituted, the biliary ducts have very thin walls, so that they collapse like
veins, and are extremely dilatable. In certain cases of retention of the bile we find the
ductus choledochus and the hepatic duct as large as the duodenum, the divisions of the
hepatic duct dilated in proportion, and the tissue of the liver more or less atrophied by
the compression to which it has been subjected.
Development of the Liver. — The development of the liver is one of the most important
subjects in its history. Under this head we have several points to consider :
1. The time of its appearance is anterior to that of any other organ :t in the first days
of intra-uterine life it may be distinguished by its colour in the midst of the ceUular mass
which represents the foetus.
2. In size the liver is relatively larger as it is examined at an earlier period of devel-
opment. Thus, according to Walter, in the embryo of three weeks it forms one half the
weight of the whole body. This enormous proportion is maintained during the first half
of intra-uterine life. After this period its growth is slower, while that of the other or-
gans is proportionally increased, so that at birth the weight of the liver is one eighteenth
that of the whole body.ij After birth the liver undergoes an absolute diminution ; some
authors have even affirmed that a comparison of the weight of the liver in new-bom in-
fants and in children of nine or ten months old, gives a difference of one fourth in favour
of the former. It is generally said that the difference in size affects the left rather than
the right lobe ; but this has not appeared evident to me. Towards the age of puberty
the liver has the same relative bulk as at later periods. Attempts have been made to
ascertain the proportion between the weight of this organ and that of the body, and it
has been said that it forms one thirty-sixth part of the whole body. But what relation
can be established between two terms, one of which, viz., the weight of the body, is
subject to continual variations 1 In old age the liver is smaller than in the Eidult, a dim-
inution apparently in unison with that which occurs in all the other organs.
3. The differences in the situation of the liver are connected with its variations in size :
thus, in the first half of intra-uterine life, the liver occupies the greatest part of the ab-
domen, and is in relation with certain regions in which it is not found at more advanced
stages. In the earUest periods it descends as low as the crest of the ilium, and when
the abdomen is opened it presents the appearance of a red mass, beneath which are
* How can this fact be reconciled with another no less incontestable, viz., the passage of lumbrici into the
biliary ducts 1 The reason is, that the lumbricus is a foreign body, which has a power of selection, and is able
to overcome an obstaCie, to seek for the orifice of the ductus choledochus, and to introduce itself within it.
t [Numerous follicles are found in the ductus communis and in the hepatic duct, and all its subdivisions ;
according to Mr. Kiernan, even in the smallest that can be examined. In the larger branches they are ar-
ranged irregularly; in the smaller ones, in two longitudinal rows, along opposite sides of the duct.]
t [In the embryo of the bird the liver is developed by a conical protrusion of the walls of the intestinal ca-
nal into a granular mass or blastema. — (See Milller^s Phys. by Baly, p. 448.) The rudiments of the cerebro-
gpinal axis, of the heart, and of the intestinal canal, appear previously to the liver.]
f) I have had occasion to notice, at the Matemite, the very great differences in the size of the liver in in-
fants at birth, for which I have been unable to find any sufficient reason. There ai'.' some well-formed in
fauts in whom the liver at birth is not relatively larger than that of adults
400 SPLANCHNOLOGY.
placed the other abdominal viscera. During the second half of intra-uterine life, and at
birth, it occupies only a part of the abdomen ; but it still corresponds to a considerable
extent of the abdominal parietes : hence the ease with which it is ruptured by pressure
upon the abdomen of a new-born infant. One fact on record seemed to me to prove,
that in a first labour, where the feet presented, the pressure of the genital organs of the
mother was S'ufficient to produce this result. — (Vide Proces-verbal de la Distribution des
Prix de la Maternite, 1832.)
In the eariiest periods the falciform ligament of the liver corresponds to the median
line of the body ; at birth it is a little to the right of that line, and is afterward removed
still farther in the same direction.
4. The great size of the liver during intra-uterine life is connected with the existence
of the umbilical vein, by which the foetus receives the blood returned from the placenta,
that is to say, all the blood necessary for its nutrition. The rapid diminution of the
liver after birth is probably owing to the obliteration of this vein. It is a very remark-
able fact, that the persistence of this vein in the adult is not accompanied by an unusu-
ally large liver. In one particular case of persistence of the umbilical vein the liver was
of a very small size. — {Anat. Path, avec planches, liv. xvii.)
5. The tissue of the liver of the foetus is of a pale red colour in the early periods, and
of a deep brown near the full term of pregnancy ; its colour becomes lighter after birth.
The liver contains a greater quantity of blood before than after birth. Its tissue is the
less consistent the earlier the stage of development at which we examine it, and its soft-
ness is accompanied with great fragility.
6. The distinction between what are called the two substances of the liver is not ap-
preciable during intra-uterine life. It only becomes apparent after birth.
Functions. — The liver is the secreting organ of the bile. The bile is secreted in the
glandular granules by an unknown process. Doubts are stiU entertained as to whether
the materials from which the secretion is formed are conveyed by the hepatic artery or
the vena portae.* The opinion advanced by some modern authors, that the yellow sub-
stance of the liver is the only part concerned in the secretion of the bile, and that the
brown substance has other uses, is a purely gratuitous hypothesis.
The bile traverses the several ramifications of the hepatic duct, and, having arrived in
the principal duct, it may either enter directly into the duodenum by the ductus chole-
dochus, or it may pass into the gall-bladder by the cystic duct. This retrograde move-
ment towards the gall-bladder has much occupied the attention of physiologists : perhaps
it may be explained by the narrowness of the duodenal orifice of the ductus choledochus,
by the elasticity of that canal, and especially by the pressure exercised on its duodenal
portion by the circular fibres of the duodenum. The gall-bladder and the cystic duct are
not indispensable to the elimination of the bile. Nothing is more common than to find
the excretory apparatus of the liver in old subjects reduced to the hepatic duct and the
ductus choledochus.
Has the liver any other function besides that of secreting bile 1 The disproportion ex-
isting between the size of that organ and of its excretory apparatus, and also the enor-
mous bulk of the liver during foetal life, i. e., at a time when the secretion of bile is at
its minimum of activity, are both in favour of the opinion that the liver has some addi-
tional function ; and if, again, we consider that, in the adult, a very important system of
veins is distributed to the liver, and that in the foetus it receives the blood from the veins
of the foetal portion of the placenta, we shall be led to presmne that the unknown func-
tions of this organ are in some way connected with the process of sanguification.
The Pancreas.
Dissection. — The pancreas may be seen through the gastro-hepatic omentum, after
drawing down the stomach, without any dissection. In order to expose it, turn the
stomach upward (see fig. 154) after having divided the two layers of peritoneum which
proceed from its greater curvature to form the great omentum. It may also be ex-
posed by turning the arch of the colon upward, and dividing the inferior layer of the
transverse mesocolon. The excretory duct is situated in the interior of the organ. In
order to dissect it, the glandular substance which covers it must be very carefully re-
moved towards tlie middle and the right extremity of the gland. It may be injected from
the ductus choledochus, after the vertical portion of the duodenum has been included be-
tween two ligatures : when the duodenum is filled with the injection, the pancreatic duct
becomes filled in its turn. It may also be injected from the ductus choledochus after hav-
ing passed a ligature round the projection or ampulla which is common to the two ducts.
The -pancreas {Trdv-Kpeag, all flesh) is a glandular organ annexed to the duodenum, with
which it has immediate relations : it is situated transversely and deeply behind the stom-
ach, and in front of the lumbar vertebrae.
* [From the researches of Mr. Kiernan (see note p. 395), it would appear that the blood of the vena ports is
directly concerned in the secretion of the l)ile, while that of the hepatic artery is only indirectly concerned,
i. e., after it has afforded nutrition to the tissue and vessels of the liver, and has entered the branches of the
■'•ena portae, and thus become portal blood.]
THE PANCREAS. 401
Form and Size. — In form, the pancreas resembles no other gland ; it is transversely
oblong, flattened from before backward, large at its right extremity, where it presents a
sort of angular expansion like a hammer, and gradually tapering towards its left extrem-
ity: hence the division of this organ into a head, body, and tail. Its long or transverse
diameter is measured by the interval between the concavity of the duodenmn (e e) and
the spleen (A). The size and weight of the pancreas present many varieties. Its weight
is generally from two to two and a half ounces, but may reach six ounces. The pan-
creas is sometimes found atrophied, and in one case of this kind it did not exceed an
ounce in weight.
Relations. — Its anterior surface, convex and covered by the peritoneum, is in relation
with the stomach, which moves freely upon it. In certain cases of disease, adhesion
between the pancreas and the stomach takes place, so that in chronic ulceration of the
latter we find the pancreas supplying the place of large portions of the walls of the stom-
ach which had been destroyed. When the stomach is situated lower down than usual,
the pancreas has relations either with the liver or with the anterior walls of the abdo-
men, from which it is separated only by the gastro-hepatic omentum, so that it may be
felt with the greatest ease through the abdominal parietes.* In such cases, even expe-
rienced practitioners have not unfrequently been led to infer the presence of scirrhus of
the pylorus. The pancreas is also in relation, in front, with the first portion of the duo-
denum, and with the angle formed by the ascending and transverse colon.
Its posterior surface is concave, and corresponds to the vertebral column, opposite the
first lumbar vertebra ; it is separated from the spine, however, by the splenic and the
superior mesenteric veins, and by the commencement of the vena portae. The two last-
mentioned veins are lodged in a deep groove, or, rather, almost complete canal, formed in
the pancreas, which also includes the superior mesenteric artery and its surrounding
plexus of nerves. A great number of lymphatic vessels and glands, the pillars of the
diaphragm (d d), the vena cava on the right side, and the aorta on the left, also separate
the pancreas from the vertebral column. To the left of the spine it is in relation vrith
the left supra-renal capsule and kidney, and the corresponding renal vessels. The rela-
tion of the pancreas to the aorta is important ; it is through the pancreas that the pulsa-
tions of that vessel are felt in the epigastrium in emaciated individuals, and it is here
that the vessel may be compressed.
Its upper border is thick, and is grooved for the reception of the splenic artery, which
often runs in a sort of hollow canal formed in the substance of the gland through its en-
tire length. It also has relations with the first portion of the duodenum (e), with the
lobulus Spigelii, and with the coeUac axis (<). The thickness of this border has led some
anatomists to say that the pancreas is prismatic and triangular.
Its lower border is much tliinner than the upper, and is bounded by the third portion of
the duodenum, from which it is separated on the left by the superior mesenteric vessels
{rOf the artery).
Its right, or duodenal, or great extremity is in contact with the duodenum and the duc-
tus choledochus. This extremity presents a very remarkable arrangement ; it is curv-
ed upon itself from above downward, like the duodenum, by the concavity of which it is
circumscribed ; then, having reached the third portion of the bowel, it passes transverse-
ly to the left, behind the superior mesenteric vessels, and forms the posterior wall of
the canal in which they are situated. This reflected portion, arranged in the form of
a whorl, is sometimes detached from the rest of the gland, on which account it has been
called the lesser pancreas. By its great extremity the pancreas is, as it were, attached
to the duodenum, beyond which it projects in front, but especially behind : it accompa-
nies this intestine in all its displacements, so that when the duodenum is situated lower
down than usual, which happens in displacements of the stomach downward, the head
of the pancreas is always removed in the same direction.
Its left, or splenic, or small extremity is narrow, and touches the spleen, upon which it
is flattened and blunted, and sometimes slightly enlarged. It is seen, then, that in its
relations to other parts, the pancreas has a great analogy with the salivary glands. Thus,
large vessels are situated near and penetrate this gland, which forms a sort of covered
passage for them, and is moved by their pulsations. The diaphragm, the duodenum, and
the stomach, also tend to disturb and press upon the pancreas.
Structure. — The analogies in structure between the pancreas and the salivary glands
are no less numerous, and fully justify the name of abdominal salivary gland given to it
by Siebold : it has the same whitish colour, the same density, t and the same arrange-
ment into lobes, which are themselves divisible into lobules. The identity is such that
it would be impossible to distinguish a portion of the pancreas from a part of a salivary
* This condition may be foretold : it occurs whenever the vertebral column can be felt immediately behind
the parietes of the abdomen. I have never met with it excepting in emaciated individuals, where a great
part of the small intestine occupied the cavity of the pelvis. It is probably the traction exercised by the small
intestine contained in the pelvis that occasions the low position of the stomach.
t The pancreas sometimes assumes an extreme density, strongly resembling that of scirrhus. In such a
case it is necessary to make sections of it, to be assured of the perfect soundness of the glandular tissue. This
stony hardness generally occurs along with atrophy of the organ
Ee E
ii402 Sl'LANCHNOLOCfY.
gland. Wlicn boiled, they both have the same aspect and the same taste. There is no
fibrous capsule, properly so called, but some fibrous lamellae, which separate the lobes
and lobules. Cellular tissue is tolerably abundant. Fat is not uncommonly met with,
either on the surface or in tlie substance of the pancreas ; I have even seen cases of atro-
phy of the gland, in which fat appeared to have been substituted for the glandular substance.
The determination of the structure of the pancreas, like that of all glands, involves two
considerations, viz., the texture of each lobule, and the arrangement of the vessels and
nerves in the substance of the gland. With regard to the first point, I shall merely re-
fer to what has been already stated respecting the salivary glands.* The arrangement
of the vessels is perfectly well known.
As in the salivary glands, the arteries enter the pancreas at a great number of points.
They are very numerous and very large, considering the small size of the organ : they
arise from the hepatic, the splenic, and the superior mesenteric. The principal arterj"
is called the pancreatico-duodenalis.
The veins terminate in the superior mesenteric and the splenic. The lymphatic vessels
are not well known ; it is probable that they enter the numerous glands which are in the
neighbourhood. The nerves of the pancreas are derived from the solar plexus.
The excretory duct {u,fig. 169) is called the canal of Wirsung, from the name of its dis-
coverer, a young anatomist, who was too soon lost to science. By an arrangement, of
which we have no other example in the body, this excretory duct is contained entirely
in the substance, we might even say, in the centre of the gland ; so that, in order to ex-
pose it, the superficial portion of the organ must be carefully divided. It is generally
single, but sometimes double, and then there is a principal duct belonging to the body of
the pancreas, and a small duct for the reflected portion, or lesser pancreas. The pan-
creatic duct measures the entire length of the gland ; it is narrow at the splenic extrem-
ity, which may be regarded as its origin, and gradually increases in size as it approach-
es the duodenal extremity ; there it bends downward, to reach the ductus choledochus,
to the left of which it is placed ; it runs along the side of that duct, then perforates it ob-
liquely, and opens, as I have already described when speaking of the liver, in the olive-
shaped ampulla immediately preceding the duodenal orifice of the ductus choledochus.
It follows, therefore, that the pancreatic duct and the ductus choledochus open by a com-
mon orifice in the human subject. This arrangement is constant, and, when we find a
pancreatic duct perforating the duodenum separately, we may be certain that there is
another duct presenting the regular arrangement ; at least, I have never observed to the
contrary. As to the precise situation of the separate opening of the supernumerary pan-
creatic duct, it may be either in front of, behind, below, or above, the orifice of the duc-
tus choledochus. Tiedemann, who has collected all the known cases of double pancre-
atic duct, and all the varieties of insertion found in the human subject, has arrived at the
curious result, that these varieties have their analogies in the different species of animals.
The mode in which the divisions of the pancreatic duct are inserted into the principal
trunk deserves to be noticed. The ultimate ducts of the pancreas do not, in fact, unite
into larger and larger branches, like the veins, but the small branches coming from each
lobule cpen directly, and in succession, into the general duct : an arrangement which
gives to the excretory apparatus of the pancreas the appearance of those insects called
centipedes.
As to the structure of the pancreatic duct, its walls are very thin ; it is collapsed, and
of a milk-white colour, very distinct from the grayish- white hue of the proper tissue of
the gland. Its internal surface is extremely smooth, like a serous membrane ; t its thin-
ness renders the determination of its texture very difficult ; it is very extensible.
Development. — The development of the pancreas presents no peculiarities excepting
such as relate to its size, which is relatively greater in the foetus and the new-born in-
fant than in the adult. Examples have occurred of disease of the pancreas during intra-
uterine life ; and I have found a scirrhous pancreas in a foetus at the full term.
Function. — The pancreas is the secreting organ of a particular fluid called the pancre-
atic fluid, the physical and chemical characters of which have not been well known until
very lately. I have met with two cases of retention of the pancreatic fluid. The dila-
ted canal resembled a transparent serous cyst ; the contained liquid was extremely vis-
cid and transparent, but of a whitish hue, like a solution of gum-arabic ; it had a slight-
ly saline taste ; the collateral ducts were extremely dilated. There were some white
patches, resembling plaster, in the centre of many of the lobules. This substance was
more abundant in some of the lobules, and, when removed, presented the appearance of
small lumps of plaster or chalk. The pancreatic fluid submitted to chemical analysis by
M. Barruel proved to be an extremely pure mucus. M. Barruel even stated to me that
it was the purest mucus he had ever examined. It possesses in the highest degree the
* [The only obsen'able difference between the lobules of the pancreas and salivary glands is, that the closed
tenninatiou of the ducts are cylindrical in the former, and slightly dilated in the latter (see note, p. 341).]
t lit is a mucous membrane, continuous with that of the duodenum, and covered with epithelium. In some
subjects, Mr. Kiernan found mucous follicles in it, similar to those in tlie biliary ducts ; in others, no traces of
them could be discovered. None were seen in the salivary ducts.]
THE SPLEEN. 460
property of rendering water viscyi, either by dissolving, or by being diffused in it. This
mucus contains free soda, a trace of chloride of sodium, and a very slight trace of phos-
phate of lime. There is, therefore, an analogy belvi^een the pancreatic and salivary fluids,
as the anatomical investigation of these glands had previously led us to suppose.*
The Spleen.
The spleen {aizTiriv, lien ; k,fig. 154) is a spongy and vascular organ, the functions of
which, though little known, appear to be connected with those of the abdominal venous
system.
It is deeply situated {k,figs. 155, 161) in the left hypochondrium, behind and to the
left of the great end of the stomach, to which it is united by a fold of peritoneum, called
the gastro-splenic omentum. It is also retained in its place by the peritoneum, which is
reflected upon it from the diaphragm,! and by the vessels which enter and pass out from
it. Being suspended rather than fixed to certain movable parts, the spleen necessarily
participates in their movements ; and the contraction or relaxation of the diaphragm, as
well as the alternate distension and collapse of the stomach, exert an undoubted influ-
ence upon it ; but these slight and temporary changes of position do not constitute a
true displacement.
It may even be said that displacements of the spleen, which are very rare, are almost
always congenital. Thus, Haller has seen this organ situated at the left side of the
bladder, in an infant one year old ; Desault has found it in the right cavity of the thorax
in a foetus at the full time. I do not here allude to cases of complete transposition of
the viscera, nor to cases where the change of situation depends on enlargement of the
spleen, or on displacement of the stomach, t I have mentioned elsewhere that I have
found the spleen in the umbilical region.
Accidental adhesions of the spleen are so frequent that they deserve to be mentioned.
They are sometimes filamentous, and sometimes cellular, and they render painful the
slightest changes of position in this organ, from violent contractions of the diaphragm,
or from great distension of the stomach : these adhesions are almost always the sequelae
of intermittent fevers.
Number. — ^The spleen is single in the human subject. The supernumerary spleens oc-
casionally met with near it are nothing more than small ovoid or spheroidal fragments
of the spleen, which at first sight might be taken for lymphatic glands. I have never
seen more than two supernumerary spleens in man. It is said that they are more fre-
quent in the fcetus than in the adult : this opinion is erroneous. § It has been said that
ten, twelve, and even twenty-three supernumerary spleens have been observed. With-
out denying the possibility of the fact, I am inclined to doubt its occurrence. As the
spleen is always multiple in a great number of animals, supernumerary spleens in man
may be regarded as the last trace of such an arrangement.
With regard to the examples of congenital or accidental absence of the spleen men-
tioned by some authors, it should be remarked, that they were accompanied with se-
rious diseases of the abdomen, and that small adherent spleens, lost in some measure
among the surrounding organs, may easily have escaped notice in a not very close ex-
amination.
Size and Weight. — There is no organ which varies more than the spleen in regard to
size and weight. These differences may be referred to the following heads :
Individual Differences. — It is in vain to attempt to establish a relation between the
size of the spleen and that of the liver, or between the size of the spleen and the stature,
weight, constitution, and habits of the individual.il
Differences from Physiological Conditions. — The spleen is often found small, wrinkled,
shrunk, or, as it were, withered and collapsed ; a state that certainly supposes the op-
posite condition of distension. In other cases the spleen is large, and looks as if it
were stretched. Ought we, then, to admit, with Lieutaud,1F that the pressure from the
* [According to the best analyses, the pancreatic fluid differs from saliva in containinsr a greater amount
of solid matter, and also in the character of its constituents : saliva is usually alkaline, and, besides other sub-
stances, contains salivine, mucus, and sidpho-cyanate of potassa ; the pancreatic fluid contains albumen, ca-
sein, but little salivine and mucus, and no sulpho-cyanate ; in other respects the two fluids agree.]
t [This reflection is called the ligamentum phrenico-lienale. The spleen is also connected by the peritic
Ileum to the arch of the colon.]
i The great end of the stomach is the most fixed part of that viscus, on account of its connexion with the
CBSophagus. Changes of position in this organ affect partly the portion between the pylorus and the cardia,
and partly the pylorus itself.
() It is true that a greater number of cases of supernumerary spleens in the fcetus have been recorded than
in adults; but the fact is easily explained, if we consider that in the fcetus supernumerary spleens cannot
escape notice, while they are often diflicult to be seen in the adult, on account of the fat with whicli the
omenta are loaded.
II The spleen is proportionally larger in man than in the lower animals. It has been said, as if it were pos-
sible to establish a relation between two such variable terms as the weight of the spleen and the body, that
the former is i^^ th of the latter.
% Lieutaudasserts that he has constantly found the spleen larger when death has occurred while digestion
was going on in the stomach than when it has happened after that process had been completed ; but the
spleen varies so much in size that we cannot compare the spleen of one subject with that of another. An in-
genious experiment has been made, the re.sult of which is opposed to Lieutaud's opinion : out of four newly-
404 SPLANCHNOLOGY.
distended state of the stomach during digestion diminishes the size of the spleen, which,
on the other hand, becomes the seat of an afflux of blood in the intervals between the
occurrence of that process. This idea is, perhaps, erroneous as far as regards the pe-
riods of collapse and turgescence ; but it is correct as to the principal fact, viz., the al-
ternation of those two opposite conditions.
Differences from Age. — The spleen is proportionally smaller in the foetus than in the
adult, and in the adult than in the aged.
Differetices from Disease. — The morbid differences in the size of the spleen suggest
most important considerations. In a great number of patients suffering with intermit
tent fevers, more especially when this organ is already enlarged from previous attacks,
it is manifestly swollen during each access. Hypertrophy of the spleen may proceed to
an extraordinary extent ; so that this organ, which, in the natural condition, is with-
drawn so deeply into the left hypochondrium as not to be seen on opening the abdomen,
in certain cases fills almost the whole of the abdominal cavity ; while its weight, which
varies from two to eight ounces in the healthy condition, may be as much as ten, twen-
ty, or thirty pounds ; one case, indeed, has been recorded where the spleen weighed
forty-three pounds.
Atrophy of the spleen is very rare. I have seen it reduced to the weight of two
drachms.
The specific gravity of the spleen is, to that of water, as 1160 to 1000.
The spleen, both upon the surface and in the interior, most commonly resembles in
colour the dark lees of wine. This colour, however, presents many varieties from a
deep-brown red to a pale gray. When the surface has been some time exposed to the
air, it becomes bright red, like the surface of venous blood soon after its abstraction.
Age, the kind of death, and diseases, have much effect on the colour of this organ, the
different parts of which are not always of a uniform tint. I have seen a spleen of a
deep chestnut-brown hue.
Consistence. — One character of the tissue of the spleen is its extreme friability. In
general it may be lacerated by the pressure of the finger, to which it communicates a
feeling of crepitation, and emits a sound like the crackling produced by bending tin.
The spleen may be regarded as the most friable of all organs excepting the brain. Thus,
examples have been recorded of its laceration from blows, or falls upon the abdomen,
and even from a general concussion, or from the contraction of the diaphragm and ab-
dominal muscles during violent exertion, &c.
The consistence of the spleen also varies much in different individuals, and in dis-
eases ; indeed, the most important alterations of this organ may be referred to either
increased or diminished consistence. In induration, which is generally accompanied
with hypertrophy, the tissue of the spleen is compact, brittle, and dry, and breaks like a
piece of compact resin. In softening, carried to its highest degree, the spleen is con-
verted into an inorganic pulp, exactly resembling a healthy spleen broken down by the
fingers, and containing a greater quantity of fluid than natural. This state is often ob-
served after malignant fevers,* and when the membranes are torn, the substance of the
spleen escapes spontaneously.
Figure. — The spleen has a crescentic form ; its long diameter is vertical, its concavity
directed to the right, and its convexity to the left side. It may be compared, as was
done by Haller, to a segment of an ellipse cut longitudinally.
It presents for consideration an external and an internal surface, and a circumference.
The external or costal surface is convex, smooth, and in relation with the diaphragm,
which separates it from the ninth, tenth, and eleventh ribs ;t hence arises the influence
of contractions of the diaphragm upon the spleen, and the possibility of its being rup-
tured during a violent effort. This relation also accounts for tlie pain felt in the region
of the spleen after quick running, and the difficulty and pain attendant on a strong inspi-
ration made while running by persons in whom the spleen is hypertrophied.
We frequently find a prolongation of the liver almost completely covering the external
surface of the spleen.
The internal or gastric surface is concave in all directions, and presents, at the junc-
tion of the two anterior thirds with the posterior, a somewhat irregular series of open-
ings, which are themselves irregular in form and number, are situated at greater or less
intervals, and arranged longitudinally. This row of openings is called XYve fissure, or hi-
lus {h,fig. 154) of the spleen. The gastro-splenic omentum is attached near this fissure.
Some varieties are observed in the arrangement of the internal surface of the spleen.
Thus, it sometimes presents a uniform concavity, and sometimes there is a sort of
projecting ridge opposite the hilus, which divides it into two unequal parts, one anterior
bom puppies, belonging to the same litter, two were kept witbout food, while to the other two milk was
given ; on killing them, their spleens were all found of the same size.
* Vide Anat. Path, avec Planches, liv. ii., art. Maladies de la Rate. I have been able to collect tho
splenic fluid in a medicine vial, and to submit it to different experiments.
t It is said that the ribs produce marks upon the spleen from the pressure exercised by them upon it during
life. 1 have never observed this appearance, and can only conceive it to exist in cases of hypertrophy of the
spleen.
THE SPLEEN. 405
and larger, the other posterior and smaller : in the latter case, which is common, the
spleen is of a prismatic and triangular form.
The following are the relations of the internal surface : the part situated in front of
the hilus has relations with the great cul-de-sac of the stomach, and, on the right and
behind this cul-de-sac, with the gastro-splenic omentum and the vasa brevia situated
within it : the left extremity of the liver, which, as we have seen occasionally, covers
the external surface of the spleen, is more frequently in relation with the internal sur-
face of that organ. Behind the hilus the spleen corresponds with the left kidney, supra
renal capsule, and pillar of the diaphragm, which separate it from the spine, and with the
small extremity of the pancreas.
The circumferenc is elliptical ; its posterior border is thicker above than below, and is
in relation with the kidney, which it sometimes covers through its entire length ; its an-
terior border is thinner, and is applied to the stomach ; its upper extremity is thick, often
bent upon itself, and in contact with the diaphragm, from which, however, it is occasion-
ally separated by the liver ; its inferior extremity is pointed, and rests upon the angle
formed by the transverse and descending colon, or upon the portion of transverse meso-
colon which supports that angle. The circumference of the spleen is notched, and
sometimes marked more or less deeply by fissures, which are prolonged upon both its
surfaces, particularly upon the external surface, and which divide it into a greater or less
number of distinct lobules. This lobular arrangement is the last indication of the mul-
tiple spleens, of which we have already spoken. The description of the relations just
given applies when the stomach is empty ; when that viscus is distended, they are some-
what different. The spleen, which before was separated from the stomach by the gas-
tro-splenic omentum, is then applied directly to it, and is moulded upon it, so, as it were,
to cover its walls. It has no longer any relations with the kidney and the vertebral column,
but is situated below and behind the great cul-de-sac of the stomach, and not to the left
of it ; and it becomes horizontal instead of being vertical, as when the stomach is empty.
Structure. — Besides two investing membranes, one serous, the other fibrous,* the
spleen consists of cells having fibrous parietes, and filled with a grumous fluid,t of the
colour of port wine dregs, of certain corpuscules not very distinct in the hirnian subject,
of a very large artery and still larger vein, and of lymphatic vessels and nerves.
The serous or peritoneal coat invests the whole spleen, with the exception of the hilus,
which corresponds to the gastro-splenic omentum. It gives a smooth appearance to the
spleen, lubricates its surface, and, at the same time, fixes it to the neighbouring parts by
the bands which it forms. Its internal surface adheres closely to the fibrous membrane.
The proper coat of the spleen forms a sort of fibrous shell, which is strong, notwith-
standing its tenuity and transparency. This membrane is the seat of those cartilaginous
plates which are so often found upon its surface, and which conceal its true colour. It
is intimately united to the peritoneal membrane by its outer surface, and adheres still
more closely by its inner surface to the tissue of the spleen by means of exceedingly nu-
merous and dense fibrous prolongations, which penetrate it in all directions, and inter-
lace in every way, so as to form areolae or cells, the arrangement of which \fre shall here-
after examine. Farther, the proper coat is not perforated at the hilus for the passage of
the vessels, but by an arrangement similar to that already noticed in the liver, it is re-
flected around the vessels opposite the hilus, like the capsule of Glisson, and is prolong-
ed upon both the arteries and veins, forming sheaths which divide and subdivide like the
vessels themselves, and receive the prolongations given off" from the inner surface of the
proper coat.
This arrangement has been very well described by Delasonne {Mim. Acad, des Scien-
ces, 1754), and especially by Dupuytren (Thise de M. Assolant). It follows, therefore,
that the basis of the spleen is composed of a fibrous structure, consisting of an investing
fibrous membrane, of fibrous sheaths which accompany the vessels in their divisions and
subdivisions, even to their terminations, and of prolongations arising from the inner sur-
face of the membrane, interlacing in all directions, and attached to the outer surface of
the sheaths.J
The internal framework of the spleen is therefore an areolar tissue, which may be
very well displayed by washing away the pulpy matter of this viscus by means of a stream
of water ; there will then remain a whitish areolar and spongy tissue. This is also very
clearly shown by injecting it either with mercury or some coloured liquid, or even by in-
flating it with air blown through a puncture. The coats are then raised in different pla-
ces, and after desiccation, the areolar structure becomes evident. This experiment also
shows that the spleen is divided into a number of compartments, for, without rupture,
only a small portion of the organ can be injected in this way.
It appears, then, that the proper tissue of the spleen is composed of an areolar fibrous
* See note, infra. t See Bote, p. 406.
t [This basis or framework is more or less developed in the different species of animals : it is much stronger
in the horse than in the ox. The proper coat of the spleen, together with the sheaths for the vessels, and the
prolongations or trabcculae given off from it, are highly elastic, and are generally »tated to consist of yellow
elastic tissue, not of ordinary fibrous tissue.]
^6 SPLAI^dHNOLOGY.
network, and of a pultaeeous matter, gf the colour of port wine lees — ^the splenic juice or
matter, regarded by the anciepts as one of the fundamental humours of the body, called
atra bills, and which modern Aemists have not yet sufficiently examined.
We have now to determine the arrangement of the cells, and the relation between
these cells and the arteries, veins, and nerves.
The Splenic Artery. — No organ of so small a size receives so large an artery. The
splenic artery is, in fact, the largest branch of the cceliac axis, and, on this account, rup-
tures or wounds of the spleen are almost always followed by fatal hemorrhage. It is
also remarkable for its tortuous course ; when reduced to half its original size, from hav-
ing given off several branches, it enters the spleen by four or five branches at greater or
less distances from each other. These branches divide in the usual manner in the sub-
stance of the organ, and preserve their tortuous character even to their terminations.
One peculiarity well worthy of attention is, that the arteries constantly divide in a ra-
diating manner, so that air, or water, or tallow, thrown into one arterial division, does
not pass into the branches of the others. This mode of division is observed not only in
the larger, but also in the smaller arteries,* so that the spleen may be considered as an
aggregate of a considerable number of small spleens, united together by a common in-
vestment ; and accordingly, if in a living animal one division of the splenic artery be tied,
the portion of the spleen to which it is distributed becomes blighted, while the rest re-
mains in the natural state. This arrangement of the arteries may be shown in a very
striking manner by injecting their several divisions with differently-coloured substances.
The injected matters will not mix, and the line of demarcation between the lobes will
become evident.
This structure explains how multiple spleens may occur in man and the lower animals,
and why there are so many varieties in this respect in the animal series.
Some branches from the splenic, lumbar, and spermatic arteries enter the spleen
through the folds of the peritoneum.
The splenic vein is four or five times larger than the artery : it forms one of the prin-
cipal roots of the vena portae, and is almost equal to the other root formed by the supe-
rior mesenteric vein. The venous communication between the spleen and the liver has,
in a great measure, given rise to the opinion that they are connected in function. The
spleen is filled by the numberless and large divisions of this vein ; it might even be said
that the texture of the spleen is essentially venous, that it is composed of a venous
plexus or an erectile tissue, and that it bears the same relation to the veins that the
lymphatic glands do to the lymphatic vessels. All the splenic cells communicate with
the veins, or, rather, they are nothing more than these veins themselves, supported by the
fibrous columns and sheaths already described : this is shown by the following consider-
ations and experiments :
1. If, according to the example of Delasonne,t we examine the spleen of the ox by lay-
ing open the splenic veins and their divisions by means of a grooved director, we shall
find that these veins are almost immediately reduced to their lining membrane, and per-
forated with very distinctly formed foramina, through which the dark reddish-brown sple-
nic matter is visible. These foramina soon become so numerous, that the veins are con-
verted into cavities or cells, the walls of which are perforated with openings of various
sizes, filled with the splenic pulp. This arrangement, which is most manifest under
water, proves that the tissue of the spleen is composed of venous cells,t like the corpo-
ra cavernosa of the penis. In man, the horse, and the dog, the great veins are not per-
forated with foramina, but the cellular and areolar arrangement of the splenic v^ins, at
a certain depth, is not less manifest.
2. If we inject the splenic artery, the spleen will become very slightly increased in
bulk at first, i. c, as long as the injected matter does not pass into the venous system ;
but as soon as this occurs, and it does so readily, the increase in size becomes rapid : it
follows, therefore, that the communication between the artery and the splenic cells is
indirect."^ On the other hand, if we inject the vein, the cells are immediately dilated,
and the spleen becomes prodigiously increased in bulk : it is easy to perceive that the
communication is direct, and that the venous system, in some measure, forms the basis
of this organ.
We can very seldom meet with a human spleen sufl5ciently healthy for the following
experiment. It will succeed perfectly with the spleen of a horse, which is of a much
denser structure. The spleen ought, in the first place, to be freed from the liquid which
it contains ; this must be accomplished by forcing water into the splenic artery. The
* [The minute arteries ramify in tufts orpenicilli.]
t Delasonne has described the structure of the spleen in the ox as belonging to the human subject.
t [According to Mr. Kiernan, these venous cells are lateral dilatations, which communicate with the venous
trunk by small branches. They contain only blood, however, for the red pulpy matter of the spleen is said by
Miiller to be external to, and not within them. This red substance consists principally of red granules, about
the size of the blood-globules, but spherical, not flattened.] ■
t) It has been erroneously asserted that the communication between the artery and vein is more direct
in the .spleen than in any other organ. The great anastamoses, visible to the naked eye, between the splenic
artery and vein, admitted by Spigelius, Diemerbroeck, Bartholin, and others, are purely imaginary. The pre-
cise mode of communication is still unknown.
THE SPLEEN. 407
water will return by the veins, at first turbid, then merely tinged, and at last limpid and
pure.* I have in vain attempted to force the injection from the veins into the arteries.
After the water, air should be blown into the artery, so as to empty the spleen as much
as possible of any liquid which it may contain.
If we examine a spleen thus freed of its contained matter, we observe that it is wrin-
kled, and, as it were, shrivelled on the surface, and remarkably diminished in bulk ; and,
on making a section of it, we find a white, spongy tissue, composed of laminae or fibres,
interlacing in every direction.
The following preparationt exhibits this structure most fully : The spleen of a horse,
prepared in the way I have indicated above, and weighing one pound, could receive ten
pounds of tallow. Tlie injection was thrown in by the veins : at each stroke of the pis-
ton, the spleen swelled up readily, an evident proof that the splenic cells communicate
directly with the veins ; while, in order to obtain the same effect by injecting through
the arteries, very considerable force was required. The injection of the spleen by the
veins did not take place in a uniform manner, but successively ; in one injection, the
upper part was injected before the lower, and the anterior border before the posterior.
The independence of different portions of the spleen on each other exists in regard to
their veins as well as their arteries. I have been enabled to observe the resistance of-
fered by the tissue of the spleen to the distending power ; a resistance which caused
the injection to flow back whenever the impelhng force was discontinued. The cells
are extensible to a certain degree, beyond which they resist very powerfully ; it does
not appear that they possess any elasticity.J
After some days, when desiccation was complete, the spleen thus injected was divided
into several portions, which were then immersed in spirits of turpentine moderately heat-
ed. The tallow, by which all the cells were distended, and which had taken the place
of their contents, having been dissolved out, the sections presented a spongy, areolar
structure, like that of erectile tissue, as found in the corpora cavernosa, or the substance
of the placenta : and this cannot be considered, as Meckel would have it, as the artificial
result of the insufflation and injection, which lacerate, as he believes, a part of the ves-
sels and fibrous tissue. — (Manuel d' Anatomic, t. iii., p. 479.) This spongy cellular struc-
ture explains why the spleen, as well as the corpora cavernosa, is susceptible of such
great variations in bulk ; and why it is sometimes found collapsed and wrinkled, and
sometimes distended, and, as it were, swollen. Are the splenic cells lined by the inter-
nal membrane of the veins T if so, the membrane is so thin as to be incapable of dem-
onstration.
Corpuscles of the Spleen. — Malpighi described, as existing in the spleen, certain cor-
puscles, regarded by him as the principal elements in this organ, and believed by him to
effect some important changes in the splenic bloodt These corpuscles, which Ruysch
considered to be essentially vascular, have been again brought into notice by Dela-
sonne, who demonstrated them by maceration. Haller denied their glandular nature,
because, as he said, there can be no glands where there is no secretion and no ex-
cretory ducts. The question is not, however, whether these corpuscles are glands or
not, but rather whether they exist at all. It is certain that, in many animals, in the dog
and the cat, for example, a great number of granules may be seen scattered through the
spleen, and which, according to a calculation, the accuracy of which I do not guarantee,
would seem to form two fifths of the weight of the organ. These corpuscles are soft,
whitish or reddish, and vary in diameter from a fourth of a line to a line. They do not
appear to me to exist in man.^
The lymphatic vessels of t^e spleen are divided into the superficial and deep. The su-
perficial only are well known ; a certain number pass from the spleen to the stomach ;
they all terminate in lymphatic glands situated opposite the hilus, within the layers of
the gastro-splenic omentum.
* This injection, which requires considerable force, continued without interruption for a long time, occa-
sions an exudation of a perfectly transparent fluid upon the surface of the spleen, even when water returned
by the vein is stiU turbid. Here we have an imitation of an exhalant process. And, as this transudation takes
place without Tupture, it is evident that there are a set of vessels by which it is effected.* Instead of making
an injection, which is always troublesome, we may attach the splenic artery to a tube, which is itself adapted
to another tube, running from the bottom of a cistern ; the column of water will overcome the resistance offered
to its passage from the arteries into the veins, and in twenty-four hours it will pass through perfectly limpid.
t This mode of preparation was suggested to me by the plan adopted with the corpora cavernosa by Bogros,
prosector to the Faculty, who died a victim to his zeal for science.
t [The lining membrane of these venous cells is not veiy eitensible, but the trabecuUe, between which they
lie, are highly extensible and elastic also.]
^ [The corpuscles here described are not those discovered by Malpighi, but large, soft, grayish bodies, rare-
ly found in the human spleen, and the nature of which is not understood. The Malpighian corpuscles are
much smaller ; they are very evident in the ox, sheep, and pig ; they lie in the red pulpy matter externally
to the venous cells, and are attached by short pedicles, or without pedicles, to the minute arteries, which,
however, have not otherwise any special relation to them ; they contain grayish granules, similar in size and
form to those of the red pulpy matter. In the human spleen they are very difficult to distinguish.
The extremities of the divided trabeculse may be mistaken for white corpuscles.]
*■ [This transudation evidently depends on the porosity or permeability of animal tissues, and not on the ex-
istence of any special vessels.]
408 SPLANCHNOLOGY.
Nerves. — The nerves are derived from the solar plexus, and are termed the splenic
plexus. It has been stated that some terminal divisions of the pneumogastric have been
seen distributed upon the spleen. Several of the nerves are remarkable for their size,
which enables us to examine in them the peculiar structure of the ganglionic nerves,
and also to trace the splenic nerves themselves deeply into the substance of the organ.*
We are completely ignorant of their mode of termination.
As to the proper ducts of the spleen, said to pass directly from that organ to the great
cul-de-sac of the stomach, or even to the duodenum, and to pour into these parts a pecu-
liar liquid, it may be confidently stated that they are purely imaginary. And again, the
three kinds of vascular conununication between the spleen and the stomach cannot in
any way explain the afflux of liquids from the spleen to the stomach ; in fact, the arte-
rial vasa brevia of the stomach are given off from the splenic artery before it reaches
the spleen ; nor do the venous vasa brevia enter the splenic vein until after it has left
the hilus of the spleen ; the lymphatic vessels alone pass directly from the spleen to the
stomach, but they are superficial, and have no connexion with the splenic cells.
There is no cellular tissue, properly so called, in the spleen, which, nevertheless, is
liable to inflammation.
Development. — In opposition to the liver, the spleen is smaller in proportion as it is ex-
amined nearer the period of conception. It appears late ; it begins to be distinguisha-
ble towards the end of the second month, and it then resembles a clot of blood. I hav^e
never seen it developed from separate lobules, which were afterward to be united by a
common investment. At birth, its proportions are almost the same as at subsequent pe-
riods. The spleen is hard, and, as it were, tense, in most infants who die during birth :
this is probably owing to impeded circulation.
The changes which the spleen undergoes during growth, both in density and in size, are
partly physiological, which are not very remarkable, and partly pathological ; these are very
considerable, but they are foreign to my subject. In the aged, the spleen decreases, like
all other organs ; and atrophy of this organ, which may proceed so far that it only weighs
a few drachms, is often accompanied by the development of a cartilaginous shell.
Functions. — The functions of the spleen appear to me to be referrible to its structure
and its vascular connexions. The quantity of blood which passes through it, its entire-
ly vascular structure, and the physical qualities of the splenic pulp prove, on the one
hand, that the blood sent to the spleen serves other purposes besides that of nutrition ;
and, on the other, that it undergoes some important changes, of which we are complete-
ly ignorant, because the means of analysis are wanting ; but, whatever they may be, they
have undoubtedly some connexion with the functions of the liver, t for in all animals
possessing a spleen, even though its arterial blood does not come to it from the same
trunk as the hepatic artery, the veins of the spleen terminate in the venous system of
the liver. It is, therefore, extremely probable that the spleen performs an important
office in the abdominal venous system ; but what this office is we do not know ; and
what tends to confound all our calculations is, that extirpation of this organ in animals
does not seem to have any marked effect upon their health, that the most complete atro-
phy of the spleen is consistent with the most regular performance of all the functions,
and that hypertrophy, even to such a degree that the organ occupies almost the whole
of the abdomen, merely produces a discoloration of the skin, diminished nutrition, and,
in young subjects, an arrest of growth.
The spongy and vascular texture of the spleen, and the absence of valves, which al-
lows the venous blood to regurgitate into the spleen when there is any obstacle to the
circulation, has led to the opinion that the spleen is nothing more than a diverticulum
intended to restore the equilibrium of the abdominal venous system whenever it is de-
ranged ; and this opinion, which we owe to Haller, is pretty generally admitted.^ A
modification of this opinion is, that the spleen fulfils, with regard to the circulation in
general, and especially to the abdominal circulation, the office of the safety-tube of Wolf
in chemical apparatus. It is certain that compression of the splenic vein in a living an-
imal causes tumefaction of the spleen, which gives place to a quick collapse, as if by
elastic contraction, when the pressure on the vein is removed : it is certain that the
whole structure of the spleen indicates that this organ may undergo alterations of ex-
pansion and turgescence, and of collapse and flaccidity ; and it is known that, during in-
termittent fever, the spleen may be felt below the false ribs, &c. But all this leads to
presumptions, and not to certainty.
From the preceding considerations, it would follow that the spleen is only an accesso-
ry organ.
* The sensibility of the spleen is very important. In a living animal it may be cat or torn without an>
apparent signs of pain. Dogs have been seen devouring their own spleens, which had been drawn out of the
abdomen'. What a diiference, in this respect, between the spleen and the intestine! and yet they derive
their nerves from the same source.
t We cannot state, with Malpighi, that the spleen is the preparatory organ of the bile, because we have
seen that it is extremely probable that the liver is concerned in the process of sanguification.
t May we not quote, in support of tliis view, the pain felt in the region of the spleen after violent running,
which can only be referred to extreme di&teusiou of this organ '
THE LUNGS. 40&
THE ORGANS OF RESPIRATION.
General Observations. — The Lungs and Pleura. — The Trachea and Bronchi. — Development
of the Lungs. — The Larynx — its Structure, Development, and Functions. — The Thyroid
Gland.
After describing the digestive apparatus, the object of which is to elaborate soHd and
liquid materials for the reparation of the waste that occurs in the body, and, at the same
time, to present a vast surface for the absorption of those materials, we naturally turn
to the consideration of the apparatus of respiration, the object of which is to renew the
Tital properties of the blood by the action of atmospheric air in the lungs.
This latter apparatus, whicli is much less complex than the former, is composed, 1. Of
the lungs, the essential organs of respiration ; 2. Of the thorax, a cavity forming a sort
of bellows, and having walls capable of alternately expanding and contracting ; 3. Of a
tubular apparatus, by which the lungs communicate with the external air, and which
consists of the bronchi, trachea, larynx, pharynx, and nasal fossce; for it is only accidental-
ly, so to speak, and in order to render respiration more certain, that air is allowed to
pass through the mouth.
The thorax has been already described (see Osteologt and Myology), and also the
pharynx, which is common to both the respiratory and digestive passages.
The nasal fossae, situated at the entrance of the respiratory passages, form the natu-
ral passages for the introduction of the air, and, at the same time, serve for the reception
of the organ of smell, by which sense we may consider the qualities of the air are exam-
ined. Their bony framework has been already described under osteology. The pitui-
tary membrane which covers the irregular surfaces of these fossae will be described in
the article devoted to the organs of the senses ; we shall only consider, in this place,
the lungs, the trachea, and the larynx.
The Lungs.
The lungs (pulmoncs ; mevfiuv, from Trviu, to breathe, p p,figs. 155, 170, 171) are the
essential organs of respiration. While the presence of an alimentary canal is the attri-
bute of all animals, that of lungs is limited to those vertebrata which live in the air, dif-
ferent modes of respiration prevailing in the other classes.
Number. — The lungs are two in number ; but, as the air which penetrates them is re-
ceived from one tube, and the blood circulating through them is derived from one vascu-
lar trunk, they must be regarded as separated parts of a single organ ; by this arrange-
ment, respiration is rendered certain, and its unity maintained.
Situation. — The lungs are situated {p p, fig. 155) in the thoracic cavity, which is, in a
great measure, occupied by them, and effectually protects them from the action of exter-
nal agents ; they are placed on each side of the heart {h,figs. 155, 170, 171), with which,
physiologically, they are so directly connected ; they are separated from each other by
the mediastinum (m) ; hence the independence of the two cavities in which they are
contained. Being separated by the diaphragm from the stomach, the liver, and all the
other abdominal organs, they are so enclosed in all directions as not to be liable to dis-
placements, or, rather, such displacements are only partial, and due to a loss of substance
in the walls of the cavity in which they are placed.
Size. — The size of the lungs necessarily corresponds exactly with the capacity of the
thorax, and therefore, like it, is subject to variations ; and as, on the one hand, the size
of the lung is generally a measure of the energy of respiration, and, on the other, the en
ergy of respiration is a measure of the muscular strength, one cannot be astonished that
a capacious chest, coinciding with broad shoulders, should be the characteristic of a san-
guine temperament and athletic constitution.
In the natural state there is neither air nor watery fluid between the parietes of the
thorsix and the surface of the lung. The absence of air or other fluid may be shown af
ter death as well as upon a Uving animal, by raising the inter-costal muscle from the
costal pleura, so as to preserve the latter,* or by removing the muscular fibres of the dia-
phragm. It is then seen that the lung is always in contact with the parietes of the chest ;
in some subjects it even appears as if ready to escape ; but scarcely is the thorax opened
when the lungs instantaneously collapse, in consequence of the expulsion of the air from
their interior. It is very common to find a small quantity of serum in the cavity of the
pleura, but it is probable that this fluid did not exist during life. There is no space to
be filled up here as in the cranium.
The differences in the size of the lungs depend, 1. On the state of inspiration or expi-
ration. Attempts have been made to determine the difference from this cause by esti-
mating the volume of air inspired or expired ; it is about thirty cubic inches, and may be
increased to forty in forced inspiration or expiration. 2. On age ; thus, in the foetus, the
lungs are relatively much smaller than after birth. 3. On some morbid condition. The
* In order to demonstrate the absence of air, we may also repeat another experiment performed by Haller,
■which consists in opening the thorax of a dead body under water.
F F F
410 SPLANCHNOLOGY.
lungs diminish in size when the abdominal viscera encroach upon the thorax, either m
ascites, in pregnancy, or in diseases of the liver, vv'hich organ has been found in some
cases to become enlarged entirely by encroaching on the chest, and to extend as high
up as the second rib. They diminish, also, when the heart is enlarged in aneurism, or
when a large quantity of fluid is accumulated in the pericardium. In effusions into the
thorax, the fluid takes the place of the lung ; the latter gradually wastes, and is reduced
to such a thin lamina, or to so small a mass, that it has sometimes been overlooked in
a superficial examination ; but if, in such cases, air be blown into the trachea, the organ
appears of its full size, and gradually fills the remainder of the cavity. This extreme
diminution of the lung, without any alteration of its substance, proves that the size of the
organ is essentially dependant upon the air within it. Attempts have been made to cal-
culate exactly the quantity of air contained in the cavity of the lungs, or, in other words,
the capacity of these organs : according to one estimate, which can only be regarded as
an approximation to the truth, it would seem to be about 1 10 cubic inches after expira-
tion, and 140 inches after an ordinary inspiration.
When an effusion in the thorax has been very slowly absorbed, the lung of the affect-
ed side remains atrophied, and the thoracic cavity contracted, while the other lung ac-
quires a very considerable size, so that the mediastinum is pushed to one side, and the
healthy lung passes beyond the median line.* In certain cases of acute pneumonia, and
in rickets affecting the thorax, we often see one of the lungs reduced to very small di-
mensions, whUe the other is very much enlarged.!
The size of the two lungs is not absolutely the same. In consequence of the heart
projecting into the left cavity of the thorax, the transverse diameter of the left lung is
not equal to that of the right ; and on account of the projection of the liver into the right
cavity, the vertical diameter of the right lung is less than that of the left. After edlow-
ing for these facts, the difference is in favour of the right lung. In determining the size
of the lungs, we must bear in mind, that the lung eis well as the thoracic cavity gains in
one direction what it loses in another : elongated lungs, which are regarded as particu-
larly liable to phthisis, have not seemed to me to be smaller than the lungs of a person
of similar stature, but having a broad chest.
The weight of the lungs must be examined with reference to their specific gravity and
to their absolute weight. The specific gravity of the lungs is less than that of any other
organ, and even much less than that of water. Their lightness depends on the great
quantity of air which penetrates them in every direction, so that the lungs rise to the
surface of the fluid in which they are immersed. The specific gravity of the lungs pre-
sents some important differences depending on age. Thus, before birth, and in an in-
fant that has died during birth, without having respired, the lungs sink in water ; on the
contrary, they swim when the infant has breathed ; not because any change has taken
place in the intrinsic nature of the organ, but because the air has insinuated itself into
the cells. The estimation of the specific weight of the lungs constitutes what is called
in legal medicine the hydrostatic test. In the adult, the lung always floats, notwithstand-
ing any efforts which may be made to expel the air contained in the pulmonary cells ; it
seems as if the air enters in some way into the composition of the lung, and even in
vacuo it cannot be completely extracted. The specific gravity of the lungs varies also
from disease. Thus, lungs infiltrated with serum, or indurated by inflammation, being
completely or partially deprived of air, on the presence of which their lightness depends,
assume, in a greater or less degree, the appearance of compact organs, such as the liver
or the spleen.
The absolute weight of the lung varies from similar causes. From age : thus, although
the specific gravity of the foetal lung is much greater than that of the adult, yet its abso-
lute weight is considerably less. In infants that have not breathed, the weight of the
body is to that of the lungs as 60 to 1, on an average, while in those that have breathed
the proportion is as 30 to 1, so that the changes in the lungs resulting from respiration
are such as to double their weight. We may easily conceive the great importance of
this fact in legal medicine. This method of estimating the weight of the lungs is known
by the name of the static test.
The absolute weight of the lungs varies much in disease. Healthy lungs are very
light ; diseased lungs may become eight or ten times heavier than natural, without in-
creasing in size. The lungs ahnost always becoming engorged at their posterior bor-
der during the last moments of life, their weight must not be estimated from an ordinary
corpse. It must undoubtedly have been from the examination of engorged lungs that
authors have stated their average weight to be four pounds.
Colour. — The colour of the lungs varies according to age and disease. In the fcetus
they are reddish-brown ; after birth, rosy-white ; in the adult and in the aged they are
* In a case of chronic induration of the left lung, the deviation of the mediastinum was so great, that the
nght lung was in relation with the left costal cartilages.
t The lungs become less increased in size from inflammation than most other organs ; and this peculiarity
is explained by the vesicular structure of the lung, the increase in size being effected at the exp«ase of the
cavity of the air-vesicles.
♦ffiE LUNGS. 411
gra>\sh-blue, and almost always marked by black spots, forming points, lines, or patches,
and describing polygons more or less regular in figure. These black patches, which be-
come much more numerous in advanced age, coexist with the black deposites in the
bronchial glands, and probably depend upon the same cause ; they lie below the serous
covering of the lungs, and are very superficial, excepting in disease. The posterior part
of the lung is usually of a reddish-brown colour, because it is distended with blood and
serum. It has not been shown that this is altogether a post mortem condition, and the
necessary consequence of the position of the corpse upon its back ; many facts woidd,
on the contrary, induce us to admit that it occurs antecedently to death.
Density, Crepitation, and Cohesion. — The lung, a spongy or aerial organ, so to speak,
is the least dense of all the organs in the body ; it yields to the pressure of the hand,
and, if no cause prevents the escape of the air, it loses very much of its original size.
I have remarked, when speaking of the spleen, that, under pressure, that organ emitted
a peculiar noise, or, rather, gave rise to a sensation which might be compared to the
crackling of tin, and that this sound was the result of rupture of the fibrous prolongations
which traverse its tissue. Pressure of the lung causes a sensation and a sound some-
what analogous to the preceding ; this sound is called crepitation. It may, in fact, be
compared to the sound produced by the decrepitation of salt or the rattling of paper.
This crepitation is only observed under a moderate pressure, and if the sensation com-
municated be strictly noted, we shall find that it is the feeling of a resistance overcome.
On careful examination of the portion of the lung which has thus crepitated, bubbles of
air are found under the pleura ; in fact, emphysema is produced. Notwithstanding its
slight density, the tissue of the lungs possesses tolerable strength ; it resists laceration
to a certain point ; and all its parts are pretty firmly bound together.
Resistance to Distension. — The lung, though it yields to the finger without recovering
itself at all, or only very imperfectly, is yet possessed of great elasticity, but such an
elasticity as is in harmony with its functions. It also offers powerful resistance to any
distending force. Thus, if a stopcock be adapted to the trachea of a dead body, and the
lungs be inflated by means of bellows having double valves, the pulmonary tissue becomes
extremely tense and hard ; the effort necessary to rupture some of the air-cells, and pro-
duce emphysema, is surprising. In opposition to those authors who speak of the dan-
gers of artificial insufflation of the lungs of asphyxiated persons, I have in vain endeav-
oured, with aU the force I could employ in expiration, to produce a laceration of some of
the pulmonary cells : and how, it may be asked, without great means of opposing every
attempt to dilate them beyond measure, could the lungs resist the force to which they
are subjected during violent exertions 1
Elasticity. — The lungs are very elastic, i. e., they have a constant tendency to tol-
lapse, and to free themselves of part of the air contained in their cells. It is this elasti-
city which maintains the vaulted form of the diaphragm after the abdomen has been
opened, and occasions the lung to collapse suddenly, when an opening is made in
the parietes of the thorax : before the chest is opened, the atmospheric pressure, opera-
ting through the trachea, prevents the elasticity of the lungs from being brought into ac-
tion. * This elasticity is also shown by the quick collapse of inflated lungs. I have been
accustomed to demonstrate, in my lectures, perfectly healthy lungs, preserved in alco-
hol. After having shown how far the inflation of the lungs may be carried, I open the
stopcock used in the experiment, and the lungs instantly collapse, driving out the air
with considerable force.
Shape and Relations. — The lungs are shaped like an irregular cone, deeply excavated
on the inner side, with the base below and the apex above ; they present for consideration
an external and an internal surface, an anterior and a posterior border, a base, and an apex.
Outer or Costal Surface. — This surface is irregularly convex, corresponding to the con-
cavity of the thoracic parietes, with which it is in contact, and on which it is exactly
moulded ; it is in relation with the costal pleura, which separates it from the ribs and
the intercostal muscles. It presents a deep fissure, the inter-lobular fissure, which pen-
etrates the entire thickness of the lung as far as the root. This fissure conunences be-
low the apex of the lung {v',Jig. 171), passes downward and forward {v',fig. 170) as fair
as the anterior part of the base, upon which it encroaches a little at its termination. It
is simple in the left lung («'), but is bifurcated in front in the right ; the lower division
of this bifurcation continues in the original direction ; the upper division (ic) passes up-
ward and forward. The left lung, therefore, is divided into two portions or lobes, dis-
tinguished as the superior («') and the inferior {u') ; while the right is divided into three
lohes, the superior (s), the inferior (m), and the middle {t). Of these lobes, the inferior,
comprising the base of the lung, is larger than the superior, which forms the apex ; the
middle lobe is the smallest. Tlie contiguous surfaces of these lobes are plane, and cov-
ered by the pleura : they are often Eidherent, and sometimes purulent matter collects be-
* [The longs Jo not collapse nntil the chest is opened, because the atmospheric pressure is exerted only on
the inner surface of the lungs, their outer surface being- protected from it by the unyielding parietes of the
thorax. When this protection is removed, the pressure on both surfaces is equal, and the elasticity of the
pulmonary tissue is tlien enabled to act.]
412
SPLANCHNOLOGY.
Fig. 170. tween them, and, being sm-
rounded on all sides by adhe-
sions, it hollows out, as it
were, a cavity for itself, at the
expense of the corresponding
surfaces of the lobes, and thus
simulates an abscess of the
lung.
There are many varieties
in the arrangement of these
lobes. Thus, sometimes, the
fissures, and more especially
those which bound the middle
lobe, do not reach as far as
the root of the lungs, but are
only slightly indicated. Three
lobes are not unfrequently
found in the left lung, or four
in the right ; there were four
lobes in the lung of a negro
lately presented to the ana-
tomical society.
Examples are on record of
lungs with five, six, and even
seven lobes, but in general this
multiplicity of lobes is only
rudimentary, and represents
the normal condition in the
majority of animals. The dog,
the sheep, and the ox have
seven lobes in their lungs
Inner or Mediastinal Surface. — This corresponds to the mediastinum (p p). On it we
observe the root (r) of the lungs, that is, the part at which they communicate with the
trachea, through the bronchi, and receive and emit their bloodvessels. This root oc-
cupies a very limited space upon the inner surface, one inch in height, and half an inch
in breadth ; it is situated at the junction of the posterior with the two anterior thirds of
this surface, at an almost equal distance from the apex and the base.
That part of the inner surface of the Jung which is behind the root corresponds to the
vertebral column and the posterior mediastinum, in which are found, on the left side, the
descending aorta and the upper part of the thoracic duct ; and on the right side, the vena
azygos, the oesophagus, and the lower part of tlie thoracic duct.
All that portion of the inner surface which is in front of the root corresponds with
the anterior mediastinum, and is excavated to receive the heart (l) ; and as the heart
projects more to the left than to the right side, it follows that the left lung, which cor-
responds to the left border and apex of the heart, and higher up to the arch of the aorta
ig), is more deeply excavated than the right lung, which corresponds to the right auricle
(m) and the vena cava superior {see Jig. 170). We can obtain an accurate idea of the
manner in which the lungs are excavated for the reception of the heart only by ex-
amining them when inflated ; we are then struck with the propriety of the expression of
Avicenna, who called the lung the bed of the heart. We can also understand how diseases
accompanied with enlargement of the heart may directly influence the respiration, by
reducing the size of the lungs. These organs, it may be remarked, are here in apposi-
tion with the heart through the medium of the pericardium and the pleura. I should not
omit to mention their relation with the phrenic nerve, which is affixed closely to the
pericardium by the pleura. In the foetus, the lungs are in relation anteriorly with the
thjTnus gland, which presses them backward.
The anterior border is thin and sinuous, presenting on the left side two notches, one
inferior and very large, corresponding to the apex of the heart ; the other superior and
small, for the subclavian artery. On the right side there are also two notches, but
smaller than those on the left ; an inferior for the right auricle, and a superior for the
vena cava superior.
The posterior border (fig. 171) is the thickest part of the lung. It fills the deep costo-
vertebral groove situated at each side of the dorsal portion of the spine.
The base is concave, and exactly moulded upon the convexity of the diaphragm (x,
fig. 170); it is, therefore, a little more excavated on the right than on the left side.
Its circumference is very thin, and slightly sinuous. Like the diaphragm, the base of
the lung forms an inclined plane from before backward and downward ; and it occupies
the deep angular groove formed behind, between the diaphragm and the parietes of the
thorax. On account of this obliquity of its base, the vertical diameter of the lung is much
THE LUNGS. 413
greater behind than in front ; and as the posteiior border is the largest part of the organ,
it may be conceived that an examination of the lung should be directed chiefly to this
part. It is of importance to form a correct idea of the manner in which the base of the
right lung and the convexity of the hver are arranged with regard to each other. The
liver is, as it were, received into the concavity of the base of the lung so completely, that
the posterior part of this base is almost on a level with the lower surface of the liver.
The relation of the hver with the base of the lung, which is only separated from it by the
diaphragm, explains how abscesses and cysts of the liver may Jjurst into the lung.
The apex is obtuse, and projects above the first rib, a very strongly-marked impression
of which is found on its anterior surface. I have observed that the height of the portion
which passes above the first rib varies in different subjects. In severed I found it from
an inch to an inch and a half In an aged female, in whom the base of the thorax was
extremely constricted, the apex of the lung (i. e., the part bounded below by the depres-
sion corresponding to the first rib) was two inches in height. May not the mechanical
pressure of the inner edge of the first rib upon the apex of the lung exercise some influ-
ence in the very frequent development of tubercles in that region 1 In order to form a
correct idea of the apex of the lung, that organ must be previously inflated.
The whole surface of the lung is free, smooth, and moistened with serum ; it is con-
nected with the rest of the body only by its root, which attaches it to the bronchi and the
heart, and by a fold of the pleura. It is very rare to meet with lungs free from adhe-
sions upon their surface, so that the older anatomists regarded these adhesions, whether
filamentous or otherwise, as natural formations.
Structure of the Lungs.
On examining the structure of the lungs, we find in each an investing membrane oi
serous sac, formed by the pleura, and a proper tissue. We shall conmxence with the
pleiira.
The Pleura.
Dissection. — In order to obtain a view of the costal pleura, saw through the six or
seven upper ribs behind, near their angles ; cut through the cartilages of the same ribs,
at a distance of some lines from their sternal articulations ; remove the intermediate
portions of ribs and intercostal muscles with great care, so as to leave the costal pleura
imtouched. The cavity of the pleura may be inflated.
In order to see the mediastinal and pulmonary portions, the costal pleura must be
opened, and its continuity traced.
The -pleura {nXevpu, the side) is a serous membrane, and, therefore, a shut sac, which
is extended partly over the parietes of the thorax, and partly over the lungs. There are
two pleurae, one for the right and the other for the left lung. The following is their gen-
eral arrangement :
The pleura lines the parietes of the thorax, the ribs, and the diaphragm, forming the
pleura costalis (p p,fig. 151) and pleura diaphragmatica ; it invests the entire surface of
the lung, constituting a sort of integument for it, and forming the pleura pulmonalis ;
lastly, it is applied to the pleura of the opposite side, so as to form a septum between
the two lungs ; this part is the mediastinal pleura.
In order to facilitate the description of the pleura, we shall suppose it to commence
at a certain point ; and then, following its course without interruption, shaU trace it
back to the point from which we started. If we thus commence at the sternum, we
shall find that it lines the internal surface of the thorax, being apphed to the ribs and
the intercostal muscles, and covering the mammary vessels and lymphatic glands in
front, the intercostal vessels and nerves behind, and the ganglia of the great sympa-
thetic opposite the heads of the ribs : below, it is reflected upon the diaphragm, and
covers the whole of its upper surface : above, it is reflected beneath the first rib, and
terminates in a cul-de-sao, intended for the reception of the apex of the lung, and pro-
jecting more or less above that rib.
Having reached the sides of the vertebral column, the two pleurae are reflected for-
ward as far as the root of the corresponding lung, and form, by their approximation, a
septum, which is called the posterior mediastinum. This septum contains within it the
aorta, the oesophagus, the pneumogastric nerves, the thoracic duct, the vena azygos, a
considerable quantity of cellular tissue, a great number of lymphatic glands, and the
trachea. We see, then, that the two pleurae are by no means in immediate contact.
Arrested, as it were, by the root of the lungs, the pleura is reflected outward behind
that pedicle, passes over a small portion of the pericardium, covers all that part of the
inner surface of the lungs which is behind its root, and also its posterior border and its
outer surface, dips into the inter-lobular fissure, so as completely to invest the contigu-
ous surfaces of the lobes, is reflected over their anterior margin upon their inner surface,
reaches the root of the lung, and covers its anterior surface, is then reflected forward
upon the side of the oericardium, in front of which it is applied to the pleura of the op-
414 SPLANCHNOLOGY.
posite side, and at length arrives at the border of the sternum, from which we had sup-
posed it to commence.*
The antero-posterior septum formed by the two plurae, between the sternum and the
root of the lung, is called the anterior mediastinum {m,fig. 155).t This septum is not
vertical nor median, Uke the posterior mediastinum, but is directed downward and to
the left side, an arrangement that is connected with the oblique position of the heart,
which encroaches more upon the left than the right cavity of the thorax. It follows,
from this, that the uppej part of the anterior mediastinum {p p,fig. 170) is behind the
sternum, while its lower portion is behind the left costal cartilages, and hence the in-
terior of this mediastinum may be reached without opening the cavity of the pleura, by
Introducing an instrument close to the left border of the sternum, opposite the fifth rib.
The anterior mediastinum is narrow in the middle, and expanded above and below, Uke
an hour-glass. The upper cone or expansion is very much developed in the fcetus, and
Is occupied by the thymus gland, which is afterward replaced by cellular tissue : the
lower cone or expansion is much larger, and contains the heart and pericardium, the
phrenic nerves, and in front of the heart a large quantity of cellular tissue.
This latter, which is so abundant in the anterior mediastinum, communicates freely
above with the cellular tissue in front of the neck, and below with that of the abdominal
parietes, through a triangular interval existing in the diaphragm behind the sternum.
This double communication explams how the pus of an abscess formed in the neck
or in the mediastinum may reach the surface in the epigastric region.
The pleura has two surfaces, one an external, the other internal.
External or Adherent Surface. — ^This does not adhere with equal firmness to all the
parts which it covers. The pleura costalis is but slightly adherent, and may be separa-
ted from the ribs and the intercostal muscles with the greatest ease. It is sometimes
raised in the situation of these muscles by subjacent adipose tissue. It is strengthened
by a layer of fibrous tissue, which, notwithstanding its tenuity, performs an important
part in diseases of the chest ; it explains why abscesses formed in the parietes of the
thorax so seldom open into the cavity of the pleura, and why effusions into the pleura
are so rarely discharged externally. The diaphragmatic pleura is more adherent than
the costal. We sometimes find here, especially round the pericardium, some large fat-
ty appendages, resembling the appendices epiploicae of the great intestine. The pleura
is extremely thin upon the lungs {pleura pulmonalis), where it is not strengthened by
any fibrous tissue ; and although it is more adherent here than the parietal pleura, still
it can be easily demonstrated. The mediastinal pleura is united to the parts contained
within the mediastinum by very loose cellular tissue, but it adheres more firmly to the
Bides of the pericardium, to which the phrenic nerves are closely applied.
The internal or free surface is smooth,t moistened with serum, and in contact with
itself throughout its entire extent, as is the case in all serous membranes. The adhe-
sions so commonly met with here are altogether accidental. The structure of the pleura
is cellular.^ It is doubtful whether it receives any arteries and veins. The vascular
network, which is sometimes so highly developed after pleurisy, does not belong to it,
but is situated upon its external surface. No nerves have been traced into this mem-
brane.
Uses. — Each pleura forms an investment for the corresponding lung, separates it from
the parietes of the thorax and from the other viscera, and, at the same time, facilitates
its movements upon the walls of the thoracic cavity by means of the serosity, which is
constantly exhaled and absorbed at its internal surface.
The Proper Tissue of the Lungs.
The pulmonary tissue appears like a spongy or vesicular texture, the cells of which
are filled with air. This is rendered apparent by the most simple inspection of the sur-
face of an inflated lung, either with the naked eye or with a lens. A microscopical ex-
amination of sections of a dried lung shows the existence of this cellular or vesicular tex-
ture in the most evident manner throughout the entire organ. The different shapes of
the cells and their unequal size may also be distinguished.
But what are the relations of the cells with each other 1 Do they communicate
throughout the whole extent of the lung, or only within a determinate space, or are they
independent of each other 1 In order to resolve these questions, it is necessary to ex-
amine the lung of a large animal, of the ox, for example, the structure of which is simi-
lar to that of the human lung, on which the same observations may be subsequently re-
* [A fold of the pleura reaching' from the lower edge of the root of the lung downward to the diaphragm,
is called the ligamentum latum pulmonis. It is triangular ; its base is attached to the diaphragm, one side to
the lung, and the other to the mediastinum.]
t According to Meckel, the anterior mediastinum is the portion of the septum situated in front of the heart,
just as the posterior mediastinum is the part situated behind that organ.
X [It is covered with a squamous epithelium, and cilia have been observed upon it in some of the mam-
malia.]
^ [Beneath the pleura another cellular layer may be demonstrated ; and in the lung of the seal and leopard
an elastic coat is said to exist. 1
THE LUN38. 415
peated. We then observe that the surface of the lung is traversed by lines, dividing it
into lozenge-shaped compartments ; and if the lung be previously inflated, it will be seen
that the surface is slightly depressed opposite these lines, but that it bulges out between
them. If, by means of a dehcate tube, air be blown under the pleura, or if the lung be
forcibly inflated through the trachea, so as to rupture some of the vesicles and produce
emphysema, we then perceive that the lines bounding the lozenge-shaped intervals cor-
respond to thin layers of very delicate, but tolerably loose cellular tissue, which divide the
lung into a large number of groups or cells, which may be completely separated from
each other by dissection, until at last we arrive at the pedicles by which they are united
into a common mass.
These groups of cells are the lobules of the lung; the cellular tissue uniting them is the
interlobular cellular tissue, which is extremely delicate, never loaded with fat, but oft,en
infiltrated with serosity, and is subject to emphysema. A great number of lymphatic
vessels traverse this cellular tissue : they are often visible to the naked eye, and are
always easily injected ; they pass deeply into the substance of the lung.
The pulmonary lobules do not communicate with each other, but each is perfectly in-
dependent of the rest. This fact is shown by inflation ; it is most distinctly proved by
dissection ; and an examination of the lungs of the foetus will remove all doubts con-
cerning it. The pleura and the interlobular cellular tissue having but little strength in
the fcEtus, the lobules become separated without dissection, resemble grapes attached to
their footstalks, and hang from a common stem, formed by the divisions of the bronchi
and the pulmonary vessels.
This independence of the lobules is also proved by pathological anatomy : thus, we con-
tinually find one lobule infiltrated with serum, with pus, or with tubercular matter, in the
midst of perfectly healthy lobules.
Each lobule, then, is a small lung, and may act independently of those by which it is
surrounded. I have satisfied myself, by a great number of experiments, that the lobules
are not all equally permeable to the air, and that a moderate inflation of the lungs, made
as much as possible within the limits of an ordinary inspiration, does not, perhaps, dilate
one third of the pulmonary lobules. I have observed, and this fact appears to me of
great importance, that the most permeable lobules are those of the apex of the lung ; and
this, perhaps, will explain the greater frequency of tubercles in that situation.* There
are some lobules in the lung which are kept, as it were, in reserve, and only act in forced
inspirations.!
The puhnonary lobules vary much in shape ; all the superficial ones resemble a pyra-
mid, the base of which is at the surface of the lung ; the deep lobules lie along the bron-
chial tubes, have numerous facettes, and are exactly fitted to each other, like the frag-
ments of mosaic work ; but they are so irregular in form, that it would be equally diffi-
cult and useless to give a description of them.
The lung, then, is a collection of an immense number of lobules, placed along the bron-
chial tubes and pulmonary vessels, which serve as a support and framework for them, and
to which they are appended by pedicles ; they are united to each other by serous cellu-
lar tissue, and are all covered by one great cell formed by the pleura, which merely
unites together this great number of parts.
The problem of the texture of the lungs reduces itself, therefore, to the determination
of the structure of a single lobule ; but the difficulty is rather postponed than got rid of,
for each lobule is a little lung, receiving an air-tube and an artery, and giving out several
veins and lymphatics.
Before describing the arrangement of the air-tube, and the vessels in each lobule, we
shall say a few words upon the structure of the lobule itself
Each lobule is an agglomeration of cells and of vesicles, all of which communicate
with each other.J These cells are always full of air. Their size is not always the same.
M. Magendie has already shown that the pulmonary cells are smaller in the infant than
in the adult, and smaller in the adult than in the aged.§ Nor is the size of the different
cells in the saime lobule constantly uniform. All the cells of the same lobule communi-
cate, but they are not all equally permeable. t Thus, in a given degree of inspiration,
some cells only are distended, while others require a greater degree of dilatation. The
septa between the cells of a lobule are incomplete,^ and consist of filaments or lamellae ;
and the reticulated arrangement of the cells, which is so evident to the naked eye in the
lung of the frog, seems to me to represent with tolerable accuracy the appearance of the
human lung under the simple microscope.
* It is rather too much to say that pneumonia almost always attacks the base of the lungs ; this disease has
no special locality ; it perhaps as often affects the apex as the base.
t In ordinary respiration, perhaps not more than one third of the lung is in action ; exercise and yawning
are probably required, from the necessity for bringing the whole lung into action. Thus, a great number of tu-
bercles may exist in the lung without manifesting their presence by impeding ordinary respiration. It is in
Tiolent inajnration, in exercise, in efforts of the voice, and in all movements during which the whole of the
lungs is called into play, that we detect the existence of a lesion in the central organ of respiration.
{ See note, p. 419.
^ Diseases have a remarkable influence upon their size ; in chronic catarrh, and in some varieties of asthma,
we find the pulmonary cells excessively dilated. Laennechas called this dilatation pulmonary emiihysemo.
416 SPLANCHNOLOGY.
With regard to the structure of the cells,* we cannot admit the existence of muscular
fibres round them ; the anatomist is unable to demonstrate them, and physiology rejects
them. Tlie most probable opinion is, that they are formed of dense cellular tissue, or of
an elastic fibrous tissue, and that the bloodvessels are ranrified upon their parietes.
The Air-tubes.
The air-tubes of the lungs consist of the trachea, the bronchi, and their divisioris.
The Trachea.
The trachea (from rpaxvg, rough), or aspcria arteria ib,fiffs. 170, 171), is the common
trunk of the air-tubes of the lungs ; it is situated between the larynx {a,Jig. 171), of which
it is a continuation, and the bronchi (p p'), which are nothing more than its bifurcation in
front of the vertebral column, extending from the fifth cervical to the third dorsal verte-
bra, t In this situation, however, it is movable, and may easily be pushed to the right
or left side. This mobility has occasioned serious accidents in tracheotomy, and has led
to the invention of an instrument for fixing the trachea.^ Its direction is vertical ; it
occupies the median line above, but appears to be slightly deflected to the right side be-
low. I have often seen it somewhat flexuous, but these slight deviations only existed
when the neck was bent upon the thorax ; they disappeared during extension.
Dimensions. — The length of the trachea equals that of the space between the fifth cer-
vical and the third dorsal vertebrae, and is, therefore, from four to five inches ; but it
varies according as the larynx is raised or depressed, and as the neck is flexed or ex-
tended. The difference produced in its length, by the utmost elongation and shortening,
may be about half its entire length, i. e., from two inches to two inches and a half; its
shortening is limited by the contact of its cartilaginous rings. ^
The diameter of the trachea is determined by that of the cricoid cartilage of the larynx ;
it is much wider in the male than in the female, and after than before puberty. Indi-
viduals who have been many years labouring under chronic catarrh have the air-passages
remarkably large, especially the trachea. The mean diameter of the trachea is from
ten to twelve lines in the male, and from nine to ten in the female. The trachea is not
of equal diameter throughout ; it is almost always dilated at its lower extremity, Avhere
it bifurcates. In some subjects it gradually increases in size from above downward,
and resembles a sort of truncated cone, with the base below.
External Surface, Form, and Relations. — In front and on the sides the trachea is cylin-
drical {fig. 170), but is flattened behind {fig. 171), so that it resembles a cylinder, the
posterior fourth or third of which has been removed. The external surface is rough,
and, as it were, interrupted by circular ridges, which correspond to the cartilaginous rings.
The relations of its external surface must be examined in the neck and in the thorax.
Relations of the Cervical Portion (x,fig. 140). — In front the trachea is in relation with
the thyroid body, the isthmus of which being sometimes very narrow and sometimes
very largely developed, covers a greater or less number of the rings of the trachea. In
general, the first ring of the trachea is above the isthmus of the thyroid. Below the
thyroid body the trachea is in relation with the stemo-thyroid muscles, the edges of
which are separated only by the linea alba of the neck ; also with the cerviced fascia, the
thyroid plexus of veins, a considerable quantity of cellular tissue, the thyroid artery of
Neubauer, when it exists, and the brachio-cephalic artery, which always passes a little
above the supra-sternal notch. All these relations are of the greatest importance in ref-
erence to the operation of tracheotomy. On the sides the trachea is embraced by the
lateral portions of the thyroid body, and, therefore, in diseases of that organ, the corre-
sponding part of the trachea is deformed, flattened on the sides, and elliptical, or even
triangular. The compression of this canal may be carried so far as to produce suffoca-
tion. The common carotid artery and the pneumo-gastric nerve are in contact with it
on either side ; and hence the possibility of wounding that artery in the operation of
tracheotomy. A great number of lymphatic glands are situated upon the sides of the
trachea, and may become so large as to prevent the passage of the air. Lastly, all the
relations of the trachea, excepting those with the thyroid body, take place through the
medium of a very loose cellular tissue in which this canal is imbedded.
Behind, the trachea is flat and membranous, and is in relation with the oesophagus,
which projects a little beyond it on the left side, and separates it from the vertebral col-
* See note, p. 419.
t The terai trachea is derived from the roughness produced by the projection of the cartilages of the wind-
pipe. The application of the term arteria, by the ancients, to the vessels which carry red blood, arose from
a serious anatomical mistake. These vessels being habitually empty in the dead body, it was supposed that
they contained air during life ; and hence the name artery, which tliey still retain.
t By a surgeon of the name of Buchot. The mobility of the trachea is an obstacle to its puncture in the
operation of tracheotomy.
^ The elongation and shortening of the trachea is much more limited in man than in birds, in which the
rings of the trachea are moved by longitudinal muscles, and can be drawn within each other ; in the greatest
possible degree of shortening three rings overlap each other, so as to equal only one in height ; and, therefore,
the trachea of a bird may be diminished by two thirds. These peculiarities of structure are connected with
the different uses of the parts ; the trachea in man and other mammalia merely conveying the air (unporte-verU),
while tlie trachea of birds conveys the voice (vn porte-voix).
THE LUNGS.
417
omn. The left recurrent nenre is situated in the groove formed between the trachea and
the oesophagus in this direction ; the right recurrent nerve lies behind the trachea.
The inunediate relation of the trachea with the oesophagus explains why foreign bodies
arrested in the gullet may produce suffocation, and require the perfonnance of trache-
otomy.
The softness and flexibility of the trachea opposite the oesophagus have appeared to
some physiologists to be intended merely to facilitate the dilatation of the latter during
the passing of the food ; but we shall see that the air-tubes continue to be membranous
behind, even where they have no relation with the oesophagus, and comparative anatomy,
which shows the trachea to be cylindrical in the bird, and angular behind in the ox, the
sheep, &c., most completely refutes this opinion.
Rdaiions of the Thoracic Portion of the Trachea. — In the thorax, the trachea occupies
the posterior mediastinum. It corresponds in. front, proceeding from above downward,
with the sternum and the sterno-thyroid muscles ; with the left brachio-cephalic vein (c,
fig. 170) ; with the brachio-cephalic artery (A), an aneurism of which may open into the
trachea ; its left side is, as it were, embraced between the brachio-cephalic artery (A)
and the left common carotid (;) ; with the back part of the arch of the aorta {g), which
rests immediately upon it, and hence the dyspnoea which so generfdly accompanies aneu-
rism of the aorta, and the frequency of its bursting into the windpipe ; and, lastly, lower
down, with the bifurcation of the pulmonary artery, which corresponds with that of the
trachea.
The trachea is in relation behind with the oesophagus, which separates it from the spinal
column ; and on the sides with those portions of the pleurae which form the mediastinum,
with the pneumogastric nerves, and with the upper part of the recurrent nerves.
In all its thoracic portion the trachea is surrounded by numerous lymphatic vessels and
glands, and by a loose and very abundant cullular tissue, which communicates with that
of the cervical region. These lymphatic vessels and glands with the loose cellular tissue
are the parts immediately adjoining the trachea ; and it may readily be conceived that
enlargement of the glands may be productive of serious consequences.
Internal Sarface. — The internal surface of the trachea is of a rosy colour, and presents
the same circular ridges as the external surface, but they are more distinct. It is also
remarkable in its membranous portion for the projection of certain vertical fasciculi, to
which we shall again refer when speaking of the structure of these parts.
The Bronchi.
The bronchi {(JpSyxoc, gutter, p p,Jig. 171) are the two branches formed by the bifiirca-
tion of the trachea, which Ft^. 171.
spread out from each other at
a right or a slightly obtuse
angle ; one {p) is intended for
the right, the other for the
left (p') lung. A tolerably
strong triangular ligament
exists at the angle of the bi-
furcation, and seems intend-
ed to prevent too great sep-
aration of the bronchi.
The bronchi differ from
each other in many respects ;
first, in width. The right
bronchus is much wider than
the left, and its diameter is
not much less than that of
the trachea. In a female
whose trachea w£is ten lines
in diameter, the right bron-
chus was eight, and the left
five. This difference in width
corresponds with the differ-
ence in the size of the two
lungs, and may afford a toler-
ably correct measure of that
size ; they differ also in length,
the right bronchus being one inch in length, the left two ; also in direction, the right
bronchus passing less obhquely than the left, probably because it enters the correspond-
ing lung sooner than the latter ; and, lastly, in their relations. Thus, the right bronchus
is embraced by the vena azygos, which forms a loop immediately above it, in order to
terminate in the vena cava superior. The left bronchus is embraced above by the arch
of the aorta {g), and has an important relation with the oesophagus behind, which it
Ggg
4ih SPLANCHNOLOGY.
crosses obliquely. Both are connected with the pulmonary plexus of nerves ; both are
surrounded with lymphatic glands, remarkable for their black colour, and for being fre-
quently diseased, and which in some measure fill up the angle formed by the bifurcation
of the trachea ; and, lastly, both have the following relations with the pulmonary artery
and veins. Each pulmonary artery {k k') is situated in front of the corresponding bron-
chus, then passes above, and finally behind it. The two puhnonary veins on each side {I I,
mm) are situated upon the same vertical plane as the corresponding artery ; they pass up-
ward in front ofthe artery and the bronchus, which is, therefore, behind the bloodvessels.*
The shape of the bronchi exactly resembles that of the trachea, i. e, they represent
cylinders, the posterior fourth of which has been removed, and which are formed by par-
allel rings. The area of the two bronchi is greater than that of the trachea, in the same
way as the area of the bronchial ramifications is greater than that of the bronchi them-
selves, so that the velocity of the expired air increases as it approaches the exterior.
At the root of the lungs the bronchi divide into two equal branches, but in a some-
what different manner. The upper branch of the bifurcation of the right bronchus is the
smaller, and is intended for the upper lobe of the lung, in order to reach which it is bent
slightly upward. The lower branch, which is larger, follows the original direction, and
after passing about an inch, divides into two unequal branches, a small one for the mid-
dle lobe, and a larger one for the lower lobe. I have once seen a small bronchus pro-
ceeding from the lower part of the trachea directly to the apex of the right lung ; the
vena azygos passed between it and the regular bronchus.t
The secondary divisions are precisely the same in the two lungs ; each branch of a
bifurcation becomes bifurcated in its turn. All these ramifications pursue a diverging
course, some ascending, others descending, and, after proceeding for a variable distance,
they again bifurcate ; so that, by separating a small portion of the pulmonary substance,
we can see that several diverging series of tubes proceed in succession from a bronchial
trunk, and pass outward into the tissue of the lung. The prevailing mode of division of
the air-tubes in the lungs is that called dichotomous, viz., a division into two equal branch-
es, which we shall afterward find to be the most favourable to the rapid transmission of
the contents of any vessel. (See Aeteries.) The two branches of a bifurcation sep-
arate at an acute angle, and a spur-shaped process, situated within the tube at the an-
gle of division, cuts and divides the column of air. However, some small bronchial
tubes are not unfrequently found arising directly from a principal division, to be distrib-
uted to the nearest pulmonary lobules. The number of subdivisions, which always cor-
responds with that of the pulmonary veins, is not so great as might at first be supposed ;
there are not many more than fifteen.
The form of the bronchial ramifications (bronchia) differs essentially from that of the
bronchi themselves and of the trachea. They represent, indeed, a complete cylinder,
which is not truncated behind ; and the cartilages, instead of forming rings, have another
arrangement, which I shall point out when speaking of their structure.
Relations. — The first divisions ofthe bronchi are surrounded, even in the substance of
the lung, by very numerous and dark-coloured bronchial lymphatic glands, enlargement
of which is a very frequent result of chronic bronchitis, and may cause suffocation.
The bronchial ramifications, as I have said, support the pulmonary lobules, which are
applied to and moulded upon them, and are united to them by very loose cellular tissue.
The following are their relations with the branches of the pulmonary artery and veins :
the artery always accompanies the bronchial ramification, and is situated behind it ; the
vein is often separated from it ; the artery and vein are not unfrequently found interla-
ced around the corresponding bronchial tube.
Relations of the Bronchial Ramifications with the Pulmonary Lobules. — ^Each pulmonary
lobule has its bronchial tube. This tube is cylindrical, of uniform diameter throughout,
and entirely membranous ; having entered the lobule, it dilates into a small ampulla, and
disappears. There can be little doubt that these small ampullae have deceived Malpighi,
Reisseisen, and others, who have stated that the bronchial tubes terminate in culs-de-
sac ; so that, according to these authors, each pulmonary cell is the termination of a par-
ticular bronchicd tube. But it is evident that such cannot be the case, for, on the one
hand, the bronchial tubes are not sufficiently numerous, and, on the other, it can be shown
that only a single bronchial tube enters into each group of cells or each lobule. If we
inject with tallow a lung which has previously been deprived of air, either by an effu-
sion in the chest during life, or by an artificial one after death, it wiU be seen that the
injection is divided into small globules or rounded tubercles, which correspond to so
many pulmonary ceUs, and that these globules are all connected with a common pedicle,
corresponding to the bronchial tube.
Reisseisen, who has made this injection, thinks that the granular appearance of the
injected matter represents the culs-de-sac, into which it had penetrated.^
* [In consequence of the oblique direction of the left bronchus towards the root of the lung, the correspond-
ing pulmonary artery is placed somewhat above it, and the pulmonary veins below it ; on the right side, the
pulmonary artery is in the middle, the bronchus above, and the veins below.]
t This appears to be the natural arrangement iu the sheep and the ox.
t [According to Reisseisen, each small bronchial tube, on entering its corresponding lobule, divides and sub-
THE LUNGS. 419
* ^ Structure of the Trachea, Bronchi, and Bronchial Ramijicattons.
Structure of the Trachea. — The trachea is composed of a series of imperfect cartilagi-
nous rings, separated by an equal number of fibrous rings, and hence it has a knotted ap-
pearance ; these cartilages keep the canal permanently open. Had the trachea been en-
tirely membranous, it would have collapsed during inspiration, which tends to produce
a vacuum in the thorax, and this collapse would have prevented the entrance of the air.
The number of the cartilaginous rings varies from fifteen to twenty. They are more
prominent on the internal than on the external surface of the trachea. In some subjects
they form two thirds, in others three fourths or four fifths of a circle. Each ring has
two surfaces, one anterior and convex, the other posterior and concave ; an upper and
a lower edge, both of which are thin, and give attachment to the fibrous rings ; and two
extremities, which terminate abruptly, without being inflected or thickened. In general,
there is but little regularity in the arrangement of these rings ; they are not exactly par-
allel, nor are they of equal depth, which varies from a line to a line and a half, two, or
even two lines and a half; and the same ring is often of unequal depth at different pakits.
Two rings are often united for a certain extent, and sometimes a ring is found birarca-
ted ; indeed, it is probable that differences in the number of the rings depend upon their
thus uniting or dividing. They are sufliciently thin to £illow of being compressed, so
that the opposite surfaces may touch without breaking. Their eljisticity enables them
to recover their original position immediately, and thus permit free access to the air.
They can only be broken when ossified, which is frequently the case in the aged.
The first ring and the two lower rings present some peculiarities. The first is broad-
er than any of the others, especially in the middle line, and it is often continuous with
the cricoid cartilage.*
The last ring of the trachea, which forms the. transition between it and the bronchi,
has the following characters : the middle part is prolonged considerably dowmward, and
curved backward, forming a very acute angle, and is developed into a spur-shaped pro-
jection within the trachea, which separates the two bronchi. The two half rings result-
ing from this arrangement/ constitute the two first rings of the bronchi. The last ring
but one of the trachea presents an angular inflection in the middle, less marked, howev-
er, than that observed in the lowest ring.
The Fibrous Tissue of the Trachea. — This is arranged in the following manner : a
fibrous cylinder commences at the lower edge of the cricoid cartilage ; the cartilaginous
rings are situated within the substance of this cylinder in such a manner, that the thick-
er layer of fibrous tissue lies on their exterior, so that, at first sight, their internal sur-
faces would appear to be in immediate contact with the mucous membrane. In the pos-
terior part of the trachea, where the cartilaginous rings are wanting, the fibrous tissue
alone forms its basis or framework.
The Muscular Fibres of the Trachea. — If we carefully remove the fibrous tissue from
the back of the trachea, opposite its membranous portion, we arrive at certain transverse
muscular fibres, extending from one end of each ring to the other, and also occupying
the intervals between the rings. The existence of these muscular fibres, which I have
seen forming a layer half a line tliick in certain cases of chronic catarrh, cannot be doubt-
ed. It is evident that their contraction must draw the ends of the rings towards each
other, and therefore narrow the trachea, the diminution in the width of which is limited
by the contact of the ends of the rings.
The Longitudinal Yellow Fasciculi. — In the membranous portion of the trachea, be-
divides in a certain uniform order into numerous tv„ i-rn
twigs (<,_/r^. 172), which, extending towards tbe °'
surface of the lobule, gradually decrease in di-
ameter, but increase in number, and at length ter-
minate in clusters of short, free, closed and round-
ed extremities (c c) ; these are the pulmonary
cells, which vary from ij^ to -g^ of an inch in
diameter. Not only are the several lobules in-
dependent of each other, but the cells of each
lobule have no communication with one another
except indirectly through the twig or twigs from
which they proceed.
This view of the minute structure of the lung,
which is opposed to the opinion of M. Cruveil-
hier, receives support from what is known con-
cerning the development of the lungs, and from
the analogy between these organs and the com-
I)onnd glands. ^___^__
In_^g'. 172, after Reisseisen, a shows the nat- "*^^ici^ h
ural size of the portion represented, magnified
about nine diameters in 6. The bronchial twigs Minute itmcture of the lung,
and pulmonary cells are seen distended with air ; the knots or projections (i) on the sides of some of the ^ga
indicate the commencement of other twigs, into which no air has passed.]
* I have met with one case in which the thin upper rings of the trachea and the cricoid cartilage were
joined together, l)ut only on one side ; the crico-thyroid muscle and the inferior constrictor of the pharynx ev-
idently arose from the first ring of the trachea. This continuity of the cricoid cartilage with the trachea
manifestly proves that the rings of the latter arc cartilages, and not fihro-cartilag-es.
420 SPLANCHNOLOGY.
tween the muscular anS'ttie mucous layer, are situated a great number of parallel, lon-
gitudinal, yellow fasciculi, which, at first sight, resemble longitudinal folds, but are not
at all effaced by distension ; these fasciculi adhere to, and produce an elevation of, the
mucous membrane, and opposite the bifurcation of the trachea they also divide, and are
continued into the bronchi.
The nature of this tissue is not well known ; it can only belong to the muscular or to
the yellow elastic tissue, though I would rather incline to the latter opinion. According
to either supposition, its use is to prevent too great an elongation of the trachea and the
bronchi ; actively in the one case, and by virtue of its elasticity in the other. Not un-
frequently some longitudinal fasciculi are found behind the cartilaginous rings.
The Tracheal Glands. — If we carefully examine the posterior surface of the trachea,
we find a certain number of ovoid flattened glands (see^^. 171), placed upon the outer
surface of the fibrous membrane ; and, by removing this membrane, we see a tolerably
thick, but not continuous, layer of similar glands between the fibrous and the muscular
coate ; and, moreover, if either the inner or the outer layer of the fibrous tissue, situated
between the cartilaginous rings, be removed, a series of much smaller glands will be
found between these layers, occupying the intervals between the rings, and even ex-
tending behind them.
The Mucous Membrane. — This is a continuation of the mucous membrane of the larynx ,
it is remarkable for its tenuity, which permits the colour of the subjacent parts to be
seen through it, and for its intimate adhesion to the structures covered by it. The lon-
gitudinal folds of which some authors speak do not exist ; the yellow longitudinal fas-
ciculi have been mistaken for them. Lastly, it presents a great number of openings,
from which mucus can be expressed. These openings are nothing more than the orii-
ces of the excretory ducts of the tracheeil glands.*
The Vessels and Nerves. — The arteries Of the trachea are derived from the superior and
inferior thyroid. The veins are generally arranged thus : some venous trunks running
along the inner surface of the trachea, beneath the mucous membrane, receive on each
side, in the same manner as the vena azygos, small veins corresponding to the intervals
between the cartilaginous rings, and then terminate in the neighbouring veins. The
lymphatic vessels are very numerous ; they enter the surrounding glands, which are of
considerable size. The nerves are derived from the pneumogastrics.
Structure of the Bronchi.
The structure of the bronchi is exactly the same as that of the trachea. The lett
bronchus has ten or twelve cartilaginous rings ; the right has five or six. They both
possess transverse muscular fibres, longitudinal yellow fasciculi, glands, &c. Their arter-
ies generally arise directly from the aorta, and are named bronchial. The veins of the right
bronchus enter the vena azygos ; those of the left terminate in the superior intercostal.
Structure of the Bronchial Ramifications {Bronchia). — The fibrous cylinder of the trachea
and the bronchi is prolonged into the bronchial ramifications. The cartilaginous rings
are remarkably modified beyond the first division of the bronchi ; they become divided
into segments, which together form a complete ring, so that there is no longer any mem-
branous portion, properly so called, and the bronchial tubes become perfectly cylindrical.
The segments above mentioned are oblong, curved, terminated by very elongated angles,
and so arranged that they can overlap and be mutually received between each other.
They are also united together by fibrous tissue. This arrangement of curved and angu-
lar segments exists as far as the last bifurcations of the bronchial tubes ; but the size
of the segments gradually diminishes, so that they soon form only narrow lines, and ul-
timately mere cartilaginous points. The fibrous and membranous constituents of the
cylinder preponderate more and more over the cartilaginous laminae, which disappear be-
yond the ultimate bifurcations of the bronchial tubes, being found last at the several an-
gles of bifurcation : the ultimate bronchial ramifications are altogether membranous.
The mucous membrane is prolonged to the very last ramifications, where it becomes
extremely thin. The longitudinal elastic fasciculi, which were limited to the membra
nous portion of the bronchi, are expanded over the entire surface of the bronchial tubes
beyond their first subdivision. The muscular fibres, which are confined to the mem
branous portion in the trachea and bronchi, become circular on the inner side of th»
bronchial ramifications, and form an uninterrupted but very thin layer, precisely resem
bling the circular fibres of the intestinal canal, t When we consider, on the one hand.
* structure of the Trachea.— iTtin muscular fibres of the trachea are of the involuntary class (see p. 323),
and are attached to the internal surface of the ends of the rings : the longitudinal fibres exist all round tht
trachea, but are collected into bundles on its membranous portion only ; they are believed to consist of elastif
tissue.
The glands of the trachea and bronchi are compound ; its mucous membrane is covered vfith a columnar
epithelium, and is provided with cilia, which urge the secretions upward towards the larynx.]
t Structure of the Bronchi and their Branches. — [According to Reisseisen, the fibrous cylinder gradually de-
generates, in the smallest bronchial tubes, into cellular tissue ; according to the same author, the longitudinal
elastic and the circular fibres can be traced as far as the tubes can be opened. The contractility of the pul-
monary tissue on the application of galvanism, recently observed by Dr. C. J. B. Williams, establishes the
muscularity of the circular fibres of the bronchial tubes. The mucous membrane, as in the trachea, has a co-
lumnar and ciliated epithelium ; it of course enters into and lines the pulmonary cells.]
THE LUNGS. 421
the arrangement of the cartilaginous segments, which appear, as it were, shaped ex-
pressly for the purpose of fitting between each other at their extremities, and of consti-
tuting an apparatus capable of being moved, and, on the other, the existence of circular
contractile fibres on the inner surface of these segments, we cannot doubt that they are
moved upon each other, the extent of such motion being measured by the space they
have to traverse in order to come into contact. When this is effected, the canals must
be almost completely obliterated.*
The Pulmonary Vessels and Nerves.
Besides the trachea, the bronchi and the bronchial ramifications, which may be re-
garded as forming the framework of the lungs, these organs receive two sets of arteries,
viz., the pulmonary and the bronchial, and give out two sets of veins, also called _p?<i[wio-
nary and bronchial. A very great number of lymphatics arise from their interior, and
from their surfaces, and they are penetrated by important nerves.
The size of the pulmonary artery is equal to, if not greater than that of the aorta ; J:he
bronchial arteries appear to be distributed upon the bronchi and their ramifications, which
they exactly follow.
The pulmonary veins correspond with the pulmonary artery : they are two in number
for each lung. The bronchial veins correspond with the bronchial arteries, and terminate
in the vena azygos on the right side, and in the superior intercostal vein on the left.
Within the lung, as well as at its root, the pulmonary arteries and veins always ac-
company the bronchial tubes. The three vessels may be distinguished from each other
upon sections of the organ by the following characters : the artery remains open, or
rather so, and is of a white colour ; the bronchus is also open, but of a more or less rosy
colour, and contains a frothy mucus, which may be pressed out of it ; the vein is collap-
sed, and much more difficult to be seen than the artery. The relations of these three
kinds of vessels have not appeared to me to be constant. Notwithstanding the investi-
gations of Haller, the arrangement of the bronchial with regard to the pulmonary arter-
ies and veins is not well known, t
I ought to notice the easy communication between the arteries and the pulmonary
veins and bronchial ramifications. The coarsest injection pushed with moderate force
passes with the greatest facility from the arteries into the pulmonary veins and the
bronchial tubes ;t only infljmied portions of the lung have appeared to me to be imper-
meable.
The lymphatic vessels, both superficial and deep, are very numerous ; they terminate
in the bronchial and tracheal glands, the number and size of which sufficiently declare
their importance. The black colour of these glands only begins to appear from the tenth
to the twentieth year.
The iierves of the lungs are principally derived from the pneumogastrics, but they re-
ceive some branches from the ganglionic system. They form a large plexus behind the
bronchi, with the divisions of which they penetrate into the substance of the lung. I
should observe that there is only one great pulmonary plexus common to the two lungs ;
and on this circumstance the sympathy between the two is without doubt partially de-
pendant.
Development. — According to Meckel, the lungs are among the latest organs to appear
in the foetus ; they can only be distinctly recognised amid the other contents of the tho-
rax, towards the end of the second month of intra-uterine existence.^
* These anatomical facts explain, in a remarkable manner, all the phenomena of nervous asthma, nervous
cuffocation, &c.
t [The following are the results of Reisseisen's observations on this subject : the branches of the pulmonary
artery accompany the bronchial tubes, and do not anastomose until their termination in a dense network of
capillaries npon the walls of the air-cells. These capillarie» have very thin coats ; they are about one twen-
tieth the diameter of a pulmonary cell, and the meshes which they form are scarcely so wide as the vessels
themselves. From this network arise tlie branches of the pulmonary veins, which unite into larger and larger
trunks, so as to correspond with the divisions of the pulmonary artery ; these veins have no valves, and their
caliber is not greater, perhaps less, than that of the artery.
> Such is the chief mcxie of distribution of the pulmonary artery and veins ; but both vessels, as indicated be-
low, also communicate with the bronchial arteries.
The bronchial arteries are the nutrient vessels of the lung ; some of their branches are distributed upon the
air-tubes and to their lining membrane, even as far as the air-cells, upon all the pulmonary vessels and nerves,
and to the bronchial lymphatic glands ; while others, passing between the lobules, or upon the surface of the
lung, anastomose with twigs from the pulmonary artery, and form, with the branches of the pulmonary vein,
a vascular network in those situations, but more particularly beneath the pleura. The branches distributed
to the lirger bronchia and vessels, and to the lymphatic glands, and also some of the vessels composing the
superficial network, terminate in the bronchial veins, which, however, cannot be traced very deeply into the
substance of the lung. But by far the greater number of the bronchial arteries end in the pulmonary veins ;
for example, those distributed deeply to the smaller air-tubes and pulmonary vessels, and to the air-cells, and
nearly all the vessels which enter into the formation of the interlobular and superficial network.]
i [This is due to rupture of the pulmonary vessels, which have exceedingly delicate coats, and are, perhaps,
less supported by surrounding tissue than the vessels of other organs.]
I> [The development of the lungs has been traced by various recent observers in frogs, birds, and mammalia,
including man ; according to Rathke and Miiller, it closely resembles, in its early stages, that of the compound
glands. In mammaUa, the lungs appear at first as a protuberance upon the anterior part of the (Esophagus,
consisting of a soft mass, like the primitive blastema of a gland : within this substance a more opaque portion
is formed, from which white lines extend, dividing and subdividing, and terminating in enlarged extremities
422 SPLANCHNOLOGY.
The lung is smallest at the earliest period of its development. Its place appears then
to be occupied by the thymus, which is the only organ that is seen when the thorax is
opened, the lungs being situated behind it, upon each side of the vertebral column. The
development of the lung takes place in an inverse ratio to that of the thymus, the lung
increasing in proportion as the thymus diminishes. In the last two months of pregnancy
the lung is completely developed, and fit for performing respiration.
Tlie weight of the lung in the foetus and in the adult presents some differences, which
are well worthy of attention. During the whole period of intra-uterine life, the foetal
lung is specifically heavier than water ; but as soon as the infant respires, it become?
much lighter, and floats in water.
Yet the absolute weight of the lung is sensibly increased, because it receives a much
greater quantity of blood than it did previously. Before birth, the absolute weight of
the lung to that of the whole body is as 1 to 60 ; after birth, it is as 1 to 30. It follows,
therefore, that lungs which float in water, and which have acquired a much greater ab-
solute weight than they would have had in the foetus, must belong to an infant that has
respired.
After birth, the lung participates in the development of the rest of the body. At the
tmie of puberty it acquires the proportions which it subsequently presents. I have not
observed that the lungs are smaller and lighter in the aged than in the adult.
The colour of the lungs varies considerably at different periods. In the earlier periods
ot development, the lung of the foetus is of a delicate pink colour ; subsequently it be-
comes of a deep red, like lees of wine, and remains so until the time of birth. After
birth, it again becomes of a pink colour. Still later, from the tenth to the twentieth
year, black spots become visible at different points along the lines which form the loz-
enge-shaped intervals on its surface. These spots subsequently unite into lines or
patches, which give to the grayish surface of the organ a mottled appearance. The de-
velopment of the black matter is so clearly the effect of age, that it is very rare not to
find small masses of it in the apex or some other part of the lungs in the old subject. It
is worthy of notice, that the black matter appears simultaneously on the surface of the
lung, and in the lymphatic glands situated at its root and along the bronchi.
With regard to structure, it may be observed, that during the four or five earlier months
of gestation, the pulmonary lobules are perfectly distinct from each other ; they may be
separated by very gentle traction, on account of the weakness of the pleura and cellular
tissue which unites them, as compared with the pulmonary tissue itself. The cartila-
ginous rings begin to be visible after the third month.
Functions. — The lungs are the essential organs of respiration, that process by means
of which the blood, though dark and unfit for supporting life before entering these or-
gans, becomes red and vivifying. For the accomplishment of this function, the lungs
receive, on the one hand, the atmospheric air, and, on the other, the venous blood, the
whole of which, in the human subject, passes through the lungs. The air is not drawn
in by any power resident in the pulmonary tissue itself, but by the muscular action of
the parietes of the thorax ; the blood is propelled into it by the right ventricle of the
heart. While the blood undergoes the changes above mentioned, the atmospheric air
loses a portion of its oxygen, which is replaced by carbonic acid gas. The manner in
which these changes in the blood are effected is not yet weU known.
The Larynx.*
It is necessary to have several specimens, from subjects of different ages and sexes,
so as to be able to examine the genpred relations of the larynx in its natural situation ;
its cartilages separated from each other, its ligaments and muscles, its vessels and
nerves, and its mucous membrane.
The larynx is a sort of box (jnxis cava) or cartilaginous passage, consisting of several
movable pieces, which form a complex apparatus intended for the organ of the voice.
It is situated {v, fig. 140) in the median line, in the course of the air-passages, opening
into the pharynx (3) above, and being continuous with the trachea (x) below : it occu- ,
pies the anterior and upper part of the neck, below the os hyoides, the movements of
which it follows, and in front of the vertebral column, being separated from it by the
pharynx : it is covered by the muscles of the sub-hyoid region, which intervene between
it and the skin, and it is, therefore, veiy liable to woimds, and may easily be reached by
the surgeon. Its mobility allows of its being raised, depressed, and carried forward or
backward, all of which movements are concerned both in deglutition and in the produc-
tion of different tones of the voice. It may also be carried to the right or left side ; but
these lateral displacements are most commonly produced by external violence, or by the
growth of tumours.
these are accompanied by bloodvessels, and are at first solid, but soon become hollowed ont, into the trachea,
bronchi, bronchial tubes, and air-cells.]
* The voice belongs essentially to the functions of relation, and, therefore, Bichat describes its organ after
the apparatus of locomotion ; but the anatomical connexions between the larynx and ihe respiratory organs
are such that all animals provided with lungs have a larynx also, while the larynx disappears where the lungs
oease to exist.
THE LARYNX. 45J3
Dimensions. — The larynx appears like an expansion of the trachea, and has, therefore,
been denominated its head, caput asperez arteria. The exact determination of its dimen-
sions, according to age and sex, or in different individuals, and their relations to the
various qualities of the voice, would be extremely interesting in a physiological point of
view. Its greater size in the male than in the female, and the development it under-
goes in both sexes, but especially in the male, at the period of puberty, are among the
most remarkable phenomena in the human economy.
Form. — It is cyhndrical below, like the trachea, but is expanded above, and becomes
prismatic and triangular. It may, therefore, be compared to a three-sided pyramid, the
truncated apex of which is directed downward and the base upward ; it is perfectly sym-
metrical.
As the larynx is a very complicated organ, I shall describe, in succession, the numer-
ous parts which enter into its composition. Being intended to admit of the continual
passage of the air in the act of r-espiration, it must, therefore, present a constantly per-
vious cavity, having strong and elastic wedls ; but as it is also the organ of the voice, it
requires to be provided with a movable apparatus, subject to the wiU. We accordingly
find in it a cartilaginous skeleton or framework, much stronger than that of the trachea ;
certain articulations and ligaments, and a vocal apparatus, composed of four fibrous
bands, or vocal cords ; muscles, which move the different pieces of the cartilaginous
skeleton, and produce certain changes in the vocal apparatus indispensable for the pro-
duction of sounds ; a mucous membrane, lining its inner surface ; glands, which pour
out their fluid upon that surface ; and, lastly, certain vessels and nerves.
We cannot enter upon a general description of the organ untU we have studied sep-
arately its constituent parts.
The Cartilages of the Larynx. — ^These are five in number, of which three are median,
single, and symmetrical, viz., the cricoid, the thyroid, and the epiglottis ; and two are lat-
eral, viz., the arytenoid, of which the cornicula laryngis are merely appendages. The car-
tilaginous nodules, described by some authors under the name of the cune^orm cartilages,
and situated in the membranous fold extending from the arytenoid cartilages to the epi-
glottis, do not exist in the human subject.
The Cricoid Cartilage. — The cricoid or annular cartilage (c c', figs. 173 to 177) forms
the base of the larynx ; it is much thicker and stronger than any j^^ j73
of the others. Its form is that of a ring, whence its name («pi«of ,
a ring); it is narrow in front (c,fig. 173), where it resembles a
ring of the trachea ; it is three or four times broader or deeper
behind (c'and c,fig. 175), where it forms by itself alone the great-
er part of the larynx, being there about an inch in height. Li
front, its external surface is sub-cutaneous in the median line ; on
each side it gives attachment to the crico-thyroid muscle, and
presents a smooth process (m, fig. 177) for articulating with the
thyroid cartilage. Behind, where it is covered by the mucous
membrane of the pharynx, it presents in the median line a verti-
cal projection, which gives attachment to some of the longitudi-
nal fibres of the oesophagus, and on each side a depression for
the posterior crico-arytenoid muscle.
Its internal surface is covered by the laryngeal mucous mem-
brane.
Its lower border is perfectly circular and slightly waved, and is
connected by a membrane with the first ring of the trachea ;
sometimes it is even united with it, and can only be distinguished by its greater thickness.
Its upper border is not exactly circular, but is oblong from before backward, as if the
ring had been flattened laterally. It is cut very obUquely forward and downward, or,
rather, it is deeply notched in front, where it is concave, and gives attachment to the
crico-thyroid membrane in the median line, and laterally by its inner lip to & fibrous
membrane, which is continuous veith the inferior vocal cord, and in the rest of its thick-
ness with the lateral crico-arytenoid muscle.
Behind, and on each side, is an oblong, articular facette, the arytenoid facettes (h h,fig.
173), which are directed outward and upward, and articulate with the arytenoid carti-
lages. Between these two facettes, the upper border of the cricoid is horizontal, and
very slightly notched, and gives attachment to the arytenoid muscle. The upper bor-
der of the cricoid cartilage is, therefore, horizontal behind, oblique at the sides, and hor-
izontal and slightly concave in front. The arytenoid facettes are situated upon the ob-
lique portion.
The Thyroid Cartilage. — The thyroid or scutiform cartilage (t,figs. 173 to 177), so na-
med because it has been compared to a shield (i^upcdf, a shield),* occupies the upper
and fore part of the larynx. It is formed by two quadrilateral plates (or alee), united at
an acute angle in the median line, and embracing the cricoid cartilage behind. Its aia-
* The name may also have been derived from its use.
424 SPLANCHNOLOGY.
teriar or cutaneous surface presents in the median line an angular projection (below c,
fig. 173), more marked and deeply notched above, and completely effaced below; much
less distinct in the female, in whom it forms only a rounded surface, than in the male,
in whom it has received the special appellation of the pomum Adami. This angular pro-
jection does not appear until puberty ; it presents certain individual varieties, but these
do not appear to me to have any relation with the qualities of the voice.
On each side the surface {t, Jigs. 173, 174) is smooth and quadrilateral, and has two
tubercles behind ; one of which is superior (b), and the other inferior {d). The latter,
or larger, is prolonged upon the inferior border of the cartilage. The two tubercles are
united by an aponeurotic arch, but there is no oblique intermediate line, as has been gen-
erally alfirmed. These tubercles, and the imaginary line between them, separate the
anterior three fourths of the surface, which are covered by the thyro-hyoid muscle, from
the posterior fourth, which is covered by the inferior constrictor of the pharynx and the
sterno-thyroid muscle. The tubercles give attachment to these three muscles.
The posterior surface {fig. 175) presents, in the median line, a retreating angle, which
gives attachment to the thyro-arytenoid ligaments, or vocal cords, and to the thyro-ary-
tenoid muscles. This angle is sometimes so acute that the cartilage has the appear-
ance of having been subjected to strong lateral pressure.
On each side {t t) the posterior surface projects beyond the cricoid cartilage, and forms
part of the lateral groove of the larynx. It is lined by the pharyngeal mucous membrane,
and corresponds in part to the thyro- and crico-arytenoid muscles.
Its upper border is horizontal and sinuous, and gives attachment to the hyo-thyroid
membrane in its whole extent. It presents a notch (e, fig. 173) in the median line, which
is shallower, but broader and more rounded in the female than in the male. On the
sides there is a small prominence, which forms a continuation of the superior tubercle, and
is often wanting. More posteriorly, we find on each side a slight notch, bounded by cer-
tain processes called the great or superior comua {s, figs. 173, 174) of the thyroid cartilage.
The lower border is sinuous, and shorter than the upper, and hence the pyramidal shape
of the larynx. It presents a slight median projection, to which the crico-thyroid liga-
ment is attached ; in the rest of its extent, it gives insertion to the crico-thyroid muscle,
and presents a rough eminence, which forms a continuation of the inferior tubercle ; and
more posteriorly, on each side, a slight notch, bounded by the lesser or inferior comua {I,
Jigs. 173, 175) of the thyroid cartilage.
Its posterior borders (s r, fig. 174) are slightly sinuous, give attachment to the stylo-
pharyngei and palato-pharyngei, and rest upon the vertebral column. As the thyroid
cartilage projects behind the upper portion of the larynx, it may be regarded as protect-
ing the larynx by its posterior borders resting upon the vertebral column.
The comua of the thyroid cartilage are four in number, two superior and two inferior, and
appear to be prolongations of the posterior borders of the cartilage. They are all round-
ed, and are bent inward and backward ; the upper or great comua (s) are generally the
larger, and are united by ligaments to the os hyoides ; the lower or lesser comua (J) are
usually smaller, and articulate with the cricoid cartilage.
The Arytenoid Cartilages. — The arytenoid cartilages {a, figs. 173, 175 to 177) are two
in number,* are situated at the upper and back part of the larynx, and have a pyramidal
and triangular form ; they are directed vertically, and bent backward like the lip of an
ewer, whence their name {dptraiua, a funnel). Their posterior surface (fig. 175) is trian-
gular, broad, and concave, and receives the arytenoid muscle ; their internal surface is
fined by the mucous membrane of the larynx ; their anterior surface (fig. 173) is convex,
narrow, rough, and furrowed, and corresponds to the series of glands called tlie aryte-
noid glands, and to the superior vocal cord ; their base is very deeply notched, articulates
with the cricoid cartilage, and is terminated by two processes : one posterior and exter-
nal (/), which gives attachment to the lateral and posterior crico-arytenoid muscles ; the
other is anterior (a), pyramidal, and more or less elongated, has the inferior vocal cord
attached to its point, and it forms a fourth, or almost a third, of the antero-posterior di-
ameter of the glottis ; their apex is surmounted, or rather formed, by two very small and
delicate cartilaginous nodules (g), which are bent inward and backward, and iiicurvated
so that they almost touch ; they are called the cornicula. They were very correctly descri-
bed by Santorini, under the name of the sixth and seventh cartilages of the larynx. They
are now generally known as the tubercles of Santorini, the capitula or cornicula laryngis.
They appear to me constantly to exist, sometimes closely united with the arytenoid carti-
lages, and not moving at all upon them, and sometimes perfectly distinct and very movable.
The Epiglottis. — The epiglottis (em, upon, and yluTrlg, the glottis, i,figs. 174 to 178),
or lingula, forming a movable and highly elastic valve, is a fibro-cartilaginous lamina,
situated (i, fig. 140) behind the base of the tongue, and in front of the superior opening
of the larynx, not upon the glottis, as its name would seem to indicate.
* It was for a long time believed that there existed only one arytenoid cartilage, because the larynx was al-
ways examined when covered by its membranes ; so that the word arytenoid, in the works of Galen, is always
applied to the two united, Galen only admitted three cartilages in the larynx— the thyroid, the cricoid, and
the arytenoid, .
^^r
THE LARYNX. 42^
Its direction is vertical, excepting at the moment of deglutition, when it becomes hori-
zontal, so as to protect the opening of the larynx like a lid {laryngis operculum). Its tri-
angular shape has been well compared to that of a leaf of purslaine. It must be separa-
ted from the neighbouring parts to be properly studied.
It varies much in size in different subjects, but always appears to me to bear some re-
lation to the dimensions of the upper orifice of the larynx, beyond which it almost al-
ways projects when depressed.
Its anterior or lingual surface presents a free and an adherent portion. The free por-
tion surmounts the base of the tongue ; it may be felt by the finger, and even seen by
strongly depressing the tongue.* Three folds of mucous membrane, one in the middle
and one on each side, pass from the epiglottis to the base of the tongue.
The adherent portion corresponds in front with the base of the tongue, the os hyoides,
and the thyroid cartilage. In order to expose it, it is necessary to have recourse to dis-
section. We then find a median glosso-epiglottid ligament, which is very strong, and com-
posed of yellow elastic tissue, and which, I beheve, assists in drawing back the depress-
ed epiglottis ; its place is occupied by muscular fibres in the larger animals ; also a hyo-
epiglottid ligament, extending from the epiglottis to the posterior surface of the os hy-
oides ; and, lastly, beneath this ligament, a yellow fatty tissue, improperly called the
epiglottid gland, occupying the interval between the epiglottis and the concavity of the
thryoid cartilage.
Moreover, the anterior surface of the epiglottis, examined in the vertical direction, is
concave above, convex in the middle, and again concave below ; it is convex in the trans-
verse direction. The posterior or laryngeal surface {figs. 175, 178), the curvatures of
which are the reverse of those on the anterior surface, is free in the whole of its extent,
and covered by the laryngeal mucous membrane.
Circumference. — Its upper margin, or the base of the triangle which it represents, is
free, bent forward, slightly notched, and continuous, by two rounded angles, with its lat-
eral margins, from each of which proceed two folds, viz., the aryteno-epiglottid {h,fig.
178), extending from the epiglottis to the arytenoid cartilage, and enclosing a ligament
(b,fig. 176), and the pharyngeo-epiglottid, situated anterior to the preceding, passing al-
most transversely outward, and lost upon the sides of the pharynx.
The epiglottis terminates below in a sort of pedicle, which is extremely slender, and
is fixed {fig. 176) into the retreating angle of the thyroid cartilage, immediately above
the attachment of the vocal cords. This attachment is effected by means of a ligament,
called the thyro-epiglottid.
The epiglottis is remarkable for the great number of perforations found in it, which
give it an appearance very much resembling that of the leaves of several of the lauracece.
In these foramina we find small glands, which, for the most part, open on the laryngeal
surface of the epiglottis. The so-called epiglottid gland has no relation with these orifices.
It is also remarkable for its flexibility and elasticity ; on account of which it is classed
by Bichat among the fibro-cartilages, a sort of tissue which we have stated does not ex-
ist. Its yellow colour gives it an appearance like the yellow elastic tissue. It is brittle,
and may be crushed between the fingers ; this depends partly upon the nature of its tis-
sue, and partly upon the numerous foramina with which it is perforated, and which ne-
cessarily diminish its strength.
The Artictdations and Ligaments of the Larynx.
The articulations of the larynx may be divided into the extrinsic and the intrinsic.
The Extrinsic Articulations. — The thyro-hyoid articulation consists of three ligaments,
which unite the thyroid cartilage to the os hyoides. The middle jy.. 174.
thyro-hyoid ligament {n, fig. 174) is a loose yellowish membrane, ex-
tending from the upper border of the thyroid cartilage {t) to the os
hyoides (m). Its vertical dimensions are much greater at the sides
than in the middle ; and, therefore, the comua of the os hyoides
can be raised higher than its body, and hence the sides of the tongue
can be elevated so as to form a groove, along which the food glides.
This membrane is thick in the middle, and thin, and, as it were,
cellular on each side.
Relations. — It is sub-cutaneous in the middle, but is covered on
each side by the thyro-hyoid muscle. It corresponds behind with
the epiglottis, from which it is separated by some adipose tissue,
and with the mucous membrane covering the posterior surface of
the tongue. It is attached to the posterior lip of the upper edge
of the OS hyoides, not to the lower edge, as is frequently asserted.
It therefore passes behind the os hyoides.
The lateral thyro-hyoid ligaments (0) may be considered as the margins of the thyro-
hyoid membrane. They are small cords, extending from the great comua of the thyroid
* I attach groat importance to inspection of the epiglottis in diseases of the larynx.
Hb H
^88 8PLANCHN0L0GT.
cartflage to the tubercular extremities of the great comua of the os hyoidea. We often
find a cartilaginous or bony nodule in these ligaments.
There is a very distinct synovial capsule between the posterior surface of the body of
the OS hyoides and the upper part of the thyroid cartilage. Its presence attests the fre-
quent movements which take place between these parts, and during which the middle
and upper part of the cartilage is placed behind the os hyoides.
The Tracheo-cricoid Articulation. — The first ring of the trachea is connected with the
lower border of the cricoid cartilage by a fibrous membrane of the same nature as that
between the rings of the trachea. A small vertical fibrous cord is added to it in the
median line in front. This membrane permits some movements between the cricoid
cartilage and the first ring of the trachea, and in these the sides of the ring are buried
behind the cricoid cartilage.
The intrinsic articulations are the crico-thyroid and the crico-arytenoid. I need merely
remind the reader of the articulation between the arytenoid cartilages and the comicula
larjTigis.
Tlie Crico-thyroid Articulations. — ^These are arthrodial. Each of the lesser comua of
the thyroid cartilage terminate in a plane surface, directed downward and inward, which
rests upon a similar plane surface {m,fig. 177) on the cricoid cartilage, directed upward
and outward. An orbicular or capsular ligament (r,figs. 174, 175), composed of shining,
fasciculated, and parallel fibres, surrounds the articulation, which is provided with a
synovial membrane. The posterior fasciculus is remarkable for its length and shape,
and extends nearly to the crico-arytenoid articulation. In some subjects the orbicular
ligament is very loose, in others the articulation is exceedingly close.
The movements are limited to simple gliding, combined with a forward and backward
movement of the th3Toid cartilage. The direction of the facettes upon the cricoid car-
tilage renders them fitted to support the thyroid.
The Crico-thyroid Membrane, or Middle Crico-thyroid Ligament. — Besides the preceding
articulations, the lower border of the thyroid cartilage is connected with the upper border
of the cricoid by a thick triangular membrane, the pyramidal or conoid ligament (v, Jig.
174), which is attached in the median line to the lower border of the thyroid cartilage,
and the base of which is fixed to the upper border of the cricoid cartilage. This mem-
brane is fibrous, thick, very strong, perforated with foramina for vessels, and is yellow
and elastic.
The Lateral Crico-thyroid Ligament. — This ligament {d,fig. 176) can be well seen
only from the inner surface of the larjoix. It consists of very strong fibres, which arise
from the inner lip of the upper border of the cricoid cartilage, in front of the crico-ary-
tenoid articulation, and pass horizontally inward to the retreating angle of the thyroid
cartilage, below the insertion of the inferior vocal cord (r). This ligament, which is very
strong, appears to be continuous above with the inferior vocal cord. It is covered on
the inside by the mucous membrane of the larynx, and it corresponds on the outside {d,
fig. 177) to the thyro- (e) and crico-arytenoid (/) muscles, which separate it from the
thyroid cartilage.
The Crico-arytenotd Articulations. — These articulations are effected by mutual reception.
The articular swr/ace, upon the cricoid cartilage, is an eUiptical facette {h,fig. 173), di-
rected obliquely downward and forward, and oblong and slightly concave in the same di-
rection. The base of the arytenoid cartilage presents an oblong articular facette, deeply
concave from without inward, i. c, in an opposite direction to the former, which it accu-
rately receives.
Means of Union. — Properly speaking, there is only one ligsunent, the internal and poste-
j^. ,.- rior (e, fig. 175). It arises from the cricoid cartilage, and is insert-
^' ' • ed in a radiated manner into the inner and back part of the base of
the arytenoid cartilage, and to the inner side of its anterior process,
behind the inferior vocal cord. This ligament is very strong, but
yet suiEciently loose to allow of certain extensive movements.
There is also a very loose synovial capsule, which can be easily
demonstrated.
The movements of this articulation, like those of all similar joints,
take place in every direction ; but the movements inward and out-
ward are much more extensive than those which are performed
forward and backward. On account of the mode of insertion of its
muscles, the arytenoid cartilage is not moved in a direct line, but
undergoes a partial rotatory movement, the centre of which is in
the articulation. In the movement, which is oblique, on account
of the obliquity of the articular surfaces, the apex of the arytenoid
cartilage is carried either outward and backward or inward and for-
ward. These motions should be studied with the greater care, because they afford an ex-
planation of the changes which take place in the glottis during the production of the voice.
The Aryteno-epiglottid Ligament. — This ligament {b, figs. 176, 177) is constituted by
some radiated ligamentous fibres contained within the aryteno-epiglottid fold of mucous
THE LARYNX. 427
membrane, and which pass from the anterior surface of the arytenoid cartilage to the
corresponding margin of the epiglottis. In some animals, this ligament is replaced by
muscular fibres.
The Thyro-arytenoid Ligaments, or Chorda Vocales. — Although there is no immediate
relation between the thyroid and the arytenoid cartilages, they are united by four very
important ligaments, named the chorda vocales, which require a special description.
The chorda vocales are also called the vocal bands, the ligaments of Ferrein, or the thy-
ro-arytenoid ligaments, because tliey have a ligamentous appearance, and extend from
the retreating angle of the thyroid cartilage to the arytenoid cartilages.
There are two vocal cords on each side, a superior (s, Jigs. 176, 178) and an inferior (r) ,
the space between them is called the ventricle of the larynx (v), and the interval between
the cords of the right and left sides is called the glottis {o,Jig. 178).* I shall speak of
these parts again presently.
The inferior vocal cord (r, Jig. 176) is much stronger than the superior, and has the form
of a rounded fibrous cord, stretched horizontally from the retreating y. j^g
angle of the thjToid cartilage to the anterior process of the arytenoid
cartilage. It is free in all directions, excepting on the outside, where
it is in contact with the thyro-arytenoid muscle. Its free portion is
covered by the mucous membrane of the larynx, which adheres inti-
mately to it, and is so thin that the white colour of the cord can be
seen through it. This vocal cord is thinner than it appears at first
sight, the projection which it forms being, in a great measure, due
to the thyro-arytenoid muscle. Its structure is entirely ligamentous,
and consists of parallel fibres, running from before backward, and not
at all elastic, t
It is continuous below with the lateral thjrro-cricoid ligament (d).
The superior vocal cord (s) is smaller, and situated farther from the
axis of the larynx than the inferior one (see Jig. 178), and extends
from the middle of the retreating angle of the thyroid cartilage to the
middle of the anterior surface of the arytenoid cartilage : like the inferior cord, it has a
fasciculated and fibrous appearance ; but the fasciculi are few in number, and are inter-
mixed with a series of glandular masses. The superior vocal cord can only be distin-
guished from the rest of the parietes of the laiynx from the reflection of the mucous
membrane below it, so as to form the ventricle. It is continuous with the aryteno-epi-
glottid ligament (Jb, Jig. 176) above, without any line of demarcation.
Muscles of the Larynx.
These are divided into the extrinsic and the intrinsic : the former, which move the en-
tire larynx, have been already described, viz., the sterno-hyoid, omo-hyoid, stemo-th)Toid,
and thyro-hyoid ; to which we might add all the muscles of the supra-hyoid region, and
those muscles of the pharynx which have attachments to the cricoid and thyroid cartilages.
The intrinsic muscles are nine in number, viz., four pairs and one single muscle.
Those which exist in pairs are the crico-thyroidei, the crico-arytenoidei postici, the cri-
co-arytenoidei laterales, and the thyro-arytenoidei. The single muscle is the arjrtenoideus.
The Crico-thyroideus.
. Dissection. — This muscle is completely exposed by separating the larynx from the
muscles by which it is covered. In order to gain a good view of the deep portion of the
muscle, the lower part of the thyroid cartilage must be removed.
The crico-thyroideus {a, figs. 147, 170) is a short, thick, triangular muscle, situated on
the anterior part of the larynx, on each side of the crico-thyroid membrane, and divided
into two distinct bundles. It is attached below to the cricoid cartilage on each side of
the median line, to the whole of the anterior surface, and even to part of the lower bor-
der of the cartilage. From these points the fleshy fibres radiate in different directions :
the internal fibres pass somewhat obliquely upward and outward ; the middle ones very
obliquely, and the lower fibres horizontally outward, to the lower border of the thyroid
cartilage (excepting to its middle portion), and to the lower margin of the corresponding
lesser cornu. The greatest number of fibres are inserted into the posterior surface of
the thyroid cartilage ; some of them are continuous with the inferior constrictor of the
pharynx (w, Jig. 147).
It is covered by the sterno-thyroid muscle and the thyroid gland, and it covers the lat-
eral crico-arytenoid and the thyro-arytenoid muscles. The inner borders of the crico-
thyroid muscles are separated from each other by a triangular space, broad above and
narrow below, in which the crico-thyroid membrane is visible.
* [In consequence of the voice being essentially produced opposite the inferior cords, they are termed the
true vocal cords ; the superior being- called the false vocal cords.]
t [The inferior vocal cords are certainly composed of elastic tissue, so, also, are the thyro-hyoid and crico-
thyroid ligaments ; and, according to M. I.auth (M'm. de VAcad. Roy. de Med., 1835), the lateral crico-thyroid
membranes, the superior vocal cords, and the aryteno-epiglottid ligaments are also composed of this tissue,
which, he says, exists even in the thyro-epiglottid, hyo-epiglottid, and glosso-epiglottid ligaments.]
428 SPLANCHNOLOGY.
Their action is not yet well determined. By taking theif'feed'pmnfuponthe' cricoid
cartilage, it appears to me that they would move the thyroid cartilage in such a way as
to increase the antero-posterior diameter of the glottis, and thus act as tensors of the
vocal cords.
The Crico-arytenoideus Posticus.
Dissection. — This muscle is exposed by removing the mucous membrane from the
posterior surface of the larynx.
It is a triangular muscle {g,figs. 171, 177), situated at the back of the cricoid carti-
lage. Its fibres arise from the lateral depression, which we have described on tlie pos-
terior surface of the cartilage, and pass in different directions ; the upper fibres are the
shortest, and are almost horizontal ; the middle are oblique, and the lower are nearly
vertical ; they £dl converge towards the posterior and external process on the base of
the arytenoid cartilage, behind the crico-arytenoideus lateralis.
Relations. — It is covered by the mucous membrane of the pharynx, to which it is very
loosely united, and it covers the cricoid cartilage.
Action. — It is a dilator of the glottis. It carries the base of the arytenoid cartilage
backward, outward, and downward, and thus renders the inferior vocal cord tense
The Crico-arytenoideus Lateralis.
Fig. 177. Dissection. — Remove with care one of the lateral halves of the
thyroid cartilage (as in fig. 177). It is impossible to separate this
muscle from the thyro-arytenoideus.
This is an oblong muscle (/), situated deeply under the thyroid
cartilage. Its fibres arise from the side of the upper border of the
cricoid cartilage, in front of the crico-arytenoid articulation ; from
this point they proceed obliquely upward and backward, to be insert
ed into the posterior and external process of the arytenoid cartilage,
by a tendon common to them, and to the thyro-arytenoideus. It is
covered by the thyroid cartilage and by the crico-thyroid muscle, and
it covers the lateral crico-thyroid membrane (d).
The Thyro-arytenoideus.
Dissection. — The same as for the preceding. This muscle may be
dissected from the interior of the larynx, by removing the vocal cords.
I describe the thyro-arytenoideus and the crico-arytenoideus lateralis separately,
merely in accordance with custom, for in no instance, not even in large animals, such
as the ox, have I ever been able to separate them completely. They have the same
arytenoid insertion ; their fibres are situated upon the same plane, without any line of
demarcation, and they fulfil the same uses. We naight, therefore, imite them under the
name of the thyro-crico-arytenoideus.
The thyro-arytenoideus (e) is a broad muscle, very thin above and very thick be-
low. It arises on each side from about the lower two thirds of the retreating angle of
the thyroid cartilage. The greater number of its fibres arise from the lower part of the
angle, and form a very thick fasciculus. From these points they pass horizontally back-
ward and outward, and terminate in the following manner : The thick fasciculus above
mentioned is inserted into the outer surface of the anterior process of the arytenoid car-
tilage, and into a depression on the outer side of the base of that cartilage, between the
two processes. The upper fibres are attached to the outer border of the arytenoid car-
tilage. In the larger animals, the upper fibres of the muscle evidently proceed to the
epiglottis, and form the thyro-epiglottideus of some authors.
Relations. — On the outside it corresponds with the thyroid cartilage, from which it is
separated by loose and sometimes adipose cellular tissue ; on the inside it is in contact
with the vocal cords and the ventricle of the larynx. The thickest part of the muscle
corresponds with the inferior vocal cord, and is almost the only cause of its projecting
into the interior of the larynx. This fasciculus may even be considered as contained
within the substance of the inferior vocal cord, and the two structures are so closely
adherent that great care is required to separate them. Many anatomists, indeed, have
thought that the fibres of the thyro-arytenoideus terminate in the vocal cord, which they
therefore regarded as the tendon of the muscle ; but the cord and muscle may always be
completely separated.
Action. — It carries the arytenoid cartilage forward, and would thus seem to relax the
inferior vocal cord, as Haller believed : " Cartilagines guttales (the arytenoid) antrosum
ducunt, glottidem dilatant, ligamentorum glottidis tensionem minuunt." {Elemcnta Physiol.,
t. iii., liv. ix., p. 387.) But if we consider the mechanism of the crico-arytenoid articula-
tions, and the mode of insertion of the thyro-arytenoid muscles into the outer side of
the bases of the arytenoid cartilages, we shall perceive that, at the same time that these
cartilages are carried forward, they undergo a partial rotatory movement, by which their
anterior processes are turned inward. The ligaments of the glottis are, therefore, ren-
THE LARYNX. 429
dered tense, and approximated towards each other. This movement may be carried to
such an extent that the anterior processes may touch, and the antero-posterior diameter
of the glottis be diminished accordingly.*
The thyro-arytenoideus is, then, both a tensor and a constrictor of the glottis. This,
moreover, was the opinion of both Cowper and Albinus, but Hedler attempted to re-
fute it.t
The sudden action of the thyro-arytenoid muscle, pressing upon the ventricle of the
larynx, may expel any mucus collected within it.
The Arytenoideus.
Dissection. — Remove the mucous membrane and glandular masses which cover it be-
hind. Detach it along one of its borders, so as to be enabled to examine its thickness.
The arytenoideus {a, fig. 171) is a single, short, thick, trapezoid muscle, situated be-
hind the arytenoid cartilages, and filling up the concavity on their posterior surfaces, as
well as the interval between them. It arises from the whole length of the outer border
of the right arytenoid cartilage, and is inserted into the corresponding part of the left.
Some of the fibres arise from the upper border of the cricoid cartilage. The fibres have
a triple direction, and form three layers, which have been regarded as so many distinct
muscles.
The two more superficial layers are oblique, and cross each other, one passing from
the base of the right arytenoid cartilage to the apex of the left, and the other following
the opposite direction ; they constitute the arytenoideus ohliquus of Albinus : both of these
layers are thin.
The third and deepest layer is very thick ; it is composed of transverse fibres, and
forms the arytenoideus transversus of Albinus.
None of the fibres reach the comicula. Under the name of the aryteno-epiglottideus,
muscular fibres have been described, extending from the arytenoid muscle to the mar-
gins of the epiglottis. Some fibres of the arytenoideus are also said to be continuous
with the thyro-arytenoideus.
Relations. — Behind, with the mucous membrane and some glandular masses, which ad-
here to the muscle by means of loose cellular tissue ; in front it is in relation with the
posterior surface of the arytenoid cartilages, and in the interval between them with a
thin fibrous membrane, extending from the upper border of the cricoid cartilage to the
whole extent of the inner borders of the arytenoid cartilages.
Action. — It would appear, at first sight, that this muscle must forcibly approximate the
two arytenoid cartilages, and therefore constrict the glottis ;t but if we remember that
it is attached to the outer borders of these cartilages, we shall understand that, besides
drawing them together, it must produce in them such a movement as will carry their an-
terior processes outward, and stretch the vocal cords, but, at the same time, separate them
from each other. And if we call to mind that the th3TO-arytenoideus occasions an ex-
actly opposite movement, it will be understood that the simultaneous action of the two
muscles must produce tension of the cords, and, at the same time, fix the processes.
Having thus obtained a knowledge of the cartilages of the larynx, the articulations by
which they are united, and the muscles which move them, we shall now proceed to give
a general description of this organ.
The Larynx in general.
The larynx, the general position of which has been already described, presents certain
diflferences in its dimensions, depending either upon the individual, upon sex, or upon age.
These differences affect both the whole of the larynx and its constituent parts. Thus,
the larynx of the female may always be distinguished from that of the male by being
smaller, i. e., about two thirds the size of the male larynx ; and by the angles and pro-
cesses of its cartilages being less prominent, and their depressions less marked. These
differences are connected with the characters of the voice, and affect principally the di-
mensions of the glottis.
The individual differences in the size of the larynx have not been thoroughly examined.
The differences depending on age will be noticed when speaking of its development.
The larynx presents for our consideration an external and an internal surface.
The External Surface of the Larynx — Anterior Region {fig. 170). — In the median line we
observe a vertical ridge, formed by the angle of the thyroid cartilage ; beneath this the
crico-thyroid membrane, and still lower the convexity of the cricoid cartilage.
On the sides we find the oblique leuninae of the thyroid cartilage, a portion of the cri-
coid covered by the crico-thyroid muscle, and the thyro-cricoid articulation.
Sub-cutaneous in the median line, where it is only separated from the skin by the linea
alba of the neck, the external surface of the larynx is covered on each side by the mus-
cles of the sub-hyoid region, the inferior constrictor of the pharynx, and the thyroid gland.
* [The effect of this will be, as stated by Haller, to relax the vocal cords, which is considered by the latest
observers to be the action of these muscles.]
■t Loc. cit. " Cum magui viri glottidem dixerint ab istis musculis arctari, experimento facto diducere didici.
Neque potest ille ad latus cartilaginis arytsenoidse musculus terminari xjuin earn rimam diducat."
t [When acting together with the lateral crico-thyroid muscles, this is certainly their action.]
430 SPLANCHNOLOGY.
The superficial position of the surface enables us to examine its different parts through
the integuments, and renders it liable to wounds. Its still greater proximity to the skin
in the median line has suggested the operation of laiyngotomy.
Posterior Region {figs. 141, 171). — In the median line we observe a prominence like a
small barrel, on either side of which the thyroid cartilage projects. This prominence is
formed by the back of the cricoid, and by the arytenoid cartilages, the expanded portion
corresponding with the bases of the latter, which are covered by folds of a pale mucous
membrane. Under this membrane we find, proceeding from above downward, the ary-
tenoideus muscle, the vertical ridge of the cricoid cartilage, the crico-arytenoidei posti-
ci, and the crico-arytenoid articulations.
On each side of the barrel-shaped prominence is a deep angular groove, formed by the
meeting of two flat surfaces, which are separated above, but approximated below ; along
these grooves it is supposed that liquids flow during deglutition. The external wall of
each groove is formed by the posterior surface of the thyroid cartilage, the os hyoides,
and the thyro-hyoid membrane. The internal wall is formed by the upper and lateral part
of the barrel-shaped prominence. The grooves are lined by a closely-adherent nmcous
membrane ; and it should be observed, that they exist only on a level with the aryte-
noid cartilages, and, consequently, in this region alone is the larynx protected by the
thyroid cartSage, the posterior borders of which rest upon the vertebral column. The
back of the cricoid cartilage is on a level with the posterior borders of the thyroid {fig.
174), and, like them, rests upon the vertebral colunm.
The Internal Surface of the Larynx. — The internal surface of the larynx does not cor-
respond, either in shape or dimensions, with its outer surface ; and this depends princi-
pally on the fact that the retreating angle of the th)T:oid is the only part of that cartilage
which enters into the formation of the laryngeal cavity, the lateral laminae being alto-
gether unconcerned in it.
Cylindrical below, where it is formed by the cricoid cartilage, the cavity of the larynx
is prismatic and triangular above, where it is constituted by the epiglottis in front, the
arytenoid cartilages and the arjrtenoid muscle behind, and on the sides by the two mu-
cous folds which extend from the margins of the epiglottis to the arytenoid cartilages.
The dimensions of the lower of these two portions of the laryngeal cavity undergo no
change, always remaining the same as those of the cricoid cartilage ; while the upper,
on the contrary, which is broadest in front, varies much in size, in consequence of the
mobility of the epiglottis and the arytenoid cartilages. Between these two portions, and
about the middle of the larynx, a fissure exists, which is narrower than the rest of the
cavity, and oblong from before backward ; this is the glottis, or vocal apparatus, properly
so called. It can be seen without any dissection by looking down into the larynx {fig.
178), and requires a very particular description.
The Glottis, or Vocal Apparatus. — The glottis (yXwrrif, from y^uaaT), the tongue), fre-
quently confounded with the superior orifice of the larynx,* is a trian-
gular opening or fissure {o,fig. 178) {rima), elongated from before
backward, and included between the vocal cords of the right and
left sides. It represents two isosceles triangles, placed one above
the other, and having perfectly equal borders, the base of each being
directed backward, and its apex forward. The lower isosceles tri-
angle is formed by the inferior vocal cords (r), and the upper one by
the superior vocal cords (s). The inferior vocal cords are situated
nearer to the axis of the larynx than the superior, so that a vertical
plane let fall from the latter would leave the inferior vocal cords on
its inner side. Many authors limit the term glottis to the lower tri-
angle. This view is supported by the absence of the superior vo-
cal cords in a great number of animals, the ox in particular.
Dimensions of the Glottis. — The glottis is the narrowest part of the larynx, and hence
the danger from the introduction of a foreign body into it, and from the formation of false
membranes in this situation. The only action of the intrinsic muscles of the larynx is
to dilate or contract the opening of the glottis. We have seen that, with the exception
of the crico-thyroidei, they are all, in some measure, collected round the crico-arytenoid
articulation, the movements of which determine the dimensions of the glottis.
The individual differences which constitute the tenour, baritone, or bass voices in sing-
ing, depend upon the size of the glottis ; to which, also, must be attributed the difference
between the male and female voice, and the change produced in its tone at the time of
puberty. A deep voice coincides with a large glottis, and a shrill voice with a small one.
In the adult male the antero-posterior diameter of the glottis is from ten to eleven lines,
in the female it is only eight lines ; in the male, the greatest transverse diameter is from
three to four lines ; in the female, from two to three lines. t
* This error is, perhaps, to be attributed to the use of the word epiglottis, so much do words influence our
ideas. It was committed even in Haller's time, who says, " Etiam hoc (laryngis) ostktm non bene pro glottide
sumilur."
t Tliese measurements are taken at the level of the inferior vocal cords ; the transverse diameter is rather
l(!i:L'er opposite the superior vocal cords
THE LARYNX. 431
From these dimensions, it may be understood how a Louis d'or might pass edgewise
through the glottis, and thus fall into the trachea. In a case of this kind, most of those
■who were called in consultation rejected the idea of the presence of the coin in the wind-
pipe, because, said they, the glottis cannot admit it. The patient died in about a year,
and the Louis d'or was found in the trachea.
Ventricle of the Larynx. — Between the superior and inferior vocal cords of each siile
there is a cavity, called the ventricle or simis of the larynx {v,figs. 176, 178) ; it is oblong
from before backward, and of the same length as the cords ; its depth is determined by
the interval separating the cords from the thjToid cartilage, or, rather, from the thyro-
arytenoid muscle, which forms the bottom of the corresponding ventricle. The opening
of the ventricle is somewhat narrower than the bottom, is elliptical in its longest diame-
ter, and has admitted the introduction of a foreign body. To each ventricle there is a
supplementary cavity, which is accurately described and figured in the works of Mor-
gagni.* This cavity resembles in shape a Phrygian cap ; it has a broad base, opening
into the ventricle, and a narrow apex ; it is found at the anterior part of the ventricle,
and is prolonged on the outer side of the superior vocal cord, between it and the thyroid
cartilage, upon the side of the epiglottis. Its dimensions vary much. In one case its ver-
tical diameter was six lines, and it was divided into two parts by a transverse band.
The Circumferences of the Larynx. — The superior circumference of the larynx {fg. 178)
is much wider than the inferior, and presents the following objects : the superior angu-
lar border of the thyroid cartilage, and the great cornua, in which it terminates ; behind
the thjToid cartilage, the epiglottis (i) ; and between the cartilage and the epiglottis, a
small triangular space, filled by a compact fatty mass, which has been incorrectly descri-
bed as the epiglottid gland. I have already said that this fatty mass is bounded above by a
fibrous membrane, extending from the epiglottis to the posterior surface of the os hyoides.
Behind the epiglottis, we find the upper orifice of the larynx, which must not be con-
founded with the glottis ; it slopes obliquely from before backward and from above down-
ward, having the form of a triangle, with its base directed forward and its apex back-
ward, consequently in the opposite direction to the glottis. This orifice is formed in
front by the free margin of the epiglottis, which is slightly notched ; on each side, by the
upper part of the lateral margin of the epiglottis, and by the free edge of the aryteno-
epiglottid fold (b) ; and behind, by the cornicula laryngis, and by the summits of the ary-
tenoid cartilages (a), and the deep notch between them.
The superior orifice is the widest part of the larynx, and admits foreign bodies which
cannot pass through its lower portion. The epiglottis, when depressed, generally cov-
ers it completely, and may even overlap it at the sides.
The inferior circumference of the larynx is perfectly circular, is formed by the cricoid
cartilage, and is continuous with the trachea.
The Mucous Membrane and Glands of the Larynx. — The mucous membrane of the la-
rynx is a continuation of that of the mouth and pharynx. The larynx presents the only
example in the body of an organ, part of whose external surface, namely, the posterior,
is covered with mucous membrane ; and this depends upon the circiunstance of its form-
ing part of the parietes of the pharynx.
The mucous membrane is disposed in the following manner : From the base of the
tongue it i& reflected upon the anterior surface of the epiglottis, forming the three glos-
so-epiglottid folds already described, one in the middle and one on each side ; it adheres
pretty closely to the epiglottis, is reflected over its free margin, covers its posterior s«r-
face, and penetrates into the larynx : on each side it passes from the epiglottis to the
•arytenoid cartilages, and becomes continuous with the pharyngeal mucous membrane,
which covers the back of the larynx. At the superior orifice of the larynx, it is reflect-
ed upon itself, to form the aryteno-epiglottid folds, which constitute the sides of the su-
pra-glottid region of the larynx ; it then covers the superior vocal cord, and lines the ven-
tricle, sending a prolongation into its supplementary cavity. In the ventricle it is re-
markable for its slight adhesion to the subjacent parts. It is reflected from the ventri-
cle upon the inferior vocal cord ; there, as well as opposite the superior cord, it is so
thin that it does not conceal the pearly appearance of the ligament beneath, to which it
adheres so closely that it is difficult to separate them. Lastly, it covers the internal sur-
face of the cricoid cartilage, and the middle and lateral crico-th)Toid membranes.
The laryngeal mucous membrane is characterized by its tenuity, its adhesion to the
parts heneath it, and by its pale pink colour.! It is perforated by the openings of a num-
ber of mucous glands. Its extreme sensibility, especially at the upper orifice and in the
* I first saw this cavity in a patient affected with laryngeal phthisis, in whom it was very much developed.
I then examined the larynx in other individuals, and found it to be constant. I did not then know that Mor
gagni had pointed it out and figured it (Advers. i., Epist. Anat., viii.).
t [The epithelium of the laryngeal mucous membrane is, in the greater part of its extent, columnar and cil
iated. The cilia urge the secretion upward ; according to Dr. Henle, they extend higher up in front than on
each side and behind ; on the sides, for example, as high as the border of the superior vocal cords, or about
two lines above them, and in front upon the posterior surface of the epiglottis, as high as its base or widest por-
tion. Above these points the epithelium gradually assumes the laminated form, like that in the mouth and
pharynx.]
432 SPLANCHNOLOGY.
supra-glottid portion of the larynx, is well known.* The aryteno-epiglottid folds, which
include the ligaments of the same name, and some muscular fibres in the larger animals,
aie remarkable for the great quantity of very loose cellular tissue which they contain :
this fact explains their liability to a serous infiltration, called oedema of the glottis, which
proves rapidly fatal.
The Glands of the Larynx. — The glands of the larynx are the epiglottid and the aryte-
noid. The thyroid gland, or body, cannot be considered as belonging to the larynx ; if
it belongs to any organ, it must be to the trachea.
The Epiglottid Glands. — The name of epiglottid glands is generally given to the fatty
mass already described as being situated between the thyroid cartilage and the epiglot-
tis ; and it has even been asserted that it opens by special ducts on the posterior surface
of the epiglottis. But there is no other epiglottid gland besides those situated in the sub-
stance of the epiglottis, which is perforated with innumerable holes for their reception :
these small glands are so numerous, that Morgagni (^Advers., i., 2 ; v., 68) regarded them
as forming a single gland ; they all open upon the laryngeal surface of the epiglottis by
very distuict orifices, from which a considerable quantity of mucus can be pressed.
The Arytenoid Glands. — These were well described by Morgagni, who very properly
considered them as forming a single glandular mass, situated in the substance of the ary-
teno-epiglottid fold. They are arranged in two lines, united at an angle, like the letter
L;t the vertical line runs along the anterior surface of the arytenoid cartilage and its
comiculum, and produces a slight prominence, perfectly distinct from that made by the
cartilages ; the liorizontal line is less prominent, and is situated in the superior vocal
cord. The arytenoid glands open separately upon the internal surface of the larynx.
Vessels and Nerves. — The arteries are derived from the superior thyroid, a branch of
the external carotid, and from the inferior thyroid, a branch of the subclavian. The veins
enter the corresponding venous trunks. The lymphatic vessels, which are little known,
terminate principally in the glands of the supra-hyoid region, if we may judge from the
frequency of their inflammation in cases of acute laryngitis, &c.
The nerves are branches of the pneumogastric, viz., the superior and the inferior, or
recurrent laryngeal. The superior laryngeal nerves are not exclusively distributed to the
muscles called constrictors of the glottis (thearytenoideus and the crico-thyroidei) ; nor
do the inferior laryngeals belong exclusively to those called dilators (the crico-arytenoi-
dei postici and laterales, and the thyro-arytenoidei), as a celebrated physiologist has af-
firmed. (See Nkukology. ) The peculiar rotatory movement of the arytenoid cartilages
somewhat interferes with any classification of these muscles into dilators and constrictors.
Development. — The evolution of the larynx is remarkable in this respect, that, after hav-
ing attained a certain size, it undergoes no appreciable change until the time of puberty.
The ventricles are as yet so slightly developed that their existence has been denied. The
prominence of the os hyoides in some measure conceals that of the larynx. M. Rich-
erand {Mem. de la Societe Med. d' Emulation, torn, iii.) has proved that there is no very
remarkable difference between the larynx of a child at three years of age and of one at
twelve. Up to the age of puberty the larynx presents no trace of the sexual differences
which afterward become so evident ; and to these anatomical conditions are owing the
shrillness and uniformity of the voice in the youth of both sexes.
At the period of puberty, at the same time as the genital organs, the larynx increases
so rapidly as to attain its full development in the space of one year ; the voice then loses
ilj uniformity, and acquires its pecidiar timbre and quality, and then also the sexual dif-
ferences in the vocal apparatus become manifest.
Is it from an unequal development of the different parts of the larynx, or from want
of a certain degree of education, that the voice at this period is so discordant, especial-
ly in singing, or breaks, as it is said 1
The simultaneous development of the genital organs and the larynx has led to the opin-
ion that they stand to each other in the relation of cause and effect ; and observation
has established that the vocal apparatus is in some measure under the influence of the
generative organs ; for in eunuchs the larynx remains as small as it is in the female.
(M. Dupuytren, Mem de la Soc. Phil., tom. ii.),
At the age of puberty the size of the glottis is increased by one third in the female,
and is nearly doubled in the male. After puberty, any changes which the larynx may
undergo are the result of exercise, not of development, properly so called.
Ossification of the cartilages of the larynx is not always the effect of age. I have seen
it at the thirtieth year quite independently of disease. Chronic inflammation of the la-
rynx induces a premature ossification of the cartilages. The th)Toid has the greatest
tendency to this change, then the cricoid, and, lastly, the arytenoid cartilages : I have
never observed it in the epiglottis.
Functions. — The larynx is the organ of voice. Numerous experiments upon living
animals, and many surgical facts, show that the vocal sound is produced exclusively in
* It has been observed, in experiments upon animals, and in introducing the canula after the operation of
laryngotomy, that the sensibility of the mucous membrane beyond the glottis is much less acute,
t " Gnomonis, sed obtusanguli figuram utervis acervns habet." — (Haller.)
THE THYROID GLAND. 433
the larynx. The lungs, the bronchi, and the trachea perform, with regard to the voice,
the office of an elastic conductor of air capable of contraction and dilatation, of shorten-
ing and elongation. The thorax acts like a pair of bellows, by which the air is driven
into the larynx with any wished-for degree of force ; and hence the quantity of air pass-
ing through the larynx, and the rapidity with which it moves, may vary to a very great
extent.
What, then, is the mechanism of the voice 1 Is it the same as that of a horn {Dodart),
of a stringed instrument {Fcrrein), of a flute ( Cuvier), of a reed instrument {Biot and Mw-
gendic), or of a bird-call* (Savart) 1 Is it produced by the vibration of the tense vocal
cords, or merely by the vibration of the air while passing through a narrow opening,
which is itself incapable of vibrating 1 We shall leave these questions to the decision
of physiologists. It is sufficient for our purpose to know that the action of the muscles
of the larynx and the arrangement of the vocal apparatus are perfectly fitted to produce
either dilatation or contraction of the glottis ; and such is the mechanism of this part,
that, from the rotatory movement of the arytenoid cartilages, the vocal cords are always
rendered tense, whatever may be the other actions of the muscles.
The voice as it issues from the larynx is simple, for the larynx is, with regard to the
voice, what the mouth-piece is in the flute, or the reed in the bassoon ; but during its pas-
sage througli the vocal tube, composed of the epiglottis, the pharynx, the isthmus of the
fauces, the mouth, and the nasal fossae, the voice becomes modified.
According to a very ingenious theory of M. Magendie, the epiglottis resembles those
soft; and movable valves which M. Grenie places in the pipes of an organ to enable the
sound to be increased without modifying the tone.
The isthmus of the fauces resembles the superior larynx of birds, which consists of a
contractile orifice that can be diminished, and even closed at pleasure ; and it is princi-
pally owing to this mechanism that the small glottis of birds can execute such an exten-
sive range of notes. We know, in fact, that the tone of a wind instrument is reduced
an octave lower by completely closing the lower orifice of the tube, and that, when it is
only partially closed, the tone is depressed in proportion. Now the isthmus of the fau-
ces acts exactly like the superior larynx of birds. On watching a person who wishes
to utter a very low note, we see that he depresses and flexes the head slightly upon the
neck, so as to approximate the chin to the thorax : by this means the vertical diameter
of the isthmus of the fauces is diminished, the larynx being carried upward, while the
velum palati is depressed ; and from this we may judge of the important part performed
by the velum in producing modulations of the voice.
If to this we add the changes which may be effected in the length and diameter of the
pharynx (see Pharynx), and if we remember that, by diminishing by one half the length
or diameter of the tube or body of a wind instrument, its tone is raised one octave, we
shall be able to understand how the human voice can execute so extensive a scale of
notes, although the glottis is so small. The voice is also modified while traversing the
buccal and nasal cavities.
Do the nasal fosscr. favour the resonance of the voice 1 or does the air, when passing
through them, merely give rise to certain sounds denominated nasal 1 The latter opin-
ion, which is supported by Mr. Gerdy, appears to me the most consistent with facts.
MM. Biot and Magendie had already correctly observed that the voice becomes nasal
only when it traverses these passages.
The voice becomes articulate in passing through the mouth, i. e., the vocal sound is
interrupted, and modified by the more or less rapid percussion of the lips and tongue
against the teeth and the palate.
Articulate voice is very distinct from speech. Animals which differ much from man
in the conformation of their vocal organs, the parrot, for example, may be made to artic-
ulate ; but speech is the peculiar attribute of man, because he alone is possessed of in-
telligence.
The Thyroid Gland.
The thyroid gland, or thyroid body, is a glanduliform organ, the uses of wnich are un-
known : it is situated like a crescent with its concavity directed upward, in front of the
first rings of the trachea, and upon the sides of the larynx.
In describing this organ in connexion with the larynx, I follow the usual custom,
which has arisen not from any direct relation between their functions, but from their
contiguity to each other.
The thyroid body varies much in size in different individuals ; there are few organs
which present greater varieties in this respect.
^ The sexual differences in the size of this organ, like all those relating to the vocal ap-
paratus, are very well marked, but in an inverse manner, that is to say, the thyroid body
is larger in the female, in whom it forms a rounded projection, which assists in making
the thyroid cartilage in that sex apj)ear still less prominent.
* A bird-call is a cavity with elastic walls, perforated upon the two opposite sides. Tlie cavity is repre-
■ented by the ventricles, and the openings by the intervals between the vocal cords. If a tube capable of
contracting and dilating be fitted to such an instrument, an infinite variety of sounds may be produced.
I I I
484 SPLANCHNOLOGY.
Climate, and more especially certain qualities in the water used as drink, have a re-
markable influence upon its size, which, in many cases of goitre, is enormous.
These differences in size affect either the whole of the gland equally, or only one lobe,
or occasionally the middle portion alone.
The iveight of the thyroid body, which is about an ounce, may be increased to a pound
and a half, or even more.
Form. — The thyroid body is generally composed of two lateral lobes or cornua, united
by a contracted portion, flattened from before backward, and called the isthmus. Tlie
varieties in shape principally affect the isthmus, which may be very narrow, long or
short, regular or irregular, or entirely absent, or it may be as thick and as long from
above downward as the lobes themselves. I have seen one case in which the thickest
part of the thyroid gland was in the middle, and the lobes terminated above in a very
narrow point.
The opinion of the ancients, and which is also met with in Vesalius, that the human
subject has two thyroid glands, no doubt arose from the narrowness or absence of the
isthmus, or, rather, from the separation and complete independence of the two lobes in
a great number of animals. The surface of the thyroid body is smooth and well defined,
and sometimes divided into lobules by superficial furrows.
We shall examine in succession the relations of the middle and lateral portions :
The middle portion or isthmus is convex in froTit, and is separated from the skin by all
the muscles of the sub-hyoid region. Behind, where it is concave, it is in contact with
the first rings of the trachea. Moreover, this middle portion descends to a greater or
less distance in different subjects, and sometimes so low, that there is not room to per-
form tracheotomy between it and the sternum.
Each lateral lobe is convex in front, and corresponds with the muscles of the sub-hyoid
region : in particular, I ought to mention the sterno-thyroid, by which it is directly cov-
ered, and the breadth of which seems to be proportioned to the size of the lobe ; in many
cases of goitre I have seen this muscle twice or three times as broad as in the natural
state. 0)1 the inside, each lateral lobe is concave, so as to be applied to the side of the
trachea and cricoid cartilage, to the lower and latter part of the thyroid cartilage, to the
lower part of the pharynx, and to the upper part of the CESophagus. The two lobes, to-
gether with the middle portion or isthmus, form a half or sometimes three fourths of a
canal, which embraces all those parts ; an extremely important relation, which explains
how, in certain goitres, the trachea is flattened on the sides, deglutition is impeded, and
true asphyxia by strangulation is the final result. Behind, each lateral lobe corresponds
with the vertebral column, from which it is separated, on the outside, by the common
carotid artery, the internal jugular vein, and the pneumogastric and great sympathetic
nerves, which, according to the size of the gland, are either covered by it, or are merely
in relation with its outer surface.
The upper extremity of each lateral lobe terminates in a point, and hence the two-
homed figure assigned to the thyroid body. It is situated on the inside of the carotid
artery, in contact with the lateral and back part of the thyroid cartilage, and sometimes
extends nearly to its upper border. Its lower extremity is thick and rounded, descends
to a greater or less distance in different individuals, and corresponds to the fifth, sixth,
or seventh rings of the trachea : it is situated between the trachea and the common ca-
rotid. The inferior thyroid artery enters the gland at its lower extremity.
Its upper border is concave and notched in the middle ; the superior thyroid arteries
run along it. A prolongation extends from this border, which has been correctly repre-
sented by Bidloo, and named the pyramid by Lalouette. It almost always exists ; it
passes perpendicularly upward, either on the right or left side of the median line, and
presents numerous varieties in several respects. Thus it varies in its origin, sometimes
arising from the isthmus, and sometimes from one of the lobes at one side of the isth-
mus ; also in its termination, sometimes ending opposite the notch in the upper border
of the thyroid cartilage, sometimes opposite the thyro-hyoid membrane, and at other
times even on a level with the body of the os hyoides ; but always firmly adherent eithei
to the membrane or the bone. It also varies in its structure : sometimes it is a fibrous
cord, and sometimes a reddish linear band, which has all the appearances of a muscular
fasciculus, and has even been described as a muscle ; it often consists of a series of
gremules arranged in a line ; sometimes, again, we find, in the middle, or at one end of
the cord, a glanduliform enlargement, exactly resembling the tissue of the thjroid gland ;
lastly, it may be double, or bifurcated, or even completely wanting ; in which case, how-
ever, there exists a glanduliform mass of a certain height. This prolongation, in which
I and many others have in vain attempted to find an excretory duct, is evidently of a
compact nature. Is it the remains of a fcetal structure, or the trace of a normal dispo-
sition in some animals 1
The lower border of the thyroid body is convex, more or less deeply notched in the cen-
tre, and is in contact with the inferior thyroid arteries.
Structure. — The proper tissue of the thyroid gland is of a variable colour, sometimes
resembling the lees of Port wine, and sometimes of a yellowish hue. It is of tolerably
THE UEINARY ORGANS. 435
nrm consistence, and feels granular. This organ presents all the anatomical characters of
glands, and, like them, may be separated by dissection into glandular grains ; but with
this difference, that these grains communicate with each other, while, in ordinary glands,
they are independent. The communication of the glandular grains may be shown in the
following manner : if the tube of a mercurial injecting apparatus be inserted into the
thyroid gland, the mercury will enter into and distend the cells, and after a certain time
all the grains will be injected ; it is easy to satisfy the mind that the mercury is not in-
filtrated into the cellular tissue, but is contained in the tissue of the gland itself, in the
centre of the granulations. The right and left lobes do not conununicate, but all the
granulations of each lobe communicate with each other.
The thyroid gland has, therefore, a vesicular structure ; and we have seen that the
glandular grains of all glands are spongy and porous, and that the products of their secre-
tion may be accumulated in these pores.
The glandular nature of the thyroid body is also shown by the viscid, Umpid, yellowish
fluid which pervades it in certain subjects, and which may be collected in sufficient
quantity for chemical analysis ; and also by the retention of this matter within a greater
or less number of the vesicles when their orifices of communication with the neighbour-
ing vesicles become obliterated.
But, in connexion with this view regarding its glandular nature, we seek in vain for an
excretory duct. If we examine the trachea and the larynx, or lay open the oesophagus,
and then press the thyroid gland, we shall see that no fluid escapes into those canals.
It has been asserted, indeed, that the excretory duct of the thyroid gland terminated in
the foramen ccecum of the tongue, in the ventricles of the larynx, or in the trachea opposite
its first ring ; but, after the example of Santorini, we are compelled to reject these fancied
and too hastily announced discoveries.
I may here notice the intimate adhesion of the side of the thyroid gland to the first ring
of the trachea. This can be very well shown by detaching the gland from behind for-
ward ; it is of a fibrous nature, and I have sometimes thought that I saw a duct in the
centre of it, passing through the membrane which connects the trachea with the cricoid
cartilage, though I have never been able satisfactorily to demonstrate it.
Still, I do not think that the absence of an excretory duct should remove the thyroid
from among the glandular organs ; for I believe that there exist in the body glands with-
out excretory ducts, as the thymus, the supra-renal capsules, and the thyroid body. The
secretion of the gland is entirely absorbed, and fulfils certain unknown uses.
Arteries. — The size and the number of the arteries distributed to the thyroid gland in-
dicate that something more than a mere nutritive process must be carried on in it. The
arteries are sometimes four, sometimes five in number ; two superior arise from the ex-
ternal carotid ; two inferior from the subclavian, and the fifth, or the thyroid artery of
Neubauer, where it exists, arises from the arch of the aorta.
The veiTis are proportionally as large as the arteries, and form so considerable a plexus
in front of the trachea, as, in certain cases, to have prevented the completion of the
operation of tracheotomy.
The lymphatic vessels terminate in the cervical lymphatic glands.
The nerves are derived from the pneumogastrics, and the cervical ganglia of the sym-
pathetic.
A thin cellular membrane envelops the gland, and sends very delicate prolongations
into its substance, where we find a very firm cellular tissue, always destitute of fat.
Development. — The thyroid gland is developed in two lateral halves, which are after-
ward united by a median portion. It is not uninteresting to remark, that this dispo-
sition, which is transitory in the foetus, represents the permanent condition of the gland
in a great number of animals. During intra-uterine life and infancy it is relatively larger
than at subsequent periods. Nevertheless, the changes which it afterward undergoes
are not to be compared with those that occur in the thymus ; and we cannot say, as of
the latter structure, that the existence of the thyroid body has any peculiar relations
with foetal life.
Functions. — It is a secreting organ, but the uses of its fluid are not known.
THE GENITO-URINARY ORGANS.
I HAVE thought it proper to describe the genital and the urinary organs together, because,
although their functions are very distinct, yet they have the most intimate anatomical,
physiological, and pathological connexions.
THE URINARY ORGANS.
Division. — The Kidneys and Ureters. — The Bladder. — The Supra-renal Capsules
The urinary organs form a very complex secretory apparatus, consisting of two secre-
ting organs, the kidneys ; of two provisional reservoirs, the calyces and the pelvis of each
kidney ; of two excretory ducts, the ureters ; of a second and final reservoir, the bladder ;
436 SPLANCHNOLOGY.
and, lastly, of a second and final excretory canal, which, in the male, is common to both
the genital and the urinary organs, viz., the canal of the urethra.
The Kidneys.
The kidneys {ve^pol) are glandular organs, intended to secrete the urine.
They are deeply situated {k k,fig. 199) in the lumbar region, hence called the region of
the kidneys, on each side of the vertebral column, externally to the peritoneum, which
merely passes in front of them ; they are surrounded by a great quantity of fat, and, as
it were, suspended by the vessels which pass into and emerge from them.
Fixed firmly in this situation, they are but little liable to displacement. Most of the
changes in their position are congenital. The right kidney generally descends a little
lower than the left, doubtless on account of the presence of the liver. One of the kid-
neys may not uncommonly be found in front of the vertebral column, or even in the.
cavity of the pelvis ; and this unusual arrangement may, in certain cases, render diag-
nosis very obscure.* I have frequently found the right kidney in the corresponding iliac
fossa in females who had been in the habit of wearing very tight stays. This displace-
ment happens when the pressure of the stays upon the liver forces the kidney out of the
depression in which it is lodged in the lower surface of that organ.
Number. — The kidneys are two in number. It is not very uncommon to find only one,
which, is almost always formed by the union of the two, by means of a transverse portion
crossing in front of the vertebral column, and having its concave border directed upward.
Sometimes the two united kidneys are situated in the right or left lumbar region, or
ija the cavity of the true pelvis. Cases of union of the two kidneys should be distinguish-
ed from those in which one of them is atrophied.
Again, Blasius, Fallopius, Gavard, &c., relate examples of individuals having three
kidneys ; in some of these cases, two were situated upon the same side, in others the
supernumary kidney was placed in front of the vertebral column.
Size. — The kidney is not subject to such great variations in size as most other organs.
Its ordinary dimensions are from three and a half to four inches in length, two inches in
breadth, and one inch in thickness. Its weight is from two to four ounces, t I have
found them more than three times their ordinary size in a diabetic patient. When one
kidney is atrophied, the other becomes proportionally enlarged, sometimes even to twice
the usual dimensions. Atrophy of the kidney may be so extreme as to reduce it to a
drachm and a half or two drachms in weight, and make it appear to be lost among the
surrounding fat ; but the presence of this fat distinguishes such a case from one of con-
genital absence of the kidney.t
Density and Colour. — The tissue of the kidney is harder than that of other glands.
Its fragility accounts for its laceration by direct violence, or by a concussion produced
by a fall from a great height.
Its colour is that of the lees of red wine, somewhat analogous to that of the muscular
tissue, but offers several different shades.
Figure. — The shape of the kidney may be well compared to a bean, with the hilua
turned inward. This form enables us to consider its two surfaces and its circumference.
Relations. — The anterior surface of the kidney is directed slightly outward ; it is con-
vex,^ and is covered by the lumbar colon, but sometimes only by the peritoneum, the gut
lying to its inner side ; on the left side it is also in relation with the spleen and the great
tuberosity of the stomach, and on the right side with the liver and the second portion of
the duodenum.
The relations of the right kidney with the liver are more or less extensive ; sometimes
it is entirely covered by the liver ; in other instances it is inclined downward, and has
no relation with that organ. The gall-bladder sometimes lies upon the anterior surface
of the right kidney through the whole of its extent. Lastly, I have seen the kidney in
immediate relation with the parietes of the abdomen, through which it could be easily felt.
As practical inferences from these relations, we would notice the difficulty of explo-
ring the kidneys from the anterior surface of the abdomen, on account of their deep sit-
uation ; also, the possibility of an abscess of the kidney opening into the colon.
The posterior surface is less convex than the anterior, and is turned inward ; it corre-
sponds with the quadratus lumborum, from which it is separated by the anterior layer of
the fascia of the transversalis muscle ; with the diaphragm, which separates it from the
* 1 latplyhad in my warJs a female labouring under hectic fever, of which I could detect no cause, either in
the thorax or the abdomen. Upon opening the body after death, I found the two kidneys united, situated in
the true pelvis, behind the rectum, and projecting a little above the brim. They contained a large quantity of
pus, which escaped by the rectum.
+ [According to M. Raver, the average weight of the kidney in the male is 4i ounces, in the female 3^
ounces ; he also states that the left kidney is almost always larger and heavier than the right.]
t 1 do not speak here of enlargement of the kidneys from disease. Many examples of extreme enlargement
wall be found in my work on Pathological Anatomy, liv. i., xviii.
() Not unfrequently the fissure of the kidney is found on the anterior surface of this organ. In one case of
this kind, the right kidney occupied the right iliac fossa; it had two arteries, a superior, which proceeded di-
rectly to the fissure, and an inferior, arising from the angle of the bifurcation of the aorta, in front of the mid'
1 He sacral artery, and terminating at the lower extremity of the kidney.
THE KIDNEYS.
437
(w6 or three lower ribs ; and with the psoas, which intervenes between it and the ver-
tebral column. These relations explain the possibility of exploring the kidney in the
lumbar region through the quadratus lumborum, account for abscesses of the kidney
opening in the lumbar region, and for the escape of renal calculi in the same direction,
and form the grounds on which the operation of nephrotomy has been proposed. It is
of importance to remark, that the relations of the kidneys with the ribs are variable in
extent, and that sometimes they do not pass beyond the last rib.
The circumference of the kidney presents an external border, convex, semi-elliptical,
and directed backward ; an internal border, directed forward, and deeply notched in the
middle, to form ih.e fissure of the kidney (hilus renalis, k,fig. 179). This notch is more
marked behind, where it corresponds with the pelvis of the kidney, than in front, where
it corresponds with the renal vein ; it is from fifteen to eighteen lines in depth.
If we separate the edges of this fissure, we expose a deep cavity containing fat, and
called the sinus ; in which are seen the pelvis of the kidney (p), the calices (c c c'), and
the divisions of the renal artery and vein.
The upper end of the kidney is directed inward, and is more or less completely em-
braced by the supra-renal capsule ; it is generally larger than the lower end, which is di-
rected slightly outward, and projects beyond the last rib.
Structure. — Make a vertical section of the kidney from its convex to its concave bor-
der. Detach the proper capsule in the same direction. Inject the arteries, veins, and
ureter, in different kidneys, and also in the same kidney. Inject also the uriniferous ducts.
The Proper Coat. — The kidney has no peritoneal covering. The remarkable fatty mass
in which it is imbedded is called the fatty capsule of the kidney. Besides this, it is pro-
vided with a proper fibrous coat, the external surface of which adheres to the fatty tis-
sue, by means of fibrous lamellae passing through it ; its internal surface is adherent to
the tissue of the kidney, through the medium of a number of small prolongations, which
are very easily lacerated.
The Tissue of the Kidney. — The kidney differs from other glands, all of which present
a homogeneous and granular texture, in being Fig. 179.
composed of two substances : one of these is ex-
ternal, cortical, or glandular {a a) ; the other inter-
nal, medullary, or tubular {b b b). Some anato-
mists have described a third substance, the mam-
millated ; but the papillas {d d) of which it is com-
posed belong to the tubular substance.
The following is the respective arrangement
of these two substances :
The cortical sabstance forms a soft, reddish,
sometimes yellow layer, of a granular appear-
ance, and about two lines in thickness, which
occupies the surface of the kidney, and sends
prolongations, in the form of pillars or septa,
from one to three lines thick, between the cones
of the tubular substance.
The tubular or medullary substance is redder,
and presents the appearance of striated cones or
pyramids (the pyramids of Malpighi), the bases
of which adhere to the cortical substance, while
their free apices are turned towards the sinus,
where they appear like papillae. Bellini, and,
before him, Berenger di Carpi, considered the
fibres or striae of the medullary substance as so many uriniferous tubes (the tubes of Bel-
lini), and hence the term tubular substance.
It follows, then, that the kidney is divided into a number of compartments, correspond-
ing to the number of cones of tubular substance ; there are from ten to twenty of these
compartments, which represent the temporary lobules of the human foetal kidney, and
the permanent lobules in the kidneys of the greater number of animals, t
The kidney, therefore, is formed by the union of a greater or less number of small kid-
neys, applied together, and connected within a common investment. We shall see, pres-
ently, that, in reference to the circulation, these small kidneys are entirely independent
of each other. Although the distinction between the two substances is well marked, it
is easy to see that some of the fibres or striae of the tubular structure penetrate the cor-
tical substance in a flexuous course, and reach the surface of the organ. This fact was
clearly shown by Ferrein, who considered the stri^ to be the excretory ducts of the gran-
ules. These cortical and flexuous portions of the tubes, which become straight as soon
as they reach the medullary substance, are termed the cortical ducts, or the convoluted
tubes of Ferrein.
* This figure is a plan, not an actual representation of the structure of the kidney.
+ In some animals the kidney resembles a bunch of grapes.
SectioDafkidoey.*
438
SPLANCHNOLOGY.
Ferrein having examined the tubes of Bellini under the microscope, believed that each
of them formed a pyramid analogous to those of the tubular substance, and that each of
these secondary pyramids consisted of about a hundred ducts ; hence the tubes of the
tubular substance have been named the pyramids of Ferrein,* in contradisl inction to the
pyramids of Malpighi.
We shall now examine the structure of the tubular and the cortical substance.
Structure of the Tubular Substance. — The tubular substance, which, at first sight, looKs
like muscular tissue, from its red colour and arrangement in lines, evidently consists of
tubes or ducts.
In fact, an examination under the simple microscope of a section made perpendicu-
Fig. 180. larly to the axis of the tubes, demonstrates the existence
6 \ of a number of small openings, each corresponding to a
tube ; and if, while the eye is fixed upon the section, the
kidney be compressed, urine will be seen to exude from all
points of the cut surface. Direct injection of the ducts, by
means of a tube containing mercury, introduced at hazard
into the tubular substance, will fill all the tubes, in whatever
direction the instrument may be directed. The ingenious
experiment performed by Galvani, who tied the ureters of
birds, and by this means obtained an injection of the tubes
with the white matter of their urine, leaves no doubt of the
existence of these tubes. Lastly, the tubes themselves are
collected together in the papillae, and open either over their
entire surface, or in a small depression which sometimes
exists at their summits.
Structure of the Cortical Substance. — The cortical sub-
stance is tubular and granular. The granules are regularly
disposed around the convoluted tubes of Ferrein. t
On examining a thin slice of uninjected kidney by the
simple microscope, we perceive a great number of oval and
spheroidal granules {c",fig. 180), the acini of Malpighi, which
may be separated from each other by maceration ; and
those granules which have been cut through present that
spongy appearance, resembling the pith of the rush, which
seems to belong to all glands. When the section is verti-
cal, these corpuscles are seen appended to the tubes of
Ferrein, like grapes upon their stalk. <J
Vessels and Nerves. — The renal artery is remarkable for
its enormous size, in proportion to that of the kidney, for its origin from the aorta being
at a right angle, and for its shortness. There are sometimes two or three renal arteries,
and two are not unfrequently found twisted spirally around each other.
When the kidney is situated in the iliac fossa or in the pelvis, the renal artery or ar-
teries generally arise from the common iliac.
The re7ial vein is as large in proportion as the artery, and passes in front of it into the
vena cava.
The lymphatic vessels are but little known.
The nerves are very numerous, and are derived from the solar plexus ; besides which,
the lesser splanchnic nerve is distributed directly to the kidney.
The spermatic nervous plexus is formed by branches from the renal plexus, and this
may explain the close sympathy between the testicle and the kidney. The great num-
ber of ganglionic nerves distributed to the kidney may account for the peculiar charac-
ter of the pain experienced in this organ.
Injection of the Renal Vessels. — A very coarse injection thrown into the artery will re-
turn by the veins. One thrown into the vein will return by the ureter, and not by the
* See note, infra.
t According to Ferrein, these convoluted tubes form, by their numerous anastomoses, a network, in the
meshes of which the granules arc contained.
t This is a plan, rather than an actual representation.
t> [The urinifcrous tubes, commencing at their orifices upon the surface of the papillae, pass up into the tu-
bular portion of the kidney, dividing and subdividing dichotomously several times {a, fig. 180), so as to consti-
tute fasciculi of straight and radiating tubes : these are the pyramids of Ferrein, a considerable number of
which are united to form one of the pyramids of Malpighi (b,fig. 179). At the base of the latter the fasciculi
spread out, and the straight tubes become the convoluted tubes of the cortical substance (fig. 180).
In the human kidney, the tubuli uriniferi are said by Weber to be of a nearly uniform diameter throughout
their entire course (averaging ^^ th of an inch) ; and all appeared to him to end in loops (b b), none in free
and closed extremities (as at b') : according to Krause, they terminate in both ways. In either case, however,
they form a closed system of tubes, independent of the bloodvessels, which merely ramify on their parietes.
They are lined with a mucous membrane, continuous with that on the papillae, and having a columnar epi-
thelium.
The acini of Malpighi, or granules of M. Cruveilhier (c"), are not of a glandular nature ; they consist en-
tirely of minute convoluted arteries, which terminate in the veins, but have no direct communication, as wai
formerly supposed, with the uriniferous tubes ; they are called the glomeruli.']
Ma^ified sixty timu.t
THE KIDNEYS. .^^
artery.* Having filled the artery with red injection, the vein with blue, and the ureter
with yellow, I observed the following facts :
The renal artery divides into several branches within the sinus, where it is surround-
ed with fat ; these branches pass between the calyces, and then between the cones of
the tubular substance, proceeding as far as the conunencement of the cortical substance
without giving off any smaller branches : at that point, however, they divide and subdi-
vide, so as to form a vascular network, the meshes of which are quadrilateral and of
different sizes, inscribed within each other. The largest of these meshes embrace the
entire base of each pyramid ; the smaller pass in different directions through the sub-
stance of the bases.
In order to obtain a good view of this arrangement, it is necessary to divide an inject-
ed kidney along its convex border, and scrape away the tubular substance, which is so
soft as to be easily removed. We shall then perceive that the arterial and venous net-
work, corresponding to the base of each cone, is surrounded by a very thick fibrous sheath,
apparently prolonged from the fibrous coat, which passes into the hilus. All the tubular
substance being thus removed, the remaining cortical portion of the kidney presents the
appearance of a series of perfectly distinct alveoli, each of which corresponds to a cone
of the tubular substance. A very beautiful preparation may thus be made.
It remains for us to inquire how the arteries terminate. A number of vessels pro-
ceed from the convexity of the vascular network above described, traverse the cortical
substance, become twisted like tendrils of the vine, and appear to terminate in small red
masses, regularly arranged along the convoluted tubes of Ferrein. These small red
masses are formed by the penetration of the injection into the cavity of each granule, as
may be seen by examining a section of the kidney with a lens.f If both the artery and
the vein be injected in the same kidney (and it is of importance that the vein should be
injected before the artery, in order to prevent a mixture of the two injections), we shall
see that the matter injected by the vein circumscribes that injected by the artery.
Almost all the vessels are destined for the cortical substance, the tubular substance
scarcely receiving any branches :$ the vessels of any one lobule do not communicate
with those of the adjacent lobules.
Injection thrown into the ureter does not enter the uriniferous ducts, or, at leeist, very
incompletely.
Development. — The surface of the kidney in the foetus, as in the lower animals, is fur-
rowed and lobulated. Each lobule is fonned by the medullary substance, covered by a
layer of the cortical substance. After birth the furrows are effaced, and the surface of
the kidney becomes plane and smooth.
This change takes place during the first three years after birth ; nevertheless, the lo-
bular arrangement not unfrequently continues for nine or ten years, and even during the
whole periwi of life. When the kidney is the seat of disease, and more particularly
when it is distended from an accumulation of urine within the calyces and pelvis, the lob-
ular arrangement reappears. Each lobule is then converted into a pouch, which is
perfectly distinct from those in contact with it. The kidney is proportionally larger in the
foetus than in the adult.
Functicms. — The kidneys are the secreting organs of the urine. The urine is secreted
by the cortical substance, and, as it were, filtered by the tubular substance ; for perfect-
ly-formed urine is found in the former situation. The mechanism of this is not better
known than that of other secretions ; its rapidity is explained by the great quantity of
blood received by the kidneys.
The Calyces, Pelvis, and Ureter.
Dissection. — Remove the fat from the sinus, and study the arrangement of the pelvis
and calyces externally. Divide the kidney from the convex border towards the hilus.
The calyces (c c c', fig. 179) are funnels (infundibula), or, rather, small membranous
cylinders, embracing the bases of the papillae by one of their extremities, almost in the
same manner as the corolla of a flower embraces the stamina and pistil, and uniting at
their other extremity with the adjacent calyces, to form the pelvis of the kidney. They
vary in number like the papillae, or even more so, for two or three papillae frequently
open into the same calyx. Whatever their number may be, they generally unite into
three trunks, a superior, a middle, and an inferior, which correspond to the three groups
of lobules, into which the kidney may be divided. These three trunks unite to form the
pelvis. The external surface of the calyces is in relation with a great quantity of fat,
and with the divisions of the renal artery and vein.
The pelvis (p) is a small membranous pouch, situated behind the renal artery and vein,
opposite the deep notch in the posterior border of the hilus, so that, when seen from be-
hind, it projects completely beyond that fissure. It is elongated from above downward,
* [This is the result of rupture.] t See note, suprd.
t [The vessels (c,fig. 180) of the tubular portion nm parallel with the tubuli from the cortical substance
to the papillae ; they were mistaken by Ruysch fur the tubub themselves, which were, therefore, supposed by
him to communicate with the arteries in the glomeruli.]
440 SPLANCHNOLOGY.
and flattened from before backward, and may become greatly dilated from retention of
the urine, or from renal calculi : almost immediately after its commencement it becomes
smaller, and takes the name of the ureter. In certain cases it would appear that there is
no pelvis, and that the ureter succeeds immediately to the two or three trunks formed
by the union of the calyces. The pelvis is, therefore, nothing more than the expanded
or infundibuliform commencement of the ureter.
The ureter {ovpov, urine, u, Jigs. 179, 181, 199) is the excretory duct of the kidney,
and ex ends obliquely from the pelvis of that organ to the inferior fundus {bos fond) of
the bladder. It is generally single on each side, but sometimes double, and that under
two very different circumstances : for example, where the two kidneys are united into
one, a double ureter is almost invariably found ; and, secondly, when, there being two
kidneys, one of them is divided into two very distinct portions. In the latter case the
two ureters are often united into one, after a course of a few inches. There is, then, no
pelvis properly so called, and the two ureters may be regarded as the prolongation of the
two trunks of the calyces, which remain separate longer than usual.
The ureter is a cylindrical tube, having whitish, thin, and extensible parietes, and va-
rying in size from that of a crow's to that of a goose's quill. The most contracted por-
tion of the canal is that situated in the substance of the parietes of the bladder. Occa-
sionally it presents, at various parts of its extent, some circumscribed dilatations, which
seem to indicate that the course of the urine had been for a time arrested. Tiiis canal
is liable to extreme dilatation, when any obstacle occurs to the passage of the urine : I
have seen it as large as the small intestine.
Each ureter is directed obliquely downward and inward, as far as the side of the base
of the sacrum : from this point {fig. 181) it passes downward, forward, and then inward
(Uffig. 186), to the lateral part of the inferior fundus (a) of the bladder, where it enters
between the muscular and mucous coats, and passes obliquely for about ten lines within
the substance of that organ, to one of the posterior angles of the trigone, at which point
it opens by an orifice narrower than the canal itself, and having the form of a parabolic
curve, with its concavity directed inward.
Relations. — In proceeding from the pelvis of the kidney to the base of the sacrum, the
ureter passes edong the anterior margin of the psoas, and is covered by the peritoneum
and by the spermatic vessels, which cross it very obliquely. The right ureter is in rela-
tion with the vena cava inferior, being situated on its outer side. Opposite the base of
the sacrum, each ureter crosses the common iliac, and then the external iliac artery and
vein of its own side. In the pelvis, the ureter is applied to the parietes of that cavity,
is covered by the peritoneum, and crosses in succession the umbilical artery, or the cord
by which it is replaced, the obturator vessels, the vas deferens (,t,fig. 181) in the male,*
and the upper and lateral part of the vagina in the female. That portion of it which is
contained within the substance of the walls of the bladder corresponds indirectly with
the neck of the uterus ; and this important relation explains why carcinoma of the neck
of the womb is so frequently accompanied with retention of urine. I have also observ-
ed that the ureters of all females who have died after delivery, or during the last months
of pregnancy, are remarkably dilated.
Internal Surface. — The internal surface of the calyces, pelvis, and ureters is white,
smooth, and has longitudinal folds, which are effaced by distension. There are no
valves, either at the opening of the calyces into the pelvis, or of the pelvis into the ure-
ter, or in any part of that canal.
Structure. — ^The calyces, the pelvis, and the ureter have all the same structure : they
are formed by two membranes ; an internal membrane, continuous with the vesical mu-
cous membrane, very thin, and even having the appearance of a serous membrane ; it is
reflected from the calyces upon the papillas, and is prolonged into the uriniferous tubes :
an external membrane, which is very thick, and supposed to be a continuation of the ex-
ternal coat of the kidney, and therefore to be fibrous. Others regard it as muscular ;t I
believe that it is formed of a tissue analogous to the dartos. Some arteries and veins,
probably, also, some lymphatics and nerves, are distributed upon the calyces, the pelvis,
and the ureters, but do not require any special description.
The Bladder.
The Madder {h,Jig. 181) is a musculo-membranous sack, which serves as a reservoir
for the urine.
It is situated in the cavity of the pelvis, upon the median line, behind the pubes (6),
and is retained in that position by the peritoneum (m), which only partially covers it,
and by the urachus, a sort of ligament connecting it with the umbilicus. These means
of attachment are in accordance with the great enlargement of which the organ is ca-
pable ; but they cannot prevent certain partial displacements, known as hcrnice of the
llcdde'' When collapsed, it is completely protected from external injury ; but when
* Passing to its outer side.
^ [lu some quadrupeds the ureter distinctly contracts on applying a stimulus.!
THE BLADDER.
441
filled, it passes above the osseous girdle in which it is contained, and enters the dilatable
cavity of the abdomen, where it can be distended to the utmost without inconvenience.
Number. — The bladder Fig. 181.
is always single ; the ex-
amples of double bladder
which have been recorded
are cases of protrusion of
the mucous membrane
through the separated
muscular fibres. But,
whatever may be the size
of these accidental blad-
ders (and I have seen
them twdce as large as the
true bladder to which they
were attached), they may
always be distinguished
by their having no muscu-
lar coat. The cases of de-
ficiency of the bladder are
generally examples of that
species of malformation,
in which the viscus is open
anteriorly, and is everted,
80 as to resemble a fungous mass.
Dimensions. — The bladder is the largest of all the reservoirs of secretion ; but its ca-
pacity varies, from a number of circumstances : from hahit — in persons who are accus-
tomed to retain their urine for a considerable period, the bladder is more capacious than
in those who immediately attend to the desire to pass urine ; from sex — thus, in the fe-
male the bladder is generally larger than in the male, because she is more influenced by
the customs of society ; from age — ^the bladder appears to be relatively larger before
than after birth ; from disease — in consequence of which it presents every variety be
tween a morbid state of contraction, in which, from the contact of its parietes, it scarce
ly permits the accumulation of a spoonful of urine, and an extreme state of dilatation, in
which it can hold several pints of that fluid.
Direction. — The direction of the bladder is determined by that of the anterior wall of
the pelvis, so that its axis is oblique from above downward and backward. On account
of this obliquity, a slight inclination of the trunk forward makes the neck of the bladder
the most dependent part of the organ. The obliquity becomes still greater when the
distended bladder has escaped from the pelvis and entered the cavity of the abdomen :
its axis then exactly corresponds with that of the brim of the pelvis, i. c, it is directed
from the umbilicus to the lower part of the curvature of the sacrum. It has been said,
since the time of Celsus, that the upper part of the bladder is a little inclined to the left
side, but I have not observed this.
Shape. — The bladder is ovoid, the great end being directed downward and the smaller
upward. Its shape differs according to age and sex, and in different individuals. The
sexual differences are not congenital ; they seem to result from the pressure to which
the female bladder is subjected during pregnancy ; but the transverse enlargement and
the vertical shortening of the bladder in a female who has borne children are not so
well marked as is generally said.
Relations. — In determining these, the bladder is divided into the fundus, which is the
highest and the narrowest part ; the body, or middle portion ; and the base, which is the
lowest and the broadest portion. It has, moreover, like all hollow organs, an external
and an internal surface.
The external surface of the bladder is convex, and presents six regions for our con-
sideration, the relations of which we shall now study, both in the collapsed and distend-
ed condition of the viscus. The anterior region, not covered by the peritoneum, is in
relation with the symphysis and bodies of the ossa pubis, and with the internal obtura-
tor muscles, with which parts it is connected by a very loose serous cellular tissue, in
stout persons more or less loaded with fat. Some fibrous bundles pass from the lower
part of this region, and are attached to the sides of the symphysis ; they are called the
anterior ligaments of the bladder, and are traversed by numerous veins ; they are a de-
pendance of the superior pelvic aponeurosis (q,fig. 181). (Vide Aponeurologv.) In
the female, on account of the absence of the prostate, the anterior region of the bladder
passes below the symphysis, and advantage may be taken of this circumstance in the
extraction of calculi. When the bladder is full, its anterior region corresponds imme-
diately with the parietes of the abdomen, and sometimes rises as high as the umbilicus.
The practical conclusions to be derived from these relations refer to the examination
of the bladder in the hypogastrium, to puncture of this organ in the same situation, to
Kkk
i
442 SPLANCHNOLdGT.
the high operation for stone, to the operation of dividing the symphysis, and, lastly, to
ruptures of the bladder in consequence of fracture of the pubes.*
The posterior region of the bladder is covered by the peritoneum (u) throughout the
whole of its extent ; in the male it corresponds with the rectum (o), and in the female
with the uterus. Some convolutions of the small intestine almost always intervene be-
tween the bladder and those parts.
The lateral regimis are also covered by the peritoneum ; and passing upon each of
them are found the umbilical artery in the foetus, and subsequently the hgament by which
it is replaced, and also the vas deferens (0 in the male. When the bladder is perfectly
contracted, there is some distance between it and that vessel and duct on either side.
The relations of the hwer region or base of the bladder, which are all very important,
differ in the two sexes.
In the male it corresponds to the rectum, from which it is separated on either side in
front by the vesicula seminalis («) and the vas deferens {t). The only part in direct re-
lation with the rectum is, therefore, the triangular space {fig. 186) comprised between
the vesiculae (s s') and the vaisa deferentia (J, I') of the two sides. It is of importance to
remark, that the peritoneum, where it is reflected from the rectum upon the posterior
region of the bladder, forms a more or less deep cul-de-sac in the middle, and two small
folds on the sides, which have been improperly named the posterior ligaments of the blad-
der. When the bladder is much contracted, the peritoneum covers the whole of the
space between the vesiculae and the vasa deferentia ; so that, properly speaking, there
is no immediate relation between that organ and the rectum. On the other hand, when
it is distended, it becomes much enlarged posteriorly, and has much more extensive re-
lations with the rectum, t It is important, also, to remark, that the peritoneum is very
loosely united to the base of the bladder, so that they can be easily separated whenever
it is desirable to reach the bladder from the rectum. On each side of the rectum the
base of the bladder corresponds with the cellular tissue of the pelvis. The superior pel-
vic fascia and the levatores ani are attached to and embrace the sides of the base.
In the female, the base of the bladder corresponds not only with the vagina, but with
the lower half of the neck of the uterus ; it adheres very intimately to the former, but
loosely to the latter.
As practical consequences of these relations, I would point out the following : In the
male, the occurrence of recto-vesical fistulae, the possibility of exploring the bladder by
the rectum, and of operating upon it in the same situation. In the female, the capability
of examining the bladder by the vagina, of puncturing it, and of performing lithotomy
through the same part ; the occurrence of vesico- vaginal fistulae, and the frequency with
which carcinoma of the bladder follows the same affection of the cervix uteri.
Summit, or Fundus. — This part of the bladder is directed forward and upward, and is
covered by peritoneum. The urachus is a sort of cord, having a muscular appearance,
and stretching from the summit of the bladder to the umbilicus, into which it appears to
enter. This cord adheres tolerably firmly to the peritoneum,^ which forms a falciform
fold over it, and may be drawn down with it when it is displaced. In a case of hyper-
trophy of the bladder, I found the cord it^lf hypertrophied, and continuous with the longi-
tudinal muscular fibres of the bladder, almost in the same way as the round ligament of the
uterus with the fibres of that organ. The urachus is merely the vestige of a canal which ex-
ists in the foetus of quadrupeds, and, according to several authors, in the human foetus also.
There have been many discussions upon this subject, some stating that the cord is
hollow, others that it is solid. I have always found it solid, both in the adult and in the
foetus. In one case I found a small concretion in it, which I regret not having submit-
ted to chemical analysis. It is very common to find the urachus large at its origin, and
becoming narrower after a course of two or three inches, and then blending with the
cord, which takes the place of the left umbilical artery ; at other times it expands into
cellular tissue, and the filaments resulting from its division proceed, some to the umbili-
cus, and others to the cords which represent the obliterated umbihcal arteries.
In the erect posture, the weight of the intestines presses on the summit of the bladder,
which is thus pushed downward ; and hence the necessity for placing the patient, during
certain operations, especially that of lithotrity, in the horizontal position, or even on an
inclined plane, so arranged that the pelvis is more elevated than the shoulders.
The internal surface of the bladder is covered by a mucous membrane, hke all cavities
which conununicate with the exterior ; and is remarkable for certain folds or wrinkles,
which are effaced by distension, and for the reticular ridges formed by the fasciculi of
its muscular coat ; these are sometimes very highly developed, and, in certain cases,
* It has even been proposed to puncture the bladder through the symphysis, by means of a flattened tro-
car ; but the difficulty of coming exactly upon the symphysis will probably prereut the execution of this plan.
t The varieties in the depth of the cul-de-sac formed by the reflected peritoneum, pointed out by modern
•nrgeons, appear to me to be explicable by the difference in size of the bladders examined. The arrange-
ment of the peritoneum seems to me to be exactly the same in all subjects.
t It would appear, from a fact which I have observed, that the bladder cannot be dragged into either inter-
nal abdominal rin^, excepting after the urachus ; this being itself drawn down by the peritoneum, with whick
it is closely united.
THE BLADDER.
443
are so large, that they form pillars, which project into the interior of the bladder. The
mucous membrane not unfrequently becomes insinuated between these columns, so as
to form cells, or what is termed sacculated bladder. The base of the bladder presents
three openings, viz., the orifices of the two ureters (r r,fig. 182), and the opening into
the urethra. These three openings occupy the angles of an equilateral triangle (" coUi-
cula ab ureteribus ad urethram producta," Holler), the sur- pig. 182.
face of which is smooth and white, and is always devoid of
wrinkles or columns. This is the trigone of the bladder, or
trigone of Lieutaud, which has been supposed to possess a
pecuhar degree of sensibihty. The posterior border (r r) of
this trigone is more or less prominent in different individ-
uals, and is formed by a line stretching between the orifices
of the two ureters ; this prominence is prolonged outward
on each side by the portion of the ureter which lies in tl>e
parietes of the bladder. It has been stated incorrectly, that
the trigone is formed by the projection of the prostate, for it
exists in females as well as in males, though it is less prom-
inent than in the former. All that part of the base of the
bladder which is behind the trigone is generally called the
las fond, ot inferior fundus.*
Most anatomists follow Lieutaud in describing, under the
name of uvula vesica, a tubercle which arises from the low-
er part of the orifice of the urethra, and partially fills up that
opening ; but it exists only in cases of disease, being the re-
sult of hypertrophy of the middle portion of the prostate, de-
scribed by Home as the middle lobe.
The orifices of the ureters are so constructed as to per-
mit the easy passage of the urine into the bladder, but com-
pletely to oppose its reflux. Their long oblique course be-
neath the mucous membrane before opening into the blad-
der explains this arrangement. The raised and reflected
portion of the membrane might be called the valve of the ureter.
The opening of the urethra, which is also called the neck of
the bladder, is habitually closed, and, as it were, corrugated.
Some force is required in order to overcome the resistance
offered by it ; the crescentic form which has been attributed to it is not very evident.
Structure. — The bladder has three coats : a peritoneal, which is incomplete, a muscu-
lar, and a mucous coat ; these are connected by layers of cellular tissue : it has also ves-
sels and nerves.
The peritoneal coat covers the posterior and laterjil regions, and the inferior fundus of
the bladder. The anterior region, and that part of the base which is in front of the infe-
rior fundus, are not covered by it. It is united to the muscular coat by very loose cellu-
lar tissue.
The muscular coat is formed of interlacing fibres, the direction of which it is, at first
sight, very diiScult to determine. + This coat is very thin, and does not form a continu-
ous layer in enlarged bladders ; but in small and contracted bladders it is continuous,
and consists of several layers, and may even acquire a thickness of eight or ten lines
from hypertrophy. It is, then, very easy to determine the direction of the fleshy fibres,
which seem to form a number of layers. The external layer consists of longitudinal
fibres, all of which proceed from the neck of the bladder, and expand over the whole sur-
face of the organ ; the next layer is formed of circular fibres, some of which are irregu-
larly interlaced, while the others are parallel. The regular circular fibres are most nu-
merous opposite the inferior fundus of the bladder, and are continuous with the annular
fibres of the neck.
The irregular circular fibres are most common in the posterior region of the organ. In
the situation of the trigone, the muscular layer consists of transverse parallel fibres, pla-
ced near each other, and forming a perfectly regular plane. The transverse thick bun-
dle stretching between the orifices of the ureters has been regarded by Sir C. Bell as the
muscle of the ureters. Its contraction, by enlarging their orifices, will facilitate the
entrance of the urine into the bladder.
The term sphincter of the bladder is applied to a muscular ring, which is continuous
with the circular fibres of the body of the bladder, and is situated at the opening of the
urethra. The vagueness and disagreement in the descriptions of this sphincter suffi-
ciently prove that no very distinct structure of the kind exists at the neck of the blad-
der. Winslow describes some fibres arising from the ossa pubis, and embracing tie
* It is not uncommon to find the bladder forming behind the trigone a deep cul-de-sac, which I have seen
insinuated between that part and the rectum. _
t [These fibres belong to the involuntary class, the microscopic characters of which are described in the
note, p. 32.-?.]
444 SPLANCHNOLOGY.
sides of the vesical orifice, as the sphincter muscle, but they evidently belong to the le-
vator ani. It is certain, however, that, in the neck of the bladder, there is a thin exter-
nal layer of longitudinal muscular fibres, and also a deep and very thick layer formed of
circular fibres ; both layers seem to be continued into the prostatic portion of the urethra
The mucous coat is extremely thin,* of a whitish colour, and presents some small papil
lae. It is so difficult to demonstrate its follicles, that their existence has been denied ;
but, with a little attention, they may always be found in the neighbourhood of the neck
of the bladder, and upon the trigone. I have seen them in all parts of the bladder, under
the form of vesicles, in certain cases of disease. The mucous membrane is moulded
upon all the ridges of the muscular coat : it sometimes dips between the muscular bun-
dles, and forms cells, in which calculi are often lodged. Bladders of this kind are call-
ed sacculated, and, moreover, are almost ,a\vf?iys fasciculated ; i. e., the muscular fibres
are so highly developed as to raise up the mucous membrane into ridges. The cellular
tissue uniting the muscular and the mucous coats is tolerably loose, serous, and extreme-
ly delicate.
Vessels and Nerves. — The vesical arteries arise either directly from the hypogastrics, or
from their branches. They are variable in number. The veins form a very remarkable
plexus around the neck of the bladder, which is prolonged upon the sides of the inferior
fundus, and terminates in the hypogastric veins. The lymphatic vessels are, for the most
part, situated between the muscular and the peritoneal coats, and terminate in the hypo-
gastric lymphatic glands. The nerves are derived from the hypogastric plexus, which is
composed both of ganglionic and spinal nerves ; and hence the bladder is partly subject
to, and partly beyond the influence of the will.
Development. — The bladder of the foetus is remarkable for the predominance of its ver-
tical over its transverse diameters, the latter being very short. This fact, added to the
imperfect development of the pelvis, explains why the entire bladder projects above the
brim of the pelvis at this period of life. The inferior fundus does not exist. The sum-
mit is gradually continued into the urachus, which is then much larger than at subse-
quent periods, and of which the bladder appears to be merely an expansion. According
to some authors, the bladder is relatively larger, and, according to others, smaller before
than after birth.
In the early periods of infancy, the bladder retains tht characters which it had in the
foetus, and many important surgical inferences may, therefore, be drawn from its more
extensive relations with the abdominal parietes. In proportion as the pelvis is devel-
oped, and also, perhaps, in proportion as the frequently-accumulated urine dilates the
bladder in its transverse and antero-posterior diameters, this organ sinks into the pelvic
cavity, and, when completely developed, presents the characters already assigned to it.
The urachus, which, we have seen, is converted into a muscular cord in the adult, and
is sometimes lost before reaching the umbilicus, is much more developed in the foetus : it
may then be traced as far as the umbilicus, and even, according to some anatomists,
through the whole extent of the umbilical cord. Analogy, and some observations upon
the human subject, would seem to show that the urachus is hollow in the foetus. In the
lower animals the cavity of the urachus may be traced into a bag called the allantois,
which is situated between the membranes of the ovum ; and it is stated by several au-
thors, that they have caused mercury injected into the bladder to pass some distance
(half an inch, one inch, or one inch and a half) into the urachus, and even for a greater
or less extent into the umbilical cord.
Moreover, in new-born infants, and even in adults, the urine has been seen to escape
through the umbilicus ; but, in these cases, the urethra is always obliterated. I have
already said that I have met with a calculous concretion within the substance of the
urachus, and I find that Haller and Harder have made a similar observation {arenuliB in
uracho visa,). M. Boyer {Traiti d" Anatomic, p. 477, Splanchnoi ogie) says that he has
dissected the bladder of a man twenty-six years of age, whose urachus formed a canal
an inch and a half long, and contained twelve urinary calculi as large as millet-seeds ;
one of them was larger, and resembled a grain of barley. He convinced himself that the
canal which contained these calculi was not formed by a prolongation of the internal
membrane of the bladder through the other coats. On the other hand, a number of ob-
servers (myself among them) have found the urachus solid in the foetus. New facts are,
therefore, necessary to settle this anatomical question ; although it is very probable that
the urachus of the human subject is of the same nature as that of animals, but becomes
obliterated at a much earlier period.
Functions. — The bladder is intended as a reservoir for the urine, and is also the prin-
cipal agent in its expulsion. The urine constantly trickles, drop by drop, into the blad-
der, but cannot flow back by the ureters, on account of the mechanism already described.
Wlien the bladder is distended, it occasions a desire to evacuate its contents, and the
urine is then expelled by the combined action of the bladder itself and the abdominal
muscles. I have said that the bladder is the chief agent in this expulsion, for, in cases
* [This and all the other portions of the genito-urinary mucous membrane have <in epithelium, which ap-
•roaches to the columnar in character.]
THE SUPRA-RENAL CAPSULES. 445
of retention of urine from paralysis, or excessive distension of the bladder, the most
powerful contractions of the abdominal muscles are not sufficient to expel it.
The Supra-renal Capsules.
The supra-rend capsules (c c,Jig^. 199) are organs whose use is unknown ; they are situ-
ated near the upper end of the kidneys, and, hke them, are outside of the peritoneum.
The proximity of the kidneys and supra-renal capsules has led to the supposition that
there is some mutual relation between their functions ; and hence they are generally de-
scribed together, though not on perfectly just grounds.* The name renes succenturiati
( Casserius) is sufficient evidence of the relation which has been supposed to exist be-
tween these organs. Nevertheless, this connexion of situation, which constitutes the
most important and characteristic feature in the history of the supra-renal capsules, is
not constant ; and, in the numerous cases in which the kidneys occupy some unusual
position, the supra-renal capsules do not accompany those organs in their displacement.
Thus, when the kidneys are situated higher than usual, the capsules are placed on their
inner side, and correspond vsith the renal fissure ; when the kidneys occupy the pelvic
region, the capsules undergo not the slightest change in their position, and no longer
have any connexion with them.
Number. — There are two supra-renal capsules ; it is said that two have been found on
each side.
Size. — They vary much in size in different individuals : sometimes they are so small
that they can scarcely be distinguished from the fat by which the kidney is surrounded ;
at other times they are very large. In a case where the two kidneys were very small,
I found the supra-renal capsules much larger than usual. It has been said that they are
larger in the negro than in the Caucasian race. I have examined two negroes, and did
not find them unusually large. In the foetus they are proportionally larger than in the
adult. I have found them very large in several females far advanced in years.
The two capsules are not of the same size. Eustachius affirms that the right is
larger than the left ; but I have generally found the reverse. Their weight is about one
drachm.
Form. — I shall follow the example of M . Boyer, in comparing these supra-renal capsules
to a helmet, flattened on its anterior and posterior surfaces, and embracing the upper
end of the kidney by a narrow and concave surface. The relations of its anterior surface
are different on the right and the left side.
On the right side it is in relation with the liver, to which it adheres by a tolerably dense
cellular tissue, so that the capsule is always removed in connexion with that organ.
This relation between the liver and the capsule is much more constant and intimate than
that between the capsule and the kidney. A small depression, already described as ex-
isting on the lower surface of the liver, to the right of the vena cava ascendens, is in-
tended for the reception of the capsule.
On the left side the capsule is in immediate relation with the pancreas, and is indirect-
ly connected with the spleen and the great end of the stomach.
The posterior surface is in contact with the highest part of the pillars of the diaphragm,
opposite the tenth dorsal vertebra. The great splanchnic nerves and the semilunar
ganglia are situated behind, and on the inner side of the capsules, to which they send off
so many branches, that Duvernoy regarded these organs as the ganglia of the renal nerves.
Their convex, thin, and slightly sinuous border, is directed inward and upward. Their
concave border is thick, and almost always deeply grooved. The surface of the capsules
is invested by a thin layer of fat, which it is extremely difficult to remove, on account
of the numerous fibrous and vascular prolongations that pass into it from the capsule ;
certain furrows, either containing vessels or not, and varying in depth and extent, trav-
erse the surface of this organ, especially in front.
Cavity. — It is still doubtful whether the supra-renal capsules have a cavity in their in-
terior, as their name would seen to indicate. It is certain that in the greater number
of subjects, on dividing them in different directions, they are found to consist of two
laminae applied to each other, and united as by an adhesive substance, a sort of dark-
coloured, false membrane ; and that these laminaj are reflected inward opposite the con-
cave border, so as to form a projection like a cock's comb in the interior of the capsule.
The colour of the external surface is yellowish, or, rather, mottled with large yellow and
brown spots. The internal surface, or, rather, of the parts which are in contact, is chest-
nut brown, or bistre colour of different shades, so that I am induced to compare its ap-
pearance with that of an apoplectic cyst. It seems as if in this, as in the other case,
blood had been effused, and then absorbed.
The internal surface is also rough, and, as it were, lacerated ; a sort of yellowish or
chestnut-coloured pulp may be scraped off it. I have seen roundish, pulpy vegetations
jpringing from several parts of this surface, sections of which presented a yellowish
colour, mottled with brovra.
The name of atrabiliary capsules, given to them by Barthohn, is undoubtedly derived
* Eustachius, who first described them, called them glanduUt qua renibus incumbunt.
446 SPLANCHNOLOGY.
from the deep brovm colour of their internal surface. That anatomist regarded them as
small pouches or capsules, and thought that they were the reservoirs of the blackish
fluid (sanguis niger, Bartholin; succus atrabiliaris, atramentum glandulosum, Lecat.) to
which the ancients gave the name of atrabilis.
Structure. — The supra-renal capsules consist of two substances : one external or cor-
tical, yellowish, and striated, which forms almost the whole thickness of the capsule ;
and an internal or central portion, presenting the appearance of a soft layer of a deep
chestnut brown colour, and traversed by numerous vessels. The striated arrangement
of the cortical layer, which is so easily seen in large animals, is frequently effaced in the
human subject, where the capsule appears reduced to a thin yellowish lamella, folded
back upon itself The lobular character of the surface is only apparent, and depends
upon the furrows formed in it for the vessels. The granular structure, admitted by most
of the authors who have called these organs glands, has not been clearly demonstrated.
A fibrous membrane, anedogous to the proper coat of the kidney, covers the supra-renal
capsules.
The capsular arteries are very numerous and very large, in proportion to the size of the
organ ; they are divided into the superior, arising from the phrenic, the middle, proceed-
ing directly from the aorta, and the inferior, furnished by the renal arteries. The ■veins
are very large, and soon pass into the vena cava ; the anterior furrow is chiefly intend-
ed for them. It h^ls been supposed that they open directly into the cavity of the capsule,
on account of the faciUty with which this latter may be distended by injecting air or any
fluid into the veins. But it is probable that in such cases laceration has occurred. The
veins of the right capsule enter the vena cava inferior directly ; those of the left enter
the renal vein of the same side. The lymphatic vessels are little known. The veins are
very numerous ; they are derived directly from the semilunar ganglia and solar plexus,
and also from the renal plexus. It is in vain to search for the excretory duct, admitted
by several anatomists ; and described by some as entering the pelvis of the kidney, and
by others as terminating in the testicle in the male, and in the ovary in the female.
Development. — The supra-renal capsules are relatively much larger in the foetus than
in the adult, and they are remarkable in this respect, that their size is inversely propor-
tioned to that of the kidneys. They are distinct as early as the second month of intra-
uterine life, and at that time exceed the kidney both in weight and size. This predom-
inance continues during the whole of the third month ; at the fourth, the kidneys and
the supra-renal capsules are of equal size ; at the sixth month, the capsules are not more
than half as large as the kidneys ; at birth, not more than one third. Tlie existence of
a cavity is not more evident in the foetus than in the adult.
In the aged, the supra-renal capsules are sometimes very large, and their colour is al-
ways yellow at this period of life.
Uses. — The uses of the supra-renal capsules are unknown ; we are even ignorant
whether they should be classed lunong the glands. The great number of vessels with
which they are supplied, and the numerous nerves distributed upon them, suiEciently
prove that something more than mere nutritive changes must occur within these organs.
Their pathological anatomy, which still remains to be investigated, may perhaps throw
some light upon this obscure point of physiology.
THE GENERATIVE ORGANS.
The generative apparatus presents this remarkable peculiarity, that the organs of
which it is composed are divided between two individuals of the same species ; and from
this division results the difference of sex.
The male sex is chiefly characterized by the faculty of producing a fecundating fluid,
the spermatic fluid, or semen. The female sex is characterized by the faculty of produ-
cing certain ovules, which become fitted for the reproduction of an individual of the same
species, as soon as they have been submitted to the fecundating influence of the fluid
secreted by the male. The female sex is also characterized, in the human species, and
in all mammalia, by the possession of a gland (the mamma), which is intended to provide
nutriment for the newly-born creature.
The genital organs occupy the lower extremity of the trunk ; they are situated in con-
tact with the termination of the digestive canal on the one hand, and of the urinary organs
on the other, with the latter of which they have the most intimate connexions, especial-
ly in the male.
THE GENERATIVE ORGANS OF THE MALE.
The Testicles and their Coverings. — The Epididymis, the Vasa Deferentia, and VesiculeB
Seminales. — The Penis. — The Urethra. — The Prostate and Cowper^s Glands.
The genital organs of the male consist of a secreting and an excretory apparatus, com-
posed of the following parts : two glands, called the testicles ; two provisional excretory
canals, the vasa deferentia ; two reservoirs for the spermatic fluid during the longer or
THE TESTICLES. -447
shorter intervals between the periods of its expulsion, named the vestcula seminales ;
and certain ultimate excretory canals, the ejaculatory ducts and the urethra. To this lat-
ter canal is annexed an erectile structure, which enables it to assume the condition ne-
cessary for the ejection of the fecundating fluid ; together, they form the pe7iis. The
prostate gland and Cmcper's glands yield secretions, the use of which is connected with
the generative functions : they may be regarded as appendages of the urethra.
The Testicles and their Coverings.
The Coverings of the Testicle.
The coverings of the testicle consist of several layers, which, reckoning from without
inward, are the scrotum, the dartos, the tunica erythroides, the fibrous coat, and the tu-
nica vagin£ilis. There is a sixth testicular covering, named the tunica albuginea ; but,
as it forms an integral part of the testis, we shall describe it with that organ.
The scrotum,* or cutaneous covering of the testicles, is a sort of pouch or bag common to
both of those organs ; the skin of which it is composed exhibits the following peculiarities :
It is of a browner colour than that of other parts of the body, so that, in some individ-
uals, a layer of colouring matter, similar to that existing in the negro, may be demonstra-
ted beneath it ; like the skin of the penis and the eyelids, it is very thin, on account of
the tenuity of its chorion ; it is much larger than is needed for containing the testicle ;
it is provided with scattered and obliquely inserted hairs, the follicles of which are large,
and project upon the surface ; and, lastly, its external aspect presents many varieties :
thus, it becomes flaccid and elongated under the influence of warmth, and in old and en-
feebled persons, while, during youth, in the robust, and under the influence of cold, it
becomes contracted, wrinkled, and closely applied to the testicle.
The scrotum is divided into two equal halves, by a sort of median line or ridge, caUed
the raphe, from the Greek word fidnru, to sew ; because the two halves of the skin ap-
pear to be united at this part, as it were, by a seam.
The object of the great extent of the skin of the scrotum is, perhaps, to enable it to
cover the penis when in a state of erection.
The dartos is a reddish filcunentous tissue, traversed by a great number of vessels,
which can be easily seen through the skin of the scrotum. This tissue envelops both
testicles, and furnishes a prolongation interposed between them, and forming the septum
of the dartos. Upon the sides, and opposite the spermatic cord, the dartos terminates
abruptly, and is replaced by adipose cellular tissue. In front it is continued around the
penis ; behind, it is prolonged upon the median line, by an angular extremity, as far as
the sphincter ani.
It follows, therefore, that there is only a single dartos, within which are contained
both testicles, a septum alone intervening between them. This separation in the mid-
dle line has led some to follow Ruysch, in describing a distinct dartos for each testicle.
The dartos is closely united to the skin of the scrotum by its external surface, and it is
very loosely connected by extremely delicate cellular tissue, with the subjacent cover-
ings, upon which it glides with the greatest freedom.
With regard to its structure, the dartos, at first sight, presents some analogy to cellu-
lar tissue, but it differs from it essentially in its aspect ; for in no situation does ceUular
tissue exliibit distinct reddish nodulated filaments, like those of the dartos. It is true
that these filaments are irregularly interlaced, but the majority of them peiss in a verti-
cal direction ; and when a single fibre is examined, we are struck with its analogy to
muscular tissue. t It also differs in its vital properties : thus, the dartos possesses the
property of active contractility, as is seen in the contraction of the scrotum, and the ver-
micular motions observed in persons exposed to cold, or under the influence of great
dread, or of the venereal orgasm, and also in the much more evident contraction of the
scrotum after an irritating injection has been thrown into the cavity of the tunica vaginalis.
It is, therefore, intermediate between cellular and muscular tissue, and might be call-
ed the dartoid tissue. It was, for a long time, supposed to be confined to the scrotum,
but it is met with in many other parts, viz., the vagina, the substance of the nipple, and
the parietes of the veins, of which it seems to me to form the external coat.
Some anatomists regard the dartos as nothing more than the remains of the guhcrnac-
tdum testis ; but, in the first place, the dartos is found in the foetus, before the descent
of the testicle ; and in an adult whose testicle had not escaped from the external ab-
dominal ring, I satisfied myself that the gubernaculum and the dartos existed separately
and independently of each other, t
* From the Latin word scrotum, a sac, or purse of leather. The Greek term for the same part is S/rxM")
and hence the word oscheocele, which serves to designate every tumour developed in the scrotum.
t [According to M. Jordan (Miiller's Archives, 1834), the tissue of the dartos is composed of uniform cylin-
drical filaments, which resemble those of cellular tissue in diameter, but are larger than the varicose fila-
ments of voluntary muscular fibre, and smaller than the involuntary muscular fibres, excepting those compo-
sing the iris. They resemble cellular tissue, and not muscle, in their chemical characters, and difT^r from the
fonner only in presenting a reddish aspect, and in being arranged into longitudinal fasciculi, instead of inter-
lacing in all directions.]
t The specimen from which this statement is taken has been presented to the anatomical society hy M. Manec
448 SPLANCHNOLOGY.
The dartos has also been incorrectly regarded as a continuation of the superficial Jascta
(see Aponeukology).
The Tunica Erythroides. — This name (derived from the Greek word kpvdph^, red) is
given to a thin membrane, formed by an expansion of the fibres of the cremaster. It is
very well marked in the young and vigorous, but becomes partially atrophied in the aged.*
We have already seen (vide Obliquus Internus Abdominis, Myology) that the cremas-
ter is essentially formed of fibres arising directly from the groove of the crural arch, on
the outer side of the inguinal canal. The loops formed by the lower portions of the ob-
liquus internus and transversalis are, where they exist, completely distinct from it. The
cremaster and the tunica erj^hroides, which is an expansion of it, are the agents of the
sudden upward movement of the testicle, which is very distinct from the slow vermicu-
lar motion resulting from the action of the dartos. In a patient whose urethra was ex-
tremely irritable, I found that the introduction of a bougie was followed by a sudden and
long-continued elevation of the testicles, with a separation of their lower ends. This
movement was entirely independent of the dartos and scrotum, which remained flaccid
and pendent in front of the thighs.
Wlien the cremaster reaches the testicles, it expands into a number of fasciculi, dis-
tributed over the surface of the fibrous coat, and inserted, in the lower animals, by well-
marked tendinous fibres, which, however, I have never been able to discover in man.
In hydrocele, these fibrous bundles resemble small cords, which, as Sir A. Cooper ju-
diciously remarks, may be mistaken for veins.
The Common Fibrous Coat. — This membrane is very distinct from the tunica vagina-
lis, which lines its inner surface ; it forms a common covering for the testicle and the
spermatic cord ; it is thin and transparent, narrow along the cord, and expanded below,
so as to cover the testicle. At the inguinal ring it divides into two laminae, one of
which, almost always incomplete, is attached to the circumference of the ring, while the
other seems to be prolonged within the canal, where it is, however, very difficult to fol-
low it. Modern anatomists regard this fibrous tunic as a prolongation of the fascia trans-
versalis, which would be dragged down with the testicle during its descent.
The Tunica Vaginalis, or Serous Coat. — The tunica vaginalis is a shut sac, and pre-
sents two portions : one, parietal (p, fig. 183), lining the fibrous coat ; the other, reflected
or testicular {v), which covers the testicle, without that organ being contained within
the sac.
The intimate union of the serous and fibrous coats of the testicle affords an example
of a fibro-serous membrane, analogous to the dura mater and the pericardium. As the
reflection of the tunica vaginalis upon the testicle takes place at a variable height, it
follows that a greater or less portion of the cord is covered by this coat.
The arrangement of the tunica vaginalis on one side of the epididymis differs from
that on the other. On the outer side it immediately invests the epididymis, is then re-
flected from it, becoming applied to the part reflected from the opposite side of the epi-
didymis, and forms a cul-de-sac, by which the middle of that body is completely separa-
ted from the upper border of the testicle. At the bottom of this cul-de-sac are some
small openings, leading into a back cavity. It forms, therefore, a fold like the mesen-
tery, at the middle of the epididymis, the two ends of which, however, are closely ap-
plied to the testicle. On the inner side it rises higher upon the cord than on the outer
side, and is separated from the epididymis by the vas deferens and the spermatic ves-
sels. It is easy to detach it from the fibrous coat, where it is reflected upon the testi-
cle, but it adheres closely to the epididymis and to the tunica albuginea.
Its internal surface, free and smooth, exhales a serous fluid, the morbid accumulation
of which constitutes the disease called hydrocele. In most animals the tunica vaginalis
communicates with the peritoneum at aU ages ; but in man this communication exists
normally only during intra-uterine life. After birth the two cavities are perfectly dis-
tinct. If, from any cause, this separation is not completed, the tunica vaginalis may
form either a hernial sac, containing displaced intestines, or a cyst containing serous fluid
effused from the abdomen. In the former case, the disease is called congenital hernia,
in the latter congenital hydrocele.
The Testicles.
The testicles (testes) are two glandular organs, intended to secrete the spermatic fluid.
They are situated in the scrotum, at the sides of and below the penis, and are, there-
fore, exposed to external violence. They are supported by their coverings, and by the
cord formed by the spermatic vessels, and are at a greater or less distance from the in-
guinal ring, according as the dartos and cremaster are in a state of relaxation or con-
traction.
The testicles are not situated at exactly the same height, the left descending a little
lower than the right. This arrangement, which has not escaped the observation of
* The cremaster is extremely well developed in the stallion ; in which animal it is easy to establish the
distinction between this muscle and the lower fibres of the internal oblique, the loops of which do not exist in
all subjects.
THE TESTICLES. 449
painters and sculptors, assists in protecting them from injury by enabling them to glide
one above the other when the thighs are closely approximated, and thus to avoid com-
pression. Their situation is not the same at all periods of life. In the foetus, they are
contained within the abdominal cavity. Sometimes they remain permanently, or much
longer than usual in that situation, which, in the natural state, is merely temporary.
Number. — The varieties in the number of the testicles are most of them only appEirent.
Thus, for example, in almost all monorchides (persons having but one testis : from fiovog,
single, and bpxi-u a testicle), that testicle which is absent from the scrotum is situated
in the abdomen. Nevertheless, I have had occasion to dissect an individual who had
only one testicle ; there was an atrophied vesicula seminalis on the side where the tes-
ticle was wanting ; the vas deferens commenced at this vesicle, and was lost upon the
side of the bladder. I was not able to examine the spermatic vessels. The examples
of three, four, or five testicles are not well attested.* An epiploic, or fatty tumour, or
a cyst, may have been mistaken for a testicle.
Size. — The testicles vary in size in different individuals, and still more at different
ages. At the period of puberty, the testicle, which up to that time had been, as it were,
in a state of atrophy in comparison with the rest of the body, increases greatly in size.
This atrophy, which is normal before puberty, may continue to a more advanced age.
In a subject about twenty years of age, in which the penis and larynx were highly de-
veloped, I found the two testicles atrophied : they weighed less than a drachm ; the
epididymis, although it was atrophied, was larger than the body of the testicle.
The two testicles are not exactly of the same size : the left is generally larger than
the right ; but this difference is so slight and inconstant, that some anatomists have
even thought that a shght predominance may be observed in the right.
The following are the average dimensions of the testicle : Length, two inches ; breadth,
one inch ; thickness, eight lines.
Weight. — According to Meckel, the weight of the testicle is four drachms ; according
to Sir Astley Cooper, one ounce.
Consistence. — It is extremely important, especially in a practical point of view, to
judge of the natural consistence of the testicle. The character of this consistence is
determined less by the proper substance of the testicle than by the degree of tension of
its immediate covering ; and in this respect the consistence of the testicle very much
resembles that of the eye. In the aged, the seminiferous ducts being empty, the testi-
cle becomes soft, and, as it were, atrophied. It would be still less consistent, if it were
not for the serous fluid with which the cellular tissue between these ducts becomes in-
filtrated.
Figure, Direction, and Relations. — The testicle is oval, but flattened at the sides. This
form, added to the polished and slippery character of its surface, enables it easily to
avoid compression. The long diameter or axis of the testicle is directed obliquely down-
ward and backward ; its lateral surfaces and its lower borderf are convex, free, smooth,
and constantly lubricated by the serosity of the tunica vaginalis. The upper Border is
straight ; it is directed backward, is embraced by the epididymis, which surmounts it
like the crest of a helmet, and is covered by the tunica vaginalis in a small portion only
of its extent. The spermatic vessels enter at the inner part of this border, and behind
the head of the epididymis. The anterior extremity of the oval is the larger, and is di-
rected upward and forward ; the posterior extremity is turned backward and downward.
The white colour of the surface of the testicle is owing to its proper fibrous covering,
which, on account of its whiteness, is called the tunica albuginea.
Structure. — The constituent parts of the testicle are a fibrous membrane, a proper tis-
sue, and certain vessels and nerves.
The fibrous membrane, tunica propria sive albuginea, is white, strong, and inextensible ;
it is analogous to the sclerotic coat of the eye, and, like it, forms the most external coat
or shell of the organ which it covers.
The tunica vaginalis invests the outer surface of the tunica albuginea, excepting op-
posite the epididymis, where the fibrous coat is destitute of the serous membrane for a
considerable extent. The serous and fibrous layers adhere closely to each other.
Within the substance of the tunica albuginea, but nearer the internal than the exter-
nal surface, are a great number of tortuous vessels, which may be seen through the
semi-transparent fibrous layer by which they are covered. These vessels project on the
internal surface of the tunica albuginea, so that at first it might be thought that they
vvere simply in contact with the membrane, and not within its substance. t
* 1 have been consulted concerning a child, who appeared to me to have two testicles upon one side, each
of which was as large as that of the opposite side ; but it is impossible to decide with certainty upon such a
matter until dissection has shown the true nature of pretended supernumerary testicles. Nevertheless, tli«
kind of pain felt upon pressing the body imagined to be a testicle may afford tolerably satisfactory indications
during life.
t [M. Cruveilhier differs from mos^ other anatomists in applying the terms upper and lower to the opposite
borders of the testicle, instead of posterior and anterior ; on the contrary, he describes the two extremities of
this organ as anterior and posterior, instead of upper and lower, as is usually the case.]
i The existence of numerous vessels within tlie substance of the tunica albuginea has led Sir Astley Coojh
Ti L L
450
SPLANCHNOLOGY
The internal surface of the tunica albuginea is in immediate relation with the proper
Fig. 183. substance of the testicle, and is connected with it by a great num-
/ . ber of vascular filaments, which traverse it in all directions, and
divide it into small masses or lobules, and also by the extension of
the substance of the gland itself into oblique culs-de-sac, or cells
formed by the tunica albuginea, several of which are a line and a
half or two lines deep. When the tunica albuginea is carefully re-
moved, filaments of the glandular substance are seen escaping from
these small cells, which are most numerous at the upper borders
of the testicle. The strength of the vascular filaments which trav-
erse the testicle has led to the opinion that they are all enveloped
by a fibrous sheath derived from the tunica albuginea, but I have
never been satisfied of the existence of these sheaths.*
At the upper border of the testicle, the tunica albuginea becomes
remarkably thickened, and forms the corpus Highmori, or medias-
tinum testis ( Cooper). In order to obtain a correct notion of this
structure, it is necessary to make a vertical section of the testicle
at right angles with its long diameter : we then observe a nucleus (i, fig. 183), or fibrous
thickening of a triangular shape, perforated by bloodvessels, but do not at first sight dis-
cover any canals in it ; so that we might be inclined to agree with Winslow (who called
it the nucleus of the testis) in denying that it contains any canals ; or, rather, with Swam-
merdam, in regarding those canals that do exist in it as destined exclusively for the ar-
teries and veins.
If, after dividing the testicle along its convex border, we reflect the tunica albuginea,
we shall see that near the upper border the filaments (a a, fig. 184) which constitute the
substance of the testicle enter {b b) numerous spaces existing in the tunica albuginea at
this part, pass towards the thickening (»') of the upper border, traverse it (c) from its pos-
terior to its anterior extremity, and then, uniting together into a greater or less number
of tubes, perforate (d) the tunica albuginea opposite the head of the epididymis (e).
The corpus Highmorianum, moreover, exists only in the anterior half of the upper
border of the testicle (see i, fig. 184). All the bloodvessels reach the testicle at this
point, and, having entered it there, divide into two sets ; one of these is situated in the
substance of the fibrous coat, so as to form its sinuses (the tunica vasculosa), and fur-
nishes a multitude of vessels, which are given off from it in succession, and are distrib-
uted to the substance of the gland.t Among these vessels, I would particularly notice
one tortuous artery which passes from before backward along the upper border of the
testicle. The other set of vessels perforate the corpus Highmorianum directly, and pass
from the upper to the lower border of the testicle. The corpus Highmorianum, then, is
a thickening of the tunica albuginea, which occupies the anterior half of the upper bor-
der of the testicle, and is perforated by the filaments composing the proper tissue of the
testicle, and also by a great number of bloodvessels.
Proper Tissue. — The proper substance of the testicle resembles a soft yellowish pulp,
grooved by a multitude of small tense and strong columns,
which divide it into a great number of masses or lobules (a a,
fig. 184). These small columns are nothing more than the
vessels given off from the tunica albuginea.t Each lobule rep-
resents a pyramid, the apex of which is directed towards the
upper border of the gland, and the base towards its lower bor-
der. The lobules consist of a collection of extremely delicate
filaments, folded a very gi-eat number of times upon themselves,
so as to resemble the granules of glands, and have, in fact, been
described as such by some anatomists.^ These filaments are
the seminiferous tubes, which were injected by Haller and Mon
Fig. 184.
er to describe two layers in it ; an external, which he compared to the dura
mater, and an internal (the tunica vasculosa), which he likened to the pia
mater, I cannot admit this analog-y. The vessels contained in the tunica al-
buginea rather resemble the sinuses of the dura mater than the vascular net
work of the pia mater. * See note, p. 421
t [According to Sir Astley Cooper, many of the arterial vessels pass along
the septa, extending from the inner surface of the tunica albuginea to the
mediastinum, and then turn back and are distributed upon the lobes. The
principal veins arise upon the larger ends of the lobes, pass up to the mediasti-
num, and perforate it.]
t [Sir Astley Cooper has described fibrous columns which extend from the
inner surface of the tunica albuginea, and unite with similar prolongations given off from the mediastinum
testis, and forming the sides of the cells described by M. Cruveilhier (p. 449). From these columns lateral
membranes proceed, so as to form septa between the larger masses of glandular structure, while other finer
membranous extensions enclose the small lobes in separate pouches. The larger bloodvessels are supported
by the columns, and the smaller ones ramify upon the membranous septa and pouches.]
4 Riolanus described a fibrous thickening'of the proper coat of the testicle. The description given by High-
more is very confused ; he describes a body obscure aut omnid non cavum, which appears to perforate the tu-
nica albuginea, and to convey the semen to the epididymis ; he has also represented as opening into this canal
• certain parallel vessels, which he considered to be an artery and a vein.
THE TESTECLES. 461
ro from the vas deferens. I have in vain attempted to perform the same experiment ;
the mercury never passed beyond the epididymis. It has been said that each lobule is
formed by one or two tubuh, and the number of these tubes has been calculated at 300.
Each tubulus is said to be 16 feet long, and -^^o of an inch in diameter. According to
Monro's calculation, there would be 5000 feet of tubuli seminiferi in the small space oc-
cupied by one testicle.
If we take hold of the substance of the testicle with a pair of pincers, and then draw
it out slowly, we shall raise a number of apparently knotted filaments from the common
mass, some of which will break immediately, while others may be drawn out to a foot,
a foot and a half, or two feet, without breaking. It is particularly easy to pull out the
filaments when the tissue of the testicle is very moist. The little knots disappear du-
ring this process, and the tubuli then assume the character of straight and almost trans-
parent filaments.*
The proper tissue of the testicle adheres to the tunica albuginea by the bloodvessels
only, excepting near the upper border of the testicle. In this situation the tubuli are
lodged in the cells or spaces, already described, in the substance of the tunica albuginea ;
they all pass towards the corpus Highmori, traverse it from behind forward, and form
within its substance what Haller described as the rete vasculosum testis {,c,figs. 184, 185),
because he supposed that the seminiferous tubes in this situation communicated with
each other. +
Lastly, the tubes composing the rete unite into an indeterminate niunber of efferent
ducts {d), estimated at from ten to thirty, which perforate the tunica albuginea, opposite
the head of the epididymis.
Vessels and Nerves. — ^The testicular artery, the principal division of the spermatic, di-
vides, before entering the testis, into several branches, which pass into the tunica albu-
ginea along the upper border of the gland, and are distributed as I have already pointed
out when speaking of the corpus Highmori. The veins are very numerous, are arranged
in an analogous manner, and form the spermatic veins. The lymphatics are very numer-
ous, and are divided into the superficial and deep.
The nerves are derived both from the ganglionic and the cerebro-spinal system. They
have not been traced mto the interior of the testicle, and yet the sensibility of that organ
is sufficient evidence of their existence there.
The serous cellular tissue, by which the seminiferous ducts are united, is so delicate,
that it can only be shown bv the aid of a very favourable light
The Epididymis.
The epididymis (e /, Jigs. 184, 185) is the vermiform appendage which lies along the
superior border of the testicle, like the crest upon a helmet. Its name is derived from
its position (enl, upon, 6i6vfiog, the testicle).
It is so situated that it does not precisely occupy the superior border of the testicle,
but encroaches a little upon its outer face (see Jig. 182, a section of the right testis), so
that when the tunica vaginalis is opened, and the inner side of the testicle examined,
we cannot see the epididymis. It is closely connected with the testicle by its anterior
extremity, which is remarkably enlarged, and is called the head, or globus majm- (e) ; its
middle portion or body (/) is separated from the testis ; and it again adheres by its pos-
terior extremity, called the tail, or globus minor (g) ; which, after being prolonged as far
as the posterior extremity of the testis, turns upward, by being reflected upon itself, £md
gives origin to the vas deferens (<)• It is flattened from above downward, concave be-
low, and slightly flexuous ; its two extremities are covered by the tunica vaginalis only
above and on the outside, but its body is completely enclosed by that membrane, which
forms a fold for it hke the mesentery. (See Tunica Vaginalis.)
Structure. — When the tunica vaginalis, which gives the epididymis a smooth appear-
ance, is removed (as in^. 185), the latter resembles a cord, so twisted upon itself that
it would appear impossible at first sight to disentangle it. This cord is hollow, as may
be shown by injecting mercury or a coloured liquid into it through the vas deferens.
The canal or duct which forms the epididymis is not unfrequently found distended with
semen ; and then we may ascertain by simple inspection, as weU as by injecting it, that
it is of a determinate size, and that its parietes are thin and semi-transparent.
The epididymis is intimately connected with the body of the testicle by its head only ;
the other means of attachment between the two parts consisting exclusively of rather
dense cellular tissue, and a fold of the tunica vaginahs. The head of the epididymis is
united to the testicle by several ducts, the number of which varies from ten to thirty.
* [The seminiferous tubes are of the same diameter throughout. According to Lauth, they most commonly
terminate in loops, and by numerous anastomoses ; in one instance oniy did he observe a free closed extrem-
ity. In some animals, Miillcr found the seminal tubes ending in free extremities ; and the same mode of ter-
mination was frequently seen by Krause in the human testis. Like the uriniferous tubes, the tubuli seminif-
eri terminate, therefore, in two ways.]
t [Immediately before the tubuli pass into the corpus Highmori to form the rete, they become rather larger
xad straight, and are hence called the tubuli recti (d d,fig. 184) : the tubuli composing the rete are stated by
Lauth to vary from seven to thirteen ; ihey are tortuous, and, as supposed by Haller, anaston-ose.]
452 SPLANCHNOLOGY.
rhey form several groups, which emerge from the corpus Highmori, and immediately
Fig. 185. afterward become convoluted, so as to form the head or glohun major
of the epididymis. These vessels, which are called the vasa efferentia,
or coni vasculosi (d), are perfectly distinct at their exit from the
corpus Highmori ; but, after a short course in the globus major, they
unite into a single canal, the numerous convolutions of which consti
tute the vermiform body called the epididymis. It is possible, by
careful and minute dissection, to unravel this duct, the folds of
which, shaped like the figure 8, are united by very dense cellular tis-
sue. Monro, who even counted the number of its inflections, has
calculated its length to be about thirty-two feet.*
It is supplied with arteries, and some veins and numerous lymphatics
issue from it. Its nerves are derived from the testicular, and accom-
pany a small branch of the hypogastric artery, which has been named
the deferential artery by Sir Astley Cooper.
Not unfrequently a dense cord, having the same structure as the
vas deferens, is found proceeding from the epididymis ; this cord is
the vas aberrans. — {Holler.)
The supernumerary ducts of this nature, injected with mercury by
Haller, extended for a few inches into the cellular tissue of the sper-
matic cord.
The Vas Deferens.
The vas deferens {t, figs. 181, 184, 186), the excretory duct of the testicle, extends
from the epididymis to the ejaculatory duct {fig. 186), which may be regarded as a con-
tinuation of it. It conunences at the point where the caudal extremity of the epididymis
becomes separated from the testicle.
The following is a description of its very complicated course : in its first or testicular
portion it passes from behind forward and upward along the upper border of the testicle,
almost parallel with the epididymis, from the inner edge of which it is separated only
by the spermatic arteries and veins. In this first portion of its course the vas deferens
pretty closely resembles a braided cord, and is, moreover, folded a great number of
times, like the canal of the epididymis.
The seconA, funicular or ascending portion of the vas deferens, forms part of the sper-
matic cord, and passes directly upward towards the inguinal ring. There it is in rela-
tion with the spermatic artery and veins, which are placed in front of it, and from which
it is perfectly distinct, being surrounded by an independent sheath of filamentous cellular
tissue. It is convoluted, at its lower part, for the space of an inch or an inch and a half,
but is straight in the rest of its extent. The third or inguinal portion of the vas defer-
ens passes through the inguinal canal to enter into tlie abdomen. Like that canal, it is
directed obliquely upward, outward, and backward, and is from an inch and a half to two
inches and a half in length. The lower margins of the obliquus internus and transver-
salis seem to curve over it ; it crosses the epigastric artery at right angles, a little above
the bend formed by that artery, where it changes its direction from horizontal to verti-
cal; in this portion of its course, as- well as in the preceding, the vas deferens forms
part of the spermatic cord. The fourth or vesical portion. — Having arrived within the
abdomen, the vas deferens leaves the vessels and nerves, proceeds vertically dovraward
into the pelvis, passes along the side {fig. 181) and then the posterior surface {fig. 186)
of the bladder, in which position it is retained by the peritoneum, crosses very obliquely
the fibrous cord formed by the remains of the umbilical artery, and is then directed in-
ward and downward to the inferior fundus of the bladder. Having arrived opposite and
internally to the entrance of the ureter into the bladder, it is directed horizontally in-
ward and a little forward like the vesicula seminalis {s, figs. 181, 186), internally to
which it is situated, and gradually approaches nearer and nearer to its fellow of the op-
posite side, with which it seems to be joined. At the anterior extremity of the vesicula
seminalis it unites at an acute angle with the efferent duct {c,fig. 186) of the latter, the
union of the two forming the ejaculatory duct {d). In its vesical portion, for about two
inches above the vesiculae seminales, the vas deferens is considerably dilated, and, at
the same time, its parietes become thinner.
On the inner side of the vesicula seminalis the canal still continues dilated, and is
sometimes sacculated, and has a flexuous appearance. Each sacculus is formed by a
small ampulla, which opens into the cavity of the canal.
The vas deferens forms, therefore, in this situation, a sort of provisional reservoir, re-
sembling, in its internal aspect and structure, the vesiculae seminales.
The spermatic cord, or cord of the spermatic vessels, is formed by the spennatic arteryt
* [The average length of the vasa efferentia is stated by Lauth to be eight inches ; they diminish in size
as they approach the canal forming the epididymis, which they enter at intervals of about three and a quajter
nches from each other. The length of that canal is, according to the same author, about twenty-one feet.]
t [Also the deferential artery, and the cremasteric branch of the epigastric artery.]
THE TESTICLES. 453
and veins, the lymphatic vessels, the spermatic plexus of nerves, a branch of the genito-
crural nerve, and the vas deferens, all being surrounded by the cremaster muscle and
the common fibrous coat.
Structure. — The following are the principal points concerning the structure of the vas
deferens : It is harder than any other excretory duct, and it can be recognised by the
touch among the other constituent parts of the cord, both in the healthy and in the dis-
eased state, in which latter condition it may become considerably enlarged It is per-
fectly cylindrical. Its bore is so small that it is almost capillary, and will scarcely admit
Mejan's probe. Its parietes are thick, and contrast singularly with the fineness of its bore.
Several anatomists admit the existence of circular and longitudinal muscular fibres in
this duct. Leuwenhoek demonstrated longitudinal fibres, with circular fibres beneath
them. All that I have been able to discover in the human vas deferens, even by the aid
of the glass, are circular. In their appearance, and kind of cohesion, they present much
analogy to muscular fibres ; but it is in the larger animals only, in the horse, for exam-
ple, that their muscularity can be clearly ascertained, and that we find distinctly a very
thin longitudinal and superficial layer of fibres, with very thick and strong circular fibres
beneath. The internal surface of the vas deferens is white, rough, and alveolar ; its
roughness is due to small and very white fibrous fasciculi, some of which are directed
longitudinally, while others are circular, and which are either regularly or irregularly ar-
ranged.
The mucous membrane lining the vas deferens is so thin that it is difficult to demoQ-
strate it.
The Vesicula Seminales.
The vesiculae seminales are two membranous pouches, which serve as reservoirs for
the semen.*
They are sitimted {s,fig. 181) between the rectum and the bladder, on the outer side
of, and parallel to, the vasa deferentia. As they are di- p. jgg
rected obliquely inward and forward (s, fig. 186), their an-
terior extremities are closely approximated, being separa-
ted from each other merely by the width of the vasa defer-
entia, while their posterior extremities are very far asun-
der ; they thus form two sides of an isosceles triangle,
within the area of which the bladder (a) is in immediate
relation with the rectum. They are flattened and oblong,
and are expanded at their posterior extremities, which
sometimes project beyond the inferior fundus of the dis-
tended bladder, and always do so when that organ is con-
tracted. Their anterior extremities are narrowed, and
surrounded by the prostate, and their surface has a saccu-
lated appearance. They vary in size, which is not always
equal on the two sides ; and they are much larger in the
adult than in youth or old age. Their size also varies ac-
cording to whether they are empty or full. They are from two inches to two inches
and a half long, and abou^ six lines broad, and two or three lines thick.
Their relations with the bladder and the rectum are not direct ; for they are surround-
ed with a filamentous tissue, consisting of transverse fibres, which separates them from
the neighbouring parts, and appears to me to be analogous to the tissue of the dartos.
When divided in various directions, the vesiculae seminales exhibit a collection of
cells, communicating with each other, and filled with a yellowish brown, thick, viscid
fluid, very different in appearance from semen as ejaculated during life. The sacculi of
the external surface, and the cells and septa of the interior of the vesiculae, are formed
by the extremely complicated convolution of a sort of intestinal tube, or narrow oblong
sac, on which I have never been able to find any appendages, ramifications, or divertic-
ula. When unravelled (as at s), its length varies from six to eight inches ; its convo-
lutions are attached to each other by fibrous tissue, but they may always be separated,
either with or without maceration. I have seen an unfolded vesicle a foot in length ; in
other subjects I have seen two distinct pouches on each side, one of which was extreme-
ly small. Lastly, the internal surface of the seminal vesicles has the same rough and
alveolar appearance as that of the vasa deferentia.
* [The semen, considered anatomically, consists, according to Wagner, of liquor seminis, seminal granules,
and seminal animalcules ; the latter were discovered by Ham, and described by Leuwenhoek. In the human
subject, the seminal granules are round granulated bodies, about ^-^Vo'^ '" TbVu'^ °^ ^"^ '"'^^ '"^ diameter ;
the seminal animalcules, or spermatozoa, have an elliptical body, about ^.^^^th to > A ^ th of an inch in di-
ameter, and a long caudal filament : their total length is from ^J^th to j-^-^th of an inch : their organization
is yet unknown ; but in the spermatozoa of the bear, Valentin has lately observed evidences of a definite in-
ternal structure ; they perform very rapid movements, which continue some hours after evacuation or removal
from the body. They are not found before puberty, and then only in the vesicuIiE seminales, vas deferens,
and epididymis. The semen of the testis contains, besides the seminal granules, certain vesicles or cysts, in
which, as shown by Wagner, the future spermatozoa are developed. i
454 SPLANCHNOLOGY.
The structure of the parietes of the vesicles is also precisely the same as that of the
deferent vessels, excepting that the external coat is thinner ; in the larger animals this
coat is evidently muscular, and it appears to me to be so in the human subject also. I
have in vain attempted to find the glands described by Winslovsr in the substance of the
walls of the seminal vesicles.
Efferent Ducts of the Vesiculcs Seminales. — From the anterior extremity or neck of each
vesicle, which we have said is situated in the substance of the prostate, arises a very
delicate duct, the efferent duct (c) of the vesicula seminalis : this duct almost immediately
unites with the vas deferens, the walls of which are thin and very dilatable in this situa-
tion. By the junction of the two, which occurs at a very acute angle, the ejaculatory duct
(d) is formed ; this passes through the prostate (which is shown divided in the figure),
upward and forward, parallel to and in contact with its fellow of the opposite side, but
without communicating with it. The ejaculatory ducts have very thin parietes, but they
are tolerably wide, and very dilatable ; closely apphed to each other, they open separately
on the enlarged extremity of the verumontanum, one on the right, the other on the left
(Jg. 182).
The Penis.
The penis, the organ of copulation, is situated in front of the symphysis pubis. When
collapsed, it is flaccid, and forms a curve with the concavity looking downward ; but du-
ring erection, it is large and hard, and forms a curve with its concavity turned upward.
It is cylindrical when collapsed, but has a triangular prismatic form, with blunt edges,
when in the opposite condition. Two of these edges are lateral, and are formed by the
projection of the corpus cavemosum ; the other is anterior, and corresponds with the
canal of the urethra. Its posterior extremity is attached to the pubis ; its anterior ex-
tremity forms a conical enlargement, called the glans, on which is seen the orifice of the
urethra.
Structure. — The penis consists essentially of the corpus cavemosum and the canal of
the urethra, the expanded extremity of which forms the glans penis. Some proper mus-
cles are attached to it ; it receives large vessels and nerves, and it is covered by integu-
ment.
The Skin of the Penis and Prepuce. — The skin of the penis has several peculiarities :
thus, it is very thin, although not so thin as that of the scrotum and the eyehds. In this
respect it contrasts remarkably with the thick hairy skin which covers the- cushion of
adipose tissue situated over the symphysis ; it is generally of a browner colour than that
of the rest of the skin ; it has no hair bulbs visible to the naked eye ; it is extremely
movable, being capable of gliding forward upon the corpus cavemosum, of forming a
covering for tumours in the scrotvun, and also of folding upon itself when the penis is re-
duced to its smallest dimensions. This great mobility of the skin is owing to the loose-
ness of the sub-cutaneous cellular tissue, which is continuous with the dartos, and ap-
pears to me to be of the same nature ; like that structure, it never contains fat, but may
become infiltrated with serum.
The Prepuce. — The skin of the penis forms a non-adherent sheath for the glans, upon
Avhich it advances, and either projects beyond it or not, according as that part is flaccid
or distended. At the free border of this sheath the skin does not terminate abruptly, but
is reflected upon itself, assumes the characters of a mucous membrane, and passes back-
ward as far as the base of the glans, so as to hne the inner surface of the cutaneous layer.
Opposite the constriction or neck surrounding the glans, the mucous membrane or re-
flected skin again becomes reflected over the glans, to which it forms a closely adherent
covering, and at the margin of the orifice of the urethra becomes continuous with the
mucous membrane hning that canal. The non-adherent sheath which covers the glans
is called the prepuce.*
Sometimes the orifice of this sheath is so narrow as to prevent its being easily drawn
backward, especiedly during erection. This constitutes what is called phymosis.i Cir-
cumcision, an operation which consists in removing an annular portion of the prepuce,
was, as we know, a general custom among the Jews, and is now recognised among the
operations of surgery.
The length of the prepuce varies in difierent individuals ; in some it is very short, and
only covers one half of the posterior third of the glans.
The term franum praputii is applied to a triangular fold of mucous membrane, which
is reflected from the prepuce upon the furrow on the lower surface of the glans, below
the urethral orifice. Sometimes the prolongation of the fraenum as far as the orifice
renders erection painful, and requires a slight operation, called section of the fraenum.
The cellular tissue, between the cutaneous and mucous layers of the prepuce, par-
takes of the characters of the sub-cutaneous cellular tissue of the penis ; its looseness
* [Beneath the mncous membrane covering the constriction behind the corona glandis are situated clusters
of small sebaceous glands, named glandule Tysoni, or odorifera.']
t When this malformation exists, if the prepuce he drawn back over the base of the glans, it cannot be re
turned ; this comlition of the parts, and the sort of strangulation resulting from it, constitutes what is known
by the name of para-phymosis.
THE PENIS. 456
enables the prepuce to be unfolded, and this takes place more or less completely during
erection.
The Corpus Cavemosum. — The corpus cavemosmn, so named on account of its struc-
ture, forms the greater portion of the penis ; it commences behind by a bifurcated ex-
tremity, forming its roots, or crura. Each root arises immediately on the inside, and
above the tuberosity of the ischium, by a very slender extremity, and gradually increas-
ing in size, passes forward and inward along the ascending ramus of the ischium and
the descending ramus of the pubes, to both of which it adheres intimately. At the sjrm-
physis the two roots unite. The triangular interval between them is occupied by the
canal of the urethra.
The corpus cavemosum results, therefore, from the union of two distinct conical
roots ; and on this account the older anatomists distinguished two corpora cavernosa ; but
the communications existing between its two halves are opposed to any such distinction.
The corpus cavemosum is cylindrical, and presents a longitudinal groove above, in
which are lodged the dorsal vessels and nerves of the penis, and a broad and deep groove
below, in which the urethra is situated. The anterior extremity is obtuse, and is em-
braced by the base of the glans, with which it does not appear to have any vascular
communication.
Structure. — The corpus cavemosum is composed of a very strong fibrous cylinder,
filled with a spongy or erectile tissue.
The Fibrous Cylinder. — The external coat is of a fibrous nature, and is remarkable for
its thickness, which is one or two lines ; for its strength, which is such that the corpus
cavemosum will bear the whole weight of the body without breaking, as may be proved
experimentally upon the dead body ; and for its extensibility and elasticity, properties which
do not belong intrinsically to the tissue itself, but depend upon the areolar disposition of
its fibres.*
Septum of the Corpus Cavemosum. — The interior of the cavernous body is divided into
two lateral halves by an incomplete septum, formed of very strong vertical fibrous col-
umns, which are much thicker and more numerous behind than in front. This median
septum (septum pectiniforme, h, fig. 187), between the two halves of the corpus caver-
nosum, is not complete ; it appears to be intended to prevent too great a distension of
this part during erection. -
The Spongy or Erectile Tissue. — An areolar tissue (a a), the meshes of which contain
a greater or less quantity of blood, occupies the interior of the fibrous cylinder of the
corpus cavemosum. This tissue, which is the chief agent in erection, consists of an
interlacement of veins, supported by prolongations or trabecule, given off from the inner
surface of the fibrous membrane.
If air or any fluid be injected into the crura of the corpus cavemosum, the penis will
acquire the same size as it has during erection, and the injection will pass readily into
the veins ; we may therefore conclude that all the cells of the corpus cavemosum com-
municate with each other, and, farther, that they communicate freely with the veins
If the corpus cavemosum be distended with tallow, and then, after being allowed to dry,
if the injection be dissolved out by hot oil of turpentine, we shall find that the cavernous
body presents a spongy stmcture, analogous to that of the spleen. The several grada-
tions from tme veins to spongy tissue may be traced in the venous plexus, situated at
the root of the penis. At first we find veins communicating with each other laterally, as
it were, by perforations ; then the communications become more and more numerous ;
and, lastly, in the corpus cavemosum all traces of distinct vessels are lost, and nothing
can be detected but a mass of cells, apparently resulting from the anastomoses of veins.
The structure of the spongy tissue of the corpus cavemosum is, therefore, essentially
venous.
A transverse section of the corpus cavemosum (^. 187), after it has been prepared
in the manner above indicated, exhibits an appearance of cells,
somewhat resembling that seen on a section of the body of a ver-
tebra ; these cells are bounded by laminae, which appear to be
chiefly derived from the lower wall of the corpus cavemosum, on
the inner surface of which is found a convexity, corresponding
with the groove for the urethra {d). These laminae radiate, as
from a centre, to the entire internal surface of the cyhnder, repre-
sented by the corpus cavemosum.
Vessels. — The veins of the corpus cavemosum are extremely
large, and are divided into the dorsal veins of the penis and the o'/
proper veins of the cavemous body ; they all pass beneath the
symphysis, and are received into fibrous canals, through which
they are transmitted into the pelvis. These veins are provided with a great number of
valves, so that injections thrown into the trunks cannot pass into the branches.
* [The outer coat of the corpus cavemosum and the trabecule, in its interior, consist of tendinous fibres,
mixed with some elastic tissue. In the penis of the horse there are pale red fibres, differiu? from cellular
tendinous, and elastic tissue, but which, according to Miiller, do not possess muscular contractility.]
456 SPLANCHNOLOGY.
The arteries arise from the internal pudic, and enter the substance of the corpus ca
vemosum. Injection of these arteries does not produce erection until the fluid has pass-
ed from them into the veins.*
The lymphatic vessels are little known.
No nerves have been traced into the interior of the corpus cavemosum.t
The Triangular Suspensory Ligament of the Penis. — This ligament is composed of yel-
low elastic tissue, and extends in the median hne from the symphysis pubis to the cor-
pus cavemosum. Muscular fibres have been described as existing in it ; but it is prob-
able some fibres prolonged from the bulbo-cavernosus, and now known as the muscle
of Houston, have been regarded as forming part of this ligament. I have seen the sus-
pensory ligament reach along the linea alba, half way up to the umbilicus.
Muscles of the Penis.
These are eight in number, four on each side, viz., the ischio-cavernosus, the bulbo-ca-
vernosus, the pubio-urethralis, and the ischio-bulbosus.
The Ischio-cavernosus, or the Erector Penis.
The ischio-cavernosus {c,Jig. 163) is an elongated muscle, situated upon the corre-
sponding root of the corpus cavemosum ; it is curved upon itself, and is aponeurotic in
part of its extent.
It arise* from the inner lip of the tuberosity of the ischium, below the transversus pe-
rinaei, by tendinous and fleshy fibres, and also from the surface of the root of the corpus
cavemosum. From these points its fibres pass inward, and are inserted, after a short
course, into the edges of the upper surface of a very strong, shining, and fasciculated
aponeurosis, having its fibres directed from behind forward, which covers the correspond-
ing root of the cavernous body, upon which it is then prolonged. The fleshy fibres, ter-
minating at the edges of the aponeurosis, form two bundles ; one internal, and extend-
ing upon the inner side of the root, the other extemal, which passes on the outer side
of the same, and is prolonged, much farther than the internal fasciculus, upon the cav-
ernous body. In order to see the structure of this muscle, it is necessary to make a
longitudinal incision into the aponeurosis, which entirely covers its lower surface ; we
then observe a muscular layer, which is tolerabjy thick behind, but thin in front, and is
formed partly by the original fibres, and pertly by others arising from the root of the
corpus cavemosum itself
Relations. — Below, with the cellular tissue and the dartos ; above, with the root of the
corpus cavemosum, upon which it is closely applied ; on the inside, with the bulbo-cav-
ernosus, being separated from it by a triangular space, the base of which is directed
backward.
Uses. — It acts solely upon the corpus cavemosum, drawing the root of the penis down-
ward and backward • instead of compressing the root of the corpus cavemosum by the
contraction of its fibres, it tends, on the contrary, to dilate its cavity, by separating the
wer from the upper wall, and, in this manner, facilitates erection.
The Bulbo-cavernosus, or Accelerator Urince.
This muscle {d,fig. 163) is much larger than the preceding ; it is situated in front of
the anus, extending along the lower surface of the bulb and the spongy portion of the
urethra, upon which it seems to be moulded.
It arises in front of the sphincter ani by a median fibrous raphe, which is common to
the two muscles of this name, and which appears to arise from the bulb, to which it ad
heres closely ; while the exteraed fibres arise from the posterior margin of the triangu-
lar ligament, or deep perineal fascia, and frequently from the rami of the ossa pubis, op-
posite that margin. From this double origin the fibres pass forward, and terminate in
the following manner : the outermost fibres form a thin layer upon the lower surface of
the triangular ligament, and are inserted by short, tendinous fibres to the inner side of the
root of the corpus cavemosum ; the middle fibres, which are larger, are directed oblique-
ly inward, and are inserted by very distinct tendinous fibres immediately in front of the
jtoint of junction of the roots of the corpus cavemosum, in the sort of groove between
that body and the urethra ; the innermost fibres are the longest ; they pass directly for-
* [Miiller has described, besides the nutritious arteries of the corpus cavemosum, which terminate, as usual,
ill the veins, a peculiar set of vessels, called the arterite helicina. They are short, curled branches, much
larger than capillaries, and ending abruptly in free rounded extremities ; they project either singly, or in tufts
arising ii-om one stem, into the venous cells,by the lining membrane of which they are supported and invested.
They are found principally in the posterior portions of the cavernous and spongy bodies, and are more marked
in man than in animals. In the horse they are very indistinct ; in the elephant they do not exist at all. Miil-
ler believes that the blood, during erection, is poured out directly from these vessels into the venous cells ;
but no openings through which the blood could escape have been detected, either in their sides o-- at their ex
tremities, nor is analogy in favour of their existence.
According to Valentin, the so-called helicine arteries are the divided branches of common arteries curled up
(after having been injected), in consequence of the retraction of the elastic trabeculie on which they are sup-
ported ; to this it is replied, by Miiller, that these vessels may be seen in cells deeper than the surface o; the
lection. Valentin farther maintains that the arteries terminate in the veins by wide, funnel-shaped orifices.]
t [Numerous nerves enter the corpus cavemosum; they arc derived from the internal pudic and sympatheV
ic nerves, and have been carefully traced by Mtiller.l
THE URETHRA. 45^
ward, and, at the point where the penis is bent in front of the pubis, are inflected out-
ward ie,fig. 163), pass upon the sides of the penis, and terminate on its dorsal surface,
becoming continuous with the suspensory ligament. Tlie last-named termination ap-
pears to me to constitute the muscle described by Houston, which, according to that
anatomist, is intended to compress the dorsal veins of the penis* in man and other ani-
mals ; but it is evident, on the one hand, that it cannot compress the veins of the penis ;
and, on the other, as M. Lenoir has pointed out, that the dorsal veins of the penis are
cutaneous veins, which do not communicate with those of the corpus cavemosum.t
Relations. — I3elow, the bulbo-cavernosus corresponds with the dartos, from which it is
separated by the superficial perineal fascia by a very thin layer of fat, and by a proper
fibrous sheath. Above, it is in relation with the bulb of the urethra, which it embraces,
like a contractile sheath, resembling the sheath around the stems of grasses. The inner
border is continuous with the muscle of the opposite side ; so that, at first sight, it might
be thought that there is but one bulbo-cavernosus.
Uses. — Its attachment to the inner side of the corpus cavemosum enables it to separ-
ate the lower wall of that body from the upper, and, consequently, to induce the entrance
of the blood. It therefore contributes powerfully to erection. On the other hand, by
compressing the urethra, it accelerates the expulsion of the urine and semen.
The Puhio-urethralis.
This muscle, known also as the muscle of Wilson, because it was described by that anat-
omist, may be regawied as the continuation of the levator ani. The two nmscles arise
from the middle of the sub-pubic arch, and descend first upon the sides and then on the
lower surface of the membranous portion of the urethra, which they surround as in a
ring. They are situated behind the triangular ligament, or deep perineal fascia.t When
spasmodically contracted, it is said that they may arrest the point of a catheter.
The Ischio-bulbosus.
We may describe under this name a small muscle situated below the deep perineal
fascia. It is stronger than the transversus perinaei ; it arises from the ascending ramus
of the ischium and the descending ramus of the pubis, and terminates on the sides of the
bulb. This muscle, which is of a triangular shape, is separated from the one last de-
scribed by the deep perineal" fascia, so that it cannot be regarded as a dependance of the
levator ani.<J
The Urethra.
The urethra is the excretory passage for the urine, and in the male it serves the same
purpose in regard to the semen.
Its direction has been particularly studied. Commencing at the neck of the bladder,
it passes forward and downward ; having arrived beneath the s3Tnphysis pubis, it de-
scribes a slight curve, with the concavity directed upward, embraces the symphysis, ri-
ses a little in front of it, and then enters the groove on the lower surface of the corpus
cavemosum. Beyond this point its direction is determined by that of the penis ; and it
* [The compressores venae dorsalis penis, according to Houston (Dublin Hasp. Reports, vol. v.), arise from
the rami of the pubes above the erectores penis and the crura of the corpus cavemosum, expand into a thin
layer, pass upward, inward, and forward, and unite in a common tendinous band over the dorsal vein. They
ftre separated by the crura from the erectores penis, of which muscles, he says, they might otherwise be re-
garded as portions : the anterior layer of the triangular ligament and the pudic artery are interposed between
them and the muscles of Wilson.]
t Dissertation sur quelques Points d'Anatomie, de Physiologic, et de Pathologic, No. cccxv., 1833.
[The dorsal veins return the greater part of the blood from the glans penis and corpus spongiosum, as well
as the skin, and are also joined by branches from the corpus cavemosum. (See M. Cruveilhier's own descrip-
tion of these veins, Anoeiologt).]
t [In the description of the muscles given by Wilson himself (Med. Chir. Trans., vol. i., p. 176, 177), it is
■tated, that " the line of tendon connecting the two bellies of these muscles is, in general, very distinctly seen
running from the apex of the prostate gland, along the under surface of the membranous portion of the ure-
thra, until it enters the corpus spongiosum penis." From this it would appear that the muscles discovered by
him are placed between the two layers of the ligament, not behind its posterior layer.
On the same plane with Wilson's muscles, i. e., between the layers of the ligament, are situated two small
transverse muscles, which arise, one on each side, by broad thin tendons, from the rami of the ischia, near
their junction with those of the ossa pubis, immediately above the crura penis and their erector muscles ; from
thence the fleshy fibres pass transversely inward and upward, and are inserted along the median line of the
upper and under surface of the membranous portion of the urethra by means of two tendinous structures,
which extend, one above the urethra, from the fascia covering the prostate to the union of the crura penis in
frjnt; of the triangular ligament, and the other below that canal, from the fascia on the prostate to the central
poirt, of the perineum : to this tendinous structure the vertical muscles of Wilson are also attached. The pu
die a'.teries run either above or below these transverse muscles, the lower fibres of which pass below Cow-
per's glands, i. e., more superficially, when viewed from the perineum.
These transverse muscles are described and figured by Santorini (Observ. Anat., c x., I) viii., t. 3, fig. 5,
also, Septemdecim Tabula, t. 16, fig. 1), who states, however, that Ihey are attached only to the lower surface
of tlie urethra, behind the bulb ; he named them elevatores urethrue, or ejaculatores. It has been recently
shown by Mr. Guthrie (Land. Med. and Surg. Journ., 1833, p. 491, 492 ; also, On the Anatomy and Diseases
of the Neck of the Bladder and of the Urethra, 1834, p. 34, &c.) that the transverse muscles of Santorini
are inserted, as already described, both above and below the urethra ; and that the vertical muscles of Wilson
are blended with them at their insertions : he therefore proposes to regard them as one muscle, which has
been termed the compressor urethra:.']
^ [The description of this muscle corresponds exactly with that of the transversus perinmi alter of Albinus.l
M M M
458 SPLANCHNOLOGY.
describes, with that organ, a second curve, much more marked than the preceding, hav-
ing its concavity directed downward, but only in the state of relaxation, for the curve no
longer exists when the penis becomes elongated, either from erection, or from direct
traction.
It follows, therefore, that, except during erection, the urethra describes two curves,
like the letter S ;* but when the penis is elongated, it forms only a single curve, which
is permanent.
Although the curvature of the urethra is not so rigid as to prevent the introduction of
a straight instrument into the bladder, it would be wrong to conclude that the canal it-
self is straight. It must be remembered that organic membranous ducts are sufficiently
pUable to accommodate themselves to the direction of instruments introduced into them ;
but the effacing, or the artificial removal of the curves, is very different from their non-
existence. Moreover, the curvature of the urethra is demonstrated by the impossibility
of drawing a straight line from the neck of the bladder, and passing a short distance be-
low the symphysis to the point where the urethra joins the corpus cavernosum ; also by
the curve acquired by bougies after remaining for some time in the urethra ; and, lastly,
by the curvature presented by a mould obtained by injecting the bladder and urethra
with any substance capable of becoming solid.
Dimensions. — The length of the urethra is from eight to nine inches ; it is sometimes
less than eight. The extreme dimensions noticed by Whately,t in measurements taken
from forty-eight subjects, are nine inches six lines and seven inches six lines. It is dif-
ficult to estimate the width of the urethra. According to Home, it is four lines, except
at the orifice, where it is only three. It is quite impossible to judge of its width exter-
nally, on account of the thickness of its walls, and especially on account of their being
unequal. The extreme dilatability of the canal allows the introduction of instnmients
of considerable caliber, as in the operation of lithotrity.
The urethra is considered as divided into three portions, as different in their structure
as in their relations ; these are the prostatic, the membranous, and the spongy portions.
The Prostatic Portion. — This part of the urethra, which forms, as it were, a continua-
tion of the bladder, and the commencement of the urethra, is called prostatic, because it
appears to be hollowed out of the glandular body called the prostate, the description of
which must be inserted here, on account of its intimate connexion with the urethra.
The prostate {i,fig. 181), a whitish glandular body, is situated in front of the neck of
the bladder, and embraces it ; it is behind the symphysis pubis, and in front of the rec-
tum. It is shaped like a cone, with its base turned backward, and its truncated apex
forward. Its axis or long diameter is horizontal, but slopes a little from behind down-
ward and forward. It has often a bi-lobed appearance in man, but it is never truly
double, as in a great number of animals.
The size of the prostate varies greatly in different subjects. The following dimen-
sions have been taken from the measurements of the prostates of adults : Vertical di-
ameter, twelve lines ; transverse, eighteen ; antero-posterior, or length, fifteen. Some-
times it acquires three or four times its nominal size ; the increase may affect either the
whole gland or one half, or the middle lobe only.
Relatione. — We shall examine the relations of the prostate with the parts correspond-
ing to its outer surface, and with those which are situated within it.
Relations of the Outer Surface of the Prostate. — The lower surface corresponds with the
rectum, adhering to it by tolerably dense celluleir tissue, in which there is never any fat
or serum ; and hence"^he rule of examining the prostate by the rectum. In consequence
of alterations in the condition of the rectum, that intestine sometimes projects on each
side beyond the prostate, as during distension ; and sometimes, as when it is contract-
ed, the prostate projects beyond it laterally. The lower surface of the gland is smooth,
and is traversed in the median line by an antero-posterior furrow, which is well marked
in some subjects, and divides it into two equal portions.
The upper surface is in relation with the recto-vesical fascia {q,fig- 1^1)> <""' rather,
with some very strong ligamentous bundles, which extend from the pubes to the blad-
der, and are called the ligaments of the bladder. This surface has no immediate rela-
tions with the arch of the pubes, behind which it is placed ; it is always some lines dis-
tant from it. Nevertheless, by means of a silver catheter or sound, introduced into the
bladder, we may draw the prostate under the pubes, and make it project in the perineum.
The sides are embraced by the levator ani and the levator prostatae. When the prostate
is pushed downward by the catheter, its sides are embraced by the circumference of
the arch of the pubes, and they then approach very near the trunk of the internal pudic
artery.
The base of the prostate embraces the neck of the bladder, and is prolonged a little
upon that organ, so as to surround the vas deferens and the neck of the vesiculffi semi-
nales.
* It was this direction of the canal which suggested to J. L. Petit the idea of making silver bougies, shaped
like the letter S, to remain in the passage.
t An Improved Method of treating Stricture of the Urethra, 1816.
THE URETHRA. 43^
The apex terminates behind the membranous portion of the urethra.
Relations of the Prostate vsith the Parts situated in its Interior. — The prostate is perfo-
rated by the urethra, by the ejaculatory ducts, and by its own excretory ducts.
The relations of the urethra with the prostate vary in different subjects : thus, sometimes
its lower three fourths only are surrounded by the gland, which is accordingly wanting
above, and is merely grooved, not perforated by a canal ; sometimes the prostate forms
a complete hollow cylinder around the urethra. The portion of the prostate situated
above the urethra is scarcely ever thicker than the part beneath it. In some cases,
however, the urethra has been found occupying the lower part of the prostate, and only
separated from the rectum by a very thin layer of glandular substance. When such is
the case, the rectum is very liable to be wounded in the different steps of the operation
of lithotomy.*
In the natural state the prostate does not project into the urethra ; but not unfrequent-
ly we find a prominence, of greater or less size, rising from the lower part of the urethra,
opposite the base of the prostate, and obstructing more or less completely the com-
mencement of that canal : this tubercle was named by Lieutaud la luette visicale {uvula
vesica) ; by Sir Everard Home, an enlargement of the middle lobe of the prostate. But,
in the first place, this prominence only exists in disease ; and, secondly, there is no
middle lobe, unless that term be applied to the slightly-grooved, and, therefore, thinner
portion by which the two lateral halves of the prostate are united.
Relations of the Ejaculatory Ducts with the Prostate. — The ejaculatory ducts (d,fig.
186), which lie close to each other, are received into a sort of conical canal, formed in
the prostate. Some loose cellular tissue separates them from the substance of the gland,
of which they are altogether independent ; it was chiefly to the portion of the prostate
which is situated above this canal that the name middle lobe was given by Home.
Density. — The density of the prostate is considerable, and yet the tissue of this gland
is friable, and can be very easily torn after having been once divided. It is of the greatest
importance to remember this friability in performing the operation of lithotomy. The
prostate, in fact, is the only obstacle to the extraction of the calculus ; and when this
gland has been divided in its antero-posterior diameter, the bladder itself may be torn
with the greatest facility.
Structure. — The structure of the prostate can only be properly studied in the adult.
In certain cases of hypertrophy without alteration of tissue, its characters are, as it
were, exaggerated. It consists of a collection of glandular lobules, which may be subdi-
vided into granules pressed close to each other in the midst of a tissue that appears to
me to be muscular, for it is continuous with the muscular coat of the bladder, and bears
the most perfect resemblance to it in cases of hypertrophy. From these granules, which
are generally of unequal size, small excretory ducts proceed, and unite into an irregular
number of prostatic ducts that open, not upon the verumontanwn itself, but upon its sides
{see fig. 182), in the whole extent of the lower wall of the prostatic portion of the ure-
thra, or prostatic sinus. I have assured myself of the existence of these ducts and their
orifices in many cases where I have found them filled with innumerable small calculi,
resembling grains of brownish sand. The orifices of the prostatic ducts may be easily
detected by pressing the gland, when the fluid secreted by it will be observed to exude
at several points.
The Membranous Portion. — The membranous portion of the urethra (c,fig. 181) ex-
tends from the prostatic portion to the bulb, and passes upward and forward.! It is in
relation above and laterally with the arch of the pubes, from which it is separated by
some considerable veins, or, rather, by a sort of erectile tissue ; below it corresponds
with the rectum, but is separated from it by a triangular space, having its base directed
forward and downward, and its apex backward and upward. It is generally in this tri-
angular space that the urethra is divided in the operation of lithotomy.
Its upper concave surface is about an inch long ; its lower surface is from four to six
lines. This difference in length is caused by the bulb projecting backward upon the
lower surface of the membranous portion of the urethra.
This part of the canal is embraced laterally and below by the two muscular bundles
which have been already described as the muscles of Wilson ; and also by the transverse
muscular fasciculi described by Santorini and Guthrie.
The Spongy Portion. — The spongy portion {I) constitutes the greatest part of the length
of the urethra ; it commences opposite the symphysis pubis by a very considerable ex-
pansion, called the bulb (below I), and terminates at the extremity of the penis by an-
other and still larger expansion, which constitutes the glans penis.
* The varieties in the situation of the urethra, in relation to the prostate, were yreU pointed out by M.
Senn, in an inaugural dissertation in 1825. According to his observations, the portion of the prostate situ-
ated below the canal is seven or eight lines thick in the middle, and ten or eleveu lines when measured down-
ward and outward.
t [The membranous portion perforates both layers of the triangular ligament, about an inch below the arch
of the pubes {see Jig. 138) ; but as the two layers are separated from each other below, the greater part of
this portion of the urethra is included between them ; a very small part is situated behind the posterior laver
both layers are prolonged over the urethra, one forward and tlie other backward.]
400 ' SPLANCHNOLOGY.
The hdb occupies the highest part of the pilbic arch, and fills the interval between the
crura of the corpus cavemosum. Its size varies in different individuals, and according
to the state of the penis ; it projects several lines below the level of the membranous
portion, which is partially covered by it in this direction, and seems to open into its up-
per part.
As the bulb is directed very obliquely upward and forward, we might be inclined to
consider the urethra to be much more curved than it actually is, if we judged of it only
by the external appearance of the canal.
The bulb is embraced below and upon the sides by the bulbo-cavernosi muscles, which
have numerous points of insertion upon it. Between these muscles and the bulb we
find Cowper's glands. The bulb terminates insensibly in front, becoming continuous
with the spongy portion : the angle of union of the crura of the corpus cavernosum may
be assigned as its anterior boundary.
The Glands of Cowper. — These are two small, rounded bodies (g g,figs. 168, 181, 182)
(so called after the anatomist who has given the best description of them), situated
against the bulb, in contact with which they are retained by a tolerably dense layer of
fibrous tissue.* From each of these glands, which are of variable dimensions, an excre-
tory duct proceeds, and after a course of an inch and a half or two inches, opens into
the canal of the urethra upon the sides of the spongy portion (c, fig. 182), passing ob-
liquely through its parietes.t
In front of the bulb, the spongy portion of the urethra enters the groove on the lower
surface of the corpus cavernosum, and is in relation below, in the first part of its course,
with the bulbo-cavernosi muscles, which separate it from the cellular tissue of the scro-
tum, and more anteriorly with the skin of the penis.
The glans, so called from its shape, is the conical enlargement which forms the ex-
tremity of the penis. It is covered by the prepuce, which is united to it below by means
of the fraenum ; its base projects considerably beyond the end of the corpus cavernosum,
and forms what is called the corona glandis. This circular projection is grooved perpen-
dicularly throughout its entire extent by some large nervous papillae, which are visible
to the naked eye. The base of the glans is cut very obliquely, so that its upper surface
is twice as long as its lower. Below, and in the median line, the corona glandis pre-
sents a groove, in which the fraenum is received.
At the extremity of the glans is situated the orifice of the urethra, meatus urinarius,
a vertical fissure, three or four lines in extent, and placed in the same line as the frae-
num, from which it is separated by a very short interval. Sometimes this orifice is
placed exactly opposite the fraenum, and, like it, is directed downward : this malforma-
tion constitutes what is called hypospadias.
Internal Surface of the Urethra. — Upon this surface (see fig. 182) we find no trace of
the distinction established between the different portions of the urethra, considered from
without, except that the prostatic portion of the canal is of a white colour, while all the
rest of it is of a more or less deep violet hue.
Dimensions. — Opposite the prostate the urethra becomes dilated, sometimes to a con-
siderable extent (sinus prostaticus) ; at the commencement of the membranous portion
it suddenly contracts, and then continues cylindrical as far as the glans, where it again
dilates so as to form the fossa navicularis (o), and terminates by an orifice, which is the
narrowest part of the entire canal.J
In order to obtain more exact ideas of the comparative dimensions of the different
portions of the urethra, M. Amussat inflated this canal, and then carefully removed all
the structures superadded to its proper parietes, so as to reduce the latter to the mu-
cous membrane only, and thus leave them of almost unifonn thickness, instead of being
very unequal. According to this mode of appreciation, which, however, is not free from
objection, he has shown that the narrowest part of the canal is the bulbous, not the
membranous portion ; that the canal, after being contracted opposite the bulb, again ex-
pands at the spongy portion, and then gradually contracts as it proceeds forward. He
denies the existence of a dilatation opposite the fossa navicularis ; and attributes the
dilated appearance of that part to the fact of the tissue of the glans being very dense,
and closely adherent to the mucous membrane of the urethra, so as not to allow it to
collapse, like that of the other parts of the canal.
However, the extreme dilatability of the walls of the urethra render an exact deter-
mination of its dimensions less important than might be imagined.
Besides the extensibility of the tissues, there is another anatomical condition which
favours the extreme dilatabihty of the urethra, viz., the existence of longitudinal folds
on the inner surface of the canal, which are effaced by distension. These folds must
* [They are placed between the two layers of the triangular ligament : the transverse musrles of Santorini
cover them below, am Jhe arteries of the bulb (e e,Jig. 168) cross above them : they are compound glands.]
t I have never seen the gland called, by Litre, the anti-prostatic ; nor have I seen the third gland of Cow-
per, which is said to be situated below the arch of the pubes.
i [Three dilatations in the urethra are usually described, viz., the prostatic sinus, the sinus of the bulb, and
the fossa navicularis. The first and the third of these are described above ; the second is at the commenco
ment of the soongy portion, in the inferior wall of the urethra.!
THE OVARIES. 461
not be confounded with certain small longitudinal fasciculi which lie beneath the mu-
cous membrane throughout the whole extent of the canal, and appear to me to be of a
muscular nature. The whole of the inner surface of the urethra presents a nmnber of
oblique orifices, which lead into culs-de-sac of variable depths. These sinuses, the ori-
fices of which are always directed forward, are sometimes large enough to receive the
extremities of bougies ; they were very well described by Morgagni, and, therefore, they
are generally called the sinuses of Morgagni. I have seen them more than an inch long.
No glands open into them.*
The Verumontanum, or Crest of the Urethra. — The lower wall of the membranous por-
tion of the urethra presents, in the median line, a crest, which has been named the ve-
rumontanum, caput gallinaginis, or urethral crest {a to d). This crest commences in front
by a very delicate extremity ; is directed backward along the median line, and termi-
nates at the anterior part of the prostatic portion by an enlarged extremity (a), upon
which the ejaculatory ducts open by two distinct orifices. From this posterior extrem
ity several radiated folds proceed on either side, called the frcena of the verumontanum,
which are lost in the opening of the neck of the bladder ; they were carefully described
by Langenbeck. The prostatic ducts open at the sides of the verumontanum.
Structure of the Urethra. — ^A very fine transparent mucous membrane, of an epidermic
character, lines the inner surface of the urethra ; and is continuous, on the one hand,
with the mucous membrane of the bladder, and, on the other, with that covering the
glans. It is also continued through the ejaculatory ducts, into the vasa deferentia and
the vesiculae seminales.f
The structure of the urethra, as regards the coats external to the mucous membrane,
is not the same in the different portions of the canal.
In the prostatic portion, we find the same elements as in the bladder, which seems as
if it were continued into the cavity of the prostate. The deepest layer of the muscular
coat of the bladder is prolonged between the mucous membrane and the prostate, while
the other layers form different planes which penetrate into the substance of the gland.
The membranous portion would be more correctly denominated the muscular part of
the canal, for it is surrounded by a layer of muscular fibres. A plexus of veins sur-
rounds these muscular fibres.
The spongy portion Q f,fig. 182; c,fig. 187) has a similar appearance to that of the
cavernous body ; it is an erectile structure, composed of a fibrous framework, formed by
numerous prolongations interlaced in all directions, so as to resemble areolar tissue. It
is probable that the internal coat of the veins lines all the cells, which contain more or
less blood, according to the state of the penis.
In the tissue of the corpus spongiosum, as well as in that of the corpus cavernosum,
are found longitudinal muscular fibres, very evident to the naked eye in the larger ani-
mals, and the existence of which appears to be shown by the microscope in the human
subject. The structure of the glans (//) is exactly the same as that of the bulb, only
its tissue is more dense. The corpus spongiosum urethrae does not communicate with
the corpus cavernosum, although at first sight it appears to be nothing more than a con-
tinuation of it. The blunt extremity of the corpus cavernosum is evidently embraced
by the base of the glans, but no communication exists between the erectile tissue com-
posing these two bodies, so that it is possible to inject them separately.
THE GENERATIVE ORGANS OF THE FEMALE.
The Ovaries. — The Fallopian Tubes. — The Uterus. — The Vagina. — The Urethra. — The
Vulva.
The genital organs of the female consist of the ovaries, the Fallopian tubes, the uterus,
the vagina, and the several parts forming the vulva. With these we may include the
mammae, as appendages to the generative apparatus.
The Ovaries.
The ovaries {ovaria), so called on account of the small vesicular ova which they con-
tain, are the representatives of the testicles in the male ; the product secreted by both
the one and the other is absolutely indispensable for reproduction. From this analogy
between the ovaries and testes the ancients called them testes muliebres (Galen).
The ovaries (a a, fig. 188) are two in number, and are situated one on each side of the
uterus, in that portion of the broad ligament {d d') termed the posterior ala (J), and be-
hind the Fallopion tube. They are retained in this position by the broad ligament, and
by a proper ligament called the ligament of the ovary (c).
* [One of these sinuses or lacunae, larger than the rest, and situated on the upper surface of the fossa na-
vicularis, is called the lacuna magna ; they appear to be mucous crypts.]
t [It is prolonged into the ducts of Cowper's glands and the prostate, into the vesiculiE seminales, vasa def-
erentia, and tubuh seminiferi, and through the ureters into the uriniferous ducts ; in the female it also linei
the vagina, uterus, and Fallopian tubes ; the whole forms the genito-urinary system of mucous membranes ; it
is covered throughout with an epithelium, which, in the male generative apparatus, approaches the columnar
form.]
462 SPLANCHNOLOGV.
Then situation varies at different ages, and also according to the state of the uterus.
In the foetus, they are placed in the lumbar regions, like the testicles. During pregnan-
cy they are carried up into the abdomen with the uterus, upon the sides of which they
are applied. Immediately after delivery, they occupy the iliac fossae, where they some-
times remain during the whole period of life, being retained there by accidental adhe-
sions. It is extremely common to find them thrown backward,* and adhering to the pos-
terior surface of the uterus.
The ovary has sometimes been found in inguinal or femoral hernise : by descending
into the labia majora, they have simulated the appearance of testicles.
The size of the ovaries varies according to age, and according as the uterus is gravid
or unimpregnated, healthy or diseased. They are relatively larger in the foetus than in
the adult ; they diminish in size after birth, again increase at the period of puberty, and
become atrophied in old age. During the latter periods of pregnancy, they sometimes
acquire double or triple their ordinary size.
The ovaries are of an oval shape, a little flattened from before backward ; they are of
a whitish colour ; their surface is rough, and, as it were, cracked, and is often covered
with very dark-coloured cicatrices, which have been incorrectly regarded as remains of
ruptures in their external coat, to allow of the escape of the fecundated ovum.
The ovary is free in front, behind, and above, but is attached by its lower border to the
broad hgament, by its outer end to the trumpet-shaped extremity of the Fallopian tube,
and by its inner end to the corresponding side of the uterus, some lines below the upper
angle of that organ, by means of a ligamentous cord, called the ligament of the ovary (c) ;
which was for a long time regarded as a canal {ductus ejaculans), intended to convey an
ovarian fluid into the uterus. The tissue of this ligament strongly resembles that of the
uterus, and seems to be a prolongation from it. I
Structure. — The ovary is composed externally of a dense fibrous coat, covered by the
peritoneum, which adheres so closely to it that it cannot be detached ; and, internally,
of a spongy and vascular tissue, the areolae of which seem to be formed by very dehcate
prolongations from the external coat ; in the midst of this tissue (the stroma, from arpufia,
a bed) the Graafian vesicles are deposited. These vesicles vary in number, from three or
four to fifty. The structure of the ovary is most evident in the recently-delivered fe-
male. At that time its tissue, expanded, and, as it were, spongy, appears to me to re-
semble that of the dartos, and is traversed by a great number of vessels. I have also
seen, in recently-delivered females, the ovaries from twelve to fifteen times larger than
usual, and converted into a sac, having very thin parietes, which were easily torn ; the
ovary itself was of a spongy, vascular, and diffluent texture, in the midst of which the
vesicles were seen unaltered.
The vesicles are nothing more than small cysts of variable size, with very thin trans-
parent walls, adhering to the tissue of the ovary, and containing a hmpid serosity, either
colourless, or of a citron yellow. According to Von Baer, the most superficial vesicles
which approach the expanded extremity of the Fallopian tube, contain a floating body,
which was imperfectly seen by Malpighi, and constitutes the germ or ovum. J
I have often metvdth ovaries destitute of vesicles ; but then they had undergone some
change, that of induration, for excunple. May the absence of these vesicles be regarded
as a cause of sterility 1
The corpora lutea, according to the observations of Haller, consist of the remains of
vesicles that have been ruptured in consequence of the act of impregnation ; they are
brownish-yellow masses, of a tolerably firm consistence, and which I have found as large
as a cherry-stone in females recently delivered. These bodies have been ascertained to
exist in females who have never borne children, and this anomaly has been explained by
supposing that they may be produced in consequence of masturbation. We would re-
mark, however, that there is no constant relation between the existence of these bodies
and the occurrence of fecundation. In some females who have had many children, no
corpora lutea can be detected, and, on the other hand, a corpus luteum has been found
in a girl of five years of age.
The bloodvessels and veins of the ovary correspond exactly with those of the testicles.
* The situation of the ovaries, behind the Fallopian tabes, prevents their displacement forward.
t It has even been stated that this so-called efferent duct of the ovary divides into two branches, one of
which opens directly into the uterus, while the other runs along its border, and opens near the os uteri.
t [The vesicles of De Graaf vary from the size of a pea to that of a pin's head ; they have two tunics, ono
external and vascular, the other called the ovi-capsule, which, according to Schwann, is lined internally with
epithelium (membrana granulosa, Bair). In each vesicle there is usually but one ovum, which at first occu-
pies its centre, but in the mature condition approaches the inner surface of its internal coat, and, sunounded
by a granular covering (tunica granulosa, Barry), is held there by retinacula (Barry). The ovum is a perfect-
ly spherical body, of uniform size (about y^th of an inch in diameter) ; it consists of a thick but very trans-
parent coat (zona pellucida, Valentiri ; chorion, Wagrier), which surrounds the sul)stance of the yolk ; within
the yolk is situated the germinal vesicle of Purkinj6 (about yg-jrth of an inch in diameter), and within that
the germinal spot of Wagner (about-g-^^th or g-rWth of an inch). The changes incidental to impregnation,
according to Dr. Barry, commence in tlie germinal spot and vesicle. For farther information, and for a list of
works upon this subject, see Milller''s Physiology, translated by Dr Baly, and Wagner's Physitlogy, trausla-
tpd by Dr. Willis.]
THE FALLOPIAN TUBES.
463
Uses. — Without precisely determining the part performed by the ovaries in reproduc-
tion, it may be said that they are indispensable to that function. Extirpation of these
bodies is followed by sterility. And, again, ovarian foetation proves that fecundation
may occur within the ovary. The use of the Graafian vesicles in generation is not well
known.*
The Fallopian Tubes.
The tula uterina {ff,fig- 188) are two ducts, situated in the substance of the upper
margin of the broad ... ,„
Ugament. They are t^-vsa.
also called the tubae
rallopianae,+ the Fal-
lopian tubes, after
Fallopius, who first
gave a good descrip-
tion of them ; they ex-
tend from the upper
angle of the uterus to
the sides of the cavity
of the true pelvis.
Situation and Di-
rection.— Floating, as
it were, in the cavity
of the pelvis, between
the ovaries behind, and the round ligaments (^ g) in front, they pass transversely out-
ward, and at the point where they terminate, bend backward and inward, in order to
approach the outer end of the ovary, to which they are attached by a small ligament.
Each Fallopian tube is straight in the inner half of its course, but describes certain wind-
ings in the remaining outer portion, which are so considerable in certain cases, and
especially when the tube has been the seat of chronic inilammation or of dropsy, as to
resemble in some degree the windings of the vas deferens. Moreover, accidental adhe-
sions of the expanded extremity very frequently give it an entirely different direction
from the one it usually takes. The tubes may be drawn down with the ovaries into a
hernial sac, as I have several times observed.
The length of the Fallopian tube is four or five inches, but it sometimes varies on the
two sides. The canal in their interior is very narrow along their inner half, but gradu-
ally enlarges as it proceeds outward to their termination, which is expanded and divided
into irregular fringes, like the calyces of certain flowers ; this expanded end constitutes
the mouth of the trumpet, or the fimbriated extremity (e) of the Fallopian tube. In order
to obtain a good view of this structure, it is necessary to place the tube in water, and
then a number of fringes or small shreds of unequal length will be seen floating in the
liquid, and consisting of folds divided unequally, and sometimes forming two or three
concentric circles. It is generally said that one of these fringes, longer than the rest, is
attached to the outer end of the ovary ; but this connexion appears to me to be effected
by means of a small ligament. All these folded fringes terminate around a circle some-
what narrower than the adjoining portion of the tube ; this circle constitutes the free
orifi.ce, or ostium abdominale of the tube.
The outer portion of the tube will admit the end of a moderate-sized catheter, while
the inner portion will scarcely admit a bristle. The diameter of that portion of the tube
which traverses the uterine walls is capillary, and it is very difficult to detect with the
naked eye its uterine orifice, or ostium uterinum (o o, fig. 189). As the canal of the tube
opens into the uterine cavity on the one hand, and into the cavity of the peritoneum on
the other, it forms a direct communication between the two ; and hence certain cases of
peritonitis have been supposed to depend upon the passage of a fluid from the uterus
into the peritoneal sac. Not very unfrequently the fimbriated orifice of the tube is ob-
literated ; in this case the tube becomes dilated like a cone, having its base directed out-
ward, and it also becomes much more flexuous.
When opened longitudinally, and placed under water, the outer or wide portion of the
tube presents longitudinal folds of unequal breadth, and touching by their free edges.
There is no valve, either in the course or at the orifices of the tube. Its narrow jior-
tion is hard to the touch, inextensible, and closely resembles in appearance the vas def-
erens ; its wide portion is collapsed, and its walls are thin and extensible.
Structure. — The peritonium adheres closely to it, and forms its outer coat ; it is lined
by a mucous membrane, which can be easily shown in the whole extent of the broad and
folded portion, and appears to form of itself the longitudinal folds already described.
This lining membrane is continuous, on the one hand, with the uterine mucous mem-
brane, and on the other, with the peritoneum, at the fimbriated extremity of the tube ;
it thus presents the only example in the human body of the direct continuity of a serous
* See note, p. 462. t [Literally, the Fallopian tnimpeU, from their expanded abdominal extremities.!
464 SPLANCHNOLOGY.
and mucous membrane. Between the peritoneal and the mucous coats is found a proper
membrane, which appears to be a prolongation of the tissue of the uterus, and is proba-
bly muscular.*
Uses. — The Fallopian tubes, which represent in the female the vasa deferentia in the
male, serve not only to transmit the fecundating principle of the male, but also to con-
duct the fecundated ovum into the uterus. These uses are proved by the sterility of
females in whom the tubes have been tied ; and by the occurrence of tubal fcEtations, in
which the fecundated ovum is arrested in the cavity of the tube, and thei'e passes
through the several stages of development.
The fimbriated extremity of the tube is intended to embrace the ovary during the act
of fecundation, and to apply itself to the spot from which the ovxun is to be detached ; it
follows, therefore, that any adhesion of the ovary or of the tube which prevents this,
acts as a cause of sterility.
The Uterus.
The uterus (uter, a leather-bottle), matrix (mater), or womb, is the organ of gestation.
It is situated {u,fig. 190) in the cavity of the pelvis, in the median line, between the
bladder and the rectum, and is retained in that position by the round and broad ligament
on each side, and by the upper end of the vagina below.
The looseness and extensibility of its connexions enable it to float, as it were, in the
cavity of the pelvis, and to be moved to a greater or less extent. The facility with
which it can be drawn towards the vulva in certain surgical operations, and its displace-
ment during pregnancy, when it rises into the abdomen, are proofs of its great mobility.
Direction. — Its long axis is directed obliquely downward and backward, i. e., it coin-
cides with the axis of the brim of the pelvis. Its direction is liable to frequent varia-
tions, the history of which belongs to midwifery ; but one of them, viz., the obliquity
downward, and from the right to the left side, is so frequent that it has been regarded
as natural, and, according to some anatomists, appears to be connected with the posi-
tion of the rectum on the left side of the pelvis. In pregnancy, this inclination is almost
constant, and has some relation with the most usual position of the child, viz., that in
which the occiput is turned towards the left acetabulum of the mother.
Number. — The uterus is single in the human species ; it is double in most animals.
The cases of double uterus observed in the human subject are nothing more than bifid
uteri, or such as are divided by a septum : this state may exist either in the body of the
uterus alone, or at the same time in the body and neck, and even in the vagina.
Size. — The size of the uterus varies according to age, and certain physiological con-
ditions peculiar to this organ. It is very small until puberty, and then acquires the size
which it subsequently presents. In females who have borne children it never returns
to its original size. It becomes enormously enlarged during pregnancy, or from the de-
velopment of certain tumours. In old age it becomes atrophied, and is sometimes as
small as it is in newborn infants. The following are the measurements of the uterus
after puberty : length, two and a half to three inches ; breadth, at the fundus, sixteen to
eighteen lines, at the neck six lines ; antero-posterior diameter, or thickness, six lines.t
Weight. — The weight of the uterus is from six to ten drachms at puberty, an ounce
and a half or two ounces in females who have had children. I have seen it from one to
two drachms in aged females, in whom it had become atrophied. At the end of preg-
nancy the weight of the uterus is from a pound and a half to three pounds.
Form. — The uterus is shaped like a small gourd, or a pear flattened from before back-
ward. It is divided into a body (m), and cervix or neck (A) ; the distinction between these
two parts being established by a more or less marked constriction.
Relations. — These must be studied in front, behind, on the sides, at the upper border
or fundus, and at the lower or vaginal extremity.
The anterior surface is covered by the peritoneum in its upper three fourths, and is in-
directly in relation with the posterior surface of the bladder, from which it is often sep-
arated by some convolutions of the small intestine ; in its lower fourth it is in imme-
diate contact with the inferior fundus of the bladder, and is united to it by rather loose
cellular tissue. The latter relation explains why cancerous affections of the uterus so
often extend to the base of the bladder.
The posterior surface is entirely covered by the peritoneum, and is in relation with the
anterior surface of the rectum, from which it is often separated by some convolutions
of the small intestine. This surface is much more convex than the anterior ; it may be
examined from the rectiun.
Its sides are slightly concave, and give attachment to the broad ligaments (d d', d d'),
which are two quadrilateral folds of peritoneum, extended transversely from the lateral
* [Muscular fibres have not yet been demonstrated in the human subject, though in some animals circular
and longitudinal contractile fibres have been found. The epithelium of the mucous membrane is columnar and
ciliated : by the action of the cilia the contents of the tubes are urged towards the uterus : Dr. Heul6 has
found cilia on both surfaces of the fimbrise.]
t [The body of the uterus, at its thickest part, viz., immediately below the fundus, is from eight to twelTe
lines thick.]
THE UTERUS. 465
borders of the uterus to the sides of the pelvis. Their upper margin is divided on each
side into three folds or ridges, formed in the following manner : a posterior fold formed
by the ovary (a) and its ligament (c), an anterior one by the round ligament (g), and a
middle fold by the Fallopian tubes (/). Hence some anatomists have described threr
wings {alee vespertilionis) in each of the broad ligaments.
The broad ligaments may be regarded as forming across the cavity of the pelvis a
transverse septum, within which the uterus and its appendages are contained. This
septum divides the cavity into two portions : one anterior, containing the bladder, the
other posterior, in which are situated the rectum, and almost always some intestinal
convolutions.
Besides the broad ligaments, there are also the ligaments of the ovary and the round
ligaments, proceeding from the sides of the uterus.
The round ligaments {g g) have a fibrous appearance, but are evidently continuous
with the tissue of the uterus. They arise from the side of the uterus, below and in
front of the Fallopian tubes, pass upward and outward in the anterior fold of the broad
ligament to the abdominal orifice of the inguinal canal, into which they enter, being ac-
companied by a prolongation of the peritoneum, which forms around them a cylindrical
sheath called the canal of Nuck. In females far advanced in life, this sheath may be
traced as far as the external orifice of the inguinal canal.
Besides the uterine fibres which enter into its composition, the round ligament also
contains a great number of veins, which may become varicose, especially near the ex-
ternal orifice of the inguinal canal, where they sometimes simulate a hernia.
The upper border or fundus (i) of the uterus is convex, and is directed upward and for-
ward ; it is covered by convolutions of the small intestine ; when not distended, it never
reaches as high as the brim of the pelvis, and cannot, therefore, be felt by the fingers in
the hypogastric region.
The lower or vaginal extremity of the uterus, called also the os tincce, from its shape, is
directed downward and backward ; it is embraced by the vagina, into which it projects,
and is divided by a transverse fissure into two lips, one anterior, the other posterior.
The OS tinccR is small, and perforated by an almost circular opening {n) in females who
have not borne children ; but in those who have been mothers it forms a more consid-
erable projection, and its fissure is more marked and longer transversely.* In some
females the os tinea; is of considerable length, and, as it were, hypertrophied, although
the uterus is healthy.
The anterior lip is thicker than the posterior, which is a little longer than the other.
It frequently happens that in old females every trace of the lips of the os tincae disap-
pears ; the orifice alone remains, and in some cases even that is obliterated. In such a
case the vagina terminates in a cul-de-sac, at the bottom of which a round and yielding
point may be felt. This disappearance of the two lips is much more common than the
elongation of the neck of the uterus, which was pointed out by my venerable colleague,
M. Lallemand.
Cavity of the Uterus. — The cavity of the uterus is extremely smeill in comparison with
the size of the organ ; its figure is that of a curvilinear triangle ; its walls are in con-
tact, and are smooth, and covered with a layer of mucus. We shall examine it in the
body and neck of the uterus.
The cavity of the body of the uterus (w, fig. 189) is of a triangular form, and has an
opening at each angle. The inferior opening {ostium internum, k) Fig. 189.
establishes a free communication between the cavities of the body
and neck ; it is often obliterated in old women, t The other two
orifices (o o) are those of the Fallopian tubes ; they are scarcely
visible to the naked eye, and are situated at the bottom of two
fiuinel-shaped cavities formed at the superior angles of the uterus,
and constituting the remains of the division of the body of the ute-
rus into two halves or comua. This division, which is normal in
many animals, is sometimes met with in the human female.
Congenital deficiency of the cavity of the uterus is very rare. My colleague. Profes-
sor Rostan, kindly sent me a specimen, in which there was no trace of a cavity in the
body of the uterus, although the cavity of the neck remained. The female to whom it
belonged had never menstruated. It is unnecessary to say that she was barren.
The cavity of the neck {h to n) represents a cyUnder flattened from before backward,
and has upon its anterior and posterior walls certain ridges, which form upon each wall
along the whole length of the neck a tolerably regular median column, from which pro-
ceed, at more or less acute angles, a certain number of smaller columns,^ which pro-
ject to a greater or less degree. The whole appearance resembles that of a fern-leaf,
* I have seen the os tincse lacerated and fissured in different directions, in consequence of parturition.
+ This obliteration, which causes retention of mucus and blood, and, consequently, distension and ramol-
lisa'inent of the body of the uterus, is so common that M. .Mayer regards it as normal.
t These rugae, which vary considerably in their arrangement. havfi-JlBfin described in detail by Haller, Bo-
yer, and others. v»^^-«^
N N N
#
466 SPLANCHNOLOGY.
and has been called the arbor vita. It generally disappears after the tirst latGtlr, at least
only traces of it are left. Nevertheless, it is not unfrequently found perfect, even after
several accouchements — a circumstance of some importance in legal medicine.
The internal surface of the body of the uterus is much more vascular than the neck.
This difference is particularly observed in females who have died during a menstrual
period, in whom the vessels of the body of the womb are much developed, and that or-
gan itself is swollen and softened, while the cervix retains its accustomed whiteness and
consistence.
Another character of the uterine cavity is the existence of a greater or less number
of transparent vesicles, which were mistaken by Naboth for ova {ova of Naboth), but are
only muciferous follicles. They exist both in the body and neck of the uterus, but are
more numerous in the neck, near the vaginal orifice, and only become apparent when
the mucus accumulates in them from obliteration of their orifices. They are sometimes
much enlarged, and have then given rise to the opinion that some more serious disease
has existed.
The orifices of the uterine sinuses, described by the older anatomists at the fundus of
the uterus, cannot be detected. They are only to be seen after delivery in the situa-
tion where the placenta had been attached.
The parietes of the unimpregnated uterus are from four to six lines in thickness. The
thinnest part is at the entrance of the Fallopian tubes, where they are not more than
two lines thick. The parietes of the cervix are thinner than those of the body.
Structure of the Uterus. — The constituent parts of the uterus are, a proper tissue, an
external peritoneal coat, an internal mucous membrane, and some vessels and nerves.
The proper tissue is of a grayish colour, very dense and strong, and creaks under the
knife like cartilage. The body appears less consistent than the neck, but this depends
upon the fact of its being more frequently the seat of sanguineous congestion. It is com-
posed of fibres, i. e., it has a linear arrangement. It may be asked, with regard to the
nature of these fibres. Do they consist of fibrous tissue 1 are they muscular, or are they
analogous to tlie yellow tissue of the arteries 1 The following considerations will de-
termine this question :
The walls of the unimpregnated uterus appear to be composed of a fibrous tissue, trav-
ersed by a great number of vessels. During pregnancy, or in consequence of the devel-
opment of tumours, or the accumulation of fluid in the cavity of the uterus, its proper
tissue acquires all the properties of the muscular tissue, as it exists in the viscera of
organic life, and, like it, is endowed with contractility. Can, therefore, the presence
of a foetus or a foreign body in the uterus cause a transformation in the tissue of that
organ 1* Assuredly not ; but the great influx of blood into the uterus, and the conse-
quent distension and development of its fibres, reveals a structure which before was con-
cealed by the state of condensation and atrophy kept up by inactivity.
This view is fully confirmed by the microscopical observations of Rtederer, and the
chemical experiments of Schwilgue ; and also by the results furnished by comparative
anatomy, which has shown circular and longitudinal muscular fibres in the uteri of some
animals, even when not in a gravid condition, t
The nature of the fibres of the uterus being determined, we may now examine their
direction. Some anatomists agree with Malpighi and Monro, that they have no regu-
larity in their disposition, but are interlaced in an inextricable manner. It must be con-
fessed that, in the unimpregnated uterus, such is the case ; but during gestation, the ar-
rangement of the greater number of fibres can be traced. J
In the body the external thin layer is composed of two median vertical fasciculi, one
on each surface of the uterus ; of another fasciculus occupying the fundus, and of some
oblique ascending and descending fibres, which converge towards the Fallopian tubes,
the round ligaments, and the ligaments of the ovaries, which contain prolongations of
these fibres.^ This first, or superficial layer, belongs exclusively to the body of the ute-
rus. The deep layer of the body consists of two series of circular fibres ; each series
forming a cone, the apex of which corresponds to the Fallopian tube, while the base is
directed towards the median hne, and is there blended with that of the opposite side.
The neck is composed entirely of circular fibres, which intersect each other at very
acute angles.
The facts furnished by comparative anatomy perfectly accord with the preceding de-
scription Thus, in the uterus of a sow, which had httered, I found that the cervix was
composed exclusively of circular fibres ; and that the cornua (aduterum of M. Geoffrey
* I conceive that I have proved by facts, that only three tissues, viz., the muscular, the nervous, and the
glandular, are never the products of organic transformations. — (Vide Essai sur VAnalomie Pathol., 1816.)
t CThe muscular fibres of the gravid uterus have been described by Dr. Baly (translation of MUller's Phys-
iology). Like other inorganic muscular fibres, they have no transverse striae ; they arc much broader than
those of the alimentary canal, and taper very much at their extremities, which are sometimes split into two
or three points : the corpuscles upon them are comparatively small.]
X Hunter, Analomia uteri. Rosemberger in Schlegel, ^yllog. Oper. Minor, ad Arlem Obstetric. Lipsis,
\om. ii., p. 290. M6moire pnisentt i 1' Academic de M6decine, par Mmc. Boivin. Oct., 1821.
ft I. c, in the i,'ravid state.
THE UTERUS. 467
St. Hilaire), which represent the body of the uterus of the human female, were formed
by two layers of fibres, one external and longitudinal, the other deep and circular. From
this arrangement, we may therefore conclude that the human uterus results from the union
of two comua, which communicate directly with each other, instead of opening separ-
ately into the cavity of the cervix.
When examined in the state of pregnancy, the tissue of the uterus is found to be trav
ersed by venous canals, or uterine sinuses, which are of very considerable size, especial-
ly opposite the attachment of the placenta. This great number of vessels gives to the
tissue of the uterus the appearance of an erectile or cavernous structure, having muscu-
lar parietes.*
The External or Peritoneal Coat. — ^The peritoneum, after covering the posterior surface
of the bladder, is reflected upon the anterior surface of the uterus, of which it covers
only the upper three fourths, the lower fourth being in immediate contact with the blad-
der. At the fundus of the uterus, it passes to the posterior surface, which it covers en-
tirely, is prolonged a short distance upon the vagina, and is then reflected upon the rec-
tum. The broad ligaments are formed by a transverse duplicature of this coat. Two
falciform folds, formed by this membrane between the bladder and the uterus, are called
the vesico-uterine ligaments, and two others, between the uterus and the rectum, are na-
med the recto-uterine ligaments.
The peritoneum adheres very loosely to the borders of the uterus, but much more
closely as it approaches the median line. When enlarged during pregnancy, the uterus
becomes covered with the peritoneum of the broad ligament, a species of mesentery, the
folds of which become separated, and yield to the increasing size of the organ.
The Internal or Mucous Membrane. — The existence of a mucous membrane upon the
internal surface of the uterus has been denied by those anatomists who have examined
it after parturition, especially by Morgagni and Chaussier, and so, also, by those who do
not admit the presence of a mucous membrane unless it can be demonstrated over a
certain space. But the existence of a mucous membrane on the internal surface of the
uterus appears to me incontestably proved by the following considerations :
First, every organized cavity which communicates with the exterior is hned by a mu-
cous membrane ; why, therefore, should the uterus form an exception to this rule ! Sec
ondly, by dissection it is shown that the mucous membrane of the vagina is continued
into the neck of the uterus, and then into the body ; but in this latter situation it is des-
titute of epithelium.! Notwithstanding the difficulty of dissecting this membrane, on
account of its tenuity, and its close adhesion to the tissue of the uterus, its presence is
demonstrated by the following observations : Under the microscope, the internal surface
of the uterus presents a papillary appearance, but the papillae are very small ; it is pro-
vided with follicles or crypts, from which mucus may be expressed by a number of
points, and which form small vesicles w^jen distended with mucus, in consequence of
obstruction or obliteration of their orifices. Thirdly, it is extremely vascular, and pre-
sents a capillary network of the same appearance as that of the other mucous mem-
branes ; and, lastly, it is constantly lubricated with mucus. Pathological observations
Eilso show that the internal surface of the uterus, like all raucous membranes, is liable to
spontaneous hemorrhages from exh2dation, without breach of continuity, to catarrhic
secretions, and to those growths which are denominated mucous, vesicular, and fibrous
polypi : and it is generally admitted that, where there is an identity of disease, there is
also identity of structure.
During pregnancy, the elements of the mucous membrane are separated; the vessels
become penicillate, and greatly increased in size ; but in proportion as the uterus returns
to its original dimensions, the mucous membrane regains its primitive form, and its dis-
sociated elements approach each other. It seems as if this membrane was destroyed
by a true exfoliation, and then entirely reproduced.
The arteries of the uterus are derived from two sources : the principal, called the ute-
rine, arise from the hypogastric ; the others proceed from the spermatic or ovarian ar-
teries to the borders of the uterus, and are distributed upon it : both sets are very tor-
tuous.
The veins are remarkable for their enormous size during pregnancy and after parturi-
tion. The term uterine sinuses has been given to the large veins which are then found
in the substance of the organ ; and this term is not altogether without foundation, for
these venous canals are formed by the lining membrane of the veins which adheres to
the proper tissue of the uterus, just as, in the sinuses of the dura mater, it adheres to
the fibrous tissue of that membrane.
The lymphatics, which have been well examined only during pregnancy and after par-
* This combination of the erectile and muscular tissues is found in the penis of the horse, and perhaps,
also, in that of man.
t [The mucous membrane of the uterus contains numerous tubular glands, or crypts, resembling, in form
and direction, the tubuli of the stomach, and the crypts of Lieberkuehn, found in the intestinal canal. The
epithelium of this mucous membrane is, according to Henl6, columnar, and also ciliated from the fundus to
the middle of the cervix uteri ; below that point it passes into the squamous form of epithelium found in the
ragina and on the labia.]
4§8 SPLANCHNOLOGY.
turition, at which time I have often seen them full of pus, are, like the veins, extremely
large (see Anat. Path., avec planches, liv. xiv.) ; they form several layers in the sub-
stance of the uterus, ^^e most superficial of which is the most developed. They termi-
nate in the pelvic and lumbar lymphatic glands ; some accompany the ovarian veins.
The nerves, as seen in the pregnant condition, have been well described and figured by
Tiedemann. Some of them are derived from the renal plexus, and surround the ovarian
arteries ; others proceed from the hypogastric plexus, and are formed by some of the
anterior branches of the sacral nerves, and by branches from the lumbar ganglia of the
sympathetic.
Development. — It is generally agreed that the body of the uterus is always bifid, or two-
horned, in the embryo, up to the end of the third month ; and that, towards the end of
the fourth month, the two halves are united to form a single cavity. I have not observed
tliis in the earliest periods of intra-uterine life.
During fcetal life, the uterus, instead of presenting the same form as it subsequently
possesses, is decidedly larger at the neck than in the body : at this period the broadest
part of the uterus is its vaginal extremity.
After birth, and up to the time of puberty, the development of the uterus is almost
stationary ; so that, according to the observations of Roederer, which are confirmed by
Professor Duges, it is from twelve to fourteen lines long in the new-born infant, and only
an inch and a half at ten years of age.
At puberty, the uterus rapidly acquires its full dimensions, and at the same time be-
comes the seat of a periodic and sanguineous exhalation, the occurrence of which con-
stitutes menstruation.
In old age, the uterus becomes atrophied, and altered in shape ; the cervix and body
are separated by a much more decided constriction. These two parts of the uterus
seem to become more independent of each other. The lips of the os tincae are general-
ly effaced in old women. The tissue of the body preserves its softness, while that of
the neck acquires an extreme density.
The situation of the uterus is very different at different ages. In the foetus it projects
beyond the brim of the pelvis, and is in the abdominal cavity ; after birth, and in conse.-
quence of the development of the pelvis, it seems gradually to sink into that cavity. At
the age of ten years, the fundus of the uterus is on a level with the brim ; afterward it
is lower down. In old women it is generally inclined to one side, or reversed upon the,
rectum.
Functions. — The uterus is the organ of gestation ; the fecundated ovum is deposited
in its cavity, and there meets with the most favourable conditions for its development.
The uterus is also the principal agent in the expulsion of the foetus.
The Vagina.
The vagina is a membranous canal, extending from the vulva to the uterus ; it is the
female organ of copulation, and also forms the passage for the menstrual blood, and the
product of conception.
It is situated in the cavity of the pelvis between the bladder and the rectum, and is
held in that situation by tolerably close adhesions to the neighbouring parts, but still is
so loose that it can be everted like the finger of a glove.
Direction. — It is directed obliquely forward and downward, i. e., it coincides with the
axis of the outlet of the pelvis ; and as the direction of the uterus corresponds with the
axis of the brim, these two parts form an angle or curvature with each other, having its
concavity directed forward.
Shape and Dimensions. — The vagina is shaped like a cylinder, flattened from before
backward, and having its walls in contact, as may be seen upon applying the speculum.
It is from four to five inches long ;* sometimes it is much shorter : I have seen it as
short as an inch and a half This congenital shortness must be distinguished from the
apparent shortness produced by prolapsus uteri.
The vagina is not of the same diameter throughout. Its lower orifice is the narrow-
est part, while its upper extremity is the widest. In females who have borne children,
the bottom of the vagina forms a large ampulla, in which the speculum may be moved
about extensively, and in Avhich, also, a considerable quantity of blood may accumulate
during hemorrhage. It is, moreover, a dilatable canal, as is proved during parturition ;
and is, at the same time, elastic, and contracts after delivery, so as almost to return to
its original dimensions. It would appear, also, to be capable of a vermicular contraction.
Relations. — In front, where it is slightly concave, it corresponds to the inferior fundus
of the bladder, to which it is united by very dense filamentous cellular tissue, resembling
the dartos ; it cannot be separated from the urethra, which appears to be hollowed out
of the substance of its walls. The close adhesion of the vagina to the bladder and ure-
tlua accounts for these latter organs always following the uterus in its displacements.
Behind, the vagina corresponds with the rectum, through the medium of the peritoneum
in its upper fourth, and immediately in its lower three fourths. It adheres to the rec-
* LFrom the nature of the cune formed by the vagina, its anterior wall is shorter than the posterior.]
THE VAGINA. 4^
turn by cellular tissue resembling the dartos, and analogous to that existing between it
and the bladder, but much looser, so that the rectum does not follow the vagina in its
displacement. The sides of the vagina give attachment to the broad ligaments above,
and to the superior pelvic fascia and the levatores ani below, and they are in relation
with the cellular tissue of the pelvis and with some venous plexuses.
Internal Surface. — The internal surface of the vagina is covered with an epithelium,
which can be very easily demonstrated, and which is prolonged as far as the os uteri,
where it terminates by a sort of indented margin, in the same manner as the epithelium
of the oesophagus ceases at the stomach.* This surface presents on both walls, but es-
pecially in front and near the orifice of the vulva, some transverse rugae, or, rather,
prominences, which very nearly resemble the irregular ridges upon the palate ; they all
pass from a median prominent line, which is often prolonged like a median raphd along
the whole anterior wall of the vagina ; the raphe on the posterior wall is not so well
marked. These two median raphes are called the columns of the vagina. They are
the remains of the median septum, which generally coexists with a bifid uterus, but ex-
ists sometimes independently of it.
The transverse rugae of the vagina are very numerous in the new-bora infant and in
virgins ; they are partially effaced after the first labour, at the upper part of the vagina,
but always remain at the lower part. These rugae are not folds, and do not appear to
assist in the enlargement of the vagina.
The upper extremity of the vagina embraces the neck of the uterus, upon which it is
prolonged without any line of demarcation, and forms a circular trench around the os
tincae, which is deeper behind than in front.
The lower extremity, or opening into the vulva, presents a corrugated transverse pro-
jection in front, which is exposed by separating the labia and nymphae ; it narrows, and
seems even to close the entrance of the vagina.
In virgins, the orifice of the vulva is provided with a membrane, concerning the form
and existence of which there have been numerous disputes ; it is called the hymen, and
is a sort of diaphragm interposed between the internal genitals on the one hand, and the
external genitals and urinary passages on the other. This membrane is of a crescentic
shape, having its concavity directed forward, and closing up the posterior and lateral
parts of the vagina: it sometimes forms a complete circle, perforated in the centre. Its
free margin is fringed ; it varies in breadth in different individuals, and thus regulates
the dimensions of the vaginal orifice. The hymen sometimes forms a complete mem-
brane, constituting what is called imperforate vagina.
The hymen is composed of a duplicature of mucous membrane, varying in strength,
and containing within it some cellular tissue and vessels. The debris remaining after
its laceration constitute the carunculce myrtiformes, which vary in number from two to five.
Structure. — The walls of the vagina consist of an erectile spongy tissue interposed be-
tween two very strong fibrous layers, of which the external is the thicker. Around this
erectile tissue we find a tolerably thick layer resembling the tissue of the dartos con-
densed. I cannot agree with sonie anatomists in admitting an identity of structure in
the walls of the vagina and uterus, for in no case does the vagina assume a muscular
character hke the latter organ. From the presence of the dartoid tissue an obscure ver-
micular movement may take place, and assist the elasticity of the walls of the vagina.
The posterior wall and the upper part of the anterior wall are thin ; the vagina is veiy
much thicker opposite the urethra, which seems to be hollowed out of its substance, and
terminates by a rugous enlargement, which forms, at the entrance of the vagina, the pto-
jection already mentioned, and which is only a very dense spongy tissue.
The mucous membrane of the vagina is remarkable for the thickness of its epitheli-
um,t for its close adhesion to the proper membrane, and for its highly developed papillae,
especially at the entrance of the passage, where the rugae are nothing more than papillae
in an exaggerated form. The mucous follicles can be easily demonstrated.
The Bulb of the Vagina. — Besides the spongy expansion at the orifice of the vagina,
there is in front and on each side of this orifice an enlargement or cavernous body, occu-
pying the interval between the entrance of the vagina and the roots of the clitoris. It
is not very thick in the middle, where it is placed between the meatus urinarius and the
union of the roots of the clitoris, but gradually enlarges from this point, and terminates
below, upon each side of the vagina, by an enlarged extremity. The posterior wall of
the vagina is the only part in which it does not exist. In position, as well as shape, it
resembles the bulb of the urethra in the male. J
The Constrictor Vagina. — ^This consists of two muscles, one on each side of the ori-
fice of the vagina, the arrangement of which very nearly resembles that of the bulbo-
* tin both of these situations the epithelium does not cease, but is merely changed in its character (see
note, p. 467).]
t [The epithelium in the vagina, and also in the vulva, is squamous.]
t In one subject, on the outer side of this vaginal bulb, I found a smooth sero-fibrous pouch, containing' a
transparent mucous fluid. A narrow canal, proceeding from this pouch, passed directly towards the entrance
of the vagina. I could not find the orifice of this caual, which was probably obliterated. The same dispoai-
tion existed on both sides.
470 SPLANCHNOLOGY.
cavernosus in the male. Each muscle commences in front of the rectum, by an inter-
lacement of fibres common to it, to its fellow of the opposite side, and to the sphincter
ani, passes forward under the fonxi of a flattened band, and terminates upon the sides
of the clitoris, a portion being continued above it, and blended with the suspensory liga-
ment of that body.
Relations. — It is covered on the outside by the skin and the fatty cellular tissue of the
labia majora ; it corresponds on the inside with the bulb of the vagina, which it must
strongly compress.
The proper vaginal arteries arise from the hypogastric. The uterine arteries also
send numerous branches to the vagina.
The veiiis are very niunerous, form plexuses, and terminate in the hypogastric veins.
The turves are derived from the hypogastric plexus.
Development. — The rugae of the vagina are not visible until about the end of the fifth
month of intra-uterine life ; from the sixth to the eighth they become much more devel-
oped than they are subsequently. The transverse rugae are visible in the whole length
of the vagina, and are placed closely to each other. The hymen does not make its ap-
pearance until about the middle of fcetal life ; it is directed forward, and is rough and
jagged. It is always present.
The Urethra in. the Female.
This canal, which is, as it were, hollowed out of the anterior wall of the vagina, dif-
fers considerably from the male urethra, of which it represents the membranous portion
only. It is about one inch in length.
It is very difficult to determine its diameter, on account of its dilatability ; but it is
about three or four lines when quite undilated. Its lower end is somewhat contracted.
It is directed obliquely downward and forward, and is slightly concave in front.
Relations. — Anteriorly, while behind the symphysis, it is in contact with the cellular'
tissue of the pelvis ; opposite the symphysis, it is in relation with the angle of union of
the two crura of the clitoris. The pelvic fascia, or, rather, the anterior ligaments of the
bladder, form a half sheath for it above, but are separated from it by numerous venous
plexuses. Posteriorly, the canal is so closely united to the vagina, that it is impossible
to separate them.
The vesical orifice of the female urethra is similar to that of the male, only there is no
prostate gland.
The internal surface is of a deep colour, and is remarkable for certain longitudinal folds
or parallel ridges, the majority of which are not effaced by distension ; one of these folds
is in the median line of the lower wall of the canal. We also find the orifices of mucous
crypts or lacunae, and some parallel longitudinal veins.
Structure. — It is muscular and erectile, like the membranous portion of the male ure-
thra. It is surrounded by a thick layer of circular muscular fibres, which seem to be
continuous with the fibres of the bladder, some of the longitudinal fibres of that organ
being prolonged upon the outside of these.* A thin layer of spongy or erectile tissue lies
subjacent to the mucous membrane, which is very thin.
The Vulva.
Under the term vulva we include all the external genitals of the female, viz., the mons
Veneris, the labia majora and minora, the clitoris, and the meatus urinarius, to which
we may add the orifice of the vagina already described.
The mons Veneris is a rounded eminence, more or less prominent in different individ-
uals, situated in front of the pubes, and surmounting the vulva ; the prominence of this
part is owing partly to the bones, and partly to a collection of fatty tissue beneath the
skin ; it is covered with hair at the time of puberty.
The labia majora are two prominent cutaneous folds, which form the limits of an an-
tero-posterior opening, by most anatomists named the vulva. They are flattened trans-
versely, and are thicker in front than behind ; their external surfaces are covered with
hairs ; their internal surfaces are moist and smooth, and in contact with each other ;
their free borders are convex, and provided with hair ; their anterior extremities are con-
tinuous with the mons Veneris ; their posterior extremities unite to form a commissure
called the fourchette, which is almost always lacerated in the first labour. The interval
between the fourchette and the anus constitutes the perineum, which is generally from
* [The female urethra perforates the triangular ligament precisely in the same way as the membranous por-
tion of the urethra in the male ; and, moreover, between the two layers of the ligament it is surrounded by mus-
cular fibres corresponding exactly with the compressor urethra in the male sex. The vertical fibres, or Wil-
son's muscles, were noticed by him (loc. cit.), descending from the symphysis, separating on the urethra, and
passing around it ; the transverse fasciculi, which are often very large, form together the depressor urethra Of
Santorini, and were described and figured by that author (Obs. Anat.) as arising by a broad tendou from the
lower part of the rami of the pubes, above the erectores clitoridis, passing obliquely upward and inward, and
uniting with each other dijove the urethra. Mr. Guthrie has shown {loc. cit.) that the relations of the verti-
cal and transverse fasciculi to each other, to the urethra, and to the layers of the Uiaugular ligament, are pre-
cisely the same as in the male.] ' .,-j4J-i
THE VULVA. 471
eight to ten lines long. The interval between the fonrchette and the entrance of the
vagina is called the fossa navicularis.
The constituent parts of the labia majora are, a cutaneous layer, a mucous layer, both
provided with numerous sebaceous follicles.* In fat persons, a great quantity of adipose
tissue, a layer of dartoid tissue next the mucous membrane, and some arteries, veins,
lymphatics, and nerves. They are therefore very analogous to the scrotum in the male,
and, Uke it, are liable to serous infiltration in anasarca.
The labia minora, or nymphcB, are seen after separating the labia majora, under the
form of two layers of mucous membrane ; they are narrow behind, where they commence
upon the inner surface of the labia majora, and they enlarge gradually as they converge
towards each other in front. At the chtoris they become slightly contracted, and bifur-
cate before their termination. The lower division of the bifiircation is attached to and
continuous with the glans of the clitoris ; the upper division unites with that of the op-
posite side, and forms a hood-like fold above that body, called the preputium clitoridis.
Tlie nymphae are provided with very large crypts, wliich are visible to the naked eye,
and secrete an abundance of sebaceous matter. They vary much in size, according to
age : thus, in new-bom infants, they project beyond the labia majora, principally on ac-
count of the imperfect development of the latter. They also vary in different individ-
ujds : in some females being extremely small, and in others always projecting beyond
the labia majora ; and, lastly, in different countries ; for in certain African nations, among
the Hottentots, for example, they are of a disproportionate length, and constitute what
is called in females of that race the apron.
The clitoris is an erectile apparatus, forming a miniature representation of the corpus
cavernosum of the penis. Its free extremity is seen in the anterior part of the vulva,
about six lines behind the anterior commissure of the labia majora, and resembles a tu-
bercle situated in the median line, covered, as by a hood, with the upper divisions of the
bifurcated nymphae, and continuous with the lower divisions of the same. This tuber-
cle, which, though imperforate, has been compared to the glans penis {glans clitoridis), is
generally very small. Sometimes, however, it is very long, so as to have excited a sus-
picion of the existence of hermaphrodism. In one instance that came under my obser-
vation, the free part of the clitoris was two inches long, and extremely slender.
Like the corpus cavernosum in the male, the clitoris arises from the ascending rami
of the ischia by two roots, which expand and converge until they arrive opposite the
symphysis, where they unite and form a single corpus cavernosum, flattened on each
side ; this, after passing for some lines in front of the symphysis, separates from it, and
forming a curve with the convexity directed forward and upward, and the concavity
downward and backward, gradually becomes smaller towards its free extremity.
It has a suspensory ligament precisely resembling that of the penis, and ischio-cavei-
nosi muscles, similar to, but smaller than those of the male. We have already said that
the constrictor vaginae, which represents the bulbo-cavemosi of the penis, has a similar
arrangement to those muscles, t. c, it passes upon the sides of the clitoris, and then be-
comes continued on to its suspensory ligament.
The last circumstance which completes the analogy between the clitoris and the corpus
cavernosum of the penis, is the reception of the canal of the urethra into the V-shaped
interval formed by the union of the two crura of the clitoris.
The corpus cavernosum of the clitoris forms a longitudinal ridge between the labia ma-
jora, extending from the anterior commissure to the glans of the clitoris.
The Meatus Urinarius. — About an inch below and behind the clitoris, we find in the
median line, immediately above the projecting margin of the opening of the vagina, tfce
meatus urinarius, or the orifice of the urethra, which constantly appears closed.
The Mucous Membrane of the Vulva. — The mucous membrane lining the vulva is con-
tinuous, on the one hand, with the skin at the intemad surface of the labia majora, and
with the mucous membrane of the vagina on the other ; upon the labia majora and nym-
phae it has a great number of sebaceous follicles visible to the naked eye, and yielding a
cheesy, odorous secretion ; and also mucous follicles, which are most numerous near the
meatus urinarius, and open into culs-de-sac, the orifices of which are visible to the na-
ked eye, and are often large enough to admit the blunt extremity of a probe.
Development. — In the foetus the labia majora are small, and separated from each other
by the nymphae, which are much larger in proportion, and also by the clitoris, which pro-
jects beyond them to a greater extent in the earlier periods of development. This pre-
dominance of the clitoris is still so decided at birth, that it has occasioned mistakes con-
cerning the sex of the infant.
THE MAMM^.
Number. — Situation. — Size. — Form. — Structure. — Development.
The mavima or breasts (jiadrbg, from fidu, to seek eagerly, because the infant seeks^
* It is not rare to see small and very short hairs growing from the sebaceous follicles on the inner surface
of the labia majora ; they are analogous to '.hose of the carunculse lachrymales.
472 SPLANCHNOLOGY.
them for the milk) are glandular appendages of the generative system, which secrete
the milk, and even after birth establish intimate relations betvireen the mother and the
infant.
The important office performed by the mammje has led zoologists to arrange in the
same class, under the term mammalia, all animals having an apparatus for lactation. We
may mention here another character peculiar to this class of animals, because it is in-
timately connected with the existence of mammae, viz., that all mammalia are vivip-
arous that is to say, give birth to their young freed from all their foetal envelopes.
The mammsE exist in both sexes, but are rudimentary and atrophied in the male, and
belong essentially to the female.
Number. — They are two in number in the human species, which is uniparous ; in the
lower animals they are generally double the number of the young. Examples of three
or four mammae in the human subject are very rare, and the supernumerary mammae
are generally nothing more than simple nipples, or, rather, masses of fat.
Situation. — They are situated on the anterior and upper part of the chest, the trans-
verse enlargement of which in the human subject is so favourable to their development.
In the lower animals they occupy the abdominal region.
They are situated on each side of the median line, over the interval between the third
and the seventh ribs. They are therefore placed at the same height as the arms, and
occupy this region, says Plutarch, in order that the mother may be able to embrace and
support her infant while she is suckling it.
Size. — In the male they are rudimentary during the whole of life ; in the female until
the period of puberty only, when they become much enlarged as the generative appara-
tus is developed more completely. They again increase in size during pregnancy, and
especially after delivery ; they become atrophied in old age. In some females who are
still young, the size of the mammas by no means corresponds to their statm-e, strength,
and soundness of constitution ; while, on the other hand, it is not uncommon to see thin,
phthisical individuals with very large breasts. In judging of the size of the mammae, we
must not confound that depending upon the gland itself with that due to fat. The lar-
gest breasts are not always those which furnish the most milk, because their extreme
size often depends on an accumulation of fat, the gland itself being small. The left mam-
ma is almost always a little larger than the right.
Form. — The mammae represent a semi-sphere surmounted by a large papilla called the
nipple.
The skin covering the mamma is remarkably delicate. Surrounding the nipple is an
areola or aureola of a pinkish hue in young girls, but of a brownish colour in most females
who have borne children ; it has also a rough appearance, owing to a number of sebace-
ous glands, which yield a kind of waxy secretion that prevents the irritating action of
the saliva of the infant. Morgagni, Winslow, and Meckel state that they have observed
milk to escape from them ; but if there was no error in their observations, it must be
admitted that, by some unusual anomaly, a lactiferous duct opened at the side of one of
these little glands.
The mammilla or nipple is of a pinkish or brown colour, rough, and, as it were, crack-
ed at the summit, and capable of undergoing a sort of erection ; it varies in form and
size in different subjects ; it is either cylindrical or conical, and sometimes so short that
the lips of the infant cannot lay hold of it ; in certain cases it is even depressed. In the
centre of the nipple we observe one or more depressions, in which the lactiferous ducts
open by a variable number of orifices.
The papilla is provided also with a great number of sebaceous glands having the ap-
pearance of tubercles, and secreting a substance which prevents the nipple from being
chapped by the act of sucking and the saliva of the infant.*
Structure. — The breasts consist of the mammary glandular tissue and of fat.
The Mammary Gland. — ^When freed from the fat by which it is surrounded, the mam-
mary gland appears like a mass flattened from before backward, and thicker in the cen-
tre than at its circumference, which is irregular, but less so on the inside than on the
outside. Its base, which is plane, and even slightly concave, rests upon the pectoralis
major, and sometimes beyond it upon the serratus magnus ; a continuation of the fascia
superficialis separates it from these muscles, to which it adheres by very loose serous
cellular tissue only, and hence it is very movable.
The cutaneous surface of the mammary gland is very unequal, and forms alveoli filled
by fat, by which means the inequalities are concealed.
The proper tissue of the gland is considerably denser than that of most glandular or-
gans. It should be examined both during lactation, and when that function is not being
performed.
In the absence of lactation, the gland has the appearance of a very compact, whitish,
* [Sir A. Cooper has described numerous cutaneous papillae upon the nipple and areola ; they are highly
*wascular and nervous. He has also shown that the glands found in the areola and at the base of the nipple
nave branched ducts, ending in blind extremities : in the female, from one to five open on each tubercle.—
(Anatomy of the Breast, 1840.)]
THE MAMMiE. 473
fibrous tissue, divided into unequal lobes, which cannot be compared to anything bettei
than to certain fibrous tumours of the uterus. The granular structure proper to the tis-
sue of glands is not visible during this state.
During lactation, the granular structure becomes very evident. The following are
the results of my observations respecting it at this period : The glandular granules or
lobules are united into small clusters, forming flattened lobes, placed one upon another.
From each little lobe proceeds an excretory duct, which may be recognised by its white
colour, is easily injected, and is formed by the union of a number of smaller ducts cor-
responding to the number of lobules. Having had an opportunity of dissecting the mam-
ma of a female recently delivered, in which the cellular tissue between the lobules was
infiltrated with serum, the lobules themselves, as it were, dissected, and the lactiferous
ducts injected with yellowish coagulated milk, I found that some of the lobules were iso-
lated, and, as it were, pediculated, while others were collected into regular or irregular
clusters. In one of these clusters the lobules had a circular arrangement, small ducts
proceeded from each lobule, and, passing from the circumference towards the centre of
the circle like radii, opened into a common efferent duct, which issued from the central
point. Another cluster was elongated and swollen at intervals, and in the centre was
a duct which received the smaller ducts from the several lobules. Each lobule had a
central cavity, from which a worm-shaped mass of coagulated caseous matter could be
expressed. When examined by the simple microscope, the parietes of these cavities
had a spongy aspect like the pith of the rush, a character which I have already noticed
as belonging to all glandular organs.*
The Fibrous Tissue of the Mamma. — Besides the lobules, a large quantity of fibrous tis-
sue also enters into the structure of the gland, forms a complete investment for it, and
then sends more or less loose prolongations into its substance, and unites the lobes to-
gether. It is to the great quantity of fibrous tissue that the hardness of the mammary
gland is to be ascribed. Sometimes the enlargement of the mamma at the time of pu-
berty is confined entirely to the fibrous tissue ; in such a case, the organ may acquire an
enormous size, the glandular tissue disappears, and the mamma is transformed into a
many-lobed fibrous mass, wliich has been sometimes mistaken for a degenerated lipoma.
The Adipose Tissue. — The alveoli on the outer surface of the mamma are filled with
masses of fatty tissue, which are separated by fibrous laminae extending from the gland
to the skin. The cells in which these masses are contained do not communicate with
each other, and hence the frequency of circumscribed abscesses in the mamma. The
relative quantities of fat and glandular tissue have an inverse ratio to each other. The
great size of the mammae in some men is owing to development of the fatty tissue.
Haller says that it is an essential element in the structure of the gland, and that he has
several times seen lactiferous ducts arise from it.
The Lactiferous Ducts. — If the mamma of a female who has died during lactation be
divided, the milk will be seen to exude from a number of points, as from the pores of a
sponge ; these points correspond to sections of the thin, whitish, semi-transparent ex-
cretory ducts of the mammary glands, which are called lactiferous, or galactophorous ducts.
They arise from the lobules, and perhaps, also, from the fatty tissue, as was thought by
Haller ;t they unite successively like the veins, converge from the circumference to the
centre, traverse the substance of the gland, and at length form a variable number of
ducts, which reach the centre of the gland, opposite the areola. In that situatioa they
acquire their utmost size, and form considerable ampullae or dilatations, between which
scarcely any intervals are left. According to some anatomists, the number of these am-
pullae is not less than twenty ; I have never counted more than ten. They are of un-
equal size. At the base of the nipple they become contracted, straight, and parallel, and
open upon its summit by orifices, which are much narrower than the ducts themselves.
Thus, then, although there is no reservoir properly so called in the mammary gland, the
ampullae above described may be regarded as such ; with this difference only, that in-
stead of one reservoir there are several.
The lactiferous ducts, moreover, are surrounded, both in the mammilla and opposite
the areola, with a dartoid tissue, the existence of which explains the state of orgasm
and erection of the nipple, as well as the expulsion of the milk in a jet when the gland
is excited. There is no trace of the cavernous structure described by some anatomists
as existing in the nipple. The lactiferous ducts do not communicate with each other in
any part of their course ; neither in their terminating canals, nor in their ampullae, nor
in their smaller ducts ; this may be proved by mercurial injections, or by filling each
duct with a differently-coloured injection. The mammary gland, like most others, is
therefore divided into a certain number of distinct compartments, which may perform
their functions independently of each other.
Injections also show that the lactiferous ducts have no valves. Tlieir structure is little
* tThe ultimate structure of the mammary gland consists of the terminations of the lactiferous ducts in
clusters of microscopic cells within each lobule ; these cells are round, and have a diameter twenty times as
great as that of the capillaries which ramify upon them.
+ (Our present knowledge of the minute structure of glands has proved the inaccuracy of this supposition ol
HaUerJ
0 o 0
474
SPLANCHNOLOGY.
known. It is generally admitted that they consist of an internal membrane continuoQs
with the skin, and which must be analogous to the mucous membranes, and of an exter-
nal fibrous coat, which I am inclined to regard as analogous to the tissue of the dartos.
The arteries of the manuna arise from the thoracic, especially that which is called the
external mammary, also from the intercostals and the internal mammary.
The veins are very large, and of two kinds, sub-cutaneous and deep ; the latter accom-
pany the arteries, the former are visible through the skin.
The lymphatics are very numerous, and enter the axillary glands. The older anato-
mists admitted a direct communication between the thoracic duct and the glandular tis-
sue of the breast ; but this opinion, suggested by the resemblance in colour between the
chyle and milk, is altogether erroneous.
The nerves are derived from the intercostals and the thoracic branches of the brachial
plexus.
Development. — The mammae become visible after the third month of intra-uterine life.
At birth they are more developed than at a subsequent period, and contain a certain
quantity of miUcy viscid fluid. Until puberty the mammae of the two sexes differ only in
the nipple being larger, and the gland somewhat larger in the female than in the male.
In the female, at puberty, they gradually acquire the size which they subsequently re-
tain, their development coinciding with that of the genital organs. Most commonly the
change precedes, but sometimes it follows, the appearance of the menses.
The mammae of the male also participate in the development of the generative appara-
tus at the time of puberty, and in some subjects even a milky secretion is formed.*
The manunae become atrophied in old age, and are sometimes replaced by fibrous tis
sue ; in several old women I have found the lactiferous ducts distended with a dark, in-
spissated mucus, of a gelatinous consistence which has enabled me to trace the ducts
even to their most delicate radicles.
THE PERITONEUM.
The Suh-umhilical Portion. — The Supra-umbilical Portion. — General Description and
Structure.
The peritoneum (nepl, around, and teIvu, to extend) is a serous membrane, which, on
the one hand, lines the abdominal parietes, and, on the other, invests nearly all the vis-
cera contained in the cavity of the abdomen.
As it enters into the formation of almost all the abdominal viscera, it has been already
Fig, 190. partially examined while describing them. It remains
for us to demonstrate these parts as a whole, and for
this purpose, we shall suppose the membrane to com-
mence at one particular point, and shall trace it with-
out interruption in a circular course until we again ar-
rive at the point from which we started.
The peritoneum is the largest and most complica-
ted of the serous membranes ; it forms, like all of
them, a shut sac, the external surface of which ad-
heres to the parts over which it is reflected, while its
internal surface is free and smooth.
Taking the umbilical region as a point of departure,
we shall divide the peritoneum into two portions, a
superior, epigastric or supra-umbilical, and an inferior
or sub-umbilical portion.
The Inferior or Sub-umbilical Portion of the Peritone-
um..— The inferior or sub-umbilical portion, supposed
to commence at the umbilicus, lines the whole of the
parietes of the abdomen (a, ^^. 190) below that point.
In so doing, it is raised up by the urachus and the two
umbilical arteries, or, rather, by the ligaments repla-
cing those arteries, so as to form three falciform folds,
one median and two lateral, which converge towards
their termination at the umbilicus, but diverge in the
direction of the bladder ; the peritoneum then dips
into the pelvis, and covers the fundus, the sides, and
the posterior surface of the bladder (J), but to a varia-
ble extent, according as that organ is distended oi
empty. When the bladder is contracted, the perito-
neum descends behind the symphysis ; when, on the
* [It has been shown by Sir A. Cooper, that the mammary gland
of the male has a system of ducts and cells like those of the fejnals
gland, but very much smaller.]
THE PERITONEUM. 475
Other hand, it is distended and rises into the abdomen, the peritoneum retires before ii,
and the bladder then comes into direct contact with the anterior wall of the abdomen,
so that it can be reached by the surgeon without wounding the peritoneum.
From the posterior surface of the bladder the peritoneum is reflected upon the other
pelvic organs, being arranged differently in the two sexes. In the male it is reflected
from the bladder upon the rectum, forming- two lateral semilunar folds, called the pos-
terior ligaments of the bladder, and a cul-de-sac between them of variable depth, which
sometimes reaches as low as the prostate.* In the female it is reflected from the pos-
terior surface of the bladder upon the neck of the uterus (m), forming a cul-do-sac between
the two, so that the inferior fundus of the bladder is entirely uncovered by it. It then
covers the two surfaces and the superior border of the uterus, and forms two lateral,
broad, transverse folds (the ligamenta lata), each of which is subdivided superiorly into
three smaller folds, the ala vespertilionis or ala of the broad ligament, the anterior fold
corresponding with the round ligament, the middle one to the Fallopian tube, and the
posterior fold to the ovary.
The peritoneum has no relation with the front of the vagina (b), but it covers the up-
per third of that canal behind ; from thence it is reflected upon the rectum (r), and has
then the same arrangement in both sexes. Inferiorly it is limited to the anterior sur-
face of the gut, but superiorly it entirely surrounds it, excepting behind, where it forms
a duplicature known as the mesorectum.
After leaving the cavity of the pelvis, the peritoneum continues to ascend, so as to
cover the posterior wall of the abdomen ; in this situation we shall examine it in the
middle and at the sides.
In the middle it passes in front of the sacro- vertebral angle, then in front of the lumbar
vertebrae, and having arrived opposite an oblique line, extending from the left side of the
second lumbar vertebra to the right iliac fossa, it is reflected forward to constitute the
left layer (m) of the mesentery {neaoq, middle, evrepov, an intestine) ; it immediately ex-
pands, so as to correspond to the whole length of the small intestine (i), lines the left
lateral half, the convex borders, and the right lateral half of that intestine, and then pass-
ing from before backward (m'), is applied to the back of the layer just described, and in
this manner forms the mesentery (m m'), the largest of all the duplicatures of the peri-
toneum, and remarkable for its resemblance to a plaited ruffle.
On the left side, the peritoneum, after having formed the mesorectum, then forms the
iliac Tnesocolon, a considerable fold, which allows great mobility to the sigmoid flexure of
the colon. From the sigmoid flexure it is prolonged upon the left lumbar colon, cover-
ing the anterior five sixths of that part of the intestine, and applying it against the kidney,
but without forming any duplicature for it ; so that the kidney and the colon are in im-
mediate relation. Still, the left lumbar colon is not unfrequently entirely surrounded by
the peritoneum, so as to have a duplicature behind it, called the left lunibar mesocolon.
Along the whole course of the great intestine, the peritoneum usually forms a number
of small folds containing fat, and named the appendices epiploica.
On the right side the peritoneum arrives at the caecum, and may be arranged in one of
two modes : it either entirely invests that portion of intestine, which is then very mo-
vable ; or else, and this is the most common arrangement, it passes iimnediately in front
of the cascum, which is thus applied against the right iliac fossa, and is attached there
by rather loose cellular tissue. The peritoneum sometimes forms a small mesentery
for the vermiform appendix, sometimes fixes it against the posterior surface of the
caecum, or against the ileum, or, lastly, against the lower portion of the mesentery. Above
the caecum the peritoneum covers the right lumbar colon, and has the same arrange-
ments as on the left side.
Such is the course of the sub-umbilical portion of the peritoneum.
The Superior or Supra-umblical Portion of the Peritoneum. — We shall trace the superior
or supra-umbilical portion from the umbilicus to the posterior wall of the abdomen, op-
posite to the mesentery and the lumbar mesocolon, to which points we have already
traced the lower portion.
Commencing at the umbilicus and proceeding upward, the peritoneum (e) lines the an-
terior abdominal parietes ; on the right side it meets with the umbilical vein, or the
fibrous cord to which that vein is reduced in the adult, covers it, and forms a falciform
duplicature, named the suspensory ligament of the liver, or falx of the umbilical vein ; this
fold is of a triangular shape, its apex corresponds with the umbdicus, and its base with
the upper surface of the liver, which is divided by it into two lateral portions or lobes, t
From the umbilicus, then, as from a centre, proceed four peritoneal folds : one superior
or ascending, for the umbilical vein ; and three descending, one for the urachus and two
for the umbilical arteries.
From the anterior wall of the abdomen, the peritoneum is continued upon the Idwer
* The peritoneum, forming the cul-de-sac between tlie bladder and the rectum, sometime.s has a fissured ap-
pearance, like that seen upon the parietes of the abdomen in women who have had many children.
t [Its lower free margin encloses the umbilical vein, and its upper or interior border is attached to the ab-
dominal parietes.]
476 SPLANCHNOLOGY.
surface of the diaphragm (/), and is arranged differently on the right and left sides and
in the middle.
The Right or Splenic Portion. — The peritoneum, after having lined the lower surface
of the diaphragm as far as the vertebral column, is reflected upon the posterior surface
of the vascular pedicle of the spleen, covers the posterior half of the internal surface of
that organ, its posterior border, the whole of its external surface, the anterior half of
its internal surface, and the anterior surface of its vascular pedicle, from which it is pro-
longed upon the great end of the stomach, and becomes continuous with the anterior
layer of the great omentum. The two layers which are applied to each other, one in
front of and the other behind the vessels of the spleen, constitute the gastro-splenic omen-
tum. Below the spleen, the peritoneum forms a horizontal fold, or septum, by which
that organ is separated from the viscera below it.
The Middle or Gastro-epiploic Portion. — In the middle the peritoneum lines the lower
surface of the diaphragm, as far back as the cardiac extremity of the oesophagus, is re-
flected over the anterior surface of the stomach (s), and descends into the abdomen in
front of the arch of the colon and the convolutions of the small intestine, to form the an-
terior layer (w) of the great omentum.
After descending towards the lower part of the abdomen for a distance, which varies
in different individuals and at different ages, it is folded backward upon itself, and passes
upward to form the posterior layer (o) of the great omentum. Having arrived at the con-
vex border of the arch of the colon (c), it covers the lower surface of that intestine, and
passes horizontally backward (q) to the anterior surface of the vertebral column, in front
of which it is again reflected, and becomes continuous with the right layer {m') of the
mesentery. The horizontal portion, which extends from the arch of the colon to the
vertebral column, forms the inferior layer {q) of the transverse mesocolon.
It follows, then, that the portion of the peritoneum which is continuous with that upon
the anterior surface of the stomach, forms below that organ a kind of bag, which has a
direct or descending layer, and a reflected or ascending layer, in the interval between
which are placed the stomach (s), the pancreas (p), the duodenum (d), and the arch of
the colon (e). We shall afterward find that each of these layers is lined internally by
another layer of peritoneum, so that the great omentum consists of four layers of serous
membrane.
The Right or Hepatic Portion. — On the right side the peritoneum is reflected from the
diaphragm upon the convex surface of the liver (/), and forms the coronary ligament of
the liver (at g), being continuous with the suspensory ligament, the direction of which
is at right angles to its ovm.
From the convex surface of the liver, the peritoneum is reflected over its anterior
margin, and then upon its concave surface, investing the gall-bladder, sometimes almost
entirely, but generally on its lower surface only. At the transverse fissure it is reflect-
ed downward in front of the vessels of the liver, and to the left of those vessels reaches
the lesser curvature of the stomach, and is continued upon the anterior surface of that
organ. That portion of the peritoneum which extends from the transverse fissure to
the lesser curvature of the stomach, constitutes the anterior layer (A) of the gastro-hcpatic
or lesser omentum. To the right of the vessels of the liver and to the right of the gall-
bladder, the peritoneum covers the lower surface of this viscus, and becomes directly
continuous with the portion which covers the right lumbar colon.
As the peritoneum is reflected from the diaphragm upon the right and left extremities
of the liver, it forms two folds, one on each side, called the triangular ligaments of the
liver.
The Foramen of Winslow and Sac of the Omentum. — Behind the vessels of the liver,
and under the anterior root of the lobulus Spigelii, is an opening which leads into a cav-
ity situated behind the stomach and the gastro-hepatic omentum. This opening is the
orifice of the omental sac, or the foramen of Winslow (in which a probe is placed in the
figure) ; the cavity is called the posterior cavity of the peritoneum, or the sac of the omen-
tum (i). The foramen of Winslow is semicircular, sometimes triangular in shape, and
about one inch in its longest diameter. It is bounded in front by the vessels of the liver,
behind by the vena cava inferior, below by the duodenum, and above by the neck of the
gall-bladder, or, rather, by the lobulus caudatus, or anterior root of the lobulus Spigelii,
these several parts being covered with peritoneum. Through this opening the perito-
neum enters the sort of pouch formed between the two layers of the great omentum.
In tracing the course of the reflected portion of the peritoneum, we shall commence
at this opening, and shall return without interruption to the same point. The perito-
neum is first applied to the posterior surface of the anterior layer of the gastro-hepatic
omentum already described, and forms the posterior layer (t) of that omentum ; it then
covers the posterior surface of the stomach ; below that organ it is applied (iv) to the
descending or anterior layer of the great omentum, behind and parallel to which it passes
down ; having arrived at the point where the anterior layer of the great omentum is re-
flected, the layer we are now describing is itself reflected (x) in the same manner, and
becomes applied to the anterior surface of the posterior layer of that omentum ; con-
THE PERITONEUM. 477
tinuing to ascend, it gains the convex border of the transverse colon, covers the upper
surface of that intestine, and, farther back, is applied to that layer of the great omentum
which is continued over the lower surface of the colon ; it thus forms the upper {y) of
the two layers of which the traiisverse mesocolon is composed. Having reached the
front of the vertebral column, it leaves the inferior layer of the transverse mesocolon,
covers the anterior surface of the third portion of the duodenum (d), the anterior surface
of the pancreas (f>), the lobulus Spigelii and the anterior part of the vena cava, and ar-
rives at the transverse fissure of the liver, opposite the foramen from which we began
to trace it.
It follows, therefore, that the great omentum, notwithstanding its thinness and trans-
parency, consists of four perfectly distinct layers, two of which, united together in front,
and two behind, constitute the parietes of a cavity called the posterior cavity of the peri-
toneum, or the sac of the omentum.
We may, however, describe the omentum in a different mode, as follows : Two lay-
ers of peritoneum applied to each other pass off from the transverse fissure of the liver,
separate along the lesser curvature of the stomach, in order to enclose that organ, again
unite along its greater curvature, then pass downward, and, opposite the brim of the
pelvis, are reflected backward upon themselves, and proceed upward. Having reached
the convex border of the colon, they separate to receive that intestine between them,
become reunited at its concave border to form the transverse mesocolon, and then sep-
arate finally. The inferior layer is reflected downward, to become continuous with the
right layer of the mesentery ; the superior is reflected upward, to cover the third portion
of the duodenum, the pancreas, and the lobulus Spigelii, and then becomes continuous
with the rest of the peritoneum at the foramen of Winslow.*
General Description of the Peritoneum. — From the preceding description, it follows that
the peritoneum forms a continuous membrane, so that, if it were possible to unfold all
its duplicatures, and to detach it entire from the surface of all the organs covered by it,
it would form a large membranous sac without an opening. Nevertheless, in the fe-
male there is a remarkable interruption at the point corresponding to the free extremity
of the Fallopian tube, in which situation we find the only example in the body of a serous
and mucous membrane being continuous with each other.
The peritoneum has two surfaces, an external and an internal. The internal surface
is free, smooth, and moist, and is the seat of an exhalant and absorbent process, which,
in the natural condition, exactly counterbalance one another.
The external or adherent surface lines the parietes of the abdominal cavity, covers most
of the abdominal viscera, of which it forms the external or common coat, and is in con-
tact with itself in the different folds formed by the peritoneum. The attachment of this
surface is effected by means of cellular tissue, the character of which varies in different
situations.
We shall examine the external surface of the portion of the peritoneum applied to the
abdominal parietes, or the parietal peritoneum ; of that upon the viscera, or the visceral
peritoneum ; and also of that forming the different folds.
The Parietal Portion of the Peritoneum. — ^Upon the diaphragm it is attached by a very
dense cellular tissue ; nevertheless, it may be torn off in dissecting that part. Upon the
anterior wall of the abdomen it adheres most strongly opposite the linea alba and the
sheath of the rectus muscle, and more loosely opposite the crural arches than in any
other part. Still, it is not very difficult to separate the whole of the membrane correspond-
ing to the parietes of the abdomen. In the lumbar region the adhesion is extremely
loose, and also in the iliac fossae on the front of the vertebral column : the same is the
case in the cavity of the pelvis.
The cellular tissue on the outside of the peritoneum, which most anatomists have re-
garded as forming the external tissue of that membrane, sends prolongations through
the numerous openings with which the walls of the abdomen are perforated. These
prolongations connect the sub-peritoneal cellular tissue with that of the lower extremi-
ties on the one hand, and with the cellular tissue external to the pleura on the other.
The peritoneum is supported throughout by a fibrous layer, and this accounts for the dif-
ficulty with which abscesses of the abdominal parietes open into the cavity of the peri-
toneum.
The Visceral Portion of the Peritoneum. — Among the viscera of the abdomen some re-
ceive a complete investment from the peritoneum, always excepting the point at which
their vessels reach them ; to this class belong the spleen, the stomach, and the small
intestines. Others have a less complete covering, so that a portion of their surface is
in immediate relation with surrounding parts : of this number are the ascending and de-
scending colon and the caecum. Lastly, others have only very slight relations with the
peritoneum, which merely pass over them, and do not appear to enter into their forma-
* In many subjects the existence of the sac of the omentum may be demonstrated by introducing a large
catheter into the foramen of Winslow, and by blowing carefully through it ; the air will enter between the
two anterior and the two posterior layers of the great omentum, and form a large and more or less regular
'iladder. For this experiment to succeed, the omentum must be parfectlv uninjured, and free from adhesions.
478 SPLANCHNOLOGY.
tion : to this class belong the bladder, the lower part of the rectum, the pancreas, the
two lower portions of the duodenum, and the kidneys. To the last-named organs the
peritoneum is connected only by very loose cellular tissue.
The visceral portion of the peritoneum is not strengthened by the fibrous layer met
with in its parietal portion, and, therefore, perforation of the serous coat of the viscera
is much more common than perforation of the parietal portion of the serous membrane.
The Folds of the Peritoneum. — Among the folds of the peritoneum, most of which have
been already described, and which need be only recapitulated here, some bear the name
of ligaments, viz., the triangular, coronary, and falciform ligaments of the liver, the pos-
terior ligaments of the bladder, and the broad ligaments of the uterus.
Others are called mesenteries, viz., the mesentery, properly so called, or the mesentery
of the small intestine, the transverse mesocolon, the right and left lumbar mesocolon
when they exist, the ihac mesocolon, and the mesorectum. With these we should in-
clude the duplicature extending from the transverse fissure of the liver to the lower cur-
vature of the stomach, and known as the lesser omentum ; it really constitutes the me-
sogastrium.
Lastly, there are certain folds, named omenta or epiploa {em, upon, n?Ju, to float), viz.,
the great, or gastro-colic, small, or gastro-hepatic, gastro-splenic, and colic omenta.*
With this class we may connect the appendices epiploicae. It may be well to make a
few observations upon the great and lesser omenta.
The Great Omentum. — The great or gastro-colic omentum, so called because it is at-
tached, on the one hand, to the stomach, and on the other to the colon, scarcely exists
in the new-born infant ; it is gradually developed as age advances, and about the period
of the termination of growth it reaches to the brim of the pelvis. It has been remarked
that it descends a little lower on the left than on the right side.
When the stomach and the colon are distended, this omentum is reduced to a more or
less narrow border extending along the arch of the colon.
It presents also a number of individual varieties : sometimes it is very regularly sus-
pended in front of the intestinal convolutions ; sometimes it is folded upon itself, and
carried to one side or the other ; occasionally it adheres at some point, becomes stretch-
ed hke a cord, and may then give rise to strangulation ; and, lastly, it is not very rare to
find it turned upward and backward between the diaphragm above and the stomach and
liver below.
It is so transparent and thin that it is difficult to conceive it to be formed of four lay-
ers. In some individuals it is even perforated with holes like a piece of lace. The
great omentum is found, in very fat persons, to be loaded with an immense quantity of
adipose tissue, deposited chiefly along the vessels ; so that it may acquire a very con-
siderable size, and a weight of several pounds.
The great omentum has an anterior and posterior surface, both of which are free, an
upper adherent border, a lower border, free, convex, and more or less sinuous, which cor-
responds with the crural arches, and the internal openings of the inguinal canals ; it is,
therefore, very often found in hernial sacs.
The lower border is more liable to adhesions than any other part of the omentum.
The lateral borders have nothing remarkable ; they proceed parallel to the ascending and
descending portions of the colon, which are sometimes covered by them.
The arteries of the great omentum are furnished by the right and left gastro-epiploic
arteries ; they descend vertically between its two anterior layers, scarcely diminishing
in caliber. At its lower border they turn upward, and ascend between the two posterior
layers as far as the arch of the colon, where they communicate with the arteries of that
intestine.
The veitis follow the same course as the arteries, and assist in forming the vena portee.
Some lymphatic glands are found in the great omentum along the curvatures of the
stomach and the arch of the colon.
Nerves. — Some nervous filaments from the solar plexus can be traced upon the arter-
ies of the omentirai ; it is doubtless from them that the epiploon derives its peculiar sen-
sibility, and on them that the phenomena of strangulation depend when it is constricted
in a hernia.
The uses of the omentum are not known.
The Lesser Omentum. — The lesser omentum, a true mesentery, the mesogastrium, pre-
sents a lower concave border, attached to the lesser curvature of the stomach, and an
upper border, attached to the transverse fissure of the liver, to that part of the antero-
posterior fissure which is behind the transverse fissure, and also to the oesophagus and
the diaphragm ; its right border contains the ducts and vessels of the liver, and behind
the border thus formed is seen the foramen of Winslow ; on the left it is bounded by the
cesophagus.t
' [The colic omentum consists of two layers of peritoneum, with intermediate vessels and fat, which de-
scend, behind the great omentum, from the upper part of the ascending colon.]
t [The cellular tissue surrounding the vessels, ducts, and nerves, contained between the layers of this small
omentum, has been described as giving origin to Glisson's capsule.]
THE HEART. 479
IStruetin-e of the Peritoneum. — ^The peritoneum, like all other serous membranes, has
neither arteries, veins, nor nerves. Those which are contained within the omenta and
the mesentery do not properly belong to this membrane. The finest capillary injections,
either natural or artificieil, form an extremely delicate network below the peritoneum,
but never penetrate it.*
ANGEIOLOGY.
Definition and Objects of Angeiology.
Angeiologt {ayyelov, a vessel) is that division of anatomy which treats of the orgauL
of the circulation.
The circulating system consists of a central organ, the heart, the agent for propelling
the blood ; of the arteries, vessels through which the blood is conveyed from the heart
to all parts of the body ; of the veins, through which the blood is returned from all parts
of the body to the heart again ; and, lastly, of the lymphatic vessels, appendages of the
venous system, into which their contents are ultimately poured.
THE HEART.
General Description. — External and Internal Conformation. — Structure. — Development. —
Functions. — The Pericardium.
Dissection. — In order to study the external conformation of the heart, inject the cavi-
ties of the right side of that organ by the pulmonary artery, or by one of the venae cavae,
taking care to tie the other ; the cavities of the left side may be filled from the aorta, or
one of the pulmonary veins.
Tallow, wax, and glue-size are the most suitable materials for this purpose.
The heart {Kapdia), the central part of the circulating apparatus, is a hollow muscular
organ, divided into several compartments, and intended for propelling through the arter-
ies into all parts of the body the blood which is poured into it from the veins.
The heart is one of the most important organs in the body. In a zoological point of
view, the presence or absence of a heart, and the complexity or simplicity of its struc-
ture, deserve particular attention, because such variations in regard to the central organ
of the circulation are accompanied by very great modifications in the entire organism.!
Congenital absence of the heart is extremely rare, and is always accompanied with
other malformations, more especially with absence of the brain. These deficiencies are
incompatible with life.
Number. — Man and vertebrated animals have only one heart ; in moUusca it is double,
or even triple. This plurality of hearts, instead of being an index of perfection, should
be regarded as a subdivision, and less perfect condition of the organ. We shall see that
man, as well as mammalia and birds, has, in reality, two hearts united into one.
Situation. — The heart is situated at the junction of the upper third with the lower two
thirds of the body ; hence the upper parts of the system are more immediately under the
influence of this important organ, t
The heart (/, fig. 170 ; o,fig. 171) occupies the middle of the thoracic cavity ; it is sit-
uated in the mediastinum, in front of the vertebral column, behind the sternum, which
forms a kind of shield for it, and beyond which it projects on the left side ; it is placed
between the lungs, and above the diaphragm, by which it is separated from the abdom-
inal viscera.
It is retained in this situation by the pericardium (p p,fig. 170), a fibro-serous cover-
ing, which is itself closely adherent to the diaphragm (x) ; by the pleurae {q q), which are
reflected on each side of it, to form the parietes of the mediastinum ; and, lastly, by the
great vessels which pass out or enter at its base.
* [The basis of the peritoneum is cellular tissue ; its smooth surface is covered with a squamous epithelium.]
t Vertebrata and mollusca are the only animals which are provided with a heart. Mammalia and birds
alone possess a double heart, i. e., a heart with two auricles and two ventricles. Fishes and reptiles have a
simple heart, t. e., a heart with only one auricle and one ventricle, this ventricle being pulmonary in fishes,
and both systemic and pulmonary in reptiles.*
t The distance from the heart to the brain varies in different individuals, according to the length of the tho-
rax and the neck. This difference may amount to two inches, and may exercise some influence upon the cere-
bral circulation. In consequence of this observation, extreme shortness of the neck has been regarded as a
predisposing cause of apoplexy.
* [A central pulsating vessel is found in some of the higher radiata, and in the articulata ; in some of the
latter it constitutes a strong muscular ventricle, but the addition of a systemic auricle to this ventricle is first
observed in the mollusca ; in the invertebrata, generally, the ventricle is entirely systemic : in the higher ce-
phalopods there are two branchial hearts. In fishes the heart consists of a systemic auricle and a pulmonary
ventricle, and is preceded by a sinus venosus, and followed by a bulbus arteriosus. In the early condition of
the batrachia the same conformation exists ; but in their adult state, and also in all reptilia, there are two
auricles and one ventricle, the additional auricle being pulmonary, i. e., receiving the blood from the lungs.
In the higher reptilia, the single ventricle, which is both systemic and pulmonary, is divided by an imperfect
leptura ascending from the apex of the heart. In the crocodilus lucius, as well as in birds and mammalia,
this interventricular septum is complete, so that in them the heart is divided into two auricles and two ventri-
cles, the cavities of one side being systemic, and of the other pulmonary.]
ANGEIOLOGY.
These means of attachment are not such as to prevent the heart from undergoing re
markable changes of position, depending upon peculiar attitudes, upon shocks acting on
the body, or upon diseases of the surrounding organs. Thus, in a case of hydrothorax
on the left side, the apex of the heart struck against the right side, and gave rise to the
suspicion that the viscera were transposed.
Size and Weight. — Neither the size nor the weight of the heart can be estimated with
exactness, on account of the numerous individual varieties in both. It is very difficult to
determine the limits, in either the one or the other, between a healthy and a morbid con-
dition ; and a heart which would be considered normal in one individual would be re-
garded as hypertrophied in another.
The defects of the method proposed by Laennec for obtaining an approximative esti-
mate of the size of the heart, by comparing it with that of the closed hand of the samo
subject, afford sufficient evidence of the difficulty of arriving at an accurate result in this
matter.*
No organ in the body is more subject to enlargement than the heart ; when caused by
dilatation of the cavities, it constitutes aneurism of the heart {dilatation) ; when due to
thickening of the parietes, it is termed hypertrophy. When enlargement occurs from
both these causes, the heart acquires an enormous size, and has been called bullock's
heart (hypertrophy with dilatation).
The size of the heart may be estimated directly by ascertaining the quantity of water
displaced by it, and by admeasurement ; it may also be determined, in an approximate
manner, by its weight, which bears a certain relation to the size.
In making these estimates, it is necessary to distinguish the size and weight depend-
ant upon thickness of the parietes of the heart, from the increase occasioned by blood
contained in its cavities. In order to obtain comparative results upon this point, the
heart must be weighed and measured both in its empty and its distended state. The
average weight of the empty heart is from seven to eight ounces. Some atrophied hearts
do not weigh more than two ounces : dilated and hypertrophied hearts, when empty,
may weigh twenty-two ounces. The ordinary weight of the heart distended with tal
low is twenty-four ounces. I have seen dilated hearts, also, filled with tallow, which
weighed three pounds.
As to the admeasurement, we shall apply it in succession to the ventricles and to the
auricles.
Form, Direction, and Divisions. — The heart has the form of a flattened cone, the axis
of which is directed obliquely from above downward, from the right to the left side, and
from behind forward. This direction, which is peculiar to the human species (for in the
lower animals the heart is vertical), appears to have some relation to the erect position.
The heart is not symmetrical in reference to the median line of the body, nor yet in re-
gard to its own axis.
The general relations of the heart will be indicated when we describe the pericardium.
I shall here simply state that the heart is in relation with the left lobe of the lungs, which
is deeply notched to receive it ; that that portion of the heart which is uncovered in front
between the lungs, after the sternum and the ribs have been removed, is extremely vari-
able in different subjects ; that independently of the volume of the heart, the adhesions
of the lungs exercise a very great influence upon the extent of these direct relations of
the heart with the anterior part of the sternum. In an old woman, whose lungs were
closely adhering to the walls of the thorax, the anterior face of the heart was almost en-
tirely bare behind the sternum and the cartilages of the ribs on the left side.t That the
posterior face of the heart deserves the name of vertebral surface just as well as that
of diaphragmatic surface ; that this surface occasions a marked impression upon the liv-
er ; that the relations of the posterior surface of the heart with the oesophagus are such
as will cause the distended oesophagus to raise the corresponding portion of the pericar-
dium, and that the posterior surface of the heart is not only separated from the vertebral
column by the oesophagus, but also by the aorta, which is situated between the oesopha-
gus and the bodies of the dorsal vertebrae.
The heart is divided into ventricles and auricles. The ventricles (Jt o,figs. 191, 192)
constitute the chief part, in some measure the body of the organ, the conical form of
which is determined by them ; the auricles (m n) are a kind of appendices, which can be
well seen only when the heart is raised ; they occupy the base of the organ ; the limit
between the auricles and the ventricles is indicated by a circular furrow.
External Conformation of the Heart.
The External Surface of the Ventricles.
The external surface of the ventricles, or the ventricular portion of the heart, called also
* The large hand of a workman does not imply the existence of a larger heart than the small hand of a fe-
male, or of a man exempt from manual labour.
t The heart descends as far as the middle portion of the xiphoid appendix. The upper half of this appendix
is, therefore, in direct relation with the heart, and the inferior half in direct relation with the liver. Should
not this circumstance be of some weight in explaining the acute pains by which a pressure upon this appendix
u accompanied ?
THE HEART. 48'!
by the ancients the arterial portion, because the arteries arise from it, presents for our
consideration an anterior and an inferior surface, a right and a left border, a base and an
apex.
The anterior or sternal surface {Jig. 191) is convex, and is divided into two unequal
parts, a larger on the right, and a smaller on the left side, ^^ 191_
by the anterior furrow of the heart (e b), which passes verti-
cally from the base towards the apex, is occupied by the an-
terior coronary artery, and is often obscured by fat. All
that part of the organ which is to the right of the furrow be-
longs to the right ventricle (I), all on the left belongs to the
left ventricle (o). The furrow itself corresponds to the sep-
tum between the ventricles.
This surface, or, rather, the pericardium which covers it,
is in relation with the sternum, more especiedly in that part
which hes to the right of the furrow ; also with the fourth,
fifth, and sixth costal cartilages of the left side, and with the
lungs, which cover it more or less completely. It should
be remarked that, in large hearts, this surface, or its peri-
cardium, corresponds immediately to the sternum, while in
the natural state it is situated at some distance from that
bone. The relations of the heart with the anterior wall of
the thorax enable us to examine its condition by means of
percussion and auscultation.
The inferior or diaphragmatic surface {fig. 192) is plane and horizontal ; it rests upon
the diaphragm, which forms a sort of floor for it, and separates it from the hver and the
stomach. Like the anterior surface, it is marked by a longitudinal furrow, the posterior
furrow of the heart {e i), which is traversed by vessels and concealed by fat. It differs
from the anterior furrow in running parallel to the axis of the heart, and dividing its
diaphragmatic surface into two nearly equal parts, excepting near the apex. In conse-
quence of the relations of this surface, pidsations are observed in the epigastrium, which
are sometimes much more distinct than those felt upon the anterior wall of the thorax.
Another result of these relations is, that the same meaning is attached to the terms
scrobiculus cordis and pit of the stomach, and also to the expressions pain at the heart, pain
at the stomach, 4-c.
The right or lower border is thin and horizontal, and rests upon the diaphragm ; it is
straight near tlft apex, but becomes convex towards the base. The left border (o b, fig.
191) is very thick, convex, and almost vertical; it resembles a surface rather than a
border, and corresponds to the left lung, which is deeply notched to receive it.
The base of the ventricular portion of the heart is turned upward, backward, and to the
right side. From it arises, upon an anterior plane, an artery, which immediately passes
from the right to the left ; this is the pulmonary artery {k) ; the portion of the ventricle
from which it proceeds forms a prominence on the right side of the anterior furrow of
the heart, and is prolonged towards the left, becoming narrower at the same time, so as
to form a funnel-shaped projection {infundibulum, conus arteriosus) {a), extending a little
beyond the base of the ventricles. Upon a second plane we find the aorta (/), the origin
of which, from the left ventricle, is concealed by the funnel-shaped prolongation of which
we have just spoken. On a third plane we find a circular furrow (o u, fig. 195), separa-
ting the auricles from the ventricles. Its posterior half is occupied by the coronary ar-
teries and veins, and the anterior and posterior furrows of the heart terminate in it at
right angles.
This circular furrow at first sight appears to be superficial, but is very deep in its pos-
terior half If we dissect carefiiUy down to the bottom of this furrow, it is found that
the base of each ventricle is, as it were, turned inward, so as to be in contact by a broad
surface with the base of the auricle. We find, also, that the base of the ventricles is cut
obUquely, and hence the anterior surface of the heart is longer than the posterior surface.
The difference in length between these two surfaces is about fifteen lines upon the right,
and from nine to ten Unes upon the left ventricle. Thus, in a heart of the ordinary size,
the length of the ventricles in front was three inches three lines, and behind two inches
three lines. In a very large heart the length in front was four inches, and behind only
three. The circumference of the base of an injected heart, of the average size, measured
ten inches ; that of a large heart was thirteen inches six lines.
The apex {h) or point of the heart is slightly curved backward in the majority of sub-
jects, and is notched opposite the junction of the two longitudinal furrows. This notch,
which is partially concealed by vessels and adipose tissue, divides the apex of the heart
into two unequal portions ; a right and a smaller, belonging to the right ventricle, and a
left and larger portion, belonging to the left ventricle. The relative size of the two por-
tions of the apex of the heart is not constant. In some cases of hypertrophy of the left
ventricle, the apex of the heart is entirely formed by it ; in other cases, on the contrary
the apex of the heart is nearly equally subdivided.
Ppp
482 ANOEIOLOGY.
The apex of the heart is directed forward, downward, and to the left, and corresponds
to the cartilages of the fifth and sixth ribs of the left side, and therefore to the region of
the corresponding mamma ; the left lung is notched opposite the apex of the heart, so
that the latter strikes directly against the parietes of the thorax.
The External Surface of the Auricles.
The attricles (m n,figs. 191, 192), forming the auricular portion of the heart, are saccular
cavities in which the veins terminate ; they may, in fact, be regarded as dilatations of
those vessels, and hence this portion of the heart is called the venous portion, in contra-
distinction to the ventricles. They are situated upon the hindermost portion of the
base of the heart (fig. 192).
Their size varies in different individuals ; in an injected heart, the average height of
the auricular portion is two inches ; its antero-posterior diameter is nearly the same ;
and when the auricles are distended, its transverse diameter extends beyond the tcl
tricles on each side.
The shape of the auricular portion of the heart, which can only be accurately deter
mined by means of injection, is irregularly cuboid. It therefore presents several sur
faces ; its anterior surface is situated on a plane much farther back than that of the front
of the ventricles {fig. 191). It is concave, and describes three fourths of a circle, so as
to embrace the aorta and the pulmonary artery, being moulded upon those vessels, and
completely concealed by them. The anterior surface of the auricular portion has no
anterior furrow along the middle line.
The posterior surface (fig. 192) is convex, and is continuous with the inferior surface
of the ventricles ; it presents a vertical furrow, which is
prolonged upward from the posterior furrow of the ventri-
cles, then deviates to the left side, and forms a curve, the
concavity of which is directed towards the right ; it corre-
sponds to the septum of the auricles. Immediately to the
right of this furrow we find the termination of the vena cava
inferior (r), and lower down, that of the great coronary vein.
The posterior surface of the auricles is turned towards the
vertebral column, from which it is separated by the oesopha-
gus and the aorta.
The superior surface of the auricular portion forms the
highest part of the heart, and is directed backward and to-
wards the right side. It is divided by a furrow, which is
convex on the right side, is continuous with the furrow upon
the posterior surface, and, like it, corresponds to the inter-
auricular septum. Upon this surface we find the termina-
tions of five different veins ; one only of these is to the right
of the furrow, viz., that of the vena cava superior (d,fig. 191) ; the other four are on
the left of the furrow, and are those of the four pulmonary veins, which are arranged in
pairs (c c,fig. 192), two at the extreme left of the auricles belonging to the left pulmona-
ry veins, and two immediately in the neighbourhood of the posterior furrow belonging to
the right pulmonary veins. This surface corresponds to the bifurcation of the trachea,
which, as it were, rides upon it.
The extremities of the auricles, or the aurievJee, are free, and somewhat resemble the
pendulous portion of a dog's ear ; hence the term auricles. They are indented like a
cock's comb ; the right auricula is anterior, the left posterior.
The right auricula {c,fig. 191) is broader and shorter than the left ; it is triangular and
concave, so as to embrace the aorta, in front of which it projects ; the left auricula (i) is
narrower and longer, it is sinuous, and curved twice upon itself like an italic S ; it em-
braces the pulmonary artery, and terminates opposite the highest part of the anterior fur-
row of the ventricles.
The right auricula is continuous with the rest of the corresponding auricle, vdthout
any well-marked line of separation ; but the left auricula is very distinct from its auricle ;
and upon this latter side, the distinction pointed out by Boerhaave, between the sinuses
and the auricles properly so called, may be particularly observed : according to him, the
sinus constitutes the body of the auricle, and may be regarded as a dilatation of the veins,
while the auricular appendix forms the proper auricle.
The Internal Conformation of the Heart.
The heart is divided internally into four cavities, which are separated from each oth-
er by complete or incomplete septa ; two of these cavities belong to the auricles, and two
to the ventricles. There are a right ventricle and auricle, and a left ventricle and auri-
cle. The auricle and ventricle of the same side are separated by incomplete septa or
valves, and communicate with each other. The cavities of the opposite sides are sep-
arated by complete septa, and do not communicate. Tlie heart is therefore, in this lat-
ter respect, truly double. The right ventricle and auricle constitute the right heart, also
THE HEART. 4^
named the cmur d. sang noir, from the colour of the blood which it contains ; and the pul-
monary heart, because it propels the blood into the lungs. The left ventricle and auricle
constitute the left heart, called also the caur a sang rouge, or the aortic heart, because it
throws the blood into the aorta.
The Internal Conformation of the Ventricles.
Dissection. — In order to obtain a general idea of the internal conformation of the heart,
make a series of sections at right angles to its length, or else make an incision along its
borders parallel to its long axis.
To obtain a more exact notion of the ventricles, make a V-shaped incision in the right
ventricle, letting one branch of the incision extend along the anterior furrow, and tte
other along the right border, while the angle at which they meet should correspond to
the apex of the ventricle.
The best method of opening the left ventricle consists in making a vertical section
through the septum ; but in doing this, the right ventricle must be sacrificed.
In order to obtain a general view of the appearance of these cavities, they may be pre-
pared in the dried state. For this purpose, the heart is to be injected with tallow, and
then, after being dried sufficiently, to be opened in the manner above described, and im-
mersed in warm turpentine, which will dissolve the tallow,and leave the ventricles dilated.
Interior of the Right Ventricle.
The right ventricle occupies the right anterior and inferior portion of the heart, and has,
therefore, been called the anterior or the inferior Fig. 193.
ventricle. Its cavity (Jig. 193) has a three-sided
pyrjunidal form. Its inner wall (6) is convex, and
is formed by the septum of the ventricles ; in its
lower half it has a well-marked reticulated appear-
ance, which is almost entirely absent in the upper
half (a). The anterior and inferior walls (partly re-
moved in^. 193) are both concave, and are re-
markable for their thinness, so that they are al-
ways collapsed when the ventricle is empty. The
base of this ventricle presents two openings, which
are separated from each other by a projecting part,
and which may be compared to the wide circular
end, and the narrow mouthpiece of a huntsman's
horn. The opening into the auricle (in which a
bristle is placed) corresponds to the wide end of
the horn, and the infundibulum (a) to the narrower
end. The transverse diameter of the base of this
ventricle is nearly equal to its height. The sum-
rait (Z) is turned towards the apex of the heart.
The walls of the right ventricle are very remark-
able for their reticulated or areolar character ; this
areolar portion might be termed the corpus cavernosum of the heart, for it presents the
spongy structure of the erectile tissues. The fleshy columns which form the areolae are
observed not only upon each of the walls of the ventricle, but they also pass across the
cavity of the ventricle near its summit, extending from one wall to the other ; in conse-
quence of which the capacity of the ventricle is singularly diminished.
The cylindrical fleshy columns {columnce carnece, teretes lacerti), which separate the
meshes or areolae, are of three kinds. Some (c) are attached to the parietes of the heart
by one of their extremities, and are free in the rest of their extent ; they terminate by a
kind of simple or double meimmillated projection, from which proceed small tendinous
cords {chorda tendinem), that are inserted into the auriculo-ventricular valves (c). They
are very few in number, and have been named the muscles of the heart {musculi papillares).
The fleshy columns of the second kind are free throughout the whole of their extent, ex-
cepting at their extremities, which are attached to the walls of the ventricle. These col-
umns, which are the most numerous, are divided and subdivided to form the areolae. The
third kind of columnae carneae adhere to the walls of the ventricle by one of their sides ;
they are therefore sculptured like pilasters upon the walls of the ventricle.
Most of the colmnnae carneae pass from the apex towards the base of the heart. In
all their free portion, the columns of the two first kinds are attached to each other or to
the walls of the ventricle, by means of small tendinous cords, which are much more deli-
cate than those proceeding to the valves. The areolar muscular structure just described
is the essential constituent of the walls of the ventricle ; but in addition to it there is a
rather thin, compact, and non-reticulated layer of superficial fibres, on which depends
the smooth appearance of the external surface of the ventricle.
The Orifices of the Right Ventricle. — At the base of the right ventricle there are two
orifices, one auricular, which establishes a communication between the ventricle and the
ANGEIOLOGY.
auricle ; the other arterial, which leads into the pulmonary artery. They are both fur-
nished with valves.
The right auricular or auriculo-ventricular orifice (through which the bristle is inserted,
Fig. 194. fig. 193) is placed at the posterior and right part of the base of
the ventricle ; it is elliptical, and is provided with a mem-
branous structure, called the tricuspid or triglochin valve (c),
which projects into the interior of the ventricle. This valve
is of an annular form (annulus valvulosus). Its ventricular sur-
face {t 1 1, fig. 194) is directed towards the parietes of the ven-
tricle, and receives a great number of small tendinous cords,
which, being attached to it at different points, give it an ir-
^ regular aspect. Its auricular surface {t t t,fig. 195), which is
turned towards the axis of the ventricle, is smooth. The ad-
herent border is fixed to the margin of the auricular orifice.
The free border or margin forms a ring, the diameter of which is equal to that of the
.gg adherent border : this margin is irregularly divided, so that, in-
''^' ■ stead of the three segments {t 1 1) generally described, and from
which the name of the valve has been derived {rpelc, tres, three,
and y^uxk, cuspis, a point), some authors admit four, or even
six segments.
The construction of the tricuspid valve can be understood
only by regarding it as composed of two parts, an anterior, cor-
responding to the anterior half of the elliptical auriculo-ventric-
ular orifice, and a posterior, corresponding to the posterior
half of the same. The tricuspid valve is not unfrequently in-
terrupted on the left side opposite the junction of these two
valves. This valve might, with as much propriety, be termed mitral, as that which is
attached to the lefl auriculo-ventricular opening.
To the free margin of the valve, upon which some small nodules are occasionally
found, are attached a number of tendinous cords of a nacreous aspect, which are ex-
tremely strong considering their tenuity. These small cords, or, rather, tendinous fila-
ments, always arise in greater or less number from the summits of the columnae car-
nese ; diverging from thence, often bifurcating during their course, and sometimes be-
coming united together, they terminate, some at the free margin, others at the ventric-
ular surface of the valve, and others, again, at its adherent border.
All the smalll tendinous cords do not arise from the columnae cameas of the first kind ;
many of them proceed directly from the parietes of the heart. We constantly find a
fasciculus of diverging cords arising from the septum.
These cords are so arranged, that, by drawing upon them, the valve is depressed and
stretched. We find, in fact, that both in the anterior and posterior part of the tricuspid
valve, those cords which arise from the free margin on one side converge towards those
of the opposite side, some even crossing each other in the form of the letter X.
The arterial or pulmonary orifice {ostium arteriosum, d,fig. 194) is placed at the anterior
Fig. 196.
part of the left side of the base of the right ventricle. It is sep-
arated from the auricular orifice by a tolerably prominent mus-
cular band, which is concave on its lower surface, and divides
the right ventricle into two portions, an auricular and a puhno-
nary portion or infundibulum. This orifice is circular, and is
provided with three very distinct valves, which are named sig-
moid or semilunar {f,fig. 195 ; a a a, fig. 196).* Although thin
and semi-transparent, they are very strong. They are directed
vertically as the blood is passing from the ventricle into the
artery, and become horizontal when it tends to flow back from
the artery into the ventricle. Of their two surfaces, the ven-
tricular corresponds to the .cavity of the ventricle ; the other, or
arterial surface, includes between it and the walls of the artery
a small cul-de-sac, which has been compared to a pigeon's nest.
The adherent border of each valve is convex, and directed to-
wards the ventricle ; its free margin presents in the middle a
small nodule, by which it is divided into two semilunar halves.
When depressed, the valves completely close the vessel, the
three nodules filling up the triangular interval left between the approximated free mar-
gins. These valves must, therefore, oppose the reflux of the blood into the ventricle ;
but the resistance offered by them is easily overcome by an injection thrown into the
pulmonary artery.
Interior of the Left Ventricle.
The left ventricle occupies the left upper and back part of the heart ; it is evidently
* It is extremely rare to find any anomaly in the number of these valves, either by an increase or a dinu
BUtion of them.
THE HEART. 485
constructed upon the same fundamental type as the right ventricle, but difFers from il
in many respects, as we shall now proceed to show.
Difference in Situation. — The different positions of the two ventricles are sufficient-
ly known from what has already been stated ; but it is important to remark, that the
left ventricle projects beyond the other at the apex of the heart {fig. 197), while the
right is more prominent at the base, in consequence of the existence of the infundibulum.
Difference in Shape. — The right ventricle is pyramidal, and becomes collapsed when
not distended ; the left is conical and convex, not only on its free surface (6), but even
at the septum (a, fig. 194), where it seems to project into the interior of the right ven-
tricle.
Difference in Size. — It is generally stated, in accordance with Senac, Winslow, and
Haller, that the right ventricle is more capacious than the left : this statement is found-
ed upon direct observation, which proves that the right ventricle gains more at the base
than the left does at the apex ; also upon deductions made by comparing the right auri-
cle and the pulmonary artery with the left auricle and the aorta ; and, lastly, upon the
results obtained by injecting the cavities of the heart. No two observers agree as to
the exact numbers which would represent the capacities of the two ventricles, as the
following different estimates will show. The capacity of the left ventricle to that of the
right has been stated as 31 to 33, as 10 to 11, as 5 to 6, as 2 to 3, and as 1 to 2. — {Hol-
ler, t. i., 1. iv., sect. 3, p. 327 )
Now the discrepancies in these estimates prove either the deficiency of the methods
of observation, or the existence of real differences resulting from a greater or less amount
of accidental obstruction to the pulmonary circulation occurring shortly before death.
In the great majority of subjects, the right ventricle is proved to be more capacious than
the left, and this, according to the judicious remark of Sabatier, depends upon the state
of the circulation through the heart during the last moments of life, at which time the
blood flows back from the lungs into the right ventricle, while the left ventricle, not ex-
periencing a similar obstruction, and, moreover, acting with greater vigour, empties it-
self, more or less completely, of the blood contained within it. After death by decapita-
tion, the right ventricle is as much contracted as the left ; also, in individuals that
have died without any agony or exhaustion, the cavity of the left ventricle has been com-
pletely contracted.*
The condition of the heart, then, in the dead body, in which that organ is found as it
was at the moment of death, affords us no means of judging of the relative capacity of
its cavities during life. If, by tying the aorta in a living animal, we cause stagnation of
the blood in the left ventricle, while the exit of that fluid from the right cavities through
the pulmonary artery remains unimpeded, the relative capacity of the two ventricles will
be found to be exactly the reverse of what is generally indicated.
The gradual injection of the heart with wax or tallow, so as to distend the ventricles
without producing laceration, enables us to determine the size and the weight of the
mass of injection contained within each cavity of the heart, and also to measure these
cavities under similar conditions, that is to say, in a state of distension. From obser-
vations which I have made in this way, it appeared that the left ventricle was rather
more capacious than the right.
Difference in the Appearance of the Cavity and in the Structure of its Parietes. — In the
left ventricle we find the three kinds of columnas carneae. Of
the columns of the first kind there are only two (i i,fig. 197),
which are remarkable for their great size. Their summits are
almost always bifurcated, and sometimes they are divided into
three parts ; not unfrequently each of these columnae results
from the apposition of two or three others, which are united
by small fibrous cords or filaments.
The fleshy columns of the second kind are smaller in the
left than in the right ventricle. The areolar arrangement is
less strongly marked, and is observed only in the innermost
layer, excepting always at the apex, the whole thickness of
which, with the exception of the most superficial layer, pre-
sents the cavernous arrangement. Moreover, the areolae are
remarkable for their small size, and for the slenderness and
jiumber of the columnae by which they are surrounded. These
muscular areolae are often completed by fibrous cords.
Difference in Thickness. — The walls of the left ventricle are
much thicker than those of the right {figs. 193, 194, 197). The proportion of one to two,
arrived at by Laennec#is too slight ; it is one to four, or even one to five. It is gener-
ally said that the muscular tissue of the heart is more compact on the left than on the
right side.
* The concentric hypertrophy mentioned by authors appears to apply to ordinary hearts, or to hearts in «
state of hypertrophy, with their cavities closed, in conseqaence of the eontraction continuing to the last mo-
ment. I, therefore, am opposed to admitting concentric liypertrophy as a pathologioal state.
486 ANGEIOLOGY.
Difference in the Orifices. — The left auriculo-ventricular orifice (through which a bristle
is inserted, ^o'. 197) exactly resembles the right one, and, like it, is provided with a
valve {g) analogous to the tricuspid, and named by Vesalius the mitral valve, from its
being regularly divided into two opposite segments {mm, figs. 194, 195). The mitral
valve is stronger than the tricuspid, it is thick<|- and longer, and receives stronger and
more numerous chordae tendineae. These differences are more particularly observed in
the right segment of the mitral valve, which projects, like an incomplete septum, into
the cavity of the ventricle, and appears to divide it into an aortic and an auricular por-
tion ; the left segment of the valve {g,fig. 196), on the contrary, is applied against the
walls of the ventricle.
The aortic orifice {e,fig. 194) exactly resembles the pulmonary orifice of the right ven-
tricle ; like that opening, it is also provided with three sigmoid valves (e, fig. 195), which
differ from those of the pulmonary artery merely in being stronger, and in having larger
nodules or globules upon their free borders ; and, as Arantius admitted their existence
only in these valves, they are therefore called globuli, noduli or corpora Arantii.*
The right auriculo-ventricular and arterial orifices are placed at a" distance from each
other, but the corresponding orifices of the left side are contiguous, so that the adherent
border of the right half of the mitral valve is continuous with the adherent border of the
corresponding sigmoid valve ; and hence it follows, that when these valves are removed,
the base of the ventricle presents only one orifice.
Interior of the Jiuricles.
Dissection of the Right Auricle. — Make a horizontal incision from the auricula to the
inferior vena cava, and then a vertical one from the vena cava superior perpendicularly
to the first.
Of the Left Auricle. — ^Make a vertical incision from before backward, between the
right and left pulmonary veins, including the entire posterior wall of the auricle. In or-
der to have an accurate idea of the shape of the interior of the auricles, inject a heart
with tallow or wax, and then examine the cast thus taken of their cavities.
Interior of the Right Auricle.
The shape of the right auricle, when distended, may be compared to the segment of
an irregular oval, the long diameter of which is directed from before backward. It has
three walls : an anterior, which is convex ; an internal, which is slightly concave, and
corresponds to the septum ; and a posterior, also concave, which forms the greatest part
of the auricle, and is remarkable for the existence upon it of fleshy columns. The right
auricle has four orifices. in the adult, and five in the foetus, viz., the auriculo-ventricular
orifice, the opening of the vena cava superior, that of the vena cava inferior, that of the
coronary vein, and, in the foetus, the foramen ovale (trou de Botal), the situation of which
is occupied in the adult by the fossa ovalis.
The auriculo-ventricular wifice {see fig. 195), the largest of all, is of an elliptical form,
from sixteen to eighteen lines in its longest diameter, which is from before backward,
and about twelve lines in its shortest diameter. It is surrounded by a whitish zone
(a q), to which is attached the adherent border of the tricuspid valve {t 1 1). The cavity
of the auricle presents a sort of constriction opposite the auriculo-ventricular orifice.
The orifi.ce {h,fig. 193) of the vena cava superior {d) is circular, and is directed down-
ward and a little backward ; it has no valves ; it is bounded on the left by a projecting
muscular band, which separates it from the auricle, and on the right by a less prominent
band intervening between it and the vena cava inferior. The former of these two bands,
which are distinctly marked upon the cast of wax, separates the fasciculated portion of
the auricle from the non-fasciculated portion, which seems to be formed by an expansion
of the venae cavae.
The orifice (?) of the vena cava inferior (r) opens into the auricle, near the septum, not
perpendicularly upward, but horizontally, and at right angles to the original direction of
the vein, which is vertical. The orifice is circular, and larger than that of the superior
cava ; the inferior cava sometimes forms an ampulla or dilatation before it enters the
auricle ; us orince, unlike that of the superior cava, is provided with a remarkable semi-
lunar valve, the valvula Eustachii (n), which surrounds the anterior half, and sometimes
two thirds of this opening. Its free margin is concave, and directed upward ; its adhe-
rent border is convex, and directed downward : one of its surfaces is turned forward to-
wards ihe auricle, the other backward towards the vessel ; one of its extremities ap-
pears to be continuous with the margin of the fossa ovalis (*), and the other is lost upon
the margin of the opening of the inferior cava.
The valve of Eustachius closes the orifice of that vein very imperfectly. In its upper
two thirds it is extremely thin, and resembles the valves of the veins ; its lower third
contains a muscular fasciculus.
* The three sigmoid valves of the aorta are generally very similar in form ; in one case, however, which I
examined, one of these valves had twice the size of the others. I have lately observed, in a man of sixty, who
died of a disease of the heart, the rare sight of an aorta provided with only two sigmoid valves ; these two
mlves were very large, and ia relation with the diameter of the aortic orifice, which they covered completely
THE HEART. 487
The orifice of the coronary vein is placed immediately in front of the preceding, from
which it is separated by the Eustachian valve. It is sometimes situated at the bottom
of a small cavity or vestibule. It is provided with a very thin semilunar valve {valvula
Thebesii, below and behind the bristle), which exactly resembles the valves of the veins,
and completely covers the mouth of the vessel. The upper extremity of this valve is
continuous with the lower end of the Eustachian valve.
The Inter-auricular Orifice. — In the foetus, the inter-auricular septum is perforated be-
hind and below by an opening improperly called the foramen of Botal, for it was known to
Galen, who described a free communication between the auricles. After birth, we find
in the situation of the foramen ovale a fossa {fossa ovalis, vestigium foramims ovalis), or,
rather, a plane surface, which is generally smooth, but occasionally uneven, and, as it
were, reticulated ; it is bounded in front and above by a semicircular ridge or border (s),
which is improperly called the isthmus or annulusVieussenii, and may be regarded as a more
or less perfect sphincter. Behind, the fossa ovalis is continuous with the vena cava in-
ferior ; the semicircular ridge or border of the fossa ovalis is formed by a curved mus-
cular fasciculus, sometimes very thick, the concavity of which is directed backward ;
the inferior extremity of the fasciculus is continuous with the Eustachian valve.
The fossa ovalis is frequently found to be prolonged beneath the semicircular border
or annulus, so as to form a sort of cul-de-sac, the bottom of which is often perforated,
and the handle of a scalpel may not unfrequently be introduced through this opening
into the left auricle, although no morbid phenomenon may have been observed during
life.
The Fasciculated and Reticulated Portion of the Auricle. — Upon the internal surface of
the auricle, to the right of the vena cava, are observed certain muscular fasciculi or
fleshy columns (musculi pectinati auricula,), which are directed vertically from the auric-
ula towards the auriculo-ventricular orifice. These fasciculi adhere to the auricle on
one side only ; they are intersected by other oblique and smaller bundles, which give a
reticulated aspect to the inner surface of the auricle.
Cavity of the Auricula. — The auricula, or that portion of the auricle which extends
from the vena cava superior to the bottom of the appendix, consists of an areolar or cav-
ernous structure, exactly resembling that which has been described in the ventricles.
The same cavernous structure is found in other parts of the auricle, and in particulai
near the orifice of the coronary vein.
I agree with Haller* and Boyer, in denying the existence of the tubercle of Lower,
described by that anatomist as situated (at m) between the openings of the venae cavse.
It is generally admitted that a certain number of small veins open into the right auri-
cle by minute orifices without valves. We find, in fact, some openings resembling vas-
cular orifices, and known under the name of the foramina Thebesii ; they are constantly
found below the orifice of the vena cava superior, but most of them only lead into small
groups of areolae, and injections do not demonstrate the existence of any corresponding
vessels. The only true vascular orifices are those for the anterior coronary veins.
Interior of the Left Auricle.
The cavity of the left auricle (fig. 197) differs from that of the right in the following
circumstances : in being less capacious than the right auricle, the proportion between
them being four to five ; in its form, which is irregularly cuboid ; in the number of its
orifices, of which there are five after birth, and six in the fcetus ; in the character of
those orifices : thus the left auriculo-ventricular orifice (see fig. 195) is smaller than the
right ; its long diameter, which is transverse, is from thirteen to fourteen lines, its short
diameter is from nine to ten lines ; the four other openings belong to the pulmonary veins,
two (c) on the right, and two (c c) on the left side, and all are without valves ;t in the
structure of its auricula, which is perfectly distinct from the rest of the auricle, and con-
tains a central conical cavity, leading into the auricle by a well-defined circular open-
ing ; in the left auricle, nothing is seen on the septum corresponding to the fossa ovalis,t
at least we perceive neither band nor ring by which it is circumscribed. When the two
auricles communicate by an oblique passage, we find a very thin fibrous band, beneath
which the scalpel may be introduced into the right auricle.
Structure op the Heart.
The heart is essentially a muscular organ, and has a framework consisting of certain
fibrous rings or zones ; it is covered by a layer of serous membrane ; the left cavities
are lined by a membrane continuous with the internal coat of the arteries, and the right
* " Id tuberculum cupide receptum est, ut fere fit, ab iis scriptoribug quibus occasio ad propria experimenta
nulla est,deinde etiam abiis qui tandem omnin(Jiu corporibus humanis dissecandis se exercuerunt." — (Ualler
Elem. Phys., t. i., lib. iv., sect. 2, p. 314.)
t It is not uncommon to meet with five openings, three on the right and two on the left side ; in other cases,
the two left pulmonary veins open by a common orifice.
t [The situation of the foetal opening {a. Jig. 197) is very commonly indicated by a recess of variable depth
opening between the left surface of the septum and the (still free) crescentic border ofhbe valve of the fora-
men ovale.]
488 ANGEIOLOGY.
cavities by one continuous with the lining membrane of the veins.* Some nerves, prop-
er vessels, and cellular tissue, also enter into its structure.
The Framework of the Heart.
This term may be applied to foxxx fibrous zones (the tendinous circles of Lower), which
may be regarded as affording both origin and insertion to all the muscular fibres of the
heart. These zones are situated at the four orifices of the ventricles, viz., the two au-
riculo-ventricular and the two arterial orifices.
Dissection. — Remove with care the adipose tissue, and the vessels which occupy the
furrows of the heart. Examine the fibrous zones from the internal surface of the heart
In order to study the relations of the orifices with each other, remove the auricles, the
aorta, and the pulmonary artery, a little above those orifices.
The Auriculo-ventricular Zones. — Each auriculo-ventricular zone is a tolerably regular
fibrous circle, which surrounds the opening between the auricle and ventricle, and de-
termines its form and dimensions. These fibrous circles give off expansions of a sim-
ilar nature, which enter into the formation of the tricuspid and mitral valves, and thus
add to their strength. The chordae tendineae of the heart also terminate in these zones,
either directly or through the medium of the valves.
The left auriculo-ventricular zone is stronger than the right.
The Arterial Zones. — These are two circular rings, the diameter of each of which is
somewhat less than that of its corresponding artery, so that there are some very distinct
folds or wrinkles produced. These two zones are exactly alike in form, but differ some-
what in strength, the aortic being stronger than the pulmonary. From these zones are
given off three very thin but very strong prolongations, which occupy the angular inter-
vals formed by the indented border by which the aorta and pulmonary artery commence ;
and three other prolongations extend into the substance of the sigmoid valves. These
prolongations form very distinct fibrous bundles in the sigmoid valve of the aorta.t
Relative Position of t'he Orifices of the Ventricles (see fig. 195). — The two auriculo-ven-
tricular orifices are situated upon the same plane, posterior to the other orifices, and ap-
proach each other at their middle.
The long diameters of these two orifices are at right angles to each other : thus, the
long diameter of the right auriculo-ventricular orifice is directed from before backward,
while that of the left orifice is directed transversely.
In the angular interval left between these two orifices in front, the aortic opening (f)
is closely united to them both ; so that the posterior half of the circumference of the aor-
tic zone is blended with both auriculo-ventricular zones. At the point of junction be-
tween them, we find a cartilaginous, and in the larger animals a bony, arch, which was
described by the ancients under the name of the bone of the heart : in this situation, also,
we frequently find the ossiform concretions of the orifices.
Lastly, upon a plane in front and on the left of the aortic opening, and about five or
six lines above it, is situated the orifice (/) of the pulmonary artery.
The orifice of the aorta is directed towards the right side, that of the pulmonary ai-
tery towards the left, so that these two vessels cross each other, so as to represent the
letter X. It follows, therefore, that the pulmonary orifice is separated from the right
auriculo-ventricular opening by the orifice of the aor a.
In examining these openings, we observe that the plane of the auriculo-ventricular or-
ifices is directed obliquely backward and downward : this explains the difference in the
heights of the ventricles before and behind. We also notice the reflection or turning in-
ward of the base of each ventricle (q a, p b) upon itself, so as to form a circular groove
or trench on the inner surface of its cavity, running entirely round the margin of the cor-
responding auriculo-ventricular orifice.
The Muscular Fibres of the Heart.
The Muscular Fibres of the Ventricles.
Dissection. — The muscular fibres of the heart may sometimes be traced without any
preparation ; but, generally speaking, either commencing putrefaction, maceration in
vinegar, or, still better, hardening and separation of the fibres by means of alcohol, and
especially by boiling, are necessary for this purpose. This being done, remove first the
* [The muscular fibres of the heart, though involuntary, very closely resemble in structure those of the
voluntary muscles (see note, p. 194), but the transverse striae upon them are less distinct.
The lining membranes of the two sides of the heart are covered by epithelium, and form what is termed
the endocardium.'] ,
t I for a long time believed that the sigmoid valves, both the aortic and the pulmonary, were formed by
two prolongations of the internal membrane of the heart reflected upon itself ; but I have from pathological
facts lately the positive demonstration that each sigmoid valve was formed, 1st, by a prolongation of the in-
ternal membrane of the aorta ; 2d, by a prolongation of the internal membrane of the ventricle ; 3d, by an in-
termediate lamella occupying only the half of the height of the valve on the side of its adhering borde.i ; this
lamella is fibrous, and comes from the arterial zone. The half of the valve which is near the free border is
not furnished with this intermediate lamella. Now the arterial lamella may be affected independently of the
ventricular, and both Ijie arterial and ventricular lamellis may be injured independently of the intermediate
fibrous lamella which constitutes the foundation of these valves, since it gives them chiefly their power of re-
sistance.
THE HEART. 489
oater membrane, and then the different muscular layers one by one, taking care to fol-
low the fibres from their origin to their termination.
The most general formula which can be given respecting the structure of the ventri-
cles is, that this portion of the heart is composed of two muscular sacs, co7itained within a
third, which is commjon to both ventricles. We should add, that, when the superficial or
common fibres arrive at the apex of the heart, they turn up so as to pass into the interi-
or of the ventricles at that point, and form the deep fibres of these two cavities, so that
the proper fibres of each ventricle are situated between the direct and the reflected por-
tion of the common fibres.
We shall now enter into some details regarding these fibres.
All the muscular fibres arise from the fibrous zones, and they all terminate upon them,
as was clearly pointed out by Lower.* They do not consist of short fibres placed end
to end, but are of considerable length, descending in one part of their course, and as-
cending in the other. The muscular fibres are ranged in successive layers, which pass,
as it were, into each other. The muscular fasciculi of each layer are not distinct from
one another, but they mutually send off fibres, by which they are bound together like the
pillars of the diaphragm ; or it may be said that they intersect each other at very acute
angles ; it is, therefore, impossible to calculate the number of layers, which, according
to Wolff, are about three in the right ventricle and six in the left. All that we are able
to determine is, the different sets of fibres which enter into the formation of the heart,
and of these we find that there are two sets, one common, the other _pro^er fibres.
The Superficial Common Fibres. — All the superficial fibres are common to the two ven-
tncles, and all are oblique and curved ; they commence at the base of the heart, and
pass obliquely, in a spiral manner, towards the apex. All the superficial fibres of the an-
terior region of the heart pass from the right to the left side ; all those of the posterior
region from the left to the right side. There are neither vertical nor horizontal fibres in
the heart, as some authors have stated. The arrangement of the fibres at the apex of
the heart forms, as it were, a key to the stnicture of the entire organ. The anterior
and the posterior superficial common fibres both converge towards that point. Each of
these sets of fibres forms a very distinct fasciculus or band, and the two bands mutually
turn round each other in a semi-spiral direction, so that the anterior band is embraced
on the left side by the posterior, which is, in its turn, embraced by the anterior band on
the right side ; from the apex of the heart the fibres change their course, and instead
of descending, they ascend ; and instead of being superficial, they become deep-seated.
Having entered the heart at its apex, they continue to be reflected upward, and present an
arrangement which I shall describe after having explained the course of the proper fibres.
The Proper Fibres. — ^These are situated between the superficial or descending, and the
deep or ascending portion of the common fibres. They form in each ventricle a sort of
small barrel or truncated cone, which is applied to that of the opposite ventricle ; the su-
perior openings of these cones correspond to the auriculo- ventricular orifices ; while the
inferior, which are smaller, leave opposite the apex of the heart two considerable inter-
vals, which are filled up by the common fibres. Do these proper fibres turn round and
round without end, hke an uninterrupted spiral, as Senac was inclined to believe 1 It
appears to me that their extremities are attached to the auriculo-ventricular zones, and
that they describe more or less complete circles, which intersect each other at very
acute angles.
The Reflected or Deep Common Fibres. — The superficial common fibres are reflected at
the apex of the heart, and penetrate into its interior through the lower orifices of the
small barrels or cones, formed by the proper fibres. In this situation the anterior and
posterior bands, by being reflected upward, and mutually turned round each other, form,
at the apex of the heart, a sort of star with curved rays.
Nothing can be more evident than the reflection or turning up of the fibres ; it was
pointed out, thougn vaguely, by Vesalius, but has been most explicitly described by Ste-
no, who stated expressly that the external fibres enter the heart at the apex, and, assu-
ming an opposite direction to their former one, become the innermost layers, and who
compared the apex of the heart to a star. It was also described by Lower, who has ac-
curately figured a radiated structure at the summit of each ventricle ; by Winslow, who
says that the superficial fibres enter the heart at its apex ; and by Wolff and Gerdy, who
state that the fibres of the heart are twisted into a whorl or vortex.
From the turning back and the lateral twisting of the anterior and posterior bands, it
follows that, by removing the serous membrane which covers the apex of the heart, we
may, without injuring the fibres, penetrate into its interior at two points, one to the
right, and the other to the left of the anterior band.
The deep reflected fibres having thus reached the interior of the ventricles, pass on
the inner side of the proper fibres, and are arranged in three perfectly different modes :
thus, some form simple loops with the superficial portion ; others are arranged like the
thread of a screw, or the figure 8. and others constitute the columnae carneae.
* The same arTangement occurs in regard to the fibres of the auricles ; it follows, therefore, that the nxii»
cular fibres of the ventricles are not directly continuous with those of the auricles.
Qqq
490 ANGEIOLOGY.
The looped fibres, noticed by Winslow under the name of the bent or arched fibres, and
so well described by Gerdy, form, by their superficial and their deep portions, the opposite
walls of the ventricle : thus, the anterior superficial fibres constitute by their reflection
the deep layer of the posterior wall, while the posterior superficial fibres, after being re-
flected, form the deep layer of the anterior waU.
The fibres, arranged like the thread of a screw, or like the figure 8, with its lower ring ex-
tremely narrow, have been accurately described and even figured by Lower, and were
improperly rejected by Winslow, Senac, and others. The superficial portion of these
fibres exactly resembles that of the looped fibres, and are always twisted after their re-
flection, so that their deep portion belongs to the same wall as their superficial. Thus,
those fibres whose superficial portion belongs to the anterior wall of the ventricle, assist
in forming the same wall by their deep portion.
The columnce, carnea of the heart are formed by a certain number of fibres reflected in
loops, or like the figure 8.
Such is the arrangement of the muscular fibres of the ventricles.*
The Muscular Fibres of the Auricles.
The auricles, like the ventricles, have common and proper muscular fibres. There is only
one fasciculus of common fibres ; it occupies the anterior surface of both auricles, and
extends transversely from the right to the left auricula. The proper fibres constitute a
very thia muscular layer for each auricle ; they all commence and terminate at the cor-
responding ventricular zone.
The Proper Fibres of the Left Auricle. — The muscular layer in this auricle is continuous
and uniform, and not areolar. It consists of circular fibres, which occupy the neighbour-
hood of the auriculo- ventricular orifice, and all the anterior region of the auricle ; and of
oblique fibres, also arising from the auriculo-ventricular orifice, and divided into several
very distinct loops. One circular loop passes between the auricula and the left pulmo-
nary veins ; a second forms a vertical zone, interposed between the right and left pulmo-
nary veins ; it is very broad, and occupies the entire interval between the veins of the
right and left side ; a third and a fourth, very small, are interposed between the two pul-
monary veins of each side. These fasciculi, by changes in their direction, become adapt-
ed to the circular form of the orifices, and constitute true sphincters. It would appear
that, besides these bundles, there are some proper circular fibres around each orifice.
The Proper Fibres of the Right Auricle. — In the right auricle the fleshy fibres do not
form a continuous layer. This auricle may be regarded as consisting, in the first place,
of a non-muscular portion, which may be called the confluence of the vence cavce {sinus ve-
nosus) ; in it there is only one small muscular bundle, situated immediately to the right
of the orifice of the vena cava superior ; and, secondly, of a muscular portion, which re-
sembles a sort of grating, and is comprised between two fasciculi, one a circular bun-
dle, surrounding the auriculo-ventricular orifice ; the other a very prominent semilunar
bundle, interposed between the vena cava inferior and the auricula, and forming a ver-
tical, or, rather, an oblique arch, which terminates to the right of the inferior cava.
Muscular Fibres of the Auricula. — The walls of the left auricula present a cavernous
or areolar structure, in the middle of which we see a central canal, which opens into the
anterior of the auricle by a distinct orifice. There is not, in general, any central canal in
the right auricula, but only an areolar or cavernous structure.
The muscular fibres of the inter-auricular septum form a muscular ring for the border
of the fossa ovalis (so incorrectly termed the isthmus or annulus of Vieussens), which
must be regarded as a true sphincter, consisting of two thirds, three fourths, or even an
entire circle. The fibres of which it is formed arise from the auriculo-ventricular ori-
fice, near the septum. Some muscular fibres are often found in the substance of the floor
of the fossa ovalis. The other muscular fibres of the septum are continuous with the
circular fibres of the auricles.
Separation of the Two Hearts.
Dissection. — Divide the anterior fibres of the ventricles carefully, layer by layer, paral-
lel to the anterior furrow. Then separate the two ventricles, by means of the finger or
the handle of the scalpel. In order to separate the auricles, carry the scalpel along the
posterior inter-auricular furrow, being particularly careful upon arriving at the fossa ova-
lis. It is often possible to separate the auricles completely without opening either of them.
The division of the heart into the right and the left heart is not merely imaginary or
theoretical, but is capable of actual demonstration. After making the beautiful prepara-
tion described above, we find that the left convex ventricle is received into a correspond-
ing concavity in the right ventricle ; the two are therefore adapted to each other, and
* The arrangement described above is common to both ventricles. In the ri^ht ventricle almost all the re-
flected fibres enter into the columnve cameae. There is no interlacing, or indigitation of the fleshy fibres along
the anterior and posterior furrows, as has been stated ; still less do we find a raph6 in the situation of these
furrows. The splitting and separation of the muscular fibres, caused by the entrance of the bloodvessels oppo-
site the furrows, and the condensation of the fibres between the openings for the vessels, have occasioned thes«
•rroneous views.
THE HEART. 4#1
their mutual reception is rendered complete by means of the infiindibuliform prolonga-
tion of the right ventricle.
On the other hand, the right auricle is convex, and is received into a corresponding
concavity in the left auricle.
By placing the two halves of the heart together, we see clearly the position of the aor-
tic opening behind and to the right side of the pulmonary, the crossing of the aorta and
the pulmonary artery in the form of the letter X ; the relation of the aorta with the base
of the right ventricle, and its situation between the right auriculo-ventricular orifice,
which is behind, and the infundibuliform prolongation of the right ventricle, which is in
front of it. This last relation explains how a communication may take place between
the aorta and the right ventricle.
The separation of the two sides of the heart also enables us to judge accurately of the
shape and the relative size of the two ventricles, the regular conical form of the left
ventricle, and the prismatic and triangular form of the right ventricle, the left wall of
which is, as it were, pushed inward by the corresponding projection of the left ventricle.
We can also ascertain the shape and relative size of the two auricles.
Vessels, JVerves, and Cellular Tissue.
Arteries. — The heart receives certain proper arteries, called cardiac or coronary, from
their being arranged in the form of a circle or crown. They are two in number, and are
the first branches given off by the aorta. They form two arterial circles placed at right
angles to each other ; that is to say, one circle follows the auriculo-ventricular furrow,
and the other occupies the inter- ventricular furrow.
Veins. — Corresponding to these two arteries there is one vein, named the great car-
diac or coronary vein, and a few small ones, called the anterior coronary veins. I do not
think that the existence of those accessory veins described by Thebesius as terminating
directly in the right auricle and the other cavities of the heart has been clearly demon-
strated. I have already said that the common openings of several groups of areolae have
been often mistaken for the orifices of veins. There is always an opening resembling
the orifice of a vein below the vena cava superior, but injection does not show any ves-
sel there.
Lymphatics. — These terminate in the numerous lymphatic glands which surround the
bronchi and the lower part of the trachea.
Nerves. — The cardiac nerves are small when compared with the nerves received by
other muscular organs, with those of the tongue, for example, and especially with those
of the muscles of the orbit. Some are derived from the cervical ganglia of the sympa-
thetic nerves, the others from the cerebro-spinal system, viz., the cardiac branches of
the pneumogastric.
These nerves, which are placed near the arteries, follow them at first, but soon sep-
arate from them, and are lost in the muscular substance. We cannot, therefore, admit
the opinion of Behrends, who attempted to prove that the nerves are intended only for
the vessels of the heart, and not for its proper tissue.
Cellular Tissue. — The serous cellular tissue which unites the muscular fasciculi of the
heart is so delicate, that it is extremely difficult to demonstrate it. In certain cases of
disease it may become loaded with fat. •
We always find a greater or less amount of fat upon the surface of the heart beneath
the serous membrane ; it abounds in the circular furrow between the auricles and ven-
tricles, in the furrow of the ventricles, at the apex and right border of the heart, in the
furrow between the pulmonary artery and the aorta, and between the small digital ap-
pendages upon the top of the left auricle.
' Development.
In Size. — The heart is larger in proportion to the rest of the body in the earlier stages
of its development.
In the foetus, at the full term and after birth, the weight of the heart is to that of the
body as 1 to 120 ; before the end of the third month of intra-uterine life it is as 1 to 50.
It should be renoembered that, at the fourth or fifth week, the heart of the foetus occu-
pies the entire cavity of the thorax. In old age, the heart does not undergo atrophy like
most of the other organs ; and, in many subjects far advanced in years, it is even hyper-
trophied.
In Direction. — During the first three months the heart of the foetus is directed verti-
cally, as in other mammalia ; it does not begin to deviate to the left side and forward, as
in the adult, until the fourth month.
In Shape.* — The heart, at an early period, forms a rounded and symmetrical mass, of
which the auricles constitute the greatest part ; the ventricles appear at this time to be
only appendages of the heart, and the right auricle alone is equal in size to all the rest
of the organ. The ventricles are gradually enlarged, while the auricles diminish, and
towards the fifth month the due proportion between the auricles and ventricles is estab-
■ "^ ^ * See note, p. 492.
4^ ANGEIOLOGY.
lished ; the left ventricle is, at this period, more capacious than the right. The walls of
the heart are thicker than they are afterward, and the heart is firmer, and does not col-
lapse when empty. The thickness of the parietes of both ventricles is almost the same.
In Interned Conformation. — It is in reference to its internal structure that the principal
changes occur during the development of the heart. The right and left sides of the
heart communicate freely during the whole period of intra-uterine existence. The in-
ter-auricular septum does not exist, or, at least, only in a rudimentary state, during the
earlier months of foetal life.
Is there any period of fcetal existence during which the inter- ventricular septum is
entirely wanting 1 and does the development of the human heart, which would then re-
semble the heart of reptiles, coincide with the general law by which the organs of man,
before acquiring their perfect form, pass successively through the several conditions rep-
resented by the corresponding organs in the lower animals'! The observations of Meck-
el, which extend as far back as the fourth week, prove that the inter-ventricular septum
always exists at that period, but that it is imperfect at the upper part, where it is perfo
rated or notched.*
Cases of malformation, in which the septum of the ventricles is absent, cannot be quo
ted in support of the opinion that the septum is wanting in the early periods of life ; foi
it would be necessary to prove that such a malformation is an arrest of development.
The opening between the two auricles becomes contracted, and forms the foramen
ovale (or foramen ofBotal), which is found at the posterior and inferior part of the septum.
The valve of Eustachius is sufficiently broad to separate the orifice of the vena cava
inferior from the cavity of the right auricle, so that the blood of that vein is carried di-
rectly into the left auricle.
Towards the end of the third month, the valve of the foramen ovale, which afterward
forms the bottom of the fossa ovalis, begins to appear ; it arises from the posterior half
of the opening of the vena cava inferior. About the same period the Eustachian valve
decreases in size, and from this time the development of these two valves proceeds in-
versely, that is to say, the Eustachian valve diminishes, while that of the foramen ovale
becomes larger. In consequence of this change, the vena cava inferior no longer opens
into the left auricle, but into the right.
At the fifth month the foramen ovale is almost entirely closed by the valve which
grows from below upward, and from behind forward ; at a later period it projects into
the left auricle, beyond the margin of the foramen ovale, so that there is an oblique pas-
sage from one auricle to the other. After birth, adhesion takes place between these
parts ; but even when this does not occur, the obliquity of the passage is such, that the
want of adhesion does not necessarily allow of any admixture of the blood of the two
auricles.
Function.
The heart is the agent by which the blood is impelled tlirough the vessels. The ve-
nous blood is poured into the auricles, which then contract ; part of the blood flows back
into the veins, but the greater portion passes into the ventricles, which contract in their
turn. The auriculo- ventricular valves meet, and prevent the reflux of the blood into the
auricles, and it is, therefore, propelled intg the arteries. The sigmoid valves at first lie
in contact with the walls of the arteries, so as to permit the blood to pass from the ven-
tricles ; they then fall down at the moment when the distended arteries react upon their
contents, and thus prevent the reflux of the blood into the ventricles. The contraction
and dilatation of the heart have been termed its systole and its diastole.
The two auricles contract simultaneously ; so also do the two ventricles. The dila-
tation of the auricles occurs during the contraction of the ventricles, and vice versa.
Dilatation is not an active phenomenon, for the fibres of the heart are so arranged that
they can produce shortening and contraction of this organ, but can neither elongate nor
dilate it.
The spiral direction of the fibres of the heart induced the ancients to conjecture that
the contractions of the ventricles took place in a spiral fashion ; and, in the first edition
of this work, looking only at the anatomical arrangement, I said that this view of the
subject was not so devoid of foundation as at first sight it might be imagined. But,
* [The researches of modern emhryologists have shown that the heart, in its simplest condition, consists of
a straight tube, which is placed vertically in the body, receives the veins at its inferior extremity, and gives
off the arteries from its superior extremity. The lower or venous end soon turns upward, so that the tube be-
comes bent into a loop, which for a time projects through a cleft on the anterior aspect of the body. The tube
then becomes divided into an auricular and a ventricular portion, and into a bulbus arteriosus, all enclosed in
a pericardium; and in this state the heart of the human ftstus corresponds with the permanent condition of
this organ in fishes. Each of these three portions becomes again subdivided : the auricular portion by a de-
scending septum into the two auricles, the ventricular by an ascending septum into the two ventricles, and
the bulbus arteriosus into the aorta and pulmonary artery. For a certain period, the right and left auricles
and the right and left ventricles communicate with each other. When the septum between the ventricles ii
yet imperfect (a condition which is permanent in reptiles generally), the common ventricular cavity gives ori-
gin to both the aorta and the pulmonary artery. Before the middle of fcetal life this septum is completed, and
then the two vessels arise each separately from its proper ventricle. The septum between the auricles re-
mains imperfect until after birth, when the foramen ovale at length becomes closed.]
THE HEART.
from the opportunities I have lately had of observing the movements of the heart in a
new-born child, full of life and vigour, whose heart, deprived of the pericardium, had
passed entirely outside of the chest, through a circular perforation in the upper part of
the sternum, I have been enabled to establish the following facts in reference to this in-
teresting subject (see Gazette de Paris, August 7th, 1841) :
First, the contraction of the right ventricle and the contraction of the left ventricle
are simultaneous, or synchronous ; this is also the case with the contraction of the au-
ricles.
Second, the contraction of the ventricles coincides with the dilatation of the auricles
and the projection of the blood into the arteries. The dilatation of the ventricles coin-
cides with the contraction of the auricles and that of the arteries.
Third, there are but two conditions in the movements of the heart : those of its con-
tractions and those of its dilatations ; the state of rest which is spoken of by authors is
completely wanting. Dilatation is immediately followed by contraction, and contraction
by dilatation.
Fourth, in observing the heart in the case referred to, the question about the order of
succession in the movements of the heart, viz., whether the contraction of the auricles
precedes that of the ventricles, as most observers assert, or whether the contraction of
the ventricles precedes that of the auricles, is found to have no foundation to rest on :
it seems that the contraction and the dilatation of the ventricles and that of the auricles
result from two opposite forces, continually active, which alternately, and, as it were,
necessarily conquer each other in an invariable order, in the fashion of the two alternate
movements of a pendulum, or a perfectly-balanced balance-pole.
Fifth, the duration of the contraction of the ventricles continues twice as long as that
of their dilatation. On dividing into three equal periods the whole duration of the sys-
tole and diastole of the ventricles, we will have two for the contraction and one for the
dilatation. The period of repose mentioned by authors has been taken from the first
period of the contraction. In regard to the auricles, on dividing into three equal parts
the whole duration of their contraction and dilatation, we wiU have two for dilatation
and one for contraction.
Sixth, during the time of their contraction or systole, the ventricles grow pale, their
surface becomes rugged, strongly folded, and, as it were, shrivelled. The superficial
veins swell ; the columnse carneae of the ventricles are marked off; the twisted fibres
of the summit of the left ventricle, which of itself constitutes the apex of the heart, be-
come more manifest.
Seventh, during their contraction the ventricles contract in all their diameters ; and
if the phenomenon of their shortening is the most sensible, this is attributable to the
greater dimension of the vertical diameter. During the systole of the ventricles, the
summit of the left ventricle, or, what is the same, the summit of the heart, describes a
spiral movement from right to left and from behind forward.
Eighth, it is this spiral contraction, which is slow, gradual, and successive, as it
were, which produces the movement forward of the summit of the heart, and, conse-
quently, the striking of the apex against the walls of the thorax. The systole of the
ventricles is not accompanied, as I had before beheved, with a movement of projection
of the heart forward : it is the spiral contraction which determines exclusively the ap-
proximation to, and even the striking of the apex of the heart against the walls of the
thorax.
Ninth, the dilatation or diastole of the ventricles takes place in a sudden, instanta-
neous manner : at first sight one would say that it constituted the active movement of
the heart, it is so rapid and energetic. No one can have any idea, without having ex-
perienced it, of the force with which the dilatation overcomes pressure made upon this
organ. The hand which firmly grasps the heart is forcibly opened by its diastole.
Tenth, the dilatation or diastole of the ventricles is accompanied with a movement
of projection of the heart downward. This movement of projection was carried to its
maximum when the child was placed in the vertical position ; it was so marked, that at
first I was induced to believe that it was during the diastole of the ventricles that the
percussion of the heart against the walls of the thorax took place. This idea I still en-
tertained, rom an experiment which I had made at a former period upon the hearts of
frogs ; but a more accurate examination of the phenomenon has shown me that it was,
indeed, during the systole of the ventricles, and towards the end of this systole, that the
percussion of the apex of the heart against the walls of the thorax took place.
Eleventh, the dilatation of the auricles takes place as suddenly as the dilatation of the
ventricles, but it lasts as long as the systole of the ventricles : the contraction of the auri-
cles, on the contrary, lasts no longer than the diastole of the ventricles.
Twelfth, during its dilatation, the right auricle seems on the point of bursting, so
great is its distension and so thin are its walls. The left auricle, which is narrower,
more elongated, and thicker, does not exhibit the same phenomenon, at least not in the
same degree. I have not been able to judge of what takes place in the auricular pro-
cesses except from the movements of the auricles.
494 ANGEIOLOGY.
In regard to the sounds of the heart, it results, from the experiments which I have
made upon the heart of this child {Medical Gazette, loco citato), that the two sounds of
the heart have their seat at the origin of the pulmonary and aortic arteries, and that
they originate in the clashing of the sigmoid valves ; that the first sound, which coin-
cides with the systole of the ventricles and the dilatation of the arteries, results from
the rising of the sigmoid valves, which were previously lowered ; that the second sound,
which coincides with the diastole of the ventricles and with the contraction of the ar-
teries, results from the lowering of the sigmoid valves pressed down again by the gush
of the returning blood. The simplicity of this theory, the easy and natureil explanation
which it affords of all the facts that have come to my knowledge, may, perhaps, be con-
sidered as a proof of its truth.
THE PERICARDIUM.
The pericardium {pp,fig- 170) is a fibro-serous sac, which surrounds and protects the
heart.
Congenital absence of the pericardium is extremely rare ; complete adhesion of the
pericardium to the heart, or cellular transformation of this membrane, have been most
commonly mistaken for such malformation. Nevertheless, I have seen the heart of an
adult to which there was no pericardium : this anomaly has been figured by M. Breschet.
The heart was free from any adhesion, and occupied the cavity of the left pleura.
The older anatomists, and particularly Senac, attempted to determine exactly how
much larger the cavity of the pericardium is than the heart. Having injected water into
the pericardium in different subjects, this observer found that the quantity of liquid con-
tained between the heart and its covering varied from six to twenty-four ounces. I have
satisfied myself that in the healthy state, the capacity of the pericardium exactly corre-
sponds to the size of the heart when that organ is dilated to the utmost. In certain
cases of hydrops pericardii, this sac becomes enormously enlarged ; on the other hand,
its inextensibility explains the syncope which immediately follows rupture of the heart,*
and which is produced by the accumulation of a small quantity of blood in the pericar-
dium. The syncope which accompanies the effusion from acute pericarditis probably
depends upon a similar cause.
Form. — The pericardium is shaped like a cone, with its base downward and its apex
upward. It has an external and an internal surface.
External Surface. — The pericardium is situated in the mediastinum, and has the fol-
lowing relations :
In front it corresponds to the sternum and the cartilages of the fifth, sixth, and seventh
ribs on the left side, from which it is separated by the pleura and the lungs ; in the mid-
dle it is separated from the sternum by some cellular tissue only. The pericardium is
in more or less immediate relation with the sternum, according to the size of the heart,
or the quantity of fluid in the pericardium. Behind, it corresponds to the vertebral col-
umn, from which it is separated by the posterior mediastinum and the organs contained
in it, viz., the oesophagus, the aorta, the thoracic duct, &c. On the sides, it is in imme-
diate relation with the pleurae, and indirectly with the lungs. The phrenic nerves and
the superior phrenic arteries are applied along the sides of the pericardium. The base
corresponds to the cordiform tendon of the diaphragm, and to the muscular fibres on the
left side of it. It adheres closely to the diaphragm only in the anterior half of its cir-
cumference ; in every other part the base of the pericardium may be easily detached.
The apex is prolonged upon the great vessels which enter and pass out at the base of
the heart.
The pericardium is covered by the pleurae in the greatest part of its extent, and is
united to them by cellular tissue, which is tolerably dense at the sides, and very abun-
dant in front and behind. The cellular tissue of the anterior mediastinum is often load-
ed with fat, as well as that which surrounds the base of the pericardium, where it
sometimes forms prolongations resembling the appendices epiploicas upon the large in-
testine.
The internal surface of the pericardiimi is free and lubricated by serosity, like the inner
surface of allfserous cavities. t
Structure. — The pericardium is a fibro-serous membrane analogous to the dura mater,
and, like it, is composed of two very distinct layers, one externd and fibrous, the other
internal and serous.
The fibrous layer consists of fasciculi mterlacing in all directions. It is extremely
thin, and from its adhesions to the cordiform tendon of the diaphragm, it has been re-
garded as a prolongation of that structure, but it adheres closely to the diaphragm only
* Death from rupture of the heart is not produced by hemorrhag'e, for often we do not find more than seven
or eight ounces of blood escaped ; but it is caused by compression of the heart, in consequence of the inexten-
sibility of the pericardium.
t On opening the thorax of dead bodies, the internal surface of the pericardium is, as it were, dried up ;
this drying up is owing to the air contained in the lungs.
THE ARTERIES. 495
in front, and much less intimately in the foetus and the new-bom infant. In conse-
quence of this adhesion, the pericardium follows all the motions of the diaphragm.
The fibrous layer is prolonged upon the surface of the great vessels which open into
the cavities of the heart, and furnishes for each of them an indistinct sheath, which is
soon lost upon them.
The scratis layer of the pericardium, like the serous membranes generally, forms a shut
sac, adherent by its outer surface, but free and smooth internally.* After having lined
the fibrous layer, it is reflected upon the great vessels at the base of the heart, and then
covers the heart itself, of which it forms the external membrane. We shall consider it
as consisting of a parietal, and a visceral or reflected portion.
The Parietal Portion. — The fibrous and the serous layer of the pericardium are so
closely adherent, that it is very difficult to separate them. We shall find the same to be
the case with the dura mater.
The Reflected w Visceral Portion. — The existence of this portion of the serous mem-
brane can be shown most readily at the points where it is reflected from the fibrous mem-
brane upon the great vessels. It forms one complete sheath, which is coirunon to the
aorta and pulmonary artery ; some fat is often found in the furrow between these two
vessels ; it also forms two semi-sheaths for the venae cavae and the four pulmonary veins,
which are thereby rendered smooth only in the anterior half of their circumference. The
heart is entirely covered by the serous membrane, which is here extremely thin. In fat
hearts it is raised from the muscular fibres by some flakes of adipose tissue, like the ap-
pendices epiploicae of the great intestine.
Vessels and Nerves. — The arteries of the pericardium are very small ; they are derived
from the surrounding arterial branches, viz., the superior phrenic, the anterior mediasti-
nal, and the bronchial. The veins accompany the arteries, and open into the brachio-
cephalic veins. Several of them are also said to terminate in the coronary veins. The
lymphatic vessels enter the lymphatic glands, which surround the vena cava superior.
No nerves have yet been demonstrated in the pericardium, though possibly they may
exist.
THE ARTERIES.
Definition. — Nomenclature. — Origin. — Varieties. — Course. — Anastomoses. — Form and Re-
lation.— Termination. — Structure. — Preparation.
The term arteriesf is applied to the vessels which arise from the ventricles of the
heart, and to their several divisions.
There are two systems of arteries, one of which commences at the right ventricle,
while the other commences at the left. The primitive trunk of the first is the pulmona-
ry artery, that of the second is the aorta.
These two arterial systems are perfectly distinct in the adult, but communicate fi-eely,
and form only one system in the foetus.
The following general remarks apply more particularly to the aorta and its divisions :
The arteries form an uninterrupted succession of decreasing canals, all arising from a
common trunk. In this respect we may compare the entire arterial system to a tree, the
trunk of which is the aorta, while the larger and smaller branches and the twigs are rep-
re^sented by the divisions which arise in succession from that vessel, as from their com-
mon origin.
Again, since the total area or capacity of all the arterial divisions greatly exceeds that
of the aorta, we may also regard the arterial system as a cone, the base of which is sit-
uated in the entire body, and the apex at the aorta.t
The study of the arteries includes that of their nomenclature, origin, course, direction,
relations, anastomoses, termination, and structure.
Nomenclature.
The nomenclature of the arteries leaves little to be desired in regard to precision ; the
names of these vessels are derived either from those of the parts to which they are dis-
tributed, as the thyroid, lingual, and pharyngeal arteries, &c. ; or from their situation, as
the femoral and radial arteries ; or from their direction, as the circumflex and coronary
arteries. '
The limits by which one artery is distinguished from another immediately succeeding
to it, may be either natural or artificial.
We may regard as natural limits the point of origin on the one hand, the point of divis-
ion on the other, as in the common iliac and conmion carotid arteries.
* Its inner surface is covered with epithelium.
t From anp, air, and Trjpclv, to keep. The etymology of this term affords us evidence of the error of the
ancients, who, because they always found these vessels empty and patent after death, imagined that they con-
tained air during life.
X Haller has collected all the comparative estimates that have been made between the area of the priacipa]
trunks and that of their respective divisions collectively. — {Elem. Phys., t. i., p. 151-163.)
406 ANGEIOLOGY.
The object oi artificial limits is to enable us to establish certain divisions of the same
arterial trunk, by which means we can describe its relations with greater accuracy.
Thus we shall find successive portions of the artery of the upper extremity named the
subclavian, the axillary, and the brachial artery.
Origin of the Arteries.
The common origin* of the arterial system is the aorta, which arises from the left ven-
tricle of the heart in the manner already indicated (see The Heart) ;t but the origins of
the other arteries take place according to certain very general laws : thus, two arteries
of equal size may arise from the extremity of a larger artery, and appear to result from
the bifurcation of that vessel ; arteries arising in this manner might be called terminal
arteries. Other arteries arise from some point in the circumference of a larger vessel ;
these may be termed collateral arteries.
The terminal arteries almost always arise so as to form a bifurcation at an acute an-
gle ; the dichotomous division or bifurcation is the most common mode of division. The
acute angle is evidently favourable to the passage of the blood, which, in the first place,
maintains nearly the primitive direction in which it was impelled, and, secondly, is easi-
ly divided into two columns by the projecting crest at the angle of division.
The collateral arteries very often arise at an acute angle, but sometimes at a right, or
even at an obtuse angle. The two latter modes, especially the last, are unfavourable to
the flow of the blood. It must, however, be remarked, that many of the arteries which
follow a retrograde course in reference to the trunk from which they are derived, never-
theless arise at an acute angle. The caliber of the terminal arteries is very nearly pro-
portional to that of the artery from which they are given oft", but the collateral arteries
bear no proportion to the caliber of their trunks. We shall see a remarkable example
of this in the spermatic arteries, as compared with the aorta from which they arise.
It should also be observed, that the caliber of a principal trunk does not diminish in
proportion to the branches which it supplies : in proof of this, observe the aorta as it en-
ters the abdomen, and just before its division into the common iliac.
Anatomical Varieties of the Arteries.
No system of organs is more subject to anatomical varieties than the arteries. These
varieties sometimes affect their origin only, sometimes their course, but hardly ever
their termination.^ The study of these varieties is of great importance in surgery, both
in reference to the ligature of arteries, and also to operations performed in their vicinity.^
Course of the Arteries.
The principal arteries generally follow the direction of the axis of the limbs. The sec-
ondary, tertiary, and farther divisions pursue the most varied courses, subject to no par-
ticular rule.
The principal arteries are usually straight ; but they present slight curves, which ren-
der the artery longer than the corresponding limb, and hence tend to prevent laceration
during the movement of extension, when the curves merely become obliterated and the
vessel undergoes no injurious stretching. The use of these curves in the arteries may
be proved by comparing the opposite conditions of the vessels during extension and flex-
ion of the upper and lower extremities.
A great number of the arteries pursue a very distinctly tortuous course, which, as
Haller remarks, is preserved by the surrounding cellular tissue, and which is connected
with certain particular conditions of the organs to which they are distributed. Thus,
we meet with very tortuous arteries in parts which are alternately subject to considera-
ble dilatation and contraction ; as, for example, the coronary arteries of the heart and
of the lips.
Again, the serpentine course of an artery, by increasing its length in a given space,
adds to the extent of surface from which collateral branches may arise. The curvatures
of the internal maxillary and of the ophthalmic arteries evidently have this advantage ;
and it is highly probable that the arch of the aorta may serve a similar purpose.
The arteries are tortuous in certain parts also, in which this arrangement would seem
to diminish the force and rapidity of the current of blood ; it cannot fail to be perceived
* The word origin must not be taken here in its exactly literal sense, for it has by no means been shown that
the arteries are developed from the heart towards the extremities. A very ingenious theory tends, on the con-
trary, to prove that development proceeds from the extremities towards the heart.
t I should add that the proper tissue of the aorta only touches the fibrous arterial zone opposite the angle,
or at the summit of the three festoons which the origin of the aorta exhibits. The arterial zone may be con-
sidered as the tangent of the three festoons.
t While the origin of the nerves exercises a great influence on their functions, the place from whence the
arteries originate appears to be of but little consequence, and is, at all events, very secondary. We cannot
agree in the opinion of Walther, that the origin of the arteries of an organ are intimately connected with the
mode of its existence, and with the functions which it performs.
^ [For special information on the varieties in the distribution of the arteries, the reader is referred to Hal-
ler, Icones Anatomicce, 1756; Murray, Descriptio Arteriarum, &c., 1783-98; Barclay, Description of the Ar-
teries, <fec., 1818 ; Tiedemann, Tabula; Arteriarum, &c., !822 ; and to R. Quain's Anatomy of the Arteries, &c.,
with drawings by J. Maclise, 1840, 1841.1
THE ARTERIES. 497
that such is the intention of the curvatures described by the internal carotid and the
vertebral arteries. Bichat, it is true, has objected to this, that, in a system of commu-
nicating and permanently distended canals, the curvature can have no influence upon
the rapidity of the fluid circulating through them. But I would answer, that this prin-
ciple, though true in reference to a system of inextensible tubes, is not so when applied
to a system of dilatable canals like the arteries. In the latter case, in fact, part of the
momentum acts against the curvature itself, and straightens it in a certain degree, and
in this way there is a loss of some portion of the original momentum.
In some arteries this tortuous condition is acquired, in others it results from the prog-
ress of age. It proceeds from elongation of tne arteries, which is itself produced in the
following manner : At each ventricular systole, the arteries tend to become elongated
a« well as dilated. In the aged, and especially in those whose heart is very powerful,
this tendency to become elongated produces an actual and permanent elongation, as
may be seen in the abdominal aorta and in the conunon iliac, the humeral, and the radial
arteries, which, in almost aU old subjects, present alternate curvatures, that are never
met with in the infant and the adult. It has been incorrectly stated, that at each sys-
tole of the heart the curves were diminished, or manifested a tendency to be dimin-
ished : on the contrary, the curves increase. This increase of curve is evidently per-
ceived in observing the tempered artery during the systole of the ventricles. If an ar-
tery is injected, its branches, at each stroke of the piston, become more flexuous. If
the arteries were straightened, the dilatations and the calcareous deposites would not be
constantly observed on the side of the convexity of the curves.
Let us remark, that the dilatation of the arteries is, just as much ^ls their elongation,
a cause of the increase of their flexuosity.
The flexuosities of the arteries are of a twofold order, zigzag and spiral. The former
are more frequent ; the latter are especially noticed in the ovarian or testicular, uterine,
and sometimes facial arteries.
We may also consider as acquired the tortuous condition assumed by collateral arte-
rial branches, after the obliteration of the main trunk.*
Anastomoses of the Arteries.
During their course, the arteries communicate with each other by certain branches,
which sometimes unite two different trunks, and sometimes form a connexion between
two parts of the same trunk. This mode of communication is called anastomosis {ava,
by. and arofia, a mouth). There are several kinds of anastomoses.
Anastomosis by inosculation, or by loops, in which two vessels running in opposite di-
rections open into each other by their extremities and form a loop.
Attastomosis by transverse communication, as when two parallel trunks are united by
means of a branch at right angles to their own direction : for example, the anterior com-
municating artery of the brain.
Anastomosis by convergence, in which two arterial branches unite at an acute angle to
form a larger artery, as in the union of the vertebral arteries to form the basilar trunk.
By means of the anastomosis by inosculation or by loops, which is the most common
method of communication, uninterrupted collateral channels are established along the
great arterial trunks, the place of which they may even supply. The existence of these
anastomoses, and the power possessed by arteries of becoming enlarged to an almost
indefinite extent, originated the bold idea of attempting to tie even the largest arte-
rial trunks.
Anastomoses by inosculation are sometimes useful in regulating the distribution of
blood,+ and spreading out the origins of arteries over a more extended space. Thus, by
means of several series of arches, the superior mesenteric artery gives off branches which
proceed at right angles to the small intestine throughout its whole length.
Forms and Relations.
The arteries represent regular cylinders when they give off no branch, and cones, or,
rather, a series of decreasing cylinders, when they gradually diminish by giving off a
certain number of branches. Their cylindrical form, together with the looseness of the
surrounding cellular tissue, preserves them from a number of accidents. Thus, the hu-
meral and the femoral arteries glide over the head of the humerus and femur in disloca-
tions of these bones ; and so the carotid arteries, contrary to all apparent probability,
sometimes escape uninjured in incised wounds of the neck.
The arteries have relations with many other parts. With the bones, being supported
by them, and more 'or less closely approximated to them. Thus, the aorta is applied to
the vertebral column, and the arteries of the limbs, after escaping from the trunk, become
* There are flexuosities originating in malformation, by deviation or by fracture. In a case of fracture of
the neck of the femur, the femoral artery described very marked inflections at the hip. This was also the case
in a luxation of the femur with considerable shortening. The aorta becomes very flexuous in cases cf hunch
backs.
t [The retia mirabilia of arterial vessels, found in some animals, are examples of the repeated subdmsioD,
and anastomosis of arteries.]
R R R
498 ANGEIOLOGY.
^pliea to the corresponding bones, their course along which is marked by a depression
and against which they may easily be compressed (see Osteology).
From the relations of the arteries with the articulations, some important practical in-
ferences are derived. The arteries always occupy the aspect of flexion ; and as flexion
is performed in the larger articulations of a limb alternately in opposite directions, the
arteries are observed to alter their relative position, as it were, to regain the aspect ot
flexion. This is seen in the femoral artery as it becomes popliteal, and also in the
brachial, which at first lies in the cavity of the axilla, and then turns forward at the
bend of the elbow. In consequence of this arrangement, the arteries are protected by
the habitual, and, as it were, instinctive, position of the Umbs.
On the other hand, the proximity of certain arteries to articulations, and the absence
of any curvatures in such situations, may explain the occurrence of rupture of these
vessels in dislocation, and often, also, in immoderate attempts at reduction.
With the Muscles. — The muscles are the essential protectors of the arteries, which
they separate from the skin. There are large cellular spaces in the centre of the limbs
for the reception of the principal arteries, which are thus removed from the influence of
external violence.
Most arteries have a special muscle, which may be termed their satellite muscle. Thus,
the sartorius is the satellite muscle of the femoral artery ; the sterno-cleido-mastoideus
of the common carotid ; the biceps of the brachial artery, &c.
With the Skin. — Some arteries are sub-cutaneous, or, rather, sub-aponeurotic, in a
certain part of their extent ; and in large arteries, this is almost always at the point
where they emerge from the trunk, as in the femoral artery. The arteries of the cra-
nium are situated between the skin and the epicranial aponeurosis in the whole of their
extent. The importance of these relations in reference to compression of the vessels
may be easily conceived.
With the Veins. — The arteries are always in relation with certain veins, which are ap-
plied to them. When there are two satellite veins {vence comites) for one artery, the lat-
ter vessel is constantly placed between the two veins.
With the Nerves. — ^The arteries support the plexuses of nerves distributed to the or-
gans of nutritive life. We may even regard their plexuses as forming an accessory coat
to this set of vessels. Other nerves, though not so immediately in contact with the ar-
teries, have a constant relation with them. This it is of importance to know, so that
the nerves may be avoided, or that they may direct the operator in applying a ligature to
the vessels themselves. For each artery it may be said there is one satellite nerve.
With the Aponeurotic Sheaths. — ^The principal artery of a limb is provided with a fibrous
sheath, which belongs to it in common with its veins, and often with its accompanying
nerve. When an artery perforates a muscle, it is protected in its passage by a sheath
or aponeurotic arch, which prevents, or at least moderates, the compression during the
contraction of the muscle.
Lastly, the arteries are surrounded by a loose cellular sheath, which allows of their
dilatation and their alterations in position. The looseness of this cellular tisssue favours
the displacement of arteries during the infliction of wounds, and enables us to isolate
these vessels by blunt instruments, which cannot injure them.* As the nutritious ves-
sels reach the coat of the arteries through this sheath, we can easily understand the im-
propriety of separating the vessel from it too extensively in tying the arteries, t
Termination of the Arteries.
The divisions of the arteries are not so numerous as would at first sight appear. The
number of successive divisions, commencing at the aorta, is not more than twenty.
The arteries terminate in the substance of organs. The number of arteries distrib-
uted to each organ is in proportion to the activity of its functions ; secreting organs are
much more plentifully supplied with vessels than those in which the function of nutri-
tion only is performed. Soemmering, Prochaska, and others, have observed that the
actual termination of the arteries is different in different organs. Referring for farther
details upon this subject to textural anatomy, I shall content myself with stating here,
1st, that the arteries terminate in the capillary system, through the medium of which
they become continuous with the veins, as is demonstrated even by the coarsest in-
jections ; 2d, that the arteries enter only in a very slight degree into the composition
of the capillary system, which is essentially venous ; this may be ascertained by in-
jecting the arteries of an organ, the venous capillary system of the same having been
previously injected by the veins ; it will then be perceived that the arteries enter but
very little into the formation of the capillary system, and that they cease to exist as
soon as they have communicated with it. If it were objected that, through this prep-
aration, the injected liquid might have passed over from the venous capillary system into
* [Another ii^portant result of this is, that a divided artery is enabled to retract within its sheath. In the
abdomen and head this slieath scarcely exists.]
t I have seen a ligature of the primitive carotid which had been laid b»re to too great an extent followed
by a consecutive hemorrhage and death.
A
V.
\ THE ARTERIES. 4^
ffie arterial, I would remark, that the impossibility of this reflux is one of the most clear-
ly demonstrated facts in anatomy.
Structure of Arteries.
The walls of an artery are composed of three coats : an external, a middle, and an in-
ternal.*
The External Coat. — This is generally called the cellular coat, because it is in some
measure continuous with the surrounding cellular tissue. Scarpa erroneously regarded
it as not forming an integrant part of the arteries. It consists of a filamentous, areolar,
and, as it were, felted tissue, which is never charged with fat or infiltrated with se-
rum, and which appears to me to present all the characters of the dartoid tissue. I
believe that the contractility which has been attributed to the middle coat is altogether
dependant upon this.t It is the only coat which remains undivided after the appUca-
tion of a ligature.
The Proper or Middle Coat. — The characteristic properties of arteries are chiefly de-
pendant upon this coat. It is composed of circular fibres, which interlace at very acute
angles, but which do not present the spiral arrangement admitted by some authors. From
its yellow colour and its elasticity, it has been called the yellow or elastic coat. It is ex-
tensible longitudinally and transversely. It is very fragile, is easily torn by longitudinal
extension, and is cut by a ligature. It is proportionally thinner in the great than in the
small arteries. This coat is of the same nature as the yellow elastic ligaments, and is
therefore not muscular. Moreover, chemical analysis shows that it contains no fibrine ;
direct irritation develops no contractility in it ; and the supposed phenomena of irrita-
bihty pointed out by Haller may be entirely attributed to elasticity. It should be re-
marked that the middle coat may be separated in several distinct layers, which are, how-
ever, not independent of each other ; while the most external layers present a strongly-
marked fibrous linear disposition, the most internal exliibit an equally marked lamellar
one ; indeed, to such extent, that authors have considered as a dependance of the inter-
nal coat the layer of yellow tissue which is in contact with the internal membrane,
properly so called.
The Internal Coat. — It is a transparent pellicle of extreme tenuity ; it must be care-
fully distinguished from the subjacent layer, which is almost always dissected off with
it. It is of a pale pink colour, and is lubricated with serosity. It appears to be of the
nature of serous membranes, of which it presents the chief characteristics, viz., tenuity
and non- vascularity. t It may even be said that, like the serous membranes, it is ex-
clusively formed by a lymphatic net. I do not think that this internal coat of the arter-
ies, which may have been considered as a sort of inorganic glue, is extensible or elas-
tic ; on the contrary, in arteries in a non-distended state, this coat exhibits the appear-
ance of folds which disappear by distension.
Vessels and Nerves. — The arteries and veins distributed to the coats of the arteries are
called vasa vasorum. In regard to the question whether the arteries receive any nerves,
or whether the nervous plexuses which accompany them are only intended for the or-
gan to which the vessels are distributed, I would observe, that it has appeared to me
that several filaments of the great sympathetic nerve were lost in the thickness of the
aorta, and it is probable that the same disposition exists in regard to the less consid-
erable arteries. As to the vasa vasorum, some believe they arise from the neighbour-
ing vessels, while others are of opinion that they are derived from the vessels them-
selves to which they belong. I adopt the latter opinion, and believe that they mostly
arise from the arteries to which they are attached. The venous vasa vasorum of the
arterial coats join the nearest veins.
Preparation.
The preparation of an artery consists in separating it from the neighbouring parts, at
the same time preserving its relations. Most of the arteries may be studied without
any other preparation than a careful dissection ; but injections are necessary in order to
follow the smaller branches. The most convenient injection with which I am acquaint-
ed is the following :^ Tallow, nine parts ; Venice turpentine, one part ; ivory black, mix
ed with spirits of turpentine or varnish, two parts.
* All the vessels, and all the tubes of the body, are formed of different layers.
t All experimenters have observed that, in an animal which dies of hemorrhage, the arteries, during the
last moments of its life, lose a considerable part of their caliber, -which is restored to them immediately after
death. This phenomenon, which appears at first sight to be in opposition to the absence of the contractility,
properly so called, of the middle coat, may be easily accounted for by the tonic contractility of the dartoid
tissue. The presence of this tissue may also account for the smallness or the contraction of the pulse, in op-
position with its fulness, a double character which is sometimes met in the same individual, and in the same
diseases, at short intervals.
t [It consists of longitudinal fibres, which are slightly interlaced, and are covered with a squamous epithe-
lium. The longitudinal wrinkles observed in arteries contracted after death are produced in this coat.]
6 [The paint or cold injection is one of the most useful ; it consists of either red or white lead, mixed a» a
paint, with a small quantity of boiled linseed oil, with spirits of turpentine, and also with some driers, viz.,
sugar of lead and litharge.J ,
500 ~^' ANGEIOLOGY.
The best injection for preparations intended to be preserved is wax, one part ; tallow,
three parts ; vermilion, indigo, or Prussian blue, first mixed with spirits of turpentine.
It is advantageous, before making the general injection, to throw in some turpentine
or spirit varnish, coloured with the substances mentioned above.
For a very fine injection it is necessary to use glue-size, coloured either Avith lamp-
black or vermilion ; but this mode of injection is not suitable where the preparation is to
be preserved.
In order to place a tube in the aorta, saw through the sternum longitudinally ; keep
tlie two halves apart by means of a small piece of wood ; open the pericardium ; be care-
ful not to mistake the pulmonary artery for the aorta ; raise up the aorta by a ligature ;
make an incision in it anteriorly, and introduce the pipe. Injections of the whole body
may also be made by introducing the tube into a large artery, such as the primitive ca-
rotid ; this mode of injection permits of injecting the heart and the cardiac arteries, and
of avoiding the mutilation of the arch of the aorta. The partial injections in a whole
subject are preferable to the general injections, especially when such substances as tal-
low are used, which are easily solidified. Of course, an indispensable condition for the
success of these partial injections is the previous isolation of the arterial system that
you wish to prepare. This isolation is effected by ligatures which are put upon the large
arteries communicating with the small arteries that are to be injected.
In injecting the coronary arteries, the pipe must be introduced into one of the carotids.
DESCRIPTION OF THE ARTERIES.
THE PULMONARY ARTERY.
Preparation. — Description. — Relations. — Size. — Development.
Preparation. — In order to inject the pulmonary artery, the injecting pipe must be in-
troduced into one of the venae cavse.
The pulmonary artery, called vena arteriosa by the older writers, because having all
the external characters of an artery ; it nevertheless contains black blood, extends from
the right ventricle to the two lungs. It arises {k, fig. 191) from the infundibuliform pro-
longation of the right ventricle, and then passes upward and to the left side, crossing in
front of the aorta, which is embraced by its concavity ; having reached the left side of
this artery, after a course of about fourteen or fifteen lines, it divides into two trunks
(k k, fig. 192), which proceed transversely, one to the right, the other to the left lung
(kk, fig. 171), where they terminate by dividing into branches. From the point of di-
vision into the right and left branches* a fibrous cord, the remains of the ductus arteri-
osus, proceeds in the original direction of the artery, and is attached to the concavity of
the arch of the aorta opposite the left subclavian artery.
At its origin the pulmonary artery is covered externally by the highest fibres of the
infundibulum ; internally it is provided with three sigmoid movable valves (a a a, fig.
196), which, when depressed, completely close the mouth of the vessel. By careful dis-
section, it is found that the pulmonary artery is cut at its origin into three festoons, cor-
responding to the sigmoid valves, and that it is connected to the tissue of the heart by
its intern5 coat, which is contiguous with the lining membrane of the right cavities of
the heart ; and also by prolongations given off from the fibrous zone, and attached to the
convex borders of the three festoons, and to the angular intervals between them.
Relations. — In front and on the left side the pulmonary artery is convex, and covered
by the serous layer of the pericardium, which is often separated from it by some fat ; be-
hind and on the right side it is concave, and is in relation with the aorta, which it em-
braces. The right and left auricles are in contact with its corresponding sides.
Size. — The left branch of the pulmonary artery is about one inch in length ; it is in
relation behind with the left bronchus, one of the bronchial arteries often passing between
them ; it is in direct relation with the aorta. In front, it is covered by the serous layer
of the pericardium, excepting near the lungs, where the pulmonary veins are placed in
front of the arterial branches.
The right division of the pulmonary artery is from sixteen to eighteen lines in length ;
it is in relation in front with the vena cava superior, and with the ascending portion of
the aorta, but not immediately, for the serous layer of the pericardium covers both the
aorta and the corresponding part of the pulmonary artery. Behind, it is in relation with
the right bronchus, and passes above the right auricle.
Development. — In the foetus, instead of the fibrous cord, which we have described as
proceeding from the point at which the pulmonary artery divides into its two branches,!
there is a canal called the ductus arteriosus, almost equal in diameter to the pulmonary
* See note, infrd.
t [It was noticed by Haller and Senac, that the ductus arteriosus in the foetus, and the cord to which it is
reduced after birth, arise, not from the angle of division into the right and left pulmonary arteries, but from
the left pulmonary artery itself : this is an interesting and important fact in reference to the development of
th« great vessels issuing from the heart.]
THE AOETA.
d9l
artery itself, the course of which vessel it pursues ; at this time the right and left branch-
es of the pulmonary artery are very small. At birth the whole of the venous blood pro-
ceeds to the lungs, none of it passing through the ductus arteriosus, which then becomes
obliterated.
Fig. 198.
THE AORTA.
Preparation. — Definition. — Situation. — Direction. — Size. — Division into the Arch of the Am-
ta, the Thoracic Aorta, and the Abdominal Aorta.
Preparation. — The aorta may be studied without having been injected.* In order to
study it in an injected subject, the median incision made for the purpose of introducing
the injection must be prolonged down to the pubes. Then disarticulate the clavicles,
separate the two sides of the thorax, even so far as to break some of the ribs, and keep
them separate by introducing a piece of wood ; cut through the abdominal parietes, and
turn the left lung over to the right side.
The aorlo {aoprri, arteria magna, arteriamm omnium mater, ah c d,fig. 198), the com-
mon origin of all the arteries of the human body, commences at the left ventricle, and
terminates by bifurcating (at d) opposite the fourth lumbar vertebra.
Situation. — It is situated deeply in the thoracic and abdominal cavities, along the ver-
tebral column, which affords it both support and protection. In those animals in which
the aorta is prolonged beyond the trunk, the vertebral column accompanies the vessel,
and forms a bony canal or sheath for it, distinct from the canal for the spinal cord.
Direction. — Immediately after its origin, the aorta advances towards the right side (a,
fig. 198), and almost directly afterward pro-
ceeds upward, describing a slight curve, the con-
vexity of which is turned forward and to the
right, and the concavity backward and to the left.
After leaving the pericardium, it changes its
direction, becomes suddenly curved, and passes
almost horizontally from the right to the left,
and from before backward, to reach the left side
of the vertebral column, on a level with the third
dorsal vertebra, at which point (6) it makes a
third curve, and becomes vertical and descend-
ing. Having reached the diaphragm (at c), it
incUnes a little to the right side, in order to gain
the median line, and to pass through the ring,
or, rather, the canal, formed for it by the pillars
of the diaphragm. From this point to its ter-
mination, it rests upon the middle of the anteri-
or surface of the vertebral column.
Varieties in its Direction. — It is not a very
rare occurrence to find the aorta curving over
to the right instead of the left side — a disposi-
tion which may either be accompanied with a
complete transposition of the thoracic and ab-
dominal viscera, or may be independent of it.
Size. — The several portions of the aorta have
not a uniform caliber ;t but its gradual decrease,
in this respect, bears no direct proportion to
the number and size of the branches given off"
from it.
At its origin it always presents three ampul-
lae, which correspond to the sigmoid valves ;
they are called the sinuses of the aorta, or sinuses
of Valsalva. They exist originally, and must,
therefore, be distinguished from a dilatation
found on the convex side of the arch of the aor-
ta in old subjects, and called the great sinus of
the aorta. This dilatation results entirely from the impulse of the current of the blood.
The caliber of the aorta, moreover, differs exceedingly in different subjects, even
when there is no appreciable organic lesion :t it should be remarked, however, that the
thickness of its coats is not at all in proportion with its caliber.
* It will be advantageous to study the aorta in the same subject in which the viscera have already been ex-
amined.
t Thus, the caliber of the commencement of the aorta, compared with that of its termination, is generally
as five to three ; hence the diminution is not by any means proportionate to the number of branches arising
from It, for the united calibers of its collateral braiiches would much exceed that of the main vessels.
t Thus, I have seen a case in which the aorta was 4 inches 8 lines in circumference opposite the arch, and
2 inches 6 lines at its lower end : the latter is the usual size of the vessel.
502 ANGEIOLOGY.
The aorta is generally divided into three portions, viz., the arch of the aorta, the tho-
racic aorta, and the abdominal aorta. The two latter portions form together the aorta de-
acendens.
The Arch of the Aorta.
I shall give this name to all that part of the aorta (a I, fig. 198^ which is comprised
between its origin from the left ventricle and the point where it is crossed by the left
bronchus.*
The direction of the arch of the aorta is neither transverse nor antero-posterior, but
oblique from the right to the left side, and from before backward ; so that it is anterior,
median, and substernal in its first portion, and posterior at its termination, and in rela-
tion with the left side of the vertebral column. In consequence of these relations, aneu-
risms of the anterior part of the arch of the aorta frequently affect the sternum, while
aneurisms of the posterior portion affect the vertebral column.
Relations. — We shall examine the relations of the arch of the aorta, first in its pericar-
diac or ascending portion, and then in its horizontal and descending portions taken to-
gether.
The Pericardiac Portion (/, fig. 191). — Concealed, as it were, in the substance of the
heart at its origin, it is in relation in front with the infundibulum of the right ventricle,
and behind with the concavity of the auricles, which are moulded upon it. On the right,
it rests upon the groove between the infundibulum and the right auriculo-ventricular or-
ifice ; on the left, it is in relation with the puhnonary artery. It is important to note
the practical consequences of these relations. I have recently seen a communication
between the aorta and the infundibulum. Again, aneurisms of the origin of the aorta
may burst into the auricles.
After leaving: the heart, this portion of the aorta is surrounded on all sides, but to a
greater extent in front than behind, by the serous layer of the pericardium, which forms
a sort of additional coat for it, excepting in front, below, and on the left side, where it is
in immediate contact with the pulmonary arteiy, as that vessel turns round it. Behind,
this portion of the aorta is in relation with the right division of the pulmonary artery ;
on the right, with ttie vena cava superior. It follows, therefore, that the pulmonary ar-
tery on the one hand, and the aorta on the other, form two half-rings, like the branches
of the letter x, which embrace each other by their concavities. The pericardiac portion
of the aorta is situated oeneath the sternum, from which it is separated by the pericar-
dium and the anterior mediastinum
The Second Portion, comprising the Horizontal and Descending Portions of the Arch. —
On the outside of the pericardium, the aorta is in relation, in front and on the left side,
with the left pleura, and is separated by it from the corresponding lung, which is exca-
vated at that point. The phrenic and pneumogastric nerves are also in immediate con-
tact with it. Behind, and on the right side (/, fig. 171), it is in direct relation with the tra-
chea, the commencement of the left bronchus, the oesophagus, the thoracic duct, the re-
current nerve, the vertebral column,t and a great nmnber of lymphatic glands.
By its convexity, which is directed upward, it gives origin to three large arterial trunks,
viz., proceeding from the right to the left side, the brachio-cephalic (e,fig. 198) or innom-
inate, the left common carotid (f), and the left subclavian {g) arteries. The highest point
of the arch is opposite the origin of the brachio-cephalic artery in the infant, and that of
the left subclavian in old subjects. The distance between the fourchette of the sternum
and the highest point of the aortic arch varies in different ages and individuals : it is
generally from ten to twelve lines in the adult ; it is much less in the aged and in the
newborn infant, but for very different reasons ; in the infant it is owing to the undevel-
oped condition of the sternum, but in advanced age it depends upon dilatation of the arch
of the aorta ; in some adults, also, we find the distance very inconsiderable, and this is
important in reference to the operation of tracheotomy.
By its concavity, which is directed downw^ard, the arch of the aorta is in relation with
the left recurrent nerve, which embraces it, as it were, in a loop, having its concavity
turned upward; with the left bronchus (p,fig. 171 ; also,^"'. 198), which is placed be-
hind the horizontal portion of the arch, and then becomes situated in front of its descend
ing portions, so that the aorta, during its curvature, has two different relations with this
air-tube ; and, lastly, with a very great number of lymphatic glands, which in some
measure fill up the concavity of the aortic arch.
Anomalies of the Arch of the Aorta.— A very remarkable anomaly of the arch of the
aorta has been observed, in which the vessel, being simple at its origin, divides into two
trunks, which pass, one in front and the other behind the trachea, and then reunite to
form the descending aorta. The aorta sometimes presents traces of a subdivision into
* The limits of the arcn of the aorta are not weJ defined : most authors exclude the first curve of the ar-
tery The lower boundary is marked by the origin of the left subclavian, according to some ; by the left bron-
chus, according to others ; and. lastly, according to a great many, by the articulation of the fourth with the
fifth dorsal verteora,
t I have, I believe, satisfactorily demonstrated, in another part of this work, that the left lateral concaviti
»f the vertebral column was owing to the presence of the arch of the aorta
BRANCHES OF THE AORTA. Mg
two from its origin ; such a case appears to indicate a fusion of two aortas into one, for
we then find five sigmoid valves.
The Thoracic Aorta.
The thoracic aorta {b c, Jig. 198) is situated in the posterior mediastinum, along the lelt
side of the vertebral column, and it projects into, and encroaches upon, the left cavity
of the chest.
Relations. — It corresponds, on the left side, with the lung, from which it is separated
by the left wall of the posterior mediastinum ; on the right, it is in relation with the
oesophagus, the vena azygos, and the thoracic duct ; in front, with the left pulmonary m-
teries and veins above ; with the oesophagus (h) below, which canal becomes anterior to
it before passing through the oesophageal opening in the diaphragm, and with the peri-
cardium in the middle, by which it is separated from the posterior surface of the heart ;
behind, it is in relation with the vertebral column, the thoracic duct passing between
them above.
The thoracic aorta is surrounded by an abundance of cellular tissue, and by a number
of lymphatic glands.
Diaphragmatic Portion of the Thoracic Aorta. — The diaphragm does not form a simple
orifice or an aponeurotic arch for the aorta, but its crura (« s,fig. 199) are arranged into
a muscular semi-canal, from fifteen to eighteen lines in length, and terminating below
by a tendinous arch. The aorta is accompanied, while passing through this canal, by
the thoracic duct* and the vena azygos, and it inclines a little to the right side, in order
to become anterior to the vertebral column.
The Abdominal Aorta.
The abdominal aorta (c d,Jig. 198) occupies the middle part of the anterior surface ot
the vertebral column, and is in relation on the right side with the vena cava inferior, and
in front with the pancreas and the third portion of the duodenum, which rests immedi-
ately upon it ; in the rest of its extent it corresponds with the adherent borders of the
mesentery, and with the peritoneum covering the lumbar region of the vertebral column.
The stomach and the convolutions of the small intestine separate the aorta from the an-
terior parietes of the abdomen. When the small intestine fdi&s down into the pelvis, the
abdominal aorta may be felt immediately behind the wall of the abdomen, and may be
easily compressed there, so as completely to intercept the passage of the blood, t
BRANCHES FURNISHED BY THE AORTA IN ITS COURSE.
Enumeration and Classification. — Arteries arising from the Aorta at its Origin, viz., the Car-
onary or Cardiac. — Arteries arising from the Thoracic Aorta, viz., the Bronchial, tie
(Esophageal, the Intercostal. — Arteries arising from the Abdominal Aorta, viz., the Lum-
bar, the Inferior Phrenic, the Caliac Axis, including the Coronary of the Stomach, the He-
patic and the Splenic, the Superior Mesenteric, the Inferior Mesenteric, the Spermatic, the
Renal, and the Supra-renal or Capsular.
The aorta is the common trunk of all the branches and twigs given off by the arterial
tree. It alone furnishes, therefore, all the arteries of the human body. The branches
which come from it I shall divide into terminal and collateral branches.
The terminal branches of the aorta consist of the middle sacral and the two commcm
iliac arteries. The collateral branches are very numerous : they may be divided into
those arising from the pericardiac portion of the aorta, viz., the coronary or cardiac ar-
teries; those arising from the aortic arch, viz., the brachio-cephalie, the left common
carotid, and the left subclavian : these we may consider as terminal arteries, which, ta-
ken together, have been termed the ascending aorta in opposition to the descending
aorta ; those arising from the thoracic aorta, which may be subdivided into the parietal
branches, viz., the intercostals and the visceral, viz., the bronchial, oesophageal, and
mediastinal arteries ; and, lastly, those arising from the abdominal aorta, which may
also be distinguished as the parietal, viz., the lumbar and inferior phrenic arteries, and
the visceral, viz., the cceliac axis, the superior and inferior mesenteric, the supra-renal,
the renal, and the spermatic arteries.
Artekies ari^no from the Aorta at its Origin.
The Coronary or Cardiac Arteries.
Dissection. — Take off the serous membrane from the heart, and also the fat which oo-
* It is a mistake to say that the right azygos vein passes through the same opening as the thoracic duct.
The ar.ygos vein traverses the evening which is destined to tVie passage of the great splanchnic branch of the
sympathetic nerve.
t This compression is very easily applied in women immediately after parturition, both in consequence of
the relaxed state of the abdominal parietes allowing them to be readily depressed, and also from the facility
with which the small intestines are moved aside.
504 ANGEIOLOGY.
cupies the furrows ; in order to see distinctly the origin of these arteries, remove the
pulmonary artery and the infundibulum of the right ventricle.
The cardiac or coronary arteries {see figs. 191, 192), the nutritious vessels of the heart,
or, as it were, its rasa vasorum, are two in number, and are named right and left on ac-
count of their origin, and also anterior and posterior from their distribution. Their
number is not constant. Thus the two coronary arteries sometimes arise by a common
trunk, to the left of the pulmonary artery.* Sometimes there arc three coronary arter-
ies ; Meckel has seen four ; but these varieties in number do not affect their distribu-
tion, for the supernumerary arteries merely represent branches, which, instead of arising
from the coronary arteries themselves, proceed directly from the aorta. I have recently
seen the right coronary artery arise from the aorta by three branches in juxtaposition,
one of which was of considerable size : the others were small.
Origin. — They arise from the anterior part of the circumference of the aorta, imme-
diately above the free margin of the sigmoid valves, at the highest points of the two
corresponding sinuses. The origins of these vessels are so situated, that their orifices
are not covered by the valves when these latter are applied to the walls of the aorta, so
that the heart receives its arterial blood at the same time as all the other organs. The
angle at which the coronary arteries arise is extremely obtuse, so that the course of the
blood in them is completely retrograde.
The coronary arteries differ from each other in caliber, the right being larger than the
left, and also in their course, so that a special description is requisite for each.
The left or anterior coronary artery is destined principally for the anterior furrow of the
heart ; it is concealed, at its origin, by the infundibulum, from between which and the
left auricula it then escapes, and entering {e, fig. 191) the anterior furrow of the heart,
traverses it in a very tortuous manner, and anastomoses, at the apex, with the right or
posterior coronary artery. Not unfrequently this artery divides into two branches, one
of which runs along the anterior furrow, while the other passes upon the anterior sur-
face of the left ventricle. In this course, opposite the base of the ventricles, the artery
gives off an auriculo- ventricular branch, which, arising at a right angle, enters the left
auriculo-ventricular furrow, and, passing along it, turns round the base of the left ven-
tricle, as far as the posterior inter- ventricular furrow {e,fig. 192), where it anastomoses
with the right coronary artery.
The right or posterior coronary arteiy is larger than the left ; it arises to the right of
the infundibulum, between that part and the right auricle. Immediately after its origin
it is surrounded with a large quantity of fat, and turns directly, so as to gain the right
auriculo-ventricular furrow. At the upper end of the posterior inter-ventricular furrow
(e, fig. 192) it bends at a right angle, and entering the furrow, runs along it to the apex
of the heart, where it anastomoses with the left coronary artery. At the point where it
changes its direction, the right coronary artery gives off a branch, which anastomoses
with the auriculo-ventricular branch of the left artery.
From this description, it follows that the cardiac arteries and their principal divisions
occupy the furrows of the heart ; that they form two vascular circles, which are placed
at right angles to each other like the furrows themselves ; that the auriculo-ventricular
circle is formed on the right by the trunk of the right cardiac, and on the left by a branch
of the left cardiac artery ; that the vessels forming these two circles are tortuous, but
especieilly those on the ventricles, because that part of the heart is subject to greater
variations in its dimensions than the part with which the auriculo-ventricular circle is
in relation; and, lastly, that both coronary arteries anastomose by inosculation, and
therefore can easily supply each other.
All the arteries of the heart proceed from these two circles. The auriculo-ventricular
circle gives off some ascending or auricular branches, an aortico-pulmonary branch to the
origins of the aorta and pulmonary artery, and an adipose branch, all of which were
pointed out by Vieussens ; also some descending or ventricular branches, the two prin-
cipal of which run somewhat obliquely along the right and left borders of the heart.
The ventricular circle gives off branches which penetrate the fleshy fibres at right an-
gles. A large artery, which has been described as the artery of the septtim, appears to be
one of the terminal branches of the left coronary artery ; it dips into and is lost in the
substance of the septum.
Lastly, the coronary arteries communicate with the bronchial. They are very liable
to calcareous deposites.f
Arteries abising from the Thoracic Aorta.
These may be divided into visceral branches, all of which arise from the front of the
* The coronary arteries were denominated by the older anatomists, and especially by Bartholin, coronaria
ntedo simplex, modo gemina. Meckel, Harrison, and others have described cases in which there was but on«
coronary artery. According to the descriptions of writers on comparative anatomy, that disposition is natural
with the elephant.
t It is not uncommon from such deposites to find cardiac arteries which are extremely narrowed, and even
obliterated. Several pathologists have considered this ossification of the cardiac arteries as the cause of those
phenomena which are designated by the name of angina vecions ; but tliis opinion is a mere hypothesis.
THE AORTIC INTERCOSTAL ARTERIES. 505
aorta, viz., the bronchial and the oesophageal, and parietal branches, which arise from the
back of the aorta, viz., the aortic intercostals.
The Bronchial Arteries.
Dissection. — Carefully take away the heart and pericardium, dissect the bronchi, and
trace these arteries both to their origin and towards their termination.
Number and Origin. — The bronchial arteries {see fig. 198) vary much both in number
and origin. There are generally two on each side ; but sometimes there are three, or
even four, arising either at different heights or by a common trunk. Occasionally, one
of them arises from the subclavian, or from the internal mammary, or, rather, from the
first intercostal, or, lastly, from the second, or even the third intercostal artery.
I have seen the inferior thyroid artery give off a bronchial artery, which, after run-
ning along the trachea, passed in front of the right bronchus, and anastomosed freely
with the right bronchial furnished by the aorta. The right bronchial artery is always
larger than the left.
Whatever be their origin, the bronchial arteries pursue a tortuous course to the cor-
responding bronchus, and are usually situated on its posterior surface. When the right
bronchial artery arises from the aorta, it crosses obliquely over the lower part of the tra-
chea. The bronchial arteries always give some branches to the oesophagus ; a very
great number to the bronchial glands ; also several to the left auricle : they anastomose
with the coronary arteries on the one hand, and with the inferior thyroid and the supe-
rior intercostal arteries on the other.
Haller believes that the terminations of the bronchial arteries anastomose with the di-
visions of the puhnonary artery, and says that he has seen free and evident communica-
tions between them.*
The (Esophageal Arteries.
The oesophageal arteries {h,fig. 198) vary in number from three to seven, and are re-
markable for their slenderness and length. They arise in succession from the front of
the aorta, which they leave at right angles, and inamediately curve downward to reach
the front of the oesophagus, where they divide into extremely slender ascending, and
into very long descending branches, from which are given off a numerous series of twigs.
The superior oesophageal artery almost always anastomoses with the bronchial arteries,
and the oesophageal branches of the inferior thyroid. The inferior oesophageal artery
anastomoses with the oesophageal branches derived from the left inferior phrenic, and
from the coronary artery of the stomach.
The branches from the oesophageal arteries perforate the muscular coat of the oesoph-
agus, ramify in the sub-mucous cellular tissue, and terminate in a network in the sub-
stance of the mucous membrane.
The Aortic Intercostal Arteries.
Dissection. — In order to see the posterior branches, dissect the posterior spinal mus-
cles, and open the vertebral canal. To see the anterior branches or the intercostals,
properly so called, expose these vessels on the inside of the parietes of the chest in the
first half of their course, and then on the outside of the chest to their termination.
The aortic or inferior intercostals (i i i' i'.fig. 198), so named to distinguish them from
the superior intercostal, a branch of the subclavian, and from the anterior intercostals,
derived from the internal mammary, are generally eight or nine in number, the upper
two or three intercostEil spaces being supplied by the superior intercostal branch of the
subclavian.
The varieties in their number depend upon the number of intercostal spaces which are
supplied with branches from the subclavian, and also upon the number of intercostal ar-
teries which arise by a common trunk.
Origin. — ^They arise at various angles from the back of the aorta ; the superior gen-
erally at an obtuse angle to gain the spaces situated above them ; the succeeding ones
at different angles, which are less and less obtuse, and sometimes right angles, or even
acute angles. In the latter case, the vessel immediately ascends to reach the intercostal
space for which it is intended. The right and left intercostals are of equal size, and there
is little difference in this respect between the superior and the inferior intercostals.
In consequence of the aorta being situated towards the left side, the right intercostals
(i' i') are longer than the left. They turn over the body of each dorsal vertebra, passing
Dchind the oesophagus, the thoracic duct, and the vena azygos, and reach the correspond-
ing intercostal space. The left intercostals enter their proper spaces at once. Bot h are
in relation with the costal pleura and the thoracic ganglia of the great sympathetic nerve,
behind which they are situated. The lower intercostals on the left side are covered by
the vena azygos minor. The two lower intercostals on both sides are covered by the
pillars of the diaphragm. In their course over the bodies of the vertebras, the intercos-
tals give off numerous nutritious branches, which enter the foramina on the anterior sur-
face of these bones.
See note, p. 421.
S 8 3
ANGEIOLOGY.
On reaching the intercostal space, each artery immediately divides into an anterior
and a posterior branch.
The anterior or intercostal branches are larger than the posterior, and may be regarded
as the continuation of the arteries themselves in their original course. They are at first
situated in the middle of the intercostal spaces, between the pleura and external inter-
costal muscles ; they then pass between the external and the internal intercostals, reach
the lower border of the rib above them, and are lodged in the grooves found in that sit-
uation ; having reached tlie anterior third of the intercostal spaces, where they have be-
come extremely small, they quit the grooves, and again become placed in the middle of
the spaces ; the superior intercostals then terminate by anastomosing with the intercostal
branches of the internal mammary, and the inferior intercostals with the epigastric, the
phrenic, the lumbar, and the circumflex iliac arteries
During its whole course, each intercostal branch is in relation with the corresponding
intercostal vein and nerve. The inferior intercostal arteries, commencing at the fifth,
after leaving the intercostal spaces, are lost in the external and internal oblique muscles
of the abdomen, which, as we have seen, form, as it were, continuations of the intercostal
muscles (see Myology).
The intercostal branch furnishes numerous ramusculi to the intercostal muscles, the
ribs, the sab-pleural cellular tissue, the muscles which cover the thorax, and even to the
integuments. A very small, but tolerably constant branch, is given off at an acute angle
from the artery, at the moment where it dips between the two sets of intercostals, gains
the upper border of the rib below, and is lost in the periosteum and the muscles, after
running a variable distance.
The posterior or dorsi-spinal branches pass directly backward between the transverse
processes of the vertebrae, on the inner side of the superior costo-transverse ligaments,
and each of them immediately divides into two branches : one, the spinal, which enters
the inter-vertebral foramen, and again divides into a vertebral branch for the bodies of the
vertebrae, and a medullary branch for the coverings of the spinal cord, and for the cord it-
self, to the distribution of which we shall hereafter return. The second, or dorsal branch,
is larger than the spinal, and forms a continuation of the dorso-spinal ttunk ; it escapes
behind between the transverso-spinalis and longissimus dorsi, sends some ramifications
between the longissimus dorsi and sacro-lumbalis, and terminates in the muscles and the
skin.
Artkkies arising fkom the Abdominal Aorta.
The branches furnished by the abdominal aorta are parietal, viz., the lumbar and the
inferior phrenic arteries; and the visceral branches, viz., the cxliacaxis, the superior and
inferior mesenteric, the spermatic, the renal, and the middle supra-renal arteries. In refer-
ence to their place of origin, these arteries may be divided into those which arise from
the anterior aspect of the aorta, viz., the coeliac axis, the superior and inferior mesenter-
ic, and tne- spermatic arteries ; and those which arise from its sides, viz., the renal, the
middle supra-renal, and the lumbar arteries. The lumbar arteries might be regarded as
arising from the back of the aorta.
The Lumbar Arteries.
?%r. 199.
Dissection. — Remove the pillars of tlie diaphragm
and the psoas muscles. In order to expose the
dorsi-spinal branches, dissect the posterior spinal
muscles, and open the vertebral canal. To ex-
pose the anterior branches, dissect the abdominal
muscles carefully.
The lumbar arteries {I I, fig. 199) continue the
series of intercostals, with which they present nu-
merous analogies in reference to their origin,
course, and termination. They vary in num-
ber from three to five, but there are usually four.
These varieties depend either upon the greater or
less size of the ilio-lumbar artery, which bears the
same relation to the lumbar arteries as the superior
intercostal does to the aortic intercostals, and
which sometimes takes the place of the last, some-
times of the last two lumbar arteries ; or the va-
rieties may depend on several lumbar arteries ari-
sing from a common trunk.
Origin. — The lumbar arteries are given off at
right angles from the back of the aorta. Very
rarely the right lumbar arteries arise by a common
trunk with the left.
Course. — They proceed transversely in the
grooves on the bodies of the vertebrae, and pass
THE INFERIOR PHRENIC ARTERIES, ETC. 507
under the tendinous arches of the psoas, by which muscle they are covered. They send
a great number of branches to the bodies of the vertebrae ; and having reached the base
of the transverse processes, each of them divides into tvt^o branches, a posterior or dar-
n-spinal, and an anterior or abdominal branch.
The posterior branch, which is analogous to the dorsi-spinal of an intercostal artery, di-
vides into two branches : one, the spinal, which enters the spinal canal through the in-
ter-vertebral foramen, and subdivides into a vertebral branch for the body of the vertebra,
and a medullary branch for the cord and its coverings ; the other branch is the dorsal,
which terminates in the muscles and integuments of the lumbar region.
The antericrr branch is smaller, and analogous to the anterior branch of an intercostal
artery : it is situated between the quadratus lumborum and the middle layer of the apo-
neurosis of the transversalis, and ramifies in the substance of the abdominal muscles.
The anterior branch of the first lumbar artery runs along the lower border of the twelfth
rib, passes obUquely downward and forward, and divides into two ramuscuU, one of which
continues in the same course, while the other turns downward to the crest of the ihum.
The anterior branches of the second and third pair of lumbar arteries are generally small :
not unfrequently the third artery is wanting. The anterior branch of the fourth lumbar
artery runs along the crest of the ilium, and sends branches to the muscles of the abdo-
men and to the iUacus and glutaei muscles.
The Inferior Phrenic Arteries.
Dissection. — Careful.y detach the peritoneum from the lower surface of the diaphragm.
The inferior phrenic or diaphragmatic, or the sub-diaphragmatic arteries {d d. Jig. 199), so
named in contradistinction to the superior phrenic, which are branches of the internal
mammary, are so frequently derived from the coeliac axis, that some anatomists, Meckel
among others, describe them as branches of that trunk. They are two in number, a
right and a left. They arise from the aorta, immediately below the cordiform tendon of
the diaphragm, either side by side, or by a common trunk. Sometimes they arise from
the coeliac axis itself, or, rather, from the coronary artery of the stomach, from the renalj
or from the first lumbar artery ; in some subjects we find as many as three or four.
Each artery passes upward and outward in front of the corresponding pillar of the dia-
phragm, gives some twigs to this pillar, and one to the supra-renal capsule, and then di-
vides into two branches, an internal and an external. The internal branch passes direct-
ly forward, ramifies and anastomoses by loops with the vessel of the opposite side around
the oesophageal opening, behind the cordiform tendon of the diaphragm. The exteriial
branch is larger and more tortuous than the preceding ; it proceeds obliquely outward,
between the peritoneum and the diaphragm, and divides into a great number of branches,
which extend as far as the attachments of this muscle, where they anastomose with the
intercostal and the internal mammary arteries.
The right inferior phrenic artery, moreover, sends some branches into the coronary
ligament of the liver ; the left artery gives off a branch to the oesophagus, which enters
through the oesophageal opening in the diaphragm, and joins the oesophageal branches
derived from the coronary artery of the stomach and from the aorta.
The Cceliac Axis,
Dissection. — Elevate the liver by means of hooks, or by a ligature fixed to the right
side of the chest ; depress the stomach ; divide the fold of peritoneum by which these
two viscera are united ; and search for the coeliac axis between the pillars of the dia-
phragm, by removing the solar plexus of nerves, which forms a thick layer in front of it.
The caliac axis or artery (from KoiXia, the belly or stomach, y, fig. 199), le tronc opis-
thogastrique, Chauss. {oTTiadev, behind, yaarrip, the stomach), supplies the stomach, the
liver, the spleen, the pancreas, and the great omentum. It is remarkable for its size,
being larger than any of the other branches of the abdominal aorta, not excepting the
superior mesenteric ; for arising at a right angle from the front of the aorta, immediate-
ly below the phrenic arteries ; for its horizontal course, which is rarely more than five
or six lines in extent, and for its very early division into three branches, ad modum tri-
dentis. These three branches are of unequal size : they are the coronary artery of the
stomach {b, fig. 200), the hepatic (c), and the splenic (d), which, together, are called the
caliac tripos, or the tripos of Holler.
In its short course the coeliac axis is in relation with the lesser curvature of the stom-
ach, or, rather, with the gastro-hepatic omentum, behind which it is situated ; on the
left side, it is in relation with the cardia ; below, with the upper border of the pancreas,
upon which it rests ; above, with the left side of the lobulus Spigelii. It is surrounded
by so large a plexus of nerves, that it cannot be exposed until the plexus is removed.
The Coronary Artery of the Stomach.
The coronary artery of the stomach, or the superior gastric {b,figs. 200, 201), is the small-
est branch of the coeliac axis. It is directed upward and to the left side, to reach the
(Esophageal orifice of the stomach ; it then turns suddenly to the right side, pursues a
90i
ANGEIOLOGY.
Fig. 200.
semicircular course along the lesser curvature
(arteria coronaria ventriculi), and terminates by in
osculating with the pyloric artery (e), a branch
from the hepatic.
In this course it gives off from its convex bor-
der ascending (esophageal branches, which peiss
through the (Esophageal opening of the dia-
phragm, ascend upon the oesophagus, and are
there distributed like the aortic oesophageal
branches, with which they anastomose ; also car-
diac branches, which form a vascular network
around the oesophageal opening of the stomach,
and pass transversely upon its great tuberosity ;
and a series o( gastric branches, which arise along
the lesser curvature, and are divided into two
sets, an anterior set for the front, and a posterior
set for the back of the stomach. No branch ari-
ses from the concavity of the curve formed by
this artery.
Not unfrequently the coronary artery of the
stomach gives off an hepatic branch, and hence
the first branch of the coeliac axis has been called
the gastro-hepatic by some anatomists. In such
cases, as may be conceived, this artery is very
large. It is also not uncommon to find the left
inferior phrenic arising from it.
The Hepatic Artery.
The hepatic artery (c, Jigs. 200, 201) is larger than the preceding. It passes trans-
versely from the left to the right side, describing a curve, having its concavity directed
upward, and moulded, as it were, upon the lobulus Spigelii. Near the pylorus it chan-
ges its direction, and passes upward to the transverse fissure of the liver, where it di-
vides into two branches. In the latter part of its course it is contained within the gas-
tro-hepatic omentum, in front of the foramen of Winslow, and is in relation with the
ductus choledochus and the vena portse, the vein being placed behind both the artery
and duct.
It is not uncommon to find two hepatic arteries, one derived from the coronary of the
stomach, and the other from the superior mesenteric. Sometimes there are even three
hepatic arteries, one from the coronary of the stomach, a second from the superior mes-
snteric, and a third from the coeliac axis.
Collateral Branches. — The hepatic artery gives off three collateral braiiihes, the pylo-
ric, the right gastro-epiploic, and the cystic.
The pyloric artery, also named the small right gastric artery, to distinguish it from the
coronary artery of the stomach, which was called the left gastric (c), is a small vessel
which arises from the hepatic, near the pylorus : it runs from right to left along the
pylorus and the lesser curvature of the stomach, and inosculates with the coronary ar-
tery (6) of that viscus. Two sets of branches, an anterior and a posterior, arise from
its convex border, and are distributed to the stomach and the first part of the duodenum,
in the same manner as those from the coronaria ventriculi itself Not unfrequently the
pyloric artery terminates near the pylorus, without anastomosing with the coronary.
T\ie right gastro-epiploic artery (f,figs. 200, 201) is remarkable for its size and for its
length. It passes vertically downward, behind the first portion of the duodenum, near
the pylorus. Having reached below the duodenum, it changes its direction, passes from
right to left (Z) along the great curvature of the stomach, where it inosculates with the
left gastro-epiploic {h, fig. 201). In one case, where the hepatic artery was given off
by the superior mesenteric, the right gastro-epiploic arose directly from the coeliac axis.
The first portion of this vessel, usually called the gastro-duodenal artery, furnishes sev-
eral branches to the pylorus, which may be called the inferior pyloric ; it then gives a
branch to the duodenum and the head of the pancreas, named the pamreatico-duodena-
lis (k), and remarkable for its anastomosing with the superior mesenteric ; an arrange-
ment that leads, as it were, to the cases in which the hepatic itself is derived from the
last-mentioned artery ; it is also remarkable for its size, which is sometimes such that
the continuation of the vessel, the right gastro-epiploic artery proper, is only half the
size of the trunk from which it is given off (the gastro-duodenal).
In its horizontal portion along the great curvature of the stomach, the right gastro-
epiploic sends both ascending and descending branches : the former, or gastric branches,
divide into two sets ; one for the anterior, and one for the posterior surface of the stom-
ach The latter, or epiploic branches (g g, fig. 200J, are extremely long and slender ;
THE SPLENIC AND SUPERIOR MESENTERIC ARTERIES. 509
they pass downward parallel to each other, without any windings, in the substance of
the two anterior layers of the great omentum, are reflected upward at its lower border,
just as the two layers are themselves, and accompany them as far as the transverse
colon, to which they are distributed.
The cystic artery (i, fig. 200) is a small vessel which almost always arises from the
right of the terminal divisions of the hepatic artery, reaches the neck of the gall-blad-
der, and divides into two branches ; one superior, running between the liver and the
vesicula, the other inferior, which pursues a tortuous course between the peritoneum
and the proper coat of the gall-bladder, divides and subdivides, and is finally distributed
to the mucous membrane.
Termhial Branches. — Of the two terminal branches of the hepatic artery, one dips into
the right extremity of the transverse fissure of the liver, and the other into the left ex-
tremity of the same fissure : in these situations they become applied to the correspond-
ing branches of the vena portae and hepatic duct, are enclosed with them in the capsule
of Glisson, and closely accompany the corresponding ramifications of those vessels
through all their divisions and subdivisions.
The Splenic Artery.
The sflenic artery {d, figs. 200, 201) is larger Fig. ZOi.
than either of the other divisions of the cceliac
axis. Immediately after its origin it is received
into a shght groove formed along the whole of the
upper border of the pancreas (i). It passes from
the right to the left side, and is exceedingly tor-
tuous in its course :* having reached the hilus
of the spleen, it divides into a great number of
terminal branches (w, fig. 201), which enter that
organ separately. It is not rare to find one of
these branches detached from the others, to be
distributed either to the upper or the lower end
of the spleen.
Near the spleen, the splenic artery and its di-
visions are enclosed within the gastro-splenic omentum.
The relations of the splenic artery to the posterior surface of the stomach explains
how, in certain cases of ulceration of the stomach opposite the pancreas, this artery
may become the source of haematemesis.
The splenic artery gives off several collateral branches :
The pancreatic arteries (i i), which are variable in number, and are very large, consid-
ering the size of the organ to which they are distributed.
The left gastro-epiploic artery (h), which often arises from one of the divisions of the
splenic, passes vertically downward, behind the great end of the stomach, gains the
great curvature, along which it runs from left to right, and anastomoses with a branch
of the hepatic, viz., the right gastro-epiploic (l) ; like which artery, it sends off ascending
or gastric, and descending or epiploic branches. The size of the gastro-epiploica sinistra
varies much, and has an inverse proportion to that of the gastro-epiploica dextra.
The vasa brevia (o o), which are remarkable for their number and shortness, generally
arise from one or several of the terminal branches of the splenic artery, just as these
are entering the spleen ; they pass directly, by a retrograde course, from that organ to
the great cul-de-sac of the stomach, as far as the cardia, where they anastomose with
the cardiac branches of the coronary artery of the stomach.
From the preceding description of the branches of the cceliac axis, we perceive that
the stomach is surrounded by an uninterrupted arterial circle, formed by the right and
left gastro-epiploic, by the pyloric, and by the coronary arteries ; and that, secondly, the
branches derived from this circle constitute an anastomotic network upon the anterior
and posterior surfaces of the stomach.
The Superior Mesenteric Artery.
Dissection. — Look for the origin of the artery between the pancreas and the third por-
tion of the duodenum ; turn the whole of the small intestines to the left side ; remove
with care the right layer of the mesentery, the left layer of the right lumbar mesocolon,
the inferior layer of the transverse mesocolon, and the numerous lymphatic glands which
conceal the artery and its divisions.
The superior mesenteric artery (below y,fig. 199) is the artery of the small intestine,
and of the right half of the large intestine. It arises from the front of the aorta, imme-
* I have seen some splenic arteries not at all tortuous ; and at other times I hare found the curvatures so
decided that the lower part only of the curves came in contact with the pancreas. Why do these curvatures
exist ? It cannot be to accommodate the variations in the size of the spleen ; but is it to retard the now ol
the blood ? There is no proof of it ; indeed, the law which governs the existence of a tortuous condition ol
certain arteries is yet to he discovered. The caliber of the splenic artery is strictly proportioned to the size
of the spleen. Where it is strophied the artery is small ■ where hypertrophied, it becomes enormously enlarged
ANGEIOLOGY.
diately below the coeliac axis, and very rarely from a common trunk with it. It is at
first situated behind the pancreas, and then passes vertically downward, between that
gland and the third portion of the duodenum, which is crossed at right angles by it,
and of which it forms the lower boundary {vide Duodenum) ; it at length reaches the
mesentery, opposite the point (a, fig. 202)
where that fold meets the transverse meso-
colon. Continuing its course within the sub
stance of the mesentery, and following its ad-
herent border, it describes a slight curve, with
the convexity directed to the left and the con-
cavity to the right side : gradually diminish-
ing in size as it advances, it proceeds to oppo-
site the ileo-caecal valve (i), and then becomes
so small that it can no longer be distinguished
from the branches given off from it. It fol-
lows, therefore, that the trunk (a b) of the su-
perior mesenteric artery corresponds with the
adherent border of the mesentery, with the
length of which it, as it were, agrees.
Collateral Branches. — While behind the pan-
creas, the superior mesenteric sends off pan-
creatic branches {k), which anastomose with
those derived from the hepatic and the splenic
arteries ; it rather frequently gives off the he-
patic, and it is then larger than the coeliac
axis.
In the mesentery, the superior mesenteric
gives off two sets of branches : one set ari
sing from its convexity, and forming the arter-
ies of the small intestine ; the other set from its
concavity, viz., the arteries of the great intestine, called the right colic arteries.
The arteries of the small intestine have received no particular name ; they are large
branches, directed obliquely downward and forward, all of which proceed parallel to
each other in the substance of the mesentery, towards the concave border of the small
intestine. Their number is irregular, and their size unequal : seven or eight of them
are at least equal in size to the radial artery, others are smaller ; the superior branches
are generally the largest. Their number is calculated at from fifteen to twenty.
After a course of about two or three inches, each of them bifurcates ; the branches
of the bifurcation separate from each other, and, curving into arches, inosculate with
the neighbouring branches. From the convexity of this series of arches, which is turn-
ed towards the intestine, a multitude of branches arise, which soon bifurcate, and form
anastomotic arches {d d d), which, as they are nearer the small intestine, describe a
curve of much greater extent in the mesentery than the first series. From the con-
vexity of this second series of arches a great many more branches arise than were given
off from the first series. Lastly, from the division of these branches a third series of
anastomotic arches is formed, which is still nearer the concave border of the intestine
than the second.
There are only three series of arches at the commencement and the termination of
the small intestine ; but in the middle there is a fourth, sometimes even a fifth.
From the convexity of the arches nearest to the small intestine arise two sets of ves-
sels, intended for the two halves of the cylindrical gut. Each of these sets of vessels
divides into superficial branches, which, ramifying beneath the peritoneum, form a super-
ficial network, and anastomose upon the convex border of the intestine ; and into deep
branches, which perforate in succession the muscular and cellular coats, and terminate
in an inextricable network in the mucous membrane.
The series of anastomotic arches formed by the divisions of the superior mesenteric
artery, not only regulate the current of the blood, but also enable a small number of
branches, occupying a very Umited space at the root of the mesentery, to supply branches
to so great an extent of surface as the entire length of the small intestine, which is from
fifteen to twenty-one feet. This spreading out of the vessels over a large surface will
be still better seen in the arrangement of the arteries of the great intestine.
The arteries for the great intestine, or the right colic arteries, are two or three in num-
ber, and are distinguished into the superior (e), middle (/), and inferior (A). They arise
from the concavity of the curve formed by the superior mesenteric artery, and pass from
the mesentery, in which they are enclosed at their origin, into the right lumbar meso-
colon. The superior is ascending, the middle horizontal, and the inferior descending ;
near the great intestine they bifurcate. The branches of the bifurcation anastomose,
and form very large arches, with their convexities turned towards the great intestine.
From these arches the intestinal branches take their origin directly, and divide into two
m
THE INFERIOR MESENTERIC ARTERY, ETC.
511
Fig. 203.
sets of parallel ramifications, an anterior and a posterior, which, like those of the small
intestine, subdivide into the sub-peritoneal and the deep branches, and terminate in the
different coats of the intestine. Where the primary anastomotic arches are situated at
a certain distance from the intestine, for example, opposite the angles of bifurcation of
the arteries, or opposite the angles formed by the ileum with the caecum, and by the as
cending with the transverse colon, we find one, or even two, small arches filling up the
angular interval.
The upper branch (g) of the right superior colic artery (e, figs. 202, 203), which sup-
plies the right half of the arch of the colon, anastomoses with the upper branch of the
left colic artery Cf^fig- 203), which is derived from the inferior mesenteric (c). This re-
markable anastomosis between the superior and inferior mesenteric arteries has been
pointed out by anatomists as the most important anastomosis in the body.
The lowest branch of the right inferior colic artery (A, fig. 202) anastomoses with the
termination (J) of the superior mesenteric, which becomes exceedingly slender. This
right inferior colic, or ileo-colic artery (h), supplies the caecum, the ileo-caecal angle, and
the appendix vermiformis.
The Omphalo-mcsenteric Artery. — In the early periods of intra-uterine life, the superior
mesenteric artery gives off a branch, called the omphalo-mesentenc, which reaches the
umbilicus, passes out of the abdomen, traverses the entire length of the cord, and is dis-
tributed upon the umbilical vesicle. I have found this artery perfectly distinct in an
anencephalous fcEtus at the full term ; it is generally obliterated towards the end of the
second month of intra-uterine life.
The Inferior Mesenteric .Artery.
Dissection. — Turn the small intestines to the right side ; spread out the arch of the
colon, the right lumbar colon, and the sigmoid flexure ; remove the peritoneum, which
forms the inferior layer of the transverse mesocolon, and the right layer belonging to the
descending colon and sigmoid flexure.
The inferior mesenteric artery (m,fig. 199 ; c,fig. 203) is much smaller than the supe-
rior. It arises from the front" of the aorta, about
two inches above the bifurcation of that vessel.
It descends vertically in front of, and in contact
with the aorta, and then in front of the left com-
mon iliac artery. It is at first enclosed in the ili-
ac mesocolon, but afterward enters the meso-rec-
tum, where it divides into two branches, which
are named the superior hemorrhoidal {h, fig. 203).
In this course, the inferior mesenteric gives off
no branch on the right side ; on the left it gives
two, more frequently three branches, called the
left colic arteries (/), which are distributed in pre-
cisely the same manner as the right colic arteries.
I have already said that the upper division of the
left superior colic artery (/) inosculates with the
upper division (g) of the right superior colic (c).
Near the sigmoid flexure we find two, and some-
times three series of arches from the sigmoid
branch, so arranged that the last may reach the
intestine.
The superior hemorrhoidal arteries are distribu-
ted to the rectum, in the same manner as the other
intestinal arteries ; near the sphincter, they anas-
tomose with the middle hemorrhoidals, which
are derived from the internal iliac arteries.
The Spermatic Arteries — the Arteries of the Testicles in Man, and the Utero-
ovarien in Woman.
Dissection. — Remove carefully the mesentery and the peritoneum. Follow these ar-
teries, in man, through the inguinal passages imbedded in the substance of the sper-
matic cord, down to the testicle and the epididymis ; and in woman, follow them into the
substance of the broad ligament as far as the ovaries on one side, and on the other, as
far as the bottom and the body of the uterus. To inject perfectly these arteries to their
termination, recourse must be had to very penetrating liquids, or, what is better, to par-
tial injections.
The spermatic arteries (o o,fig. 198 ; ff,fig. 199) are distributed to the testicles in the
male, and to the ovaries in the female.
They are two in number, and are as variable in their origin as they are regular in their
course and distribution.
Their origin is remarkably distant from their termination ; an unsatisfactory attempt
®
612 ANGEIOLOGY.
has been made to explain this circumstance by referring to the situation of the testicle in
the foetus.
Varieties of Origin. — These arteries generally arise from the front, sometimes from
the side of the aorta, below the corresponding renal artery, rarely above it, and still
more rarely from the renal itself It is rather rare for the right and left spermatics to
come off at the same heights. I have seen the right spermatic artery arise below the
renal, and the left by the side of the inferior mesenteric*
Whatever may be their origin, these arteries pass directly downward. Sometimes
they come off at a riglit angle, and then curve downward, so as to descend almost ver-
tically upon the sides of the spine, behind the peritoneum, in front of the corresponding
psoas muscle and ureter, and on the inner side of the spermatic veins. The right sper-
matic artery is in relation with the vena cava inferior, and almost always passes in front,
but sometimes behind it ; the artery of the left side is situated behind the sigmoid flex-
ure of the colon. On both sides, having reached the side of the pelvis, the artery is sit-
uated on the inner side of the psoas, in front of the external iliac artery, and is then dif-
ferently distributed in the two sexes.
Li the male {f, fig- 199), it enters the abdominal orifice of the inguinal canal, along
which it proceeds, and, together with the vas deferens and the spermatic veins, forms the
spermatic cord ; it escapes from the canal, and, at a greater or less distance from the
ring, divides into two branches, one of which enters the head of the epididymis, while
the other, the testicular, penetrates the testicle at its upper border, and is then distribu-
ted as already described (see Testicles).
In the female, the ovarian arteries (o o,fig. 198), which are much shorter than the
spermatics of the male, dip into the pelvis, reach the upper border of the ovaries, supply
them, and also the Fallopian tubes, with a great number of branches, and terminate
upon the sides of the uterus, by anastomosing freely with the uterine arteries (« w').+
The ovarian arteries are distributed more to the uterus than to the ovary, as may be
proved by the post mortem examination of the body of a pregnant or puerperal female ;
for it is then seen that the ovarian arteries also become largely developed as well as the
uterine, and that the branches sent to the uterus are enormous in comparison with those
given off to the ovaries.
The ovarian arteries are very tortuous, especially opposite the brim of the pelvis ;
they are quite as much convoluted as the uterine arteries.
The Renal or Emulgent Arteries.
Dissection. — The renal arteries are prepared after the intestines, the peritoneum, the
renal adipose tissue, and the numerous nervous filaments by which the arteries are sur-
rounded, have been removed.
The renal or emulgent arteries {,e e,fig. 199) arise at right angles from the side of the
aorta, above the inferior mesenteric : the left renal artery often arises a little higher
than the right, doubtless on account of the size of the liver. These arteries are very
large in comparison to the kidney, for they are nearly equal in size to the cceliac axis,
or the superior mesenteric ; they are remarkable for their transverse, and, generally,
straight direction ; for their shortness ; and, lastly, for their numerous varieties. These
we shall now mention.
Varieties as to Number. — There is generally one for each kidney, but frequently there
are two, three, or four. Varieties as to Origin. — Not uncommonly the renal arteries arise
from the aorta lower down than usual, or even from the common iliac or the internal
iliac. The two latter modes of origin are scarcely observed, excepting when the kidney
is displaced, and occupies either the ihac fossa or the cavity of the pelvis. In a case
which I recently examined, the kidney occupied the cavity of the pelvis, and there were
two renal arteries, one of which arose from the aorta at its bifurcation, and the other
near the inferior mesenteric. Lastly, I should add that Meckel has seen the two renal
arteries arise by a common trunk from the front of the aorta. Varieties in Direction.—
When two renal arteries arise from the same side, or when one divides into two branch-
es, I have found them, in several cases, twisted spirally round each other, like the um-
bilical arteries. Varieties as to Division. — The renal artery sometimes divides immedi-
ately after its origin ; and then one of the branches, separating itself from the others,
proceeds to one or other extremity of the kidney. Such a mode of division leads to
those cases in which there is more than one artery.
Relations. — The renal arteries are covered by the peritoneum and the corresponding
renal veins ; they are surrounded by a quantity of adipose cellular tissue, and they rest
behind upon the bodies of the vertebrae. The right renal artery is also covered by the
inferior vena cava. In one case, where there were two renal arteries on the right side,
one of these was in front, and the other behind the vena cava.
* It IS not micommon to meet witn two spermatic artenes on one siae
t We know that the development of the uterus, (luring the first five months a& pregnancy, takes place al-
most exclusively at the expense of the body, and that the neck of the uterus be^ns to be developed from the
fifth to the sixtii month. I have seen some diseases of the uterus in which a sort of independence might have
been traced between the neck and the body of the womb.
THE CAPSULAR ARTERIES, ETC. 618
Collateral Branches. — The renal arteries give off some small twigs to the supra-renal
capsules, which are called the inferior capsular or supra-renal, and also some small branch-
es to the adipose tissue which covers the kidney, and to its proper cellular coat.
Terminal Branches. — At the hilus of the kidney, the renal artery divides into three or
tour branches, all of which enter the hilus, between the pelvis of the ureter, which is
behind, and the branches of the renal vein, which are in front. The arteries subdivide
in the kidney so as to form a network at the Umits between the tubular and cortical sub-
stances. (See Kidney.) A very few of the branches from this network proceed to the
tubular substance, almost all of them being distributed to the cortical substance. Most
anatomists have remarked the facility with which even coarse injections pass from the
renal arteries into the veins and ureters.
The Middle Supra-renal, or Capsular Arteries.
The middle supra-renal arteries {s s,fig. 199), so named in contradistinction to the supe-
rior vessels of the same name, derived from the diaphragmatic and the inferior, pro-
ceeding from the renal, are of large size in comparison with the organ to which they are
distributed. They arise from the sides of the aorta, above the renal, supply twigs to the
surrounding fat, and to the pillar of the diaphragm, run along the concave border of the
corresponding supra-renal capsule, give off anterior and posterior branches, which enter
the furrows on the surface of that organ, and penetrate and ramify in its interior.
ARTERIES ARISING FROM THE ARCH OF THE AORTA.
Enumeration and Varieties. — The Common Carotids. — The External Carotid — the Superior
Thyroid — the Facial — the Lingual — the Occipital — the Posterior Auricular — the Parotid
— the Ascending Pharyngeal — the Temporal — the Internal Maxillary. — The Internal Ca-
rotid— the Ophthalmic — the Cerebral Branches of the Internal Carotid. — Summary of the
Distribution of the Common Carotids. — Artery of the Upper Extremity. — The Brachio-Ce-
phalic. — The Right and Left Subclavian^ — the Vertebra} and its Cerebral Branches, with
Remarks on the Arteries of the Brain, Cerebellum, and Medulla — the Inferior Thyroid —
the Supra-scapular — the Posterior Scapular — the Internal Mammary — the Deep Cervical
— the Superior Intercostal. — The Axillary — the Acromio-thoracic — the Long Thoracic — the
Sub-scapular — the Posterior Circumflex — the Anterior Circumflex. — The Brachial and its
Collateral Branches. — The Radial, its Collateral Branches, and the Deep Palmar Arch. —
The Ulnar, its Collateral Branches, and the Superficial Palmar Arch. — General Remarks
on the Arteries of the Upper Extremity.
Three arterial trunks, intended to supply the head and the upper extremities, take
their origin from the arch of the aorta. Proceeding in the order in which they arise, i. e.,
from right to left, they are the innominate or brachio-cephalic {e,fig. 198), which soon sub-
divides into the right common carotid (/) and right subclavian (g), the left common carotid (f)
and the left subclavian (g).
The direction of that portion of the arch of the aorta which gives origin to these arter-
ies is such, that they are arranged one after the other upon a plane which slopes down-
ward, backward, and to the left ; so that the trunk of the innominate artery lies almost
immediately behind the sternum, while the left subclavian is near the vertebral column.
Varieties. — These three arteries present numerous varieties in their origin, all of which
appear to me to be referrible to the three following heads : varieties by approximation or
fusion, varieties by multiplication, and varieties by transposition of their origins. In
many cases, several of these kinds of varieties may coexist.*
Varieties by Approximation or Fusion of Origins. — Sometimes the left common carotid
becomes closely approximated to the brachio-cephalic trunk ; and this condition leads us
to the not very uncommon variety in which these two vessels arise by a common trunk, t
Again, two brachio-cephalic trunJjs may be given off from the arch of the aorta, one on
the right, the other on the left side.t Of these two trunks which arise from the aorta,
the first, which is the most voluminous, gives origin to the two carotid arteries, and to
the right subclavian ; the second, which is the smallest, gives origin to the left subcla-
vian. The greatest amount of variety of this kind is observed in the case where the
three branches which usually arise from the arch are united into one common trunk,
which forms an ascending aorta. In this case, there is no arch of the aorta ; the aorta,
* [A variety, affecting merely the situation of the three primary vessels upon the arch, is noticed by Pro-
fessor R. Quain {Operacit.). It consists in those vessels arising to the riglit of their usual position, t. e., near-
er to the origin of the aorta.]
t I have often seen these three branches, viz., the brachio-cephalic trunk, the left primitive carotid, and the
left subclavian, arising by tlie side of each other, so that their three orifices were only separated, as it were,
by a spur.
i This variety, which, together with the preceding, constitutes the normal state of some animals, seems,
moreover, th& reproduction of the normal disposition of the venous system, in which there are two cephalic
venous trunks, one right, the other left, which unite for the purpose of forming the superior vena cava. Meck-
el, I believe, was the first to remark that certain anomalies of the arterial system might be attributed to the
normal disposition of the venous system. — (See the excellent article of Dr. Rendu, Memoir on the History of
Arterial Anomalies, Gazette Medicate, 1842, vol. x., p. 129.)
Ttt
514 ANGEIOLOOY.
immediately after its origin, is divided into ascending and descending. This arrange-
ment is normal in the ox, the horse, the sheep, the goat, and some other animals.*
Varieties by Multiplication of Origin. — Sometimes the two common carotids arise sep-
arately in the interval between a right and a left subclavian, a condition that leads us to
the case in which the two carotids arise by a common trunk between the separated sub-
clavians. Again, the left vertebral artery may arise directly from the aorta, between
the left carotid and subclavian ; this is very common : or the two vertebrals, the two
carotids, and the two subclavians may all arise separately ; or the inferior thyroid, or the
thyroid of Neubauer, from the name of the anatomist who first described this variety,
may arise directly from the curvature of the aorta ; lastly, the right internal mammary
and the left vertebral may arise directly from the arch of the aorta.
Varieties by Transposition or Inversion of Origin. — The brachio-cephalic trunk is some-
times found on the left side instead of the right ; still more frequently the right subcla-
vian arises separately below the left subclavian, and then passes upward and to the
right side, most commonly behind the trachea and oesophagus, but sometimes between
these two canals. Again, the trunks arising from the arch of the aorta have been seen
to be given off in the following order : a single trunk for both common carotids ; then
the left subclavian ; and, lastly, the right subclavian, which arose from behind the arch
of the aorta, and passed as in the preceding case. A fifth variety consists in a combi-
nation of the variety by transposition either with the variety by fusion or with the vari-
ety by multiplication.
The Common Carotid Arteries.
Dissection. — Dissect the anterior cervical region, preserving all the parts in relation
to the vessels. In order to see the tlioracic portion of these arteries, remove the upper
part of the sternum.
The primitive or common carotid arteries {ff, jig. 198 ; a, fig. 204) are the arteries of
the head. Their limit above is marked by the upper border of the thyroid cartilage, op-
posite which they divide into the external and internal carotids. +
They are two in number, distinguished as the right and left : they differ as to their
origin, their length, and their directions ; thus, on the left side, the common carotid ari-
ses directly from the aorta ; on the right, it arises from a trunk common to it and to the
subclavian, viz., the innominate, or brachio-cephalic artery {e,fig. 198). As the brachio-
cephalic and the left common carotid are given off from the aorta nearly at the same
level, it follows that the left common carotid is longer than the right by the entire length
of the brachio-cephalic.
It follows, also, from the obliquity of the arch of the aorta, that the left common ca-
rotid is placed much deeper than the right at its origin ; but, in the cervical region, the
two carotids are upon the same plane.
They pass somewhat obliquely upward and outward immediately after their origin,
but they are directed vertically and parallel to each other in the cervical region. t The
interval between them is occupied by the trachea and the oesophagus below, and by the
larynx and phaiynx above. Their course is straight, and without any winding. Their
diameter is uniform throughout, a circumstance which is connected with the absence
of any collateral branches. The caliber of these arteries is relatively larger in man than
in other animals ; and this has reference to the greater size of his brain. I have not ob-
served any difference in diameter between the right and left common carotids.
As about one inch in length of the left common carotid lies in the thorax, its relations
must be separately studied in that situation.
Relatians of the Thoracic Portion. — In front, with the left subclavian vein, and the ster-
no-hyoid and sterno-thyroid muscles, which separate it from the sternum ; behind, with
the trachea and oesophagus, and with the left subclavian and left vertebral arteries ; on
the outside, with the pleura or the left wall of the mediastinum ; on the inside, with the
brachio-cephalic trunk, from which it is separated by a triangular interval, in which the
trachea is visible.
Relations of the Cervical Portion. — These are the same for both arteries. In front,
each common carotid is covered below by the stemo-mastoid, and more immediately by
the sterno-hyoid, sterno-thyroid, and omo-hyoid muscles, the latter of which crosses
the artery obliquely.^ In its upper half it corresponds to the platysma myoides, which
separates it from the skin. The cervical fascia, the superior thyroid vein, and the de-
scendens noni, a branch of the hypoglossal nerve, are in more immediate relation with
* Some anomalies of the arterial system of man may be in some measure explained from the normal state
of the arterial system of certain animals ; but the number of such cases is extremely limited. I do not know
whether any one hai ever thought of applying- to these anomahes the rule of the arrest of development, wliich
some have lately made to play such an exaggerated part in the theory of the vices of conformation.
t [The common carotid has been seen to divide above the os hyoidos, also opposite the thyroid cartilage,
and even low down in the neck.]
t [In consequence of the larynx being wider than the trachea, the common carotids arc not quite parallel
in the neck, but are somewhat farther apart above than below.]
I) In order to omit nothing, I should say that the common carotid is crossed obliquely by a branch which i»
given off from the superior thyroid artery to the stemo-niastoid muscle.
THE EXTERNAL CAKOTID ARTERY.
515
It. The most important of these relations is that with the sterno-mastoid, which, in a
surgical point of view, may be regarded as its satellite muscle. Behind, the common
carotid is the vertebral column, from which it is separated by the pre- vertebral muscles,
the great sympathetic nerve, and below by the recurrent nerve and inferior thyroid
artery.* On the itiside, it is in relation with the trachea, oesophagus, larynx, and thy-
roid gland, which passes in front of the artery when larger than usual ; on the outside
of the artery is the internal jugular vein. The pneumogastric nerve lies at the back,
between the artery and vein. The common carotids are also surrounded by much loose
cellular tissue, and by some lymphatic glands.
The left common carotid is in more direct relation with the oesophagus than the ar-
tery of the right side.
The common carotids give off no branch during their course : nevertheless, it is not
very rare for this artery to give off the inferior thyroid artery, or a supernumerary branch
known as the middle thyrmdA Neabauer has seen the common carotid give off a thy-
roid artery, and the internal mammary of the right side.
Terminal Branches. — Having reached the upper border of the thyroid cartilage, at a
variable height, according to the subject, the common carotid divides into two branches,
called the external and internal carotids, which, by no means a common arrangement, do
not leave each other at an acute angle, but remain in contact, and even frequently be-
come crossed before they separate. The point of division is also remarkable for a sort
of ampulla or dilatation, which the primitive carotid exhibits. Sometimes the primitive
carotid bifurcates much sooner than usually. Morgagni relates a case in which the
bifurcation took place at the distance of an inch and a half from the origin of the ar-
tery. Sometimes the primitive carotid does not terminate in a bifurcation. In such a
case, all the branches given off by the external carotid arise successively from the prim-
itive carotid, which penetrates the cranium and terminates as the internal carotid.
The External Cakotid Artery.
Dissection. — Prolong the incision made for exposing the conmion carotid as far as th,e
neck of the condyle of the lower jaw. Dissect carefully the styloid muscles and the diga!s-
tricus, and cautiously separate the artery from the surrounding tissue of the parotid gland .
The external or superficial carotid artery {h,fig. 204) is, in a great measure, intitw !
Fig. 204.
for the face, and has, therefore, been
called the facial carotid by Chaussier.
It arises from the conunon carotid,
forming one of its two divisions, and
extends as far as the neck of the con-
dyle of the lower jaw, where it termi-
nates by dividing into the temporal and
internal maxillary arteries.
The origin of this artery is remark-
able for being situated on the inner
side of the internal carotid. It as-
cends vertically as high as the digas-
tricus, and passes under that muscle ;
it is then directed a little backward
and outward, leaves the vertebral col-
umn, reaches the angle of the lower
jaw, and again becomes vertical as it
proceeds upward to the neck of the
condyle, opposite to which it termi-
nates. It is very slightly tortuous in
the adult, and in the infant is almost
straight. In the adult it is nearly equal
in size to the internal carotid, but it is
much smaller in young subjects. It diminishes rapidly in diameter, on account of thn
number of branches given off from it, so that at its termination it is scarcely one tliird
Its origmal size. Sometimes it divides immediately into a sort of bunch of arterial ves-
sels ;in other cases its branches arise in succession from the common carotid, which is
then directly continuous with the internal carotid. ±
J\.^ l^^^^J °^ relations which it is important to know m a surgical point of view is the relation which often
exists behind, between the right primitive carotid and the trachea. Where this anomaly eiists, the brachio-
cephalic trunk arises a Lttle more to the left side than usually «:»J»t»,
t This supernumerai7 artery arises at different elevations, 'in a case which has been communicated to me
.IJa ^Tv't i '^^ '^'^'^^^ °l s"P?"iumerary thyroid artery was given off by the right primitive ca-
rotid at the distance of a centrmeter from the innominata. It passed up in a straight line into the gland, where
nfT.i? i ,1' a"|=""'5t°'n°s'='i freely with the superior and inferior thyroidian arteries on each side. The right
inferior thyjoidian artery was not half as voluminous as usual. Mr. Dubreuil, who teaches anatomy with so
much talent at Montpelier, has communicated to me several arterial anomalies, which are to be inserted in a
professional work that he is prnparing on that subject in a surgical point of view
» It IS doubtless on account of the numerous branches given off by the external carotid that several ancient
516 ANGEIOLOGY.
Relations. — It is superficial at its origin, like the upper part of the common carotid,
and, like it, is merely separated from the skin by the platysma myoides ; but it then
dips into the supra-hyoid region, below the digastricus, the stylo-hyoideus, and the hypo-
glossal nerve.* Higher up it is situated deeply in the parotid excavation, surrounded
on all sides by the tissue of the parotid gland, which, on this account, cannot be entire-
ly extirpated without wounding the vessel.
Collateral Branches. — These are six in number, and are arranged into three sets, viz.,
an anterior set, consisting of the superior thyroid, the facial, and the lingiud ; a posterior,
including the occipital and the auricular ; and an internal set, formed by one vessel, the
inferior, or ascending pharyngeal.
The terminal branches are two in number, the superficial temporal and the internal max-
The Superior Thyroid Artery.
The superior thyroid artery (d. Jig. 204) belongs both to the larynx and the thyroid
gland. It is the first branch given off from the external carotid ; it rather frequently
arises opposite the bifurcation of the common carotid, which in this case would seem to
divide into three branches. In some cases it arises directly from the common carotid ;
at other times it has been seen to come off by a conmion trunk with the lingual. It is
always of considerable size, but varies in this respect, maintaining either a direct rela-
tion to the size of the thyroid body, or an inverse proportion to that of the other thyroid
arteries.
Direction. — It is at first airected horizontally forward and inward ; but it almost im-
mediately bends, and proceeds vertically to the upper end of the corresponding lobe of
the thyroid gland, in which it terminates.
Relations. — It is superficial at its origin, where it is covered only by the skin and the
platysma ; it then dips under the omo-hyoid, sterno-hyoid, and sterno-thyroid muscles,
and it is also covered by the cervical fascia and the superior thyroid veins. This artery
furnishes several collateral branches, viz., the superier laryngeal, the inferior laryngeal or
crico-thyroid, and the sterno-mastoid branch, t
The Superior Laryngeal Branch. — This (c) comes off from the thyroid, at the point
where the latter changes its direction ; sometimes it arises from the external carotid.
In certain cases it is so large that it may be regarded as formed by a bifurcation of the
thyroid. In one case where it was wanting on the left side, I found it replaced by the
right superior thjnroid, which was almost double its usual size. This artery passes
transversely inward between the thyro-hyoid muscle and the membrane of the same
name, which it perforates along with the superior laryngeal nerve ; having reached the
cellular tissue behind this membrane, it divides into two branches, an ascending, or epi-
glottid branch, which passes upon the side, then in front of the epiglottis, and ramifies
upon it ; and a descending, or laryngeal branch, properly so called, which passes behind
the thyroid cartilage, between it and the thyro-arytenoid muscle, and is distributed upon
the muscles and mucous membrane of the lar)Tix. Not unfrequently the superior laryn-
geal branch enters the larynx through a foramen existing in the thyroid cartilage in
some subjects.
The Inferior Laryngeal or Crico-thyroid Branch. — This arises from the internal termina-
ting branch of the superior thyroid artery ; it is more remarkable for its constant presence
than for its size. It is sometimes wanting on one side, but it is then replaced by the
superior thyroid artery of the other side. It passes transversely inward, in front of the
crico-thyroid membrane, along the lower border of the thyroid cartilage, and inosculates
with the branch of the opposite side. From the arch thus formed twigs proceed, which
perforate the crico-thyroid membrane, and ramify in the muscles and the mucous mem-
brane of the larynx.
It is not uncommon to find the inferior laryngeal artery dividing into two branches :
one superficial and transverse, the other ascending, which passes up behind the thyroid
cartilage.
M. Chassaignac has exhibited, at the Anatomical Society, a preparation, in which the
trunk of the superior thyroid artery, instead of giving off the inferior laryngeal branch,
passed itself transversely over the crico-thyroid ligament.
I'.ie Sterno-mastoid Branch. — This is constant, but of variable size. It comes off from
the superior thyroid, a little below the superior laryngeal, and passes downward to reach
the deep surface of the sterno-mastoid muscle, to which it is distributed.
Terminal Branches. — Having reached the gland, the thyroid artery divides into three
branches, viz., one which passes between the gland and the trachea ; another, which
authors have not described this vessel as a particular artery, but have contented themselves with describing
the branches which it gives off.
* [It crosses over the styloid process, the stylo-glossus and pharjmgeus muscles, and the glosso-pharyngeal
nerve, which lie between it and the internal carotid.]
t [The first branch is usually a small one, named the hyoid, which arises opposite the great comu of the
OS hyoides, passes inward on the thyro-hyoid membrane, and anastomoses with the vessel of the opposite
side.}
THE FACIAL AHTERY. 5X7
proceeds along the outer border of the corresponding lobe ; and a third, which runs
along the inner border, and anastomoses in the median line with the corresponding
branch of the opposite side. It is this vessel which sometimes gives off the inferior
laryngeal.*
The Facial, the Labial, or External Maxillary Artery.
Dissection. — Let the head fall backward by means of a billet placed under the neck,
and incline it towards the side opposite to that on which the artery is to be laid bare ;
dissect carefully the digastricus and stylo-hyoid muscles, which must be cut superiorly
at their origin from the styloid process ; dissect the sub-maxillary gland, then the mus-
cles of the ia.ce, avoid injuring the numerous branches which may come under the scalpel.
The facial artery (/, figs. 204, 206), so called from its distribution, is given off from
the front of the external carotid, a little above the os hyoides : it is so large in some
subjects that it seems to be formed by a bifurcation of the extemcil carotid. It pro-
ceeds in a tortuous course from below upward, and then from behind forward, along
a groove formed in the sub-maxillary gland. After leaving this groove, it passes verti-
cally upward, crosses the body of the lower jaw at right angles in front of the masseter
muscle, becomes oblique, arrives near the conunissure of the lips, reaches the furrow
between the ala nasi and the cheek, and terminates near the inner angle of the eye, by
anastomosing with one of the branches of the ophthalmic, and with the infra-orbital ar-
tery. The termination of the facial artery is subject to numerous individual varieties.
The vessel is also remarkable for being extremely tortuous, a condition which is con-
nected with the mobility of the parts supplied by this artery, which runs in succession
over the supra-hyoid, the inferior maxillary, the buccal, and the nasal regions.
Relations. — In the supra-hyoid region the facial artery is covered by the digastric and
stylo-hyoid muscles ; then, along the base of the jaw, it is in relation with the outer sur-
face of the sub-maxillary gland, and is separated from the skin by the platysma and a
great number of lymphatic glands. In the facial region, the artery is covered below by
the platysma, higher up by the triangularis oris and the zygomaticus major, and in all the
rest of its extent by a greater or less quantity of fat, which separates it from the skin ;
it lies upon the inferior maxilla, against which it may be compressed in front of the
masseter, also upon the buccinator, the orbicularis oris, the levator communis, and the
levator proprius.
Collateral Branches. — The following branches are given off by the facial artery in the
supra-hyoid region. The inferior palatine, a small branch which is sometimes derived
from the external carotid, or from the ascending pharyngeal artery, passes up behind
[or between] the stylo-glossus and stylo-pharyngeus muscles, to which it furnishes some
branches, gains the side of the pharynx, and is distributed to the tonsil, which it covers
with its ramifications, and also to the velum palati and the pillars of the fauces, oppo
site which it anastomoses with several branches of the ascending pharyngeal artery. 1
have seen the palatine branch of the facial extremely large, and taking the place of the
tonsillar and palatine branches of the ascending pharyngeal artery.
The sub-mental branch (g,fig. 204) runs along the inner side of the lower border of the
ramus of the jaw, between the digastricus and mylo-hyoideus, passes upward in front of
the bone, on the outer side of the anterior attachment of the digastricus, and ramifies in
the skin and muscles of the chin, anastomosing with the ramifications of the inferior
dental artery. Sometimes the sub-mental divides into two or three branches, all of which
terminate in the same manner, after perforating the digastric muscle.
Branches for the Sub-maxillary Gland. — These are three or four in number, and are
large in proportion to the organ which they supply.
The Pterygoid Branch. — This is a small branch which passes into the internal ptery-
goid muscle.
The collateral branches of the /aciaZ region are divided into external and internal. The
external branches ramify in all the muscles and integuments of the cheek, and anastomose
freely with the transverscdis faciei, a branch of the superficial temporal : the most re-
markable of these branches are the two given to the masseter and buccinator muscles.
Among the internal branches, besides a number of small twigs which have received no
names, we remark the following .
The inferior coronary or labial artery (h), which is given off from the facial, a little be-
low the commissure of the lips ; it pursues a serpentine course in the substance of the
lower lip, between the muscular and glandular layers, at a greater or less distance from
the free border of the lip, and anastomoses, in the median line, with the corresponding
vessel of the opposite side. I have seen this artery occupy the lower or adherent border
of the lower lip until it reached the median line, when it ascended vertically to the free
border, wh'ere it divided into two equal branches, which passed, horizontally, one to the
* I have seen the branch winch runs along^ tlie inner border of the thyroid gland pass transversely to the
left side, above and at a certain distance from this border ; having reached the median line, it proceeded ver-
tically downward, in front of the crico-thyroid ligament, to the middle of the thyroid gland, where it gave off
the right and left inferior laryngeal branches. The left thyroid was very small, and only furnished the ex-
ternal branch for the thyroid gland.
5f8
ANGEIOLOGY.
right and the other to the left, in order to form a second coronary artery, smaller than
the first.
The superior coronary, or labial, arises opposite the commissure, passes in the upper
lip between the muscular and glandular layers, and inosculates, in the median line, with
the vessel on the opposite side. Branches are given off from this arch to the mucous
membrane, the gums, the muscles, and the skin. One branch only of this artery requires
a special description ; it is known by the name of the artery of the septum nasi (z). It
comes off, in the median line, by one, two, and sometimes three branches, which pass
vertically upward, and then horizontally beneath the skin, covering the under surface of
the septum as far as the tip of the nose, where they anastomose with the artery of the ala.
The artery of the ala nasi, or lateral artery of the nose (/), which is very often the ter-
mination of the facial, divides into two branches : a small one, that runs along the lower
border of the cartilage of the ala, and anastomoses with the anery of the septum ; and a
larger one, that runs along the upper convex border of that cartilage. A small branch pen-
etrates into the interior of the nares, between the cartilage and the opening of the nostril.
Termination of (he Facial Artery. — The facial artery having become extremely slender,
sometimes terminates, under the name of the angular branch (m), upon the side of the
nose, by anastomosing with the nasal branch of the ophthalmic, and with the infra-orbit-
al. At other times its termmation is formed by the artery of the ala of the nose, or by
the superior coronary of the lip, or even by the inferior coronary. I have seen i'l termi-
nate in the artery of the septum. We seldom find the facial arteries of both sides ahke.
Sometimes there is merely a trace of one, while the other is very much developed, and
supplies by itself alone all the nasal and labial branches. No artery varies more thai?
the facial, both in size and extent of distribution.
Its anastomoses with the inferior dental and infra-orbital arteries, branches of the in
ternal maxillary, as well as those with the ophthalmic, a branch of the internal carotid,
should be particularly noticed.
The Lingtial Artery.
Dissection. — Cut the hyoidian insertions of the mylo-hyoid muscle, which is to be
turned up from below upward ; saw the inferior maxillary bone, either at the symphysis
or on each side of it. Hook the tongue and draw it out of the mouth, and maintain it in
that position while you follow the artery as situated at its inferior surface.
The lingual artery {n, figs. 204, 205), which is very large considering the size of the
Fig. 205. organ to which it is distributed, comes off from the front of the ex-
ternal carotid, between the facial and the superior thyroid, and often
by a common trunk with the facial ; it passes at first obliquely up-
ward, and then transversely inward and forward, along the upper
margin of the corresponding great cornu of the os hyoides : oppo-
site the lesser cornu of that bone it changes its direction, and runs
in a serpentine course from behind forward, in the substance of the
tongue as far as the apex, where it terminates by anastomosing
with the artery of the opposite side ; in the latter part of its course
it is named, we know not why, the ranine artery Q, fig. 205 ; rana,
a frog). Its remarkably tortuous course is connected with the lia
bility of the tongue to undergo great changes in its relative dimen-
sions.
Relations. — It is deeply seated, at its origin, under the digastric
'* and stylo-hyoid muscles and the hypo-glossal nerve ; opposite the
OS hyoides (at n. fig. 205) it is situated between the hyo-glossus (the nerve passing over
that muscle) and the middle constrictor of the pharynx : in the substance of the tongue
it is placed between the genio-hyo-glossus and the lingaalis, and is accompanied by the
lingual branch of the fifth nerve ; consequently, it occupies the inferior surface Of the
tongue.
Collateral Branches. — A small transverse branch, the hyoid (e), forms an anastomotic
«irch with the vessel of the opposite side, upon the body of the os hyoides, between the
genio-hyo-glossus and the genio-hyoideus.
The dorsal artery of the tongue (/), generally small and diflicult to demonstrate; it
arises opposite the great cornu of the os hyoides, ascends upon the lateral border of the
tongue, near the anterior pillar of the fauces, to which it gives branches, then passes
forward and inward, and giving several epiglottid branches, which anastomose with
those of the opposite side, is finally distributed to the caliciform papillae. In the whole
of its course, this artery lies immediately beneath the mucous membrane.
The sub-lingual artery (i) is large enough to be regarded by some as resulting from the
bifurcation of the lingual, which, according to them, takes the name of raninal only after
it has furnished the sub-lingual branch. It arises as often from the facial, by a common
trunk with the sub-mental, as from the lingual itself It passes horizontally forward be-
tween the mylo-hyoideus, which separates it from the sub-mental, and the genio-hyo-
glossus, and, in company with the Warthonian duct, runs along the lower border of the
THE OCCIPITAL ABTERY, ETC. 519
•Qb-Iingual gland, to which it furnishes numerous twigs, and then divides into two
branches : the larger, or the artery of the franum, anastomoses, in an arch, with the ves-
sel of tlie opposite side above thefraenum ; while the smaller, or ascending branch, pass-
es upon the sides of the symphysis menti, and sends twigs into the several incisor fora-
mina, situated behind the teeth of the same name. It is this artery of the fraenum, not
the ranine artery, which is liable to be wounded in division of the fraenum. Not unfre-
quently the sub-lingual artery gives off a superficial branch, which passes through the an-
terior belly of the digastricus, and ramifies upon the region of the chin, like the analo-
gous branches of the sub-mental.
Lastly, in the substance of the tongue, the lingual artery gives off superior, internal, and
external branches, which supply the muscles and the papillary membrane oif that organ.
The Occipital Artery.
Dissection. — Detach the sterno-mastoideus and the splenius at their superior inser-
tions. To uncover more completely this artery, which is deeply situated between the
mastoid process and the transverse process of the atlas, cut with a chisel or saw the
mastoid process at its base, turning it from above downward with the muscles which are
inserted into it ; cut the styloid process at its base, and turn the styloid muscles down.
Remove carefully the skin of the occipital region, so as to enable you to follow the sub-
cutaneous branches.
The occipital artery (o o, fig. 204), which is distributed to the posterior region of the
head, is smaller than the three branches of the external carotid already described. It
arises from the back of the external carotid, on a level with the lingual or the facial,
sometimes immediately below the parotid gland : it passes obliquely upward and back-
ward, as high as the apex of the mastoid process ; it then passes horizontally backward,
and on the inner side of the splenius muscle, divides into two ascending branches : one
external, which immediately bends upward ; the other internal, which is continued hori-
zontally, and is then reflected vertically upward on the side of the occipital protuber-
ance. These two branches, which are very tortuous, cover the occipital region with
their numerous ramifications, and reach as high as the vertex, anastomosing with each
other, and with the superficial temporal arteries.
It is situated deeply at its origin, and is covered by the digastric muscle and the hypo-
glossal nerve ; it is still more deeply situated as it passes between the mastoid process
and the atlas, where it is covered by the digastric and the sterno-mastoid ; its horizon-
tal portion is situated between the obhquus capitis superior and the splenius muscle, then
between the complexus and the splenius, running along the occipital insertion of the lat-
ter muscle, on the inner side of which it becomes sub-cutaneous. The two branches
into which this artery divides, and all its succeeding ramifications, are situated between
the skin on the one hand, and the occipital muscle and the oceipito-frontal aponeurosis
on the other.
Collateral Branches. — Among a great number of small and unnamed ramusculi, we
shall distinguish the following branches : a superior sterno-mastoid artery, which constant-
ly exists, but is sometimes given off from the external carotid itself: it forms a curve,
with its concavity directed downward, under which the hypo-glossal nerve turns ; it then
penetrates the deep surface of the upper portion of the stemo-raastoid : a stylo-mastoid
branch, which is often derived from the posterior auricular artery : a meningeal artery, or
posterior mastoid, which enters the cranium, either by the foramen mastoideum, the fo-
ramen lacerum posterius, or even the foramen magnum, and is distributed to the dura
mater : & cervical artery {princeps cervicis), which descends between the splenius and com-
plexus muscles, and may be followed down to the lower part of the neck ; this branch is
sometimes of considerable size ; lastly, very often, a terminal branch, the parietal, which
enters the cranium by the parietal foramen, and ramifies in that portion of the dura ma-
ter which forms the superior longitudinal sinus.
The Posterior Auricular Artery^
Dissection. — ^Avoid cutting this artery at its origin in preparing the trunk of the exter-
nal carotid ; turn the pinna of the ear forward ; seek for the trurdc of the artery between
the meatus auditorius extemus and the mastoid process ; follow up the dissection on
one side towards the origin, on the other towards the termination of this artery, being
guided by the description.
The posterior auricular artery {,s,fig. 204) is intended for the pinna, the internal ear, and
the neighbouring parts of the cranium : it is usually smaller than the occipital, but is
sometimes as large ; it arises from the back of the external carotid, a little above the
occipital,' and rather often by a common trunk with that artery. It passes vertically up-
ward, being deeply seated under the digastricus ; it is then covered by the parotid gland,
which it perforates to gain the posterior border of the mastoid process, upon which it di-
vides into two branches, a mastoid, and an auricular.
In this course it gives off several parotid and muscular branches, and the stylo-mastoid
artery, which is sometimes derived from the occipital. The stylo-mastoid artery, so re-
520 ANGEIOLOGY.
markable for the length of its course, dips into the stylo-mastoid foramen, runs the whole
length of the aqueduct of Fallopius, giving off, as it proceeds, some twigs to the internal
ear, and terminates by anastomosing with a branch of the middle meningeal artery, which
enters by the aqueduct of Fallopius.
The terminal mastoid branch of the posterior auricular passes upward and backward be-
tween the mastoid process and the skin, and subdivides into two sub-cutaneous ramus-
culi : one horizontal, which passes inward along the occipital attachment of the sterno-
mastoid and splenius ; the other ascending, which continues in the original course of
the vessel, and is lost in the skin upon the outer margin of the occipitalis muscle.
The terminal auricular branch almost always divides into two : a superior and an infe-
rior. The superior branch runs along the anterior border of the mastoid process, rami-
■ fies upon the upper half of the internal surface of the pinna, and turns round its free mar-
gin, so as to reach the external surface. The inferior branch passes behind the auditory
meatus, supplies the lobule of the ear, insinuates itself into the fissure in the cartilage,
between the helix and concha, and thus gains the external surface of the pinna, upon
which it passes upward in the furrow between the helix and antihelix. It terminates by
anastomosing with the superior branch.
I have seen the auricular artery of great size, to supply the place of the posterior
branch of the superficial temporal.
The Parotid Arteries.
While passmg through the parotid gland, the external carotid gives ofl^ four or five
large branches to that organ, which deserve special description. They arise from the
carotid at right angles, cross the ramus of the lower jaw also at right angles, and divide
into a great number of ramifications, most of which are lost in the substance of the
gland ; the remainder are distributed to the skin and muscles. One or more of these
branches pass between the parotid gland and the masseter muscle, parallel to the trans-
versalis faciei artery, and reach as far as the zygomaticus major ; others gain the angle
of the jaw, and are lost in the supra-hyoid region.
The Inferior or Ascending Pharyngeal, or Pharyngo-meningeal Artery.
Dissection. — Make the section necessary for examining the pharynx, as described in
d former part of this work when on the Anatomy of the Pharynx. The steps required
for this purpose render it advisable that the study of this artery should be postponed until
after that of the internal maxillary.
The ascending pharyngeal is the smallest branch of the external carotid : it arises from
the inner side of that artery opposite the lingual. I have seen it arise from the occipital.
Not unfrequently it is given off either from the angle of bifurcation of the common caro-
tid, or from the internal carotid ; and in this last case, there is almost always a very
small pharyngeal branch arising from the external carotid, and passing transversely in-
ward to the pharynx.
It varies in size to a certain degree, and, as it appears to me, in an inverse ratio to
that of the palatine branch of the facial. I have seen it almost as large as the occipital.
Inunediately after its commencement the ascending pharyngeal passes vertically up-
ward, at first between the external and internal carotid, and then behind the internal ca-
rotid, with which latter vessel it is found in the triangular interval between the pharynx
and the internal pterygoid muscle ; it then almost immediately divides into two branch
es, a meningeal and a pharyngeal.
Before dividing, it gives off an inferior pharyngeal branch, which passes transversely
inward, and subdivides into ascending and descending branches, the latter of which an-
astomose on the pharynx with some twigs of the superior thyroid.
The meningeal branch, which is situated behind the internal carotid, passes vertically
upward, gives off twigs to the superior cervical ganglion of the sjTnpathetic nerve, to the
pneumogastric, glosso-pharyngeal, and hypo-glossal nerves, and to the accessory nerve
of Willis, enters the cranium through the foramen lacerum posterius, and ramifies upon
that portion of the dura mater which lines the inferior occipital fossa. I have seen this
vessel divide into a great number of branches, one of which entered the cranium by the
carotid canal, and another by the foramen lacerum anterius.
The meningeal branch, and sometimes even the trunk of the pharyngeal, gives off a
prcBvertebral branch, which passes upward in front of the longus colli and the recti antici
major et minor, supplying these muscles, and anastomosing with the cervicalis ascen-
dens. I have traced a branch into the cranium through the first intervertebral foramen
(i. e., along the superior notch of the atlas), and another which entered the vertebral ca-
nal between the atlas and axis. I regard this praevertebral branch as supplementary to the
cervicalis ascendens (a branch of the inferior thyroid), for it has a similar distribution.
The pharyngeal branch passes in front of the internal carotid, and having reached the
base of the cranium, divides into numerous branches, which ramify in the very dense
fibrous tissue found at the occipital attachment of the pharynx : they are all reflected
downward, and are distributed upon the Eustachian tube and the muscles of the pharynx.
THE TEMPORAL ARTERY. S^f
In a case in which the palatine branch of the facial artery was absent, this pharyngea.
branch was very large and supplied the tonsil, and, finally, ramified in the velum palati.
The Temporal Artery.
Dissectton. — ^Tum bacK the parotid gland ; seek for the artery under the skin of the
temporal region ; follow its different collateral and terminal branches upon the cranium
as far as the vertex, on the face, and on the ear.
The temporal or superficial temporal artery (p, fig. 204) appears, by its direction, to form
the continuation of the external carotid. It commences opposite the neck of the con-
dyle of the lower jaw, between it and the external auditory meatus, which is behind ; it
passes vertically upward, immediately behind the zygomatic arch, reaches the temporal
region, where it describes some curves, still continuing its vertical course, and termi
nates by bifurcating at the middle, or sometimes the upper part of that region.
Relations. — It is covered at its origin by the parotid gland ; it becomes subcutaneous
as soon as it passes beyond the zygomatic arch, and then rests upon the temporal fziscia
at first, and upon the epicranial aponeurosis afterward. Its superficisd position, added
to its proximity to a bony surface, render it easily compressible, and explain why this
artery, and especially its anterior or frontal branch, is generally chosen for arteriotomy.
Collateral Branches. — These are divided into anterior, posterior, and interned.
The Anterior Branches. — The most remarkable of these is the transversalis faciei (u),
which arises from the temporal immediately after its origin, opposite the neck of the
condyle of the lower jaw. and, consequently, in the substance of the parotid gland : it
very often comes directly from the external carotid. It varies much in its size, which
is generally in an inverse proportion to that of the facial artery. It proceeds horizon
tally forward, across the direction of the neck of the condyle and the masseter muscle,
about six lines below the zygoma, above the Stenonian duct, which runs parallel to it.
Tlie transversalis faciei gives an articular branch to the temporo-maxillary articulation,
and several deep masseteric branches, of which one of considerable size penetrates the
back part of the muscle, and anastomoses with the masseteric branch of the internal
maxillary. It also gives a small twig, which runs along the Stenonian duct. At the
anterior margin of the masseter the transverse facial artery subdivides into a great num-
ber of cutaneous, muscular, and anastomotic branches. Among the first we should notice
a maiar cutaneous branch ; and among the muscular branches, those which are distributed
to the great zygomatic muscle. The muscular branches of the transversalis faciei may
be traced in one direction as far as the orbicularis palpebrarum, and in another into the
levator proprms fibii superioris. The anastomotic branches establish an intimate com-
munication between the temporal artery and the buccal, infra-orbital, and facial arteries.
A second anterior branch of the temporal artery also requires special notice, viz., the
orbital, which is given off above the zygomatic arch, passes from behind forward, be-
tween the superficial and deep layers of the temporal fascia, then behind the orbicularis
muscle, which it supplies, as well as the corresponding skin, and anastomoses with the
superior palpebral branch of the ophthalmic. This artery is very variable in regard to
size. I have seen it very large and reflected upward, between the frontalis muscle and
the skin, parallel to the supra-orbital branch of the ophthalmic, and capable of being fol-
lowed as far as the parietal region. From the bend which it forms by turning upward,
it gives off a palpebral branch, which completes the superior palpebral arch, and also a
branch which anastomoses with the supra-orbital. This orbital branch of the tempered
does not exist in all subjects ; the branches which it furnishes are then given off direct-
ly from the temporal.
The posterior branches consist of the anterior auriculars (v), which are irregular as to
number : the lower branches are distributed to the lobule, the middle ones to the exter-
nal auditory meatus, and the upper branches to the highest part of the pinna.
The internal branch is the middle deep or sub-aponeurotic temporal artery ; it arises from
the temporal above, sometimes on a level with the zygoma, perforates the fascia, and is
distributed to the temporal muscle, anastomosing with the anterior and posterior deep
temporal branches derived from the internal maxillary.
Terminal Branches. — Of the two branches into which the temporal artery divides, the
anterior or frontal {q) passes forward and upward towards the frontal region, upon which
it ramifies, anastomosing with the branches of the frontal and supra-orbital arteries, and
with the temporal of the opposite side. This branch is divided in the operation of arte-
riotomy. The posterior or parietal branch (y) is larger than the anterior : it passes up-
ward and ramifies upon the parietal bone, anastomosing with the auricular and occipital
arteries, with the frontal branch of the temporal, and with the temporal of the opposite
side. It is 'sometimes derived from the auricular artery.
The Internal Maxillary Artery.
Dissection. — Saw through the zygomatic arch in two places, and turn it downward to-
gether with the masseter muscle, taking care not to tear the masseteric artery.
Dissect the temporal muscle, and saw through the coronoid process of the inferior
Uuu
SS2 ANGEIOLOGY.
maxilla. Saw through the cranium circularly, and remoTc the brain, which may be put
into diluted nitric acid or alcohol, to be hardened for the subsequent dissection of the
cerebral arteries. The artery may then be exposed in two ways, either from the outer
or else from the upper wall of the zygomatic fossa.
It may be reached from the outer wall of the zygomatic fossa by sawing through the
lower jaw in front of the masseter, by disarticulating the condyle, or, rather, by sawing
it across its neck, and by carefully dissecting the pterygoid muscles
The artery can be reached from the upper wall by making two sections in this part of
the bone, which will meet at an acute angle in the foramen spinosum of the sphenoid bone.
The branches of this artery, especially those which are e"hclosed in bony canals, such
as the dental, the pterygo-palatine. the vidian, dec, must be dissected by carving out
their courses in the bone.
A vertical section, made from oefore backward through the middle of the face, facili-
tates the examination of this artery, and enables us to see the terminations of its nasal,
palatine, and pharyngeal branches.
The internal maxillary artery (e, fig. 206), little known to the older anatomists, but ac-
Fig. 206. curately described by Haller, is the continuation of the
external carotid, at least as far as size is concerned.
Immediately after its origin, it forms a curve, and
passes deeply to the inner side of the neck of the con-
dyle of the lower jaw.
Tortuous and horizontal in the first part of its course,
it traverses the zygomato-maxillary fossa diagonally,
passes forward, inward, and a little upward, to reach
the highest part of the tuberosity of the superior max-
illary bone, upon which tuberosity it describes a very
considerable curve with the convexity turned for-
ward, and then dips into the bottom of the zygomat-
ic fossa, i. e., the spheno-maxillary fossa, where it ter-
minates by one or several branches, called the sphe-
no-palatine. The tortuous course of the internal max-
illary is connected with the great number of branches
given off from it.
Relations. — Opposite the neck of the condyle, it is situated between the condyle, to
which it is applied, and the styloid process — an important relation in a surgical point of
view. Its relations in the zygomato-maxillary fossa are not very definite. Some anat-
omists, with Bichat and Meckel, state that it is situated between the internal and exter-
nal pterygoid muscles ; others, with Haller, that it is placed in front of the external pte-
rygoid, i. e., between that muscle and the temporal. Both modes of distribution are
equally common, and I have even seen one existing on the right, and the other on the
left side in the same subject. If the internal maxillary is situated betwt en the ptery-
goids, it passes directly forward, on the outside of the dental and lingual nerves ; when
it has to get between the external pterygoid and the temporal, it bends downward and
then upward, so as to embrace the lower half of the circumference of the external pte-
rygoid : in this manner it gains the outer surface of that muscle, appears opposite the
sigmoid notch of the lower jaw, and passes from behind forward, between the external
pterygoid and temporal muscles ; in both cases it passes between the two origins of the
external pterygoid, in order to reach the pterygo-maxillary fissure.
Collateral Branches. — These are thirteen in number, and are divided into those arising
on the inner side, and near the neck of the condyle, viz., the tympanic, the middle menin-
geal, and inferior dental, the posterior deep temporal, the masseteric, the pterygoids, and the
small meningeal arteries ; those arising near the maxillary tuberosity, viz., the buccal, the
anterior deep temporal, the alveolar, and the infra-orhital arteries ; and those arising with-
in the spheno-maxillary fossa, viz., the vidian ot pterygoid, the pterygo-palatine, and the
guperior palatine arteries.
Branches arising near the Neck of the Condyle.
The tympanic artery is a very small branch, which sometimes arises from the tempo-
ral, and sometimes from the inferior dental ; it is distributed to the external auditory
meatus and the temporo-maxillary articulation, and penetrates through the Glasserian
fissure into the cavity of the tympanum, to the muscles and walls of which it sends its
ramifications.
The middle or great meningeal artery, or spheno-spinous artery, is destined for the dura
mater and the bones of the cranium ; it almost always arises from the internal maxilla-
ry before the dental, but sometimes in the same situation ; it passes vertically upward,
behind the neck of the condyle, and gains the foramen spinosum in the sphenoid bone,
through which it enters into the interior of the cranium ; it is then reflected upon the
anterior margin of this foramen, becomes horizontal, and divides into two branches, an
interior and a posterior. The anterior branch is the larger ; it runs upon the outer ex-
THE INTERNAL MAXILLARY ARTERY. "iSfe
tremity of the lesser wing of the sphenoid, and reaches the anterior angle of tho parietal
bone, where it is received into an imperfect, and sometimes even into a complete bony
canal, and then divides and subdivides in the ramified grooves upon the internal surface
of the parietal bone. Its branches may be traced even into the walls of the longitudinal
sinus.
The posterior branch is smaller, and passes backward and upward upon the squamous
portion of the temporal bone, and upon the internal surface of the parietal bone, enters
into the ramified grooves upon that surface, and terminates in the dura mater and the
bones of the cranium. The ultimate twigs of the middle meningeal artery anastomose
with those of the opposite side, and with the branches of the anterior and posterior me-
ningeal arteries.
Relations. — In the first part of its course, it is very deeply situated, and is in relation
in front with the condyloid attachments of the external pterygoid muscle ; in the crani-
um it is situated on the outer surface of the dura mater, between that membrane and the
bones, into the substance of which it sends a number of extremely fine ramusculi. The
relation of the two divisions of this artery with the two inferior angles of the parietal
bone deserves notice in a surgical point of view. In consequence of its sending branch-
es into the bones, separation of the dura mater is always followed by effusion of blood.
The middle meningeal artery also gives off some collateral branches. On the outside
of the cranium it furnishes some unnamed twigs. Within the cranium it gives a small
branch, named the vidian, which enters the aqueduct of Fallopius through the hiatus Fal-
lopii, and supplies the facial nerve, ramifying in its neurilemma, and anastomosing with
the stylo-mastoid branch of the occipital artery ; some small branches, which supply the
fifth or trigeminal nerve, and evidently anastomose with the meningeal branches of the
internal carotid ; a small twig, which enters the canal for the internal muscle of the
malleus, and is distributed upon that muscle ; opposite the sphenoidal fissure, several
orbital branches, which enter the orbit at the narrowest part of that fissure, or even by
proper canals in its neighbourhood ; and, lastly, some rather large temporal branches,
which pass into the great alae of the sphenoid at their orbital surface, and anastomose in
the temporal fossa with the deep temporal arteries : not unfrequently the lachrymal ar-
tery, or a small supplementary lachrymal artery, is furnished by the middle meningeal.
The inferior dental artery (d) is the artery of the lower jaw : it generally arises on a
level with the middle meningeal, but sometimes before and sometimes after that vessel ;
it passes downward, along the inner surface of the ramus of the jaw, between the bone
and the internal pterygoid, sending off branches to that muscle, but being separated
from it by the fibrous band called the spheno-maxillary ligament ; it thus reaches the
superior orifice of the dental canal, before entering which it gives off a small branch
that passes downward and forward in a groove on the inner surface of the jaw, and ter-
minates in the mylo-hyoid muscle.
The inferior dental artery traverses the entire length of the dental canal, accompanied
by the nerve of the same name. Opposite the bicuspid teeth it divides into two branch-
es : a menial branch, the larger, which escapes through the mental foramen, and anasto-
moses with the submental artery and the inferior coronary artery of the lip ; and an in-
cisor branch, which continues in the original course of the artery, passes beneath the
canine and incisor teeth, and is lost in the diploe opposite the symphysis.
During its course, the dental artery, as well as its incisor branch, gives off a great
number of twigs, which are lost in the diploe of the bone ; and a series of dental branches,
which correspond in number with the roots of the teeth, penetrate into the alveoli, and
from thence into the teeth through the foramen observed at the apex of each fang.
The posterior deep temporal artery (g) arises opposite the sigmoid notch, passes verti-
cally upward between the external pterygoid and the temporal muscles, gains the pos-
terior border of the latter muscle, gets between that border and the temporal fossa, re-
mains in contact with the periosteum, and then divides and subdivides so as to termi-
nate partly in the temporal muscle and partly upon the periosteum, anastomosing with
the middle and anterior deep temporal arteries. It often gives off the masseteric, and
sometimes the buccal artery.
The masseteric artery is a small branch, the size of which is inversely proportioned to
that of the masseteric branch of the transversalis faciei. It often arises by a common
trunk with the posterior deep temporal, passes outward in front of the condyle, and, tliere-
fore, in the notch between the condyle and the coronoid process, and enters the internal
surface of the masseter, in which muscle it anastomoses with the masseteric branches
given off by the transversalis faciei and facial arteries.
The pterygoid arteries are irregular in number ; some of them arise directly from the
internal maxillary, others from the posterior deep temporal and the middle meningeal.
The small meningeal artery is not constant, but I have seen it in one case as large as ■
the middle meningeal ; it arises at the same height as the inferior dental, passes between
the pterygoid muscles, and divides into two branches, one of which turns round the ori-
gin of the internal pterygoid, and terminates in the velum palati and the nasal fossae ;
and another, which passes vertically upward, between the external pterygoid and the
m
ANGEIOLOGY.
upper wall of the zygomatic fossa, enters the cranium by the foramen ovale, and sup-
plies the trip^eminal nerve and the dura mater, anastomosing with small branches given
off from the internal carotifl.
Branches arising near the Tuberosity of the Superior Maxillary Bone.
The buccal artery (h) is a small branch of variable size, and sometimes exists only in
a rudimentary state. It rather frequently arises by a common trunk with the superior
dental artery, passes in a tortuous course from behind forward, between the ramus of
the lower jaw and the internal pterygoid muscle, emerges in front of the ramus, and is
lost in the buccinator muscle, anastomosing with the buccal branches of the facial and
transversalis faciei.
The anterior deep temporal artery (i) is of considerable size : it passes vertically up-
ward, along the anterior border of the temporal muscle, with which it is in contact, is
lost in that muscle, anastomosing with the posterior deep temporal and the middle tem-
poral. It gives off some extremely delicate orbital branches, which traverse the canals
in the malar bone, and are lost in the adipose tissue of the orbit.
The alveolar or superior dental (Z) often arises by a common trunk with the infra-or-
bital, passes in a very tortuous manner forward and downward upon the tuberosity of
the superior maxilla, and divides into several branches ; some of these, having reached
the alveolar border, are reflected upon the margins of the alveoli, pass into their cavities,
and ramify in the alveolo-dental periosteum ; other branches enter the small posterior
dental canals, penetrate into the alveoli of the molars and bicuspids, and divide into as
many ramusculi as there are roots to each of those teeth. Several of these branches
penetrate into the maxillary sinus. I have seen one which ran along this sinus from
behind forward near its lower wall, was reflected upward on the anterior wall of the
same cavity, and entered the base of the ascending process of the superior maxilla, at
which point I could no longer follow it. This branch was situated between the lining
membrane of the sinus and the bones. All the divisions of the alveolar artery furnish
branches to the superior maxillary bone, and, at the same time, supply them to the cor-
responding teeth. Lastly, some very delicate twigs of the superior dental artery enter
the buccinator muscle.
The infra-orbital artery arises from the internal maxillary opposite the spheno-mEixil-
lary fissure, sometimes alone, sometimes by a common trunk with the superior dental,
immediately enters and then traverses the infra-orbital canal, emerges at the infra-or-
bital foramen, and divides into a great number of branches (m), which are distributed to
the skin and mucous membrane of the cheek, anastomosing with the facial artery, the
transversalis faciei, and the alveolar and buccal branches just described. Several branch-
es enter the alveoli of the canine and incisor teeth at their borders : others penetrate
into the nasal fossae at the nostril.
During its course, the infra-orbital artery furnishes a very remarkable branch, which
enters the cavity of the orbits, where it divides into two branches, one of which passes
directly forward, and is lost in the lower eyelid, while the other, which is larger, turns
inward, and inosculates with the inferior palpebral branch of the ophthalmic artery ; an-
other branch of the infra-orbital artery enters the anterior dental canal, to supply the
canine and incisor teeth, penetrating into the foramina at the points of their fangs, in
the same way as in the other teeth.
Branches arising in the Pterygo-maxillary Fossa.
The vidian or pterygoid artery is a very small vessel, which, immediately after its com-
mencement, enters the vidian canal, traverses its whole length, and then ramifies in the
pharynx and around the Eustachian tube.
I'he pterygo-palatine artery is as small as the preceding, below and to the inner side
of which it is situated : it traverses the pterygo-palatine canal, and terminates in the
pharynx and on the Eustachian tube. It sometimes arises from the spheno-palatine artery.
The superior palatine artery is larger than the preceding branches, and pursues a down-
ward course : it arises opposite the pterygo-maxillary fissure, passes vertically down-
ward, enters the posterior palatine canal, and, having emerged from its inferior orifice,
is reflected from behind forward, advances in a tortuous manner (r, fig. 205) between
the hard palate and the mucous membrane, in the groove which runs along the alveolar
border, and forms an anastomotic arch in the median line, with the palatine artery of
the opposite side. Before entering the posterior palatine canal, it gives off some branch-
es, which run through the accessory palatine canals, and ramify upon the velum palati.
While upon the hard palate, it sends off branches, which are distributed to the glands
of the mucous membrane ; others, which are distributed to the gums, and enter at the
margins of the alveoli, and supply the alveolo-dental periosteum ; and, lastly, a small
nasal branch {t, fig. 205), which enters the anterior palatine canal, bifurcates above like
that canal itself, so as to penetrate into each of the nasal fossae, and anastomoses with
the spheno-palatine artery of both sides.*
* There are, in the interior of the bones of the face, as in all spongy bones, true arterial canals, the study of
which is not less important than that of the venous canals found in similar situations.
THE INTERNAL CAROTID. 525
Terminal Branch of the Internal Maxillary Artery.
This is named the spheno-palatine ; it is a large vessel, often multiple, and is intended
exclusively for the pituitary membrane ; it passes from below upward, in a tortuous man-
ner, to penetrate the corresponding nasal fossa, by the spheno-palatine foramen, that is,
at the back part of the superior meatus, where it immediately divides into two branches :
one internal {s, fig. 205), which passes obliquely downward and forward, covers the sep-
tum with a complicated network, and anastomoses in front with the nasal branch of the
superior palatine ; the other external, which divides into three ramusculi for the three
meatuses, and ramifies in them and upon the turbinated bones. Some of the twigs en-
ter the sphenoidal and maxillary sinuses, the posterior and the anterior ethmoidal cella^
the frontal sinus, and the lachrymal canal
All these arteries form areolae of different sizes in the pituitary membrane, and give t,
in successful injections, a reticulated aspect ; they are situated between the periosteum
and the pituitary membrane, properly so called. The arteries of the turbinated bones
are lodged in the areolar cells on the surface of those bones, and in the arterial canals
which are hollowed out of them
Summary of the Distribution of the IrUernal Maxillary Artery
The internal maxillary sends branches to the organs of mastication and deglutition, to
the nasal fossae, to the bones and fibrous membranes of the cranium, to the face, and to
the organ of hearing. Its different branches are distributed in the following manner :
To the passive instruments of mastication, viz., the jaws and teeth, the inferior dental,
the superior dental, and the infra-orbital arteries ; to the active organs concerned in that
process, the masseteric, the anterior and posterior deep temporal, and the pterygoid arteries.
To the organs of deglutition, viz., the hard and soft palate and the pharynx, the supe-
rior palatine, the small meningeal, the vidian, and the pterygo-palatine arteries.
To the nasal fossae, some branches of the infra-orbital, and the whole of the spheno-
palatine artery ; the latter vessel, and, consequently, the internal maxillary artery also,
are very large in those animals which have a highly-developed olfactory apparatus.
To the organ of hearing, the tympanic artery, those branches of the middle meningeal
which enter the hiatus Fallopii, and also those which enter the canal of the internal
muscle of the malleus.
To the face, viz., to the muscles and integuments, the buccal, the infra-orbital, and the
merUal arteries. The region of the eye is the only part not supplied by the internal max-
illary.
To the bones of the cranium, and to the dura mater, the middle and the small meningeal
arteries. ^
The Internal Carotid.
Dissection. — The simplest method of exposmg this vessel is to make the section for
examining the pharynx. The carotid canal must be opened with a chisel, and the outer
wall of the cavernous sinus removed.
The internal carotid is distributed to the anterior part of the brain, and to the eye and
its appendages.
It is one of the two branches into which the common carotid divides : situated, at its
origin, on the outside of the external carotid, it passes sometimes vertically upward, par-
allel to, and in contact with, that artery, and sometimes behind it, by crossing it at an
acute angle opposite the digastric muscle ; it then leaves ine external carotid to pass
deeply into the triangular space between the pharynx and the ramus of the lower jaw,
and reaches the base of the cranium, into which it penetrates by the carotid canal. After
emerging from this canal, it is situated in the cavernous sinus, upon the sides of the
sella turcica, is reflected upward on the inner side of the anterior clinoid process, and
terminates by dividing into three branches.
The size of this artery, which is always exactly proportioned to that of the brain, is,
in the adult, equal to that of the external carotid ; in the infant it is much larger (ramus
grandior carotidis, Vesal.). In man, cis in the whole series of animjds, the relative size
of the internal and external carotids is determined by the relative development of the
brain and the face. The internal carotid is remarkable for retaining the Same diameter
from its commencement to its termination.
Its direction is generally straight until it reaches the base of the cranium, but some-
times it describes a single curve immediately after its commencement, sometimes sev-
eral curves having opposite directions. At the base of the cranium, before entering the
carotid canaU it becomes horizontal, and then vertical and ascending.
In traversing the carotid canal, it follows the angular course of that passage ; in the
cavernous sinus, it passes directly forward and upward, like the carotid groove ; at oth-
er times it describes two distinct curves ; lastly, on the inside of the anterior clinoid
process, it is reflected directly upward and a little backward. The double curvature
which it describes in traversing the carotid canal and the cavernous sinus has been weU
compared to the Roman letter S. The numerous inflections of the internal carotid form
536 ANGEIOL06Y.
one of the most decided arguments in favour of the opinion that the use of these wind-
ings is to retard the passage of the blood.
Relations : from its Origin to the Base of the Cranium. — At its origin, the internal carot-
id is situated as superficially as the termination of the common carotid, and is crossed
by the hypoglossal nerve and the occipital artery ; it soon passes behind the external
carotid, and becomes deeper and deeper Protected by its position m the triangular
space, which is bounded on the inside by the pharynx, and on the outside by the ramus
of the lower jaw, it rests behind upon the vertebral column, from which it is separated
by the praevertebral muscles and aponeurosis ; it is in relation in front and to the outer
side with the stylo-glossus and stylo-pnaryngeus muscles, which pass between it and
the external carotid ; on the inside, with the pharynx ; and on the outside and behind,
with the internal jugular vein The ascending pharyngeal artery is, moreover, in rela-
tion with it behind, and the great sympathetic nerve on the inside : the pneumogastric,
glosso-pharyngeal, and h3rpoglossal nerves are situated behind the internal carotid at
their exit from the cranium, but soon get to its outer side, between it and the internal
jugular vein.
The relation of the artery with the external surface of the pharynx explains how this
vessel may be wounded from the interior of that cavit)'. Sometimes one of its curves
approaches the region of the tonsil ; and this may, perhaps, have been the case when
the artery has been wounded by an instrument directed transversely outward and car-
ried into the tonsil, either to open an abscess or to excise the gland.
In the carotid canal, tae artery is in relation with the nervous filaments ascending
from the superior cervical ganglioa A very thin fibrous lamina, a prolongation of the
dura mater, separates the vessel from the bony walls of the canal. Its proximity to the
internal ear while traversing the petrous portion of the temporal bone, is probably the
cause of the arterial pulsations which are heard in certain cases.
In the cavernous sinus, the artery is applied against the inner wall of that cavity, and
IS, therefore, placed on the inner side of the nerves which pass through the sinus, and
more particularly of the sixth pair ; it is said that the artery is not bathed in the blood
contained in the sinus, but is protected from it by a very thin layer of membrane, con-
tinuous with the internal coat of the veins. However careful I may have been, I have
never succeeded in separating this membrane.
On the inner side of the anterior clinoid process, the artery is upon the outer side of
the optic nerve ; and at the point where it emerges from the dura mater, above the an-
terior clinoid process, it is received in a sheath formed by the arachnoid.
Branches of the Internal Carotid. — On the outside of the cranium it gives offno branch,
excepting in a few cases where it furnishes the ascending pharyngeal, or, rather, only
a supplementary pharyngeal brancl? ; and, lastly, when it gives off the occipital. In the
carotid canal, it sends a twig into the cavity of the tympanum by a special opening. In
the cavernous sinus, it furnishes several small branches {arterice reccptaculi), some of
which are reticulated, and distributed to that portion of the dura mater which lines the
basilar surface of the occipital bone, and to the walls of the inferior petrosal sinus ;
while others ramify upon the pituitary body, the fifth pair of nerves, and the adjacent
portion of the dura mater : a larger branch anastomoses with the middle meningeal ar-
tery.
Lastly, on the inner side of the anterior clinoid process, just as it passes above that
process, the internal carotid gives off in front a remarkable artery, named the ophthalmic.
The Ophthalmic Artery.
Dissection. — Make a partial injection, either from the common or internal carotid.
Remove the roof of the orbit, after having carefully detached the integuments and peri-
osteum of the frontal region ; leave a small bridge of bone on the inner part of the
margin of the orbit for the supra-orbital artery, or, rather, open the supra-orbital fora-
men and disengage the artery from it. Dissect the muscles of the eye with great care,
preserving all the vessels which present themselves. The study of the branches of the
ophthalmic artery, which are distributed to the ball of the eye, requires a perfect knowl-
edge of that organ.
This artery is principally destined for the eye and its appendages, and is less remark-
able for its size, which is inconsiderable, than for the number of its branches. Imme-
diately after its origin, it enters the optic foramen {b, fig. 207), on the outer side of and
below the optic nerve.* The artery is at first contained in the same sheath as the
nerve, but, soon escaping from it, penetrates into the orbit between the abducens oculi
nerve and the external rectus muscle of the eye, turns inward and crosses the optic
' A very remarkable variety in the origin of the ophthalmic artery is that m which this artery arises by a
common trunk with the middle meningeal or arteria media dura matris, which is a branch of the intenial
maxillary. In a case of this kind, which has been communicated to me by M. Dubreuil, the ophthalmic ar-
tery arose from the anterior branch of the meningeal ; when this branch reached the canal at the anterior in
ferior angle of the parietal bone, it entered the orbit by the external extremity of the foramen lacerum or-
bitale, and successively gave off the branches furnished by the ophthalmic artery.
THE OPHTHALMIC ARTERY. 527
nerre, sometimes at right angles and sometimes obliquely, and is then placed above the
nerve. Having reached the inner wall of the orbit, it again changes p.. ^^^
its direction, passes horizontally and in a slightly tortuous manner ^'
along the lower border of the superior oblique muscle of the eye,
and terminates by bifurcating at the margin of the orbit. Not un-
frequently, the ophthalmic artery, immediately after its origin, is
placed on the inner side of and below the optic nerve, and then pass-
es directly forward along the inner side of that nerve ; so that, in
these cases, the nerve and artery do not cross each other.
The ophthalmic artery gives off a great number of branches,
which, according to their origin,* may be divided into those ari-
sing on the outside of the optic nerve, viz., the lachrymal artery
and the central artery of the retina ; those arising above the nerve,
viz., the supra-orbital, the short ciliary, the middle or anterior ciliary,
the superior and the inferior muscular arteries ; those arising on the ^5^ '
inner side of the optic nerve, viz., the posterior and anterior eth-
moidal and the inferior and superior palpebral arteries ; in all, eleven branches, to which may
be added the terminal branches, viz., the nasal and the frontal arteries. It is well to remark,
that the origins of most of the above-named branches are subject to extreme variety.
Branches arising on the Outer Side of the Optic Nerve. — The lachrymal artery {c,Jig.
207), one of the largest branches of the ophthahnic, arises immediately before the en-
trance of the latter into the orbit. Not unfrequently it is given off from the middle me-
ningeal artery.
The lachrymal artery passes from behind forward along the outer wall of the orbit,
between the periosteum and the external rectus muscle, and enters the lachrjTnal gland
(/), supplying it with a great number of branches. Emerging from the gland very much
reduced in size, it terminates partly in the conjunctiva, and partly in the structures com-
posing the upper eyelid.
In its course it sometimes gives off a small meningeal branch, which passes back-
ward through the sphenoidal fissure, and enters the dura mater, in which it anastomoses
with the middle meningeal artery. This branch may be considered, in some subjects,
as one origin of the lachrymal artery ; a condition that leads to those cases in which
the lachrymal artery arises from the middle meningeal. It often gives off a long cihary
artery, and always some twigs to the neurilemma of the optic nerve, and muscular
branches to the levator palpebrse superioris and the superior rectus ; lastly, it furnishes
a muscular branch, the malar, which perforates the malar bone, and anastomoses in the
temporal fossa with the anterior deep temporal artery, and upon the malar bone itself
with the transversalis faciei.
The central artery of the retina {artena centralis renna, t), quite distinct from the twigs
supplied to the neurilemma of the optic nerve, is an extremely delicate vessel : it arises
either from the ophthalmic, or from one of the ciliary arteries, penetrates obliquely into
the substance of the nerve, runs along its centre from behind forward, enters into the
globe of the eye, and expands in diverging ramifications, which are applied to the inter-
nal surface of the retina, and accompany it as far as the ciliary processes. A branch
very distinct from those just mentioned traverses the vitreous body from behind forward,
in the axis of the eye, and reaches the capsule of the crystalline lens, after having fur
nished some extremely fine twigs to the hyaloid membrane.
Branches arising above the Optic Nerve. — The supra-orbital or superciliary artery (d)
arises from the ophthalmic as that vessel is crossing the optic nerve ; it is sometimes
given off from the lachrymal. It is very variable in size, and appears in certain cases
to be partially replaced by the orbital branch of the temporal, or by the frontal branch
of the ophthalmic. It passes horizontally between the periosteum of the roof of the or-
bit and the levator palpebrae superioris, accompanied by the frontal nerve ; it escapes
from the orbit at the superciliary notch, is reflected over it as over a pulley, ascends
vertically, and divides into two branches, one of which passes upward between the skin
and the orbicularis and occipito-frontalis muscles, and the other is situated between the
muscles and the periosteum, and ramifies in that membrane. The sub-cutaneous branch
often divides into an internal and an external twig. It is also said constantly to furnish
a branch to the diploe of the frontal bone, as it is passing through the superciliary notch.
It appears to me that this branch is often wanting.
The ciliary arteries may be divided into the posterior or short, the mjiddle or long, and
the anterior.
The posterior cuiary arteries (r) distributed to the choroid coat and the ciliary processes
(arteres uveales, Chauss.) are irregular in number which is stated to be thirty, or even
* The branches given off by the ophthalmic artery might be more philosophically divided as follows : Ist.
Those -which are destined to the globe of the eye, viz., the arteries of the retina, the short cihary or choroi-
dian, the middle or long ciliary, and the anterior ciliary ; 2d. Those which are distributed to the parts con-
tained in the orbital cavity, lachrymal and muscular arteries ; 3d. Those which are on the outside of tha
orbital cavity, the palpebral, sub-orbital, ethmoidal, frontal, and nasal artenes.
628 ANGEIOLOGY.
forty; they arise from two trunks : one inferior, which is given off from the ophthalmic
artery on the outer side of the optic nerve ; the other is superior, and arises above that
nerve. Not unfrequently the lachrymal artery gives off the inferior long ciliary trunk.
They run in a very tortuous course along the optic nerve, and, having reached the ball
of the eye, twist spirally and immediately expand into a tuft of tortuous ramusculi,
which surround the optic nerve, perforate the sclerotic coat around the entrance of the
nerve, and then ramify, as will be elsewhere stated, in the choroid coat and ciliary pro-
cesses.
The middle or long ciliary arteries (arteres iriennes, Chauss.), which are distributed to
the iris, are two in number, an internal and an external ; they perforate the sclerotic at
some distance from the optic nerve, and pass between the sclerotic and the choroid
membrane on the sides of the eyeball. Having reached the ciliary ring, each of them
divides into two branches, which anastomose together, and form the great vascular circle
of the iris. Numerous radiating branches proceed from all points of the inner border of
this circle towards the free margin of the iris, where they subdivide and anastomose to
form the lesser vascular circle of that membrane.
The anterior ciliary arteries are irregular in number, and are derived from the muscu-
lar branches, and sometimes from the lachrymal and infra-orbital ; they give some
branches to the conjunctiva, penetrate the sclerotic at a short distance from the cornea,
and terminate in the great circle of the iris.
The muscular arteries are two, viz., the superior and the inferior. The superior is the
smaller : it is often wanting, and is then replaced by branches from the lachrymal, infra-
orbital, or ciliary arteries. It is distributed to the levator palpebrae superioris, the supe-
rior rectus, and the obliquus superior. The inferior, which always exists, passes from
behind forward between the optic nerve and the inferior rectus, gives off most of the
anterior ciliary arteries, and is distributed to the external and inferior recti, and to the
obliquus inferior. Sometimes the inferior muscular is not entirely distributed to the mus-
cles, but forms an anastomotic arch with the infra-orbital branch of the internal maxillary.
Branches arising on the inner Side of the Optic Nerve. — The ethmoidal arteries are two,
viz., the anterior and the posterior. The posterior ethmoidal (e) is given off the first
from the ophthalmic, and is sometimes as large as the continuation of that artery : at oth-
er times merely a trace of it exists. It runs from without inward, passes through the
posterior internal orbital canal to reach the ethmoidal groove within the cranium, and
then divides into a meningeal and a nasal branch. The meningeal ramifies in the dura
mater, particularly in the falx cerebri ; the nasal branch enters the nasal fossa, through
the foramina of the cribriform plate, and anastomoses with the ultimate divisions of the
spheno-palatine artery.
The anterior ethmoidal (/) is mversely proportioned, as regards size, lo the posterior
artery, which is sometimes replaced by it ; it enters the cranium through the anterior
internal orbital canal, and divides into a meningeal branch, distributed upon the fabc cer-
ebri, and a nasal branch, which penetrates the olfactory cavities by the foramina of the
cribiform plate. The branches to the falx are remarkably tortuous.
The palpebral arteries are divided into the superior and the inferior. Both arise from
the ophthalmic, opposite the cartilaginous pulley of the superior oblique. Sometimes
they arise by a common trunk. Most commonly the inferior palpebral is given off a lit-
tle before the superior. Sometimes the superior is so large that it appears to result
from a division of the ophthalmic itself into two equal branches.
The inferior palpebral passes vertically downward, behind the tendon of the orbicularis
muscle, proceeds outward to reach the lower eyelid, along the whole length of which it
runs in the form of an arch without any winding, and is gradually lost at the external
canthus or angle of the eyelids.
The vascular arch thus formed, the inferior palpebral, is situated between the muscular
fibres of the eyehd and the tarsal cartilage, immediately below the free border of that
cartilage.
At the point where it enters the eyelid, it gives off a very remarkahle branch, which
anastomoses with the orbital branch of the infra-orbital artery. From the arch of anas-
tomosis a branch arises, which enters the nasal duct (branch of the nasal duct), and ram-
ifies in the mucous membrane of that passage, as far as the inferior meatus.
The superior palpebral passes downward behind the orbicularis palpebrarum, and, having
reached the superior punctum lachrymale, is reflected outward, between the muscular
fibres and the tarsal cartilage, immediately above its free border, along which it forms
an arch, and terminates by anastomosing with a palpebral branch derived from the su-
perficial temporal.
Terminal Branches of the Ophthalmic. — At the anterior extremity of the angle formed
by the upper and internal walls of the orbit, the ophthalmic artery terminates by divi-
ding into a nasal and a frontal branch.
The 7iasal branch varies in size, and is often larger than the ophthalmic artery itself,
so that some anatomists have regarded it as a branch of the facial, with which it always
anastomoses. It emerges from the orbit above the tendon of the orbicularis, and hav'
UEttEBRAL BRANCHES OF THE INTERNAL CAROTID.
(ng given off a small branch, which afterward enters the groove in the os unguis, to be
distributed to the mucous membrane of the lachrymal sac, it divides into two branches :
one, named the angular artery, runs in the groove formed by the nose and cheek, be-
tween the pyramidalis nasi and the levator labii superioris alaeque nasi ; it is accompa-
nied by the vein, which lies to its outer side, and it is continuous with the facial artery,
without any line of demarcation, the two vessels inosculating so completely, that it is
impossible to define their respective limits : the other branch, the dorsal artery of the
nose, runs along the dorsum of the nose, and terminates opposite each ala by anastomo-
sing with its corresponding artery. These two divisions of the nasal branch of the oph-
thalmic are sub-cutaneous, and give off numerous ramifications, which cover the whole
surface of the nose.
The frontal branch is smaller than the nasal, and generally smaller than the supra-
orbital or superciliary ; it passes upward upon the forehead, parallel to the supra-orbital,
with which it communicates above by a transverse branch ; it divides into sub-cutaneous
twigs, situated between the skin and the muscles, and into muscular and periosteal t\yigs.
Summary of the Distribution of the Ophthalmic Artery, — The ophthalmic sends branches
to the ball of the eye, to its appendages, viz., the muscles, eyelids, and lachrymal appa-
ratus, to the frontal region, and to the nose and nasal fossae.
To the ball of the eye it gives the arteria centralis retinae, which supplies the retina,
the hyaloid membrane, and the capsule of the crystalline lens ; the posterior, middle,
and anterior ciliary arteries, which are distributed to the choroid membrane, the ciliary
processes, and the iris.
It supplies proper muscular branches, and also twigs from its other branches, to the
muscles of the eye.
To the eyelids it gives off the palpebral arteries. To the lachrymal apparatus it sup-
plies the lachrymal artery for the gland, and the two branches for the lachrymal sac and
the nasal duct.
The frontal region receives its frontal and supra-orbital branches ; the nose, the nasal
branch, and the nasal fossae, the anterior and posterior ethmoidal arteries.
The Cerebral Branches of the Internal Carotid Artery.
When the internal carotid has given off the ophthalmic artery, it enters (c, fig, 208> a
Fig. 208.
deep fossa seen on the base of the brain at the inner
end of the fissure of Sylvius, and immediately divides
into three branches, which spread out from each other.
Of these three branches, the anterior is called the
anterior cerebral, or artery of the corpus callosum ; the
external is named the middle cerebral, or artery of the
fissure of Sylvius ; and the third, or posterior, is the
posterior communicating artery.
Not unfrequently the carotid gives origin to the pos-
terior cerebral artery, from which, in that case, the
posterior communicating artery is then given off, and
immediately joins the anterior extremity of the basi- |^/
lar artery.
The Anterior Cerebral Artery. Dissection. — The
study of these arteries requires no preparation ; it is
sufficient to overturn the brain in a manner which
will bring its base into view. Each artery will be
recognised by the following description : This vessel
{d d, fig. 208), also called the artery of the corpus cal-
losum, passes, immediately after its origin, forward
and inward, towards the median line, and thus reaches the longitudinal fissure between
the right and left anterior lobes of the brain. There it approaches its fellow of the op-
posite side, and communicates with it by a transverse branch, which passes at right an-
gles between them. This anastomotic branch (a), so remarkable for its size, shortness.
and direction, is called the anterior communicating artery ; instead of one, there are some-
times two smaller branches ; sometimes it is so short that the two anterior cerebral ar-
teries may be said to be applied to each other, and blended together at this point : most
commonly it is from one to two lines in length, and it then gives off some small twigs.
which penetrate into the third ventricle.
^Lfter communicating in this manner, the anterior cerebral arteries become parallel,
run from behind forward, turn upward in front of the anterior extremity of the corpus
callosum, and then run backward upon its upper surface, as far as its posterior extremity,
describing a curve, which exactly corresponds with that of the corpus callosum itself
Before turning over the anterior border of the corpus callosum, the anterior cere
bral arteries give off some ramuscuh to the optic and olfactory nerves, to the third ven-
tricle, and the adjacent part of the anterior lobe of the brain,"and also a series of large
branches, which are distributed to the inferior surface of the samr lobe. At the poin*
X X X
530 ANGEIOLOGY.
where the arteries are reflected, and also along the upper surface of the corpus callosum,
large branches arise from the convexity of the curve described by these vessels, and
ramify upon the inner surface of the two hemispheres : the anterior branches run from
behind forward, and the others from before backward, and from below upward ; most of
them reach the convex surface of the brain. Some capillary twigs proceed from the con-
cavity of the curve, and penetrate the substance of the corpus callosum.
We may regard as the termination of each anterior cerebral artery a very small branch
which continues in the same course, reaches the posterior extremity of the corpus callo-
sum, is there reflected downward, and terminates in the adjacent convolutions of the
brain.
The Middle Cerebral Artery. — This is larger than the preceding vessel ; it passes (/,
Jig. 208) outward and backward to enter the hssure of Sylvius, having previously given
off a great number of rather large branches, which run perpendicularly upward into the
very thin layer of cerebral substance situated at the junction of the longitudinal fissure
of the brain with the fissure of Sylvius.*
As soon as the middle cerebral artery has entered the fissure of Sylvius, it divides into
three branches : an anterior, which is applied to the anterior lobe ; a posterior, which
lies upon the middle lobe ; and a median branch, which corresponds to the small lobe
that is concealed within the fissure : they all follow the direction of this fissure, and are
concealed within it, but soon emerge so as to ramify upon the convolutions and anfrac-
tuosities of the brain, anastomosing with each other, and with the branches of the ante-
rior and posterior cerebral arteries.
It is of importance to remark, and this observation applies to all the cerebral arteries,
that the arterial ramifications destined for the surface of the brain are extremely tortuous,
that they dip into the anfractuosities, and cover the free borders and the two surfaces of
the convolutions, between which they are situated ; that they ramify very freely, and run
a very extensive course ; and that they do not divide gradually into smaller and smaller
branches, but that bundles of very fine capillary vessels arise from every part of the cir-
cumference of vessels of a certain size, and immediately penetrate the cerebral substance.
The Posterior Communicating Artery, or Communicating Artery of Willis. — This artery
varies exceedingly in size, being generally small, but sometimes forming the largest di-
vision of the internal carotid. It arises from the back of the carotid, runs from before
backward (?), and terminates in the posterior cerebral branch of the basilar artery. In
certain cases, the communicating artery of Willis may be regarded as the chief origin
of the posterior cerebral, which then seems to result from the union of this communica-
ting artery with the anterior bifurcation of the basilar.
The Choroid Artery. — A very small but constant branch (s) arises from the back of the
internal carotid, on the outer side of the communicating artery of Willis. This is the
artery of the choroid plexus, which passes backward and outward, along the optic tract,
and, consequently, along the eras cerebri, to both of which it sends branches, and then en-
ters the lateral ventricle at the anterior extremity of the great transverse fissure of the
brain, gives twigs to the hippocampus major and corpus fimbriatum, and terminates in
the choroid plexus, t
Summary of the Distribution of the Common Carotid Arteries.
The common carotids are distributed to the head, and to the organs which occupy the
front of the neck.
The internal carotid belongs exclusively to the brain, and to the organs of vision ; and
hence, doubtless, at least in part, arises that intimate relation between the condition of
the brain and of the eye, which is expressed by the common saying, that the eye is the
mirror of the soul.
Although the size of the internal carotid is almost always in proportion to that of the
brain, yet this artery is not the only one by which that organ is supplied with blood. The
vertebral artery, a large branch of the subclavian, completes the arterial system of the
brain ; and the fact of an artery, principally destined for the upper extremity, also send-
ing a branch to the brain, proves that there is nothing peculiar in the quality of the blood
transmitted to the encephalon.
We have already seen that the ophthalmic artery communicates by its nasal branch
with the facial artery, and by its inferior palpebral branch with the infra-orbital branch
of the internal maxilleury. But the internal carotid has no direct communication with the
external, unless when it gives origin to the ascending pharyngeal and the occipital arter-
ies. I may remark, however, that some meningeal branches are given off by the inter-
nal carotid within the cavernous sinus.
The external carotid differs from the internal, in giving origin to a very great number
of branches, which are distributed to the face, to the parietes of the cranium, to the or-
gans of respiration, and, lastly, to the organs of digestion.
The facial branches may be divided into the superficial and the deep-seated.
* We shall see hereafter that this region of the brain belongs to the corpus striatum.
.- ^ f See vertebral artery (p. 533), for the completion of the arterial system of the enceohalon.
ARTERY OF THE UPPER EXTREEITY. 531
The superficial arteries of the face are derived from many sources. The principal one
is furnished by the facial or external maxillary ; the others are the transverse artery, or
transverse arteries of the face, coming from the temporal ; the nasal, a descending branch
of the ophthalmic ; the buccal, masseteric, infra-orbital, and mental— all derived from
the internal maxillary. The arteries of the right side communicate very freely and fully
with those of the left ; and on each side, branches from the different sources communi
cate as freely with each other ; so that, in hemorrhage from any of them, the injured
vessel must be tied on both sides of the wound. I may call attention to the abundance
of arterial vessels in the face, and to the number and size of the muscular and cutaneous
branches ; this is evidently connected with the extreme susceptibility of the skin of tliis
region, the existence of the hair-bulbs, and the action of the muscles in giving expression
to the features.
The deep arteries of the face are principally derived from the internal maxillary. Thus,
the spheno-palatine supplies the nasal fossae : some branches of the infra-orbital enter
the orbit. We shall afterward allude to the branches which are furnished to the buccal
cavity and the zygomatic and spheno-maxillary fossae. Lastly, the superficial and deep
arteries of the face are united by numerous anastomoses.
The first set of cranial branches, derived from the external carotid, are the arteries of
the hairy scalp, viz., the occipital, temporal, posterior auricular, supra-orbital, and frontal.
With regard to these arteries, it is important to notice their large size, which is connect-
ed with the great vitality of the skin of the head, and with the existence of the bulbs of
the hair ; also, that they are extremely tortuous, which appears to me to be in corre-
spondence with the great number of branches which they give off; and, lastly, that they
are situated in the dense cellular tissue which connects the skin with the muscles and
the epicranial aponeurosis.
Besides these, small branches are found upon the pericranium, under the muscles and
epicranial aponeurosis : they are seen on the forehead, where they arise from the fron-
tal and infra-orbital arteries, and also in the temporal region, where they axe C2illed the
deep temporals ; these branches are both periosteal and muscidar.
The second set of branches to the cranial parietes are arteries of the interior of the cra-
nium, viz., the meningeal, the chief of which is the middle meningeal, a branch of the in-
ternal maxillary : the others, or small meningeals, enter through most of the foramina
at the base of the cranium. Among these latter we would mention the meningeal
branches of the ascending pharyngeal artery, and meningeal branches from the ethmoidal
arteries, to which may be added some small twigs given off from the internal carotid,
while enclosed in the cavernous sinus.
We may also refer the arteries of the organ of hearing to those of the cranial pirietes.
They are the posterior auricular and the anterior auricular, which are distributed to the
pinna and to the external meatus ; the tympanic, which passes through the fissure of
Glasserus, and a small branch of the middle meningeal, which enters through the hiatus
Fallopii.
The branches of the external carotid distributed to the orguns of digestion belong to the
following parts :
To the organs of mastication, viz., the alveolar, the infra-orbital, and the inferior den-
tal arteries, which go to the teeth and the jaws ; the superior palatine, which supplies
the roof of the palate ; and, lastly, the deep temporal, the masseteric, and the pterygoid,
which are distributed to the muscles of mastication. To the salivary organs : thus, the
parotid receives its branches from the external carotid and the temporal ; the sub-max-
illary gland from the facial ; and the sub-lingual gland from the sub-lingual branch of the
lingual artery. To the velum pdati and the tonsils we find the ascending or inferior
palatine branch of the facial artery, the superior palatine branch of the internal maxillary,
and the ascending pharyngeal. To the pharynx, the pharyngeal twigs from the superior
thyroid, the ascending pharyngeal, the pterygo-palatine or superior pharyngeal, and the
vidian from the internal maxillary, and the inferior palatine branch of the facial. To
the oesophagus there are the descending oesophageal branches of the superior thjToid.
The branches given by the external carotid to the air-passages are the superior and infe-
rior laryngeal, from the superior thyroid artery, which is essentially distributed to the
thyroid gland.
Aeteet of the Uppee Extremity.
A aiagle arterial trunk, called the brachial trunk ( Chaussier), is destmed for the upper
extremity. On the left side it arises directly from the arch of the aorta, and on the
right side from the innominate artery ; it emerges from the thorax, between the first rib
and the clavicle, traverses the axilla, runs along the inner side of the arm, passes in front
of the elbow-joint, and divides into two branches, which supply the forearm and the hand.
As the brachial trunk has some highly important relations during its course, and,
moreover, furnishes a very great number of branches, it has been artificially divided, in
order to facilitate its study : each of the divisions has received a particular name, ac-
cording to the region through which it passes : thus, the arterv of the upper extremity
532 ANGEIOLOGY.
is called successively the sub-clavian, the axillary, and the hwneral artery , and its termi-
nal divisions are named the radial and ulnar arteries.
The Brachio-cephalic Artery.
The brachio-cephalic or innominate artery {arteria anonyma of many authors, e,fig. 198)
is the common trunk of the right sub-clavian and right common carotid arteries, and has
in turns been regarded as a portion of the carotid, and as a part of the sub-clavian. It
arises from the aorta, at the point where that vessel changes its direction from vertical
to horizontal. It is situated in front and to the right of the other arteries given off from
the arch of the aorta. It is from one inch to fifteen lines in length. It is directed ob-
liquely upward and outward.
Relations- — In front of the mnommate artery is the sternum, beyond the upper end of
which the artery almost always projects, and from which it is separated by the left
brachio-cephalic vein, by the remains of the thymus, and by the sternal attachments of
the stemo-hyoid and sterno-thyroid muscles. Behind, it is in relation with the trachea,
which it crosses obliquely ; on the outer side, with the pleura and mediastinum, which
separate it from the lungs ; on its inner side is the left common carotid, from which it is
separated by a triangular interval, in which the trachea is seen.
From a knowledge of these relations, modem surgeons have succeeded in applying a
ligature to the innominate artery. Its relations, however, vary in different individuals.
In some cases almost the whole length of the vessel projects beyond the sternum ; and
it is then extremely accessible, either to accidental wounds, or to the surgeon in the ap
plication of a ligature. It has been thought that the presence of the innominate artery
explains the predominance of the right over the left upper extremity ; but this opinion
is entirely unfounded.
The arteria innominata gives off no collateral branch, except in those cases in which
it affords origin to the thyroid artery of Neubauer, so named from the anatomist who
called attention to this anatomical variety.* The same anatomist has seen the right in-
ternal mammary artery arise from the brachio-cephahc trunk
The Right and Left Sub-clavian Arteries.
The right sub-clavian artery {g, fig. 198 ; f,fig. 204) arises from the innominate (c) ;
the left sub-clavian {g"), from the arch of the aorta.
Varieties of Origin. — One very common variety is that in which the right sub-clavian
arises below the left, from the posterior and inferior part of the arch of the aorta, from
which it passes upward and to the right side, generally behind the trachea and oesopha-
gus, sometimes between the two, and rarely in front of the trachea, t
The precise termination of this artery is not well defined. By some authors it is said
to end, and the vessel to take the name of axillary artery as it passes between the sca-
leni.t It appears to me more convenient to take the clavicle as indicating the respect-
ive limits of the two vessels. All above the clavicle, then, belongs to the sub-clavian,
and all below it to the axillary artery.^
From the difference, as to origin, between the right and left sub-clavians, they diffei
from each other remarkably in length, direction, and relations.
Differences in Length. — The right sub-clavian is shorter than the left by the length of
the innominate artery ; and we should, moreover, bear in mind the slight difference in
the height between the origin of the innominate and the left sub-clavian. The difference
in the size of the two sub-clavian arteries requires no special notice.
Differences in Direction. — The right sub-clavian passes at first obliquely outward and a
little upward, and then bends over the apex of the lung, describing a curve with the con-
cavity looking downward. The left sub-clavian passes vertically upward before curving
over the apex of the lung, opposite which it changes its direction abruptly, and becomes
horizontal.
Differences in Relations. — In describing these, we shall divide the sub-clavian artery
into three portions : the^rs^, extending from the origin of the artery to the scaleni mus-
cles ; the second, situated between the scaleni ; and the third, extending from the scale-
ni to the clavicle. The relations of the right and left sub-clavians differ from each other
only in the first of these portions.
The first portion {I, fig- 204) of the right sub-clavian is in relation in front with the inner
end of the clavicle, the sterno-clavicular articulation, the platysma, and the clavicular
attachment of the sterno-mastoid muscle, with the stemo-hyoid and sterno-thyroid mus-
cles, with the termination of the internal jugular and vertebral veins in the sub-clavian
* This inferior thyroidean artery arises, perhaps, more frequently from the arch of the aorta, between the
brachio-cephalic trunk and the left primitive carotid.
t [It rarely passes between the trachea and o;sophagTis ; and it appears there is no record of its having been
actually seen in front of the trachea (see Quain on the Arteries).'^
X According to some authoi-s, the artery changes its name as it emerges from between the scaleni ; accord-
ing to others, while it is yet between those muscles.
^ We are in the habit of dividing this artery into three portions : a cardiac, a middle, and an axillary por-
lion. The first, that part between its origin and the scaleni ; the second, the portion embraced between tho
Bcaloni ; and the third, the remaining part of the artery. — Ed.
THE VERTEBRAL ARTERY. 533
Tein, and with the right pneumogastric and phrenic nerves ; behind, with the recurrent
laryngeal nerve and the transverse process of the seventh cervical vertebra ; on the out-
er side, with the mediastinal pleura, which separates it from the lung. On the inner
side, it is separated from the conmion carotid by a triangular interval.* It is surround-
ed by loose cellular tissue, a great number of lymphatic glands, and nervous loops formed
by the great sympathetic.
The first portion of the left sub-clavian is in relation with the same parts, though to a
somewhat different extent : thus, its relations with the left mediastinal pleura and lung
are much more extensive. The sub-clavian vein crosses it at right angles, instead of
being parallel to it ; but the left pneumogastric and phrenic nerves run parallel to, in-
stead of crossing it. It is parallel to the left common carotid, instead of forming an an-
gle with it ; and, instead of being near the clavicle, the left sub-clavian is close to the
vertebral column, and rests on the longus colli, the inferior cervical ganglion of the sym-
pathetic nerve, and the thoracic duct, which is there to its inner side.
The second portion of both the right and left sub-clavian arteries, situated between the
scaleni, is in close relation below with the middle of the upper surface of the first rib, on
which there is a corresponding depression behind the tubercle for the attachment of the
anterior scalenus ; above, with the two scaleni, which are in contact with each other
above the vessel ; behind, with the brachial plexus ; in front, with the scalenus anticus,
which separates the subclavian artery from the sub-clavian vein. This separation of the
artery from the vein is one of the most important points in its history. +
The third portion of the sub-clavian, or that extending from the scaleni to the clavicle,
corresponds to a triangular space, bounded in front by the stemo-mastoid and anterior
scalenus, above by the omo-hyoid, and below by the clavicle : this space is named the
lower or clavicular portion of the posterior triangle of the neck, which is bounded in front
by the stemo-mastoid, behind by the trapezius, below by the clavicle. In front of, but
somewhat lower than the artery, is the clavicle, that bone being separated from the ves-
sel by the sub-clavian vein, which is here below and in contact with the artery, and by
the sub-clavius muscle ; behind and to the outside of the artery is the brachial plexus
of nerves, which surrounds the vessel in the axilla ; it is covered by the deep cervical
fascia, the platysma, the superficial fascia, and the skin, and is crossed by the descend-
ing cutaneous branches of the cervical plexus, and obliquely by the supra-scapular ar-
tery and vein ; below, it rests upon the first rib.
In consequence of these relations, the sub-clavian artery may be compressed, and the
circulation of the upper extremity stopped by forcible depression of the clavicle ; the
sub-clavian may be easily felt, compressed, and tied above the clavicle ; and, lastly, it
follows that the sharp fragments of a broken clavicle can wound the coats of the artery
only after having transfixed the sub-clavius muscle and the sub-clavian vein.
This artery, moreover, presents individual varieties both in regard to its direction and
relations ; it usually rises slightly above the clavicle, but in persons with short necks
and high shoulders it is situated deeply under the clavicle, while in those who have long
necks and low shoulders it may even slightly raise up the platysma and the skin. But
the most important variety is that in which the relations of the sub-clavian with the sca-
leni muscles are changed. It is not uncommont to see the sub-clavian artery situated
in front of the scalenus anticus, forming immediate relations with the sub-clavian
▼ein.ij
Collateral Branches. — The sub-clavian artery gives off certain collateral branches,
which may be divided into the superior, inferior, and external. The superior are the rer-
tebral and the inferior thyroid ; the inferior are the internal mammary and the superior in-
tercostal ; the external are the supror scapular, the posterior scapular or transversalis colli,
and the deep cervical.
Besides these, the sub-clavian arteries sometimes give off, near their origin, pericar-
diac, thymic, and oesophageal branches ; not unfrequently the left sub-clavian gives ori-
gin to the bronchial artery of that side.
The Vertebral Artery.
TTie vertebral artery, destined for the cerebro-spinal nervous centre, supplies more
particularly the spinal cord, the pons Varolii, the cerebellum, and the posterior portion
of the cerebrum. It is the first and largest branch of the sub-clavian, and in some
subjects is about equal in size to the continuation of that vessel. A very great inequal-
ity in the size of the two vertebrals is rather frequently met with. Morgagni states
* [It has been observed by Professor R. Quain (Joe. cit.) that the origin of the right sub-clavian is sometimes
partially or completely covered by the right carotid, a process of the cervical fascia separating the two vessels.]
t [Professor Quain has seen, in a few cases, the artery perforating the anterior scalenus ; and it has even
been found, by himself and others, anterior to that muscle, and therefore in contact with the vein.]
t According to our observation, this is a most rare variety. — Ed.
♦ In a case of this kind, which has been communicated to me by M. Demeaux, adjunct of anatomy to the
Faculty, there was no brachio-cephalic trunk, but a bi-carotid trunk : the right sub-clavian arose from the de-
scending aorta, and went behind the trachea and the oesophagus. (This preparation has been deposited in the
museum of the Faculty.)
h^
ANGEIOLOGT
that he has seen the right vertebral four times as large as the left ; I have seen the left
vertebral represented by a very small twig.
The vertebral artery arises (2, fig. 204) from the upper and back part of the sub-clavi-
an, at the point where it curves over the apex of the lung ; the left vertebral often ari-
ses directly from the arch of the aorta, between the common carotid and sub-clavian of
the same side. The right vertebral has been found arising from the point at which the
innominate divides into the right common carotid and right sub-clavian. It has also
been seen arising by two trunks, both of which sometimes come from the sub-clavian ;
and at others, one proceeds from that artery, and the other from the arch of the aorta.*
Immediately after leaving the sub-clavian, the vertebral artery passes vertically up-
ward and a little backward, enters between the transverse processes of the sixth and
seventh cervical vertebrae, in order to reach the foramen in the base of the transverse
process of the sixth, ascends through the foramina in the transverse processes of the
succeeding cervical vertebrae, describing some slight curves in passing from one to an-
other. In order to gain the foramen in the axis, it forms a considerable vertical curve
between the atlas and that bone ; it then forms a second horizontal curve between the
atlas and the occipital bone.t perforates the posterior occipito-atloid ligament and dura
mater, and enters the cranium by the foramen magnum. The right and left vertebral
arteries turn round the sides of the medulla oblongata, between the hypoglossal and sub-
occipital nerves, converge {i i, fig. 208) in front of the medulla, and near the furrow
which separates it from the pons Varolii, unite at an acute angle to form the basilar ar-
tery {b). The two remarkable curves described by the vertebral artery before it enters
the cranium are in accordance with those formed by the internal carotid within the ca-
rotid canal and cavernous sinus. I have seen the vertebral very tortuous at the lower
part of the neck, before it entered the covered way formed for it by the cervical trans-
verse processes.
Not unfrequently the vertebral artery enters the canal of the transverse processes at
the fifth cervical vertebra ; it has occasionally been seen to enter at the fourth, third, and
even at the second. It very rarely enters the foramen of the seventh cervical vertebra.
Relations. — Before entering the foramen of the sixth cervical vertebra, the vertebral
artery is situated deeply upon the spine, between the longus colli and the anterior scale-
nus, and behind the inferior thyroid artery. The thoracic duct is at first on the inner
side, and then in front of the left vertebral artery. From the sixth cervical vertebra to
the atlas, it is protected by the canal formed by the series of foramina in the transverse
processes, and in the intervals between them by the inter-transversales muscles ; it lies
in front of the cervical nerves, but the sub-occipital nerve lies between it and the groove
in the atlas. In the intervals between the axis and atlas, and between the atlas and oc-
cipital bone, it is in relation with the complexus and trachelo-mastoideus, and with the
rectus capitis posticus major and obliquus superior. In those cases where the vertebral
artery does not enter the vertebral foramina until it has passed up to the third or second
cervical vertebra, it goes upward along the side of the internal carotid artery. In the
cranium, it is situated between the basilar surface of ti^e occipital bone and the anterior
surface of the medulla oblongata.
Collateral Branches. — In its course along the canal of the transverse processes, the ver-
tebral artery gives off spinal branches, which enter the vertebral canal through the in-
ter-vertebral foramina, and are distributed in the same manner as the spinal branches of
the intercostal and lumbar arteries. Several of these branches, however, are derived
from the ascending cervical artery, and from the praevertebral branches of the ascending
pharyngeal. From the two curves formed by the vertebral artery arise a great number
of small muscular branches, which are distributed to the deep muscles of the cervical re-
gion, and anastomose with branches of the occipital and deep cervical arteries. Among
these there is one, sometimes two, which enters the cranium through the foramen mag-
num, and is distributed to the dura mater lining the inferior occipital fossa:, and to the
falx cerebelli : it is the posterior meningeal artery (rami meninges posteriores, Holler).
Soemmering has pointed out a small meningeal branch, which enters the cranium with
the first cervical or sub-occipital nerve, and which appears to me to be constant.
In the cranium, before uniting to form the basilar, the vertebral arteries give off the
posterior and anterior spinal arteries, and the inferior cerebellar.
Spinal Arteries. — These are small branches, remarkable for being extremely slender,
and for arising at an obtuse angle, so that they descend in a precisely opposite direction
* One of the most remarkable varieties of origin of the vertebral artery is the followring, which has been
communicated to me by Professor Dubreuil :
In a woman of forty- five years, the left vertebral arteries arose neither on the right nor on the left side from the
corresponding sub-clavian arteries. The left Tertebral took its origin directly from the arch of the aorta, be-
tween the left sub-clavian and the left primitive carotid. The right vertebral arose from the right primitive
carotid, at the distance of four millimeters from its origin. Both arteries passed upward, in parallel lines,
along the vertebral column, as far as the third cervical vertebra, when they entered the vertebral foramina of
the transverse processes of this vertebra, having previously given off several small supplementary branches of
the ascending cervical arteries. The sub-clavian artery gave here origin only to five collateral branches.
t Have the curvatures of the vertebral artery any relation to the motions of the head upon the vertebnkl
(tolumn ?
THE VERTEBRAL ARTERY. 635
to the vertebral arteries, which ascend vertically ; they are distinguished into the anterior
and the posterior spinal artery. It is incorrect to regard them as continued down to the
lower part of the spinal cord : they are so slender, that they can only supply a very small
portion of the cord ; in reality, they are nothing more than the commencement of the spi-
nal arteries, which are continued through the whole extent of the cord by means of
branches given off from the cervical, dorsal, and lumbar arteries.
The posterior spinal artery arises from the vertebral while that vessel lies upon the
side of the medulla oblongata, and sometimes from the inferior cerebellar artery ; it pass-
es in a tortuous manner inward, and divides into an ascending branch, which terminates
upon the sides of the fourth ventricle, and a descending tortuous branch, which winds
along the sides of the posterior surface of the cord, and divides into two twigs, a small
one situated before, and a larger one placed behind the posterior roots of the spinal
nerves ; around each of these roots they form a network, and, by means of transverse
branches, which are twisted on themselves and much interlaced, they communicate with
the corresponding branches of the opposite side. Chaussier was therefore incorrect in
giving the name of the posterior median artery of the spine to the two posterior spinal ar-
teries. Tliese small branches of the vertebral are soon exhausted ; they are continued
on each side by branches of the cervical, dorsal, and lumbar spinal arteries, which run
upward along the posterior roots of the nerves, and having reached the sides of the cord,
divide into ascending and descending branches, which anastomose witli the neighbour-
ing vessels, form a network around each pair of nerves, and communicate by tortuous
transverse branches with the arteries of the opposite side.
The anterior spinal artery (m, Jig. 208), which is somewhat larger than the posterior,
arises from the vertebral near the basilar, sometimes even from the basilar itself, or from
the inferior cerebellar, passes almost vertically inward and downward, in front of the
medulla oblongata, and anastomoses in the same manner as the vertebral with its fellow
of the opposite side, so as to constitute a median trunk, which is correctly named the
anterior median artery of the spine ; it is situated beneath the pearly fibrous band found
along the anterior median furrow, and is continued by branches from the cervical, dorsal,
and lumbar arteries.
The anterior, or median spinal artery, therefore, results from the anastomoses of the
two anterior spinal branches of the vertebral. In one case there was no artery on the
left side, but the right was twice as large as usual. The vessel is of considerable size,
until it has passed below the cervical enlargement of the cord, from which point down
nearly to the dorsal enlargement it becomes exceedingly delicate ; a little above the last-
named enlargement it suddenly increases in size, again gradually diminishes as it ap-
proaches the lower end of the spinal cord, and becoming capillary, is prolonged down to
the sacrum, together with the fibrous string in which the spinal cord tenninates.
During its course, this artery receives lateral branches from the ascending cervical
and the vertebral in the neck, and from the spinal branches of the intercostal and lum-
bar arteries in the back and loins. These branches penetrate the fibrous canal formed
by the dura mater around each of the spinal nerves ; become applied to the nervous
ganglia, to which they supply branches ; get intermixed with, and follow the course of,
the corresponding nerves ; send small twigs backward to the posterior spinal arteries,
and terminate in the anterior spinal trunk, at variable angles, similar to those at which
the nerves are attached to the spinal cord.
The re-enforcing spinal branches are not nearly so numerous as the nerves. If the con-
dition which I have observed in three subjects be constant, there are three in the cervi-
cal region, one or two in the contracted portion of the cord, and one only at the inferior
enlargement. This last, which in one case was as large as the ophthalmic artery, reach-
ed the cord at a very acute angle ; opposite the median line, it divided into two branch-
es, one ascending and very small, the other descending, of considerable size, and form-
ing the true continuation of the trunk.
From the anterior spinal arteries there proceed a great number of twigs, which pass
backward into the anterior median furrow, and from thence into the substance of each
half of the corresponding portion of the cord ; also some lateral branches, which ramify
on the sides of the cord in the pia mater.
The Inferior and Posterior Cerebellar Arteries. — These (A h) arise from the outer side of
the vertebral, and sometimes from the basilar ; they are of considerable size, and often
differ in this respect on the two sides. Each of them soon turns round the medulla ob-
longata, pursuing a tortuous course, passes between the filaments of origin of the hypo-
glossal nerve, runs in front of the roots of the pneiunogastric and glosso-pharyngeal nerves,
crosses the restiform body, and reaches the back of the medulla oblongata on one side of
the opening of the fourth ventricle ; it then passes backward, between the inferior ver-
miform process and lateral lobe of the cerebellum, and divides into two branches : one
internal, which continues along the furrow between the vermiform process and lateral
lobe, supplies the former, and turns upward into the notch in the posterior margin of the
cerebellum ; the other branch is external, and passes outward upon the lower surface of
the cerebellum, and divides into a great number of twigs, which may be traced as far as
536 ANGEIOLOGY.
the circumference of the cerebellum, and which anastomose with those of the superior
cerebellar artery.
The Basilar Trunk. — The basilar trunk (^>) results from the junction or confluence of
the two vertebral arteries. It is larger than either of them singly, but its area is not
equal to the sum of their areas ; so that, by this arrangement, the passage of the blood
is accelerated. It commences opposite the furrow between the medulla oblongata and
the pons Varolii, and terminates by bifurcating in front of the anterior border of the pons ;
its length, therefore, corresponds to the antero-posterior diameter of the pons, on the
median furrow of which it is situated. When the vertebral arteries are displaced to-
wards the right side (a very common condition), the basilar trunk passes horizontally or
obliquely to the left, so as to reach the median furrow.
It gives off no branch from its lower surface, which rests upon the basilar groove of
the occipital bone. A great number of capillary twigs are detached from its upper sur-
face, and enter the pons Varolii. From its sides proceed the anterior inferior cerebellar
and the superior cerebellar.
The anterior and inferior cerebellar arteries {I I) vary much in size in different subjects,
and are rarely equal in this respect on the right and left sides : each of them arises from
about the middle of the basilar, and occasionally from the vertebral itself, passes out-
ward and backward, sometimes behind, and sometimes in front of the sixth nerve, l^lns
along the cms crebelli, passes in front of the facial and auditory nerves, and terminates
upon the anterior portion of the hemisphere of the cerebellum.
The superior cerebellar arteries (t t) arise one from each side of the basilar, immedi-
ately before it divides into its two terminal branches ; they might, therefore, also be re-
garded as terminal branches of that artery, which would thus end by dividing into four
branches. Having arisen at a right angle behind the third, or motor oculi nerve, each
superior cerebellar artery, accompanied by the fourth or trochlear nerve, turns round the
crus cerebri in the groove between it and the pons Varolii, and, having reached the up-
per surface of the corresponding crus cerebelli, divides into two branches : one external,
which passes outward on the upper surface of the cerebellum, along the anterior half of
its circumference ; the other internal, which is directed inward upon the sides of the su-
perior vermiform process, or median lobule of the cerebellum, and then subdivides into
an antero-posterior branch, which passes from before backward upon the sides of the
vemiiform process, as far as the circumference of the cerebellum, upon which it ramifies ;
and a transverse branch, which continues the original course of the vessel towards the
median line, running between the superior vermiform process and the valve of Vieussens,
and being distributed to both.
The terminal branches of the basilar trunk are the posterior cerebral arteries (n n) ; they
arise at variable angles, are directed forward and outward, and then curve backward, so
as to turn round the crus cerebri, parallel to the superior cerebellar arteries, from which
they are separated by the third or motor oculi nerve. They follow the concave bordei
of tiie great transverse fissure of the brain, and, having reached the posterior extrem-
ity of the corpus callosum, leave this fissure to pass backward upon the lower surface
of the posterior lobe of the cerebrum, where they may be traced as far as the occipital
region. Each of the posterior cerebral arteries gives off, immediately after its origin, an
immense number of small parallel twigs, which enter the substance of the brain between
the anterior crura, whence the name of perforated spot given to that portion of the brain.
Just as each posterior cerebral artery curves backward, it receives the communicating
artery of Willis (r), which is sometimes very large, and at other times very small. When
large, it evidently assists in the formation of the posterior cerebral, which, after its junc-
tion with the communicating artery, sometimes becomes doubled or trebled in size. The
part performed by the internal carotid in the formation of the posterior cerebral is, there-
fore, subject to variety. In certain cases, as I have already stated,, the posterior cere-
bral is exclusively derived from it.
The posterior choroid artery arises from the back part of the posterior cerebral, imme-
diately after the junction of that vessel with the communicating artery ; it turns round
the crus cerebri, passes above and supplies the tubercula quadrigemina, and terminates
in the velum interpositum and choroid plexus.
As the posterior cerebral artery quits the crus cerebri, it gives off a branch which
passes outward and backward, crosses obliquely the long convolution which forms the
lateral boundary of the great fissure of the brain, and ramifies upon the lower surface of
the cerebrum. Lastly, the posterior cerebral gives off a small constant branch, which
may be called the artery of the fascia dentata, to which it is distributed.
Remarks on the Arteries of the Brain, Cerebellum, and MeduU-a Oblongata.
The arteries of the encephalon, i. e., of the brain, cerebellum, and medulla, are deri
ved from four principal trunks, tw^o anterior, viz., the internal carotids, which arise from
the common carotids, and two posterior, viz., the vertebrals, which are branches of the
sub-clavian arteries. There are several circumstances to be remarked concerning these
vessels, viz., their great size, which is dependant on that of the brain ; their depth from
THE INFERIOR THYROID ARTERY. 637
the surface before they enter the cranium ; the numerous curves formed by them as they
are entering the cranial cavity, the use of vphich is evidently to retard the course of the
blood ; the absence of any large collateral branches, the only exception being the oph-
thalmic branch of the internal carotid, by the existence of which the circulation in the
eye is connected with that in the brain. Another remarkable point concerning these
vessels is their anastomoses at the base of the cranium, viz., the anastomosis, or, rath-
er, the confluence of the right and left vertebral so as to form the basilar artery ; the
anastomosis of the right and left internal carotids by means of the anterior communica-
ting artery, which unites the anterior cerebrals, and the anastomosis of the internal ca-
rotids with the vertebrals by the communicating arteries of Willis. By these anasto-
moses an arterial hexagon (the circle of Willis) is formed, the anterior margins of which
correspond with the anterior cerebral arteries, the posterior with the posterior cerebrals, '
and the lateral with the communicating arteries of Willis.*
From this hexagon, as from a centre, proceed all the arteries of the brain, viz., from
the anterior angle, the anterior cerebral arteries ; from the posterior angle, the basilar
artery ; from the anterior lateral angle on each side, the middle cerebral ; and from the
posterior lateral angle on each side, the posterior cerebral artery
Owing to the existence of these large anastomotic communications, any one of the
four arterial trunks would be sufficient to carry on the circulation in the brain, if the
other three were wanting or obliterated The situation of this arterial hexagon between
the bones of the cranium and the brain is remarkable, because it explains the alternate
movements of elevation and depression seen in the brain when that organ is exposed
during life
It should also be observed, that the arteries of the cerebellum, pons Varolii, and me-
dulla oblongata, are derived from the same sources as those of the brain.
Lastly, as to the mode of distribution of these vessels, it may be remarked, that the
arteries of the brain pass over the free surface of one or more convolutions, dip into the
sulci between the convolutions, are reflected from one side of them to the other, give
off a great number of very small branches, emerge from a given sulcus to regain the
surface of the adjacent convolutions, and so on until they are exhausted. The princi-
pal arteries of the cerebellum run upon its surface without passing into the sulci, be-
tween the laminae, into which they send only very small branches. With some excep-
tions, the arteries are reduced to capillary dimensions before they enter the nervous
substance.
The Inferior Thyroid Artery.
Dissection. — Dissect the muscles of the sub-hyoid region ; follow the branches of the
thyroid ; trace the divisions of the ascending cervical artery into the grooves upon the
transverse processes of the cervical vertebrae, and into the vertebral canal.
The inferior thyroid artery. (3, fig. 204) arises from the front of the sub-clavian on a
plane anterior to the vertebral, which often comes off exactly opposite to it. It varies
remarkably in size and origin, as well as in the branches which it furnishes. It fre-
quently arises from the common carotid ; sometimes from the arch of the aorta, between
the brachio-cephalic and the left common carotid ; at other times from the brachio-ce
phalic itself Lastly, it is occasionally replaced by the thyroid of Neubauer.
It often commences by a common trunk with the supra-scapular, less frequently with
the posterior scapular, and rarely with the internal mammary.
Its size bears an inverse proportion to that of the superior thyroid of the same side
and depends, also, on the presence or absence of a third thyroid. It is larger in infancy
than at any other period. In certain cases of goitre it becomes prodigiously developed.
Sometimes there is merely a trace of its existence, or it is even altogether wanting.
Immediately after its origin it passes vertically upward, then descends so as to de-
scribe a curve with its concavity directed downward, and again forms another curve
with its concavity turned upward, to reach the lower end of the lateral lobe of the thy
roid gland, in the interior of which it ramifies.
Relations. — Behind, it is in relation with the trachea, the oesophagus, and the verte-
bral column, being separated from the latter by the praevertebral muscles and the ver-
tebral artery. Its relation with the oesophagus is more marked on the left than on the
right side, and it is important to bear this fact in mind in performing thq operation of
oesophogotomy. In front, its first curve embraces the common carotid, the internal
jugular vein, the pneiuntiogeistric, and the great sympathetic nerves. The middle cervi-
cal ganglion, when it exists, rests upon it. The second curve embraces the recurrent
laryngeal nerve, and is also in relation with the muscles of the sub-hyoid region. It
may be remarked, that there is one point in the neck where three arteries come into
contact, viz., the common carotid, the inferior thyroid, and the vertebral.
Collateral Branches. — The inferior thyroid gives off, downward, an oesophageal branch,
" In a person who died ol apoplexy, Morgagni found a want of communication between the vertebrals and
carotids ; and he attributed the apoplexy partly to this circumstance, and partly to the fact that the left ver-
tebral arose directly from the arcli of the aorta.
Yyy
^4|P ANGEIOLO&Y.
some tracheal branches, and a small brojichial twig. I have seen the right bronchial ar-
tery derived from it. It also gives off several muscular branches to the scalenus anti-
cus and the praevertebral muscles. The most remarkable of all these is the ascending
cervical artery (4), which is of variable size, and is sometimes so large that it may be
regarded as resulting from the bifurcation of the inferior thyroid. It passes vertically
upward, in front of the scalenus anticus, then in the groove between it and the rectus
capitis anticus major, to both of which, as well as to the attachments of the levator an-
guli scapulae, it gives some small branches. The most remarkable of its branches, call-
ed the cervicorspitial, enter the grooves by which the cervical nerves emerge, run in
front of these nerves, and anastomose with the branches of the vertebral artery. I have
seen these branches divide into two ramusculi : the one anterior, very small, which
passed in front of the vertebral artery, and emerged upon the sides of the body of the
vertebra ; the other posterior, which passed between the corresponding nerve and the
artery, entered the spinal canal through the intervertebral foramen, and was distributed
to the vertebrae, and to the spinal cord and its membranes, in the same manner as the
dorsal and lumbar spinal arteries. The praevertebral branch of the ascending pharyn-
geal artery sometimes supphes the cervico-spinal branch of the first two intervertebrcd
spaces in the cervical region.
Terminal Branches. — Opposite the lower extremity of the lateral lobe of the thyroid
gland, the inferior thyroid artery divides into three branches : of these, one follows the
lower border of the gland, another passes to the posterior surface of its lateral lobe,
while the third dips between the gland and the trachea, runs along the lower border of
the cricoid cartilage, sometimes becomes superficial opposite the isthmus of the thyroid
body, and forms an anastomotic arch with its feUow of the opposite side, along the upper
margin of that isthmus.
The Supra-scapular Artery.
The superior or supra-scapular artery {transversus humeri, 5, fig. 204), destined for the
supra- and infra-spinous fossae, and which might also be denominated the cleido-supra-
scapular from its course, arises from the front of the sub-clavian below the inferior thy-
roid, and often by a common tmnk, either with the posterior scapular, or with the in-
ferior thyroid and posterior scapular united, forming what is then called the thyroid axis.
It is at first directed vertically downward, then bends horizontally outward, to run along
behind the clavicle and gain the upper border of the scapula, where it passes over, very
rarely under, the ligament, which converts the coracoid or supra-scapular notch into a
foramen, and, being reflected over that ligament, dips into the supra-spinous fossa, and
crossing the concave border of the spine of the scapula, enters the infra-spinous fossa,
in which situation it terminates {5', fig. 209).
Relations. — It is concealed at its origin by the stemo-mastoid muscle, and is then sit-
uated along the base of the supra-clavicular triangle ; it is in relation in front with the
clavicle, following the direction of that bone ; behind, with the sub-clavian artery and
the brachial plexus of nerves, which it crosses at right angles ; above, with the deep
fascia and the platysma myoides, which separate it from the skin ; and below, with the
sub-clavian vein : more externally, it dips under the trapezius, and comes in contact
with the supra-scapular nerve, is separated from it at the coracoid notch, and again be-
comes applied to it in the supra- and infra-spinous fossae, where it is situated between
the muscles of the bone.
Collateral Branches. — Among a great number of unnamed muscular and cutaneous
branches, I would particularly notice, 1. A small thoracic branch, which passes verti-
cally downward behind the clavicle, perforates the sub-clavius, and anastomoses with
the thoracic arteries. 2. A branch for the trapezius, which is so large that it appears to
result from the bifurcation of the artery. It generally arises at the point where the ves-
sel dips into the supra-spinous fossa ; at other times it comes off very near the origin of
the artery, passes from before backward, turns round the scaleni muscles parallel with
the posterior scapular artery, with which one might confound it, and ramifies in the tra-
pezius and the supra-spinatus muscles, entering the former at its under, and the latter at
its upper surface : some of the branches are distributed to the periosteum of the acromion
and to the corresponding integuments.
Again, in the supra- and infra-spinous fossae it gives off a great number of periosteal,
osseous, muscular, and articular branches. In the infra-spinous fossa (5, fig. 209), it
forms a free arched anastomosis with the sub-scapular artery, and gives off a branch
which runs along the axillary border of the scapula, and anastomoses with the posterior
scapular artery at the lower angle of that bone.
The Posterior Scapular Artery.
The posterior scapular {transversus cervicis, transvcrsalis colli, 6, fig. 204, 209) is larger
than the preceding, and extends from the sub-clavian to the vertebral border of the scap-
ula ; it arises from the front of the sub-clavian, sometimes to the inner side of the sea-
THE INTERNAL MAMMARY ARTERY. 639
leni, sometimes between them, but most commonly on the outer side of those muscles ;*
in the first case it often comes off by a common trunk with the inferior thyroid, and in
the two other cases by a common trunk with the supra-scapular. It passes transversely
and in a slightly tortuous manner outward, through the nerves of the brachial plexus,
and sometimes through the scalenus posticus, and curves backward towards the poste-
rior superior angle of the scapula. Then, opposite the levator anguli scapulae, it divides
into an ascending and a descending- branch. The ascending or cervical branch, the super-
Jicial cervical artery of authors, passes beneath the trapezius, and divides into a great
number of twigs, which ramify in that muscle, in the levator anguli scapulae, and in the
splenius. The descending branch forms the posterior scapular artery, properly so called
(a. Jig. 209), and may be regarded as the continuation of the vessel ; it turns round the
posterior superior angle of the scapula, beneath the levator Fig. 209.
anguli,. passes vertically downward along the vertebral bor- ^
der of that bone, and terminates at the inferior angle by an- , ^\
astomosing with the sub-scapular artery, a branch of the ax- , ^A
illary, and with the supra-scapular, already described. '^^^jS^^»— ^.^^
Relations. — It is superficial in the first part of its course, ••',:^^^^^^~^^^
during which it traverses the supra-clavicular triangle hor- -V>^^^^^^^
izontally, being merely covered by the cervical fascia, the '^^^^ib^W^tk
platysma myoides, and the omo-hyoid ; and hence, doubt- ^^^-■C/Wt^^^>\
less, the name superficial cervical, which has been given to -' v~T^^^^^^\
it by some authors. + It is but rarely that the posterior ' /-^•^^'P^^^^^w
scapular turns round the posterior scalenus and the brach- , ' / -s5^y^;J^W^w//^
ial plexus, without passing between the nerves of the plex- .^j!^yj/^ fms^mWli^w
us, which it traverses at variable heights. As it proceeds \ ' v^ it0^i^MJMj]r'
backward, it is protected by the trapezius ; and, lastly, ^- it'^^^^^^^oi-.JssJ
along the vertebral border of the scapula, it lies between the rhomboideus and the serra-
tus magnus
Its collateral branches are destined for the following muscles : the trapezius, sc£ilenus
posticus, levator anguU scapulae, splenius, supra- and infra-spinati, sub-scapularis, rhom-
boideus, and serratus magnus.
The Internal Mammary Artery.
The internal mammary, or internal thoracic artery, not so remarkable for its size,
which is less than that of the vertebral, as for its length and the number of its branches,
arises (7, fig. 204) from the sub-clavian opposite the inferior thyroid, and behind the supra-
scapular. Few arteries are less variable in their origin. The only varieties which have
been observed are those in which it arises from the brachio-cephalic, from the arch of
the aorta, or from a common trunk with the inferior thyroid. Immediately after its ori-
gin, it passes vertically doAvnward behind the inner end of the clavicle, enters the thorax,
crosses obliquely behind the cartilage of the first rib, and bends a little inward to run
along the first portion of the sternum, below which it resumes its vertical direction, par-
allel to the border of that bone, as low down as the sixth rib, where it divides into an
internal and an external branch.
Relations. — It is situated in front of the scalenus anticus, and is covered at its origin
by the phrenic nerve, which crosses it very obliquely, in order to reach its inner side ; it
corresponds to the inner end of the clavicle, from which it ie separated by the brachio-
cephalic vein ; it is then placed behind the costal cartilages and the intercostal muscles,
in front of the pleura, from which it is separated by the triangularis sterni. It is situa-
ted about two lines to the outer side of the margin of the sternum, so that a cutting in-
strument may be carried into the thorax along that bone without injuring the internal
mammary ; the name sub-sternal is, therefore, not at all appUcable to this artery, which
would be better named sub-chondro-costal.
Collateral Branches. — These are very numerous ; they may be divided into the poste-
rior, anterior, and external. The posterior branches are, the thymic or anterior mediastinals,
and, lower down, the superior phrenic, an extremely small artery, which runs along the
phrenic nerve, is situated, like it, between the pericardium and the corresponding layer
of the mediastinum, and reaches and is ramified in the diaphragm. Bichat has seen the
superior phrenic artery as large as the internal mammary itself.
The external branches are the anterior intercostals. Their number corresponds with
that of the intercostal spaces : they are small in the first two, and gradually increase or
diminish according to the length of the corresponding spaces. I have seen the common
trunk for the third intercostal space so large, that it appeared like a bifurcation of the
mammary. There are generally two branches for each intercostal space : one, which
runs along the lower margin of the rib above, and the other along the upper margin of
the rib below. These two branches sometimes arise separately from the mammary,
* In the last case, those authors who describe the sub-clavian as terminating between the scaleni, say that
the posterior scapular arises from the axillary artery,
t [It is the ascending- or cervical branch only that is named superficial cervical.]
540 ANGEIOLOGY.
sometimes by a common trunk ; as they arise above the level of the space for which
they are intended, it follows that they pass obliquely behind the costal cartilages. The
anterior intercostals inosculate with the aortic or posterior intercostals, so that it is
sometimes impossible to determine the limits between these two sets of vessels. In
some subjects they form a communicating arch of uniform caliber, extending between
the internal mammary and the thoracic aorta.
The anterior branches are superficial, and correspond in number to the intercostal spa-
ces ; they arise from the internal mammary, pass directly from behind forward, through
the corresponding intercostal space, and divide into cutaneous and muscular branches,
both of which sets curve outward, the muscular branches beneath the pectoralis major,
in which they ramify, and the cutaneous branches beneath the skin. Tlie anterior
branches of the first three spaces are distributed to the mammary gland. In females re-
cently delivered, and in nurses, these branches become extremely large, especially the
second, which I have seen as large as the radial artery, and very tortuous. Before per-
forating the intercostal muscles, the anterior branches send some periosteal twigs be-
hind the sternum, some of which penetrate the bone directly, while others ramify on
the periosteum.
Terminal Branches. — Of the two terminal branches, the internal, and smaller, contin-
ues the original course of the artery, passes behind the rectus abdominis muscle, enters
its sheath, and then divides into a great number of branches ; some of these are lost in
this muscle by anastomosing with the capillary divisions of the epigastric, while the oth-
ers emerge from the sheath of the rectus by special openings, and are distributed to the
broad muscles of the abdomen, and to the integuments. Before leaving the cartilage of
the seventh rib, it gives off a small twig, which passes inward upon the side of the en-
siform cartilage, and forms an anastomotic arch with its fellow of the opposite side, in
front of that cartilage. The anastomosis of this artery with the epigastric, which has
been known from the very earliest periods, and afforded the ancients an explanation of
the intimate physiological connexions between the genital organs and mammary glands,
is accomplished in the usual manner of capillary communication.
The external terminal branch, as far as distribution is concerned, is the continuation of
the internal mammary. It is directed downward and outward, behind the cartilages of
the seventh, eighth, ninth, tenth, and eleventh ribs, which it crosses obhquely, and ter-
minates opposite the last intercostal space. During its course, it gives off the anterior
intercostals of the corresponding spaces, two for each space, sometimes only one, which
immediately subdivides. These intercostals diminish gradually in size as the spaces
decrease in length, and are distributed precisely as the anterior intercostal branches of
the internal mammary itself The external terminal branch, and also the internal, while
passing through the diaphragm near its costal attachments, give off a great number of
branches to that muscle, and hence the name musculo-phrenic, given by Haller to the
external division, which, indeed, furnishes many more branches to the diaphragm than
the internal.
The Deep Cervical Artery.
Dissection. — Seek at first for the artery behind the scalenus anticus, between the
transverse process of the seventh cervical vertebra and the first rib ; trace it, both to its
termination, between the complexus and semi-spinalis colli, and towards its origin, with-
in the scaleni.
The posterior, or deep cervical, comes off deeply from the upper and back part of the
sub-clavian, on the same plane as the vertebral, to the outside of which it is situated.
Very often it arises by a common trunk with the first intercostal. It passes at first up-
ward and backward, then bends outward behind the scalenus anticus to dip between the
transverse process of the seventh cervical vertebra and the first rib. I have never seen
it pass between the transverse processes of the sixth and seventh cervical vertebrae,
though for this purpose I have examined forty subjects.*
After leaving the inter-transverse space, the deep cervical artery divides into two
branches : one descending, which I have been able to trace as far as the middle of the
dorsal region, between the long muscles of the back ; the other ascending, which passes
up between the complexus and the semi-spinalis colli, in which it terminates, and anas-
tomoses with the occipital and vertebral arteries.
The Superior Intercostal Arteries.
Dissection. — This artery can only be dissected from the internal surface of the thorax.
For this purpose it is necessary to saw through the thorax vertically. The artery must
be exposed by removing the pleura from the two upper ribs and intercostal muscles.
* This relation is so constant, that, even in cases where there is a supernumerary cervical rib, the deep
cervical artery passes betwreen this supernumerary rib and the first dorsal rib. Some students having called
me to examine a subject in which this artery was wanting, I sought in vain for it between the first rib and
the transverse process of the last cervical vertebra, and then perceived that there was a cervical rib, between
which and the first dorsal rib the artery was found.
[In 264 observations, Professor Quain met with this variety in the course of the artery four times, and also
other peculiarities.]
THE AXILLABY ARTERY.
The superior intercostal artery, intended for the two or three superior intercostal spa-
ces, sometimes only for the first, varies in size according to the extent of its distribu-
tion. It comes off from the lower and back part of the sub-clavian, near the deep cer-
vical, and sometimes by a common trunK with it. It descends, m a tortuous manner, m
front of the neck of the first, and then of t'ne second rib, on the outside of the first dorsal
ganglion of the sympathetic nerve, and terminates in the second intercostal space, like
an aortic intercostal artery ; sometimes it anastomoses freely with the first of the aortic
intercostals. It gives off in each space a dorso-spirud branch, and an intercostal branch,
properly so called. It is not rare to find the intercostal branch wanting in the first space :
in all cases it is extremely small.
The Axillaky Artery.
Dissection. — In order to prepare the axillary, as well as all the other arteries of the
upper extremity, it is sufficient to dissect the muscles
carefully, at the same time preserving aU the branches
which are met with, and tracing them to their origin.
The axillary artery {a a', fig. 210) is that part of the
artery of the upper extremity which intervenes be-
tween the sub-clavian and the brachial. Its limits,
which are entirely artificial, are the clavicle,* on the
onp hand, and the lower border of the pectoralis major
on the other. It traverses the axilla diagonally, and
bends opposite the neck of the humerus, so as to be-
come continuous with the brachial artery. Its upper
part rests upon the thorax, and its lower upon the hu-
merus ; it is not very tortuous, so that in forcible ab-
duction of the arm it may be stretched even to lacera-
tion. Its direction corresponds pretty nearly with the
cellular interval so generally existing between the
sternal and the clavicular portions of the pectoralis
major, or, rather, with an imaginary line, extending
from the junction of the outer with the two inner thirds
of the clavicle to the inner side of the neck of the hu-
merus.
Relations. — From the importance necessarily attach-
ed to an accurate knowledge of the relations of this ar-
tery, we shall consider them in the four aspects of the
vessel.
In front, the axillary artery is in relation from above
downward with the sub-clavius muscle, a process of
the deep cervical fascia intervening between them ;
then with the costo-coracoid ligament and the pecto-
ralis major ; next with the pectoralis minor ; below
this muscle, with the pectoralis major again ; and, last-
ly, with the coraco-brachialis. In a subject where the
pectoralis major had no clavicular insertions, that por-
tion of the axillary artery which is intermediate be-
tween the clavicle and the superior border of the pec-
toralis minor, was separated from the skin only by the
platysma myoides. Behind, it is in relation with the
cellular interval between the sub-scapularis and serra-
tus magnus ; lower down, with the teres major and
latissimus dorsi. On the inside, it rests at first upon
the first rib and the first intercostal space ; it next
leaves the thorax, from which it is separated by the
hollow of the armpit, and its inner side is then in re-
lation with the skin which forms the outer wall of the
armpit, and with the subjacent fascia. On the outside,
it is at first embraced by the concave surface of the
coracoid process, and it is then placed opposite the head of the humerus, from which it
is separated by the sub-scapularis muscle
Relations with the Axillary Vein and Nerves. — Immediately below the clavicle, tne axdlary
vein is situated on the inner side of, and at some distance from, the artery ; lower down,
the vein lies upon the artery. The cephahc and acromial veins pass in front of the artery.
Immediately below the clavicle, the entire brachial plexus is situated on the outer side
* Those authors who consider the sub-clavian as terminating between the scaleni, describe the axillary aa
commencing at the same point
[The axillary artery is commonly said, in this country, to commence at the lower border of the first rib (a),
and to terminate at the lower border of the conjoined tendons (a') of the latissimus dorsi and teres major
muscles.]
542 ' ^ ANGEIOLOGY.
of the artery, only one thoracic nerve crossing in front of it. Under the pectoralis minor
the artery is surrounded by the plexus ; it is at first embraced by the external and inter-
nal roots of the median nerve, which meet in the form of a V opening upward ; lower
down, it is placed between the external cutaneous nerve on the outer side, the median
in front, the internal cutaneous and the ulnar on its inner side, and the radial, or muscu-
lo-spiral, and the circumflex behind. In order to expose the artery in the axilla, the ves-
sel may be sought for between the median and ulnar nerves.
In consequence of these relations, wounds of the axilla may be very serious ; com-
pression may be applied to the axillary artery, either by forcibly depressing the clavicle
against the first intercostal space and second rib, or by placing the finger upon the ves-
sel in the axilla, and pressing it against the head of the humerus ; a ligature may be ap-
plied to this artery, either under the clavicle above the pectoralis minor, or in the axilla ;
lastly, the artery may be torn from extreme violence in attempting to reduce a dislocation.*
Collateral Branches. — The axillary gives off five branches, viz., the acromio-thoracic,
alpove the pectoralis minor ; the inferior thoracic, or external mammary, below the pecto-
ralis minor ; the inferior scapular, and the anterior and posterior circumflex arteries, op-
posite the neck of the humerus.
The Acromial and Superior Thoracic Arteries.
Under the name of acromio-thoracic I include two arteries, the acromial and the supe-
rior thoracic, which almost always arise by a common trunk, which is detached at right
angles from the inner side of the axillary artery immediately above the pectoralis minor,
then crosses the upper border of that muscle at right angles, and immediately divides
into the two above-named branches.
The thoracic branch passes downward and inward, and subdivides {b b) between the two
pectoral muscles, both of which it supplies, but especially the lesser. Some branches
perforate the pectoralis major, and are distributed to the skin and the mamma.
The acromial branch subdivides into two others : a descending or deltoid branch (c),
which enters the cellular interval between the pectoralis major and the deltoid, traverses
it throughout, and is distributed to these two muscles, but especially to the deltoid ; it
is accompanied by the cephalic vein : the second is a transverse or acromial branch {d),
which runs horizontally outward, passes over the apex, and sometimes over the base of
the coracoid process, then upon the coraco-acromial ligament, and runs along the outer
third of the anterior border of the clavicle. It is covered in the whole of its course by
the deltoid, to which it is in a great measure distributed. Some twigs terminate in the
skin over the acromion. This acromial branch terminates near the acromio-claviculax
articulation : sometimes one of its divisions closely follows the anterior border of the
clavicle.
The Inferior or Long Thoracic Artery.
The inferior thoracic, long thoracic, or external mammary artery (e, fig. 210), is much lar-
ger than the acromial thoracic, and sometimes arises by a common trunk with it or with
the sub-scapular ; it is given off from the axillary below the pectoralis minor, passes
downward and forward upon the side of the thorax, between the pectoralis major and
serratus magnus, then between the serratus and the skin, and terminates at about the
sixth intercostal space. During this course it gives off a great number of branchest to
the lymphatic glands in the axilla, to the sub-scapularis, pectoralis major, and serratus
magnus muscles, to the second, third, fourth, fifth, and sixth 'intercostal spaces, to the
mamma, and to the skin. Not unfrequently the inferior thoracic partially supplies the
place of the sub-scapular artery, in which case it is as large as that vessel.
The Sub-scapular Artery.
The inferior, common, or sub-scapular artery (/), the largest branch of the axillary,
arises near the lower part of the head of the humerus opposite the lower border of the
sub-scapular muscle, sometimes by itself, sometimes by a common trunk with the poste-
rior circumflex, the long thoracic, or the deep humeral artery ; in the last case it is as
large as, perhaps even larger than, the brachial. At its origin, which is from the outer
aspect of the axillary, it has the musculo-spiral nerve to its inner side, and the principal
orig;in of the median on its outer side ; it passes in a tortuous manner downward and out-
ward along the lower border of the sub-scapularis muscle, parallel with the teres major,
and beneath the head of the humerus,^ furnishes large branches to all these muscles,
and having arrived below the insertion of the sub-scapularis, divides into two branches,
a descending or thoracic, and a scapular, properly so called.
* I hare seen two cases of rupture of the axillary artery from attempts to reduce old dislocations.
t [These branches represent the alar thoracic artery, and sometimes arise directly from the axillary, behind
the pectoralis minor, or from the sub-scapular.]
t The relation of the sub-scapular artery to the head of the humerus appears to me to be important. In
abduction thi« artery is much stretched, and I am surprised that it has not been torn in same cases of luxation ;
on the contrary, the circumflex artery, and, therefore, the circumflex nerve, appear to me to be much less lia
ble to be stretched during abduction. Nevertheless, it is certain that the circumflex nerve has been lacerated
in some dislocations of the humerus, because they have been followed by paralysis of the deltoid muscle.
THE BRACHIAL ARTERY. 543
The descending or thoracic branch (g), which is often given off by the inferior or long
thoracic, passes downward and forward near the axillary border of the scapula, parallel
with and behind the long thoracic, and divides into a great number of large branches,
some of which enter the latissimus dorsi, several penetrate the serratus magnuseven as
far as the lowest portion of that muscle, while others turn round the lower angle of the
scapula, and anastomose with the following or scapular branch, and with the posterior
scapular derived from the sub-clavian.
The scapular branch (i), properly so called, proceeds along the lower border of the sub-
scapularis muscle, in front of the long head of the triceps, and having reached below the
scapular attachment of the triceps, divides into three branches : an anterior or sub-scapu-
lar branch, which dips into the sub-scapular fossa below the muscle, and expands into a
great number of branches, the highest of which are distributed to the capsule of the
shoulder-joint ; an infra-spinous branch (Jb,fig. 209), which turns round the axillary border
of the scapula, runs between the muscle and the infra-spinous fossa, and anastomoses,
by a considerable branch, with the termination of the supra-scapular artery ; a median
branch (c,fig. 209), which continues in the original course of the vessel, runs along the
axillary border of the scapula, between the teres major and minor, then becomes poste-
rior, and terminates by anastomosing again upon the lower angle of the scapula with the
thoracic branch of this artery, and with the infra-spinous branches of the supra-scapular.
The Posterior Circumflex Artery.
The posterior circumflex artery (Z, fig. 210) arises from the back of the axillary opposite
the sub-scapular, which it sometimes equals in size. It passes horizontally backward,
between the sub-scapularis above and the teres major below, turns inward round the
surgical neck of the humerus, passing first between the internal head of the triceps and
the teres minor, then between the long head of the triceps and the bone, and finally (Jl,fig.
209) under the deltoid, to the deep surface of which it is applied ; it always turns round
so as to describe three fourths of a circle, and thus reaches the anterior and outer aspect
of the humerus, and is lost in the deltoid by anastomosing with the deltoid branches of
the acromio-thoracic artery. In the whole of its course it is accompanied by the cir-
cumflex vein and the circumflex nerve. As it turns round the bone, the posterior cir-
cumflex gives off some articular and periosteal branches, which pass to the capsular lig-
ament of the shoulder-joint, and to the periosteum of the humerus.
The Anterior Circumjlex Artery.
The anterior circumflex, a small artery {n,fig. 210), sometimes represented by several
branches, arises from the axillary in front of the posterior circumflex, and often by a
common trunk with it. It passes horizontally outward above the conjoined tendons of
the latissimus dorsi and teres major, covered by the coraco-brachialis and the short head
of the biceps, runs beneath the tendon of the long head of the biceps, turns round the
neck of the humerus, crosses the bicipital groove at right angles, being held down by
the synovial membrane, and divides into an ascending and a descending branch. The
Jatter presents nothing remarkable ; but the ascending branch, having reached the up-
per part of the groove, anastomoses with the osseous branch of the acromial artery,
and is lost in the head of the humerus, which it penetrates at one or more points. The
anterior circumflex is, therefore, intended for the humerus, its periosteum, and the syno-
vial membrane of the groove. Sometimes there are several anterior circumflex arteries,
which enter the substance of the deltoid muscle.
The Brachial Akteky.
The brachial or humeral artery (a' h,fig. 210) is that portion of the artery of the upper
extremity which extends from the lower border of the axilla to the point of its bifurca-
tion at the upper part of the forearm. It passes downward, and a little forward and
outward, so that it is situated on the inner side of the humerus above, and in front of it
below. The absence of any bendings in this artery explains the possibility of its being
torn from extreme extension of the forearm in dislocations of the elbow, &c.*
The relations of the brachial artery require to be examined separately along the arm,
and in front of the elbow-joint.
Along the arm, the artery is in relation, in front, with the coraco-brachialis and the in-
ner margin of the biceps, which may be regarded as the satellite muscle of the artery :
in emaciated subjects the biceps does not cover the artery, which is then situated im-
mediately under the fascia ; behind, it is in relation with the triceps, and then with the
brachialis anticus ; on the inner side, with the fascia of the arm, which separates it from
the skin ; on the outer side, with the coraco-brachialis, then with the inner side of the hu-
merus, from which it is separated by the tendon of the coraco-brachialis, and in the rest
of its extent with the cellular interval between the biceps and the brachialis anticus.
The brachial artery is enclosed in a fibrous sheath, which is common to it and the me-
* In old subjects, the humeral artery is almost always tortuous, and sometimes these windings are so re-
markable that the artery is sub-aponeurotic during a portion of its course.
6)44 ANGEIOLOGY.
dian nerve. The following are its relations with the veins and nerves : the principal
brachial vein is situated on its inner side ; another smaller vein is on its outer side :
both are in contact with the artery, which they separate from the nerves, and they are
connected by several transverse branches, which embrace the artery.
The median nerve is situated in front of the artery, excepting above, where it is on
its outer side, and below, near the elbow, where it passes to its inner side ; the median
nerve sometimes crosses behind the artery.* The ulnar nerve is placed on the inner
side of the artery above, then passes behind it, and is lodged in a separate sheath. The
musculo-spiral nerve is situated, together with the deep humeral artery, at first behind
the brachial, but soon leaves it to turn round the humerus ; lastly, the internal cutane-
ous follows the same course as the vessel, crossing it slightly from before backward.
From these relations, it follows that the vessel may be most eificaciously compressed
from within outward, against the inner surface of the humerus, and also that it may be
tied in any part of its course.
At the bend of the elbow, the brachial artery occupies the middle of the articulation ; it
is superficial in front, where it is only separated from the skin by the fascia and tendi-
nous expansion of the biceps, and by the median basilic vein, which crosses it at a very
acute angle ; behind, it rests upon the brachialis anticus, by which it is separated from
the elbow-joint ; on its inner side is the median nerve and pronator teres muscle, and,
on its outside, the tendon of the biceps, over which it soon crosses, and, farther outward,
the supinator longus.
In consequence of the superficial position of the brachial artery at the bend of the el-
bow, and from its relations with the median basilic vein and the elbow-joint, it follows
that this artery may be easily compressed, may be wounded in the operation of vene-
section, and may be lacerated in dislocations of the joint, t
Collateral Branches. — These may be divided into the external and anterior, and the inter-
nal and posterior.
The external and anterior are very numerous, and are intended for the coraco-brachia-
lis and biceps, which they penetrate at different heights, and also for the brachialis an-
ticus. A very remarkable branch, which appears to me to be constant, viz., the deltoid,
passes transversely in front of the humerus, beneath the coraco-brachialis and the biceps,
and terminates partly in the deltoid at its humeral insertion, and partly in the brachialis
anticus. The internal and posterior branches are small, excepting those which enter the
brachialis anticus directly : I have seen them all arise from the axillary by a large branch
given off from a common trunk with the sub-scapular and the posterior circumflex arteries.
Whatever may be their mode of origin, four of these collateral branches are remark-
able for their regular distribution, viz., the deep humeral, the internal collateral, the super-
ficial branch for the internal portion of the triceps, and the superficial branch for the brachi-
alis anticus. The two former only have received particular names.
The deep humeral artery {profunda superior, k, fig. 210), called aJso the external collateral,
from its terminating on the outer side of the articulation of the elbow, arises from the
brachial, opposite the lower border of the teres major. It occasionally comes off by
a common trunk with the posterior circumflex, which, in that case, arises from the
brachial instead of the axillary artery. It passes downward and backward, gains the
groove for the musculo-spiral nerve, and traverses the whole extent of that groove to-
gether with the nerve. In this part of its course it is situated between the triceps mus-
cle and the humerus, as it turns round the posterior surface of that bone ; below the in-
sertion of the deltoid it emerges from the groove, between the brachialis anticus and the
triceps, and divides into a deep branch, which continues with the nerve, and a superficial
branch. The former is distributed essentially to the triceps muscle, and sometimes
comes off directly from the brachied ; it passes vertically downward in the substance
of the triceps, supplies its internal and external portions, and terminates in them by
anastomosing freely with the collateral branches situated around the elbow-joint. The
superficial branch perforates the external head of the triceps, and the external inter-mus-
cular septum, along which it descends vertically to the back of the epicondyle, or external
condyle of the humerus, where it anastomoses with the interosseous recurrent artery.
The internal or ulnar collateral artery {profunda inferior, m, figs. 210, 211) is much
smaller than the external collateral, from which it is sometimes derived ; it is often
double. It usually arises at a variable height from the lower part of the brachial, some-
times passes transversely inward, and sometimes proceeds in a tortuous manner down-
ward before becoming transverse, and then divides into two branches : one anterior, which
is distributed to the brachialis anticus, the muscles attached to the epitrochlea or internal
condyle of the humerus, and the periosteum upon that process ; the other posterior, which
perforates the internal intermuscular septum, and divides into muscular branches for the
* Dubreuil has seen that arrangement in three cases ; and M. Chassignac has met with it twice last winter.
t I have seen this artery lacerated in a case of luxation forward of the humerus on the forearm, in conse-
quence of a fall from a horse upon the wrist. The lower extremity of the humerus had torn the brachialis
anticus, the artery and the skin through which it had passed. A hemorrhage, followed by syncope, took
place at the moment of the accident. The patient having been carried to her residence in this swoon, the
reduction was accomjdished, the hemorrhage did not return, and the cure was as perfect as possible.
THE BRACHIAL AATEEY. 545
triceps ; into periosteal and osseous branches, which pass transversely in front of the
triceps, and anastomose with the interosseous recurrent ; and into a descending branch,
which accompanies the ulnar nerve, and anastomoses with the posterior ulnar recurrent.
The superficial branch for the internal portion of the triceps is remarkable for its size and
length ; it arises from the brachial, inunediately below the profunda superior, from which
also it is rather frequently derived, and passes vertically downward applied to the idnar
nerve. It is at first situated in front of the internal intermuscular septum, then perfo-
rates it, accompanied by the idnar nerve, and, passing backward between the epitrochlea
and the olecranon, aneistomoses with the posterior ulnar recurrent.
The superficial branch for the braehialis anticus arises from the brachial artery at the
same height as the preceding, runs along the inner side of the braehialis anticus, grad-
ually diminishing in size down to the lower part of the arm, where it anastomoses with
the internal collateral artery.*
The terminal branches of the brachial are the radial (jp,figs. 210, 211) and ulnar (g) ar-
teries. The bifurcation of the brachial artery into the radial and ulnar usually takes
place below the bend of the elbow, sometimes on a level with it, but rather frequently
above the articular line ; in the latter case, the bifurcation has been observed to occur
sometimes at the lower third or at the middle of the arm, sometimes at the junction of
the upper with the two lower thirds, and sometimes in the axilla itself, the radial and
ulnar arteries immediately succeeding to the axillary. In these cases, one division of
the artery, generally the radial, is sub-cutaneous, while the ulnar assumes the ordinary
relations of the brachial ; but the reverse of this may take place ; and, lastly, the radial
and the ulnar have both been found sub-cutaneous. Not unfrequently, the radial artery,
at its origin, is the inner branch of the bifurcation, and then crosses the ulnar at a very
acute angle, in order to reach the radius. Besides these anomalies resulting from va-
rieties in the point of bifurcation, there is yet another, in which a premature division takes
place into two branches, one of which forms the interosseous artery, and the other the
brachial, which has its usual arrangements ; at other times, instead of a bifurcation,
only a very slender branch is given off, and terminates in the ulnar, which in that case
arises by two roots.
The frequency of high divisions of the humeral artery require that the practical con-
siderations to which these give rise should be taught. If, therefore, a hemorrhage by
the arteries of the forearm should not yield to a ligature of the humeral artery, we should,
with M. Danyau, suspect the high division of the humeral artery, and search for the
other branch.
Here follows the minute description of three rare varieties which I have exhibited at
the Anatomical Society. From the inferior part of the axillary artery arose a slender ar-
tery, which first coursed all along the humeral artery, on the inside of which it was situ-
ated ; it then crossed this vessel by passing before it at the union of the two superior with
the inferior third of the arm, and finally joined the radial artery opposite the bicipital tu-
berosity of the radius.
At the bend of the elbow, this artery, which might be considered as a slender branch
of origin of the radial artery, occupied the same relations as the humeral artery, and
was situated below the aponeurotic expansion of the biceps, while the trunk of the hu-
meral artery was not placed under this expansion, but below the tendon of the biceps.
It was behind this tendon, a little above its insertion into the radius, that the humeral
artery was divided into radial and ulnar ; the radial, instead of coursing directly down-
ward, described a curve with the concavity inward ; and it was with the lower part of
this curve that the long and feeble branch coming from the axillary artery united.
I have met, again, a similar anomaly, with this difference, that the long and slender
arterial branch, instead of going to the radial, anastomosed with the ulnar. This variety
may be considered as a mode of anastomosis between the upper and the lower part of
an arterial trunk, a mode of anastomosis by a collateral canal, unusual in the arterial, but
very frequent in the venous system.
In a case where one of the branches of the high division was the interosseous artery,
and the other the common trunk of the radial and ulnar arteries, the respective relations
of these vessels were as follows :
The humeral dichotomic division took place below the hollow of the axilla. One of
the branches was the common trunk of the interosseous arteries, which first followed
the usual course of the humeral artery, then crossed, at a very acute angle, the other
branch by passing behind it, coursed obliquely downward and outward, and finally reach-
ed the external border of the tendon of the biceps. Having been sub-aponeurotic so far,
it now dipped under the pronator teres, gave off the radial and ulnar recurrent branches.
iQd terminated as the interosseous arteries terminate.
ITie other branch constituted the common trunk of the radial and cubital arteries ;
* [These two superficial braaches are frequently represented in their distributioo by a sing-le branch, nailed
the anastomotic artery (u,figs. 210, 211), which arises from the brachial, about two inches above the elbow.
The nutritious artery of the humerus is small, but constant : it as-ises from the outer side of the brachial, or
one of its collateral branches, passes downward, perforates the insertion of the coraco-lwachialis muscle, and
enters the oblique foramen in the inner side of the humerus, to ramify in the aicduilary c«nal of that bone 1
Z 2 Z
546 AN6EI0L06T.
sub- aponeurotic, like the preceding, it reached the anterior side of the epitrochlea, and
divided into two secondary branches : one internal, which was the ulnar, a little tortu-
ous, coursed downward as far as the annular carpal ligament ; the other external, which
was the radial, passed obliquely downward and outward as far as the radial insertion of
the pronator teres, when it became vertical. During their whole course, the radial and
ulnar arteries were sub-aponeurotic.
I have been on the point of opening the radial artery at the bend of the arm, in a
case where it lay over the superficial tendon of the biceps.*
A knowledge of these anomahes, both in reference to the point of bifurcation and to
the new relations of the parts, is extremely important to the surgeon.
The Radial Artery and its Branches.
Dissection. — The radial artery in the forearm is completely exposed by dissecting the
supinator longus ; the carpal portion of the artery by dissecting the tendons of the
thumb opposite the vnrist ; the palmar portion by dividing all the flexor tendons in the
palm. It is, therefore, advisable to postpone the examination of the palmar portion of
the artery until the ulnar has been studied.
The raAial artery (j),figs. 210, 211), the outer of the two branches into which the brach
ial divides, is more superficial and smaller than the ulnar ; it extends from the point
of bifurcation of the brachial down to the peilm of the hand. Sometimes the radial turns
backward, after having reached the lower third of the forearm, and remains sub-cutane-
ous until it dips between the first and second metacarpal bones ; its place in front of the
lower part of the radius is then supplied by the radio-palmar artery or superficialis volaj,
which is extremely small. It is very common to find the radial artery of one arm larger
than that of the other ; in one case I found both radials wanting in front of the lower
part of the radius.
Tlie radial artery is at first directed downward, and somewhat obliquely outward, like
the brachial, with the direction of which it corresponds ; it then descends vertically as
far as the lower end of the radius, turns round the anterior surface and apex of the sty-
loid process, to gain the outer side of the carpus, and passes obliquely downward and
backward, to reach the upper part of the first interosseous space ; there it turns abrupt-
ly forward, between the upper extremities of the first and second metacarpal bones,
passing between the two origins of the first dorsal interosseous muscle, enters the palm
of the hand, and runs almost transversely inward, to form the deep palmar arch {b, Jig.
211). The radial artery is frequently tortuous at the lower part of the forearm. From
the long course and the direction of the radied, it may be divided into three portions,
corresponding to the forearm, the wrist, and the palm of the hand.
The first jiortion of the radial artery, viz., that situated in the forearm, has the following re-
lations : In front, with the inner border of the supinator longus, which overlaps it, especial-
ly above ; in the rest of its extent it lies beneath the fascia. In emaciated subjects the su-
pinator longus is narrow, and this part of the artery is sub-aponeurotic in its whole extent.
Behind, it corresponds to the anterior surface of the radius, from which it is separated
above by the supinator brevis ; lower down by the pronator teres, and by the radial ori-
gins of the flexor sublimis and flexor longus poUicis ; still lower by the pronator quadra-
tus, below which it rests directly upon the inferior portion of the radius. The superficial
position of the radial artery, and the support afforded it by the bone, are the reasons
why it is chosen for examining the pulse.
On the inner side, it is in relation with the pronator teres, then with the tendon of the
flexor carpi radialis, along which it runs, and which is on a plane anterior to it ; so that
the contraction of this muscle, by causing its tendon to project, renders the pulsations
of the vessel more difficult to be felt.
On the outer side, it is in relation with the supinator longus, and in the middle part of
its course with the radial nerve (the continuation of the musculo-spiral), which is situ-
ated at some distance from it, both above and below, and has a separate fibrous sheath.
Of the collateral branches of the radial artery in the forearm, only three require a special
description, viz., the anterior radial recurrent, the anterior carpal branch, and the radio-
palmar artery.
The anterior radial recurrent artery {r,figs. 210, 211) is given off from the back part,
and immediately below the origin of the radial. It is very large in some subjects, in-
deed as large as the radial itself : it descends a little, and then turning upward, so as to
describe a curve with its convexity directed downward, it ascends between the supina-
tor longus and the brachialis anticus, in order to anastomose with that part of the pro-
* The editor, engaged as he has been, for thirty years, in teaching anatomy, has had very extensive oppor-
tunities of observing varieties in the origins of the radial and ulnar arteries ; and as the result of these, he
would state as a general rule, liable to very few exceptions, 1st. When the radial arises prematurely, it pass-
es, like the humeral, under the aponeurotic expansion of the biceps muscle.
2d. When the ulnar arises above the elbow, it passes superficially above this aponeurosis, being placed sub-
cutaneous in connexion with th« veins.
The editor believes, that in the majority of cases where an artery is wounded in performing the operation of
jloodletting at the bend of the arm, the vessel injured is the ulnar, which has arisen prematurely. In several
cases where he has been called on to operate for aneurism produced by this accident, he has found this to he
the case.
THE RADIAL ARTERY. 549
fimda superior which forms the external collateral branch of the elbow. I have seen
this recurrent artery arise from the ulnar.
From the convexity of the arch described by the radial recurrent, a great number of
branches proceed obliquely downward and outward, and are distributed to all the raus
cles on the external aspect of the forearm, viz., the long and short supinators, and the
two radial extensors. One of these branches passes transversely between the long supi-
nator and the long radial extensor, to anastomose on the outer condyle with the profun-
da artery ; others pass between the radius and the muscles attached to it, ramifying in
the extensor muscles of the forearm, and anastomose with the posterior interosseous
artery derived from the ulnar.
The anterior carpal branch of the radial artery is a small branch {a, fig. 211) which
passes transversely inward at the lower margin of the pronator quadratus muscle, and
anastomoses with a similar branch from the ulnar artery.
The radio-palmar or superficial palmar artery {superficialis voIcf,, s, fig. 210) arises at an
acute angle from the inner side of the radial, at the point where that vessel turns out-
ward to pass over the carpus. Sometimes its origin is situated at the junction of the
lower with the two upper thirds of the forearm. It varies much in its size and distribu-
tion ; most commonly it passes vertically downward, on a level with the anterior liga-
ment of the carpus, perforates the origin of the short abductor of the thumb, and anasto-
moses with the extremity of the superficial palmar arch {t) of the ulnar (g). Several
branches arise from its convexity, and are distributed to the muscles and integuments
of the ball of the thumb. The radio-palmar branch is frequently very small, is entirely
lost in those muscles, and does not assist in the formation of the superficial palmar arch.
On the contrary, it is often so large that it may be regarded as formed by the bifurcation
of the radial, and then assists as much as the ulnar in forming the superficial palmar
arch. In some cases in which the superficial palmar arch did not exist, I have seen the
radio-palmar give origin to the internal collateral artery of the thumb, both collateral ar-
teries of the index, and the external collateral of the middle finger, the ulnar artery fur-
nishing the collaterals of the other fingers. In one case, a transverse branch, resembling
the anterior communicating artery of the brain, formed the anastomosis between the ra-
dio-palmar and the ulnar arteries.
The second or carpal portion of the radial artery extends from the styloid process of the
radius to the upper part of the first interosseous space. Closely applied to the ligaments
and bones of the carpus, it passes at first obliquely downward and inward, and then be-
comes vertical as it dips into the interosseous space, to pass between the two heads of
the first dorsal interosseous muscle. It is well protected on the outer side of the carpus
by the projecting tendons of the two extensors and the long abductor of the thumb, edl
of which cross it obliquely, and separate it from the skin ; but between the tendons of
the long abductor of the thumb and the long radial extensor it becomes sub-aponeurotic,
and therefore very superficial. In this short course it gives off several branches.
The dorsal carpal branch of the radial artery, more remarkable for its constancy and
the mode of its distribution than for its size, which is inconsiderable, arises opposite the
articulation of the two rows of carpal bones, passes transversely inward, and terminates
either by being lost in the adjacent parts, or by anastomosing with the corresponding
branch of the ulnar artery. From the arch thus formed proceed certain ascending branch-
es, which anastomose with twigs from the anterior interosseous artery, sometimes ap-
pearing to form the termination of that vessel, which, as we shall presently describe, be-
comes posterior at the lower part of the forearm ; and also some descending branches, of
very variable size, which, having reached the upper part of the third and fourth interos-
seous spaces in peirticular, anastomose with the perforating branches of the deep palmar
arch, and form ope of the origins of the small twigs, which are named the dorsal interos-
seous arteries of those spaces.
The dorsal interosseous branch for the second space, known also as the dorsal metacarpal
branch of the radial artery, is sometimes so large that it seems to be a continuation of
the radial, and at other times very small, and, as it were, a mere vestige. It often ari-
ses by a common trunk with the dorsal carpal branch just described ; it runs along the
dorsal surface of the second interosseous space, and, having reached the lower part of
it, gives superficial dorsal arteries to the index and middle fingers, and then bends for
ward between the heads of the second and third metacarpal bones, to anastomose witli
that digital branch of the superficial palmar arch which gives off the internal collateral
artery of the index, and the external collateral artery of the middle finger.*
The interosseous artery of the first space is so large that it is described as formed by the
bifurcation of the radial : it arises from that artery between the first and second meta-
carpal bonesj and sometimes runs along the dorsal aspect of the first interosseous space,
and at others between the first dorsal interosseous muscle and the adductor poUicis ; in
* [Three small branches, two of which usually arise by a common trunk, are given off from the radial ar-
tery near the dorsal aspect of the head of the first metacarpal bone ; two of them form the superficial dorsal
arteries of the two sides of the thumb {dorsales pollids), while the other is the dorsal artery of the radial side
•f the indtx finger {dorsahs indicis).'i
$4^ AN6ET0LO6Y.
«ther case, when it reaches the lower part of the space, it divides into two branches,
which may arise separately from the carpal portion of the radial artery, as in^^. 211,
and which constitute the internal collateral artery of the thumb and the external collateral
artery of the index finger (x). The external collateral artery of the thumb, sometimes deri-
ved from the preceding, or even from the extremity of the superficial palmar arch, cross-
es the muscles of the ball of the thumb obliquely, to reach the outer side of its metacar-
po-phalangal articulation (v,fig. 210), and runs along the outer border of the thumb.*
The Deep Palmar Arch.
The third or 'palmar portion of the radial artery constitutes the dee'p palmar arch (i, fig.
211), which is completed by inosculating with a branch of the ulnar, in the same man-
ner as we have seen the superficial palmar arch of the ulnar artery completed by a branch
of the radial. This arch is situated deeply across the front of the metacarpal bones, im-
mediately below their upper extremities ; it rests immediately upon them and the inter-
osseous muscles, and is therefore subjacent to all the nerves, tendons, and muscles (ex-
cept the interosseous) in the palm of the hand. The deep palmar arch describes a slight
curve, the convexity of which is directed downward. I have seen the palmar arch form-
ed by the dorsal artery of the second interosseous space, which then dipped between the
upper ends of the second and third metacarpal bones.
The deep palmar arch gives off very short superior or ascending branches {recurrentes),
which are lost in front of the carpus, anastomosing with the anterior carpal branches of
the radial and ulnar arteries ; also some descending or palmar interosseous arteries (d d,
interosseae volares, Holler), three or four in number, which descend vertically along the
interosseous spaces, and anastomose with the descending digital branches (cut across in
fig. 211) of the superficial palmar arch, either opposite or above their bifurcation into
the collateral arteries of the fingers. The size of the palmar interosseous arteries is ex-
tremely variable, as well as that of the deep palmar arch itself; it bears an inverse pro-
portion to that of the superficial palmar arch and its branches. The relative size of the
difierent palmar interosseous arteries, also, varies much ; most generally the first is the
largest, at other times the second, and occasionally the third.
The deep palmar arch also gives off the posterior or perforating branches (c c). These
are three in number, and form for the second, third, and fourth interosseous spaces what
the radial itself is for the first, with this difference, that the radial perforates the first
space from behind forward, while these perforating branches traverse the corresponding
spaces from before backward. They arise from behind the deep palmar arch, and imme-
diately perforate the upper part of the interosseous spaces in a straight line, and having
reached the dorsal aspect of the hand, generally anastomose with the corresponding dor-
sal interosseous arteries, which, in a great number of cases, are formed entirely by these
perforating branches. In some subjects, the dorsal interosseous arteries result from the
anastomoses of the perforating arteries with the interosseous arteries derived from the
dorsal carpal arch formed by the dorsal carpal branches of the radial and ulnar arteries ;
they pass vertically downward on the dorsal surface of the interosseous spaces, and hav-
ing reached their lower parts, anastomose with the descending digital branches of the
superficial palmar arch, and thus assist in the formation of the collateral arteries of thp
fingers.
The Ulnar Artery and its Branches.
The ulnar artery {g,figs. 210, 211), which is larger than the radial, leaves that vessel
at a very acute angle, passes at first downward, inward, and backward, in front of the
ulna, describing a slight curve, the convexity of which is directed upward and inward, and
then descends vertically. Having arrived at the wrist, it is placed on the outer or radi-
al side of the pisiform bone, in front of the annular ligament of the carpus, and then
enters the pahn of the hand,'where it describes beneath the palmar fascia an arch, which
has its convexity turned downward, and is named the superficial palmar arch {t,fig. 210 ;
removed in^^. 211).
The relations of the ulnar artery must be separately examined in the forearm and in
the hand.
In the forearm, it is at first covered by the thick bundle of muscles which are attached
to the inner condyle of the humerus, and also by the median nerve, from which it is sep-
arated by that part of the pronator teres which arises from the coronoid process ; it is
then covered by the flexor sublimis, and finally by the fascia and skin ; the tendon of the
flexor carpi ulnaris is upon its inner side, and that of the flexor sublimis on its outer :
these two tendons, by their projection, occasion an interval between the artery and the
skin. It is in relation behind with the brachialis anticus, the flexor profundus digitorum,
and the pronator quadratus. The ulnar nerve is applied to the inner side of the artery
* [The two collateral arteries of the thumb, and the external collateral of the index finger, frequently arise
in a different manner from that described above : thus, the two arteries for the thumb may take origin from a
common trunk, which is then named the great or principal artery of the thumb (magna vel princeps pollicis) ,
while the artery for the index finger arises separately, and is named the radial collateral artery of the index
Unger (radialis indicis).1
THE ULNAR ARTERY.
mi
I!^. 211.
at the point where the vessel becomes vertical, and accompanies it as
far as the hand. The median nerve is situated on its inner side at the
bend of the elbow, but afterward becomes anterior, and then external
to it. In some cases of high division of the humeral artery, the ulnar
has been found immediately under the fascia in its whole length.
In the hand, it is at first situated on the outer or radial side of the
pisiform bone, and then in front of the hook-like process of the unci-
form bone ; finally, where it forms the superficial palmar arch, it is
entirely sub-aponeurotic.
In the forearm, the ulnar artery gives off a great number of un-
named collateral branches, which are divided into internal, external,
anterior, and posterior, and are distributed to the muscles and integ-
uments. Four branches, however, require special notice, viz., in
the forearm, the common trunk of the ulnar recurrents, the interosseous
artery, the branch for the median nerve, and the anterior artery of the
carpus; in the palm of the hand, the ulnar artery gives off the collet-
erai arteries of the fingers.
The anterior arid posterior ulnar recurrent arteries generally arise
by a common trunk, which is given off from the back of the highest
portion of the ulnar artery, passes transversely inward, and divides
into two branches — an anterior and a posterior. The former, or an-
terior ulnar recurrent artery {e,fig. 211), passes between the brachialis
anticus and pronator teres, gives branches to all the muscles attach-
ed to the inner condyle, and anastomoses with the internal collateral
branch from the brachial. The other branch, the posterior ulnar re-
current, is larger than the anterior, runs behind the muscles arising
from the inner condyle, is then situated between that condyle and
the olecranon, passes between the two origins of the flexor carpi
ulnaris in front of the ulnar nerve, anastomoses freely with the in-
ternal collateral branch of the brachial artery and with the interosseous recurrent, and
contributes to form an arterial network upon the back of the elbow-joint. The branch
given off by the posterior ulnar recurrent to the ulnar nerve deserves to be pointed out ;
it may be traced from below upward, along that nerve, and anastomoses with the other
branches given off to the same nerve from the brachial artery.
The interosseous artery is so large that it appears to be the result of a bifurcation of the
ulnar, and is described as such by many anatomists ; it comes off from the back of the
ulnar, immediately below the trunk of the recurrents, on a level with the bicipital tuber-
osity of the radius ; it not unfrequently arises from the radial. Lastly, in several cases
of high division, either of the brachial or of the axillary artery, the interosseous has been
found to constitute one of the branches of the bifurcation, the other branch being the
common trunk of the radial and ulnar arteries.
Immediately after its origin, the interosseous passes directly backward, and divides
into two branches of almost equal size, which are named, from their distribution, the an-
terior and posterior interosseous.
The anterior interosseous if fig- 211) descends vertically in front of the interosseous
ligament, and is held down to it by a layer of fibrous tissue ;* it is placed behind the
flexor profundus digitorum and the flexor longus pollicis, in the cellular interval between
these muscles. Having reached the upper borders of the pronator quadratus, it passes
between that muscle and the interosseous ligament, rests upon the latter, and perforates
it towards its lower part ; having thus reached the back of the forearm, the anterior in-
terosseous descends upon the dorsal surface of the carpus, and terminates by anastomo-
sing with the dorsal carpal branches of the radial and ulnar. While perforating the in-
terosseous ligament behind the pronator quadratus, the artery almost always gives off a
small twig, which descends perpendicularly to join the arch formed by the anterior ar-
teries of the carpus.
In one case where the radial artery was exceedingly small, indeed in a rudimentary
state, its place was supplied by the anterior interosseous ; which, after having passed
behind the pronator quadratus, escaped forward under the lower border of that muscle,
and passed transversely outward, to anastomose with the rudimentary radial artery,
which, thus re-enforced, immediately assumed its usual size.
During its course, the interosseous artery only gives off some small branches to the
front of the forearm, among which the artery of the median nerve deserves special notice ;
but several large branches are detached in succession from its posterior aspect, and im-
mediately perforate the interosseous ligament : they are called the perforating arteries of
the forearm, and are distributed to the deep layer of muscles on the back of the forearna.
I have seen one of these run along the posterior surface of the interosseous ligament, in
the same manner as the anterior interosseous artery.
* After amputation of the forearm, the interosseous artery becomes retracted between thi« fibrous layer and
the interosseous ligament ; and it is hence so difficult in some cases to place a ligature upon it, that it haa
been recommended to divide the inte"-=«^"~ '■ -•nent for a short distance.
ANGEIOLOGY.
The artery of the median nerve is remarkable for its constancy and its length ; it comes
, off from the front of the anterior interosseous artery, reaches the posterior surface of the
median nerve, penetrates it, and then runs downward along its inner side. I have seen
the artery of the median nerve very large, and anast9mosing with the superficial pahnar
ar<3h. It has also been found continuous with the brachial artery, and supplying the
place of both the radial and ulnar, which were in a rudimentary state.
The posterior interosseous artery is generally smaller than the anterior ; it perforates
the interosseous ligament opposite the lower border of the supinator brevis, and imme-
diately gives off an ascending branch, the interosseous recurrent ; it then descends be-
tween the deep and superficial layer of muscles on the back of the forearm, and divides
into a number of branches, which are distributed to those muscles, but especially to the
superficial layer.*
The interosseous recurrent is a branch of the posterior interosseous, of such size that it
may be regarded as resulting from the bifurcation of that artery : it passes vertically up-
ward, having the anconeous and the extensor carpi ulnaris behind it, and the supinator
brevis in front of it ; it runs behind the inner condyle, and anastomoses on the outer side
of the elbow-joint with the cutaneous, muscular, and periosteal divisions of the superior
profunda artery, the external collateral branch of the brachial
The anterior carpal branch of the ulnar artery is a small twig, which arises opposite the
lower borders of the pronator quadratus, passes between the tendon of the flexor carpi
ulnaris and the ulna, and anastomoses with a similar branch from the radial, to form the
anterior carpal arch, from which several branches descend to reach the interosseous
muscles, and those of the ball of the thumb -
The Superficial Palmar Arch.
Opposite the articulation between the two rows of carpal bones, and before it forms
the superficial palmar arch, the ulnar artery gives off a deep branch backward, called the
radio-cubital, or communicating artery {y,fig- 210), which dips between the short abduc-
tor and short flexor of the little finger, then passes outward between the short flexor and
opponens, to anastomose with and complete the deep palmar arch. This artery is some-
times so large that it may be regarded as formed by the bifurcation of the ulnar
The superficial palmar arch (t,fig. 210), which constitutes the termination of the ulnar,
gives off no important branch from its upper or concave side. Four or five diverging digi-
tal branches pass from its lower or convex side, and constitute the collateral arteries ol
the fingers.
The digital branches (w u u) are distinguished as the first, second, third, and fourth,
proceeding from within outward. The first reaches the inner or ulnar border of the lit-
tle finger, and constitutes its internal collateral artery ; the second runs along the fourth
interosseous space, and divides into the external collateral artery of the little finger, and the
internal collateral artery of the ring finger ; the third runs along the third interosseous space,
and supplies the external collateral artery of the ring finger and the internal collateral artery
of the middle finger ; the fourth runs in the second interosseous space, and gives the ex-
ternal collateral artery of the middle finger and the internal collateral artery of the index fin-
ger. It is very rare to find the external collateral artery of the index finger (x), and the
internal collateral of the thumb derived from the superficial palmar arch ; and still more
rare to see the external collateral artery of the thumb (r) given off by that arch.
Whatever varieties there may be in the arteries of the palm of the hand,J in reference
to the share which the radial and ulnar respectively take in the formation of the collat-
eral arteries of the fingers, the following general facts are apparent in their distribution :
The size of the superficial and deep palmar arches respectively are always inversely pro-
portioned to each other ; the communication between the two arches takes place not
only directly between the arches themselves, but also indirectly in a great number of
points by their branches ; all the descending branches of the deep palmar arch anasto-
mose with the angle of bifurcation of the descending branches of the superficial palmar
arch : those from the deep arch are sometimes smaller, sometimes larger than those
* Some branches may oe traced as far aa the carpus.
t [There are usually two other branches given from the ulnar in the vrrist : the first is a dorsal metacarpal
branch, which arises above the anterior carpal, runs under the tendon of the flexor ulnaris, turns round the
ulna to reach the back of the carpus, anastomoses with the dorsal metacarpal branch of the radial, and sends
a twig along the fifth metacarpal bone, to form the superficial dorsal artery of the little finger. The second
branch of the ulnar in this situation may arise with the one just described ; it is a posterior or dorsal carpal
branch, which passes backward, and anastomoses beneath the extensor tendons with the dorsal carpal branch
of the radial artery.]
i In one case the superficial palmar arch was formed in the most regular manner by the radial and the ul-
nar arteries, which concurred in its formation by two perfectly equal trunks, and gave off the collateral branch-
es to all the fingers except the external collateral of the thumb, the internal collateral of the index, and the
external collateral of the middle finger.
The deep palmar arch, very small in comparison with the superficial palmar arch, which was very consider-
able, was formed as usual. It gave off the external collateral of the thumb and the common trunk of the in-
ternal collateral of the index, and the external collateral of the middle finger. This common trunk was the
continuation of the non-flexed portion of the radial artery. The radial artery in this case was much larger
than the ulnar.
REMARKS ON THE ARTERIES OF THE UPPER EXTREMITY. 551
trom the superficial arch ; they are rarely of the same size, but always bear an inverse
ratio to them ; the bifurcation of each digital branch of the superficial pahnar arch takes
place two or three lines below the metacarpo-phalangal articulation, opposite the junc-
tion of the body with the upper end of the first phalanx ; the collateral arteries of the
fingers are situated upon the anterior aspect of the phalanges, on each side of the sheath
of the flexor tendons ; they give off dorsal and palmar branches, and anastomose with
each other in front of the body of the phalanges by small transverse branches ; having
reached the middle of the last phalanx, they anastomose in an arch, from the convexity
of which a great number of anterior branches pass to the skin, over the last phalanx, and
some dorsal branches to the matrix of the nail ; one of these branches runs along the
curved adherent border of the nail.
The termination of the superficial palmar arch is subject to variety: thus, it terminates
either by anastomosing with the radio-palmar or superficialis volae, of the same size as
itself, or by receiving a very small radio-palmar branch, and being prolonged so as to con-
stitute the common trunk of the internal collateral artery of the thumb, and the external
collateral artery of the index finger ; or else it terminates in the external collateral of
that finger ; or, lastly, after having given off the internal collateral of the thumb and the
external collateral of the fore-finger, it ends in the external collateral of the thumb. At
other times, again, there is no superficial palmar arch properly so called, and the ulnar
artery terminates by furnishing the collaterals of the little and ring fingers, and the in-
ternal collateral of the middle finger, the other collaterals being derived from the radio-
palmar, which is then very large. In certain cases, a very small transverse branch forms
the communication between the radial and the ulnar arteries.
General Remarks on the Arteries of the Upper Extremity.
A single trunk, which may be called the brachial trunk, supplies the whole of the up-
per extremity ; it forms, in succession, the sub-clavian, the axillary, and the brachial ar-
tery, which latter bifurcates near the bend of the elbow into the radial and ulnar arteries :
these form the palmar arteries, from which the arteries of the fingers take their origin.
The difference in the origin of the right and left brachial trunks has been considered
to account for the difference in strength between the two arms ; and the different size
of the two vessels has also been supposed to be connected with the same fact, which,
however, in reality, depends upon the more frequent exercise of the right than of the
left arm.
The brachial trunk is not exclusively distributed to the upper extremity, but supplies
the most dissimilar parts ; a fact which shows that the conditions of origin, which have
so great an influence in regard to nerves, are altogether without importance in reference
to the arteries. Thus, the brachial trunk sends branches to the following parts : the ver-
tebral artery to the brain, the cerebellum, the pons varolii, the medulla oblongata, and
the spinal cord ; the inferior thyroid artery, to the thyroid gland, the larynx, the trachea,
the oesophagus, and sometimes the bronchi ; the internal mammary and thoracic arteries,
to the corresponding manrnia ; and the same arteries, together with the superior inter-
costal, to the parietes of the thorax and abdomen ; the ascending cervical, to the praever-
tebral muscles and the spine ; and, lastly, the deep cervical, sub-scapular, and posterior
scapular arteries, to the superficial and deep muscles of the back of the neck.
Setting aside those branches which do not belong to the upper extremity properly so
c^ed, we find that, during its course along the limb, the artery always occupies the as-
pect of flexion, which is at the same time the position where it can be best protected ;
and that, for this purpose, it is directed from the axilla to the bend of the elbow : we
find, also, that it gives off a great number of anastomotic branches around the articula-
tions, and thus establishes a collateral circulation, through which the blood can pass
when the principal artery is obliterated. This anastomosis, and, consequently, the col-
lateral circulation, is effected by the cutaneous, muscular, and periosteal branches, and
even by those distributed to the nerves. Thus, along the clavicle, we find the acromio-
thoracic in front, and the supra-scapular or transversus humeri behind ; around the scap-
ula there are the supra-scapular on the upper border, the posterior scapular on the ver-
tebral border, and the sub-scapular on the axillary border ; so that that bone is complete-
ly surrounded by an anastomotictriangle.
Around the elbow-joint are the external and internal collateral branches of the brach-
ial artery, and the radial, ulnar, and interosseous recurrents.
Around the wrist we find the anterior and posterior carpal arteries, and also anasto-
motic arches around the metacarpo-phalangal and phalangal articulations.
On comparing the size and number of the arteries of the arm and forearm with the
size and number of the arteries of the hand, it will be seen that the latter has greatly
the advantage : indeed, in this part of the body, there is an unusual distribution of the
arterial system into a deep and a superficial set of vessels, precisely as is the case with
the veins. Why is this \ Is it not extremely probable that, as the deep veins are in-
tended to supply the place of the superficial, when the circulation in the latter is for a
time impeded, so in the hand the arteries are arranged in a similar manner, because the
bS2 ANGEIOLOGY.
superficial circulation is liable to be interrupted by pressure from grasping hard bodies
firmly in the hand for a longer or shorter period 1 and is it not for the same reason that
the superficial system derived from the ulnar artery has so many communications with
the deep system given off from the radial 1
It is virorthy of remark that the radial, which is the superficial eirtery of the forearm,
becomes deep-seated in the hand ; and that the ulnar, which is deep-seated in the fore-
arm, becomes superficial in the hand.
The great quantity of blood circulated through the hand is connected with the active
use of that part, in the ahnost constant exercise of the sense of touch, and in prehension
ARTERIES ARISING FROM THE TERMINATION OF THE AORTA
Enumeration. — The Middle Sacral. — The Common Iliacs. — The Internal Iliac, or Hypogas-
tric— the Umbilical — the Vesical — the Middle Hemorrhoidal — the Uterine — the Vaginal —
the Obturator — the Uio-lumbar — the Lateral Sacral — the Glutceal — the Sciatic — the Inter-
nal Pudic. — Summary of the Distribution of the Internal Iliac. — Artery of the Lower Ex-
tremity.— The External Iliac — the Epigastric — the Circumflex Iliac. — The Femoral — the
Superficial Epigastric — the External Pudic — the Muscular — the Deep Femoral, its Cir-
cumflex and Perforating Branches. — The Popliteal and its Collateral Branches. — The An-
terior Tibial and the Dorsal Artery of the Foot. — The Tibio-peroneal — Peroneal — Poste-
rior Tibial, and the Internal and External Plantar. — Comparison between the Arteries of
the Upper and Lower Extremities.
The arteries arising from the termination of the aorta are the middle sacral and the
two common iliac arteries.
The Middle Sacral Artery.
The middle or anterior sacral artery {n,fig. 199), the small median artery of the sacrum,
arises from the lower and back part of the aorta, a little above its termination. Like
the aorta, it is a single vessel, and seems to be the continuation of it, as far as direction
is concerned ; which, indeed, is really the case in such animals as are provided with a
tail. Sometimes, but rarely, it arises from the left common iliac, or the last lumbar ar-
tery. I have seen it arise by a common trunk with the two lower lumbar arteries.* It
passes vertically downward in front of the fifth lumbar vertebra, the sacrum and the
coccyx being closely applied to them all. It is situated in the median line at its origin,
but sometimes deviates to one side or the other. In size it is scarcely equal to one of
the lumbar arteries, and it gradually diminishes from its origin to the first bone of the
coccyx, towards the apex of which it terminates in a very variable manner.
The size of the middle sacral is generally inversely proportioned to that of the lowest
lumbar arteries. When the aorta divides higher than ordinarily, and the last lumbar is
given off from the middle sacral, the last-named artery is of course unusually large.
During its course, the middle sacral gives off, opposite the fifth lumbar and each of
the sacral vertebrae, a right and left lateral branch, which correspond with the series of
intercostal and lumbar arteries. The two lumbar branches are generally small, but are
very large when the fifth lumbar arteries are neither furnished by the aorta, nor by the
fourth lumbar, nor by the ilio-lumbar. The lateral branches given off upon the sacrum
pass transversely outward, supply twigs to the periosteum and bone, and anastomose
with the lateral sacral, the place of which they sometimes supply within the interior of
the sacral canal.
The middle sacral having become very slender near the base of the coccyx, bifurcates
in order to form an anastomotic arch with the right and left lateral sacral arteries. I
have seen its lower end divided into three branches, of which the median was prolonged
as far as the tip of the coccyx, while the lateral branches anastomosed with the lateral
sacral arteries.
The Common Iliac Aeteeies.
The primitive or common iliac arteries (i i, figs. 199, 212), the two branches into which
the aorta subdivides, commence opposite the lower margin of the fourth lumbar vertebra,
and terminate by bifurcating opposite the base of the sacrum ; they separate from each
other at an acute angle, pass obliquely downward and outward, and form the two sides
of an isosceles triangle, the base of which corresponds with the transverse diameter of
the fifth lumbar vertebra. These arteries are generally straight, but not unfrequently
they are tortuous in aged persons. In the adult they are about two inches long, the
right being rather longer than the left, from the position of the aorta ; but they are often
much shorter, on account of their bifurcating higher than usual. Meckel has remarked
that this premature bifurcation is more common on the left than on the right side. In
a specimen deposited in the museum of the Ecole de Medecine, the right common iliac
* 1 have geen the middle sacral artery arise from the renal artery. In this case, the renal artery came frtau
the angle of bifurcation of tke aorta.
THE INTERNAL ILIAC ARTERY. 553
is entirely wanting ; the aorta dividing into three branches, two on the right, viz., the in-
ternal and external iliacs, and one on the left, viz., the common iliac, which is distributed
in the usual manner. In this case the descending aorta resembled, to a certain extent,
the ascending aorta, and, like it, gave off three trunks
Relations. — They are covered by, and loosely connected with, the peritoneum ; they
are crossed by the ureters and the spermatic vessels, besides which, the left common il-
iac is crossed by the inferior mesenteric artery ; they are surrounded by a great number
of lymphatic glands, and rest above upon the vertebral column, and on the outside and
below upon the inner side of the psoas muscle.
It is of great importance to comprehend their relations with the common iliac veins.
The veins are situated behind the arteries ; but as the right and left vein unite on the
right side of the vertebral column, the left common iliac vein comes into relation with
both common iliac arteries.
The common iliac artery gives off no collateral branch ; it merely supplies some twigs
to the cellular tissue, the lymphatic glands, and the coats of the common iliac veins. It
occasionally gives off one of the renal arteries ; and it has been seen to supply the sper-
matic and the ilio-lumbar arteries.
Terminal Branches. — The common iliac artery terminates by dividing into two branch-
es, which remain in contact with each other for a short distance : the internal branch
dips into the pelvis, and is called the internal iliac or hypogastric artery ; tlie external
branch continues in the original course of the common iliac, and is termed the external
iliac artery.
Thk Internal Iliac or Hypogastric Artery.
The internal iliac or hypogastric artery {t,figs. 199, 212) is distributed to all the organs
contained in the cavity of the pelvis ; to the muscles pig, 212.
which line it within and cover it without ; to the exter-
nal and internal organs of generation, and to the integ-
uments.
It passes at first obliquely downward and forward,
and, as it were, in contact with the external iliac ; it
then dips vertically into the pelvis in front of the sacro-
iliac synchondrosis, describing a short curve ; and, after
a course of about one inch or one inch and a half in length,
divides opposite the upper part of the sacro-sciatic notch
into a greater or less number of branches, which do not
always arise in the same way from the principal trunk,
but whose ultimate distribution is constant. It is cov-
ered by peritoneum, and is crossed by the ureter ; it rests
behind on the lumbo-sacral nerve and pyriformis muscle*;
and the internal iliac vein is behind and to its outer side.
Its branches, all of which sometimes arise from two
principal trunks, one anterior and the other posterior, may be divided into an antenar
set, consisting of the umbilical, vesical, obturator, middle hemorrhoidal, uterine, vaginal, aei-
atic, and internal pudic arteries ; and a posterior set, including the ilio-lumbar, lateral, *a-
cral, and gluteal arteries. Altogether, there are nine in the male and eleven in the female.
The Umbilical Artery.
The umbilical artery, which is so large in the foetus, is converted into an impermeable
cord {xt;fig. 212) in the adult, excepting near its origin {a), where it gives off some ves-
ical branches : the examination of the umbilical arteries belongs, therefore, more espe-
cially to the anatomy of the foetus. They are intended to convey the blood of the foetus
to the placenta, and are then the continuations of the common iliac arteries. The ex-
ternal and internal iliacs, being very small at that period, in correspondence with the
small size of the abdominal extremities, appear to be nothing more than divisions of the
umbilical.
The umbilical arteries pass downward, forward, and outward, and, having arrived at
the sides of the bladder, run along them, in order to reach the umbilical ring, through
which they emerge from the abdomen, and, having traversed the whole length of the
umbilical cord in a spiral and tortuous manner, are at length distributed to the placenta.*
The vesical, middle hemorrhoil.il, uterine, vaginal, and obturator arteries are given
off in succession from the apparently ligamentous cord formed by the umbilical artery
near its origin.
The Vesical Arteries.
These are variable in number : the principal of them on each side are given off from
* It is curious to study the variable manner in which the umbilical arteries are converted, after Ijirth, into
a fibrous tissue. Sometimes these arteries are converted into two regular cords, which converge towards the
umbilicus. At other times each of these cords is subdivided into irregular bundles which it is difficult to
trace to their true origin.
4A
654 ANGEIOLOGY.
the umbilical artery (a), which seems to be converted into a ligamentous cord (u) at the
place where the vesical arteries arise, but which is in reality pervious. This ligament-
ous appearance of the umbilical arteries depends upon the narrowness of their canal, as
compared with the thickness of their coats. Other vesical branches arise from the mid-
dle hemorrhoidal and obturator arteries, and in the female from the uterine and vaginal.
We shall divide the vesical arteries into the posterior, the anterior, and the inferior.
The posterier vesical artery {b,fig. 212) frequently arises, in the female, by a common
trunk with the uterine. It reaches the base of the bladder, on the outer side of the ure-
ter, passes inward and upward upon the posterior surface, as far even as the summit of
that viscus. I have seen the right posterior vesical artery, of large size, running along
the posterior surface of the bladder in the median line, and prolonged upon the urachus ;
the left posterior vesical was very small, and, in fact, rudimentary.
The anterior vesical (c) arises from the umbilical, from the obturator, and sometimes
from the internal pudic artery. When it arises from the umbilical, it is given off from
that artery opposite the sides of the bladder, and passes downward and inward along its
anterior surface. I have seen it given off near the summit of that organ. When it ari-
ses from the obturator or the internal pudic, it traverses the anterior lig2iment of the blad-
der, and passes upward upon the front of that organ.
I have seen a very large vesical artery given off from the obturator, which, in that
case, arose from the epigastric, and farther the vesical artery arose by a common trunk
with the artery of the corpus cavernosum.
The inferior vesical {d), which often arises direct from the internal iliac, reaches the
inferior fundus of the bladder, and ramifies abundantly upon it and the commencement
of the urethra : in the male it also supplies the corresponding vesicula seminalis and vas
deferens, the branch to which is called the deferential artery, and the prostatic portion
of the urethra. I have seen the dorsal artery of the penis arise from the inferior vesical.
The Middle Hemorrhoidal Artery.
This is a small artery (e), which is sometimes wanting, its place being then supplied
by branches from different sources, but especially from the sciatic or the internal pudic ;
it passes upon the sides of the anterior surface of the rectum, where it terminates by
anastomosing with the superior and inferior hemorrhoidal arteries.
The Uterine Artery.
The uterine artery {n n,jig. 198) arises from the umbilica., near the posterior vesical,
and frequently by a common trunk with it ; passes transversely inward to the corre-
sponding lateral border of the uterus, a little above the os tincae ; is reflected upward
along the uterus, and terminates by expanding into several ascending branches, of which
the anterior reach the front, the posterior the back, and the middle the upper border of
the viscus, and inosculate either with their fellows of the opposite side, or with the uter-
ine branches of the ovarian artery. The uterine arteries are remarkable for the great
size which they acquire during pregnancy, and also for their tortuous and spiral course,
even to their smallest branches : a disposition which no other artery presents in the
same degree. These tortuosities, instead of diminishing, appear to increase during
pregnancy : a fact which seems opposed to the view generally adopted regarding the
use of arterial flexuosities in organs liable to variations in their size.
Collateral Branches. — At the point of its reflection, each uterine artery gives off one or
more descending branches between the vagina and the bladder to supply both parts ; in
their course along the borders of the uterus, they furnish a series of anterior and poste-
rior ascending branches, which are distributed in the same way as the terminal ascending
branches ; they all anastomose in the median line with their fellows of the opposite side.
Relations. — The trunks of the uterine arteries are beneath the peritoneum ; the prin-
cipal branches are situated under a thin layer of the substance of the uterus, and the ul-
timate divisions and subdivisions enter its tissue.
The Vaginal Artery.
The vaginal artery arises from the umbilical, sometimes before, sometimes after the
origin of the uterine, which is sometimes given off from a conunon trunk with it. It is
as large as the uterine in young subjects, but is smaller than it after puberty. It de-
scends directly upon the sides of the vagina, to which it gives off a numerous series of
branches, supplies a considerable branch to the neck of the bladder and the urethra,
gives an equally large one to the bulb of the vagina, and then passes backward between
the orifice of the vagina and the rectum, and anastomoses with its fellow of the oppo-
site side.
The Obturator Artery.
The obturator artery {f,fig. 212) is remarkable for the varieties of its origin, and for
the important consequences which result from those varieties, in reference to the oper-
ation for femoral hernia.
THE ILIO-LUMBAR ARTERY. SS5
It generally arises from the internal iliac by the side of the umbilical, but sometimes
above the gluteal ; it is almost as frequently given off from the external iliac, either di-
rectly,* which is rare, or by a common trunk with the epigastric. Lastly, and much
- more rarely, it arises from the femoral artery.
The course of the obturator artery is modified by these differences of origin, which,
notwithstanding the assertion of some anatomists, are as common in the male as the fe-
male, and which may occur on one side only, or on both sides of the same subject.
Thus, when the obturator comes from the femoral, it passes upward on the inner side
of the femoral vein, enters the pelvis through the crural ring, is reflected upon the upper
surface of the body of the os pubis, then passes behind it and gains the internal opening
of the sub-pubic canal. When it arises by a common trunk with the epigastric, it dips
vertically behind the os pubis to the same opening. In its ordinary mode of origin, it
passes horizontally forward upon the sides of the brim of the pelvis, being bound down
by the peritoneum, runs parallel with the obturator nerve (n), which is placed above i
gains with it the internal orifice of the sub-pubic canal, and, having traversed this pas-
sage, divides into an internal and an external terminal branch.
Collateral Branches. — Near its origin, the obturator artery gives off a tolerably large
branch, the iliac, which perforates the iliac fascia, dips between the iliacus muscle and
the ihac fossa, and anastomoses with a branch of the circumflex iliac artery, t
As it enters the sub-pubic canal it gives off a small branch, which passes transversely
behind the body of the pubis, and ramifies upon the side of the symphysis, anastomo-
sing with its fellow of the opposite side ; also a small ascending branch (s), which anas-
tomoses with the epigastric artery, and which may be regarded, according to Meckel, as
one of the origins of the obturator ; so that the variety in which the obturator arises
from the epigastric is often nothing more than an unusual development of this commu-
nicating branch. In support of this view, we may quote the very rare case, in which
the obturator arises by two roots of almost equal size, one coming from the epigastric,
and the other from the interned iliac.
Terminal Branches. — The interned branch passes between the obturator extemus mus-
cle and the conjoined rami of the pubes and ischium, so as to describe a semicircle
around the inner half of the obturator foramen, gives branches to the periosteum of the
OS pubis, muscular branches to the two obturator and to the adductor muscles, some
genital branches to the coverings of the testis in the male and to the labia majora in
the female, and, lastly, some very important anastomotic branches, which join those of
the internal circumflex.
The external branch runs along the outer half of the obturator foramen ; it is placed,
like the preceding, between the two obturator muscles, and terminates between the
neck of the femur and the quadratus femoris muscle by anastomosing with the sciatic
artery. This anastomosis is very remarkable. During its course, the external branch
supplies the obturator muscles and the hip-joint ; the articular branch enters by the
notch of the cotyloid cavity, and is lost in the reddish, fatty tissue situated at the bottom
of it. The distribution of the obturator artery is much more limited than that of the ob-
turator nerve.
The Ilio-lumbar Artery.
The ilio-lumbar artery (A) arises from the back of the internal iliac, and, tolerably fre-
quently, from the gluteal. There are often two ilio-lumbar arteries. This vessel bears
the same relation to the lumbar arteries that the superior intercostal does to the aortic
intercostals ; its size and distribution vary according to the presence or absence of the
fifth lumbar artery.
It has a retrograde course, running upward and backward in front of the lumbo-sacral
nerve, and behind the psoas muscle, and soon divides into two branches : an ascending
or lumbar, and a transverse or iliac. The ascending or lumbar branch passes vertically
upward along the bodies of the lumbar vertebrae, hidden by the psoas, and subdivides
into a muscular branch, which corresponds to the abdominal branches of the lumbar ar-
teries, and is distributed to the psoas and to the quadratus lumborum ; and a spinal
branch, which enters the vertebral canal by the foramen between the fifth lumbar verte-
bra and the sacrum, and is distributed in the same manner £is the other spinal arteries.
* The cases where th*' obturator artery arises separately from the external iliac are not unfrequeut. The
following description may serve as an example. In one case, the obturator artery arose separately from the
external iliac artery, at the distance of one inch above the femoral arch, and above the origin of the epigastric
artery ; it went downward and inward to reach the lateral wall of the pelvis, crossed the obturator nerve, and
entered the sub-pubic canal. In this subject, the obturator vein joined also the external iliac vein. The same
disposition existed on both sides.
t The obturator artery sometimes gives off the artery to the bulb of the urethra. In a preparation which
was exhibited by M. Dcnonvilliers, now chef des travaux anatomiques, at the concours for the office of prosec-
tor, I have seen a voluminous branch whicli had arisen from the obturator artery, extending all along the in-
ternal part of the obturator foramen, cross perpendicularly the posterior surface of the descending branch of
the pubis, reach the bulb transversely by crossing the internal pudic artery, above which it was placed. This
was on the left side. On the right side the arrangement was normal. This arrangement is not as rare as
might be believed : it is evident that the ligature of ihe internal pudic artery would be useless in a case of
this kind, in arresting a hemorrhage consequent upon nii operation for the stone.
ANGEIOLOGT.
The transverse or iliac branch passes horizontally outward, opposite the brim of the
pelvis, and divides into a superficial branch, which passes under the iliac fascia, ramifies
upon the iliacus muscle, and anastomoses with the circumflex iliac artery ; and into a
deep and much larger branch, which passes between the ihacus muscle and the ihac
fossa, and divides into muscular and periosteal twigs. The principal nutritious artery
of the ilium is derived from this branch.
When there are two ilio-lumbar arteries, the superior represents the lumbar branch,
and the inferior the iliac branch : in such a case the latter branch always arises from the
gluteal artery.
The Lateral Sacral Arteries.
Most'commonly there are two lateral sacral arteries on each side ; they belong rather
to the interior of the sacral canal than to the cavity of the pelvis, and form a continuation
of the spinal branches of the lumbar arteries ; they almost as frequently arise from the
gluteal as from the internal iliac ; sometimes they are derived from the sciatic or the
Sio-lumbar arteries.
The superior lateral sacral is generally of considerable size. It passes almost horizon-
tally inward, and after having given off some small transverse branches, which anasto-
mose with the middle sacral, enters the first anterior sacral foramen, and divides into
two branches : one intended for the nerves and their coverings, and another which emer-
ges from the sacral canal by the corresponding posterior sacral foramen, and is distribu-
ted to the spinal muscles and to the skin.
The inferior lateral sacral (Ji,fig. 212) is situated at first under the digitations of the
pyriformis muscle, afterward passes in front of that muscle, and is directed inward and
downward on the inner side of the sacral foramina, and along the borders of the coccyx,
where it anastomoses with the middle sacral. In this course it gives off a series of very
small internal branches, which correspond to the several sacral vertebrae, and anastomose
with the middle sacral ; also some posterior or spinal branches, each of which enters the
sacral canal through the corresponding sacral foramen, and subdivides into two small
branches : one intended for the nerves and their coverings, while the other emerges from
the sacral canal by the corresponding posterior sacral foramen, and is distributed to the
muscles and the skin. "When the superior lateral sacral is small, the posterior or spinal
branch of the inferior lateral sacral is very large. The inferior lateral sacral artery often
terminates by a spinal branch, which enters at the lowest anterior sacral foramen.
The Gluteal Artery.
The gluteal artery (rn,fig. 212), called also the posterior iliac, is the largest branch of
the internal iliac, of which it might be considered the continuation. It might be called
superior gluteal, in contradistinction to the sciatic, which is, in reality, an inferior gluteal.
It passes downward and backward between the lumbosacral nerve and the first sacral
nerve, escapes from the pelvis at the upper part of the great sacro-sciatic notch, above
the pyriformis muscle {m,fig. 45), is reflected upon the border of that notch, and divides
into a superficial and a deep branch. The superficial branch (a) passes horizontally for-
ward, between the glutaeus maximus and medius, and is almost entirely distributed to the
upper part of the first-named muscle and to the adjacent part of the skin ; the deep branch
{b) passes between the glutaeus medius and minimus, and subdivides into two branches ;
the lower of these runs horizontally, and may be traced as far as the anterior border of
the glutaeus medius, while the other very nearly follows the curve described by the origin
of the glutaeus minimus. This branch gives off some muscular arteries, several nutri-
tious arteries to the bone, and severtd articular branches.
One circumstance regarding the gluteal artery worthy of remark is the fact that, in
common with all arteries of a certain size, it is liable to aneurism, and that for the cure
of this aneurism (which has always been the result of external violence), the common
iliac artery has in two cases been tied in America, and the gluteal artery itself recently
by an English surgeon.
The Sciatic Artery.
The sciatic artery (o, fig. 212), from its distribution, might be called the inferior gluteal.
It often arises by a common trunk, either with the gluteal or with the internal pudic, be-
hind and internal to which it is situated ; it descends in front of the sacral plexus and the
pyriformis muscle, traverses the sacral plexus, emerges from the pelvis (o, fig. 215) be-
tween the pyriformis and the lesser sacro-sciatic ligament, accompanied on its inner side
by the great sciatic nerve, and behind by the internal pudic artery (p). Outside the pel-
vis, the sciatic artery gives off iniernal or transverse branches, some of which pass trans-
versely inward between the gluteus maximus and the great sacro-sciatic ligament, while
others (c) perforate that ligament, and ramify in the internal attachments of the glutaeus
maximus. Several of these branches ramify upon the skin of the coccygeal region ; its
other branches are descending, the largest of which {d) gains the deep surface of the
glutaeus maximus, and enters that muscle by numerous branches, which become cuta-
INTERNAL PUDIC ARTERY.
657
Fig. 213.
neous at their termination ; one and often two or three branches (c) of the sciatic artery
attach themselves to the deep surface of the great sciatic nerve, and accompany it to the
lower part of the thigh. A great number of twigs are given off from the several branches
of the sciatic artery, which are distributed to the small rotator muscles, or to the origins
of the muscles attached to the tuberosity of the ischium, while others anastomose with
the circumflex (/) and perforating arteries («) derived from the femoral. Among these
anastomoses, I would point out one very considerable anastomotic loop, formed behind
the neck of the femur by the sciatic and internal circumflex arteries, and constituting one
of the principal communications between the internal iliac and femoral arteries.
The hitemal Pudic Artery.
The internal pudic (jp,fig. 212), the terminal branch of the internal iliac, is, practically
speaking, the most important of all the pelvic arteries. It is smaller than the sciatic,
from which it is sometimes given off, either shortly after the origin of that vessel, or as
it is passing out from the pelvis. The internal pudic runs in a tortuous manner down-
ward, in front of the sacral plexus and the pyriformis muscle, parallel to the sciatic ar-
tery (o), which is behind it ; escapes from the pelvis, together with that vessel {p, o,fig.
215), between the pyriformis muscle and the spine of the ischium ; is reflected upon
that process, turning round it from behind forward, so as to embrace in succession its
posterior, its external, and its anterior surfaces, and then enters the pelvis again between
the two sacro-sciatic ligaments. The artery, af-
ter descending a short distance, then becomes as-
cending, and is situated in the ischio-rectal fossa
{a, Jig. 213), and is applied to the internal surface
of the tuberosity of the ischium, or, rather, of the
obturator internus muscle, with which it is kept
in contact by a layer of fascia : it is separated
from the levator ani by a considerable quantity of
fat, and having reached the posterior border of ^
the transversus perinei muscle, it divides into an
inferior, superficial, or perineal branch (c), and a
stiperior or deep branch (e), w^hich is distributed to
the penis in the male and to the clitoris in the fe-
male. An important variety in the course of this
artery has been pointed out by Bums, who, in a
male subject, saw the trunk of the internal pudic, instead of passing out of the pelvis, run
upon the sides of the inferior fundus of the bladder, perforate the upper part of the pros-
tate, and then terminate in the usual manner.
Collateral Branches. — During its course within the pelvis, the internal pudic supplies
branches to the bladder, rectum, vesiculae seminales, and prostate in the male, and to
the vagina in the female ; it also rather frequently gives off the middle hemorrhoidal.
As it turns round the spine of the ischium, it gives some branches to the rotator mus-
cles of the thigh. Opposite the internal surface of the tuberosity of the ischium, it gives
origin to one or more branches, named the external or inferior hemorrhoidal (b,jig. 213),
which run inward to be distributed to the lower end of the rectum, to the sphincter,
the levator ani, and the skin ; also some branches which proceed outward, some to sup-
ply the periosteum of the tuberosity, while others ramify in the muscles attached to that
process ; lastly, a very important communicating branch passes between the tuberosity
of the ischium and the great trochanter, and anastomoses with the sciatic and internal
circumflex arteries.
Terminal branches. — These differ in the two sexes. We shall first describe them in
the male :
The inferior branch, the superficial artery of the perineum, or the perineal artery (c), is
smaller than the superior branch : it passes forward and inward, in the cellular interval
between the ischio-cavernosus and the bulbo-cavernosus ; above, i. e., deeper than the
superficial fascia of the perineum, which separates it from the skin ; and below, i. e.,
superficial to the transversus perinei muscle, it thus reaches the dartos at the side of the
median line, where it is named the artery of the septum, and is distributed to the scrotum
and the skin of the penis.
During its course the superficial perineal artery gives internal and external branches.
Some of the internal branches run along the posterior border of the transversus perinei
muscle, and are sometimes so large as to bleed very profusely when they are divided in
the operation of lithotomy ; from its situation, one of them is named the transverse ar-
tery of the perineum (d).
The deep superior or deep branch (e), or the artery of the penis (in the male), is the con-
tinuation of the trunk of the internal pudic, both in regard to size and direction : it runs
along the ascending ramus of the ischium, between the layers of the triangular ligament ;
above, i. e., deeper than the transverse muscle, which it sometimes perforates, also above
the ischio-cavernosus and the corresponding crus of the corpus cavernosum ; and oppo-
ANGEIOLOGY.
site the point at which the two crura unite, it subdivides into two branches, viz., the
dorsal artery of the penis (g) and the artery of the corpus cavernosum Qi).
During its course, the artery of the penis gives off a very important collateral branch,
named the artery of the bulb (/), which is as large as the superficial perineal artery, is
sometimes double, and generally arises near the bulb, passes transversely inward, above
the middle perineal fascia or triangular ligament, or, rather, in the substance of that
ligament, and is distributed to the bulb of the urethra and to the spongy portion of this
canal.*
The dorsal artery of the penis (g) is sometimes the only terminal branch of the internal
pudic, and then a very delicate twig supplies the place of the artery of the corpus cav-
ernosum, which, in this case, is supplied from another source. This artery reaches the
dorsal surface of the penis by passing between the symphysis pubis and the crura of the
corpus cavernosum, and perforating the suspensory ligament of the penis, and then runs
in a very tortuous manner along, beneath the skin, upon the dorsal aspect of that organ,
on one side of the median line, being retained in its position by a layer of fibrous mem-
brane : it terminates by ramifying in the prepuce and in the glans, around the base of
which it forms a corona. I have seen the dorsal artery of the penis given off by one of
the external pubic arteries, from which it arose immediately above the entrance of the
saphenous vein into the femoral ; it then formed a curve in the groin, with its concav-
ity directed downward, and passed upon the sides of the dorsal surface of the penis ; in
another instance, the dorsal artery of the penis was derived from the obturator, or, rath-
er, it had two roots : a very small one, which had the usual origin, and a large one,
which arose from the obturator and passed under the symphysis. The right and left
dorsal arteries of the penis sometimes anastomose by a transverse branch, like the an-
terior cerebral arteries.
The artery of the corpus cavernosum (h) is also sometimes the only terminal branch of
the internal pudic artery, the dorsal artery of the penis, in such cases, being derived from
some other source. I have seen the cavernous artery arise from the obturator. In all
cases it enters the corpus cavernosum by the corresponding crus, runs along its median
septum, and ramifies in its areolar structure.
I have seen the dorsal arteries of the penis and the cavernous artery arise by a com-
mon trunk from the hypogastric ; this trunk passed directly from behind forward to be
divided immediately. The same disposition existed on both sides. The internal pudic
artery gave off a small cavernous artery.
In the female, the terminal branches of the internal pudic are arranged as follows :
the inferior or superficial perineal branch is larger than the superior, and might be named
the artery of the labia majora, to which it is distributed ; the superior or deep branch, or the
artery of the clitoris, runs along in contact with the tuberosity of the ischium, and then
with its ascending ramus, and having given off a branch, which runs inward to the bulb
of the vagina, terminates in the dorsal artery and cavernous artery of the clitoris, these ves-
sels being very small in consequence of the diminutive size of that organ.
Summary of the Distribution of the Internal Iliac Jlrtery.
The internal iliac artery, which is so deeply situated as to be inaccessible to the sur-
geon, sends branches to all the organs contained in the cavity of the pelvis ; to the bony
parietes of the pelvis and the sacral canal ; to the muscles which line the pelvis within
and cover it without ; and to the skin and the external genital organs.
Its several branches may be divided into parietal and visceral. The visceral branches
are the vesical, middle hemorrhoidal, vaginal, and uterine arteries, and the deep branch
of the internal pudic. The sympathy existing between all the organs to which the above-
named vessels are distributed, depends less upon those vessels having a common source
than upon the community of origin of the several nerves which those vessels serve to
support.
The parietal branches are the ilio-lumbar and lateral sacral arteries, which, with the^
middle sacral, continue the series of intercostal and lumbar arteries into the sacral re-*
gion, and supply the sacrum, the spinal nerves and their coverings, and also the muscles
of the vertebral grooves and the skin of the sacral region ; the glutaeal and the sciatic ar-
teries intended for the muscles of the glutaeal region ; the superficial branch of the internal
pudic artery, which supplies the perineum ; and, lastly, the obturator artery, which forms
an arterial circle around the obturator foramen, and supplies the obturator muscles.
Several branches of the internal iliac artery establish anastomoses between that ves-
sel and the femoral artery ; these are more especially the sciatic, the internal pudic, the
gluteal, and the obturator arteries.
Artery of the Lower Extremity, or Crural Trunk.
The arterial trunk of the lower extremity, or the crural trunk (Chaussier), corresponds
* The artery of the bulb, after having traversed the bulb, is directed from behind forward in the substance
of the spongy portion of the urethra, and may be followed up to about its middle part. When the artery of ths
bulb comes from the obturator artery, the inferior pudic sends a rudimentary branch to the bulb. It is the
pudic artery which supplies Cowper's glands.
THE EXTERNAL ILIAC ARTERY. 559
With the brachial trunk of the upper extremity. This vessel, which is the direct con-
tinuation of the common iliac artery, passes downward and outward, emerges from the
pelvis beneath the crural arch, and thus reaches the anterior region of the thigh. Op-
posite the junction of the two upper thirds with the lower third of the femur, it traverses
the fibrous canal formed for it by the tendon of the great adductor muscle, and thus
gains the popliteal space, at the lower part of which it terminates by dividing into two
branches. The numerous and important relations of this vessel, and the great number
of branches arising from it, have led to its division by anatomists into three portions,
which are named the external iliac artery, the femoral or crural artery, and the popliteal ar-
tery. The two terminal branches are the anterior tibial, which, in the foot, is termed the
dorsal artery of the foot, and the tibio-peroneal trunk, which divides into the peroneal and
posterior tibial arteries, the latter of which terminates in the sole of the foot by subdivi-
ding into the internal and external plantar arteries.
The External Iliac Arteky.
The external iliac artery (r, figs. 199, 212), the outer of the two branches into which the
common iliac divides, is analogous to the subclavian artery in the upper extremity. It
extends from the highest part of the sacro-iliac symphysis to the lower border of the fem-
oral arch or Poupart's ligament, below which it takes the name of femoral artery. It is
directed obliquely downward and outward, in a line extending from the sacro-iliac sym-
physis to the crural ring, and is almost always straight, but sometimes tortuous. It has
the following relations : in front and on the inner side, it is covered by the peritoneum,
which is very loosely attached to it : an important fact, which enables the surgeon to
separate that membrane from it in applying a ligature to the vessel ; on the outer side, it
rests against the psoas muscle, from which it is separated by the iUac fascia ; behind, the
artery of the right side is in relation with the corresponding external iliac vein, which
is placed to its inner side below ; on the left side the vein is below, and on the inner side
of the artery ; lastly, the genito-crural nerve, just as it is about to enter the inguinal ca-
nal, crosses in front of this artery, and so also do the spermatic vessels ; the circumflex
iliac vein crosses it at right angles behind the femoral arch, in order to terminate in the
external iliac vein ; besides this, it is covered immediately behind the arch by several
lymphatic glands ; higher up, the ureter crosses obliquely in front of it, and the artery of
the right side is covered by the termination of the ileum, and that of the left side by the
sigmoid flexure of the colon.
Collateral Branches. — The external iliac artery furnishes no branches, excepting at its
lower part, near the femoral arch, where it gives off the epigastric and circumflex iliac
arteries.
The Epigastric Artery.
The epigastric artery is, practically speaking, one of the most important to be well un-
derstood, on account of its relations with the crural ring and inguinal canal, that is to
say, with the parts through which the viscera generally descend in herniae.
This artery (v,figs. 199, 212) arises from the inner side of the external iliac, two or
three lines above the femoral arch. Its origin, however, is subject to some varieties :
sometimes it takes place half an inch, one, or even two inches above the crural arch : an
important fact in reference to the application of a ligature to the external iliac. Hessel-
bach and several others state that they have seen the epigastric arise from the obtura-
tor artery ; but their descriptions appear to me to prove nothing more than that the epi-
gastric and obturator arteries may arise by a common trunk. It is worthy of remark
that the obturator is often observed to arise from the epigastric, while there is, perhaps,
no example of the epigastric being derived from the obturator. The obturator so fre-
quently arises by a common trunk with the epigastric,* that many anatomists have
thought that the obturator is derived from the epigastric more frequently than from the
internal iUac artery. In 250 subjects examined for this purpose by M. Jules Cloquet,
the obturator arose 150 times from the epigastric on both sides, 28 times on one side
only, and 6 times from the femoral artery. Althoug:h it is a very common occurrence to
have the obturator artery arising from the epigastric, it is very rare to find the epigas-
tric taking its origin from the obturator. This anatomical variety has only been report-
ed as having occurred in two cases. One can easily understand how dangerous it would
be to operate for the relief of a strangulated hernia in such a case.
The epigastric artery, whether it gives off the obturator or not, passes transversely
or obliquely inward, and, having arrived below the spermatic cord in the male, and the
round ligament in the female, is reflected upward, so as to describe a curve having its
concavity directed upward, and corresponding to the loop formed by the spermatic cord
o' round ligament, the concavity of which is directed downward. When the cbturator
arises by a common trunk with the epigastric, it is given oflf at the point where the lat-
ter is reflected upward, and from the convexity of the curve. After being reflected, the
* It would be very difficult to explain why the epigastric and the obturator arteries are so intimately cott
nected at their origins.
9Bfk ANGEI0L06Y.
epigastric artery ascends obliquely inward, soon reaches the outer border, and next the
posterior surface of the rectus abdominis muscle, and then passes vertically upward.
Having reached the umbilicus, it penetrates into the substance of the rectus, and termi-
nates by anastomosing with the internal mammary artery.
Relations. — The relations of the transverse, oblique, and vertical portions of the epi-
gastric artery should be examined separately. The transverse portion varies in length
in different subjects ; sometimes it is almost entirely wanting, the artery running im-
mediately upward ; at other times it is an inch and a half in length. This difference in
length, which is of no consequence when the obturator artery arises from the internal
iliac, becomes highly important when that vessel is given off from the epigastric*
This transverse portion of the artery is directed obliquely downward, when the ej -
gastric arises at a certain distance above the ring.
The oblique portion of the epigastric artery forms the outer side of a triangle, the in-
ner side of which is formed by the outer border of the rectus abdominis muscle, and the
base by the crural arch : the epigastric constitutes the true boundary between the inter-
nal inguinal fossa, which comprises all the triangular space situated on the inner side
of the vessel, and the external inguinal fossa, which comprises the space upon its outer
side. The abdominal orifice of the inguinal canal is situated in the external inguinal
fossa, and, consequently, to the outer side of the epigastric artery. Those inguinal her-
nise which pass through the internal fossa are called internal or direct inguinal herniae ;
those which take place on the outer side of the artery are called external or oblique in-
guinal.
In its horizontal and oblique portions, the epigastric artery is placed between the per-
itoneum and the fascia transversalis. I should observe that the spermatic cord in the
male, and the round ligament in the female, do not cross the epigastric artery precisely
in the situation of the loop which this vessel describes, but a little above it. The axis
of the inguinal canal being directed obliquely downward and inward, intersects at right
angles the oblique portion of the artery, which slopes in the opposite direction.
In its vertical portion, the epigastric artery is situated between the rectus and the pos-
terior wall of the sheath of that muscle until near the umbilicus, where it dips into the
fleshy fibres.
Collateral Branches. — Near its origin, or, rather, opposite the bend which it takes, the
epigastric artery sometimes gives off the internal circumflex, which, as we shall here-
after see, generally arises from the deep femoral. It always gives off the following
branches : a cremasteric branch {I, Jig- 214), which enters the inguinal canal, runs along
the fibrous sheath of the cord in the male, and the round ligament in the female, and
passes in the one to the coverings of the testicles, and in the other to the labia majora ;
a second branch, which runs along the inner portion of the femoral arch, and anasto-
moses with its fellow of the opposite side behind the symphysis ; and, lastly, a branch
which crosses the horizontal ramus of the pubes at right angles, and anastomoses with
the obturator. I have already stated that this small branch may be regarded as forming
the trunk of the obturator when that artery arises from the epigastric. In its oblique
and vertical portions, the epigastric gives off a number of internal and external ascending
branches, which pass very obliquely through the rectus abdominis, partially supply that
muscle, and then pierce the anterior wall of its sheath, the internal branches near the
linea alba, and the external branches near the outer border of the sheath, to ramify upon
the skin. These branches anastomose with the internal mammary and with the lumbar
arteries.
The anastomosis of the epigastric with the internal mammary takes place only in the
substance of the rectus, and by very small vessels.
The Circumflex Iliac Artery.
The circumflex or posterior iliac artery {x, figs. 199, 212), smaller than the epigastric,
arises from the outer part of the external iliac, either opposite the epigastric or a little
below it. It sometimes arises from the upper part of the femoral artery : it is generally
single, but occasionally double, which may be regarded as resulting from a premature
division of the vessel.
It passes obUquely upward and outward, behind the crural arch, with which it is held
in contact by a fibrous layer interposed between it and the peritoneum. Opposite the
anterior superior spinous process of the ihum it divides into two branches : one is an
ascending or abdominal branch, which passes upward, in the substance of the abdominal
parietes, between the transversalis and obUquus intemus muscles, parallel with the ep-
igastric artery, and terminates by anastomosing with the inferior intercostal and the
lumbar arteries ; the other is the circumflex ihac artery properly so called, which is the
* [If the obturator arises high up from the epigastric, it describes, before it euters the pelvis, a semicircle
extending along the upper, and then the inner border of the crural ring ; and, consequently, has such rela-
tions with the neck of the sac in femoral hernia, that render it almost impossible to avoid wounding the ar-
tery in dividing the stricture upward and inward. But if, as is much more frequently the case, it arises from
near the commencement of the epigastric, or by a common trunk with it, it then descends at once into the pel
vis obliquely along the outer border of the crural ring, and will have the same relation with a femoral henua.J
THE FEMORAL ARTERY.
56«
continuation of the vessel in direction and sometimes in size ; it runs along the crest
of the ilium, is at first sub-aponeurotic, or, rather, is contained between two layers of
fascia in the cellular interval separating the transversalis from the obliquus internus,
and terminates by anastomosing with the fourth lumbar artery upon the crest of the ilium.
During its course, the circumflex iliac artery gives off ascending branches, which ram-
ify in the muscles and integuments of the abdominal parietes ; and descending branches,
which ramify in the iliac fossa, and anastomose with the iliac branches of the obturator
artery.
The Femoral Artery.
The femoral or crurcu artery (a a', fig. 214) is that portion of the artery of the Icn'er ex-
tremity which intervenes between the external iliac and pop- Fig. 214.
liteal arteries ; it is bounded above by the crural arch, and
below by the junction of the two upper thirds with the lower
third of the thigh, or, rather, by the place where the artery
passes through the tendinous ring formed by the adductor
magnus.
It has been proposed to take as the lower boundary of the
femoral artery the origin of the deep femoral or profunda ar-
tery, which has been correctly regarded as a terminal branch
resulting from the bifurcation of the femoral artery, rather
than as a collateral branch. According to this view, which
has not been generally adopted, the femoral would not be more
than from an inch and a half to two inches in length, and
would divide into a superficial and deep femoral.
The femoral artery is directed vertically, and somewhat
obliquely backward, so that it forms a slight angle with the
external iliac, on account of the oblique inclination forward
of that vessel ; and, farther, although it is in front of the fe-
mur above, it is placed on the inner side of it below, prepara-
tory to becoming posterior to it in the popliteal space. A line
drawn from the middle of the space between the anterior su-
perior spinous process of the ilium and the symphysis pubis,
down to the inner side of the femur, below the middle of that
bone, would exactly represent its direction. The direction
of the femoral artery, in respect to the femur, is such, that
immediately below the femoral arch it is situated over the
point of junction of the inner with the two outer thirds of the
head of that bone, while lower down it is in relation with the
inner aspect of the bone ; the artery, therefore, forms an acute
angle, opening upward, with the shaft of the femur, and there
is an interval of an inch to eighteen lines between the vessel
and the upper part of the bone, into which instruments may
be passed without wounding the artery. Advantage is taken
of this fact in disarticulating the head of the femur in amputation at the hip-joint.
The femoral artery, which is slightly tortuous when the thigh is flexed upon the pelvis,
becomes straight when the limb is extended, and it is much stretched during forcible ex-
tension.
Relations. — In front, the femoral artery lies beneath the fascia in the triangular space
which is bounded on the inside by the inner border of the adductor longus ; on the out-
side, by the sartorius ; and above, by the femoral arch. Lower down, the sartorius is
placed between the fascia and the artery, which is in relation, first, with the inner bor-
der, then with the posterior surface, lastly, with the outer border of that muscle : besides
the fascia, a number of lymphatic glands lie between the upper part of the artery and
the skin. Enlargement of one or more of these glands has been mistaken for an aneu-
rism, and an aneurism for an enlarged gland. From these relations of the front of the
femoral artery, it foUoivs that its anterior aspect may be exposed in the whole of its ex-
tent, but that it is more superficial in the neighbourhood of the crural arch.
Behind, the femoral artery rests, first, upon the body of the pubes, or the ilio-pectineal
eminence, with which it is in immediate contact in emaciated subjects, but from which
it is generally separated by the contiguous borders of the psoas-iliac and the pectineus
muscles. The iliac fascia separates it from the psoas-iliac muscle, so that, in cases of
simple psoas abscess, or congestive abscess from caries of the lumbar vertebrae, the fem-
oral artery is situated in front of the sac of the abscess. The femoral artery is also in
relation, behind, with the head of the femur ; lower down, with the pectineus, and then
with the adductor longus. It follows, therefore, that the femoral artery may be very
eflfectually compressed at its upper part, since it is superficially situated, and rests upon
hard parts.
On Ike outer «ie, it is in relation, first, with the psoas-iliac, then with the inner border
4B
562 ANGEIOLOGY.
of the sartorius, and, lastly, with the vastus internus, which separates it from the inner
surface of the femur.
In consequence of this relation to the bone, and also of the slight thickness of the sar-
torius, which separates it from the skin, the femoral artery may be compressed against
the femur from within outward in the middle third of the thigh.
On its inner side, it is in relation with the pectineus, the adductor longus, and afterward
with the outer border of the sartorius.
Relations of the Artery with the Vein and Nerves. — The femoral vein is situated on the
inner side of the artery above, but it soon passes behind it, and, still lower down, is on
its outer side. The crural nerve lies on the outer side of tlie artery, from which it is
separated by a fibrous layer belonging to the sheath of the psoas and iliaeus. The artery
and nerve, therefore, have no immediate relation with each other ; but the internal or
long saphenous nerve soon runs upon the sheath of the femoral vessels, and is situated
on the outside of the artery ; but as the vessel is passing through the tendon of the ad-
ductor magnus, the nerve leaves it, and, lower down, escapes from under the tendon of
the sartorius. The short saphenous nerve, or nerve of the internal vastus, is in relation
with the outer side of the artery for a short distance, and the vessel is also crossed by
another small nerve.
The Sheath of the Femoral Vessels. — ^The femoral artery and vein are enclosed in a proper
fibrous sheath, which is constructed, as it were, in the midst of the muscles of the thigh
(see Aponeurology). It is, therefore, necessary to open this sheath, and not that of
any of the surrounding muscles, in order to expose the artery.
Anatomical Varieties. — Independently of the very frequent and remarkable anatomical
varieties in the origin of the deep femoral artery, which is often given off opposite, and
sometimes above the femoral arch — varieties to which I shall immediately refer in speak-
ing of the deep femoral artery — ^the common femoral artery itself offers some varieties
which are not less interesting. The most important is the following, found in a prep-
aration deposited by M. Manec in the museum of Clamard : In this preparation, the fem-
oral artery presents behind the Fallopian ligament a caliber which is not larger than that
of the radial artery, and is lost in the anterior muscles of the thigh. The ischiatic ar-
tery, which is a branch of the hypogastric, presents, on the contrary, the caliber of the
femoral artery, descends backward along the great sciatic nerve, and is continuous with
the popliteal artery. During its course along the thigh, the ischiatic artery gives off the
muscular branches which generally come from the deep femoral artery.
Collateral Branches. — The collateral branches of the femoral are, the superficial epigas-
tric artery, the two external pudic arteries, a great number of muscular branches, and the
deep femoral artery.
The Superficial Epigastric Artery.
The superficial epigastric or sub-cutaneous abdominal artery (cut across at b,fig. 214)
is a very small, but remarkably constant branch, which arises from the front of the
femoral, and sometimes from the external pudic, immediately below the crural arch,
passes vertically upward, between the integuments and the superficial fascia, gives some
branches to the inguinal lymphatic glands, and terminates in the skin, near the umbili-
cus (arteria ad cutem abdominis, Haller).
The External Pudic Arteries.
The external pudic or genital arteries, also named scrotal in the male, and vulvar in the
female, arise from the inner side of the femoral : they are two in number (c c, fig. 214),
and are named the superior or sub-cutaneous, and the inferior or sub-aponeurotic.
The superior or sub-cutaneous arises immediately below the crural arch, passes trans
versely inward in the sub-cutaneous cellular tissue, and divides into two branches : a
superior, which passes to the pubic eminence, and an inferior, which is distributed to
the skin of the penis and scrotum in the male, and to the corresponding external labium
in the female. I have seen the dorsal artery of the penis arise from this vessel.
The inferior or sub-aponeurotic branch arises a little below the preceding, and some-
times even from the deep femoral ; it passes transversely inward, crosses the femoral
vein at right angles immediately below the point where it is joined by the saphenous
vein, so that this artery is generally received in the loop described by the upper end of
the saphenous vein : it soon perforates the fascia and becomes sub-cutaneous, and then
ramifies in the scrotum in the male, and in the external labium in the female. The
anastomoses of the superior and inferior external pudics, both with each other and with
those of the opposite side, are so free and large, that when one of them is cut across, it
becomes necessary to tie both of the cut ends of the vessel. These arteries are re-
Tnarkable on account of their relations with hernial tumours.
The Muscular Arteries.
The femoral gives off a great number of muscular and cutaneous branches, which have
received no particulai names. One, however, is usually described as the superficial m
THE DEEP FEMORAL ARTERY. 563
greax muscular artery, which frequently arises from the deep femoral ; it passes trans-
versely between the sartorius and the rectus femoris, and immediately divides into as-
cending branches, which proceed to the iliacus, sartorius, and tensor vaginee femoris, and
into very large descending bra?iches, some of which are distributed to the rectus fem-
oris, passing in at its posterior surface, while others penetrate the vastus internus and
vastus externus. The last-mentioned branches can be traced as far as the lower part
of the triceps muscle ; and, indeed, the great muscular artery might be named the mus-
cular artery of the triceps extensor femoris, which ig,fig. 214) may arise from the deep
femoral artery.
The Deep Femoral Artery.
The deep femoral artery {profunda femoris ; d d', fig. 214.) is intended to supply the
muscles and integuments of the internal and posterior regions of the thigh.*
It arises from the back of the femoral, generally about one and a half or two inches
below the crural arch, about half way between the pubes and the lesser trochanter, very
rarely below this point, but more commonly above it. Thus the femoral often divides,
either about six lines below the crural arch, or immediately beneath and on a level with
it, into two equal and parallel branches, of which the external is the deep femoral, and
the internal the femoral properly so called. I have seen this subdivision, which bears a
rather close analogy to the bifurcation of the humeral artery into the radial and ulnar
in the axilla, take place above the crural arch, that is to say, in the external iliac artery.
Immediately after its origin, the deep femoral passes backward and outward, and then
vertically downward, gradually approaching the femur ; it is situated deeply behind the
femoral artery, but is separated from it by the femoral and deep femoral veins ; it runs
parallel to th'fe femoral artery, in front of the pectineus, and on the outer side of the vastus
internus ; having reached the upper border of the long adductor, it passes behind that
muscle to arrive between it and the short and great adductors, perforates the latter mus-
cle a little below the tendinous opening for the proper femoral artery, and terminates by
ramifying in the biceps and semi-membranosus. Sometimes the deep femoral perforates
the adductor magnus almost immediately, and at once becomes posterior to it.
Varieties of Origin. — In the history of the deep femoral artery, the varieties in its origin
are most important, considered in a surgical point of view.
The common femoral artery is very often divided prematurely into two equal and
parallel branches, the external of which is the deep femoral, and the internal the true or
superficial femoral artery, t This premature division may take place at a distance of
six lines below the crural arch, opposite this arch, or even beneath it. I have seen this
division, which bears a resemblance to the high division of the humeral artery into the
radial and ulnar arteries in the hollow of the axilla, to take place above the femoral arch,
consequently at the expense of the external iliac artery. Bums has seen this division
taking place in the pelvis three times ; Tiedemann, who has observed it on both sides,
thinks that it is only met with in small-sized individuals. In a case which Professor
Dubreuil has communicated to me, where the right femoral artery was divided higher
than usual, the epigastric artery, instead of being given off by the external iliac, came
from the deep femoral, and the anterior circumflex iliac artery came from the superficial
femoral artery.
In another case which has been furnished to me by the same observer, the external
iliac or femoral artery, in its passage below the crural arch, was divided into three branch-
es : the external branch was the superficial muscular, the internal branch was the deep
muscular, which, immediately after its origin, dipped between the muscles ; the middle
branch, which was of a larger size than the two others, was the true femoral artery.
The only anomalies in this case were in the origin of the branches ; in their distribution
they were as usual.
During its course, the deep femoral gives off a great number of collateral branches,
which are soon expended in the adjacent muscles, and most of which are unnamed.
Those that are named are the internal and external circumflex, and the several f erf orating
arteries.
The internal circumflex artery (e) is larger than the external, and is the first branch
given off from the deep femoral ; not unfrequently it arises from the femoral. I have
observed, however, that this only takes place when the deep femoral artery arose a lit-
tle lower down than usual. In a case of this kind, the origin of the deep artery took place
* It is the proper artery of the thigh, while the femoral itself may be regarded as the artery of the leg and
foot.
t This relation is the one which always exists when the deep femoral artery arises opposite or above the
femoral arch ; the deep femoral passes down close by the external side of the superficial femoral ; this latter
covers the vein : if, in a case of this kind, the femoral artery were to be tied, and the ligature were applied
only to one vessel, it would be to the deep artery, which holds the relations that generally belong to the trunk
of the femoral artery itself.
Tn a case exhibited at the Anatomical Society by M. Mercier, the deep femoral, which arose from the ante-
rior side of the common femoral six lines below the arch, descended downward before the feiii ral vein, which
it crossed opposite the opening for the scaphena vein, turned round this vessel to become the c<;f\i artery, and
coursed along as usual. In this case, the deep femoral gave off the external pudic iirteries
564 ANGEIOLOGY.
more than two inches below the femoral arch. Sometimes the internal circamflex comes
from the external iliac artery. Whatever may be its origin, it almost immediately dips
backward, between the pectineus and the neck of the femur, round which it turns in the
same manner as the posterior humeral circumflex artery, so that it may be ruptured in
luxation of the femur inward : it escapes backward beneath the quadratus femoris, and
terminates by dividing into ascending branches, and into internal and external descend-
ing branches.
Opposite the pectineus, it gives off the following collateral branches : cae very re-
markable articular branch ascends along the capsular ligament, enters the hip-joint, passes
under the ligament which converts the cotyloid notch into a canal, and is distributed to
the synovial membrane, the adipose tissue, and the fibrous capsule of the joint : one or
more anastomotic branches communicate freely with the ramifications of the obturator
artery ; lastly, a great number of muscular branches, some of which are very small, and
pass in front of, while others, which are larger, run behind, the pectineus, and are distrib-
uted to the obturator externus, the pectineus, and the adductors : the largest is intended
for the adductor magnus.
The terminal branches are as follows : Ascending muscular branches, some of which are
external, and ramify in the glutaeus maximus, while others are internal, and are dis-
tributed to the ischiatic attachments of the biceps, semi-tendinosus, and semi-membra-
nosus muscles ; descending muscular branches, which ramify upon the anterior surface
of the biceps, semi-tendinosus, and semi-membranosus, upon the great sciatic nerve,
and also in the small muscles situated between the pelvis and the trochanter major ;
periosteal branches, of which some ramify upon the periosteum of the trochanter, other&
upon the posterior surface of the neck of the femur ; and, lastly, anastomotic branches,
which pass upon the obturator, gemelli, and pyriformis muscles, and anastomose freely
with the sciatic, glutaeal, internal pudic, and obturator arteries, but especially with the
sciatic and the obturator.
It follows, then, that the internal circumflex is an important means of communication
between the internal Uiac, and, consequently, the common iliac and the femoral ; for,
independently of the direct anastomoses above mentioned, there are a great number of
indirect communications in the substance of the muscles and upon the periosteum.
The external or anterior circumflex (/), smaller than the internal, sometimes arises di-
rectly from the femoral ; it is often given off from the profunda by a common trunk with
the great muscular artery of the triceps, and it may then be regarded as fonned by the
bifurcation of the profunda : it passes horizontally behind the rectus femoris, crossing
in front of the psoas and iliacus, to which it gives a rather large vessel, and then divides
into two branches : an ascending muscular, Avliich is distributed to the glutaeus minimus
and to the tensor vaginse femoris ; and a circumflex branch, properly so called, which
turns round the base of the great trochanter {f,flg. 215), dips into the substance of the
triceps, and expands into a great number of ascending branches, which anastomose w ith
the internal circumflex upon the outer surface of the great trochanter. Not unfrequent-
ly, an anastomosis is formed in front by a transverse branch between the internal and ex-
ternal circumflex arteries, by which the arterial circle of the hip-joint is completed.
The perforating arteries (r r,fig. 214) are both muscular and cutaneous, and are intend-
ed for the posterior region of the thigh : they vary in number from one to four, and are
all distributed in a similar manner. They perforate the tendinous attachments of the
adductor muscles to the femur, and, having reached the back of the thigh, they turn
horizontally round the bone, and divide into ascending and descending branches, which
form a series of loops or anastomotic arches in the substance of the muscles ; these
loops acquire a great size in cases where the femoral has been tied after Hunter's meth-
od, i. e., in the middle third of the thigh.
The first perforating artery {r,fig. 215), which is the largest, and sometimes repre-
sents two, or even the whole of the perforating arteries, passes through the great ad-
ductor about one inch below the lesser trochanter, between the horizontal and oblique
fibres of the muscle ; its ascending branch («) turns round the great trochanter, and anas-
tomoses with the internal circumflex and sciatic in the substance of the glutaeus maxi-
mus ; its descending branch (Z) is distributed to the vastus externus, the semi-tendinosus,
semi-membranosus, biceps, and adductor magnus muscles. Some branches ramify upon
the great sciatic nerve.*
I have seen an inferior perforating artery arise from the femoral, just where it passed
through the tendon of the adductor magnus.
The terminal branch (d',flg. 214) of the deep femoral constitutes the last perforating
artery, which is distributed in the same manner as the other arteries of that name.
The Popliteal Arteky.
When the femoral artery has perforated the tendinous portion of the adductor magnus,
it takes the name of the popliteal artery, which extends down to its division into the an-
terior tibial and tibio-peroneal arteries.
* The principal nutritious artery of the femur arises from the first or second perforating artery.
THE POPLITEAL ARTERY.
ffe
The popliteal artery {o,figs. 215, 217) is the artery of the ham or popliteal space ; it
Fig. 215.
is bounded above (p,fig- 215) by the tendinous ring formed
in the adductor niagnus, and below (p, fig. 217) by the low-
er border of the popliteus muscle, at which place it is sit-
uated opposite the lower end of the upper fourth of the
leg.* Its length in an adult subject is about seven inches.
It passes vertically, or somewhat obliquely outward and
downward, the direction of the artery being represented
by a line extending from the inner surface of the femur to
the space between its two condyles. It is tortuous when
the leg is flexed upon the thigh, but it becomes straight
when the leg is extended, and may be ruptured by very
forcible extension. It has been proved by experiment,
that extension may be carried as far as to cause lacera-
tion of the ligaments of the joint, without rupturing the ar-
tery, t
Relations. — It is situated deeply in the whole of its
course, and it is in relation, behind, with the semi-mem-
branosus above ; lower down, with the popliteal fascia,
from which it is separated by a layer of fat of greater or
less thickness, according to the prominence of the ham-
string muscles ; below this, with the gastrocnemius and
plantaris muscles ; and still lower, with the soleus. The
popliteal vein lies behind and slightly to the outer side of
the artery, and then behind it, adhering rather firmly to
it. The internal popliteal nerve also lies upon it behind,
but is separated from it by a very thick layer of fat. The
veins and nerves both cross the artery beneath the gas-
trocnemius, so as to get to the inner side of the lower
portion of the vessel.
From these relations, it follows that the popliteal artery
may be exposed from behind in the whole of its extent,
but that it is deeper seated below than above.
hi front, it is in relation, from above downward, with
the adductor magnus ; with the internal surface of the fe-
mur, which appears to be expanded and become posterior,
so as to support the vessel ; with the knee-joint, with
which it is in direct contact ; and, lastly, with the popli-
teus muscle. The direct relation of the popliteal artery with the joint explains the fa-
cihty with which it may be lacerated when its tissue has been rendered fragile from or-
ganic change, and accounts for the frequency of aneurism in this region.
On the inner side, this artery is in relation with the semi-membranosus, the inner con-
dyle of the femur, and the inner head of the gastrocnemius.
On its outer side, it has the biceps, the outer condyle, the outer head of the gastroc-
nemius, and also the plantaris and soleus muscles.
Collateral Branches. — The popliteal artery gives off- from its posterior aspect several
small branches, which pass into the muscles of the ham ; most of them are not named ;
but there are some which are distinguished as the sural arteries : in front it gives sev-
eral arteries, named articular, because they surround the knee, like the collateral arter-
ies of the elbow-joint. The articular arteries are divided into superior, middle, and in-
ferior ; the superior and inferior would have been better named the collateral arteries of
the knee.
The sural arteries {g g,fig*- 215, 217) are two in number: one internal, for the innei
head of the gastrocnemius, and the other external, for the outer head of the same muscle.
Arising from the back of the popliteal artery, they pass downward and backward, are
separated from each other by the internal popliteal nerve, enter the anterior and inter-
nal surface of each head of the gastrocnemius a little before the two heads meet, and
may be traced down to the lower part of the fleshy belly of that muscle. Generally one
of their branches accompanies the external saphenous nerve from the popliteal space to
the upper part of the tendo Achillis.
The superior articular or collateral arteries of the knee are divided into internal and
external.
The internal superior articular arteries are sometimes three, but most commonly two
in number, one of which arises higher than the other ; their origin is subject to variety,
* The divisioa of the popliteal artery takes place sowetiraes higher, sometimes lower than usual. In a case
■where its bifurcation was premature, the anterior tibial has been seen passing between the popliteus muscle
and the posterior face of the til)ia.
t I have had an opportunity of observing a case of luxation of the knee, with complete laceration of the
crucial ligaments, where the popliteal artery was left entire.
566 ANGEIOLOGY.
but they are constant in their distribution. We sheill distinguish them as the first and
second.
The first internal superior articular artery, usually called the great anastomotic artery
of the knee, is the largest of the whole : it arises opposite the point where the femoral
becomes the popliteal artery, and sometimes even from the lower part of the femoral it-
self; it perforates the adductor magnus from behind forward, and immediately divides
into four descending branches: the first is a muscular branch {i,fig. 214), which enters
the substance of the vastus internus, passes inward and downward to reach the inner
border of the tendon of the triceps, and, opposite the base or upper border of the patella,
perforates the fibres of the muscle, becomes superficial, and runs transversely outward
along the base of the patella, and forms an anastomotic arch with the external superior
articular artery. The second and third branches are periosteal ; one of them passes be-
tween the triceps and the femur, with which it is in contact, and terminates above the
trochlea of that bone by anastomosing (at s) with the external superior and the second
internal superior articular arteries ; while the other runs along the adductor magnus,
being held down against it by a layer of fibrous tissue, and anastomoses with tlie second
internal superior articular artery, supplying its place when that vessel is only in a rudi-
mentary state. The fourth branch (A) accompanies and supplies branches to the inter-
nal saphenous nerve : it appears to be constant ; it is placed under the sartorius, along
which it runs, together with the internal saphenous nerve, continuing with it below that
muscle.
The second internal superior articular artery {h,figs. 215, 217) arises immediately above
the inner condyle of the femur, turns round it horizontally, and divides into condyloid
branches, which cover the condyles with their ramifications, and communicate partly
with the first internal superior articular artery, and partly with the external superior ar-
ticular artery coming from the opposite side. It also gives off a patellar branch, which
runs upon the borders of that bone, supplies the skin and the synovial membrane of the
knee-joint, and anastomoses with the internal inferior articular artery.
The external superior articular artery {i,figs. 215, 217) arises opposite the second in-
ternal superior, turns horizontally round the outer condyle of the femur, gives off some
ascending muscular branches, which ramify in the vastus externus, and then terminates
in three periosteal branches. One, which is superior and transverse, turns round the
lower end of the femur, and anastomoses with the corresponding branch of the second
internal superior articular ; another and inferior branch ramifies upon the inner condyle,
and anastomoses freely by a great number of branches with the external inferior articu-
lar ; the third is a more superficial branch for the patella, on the side of which bone it
runs, and near its upper border gives off a transverse twig, which anastomoses on the
upper border of the patella with a similar one from the internal superior articular arter-
ies, and a descending twig, which runs along the outer border of the bone, and anasto-
moses with the external inferior articular artery.
The inferior articular or collateral arteries of the knee are also divided into the internal
and the external. They both arise from the front of the popliteal artery, opposite the
middle of the knee-joint.
The internal inferior articular artery {c,fig. 217) runs downward and inward, and, hav-
ing reached the internal tuberosity of the tibia, turns horizontally forward, passes be-
neath the tendons of the semi-teHdinosus, semi-membranosus, and gracilis muscles, and
also beneath the internal lateral ligament of the knee, turns upward upon the inner side
of the anterior tuberosity of the tibia and ligamentum patellaj, describing a curve with
its concavity directed upward, and anastomoses either with the superior articular arter-
ies or with the anterior tibial recurrent. During its course it gives off ascending and
descending periosteal and osseous branches.*
The external inferior articular artery {b,fig. 217) arises opposite the internal vessel,
turns horizontally forward, not upon the external tuberosity of the tibia (for this is pre-
vented by the tibio-fibular articulation), but upon the convex borders of the external
semilunar cartilage, passes beneath the tendon of the biceps and the external lateral
ligament of the knee-joint, and terminates by dividing into an ascending branch, which
runs upward along the outer border of the patella, a descending branch, which anasto-
moses with the anterior tibial recurrent, and a transverse branch, which passes behind
the ligamentum patellae below the patella, and anastomoses with a similar branch from
the internal inferior articular. The inferior articular arteries complete the arterial circle
which surrounds the patella, and from which numerous branches are given off, some
covering the patella by their anastomoses, and others entering the bone directly through
the numerous foramina which exist upon its surface.
The middle articular arteries (*, fig. 215) consist of several small branches, which arise
directly from the front of the popliteal artery, or from the external inferior articular, run
from behind forward into the interior of the knee-joint, and are distributed in the inter-
condyloid notch to the crucial ligaments, the adipose tissue, the synovial membrane, and
* By osseous branches I mean those which enter the bone directly through the foramina, on the internal
and external tuberosities of the tibia.
THE ANTERIOR TIBIAL ARTERY.
567
especiaDy to the lower extremity of the femur, which they penetrate through the large
foramina on the adjacent surface of each condyle. The middle articular artery or arter-
ies belong, therefore, to the knee-joint exclusively, and do not assist in the restoration
of an impeded circulation : in this respect they differ entirely from the other articular
arteries, which acquire a very considerable size when the principal trunk has been tied.
The Anterior Tibial Artery.
Opposite the lower border of the popliteus muscle, the pophteal artery divides into
two branches : an anterior, named the anterior tibial {a, Jig. 217) ; and a posterior, which
forms the continuation of the popliteal, and may be denominated the tibio-peraneal trunk
(/). This trunk soon subdivides into the posterior tibial (t) and the peroneal {k) arteries.
The anterior tibial artery {a, Jigs. 216, 217), the anterior branch of the bifurcation of
the popliteal, terminates opposite the dorsal annular ligament of the Fig. 216.
tarsus (J), Jig. 216), below which the vessel is named the dorsal artery
oj the foot (/). Immedidtely after its origin, it passes horizontally
forward, perforates the upper part of the interosseous ligament, is re-
flected over it, and descends vertically in front of it ; having reached
the lower fourth of the leg, it is directed somewhat obliquely inward,
following the direction of the external surface of the tibia, and then
passes under the annular ligament, at the lower border of which, as
stated, it terminates.
A line stretched from that process of the tibia, which has been de-
scribed as the tubercle of the tibialis anticus (Osteology, p. 278), to
the middle of the tibio-tarsal articulation, will indicate its direction
and course.
Relations. — The anterior tibial artery is situated very deeply, and
yet it can be exposed at any point ; it is in relation, behind, with the | f
interosseous ligament in its three upper fourths, and with the tibia in
its lower fourth ; it lies in contact with the interosseous ligament,
and is retained in its place by a layer of fibrous tissue, so that, after
amputation of the leg, it retracts between these two fibrous layers,
and is sometimes seized and tied with difficulty.
In front, it is covered successively by the tibialis anticus, the ex-
tensor longus digitorum, and the extensor proprius poUicis, the ten-
don of which crosses over it ; it is placed exactly along the cellular
interval between the tibijdis anticus and the extensor muscles ; and
the incision should, therefore, be made along the line corresponding
to that interval, in order to expose the artery when it is to be tied ;
lower down it is only separated from the skin by the fascia of the leg
and the projecting tendon of the extensor proprius pollicis, and hence
it may be compressed in this situation. UiPS?iiif <i
On the inner side, it is in relation with the tibialis anticus, then with
the tibia, and, lastly, with the tendon of the extensor pollicis, being
lodged in the same sheath-
On its outer side, it has the extensor longus digitorum, then the ex-
tensor pollicis, both of which afterward cross over it ; and, lastly, it
has only the fascia of the leg : the anterior tibial nerve runs along the
outer side of the artery in its whole extent.
Its collateral branches are very small and numerous, and are distrib-
uted to the muscles and the skin. Among them, the anterior tibial
recurrent, and the external and internal malleolar, require special notice.
The anterior tibial recurrent artery (c,Jig. 216) is sometimes of considerable size ; it
arises from the tibial, after that vessel is disengaged from the interosseous ligament,
passes obhquely upward and inward between the tibialis anticus and the external tuber-
osity of the tibia, with which it is in contact, and expands into diverging, periosteal, and
articular branches, some of which ascend and anastomose with the external inferior ar-
ticular of the knee, while others pass transversely, and anastomose with the internal in-
ferior articular. I have seen the anterior tibial recurrent, of large size, run transversely
below the patella, and terminate upon the internal tuberosity of the tibia.
The malleolar, which would be more correctly named articular arteries, are divided
into the internal and external.
The internal malleolar or articular artery (d) arises opposite the dorsal annular ligament
of the tarsus, passes transversely inward under the tendon of the tibialis anticus, and di-
vides into two branches : a deep, or articular, which dips perpendicularly into the ankle-
joint, and is distributed to that articulation; and a superjicial, or malleolar, properly so
called, which passes above the malleolus, and is distributed upon it, on the inner side
of the tarsus, as far as the internal plantar region, where it anastomoses with the branch-
es of the internal plantar artery.
The external malleolar or articular artery (I), larger than the preceding, vart-s much in
568 ANGEIOLOGY.
its origin. Thus, it sometimes arises under the dorsal ligament of the tarsus, opposite
the internal malleolar ; it often arises from the tibial, about two or three inches above
the annular ligament. Sometimes it is derived from the posterior peroneal artery, and
perforates the lower part of the interosseous ligament. Lastly, and most commonly,
it arises by two roots ; one of which is small, but variable in size, and is derived from the
peroneal, while the other is larger, and is given off from the anterior tibial.
These differences of origin affect the course of the artery. When it arises under the
Ugament of the tarsus, it passes transversely outward, and then turns in front of the ex-
ternal malleolus to run forward, resting upon the tarsus. It receives the branch from
the posterior peroneal at the point where it changes its direction. In those cases where
it arises higher, it passes obliquely downward, in front of the external malleolus, and
then upon the outer side of the astragalus. In all cases, the external malleolar artery
runs forward on the outer side of the cuboid bone, and forms an anastomotic arch with
the dorsjd artery of the tarsus. It is in contact with the booes througliout its course,
and is crossed by the tendon of the extensor longus digitonim : it gives off malleolar
branches, which ramify upon the outer surface of the external malleolus ; very large ar-
ticular branches, which dip into the tibio-tarsal articulation ; and one, which I would es-
pecially notice, that enters the deep fossa between the astragalus and os calcis ; and,
lastly, external calcaneal branches, which pass under the tendons of the peroneus longus
and peroneus brevis, and ramify upon the outer side of the os calcis, where they termi-
nate by anastomosing with the peroneal artery, and with some branches of the external
plantar. Several of these branches are reflected upon the upper surface of the os calcis in
front of the tendo Achillis, and anastomose with branches from the posterior tibial artery.
The Dorsal Artery of the Foot.
The dorsal artery of the foot {dorsalis pedis, f,Jig. 216) is the continuation of the an-
terior tibial, which takes this name after emerging from below the dorsal annular liga-
ment of the tarsus ; it terminates in the sole of the foot, by becoming continuous with
the plantar arch. Not unfrequently this artery arises by two roots, one of them being
formed by the anterior tibial, which is much smaller than usual, and is, as it were, ex-
hausted near the ankle, and the other by the peroneal, which is then very large, and per-
forates the lower part of the interosseous ligament. In a few rare cases, the anterior
tibial is entirely wanting, and is represented by some small perforating branches from
the posterior tibial or the peroneal ; the dorsal artery of the foot is then wholly derived
from the peroneal.
The size of the dorsal artery of the foot is also subject to variety; it generally bears
a direct proportion to that of the anterior tibial, which I have seen as large as the poste-
rior tibial and peroneal arteries together, while it has an inverse ratio to that of the two
last-mentioned vessels combined.
The dorsal artery runs horizontally and directly forward upon the dorsum of the foot,
as far as the posterior extremity of the first interosseous space, at which point it bends
downward at a right angle, perforates that space like a perforating artery, and termi-
nates by becoming continuous with the plantar arch.
The direction of the dorsal portion of this artery is marked by a line extending from
the middle of the tibio-tarsal articulation to the posterior extremity of the first interos-
seous space.
Relations. — It lies in contact with the bones of the tarsus, in which position it is re-
tained by a layer of fibrous tissue. It is separated from the skin by the fascia of the
foot, and also anteriorly by the inner portion of the extensor brevis digitorum. It runs
along the outer side of the tendon of the extensor proprius pollicis, which projects so as
to raise the integuments from the vessel ; it may be exposed in its entire length by cut-
ting along the outer border of that tendon. It is not uninteresting to remark that, un-
der the dorsal ligament of the tarsus, this artery is situated in the same sheath as the
tendon of the extensor proprius pollicis.
Its collateral branches are internal and external.
The internal branches are numerous, but are not named ; they ramify upon the inner
side of the tarsus, and anastomose upon the inner border of the foot, either with each
other, with the internal malleolar arteries, or with the internal plantar artery. One of
them may be described under the name of the internal tarsal artery, a branch which
has a remarkable course : it passes obliquely forward and inward as far as the posterior
extremity of the first metatarsal bone, and is sometimes continued along the inner side
of that bone to form the internal collateral artery of the great toe ; at other times it is
reflected under the first metatarsal bone, and anostomoses directly with the internal
plantar artery, after having given off a great number of branches to the inner side of the
metatarso-phalangal articulation of the great toe.
Among the external branches there are two which require particular description, viz.,
the dorsal artery of the tarsus, or the external tarsal, and the dorsal artery of the metatarsus
or the metatarsal artery.
The external tarsal artery {g) varies in its size, which almost always bears an inverse
THE TIBIO-PERONEAL ARTERY.
569
proportion to that of the external malleolar and metatarsal arteries. I have seen it as
large as the dorsal artery of the foot, by the bifurcation of which vessel it appeared to be
formed.
It passes transversely outward under the extensor brevis digitorum, anastomoses
freely with the external malleolar artery, and gives off the following branches : some
which ramify upon the outer side of the os calcis, and anastomose with the peroneal ; a
branch which runs upon the cuboid bone, sometimes being so large as to be regarded
the continuation of the artery, and then passes under the sole of the foot to anastomose
with the external plantar ; and, lastly, some branches in front, which anastomose with
the metatarsal artery, the place of which vessel it sometimes partially supplies, by giv-
ing off the dorsal interosseous arteries. In one case, where the external tarsus artery
was very large, it passed transversely outward as far as the outer surface of the cuboid
bone, was reflected backward on the outer surface of the calcaneum, and there anasto-
mosed very freely with the external malleolar and the peroneal arteries. In another
case, the external tarsal artery divided into two branches, one of which ran transversely
outward and reached below the sole of the foot, while the other formed the dorsal inter-
osseous artery of the fourth interosseous space.
The metatarsal artery (h) generally arises from the front of the dorsal artery of the
foot, opposite the posterior extremity of the first interosseous space, sometimes by a
common trunk with the external tarsal just described. According to the most regular
distribution, it passes transversely outward, opposite the posterior extremities of the
several metatarsal bones, and constitutes the dorsal arch of the metatarsus (?).
Three branches given off from the convexity of this arch, which is directed forward,
are named the dorsal interosseoas arteries {I I). They run along the dorsal surface of the
second, third, and fourth interosseous spaces, and having arrived opposite the metatarso-
phalangal articulations, divide into two collateral branches for the corresponding toes.
During its course along its own interosseous space, each dorsal interosseous artery re-
ceives two perforating branches, viz., a posterior perforating artery, opposite the posterior
extremity of the interosseous space, and an anterior perforating, opposite the anterior ex-
tremity of the same space. This explains the otherwise sin-
gular fact, that the dorsal interosseous arteries are increased
in size opposite the posterior and anterior extremities of their
respective spaces. In some subjects, the dorsal interosseous
arteries are derived exclusively from the perforating arteries.
It is not very rare to find the metatarsal and the dorsal inter-
osseous arteries wanting ; their places are then supphed by the
plantar interosseous arteries.
The dorsal interosseous artery of the first interosseous space (n)
is given off directly from the dorsal artery of the foot, at the
point where that artery dips into the first interosseous space ;
it is larger than the other dorsal interosseous arteries, but is
distributed in a similar manner.
The dorsal interosseous artery of the second space is also
rather frequently derived directly from the dorsalis pedis.
The Tibio-peroneal Artery.
'* The tihio-peroneal artery or trunk (^f,fig- 217), the posterior
branch of the bifurcation of the popliteal artery, is bounded
above by the origin of the anterior tibial, and below by its sub-
division into two branches, viz., the posterior tibial (Z) and the
peroneal (^■). It is from one inch to eighteen lines in length,
sometimes it is not more than six lines, and it may be two or
even three inches ; I have seen it extend as low as the inner
part of the os calcis, where it divided into the internal and ex-
ternal plantar arteries.* '
It forms the continuation of the popliteal in regard to direc-
tion, and is in relation with the soleus behind and the muscles
of the deep layer in front ; the posterior tibial nerve crosses
behind to get to its outer side below.
The collateral branches of the tibio-peroneal artery are, first,
an internal recurrent branch, which perforates the soleus from
behind forward, turns round upon the inner border of the tibia,
is reflected upward, and anastomoses with the internal inferior
articular artery upon the internal tuberosity of that bone ; sec-
ondly, the nutritious artery of the tibia (s) ; and, lastly, a single
large branch, or several branches, to the soleus muscle, which
* M. Dubreuil has communicated to me n case in which the tibio-peroneal trunk continued undivided al'
along the posterior face of the peroneus, and gave off the posterior tibial artery only at the lower part of the leg
4 0
';:StO .'/J?.-.' ANGEIOLOGY.
they enter near its peroneal attachments, and then anastomose with the anterior tibial
and the external inferior articular. When the tibio-peroneal artery is short, the branch
to the soleus is derived from the peroneal artery.
The Peroneal Artery.
The peroneal artery (i) extends from the bifurcation of the tibio-peroneal trunk to the
OS calcis. It is generally smaller than the posterior tibial, and even than the anterior
tibial, and bears an inverse proportion to the size of the two, more particularly to that
of the anterior tibial, the place of which it often partially supplies. In some cases it is
itself replaced by some small branches derived from the posterior tibial.*
It descends vertically along the posterior surface of the fibula, from which it is separ-
ated by the flexor longus pollicis ; it is covered by the soleus, and dips below between
the flexor longus pollicis and the tibialis posticus, to reach the interosseous ligament, at
the lower part of which it divides into a posterior and an anterior branch.
Its collateral branches are, first, posterior ones, which are very numerous, and supply
the soleus ; the highest of these are of considerable size, and often arise from the tibio-
peroneal artery. Secondly, there are internal and external branches, which pass to the
deep-seated muscles of the leg : among the external branches is the nutritious artery of
the fibula ; and among the internal branches a transverse or oblique anastomotic twig
may be specially noted, which extends from the peroneal to the posterior tibial. Some-
times this anastomotic branch is very large, and, in that case, the posterior tibial is more
slender than usual up to that point, but increases in size after receiving this addition,
and afterward gives off the plantar arteries.
Terminal Branches. — The anterior terminal branch, named the peroneal perforating, oi
the anterior peroneal artery {g,fig. 216), perforates the lower part of the interosseous lig-
ament, descends upon the lower end of the tibia, and anastomoses with the external
malleolar artery, which is sometimes formed by it. This peroneal perforating branch,
which is generally very small, is sometimes as large, or even larger, than the posterior
branch, and then supplies the place of the lower part of the anterior tibial, and forms the
dorsal artery of the foot ; the anterior tibial is then very small. There almost always
exists a trace of this distribution in the presence of a small branch, which anastomoses
with the anterior tibial.
The posterior terminal branch (I, Jig. 217) of the peroneal artery, which might be called
the external calcaneal, forms the continuation of that vessel, and gains the posterior as-
pect of the external malleolus, to which it is applied, after running along the outer bor-
der of the tendo Achillis, being separated from the skin by the fascia of the leg and an-
other layer of fibrous tissue. It gives off to its inner side, opposite the posterior border
of the lower end of the tibia, a transverse branch, which anastomoses with the posterior
tibial artery. It then ramifies upon the outer surface of the os calcis, supplies the cal-
caneal attachments of the muscles of the sole of the foot, and also the skin of the heel,
and anastomoses with the external malleolar, and also with the external plantar artery.
Some small ascending branches pass above the os calcis, and anastomose in front of the
tendo Achillis with corresponding branches of the posterior tibial. I have seen the ev
ternal calcaneal artery derived from the posterior tibial.
The Pbsterior Tibial Jlrtery.
The posterior tibial artery (t, Jig. 217) is the internal branch of the bifurcation of the
tibio-peroneal artery or trunk, and having entered a groove on the os calcis, beneath the
internal annular ligament of the tarsus {t,Jig. 218), terminates by dividing into the inter-
nal (a) and the external {b) plantar arteries. It is larger than the other arteries of the leg,
and is generally inversely proportioned to the anterior tibial and the peroneal. Thus, in
a subject in which the anterior tibial and the dorsal artery of the foot were very large,
the posterior tibial and the internal plantar were scarcely one third of their ordinary size.
The posterior tibial artery is at first directed obliquely inward, and then vertically
downward ; and it is in relation, in front, with the tibialis posticus ; lower down, with the
flexor communis digitorum, which separates it from the tibia ; below that, with the pos-
terior border of the internal malleolus, from which it is separatad by the tendons of the
tibialis posticus and flexor longus digitorum ; still lower, with the ankle-joint ; and, last-
ly, while under the arch of the os calcis, with the groove for the tibialis posticus. Be-
hind, it is at first covered by the gastrocnemius and soleus ; and in the lower third of the
leg, where these muscles are wanting, it is in relation with the inner border of the tendo
Achillis, and is separated from the skin by two fibrous layers. The internal popliteal
nerve runs along the outer side of this artery.
It follows, then, that the posterior tibial artery may be compressed and exposed in the
whole of the lower third of the leg.
* In a case where the anterior tibial, being very small, disappeared at the union of the two superior with
the inferior third of the leg, the peroneal artery, which was twice as large as the posterior tibial, arose on
the inside of this latter artery, which it crossed at a very acute angle, to become external. When it had
reached the lower third of the leg, it passed down close to the posterior surface of the interosseous ligament
which it traversed at its inferior portion, and then formed the artery of the foot.
THE INTERNAL AND EXTERNAL PLANTAR ARTERIES.
571
The collateral branches of the posterior tibial artery are very ermall, and do not require
any particular description : some of them are posterior, and pass to the soleus and gas-
trocnemius ; others are anterior, and supply the deep-seated muscles, and the perios-
teum of the tibia. The principal nutritious artery of the tibia, which we have stated to
arise from the tibio-peroneal trunk, is often given off by the posterior tibial. Most of the
lower internal branches perforate the flexor longus digitorum, turn round over the inter-
nal border of the tibia, and ramify in the periosteum and integuments. Lastly, opposite
the .posterior border of the lower end of the tibia, we find a small transverse branch,
which anastomoses with a corresponding branch, already mentioned as arising from the
peroneal artery.
Beneath the concavity on the under surface of the os calcis, the posterior tibial gives
off before its subdivision several calcaneal branches, some of which ramify upon the in-
ternal surface of the os calcis, while others mount up above that bone, apd anastomose
with twigs from the peroneal ; also, some articular branches for the tibio-tarsal and as-
tragalo-calcaneal articulations ; and, lastly, some branches which pass up upon the inner
boixler of the tarsus, to anastomose with the internal malleolar artery.
The Internal and External Plantar Arteries.
The internal and external plantar arteries, the terminal branches of the posterior tib-
ial, conunence in the concavity beneath the os calcis, under the internal annular ligament
of the tarsus.
The internal plantar artery ( a, fig. 218) is generally much smaller than the external ; it
passes horizontally forward, along the inner side of the sole of the j^g. 218.
foot, between the abductor poUicis and the tendons of the flexor
longus digitorum ; more anteriorly, it is subjacent to, i. e., farther
from the skin, than the flexor brevis digitorum ; it supplies the
muscles ]n question, gives off several ascending and oblique branch-
es to the numerous articulations of the tarsus, anastomoses freely
by some internal branches with the internal malleolar and internal
tarsal arteries, and ends in different ways. The following is its most
common mode of termination : having reached the posterior extrem-
ity of the first metatarsal bone, it divides into two branches ; one of
which is internal, and runs along the outer side of the abductor pol-
licis, and deviates a little, so as to form the internal collateral artery
(i) of the great toe : the other is external, varies much in size, and
anastomoses (at g) with the common trunk of the collateral arteries
of the first and second toe. We may regard as its terminating branch
a cutaneous artery, which perforates the plantar fascia, and is distrib-
uted to the skin and sub-cutaneous cellular tissue on the inner side
of the foot. I have seen the internal plantar artery very small, and
terminating in the flexor brevis pollicis.
The external plantar artery (6) forms the continuation of the pos-
terior tibial in reference to its size ; but in certain cases, howev-
er, it is not larger than the internal plantar arteiy. It passes
obliquely downward, outward, and forward, accompanied by the
external plantar nerve, under the os calcis, between the flexor brevis digitorum, which
is below or superficial to it, and the flexor accessorius, which is above or deeper : as
soon as it gains the outer border of the flexor brevis digitorum, upon the aponeurotic
septum between this muscle and the abductor of the little toe, it turns directly forward,
and having reached the under surface of the posterior extremity of the fifth metatarsal
bone, it changes its direction, leaves the nerve, and curves inward and forward, towards
the posterior extremity of the first interosseous space (at g), where it inosculates with
the dorsal artery of the foot : this curved portion of the artery, extending from the fourth
to the first interosseous space, constitutes the plantar arch, which is formed by tlie junc-
tion of the dorsal artery of the foot with the external plantar artery ; it runs obliquely
below the posterior extremities, or sometimes the middle of the metatarsal bones, be-
tween them and the adductor of the great toe, by which, and all the other muscles of
the middle plantar region, it is covered in below ; and it establishes a free and uninter-
rupted communication between the anterior and posterior tibial arteries. I have seen
the plantar arch formed exclusively by the dorsal artery of the foot, the external plantar
being very small, and losing itself in the abductor and flexor brevis minimi digiti ; at
other times, the external plantar artery only communicates with the plantar arch by
means of some small branches.
Before it constitutes the plantar arch, the external plantar artery gives off an inferior
calcaneal branch (c), which passes transversely outward, in front of the tubercles on the
lower surface of the os calcis, above the flexor brevis digitorum, and terminates in the
muscles of the external plantar region ; also, some muscular branches to the muscles of
the external plantar region, the flexor brevis digitorum, and the flexor accessorius ; and,
lastly, some periosteal, osseous, and articular branches, to Jhe bones and to the corre-
sponding articulations of the tarsus.
Wffi ANGEIOLOOY.
The plantar arch itself gives off superior and anterior branches. The superior branch-
es, or the posterior perforating arteries, pass perpendicularly upward, through the poste-
rior extremities of the interosseous spaces, and anastomose with the dorsal interosse-
ous arteries. There are only three posterior perforating arteries, which belong to the
second, third, and fourth (d) interosseous spaces : the dorsal artery of the foot repre-
sents the perforating artery of the first interosseous space.
The anterior branches are five in number ; of these, four are plantar interosseous or
digital arteries, and are distinguished by the numerical names of first, second, and third,
proceeding from within outward ; the fifth anterior branch is the external collateral ar-
tery of the little toe.
All the plantar interosseous or digital arteries (e) run forward in the corresponding in-
terosseous spaces, and then between two of the metatarso-phalangal articulations ; op-
posite the anterior extremity of the metatarsal bone, each digital artery gives off a small
anterior perforating branch (as at s), which anastomoses with the corresponding dorsal
interosseous artery ; having reached beyond the posterior extremity of the first phalan-
ges of the toes on either side, each digital artery divides into two branches, which con-
stitute the internal and external eoUateral arteries (/) of the corresponding toes, and are
distributed in precisely the same manner as the collateral arteries of the fingers ; that
is to say, the internal and external collaterals of each toe anastomose by a small trans-
verse branch opposite the second phalanx, anastomose again opposite the middle of the
last phalanx, and are almost entirely distributed to the skin.
The first plantar interosseous or digital artery (arteria magna poUicis pedis) recjuires a
special description. It is very large, and arises precisely at the point {g) where the dor-
sal artery of the foot terminates in the plantar arch, so that it appears to result from the
bifurcation of the dorsal artery of the foot ; it passes under the first metatarsal bone,
and, having arrived behind the anterior extremity of that bone, it gives off a branch from
its inner side, which sometimes forms the internal collateral artery of the great toe ; it
then passes outward to reach the space between the metatarso-phalangal articulations
of the first and second toes, and divides into the external collateral artery of the great toe
{h) and the internal collateral artery of the second toe (/). Opposite the middle of the first
phalanx of the great toe, its external collateral artery gives off a branch inward, which
anastomoses with the internal collateral artery, and sometimes even constitutes that
artery.
The external collateral artery of the little toe (l), which may almost be regarded indiffer-
ently as arising from the external plantar artery, or from the plantar arch, passes for-
ward under the flexor brevis of the little toe, and terminates along the outer border of
that toe, by anastomosing with the tarsal and metatarsal arteries derived from the dor-
sal artery of the foot. I have seen this branch give origin to both the external and in
temal collateral arteries of the little toe.
Comparison between the Arteries of the Upper and Lower Extremities.
All the arteries of the lower extremities are derived from two primitive trunks, viz.,
the right and left common iliac arteries, each of which soon subdivides into an internal
and external iliac. The arteries for the upper extremities and head arise from three
primitive trunks, the first being the brachio-cephalic, or innominate artery, which soon
subdivides into the right common carotid and right sub-clavian ; the second is the left
common carotid, and the third the left sub-clavian, which may justly be regarded as
forming together a single primitive trunk. There are, then, ultimately, four trunks for
the upper as well as the lower parts of the body.
The common carotid arteries, distributed as they are to the head, cannot be compared
to the internal iliacs, which are given to the pelvis and the organs contained in the pel-
vic cavity ; but as the pelvis corresponds to the shoulder, we may find some analogy, if
not in origin, at least in distribution, between the arteries of the one and of the other.
The external iliac corresponds to the sub-clavian ; the more numerous collateral
branches of the latter are in part represented by the branches of the internal iliac to the
walls of the pelvis. Thus, the os coxae, as well as the scapula, is, as it were, girdled by
an arterial circle. The posterior scapular artery, which runs along the vertebral border
of the scapula, represents the circumflex iliac, which turns round the crest of the ilium,
and is distributed to the muscles of the abdominal parietes in the same manner as the
posterior scapula is distributed to the serratus magnus and the rhomboideus. I will not
carry the analogy farther, by comparing the supra-scapular, sub-scapular, and internal
mammary arteries with the sciatic, gluteal, obturator, and internal pudic.
The axillary and brachial arteries correspond to the femoral and popliteal.
The deep humeral artery represents the deep femoral ; the circumflex branches of the
femoral correspond to the circumflex and sub-scapular branches of the axillary : the anas-
tomoses of the femoral circumflex arteries with the obturator, gluteal, and sciatic, cor-
respond to the anastomoses of the circumflex and sub-scapular branches of the axillary
with the supra-scapular and posterior scapular branches of the sub-clavian.
The popliteal portion of the femoral represents that part of the brachial which is sit-
THE VEINS. 573
uated opposite the bend of the elbow ; the internal and external collateral arteries deri-
ved from the brachial, together with the radial, ulnar, and interosseous recurrents, form
anastomotic circles around the elbow, which are exactly analogous to those formed by
the superior articular arteries given off from the popliteal with the inferior articular ar-
teries and the anterior tibial recurrent artery.
The bifurcation of the pophteal into the anterior tibial and the tibio-peroneal trunk
represents the bifurcation of the brachial into the radial and ulnar : the anterior tibial
corresponds to the portion of the radial situated in the forearm ; the dorsal artery of the
foot to the carpal portion of the radial ; and the plantar arch, which is continuous with
the dorsal artery of the foot, represents the deep palmar arch, which is the continuation
of the radial in the hand.
The tibio-peroneal trunk corresponds to the commencement of the ulnar artery, the
posterior tibial artery to the trunk of the ulnar, and the peroneal artery to the interos-
seous artery of the forearm. Just as the peroneal often gives origin to the dorsal ar
tery of the foot, so does the interosseous sometimes give off the carpal portion of the
radial.
The plantar arch is represented by the deep p^dmar arch ; the plantar interosseous and
the collateral arteries of the toes, by the palmar interosseous and the collateral eirteries
of the fingers.
If it be asked why there is no superficial plantar arch corresponding to the superficial
palmar arch, it may be said, first, that the arteries of the dorsum of the foot are much
larger than those on the back of the hand ; and, secondly, that the hollow, vaulted form
of the sole of the foot preserves the plantar arch from the compression to which the pal-
mar arch is liable in consequence of the flattened form of the hand.*
THE VEINS.
Definition. — The Venous System. — Origin of the Veins. — Course. — Anastomoses and Fiex-
uses. — Varieties. — Termination. — Valves. — Structure. — Preparation. — Method of Descrip-
tion.
The veins (0^ei/') are those vessels which convey the blood back from the extremitie&
to the heart. They are also called les vaisseaux a sang noir, in opposition to the arteries,
which are then named les vaisseaux d sang rouge ; but these terms are incorrectly appli-
ed, for the pulmonary veins convey red, and the pulmonary artery black blood.
There are two venous systems, corresponding to the two arterial systems, viz., the
pulmonary venous system, through which the blood returns from the lungs to the left au-
ricle, and the general venous system, which conveys the blood from all parts of the body
to the right auricle. There is also a third venous system, the system of the vena porta,
which is an appendage of the general venous system, and, as we shall see, forms by it-
self a perfect circulatory apparatus. In the foetus there is a fourth venous system na-
med the umbilical.
General View of the Venous System.
Both the general venous system and the pulmonary venous system, regarded as a
whole, resemble the roots of a tree, the trunk of which, in the former case, would cor-
respond to the right auricle, and, in the latter, to the left auricle. While a single arte-
rial trunk, the aorta, gives origin to the general arterial system, the corresponding veins
terminate in three venous trunks, viz., the superior and inferior venae cavae and the coro-
nary vein ; and so in the pulmonary venous system there is a single arterial trunk, the
pulmonary artery, to four veins, two for each lung.
Each artery has generally two accompanying veins, which are called its satellite veins
{vena comites), and bear the same name as the artery ; besides these, there exist in some
parts certain superficial or sub-cutaneous veins, which form a system totally apart from the
arteries, and may be regarded as supplementary veins.
The number of the veins is, therefore, much greater than that of the arteries. This
rule, however, has some exceptions ; in fact, there is only one accompanying vein for
the great arterial trunks, and even for some arteries of moderate size ; lastly, in some
few instances, there is but one vein to two arteries. Thus, there is only one superior
and one inferior mesenteric, one renal, and one external iliac vein, each of which cor-
responds to the artery of the same name ; but there is but one umbilical vein to two um-
bilical arteries, and there are several supra-renal arteries, but only one supra-renal vein.
It is impossible to estimate the size of the veins with accuracy, in consequence of the
variations to which they are liable from their extreme dilatability. Hence the very dif-
ferent results obtained by authors in this respect. According to Haller, the capacity of
* [For farther information concerning varieties in the distribution of arteries, the reader is referred to the
" Anatomy of the Arteries, with its Applications to Pathology and Operative Sursery," by Professor R. Qaain,
with drawings by J. Maclise, 1841, 1842.]
ANGEIOLOGY.
the veins is to that of the arteries as two to one ; according to Borelh, as four to one
according to Sauvages, as nine to four.
The entire venous system represents a truncated cone, the apex of which corresponds
to the heart, and the base to the origins of the veins. From this disproportion between
the total area of the smaller veins, and the area of the trunks in which they terminate,
it follows that, in the course of the circulation, the blood passes from a wider to a nar-
rower space ; an arrangement which tends to accelerate the progress of the fluid.
The study of the veins includes the consideration of their origin, course, anastomoses,
relations, termination, and structure.
Origin of the Veins.
The veins are continuous with the arteries ; a fact that is proved by the facility with
which even very coarse injections will pass from the arteries to the veins, and is also
most satisfactorily shown by examining the circulation in the mesentery of the frog. In
some parts, instead of the communication between the arteries and veins being direct,
it is established by means of an intermediate vascular network or spongy tissue, which
is entirely venous : of this we have an example in the corpus cavernosum penis. Last-
ly, the facihty with which injections forced into the veins from the trunks towards the ex-
tremities escape upon the surface of the mucous membranes, would seem to establish
the fact of these vessels arising by open mouths at the surface of those membranes.
HaUer admitted the existence of absorbent veins arising from all the free surfaces.*
Course.
Immediately after their origin, the veins form networks, from which small branches
are given off to anastomose together and form larger and larger networks : from these,
again, proceed larger branches, which become successively united, just as the arteries
are successively divided ; that is to say, the smaller branches unite to form larger ones,
and these still larger branches, which are at length united into the venous trunks. In
the limbs, the veins are divided into the superficial and the deep. The deep veins, which
accompany the arteries, have similar relations with the bones, muscles, nerves, fasciae,
and skin, as those vessels. The deep veins are always in contact with the arteries,
and are contained in the same fibrous sheaths. All attempts to ascertain any law by
which the relations of the veins with the arteries are regulated have been unsuccessful.
Indeed, the relative position of the two kinds of vessels, although constant, does not
seem to follow any general rule. The close relations between the arteries and veins,
interesting as they are to the surgeon, who is required to separate the veins carefully
from an artery before tying the latter, are no less so to the physiologist. The shock
communicated to the blood in the venae comites by the pulsations of their correspond-
ing artery, must assist the circulation of that fluid. In some cases of hypertrophy of the
heart, I have seen the blood issue in jets from a vein as if it were from an artery.
When, as it in some places happens, the deep veins do not accompany the arteries,
there is always some special roason which observation may determine. For example,
the cerebral sinuses, which are really veins, do not accompany the arteries ; nor are the
hepatic veins, the ophthahnic vein, and the vena azygos, satellites of their correspond-
ing arteries.
The superficial veins exist only in parts where the circulation in the deep veins is liable
to be obstructed during the exercise of those parts. In fact, as the venous blood does
not circulate like the arterial, under the influence of an impelling agent directly connected
with them, it is retarded by the slightest cause, and hence, therefore, the necessity foi
additional means of circulation.
The superficial veins, therefore, constitute, in reference to the deep veins, a collateral
route for the venous blood, especially during the contraction of the muscles of the uppei
and lower extremities, as we find in persons who exercise their limbs much. I have
shown that the tongue, as well as the extremities, is provided with a superficial and a
deep set of veins. The superficial veins are situated between the investing aponeuroses
of the muscles and the skin, from which they are separated by a very thin layer of fascia :
they are accompanied by the sub-cutaneous nerves and lymphatics.
From this description it follows, that such of the deep veins as accompany the arteries
do not require any special description, because they have the same distribution and the
general relations as the arteries : the description of the venous system will therefore be
confined to an examination of such veins as pursue a course independent of that of the
arteries.
Anastomoses and Plexuses.
The anastomoses of the veins are more numerous than those of the arteries, and they
take place by means of much larger vessels ; an arrangement which compensates for
the want of an impelling organ directly connected with them. Thus, anastomoses by
* [The eseapfi of injections upon mucous membranes is due to rupture or transudation ; the existence oJ
veins having open mouths tipon these or other free surfaces is now denied by the best authorities.!
THE VEINS. 575
direct inosculation, by lateral, transverse, or oblique communications, and anastomoses
by convergence, are found in every situation, and with all conceivable varieties. The
branches of the veins form lozenge-shaped meshes ; and both the trunks and the branches
communicate freely with each other ; that is to say, the superficial with the deep set, the
veins of the superficial set and those of the deep set among each other, and the vena
cava superior with the vena cava inferior ; so that we may say that the whole venous
system forms one vascular network, and it is by these free communications that such
obstacles as impede, or even completely intercept the course of the blood in a given part,
are rendered incapable of stopping it altogether. In order to intercept the course of the
venous blood completely, it would, in fact, be necessary to obliterate, not only the prin-
cipal trunk, but also all the collateral channels. One remaAable mode of anastomosis
is the following : a collateral vein arises from some point of a particular vein, and termi-
nates at a greater or less distance in the same vein, like a canal intended to unite two
distant points of the same stream ; this collateral channel is intended to receive a num-
ber of veins, which would otherwise have terminated in the principal vessel. The fol-
lowing is a variety of this kind of anastomosis : one vein divides into two of equal size,
which diverge from each other at a very acute angle, or, rather, run parallel, and reunite
at a greater or less distance. The saphenous vein often presents this arrangement.
A venous plexus, which consists of a complicated network of vessels, is nothing more
than the highest development of an anastomosis : venus plexuses are found in parts
where the circulation is liable to be retarded, or in organs whose functions require a large
aflJux of blood ; example, the vesical, uterine, and spermatic plexuses.
The veins are rarely tortuous, like the arteries, but are generally straight ; a circum-
stance which also helps to lessen the effects of the deficiency of a direct impelling organ ;
for tortuosities, by multiplying the points of friction, would evidently retard the flow of
blood in the veins. The great veins are not at all tortuous, but the smallest veins, and
those forming the plexuses, are distinctly so. The tortuosities of veins are generally
regarded as the result of their too great development. Thus, hypertrophied veins,
whether varicose or not, always pursue a distinctly zigzag course.
Varieties.
The varieties in the size, the anastomoses, and the terminations of the veins are so
numerous, that it is impossible to include them in any general description ; it would seem
that, for the due performance of its function, it matters not whether a vein terminates in
one or another part of the venous system. It may be readily conceived that as the an-
astomoses of the veins are very numerous, and take place by very large branches, it can
be of little consequence which of those anastomotic branches predominates.
Terminaiion.
The veins of all the supra-diaphragmatic portion of the body terminate in the vena
cava superior ; the veins of the sub-diaphragmatic portion terminate in the vena cava
inferior ; the veins of the heart terminate separately in the auricle ; the two venae cavae
communicate with each other through the vena azygos, and especially through the veins
of the spinal canal, so that when either of them is obliterated the other supplies its place.
Valves.
The existence of membranous folds, or valves (a a. Jig. 218*), in the interior of the
veins is one of the most characteristic features in their structure. p^ 218 *
The existence of these valves is shown externally in injected veins
by a more or less distinct knotted appearance.
If we open, under water, a vein provided with valves, we perceive
attEiched to its interior surface certain membranous folds, or mem-
branous processes, as they were named by Charles Etienne, who
appears to have discovered them ; there are generally two, placed one
opposite the other ; they are rarely solitary even in the smallest ves-
sels, and still less commonly are three found together, as Haller and
Morgagni say they have observed. They all have a semilunar form,
like the sigmoid valves of the aorta and pulmonary artery ; their ad-
herent border is convex, and directed towards the extremities ; their
free border is straight, and is directed towards the heart.
Both surfaces are free ; the inferior is turned towards the centre
of the vessel, while the superior corresponds to its sides, which al-
ways present a dilatation or sinus (i) opposite the valves, that gives
a knotted appearance to the vein when distended ; the constricted
part of the vein corresponds to the adherent border of the valve, and
the dilated portion to the valve itself
As a necessary consequence of their direction, the valves permit the blood to flow
from the extremities towards the heart, but prevent its course in the opposite direction ;
it was this anatomical fact which led Harvey to the discovery of the course of the venous
SW ANGEIOLOGY.
blood. The valves are so long, that when tvv'o opposite ones are depressed, they almost
completely close the channel of the vessel.
Notwithstanding their tenuity, the valves are extremely strong : a fact of which we
may be easily convinced by endeavouring to inject the veins in the opposite direction to
that in which the blood flows through them. The perforations and notches sometimes
observed in the valves of veins appear to me to be accidental.
The office of the valves is to prevent that retrograde movement in the course of the
blood which would otherwise occur from so many causes.
All veins are not provided with valves, and those which have them are very unequally
so. It may be said that their presence and their number, their proximity, and their dis-
tance from each other, are directly influenced by the degree of opposition to the onward
progress of the blood in any set of veins : thus, the v^ves are more numerous in the
veins of the limbs where the blood flows against its own gravity than in those parts
where it follows the direction of gravitation. There are no vedves in the system of the
vena portaj. They are generally more numerous in the deep than in the superficial veins.
We always find a pair of valves at the termination of a vein in a larger trunk. Very
small veins have no valves. I shall take care to describe the number and arrangement
of the valves in the principal veins.
The number of the valves is subject to many varieties. Some valves completely, and
others but imperfectly intercept the course of the blood.
Structure.
In structure, a vein appears to me to resemble an artery, without its middle coat.* In
fact, even by the most careful examination, we can only distinguish two coats in a vein ;
an external, called the cellular coat, but which I believe to be of the same nature as the
dartos, and an internal coat, very thin, which is analogous to the lining membrane of the
arteries, and, therefore, resembles the serous membranes. The internal membrane is
the essential constituent of a vein ; for the external coat may be wanting, or its place
may be supplied by some other tissue : thus, in the sinuses of the dura mater, in the cells
of the corpora cavernosa penis, in the substance of the walls of the uterus, and in the
venous canals of bones, the place of the external membrane is supplied by the dura mater,
by the fibrous parietes of the cells of the corpora cavernosa, by the tissue of the uterus
itself, and by the proper substance of the bones.
The valves are formed by a fold of the internal membrane, containing some fibrous
filaments, which are found especially along their adherent border.
The existence of a middle coat in the veins is admitted by authors, some of whom
say it is composed of longitudinal fibres, while others think it consists of circular fibres ;
but such fibres do not, in reality, exist. Vesalius relates that, wishing to show them at
one of his lectures, he was obliged to confess that he had never seen them, and could
not find them.t
The walls of the veins are themselves supplied with small arteries and veins {vasa, vaso-
rum). No nerves have been demonstrated in them, nor do either mechanical or chem-
ical stimuli applied to the inner membrane of the veins occasion pain.
It is rather a remarkable fact, in reference to the relations of the veins with the nerves,
that nervous plexuses are never supported by veins, but, on the contrary, seem always
to be separated from them. The trunk of the vena portas is the only exception.
Pr ^oration.
Most of the veins above a certain size may be examined without being previously in-
jected ; but injections are necessary for their minute investigation. The arrangement
of the valves, which, in general, oppose the transmission of liquids from the heart to-
wards the extremities, renders it necessary to inject a great number of veins from their
extremities towards the heart. In general, in order to obtain as perfect an injection as
possible, it is necessary to throw in the fluid simultaneously at several points and in sev-
eral directions. Thus, a pipe may be placed in the vena cava superior, into which the
injection should be pushed from the heart towards the extremities ; another in the upper
part of the cephalic or basilic vein of the right side ; a third in the dorsal vein of the left
thumb ; a fourth in the right femoral vein ; and, lastly, one in the left internal saphenous
vein. In all these vessels, excepting in the vena cava, the injection should be thrown
from the extremities towards the heart.
The injection of the veins from the arteries, which was proposed by Jankius, is doubly
♦ [The walls of a vein are thinner than those of an artery ; and hence the former, when cut across, docs not
remain patent, like the latter kind of vessel. The coats of tlie superficial veins are thicker than those of the
deep-seated ones, especially in the lower limbs.]
t [Nevertheless, the veins have an intermediate set of fibres, constituting a thin middle coat. The external
coat is thinner than that of the arteries, and consists of interlaced cellular filaments. The middle coat, differ-
ing from that of an artery, is composed of pale red filaments, like those of cellular tissue, miied with others
resembling elastic tissue ; the bundles into which these filaments are collected pursue a very irregular course
around the vein. The internal coat is more distinct, less brittle, and more readily detached than the corre-
sponding- arterial tissue : it consists of fine longitudinal interlacing filaments, covered with an epithelium ; it
is continuous with the lining membrane of the auricles.]
THE PULMONARY VEINS. 15*S^
inconvenient ; first, because both veins and arteries would be coloured alike, which would
make it difficult to distinguish between them ; and, secondly, because we must use a
very thin liquid, which would not become firm.
The most convenient injection mass is a coloured glue-size, because it sets slowly.
If tallow be used, the subject must be placed in warm water.
The dissection of the veins, as well as that of the arteries, consists in separating them
from surrounding parts, and preserving their relations as much as possible.
Method of Description,
In describing the veins, we may either follow the course of the blood, ana trace the
veins from the extremities to the heart, or we may pursue an opposite direction, and
trace them from the heart to the extremities. I shall adopt a combination of the two
methods ; that is to say, I shall commence with the trunks, and pass in succession to
the larger and then to the smaller branches ; but in the particular description of each
vein, I shall consider it as originating at the point most remote from, and terminating at
the point nearest to, the heart.
DESCRIPTION OF THE VEINS.
THE PULMONARY VEINS.
Preparation. — Description. — Relations. — Size. — Peculianttes.
Preparation. — These veins may be traced from the heart towards their terminations
The facility with which injections pass from the pulmonary arteries into the pulmonary
veins should be borne in mind.
There are four pulmonary veins (I l,m m,fig. 171), two for each lung, which open sep-
arately into the left auricle. Not unfrequently, however, there are five ; three for the
right, and two for the left lung. Sometimes the two left puhnonary veins seem to unite
immediately before opening into this auricle.
The trunks of these veins, each of which corresponds to a lobe of the lung, pass out
of that organ in front of the corresponding pulmonary artery. The two upper veins of
the right lung generally unite into a single trunk, which descends towards the root of
the lung, while the inferior trunk runs horizontally. In the interior of each lobule, the
pulmonary veins coimnence from the ultimate ramifications of the pulmonary artery, and
unite into a single branch, which emerges from the lobule in contact with the corre-
sponding artery. These venous branches successively unite, so as to form a single
trunk for each lobe of the lung. There are, therefore, three trunks for the right lung
and two for the left ; but the trunk from the middle lobe of the right lung soon unites to
that from the upper lobe. The pulmonary trunk belonging to the upper lobe lies in front
of that belonging to the lower lobe ; it also passes obliquely downward and outward,
while that which belongs to the lower lobe runs horizontally. These four trunks open
into the four angles of the left auricle (n), after having perforated the pericardium, with-
in the cavity of which their course is exceedingly short.
Relations. — In the substance of the lungs the branches of the veins are behind, those
of the arteries are in front, and the bronchia are in the middle. The larger branches of
these three kinds of vessels cross each other at acute angles, but their extreme ramifi-
cations are parallel. At the root of the lung, the veins are in front, the artery is in the
middle, and the bronchus behind.
In the pericardium, the anterior surface of the veins is invested by the serous layer
of the pericardium. The right pulmonary veins are in relation, in front, with the vena
cava superior, which crosses them at right angles : the left puhnonary veins are in re
lation with the left pulmonary artery.
It is generally said that the pulmonary artery is larger than the pulmonary veins ; but
it has appeared to me that the pulmonary veins are no exception to the general rule that
the veins are larger than their corresponding arteries.
Moreover, although there are two pulmonary venous trunks for each lung, by a re-
markable exception only a single vein accompanies each branch of the artery.
The pulmonary veins have no valves, even at their openings into the auricle ; they
carry red blood like the arteries, and hence the name arteria. venosce, by which they were
designated by the ancients. Distinctly circular muscular fibres can be traced upon the
portion of the pulmonary veins situated within the pericardium. The serous layer only
partially invests these veins, and it is doubtful whether the fibrous layer is prolonged.
upon them at all.
THE VEINS OF THE HEART.
The Great Coronary or Cardiac Vein. — The Small Cardiac Veins.
The cardiac veins are divided into the great coronary vein and the small coronary
veins of the heart.
4D
S78 ANGEIOLOGY.
The great coronary vein commences near the apex of the heart, at the lower part of
the anterior inter-ventricular furrow, up which it runs (e, fig. 191), gradually increasing
in size ; having arrived at the base of the ventricle, it turns to the left, so as to leave the
anterior coronary artery, and, changing its direction, it runs along the left auriculo- ven-
tricular furrow, becoming larger as it proceeds, and at length opens (e,fig. 192) into the
posterior and inferior part of the right auricle, near the inter-auricular septum.
The very great size of that portion of the vein which embraces the left auriculo-ven-
tricular furrow has obtained for it the name of the coronary venous sinus. It almost always
presents a very remarkable dilatation, or ampulla, before it enters the auricle. During
its course it receives a great number of branches.
Thus, its vertical or ascending portion receives both superficial and deep veins, which
emerge from the adjacent parts of the ventricles and their intervening septum.
Its circular portion receives some small descending or auricular branches from the left
auricle, and also larger ascending or ventricular branches, which enter it at right angles ;
among the latter, we find the vein of the left border of the heart, which commences near
the apex of the left ventricle, runs backward, crossing obliquely over the corresponding
artery, and opens, almost at a right angle, into the great coronary vein, behind the left
border of the heart ; secondly, two or three branches from the posterior surface of the
left ventricle ; and, lastly, a posterior inter-ventricular branch, which traverses the poste-
rior inter-ventricular furrow, and terminates in the ampulla, at the opening of the coro-
nary vein into the right auricle. I have seen this branch terminate at once in the auri-
cle by a distinct opening, covered or protected by the valve of the coronary vein. A
small vein which runs along the posterior half of the right auriculo-ventricular furrow
opens directly into the right auricle, near the ampulla of the great coronary vein : I do
not know whether this small vein is constant. The great coronary vein has no valves,
excepting at its entrance into the right auricle, where the valve, however, cannot
completely oppose the reflux of the blood, for the great coronary vein is always filled
when an injection is thrown into the vena cava superior.
The small or anterior coronary veins of the heart, or small cardiac veins {vence innomi-
nate of Vieussens), consist of three or four small veins, which run upon the anterior
surface of the right ventricle, and open at the lower part of the right auricle. Among
them we may point out one which runs along the right border of the heart, and has been
CEdled the vein of Galen ; and also another very small one, which commences upon the
infundibuliform prolongation of the right ventricle, enters the right auriculo-ventricular
furrow, and opens directly into the right auricle.
It follows, then, that the small cardiac veins belong to the front of the right ventricle
and auricle, or, we might even say, to the greater part of the right side of the heart;
while the great coronary vein belongs to the left side of the heart, and to the remaining
part of the right side.
I have already said that the veins of Thebesius, or vena minima, which are described
by Vieussens, Thebesius, and Lancisi, and which are said to pour their contents into all
the cavities of the heart, do not exist at aU, and that their supposed orifices are nothing
more than culs-de-sac, formed by intervals between the muscular fasciculi of the heart,
and at the bottom of which an areolar structure is seen. I agree with Senac in admit-
ting the existence of venous openings in the right auricle only (of course excepting those
of the pulmonary veins)
THE SUPERIOR, OR DESCENDING VENA CAVA AND ITS BRANCHES.
The Superior Vena Cava. — The Brachio-cephalic Veins — the Inferior Thyroid — the Internal
Mammary — the Superior Phrenic, the Thymic, Pericardiac, and Mediastinal — the Verte-
bral.— The Jugular Veins, viz., the External — the Anterior — and the Internal. — The En-
cephalic Veins, and the Sinuses of the Dura Mater, viz., the Lateral — the Superior Lon-
gitudinal— the Straight — the Superior and Inferior Petiosal — the Cavernous — the Coro-
nary— and the Anterior and Posterior Occipital Sinuses — the Conflux of the Sinuses. —
jyie Branches of Origin of the Jugular Veins — the Facial — the Temporo-maxillary — the
Posterior Auricular — the Occipital — the Lingual — the Pharyngeal — the Superior and Mid-
dle Thyroid — the Veins of the Diplo'e. — Summary of the Distribution of the Veins of the
Head. — The Deep Veins of the Upper Extremity — the Palmar, Radial, Ulnar, Brachial,
and Axillary — the Sub-clavian. — The Superficial Veins of the Upper Extremity — in the
Hand — in the Forearm — at the Elbow — aiid in the Arm. — General Remarks en these Su-
perficial Veins.
The vena cava superior, descenden^, is the common trunk of all the veins of the upper
naif of the body, and very nearly corresponds to the ascending aorta in the parts to
which it is distributed. It is situated to the right of the sternum, within the thorax, and
hence has been named the thoracic vena cava ; it commences immediately below the car-
tilage of the first rib on the right side, where it is formed by the junction of the two
brachio-cephahc veins (c c', fig. 1 701. which return the blood from the whole supra-dia*
679
pbragmatic portion of the body : from the point above mentioned it descends vertically,
describing a slight curve, the concavity of which is turned to the left, and the convexity ■
to the right side ; it enters the pericardium, and (d,figs. 191, 193) opens into the upper
part of the right auricle (m h, Jig. 193) behind the auricula ; its posterior half appears to
be continuous with the corresponding part of the vena cava inferior: hence, doubtless,
arose the opinion of Vesalius, that there is but one vena cava.
Its relations, while without and within the pericardium, require to be separately ex-
amined. Externally to the pericardium, the vena cava superior is in relation with the
right lung, being separated from it, however, by the right wall of the mediastinum, and
by the phrenic nerve, which is at first on the outer side, and then passes in front of the
vein ; on the left side, it is in relation with the arch of the aorta ; in front, with the re-
mains of the thymus gland and the cellular tissue of the mediastinum, by which it is
separated from the sternum ; behind, with the trachea, a great number of lymphatic
glands intervening between them.
Within the pericardium the vena cava is covered by the serous layer of that membrane
in its anterior three fourths : it is in immediate contact behind with the right pulmonary
artery and right superior pulmonary vein ; on the left side, it is merely in contact with
the aorta.
The superior vena cava has no valves, either in its course or at its opening : it follows,
therefore, that each contraction of the auricle is accompanied by a regurgitation of blood
into the vena cava and into the branches immediately opening into it. Upon this regm-
gitation depends the phenomenon of venous pulsation.
The vena cava presents certain conditions in its structure which require special notice.
It has been said that the muscular fibres of the auricle are prolonged upon it ; I can state
that such is not the case. The serous layer of the pericardium covers the pericardial
portion of this vein, and the fibrous layer is prolonged upon that part of the vessel which
is external to the pericardium.
Lastly, the relative length of the intra- and extra-pericardial portions of the vena cava
is subject to much variety : sometimes the vein enters the pericardium at about the mid-
dle of its course ; sometimes only a few lines from its termination in the auricle.
The caliber of the vena cava superior is less than that of both the brachio-cephalic
trunks taken together, and also less than that of the vena cava inferior. Its length va-
ries from two and a half to three inches.
Sometimes this vein is double : I once found in an adult two superior cavae, opening
into the right auricle, a variety which evidently depended upon the two brachio-cephalic
veins not having united. This condition is normal in several animals.
Collateral Veins. — The vena cava superior receives no branch while within the pericar-
dium, immediately before entering which it receives the vena, azygos. The right inferior
thyroid and internal mammary veins, and the small veins called thymic, pericardiac, medias-
tinal, and right superior phrenic, generally enter opposite the junction of the two brachio-
cephalic trunks, and not into the vena cava itself
As the vena azygos forms part of the system of spinal veins, it will be described with
them.
As the other veins have a similar distribution on both sides, the description of those
on the left side will apply to those of the right also.
The Brachio-cephalic Veins.
The brachio-cephalic veins, or vencE innominatts of Meckel {cc',jig. 170), which are gen-
erally included in the description of the sub-clavian vein, correspond exactly to the bra-
chio-cephalic or innominate artery, being fonned by the union of the internal jugular
vein {d) and the sub-clavian vein (e), properly so called, which correspond to the common
carotid and the sub-clavian arteries.
There are two brachio-cephalic veins, one for the right (c') and one for the left side
(c) ; so that the arrangement of the veins of the upper half of the body is more sym-
metrical than that of the arteries.
The right and left venous trunks differ from each other in length ; for as they both
commence at the junction of the corresponding internal jugular and sub-clavian veins,
opposite the sternal end of the clavicle of their own side, and terminate on the right of
the median hue, to form the commencement of the vena cava superior, it follows, therefore,
that the right brachio-cephalic vein must be much the shorter ; it is, in fact, only from
twelve to fourteen lines in length, while that of the left side is twice as long.
They differ also in caliber, the left brachio-cephahc trunk being much larger than the
right, in consequence of receiving the internal mammary and inferior thyroid veins of its
own side.
Also in direction, the right being almost vertical, and sloping only slightly to the left
side as it descends, like the superior vena cava, which follows the very same direction ;
the left vein, on the contrary, is almost horizontal, and describes a curve with its con-
cavity directed backward ; the two brachio-cephahc veins, therefore, unite at a right
angle to form the vena cava.
580 ANGEIOLOGY.
Lastly, they have different relations. Tlie concavity of the left vein embraces the
front of the highest part of the aortic arch, and the three great arteries arising from it.
It coiTesponds anteriorly veith the sternal extremity of the left clavicle and the sterno-
clavicular articulation, and runs along the upper border of the sternum. The right vein
is situated in the right cavity of the thorax ; it is parallel with, and on the outer side of,
the brachio-cephalic artery, and it is in contact behind and on the right side with the right
wall of the mediastinum and with the pneumogastric nerve, which are interposed be-
tween it and the apex of the lung.
The relations of the left brachio-cephalic vein with the arch of the aorta account for
its obliteration in aneurism of that vessel, and its relation to the upper part of the ster-
num explains the venous pulse, seen so distinctly opposite the fourchette of the sternum
in severe attacks of dyspnoea.
There are no valves in the interior of these veins, and hence considerable regurgita-
tion may occur.
Collateral Branches. — The right brachio-cephalic vein, in some cases, receives only the
vertebral brain ; but most commonly the right inferior thyroid and right internal mam-
mary veins terminate in it. The left brachio-cephalic vein always receives the above-
mentioned veins of its own side, and also the superior phrenic, the thymic, and pericardiac
veins, and often the superior intercostal vein. As this last forms part of the system of the
vena azygos, it will be described in another place.
The Inferior Thyroid Veins.
There are two o tnese, viz., a right and a left inferior thyroid vein : not unfrequently
there are three, and even four.
The course of the inferior thyroid veins corresponds exactly with that of the inferior
thyroid artery of Neubauer, when it exists. They arise from the thyroid venous plex-
uses, and sometimes directly from the superior thyroid vein by an anastomotic arch ;
they descend vertically between the trachea and the muscles of the sub-hyoid region,
and terminate differently on the right and left sides, the right inferior thyroid vein ter-
minating at the junction of the two brachio-cephalic veins, and sometimes even in the
upper and anterior part of the superior vena cava, while the vein of the left side enters
the corresponding brachio-cephalic vein.
In one case in which there were thi-ee inferior thyroid veins, the middle one ended in
the superior cava, and the two lateral veins in the corresponding brachio-cephalic trunks.
These veins, moreover, present innmnerable varieties in their number, course, anas-
tomoses, and termination. One of the most curious and frequent of these varieties is
that in which the right and left veins form an arch, which receives four or five parallel
branches that issue from the thyroid gland.
The inferior thyroid veins are joined by the tracheal and inferior laryngeal veins, so
that Winslow named them guttural or tracheal. They form, in front of the trachea, a
large plexus, which it is impossible to avoid in performing tracheotomy.
The Internal Mammary Veins.
The internal mammary veins follow the same course as the arteries of that name, and
receive a series of branches corresponding to those given off by the arteries, excepting
in one instance, viz., the superior phrenic veins, neither of which, in general, terminates
in the corresponding internal mammary.
Usually, there are two veins of unequal size for each internal mammary artery, which
is placed between them. The two almost always unite into a single trunk, which ter-
minates on the right side at the junction of the two brachio-cephalic veins, or in the up-
per and front part of the superior cava, and on the left in the corresponding brachio-
cephalic vein.
Among the veins which open into the internal mammary, I should mention the proper
veins of the sternum, which form a very remarkable venous network in front of and be-
hind each piece of that bone beneath the periosteum.
The Superior Phrenic, and the Thymic, Pericardiac, and Mediastinal Veins.
These are small veins which unite into two groups, one for the right side, terminating
at the junction of the two brachio-cephalic veins, or at the upper and anterior part of the
superior vena cava ; the other for the left, and teraiinating in the left brachio-cephalic
veni. The pericardiac and mediastinal veins commence upon the pericardium and the
anterior mediastinum.
The thymic veins, which are very large in the fcetus, may still be seen in the adult and
the aged, for the th)nnus gland is never completely absorbed.
The superior phrenic veins are remarkable for their length as well as for their small
size ; they accompany the phrenic nerve and the superior phrenic arteiy : the left supe-
rior phrenic vein often enters the corresponding superior intercostal vein, and frequent-
ly the internal mammary vein
THE JUGULAR VEINS.
Fig. 219.
The Vertebral Veins.
The vertebral vein corresponds to the cervical portion of the artery of the same name,
and, like it, is contained in the canal formed by the series of foramina at the base of the
transverse processes of the cervical vertebra ; it opens into the braehio-cephalic vein im-
mediately behind the internal jugular ; and it is said to open occasionally into the last-
mentioned vein. Not unfrequently, as Eustachius remarks, this vein divides into two
branches near its termination, one of which emerges with the artery, between the fifth
and sixth vertebrae, while the other, either alone or accompanied by a small arterial twig,
escapes by the foramen of the seventh cervical vertebra. I have seen these two branch-
es emerge, one at the foramen of the fifth, the other at that of the sixth cervical vertebra.
This vein commences in the deep muscles at the back of the neck, communicates by
a large branch with the occipital vein, and sometimes receives a small branch, which
passes out at the posterior condyloid foramen ; it enters the canal of the transverse pro-
cesses, between the occipital bone and the atlas ; and while within this canal, it receives
anterior muscular branches from the praevertebral region, posterior branches from the
external spinal veins, and vertebro-spinal branches from the interior of the spinal canal.
At the point where it opens into the braehio-cephalic vein, it receives a large branch,
which corresponds in its course to the ascending cervical artery ; it also receives the
deep cervical vein, which has the same distribution as the artery of that name.
The Jugular Veins.
The jugular veins (from jugulum, the throat) are three in number on each side, viz.,
the internal or deep jugular {n,Jig. 219), the external jugular (A), and the anterior jugular
(m). The two latter veins form part of the superficial or sub-cutaneous venous system ;
but the internal jugular is the satellite vein of the common carotid artery and its branch-
es. I shall describe these three veins in succession, but shall not notice the veins with
which they are directly continuous, nor yet their branches of origin, until I have described
all three of them, because those branches terminate almost indifferently in either of them.
The External Jugular Vein.
The external jugular (h), one of the supplementary veins of the internal jugular, is a
6ub-cutaneous vein of the neck, on the lateral and
anterior aspect of which it is situated. It is bound-
ed above by the angle of the lower jaw according to
some authors, by the neck of the condyle of that bone
according to others : the former mode of limitation
seems to me to be preferable. It is bounded below
by the clavicle, behind which it ends in the sub-cla-
vian vein (o), immediately to the outer side of the
internal jugular, and sometimes even opposite that
vein, but upon a plane anterior to it.
The external jugular is generally single, but is
sometimes double ; and this depends either upon
some of its branches of origin not joining it until
they reach the lower part of the neck, or else upon
the existence of a small collateral branch, which ari-
ses from the upper part of the external jugular, runs
along its outer side, and opens into it below, imme-
diately before its termination ; at other times the
external jugular bifurcates before it ends in the sub-
clavian.
The external jugular varies extremely in size,
which frequently differs on the two sides, and is not
uniform throughout its whole length. Thus, it al-
most always presents an ampulla, or ovoid dilatation
of variable dimensions, near its termination. In size
it is inversely as that of the other jugular veins of the same and the opposite side, and
its differences are either congenital or acquired ; the former depending upon the fact of
its receiving more or fewer branches, while acquired alterations in size are occasioned
either by some occupation requiring violent respiratory efforts, or by the venous circula-
tion being impeded by disease.
Direction.. — The external jugular vein passes obliquely downward and backward in the
opposite direction to the sterno-cleido-mastoideus, which it crosses at a very acute an-
gle, and then runs parallel to the posterior border of that muscle. A line drawn from
the angle of the jaw to the middle of the clavicle will exactly indicate its direction. Op-
posite the clavicle, the external jugular vein turns forward and opens into the sub-clavi-
an, either directly, or after running horizontally for some lines.
Relations. — The external jugular vein runs first across the stemo-mastoid, and then
the supra- clavicular region of the neck. In the whole of its extent it is covered and
582 ANGEIOLOGY.
separated from the skin by the platysma ; hence the rule to open this vein across the
fibres of the platysma, when it is desirable that the orifice should be free, and favourably
disposed for the flow of blood. By its deeji surface it is in relation with the stemo-
mastoid, which it crosses obliquely, so that it rests above upon the anterior border of
that muscle, and below upon its external surface, and parallel with its outer border.
In the supra-clavicular region it is in relation behind with the omo-hyoid and scalenus
anticus muscles and with the brachial plexus. It is always separated from these differ-
ent parts by the cervical fascia, which is perforated by it as it curves forward to entei
the sub-clavian vein.
The external jugular vein is surrounded by the superficial nerves of the cervical plex-
us, some of which pass in front, and others behind it. The auricular nerve runs behind
its upper portion.
This vein has generally two valves, one in the middle, the other near its termination ;
sometimes only the latter exists. These valves do not appear, in general, to oppose any
great obstacle to an injection thrown from the heart towards the extremity of the vein.
Collateral Branches. — The external jugular vein receives, in front, branches of variable
size and number, which communicate with the anterior jugular vein, and others which
pass directly out of the sterno-mastoid muscle ; behind, it receives the superficial occip-
ital veins (k), and several superficial branches from the posterior and lateral regions of the
neck ; lower down, it also receives the supra-scapular and posterior scapular veins (1),
which exactly correspond to the arteries of the same names. A constant branch passes
beneath the clavicle, and establishes a communication between the external jugular vein
and the upper part of the veins of the arm.
Branches of Origin. — These are extremely variable ; most commonly the external jug-
ular is formed by the junction of the temporal (/) and the internal maxillary veins. Some-
times it is formed by a branch resulting from the bifurcation of a trunk common to those
two veins ; at other times, by the successive juction of the temporal, internal maxillary,
facial, lingual, and superior laryngeal veins.
In all cases the external communicates either directly or indirectly with the internal
jugular vein in the substance of the parotid gland by means of a communicating branch,
which may be regarded as a branch of origin, and which sometimes is the only branch of
origin.
The interior Jttgular Vein.
The anterior jugular is a sub-cutaneous vein {m,fig. 219), supplementary to the exter-
nal and even to the internal jugular, and collects the blood from the parts situated in the
middle of the anterior region of the neck.
It varies in size in different individuals, is almost always inversely proportioned to the
external jugular, and is often larger than that vein. We frequently find both a right and
a left anterior jugular vein ; but then they are rarely of equal size. Rather frequently,
however, there is only one, scarcely a trace of the other existing. Lastly, instead of
these veins, there are occasionally only some small branches, which scarcely deserve
notice.
Direction. — From the supra-hyoid region, where it commences, this vein passes verti-
cally downward, between the median line and the inner border of the sterno-mastoid mus-
cle ; opposite the fourchette of the sternum it bends abruptly, passes horizontally out-
ward behind the two lower fasciculi of the sterno-mastoid, and enters the sub-clavian
vein on the inner side of the external jugular, sometimes opposite to, but in front of the
internal jugular ; lastly, in other cases, it terminates by a common orifice with the ex
temal jugular.
During its course it runs in the substance of that median layer of fibrous tissue which
we have called the cervical linea alba, and it receives several collateral branches.
Collateral Branches. — The anterior jugular veins communicate with the external by
one or two branches of variable size ; they also communicate freely with the internal
jugular veins ; the communicating branches often form the origins of this vein. The an-
terior jugular receives some laryngeal branches, and sometimes an inferior thyroid vein. At
the point where it bends at the lower part of the neck it receives a sub-cutaneous vein,
which comes from the upper part of the thorax, and passes above the fourchette of the
stemiun. At the same point, also, the right and left anterior jugular veins communicate
with each other by a transverse branch {r,fig. 223), into which branches derived from
the inferior thyroid vein, or even some branches communicating directly with the left
brachio-cephalic vein, pour their contents.
Branches of Origin. — The anterior jugular vein often commences by sub-cutaneous
and muscular branches, derived from the supra-hyoid region, and corresponding in their
several courses to the branches of the sub-mental artery. I have seen it arise from one
end of a loop, the other end of which was continuous with the external jugular vein ; at
other times it commences by a common trunk with the facial and lingual veins. Lastly,
I have seen the anterior jugular form the continuation of the facial vein.
THE INTERNAL JUGULAR VEIN, ETC.
The Internal Jugular Vein.
The internal jugular vein (n,fig. 219), the principal vein of the head, collects the blood
from the interior of the cranium and from the greater part of the face and neck ; it com-
mences at the posterior lacerated foramen, and terminates in the brachio-cephalic vein
(r), which is formed by the junction of the internal jugular with the sub-clavian vein (o).
Its direction is vertical, without any deviation or bending.
It is of considerable size, but varies in different individuals ; it is seldom of equal size
on both sides, and is inversely proportioned to the external and anterior jugular veins ;
it becomes extremely large in such chronic diseases as impede the entrance of blood
into the cavities of the heart. I have sometimes seen the internal jugular vein of the
left side very small, its place being then supplied, as in the lower animals, by a very large
external jugular.
Moreover, the internal jugular is not of uniform size throughout its whole length. It
commences at the posterior lacerated foramen by a dilatation, which is called the gulf of
the internal jugular vein ; it continues of the same size until opposite the larynx, where
it becomes greatly enlarged in consequence of receiving several branches ; it terminates
below in an oblong dilatation, and is again slightly contracted as it opens into the brachio-
cephalic vein. This oblong dilatation in some asthmatic persons is very large, and might
be called the sinus of the internal jugular vein.
That part of the internal jugular vein which extends from the os hyoides to the brachio-
cephalic vein represents the common carotid artery ; the part included between the os
hyoides and the posterior lacerated foramen represents the internal carotid ; and the se-
ries of branches which terminate in it represent the external carotid and the ramifica-
tions of that artery. These branches of the internal jugular, however, do not unite into
a common trunk corresponding to the trunk of the external carotid arteiy, so that the
distribution of this vein represents very nearly that variety in the distribution of the ar-
teries of the neck, in which there is no external carotid artery ; the branches usually
given from it arising from the common carotid artery, which then terminates in the in-
ternal carotid.
Relations. — In that portion of its course which corresponds to the internal carotid ar-
tery, the internal jugular vein has almost the same relations as that vessel : thus, it is
situated in the triangular interval between the pharynx and the ramus of the lower jaw ;
the artery, together with the pneumogastric, hypo-glossal, glosso-pharyngeal, and spinal
accessory nerves, lie to the irmer side and in front of it ; the styloid and vaginal pro-
cesses, and the styloid muscles, are also anterior to the internal jugular vein. That por-
tion of the vein which represents the common carotid artery lies on the outer side of
that vessel and in contact with it, excepting below, where the carotid is directed some-
what inward to reach the arch of the aorta, while the vein continues to be vertical, and
is therefore separated from the artery. During its course it has the same relations as
the artery, only on account of being situated to the outer side of that vessel, it follows
that it is not covered by the platysma myoides to so great an extent as the artery, and,
therefore, that it is covered for a greater length by the stemo-mastoid ; and, indeed, its
lower end is inclined to project beyond the outer border of that muscle, so that in asth-
matic persons the skin covering the anterior part of the supra-clavicular triangle be-
comes elevated when the enlarged part of the vein is dilated. The pneumogastric nerve
is situated behind, between the artery and the vein. A very important relation of the
internal jugular vein is that which it has with the sub-clavian artery, which is situated
between it and the vertebral vein, the internal jugular being in front, and the vertebral
vein behind the artery.
The internal jugular vein returns all the blood from the interior of the cranium, re-
ceiving it from the lateral sinus, which may be regarded as the origin of this vein, and
as the common trunk of all the veins within the cranium. Its collateral branches, several
of which belong sometimes to the internal, and at others to the external jugular, are the
facial (c), lingual, inferior pharyngeal, superior thyroid (all which open by a common trunk),
and middle thyroid veins, sometimes also the temporal (f), internal maxillary, and deep oc-
cipital veins. "We shall describe in succession the branches of origin, and then the col-
lateral branches of the internal jugular vein.
The Encephalic Veins and thb Sinuses of the Dura Mater.
The commencing twigs and the branches of the cerebral veins are like all other veins,
but their trunks are essentially different, for they consist of fibrous canals, formed, as it
were, in the substance of the dura mater ; the lining membrane of these canals is the
only part in which they correspond in structure with the rest of the venous system, the
dura mater forming their outer coat. These canals are called the sinuses of the dura
mater. They receive the blood from the brain, cerebellum, and medulla, from the eye.
and from the bones of the cranium.
All the sinuses of the dura mater have a similar situation ; they all occupy grooves form-
ed for them upon the internal surface of the bones of the cranium, and which we have
already described. They are, for the most part, situated opposite the intervals between
ANGEIOLOGY.
the great divisions of the encephalon : thus, the superior longitudinal sinus occupies the
fissure between the two hemispheres of the brain ; the lateral sinuses are situated op-
posite the great fissure which separates the cerebrum from, the cerebellum. All the
sinuses communicate with each other, and form an uninterrupted series of canals ; they
all open into the later£il sinuses, which are to the other sinuses what venous trunks are
to their branches.
There are twelve sinuses in all, not including the inferior longitudinal sinus, which may-
be regarded as a vein. Eight of the sinuses exist in pairs, the remaining four are sin-
gle, and occupy the median line. The single sinuses are the superior longitudinal sinus,
the straight sinus, the coronary sinus, and the transverse occipital sinuses. The eight
sinuses which exist in pairs are placed four on each side of the cranium ; they are the
two superior and two inferior petrosal, the two occipital, and the two lateral sinuses.
As the lateral sinuses form, as it were, the common trunks of all the others, I shall
oescribe them first.
The Lateral Sinuses.
The lateral or transverse sinuses (a a. Jig. 221) are situated in the lateral grooves {vide
Osteology, p. 80) ; each of them commences, like those grooves, at the internal occip-
ital protuberance, and passes horizontally outward as far as the base of the petrous por-
tion of the corresponding temporal bone, at which point it dips obliquely downward
and inward into the inferior occipital fossa, turns round the base of the pars petrosa, and
again ascends to reach the posterior lacerated foramen of its own side (s s,fig. 221),
where it terminates in the internal jugular vein. Like the corresponding grooves, the
right and left lateral sinuses are of unequal size, the right being almost always the lar-
ger. Both of them gradually increase in size from their posterior extremity, which may
be regarded as their origin, to their anterior extremity.
A section of the horizontal portion of each lateral sinus, which is situated in the outer
margin of the tentorium cerebelli, is triangular, while that of its vertical or curved por-
tion is semi-cylindrical. In the first part of its course it projects beyond the correspond-
ing groove in the occipital bone, so as to occupy the fissure between the cerebrum and
cerebellum. In the remamder of its course it does not project into the interior of the
cranium, or pass beyond the groove, which is exactly suited to its dimensions.
The internal surface of each lateral sinus is smooth, and it is not traversed by bands
like those found in the other sinuses. However, I once found in the horizontal portion
of this sinus some of the white bodies called glandulse Pacchioni.
One of the lateral sinuses has been found divided, in front, into two equal parts, a su-
perior and inferior, by a perfect horizontal septum ; it is very common to find a fibrous
lamina indicating a trace of this subdivision.
The anterior extremity of each lateral sinus is continuous with the gulf of the corre-
sponding internal jugular vein, and the inferior petrosal sinus of its own side opens into
it at the same point. During its course it receives some inferior cerebral veiris, some cere-
bellar veins, and the superior petrosal sinus (/), which enters it at the point where it chan-
ges its direction from horizontal to oblique, i. e., opposite the base of the petrous portion
of the temporal bone.
The lateral and inferior cerebral veins commence partly on the lateral and inferior parts
of the convex surface of the. cerebrum, and partly on the base of the brain ; they unite
so as to form a group of three, four, or five veins, which open into the horizontal por-
tion of the lateral sinus. They enter from before backward, that is to say, in an oppo-
site direction to the course of the blood in the sinus. One of these veins is sometimes
observed to run along the tentorium cerebelli, with which it is maintained in contact by
the parietal layer of the arachnoid for about an inch before it opens into the lateral sinus
The lateral and inferior cerebellar veins are very large ; they commence upon the lower
surface of the cerebellum, and terminate in two or three trunks, which are found upon
the circumference of the cerebellum, and open into the horizontal portion of the lateral
sinus by perforating its lower wall.
A large mastoid vein, which may be regarded as one of the principal origins of the oc-
cipital, also opens into the lateral sinus, and thus establishes a free and direct commu-
nication between the venous system within and that outside the cranium.
The Superior Longitudinal Sinus.
The superior longitudinal sinus {b b,fig. 220) is a single and median sinus, which occu-
pies the longitudinal groove, and accordingly extends from the crista galli to the inter-
nal occipital protuberance ; it is formed within the substance of the convex border of the
falx cerebri, and is three-sided; a section of it represents an isosceles triangle {I, Jig.
221), with its base turned upward and its apex downward. It is small at its anterior
extremity, but gradually increases in size as it approaches the confluence of the sinuses
(«, Jig. 221), in which it terminates. It not unfrequently bifurcates near its posterior ex-
tremity ; sometimes it is directly continuous with the right lateral sinus.
The internal surface of this sinus is remarkable for the transverse bands found in it.
THE SUPERIOR LONGITUDINAL SINUS, ETC. 6S5
especially along its inferior angle. These bands Fi^. S20.
consist of fibrous tissue covered by the lining mem-
brane of the sinus, and they conceal the orifices
of the veins which open into it ; in some points
they are so numerous as to form an areolar tissue.
Lastly, we ahnost always find on the internal sur-
face of the sinus some small white projecting bod-
ies, the glandulce Pacchioni.
The following veins open into the superior lon-
gitudinal sinus : some from the internal or flat sur-
face of each cerebral hemisphere, called the inter-
nal cerebral veins ; others from the upper half of the
convex surface of the brain, or the external cere-
bral ; and, lastly, several veins from the dura mater
and the bones of the cranium.
The internal cerebral veins, three or four in number on each side, return the blood from
all the convolutions of the flat surface of the corresponding hemisphere of the brain, and
enter the superior cerebral veins at the point where these are applied to the surface of
the falx.
The superior cerebral veins vary in number, but are generally seven or eight on each side.
The anterior of these veins are very small ; the posterior are much larger. There is al-
most always one of greater size than the rest, which may be named the great superior
cerebral vein : it appears to commence in and run along the fissure of Sylvius, is then
prolonged obliquely backward, and turning forward upon the convex surface of the brain,
so as to describe a curve having its concavity directed forward, it becomes applied to
the falx cerebri, and opens into the longitudinal sinus, after having run for about one inch
in the substance of its walls. During its course this vein receives a great number of
branches, some anterior and others posterior, which, although corresponding to the arter-
ies in their origin and in a part of their course, are completely separated from those ves-
sels at their termination. The common trunks pass inward towards the great median
fissure of the brain ; near the sinus they become attached to the dura mater, being held
down by the arachnoid membrane, which is reflected from the brain upon the dura ma-
ter; they then change their direction, turn forward in the substance of the falx cerebri,
beneath a very thin layer of the dura mater, and after a course of from six to ten lines in
length, terminate in the longitudinal sinus by one or more openings. The manner in
which the cerebral veins open into the sinus varies : for some there are lateral openings,
as if made by a punch ; others open by means of an areola fibrous tissue, which, as I have
already stated, is found in certain parts of the walls of the sinuses. All the venous ori-
fices are concealed by fibrous areolae, none of the veins opening directly into the sinus.
Most of them run for a certain distance from behind forward, i. e., in an opposite direction
to the course of the blood, before they open into the sinus ; the most anterior veins,
which run from before backward, are the only exceptions to this rule. Moreover, the fold
or bands which are formed in this and other sinuses do not perform the functions of
valves, for they permit fluids to pass from the sinus into the veins. The inferences drawn
by physiologists from the direction in which the cerebral veins open into the sinuses ap-
pear to me to be erroneous, for that direction facilitates instead of opposing the reflux
of the blood. I have satisfied myself that the cerebral veins have no valves in any part
of their extent.
The superior longitudinal sinus also receives proper veins from the dura mater, some
venous or diploic veins, and several veins which conmience in the pericranium, and es-
tablish a communication between the external and internal veins of the cranium. Among
the communicating veins are those which traverse the parietal foramina, and are called
the veins of Santorini. A very great number of veins penetrate through the longitudinal
suture, to open into the corresponding sinus in young subjects ; the communication of the
diploic veins with those of the dura mater, and with the sinuses and cerebral veins, may
be shown by perforating with a pin, in a young subject, the very thin and brittle external
bony table which covers one of the numerous veins of the diploe, and then inserting into
the orifice the fine point of a mercurial injecting apparatus : the mercury will fill the diplo-
ic veins, and will pass into the sinuses, the veins of the dura mater, and the cerebral veins
The Straight Sinus.
The straight sinus (,c,Jig. 220) occupies the base of the falx cerebri, corresponding with
the line of junction of the falx with the tentorium cerebelli.
The straight sinus is therefore single, and situated in the median line ; it is directed
somewhat obliquely backward and downward, and it opens into the confluence of the si-
nuses or torcular Herophili (n), by one or sometimes two orifices, according to the pres-
ence or absence of a vertical band across its termination. It is three-sided, and a sec-
tion of it represents an isosceles triangle {c,fig. 221), having its base turned downward.
This sinus increases in size as it proceeds backward.
4 £
<S86 ANGEIOLOGY.
The straight sinus receives by its anterior extremity the inferior loTigitudinal vein or
sinus, the two great vc7itricular veins or vena Galeni, the inferior median cerebral veins, and
the superior median cerebellar vein.
The inferior longitudinal vein (rf), which is generally but incorrectly described as the
inferior longitudinal sinus, may be regarded as an ordinary vein enclosed within the pos-
terior half of the free margin of the falx cerebri. This vein increases in size from be-
fore backward, and enters directly into the straight sinus. It sometimes bifurcates be-
fore its termination, and then the lower branch of the bifurcation opens into the anterior
extremity of the straight sinus, and the upper describes a decided curve, and enters at
the middle of that sinus.
The inferior longitudinal vein receives the proper veins of the falx cerebri. It seldom
receives any vein belonging to the brain itself.
The ventricular veins, or vena Galeni (c), are two in number, one proceeding from the
left, and one from the right lateral ventricle. Each of them is formed by the union of two
branches, viz., the choroid vein, and the vein of the corpus striatum.
The choroid vein runs along the whole length of the outer border of the choroid plexus,
m a direction from behind forward. During this course it receives the vein from the
hippocampus major, one from the fornix, and one from the corpus callosum, and having
reached the anterior extremity of the choroid plexus, it turns back again within the sub-
stance of the plexus, and unites with the vein of the corpus striatum.
The vein of the corpus striatum is much smaller than the preceding ; it commences be-
hind in the furrow between the corpus striatum and the thalamus opticus, traverses the
whole length of that furrow, covered by the taenia semicircularis, receives, during its
course, a great nmnber of small veins from the corpus striatum and thalamus opticus,
and having arrived behind the anterior pillow of the fornix, unites with the choroid vein
to form one of the venae Galeni.
The two vena Galeni proceed parallel with each other, and horizontally backward be-
neath the velum interpositum, pass out from the brain beneath the corpus callosum, and
immediately enter the straight sinus below the opening of the inferior longitudinal vein
without crossing each other, as is stated by some anatomists.
Not unfrequently we find an anterior and superior cerebellar vein opening into the ve-
nae Galeni, as the latter enter the straight sinus.
The inferior median cerebral veins are very large. One is anterior, and commences
upon the fore part of the lower surface of the cerebrum, and turns round its correspond-
ing crus ; while the other, which is posterior, arises upon the posterior convolutions ;
they both enter the anterior extremity of the straight sinus, behind the venas Galeni.
The superior mediaii cerebellar vein passes upward between the valve of Vieussens and
the superior vermiform process, and opens into the anterior extremity of the straight
sinus.
The Superior Petrosal Sinuses.
The superior petrosal sinuses {fffg- 221) are situated along the upper border of the
Pig, 221. petrous portion of the temporal bones, and are partly lodged
in the small corresponding grooves ; they are continuous as
regards their direction with the horizontal portion of each
lateral sinus, and occupy the anterior half of the lateral or
adherent borders of the tentorium, the lateral sinuses occu-
pying the posterior half They are very small, and, hke the
part of the lateral sinus with which they are continuous,
they are three-sided. The anterior extremity of each su-
perior petrosal sinus communicates with the corresponding
cavernous sinus {h h) ; and its posterior extremity opens
into the corresponding lateral sinus at the point where the
latter leaves the tentorium cerebeUi to turn round the base
of the petrous portion of the temporal bone.
The superior petrosal sinuses, therefore, establish a di-
rect communication between the cavernous and the lateral
sinuses ; they sometimes receive an inferior lateral cerebral
vein, but always an anterior lateral cerebellar vein, which
passes upward under the free margin of the tentorium cerebeUi, behind the fifth pair of
nerves. The veins which come from the sides of the pons Varolii also enter the an-
terior extremity of this sinus.
The Inferior Petrosal Sinuses.
The inferior petrosal sinuses (g g) are situated, one on each side, upon the petro-occip-
ital sutures, and lie in corresponding grooves ; each of them extends from the anterior
to the posterior lacerated foramen of- its own side. They are larger than the superior
petrosal sinuses, and are semi-cylindrical, like the anterior part of the lateral sinuses,
with which they are continuous. The anterior extremity of each opens into the anterior
THE CAVERNOUS SINUSES, ETC.
occipital sinus (r) and into the cavernous sinus of its own side ; while its posterior ex-
tremity opens into the anterior end of the corresponding lateral sinus, opposite the com-
mencement of the internal jugular vein (s). These sinuses establish a free anastomosis
between the anterior and posterior sinuses found at the base of the cranium.
Excepting one vein which comes from the base of the cranium through the foramen
lacerum anticus, the inferior petrosal sinus receives no vein of importance.
The Cavernous Sinuses.
The cavernous sinuses (h h), so named from their reticulated, and, as it were, spongy
structure, occupy the sides of the sella turcica and the grooves on the body of the sphe-
noid bone. Each cavernous sinus is bounded in front by the inner part of the sphenoidal
fissure, and behind by the apex of the petrous portion of the temporal bone : its cavity
(shown on the right side in the figure) is larger than it at first sight appears to be, but is
encroached upon by the internal carotid artery, which curves twice upon itself during its
passage through the sinus, and also by the abducens oculi, or sixth cranial nerve. The
motor oculi or third nerve, the trochlearis or fourth, and the ophthalmic branch of the
fifth cranial nerve, are situated in the substance of tlie outer wall of the sinus. It is
traversed by reddish reticulated filaments, the nature of which is unknown. The older
anatomists said that the internal carotid artery and the sixth nerve were bathed in the
blood of the sinus ; but it is now generally believed, in accordance with the opinion of
Bichat, that they are protected by the lining membrane of the veins ; it is difficult to
prove the accuracy of this opinion, although analogy is in its favour. Bichat also thought
that the reticulated filaments mentioned above were folds of the lining membrane of the
vein. The anterior extremity of each cavernous sinus has been named the ophthalmic
sinus, doubtless on account of its being prolonged outward. Its posterior extremity opens
into the corresponding superior and inferior petrosal sinuses, and into the transverse oc-
cipital sinus. On the inner side it receives t)ie coronary sinus, which establishes a di-
rect communication between the right and left cavernous sinuses. Lastly, each cavern-
ous sinus receives below several branches, which connect the veins within with those
outside the base of the cranium, more particularly with the pterygoid venous plexuses.
The cavernous sinuses receive in front the inferior and anterior cerebral veins, which
commence upon the lower surface of the anterior lobe of the cerebrum. The largest of
these veins on each side reaches the sphenoidal fissure, turns backward over the lateral
and middle fossa of the base of the cranium, and enters the middle meningeal vein.
Several anatomists state that they have seen the middle meningeal veins open into the
cavernous sinuses.
Lastly, the anterior extremity of each of these sinuses receives the ophthalmic vein.
The ophthalmic vein is a very large vessel, which commences on the inner side of the
orbit as a continuation of the frontal vein, and terminates by opening into the anterior
extremity of the corresponding cavernous sinus ; and it thus establishes a very free com-
munication between the veins of the interior and exterior of the cranium. It pursues
the same course as the ophthalmic artery, but without any windings, and receives venous
branches corresponding to the ramifications of that artery. Among them, I shall men-
tion particularly the ciliary veins, which commence in the choroid membrane of the eye,
where they are called vasa vorticosa, on account of being arranged in whirls.
The Coronary Sinus.
The coronary sinus, or circular sinus of Ridley (i), runs round the margin of the pituitary
fossa, and completely surrounds the pituitary body. Its posterior is much larger than
its anterior half. In old subjects it is not rare to find the quadrilateral plate of the sphe-
noid bone behind the pituitary fossa worn away, as if corroded by the blood of the sinus,
so that it may easily be broken. At this period of life, the coronary sinus is larger than
in young subjects, and extends under the pituitary body itself
The coronary sinus only receives osseous veins from the sphenoid, some veins from
the dura mater, and those from the pituitary body. It opens freely on each side into the
cavernous sinuses, which thus communicate with each other.
The Anterior Occipital, or the Basilar Sinus.
The anterior or transverse occipital sinus (r) is median and single ; it extends trans-
versely across the basilar groove from the foramen lacerum posticus of one side to that
of the other ; it is of an irregular form, much larger in the aged than in adult and young
snbjects, and connects the superior and inferior petrosal sinuses and the ca\ ernous sinus
of one side with the corresponding sinuses of the opposite side. In old subjects, the
basUar surface not unfrequently appears as if corroded opposite this sinus, the cavity ol"
which often presents a cellular or spongy structure.
The Posterior Occipital Sinuses.
These {k k) are the smallest of all the sinuses of the dura mater ; they commence one
at each foramen lacerum posticus, pass from thence upon each side of the foramen
688 ANGEIOLOGY.
magnum, converge towards the falx cerebelli, enter its substance, and open separately
into the confluence of the sinuses : they receive some small veins from the bones of the
cranium and from the dura mater : the posterior occipital sinuses may be said to repre-
sent the chord of the arc formed by the lateral sinuses.*
The Confluences of the Sinuses.
From what has been stated above, it appears that there are three central points in
which all the sinuses meet : one situated behind and in the middle line, and one on each
side of the middle line in front. The term confluence of the sinuses might be applied to
all three points, but it has hitherto been confined to the posterior and median central
point, or occipital confluence. All the sinuses open directly into one of these three
points, the inferior longitudinal, if it be considered a sinus, forming the only exception.
The Posterior or Occipital Confluence, or Torcular Herophili. — If that portion of the dura
mater which corresponds to the occipital protuberance be opened from behind, six ori-
fices will be exposed to view, viz., a superior, which belongs to the superior longitudinal
sinus ; an anterior, sometimes divided into two by a vertical band, which belongs to the
straight sinus ; two lateral orifices, which belong to the two lateral sinuses ; and two in-
ferior, which belong to the posterior occipital sinuses. The point at which these sinuses
meet is named the torcular Herophili (n n,figs. 220, 221), because it is supposed that the
columns of blood flowing from the different sinuses must, in some degree, press against
each other.
The Anterior or Petro- sphenoidal Confluence. — Between the apex of the petrous portion
of the temporal bone and the sphenoid bone, there is on each side another confluence,
at which a great number of sinuses meet, viz., in front, the cavernous sinus and the cor-
onary sinus ; on the inside, the transverse occipital sinus ; and behind, the superior and
inferior petrosal sinuses.
The Branches op Origin of the Jugular Veins.
The Facial Vein.
The facial, or external maxillary vein (e, fig. 219), represents the artery of the same
name ; also the terminal divisions of the ophthalmic artery ; and, lastly, some of the
branches of the internal maxillary artery.
It commences in the frontal region, where it is called the frontal vein ; at the inner
angle of the eye it is named the angular vein ; and afterward the facial vein until its ter-
mination.
The frontal vein (la vein preparate, a, fig. 219) is a sub-cutaneous vein, which was se-
lected by the ancients for phlebotomy : it is sometimes single, and is then placed in the
median line ; but there are generally two frontal veins united by a transverse anasto-
mosis. Among the numerous varieties which this vein presents, I shall point out one
in which the two frontal veins are united into a single trunk, which bifurcates above the
root of the nose. These veins do not exactly follow the course of the frontal arteries ;
they descend from the vertex, where, by their numerous anastomoses, either with each
other or with the temporal veins, they form a venous plexus large enough to cover the
whole frontal region. They open into a transverse venous arch, having its concavity
directed downward ; it is sometimes tortuous : it is situated at the root of the nose, and
is named the nasal arch (t). This arch is also joined by the supra-orbital vein, a deep-
seated vessel (indicated by the dotted lines c), which runs transversely along the upper
part of the orbit, receives the superior internal palpebral vein, and opens into the ex-
tremity of the arch, on the outer side of the frontal vein : the ophthalmic vein also termi-
nates in the nasal arch of the vein, between which and the cavernous sinus it establishes
a free communication. Thus the upper parts of the face, more particularly the eye and
its appendages, are intimately connected with the brain through the medium of the veins
as well as of the arteries. Moreover, the dorsal veins of the nose, which run on each side
of the ridge of that organ, open into the concavity of the nasal arch.
The angular veins are given off from the right and left extremities of the nasal arch,
and may be regarded as the continuations of the frontal veins ; like the corresponding
arteries, each of them (d) is situated in the furrow between the nose and the cheek.
The inferior palpebral vein and the vein of the lachrymal sac and nasal duct enter the outer
side of each angular vein, which is joined on its inner side by the veins of the corre-
sponding ala of the nose.
The veins qf the ala nasi form a very dense network between the cartilage and the skin,
and also between the cartilage and the mucous membrane ; from these networks two
branches are given off: a superior, which runs along the convex border ; and an infe-
rior, which runs along the lower border of the inferior lateral cartilage, or the cartilage
of the ala. These two branches unite into a very large common trunk, which passes
upward, often very obliquely, into the angular vein.
The facial vein (e) commences in the angular vein, at the point where the latter is
* [They sometimes join the lateral sinuses in front, as shown in the figure.]
THE TEMPORO-MAXILLARY VEIN. 58^
joiaed by the veins of the nose ; it proceeds very obhquely dovi^nward and outward,
passes under the great zygomatic muscle, reaches and then runs along the anterior bor-
der of the masseter, crosses at right angles over the base of the jaw, is received into a
groove in the sub-maxillary gland, and terminates in several different modes.
Most commonly, it unites with the lingual to form a common trunk, which enters the
internal jugular ; it is into this common trunk of the facial and lingual veins that the su-
perior thyroid and the pharyngeal vein, and the common trunk of the temporal and inter-
nal maxillary veins, sometimes open. In other cases the facial vein passes obliquely
across the outer surface of the sterno-mastoideus, and enters at some point of the exter-
nal jugular vein. I have seen it directly continuous with the anterior jugular, also with
the external jugular of the same or of the opposite side, or it may enter the convexity
of an arch of conununication between the external and anterior jugular veins.
Collateral Branches. — During its course the facial vein in joined on its outer side by the
alveolar venous trunk, which is very large, and may be regarded as the deep branch of
origin of the facial vein, which, in fact, becomes much larger, sometimes even twice as
large, after its reception. This alveolar trunk commences in a very remarkable venous
plexus, named the alveolar plexus, in which the alveolar veins ■properly so called, together
with the infra-orbital, superior palatine, vidian, and spheno-palatine veins terminate, and
which communicates with the pterygoid plexus. All these veins accompany the branches
of the internal maxillary artery having the same names. From the alveolar plexus the
alveolar trunk runs forward and downward below the malar bone, and unites obliquely
with the facial vein. The facial is also joined on its inner side by the superior and infe-
rior coronary veins of the lip, which are distributed like the arteries, but are not tortu-
ous ; by the buccal vein or veins ; and by the anterior masseteric veins.
Below the base of the jaw, the facial vein is joined by the sub-mental vein ; by the in-
ferior palatine, which is remarkable for the plexus around the tonsils, which is formed al
most entirely by it ; also by the vein or veins from the sub-maxillary gland, and some-
times by the ranine vein.
During its course the facial vein is, in general, more superficial than the facial artery,
and does not accompany it on the face, but is situated more to the outside, and is not
tortuous.
The Temporo-maxillary Vein.
The temporo-maxillary vein, or venous trunk, represents the temporal artery, a part of
the internal maxillary, and the upper part of the external carotid : many authors follow
Walther in naming it the posterior facial vein, in contradistinction to the facial vein prop-
erly so called, which they name the anterior facial. The temporo-maxillary is formed
by the junction of the temporal and internal maxillary veins : it most frequently termi-
nates in the external jugular vein.
The Temporal Vein. — This vein commences above by superficial, middle, and deep
branches.
The superficial temporal veins (f,fig. 219) commence upon the crown of the head by
anterior or frontal branches, which communicate freely with the origin of the frontal vein,
by middle or parietal branches, which communicate with the corresponding branches of
the opposite side, and by posterior or occipital branches, which communicate with the
branches of the occipital vein. These form a very open network over the greater part
of the cranium. From this network anterior and posterior branches arise, and unite
with each other above or opposite to the zygomatic arch. During this course the veins
do not exactly follow the direction of the corresponding arteries. It might be said that
the veins of the scalp partake of the characters both of the venae comites and the sub-
cutaneous veins. These venous networks are, moreover, situated in the substance of
the hairy scalp, and, like the arteries, are placed between the skin and the occipito-
frontalis muscle.
The middle temporal vein is a very large vessel, often much larger than the common
trunk of the superficial veins. It is situated (as indicated by the dotted lines, g,fig. 219)
beneath the temporal fascia, between it and the temporal muscle. It is sometimes
formed principally by the junction of the palpebral with the external orbital veins, which,
corresponding in their distribution to the arteries of the same name, unite into a common
trunk that runs backward at first between the two layers of the temporal fascia, then be-
tween the muscle and the fascia, is directed backward and downward, again perforates
the fascia from within outward above the antero-posterior root of the zygomatic process,
and unites with the superficial temporal vein in front of the external auditory meatus.
The trunk resulting from the junction of the superficial temporal and middle temporal
veins passes vertically downward, between the external auditory meatus and the tem-
poro-maxillary articulation, dips into the substance of the parotid gland, and, having ar-
rived behind the neck of the condyle, receives the internal maxillary vein, wliich consti-
tutes the deep origin of the temporo-maxillary trunk.
The Internal Maxillary Vein. — This vein, the deep origin of the temporo-maxillary trunk,
is called by Meckel the internal and posterior maxillary, in opposition to the alveolar branch
600 «*> ANGEIOLOGY.
of the facial vem/wRicIi^lie calls the internal and anterior maxillary: it corresponds to all
the branches given off from the internal maxillary artery behind the neck of the condyle,
in the zygomato-maxillary fossa ; while the alveolar vein, the deep branch of the facial,
corresponds to all the branches given off by the internal maxillary artery upon the tuber-
osity of the superior maxilla and in the pterygo-maxillary fossa.
Thus it is joined by the middle meningeal veins. The venae comites of the middle me-
ningeal artery, the existence of which has been erroneously denied, are two in number,
and are situated, one in front, the other behind the artery. These veins often receive
some inferior and anterior cerebral veins, which enter them near the foramen spinosum
of the sphenoid ; they always receive veins from the bones of the cranium and from the
dura mater, and communicate with the superior longitudinal sinus ; they are sometimes
so large, especially the anterior branch, that they have deep grooves formed for them
upon the sphenoidal fossa, reaching from the foramen spinosum to the point of the great
ala of the sphenoid bone. Lastly, the distribution of the middle meningeal veins is sim-
ilar to that of the corresponding artery.
The internal meixillary vein is also joined by the inferior dental, by the deep temporal,
by the pterygoid, and by the posterior masseteric veins. All of these veins communicate
with a very large and important venous plexus, the pterygoid plexus, situated between
the temporal and external pterygoid muscles, and between the two pterygoid muscles.
In this plexus, which communicates freely with the alveolar plexus, so freely, indeed,
that they may be regarded as forming but a single plexus, the internal maxillary vein
commences and joins the temporal vein, behind the neck of the condyle of the lower jaw.
The temporo-maxillary trunk, thus formed by the junction of the temporal with the
internal maxillary vein, is much larger than the former vein, and continues its course
through the substance of the parotid gland ; it is joined directly by some parotid veins,
by the posterior and anterior auricular veins, and, lastly, by the transverse veins of the face.
The last-named veins form, between the parotid gland and the masseter muscle (j, fig.
219), between that muscle and the ramus of the lower jaw, and around the temporo-max-
illary articulation, a very large plexus, named the masseteric plexus, which communicates
freely with the pterygoid plexus through the sigmoid notch.
Termination of the Temporo-maxillary Trunk. — Most commonly the temporo-maxillary
vein or trunk terminates directly in the external jugular vein (h) ; at other times it enters
the internal jugular, and then there is merely a trace of the external jugular, which is
formed principally by the superficial branches of the occipital vein, and by some commu-
nicating branches from the anterior jugular. In some cases, the temporo-maxillary vein
is almost equally divided between the internal and external jugulars ; lastly, it is some-
times united to the lingual and the facial vein : when it ends in the external jugular, it
sends to the internal jugular a large conmiunicating branch which passes above the di-
gastric muscle.
The Posterior Auricular Vein.
The posterior auricular vein follows the distribution of the artery of that name ; it re-
ceives the stylo-mastoid vein, and enters the external jugular, or, rather, the temporo-
maxillary vein, which does not take the name of external jugular until after it is joined
by this vein.
The Occipital Vein.
The occipital vein is distributed in the same manner as the occipital artery ; it com-
mences at the back of the cranium, passes beneath the splenius muscle, and is joined
opposite the mastoid process by one or more large mastoid veins, which come from the
corresponding lateral sinus, establishing a direct and free communication between the
venous circulation in the interior and exterior of the cranium. It was this that led Mor-
gagni to prefer the occipital veins for the purpose of bloodletting in apoplexy. The oc-
cipital vein ends in the internal, and sometimes in the external jugular.
The Lingual Veins.
The lingual veins, being intended for a contractile organ, the circulation in which is on
that account liable to be much interfered with, are divided, hke the veins of the limbs,
into the superficial or suh-mucous, and the deep veins.
The superficial veins of the dorsum of the tongue, which are generally named the lingual
veins, occupy the dorsal region of the tongue, ramifying in a remarkable manner between
the mucous membrane and the muscular fibres of that organ : all these veins open into
a dorsal or superior lingual plexus, which is situated at the base of the tongue, and is
joined by a great number of veins from the tonsils and epiglottis.
The satellite vein of the lingual nerve emanates from this plexus, accompanies the lin-
gual nerve, receives some branches from the sub-lingual glands and the tissue of the
tongue, and enters the facial or the pharyngeal vein, or terminates directly in the exter-
nal jugular, communicating freely with the ranine veins.
The ranine veins are the superficial veins of the lower surface of the tongue. They
THE PHARYNGEAL VEIN, ETC. 991
are seen one upon each side of the fraenum, where they form a ridge beneath the mucous
membrane. Each of them accompanies the corresponding hypoglossal nerve, between
the genio-hyoglossus and hyoglossus muscles, and terminates either in the common
trunk of the lingual and facial veins, or directly in the facial vein.
The ranine veins communicate upon the sides of the tongue with a very large plexus,
the vessels composing which are sometimes provided with valves, so that it is impossi-
ble to inject it in a direction from the heart towards the extremities of the veins, which,
in other cases, may be done with the greatest facility.
Lastly, the lingual veins, properly so called, are extremely small; they are two in
number, and accompany the lingual artery throughout the whole of its course. Not un-
frequently the veins of the tongue terminate directly in the internal jugular : I have seen
them open into the anterior jugular.
The Pharyngeal Vein and Pharyngeal Plexus.
The Pharyngeal Plexus. — In making the section already described for examining the
pharynx, we observe round the back of that organ a considerable venous plexus, which
forms loops or rings for embracing the pharynx ; several meningeal branches, and some
derived from the vidian and spheno-palatine veins, open into this plexus ; from which a
variable number of pharyngeal branches arise, and terminate by a common trunk, or by
several distinct branches, in the lingual vein, sometimes in the facial or the inferior thy-
roid, and frequently in the internal jugular.
Besides this plexus, which may be called the superficial pharjTigeal plexus, an ex-
tremely dense network is found beneath the mucous membrane, from which branches
proceed to join with those that arise from the superficial plexus just described
The Superior and the Middle Thyroid Veins.
The superior thyroid, or thyro-laryngeal vein, commences upon the thyroid gland by
branches corresponding to the thyroid arteries, and upon the larynx by branches corre-
sponding to the ramifications of the superior laryngeal artery. The thyroid and laryn-
geal branches unite and end in the internal jugular vein, opposite the upper part of the
larynx ; they perhaps end more frequently in the common trunk of the facial and lingual
veins. It is not uncommon to find the superior laryngeal branch terminating directly
either in one or the other of these veins, or in the anterior jugular.
The middle thyroid vein arises from the lower part of the lateral lobe of the thyroid
gland, and is joined by some branches from the larynx and the trachea. By their union
they form a trunk, which ends in the lower part of the internal jugular vein. The con-
stant existence of this vein explains in some degree a rather frequent variety in the ar-
teries of the thyroid gland, viz., the existence of a middle thyroid artery given off by the
common carotid. Not unfrequently there are two middle thyroid veins on each side
These, as well as all the other thyroid veins, are much enlarged in goitre
The Veins of the Diplo'e.
To complete the description of the vessels of the head, it only remains for me to no-
tice the diploic veins, or the proper veins of the bones of the cranium. They were first
described by M. Dupuytren, in his inaugural thesis, under the name of venous canals of
the bones : they were afterward figured by M. Chaussier (Traite de V Encephale), and, to-
gether with their principal varieties, they have lately been represented with uncommon
accuracy by M. Breschet, in his admirable work upon the veins.
In the substance of the cranial bones there are found ramified venous canals, which
are occupied by veins, having only their internal membrane, the bony canals themselves
serving for an external coat. These venous canals are not exclusively confined to the
bones of the cranium : they exist in all spongy bones, and even in compact bones ; but,
while the canals are found in the entire substance of spongy bones, in the compact part
of the long bones they are situated near the medullary canal.
The venous canals of the bones of the cranium vary much in their size, and in the
extent to which they are distributed : they are independent of each other as long as the
cranial bones remain distinct and separable ; but they almost always communicate when,
in the progress of age, those bones become united together. They get larger and larger
as life advances, and their size is indirectly proportioned to the number of their ramifi-
cations : they sometimes present ampullae or dilatations, and at other times are suddenly
interrupted, and terminate in culs-de-sac, reappearing again farther on, or ceasing alto-
gether : these peculiarities depend upon the venous canal opening at different points
into the middle meningeal veins. Moreover, these venous canals communicate by a
number of orifices of different sizes, either in the interior of the cranium with the me-
ningeal veins, and with the sinuses of the dura mater, or on the exterior with the veins
which lie in contact with the bones of the scull.
In some heads of old subjects, these canals are found blended with the furrows for
the branches of the meningeal arteries ; those furrows- themselves present some large
foramina, which open into the cranium in various nlaces.
69^ ANGEIOLOGY.
In new-born infants there are no venous canals, properly so called ; but the whole
substance of the bones is traversed by a venous network, which may be seen when its
constituent veins are naturally injected with blood, or when they have been filled with
mercury, by which as delicate a network of vessels can be shown in the diploe as in in-
jections of the soft parts. At this period all the cells of the bones are filled with venous
blood.
On the roof of the cranium the canals of the diploe are divided into the frontal, tempo-
ral, parietal, and occipital.
The frontal diploic canals are two in number, one on the right, the other on the left
side : they commence by numerous ramifications upon the upper part of the frontal
bones, increase in size as they approach the lower part of the roof of the scull, commu-
nicate with each other by transverse branches, and also with the periosteal or the me-
ningeal veins, open externally by vascular foramina, and then enter the supra-orbital
and frontal veins.
The temporo-parietal diploic canals are divided into anterior and posterior : they corre-
spond to the furrows which contain the ramifications of the meningeal artery, and open
into those furrows by a great number of foramina, which become very distinct in advanced
life : they also communicate with the deep temporal veins on the exterior of the scull.
The occipital diploic canals, two in number, a right and a left, communicnte with each
other by a great number of branches, and open below into the occipital veins.
Summary of the Distribution of the Veins of the Head.
Circulation in the Brain. — Corresponding to two of the arterial trunks, the common
carotids, which convey blood to the head and neck, there are six veins, to return it back
to the heart from the same parts, viz., the two internal, the two external, and the two
anterior jugulars. This arrangement tends to prevent interruption of the venous circu-
lation in the head, which, from so many causes, is liable to be disturbed. The external
and anterior jugular veins belong to the sub-cutaneous venous system, and may be re-
garded as supplementary veins which have no corresponding arteries, and which would
be sufficient of themselves to carry on the venous circulation ; and as the veins of the
right and left sides communicate very freely with each other, it follows that one of them
would suffice to return the blood from the head. It will be seen hereafter, when de-
scribing the veins of the spine, that the obliteration of all the six jugular veins would
not of necessity be followed by interruption of the venous circulation in the cranium.
Lastly, it is important to observe, that the external and anterior jugulars open into the
sub-clavian vein, while the internal jugular joins the inner end of the sub-clavian, to
form the brachio-cephalic vein.
We have seen that the lower part of the internal jugular vein represents the common
carotid, and the upper part of it the internal carotid ; and that the external carotid is
represented by all the veins of the face and neck, which open into the internal jugular
either by a common trunk, or by several distinct branches.
The cerebral venous system is remarkable for the extreme thinness of the parietes
of the veins upon the brain, and for the existence of the sinuses, which take the place
of the venous trunks, and differ so much in their distribution from the arteries. The
cerebral veins are divided into the ventricular veins, which go to form the venae Galeni,
and the superficial veins of the brain. All of them run towards the sinuses, in which they
terminate in succession like the barbs of a feather upon the common shaft, but do not
acquire a great size. From the absence of valves at their orifices into the sinuses, the
blood may regurgitate into them. The presence of the spongy areolar tissue at the or-
ifices of these veins, together with their oblique course through the walls of the sinus,
must diminish this regurgitation : the communication of the cerebral veins with each
other, and the continuity of the several sinuses, explain the varied means contrived for
carrying on the cerebral circulation, which can only be interrupted by obliteration of the
lateral sinuses.
Lastly, the position of the principal sinuses opposite the fissures between the great di-
visions of the encephalon, and the resisting nature of the walls of the sinuses themselves,
prevent the fatal effects which might otherwise ensue from compression produced by
obstruction of the venous circulation.
Circulation in the Parietes of the Cranium. — In the parietes of the cranium we find the
veins of the dura mater, the veins of the diploe, the periosteal veins, and the veins of
the hairy scalp. The numerous communications existing between these four systems
of veins, and the direct communications established between the sinuses of the dura
mater and the veins on the exterior of the scull, are worthy of particular attention. I
would observe that the principal veins of the scalp, like the arteries of the same part,
are situated between the skin and the epicranial aponeurosis. I have ascertained the
existence of free and frequent anastomoses among these veins. As at the back of the
cranium there is a very free communication between the occipital vein and the lateral
sinus by means of a large vein, so, also, along the superior longitudinal groove, and op
posite the sutures upon the base of the scull (through most of the foramina found in that
THE DEEP VEINS OP THE UPPER EXTKEMITY. 593
ntoation), an uninterrupted communication is established between the veins within and
^ose outside the cranium.
Venous Circulation of the Face. — ^All the veins of the face and of the parietes of the
cranium end in two principal trunks, the facial and the temporal. The facial vein cor«
responds to a part of the internal maxillary artery, to a part of the ophthalmic artery,
and to the facial artery properly so called. One of the most remarkable circumstances
connected with the distribution of the facial vein is the communication between it and
the cavernous sinus, established at the inner angle of the orbit by means of the ophthal-
mic vein, so that the veins on the inside and on the outside of the cranium are most in
timately connected.*
The temporal vein represents the temporal artery, a part of the internal maxillary ar-
tery, and the upper part of the external carotid, and returns the blood from the entire
side of the head.
With regard to the veins of the tongue, we should remark the existence of two sub-
mucous veins, corresponding to the sub-cutaneous veins in the limbs, and intended to
return the blood, instead of the deep veins of the tongue, during the contractions of that
organ.
The size of the superior middle thyroid veins, their number, which exceeds that of
the arteries, and their free anastomoses with the inferior thyroid veins, render them an
important medium of circulation when the passage of the blood from the head is obstruct
ed, and, at the same time, a diverticulum in great impediments to the circulation.
The irregularity which exists in the relative size of the internal, external, and ante-
rior jugular veins, and also in the distribution of the veins of the head between these
three trunks, proves that, in the venous as well as in the arterial system, the origin or
termination of the vessels is of little importance, and that, after the venous system of
any part is once formed, it matters but little with which of the great vascular trunks it
is connected.
Lastly, the free communications which exist between all the preceding veins afford
sufficient evidence that but little interest need be attached to their termination in one
or another of the principal venous trunks.
The Deep Veins of the Upper Extremity.
The veiTts of the upper extremity are divided into the deep and the superficial or sub-
cutaneous.
The Palmar^ Radial, Ulnar, Brachial, and Axillary Veins.
The deep veins of the upper extremity exactly follow the course of the arteries, form
their venae comites, and take the same names : there are almost always two to each ar-
tery. The large venous trunks alone form exceptions to this rule. Thus, there are two
superficial and two deep palmar veins ; two deep radial and two deep ulriar veins ; we also
find two brachial veins ; but there is only one axillary and one suh-clavian vein. All these
venae comites receive branches formed by the union of still smaller ones, which are them-
selves the vense comites of the ramifications of the arteries, there being two veins with
each small artery. The sub-clavian vein, however, is an exception to this, for it does
not receive all the veins which correspond to the branches of the sub-clavian artery ;
while, on the other hand, it receives other veins that are totally unconnected with the
distribution of that artery. I ought to allude, in this place, to a mode of termination of
the collateral veins, which is frequently observed, especially in the brachial vein. The
circumflex veins, for example, instead of entering the brachial vein directly, terminate
in a collateral branch, which runs parallel to the brachial vein, like a canal running along-
side a river, and communicates with that vein above and below. Several large veins
have these collateral caneils, which establish a communication between different points
of their length. Thus, I have seen a venous trunk proceed from the external jugular, de-
scend through the brachial plexus of nerves, and enter the lower part of the axillary vein.
The deep veins, moreover, communicate freely and frequently with the superficial
veins. They are also provided with valves, like the superficial veins, and, it appears,
even with a greater number : an injection thrown from the heart towards the extrem-
ities will not enter more readily into one than into the other set. We always find two
valves at the mouth of a small vein where it opens into the larger trunk ; and it is a re-
markable fact that, while the valves situated in the course of the veins are sometimes
passed by the injection, those which are placed at the mouths of the small veins are
scarcely ever overcome.
The Sub-clavian Vein.
The term suh-clavian is generally given to all that portion of the brachial venous trunk
* The study of these anastomoses ought to lead us again to have recourse to those local venesections which
have fallen into disuse since the discovery of the circulation ; and it will enable us to determine, on anatomi-
cal grounds, the proper places at which they should be performed. Thus, it appears to me that we might ad-
vantageously introduce into jiractice bleeding from the angular vein in diseases of the eye ; from over the mas-
toid region, and the point wl'.ch corresponds to the junction of the longitudinal with the lambdoidal suture, in
cerebral affections; and bleeding from the ranine vein in diseases of the pharynx.
4 F
694 ANGEIOLOGY.
which extends from the vena cava superior to the scaleni muscles ; but this vein may
be described more naturally, as being limited internally by the brachio-cephalic vein, or,
rather, by the junction of the internal jugular vein with the venous trunk of the upper
extremity, and externally by the clavicle, or, rather, by the costo-coracoid, or sub-cla-
vian aponeurosis. If the sub-clavian veins be thus defined, they will be of equal length
on both sides ; and the left vein, and even the right vein also, will be shorter than the
corresponding artery.
The direction of the sub-clavian veins differs much from that of the arteries : we have
Seen that the sub-clavian arteries describe a curve over the apex of the lung, with its
concavity turned downward ; the sub-clavian veins, on the contrary, proceed directly
outward as far as the first rib, over which they bend, so that they resemble the cord of
the arc described by the sub-clavian artery. We have seen, also, that the inferior thy-
roid vein, the internal mammary, the vertebral, the supra-scapular, the posterior scapu-
lar, the deep cervical, and the left superior intercostal veins, enter not into the sub-cla-
vian, but either into the superior vena cava, or into the brachio-cephalic vein. The right
superior intercostal vein, when it exists, that is to say, when the branches which should
form it do not terminate separately in the vena azygos, is the only one of the veins cor-
responding to the branches of the sub-clavian artery which opens into the sub-clavian vein
The external jugular, the anterior jugular, and a small branch from the cephalic vein
of the arm, also terminate in the sub-clavian vein. It would therefore, in some respects,
be proper to describe the external and anterior jugulars in connexion with the sub-cla-
vian vein, instead of with the internal jugular. I would remark, that the external and
anterior jugulars frequently terminate, not in the sub-clavian vein, but at the point where
it ends in the brachio-cephaUc vein, in front of the internal jugular.
Relations. — In front of the sub-clavian vein is situated the clavicle, which is separated
from the vein only by the sub-clavian muscle, so that this vessel may be wounded in
fractures of the clavicle : a very dense fibrous sheath binds it down to the sub-clavius
muscle ; and it perforates the costo-coracoid or sub-clavian aponeurosis, which adheres
to it, and keeps it open when cut across ; behind the vein is the sub-clavian artery, from
which it is separated, towards the inner part, by the scalenus anticus ; below, it is in re-
lation with the pleura and with the first rib, on which there is a corresponding but slight
depression ; above, it is covered by the cervical fascia, which separates it from the skin :
a considerable swelling is often seen in this region when the venous circulation is ob-
structed.
The Superficial or Sub-cutaneous Veins of the Upper Extremity.
The sub-cutaneous veins of the upper extremity belong essentially to the skin and to the
subjacent adipose tissue, since all the branches from the muscles enter the deep veins.
The superficial are larger than the deep veins, with which they communicate freely at a
great number of points ; and it may be remarked, that the size of the one set of vessels
is always inversely proportioned to that of the other set. We proceed to describe them
in succession in the hand, the forearm, and the arm.
The Superficial Veins of the Hand.
All the largest veins of the hand are situated upon its dorsal aspect ; and it is worthy
of notice, that the largest arteries, on the contrary, occupy the palm of the hand. If the
superficial veins had existed on the palmar aspect, the venous circulation would have
been impeded whenever the hand was used in prehension. Entering into the large sub-
cutaneous network of veins situated upon the back of the hand are several branches,
which constitute the superficial, external, and internal collateral veins of each fingei , they
occupy the outer and inner borders of the dorsal surface of the fingers, and comnmni-
cate frequently on the dorsal surface of each phalanx and around the phalangeal artic-
xilations, but not upon the articulations themselves.
Opposite the lower part of each interosseous space, these collateral veins unite at an
acute angle, just as the digital arteries bifurcate at the same point. All the superficial
digital veins ascend vertically between the metacarpo-phalangeal articulations, which
they seem to avoid, and then enter into the convexity of a very irregular venous arch,
■which is formed by a series of loops, at each of the junctions of which one of the digital
veins is seen to terminate.
From the concavity of this irregular arch, which is turned upward, are given off a
/greater or less number of ascending branches, which are sometimes formed directly by
■ the junction of the digital veins, without the intervention of an arch. Among these
branches, we should especially notice the external branch, which is situated nearest to
the first metacarpal bone, and is called the cephalic vein of the thumb; also the innermost
branch, which corresponds to the fifth metacarpal bone, and, for some reason not very
'.well known, has been named the vena salvatella.
The Superficial Veins of the Forearm.
"The superficial veins are much more numerous on the anterior than on the posterior
THE SUPERFICIAL VEINS AT THE ELBOW, ETC. 595
aspect of the foreann. We find there the radial vein or veins, the ulnar vein, and the
median vein.
The superficial radial vein (r, in the representation of the superficial nerves of the arm)
is the continuation of the cephalic vein of the thumb ; it is situated along the outer side
of the carpus and of the radius, and it soon unites with some branches from the vena
salvatella, or vi^ith the salvatella itself The superficial radial vein often divides into
several branches, which are joined by others from the venous arch at the back of the
hand. There are sometimes two superficial radial veins. The vein or veins having
reached the middle of the forearm, turn forward upon the outer border of the radius, and
then continue to ascend vertically along the outer side of the anterior surface of the fore-
arm, up to the bend of the elbow.
The ulnar vein {u) commences partly from the vena salvatella, and another vein on the
dorsal region of the forearm, and partly from some branches which arise from the lower
part of the back of the forearm, and even from some small veins proceeding from the
thenar and hypothenar eminences.
The branches which arise from the vena salvatella and the back of the wrist pass for-
ward ; the other branches run backward ; the common trunk or trunks resulting from
their union are directed at first vertically upward, parallel with the superficial radial
vein, then somewhat obliquely forward, to anastomose with the median basilic vein,
above the bend of the elbow. When there is a second or posterior ulnar vein, it ends in
the basilic higher up, or else it anastomoses with the anterior ulnar vein.
Between the anterior radial and ulnar veins we find the common median or median vein
(m), formed by the anterior veins of the carpus and forearm. There may be more than
one median vein, and it is not unfrequently wanting, in which case its place is supplied
by a venous network, the branches from which enter separately into the radial and ulnar
veins. In some cases its place is supplied by an additional radial vein, and at other
times by the deep veins.
The Stiperficial Veins at the Elbow.
At the elbow all the veins are on the anterior aspect. The most common arrangement
is the following : on the outer side we find the upper portion of the radial vein or veins ;
on the inner sMe, the upper portion of the ulnar vein or veins, which pass in front of the
internal condyle of the humerus ; between the radial and ulnar veins is the median,
which divides into two branches : one external (a), which unites with the radial to form
the cephalic vein (c), and is called the median cephalic ; the other internal (e), generally
smaller, but more superficied than the preceding, which unites with the ulnar to form the
basilic vein {b), and is called the median basilic.
Several varieties are observed in the arrangement of the veins of the elbow ; some-
times the common median vein is wanting ; but then its cephalic and basilic branches
are given off by the radial, and the cephalic vein is almost always very small. In other
cases we only find two veins at the bend of the elbow, viz., the radial and the ulnar,
which are directly continuous with the cephalic and basilic. I once saw the common
median vein replaced by the anterior radial, and by a branch from one of the deep ulnar
veins.
The Superficial Veins in the Arm.
In the arm there are only two superficial veins, an external, named the cephalic vein,
and an internal or basilic.
The cephalic vein (c) is formed by the junction of the radial with the median cephalic
vein, which junction may occur at very different heights. It ascends vertically along
the outer border of the biceps ; then, running a Uttle inward, it gains the furrow be-
tween the deltoid and pectoralis major, passes over the summit of the coracoid process,
above or in front of which it curves backward, so as to enter the axillary vein immedi-
ately below the clavicle. From this curve the cephalic vein gives off a branch, which
passes in front of the clavicle, crosses at right angles over the middle of that bone, and
enters the sub-clavian vein. Not unfrequently the cephalic vein is replaced by a very
small branch.
The internal vein of the arm, which is called the basilic vein (i), is generally larger
than the cephalic. It is formed by the junction of the ulnar with the median basilic vein,
passes at first obliquely backward, and then vertically upward, in front of the internal
intermuscular septum, and enters either the brachial or the axillary vein.
General Remarks upon the Superficial Veins of the Upper Extremity.
From the preceding description, it follows that the cephalic vein forms the continua-
tion of the radial, which is itself the continuation of the cephalic vein of the thumb, and
that the basilic is a prolongation of the ulnar, which is a continuation of the vena salva-
tella. The median vein, placed as it is between the radial and ulnar veins, bifurcates
so as to tei-minate equally in the two latter veins, and estabhshes a free anastomosis be-
tween them. • ,
998 ANGEIOLOGY.
The anastomoses of the several sub-cutaneous veins together are very numeroois, and
enable them mutually to supply the place of each other. The anastomoses betvireen the
sub-cutaneous and deep veins are not less numerous.
Thus, the superficial collateral veins of the fingers communicate with the deep collat-
eral veins : communications exist between the superficial and deep veins of the carpus ;
very large communications exist between the two sets of vessels at the bend of the el-
bow, so that, in fact, they are continuous with each other ; thus, the superficial radial
vein is sometimes continuous with one of the deep radials, and the median, as it divides
into the median basilic and median cephalic, occasionally sends a very large branch to
the brachial. In one case, where the median vein was wanting, I found that the ulnar,
the deep interosseous, and the deep radial veins, formed a plexus, which gave oflT two
branches, an external to the cephalic, and an internal, which formed the deep brachial
vein. The superficial ulnar veins often communicate freely with the deep ulnar, beneath
the muscles attached to the internal condyle.
Along the arm, the basilic vein communicates with one of the brachial veins by several
transverse branches. Not unfrequently the basilic vein communicates with the brachial
by a very delicate branch, which forms a lateral canal.
Valves. — ^The valves are more numerous in the deep than in the superficial veins ;
they increase in number as we approach the upper part of the arm, and are much more
numerous in the basilic than in the cephalic vein. There are three in that part of the
cephalic which corresponds to the furrow between the deltoid and the pectoralis major.
There is one at the opening of the cephalic into the axillary ; another at the opening of
the basilic into the brachial ; all the small veins which enter the cephalic and basilic, as
well as those which terminate in the deep veins, are also provided at their openings
with valves, which prevent the regurgitation of the blood during life, and the passage of
an injection from the heart towards the extremities.
General Relations. — The sub-cutaneous veins are separated from the skin by the super-
ficial fascia, and by the layer of fat above it. The median basilic is the only exception,
for it is in contact with the skin, at least in the majority of subjects.
The sub-cutaneous veins must be carefully distinguished from the cutaneous veins, prop-
erly so called, which are in contact with the true skin, or even ramify in its substance,
and which are sometimes of considerable size, especially in the neighbourhood of certain
tumours.
From the relation of the median basilic vein with the brachial artery, over which it
crosses at a very acute angle, and from which it is separated only by the fibrous expan-
sion from the tendon of the biceps, it follows, that in emaciated persons the vein is al-
most in contact with the artery ; so that, in bleeding from the median basilic, if the vein
be perforated quite through, the artery may be wounded. The practical rules to be de-
rived from this anatomical fact are, in the first place, to avoid bleeding in the median
basilic as much as possible, and whenever it must be chosen, to open it either below
or above the point where it crosses over the artery.
In the description of the lymphatics and nerves of the arm, I shall point out their re-
lations with the superficial veins. I may now state, however, that the musculo-cutane-
ous nerve passes behind the median cephalic vein, and that the internal cutaneous di-
vides into several branches, some of which pass in front, and others behind the median
basilic vein.
THE INFERIOR OR ASCENDING VENA CAVA AND ITS BRANCHES.
The Inferior Vena Cava — the Lumbar or Vertebro-lumbar Veins — the Renal — the Middle
Supra-renal — the Spermatic and Ovarian — the Inferior Phrenic. — TVie Portal System of
Veins — the Branches of Origin of the Vena Porta — the Vena Porta — the Hepatic Veins.
— The Common Iliacs — the Internal Iliac — the Hemorrhoidal VeiTis and Plexuses — the
Pelvic Veins and Plexuses in the Male and in the Female. — The Deep Veins of the Lower
Extremity — the Plantar, Posterior, Tibial, Peroneal, Dorsal, Anterior Tibial, and Pop-
liteal— the Femoral — the External Iliac. — The Superficial Veins of the Lower Extremity
— the Internal Saphenous — the External Saphenous.
The vcTia cava inferior or ascendens, or the abdominal vena cava {I, fig. 222), is the large
venous trunk which returns the blood from all the parts below the diaphragm to the
heart.
It is formed below by the junction of the two common iliac veins (n n), opposite the
mtervertebral substance between the fourth and fifth lumbar vertebras ; it passes verti-
cally upward, and, having reached the lower surface of the liver, inclines a little towards
the right side, to gain the groove formed for it in the posterior border of that organ. At
the upper end of that groove the vena cava inferior perforates the tendinous opening in
the diaphragm, and also the fibrous layer of the pericardium, which is, as it were, blend
ed with the cordiform tendon at this point ; the vein then curves suddenly to the left,
and opens (r, fig. 192) horizontally into the posterior inferior part of the right auricle.
THE VERTEBRO-liUMBAU VEINS, ETC. 597
It is larger than the vena cava superior, but is not of uniform caliber throughout ; for
example, it increases in size in a marked degree immediately above the renal veins.
The vena cava inferior presents also a second still larger dilatation opposite the liver,
vphere it is joined by the hepatic veins ; in comparison w^ith its diameter at that point,
the vena cava inferior appears to be slightly contracted as it passes through the dia-
phragm.
Relations. — The inferior cava is in contact with the anterior surface of the vertebral
column, and runs throughout the whole of its extent along the right side of the aorta ; it
inclines somewhat obliquely to the right as it is about to pass into the groove on the
liver. In front it is covered by the peritoneum, the third portion of the duodenum, the
pancreas, the vena portse, which crosses it at a very acute angle, and at its upper part
by the liver, which forms a semi-canal, or a complete canal for it.
It adheres closely to the margins of the tendinous opening in the diaphragm, and to
the fibrous layer of the pericardium, as if its outer coat were blended with those struc-
tures.
The serous layer of the pericardium covers the vein, but the fibrous layer does not
form a sheath for it. The relations of the inferior cava with the liver account for the
erroneous notion of some old anatomists, that this organ was the centre from which all
the veins of the body proceeded.
There is no valve in the inferior cava ; but at its termination we find the Eustachian
valve, which has been already described with the heart.
Branches of Origin. — We have stated that the junction of the common iliac veins con-
stitutes the origin of the inferior cava. It is very rare to find these veins uniting above
the intervertebral disc between the fourth and fifth lumbar vertebrae ; but in some few
cases the junction has been observed to take place opposite the renal veins.
Collateral Branches. — The vena cava inferior receives all the veins corresponding to
the branches of the abdominal aorta, excepting the veins from the alimentary canal and
its appendages, of which it only receives those from the liver, viz., the hepatic veins.
All the abdominal veins which do not open directly into the inferior cava unite to form
a large venous trunk, called the vena porta. Thus, the vena cava inferior receives the
renal, the spermatic or ovarian, the lumbar, the supra-renal, and the inferior phrenic
veins ; while the superior and inferior mesenteric, the splenic, the pancreatic, and the
gastric veins open into the vena portae. It may still be said, however, that the vena
cava inferior receives all the abdominal veins ; for, in fact, the veins of the portal sys-
tem terminate in the vena cava through the medium of the hepatic veins. The portal
system is, therefore, an appendage to the inferior cava. For this reason, and also for
the sake of economizing subjects, I shall not describe the vena portae and its branches
until I have noticed the collateral veins of the vena cava inferior.
The Lumbar or Vertebro-lumbar Veins.
The vertebro-lumbar veins are three or four on each side, and correspond to the arteries
of the same name ; they have two branches of origin : an external or abdominal branch,
which represents the intercostal veins, and a posterior or dorso-spinal branch, which is
itself formed by the union of two other branches ; one muscular or cutaneous, which com-
mences in the muscles and integuments, and the other a proper spinal branch, which
forms part of the rachidiau venous system, to be hereafter described.
By the junction of these two branches a lumbar vein is formed, which runs forward
and inward in the groove on the body of the corresponding lumbar vertebra, and enters
the vena cava at a right angle. The left lumbar veins are longer than the right, in con-
sequence of the vena cava being situated towards the right side of the vertebral column •
they pass under the aorta.
The Renal Veins.
The renal veins are remarkable for their size, and occasion a great increase in the
diameter of the inferior cava, above the point where they open into it ; they are of un-
equal size on the two sides, and are unequal in length, on account of the vena cava be-
ing placed towards the right side of the vertebral column, and, therefore, nearer the right
than the left kidney : they also run more obliquely on the right side, on account of the
right kidney being generally situated lower down than the left.
These veins commence in the substance of the kidney by a number of minute divisions,
which unite into small, and then into larger branches, gain the surface of the organ, and
are collected into a single trunk, either in the hilus or at some distance from it. The
trunk of each renal vein is always placed in front of the corresponding artery. The left
renal vein passes in front of the aorta. We sometimes find one division of the left renal
vein in front of the aorta, and another behind it.
Plurality of the renal vein appears to me less common than an excess in the number
of the arteries.
The renal veins receive the inferior supra-renal and several veins from the surrounding
598 ANGEIOLOGY.
adipose tissue. The left renal vein is almost always joined by the spermatic or ovarian
vein of that side.
In some cases we find several communicating branches between the left renal vein
and the superior mesenteric, which is one of the branches of the portal system.
The Middle Supra-renal Veins.
The middle supra-renal or capsular veins, which are often numerous and very large, are
found on the surface of the supra-renal capsules, while the arteries enter into their sub-
stance from every point. The venous trunks run in the grooves seen upon the surface
of the organ. The left middle supra-renal vein almost always enters the renal vein of
the same side ; the right vein generally opens into the vena cava inferior.
The Spermatic or Ovarian Veins.
The spermatic veins commence in the interior of the testicle, where they form a great
number of those filaments which traverse the proper substance of the gland : they aU
terminate in branches, which are applied to the inner surface of the tunica albuginea, and
are bound down to it by a thin layer of fibrous tissue, a disposition somewhat resembling
that of the sinuses of the dura mater. The spermatic veins perforate the tunica albu-
ginea on the inner side of the epididymis, not opposite that body. They are soon joined
by the veins of the epididymis, so as to form a plexus, which communicates with the dor-
sal veins of the penis, and with the external and internal pudic veins. The spermatic
veins soon unite into five or six trunks, which pass upward in front of the vas deferens,
and, together with that caneil and the spermatic artery, enter into the formation of the
spermatic cord. These veins are tortuous ; they divide, and anastomose so as to form
the spermatic venous plexus, which is often tlie seat of varicose dilatations. The veins
ascend through the inguinal ring and canal, and having reached the interior of the pel-
vis, they leave the vas deferens, accompany the corresponding spermatic artery along
the psoas muscle, and terminate either in the renal vein, or in the inferior vena cava of
their own side.
In some cases the right spermatic vein opens both into the renal vein and the inferior
cava. When there are two veins on one side, they communicate with each other by a
great number of transverse branches, and, before terminating, unite into a single trunk.
The name plexus pampiniformis is given to a plexus generally formed by the spermatic
veins before their termination : this plexus is more frequently found on the left than on
the right side, according to the observations of Meckel.
The spermatic veins sometimes communicate with some branches of the portal system.
The left spermatic vein passes under the sigmoid flexure of the colon, which may per-
haps account for the greater frequency of varicocele on the left side.
The ovarian veins accompany the arteries of the same name : they commence by sev-
eral sets of branches, viz., uterine branches, which communicate very freely with the
uterine sinuses ; ovarian branches, properly so called ; branches from the round ligaments ;
and, lastly, some from the Fallopian tubes. All these unite within the substance of the
broad ligaments, and pass vertically upward, without being at all tortuous : in some ca-
ses they form a plexus pampiniformis.
The ovarian veins, like the uterine veins, become much enlarged during pregnancy.
The Inferior Phrenic Veins.
These exactly follow the course of the inferior phrenic arteries, to each of which there
are two veins.
The hepatic veins do not in any way correspond to the artery of that name ; they form
a separate system, or, rather, they are connected with the portal venous system, of which
they may be regarded as an appendage.
The Poktal Ststem of Veins.
The system of the vena porta {vena portarum), or the portal system, constitutes a spe-
cial venous apparatus, appended to the general venous system, and representing by it-
self a complete circulatory tree, having its roots, trunk, and branches. The first, or ve-
nous portion of this system of veins, is arranged like the veins of the other parts of the
body, and has its roots of origin in the spleen and pancreas, and in the sub-diaphragmatic
portion of the alimentary canal ; while the second, or arterial portion, sends its branches,
like those of an artery, into the interior of the liver.
The hepatic veins, which perform the functions of ordinary veins in reference to the
second or arterial portion of the vena portae, connect the system of the vena portae with
the general venous system.
The Branches of Origin of the Vena PortcB.
The branches of origin of the vena portae {i, fig. 222) consist of all the veins which
return the blood from the sub-diaphragmatic portion of the alimentary canal, and also
from the spleen and pancreas. They correspond to the branches of the coeliac axis,
THE VENA PORTiE.
M9
with the exception of the hepatic artery ; they unite FigL a». '
into three trunks, the great mesenteric (a), small mes-
enteric (b), and splenic (c) veins.
These veins are arranged like venae coraites to
the corresponding arteries.
The Great and Small Mesenteric Veins. — The intes-
tinal or mesenteric veins commence just as the ar-
teries terminate, by two layers of vessels, viz., a
sub-serous layer, the vessels of which ramify be-
neath the peritoneum, and a deep layer, formed by
the vessels of the coats of the intestinal canal. These
small vessels unite into anastomotic meshes, which
always lie subjacent to the arterial network, and
which terminate in larger branches, and thus con-
stitute a series of veins corresponding to the arter-
ies of the intestine. The right colic veins {d d) and
the veins of the small intestine (shown cut short at
e) terminate, the one in the right and the other in
the left side of the superior mesenteric or great mes-
araic vein (a) : this vein, in the early periods of in-
tra-uterine life, receives the omphalo-mesenteric vein,
a branch which corresponds to the omphalo-mesen-
teric artery, and commences upon the vesicula um- i
bilicalis ; the artery and the vein disappear about
the third month of utero-gestation, but the vesicle remains for a longer period. On the
other hand, the left colic veins (/) enter the inferior mesenteric or small mesaraic vein (J) :
this vessel forms the continuation of the superior hemorrhoidal veins {g), which commu-
nicate very freely with the middle and inferior hemorrhoidal branches of the internal
iliac vein.
The splenic vein (c), which is proportionally larger than the artery, arises in the cells
of the spleen by a great number of roots, which gradually unite in the hilus of that organ,
and form the same number of branches as there are arteries, each coming from a dis-
tinct compartment of the organ. All these branches soon unite into a single trunk,
which passes across to the right side behind the pancreas, and, therefore, behind the
splenic artery, which it accompanies without being tortuous : it is one of the branches
immediately concerned in forming the trunk of the vena portae. During its course, the
splenic vein receives the venous vasa brevia {h h) from the stomach.
The inferior mesenteric vein opens into the splenic ; so that there are only two venous
trunks, the union of which constitutes the vena portae, viz., the splenic and the great or
superior mesenteric.
The Vena Portce.
The trunk of the vena porta (i) is formed by the union of the splenic and superior mes-
enteric veins at an acute angle, behind the right extremity of the pancreas, in front of the
Tertebral column, and to the left of the vena cava inferior. The vena portae is larger
than either of its two branches of origin, but is smaller than the two taken together. It
passes obliquely upward and to the right side ; and, after running for about four inches,
reaches the left extremity of the transverse fissure of the liver, where it terminates by
bifurcating. The following are its relations during its course : anteriorly it is covered
by the head of the pancreas, the second portion of the duodenum, the hepatic artery, the
biliary ducts, and the lymphatics of the liver, and also by some branches from the hepatic
plexus of nerves ; posteriorly it is covered by that portion of peritoneum which dips be-
hind the vessels of the liver into the foramen of Winslow, to line the sac of the great
omentum. By this foramen it is separated from the inferior vena cava, the direction of
which it crosses at a very acute angle.
The two branches into which the vena porta? divides in the transverse fissure of the
liver separate so widely from each other, that they seem to form a trunk, at right angles
to which the vena portae itself is attached. Some anatomists apply the term sinus of the
vena porta to that portion of the vein which is situated in the transverse fissure ; that part
of the vein which adheres to the liver is more commonly called the hepatic portion of the
vena portae, to distinguish it from the free and floating part, which is named the abdom-
inal portion.
The two divisions of the vena portae pass horizontally each towards the correspond-
ing lobe of the hver ; they soon divide and subdivide into diverging branches, which sup-
ply all the granules or lobules of the liver. The branches of the vena portae are accom-
panied by the ramifications of the hepatic artery and biliary ducts. The capsule of Glis-
son, or the fibrous coat of the liver, is reflected upon them, and forms a common sheath
for them. (See Liver.)
Before birth, the hepatic portion {p, fig. 164) of the vena portae receives, besides the
v|690 ANGEIOLOGY.
abdominal portion of the same vein, the umbilical vein (u), which is obliterated soon after
birth. Nevertheless, I once found it perfectly permeable in an adult.*
Before birth the ductus venosus (d) extends from the hepatic portion of the portal vein
to the vena cava inferior, between which and the vena portae it establishes a direct com-
munication. This hepatic portion might> therefore, be named the confluence of the veins
of the liver.
The Hepatic Veins.
The capillary radicles of the hepatic or supra-hepatic veins commence in the capillary
divisions of the vena portae, and, gradually uniting into larger and larger branches, con-
verge towards the posterior border of the liver, or, rather, towards the fissure for the
vena cava inferior, at which point they terminate by an indefinite number of small
branches, named the small hepatic veins, which open all along the fissure ; and also by two
principal trunks, the great hepatic veins, which end in the vena cava immediately before
It passes into the opening in the diaphragm. One of these great hepatic veins comes from
the right lobe, and the other from the left lobe of the liver.
The vein of the left side often receives a great number of branches from the right lobe
of the liver, and is larger than the vein of the right side.
The vena cava inferior is always dilated into a large ampulla opposite the openings of
the hepatic veins.
It follows, from the previous description, that, in the liver, the branches of the hepatic
veins and those of the vena portae run directly across each other, since the latter diverge
from the centre of the organ towards its right and left extremities, while the former con-
verge from the anterior towards the posterior border.
Moreover, the branches of the hepatic veins are unaccompanied by other vessels, and
are in direct contact with the tissue of the liver ; while those of the vena porta; are sep-
arated from it by the capsule of Glisson, and are accompanied by the ramifications of the
artery, the nerves, and the hepatic ducts.
I shall farther remark, that although the hepatic veins gradually unite, like other veins,
into branches, which decrease in number, but increase in size, they most of them receive
besides, during their course, a multitude of capillary vessels, the inter-lobular hepatic
veins, from the neighbouring lobules ; so that their internal surface is perforated with in-
numerable foramina.
The cribriform structure of their internal surface is therefore a peculiar characteristic
of all the hepatic veins [except the very large ones], and enables us always to distinguish
them from the branches of the vena portae.
Lastly, the capillary communication between the extremities of the vena portse and
hepatic veins is extremely free, as may be shown even by very coarse injections.
AH the veins of the portal system are without valves,t and they can therefore be in-
jected with the greatest ease from the trunks towards the extremities. An injection
thrown in towards the intestine penetrates very readily into the interior of the alimentary
canal, so that the minute branches of the vena portae appear to open at the apex of each
villus. This can be made evident by throwing mercury into the vena portae, and then
forcing it on by an ordinary injection ; drops of the mercury will then be seen in the
open mouth of each villus.J
The system of the vena portas is not so completely isolated from the general venous
system as is commonly stated. It always communicates with branches of the iirtemal
iliac veins by means of the middle hemorrhoidal veins, and communicating branches
with the renal veins have also been noticed ; and hence injections of the vena cava in-
ferior always enter in a greater or less degree into the veins of the portal system.
The Common Iliac Veins.
The common iliac veins (n n, fig. 222) correspond exactly to the arteries of the same
name ; they commence opposite the sacro-vertebral articulation by the junction of the
internal and external iliac veins, and terminate by uniting at an acute angle to form the
vena cava inferior or ascendens, the point of union being opposite the articulation of the
fourth and fifth lumbar vertebrae, to the right side of, and a little below, the bifurcation
of the aorta.
The common iliac veins hare the same relation to the lower extremities that the
brachio-cephalic veins bear to the upper ; and as the right brachio-cephalic vein is shorter
and more vertical than the left, so also is the right common iliac vein shorter and mere
vertical than the left.
The relations of the common iliac veins with the corresponding arteries are remarkable,
inasmuch as they are placed between these vessels and the vertebral column. The
right common iliac vein is situated to the outer side of and behind the corresponding ar-
* Anat. Pathol., livraison 17.
t M. Bauer says that he has seen valves in the venous vasa brevia of the stomach ; I have never been able
to discover them.
t [The escape of the mercury is due to rupture of the bloodvessels. In tlie villi, the minute branches of
the vena portae commence la t!',t ciijiillary network described and figured at page 36!).]
THE INTERNAL ILIAC VEIN, ETC. %9i
leiy, and is parallel to it ; while the left common iliac is situated on the inner side, and
behind the corresponding artery, and is covered by its lower part. At the point where
the left common iliac vein joins the vena cava inferior, it is also crossed obliquely by ihe
right common iliac artery. It follows, therefore, that the left common illiac vein is
covered, and may be compressed by both common iliac arteries, while the right common
iliac vein cannot be compressed by either of them, and probably this is partly the reason
why anasarca of the left lower extremity is more common than in the right extremity
m atonic diseases.
The right common iliac vein receives no collateral branch ; the left common iliac (n,
fig. 223) is joined by the middle sacral vein (h).
The middle sacrai vein is situated in the median line, and its size depends upon that of
the artery of the same name ; it belongs to the rachidian veins, with which it will be
described
The Internal Iliac Vein.
The internal iliac or hypogastric vein exactly represents the internal iliac artery, on the
inner side of which it is situated, separated from it, however, by a very thin fibrous
layer, which holds it down against the walls of the pelvis.
The internal iliac vein receives the venae comites of the branches of the internal iliac
artery, the umbilical arteries in the foetus alone being excepted ; for their satellite vein,
the umbihcal vein, which is £dso peculiar to the foetus, terminates in the hepatic portion
of the vena portae, as we have already seen.
The internal iliac vein, therefore, receives the blood returned from the parietes of the
pelvis, from the organs contained within the cavity of the pelvis, and from the external
genitals. There are always two veins for each artery ; but the two unite into a single
vein at their point of termination in the principal trunk.
The veins belonging to the parietes of the pelvis, viz., the gluteal, obturator, and sciatic
veins, are arranged precisely like the corresponding arteries. The ilio-lumbar and lateral
sacral veins {i,fig. 223) form part of the rachidian system, which will be specially described.
The veins belonging to the genito-urinary organs present a plexiform arrangement
both in their trunks and in their roots, which deserves particular attention.
Some of the venous plexuses of the pelvis are found both in the male and female, as
the hemorrhoidal, while some are peculiar to one or the other sex, as the vesico-prostatic
and the plexuses of the penis to the male, and the vaginal and uterine plexuses to the
female.
The Hemorrhoidal Veins and Plexuses.
The hemorrhoidal veins and plexus form a venous network, surrounding the lower end
of the rectum. They are formed by the superior hemorrhoidal veins, which form the com-
mencement of the inferior mesenteric, and by the middle and inferior hemorrhoidal veins,
which are branches of the internal iUac. We ought to notice in particular the sub-mu-
cous venous network near the anus. The plexus formed by it is analogous to that found
in all other mucous membranes ; its vessels are liable to become varicose, a condition
which constitutes the greater number of hemorrhoidal tumours.
The Pelvic Veins and Plexuses in the Male.
Preparation. — Introduce one injection-pipe into the corpus cavernosum, and another into
the glans penis, and then push an injection simultaneously into both of them, and also
into the crural vein.
The superficial scrotal veins tenninate partly in the superficial veins of the perinseum,
and partly in the external pudic branches of the femoral vein ; they communicate with
the superficial veins of the under surface of the penis.
The Vesical Veins, or Vesico-prostatic Plexus. — The prostate gland and the neck ol the
bladder are covered by a very complicated plexus of veins, which become exceedingly
developed in chronic inflammation of the bladder ; it receives the superficial veins of the
penis, and gives off the vesical veins.
This plexus, which communicates with the hemorrhoidal plexus behind, is supported
by a very thick fibrous layer, which is continuous with the pelvic fascia, and which lim-
its the degree of dilatation of the veins of the plexus in the same way as the dura mater
limits the dilatation of the sinuses contained between its layers.
The Veins and Plexuses of the Penis. — The veins of the penis are divided into a superfir
cial and deep set, the former representing the sub-cutaneous veins of the limbs. They
commence in the skin of the prepuce, and run backward along the upper and lower sur-
faces of that organ. The superior are called the dorsal veins of the penis ; they commu-
nicate freely with each other by large branches ; most of them run beneath the arch of
the pubes, between it and the corpus cavernosum, passing through some openings or
fibrous canals in the sub-pudic ligament, which have the effect of keeping the veins al-
ways open ; they end by assisting in the formation of the prostatic plexus. These veins
communicate freely with the deep veins, especially opposite the junction of the two crura
4 G
602 ANGEIOLOGY.
of tHfe corpus cavemosum : this communication is proved by the fact that the superficial
vessels are always filled when the injection is thrown into the deep veins.
The areolar tissue of the corpus cavemosum and that of the corpus spongiosum may
be regarded as composed of a venous network or plexus at its maximum of development.
Branches proceed from this plexus, which correspond to the divisions of the internal
pudic artery, and follow the same course.
These veins, and the vesico-prostatic plexuses, are liable to become varicose ; hard
earthy concretions, called phlebolites, are also frequently found in them.
The Pelvic Veins and Plexuses in the Female.
The vesical, or vesico-urethral plexus of the female, is less developed than that of the
male, on account of the absence of veins corresponding to the superficial veins of the pe-
nis, which are represented by a few branches from the labia majora. This plexus commu-
nicates with the veins of the clitoris, and also very freely with the vaginal plexus behind
The vaginal plexus is a vascular network, extremely well developed, especially oppo-
site the orifice of the vulva, which is entirely surrounded by it with several series of cir
cular anastomosing veins : it communicates with the vesical plexus in front, and with
the hemorrhoidal plexus behind ; so that all the plexuses in the pelvis are involved in
the state of turgescence, which a.ccompanies the phenomenon of erection in the female.
The radicles of this vaginal plexus commence in the mucous membrane of the vagina,
and especially in the erectile tissue surrounding the orifice of that canal ; some large
veins arise, in particular, from the bulb of the vagina, forming a true erectile apparatus,
which we have already described. (See Splanchnology, p. 320.)
The Uterine Plexus. — The veins contained in the substance of the walls of the uterus
do not present any trace of the tortuous arrangement of the corresponding arteries. In
order to obtain a satisfactory idea of them, they should be studied in a gravid uterus.
The uterine veins, like the uterine arteries, are then found along the sides and upper an-
gles of the organ ; opening into these veins are found larger venous canals, which run from
side to side through the substance of the uterus, and anastomose frequently with each
other. These venous canals are called the uterine sinuses, on account of their great
size during gestation, and from the dilatations presented by them at the confluence of sev-
eral secondary veins : they are also entitled to be so named from their structure, which
has some analogy with that of the sinuses of the dura mater, inasmuch as only the lining
membrane of the veins is prolonged into them ; their outer coat is formed by the proper
tissue of the uterus, and hence the walls of these veins are contractile. I have stated
elsewhere that, in reference to its veins, we may consider the uterus as consisting of an
erectile tissue with muscular walls ; it is scarcely necessary to add, that these sinuses
are unequally developed in different parts of the uterus, and that the point to which the
placenta has been attached may be recognised by the greater size of the adjacent ute-
rine sinuses.
The veins contained within the substance of the walls of the uterus do not open into
the uterine veins alone ; several of them terminate in the ovarian veins, which commu-
nicate freely with the uterine, and may, if necessary, supply their place.
The great size acquired by the uterine veins, both in the substance and on the surface
of the uterus, proves that the venous apparatus plays an important part in the intersti-
tial development of this organ.
Moreover, the size of the veins and venous plexuses belonging to all the genito-urinary
organs, and the essentially venous structure of such organs as are capable of being erect-
ed, prove that the venous system performs an essential part in the truly active phenom-
ena of erection. It is partly upon these anatomical and physiological arguments that I
have endeavoured to show the active part performed by the veins in all the great phe-
nomena of the economy, such as nutrition, secretion, inflammation, &c.
The pelvic veins are provided with a great number of valves, which prevent injections
from passing from the heart towards their extremities ; it ought to be remembered, that
the venous plexuses of the pelvis establish a very important and verv free communica-
tion between the veins of the right and left sides of the body.
The Deep Veins of the Lower Extremity.
The veins of the lower extremities, like those of the upper, are divided into the deep
veins or venae comites of the arteries, and the superficial veins.
The Plantar, Posterior Tibial, Peroneal, Dorsal, interior Tibial, and Pop
liteal Veins.
The external and internal plantar veins unite to form the posterior tibial, which accom-
panies the artery of that name, and soon joins the peroneal vein, to constitute the tibio-
peroneal vein : again, the anterior tibial vein, which commences by the vena dorsalis pedis,
perforates the upper part of the interosseous ligament, joins the tibio-peroneal vein, and
in this way forms the popliteal vein Up to this point there are two venae comites for
each artery, one of the veins being placed on each side of the artery, across which thev
THE FEMORAL VEIN, ETC. 608
very frequently send communicating branches. The peroneal veins are generally larger
than the posterior tibial, and receive all the muscular veins from the posterior and out«»-
tegions of the leg.
Commencing with the popliteal, there is only one vein for the main artery of the
limb ; but the arteries of the second and third order always have two veins.
The popliteal vein is situated in the popliteal space, behind and in contact with the ar-
tery. Its coats are remarkably thick, so that when cut across it remains open, and in
the dead body has been sometimes mistaken for the artery. Below, and opposite the
articulation of the knee, the vein is situated immediately behind the artery ; above the
joint it is behind, and a little to the outer side.
The popUteal vein receives the large bundles of veins, the sural veins, from the gas
trocnemius muscle : they are remarkable ft)r the number of their valves ; also the articu-
lar veins, and generally the external saphenous vein. I have seen a small vein having
very numerous valves, and being analogous to the collateral venous canals of which I
have already spoken, extend from the upper part of the anterior tibial to the middle of
the popliteal vein.
The Femoral Vein.
The femoral vein, like the artery of that name, is bounded below by the ring in the
tendon of the adductor magnus, and above by the crural arch ; it has different relations
with the femoral artery in various parts of its course : thus, below, it is on the outer
side of the artery ; higher up, it is situated behind that vessel ; lastly, from the entrance
of the vena saphena interna to the crural arch, it is placed to the inner side of the artery,
and is in close contact with the posterior part of the opening for the femoral vessels ; so
that femoral hemiae descend in front of the vein, but not of the artery. The femoral vein
is single, like the artery ; nevertheless, there are one or two collateral venous canals,
which run parallel with the lower half, or lower two thirds of that vein ; some commu-
nicating branches from the internal saphenous vein, and some muscular branches, open
into these venous cauEds, which are always abundantly supplied with valves.
The femoral vein receives all the branches corresponding to the divisions of the fem
oral artery, excepting the external pudic veins and the cutaneous veins of the abdomen,
which terminate in the internal saphenous vein.
The great deep vein (profunda) opens into the femoral about ten or twelve lines be-
low the crural arch.
The External Iliac Vein.
The external iliac vein is bounded below by the femoral arch, and terminates at the up-
per part of the sacro-iliac symphysis by uniting with the internal iliac vein ; it has the
same relations as the artery, and is placed behind and to the inner side of that vessel,
excepting over the os pubis, where it is exactly to the inner side of the artery. In one
case I found the left common iliac receiving the right internal iliac, so that the right ex-
ternal iliac was prolonged into the vena cava.
The external iliac receives the epigastric and the circumflex iliac veins. These two
veins are double, but each pair unites into a single trunk, as it is on the point of open-
ing into the external iliac vein.
All the deep veins of the lower extremity, excepting the external iliac, are provided
with valves. There are four in the deep femoral, the same number in the popliteal, and
many more in the tibial and peroneal veins ; the mouths of all the small veins which
open into them are provided with a pair of valves.
The Superficial Veins of the Lower Extremity.
The superficial veins of the lower extremity are much less numerous than those of
the upper, and all terminate in two trunks, viz., the internal saphenous vein and the exter-
nal saphenous vein.
As in the hand, they are all situated upon the dorsal region of the foot. All the col-
lateral veins of the toes enter the convexity of a venous arch, which is more regular and
constant than that in the hand, and which is placed on the fore part of the metatarsus.
From the inner end of this arch is given off a large branch, named the internal dorsal
veir of the foot, which is the origin of the internal saphenous vein ; the outer extremity
also gives off a somewhat smaller branch, called the external dorsal vein of the foot, which
forms the commencement of the external saphenous vein.
The Internal Saphenous Vein.
The internal or great saphenous vein (saphena interna, s, in the representation of the
superficial nerves of the leg) is a collateral vein gf the femoral venous trunk, and is con-
tinuous with the internal dorsal vein of the foot. The last-mentioned vein commences
at the inner extremity of the dorsal venous arch of the foot, into which the collateral
veins of the great toe open ; it runs along the dorsal surface of the first metatarsal bone
and the corresponding part of the tarsus, and receives, during its course, a deep branch
from the internal plantar vein and all the superficial veins of the internal olantar region,
604 ANGEIOLOGY.
and particularly the internal calcaneal vein, which is sometimes large, and which, in cer-
tain cases, does not terminate in the saphenous vein until it has reached above the in-
ternal malleolus, around the posterior border of which it turns. The internal saphe-
nous vein succeeds to the one just described ; it is reflected upward in front of the
internal malleolus, and continues to ascend upon the inner surface, then along the pos-
terior border of the tibia, and upon the back of the internal tuberosity of that bone and
the internal condyle of the femur. In this place it is situated on the inner side of the
tendons of the semi-tendinosus, gracilis, and sartorius ; it then inclines forward, descri-
bing a slight curve, with its concavity directed forward ; ascends along the anterior bor-
der of tfie sartorius, and crosses obliquely over the adductor longus ; having arrived at
the saphenous opening in the fascia lata, about eight or ten inches below Poupart's lig-
ament, it immediately curves backward, passes through that opening, and enters into
the femoral vein, just as the vena azygos enters into the superior vena cava, that is to
say, it describes a loop having its convexity directed downward. Several lymphatic
glands are found near this curve.
Relations. — The internal saphenous vein is separated from the skin by a very thin
fibrous layer, the superficial fascia, and is in relation with the internal malleolus, the
tibia, the tibial origin of the soleus, the tendons of the semi-tendinosus, gracilis, and sar-
torius, with the last-named muscle itself, and with the adductor longus. It is accompa-
nied by the internal saphenous nerve, from the knee down to the internal malleolus.
During its course it receives all the sub-cutaneous veins of the thigh, most of the sub-
cutaneous veins of the leg, the sub-cutaneous veins of the abdomen, the external pudic
veins, and several communicating branches from the deep veins.
The sub-cutaneous femoral veins of the back of the thigh sometimes unite into one rath-
er large trunk, which appears like a second internal saphenous vein ; it runs parallel with
the regular vein, and enters it at a greater or less distance from its termination. I have
met with an anterior superficial vein which commenced around the patella, ascended
vertically along the anterior region of the thigh, and might be regarded as a third.saphe-
nous vein. In one case of this kind, these three saphenous veins, viz., the anterior,
posterior, and internal, entered separately into the femoral vein, or, rather, into a dilata-
tion in which the internal saphenous vein terminated.
The internal saphenous vein often presents the following arrangement : opposite the
lower part of the leg, or at the lower end of the thigh, it divides into two equal branches
which pass upward, communicate with each other by transverse branches, and unite af-
ter running a variable distance ; in these cases the two branches represent a very elon-
gated ellipse. I have even seen this arrangement in both the thigh and leg of the same
subject, that is to say, the saphenous vein divided into two branches in the leg, which
united opposite the internal tuberosity of the tibia, and again divided in the thigh.
It is not uncommon to find a venous network supplying the place of the internal saphe-
nous vein in the thigh.
The sub-cutaneous abdominal veins should be arranged among the superficial and sup-
plementary veins, although there is a small artery, the superficial epigastric, which cor-
responds to them. There are three or four of these veins, which are joined by one from
the gluteal region ; they open sometimes by a common trunk, sometimes by three or
four distinct trunks, into the internal saphenous, just as that vein is passing through the
fascia lata. In a case of obliteration of the vena cava I found these veins very large,
and prolonged over the thorax into the axilla, where they anastomosed with the cuta-
neous branches of the intercostal and thoracic veins. In a case in which the umbilical
vein was persistent, the right and left internal saphenous veins were tortuous, and as
large as the little finger.*
The internal saphenous also receives the external pudic veins ; and I have seen it joined
by the obturator vein, which commenced by a common trunk with the epigastric.
The communicating branches of the internal saphenous with the deep veins are very nu-
merous, and should be studied in the foot, the leg, and the thigh. The origin of the in-
ternal saphenous vein gives off a branch, which communicates with the internal plan-
tar vein.
Along the leg several other branches exist, which establish a communication between
the internal saphenous and the posterior tibial veins ; these branches perforate the tib-
ial origins of the soleus muscle.
There is a very remarkable communication between the anterior tibial and internal
saphenous veins in the middle third of the leg, by means of a branch which proceeds
from the anterior tibial vein in front of the fibula, becomes sub-cutaneous, is reflected
inward and upward between the fascia of the leg and the skin, and terminates in the in-
ternal saphenous.
Again, an inferior, internal, articular vein enters the internal saphenous.
Lastly, the anastomoses in the thigh, between the deep and the superficial veins, aiu
less numerous than those in the leg ; at most we only find two such describing loops, with
the concavity directed upward.
* Anat. Path., liv. xviii.
1
THE VEINS OF THE SPINE. #11$
Valves. — The number of the valves appears to me variable : I have counted six along
the internal saphenous, but at other times I have not found more than two or four.
There is a greater number of valves in this vein in the thigh than in the leg.
The External or Posterior Saphenous Vein.
The external saphenous vein (la peroneo-malleolaire, Chauss. ; see figure of nerves ot
.eg), smaller and much shorter than the internal saphenous, is a branch of the popliteal
vein ; it forms a continuation of the external dorsal vein of the foot, vi'hich commences
from the outer extremity of the dorsal venous arch ; it passes behind the peroneo-tibial
articulation, crossing it from before backward ; it receives, as it runs outward, a grea<
number of branches, the chief of which come from the external plantar region ; also an
external calcaneal vein, which is sometimes of considerable size, and comes from thr
outer side of the os calcis ; the vein then runs along the outer border of the tendo Achil-
lis, and crosses it at a very acute angle, to reach the middle line of the posterior aspect
of the leg : conmiencing at this point, it passes directly upward, crosses the internal
popliteal nerve, and terminates in the popliteal vein between the internal and external
popliteal nerves, between the two heads of the gastrocnemius, and by the side of the in-
ternal inferior articular vein.
In some subjects the external saphenous, at the moment when it bends to dip into
the pophteal space, gives off an ascending vein, which runs along the posterior border
of the semi-membranosus muscle, as high as the upper third of the thigh, where it then
turns forward to open into the internal saphenous, or one of the branches of that vein,
immediately below its opening into the femoral.
Relations. — The external saphenous vein is covered by the superficial fascia, which
separates it from the skin, and it covers the externeil saphenous nerve, from which it is
separated by a layer of fascia ; it crosses this nerve twice, being at first situated to the
inner side, then to the outer side, and again on the inner side of the nerve.
The external saphenous vein communicates with the deep veins only, behind the ex-
ternal malleolus, and upon the dorsum of the foot.
This vein has only two valves, one of which is situated immediately before its open-
ing into the popliteal vein.
Such are the veins of the lower extremity. The analogy which exists between the in-
ternal dorsal branch of the foot and the cephalic vein of the thumb ; between the exter-
n£il dorsal branch and the vena salvatella ; between the external saphenous and the ra-
dial and cephalic veins ; between the internal saphenous and the ulnar and basilic veins,
cannot be doubted. There is no branch in the lower extremity analogous to the median
vein.
THE VEINS OF THE SPINE.
General Remarks. — The Superficial Veins of the Spine. — The Anterior Superficial Spinal
Veins, viz., the Cheater Azygos — the Lesser Azygos — the Left Superior Vertehro-costals
— the Right Vertebro-costals — the Vertebro-lumbar — the Ilio-lumbar, and Middle and Lat-
eral Sacral — the Anterior Superficial Spinal Veins in the Neck. — The Posterior Superfi-
cial Spinal Veins. — The Deep Spinal or Intraspinal Veins — the Anterior Longitudinal,
and the Transverse Veins or Plexuses, and the Vein^ of the Vertebra — the Posterior and
the Posterior and Lateral Transverse Veins or Plexuses — the Medullary Veins. — General
Remarks on the Veins of the Spine.
The spinal or rachidian veins constitute a very important part of the venous system,
which has only recently been specially studied.
These veins differ, in many respects, from the spinal arteries, so that the description
of the one does not afford much assistance in the study of the other ; nevertheless, I
shall frequently have occasion to point out some remarkable analogies between these two
sets of vessels.
The spinal veins are arranged most distinctly as venae comites and supplementary veins.
We shall divide them into the veins exterior to the spine or the superficial veins, and
the wms in the interior of the spinal canal, or the deep veins.
The Superficial Veins of the Spine.
The superficial veins of the spine may be subdivided into the anterior and posterior.
The Anterior Superficial Rachidian Veins.
The anterior superficial rachidian or spinal veins (see fig. 223) comprise the vena azy-
gos major, the vena azygos minor, the common trunk of the right superior intercostals,
that of the left superior intercostals, the vertebro-lumbar and ilio-lumbar veins, and the
lateral and middle sacral veins ; in the neck, the ascending cervical and the vertebral
veins.
The Greater Azygos Vein.
The vena azygos major (a «',^^.223) is a large single vein (dC^rof' without a rellow),
606
ANGEIOLOGY.
Fig. 223.
situated along the vertebral column ; it commences {a') in the lumbar region, and termi-
nates at the upper part of the thorax by opening into the vena cava superior.
Its origin is subject to much variety. It very rarely arises from the trunk of the inle
rior vena cava itself, with which, however, it almost always communicates by small
branches. It generally forms the continuation of a series of anastomoses, which sur-
round the bases of the right transverse processes of the lumbar vertebrae, and which may
be called after some authors the ascending lumbar vein {b, on the right side) ; sometimes
it arises from the trunk of the last vertebro-costal, or the first vertebro-lumbar vein : we
rarely find a branch of origin from the renal or supra-renal veins. It often has two ori-
gins, one from the ascending lumbar, and the other from the first vertebro-lumbar, or
last vertebro-costal vein. The vena azygos, almost immediately after its origin, passes
from the abdominal into the thoracic cavity, through the aortic opening in the diaphragm,
ascends upon the right side of the bodies of the thoracic vertebrae, as high as the third
intercostal space, i. e., between the third and fourth ribs,
where it curves forward, forming, like the aorta, an arch,
which passes over and embraces the right bronchus, and opens
into the back of the vena cava superior, as that vein is enter-
ing the pericardium.
During its course the vena azygos is in contact with the
vertebred column, and is situated in the posterior mediasti-
num, on the right side of the aorta and of the thoracic duct
{t t), which runs parallel to it ; it lies in front of the right in-
tercostal arteries, and crosses them at right angles. It va-
ries in size, according to the number of branches which it re-
ceives, but gradually increases from below upward.
The question of the existence of valves in the vena azy
gos has given rise to much discussion. It appears to me to
be settled in the negative.
The vena azygos is joined in front by the right bronchial
vein and some oesophageal and mediastinal veins ; on the right
side by the eight inferior vertebro-costal veins (c c) of that side ;
and on the left by the lesser azygos (d) and the common trunk
(e) of the left superior intercostal veins.
Before opening into the superior vena cava, opposite the
third intercostal space, the azygos vein receives at its curve,
either by a common trunk, or by two or three separate branch-
es, the three superior right vertebro-costal veins, which some-
times enter the right brachio-cephalic vein, and sometimes
the vena cava superior, above where it is joined by the vena
azygos. In the last case they pass vertically upward ; in the
second they are directed almost vertically downward.
The Semi-azygos, or Lesser Jlzygos Vein.
The lesser azygos vein {d d,' azygos minor, semi-azygos)
may be regarded as the common trunk of the three, four, or
five inferior vertebro-costal veins (c' c') of the left side : it
opens into the great azygos vein.
It commences below {d') in as many different ways as the
great azygos vein, but it communicates with the renal vein
much more frequently. It runs upward upon the left of the
vertebral coliunn, approaches the median line, and opens into
the great azygos at a different height in different subjects. It
joins the great azygos either at right angles or obliquely,
passing behind the thoracic duct. The lesser azygos vein
may be regarded as the left branch of origin of the greater azy-
gos : sometimes it is extremely large ; in that case the great-
er azygos is directly continuous with it, and the right branch
is very small.
The lesser azygos vein is joined by the four or five inferior
vertebro-costal veins (c' c') of the left side. It also frequent-
ly receives the common trunk of the superior vertebro-costal
veins, which might be said to form a superior lesser azygos
vein.
The Left Superior Vertebro-costal Veins
The common trunk (e) of the left superior intercostal veins (//) might be called the
left superior lesser azygos, for it has the same relation to these veins that the lesser azy-
gos has to the inferior intercostals of the same side. It runs downward upon the left
of the vertebral column, increasing in size as it approaches its termination, which is
THE INTERCOSTAL VEINS, ETC. 60T
either near the end of the lesser azygos, or in the greater azygos. Not unfrequently the
common trunk of the left superior intercostals bifurcates and opens both into the lesser
azygos and into the left brachio-cephaUc vein. In some cases it terminates entirely
in the left brachio-cephalic vein : I have myself met with this disposition. I have seen
the left superior phrenic and the mediastinal veins enter the trunk of the lesser vena
azygos immediately before its termination.
The number of the left vertebro-costal veins which unite to form the lesser azygos
vein varies from three to seven ; when only three or four of the highest of these verte-
bro-costal veins end in it, the two or three lower ones enter directly into the greater
azygos vein.
General Remarks on the Vena Azygos Major. — This vein returns the blood of the right and
left vertebro-costal vems to the heart ; its presence is rendered necessary, first, in con-
sequence of the inferior vena cava not being able to receive any veins from the point
where it enters the groove in the liver to its termination in the right auricle ; and, sec-
ondly, because the superior vena cava is also unable to receive any veins while it is
within the pericardium. The greater azygos is, therefore, a supplementary vein, a true
collateral canal which supplies the place of the venae cavae, and receives all the veins
corresponding to the branches given off" by the aorta during this long course. These ob-
servations are, for the most part, applicable to all the azygos veins.
Anatomical Varieties of the Azygos Veins. — It would be both useless and tedious to no-
tice here all the varieties that have been observed in the distribution of the azygos veins.
M. Breschet has described six, but there are many more. The following is a very cu-
rious variety : the greater azygos occupies the median line of the dorsal portion of the
vertebral column, and is divided below into two equal branches, a right and a left, each
of which receives the three inferior vertebro-costal veins of its own sides ; all the other
vertebro-costal veins end directly in the greater azygos.
Another not less curious variety is the following : there are two equal and parallel
azygos veins, a right, which receives all the right intercostal veins, and a left, which re-
ceives till the left intercostals : the two main trunks communicate with each other oppo-
site the seventh or eighth dorsal vertebra by a very large transverse branch.
The Intercostal or Vertebro-costal Veins.
The intercostal or vertebro-costal veins of both sides (c c, c' c',ff) correspond to the in-
tercostal or vertebro-costal arteries, the distribution of which it is important to caU to
mind. We have seen that each of these arteries divides into two branches : an intercos-
tal branch, properly so called, intended for the intercostal spaces ; and a spinal branch,
the dorsal division of which terminates in the spinal muscles and the skin, while its ver-
tebral, or intra-spinal division, is distributed to the vertebrae, to the spinal cord, and to
its coverings. In like manner, the vertebro-costal vebis are formed by the junction of the
spinal branch, to which we shall presently return, and the intercostal branch. These
two sets of branches unite into a common trunk, the vertebro-costal vein, which passes
transversely along the groove on the body of each vertebra, receives some veins from
the bone in that situation, and enters at a right angle into the corresponding axygos vein.
The Lumbar or Vertebro-lumbar Veins.
In the lumbar region there are no azygos veins, and each vertebro-lumbar vein en-
ters separately, or by a common trunk, with its fellow of the opposite side, into the back
of the vena cava inferior. Not unfrequently two of the vertebro-lumbar veins of the
same side open by a common trunk ; and it is not rare to find the left superior vertebro-
lumbar vein enter the renal vein.
The vertebro-lumbar veins {g) are distributed very differently from the corresponding
arteries. Opposite the bases of the transverse processes there are a series of anasto-
motic arches, wliich together constitute, on each side, an ascending branch, called the
ascending lumbar vein {b b), which communicates above with the corresponding azygos
vein, and below with the ilio-lumbar veins, and which might be regarded as a lumbar
azygos vein. The trunks of the vertebro-lumbar veins proceed from this series of arches
to the vena cava ; and all the intra-spinal and dorsi-spinal veins terminate in it.
The Ilio-lumbar, Middle Sacral, and Lateral Sacral Veins.
The ilio-lumbar vein, which opens into the common iliac, is distributed like the artery
of that name ; it sometimes receives the last vertebro-lumbar vein : it is joined by the
great veins which emerge from the lower inter- vertebral foramina of the lumbar verte-
brae ; by the branch which is continuous in front of the fifth lumbar vertebra, with the
series of arches forming what may be called the lumbar azygos ; and, lastly, by a com-
municating branch from the lateral sacral veins.
The middle sacral and lateral sacral veins represent the azygos veins in the sacral re-
gion ; they are joined by all the dorsi-spinal branches passing out from the inter-vertebral
foramina, and end in the common iliac veins.
The middle sacral vein (A) often conmiences below by three branches, a median in
ANGEIOLOGY.
front of the coccyx, and two lateral and anterior branches. One of these joins the ves-
ical plexus, while the other communicates with the hemorrhoidal veins, and establishes
a remarkable communication between the general venous system and the system of the
vena portae.
The middle sacral vein passes vertically upward, somewhere near the middle line, and
opens into the left common iliac vein {71) at a greater or less distance from its junction
with the right common iliac. I have seen it bifurcate above to enter both common iliacs.
During its course it is joined opposite each vertebra by some transverse, plexiform
branches, which establish a free communication between it and the lateral sacral veins,
and which receive some large branches from the bodies of the sacral vertebrae. These
transverse branches represent the vertebro-costal and vejrtebro-lumbar veins, which also
receive the veins which issue from the bodies of the vertebrae, through the foramina,
upon the inner surface of those bones.
The lateral sacral veins (i), of which there are always more than one on each side, are
continuous with the dorsi-spinal veins, which emerge from the anterior sacral foramina ;
there are generally two, a superior, which enters the common iliac vein, and an inferior,
which forms a very remarkable plexus, opposite the great sciatic notch, and ends in the
internal iliac vein, or in its gluteal and sciatic branches.
The Jlnterior Superficial Spinal Veins in the J^eck.
In the anterior cervical region we lind transverse plexiform branches (A) opposite each
vertebra, more particularly opposite the first and second ; these plexuses open partly
into the ascending cervical vein, which corresponds to the ascending cervical artery,
but principally into the vertebral vein, which is contained within the canal formed by
the series of foramina at the base of the transverse processes of the cervical vertebrae.
These plexiform branches, which cover the sides of the bodies of all the vertebrae, are
joined by the veins from the praevertebral muscles, by the articular veins, and by the
anterior osseous veins from the bodies of the corresponding vertebrae.
The vertebral veins and the ascending cervical veins may therefore be said to repre-
sent the azygos veins in the cervical region.
The Posterior Superficial Spinal Veins.
The posterior superficial spinal veins commence in the skin, and in the muscles of the
vertebral grooves : some of them closely accompany the arteries ; for example, those
that pass between the muscles of the vertebral grooves ; the others have a peculiar dis-
tribution, and require a special description.
These veins, which are called dorsi-spinales by MM. Dupuytren and Breschet, form
an exceedingly complicated network, the meshes of which surround the spinous process-
es and laminae, and the transverse and articular processes of all the vertebrae : these
meshes are more numerous in proportion as the injection is more perfect.
After a successful injection, we sometimes find along the summits of the spinous pro-
cesses, especially in the dorsal and cervical regions, certain median longitudinal veins,
from which the interosseous branches proceed. These latter run forward, on each side
of, and in contact with, the inter-spinous ligaments. Having reached the base of the
corresponding spinous process, they pass outward, opposite the intervals between the
laminae of the vertebrae, as far as the bases of the transverse processes, and then divide
into two branches : one of these ascends, and anastomoses with the descending branch
from the vein above ; while the other branch descends, and anastomoses with the as-
cending branch of the vein below. It follows, therefore, that around the transverse pro-
cesses and the laminae of the vertebrae there is a series of venous circles, which com-
municate, opposite each inter- vertebral foramen, with the veins contained in the interior
of the spine.
The posterior superficial spinal veins in the neck have a much more complicated ar-
rangement, and, indeed, form a plexus. Moreover, we generally find, between the com-
plexus and the semi-spinalis colli, two longitudinal veins, which appear to me to deserve
a jiarticular description, under the name of the posterior jugular veins.
The posterior jugular veins commence between the occipital bone and the atlas, pass
tortuously out from the interval between these bones, run downward and inward, and,
opposite the spinous process of the axis, the veins of the two sides anastomose by a
transverse branch. They then change their direction, pass downward and outward, and
having reached the lower part of the neck, turn forward, between the seventh cervical
vertebra and the first rib, and open into the back of the brachio-cephalic vein behind the
vertebral vein. The two posterior jugular veins are therefore arranged in the form of
the letter X.
The posterior jugular vein, which does not always exist, for its branches of origin
sometimes remain separate, seems to be inversely proportioned to the vertebral vein,
with which it communicates opposite each inter-transverse space. It has appeared to
me to communicate above with the deep occipital and the mastoid veins, with the veins
situated in the spinal caned, and with the interned jugular vein. Throughout the whole
THE INTRA-SPINAL VEINS. OOII
01 Its course, it communicates freely, opposite each inter-vertebral foramen, with the
veins contained in the interior of the spinal canal, and with the vertebral vein.
The Deep Spinal or Intra-spinal Veins.
The veins in the interior of the spine comprise the proper veins of the spinal cord, and
the veins situated between the bones and the dura mater, which are subdivided into the
anterior and the posterior longitudinal veins or plexuses, and the transverse veins or plexus-
es ; the latter establishing a free communication between all four of the longitudinal
veins or plexuses, opposite each vertebra.
Before describing the veins situated between the bones and the dura mater, I must
state, in a few words, what is the arrangement of the proper arteries of the vertebras.
The spinal branches which are given off on each side of the body by the vertebral ar-
tery in the neck, by the intercostal arteries in the back, by the lumbar arteries in the
loins, and by the lateral sacral arteries in the pelvis, enter the spinal canal through the
several inter- vertebral foramina, and then each of them divides into an ascending and a
descending branch ; the ascending branch runs upward upon the lateral part of the body
of the vertebra above, and anastomoses with the descending branch of the spinal artery
above it, while the descending branch anastomoses with the ascending branch of the
artery below. Each of the anastomotic arches thus formed has its concavity directed
outward ; so that there is a series of arterial arches, united at their extremities, situ-
ated upon each side of the posterior surface of the bodies of all the vertebra. From the
convexity of each arch two transverse branches are given off, one running above and
the other below the small foramina upon the posterior surface of the body of the corre-
sponding vertebra. The cribriform portion of the bone is thus surrounded by the arte-
rial arches with their transverse branches ; and from all points of the polygon which
they form small arteries are given off, which penetrate into the substance of each ver-
tebra, and anastomose with the arterial twigs that enter the anterior surface of the body
of the vertebra.
The arrangement of these arteries gives a perfect idea of that of the veins known as
the anterior longitudiruU veins or plexuses, and of the transverse plexuses, which pass from
one to the other.
The ^Interior Longitudinal Intra-spinal Veins or Plexuses, the Transverse
PlexuseSy and the Proper Veins of the Bodies of the Vertebra.
Dissection. — Remove the arches of the vertebrae, and the spinal cord and its coverings.
The plexus may also be viewed from the front, by carefully sawing through the pedicles
and then removing the bodies of the vertebrae.
The anterior longitudinal plexuses, described by Chaussier, but still more correctly by
Breschet, form two venous trunks, named the great anterior longitudinal veins, extending
from the foramen magnum to the base of the coccyx, one on each side of the posterior
common vertebral ligament, and therefore upon the sides of the posterior surface of the
bodies of the vertebrae, and on the inner side of their pedicles. These veins, improperly
called vertebral sinuses, communicate together opposite each vertebra by a transverse
plexus, situated between the body of the vertebra and the posterior common ligament.
These longitudinal plexuses are less developed in the cervical and sacral regions. It is
probable that in the neck their place is supplied by the vertebral veins.
It would be in vain to consider these plexuses as having a distinct origin, course, and
termination ; the description given above of the distribution of the arteries is applicable
to the veins in every respect : thus, the venous plexuses are formed by a series of plex-
iform arches, which embrace the pedicles of each vertebra, have their concavity directed
outward and their convexity inward, and the extremities of which anastomose together
opposite the inter- vertebral foramina, where they communicate with the branches on the
outside of the spine, and assist in the formation of the vertebro-lumbar and vertebro-
costal veins, and, consequently, of the azygos veins. From the convexity of each arch
proceeds a transverse plexus, which goes to join with its fellow of the opposite side ;
and, just as we have seen that the transverse arteries extending from one arterial arch
to another give off branches to the bodies of the vertebrae, so, in like manner, the trans-
verse venous plexuses receive the veins which emerge from the body of each vertebra.
The arrangement of the veins or plexuses just described explains the alternate en-
largements and contractions observed in different parts of the anterior longitudinal plex-
uses. The rare interruptions described by M. Bresche( I believe to depend upon im-
perfect injections, which succeed so differently in different subjects.
The anterior longitudinal veins or plexuses cannot be regarded as sinuses, for they are
not contained in a fibrous sheath, like the veins of the dura mater, nor are they reduced*
merely to the lining membrane of the veins. Notwithstanding their extreme tenuity,
we can recognise an external coat, and the posterior common ligament does not covet
them behind. Nor is the term sinus more applicable to the transverse plexuses, although
they are situated between the bodies of the vertebrae and the posterior common ligament,.
for the ligament merely covers them without forming a sheath for them.
4H
610 ANGEIOLOGY.
The Proper Veins of the Bodies of the Vertebra. — The foramina upon the posterior sux-
face of the body of each vertebra, which are generally proportioned to the size of the ver-
tebra, are principally intended for the proper veins of the bodies of their bones : the ar-
teries are much smaller, and though they enter by the same openings, they occupy but a
small part of their areas. These veins belong to that system of venous canals found in
the substance of bones, which we have already noticed as existing in the bones of the
cranium. Their chief varieties have been correctly described and delineated by M. Bres-
chet. These venous canals, which are more developed in the old than in young sub-
jects, occupy the centre of the body of the vertebra, and always run parallel to the up-
per and lower surfaces of the bone : they arise from all parts of the circumference of the
vertebra, communicating with the veins which enter by the foramina on its anterior sur-
face, and converge towards the principal foramen, or foramina, upon its posterior eis-
pect. They frequently enter a semicircular canal, which has its convexity directed for-
ward, and gives off from its concavity a venous canal, which opens directly into the
transverse plexus : the lateral veins of the body of the vertebra open into the extremities
of this semicircular canal ; while within the venous canals of the vertebrae, the veins are
reduced to their lining membrane, like the veins in the canals of the cranial bones.
The transverse plexuses, therefore, collect the blood from the bodies of the vertebra),
and transmit it to the anterior longitudinal plexuses.
The Posterior IntrU'Spinal Veins or Plexuses, and the Posterior and Lateral
Transverse Plexuses.
The posterior intraspinal plexuses, much smaller than the anterior, are situated one on
each side between the vertebral laminae and ligamenta subflava behind, and the dura
mater in front. These veins are rarely injected along the whole length of the spine, and
hence they sometimes appear to exist only in the dorsal region. They communicate op-
posite each vertebra, by means of posterior transverse plexuses, or by transverse veins.
They communicate with the anterior longitudinal plexuses by small lateral transverse
plexuses, which pass from behind forward. It follows, therefore, that the veins within
the spine, but external to the coverings of the cord, consist of four longitudinal plexuses,
all of which are connected by a transverse circular plexus opposite each vertebra. A
strict analogy may be said to exist between the sinuses of the cranium and the intra-spi-
nal plexuses ; an analogy which did not escape the notice of the ancients, as the com-
mon application of the term sinus by them to the veins of the cranium and to those of the
spine would seem to indicate. Thus, in the cranium we find certain longitudinal sinus-
es, that is, those which run from before backward, viz., the superior longitudinal sinus,
the straight sinus, and the posterior occipital sinuses ; also, the superior and inferior pe-
trosal sinuses, the cavernous sinuses, and the right and left lateral sinuses. The former
set represent the posterior intra-spinal plexuses ; the latter correspond to the anterior in-
tra-spinal plexuses.
In the cranium we also find certain transverse sinuses, viz., the basilar or transverse
occipital sinuses and canals, and the coronary sinus, which exactly correspond to the
transverse plexuses, extending from one anterior intra-spinal plexus to the other. We
sometimes find two or three transverse venous plexuses in the basilar groove of the oc-
cipital bone.
Lastly, may we not compare the veins on the outer surfaces of the spine to the occipital,
frontal, and temporal veins ; and do not the veins passing through the posterior lacerated
foramen and the sphenoidal fissure, which we have regarded as representing the inter-
vertebral foramina (see Osteology), establish a communication between the veins on
the inside and those on the outside of the cranium, just as the veins which escape through
the inter-vertebral foramina connect together the superficial and the intra-spinal veins 1
The anterior and posterior deep spinal veins communicate with the superficial veins
of the spine at the inter-vertebral foramina so freely, that the circulation would not be
interfered with even if a considerable amount of obstruction existed. I have already
stated (see VERTEBRiE) that the diameter of the inter-vertebral foramina is in relation,
not with the size of the nervous ganglia, but rather with that of the veins, which estab-
lish a communication between the superficial and intra-spinal venous systems.
The Proper Veins of the Spinal Cord, or the Medullary Veins.
If we examine the pia mater of the spinal cord, even without having injected it, in the
body of a person who has died suddenly, as in that of a new-born infant after death from
asphyxia or apoplexy, the surface of the pia mater will be found covered by very tortu-
ous veins, which emerge from the posterior median furrow of the spinal cord. This ve-
nous network, which is spread over the whole surface of the cord, gives off opposite the
roots of each nerve a small vein, which runs directly between those roots, enters the
corresponding inter-vertebral foramen, is enclosed with the nerve in the sheath formed
by the dura mater, and having emerged from that sheath, opens into the large vein sit-
uated in the inter-vertebral foramen.
There is, therefore, this difference between the proper veins and arteries of the spinal
THE LYMPHATIC SYSTEM. 811
cord, that the number of veins is equal to that of the nerves ; while the arteries are less
numerous, and enter the fibrous sheaths of the nerves only at intervals, and in propor-
tion as the preceding arteries are exhausted. Moreover, the anterior and posterior spi-
nal veins, like their corresponding arteries, may be regarded as belonging only to the up-
per part of the cord, and not as being intended to traverse its whole length.
General Remarks on the Veins of the Spine.
The veins of the spine maybe regarded, in reference to the general circulation, as es-
tablishing an unbroken communication between the veins of all parts of the trunk ; so
that we can suppose one of the venae cavae to be obliterated, without the venous circu-
lation being interrupted. The greater azygos itself, which is generally regarded as the
principal means of communication between the two venae cavae, is not, however, neces-
sary, when we consider the arrangement of the anterior and posterior spinal plexuses.
Thus, I have sometimes seen the inferior, and sometimes the superior vena cava oblit-
erated without any apparent increase in the diameter of the vena azygos, and, what will
perhaps be thought surprising, without oedema, either of the upper or lower extremities.
Supposing the vena cava ascendens to be obstructed from the entrance of the hepatic
veins down to the renal veins, the blood would then flow back by the vertebro-lumbar
veins into the plexuses contained within the spinal canal ; through these plexuses, it
would ascend to the vertebro-costal veins, from thence to the azygos veins, and through
them into the superior vena cava.
If all the jugular veins were obliterated, the venous circulation in the head would still
continue, and would be carried on through the spinal veins. I have tied the two exter-
nal jugular veins in a dog. The animal showed no sign of cerebral congestion : after
opening the body, I did not find any increase of size in the small veins which accom-
pany the carotid arteries, and which in those animals are naturally very smalL In this
case, the circulation was evidently carried on by means of the spinal veins.
THE LYMPHATIC SYSTEM.
Definition, History, and general View of the Lymphatic System. — Origin. — Course. — Tcrim-
nation and Structure of the Lymphatic Vessels. — The Lymphatic Glands. — Preparation oj
the Lymphatic Vessels and Glands.
The term lymphatic vessels is applied to certain transparent tubes provided with valves,
and conveying either lymph or chyle, which pass through small, rounded, glanduliform
bodies called lymphatic glands, and in all cases empty themselves into the venous sys-
tem, to which, indeed, they may be said to form an appendage.
From their tenuity and transparence, these vessels for a long time escaped the notice
of anatomists. The thoracic duct was discovered by Eustachius in 1565. The lac-
teals were discovered in 1622 by Gaspard Asellius, who, by a lucky chance, while seek-
ing quite another object, discovered certain vessels filled with chyle. In 1641, Pecquet
discovered the receptaculum chyli, and showed that the lacteals entered the thoracic
duct, and not the liver, as Asellius and all his contemporaries believed.
Rudbeck, Thomas Bartholin, and JolyfF dispute the honour of having discovered the
l)Tnphatic vessels, properly so called, in contradistinction to the lacteals or chyliferous
vessels.
Mascagni devoted a great part of his life to the study of the lymphatic system ; and
his work, ornamented by magnificent plates, is a monument of science, which should be
taken for a model by all who are engaged in anatomical inquiries. Lastly, within the
last few years, MM. Fohmann, Lauth, Lippi, Panizza, and Rossi have thrown light upon
some most important points in the anatomy of this system.
In describing this system of vessels, the lacteals, or the Ijntnphatics containing chyle,
have commonly been separated from the lymphatics, properly so called, or the vessels
containing lymph. This distinction, however, is not warranted by anatomy, for the two
sets of vessels are perfectly identical in structure.
The IjTnphatic system offers many analogies with the venous system ; but there ar
also no less remarkable differences between the two.
Like the venous system, it consists, as a whole, of afferent or converging vessels
which arise from all parts of the body, and run from the periphery towards the centre.
Like the veins, the lymphatics are divided into two sets : a srib-cutaneous set, which,
in general, accompanies the superficial veins of the limbs ; and a deep set, which follows
the course of the deep arteries and veins ; and, lastly, the lymphatics resemble the veins
in being provided with valves.
The lymphatics differ from the veins in passing through certain bodies improperly
called glands, which, at intervals, intercept their course. They differ from the veins,
also, in their arrangement ; for they do not successively unite into larger and larger
branches, and these into trunks, but they scarcely increase in size from their origin to
their termination ; and, though they communicate with each other by numerous anasto-
6t$ ANGEIOLOGY.
moses, each of them follows, as it were, an independent course : lastly, the blood which
circulates in the veins is still, though indirectly, under the influence of the heart's ac-
tion, while the onward movement of the lymph is exclusively dependant upon the pari-
etes of the vessels.
Before proceeding to the special description of the lymphatics, we shall make some
general remarks upon the origin, course, and termination of these vessels.
Origin of the Lymphatics.
Tlie origin of the lymphatics, hke every point connected with the minute structure of
the tissues, is yet a new subject for inquiry.*
It has been said that the Ijmnphatics are continuous with the arteries, so that, accord-
ing to this hypothesis, the arteries are continuous with two kinds of vessels, viz., with
the lymphatics, which carry off the serum, and with the veins, which transmit the col-
oured part of the blood. The continuity of the arteries with the lymphatics has been
admitted, in consequence of its having been observed that injections thrown into the
arteries passed into the lymphatics. I have frequently seen this in injecting the spleen
and the liver ; but it was only when the injection was pushed in with great and contin-
ued force : so that it is possible, as thought by Hunter, Monro, and Meckel, that, in these
cases, some of the vessels had been ruptured, and the injection extravasated ; or, what
is still more probable, there may have been transudation through the pores of the tis-
sues. Microscopical observations show most distinctly that the arteries are continuous
with the veins ; but there is no fact to demonstrate the continuity of the arteries with
the lymphatics.
The origin of the lymphatics can be actually shovra only upon free surfaces, such as
the mucous membranes, the skin, the serous and synovial membranes, and the lining
membranes of arteries and veins ; so that, in the actual state of our knowledge, it might
be maintained that the lymphatic vessels arise exclusively from all the free surfaces.
All the lymphatics arise by a network of such tenuity that, when .injected with mer-
cury, the whole surface appears changed into a metallic layer.
About eight years since, having introduced at random a tube filled with mercury for
injecting the lymphatics into the pituitary membrane in a calf, I was astonished to find
the surface covered by a metallic pellicle : I repeated the experiment frequently, and
constantly found that the pellicle was not caused by extravasation, for the mercury ran
in determinate lines, forming plexuses of different kinds ; also that, to succeed in this
experiment, it was necessary to puncture the membrane very superficially, or the mer-
cury would run into the subjacent plexus of veins; and, lastly, that there was no com-
munication between that plexus of veins and the more superficial network, which I sus-
pected to consist of lymphatic vessels, for it exactly resembled the network of those
vessels in the peritoneum covering the liver. I ascertained that the same structure ex-
isted in the skin ; in the lingual, buccal, and vaginal mucous membranes ; in the con-
junctiva ; and, lastly, in the uterine mucous membrane of a sow which had lately lit-
tered. I showed this lymphatic network of the pituitary membrane in several of my
lectures ; and lately, having again examined the subject for the purposes of the present
work, I have ascertained that this network exists upon all the free surfaces, that it com-
municates with the lymphatics, and that it is possible to inject those vessels and the
lymphatic glands by introducing the pipe very superficially into the surfaces of these
membranes.! I may be permitted to observe, that it is only a few months since I be-
came acquainted with the splendid work of M. Panizza, of Pavia, upon the lymphatic ves-
sels of the testicles {Osservazioni Antropo-zootomico Fisiologiche, 1830) ; and with M. Foh-
mann's last very important memoir {Mimoire sur les Vaisseaux Lymphatiques de la Peau,
des Membranes Muqueuses, Sereuses, du Tissu Nerveux, ct des Muscles, 1833).
Origin of the Lymphatics from the Mucous Membranes. — The villi found upon the mu-
cous membrane of the small intestines contain, in their centre, a cavity, named the am-
pulla of lAeberkuhn, which I have seen in one instance filled with tuberculous matter.
{Anat. Pathol, \w. ii.) Still, I have never been able to discover any open orifice on the
summit of that villus.J Independently of these cavities within the villi, which are proper
to the system of lacteal vessels, the thin pellicle of the mucous membranes which can-
not be injected from the arteries or veins {vide p. 370), when carefully and very super-
ficially punctured by the pipe of a mercurial injecting apparatus, is covered by a metallic
pellicle. Panizza and Fohmann have proved that the membrane which covers the glans
penis has two sets of lymphatics : a superficial and a deep. M. Fohmann has figured, in
some very beautiful plates, the lymphatic network of the mucous membranes of the glans
penis, bladder, urethra, trachea, bronchi, oesophagus, stomach, ileum, and colon. This
network is so superficial, that the mercury appears almost uncovered ; it does not com-
* Do lymphatics commence in all parts of the body ? It is true that absorption is carried on in every part,
for absorption is one element of the process of nutrition ; but, as it can be effected by other vessels besides the
lymphatics, its occurrence in any part does not necessarily involve the presence of this peculiar class of vessels.
T These preparations were made by M. Bonami, my prosector, under my direction, with extreme skill, and
a zeal above all praise.
', [For what is known conceming^ the structure of the villi, see note, p. 369]
ORIGIN OF THE LYMPHATICS. 613
municate either with the arteries or the veins, but communicates freely with the lym-
phatic vessels. It was correctly delineated by Mascagni : according to that anatomist,
it covers all the intestinal villi, as with a sheath, and does not appear to have any open-
ings on the exterior.
Origin of the Lymphatics from the Skin. — Are the openings or pores so evident upon the
skin when viewed through a lens, and from which drops of sweat maybe seen to exude,
intended to serve the purpose both of exudation and absorption 1 or are there rather two
distinct kinds of orifices for these two functions 1 or, lastly, are these orifices altogether
unconnected with the absorbent vessels 1*
If we puncture the skin very superficially, so that the injecting pipe may enter imme-
diately below the epidermis, the mercury will be seen to run with great rapidity into
some very small vessels, and to form a metallic network, precisely like that already de-
scribed as existing in the mucous membranes ; from this layer proceed sub-cutaneous
lymphatics, which may be traced filled with mercury as far as the adjacent lymphatic
glands, or even beyond them. In order that this experiment may succeed, it is neces-
sary that the skin to be injected should be plunged into hot water.
I made the following experiment in order to detect, if possible, in the lymphatics of
the skin, the mercury absorbed during mercurial frictions. I caused two dogs to be
rubbed with mercurial ointment night and morning ; and, that the absorption might be
more complete, I enveloped their bodies in a frock made of skin. These animals died in
about eight days with gangrene of the gums ; but I could not find in any part the slight-
est trace of mercury, although the frictions were continued up to the period of their
death.
Origin of the Lymphatics from the Serous and Synovial Membranes. — The same results
as those above stated are obtained by injecting the serous and synovial membranes.
The portion of peritoneum covering the liver is generally chosen for injecting the l>Tn-
phatic network of serous membranes, because the tension and adhesion of the perito-
neum over the liver renders it more easy to inject. The same results may be obtained
by injecting the costal or pulmonary pleura, the tunica vaginalis, or the parietal and vis-
ceral portions of the arachnoid.
The synovial membranes may be injected with the greatest facility, either near the
cartilages, where they are more tense than in other parts, or upon the ligaments, to
which they adhere.
Origin of the Lymphatics from the Lining Membrane of the Veins and, Arteries. — ^The
lymphatic plexuses upon the lining membrane of veins and arteries have hitherto been
only partially displayed, but the analogy between these and serous membranes is so
close, that I have no doubt of their identity in this respect. I have, moreover, found the
lymphatic vessels of the aorta filled with blood in several cases of degeneration of the
coats of that vessel.
Origin of the Lymphatics in the Free Cellular Tissue. — In order to exhibit the origin of
the lymphatics in this situation, I injected coloured liquids, such as ink, into the sub-
cutaneous and inter-muscular cellular tissue in several animals, and I found the lym-
phatic vessels and the corresponding lymphatic glands of a jet-black colour. I made a
great number of experiments to induce absorption of mercury, by injecting it either into
the cellular tissue, or into a serous cavity ; but the metallic mercury always acted like
a foreign body, the mechanical effect of which produced more or less inflanunation, but
it was never absorbed.
I have found pus in both the superficial and deep lymphatics, and in the lymphatic
glands of the groin, after phlegmonous erysipelas and acute abscesses of the leg ; but it
is not proved that the presence of this pus was the result of absorption. It is more
probable that it had been produced by inflammation of the lymphatics themselves.
Although it is impossible to demonstrate, anatomically, the presence of lymphatics in
the free cellular tissue, it is most probable that that tissue, as well as the serous mem-
branes, with which it heis so many anedogies, is formed by this kind of vessels. Mas-
cagni stated that all the white tissues consist of lymphatic vessels, and that the lym-
phatic system forms the basis of the whole body.
From the preceding observations, it may be stated that, with the exception of the
lacteals which open upon the summits of the villi, + all the lymphatic vessels of free sur-
faces arise by an exceedingly delicate network ; M. Fohmann believes that all the lym-
phatics commence by a network of closed vessels.t
I have never been able to discover the l)Tnphatic networks, either in the nervous sub-
stance, in muscles, glands, or in the fibrous, cartilaginous, and osseous tissues.
* [These pores are the orifices of the ducts of the sudoriferous glands, which are imbedded in the true skin,
or the sub-cutaneous cellular membrane, and have no direct connexion with the lymphatics.]
+ [Whether the lacteals commence in each villus by a network, or by free closed extremities, is not yet de-
termined ; but they form no exception to the rule that the absorbent vessels arise by closed extremities, and
not by open mouths. See p. 370.]
t [These networks are arranged in layers, the most superficial of which is formed by the finest vessels, and
has the smallest meshes.]
m4
ANGEIOLOGY.
Course of the Lymphatics.
From the networks above described, the lymphatics themselves arise, and, in aD the
organs, are divided into a deep and a superficial set. The former set accompany the deep
vessels of the organ, while the others follow the superficial veins in such parts of the
body as are provided with them. In those organs which are covered with a serous coat,
they appear to be contained within the substance of that membrane. The lymphatics
run parallel with each other, and communicate pretty frequently by bifurcating, and then
joining the neighbouring vessels ; but they do not converge towards each other, nor do
they, like the veins, unite successively into a smaller and smaller number of larger and
larger branches ; thus, their increase in size is not progressive ; and it might even be
said that, throughout their whole course, they undergo no decided increase nor dimi-
nution.
Their direction is slightly tortuous. (In^^. 224 are shown short portions of lymphat-
ics of different sizes.)
Anastomoses. — ^We do not find in the lymphatics those numerous and important anas-
tomoses which form such characteristic points in the history of the arteries and veins.
These vessels present only one kind of anastomosis, which is accomplished in the fol-
lowing manner : A Ijonphatic, after a certain course, divides into two equal branches,
which diverge at a very acute angle ; these two branches anastomose with two other
lymphatics, each of which communicates either by bifurcation or directly with the neigh-
bouring lymphatic vessel. This explains how, by injecting a single lymphatic, a certain
group of these vessels may be filled. Not unfrequently, a lymphatic divides into two
branches, which, after a certain distance, again unite.
During their course, the lymphatic vessels meet certain small giandulifm-m ladies, the
conglobate glands of the ancients, but which are also called lymphatic ganglia, on account
of the analogy pointed out by Soemmerring between them and the ganglia of nerves ; the
lymphatic glands form centres, to which a number of lymphatic vessels proceed, and are
lost in them for a time, but from which they afterward emerge.
The name of afferent lymphatics (vasa afferentia, a a a, fig. 225) is applied to those
which enter a gland, and those which emerge from it are called efferent lymphatics (vasa
efferentia, b h).
Do all the lymphatics necessarily traverse one or more of these glands t Mascagni
has successfully maintained the affirmative in opposition to Hewson and others, who as-
sert that they have seen lymphatics entering directly into the thoracic duct. Mascagni
states that he invariably found that these vessels passed through one or more glands.
As to the argument derived from the absence of dropsy in oases of obstruction in the
lymphatic glands, Mascagni explains this by the frequent anastomoses of the lymphatic
vessels, the result of which is, that they communicate with several series of glands,
some of which are situated at very great distances.
The most numerous anastomoses of the lymphatics take place within the lymphatic
glands ; thus, if we inject the afferent vessels of a lymphatic gland, the mercury escapes
by its efferent vessels. In injecting a gland, it frequently happens that the mercury
passes not only into the efferent, but also into some of the afferent vessels.
Size of the Lymphatics. — The lymphatics are generally so small as to escape the no-
tice of the observer ; but they may become enlarged to a remarkable degree. Thus, I
have seen the lymphatics of the groin and of the uterus as large as the thumb.
An attempt has been made to draw some comparison between the toted capacities of
the lymphatic, venous, and arterial systems ; but all that has been said respecting this
is founded upon no positive data. I would, moreover, observe, that in all probability we
are acquainted with but a portion of the lymphatic system.
Termination of the Lymphatics.
According to the most generally received opinion, all the lymphatics terminate in two
trunks, the thoracic duct and the great right lymphatic duct; the latter vessel receives the
lymph from the right upper extremity, and from the right half of the head, neck, and tho-
rax ; the lymphatic vessels of all the other parts of the body end in the thoracic duct ;
the lymphatic vessels enter successively into these two trunks, as the plumes of a feath-
er are attached to its shaft. The two trunks themselves end as follows ; the thoracic
duct enters the left sub-clavian vein, at the junction of that vein with the internal jugu-
lar ; the great right lymphatic duct terminates in the right sub-clavian vein ; hence it is
that the lymphatic system may be regarded as an appendage of the venous system.
Are the thoracic and the great right lymphatic ducts, notwithstanding their small size,
the only terminations of the lymphatic system] With this question may be connected
another : Are the lymphatics the exclusive agents of absorption, or do they share this
function with the veins 1
Mascagni appeared to have established, beyond dispute, that absorption was performed
by the lymphatics to the exclusion of the veins ; when Magendie* and Delille in France,
* It is established, says M. Magendie, that the lacteals absorb the chyle, and that the intestinal veins ab-
TERMINATION OF THE LYMPHATICS. 615
Tiedemann and Gmelin in Germany, and Flandrin and Emmert in England, relying upon
some ingenious experiments, again attributed a power of absorption to the veins, and
hence led other anatomists to undertake still farther researches.
The inquiry was soon entered upon by M. Fohmann in 1820 and 1821, by M. Lauth in
1824, and by M. Lippi in 1825, all of whom again referred the phenomena of absorption
exclusively to the lymphatics, and supported that opinion both by arguments and facts.
MM. Fohmann and Lauth admit two other modes of termination of the lymphatic sys-
tem in the veins besides the one already indicated : first, a direct termination of the
lymphatic radicles in the radicles of the veins, which is supposed to occur in the sub-
stance of organs ; and, secondly, a communication between the lymphatics and veins
within the lymphatic glands. This opinion, which seems reconcilable with the fact that
the area of the thoracic and right Ijonphatic ducts is very small as compared with that
of all the IjTnphatic vessels, appears, k priori, to be exceedingly probable.
But an anatomical fact must be shown anatomically before it can be admitted. Now
there is no proof of the communication of the lymphatic and venous radicles. M. Foh-
mann relies upon certain more or less ingenious inductions, but not upon direct ana-
tomical facts. I am, therefore, still compelled to doubt the existence of these commu-
nications, and to class them with the vasa serosa, or serous veins of Haller.
Again, a communication between the lymphatics and the veins in the substance of the
lymphatic glands had been conjectured by many anatomists ; the elder Meckel had seen
mercury, when thrown into the lumbar lymphatics, pass into the abdominal veins ; but
this fact was attributed to rupture in the interior of the glands. — {Hewson, Cruickskank.)
This apparent communication had also frequently been observed by Mascagni, and was
attributed by him to rupture.
M. Fohmann urges in reply, that this communication takes place under too slight a
pressure to be referred to rupture, that actual extravasations may be easily recognised,
and that the mercury is then infiltrated into the cellular tissue with much greater facility
than it can enter the veins. " Why," he asks, " supposing the existence of rupture,
does the mercury never pass from the lymphatics into the arteries 1" He also adduces
in support of his opinion a considerable number of facts, which show that injections
thrown into the lymphatic glands sometimes escape by the lymphatics alone, sometimes
by the veins alone, and sometimes by both the lymphatics and the veins. He states
that, having emptied the veins passing out from a mesenteric gland in a horse which had
been killed while digestion was going on, and having replaced the intestines in the ab-
domen, he found some streaks of chyle in the veins. Lastly, he has seen, in birds, the
renal lymphatic vessels, which represent the l)Tmphatic glands in those animals, opening
directly into the renal and sacral veins. M. Lauth has repeated these experiments, and
obtained the same results. But, however imposing the authority of the authors just ci-
ted may be, I must confess that I am far from being convinced, and that the facts stated
by them do not appear to me to be conclusive. I have made a great number of injec-
tions of lymphatics, and in by far the greater number of cases the mercury passed from
the afferent into the efferent lymphatic vessels, and not at all into the veins. In some
cases, it passed from the glands into the veins ; but it appeared to me that the glands
had then undergone a change in their texture, more particularly a red softening.
It does not seem to me, then, to be shown that there is any direct conununication be-
tween the lymphatics and the veins within the substance of the lymphatic glands.
Lippi (of Florence) denies the communication of the lymphatics with the veins within
the lymphatic glands ; but believes that, besides the terminations of the lymphatics in
the venous system through the thoracic duct and the great right lymphatic trunk, there
are a great number of direct communications between the lymphatics and the vena por-
tae, the internal pudic and the renal veins, and the vena cava ascendens and vena azygos.
Several anatomists, indeed, had already met with lymphatic vessels opening directly
into the venous system ; among whom were Walceus, Wepfer, Abraham Kaw, Heben-
streit, the elder Meckel, Galdani, and Vrolyk ; but the isolated facts recorded by them
were regarded by Haller, Mascagni, and Soemmering as anomalies, or as the results of
rupture.
The memoir published by Lippi excited new investigations on all sides. I was the
more inclined to subscribe to the opinions of that observer, because, in 1825, I had most
distinctly seen a large lymphatic trunk opening directly into the external iliac vein ; be-
cause it appeared to me rational to admit that the communications between the lymphatic
and venous systems would not be restricted to the internal jugular and sub-clavian veins ;
because the communications supposed to exist by Fohmann and Lauth had not been de-
monstrated ; because ligature of the thoracic duct does not prove fatal to all anunals
subjected to that experiment, even when the duct is single ; and, lastly, because the
thoracic duct has been found obliterated in many individuals. There seemed, besides, a
difliculty in admitting that the thoracic and right lymphatic ducts formed the termination
Borb other substances. It is shown that the veins are the absorbing- agents in other parts of the body, but tt
is not shown that the lymphatics absorb. Some authors have stated that the veins absorb only when the lym-
phatic; system is diseased.
616 ANOEIOIiOGT.
of the whole of the lymphatic vessels. It appeared, moreover, at variance with the gen-
eral laws of the animal economy to suppose that two sets of organs should be devoted to
the same functions ; fbr, if the veins absorb, the lymphatic system would seem to have
no special use.
Nevertheless, truth compels me to state that, after the most minute and frequent re-
searches which I have been able to make, I have not obtained a single result confirma-
tory of the statements of M. Lippi ; and that, with his plates before me, I have searched
for the communications in all the points which he has indicated, and have never found
any. I am, therefore, obliged to conclude, with MM. Rossi, Fohmann, and others, that
the vessels which M. Lippi has described as lymphatics opening into different parts of
the venous system are nothing more than veins.
Structure of the Lymphatics.
The lymphatics, as well as the veins, have two coats. This structure can be readUy
shown in the thoracic duct of the human subject, and still better in that of the horse : the
existence of these two coats may also be shown by a method suggested by Cruickshank,
which consists in turning the thoracic duct inside out, and forcibly introducing a tube
into it ; the lining membrane, which is then on the outside, being less extensible than
the external coat, becomes lacerated.
The external coat is considered to be fibrous by some, and muscular by others. Shel-
don says that he has distinctly seen muscular fibres arranged circularly around the tho-
racic duct of the horse. It appears to me that this external coat resembles the dartoid
tissue, like the outer coat of the veins. It is not uninteresting to remark, that the outer
surface of the lymphatics is often covered by a thin layer of fat, which has deceived sev-
eral anatomists.
The internal coat of the lymphatic vessels appears to be of a serous nature, like that of
the veins. Some arterial and venous twigs ramify in their parietes ; but no nerves have
yet been traced into them. Minute lymphatics probably arise from the coats of the larger
ones. Mascagni believes that their lining membrane is entirely lymphatic.
Notwithstanding their excessive tenuity, the lymphatics are tolerably strong ; less so,
however, than is generally stated, for they are often lacerated by the weight of a small
column of mercury. They do not appear to me to be stronger than the veins. They are
much less extensible. When the thoracic duct, or any other lymphatic vessel, is punc-
tured, it immediately collapses, and forces out its fluid contents sometimes in a jet. Some
admit the existence of muscular contractility in them. The vemiicular motion caused
by contraction of their external coat is sufficient to explain the above-named fact.*
The lymphatics are much more abundantly supplied with valves than the veins. The
Fig. 224. valves {a a, Jig. 224) are parabolic, and are arranged in pairs ; they
have an adherent border turned towards the commencement, and a free
border towards the termination of the vessel ; they are generally sit-
uated at very short intervals apart, as is shown by the knotted ap-
pearance of the vessels (see fig. 224), and occasionally they present
a circular or annular arrangement, from which they have been re-
garded as true sphincters.
In general, these valves are strong enough to prevent the retrograde
course of the lymph, and, consequently, of injections also. Never-
theless, Hunter inflated all the lacteals from the thoracic duct ; Hal-
ler filled all the lymphatics of the lung from the upper part of the same
canal, and Marchettis says that he has injected the whole of the lym-
phatics from the reservoir of Pecquet. The valves are extremely
numerous in the lymphatics ; they have sometimes appeared to me
to be wanting in the thoracic duct. Like those of the veins, the
valves of the lymphatic vessels appear to be formed by a fold of the
internal membrane.
The Lymphatic Glands.
Sylvius was the first to distinguish the lymphatic glands under the term conglobate
glands, from the glands properly so called, which he named conglomerate. Chaussier
called these little bodies lymphatic ganglia, following Soemmering, who first pointed out
the analogy between them and the venous ganglia.
The lymphatic glands are situated along the course of the lymphatic vessels, in refer-
ence to which they may be regarded as centres in which a certain number of the ves-
sels open ; those of the extremities are chiefly found at the upper part of the limbs on
the aspect of flexion ; those of the thorax, the abdomen, the head, and the neck are pla-
ced along the vertebral column and the great vessels ; they are found also in tlie sub-
stance of the mesentery, in the mediastina, at the roots of the lungs, &c.
* [The lacteal vessels have been seen to underijo a slow contractility on exposure to air. or to the action of
any other stimulus ; but there is no evidence of the muscularity of any part of the lymphatic system of mam
malia. In certain reptilia and amphibia there are pulsating muscular sacs connected with the lymphatic syi
tern, v?hich are called lymphatic hearts.'^
PREPARATION OF THE LYMPHATIC VESSELS AND GLANDS. 617
Their size varies from that of a millet seed to that of a large filbert. The smallest are
situated in the epiploon, the largest at the roots of the lungs. They are often greatly
enlarged by disease. They are generally of a reddish-gray colour, excepting at the root
of the lungs, when they are black. Their form is irregularly spheroidal ; and they have
been distinctly shown by Malpighi to have a cellular structure.* If we examine with a
lens a lymphatic gland distended with fluid, we observe that it contains cells ; the same
fact is clearly demonstrated by injecting it with mercury, which shows, moreover, that
the cells communicate freely with each other. It is, nevertheless, doubtful whether all
the cells communicate. The researches which I have made upon this subject appear
to show that each lymphatic vessel is connected with a distinct portion of the lymphatic
gland ; and diseases of the glands establish the same fact, by attacking one part only of
a gland, the rest continuing unaffected.
Several l)rmphat?ic vessels enter each gland, and several emerge from it. Each affer-
ent vessel (a a a, fig. 225), as it reaches the circumference of the pig. 225.
gland, divides into a considerable number of branches, which diverge
and run for a short distance upon the surface of the gland, and then
dip into its substance.! The efferent lymphatics (i b) commence in
precisely the same manner as the afferent vessels terminate.
The study of these vessels in the larger animals appears calcula-
ted to clear up all doubts as to the structure of the lymphatic glands.
Abernethy having injected the mesenteric arteries and veins of a
whale, saw the fluid run into pouches about the size of an orange ;
he then injected mercury into the lacteals, and found that it flowed
into the same cavities ; he therefore concluded that the arteries,
veins, and lacteals all opened into the same cavities. This fact ap-
pears to confirm the observations quoted by MM. Fohmann and Lauth,
relative to the communications of the lymphatics with the veins
within the substance of the glands ; but the objections already urged
against those observations will apply to this one also.
The lymphatic glands are enclosed in a fibrous membrane ; I have
in vain attempted to find the fleshy coat described by Malpighi, and which he imagined
sent prolongations into the substance of these glands.
The lymphatic glands are supplied with very large arteries for their size, and they
give off still larger veins : a proper tissue {d) appears to enter into their composition.
The lymphatic glands may be said to consist essentially of an inextricable interlace-
ment of lymphatic vessels, their structure having some analogy to that of the corpus
cavernosum penis, and to that of the spleen. This opinion is confirmed by reference to
the anatomy of birds, in which lymphatic glands exist only in the neck, their place being
supplied by plexuses in all other parts.
Preparation of the Lymphatic Vessels and Glands.
I have already said, that in order to inject the network of lymphatics, the pipe should
be very superficially introduced into the free cutaneous, serous, or mucous surfaces.
When the injection is successful, the mercury passes from this network into the vessels
which emerge from it, reaches as far as the l3anphatic glands, and even penetrates through
several series of them.
The great number and peculiar arrangement of the valves prevents the injection of the
lymphatics from the centre towards the extremities ; I have attempted to do this several
times, without success, by introducing the tube into the thoracic duct.
From the small caliber of the lymphatics, it is necessary to use a capillary tube for
these injections. Mercury, notwithstanding the inconvenience of its fluidity, and in-
capability of being made solid, is the most convenient material for the purpose ; the
weight of a column of mercury about fifteen or eighteen inches in height aflJbrds suffi-
cient power for the injection. Anel's syringe is well adapted for injecting the thoracic
duct, which may be filled with a solution of isinglass, or, still better, with milk, which be-
comes coagulated by the alcohol. The best apparatus for injecting the lymphatics is a
glass cylinder, to the lower end of which is adapted a flexible tube, which is terminated
by a metal pipe, provided with a stopcock, and supporting a capillary tube of glass, which
is better than one made of steel or platinum, like those generally used in Germany. A
ring is attached to the upper end of the glass tube, by means of which the apparatus may
be suspended : this greatly facilitates the employment of the apparatus.
In order to inject the lymphatics, one of these vessels should be exposed at a greater
or less distance from the centre ; for example, in the lower extremity, upon either the
internal or external malleolus, or, what is still better, over the metatarso-phalangal artic-
ulations, in the way practised by Mascagni ; the vessel must then be punctured, and
the tube introduced into its interior ; the stopcock is then opened, and the mercury run?
* See note, infra.
t [Within the gland the lymphatics form a dense network (c) ; when the vessels of which this network ia
composed are distended, they give the cellular appearance to a section of the g-land noticed by Malpighi.
Cruickshank, <&c.]
41
'IBI'8 ANGEIOLOGY.
as far as the gland into which the vessels opens, and at the same time enters all the
vessels which anastomose either directly or indirectly with the one into which the tube
IS introduced. The vasa efferentia are also soon injected, and if the experiment be con-
tinued long enough, the mercury will, in all probability, reach the thoracic duct if no
rupture should occur. The internal jugular, sub-clavian, and brachio-cephalic veins of
both sides of the body may be previously injected, in order to prevent the mercury enter-
ing these vessels by the thoracic duct and its supplemental canals.
We may also have recourse to the following method, on account of its greater facility .
Puncture a lymphatic gland with a capillary tube ; all the efferent vessels which com-
municate with the cells thus punctured, and all the other portions of the lymphatic sys-
tem which communicate with those vessels, will thus be injected. But this method is
manifestly defective.
With regard to the choice of subjects, it may be remarked that the lymphatics are
much more easily seen when the cellular tissue is moderately infiltrated than when there
is extreme emaciation. Fat subjects are the worst of all : adults are preferable to chil-
dren and old subjects.
In describing the lymphatics, I shall follow the same arrangement as Mascagni, with
some slight modifications. Thus, after having described the thoracic duct and the great
right lymphatic trunk, I shall notice in succession all the lymphatic vessels which enter
it, beginning with those of the lower extremities. I shall not describe the vessels and
glands separately, but I shall group the vessels around the glands, as around central
points towards which they all converge.
DESCRIPTION OF THE LYMPHATIC SYSTEM.
The Thoracic Duct — the Right Thoracic Duct. — The Lymphatic System of the Lower Ex-
tremity— of the Pelvic and, Lumbar Regions — of the Liver — of the Stomach, Spleen, and
Pancreas — of the Intestines — of the Thorax — of the Head — of the Cervical Regions — of the
Upper Extremity and Upper Part of the Trunk.
The Thohacic Duct.
Dissection. — The thoracic duct may be examined, when distended with chyle, in an
animal killed during the process of digestion. If it is to be injected in the human sub-
ject, turn the intestines to the left and the liver to the right ; seek for the reservoir of
Pecquet (receptaculum chyli) between the aorta and the right crus of the diaphragm ; fol-
low one of the lymphatic trunks leading from this reservoir to the lumbar glands, and
puncture it with the injecting tube. Care must be taken to tie the left sub-clavian vein
both on the inside and on the outside of the termination of the internal jugular vein ; or,
still better, first fill the sub-clavian and internal jugular veins with a solid injection. If
we wish to make a preparation to be preserved, it is much better to inject the thoracic
duct with isinglass size by an Anel's syringe than to use mercury.
The thoracic duct {s 1 1 u, fig. 223), so called from its situation, is the common trunk
of all the lymphatics of the human body, excepting those of the right side of the head,
neck, and thorax, and of the right upper extremity.
It commences opposite the second lumbar vertebra, by the junction of a variable num-
ber of branches : Meckel says there are three, but I have generally found five or six.
These vessels, which are usually of large size, pass out from the abdominal lymphatic
glands ; they all converge towards a dilatation or ampulla of a triangular shape, which
is called the reservoir or cistern of Pecquet (cisterna, receptaculum chyli, s, fig. 223), after
the anatomist who showed that the lacteals did not pass to the liver, as was generally be-
lieved, in accordance with the opinion of Aselli, but that they entered the thoracic duct.
This ampulla, which is often nothing more than the point at which the lymphatic ves-
sels meet, and presents no dilatation, is situated to the right of and behind the aorta,
immediately below the aortic opening in the diaphragm, and by the side of the right eras
of that muscle.
Having commenced thus, the thoracic duct passes verticaUy upward, enters the tho-
rax through the aortic opening in the diaphragm, and becomes situated in the posterior
mediastinum {t t), in front of the vertebral coliunn, a little to the right of the median
Jine, and has the vena azygos (a a') on its right side, and the aorta on its left. Having
reached the front of the fourth dorsal vertebra, it inclines towards the left, still continu-
ing to ascend, passes behind the aorta, gains the left side of the oesophagus, runs along
oehind and on the inner side of the left sub-clavian artery, and escapes through the su-
perior opening of the thorax ; having arrived behind the left internal jugular vein, and
in front of the seventh cervical vertebra, it immediately bends forward, so as to form an
arch (m) like that of the aorta, and finally opens into the angle formed by the junction of
the left internal jugular and sub-clavian veins, or sometimes into the sub-clavian vein
externally to that angle. The direction of the thoracic duct is not straight, but flexu-
ous : its windings are sometimes very mmierous.
From the relations of the thoracic duct while within the posterior mediastinum, it fol-
THE RIGHT THORACIC DUCT, ETC. ^'Wfe
lows that, in order to expose its lower portion, it must be sought for on the right side
of that cavity, and that we must look for its upper portion on the left side, and must di-
vide the left layer of the mediastinum in order to expose it.
The thoracic duct terminates in many different ways : thus, it not unfrequently opens
by several trunks into the left internal jugular and sub-clavian veins. A still more fre-
quent method of termination, and one which it is extremely important to know, is that
in which the duct, at its upper part, is divided into two branches, the left one of which
(m) is distributed in the usual manner, while the right (indicated by a smaller letter «)
opens into the right sub-clavian vein in connexion with the great lymphatic duct of the
right side.
The caliber of the thoracic duct is not at all proportioned to the number and size of
the lymphatics which terminate in it. Sometimes, in fact, lymphatics are found which,
when distended, are as large as a goose-quill. Still less is it proportioned to all the
lymphatics of the body, of which it is regarded as the common trunk. Its caliber is even
smaller than that acquired by some lymphatics under many circumstances ; for exam-
ple, by those of the uterus during pregnancy : this is a powerful argument in favour of
those who regard the thoracic duct as by no means corresponding to all the lymphatics
of the human body.
The thoracic duct is not of uniform caliber in its entire length. It commences by a
dilatation of two or three lines in diameter ; in the middle of the thorax it becomes con-
tracted to less than two lines in diameter, and it is again dilated a little at the arch
which it forms before its termination.
The thoracic duct not unfrequently divides, during its course, into several branches,
which form a sort of network ; it often subdivides into two branches of unequal size,
which unite again after a variable distance.
The thoracic duct receives, while in the thorax, a very large trunk, which is derived
from the liver, and perforates the diaphragm through a special opening. I have seen this
trunk cross and continue in front of the thoracic duct, being equal to it in size, and at
last enter it opposite the fifth dorsal vertebra.
The thoracic duct has been observed to end on the right side, and then the lymphat-
ics of the left side of the head, left upper extremity, left lung, and left side of the heart,
entered separately into the sub-clavian vein of the corresponding side. Meckel has cor-
rectly observed, that such a disposition is a first trace of the lateral transposition of the
viscera.
Valves. — Of all parts of the lymphatic system, the thoracic duct has the fewest and
the smallest valves. The most remarkable are those situated at its termination in the
sub-clavian vein ; their free borders are turned towards the vein, so that they oppose
any influx of the venous blood into the thoracic duct. The free borders of the other
valves, when they exist, are turned upward, their convex borders being directed down-
ward : the course of the fluid within the duct is, therefore, from below upward.
The Right Thoracic Duct.
The great right lymphaiic duct, or right thoracic duct, is a large vessel, the common
trunk of all the lymphatics derived from the right half of the head and neck, the right
upper extremity, the right lung, the right side of the heart, and often, also, of those from
the right half of the diaphragm and of the liver. This trunk (v, fig. 223), which is not
more than an inch long, resembles the curved portion of the thoracic duct ; it opens at
the angle formed by the junction of the right internal jugular and sub-clavian veins.
Sometimes this common trunk does not exist, and then the lymphatics, by the junc-
tion of which it is usually formed, enter the veins separately. Anastomoses always ex-
ist, moreover, between the left and right thoracic ducts.
The Lymphatic System of the Lower Extremity.
The Lymphatic Glands of the Lower Extremity.
Tlie lymphatic glands of the lower extremity are the anterior tibial gland, the popliteal
gland, and the inguinal glands.
The anterior tibial gland is situated at a variable height in front of the interosseous
ligament, generally at its upper part. Hewson has seen it below the middle : Meckel
has found two glands here ; but the existence even of one gland is not constant.
The popliteal glands are four in number ; one of them is situated immediately beneath
the fascia ; the other three are placed deeply at variable heights along the vessels of the
popliteal space : they are rather small.
The inguinal glands are the most numerous and important ; they are situated in the
fold of the groin, below Poupart's ligament, and are generally grouped around the en-
trance of the internal saphenous into the femoral vein, in a sort of depression formed
between the adductor longus and pectineus on the inside, and the psoas and iliacus on
the outside. They are not unfrequently continued along the internal saphenous vein as
low down as the middle of the thigh. They are divided into superficial and deep. The
latter are very variable in size and number, and are often wanting : they are sometimes
620 ANGEIOLOGY.
continuous with the superficial, through the saphenous opening in the fascia lata. Thff
number of the superficial glands also varies much : it is nearly always inversely propor-
tioned to the size of the glands, which is also subject to great variety in diflferent indi-
viduals and at different ages. There can be no doubt that these differences in number
and in size depend, ceteris paribus, no less upon actual differences than upon the subdivis-
ion of one gland into several, or, rather, upon the union of a certain number of glands
into one. Sometimes we find a large circular gland situated around the termination of
the saphenous vein. The inguinal glands, moreover, are placed at different depths in
the substance of the fibrous layers which constitute the superficial fascia. Several of
these glands are frequently united to each other, not only by lymphatic vessels, but also
by prolongations of their proper substance.
The Lymphatic Vessels which enter the Lymphatic Glands of the Lower Ex-
tremity.
Preparation. — Introduce the pipe into some of the lymphatic vessels between the toes,
over the metatarso-phalangal articulations. Mascagni employed this method, which is
as easy as introducing the pipe into the vessels which run between the internal malleo-
lus and the skin. A still better method of injection, when it proves successful, is to fill
the lymphatic network in the skin by introducing the pipe into the dermis at any point
beneath the cuticle. But the limb requires to be warmed for this injection to succeed.
I have made a very beautiful preparation by injecting the cutaneous network of lymphat-
ics upon the sole of the foot in a new-born infant. The mercury ran as far as the glands
situated along the iliac vessels.
If the pipe be inserted into the skin upon the scrotum, or into the mucous membrane
covering the glans penis in the male, or into the skin of the labia majora in the female,
the mercury will reach the lymphatic glands of the groin.
The lymphatics which ramify in the gluteal region, and those situated in the sub-cu-
taneous cellular tissue of the abdominal parietes, may be injected in the same manner.
The deep lymphatics of the leg open into the anterior tibial gland and popliteal glands.
All the superficial lymphatics of the lower extremity, and also those of the gluteal re-
gion, perineum, external genital organs, and sub-umbilical portion of the parietes of the
abdomen, terminate in the inguinal glands.
Lymphatics of the Lower Extremities. — The lymphatics of the lower extremities, like
the veins, are divided into superficial and deep.
The deep-seated lymphatics are fewer in number and less accurately known than the
superficial ; they accompany the deep-seated bloodvessels. It is probable that every ar-
terial and venous branch has its corresponding lymphatics ; but those only which ac-
company the great vessels have been as yet discovered. They are divided into the pe-
roneal, the anterior and posterior tibial, and the femoral.
Of the anterior tibial lymphatics, two only have been demonstrated, although their num
ber must certainly be greater. One of these accompanies the plantar arch, the dorsal
artery and vein of the foot, and the anterior tibial vessels ; it communicates with the
posterior tibial and the peroneal lymphatics, opposite the upper part of the interosseous
ligament, and enters the anterior tibial gland, or more frequently perforates the interos-
seous ligament, and enters the popliteal glands.
The other anterior tibial lymphatic arises deeply from the outer side of the foot, and
joins the preceding.
The posterior tibial lymphatics, two or three in number, and likewise the peroneal lymphat-
ics, sometimes unite into a single trunk, and enter the popliteal glands.
The branches which emerge from the popliteal glands, five or six in number, traverse
the opening in the adductor muscle, ascend along the femoral vein, and open into the
deep inguinal glands.
The superficial lymphatics, which can be very easily shown to arise from a network in
the skin, run upward and inward, to reach the inner side of the leg, and then pass be-
hind the internal condyle of the femur : those which arise from the outer side of the foot
and leg, after ascending vertically in front of the muscles of the anterior region of the
leg, cross over the upper part of the tibia obliquely from without inward, so that all the
superficial lymphatics at last gain the inner and back part of the internal condyle of the
femur : from this point they incline forward like the sartorius, upon which they are pla-
ced, and then pass vertically upward, and are distributed to the different lymphatic glands
of the groin.
A certain number of lymphatic vessels which commence upon the outer border of
the foot (there are not more than two or three) pass over the external malleolus tc
reach the external saphenous vein, become sub-aponeurotic like that vein, and enter the
most superficial of the popliteal glands. These lymphatics, which accompany the exter-
nal saphenous vein, are regarded by some authors as forming part of the deep set o*
vessels.
Superficial Lymphatics of the External Genital Organs, Gluteal Region, Perineum, and
THE PELVIC AND LUMBAR LYMPHATIC GLARDS. 621
Lower Part of the Abdomen. — The superficial lymphatic vessels from these parts also en-
ter the inguinal glands.
The superficial lymphatics of the external genital organs of the male are divided into those
of the scrotum and those of the penis. If the skin of the scrotum be injected, several
8ub-cutaneous branches will be seen to pass from the network beneath the epidermis
upward along the sides of the penis, and then, after describing a curve with the concav-
ity directed downward, to open into the inguinal glands, generally into those which are
nearest the middle line, but I have seen them pass to the glands surrounding the saphe-
nous opening. If we inject the skin of the penis, and more especially the membrane
covering the glans, the mercury penetrates into the dorsal lymphatics of the penis, and
reaches the innermost and highest of the inguinal glands. The injection from the skin
of the penis enters the superficial lymphatics ; the injection from the membrane cover-
ing the glans enters only those superficial lymphatics which accompany the dorsal blood-
vessels of the penis.
In the female, injections of the skin of the labia majora, and of the mucous membrane
of the labia majora, labia minora, and clitoris, yield similar results as the injection of
the scrotum and penis in the male. We know that diseases of the labia, nymphai, and
clitoris, like those of the prepuce, penis, and scrotum, occasion enlargement of the in-
guinal lymphatic glands.
The lymphatics of the perineum unite with the preceding, and with the lymphatics of the
lower extremities.
The superficial lymphatics of the gluteal region turn horizontally round the glutaeus max-
imus and medius, and enter the external and middle lymphatic glands of the groin. This
is the reason why furunculi or other diseases of the skin upon the nates may give rise
to enlargement of the inguinal glands.
The superficial lumbar lymphatics, as well as those of the sub-umiilical portion of the
abdominal parietes, have a descending course : those of the loins run forward and down-
ward, those of the abdomen vertically downward ; they both terminate in the outermost
and highest of the inguinal glands ; and hence diseases of the skin covering the lumbar
and sub-umbilical regions may occasion swelling of the inguinal glands.
The lymphatic vessels which accompany the epigastric and circumflex iliac veins also
enter the glands of the groin.
The Lymphatic System of the Pelvic and Lumbar Regions.
The Pelvic and Lumbar Lymphatic Glands.
The lymphatic glands of the pelvis are divided into the external iliac, the internal iliac,
and the sacral.
The external iliac lymphatic glands, irregular in number, are situated along the artery
of that name. Three of them require to be particularly noticed ; they are situated im-
mediately behind the femoral arch, one of them on the outer side, another in front, and
the third on the inner side of the external iliac vessels. It is important, in reference to
the ligature of the external iliac artery, to know that these lymphatic glands are subject
to enlargement.
The internal iliac lymphatic glands occupy the space between the external and internal
iliac vessels. The bladder has proper lymphatic glands situated upon its posterior sur-
face, and near its summit. In the female, some of the pelvic lymphatic glands may be
regarded as belonging to the vagina and uterus. One tolerably large gland, which may
be said to be constant, occupies the internal orifice of the obturator canal, and I have
often found it inflamed or indurated in diseases of the uterus.
The sacral lymphatic glands occupy the sides of the anterior surface of the sacrum :
several of them are situated within the folds of the meso-rectum, and belong to the rec-
tum itself
The lumbar or aortic lymphatic glands are very numerous, and form a continuous chain
with the pelvic glands ; they occupy the angular interval between the conunon iliac ar-
teries, being placed along those arteries themselves, and also surround the aorta and the
ascending vena cava, but more particularly the aorta. It is important to note the rela-
tion of these lymphatic glands with the aorta, for that vessel is sometimes found much
compressed and narrowed from enlargements of these glands by tubercular or cancerous
deposite.
There is also a lymphatic gland in each intef-transverse space on both sides of the
lumbar region ; so that the lumbar lymphatic glands may be divided into the median and
the lateral.
The Lymphatic Vessels which enter the Pelvic and Lumbar Lymphatic Glands.
The different lymphatic vessels which proceed from the inguinal glands enter the pel-
vis behind the femoral arch, and near the femoral vein. The foramina through which
they pass are so numerous, that the fascia which is perforated by them is named the
cribriform fascia. Having arrived beneath the peritoneum, they are divided into two
633' ANGEIOLOGY.
sets, one of which descends into the cavity of the pelvis, and tenninates in the several
internal iliac lymphatic glands ; while the other enters the external iliac glands, and
more particularly those situated behind the femoral arch. These external iliac glands,
moreover, are joined by the epigastric lymphatics, some of which enter the inguinal glands,
and by the ilio-lumbar lymphatics.
The lymphatic glands of the pelvis also receive the deep lymphatics of the nates, which
accompany the gluteal and sciatic arteries ; the lymphatics corresponding with the ob-
turator vessels ; the lymphatics of the bladder and lower end of the rectum, those of the
prostate and vesiculse seminales, and the deep lymphatics of the penis in the male, and
those of the vagina, clitoris, and neck of the uterus, in the female. The lymphatics of
the bladder, before entering the pelvic glands, traverse the glands proper to itself : the
greater number of the lymphatics of the bladder run beneath the peritoneum upon its
posterior surface. I have seen the vesical lymphatics filled with pus. Some other
lymphatics emerging from the internal iliac glands accompany the external and internal
iliac arteries and veins, ascend in front of the sacrum, pass through other lymphatic
glands, and arrive at the brim of the pelvis. At this point, the lymphatics of the right and
left sides unite together. These vessels pass through one or several series of lumbar
lymphatic glands, and at last open into the thoracic duct. This collection of lymphatic
vessels and glands forms the internal and external iliac lymphatic plexuses. The inter-
nal iliac lymphatic plexus is placed in the cavity of the pelvis, and surrounds the inter-
nal iliac vessels : the external iliac lymphatic plexus is situated along the vessels of that
name.
All the lymphatics of the lower extremities, after having passed through a greater oj
less number of glands, open at last into these lumbar glands, so that the vessels and
glands together may be said to form an uninterrupted chain. Thus, passing from plex-
us to plexus, and from gland to gland, the lymphatics of even the most distant parts ar-
rive, at length, at the thoracic duct.
The lateral lumbar lymphatic glands, viz., those which occupy the spaces between the
transverse processes of the lumbar vertebrae, receive the lumbar lymphatics, properly so
called, which correspond to the bloodvessels of that name. From these glands, commu-
nicating vessels pass to the aortic lumbar glands. The collection of lymphatic vessels
and glands occupying the lumbar region is called the lumbar lymphatic plexus. The
following lymphatic vessels also enter directly into the lumbar glands : the lymphatics
of the testicles in the male ; the lymphatics of the ovaries and Fallopion tubes, and also
of the body and upper part of the neck of the uterus, in the female ; and the lymphatics
of the kidneys in both sexes.
The Lymphatics of the Testicle. — It has been already stated that the lymphatics of the
covering of the testicle enter the superficial inguinal glands ; those which belong to the
gland itself are divided into the superficial and deep. The superficial lymphatics may be
injected with the greatest facility by puncturing the serous membrane covering the tu-
nica albuginea ; the tunica vaginalis will then appear as if covered with a coat of silver.
(See the beautiful plates of Panizza.) These superficial vessels have numerous commu-
nications with the deep-seated lymphatics, so that both sets are injected at the same
time. All the lymphatics from the epididymus and the body of the testicle, which are
very numerous and large, ascend with and assist in forming the spermatic cord, pass
through the inguinal canal, follow the course of the spermatic vessels, and enter the
lumbar lymphatic glands.
The Lymphatics of the Uterus. — Having, in diseases of the uterus incidental to the pu-
erperal state, frequently detected pus in the lymphatics of the uterus (vide Anat. Path.,
liv. xiii., pi. 1, 2, 3), I have been able to trace the exact distribution of these vessels, and
would divide them into superficial and deep. The superficial lymphatics are situated im-
mediately under the peritoneum ; the deep lymphatics form several successive layers,
which occupy different planes within the substance of the uterus. The IjTnphatics near
the neck of this organ enter the pelvic and sacral lymphatic glands. A certain number
of the uterine lymphatics enter a lymphatic gland situated at the internal orifice of the
obturator canal.
All the uterine IjTnphatics, excepting those near the neck of that organ, pass towards
the sides and upper border of the uterus ; some run within the substance of the broad lig-
aments, and they all reach the upper or tubal angles of the viscus. They are joined by
the lymphatics of the ovaries, broad ligaments, and Fallopian tubes, and then ascend in
front of the corresponding ovarian artery and veins. Having arrived in front of the lower
part of the kidneys, they incline towards the middle line, and enter the glands which are
situated in front of the vena cava and aorta. Without having witnessed it, it is impos-
sible to form any idea of the enormous size which the uterine lymphatics may acquire
during pregnancy : several of these vessels, when filled with pus, become so dilated that
one would at first sight believe that an abscess had been formed.
The Lymphatics of the Kidneys and Supra-renal Capsules. — These are divided into super-
ficial and deep. The superficial lymphatics have never been injected directly ; but if a
fine injection be thrown into the renal arteries and veins, the injection, freed from col-
THE LYMPHATICS Of THE LIVER. 623
ouring matter, passes into the lymphatics. This was the only way in which Mascagni
could inject the superficial lymphatics of the kidney, which he has represented in his
beautiful plates.
The deep lymphatics, which are very numerous, pass out of the fissure of the kidney,
and enter the glands in front of and behind the aorta and vena cava.
The lymphatics of the supra-renal capsules are remarkable for their size and number ;
they unite with those of the kidneys, and terminate in the same manner.
The Lymphatic System of the Liver.
Preparation. — Of all the lymphatic vessels, those of the liver are the most easily de-
monstrated. Before they are injected, they may be rendered more apparent, and even
be filled, by throwing water either into the hepatic arteries, the vena ports, the hepatic
veins, or the hepatic ducts. In order to inject them, it is sufficient to make a superfi-
cial puncture in any part of the peritoneum covering the liver ; but it is most convenient
to operate upon one of the lymphatic trunks which run upon the surface of that organ.
It is of importance that the tube should be introduced between the peritoneal covering
and the fibrous coat, without perforating the latter. It is sufficient to inject from a sin-
gle vessel in order to fill all the others. The mercury generally runs as far as the near-
est lymphatic gland, the resistance in which causes the fluid to flow back into the sur-
rounding branches, even as far as their most delicate ramifications, so that, in successful
injections, the whole surface of the liver has a silvery aspect ; the possibility of injecting
the lymphatics of the liver, from the trunks towards the branches, must lead us to sup-
pose that there are fewer valves in them than in the lymphatics of other pjirts of the body.
The Lymphatic Glands of the Liver.
These are situated along the hepatic vessels, behind the pylorus, and are continuous
with the cceliac lymphatic glands. I have seen them of a jet-black colour ; a liquid may
be expressed from them, resembling that contained in the bronchial lymphatic glands.
The Lymphatic Vessels of the Liver.
The lymphatics of the liver may be divided into the superficial and the deep.
The Superficial Lymphatics. — These are subdivided into those of the convex and those
of the concave surface.
The lymphatics of the convex surface of the liver consist of a certain number of trunks,
some of which belong to the right and the others to the left lobe. Some of them run
from behind forward, others from before backward, towards the posterior border of the
organ.
The first set, or those which run from behind forward, reach the suspensory ligament
of the liver, and unite into several trunks, some of which perforate the diaphragm, enter
the anterior mediastinum, behind the xiphoid cartilage, and tenninate in the mediastinal
lymphatic glands ; while others are reflected over the anterior margin of the liver, to
gain the longitudinal fissure, along which they run as far as the gastro-hepatic omentum,
by which they are conducted to the lymphatic glands placed round the pylorus, to tbose
around the cardiac orifice of the stomach, and to those which lie along the lesser curva-
ture of that organ, and near the lobulus Spigelii.
The second set of the lymphatics of the convex surface of the liver, or those which
run from before backward, having reached the posterior border of the liver, divide into
three distinct groups of vessels : those on the left enter the substance of the left triangu-
lar ligament of the liver ; those on the right pass into the right triangular ligament ; while
the remainder, which occupy the middle, enter the substance of the coronary ligament.
Those lymphatics of the second set that do not perforate the diaphragm enter the
lymphatic glands along the vena cava, and from thence reach the thoracic duct. Some
of them run along the lower border of the twelfth rib, and open into the glands situated
near its posterior extremity, and into another gland which rests upon the twelfth dorsal
vertebra.
Those lymphatics of the second set which do perforate the diaphragm pass through
its crura, and proceed, some to the intercostal lymphatic glands, or into those which lie
along the vena azygos and the aorta, and thence into the thoracic duct ; while others
enter that duct directly. I have seen a veiy large lymphatic trunk open directly into
the thoracic duct, opposite the fifth dorsal vertebra. Mascagni pointed out some lym-
phatic vessels which, after having perforated the fleshy fibres of the diaphragm, ran be-
tween the pleura and that muscle, re-entered the abdomen through the aortic opening in
the diaphragm, and then passed into the glands surrounding the aorta and vena cava, or
entered the thoracic duct at no great distance from the reservoir of Pecquet, without
passing through any lymphatic glands.
The lymphatics of the concave surface of the liver consist of several tninks, which are all
directed from before backward, and are divided into three sets : those which are situ-
ated to the right side of the gall-bladder ; those which surround it ; and those which are
situated to its left side.
ANGEIOLOGY.
Those situated on the right of the gall-bladder partly enter the lumbar glands, and
partly terminate in the glands around the vena cava and aorta.
Those which surround the gall-bladder lorm a remarkable plexus, vphich accompanies
the hepatic vessels, and terminates in the lymphatic glands which lie along those ves-
sels, and in the glands situated in the substance of the gastro-hepatic omentum. Among
this set of lymphatics I would point out one considerable trunk, which runs in the cellu-
lar tissue connecting the gall-bladder to the liver.
The lymphatic trunks on the left of the gall-bladder end in the oesophageal lymphatic
glands, and in those which occupy the lesser curvature of the stomach.
The Deep-seated, Lymphatics of the Liver. — These vessels accompany the hepatic ducts
and the vena portae, and are contained with them in the capsule of Glisson ; they emerge
from the transverse fissure of the liver, penetrate the substance of the gastro-hepatic
omentum, and enter the lymphatic glands situated along the lesser curvature of the
stomach and behind the pancreas.
Those lymphatics of the liver which accompany the hepatic artery and duct and the
vena ports are extremely large, and are often filled with yellow lymph : they are some-
times found distended with gas in cases of commencing putrefaction. They were known
long before the lacteals ; indeed, they were the first lymphatic vessels that were dis-
covered.
The Lymphatic System of the Stomach, Spleen, and Pancreas.
The Lymphatic Glands of the Stomach,, Spleen,, and Pancreas.
Those of the stomach accompany the coronary vessels along the great and lesser cur-
vatures of the stomach ; some of them are situated within the gastro-splenic omentum,
and a great number surround the pyloric and cardiac orifices.
The lymphatic glands of the spleen occupy the hilus of that organ.
The pancreatic lymphatic glands are ranged along the splenic artery, and, consequently,
along the upper border of the pancreas ; several of them are grouped around the coeliac
axis. They receive a very great number of lymphatic vessels.
The Lymphatic Vessels of the Stomach, Spleen, and Pancreas.
The lymphatic vessels of the stomach are divided into the superficial and deep.
The sxiperficial lymphatics form a network beneath the peritoneum ; the deep lyni
phatics arise from an equally complex network situated in the mucous membrane. They
follow difl'erent directions : a great number of them pass to the great curvature, and enter
the glands situated there ; others proceed to the lesser curvature, and pass through the
glands in that situation. Several run towards the spleen, and enter the splenic lymphat-
ic glands ; and, lastly, others go to the lymphatic glands around the pylorus.
It has been stated that the lymphatics of the stomach have been seen filled with chyle :
this is at least doubtful.
The Lymphatics of the Spleen. — The superficial lymphatics of this organ cannot be seen
unless the splenic bloodvessels have been previously injected with size injection : the
size freed from the colouring matter will pass into them. I have seen tallow, thrown
into either the arteries or veins of the spleen, pass into the superficial lymphatics. It is
true that the injection was made forcibly, and kept up for some time. The deep lym-
phatics of the spleen are not known.
The proper lymphatics of the pancreas are little known.
The Lymphatic System of the Intestines.
The Lymphatic Glands of the Intestines.
The lymphatic glands of the small intestine, or the mesenteric glands, are extremely nu-
merous. Several anatomists, who have had the patience to count them, have arrived at
very different results, partly on account of individual varieties, and partly because sev-
eral, having chosen tuberculated subjects for the purpose, have mistaken the tubercles
for Ijnnphatic glands.
The mesenteric glands are situated between the folds of the mesentery, in the meshes of
the network formed by the arteries and veins. Those which are nearest to the intestine
are found in the intervals observed between the vessels of the mesentery close to the in-
testine. Those which are most distant from the intestine are situated near the adherent
border of the mesentery, along the trunk of the superior mesenteric artery. The largest
of these glands are found near the origin and termination of that artery. Thus we find,
below, a group of large lymphatic glands, the ileo-colic, opposite the termination of the il-
eum in the colon. Another cluster, named the duodenal, is situated above, in front of the du-
odenum : they are extremely large. We generally find one larger than the rest ; it is repre-
sented in the oldest works on anatomy, and has been sometimes mistaken for the pancreas.
The group of ileo-colic lymphatic glands is remarkable for frequently becoming inflamed
in follicular enteritis.
The lymphatic glands of the great intestine, or m^so-colic glands, much less numerous
than those of the mesentery, generally lie along the vascular arches formed by the colic
art(iries and veins : several of them are situated near the posterior border of the intes-
THE LYMPHATICS OF THE INTESTINES, ETC. -fHI
tine ; and some are even found upon the intestine, accompanying those bloodvessels
which run for a short distance beneath the peritoneal coat, and then penetrate the mus-
cular coat. The meso-colic lymphatic glands are not nearly so numerous along the
transverse colon as along either the ascending or descending colon. Those situated in
the transverse meso-colon form an uninterrupted chain with the mesenteric glands.
The. Lymphcaic Vessels of the Intestines.
The Lymphatics of the Small Intestine.— These vessels are divided into two sets, the
lymphatics, properly so called, and the lacteals.
The lymphatics, properly so called, like those of the stomach and great intestine, arise
from two sets of networks ; one in the serous, the other in the mucous coats. The ves-
sels which pass out from these networks have a remarkable character, which was well
described by Mascagni ; instead of passing directly into the mesentery, they first proceed
for a short distance along the intestine, and then curve and enter the mesenteric glands.
The lacteals, or lacteal vessels of the small intestine, can be easily seen in an animal that
has been killed while the absorption of chyle is going on in the intestine ; and they have
occasionally been observed in the human subject, in cases of accidental death. They
then appear as white, nodulated, and slightly flexuous lines, which communicate occa-
sionally with each other, pass from one mesenteric gland to another, enter the lymphat-
ic glands situated in front of the aorta and vena cava, and terminate in the thoracic duct
by a variable number of trunks : the lymphatic plexuses of the left side pass behind the
aorta.
The lacteals commence, according to Lieberkuhn, upon the summit of each of the villi
«)f the small intestines, run down to its base, and then enter at right angles mto the sub-
mucous lacteal vessels, which invariably perforate the other coats of the intestine, on its
concave border. This arrangement was very evident in a case in which the lacteals were
filled with tuberculous matter. — {Anath. Pathol., liv. ii., pi. 2.)*
The Lymphatics of the Great Intestine. — We may, with Mascagni, divide these l)Tnphatics
into two sets, according to the glands in which they terminate, viz., those of the coecum
and of the ascending and transverse colon, which pass through the meso-colic lymphatic
glands, and then terminate in the mesenteric glands ; and those of the descending colon
and rectum, which enter the lumbar lymphatic glands together with the lymphatics of
the genital organs, and of the lower extremities.
The Lymphatic System of the Thorax.
The Lymphatic Glands of the Thorax.
The thoracic lymphatic glands are divided into those of the parietes of the thorax,
those of the mediastinum, and the bronchial or pulmonary glands.
The lymphatic glands of the parietes of the thorax are very small, and are thus arranged :
t>ie intercostal glands are situated on each side of the spine near the costo- vertebral ar-
ticulations ; some are placed between the two layers of the intercostal muscles : they
are very smaU, and irregular in number. The sub-sternal or mammary glands are found
at the anterior extremity of the intercostal spaces near the internal mammary vessels,
and applied along the borders of the sternum ; there is one for each intercostal space.
The mediastinal lymphatic glands are divided into those of the posterior mediastinum, which
are arranged along the cEsophagus and aorta, and form a continuation of the intercostal
glands : they have been known to become enlarged and press upon the oesophagus, so as
to cause dysphagia ; and into those of the anterior mediastinum, the principal of which lie
upon the diaphragm in front of the pericardium, and around the great vessels connected
with the base of the heart.
The bronchial or pulmonary glands were noticed by the oldest anatomists, and espe-
cially by Vesalius, whence the name of glandula Vcsdiance, by which they are still known :
they are remarkable for their situation, number, size, and colour. They are situated
along the bronchi and their first divisions. The largest are generally placed opposite
the bifurcation of the trachea. The smallest lie within the substance of the lungs, around
the first divisions of the bronchi ; some of them are seen in the inter-lobular fissures.
Their number is very considerable.
In disease, they may acquire such a size as to compress and narrow the bronchi, and
thus prevent the passage of the air through those tubes.
In infancy they do not differ in colour from the other lymphatic glands, but they are
black in the adult, and especially in the aged. They are also liable to become the seat
of depositions of phosphate of lime.
Senac considers them to be secreting glands quite distinct from the lymphatic glands.
Portal divided them into true glands and lymphatic glands ; but no one has been able to
demonstrate the excretory ducts, which, according to Portal, proceed from the lymphat-
ic glands upon the trachea. The communications between these and the trachea, ob-
served in some cases of disease, are altogether accidental.
* See also note, p. 368.
4K
ANGEIOLOGY.
- The Lymphatic Vessels of the Thorax,
The lymphatic vessels of the thorax are divided into those of the parietes and those
of the organs contained in the thoracic cavity.
The Lymphatics of the Thoracic Parietes. — We shall here merely notice the deep-seat-
ed lymphatics. They are divided into the intercostal, the sub-sternal or internal mam-
mary, and the diaphragmatic.
The intercostal lymphatics accompany the arteries and veins of that name ; they re-
ceive the lymphatic vessels of the intercostal muscles and costal pleura, run along the
grooves of the ribs, pass through the intercostal lymphatic glands, reach the sides of the
vertebrae, unite with other lymphatics from the back of the thorax and from the spinal
canal, enter the lymphatic glands on the sides of the vertebral column, and are for the
most part directed downward to terminate in the thoracic duct.
The sub-sternal or internal mammary lymphatics arise from the supra-umbilical portion
of the anterior walls of the abdomen : they pass into the thorax, behind the ensiform
cartilage, and form two bundles, which run upon the sides of the sternum, unite with the
anterior intercostal and external mammary lymphatics, and enter the internal mammary
lymphatic glands. From the lowest of these glands other lymphatics proceed, and as-
cend in succession from one gland to another up to the inferior cervical lymphatic
glands ; on the left side they enter the thoracic duct, and on the right, the great lym-
phatic trunk. Sometimes, but rarely, the mjimmary lymphatics open directly into the
internal jugular and sub-clavian veins.
The lymphatics of the diaphragm for the most part unite with the intercostal and he-
patic lymphatics ; the others run forward between the pleura and the fleshy fibres of the
diaphragm ; some of them enter the inferior mediastinal glands, and the others, the in-
ternal mammary lymphatic glands.
The Lymphatics of the Thoracic Viscera. — The lymphatics of the lungs are divided into
superficial and deep : the superficial lymphatics may be injected in the same manner as
those of the liver ; they form an extremely close network beneath the pleura pulmonalis,
and frequently present a number of, as it were, varicose enlargements : these were no-
ticed and figured by Mascagni ; and the frequency of their occurrence led him to inquire
whether such was not the natural structure of lymphatics. Some of the vessels which
proceed from this network run in the inter-lobular fissures, and enter the lymphatic glands
situated at the bottom of these fissures ; while the others reach the internal surface of
the lung, and terminate in the bronchial glands.
These superficial lymphatics also communicate with the deep lym^phatics in the cel-
lular intervals between the lobules of the lung.
The deep lymphatics of the lung are very numerous : the manner in which they com-
mence in the lobules is not well known : they run in the inter-lobular cellular tissue, and
all proceed towards the root of the lung, in order to terminate in the glands situated
around the bronchi, and in several which lie along the oesophagus. It is doubtful wheth-
er a single pulmonary lymphatic vessel enters directly into another lymphatic gland
without first going through a bronchial gland.
Other lymphatics proceed from these bronchial glands ; some of which pass in front
of the trachea to enter the tracheal lymphatic glands, while the others proceed to the
lymphatic glands upon the oesophagus. On the left side both sets enter the thoracic
duct, at a short distance before its termination ; these are more numerous than those on
the right side, which enter the right lymphatic duct. Some of them terminate in the
thoracic duct, before it emerges from the thorax ; severeil of these vessels are sdso seen
to enter the internal jugular and sub-clavian veins.
I should observe that, in consequence of the above-mentioned anatomical fact, the
cervical lymphatic glands sometimes become enlarged in diseases of the lungs.
The Lymphatics of the Heart, Pericardium, and Thymus. — The lymphatics of the heart
are divided into superficial and deep ; the superficial vessels commence by a sub-serous
network, and, for the most part, run along the right border of that organ ; the deep lym-
phatics arise from the internal membrane of the heart, in which I have never been able
to inject a perfect network : they all accompany the coronary vessels, and all pass out
of the pericardium ; some of them unite with the lymphatics of the lung ; the others en-
ter the glands in front of the arch of the aorta and puhnonary artery, and from thence
pass to the thoracic duct.
The lymphatics of the pericardium and thymus enter the internal mammary, anterior
mediastinal, and bronchial lymphatic glands.
The Lymphatic System of the Head.
The Lymphatic Glands of the Head.
There are more lymphatic glands in the face than in the cranium.
All the lymphatic glands of the cranium are found upon its posterior region : some of
■"them are situated behind the ear, along the attachments of the occipito-frontalis ; several
.are placed beneath the upper end of the sterno-mastoid ; they are very small, and often
THt; I.YvIPHATICS OF THE HEAD, ETC. 627
escape notice in a hasty dissection : they become veiy distinct in diseases of the
scalp.
Are there any deep lymphatics of the cranium ? The pituitary body, the pineal gland,
and the white bodies known as the glandulae Pacchioni, have been regarded as belong-
ing to the lymphatic system. Some authors have even considered the tubercles, so
frequently found in the brains of infants, and which are evidently accidental formations,
to be of the same nature. Certain bodies found in the carotid canal, and which are
evidently enlargements of the ganglionic nerves, have also been described as lymphatic
glands ; but this opinion is now completely rejected.
Of the lymphatic glands of the face, the largest occupy the base of the lower jaw, and
are called the sub-maxillary l5Tnphatic glands : several of them are situated upon the
outer surface of the maxillary bone, along the facial vessels, in front of the masseter
muscle.
We find, also, in the face, the parotid lymphatic glands, some of which are superficial
and others deep, the latter being situated in the substance of the gland : we find some,
also, between this gland and the masseter : lastly, there are the zygomatic glands, situ-
ated imder the zygoma, and the buccinator lymphatic glands.
TJie Lymphatic Vessels of the Head.
These belong either to the cranium or to the face.
The Lymphatics of the Cranium. — The superficial or sub-cutaneous cranial lymphatics
are divided into two sets : the temporal lymphatics, which run along the superficial tem-
poral artery, and pass through the parotid lymphatic glands, from which vessels proceed
to the glands in the anterior region of the neck ; and the occipital lymphatics, which fol-
low the occipital artery, and terminate in the mastoid and the occipital lymphatic glands.
The deep lymphatics of the cranium, the lymphatics of the dura mater, or the meningeal
lymphatics, accompany the meningeal vessels, escape through the foramen spinale of the
sphenoid bone, and enter the jugular lymphatic glands.
Ruysch appears to have been the first who noticed lymphatics in the brain ; he has
named them vasa pseudo-lymphatica. Mascagni could only show the presence of the su-
perficial lymphatics of the brain by injecting coloured size into the carotid arteries. The
size freed from the colouring material passed into the lymphatics.
The lymphatics of the brain are but little known. M. Fohmann has described and
figured a lymphatic plexus situated between the arachnoid and pia mater, and precisely
resembling those found in other parts of the body. This network dips into the sulci,
and appears to be continued into the substance of the brain, where it is no longer possi-
ble to follow it. From this network some small lymphatic trunks proceed, and accom-
pany the arteries and veins as far as the foramina, in the base of the cranium, beyond
which M. Fohmann was never able to trace them ; so that he inquires whether these
vessels do not form an exception to the general rule from their want of connexion with
the absorbent system generally, and whether they do not enter directly with the veins
upon which they are- placed. On the other hand, Mascagni has figured some lymphatics
around the internal carotid, within the carotid canal, and also around the vertebral ar-
teries and internal jugular vein. The existence of these trunks leads us to suppose
that there must be cerebral lymphatics.
M. Fohmann has also found lymphatics in the choroid plexuses of the lateral ventri-
cles of the brain : these vessels were remarkably dilated, so as to present ampullae.
The Lymphatic Vessels of the Face. — These are divided into the superficial and deep.
The superficial lymphatics are much more numerous than those of the cranium. They
commence upon all parts of the face ; those from the frontal region accompany the
frontal vessels : the others accompany the adjacent bloodvessels ; several of them pass
through the buccinator glands, and they all finally enter the sub-maxillary lymphatic
glands. The lymphatics of the face are to be injected by introducing the pipe into the
plexus contained in the skin.
The deep lymphatics of the face accompany the bloodvessels. They are divided into
those of the temporal fossae, those of the zygomatic and pterygo-maxillary fossae, and
those of the nasal fossae. The lymphatics of the pharynx, velum palati, mouth, tongue,
and larynx, enter the deep parotid and the cervical lymphatic glands. The lymphatic
plexuses of the pituitary membrane, and of the lingual, buccal, and pharyngeal mucous
membranes, may be perfectly injected. Indeed, it is only in that way that we can
demonstrate the lymphatic vessels which emerge from these diflTerent parts
The Lymphatic System of the Cervical Regions.
The Cervical Lymphatic Glands.
The lymphatic glands of the neck are concentrated in the anterior region of the neck.
They are divided into the superficial and deep.
The superficial lymphatic glands of the neck are found principally along the external
jugular vein ; they are therefore situated between the platysma and the stemo-mastoid ;
and in the supra-clavicular triangle, that is to say, in the triangulfr interval between the
6!^ ANGEIOLOGY.
«>-
clavicle, the sterno-mastoid, and the trapezius. We also find several very small supei-
ficial glands between the os hyoides and the thyroid cartilage, and upon the sides of the
larynx.
The deep lymphatic glands of the neck are very numerous, and form an uninterrupted
chain around the internal jugular vein and the carotid artery, from the mastoid process
to the superior opening of the thorax, in front of the vertebral column, and upon the
sides of the pharynx and oesophagus.
The tracheal lymphatic glands are also continuous with the deep cervical glands.
The cervical glands form a continued series with the facial and sub-maxillary lym-
phatic glands on the one hand, and with the lymphatic glands of the thorax and axilla
on the other.
The Cervical Lymphatic Vessels.
The cervical lymphatics consist of those which have passed through the sub-maxillary
and facial lymphatic glands, and which afterward traverse the chain of glands along the
jugular veins. They are joined by those of the pharynx, oesophagus, larynx, trachea,
and thyroid gland. They then proceed from one lymphatic gland to another, and from
one plexus to another, down to the lower part of the neck, where they are joined by
some lymphatics from the lung, which also pass through some of the cervical glands :
they terminate on the left side in the thoracic duct, and on the right side in the right
lymphatic duct.
The Lymphatic System of the Upper Extremity.
The Lymphatic Glands of the Upper Extremity and of the Upper Part of the
Trunk.
There are generally no lymphatic glands in the hand or forearm, but Meckel found
several very small ones along the ulnar and radial bloodvessels. There are two or three
which are sub-cutaneous in the front of the bend of the elbow, and one or two above the
internal condyle of the humerus, behind the basilic vein ; in the arm we also find a se
ries of small lymphatic glands, which are never numerous, along the inner side of the
humeral artery.
The axillary lymphatic glands are situated deeply in the axilla, and are very numerous ,
some lie along the great vessels, others are scattered through the axilla : they are often
of a very large size.
The following may be regarded as appendages of the axillary glands : a small sub-cla-
vicular gland, situated deeply beneath the costo-coracoid membrane, opposite the trian-
gular interval between the pectoralis major and the deltoid, and two or three small glands
situated along the attachments of the pectoralis major, as far as the mammary gland.
Mascagni has figured a small lymphatic gland near the umbilicus.
The Lymphatic Vessels of the Upper Extremity and of the Upper Half of the
Trunk.
The Lymphatics of the Upper Extremity. — The superficial set of these vessels arise
from the skin of the hand, and run parallel to the fingers : they are, for the most part, sit-
uated upon the back of the hand ; they cross obliquely over the metacarpal bones, pass
over the carpus, and thus reach the forearm.
In the /orcarm they are distributed almost equally upon its anterior and posterior aspects.
The anterior lymphatics are collected upon the inner and outer sides of the forearm ;
having reached the elbow, some pass in front of the epitrochlea and its muscles ; others
in front of the epicondyle. In this place they are re-enforced by the lymphatics from
the posterior aspect of the forearm, which are also collected into an outer and innei'
group. Not unfrequently a certain number of the posterior lymphatics, which arise from
the outer side of the hand and forearm, after ascending almost vertically for some dis-
tance, pass obliquely, or cross transversely inward, above and below the olecranon, and
unite with the inner group.
In the arm some of the inner group of lymphatics pass to the lymphatic glands above
the epitrochlea ; the others run along the inner border of the biceps muscle and basilic
vein, and then pass backward and upward to reach the axillary glands.
The external lymphatics cross very obliquely over the anterior aspect of the arm, to
terminate, like the preceding, in the axillary glands. One of them has a remarkable
course ; it runs along the cephalic vein, gains the cellular interval between the pectoral-
is major and the deltoid, dips down over the upper edge of the pectorahs minor and be-
low the costo-coracoid membrane, and describes a curve so as to enter the sub-clavicu-
lar lymphatic ganglion.
The deep lymphatics of the upper extremity exactly follow the course of the bloodves-
sels ; they often communicate with the superficial lymphatics, and terminate in the ax-
illary glands. I have seen some of the deep lymphatics of the forearm communicate at
the bend of the elbow with the superficial lymphatics on the outer part of the back of the
arm, and enter the glands above the epitrochlea.
THE SKIN. 010111^
The Lymphatic Vessels of the Upper Half of the Trunk. — We have seen that all the lym-
phatics of the sub-umbilical portion of the trunk enter the inguinal glands ; and so all the
lymphatic vessels of the supra-umbilical portion terminate in the axilla.
The anterior and lateral lymphatics pass upward upon the pectoralis major and the ser-
ratus magnus, to gain the axilla.
The posterior lymphatics are divided into those of the neck and those of the back ; the
posterior cervical lymphatics descend upon the trapezius and the deltoid, and are reflected
over the posterior border of the leist-named muscle, in order to reach the cavity of the
axilla ; the posterior dorsal lymphatics run in different directions ; some horizontally, the
others from below upward, to be reflected into the axilla below the tendons of the la-
tissimus dorsi and teres major.
NEUROLOGY.
Neuroloot is that part of anatomy which treats of the apparatus of sensation and in-
nervation : this apparatus consists of the organs of the senses, of the cerebrospinal axis,
or central portion of the nervous system, and of the nerves, or peripheral portion of that
system.
THE ORGANS OF THE SENSES.
The Skin — its External Characters, Structure, and Appendages. — The Tongue considered as
the Organ of Taste. — The Organ of Smell — the Nose — the Pituitary Membrane. — The Or-
gan of Sight — the Eyebrows — the Eyelids — the Muscles of the Orbit — the Lachrymal Ap-
paratus— the Globe of the Eye, its Membranes and Humours — the Vessels and Nerves of the
Eye. — The Organ of Hearing — the External Ear — the Middle Ear or Tympanum — the
Internal Ear or Labyrinth — the Nerves and Vessels of the Ear.
The organs of the senses are certain parts of our bodies which are intended, by means
<n the sensibility they possess, to establish relations between us and external objects.
The organs of the senses, to use a strong figurative expression, are, as i« were, the
bridges which connect the individual with the world around him. — (^Meckel's Anatomy, by
Jourdan, p. 471.)
The organs of the senses, being placed between the brain and surrounding objects,
have the following characters in common : they occupy the surface of the body ; they
communicate with the brain by means of nerves of greater or less size ; and, lastly, each
of them has a peculiar structure in harmony with that particular quality of matter, the
perception of which it is intended to convey to us.
Anatomists generally admit five organs of sense, which we shall name, and then de-
scribe in the following order : the skin, or the organ of tact and touch, the organ of taste
the organ of smell, the organ of sight, and the organ of hearing.
The Skin.
General Remarks on the Skin.
The skin, the proper organ of tact and of touch, is a membrane which serves as a cov-
ering or integument to the body, and is so accurately moulded upon it as to preserve the
form, and yet conceal the inequalities, of its entire surface. It may be regarded as form-
ing an external surface or limit, endowed at the same time with sensibility and a poicer
of resistance ; enabling us by the one to perceive such qualities of bodies as are distin-
guishable by the touch, and by the other preserving us, to a certain extent from their ac-
tion. It forms, moreover, an exhalant surface, or sudorific organ, by which the system
is freed from noxious substances, and also an inhalant surface, by which fluids may be
absorbed.*
External Characters.
Examined in reference to its external characters, the skin presents an external or free
surface, and an internal or adherent surface.
The Free Surface. — Upon the/r«e surface of the skin the following objects require at-
tention : its folds, or wrinkles, and its furrows ; a peculiar colour, which is subject to
* Some ancient authors, Marcus Aurelius Severinus among others, adhering closely to the order of super-
imposition, which is sometimes called the anatomical order, commenced the description of the human body
with the skin ; and the same part, though for a very different reason, is described first by M. de Blainville, in
his Anatomic Comparie : that celebrated naturalist, carrying out analogical induction to its utmost limit»,
makes the skin the fundamental organ of the body, connecting with it all the organs of the senses, which he
regards as analogous to hairs, and names phanerac (a word constructed by M. Blainville in opposition to the
term crypto:, hidden, and derived from ipapcfiog, evident, manifest, apparent). He considers that the appa-
ratus of locomotion is a development of the elastic element of the skin, which becomes endowed with contractili-
ty ; the digestive and respiratory organs he regards as modifications of the absorbent apparatus of tlie skin ;
and the organs of secretion and generation as developments of its e.xhalant structure. The circulatory appa-
ratus alone is not derived by him immediately from the external integuments ; yet he almost believes that it
is an extension or prolongation of the meshes of the cutaneous cellular tissue
'6S0 NEUROLOGY.
variety in different races of men, and in different individuals ; certain horny growths, as
the nails and hairs, which are appendages of the skin ; and, lastly, numerous orifices for
the escape of the cutaneous secretions, some of them being the orifices of the sebaceous
foUicles, others of the sudorific glands, while others, again, are the foramina, or depres-
sions through which the hairs protrude. The horny growths of the skin will be noticed
presently ; and its colour and orifices, or pores, will be examined under the head of its
structure.
We shall here make a few remarks upon the different folds or wrinkles found in the
surface of the skin : they are of several kinds.
Some of them may be termed folds of locomotion ; they are permanent, and are inhe-
rent, as it were, in the skin itself, and have distinct relations to the various movements
of the body. They are of two kinds : the larger folds are observed around the joints, both
on the aspect of flexion, and that of extension ; for example, over the knuckles and in
the palms of the hands ; the small folds are found over the whole surface of the skin,
which is divided by them into irregular lozenge-shaped intervals ; it is to these folds that
the skin owes its extensibility.
Other folds, called wrinkles, are produced by the contraction of sub-cutaneous muscles ;
such as the transverse wrinkles produced by the action of the occipito-frontalis, the ver-
tical wrinkles by that of the corrugatores supercilii, and the radiated folds caused by the
contractions of the orbicularis palpebrarum, the orbicularis oris, and the sphincter ani.
These wrinkles, like the contraction of the muscles by which they are produced, are only
transitory ; but they become permanent when their causes are frequently repeated. In
the same class as these we must include the corrugations of the skin of the scrotum,
from contraction of the dartos.
The folds or wrinkles resulting from age and from emaciation depend upon the skin be
coming, after more or less distension, too much stretched, and, therefore, too loose to fit
closely to the parts beneath. Hence, emaciation in young subjects does not produce the
same effects as in the aged ; for in the latter, the wrinkles are caused by the want of
elasticity in the skin, and they are more distinct in proportion as that property is lost.
In cases of extreme distension, when the skin has been altered in its texture, the wrinkles
are more marked, and are permanent ; as, for example, those observed on the abdomen
of females after pregnancy, and of either sex after dropsy.
Furrows between the Papilla. — It is necessary carefully to distinguish from the folds or
wrinkles of the skin those more or less regular but slight furrows which exist between
the linear ridges or eminences formed by the cutaneous papillae in the palm of the hand
and the sole of the foot, and which are also found, though in a less marked degree, in all
other parts of the body.
Adherent Surface of the Skin. — In mammiferous animals the skin is lined throughout
the greater part of its extent by a layer of muscular fibres, which are intended to act
upon it, and constitute the cutaneous muscle or panniculus carnosus ; but in man the only
traces of this structure are the platysma myoides and the palmaris brevis.
The sub-cutaneous muscles of the human subject are concentrated in the face. It
follows, therefore, that, although in animals the passions can be expressed by move-
ments of the entire surface of the body, in man their expression is limited to the face.
It has been erroneously supposed that the phenomenon termed cutis anserina, or goose-
skin, a corrugated condition of the skin, in which the bulbs of the hairs are rendered
prominent by being forced outward, depends upon the contraction of a layer of muscular
fibres situated beneath the integument. But the most careful examination has demon-
strated no muscular fibres there ; we do not even find a dartoid tissue, such as is ob-
served wherever there exists a certain kind of active contractility independent of the will.
Beneath the skin of the human subject we find a layer of adipose tissue, panniculus
adiposus ; it varies in thickness, and is contained in the meshes formed by the fibrous
lamellae, which extend from the internal surface of the skin, and are then either attached
to the investing aponeuroses where the skin is said to be adherent, or become expanded
into a very thin aponeurotic membrane, called the fascia superficialis, in which case the
skin is movable. The quantity of sub-cutaneous adipose tissue, and the fixed or mo-
vable condition of the skin, have a constant and necessary relation with the functions of
each particular region. Thus, while adipose tissue is very abundant in the palm of the
hand and sole of the foot, where we always find a cushion of fat, it is never present in
the skin of the eyelids and penis.
When the skin over any bony eminence is required to be very movable, and at the
same time is exposed to continual friction, we find beneath it a sort of synovial capsule,
or bursa, as it is called ; some of these bursse exist at birth, and belong to the original
organization ; while others are accidental, and result from friction.
We must regard the sub-cutaneous adipose tissue as a dependance, or even as a con-
stituent part, of the integument, for it is impossible to separate one completely from the
other. The adipose tissue, in fact, penetrates into, and entirely fills the areolar spaces
in the skin.
The cutaneous vessels enter or pass out, and the cutaneous nerves penetrate at the
STRUCTURE OP THE SKIN. 631
adherent surface of the skin, and more particularly opposite the areolas observed on that
surface ; so that whenever the skin is stripped off for a certain extent, it either sloughs
off, or its vitality is so greatly impaired as to be incapable of completing the process of
cicatrization. An accurate idea is, perhaps, not generally entertained of the enormous
quantity of nervous filaments and of the immense number of arteries which enter the
skin, or of the number of veins which issue from it. Its importance, both in a healthy and
in a diseased condition, is sufficiently explained by these anatomical facts regarding it.
Structure of the Skin.
The skin consists essentially of the cutis, dermis, or true skin (a, fig. 226) ; of the pa-
pillcR, which project upon its external surface ; of the pigmentum, or colouring matter (i') ;
of the lymphatic network ; and of the epidermis, or cuticle (b) ; as accessory parts, it edso
contains the sebaceous follicles, as well as arteries, veins, lymphatics, and nerves ; and has
connected to it the hairs and the nails.
The Cutis or Chorion. — The dermis, chorion, or cutis vera (a, fig. 226 ; e, fig. 227), is the
fundamental part or the basis of the skin ; and to it the skin owes ^ 226
its strength, extensibility, and elasticity. If the skin be regarded
as formed of several distinct layers, the dermis constitutes the
deepest of these.
The thickness of the dermis varies in different parts, but is always
in proportion to the amount of resistance which it is required to
offer. Thus, in the cranium, it is very thick and dense ; on the face,
generally, it is thinner than on the cranium, but not in every part
of the face. Compare, for example, its density and thickness in
the skin upon the lips with its tenuity and delicacy in that of the
eyelids. On the trunk it is almost twice as thick behind as in front ;
and upon the penis, scrotum, and mamma it is much thinner and
finer than upon any other part of the anterior aspect of the body. skJnofNesro.
In the limbs the dermis is much thinner on the surfaces which are turned towards the
median line and on the aspect of flexion, than it is on the outer side of the limbs and on
the aspect of extension, which are more exposed to the action of external objects. On
the palms of the hands and soles of the feet, which are almost incessantly in contact
with external objects, the dermis is very thick.
The thickness of the dermis varies in different individuals, and also according to sex
and age. In old persons it participates in the general atrophy of the tissues, and be-
comes so thin as to be somewhat translucent, and enables us in certain regions to dis-
tinguish beneath it the pearly aspect of the tendons, and the reddish colour of the muscles.
The dermis has a deep surface, and an epidermic or papillary surface.
The deep surface presents a number of conical depressions, the base of each of which
corresponds to the sub-cutaneous layer of adipose tissue, while its summit is directed
towards the outer surface of the skin, and is pierced with very fine openings. These
depressions or alveoli, which are most strongly developed in the soles of the feet and
palms of the hands, are filled with conical prolongations or masses of fat, which, when
inflamed, give rise to boils, and in a state of gangrene, constitute the slough from such
sores.
When examined in reference to its structure, the dermis is found to be composed of
bundles of ceUulo-fibrous tissue, interlaced with each other, and becoming closer and
closer towards its external surface : this fibrous tissue is scarcely extensible or eleistic,
so that the extensibility and elasticity of the skin are due, not to the nature of the der-
moid tissue, but to the arrangement of its component bundles.* The elasticity of a tis-
sue may depend, like that of caoutchouc, upon the nature of its material, or, like that of
a spiral piece of brass wire, may result from the arrangement of that material. The elas-
ticity of the skin appears to be of the latter kind.
The PapUlm. — Upon the external or epidermic surface of the cutis are found a multi-
tude of small eminences, which are either arranged side by side, in rows or ridges {d,
fig. 227), as in the palms of the hands and soles of the feet, or are irregularly scattered
over the surface. These eminences are called the cutaneous papilla ; together, they con-
stitute the papillary body {corpus papillare). To understand them properly, we must ex-
ami le a section of a portion of skin from the palm of the hand or the sole of the foot,
which section should be made transversely to the direction of the papillary ridges (see
fig. 227) : nimierous small eminences are then seen projecting from the dermis into the
substance of the epidermis, which may be distinguished from these projections by its
transparency and its horny appearance. The papillae are still more distinctly seen by re-
moving the epidermis from a piece of skin, and then examining the latter under a thin
layer of fluid.
The papillae consist of a spongy erectile tissue,i- containing nervous filaments, arter-
ies, and veins.
* The dermoid, like other cellular and fibrous tissues, is resolved into gelatine by boiling. It acquires great
density and strength in the process of tanning, by which it is converted into leather.
t It is impossible to doubt the analosv of the papilla; of the skin to those of the tongue, and even to the in-
632 NEUROLOGY.
Tl:e nerves of the papillae are very numerous. In reference to this point, it is observed
that the number of nervous filaments distributed to the skin is always in a direct ratio
with the number and size of the cutaneous papiUae ; and hence the nerves of the skin
covering the palm of the hand are exceedingly numerous.
Several anatomists state that they have seen the nerves spreading out like pencils in
the papillae themselves.*
The papillae receive both arteries and veins ; in successful injections with mercury,
or with glue-size, spirit-varnish, or turpentine, coloured with vermilion, all the papillae
are penetrated by the injection, and exhibit, both in their interior and on their surface, a
vascular network, which might be called an erectile tissue. +
Lymphatics of the Skin. — If we introduce the pipe of the mercurial injecting apparatus
very obliquely beneath the epidermis, the mercury, if the process is successful, will run
into a sub-epidermic network of vessels, and will soon cover the skin with a metallic lay-
er. These vessels are most evidently lymphatics, for the mercury soon passes from
them into the sub-cutaneous lymphatic vessels, and from them into the adjacent lym-
phatic glands : in no case does it enter the bloodvegsels.
Mascagni, who has given so many representations of the vessels of the skin in his
beautiful plates, has delineated in several of them this lymphatic network, lying super-
ficially to the layer of bloodvessels.
The universal prejudice against microscopical observations had very improperly
thrown some discredit upon the positive results obtained by this great anatomist, when
an accidentally successful injection enabled Haase to trace and delineate the cutaneous
lymphatics of the groin from the skin to the inguinal glands. t M. Lauth, also, by acci-
dent, injected the lymphatic network of the same region. Panizza, in 1830, clearly de-
monstrated the arrangement of the superficial lymphatic network upon the glans penis
and the prepuce, in his beautiful injections of that organ in the human subject and in an-
imals. Lastly, M. Fohmann {Essai sur les Vaisseaux Lymphatiques do divers Ordrcs, 1833)
has made some special researches upon this subject, viz., upon the lymphatic network
in the skin and in other parts. Two beautiful plates, one representing the skin of the
mamma, and the other that of the scrotum, glans penis, and prepuce, give a perfect idea
of the arrangement of this network, which, when filled with mercury, forms a silvery
layer beneath the epidermis. From this network branches are given off which perforate
the dermis in all directions, and enter the sub-cutaneous lymphatic vessels proceeding
from its internal surface. We have succeeded perfectly in injecting the sub-cutaneous
lymphatic vessels in the entire lower extremity of a new-born infant, merely by introdu-
cing the pipe into the sole of the foot.
This lymphatic network is remarkable for being situated superficially to the bloodves-
sels, as Mascagni had correctly observed, and for being completely independent of any
other system of vessels ; also, for its vessels being dilated into ampullae at various pla-
ces, for being destitute of valves, and for not opening anywhere upon the surface of the
skin ; so that, excepting from laceration, the mercury does not escape through the pores
of the epidermis. Lastly, the network generally consists of two very distinct layers, sit-
uated between the epidermis and the dermis ; one extremely delicate and superficial,
the other lying immediately upon the dermis, and belonging to deeper vessels.^
The Pigmentum. — All the different shades of colour observed in the skin of the sev-
eral races of mankind belong to either the white, the black, or the copper-coloured va-
riety : they depend upon the presence of a colouring matter called the pigmentum, which
exists in the European as well as in the negro, though in a less marked degree, and
which is deposited beneath the epidermis.
This colouring matter, or pigmentum (b', fig. 226 ; c, fi^. 227), may be demonstrated in
the skin of the negro (represented in fig. 226) with the greatest facility by means of
maceration. It is tlien found not to be contained in special vessels, as Bichat supposed,
but to be deposited beneath the epidermis, where it constitutes a uniform layer, that
either comes off with the epidermis or remains attached to the dermis, but is independ-
ent of either. II The epidermis, the papillae, and the chorion are of precisely the same
colour in the negro as in the white races. The pigmentum of the skin is identical in
testinal villi. Although we are unacquainted with their precise structure, it is enough to know that they are
composed of an erectile spong-y tissue, in which both nerves and vessels terminate. The nervous lilaraentscan
be traced by dissection as far as the bottom of the alveolar depressions in the dermis.
* Analysis of a former Memoir upon the Structure and Functions of the Skin, by MM. Breschet and Rous-
sel de Vauzfime. These authors state that they have ascertained that the nerves of the skin terminate in loops
or arches, as had been pointed out by MM. Prevost and Dumas, in regard to the nerves of the muscles. We
shall elsewhere see what is to be thought concerning the existence of thesu terminal loops of the nerves in
muscles, and the theory of muscular contraction founded upon it.
t [The papillae are prolongations of the vascular and nervous chorion.]
X De Vasis Cutis et Intestinorum Absorbentibus, LipsiiK, 1789. In the plate given iu this work, the lym-
phatic plexus is very badly represented.
^ According to M. Fohmann, the skin is composed of the following parts proceeding from within outward :
1. The panniculus adiposus. 2. The internal layer of the dermis, characterized by its fibrous moshes. 3. A
vascular layer composed of lymphatics, and the terminations of the bloodvessels and veins, united by a small
quantity of animal matter. 4. A vascular network, formed exclusively by the ultimate rami ficatious of ' le lym-
phatics, 5. The rete mucosum of Malpighi. 0. The epidermis. !i See not« . 635.
THE PIGMENTUM. 63S
every respect with the choroid pigment in the eye, and is formed of black molecules in-
soluble in water. Blumenbach conjectured that this black matter was nothing more
than carbon : several experiments appeared to confirm this opinion, but it is now gen-
erally believed to be formed by the colouring matter of the blood.* In the European it
escapes observation, because it does not differ much in colour from the epidermis and
dermis.
The colour of the skin, which is a matter of such interest in the natural history of
mankind, and which forms one of the principal characters of the several human races,
has a tolerably constant relation to the colour of the hair : thus, individufds with light
hair have generally fairer skins than such as have dark hair ; and thus, also, red hair is
accompanied with a somewhat analogous colour of the skin. In albinoes the colouring
matter is deficient in the skin, as it is in the hair, and in the interior of the eye. More-
over, the transition, in regard to the colour of the skin, from the white to the black races
of mankind, occurs through a succession of intermediate shades : thus, I have found a
colouring matter precisely similar to that of the negro's skin beneath the epidermis of
several Europeans, particularly upon the scrotum, and upon the tanned faces of those
who have lived exposed to a strong solar heat. In the disease called black or green
jaundice, the skin of white persons becomes black or olive-coloured. A superficial
chronic irritation produced by blisters, or certain skin diseases, or by an adjacent wound,
will also sometimes cause a black discoloration of the skin.
• As to the source of the pigment of the skin, it is thought by M. Gauthier that it is
yielded by the bulbs of the hairs. M. Breschet describes a series of glandular organs for
secreting this pigment, which, according to him, are situated in deep furrows in the
outer portion of the dermis, and are surmounted by a great number of excretory tubes,
from which the globules of pigment are poured out beneath the epidermis. I have never
been fortunate enough to ascertain the existence of these glandular organs and their ex-
cretory tubes. It is generally supposed that the vessels of the cutaneous papillae are the
source whence the pigment is derived ; the mechanism of its formation must be the
same as that of the formation of the choroid pigment in the eye, and it is quite as little
understood.*
The Epidermis. — The epidermis, or cuticle (J, fig. 226 ; a b, fig. 227), is the outermost
of the several layers of the skin ; it is a semi-transparent, homy layer, which is moulded
upon the surface of the dermis and its papillae like a coat of varnish, and protects them
from the action of external agents. Its internal surface is, in fact, marked by a multi-
tude of little pits, into each of which a papilla is received ; so that this surface of the
epidermis may be said to form a mould of the papillary surface of the skin. In the skin
of the negro, the colouring matter occupies the little pits in the epidermis, and is found
in greater abundance between the papillae than upon them.
In order to obtain a good view of the structure of the internal surface of the epidermis,
various sections may be made of the skin upon the palms of the hands and soles of the
feet. It will then be seen that the papillas dip, as it were, into the epidermis, which fur-
nishes a kind of sheath for each of them. This arrangement is exceedingly distinct in
the skin upon the lower surface of the bear's foot. I have alluded to this structure in
vay Anatomie Pathologique (-'Diseases of the Lymphatics," liv. ii.). M. Breschet has
recently observed it in the skin of the whale, in which animal the epidermis forms a
complete tube for each of the papillae. These sheaths, or tubes, are united by a gluti
nous matter, and may be separated, at least in the bear, with the greatest facility.
The internal surface of the epidermis is intimately adherent to the external surface oi
the dermis ; but this adhesion may be destroyed in the living subject by the application
of a blister, and after death by maceration. If in a piece of macerated skin the epider-
mis be carefully separated from the true skin, it will be seen that the adhesion of one to
the other is in part effected by a number of very delicate transparent filaments, which
may be stretched to the extent of several lines without breaking. On examining the in-
ternal surface of the epidermis imder water, these filaments are seen floated out.
What, then, is their nature 1 Are we to regard them, with Cruickshank, as prolonga-
tions of the epidermis which dip into the areolae of the true skin"! or, with Beclard, as
strings of mucus formed by the stretching out of the viscid mucous matter situated be-
tween the dermis and the epidermis 1 or, on the other hand, are they canals 1 and if so,
are they to be regarded as exhalant vessels, as Kaaw, Boerhaave, and W. Hunter be-
lieved'? are they exhalant and absorbent vessels too, as Chaussier and Bichat imagined?
or are they not, rather, special vessels, the vasa sudoris of Bidloo, and the vasa sudatoria
of Eichhorn, the latter of whom attributed to them both an exhalant and an absorbent
function 1 These questions are not yet satisfactorily solved. The very great activity,
both of exhalation and absorption of the skin, necessarily supposes the existence of some
special apparatus for these processes.
Steno, Malpighi, and others admitted the existence of certain sudoriferous glands, sit-
uated in the adipose cellular tissue, and consisting of tubes which opened on the exte-
* See note, p. 635
4L
634 NEUROLOGY.
rior by means of an orifice provided with a valve. (Vide Holler, t. v., lib. xii., p. 42.)
Fig. 227. Th.\s description, when somewhat modified, agrees with the
statements recently made by M. Breschet, who has described
sudoriferous glands {g g, figs. 227, 228) having a saccular form,
and situated in the substance of the dermis. A spiral canal*
(h, fig. 227), proceeding from each of these sacs, traverses the
dermis and epidermis, and, after having made several turns,
opens upon the external surface of the skin (at i).t
Besides these filaments, the deep surface of the epidermis
presents certain irregularities, which may be felt by the finger,
and which, under the microscope, appear pointed like thorns ;
they seem to be prolongations of the epidermis, but I have not
been able to detennine their precise nature.
The external surface of the epidermis presents corresponding
folds and furrows to those already described upon the free sur-
face of the skin. It also has numerous orifices or pores, visi-
ble to the naked eye on the palms of the hands and soles of
the feet, and very distinctly seen by the aid of a lens. Along
each of the ridges formed by the rows of papillae are found a
series of orifices, arranged in a regular manner, and resem-
bling in appearance the puncta lachrymalia in the eyelids. If
the skin be examined with a lens during life, while the person
is perspiring, drops of the excreted fluid are seen to exude,
and form into a small globule, which is soon lost by evaporation,
and, after a few seconds, another globule makes its appearance.
It is impossible to conceive how several celebrated anatomists could have denied the
existence of pores in the skin. J
Delia Torre, Fontana, and Mascagni believed that the epidermis was organized, and
that it consisted of a network of lymphatic vessels. But as Panizza has clearly proved
(Osservazioni Antropo-zootomico Fisiologiche, 1830, p. 83), the lymphatic network always
lies beneath the epidermis, which may, by maceration, be raised up from it. After the
example of Panizza, I have endeavoured to inject the epidermis upon the soles of the
feet, and upon other parts of the body, but without being able to find a single vessel.
As for the opinion that the epidermis contains arterial and venous capillaries, it is so at
variance with the results of observation that it does not require refutation. The epi-
dermis, then, is unorganized [non-vascular].
It is a product of secretion, a layer of concrete, transparent, and very hygrometric
mucus ; a sort of horny matter, of variable thickness, capable of reproduction after hav-
ing been destroyed, and the morbid alterations of which result, not from any proper vital
action in itself, but from a diseased condition of those living parts of the skin by which
it seems to be produced.
As to the structure of the epidermis, it has been repeatedly stated to consist of imbri-
cated scales ; but the most careful examination discloses nothing more than a layer ol
uniform structure, into which the papillae enter ; so that it may be decomposed, hypo-
thetically and even actually, by the aid of the scalpel, in some animals, into a number of
agglutinated tubes or sheaths, each of which belongs to a single papilla. The different
forms of the fragments of epidermis, detached either spontaneously or in consequence of
disease, depend upon accidental circumstances, and show the continuity of this mem-
brane in the human subject.^ I shall presently describe the relations of the epidermis to
the hair, the nails, and the sebaceous follicles.
* Fontana had previously spoken of serpentine vessels, which he had seen beneath the epidermis by meaua
of the microscope.
+ [The sudoriferous glands, discovered by Breschet, Purldnj6, and Wendt, may be seen best by examining
under the microscope a thin perpendicular section of a piece of skin taken from the palm of the hand (as ia
fig. 227), and hardened in a solution of carbonate of potash. They are situated in the sub-cutaneous adipose
cellular tissue (/) ; they consist of a long convoluted tube (or of two tubes which unite together), ending in an
efferent duct (A), which opens (i) upon the free surface of the epidermis, and is lined by flattened epidermic
corpuscules. Where the epidermis is thin, these ducts are nearly straight, as in the scalp (see Jig. 228), and
their orifices are scattered irregularly over the surface ; where it is thick, they have a spiral course, as in the
palm and sole (fig. 227), where their orifices are arranged in single rows on the papillary ridges. These spi-
ral ducts are turned in opposite directions on the right and left extremities ; the average number of their ori-
fices is fifty in the square line ; the filaments described in the text as connecting the epidermis to the dermis
are the epidermic linings drawn out of these ducts, and out of the sebaceous and piliferous follicles.]
i See note, p. supra.
[^ The epideiTuic portion of the skin has been so long supposed to consist of several distinct structures, that
it is still convenient to describe separately an epidermis, a pigmentum, and a rete mucosuni ; but modern re-
search has shown that these are merely different layers of the same structure, in different stages of develop-
ment. The most superficial and hardest of these layers, which is separated from the skin in vesication during
life, and by maceration after death, is the epidermis described in the text, and by authors generally ; the
deeper, more recently formed, and softer portions, which may be displayed and subdivided into several layers
by maceration and dissection, constitute the pigmentum and the rete mucosum : together, these insensible,
extra-vascular, but not inorganic layers, form what is now called the epidermis.
Thus defined, the epidermis exactly resembles the epithelium of mucous membranes, in consisting of a
number of adherent nucleated corpuscules, each of which undergoes an independent development. Ininiedi
APPENDAGES OF THE SKIN. '"635
According to M. Breschet, certain minute reddish glands are situated among the sub-
cutaneous adipose vesicles, and constitute the secreting apparatus of the epidermis. Ex-
cretory ducts are said by him to proceed from the summits of these small glands, to trav-
erse the dermis, and to open at the bottom of the furrows found upon its external sur-
face. According to the same observer, these ducts generally resemble rows of regular-
ly-arranged columns, and the glands are sometimes situated at unequal depths from the
surface, and communicate with each other by intermediate ducts. I have never suc-
ceeded in verifying these observations ; and I have equally failed in attempting to decom-
pose the epidermis into a series of layers, becoming less and less compact in proportion
to their distance from the surface.
The Corpus Mucosum, or Corpus Reticulaire of Malpighi. — Malpighi applied the term
reticulum, and others, following that great anatomist, have given the names corpus retic-
ulaire, corpus mucosum, and rete mucosum, to a gelatiniform layer {d, fig. 227) of what is
regarded as a concrete mucus, situated beneath the epidermis and perforated by the pa-
pillae, which thus give it a reticulated appearance. This inorganic [non-vascular] layer,
which Malpighi first demonstrated beneath the thick epithelium of the tongue of the ox,
after it had been boiled, and which he then supposed to exist also in the skin, cannot be
demonstrated anatomically ; so that the expressions corpus mucosum, corpus reticulaire,
have lost their original signification, and have been interpreted in a different sense.
Haller, and several anatomists quoted by him, regarded the corpus mucosum as a deep
layer of the epidermis, some of them confounding it with the pigmentum, and others dis-
tinguishing it from that body. Bichat considered the corpus mucosum to be an extreme-
ly delicate network of vessels, or system of capillaries, which formed, with the papillae,
an intermediate layer between the chorion and epidermis, and was partly intended to
convey the blood, and partly the colouring matter of the skin.
M. Gauthier, in examining the skin of the heel in the negro, recognised four distinct
layers in the corpus mucosum, arranged in the following manner, from within outward :
1. Vascular processes containing red blood {bourgeons sanguins), which are situated upon
and adhere to the papillae ; 2. A deep white layer, composed of serous vessels, and
moulded upon the vascular processes and papillae ; 3. A layer of gemmules, forming a
kind of coloured membrane, excavated upon its deep surface, and separated from the
vascular processes and papillae by the deep white layer ; 4. A superficial white layer,
which he regards as formed of serous vessels, as well as the deep white layer. Exter-
nally to this is the epidermis. M. Dutrochet, founding his opinion upon the examination
of the skins of quadrupeds, admits the different layers of M. Gauthier, excepting the vas-
cular processes, which he very properly regards as forming parts of the papillfe : he
calls the deep white layer of M. Gauthier the epidermic inembrane, the gemmules he terms
the coloured layer, and the superficial white layer he names the horny layer.
Lastly, Gall regarded the corpus mucosum as a layer of gray nervous matter, precisely
similar to that of the gray substance of the brain and of the nervous ganglia.
I agree with Chaussier that we ought altogether to reject the corpus mucosum, in
whatever sense that term may be understood ; and I believe there are good grounds for
supposing that the different layers described as forming this body belong, in reality, some
to the papillae, and others to the epidermis.*
Appendages of the Skin.
Under this title may be included the sebaceous follicles and the homy growths, viz.,
the nails and hairs.
The Sebaceous Follicles. — The skin contains within its substance certain sebaceous fol-
licles {i i, fig. 228) ; these consist of small pouches, or bags, about the size of a millet
seed, which form projections beyond the epidermis, but are lodged in the substance of the
dermis, and open externally by very small orifices, which are visible under a lens, and,
in some persons, even to the naked eye. From these orifices an unctuous matter is con-
stantly poured out upon the surface of the skin, and assists in preserving its pliability ;
in some individuals this unctuous matter may be expressed from the follicles upon the
ately upon the surface of the true skin, these corpuscules are soft, roundish vesicles, containing a distinct nu-
cleus and peculiar pigment granules, and adhering together by a viscid matter, the cytoblastema, in which
they are first developed. In approaching the surface of the cuticle, they become larger and more compressed,
their walls become thicker and denser, their nuclei less distinct, and their pigment paler, until, at length, they
form thethin, flattened, horny, nucleated, colourless discs, whicli, adhering to each other firmly in an imbricated
manner, constitute the upper and horny portion of the epidermis, from the free surface of which they are con-
stantly being thrown off as minute scales, to be continually replaced by others having a similar origin, and un-
dergoing the same changes : these imbricated scales were described by Leuwenhoek and Baker.
The epidermis is insoluble, even in boiling water ; but it swells and becomes softened and transparent, in
these respects resembling mucus and epithelium ; it consists of a substance called keratin.
The pigment granules contained in the deeper epidermic corpuscules are the cause of the colour in the
skin ; they are black in the negro, &c., of lighter hues in other dark races, and fawn-coloured in the Euro-
pean ; in all cases they are darlcest in the deeper and newly-formed corpuscules, and fade as these approach
the surface : in albinoes they are either absent or colourless. The pigment contains iron and carbon, both in
a combined state, phosphate of lime, and animal matter ; but as it is bleached by chlorine, it contains no free
carbon, as supposed by some.]
* See note, p. 634.
636
NEUROLOGY.
Section of skin from the head,
magnified 14 times.
Fig. 228. alae of the nose, in masses which look like small worms.
These sebaceous follicles are somewhat analogous to
the follicles of the mucous membranes ; they are not
found in the palms of the hands and soles of the feet ;
but, in all probability, they exist in every part of the
body : they are especially observed in the axilla, on the
hairy scalp, and around the margins of the anus and
vulva, and the openings of the nose and mouth : they
are very much developed in the new-bom infant. The
sebaceous follicles appear to me to have a glaiidular
structure ; and this is particularly evident in those of
the axilla, the organization of which seems to me to be
more complex than that of those found in other parts
The supposition that these follicles are formed by the
reflection of the thin portion of the skin is altogether
fanciful.*
The Nails and the Hair. — In man the horny growths
of the skin are less developed than in any animal expo-
sed to similar atmospheric conditions ; and in man, also,
we find the highest development of the sense of touch.
The nails of the human subject are hard, yet flexible
and elastic, semi-transparent scales, and present the ap-
pearance of laminae of horn : they are situated upon the dorsal surface of the last phalan-
ges, which are therefore called the ungual phalanges ; and they appear rather to be in-
tended for the support and protection of the pulpy extremities of the*ngers. than as weap-
ons of attack, or instruments of defence and prehension. In a state of civilization it is
customary, therefore, to cut ofl!'that part of the nail which projects beyond the end of the
finger. The ingenuity of man enables him to provide himself with oflfensive M^eapons
amply sufficient to compensate for the weakness of those provided by nature, which, in-
deed, are quite rudimentary in him, and if more fiilly developed, would greatly interfere
with the delicacy of his sense of touch.
The peculiarity of the human nail consists in its only covering the dorsal surface of the
last phalanx, and in its being of considerable breadth, corresponding, in this respect, with
the horseshoe-like enlargement at the end of the phalanx. It follows from this, that the
whole of the pulp of the finger is concerned in the exercise of the sense of touch, t
The nail is divided into the root, the body, and the free portion : the root is that part of
the nail which is covered on both surfaces ; the body is that part which has one sur-
face free ; while the third, or entirely /rec portion, projects beyond the end of the finger,
and has a tendency to become incurvated when left to grow naturally.
In order to obtain a correct idea of the anatomy of the nails, we should, by a longitu
dinal incision, make a vertical section of the ungual portion of one of the fingers (see fig.
229). We shall then perceive that the root is about one fourth of the length of the body
of the nail (J) ; that it is also the thinnest part of the nail ; that it diminishes in thick-
ness towards its posterior edge, which is slightly indented, and that it increases towards
the body of the nail ; that it is flexible, and is received into a duplicature of the skin (c
c), to which it is attached by both surfaces ; that the posterior edge and lower surface of
the root adhere so slightly to the skin, that they may be said to be merely applied to it ;
that the upper surface of the root, though it adheres more closely to the skin than the
lower surface, is yet much less firmly attached to it than the under surface of the body
of the nail, which cannot be torn off without great violence ; that the nail is separated
from the phalanx by a very thick dermis (c') ; that this skin is of a white colour at the
root of the nail, and for some distance in front of it, where it occasions a semilunar
white mark, visible through the transparent nail, and called the lunule (lunula) ; and, lastly,
that the dermis, which corresponds to the body of the nail, is extremely vascular, and
hence the nail has a rosy hue, because its semi-transparency enables us to perceive the
colour of the subjacent tissue.
One of the most important points in the anatomy of the nail is the nature of its con-
nexion with the dermis. The fold of the skin, which is called the matrix of the nail, is
Ibrmed in the following manner : the skin (c, fig. 229, being the dermis) is prolonged
* [The sebaceous glands (t't, _/5^. 228) are mtiltilocular follicles; their ducts are lined by epi.lennic cor-
puscules, and open upon the surface of the skin in parts without hairs ; where hairs exist, they open into the
hair follicles (c), to each of which two sebaceous glands (it) are generally attached. On the face, very nii-
B^ite hairs have been found around the orifices of the ducts of these glands : their secretion is albuminous as
well as fatty.]
t The hoof, of which a very perfect example is met in the horse, is nothing more than a nail which enclo-
ses the united phalanges on all sides, like the wooden shoes sometimes worn ; the claw of carnivorous animals
is a nail which covers two thirds of the slender ungual phalanx, is compressed at the sides, and terminates in
a pointed hook. The nail, properly so called, is found only in man and in quadrumana, and in the latter it
approaches in ch.aracter to the claw. The division of mammalia into ungulatcd and unsrniciila'pd is exceed-
ingly natural, and is, in some measure, represented by certain correlative and constant differences in all other
Darts of the system. — (See Anatomic Comparee de M. de Jilainville.)
THE APPENDAGES OF THE SKIN. $^
from the finger on to the dorsal suiface of the nail, as far
as the curved line that marks the posterior boundary o!
the body of the nail ; from thence it is reflected b;ick-
ward, folded upon itself, as far as the posterior bonlrr
of the root of the nail. At this point it is again reflected
forward upon itself by passing behind that border, and
then (c' c') between the under surface of the nail and th'i
dorsal aspect of the phalanx : in consequence of this two-
fold reflection, it follows that it is always the epidennic ^"''°" "'"'='" "^ *"»'•
surface of the true skin that is in contact with the nail : at the anterior extremity of the
nail the skin again meets, as it were, the epidermis (a'), and becomes continuous with
the integument upon the tip of the finger. But what is the arrangement of the epider-
mis at the point where the skin is first reflected backward 1 It is prolonged forward
(a), slightly beyond the curved line formed by the reflection of the dermis, and forms a
semicircular zone or band, which terminates by a smooth border, and jidheres intimately
to the nail. As to its arrangement beyond this point authors are not agreed. Some are
of opinion that it would be prolonged upon the free surface of the nail, if it were not de-
stroyed by friction ; but they overlook an objection to this view to be derived from the
accustomed regularity of the epidermic border : others, again, believe that the epidermis
is reflected backward like the dermis, but differ among themselves cis to its ultimate dis
position ; some, for example, conceiving, with Bichat, that tlie epidermis is continuous
with the posterior border of the nail, and some supposing that it is again reflected for
ward beneath the nail, together with the dermis (see dotted line), which, according to
this hypothesis, it never quits.*
A very simple experiment most clearly demonstrates the nature of the connexion be-
tween the epidermis and the nail : it consists in submitting a finger to the process of
maceration, by means of which the nail and epidermis come off together in the form of
a partly epidermic and partly horny sheath. In this the epidermis (a) is found to be re-
flected backward upon the dorsal surface of the root of the nail, and to become blended
with it (see fig. 229) without ever passing beyond its posterior border ; while in front, at
the limits between the body and the free portion of the nail, the epidermis (a') is mani-
festly continuous with the deepest layer of the homy lamina ; so that it cannot be doubt-
ed that there is an identity of nature between the nail and epidermis.
Structure and Growth of the Nail. — On examining the two surfaces of the nail, and es-
pecially its deep surface and posterior border, it is found that they are marked by very
distinct longitudinal lines or striae, which appear to indicate a corresponding linear tex-
ture. It would seem, accordingly, that the nail was formed by the agglutination into
laminae of a number of longitudinal fibres ; but, if we examine the free surface of the nail
attentively, we find that it is marked by curved striae, which intersect the longitudinal
ones. These curved striae are particularly distinct in the not uncommon cases in which
the nail of the great toe is much hypertrophied, and becomes incurvated upon the plantar
surface of the toe : the enlarged nail is found to consist of imbricated laminae, received
one into the other like the several laminae in the hoof of an animal. We may even sep-
arate these different layers by aid of maceration, and find that they are fitted one into
the other, the deepest being that which was last secreted. The nails, therefore, are
developed by a method very analogous to that by which we have already stated the teeth
are formed. (See p. 179.)
The nails, then, like the hoofs of animals, and like the epidermis, are products of se-
cretion : they receive neither vessels nor nerves : alterations in their texture are not de-
pendant upon diseases inherent in themselves, but result from some morbid condition of
their formative organ. The fold of the dermis, which is called the matrix of the nail, is
not the only part by which the substance of the nail is secreted, but the whole papillary
surface of the dermis, to which the nail adheres, is concerned in its formation. The
papillae are ananged in longitudinal rows, and hence the substance of the nail is depos-
ited in longitudinal striae. -f
The nail grows continually in length ; it does not increase sensibly in thickness, ex-
cepting during disease. The layers that have been deposited the longest time are the
most superficial, and occupy the free extremity of the nail, in precisely the same manner
as the oldest-formed ivory in the tooth is nearest to the enamel.t
* See note t, below.
f The arrangement of the papillary dermoid layer which covers the dorsal surface ot the ungual phalanx
IS worthy of notice : it adheres intimately to the periosteum, and forms an extremely dense, grayish stratum,
penetrated by vessels and nerves ; so that, if the mode of termination of the nerves in the papillse c.an ever be as-
certained, it is, without doubt, beneath the nail, where these papillae present their highest state of development.
t [The nails are found by Schwann to consist of nucleated corpuscles, which, like those of the epidermis,
are formed upon the surface of the dermis, where they are soft and vesicular, and afterward become hard,
flattened, and firmly agglutinated together, as in the substance of the nail. These corpuscles are developed,
not only opposite the matrix of the nail, but beneath the whole of its attached surface ; the nail is thus elon-
gated, and, at the same time, its thickness is maintained, notwithstanding the flattening of the corpuscles
formed at the root as they approach the surface. The thin layer of epidermis, described by Weber, Lauth,
and Gurlt, as continued under the whole attached surface of the nail, is nothing more than the soft stratum
of growing corpuscles, which pass insensibly into those of the true epidermis.
Like the epidermis, the nails consist of keratin.}
638 NEUROLOGY.
The Hairs. — The hairs are filiform productions of tiie epidermis, generally flexible, va-
riable in length, size, and colour, and bearing different names, according to the region on
which they are situated.*
The surface of the human body, with the exception of the palms of the hands and the
soles of the feet, is covered by very fine and short hairs, which form a light down, as it
is named ; but the hairs, properly so called, are collected upon particular parts of the sur-
face of the body, where they serve some special purpose. Thus, they exist in great
abundance upon the cranium, where they are called the hair ; on the face, where they
form the whiskers and beard ; the hairs upon the margins of the eyelids are called the eye-
lashes ; the arched row over each orbit is called the eyebrow ; the hairs upon the lips con-
stitute the mustache.
On the trunk the hairs are collected, in more or less abundance, around the genital or-
gans : they exist, also, in the axillae of both sexes ; and on the chest, between the breasts,
in the male. The hairs present well-marked differences, according to sex, age, and the
peculiar race to which the individual belongs. The pilous system is most developed in
the Caucasian race, and least so in the negro.
The hair, eyelashes, and eyebrows exist before birth : before birth, also, the whole
body is clothed with a very thick down, which is shed during the first few months after-
ward. At the period of puberty, hairs are developed upon the pubic region, and in the
axillae of both sexes, upon the labia majora of the female, and upon the scrotum and
around the anal orifice in the male : the beard also appears in the male, and the ante-
rior aspect of the trunk, and the limbs are covered with hairs of variable length in dif-
ferent persons. I should observe, that the development of the hairs is not always in
proportion to the personal strength, as is asserted by certain authors, who regard an
abundance of hair as an attribute of strength and virility. But, although some men with
hairy skins have robust constitutions, a great number are delicate, and are even affected
with tubercular phthisis.
In mammalia, the hairs upon the posterior or dorsal region of the trunk are more de-
veloped than those upon the anterior or abdominal aspect, a proof that they are destined
to the quadruped attitude : in some animals, which turn upon their backs to protect them-
selves, the hairs upon the abdominal surface are most highly developed.
The hair of the head may grow to a very considerable length : it has been seen to reach
as low down as the middle of the leg, and, when thrown around the trunk, sufficiently
abundant to cover it like a garment. The length and the direction of the hair upon the
head evidently prove that man is destined for the erect posture ; for, if he assumed the
attitude of a quadruped, it would trail upon the ground, and fall over the face.
The hair also presents peculiarities, or differences, in many respects ; for example, in
direction, some hair being long and smooth, some crisped and woolly ; this latter kind is
peculiar to the negro race, and it never grows to a very great length : also in diameter,
some hair being excessively fine, and some large and coarse. t It differs, again, as to
quantity, for, in general, the hair of the head is more abundant in the female than in the
male, as if the activity of the pilous system was principally confined to the hairy scalp
in the former sex ; and, lastly, in its colour, from which certain very important distinc-
tions among men are established.
Every different shade in the colour of the hair may be referred to three principal va-
rieties, the black, the flaxen, and the red. The flaxen hair belongs particularly to the
inhabitants of the north, and to persons of lymphatic and sanguineous temperaments ;
the black is characteristic of the inhabitants of the south, and of those of a bilious and
sanguineous temperament ; the red belongs to no particular temperament ; and in our
ideas of beauty, this coloured hair, which is usually accompanied with a disagreeable
odour of the perspiration, is regarded as a natural misfortune.
The beard and whiskers are peculiar to the male sex ; they occupy the lower part of
the face, and, consequently, leave uncovered all those parts which are principally con-
cerned in giving expression to the physiognomy, viz., the ocular, nasal, and frontal re-
gions. We cannot insist too strongly on the connexion existing between the develop-
ment of the genital organs and that of the beard. The eunuch is almost destitute of
that appendage.
The great attention rendered necessary by wearing a long beard and long hair has led
to the custom of cutting the hair and shaving. It is remarkable that the most effemi-
nate nations, the Orientals, for example, are those among whom long beards are in high-
est estimation. The influence of these different customs upon the health are deservedly
subjects of examination for those who study Hygiene.
Structure and Growth of Hairs. — The only method of obtaining an accurate knowledge
of the structure of hairs is to study their growth. The extremity of the hair which is
inserted into the skin is contained in a sort of follicle, very analogous to the dental folli-
* The spines of the hedgehog, the bristles of the boar, the hair of horses, the wool of sheep, and the fur of
most mammalia, are different kinds of hair.
t [The hair of the head also varies in its form; a section being a more or less flattened oval, or even reni
form, from the hair being excavated along one side. On the face, the hairs are still more flattened.]
THE ORGAN OF TASTE. 639
'.les. Tliis hair-follicle (e,fig. 230), which is the formative organ of
-lie hair, is imbedded in the sub-cutaneous cellular tissue (g), and is
prolonged to the surface of the skin by a sort of meinbranous canal,
which was well described by Bichat. The hair-follicles consist es-
sentially of a pouch or sac, and a papilla.
The membranous pouch or sac (c c), called the bursal membrane
by Heusinger, forms a sort of cul-de-sac, having a narrow neck, and
opening externally by a contracted orifice, through which the hair
(A) passes without adhering to it at all. Its walls are sufficiently
transparent to allow the hair contained in its cavity to be seen. If
this cavity or sac, which, according to M. Dutrochet, is formed
merely by the inversion of a portion of the skin, be laid open, its in-
ternal surface (c) is found to be smooth, not adherent to the hair, but
separated from it by a reddish liquid, first pointed out by Heusinger. Magnmrf."
From the bottom of this sac, i. e., from the part farthest from the orifice through which
the hair protrudes, a papilla (a), called the pulp of the hair, arises : this papilla is of a
conical form, its base being adherent, while its apex is free ; it reaches nearly to the
orifice of the sac, and even projects beyond it in the disease called plica polonica.
Bloodvessels and nerves pass to the bottom of the hair-follicle, and are probably distrib-
uted upon the papilla.
It is upon the papilla that the hair is formed. At its commencement it resembles a
conical horny sheath, which is exactly moulded upon the apex of the papilla. On the in-
ner side of this horny cone another is formed, which raises up the preceding one, and
so on in succession, the entire hair constantly maintaining a conical form. According
to the experiments of Heusinger, who plucked out at intervals the hairs from the whis-
kers of a dog, and afterward killed the animal, so as to observe the successive changes
which took place in the hair-follicles during the development of the new hairs, a rather
long period elapses before the hair projects beyond the epidermis ; but, when once it has
overcome that obstruction, its growth proceeds rapidly.
What is the arrangement of the epidermis at the point where the hair emerges beyond
its surface 1 According to some, it is prolonged upon the hair, and forms its outer coat ;
according to others, it dips into the cavity of the hair-follicle, and is reflected upon the
base of the hair, so as to form upon it an epidermic tube, which falls off in scales as the
hair is prolonged outward ; according to others, again, the epidermis has no connexion
with the hair ; and I am the more inclined to subscribe to such an opinion, because the
hair is of the same size both before and after it has left the follicle.*
The hair is the product of a secretion, and, therefore, destitute of vitality, being form-
ed by a series of small horny cones fitted one into the other. It is generally admitted
that it is composed of a homy, colourless, transparent, epidermoid sheath, containing a
sort of coloured pith in its interior. Bichat presumed that this central substance was
formed of certain bloodvessels which contained the colouring matter ; but the mode in
wiiich the hair is developed proves that it is not tubular, and also that the colouring
matter itself is produced by the papilla at the same time as the epidermoid sheath. The
white hairs of old people are merely deprived of colouring matter. +
The Organ of Taste.
The structure of the tongue, the organ of taste, which has already been described (see
j). 332), presents a greater analogy to that of the skin than any other of the organs of
liio senses.
Tlie sense of taste resides essentially in the papillary membrane which covers the up-
i>or surface of the tongue. t It has already been stated that the perforated eminences
found at the base of the tongue are not papillae, but glands ; and the true papillae have
been divided into the large or cahciform papillae, which are arranged in the shape of the
lettov V at the base of the tongue, and the small papillae ; which may be again subdivided
iiiro the conical, the filiform, and the lenticular or fungiform, according to their respect-
iv shapes.
i>ery special sense, by which term is understood ail such as receive sensations dif-
ftrent from that of touch, properly so called, presents for our consideration a special ap-
*■ rThe root of some hairs is larger than the shaft, and is named the bulb ; this, however, does not depend
(.u thu hair being covered by the epidermis, a thin layer of which (d d,fig. 230) lines the follicles, and is be-
liiivdd to terminate at the root of the hair. Into each hair-foUicle one or more sebaceous glands (i i,fig' 227)
;i.n;r tlieir secretion.]
t Lllairs, like the nails, consist, according to recent researches, of nucleated corpuscles, which differ in
U.xm, density, and arrangement, in different parts of the hair. At the root, upon the surface of the papilla,
»h: re they are first developed, they are soft and vesicular ; in the central medullary part of the shaft they are
b:inkr, compressed, and polyhedral ; in the cortical part they form an immense number of very long and fine
liiirrs, and, on the outside of these, a layer of short, hard scales.
The hairs consist principally of keratin and an oily matter ; besides which, they yield sulphur, phosphorus,
iron, salts of lime, and traces of manganese, silica, and magnesia.]
X [The mucous membrane on the under surface of the tongue, and that covering the buccal surface of the
soft palate and the immediately adjacent parts of the fauces, also possess the sense of taste.]
649 NEUROLOGY.
paratus, on which the impressions act, and a special nerve or nerves, adapted to receive
those impressions and transmit them to the brain.
The nmscular structure of the tongue, which at first sight appears to be useful only in
mastication, deglutition, and the articulation of sounds, is intimately connected with the
sense of taste, which would have been exceedingly imperfect, had not the gustatory
membrane been capable of being moved over the bodies to be tasted. The gustatory
apparatus of the tongue consists, then, of a papillary membrane stretched over a muscu-
lar surface, and united so closely to it that it is impossible to separate one from the oth-
er. Moreover, this membrane is constantly kept in a state of humidity, and occupies
the first cavity presented by the digestive apparatus.
The Gustatory Papillary Membrane. — All the elements of the skin are found in the gus-
tatory membrane.
The chorion is as dense as the densest part of the chorion of the skin : a very great
number of muscular fibres are inserted into it, so that the gustatory membrane can be
moved not only as a whole, but each part of it has its own separate movements.
The papilla, by which the surface of the tongue is rendered so rough, may be said to
represent the papillary body of the skin in a very highly-developed state.*
The lingual papilla are supplied with nerves, which can be more easily shown than
those in the cutaneous papillee. Haller has traced them into the papilla; ; and I have suc-
ceeded in doing the same, but without being able to ascertain their mode of termination.
The papillae also receive bloodvessels, which are so abundant that, in successful injec-
tions, the papillary body appears to be altogether vascular.
The Lymphatic Network. — By making a superficial puncture into any part of the mem-
brane which covers the dorsum or the borders of the tongue, we may inject a lymphatic
network upon it, precisely similar to that found in the skin.
The mucous body, or rete mucosum, does not exist as a distinct membrane upon the
tongue any more than in the skin. I have already stated that it was while examining
the boiled tongue of the ox that Malpighi discovered a glutinous stratum situated be-
tween the epidermis and the papillae, and perforated by a number of openings, corre-
sponding to that of the papillae themselves ; hence the name of reticulum which he gave
it ;t but it is as impossible to demonstrate it upon the tongue as in the skin.
The Pigmentum. — There is never any black colouring matter in the tongue of the hu-
man subject ; but it is distinct upon the tongue of some animals, as the ox, and can be
easily demonstrated between the papillae and the epithelium.t
The Epithelium. — Each papilla is covered with a sort of epidermic sheath, which, ac-
cording to Haller, was discovered by Mery and Cowper, and which has been perfectly
described by Albinus under the name of the periglottis. This epidermis, or epithelium,
so easy of demonstration in the lower animals, in which it has the consistence of horn,
may be also readily shown in the human subject, although, in accordance with the great-
er perfection of the sense of taste in man, the epithelium is comparatively thin. If the
upper surface of the tongue be examined with a lens, especially after maceration, the
lingual epithelium will be seen to be arranged in precisely the same manner as the epi-
dermis of the skin, and to form a protecting sheath for each papilla. In persons who
have sunk after long abstinence, the epithelial covering forms several imbricated layers,
which can be rubbed off; the fur which adheres to the tongue is in a great measure
formed by this debris of the epithelium somewhat dried. The epithelium of the tongue
can be removed by friction ; and, in certain inflammatory diseases, the tongue is denuded
of it. When one of the lingual papillae is thus exposed, it becomes excessively painful.
The Nerves of the Tongue. — No other organ, perhaps, of equal size, receives so many
nerves as the tongue : one pair, the ninth or hypoglossal, is exclusively appropriated to
it ; and it also receives, on each side, the glosso-pharyngeal branch of the eighth, and
the lingual branch of the fifth of the cerebral nerves. Which of these nerves must be
regarded as the nerve of taste in the tongue 1 Evidently the one that is distributed to
the papillae. On this account, since the time of Galen, the lingual branch of the fifth
pair, or the lingual nerve, as it is called, has been regarded as the gustatory nerve ;
though it would seem more natural to admit, with Boerhaave, that the hypoglossal nerve,
which is distributed exclusively to the tongue, should, as it were, preside over the spe-
cial sense situated in this organ. But the lingual nerve is found to enter the tongue at
its corresponding border, and to spread out into branches which pass vertically upward,
and are exclusively distributed to the papillary membrane of the anterior, or free portion
of the tongue.
The ninth or hypoglossal nerve of each side runs from behind forward, between the ge-
nio-glossus and stylo-glossus muscles, and communicates with the lingual nerve, so as
to form the lingual plexus. It is not certain that some of the filaments of the hypoglos-
* If the epidennic tubes, which are so remarkably distinct on the foot of the bear, be removed from the pa-
pillae, the latter, when exposed, exactly resemble those of the tongue.]
t " Hanc fabricam a Malpighio inventam, et a Bellino libenter acceptam, scriptores anatomicorum, et phys-
iologicorum operum iconibus etiam pictis expresserunt." — {Haller, t. v., lib. xiii., p. 107.)
t [The pigment in these cases, and the lingual rete mucosum also, are the lowermost layers of the ectra
vascular squamous epithelium.]
THE NOSE» 641
sal nerve do not reach the papillae ; but there is no doubt but that almost all of them are
lost in the intrinsic muscles of the tongue.
The right and left glosso-pharyngeal nerves supply the base of the tongue, and are ex-
clusively distributed to the mucous membrane covering that part. No filament of the
glosso-pharyngeal nerve is intended for the muscular fibres ; and it is a remarkable fact,
that in one case in which the facial nerve sent a branch to the tongue supplementary to
the glosso-pharyngejd, that branch was distributed precisely in the same manner as the
glosso-pharyngeal itself; that is, it was exclusively distributed to the mucous membrane
at the base of the tongue. From what is stated above, then, it is anatomically shown
that the lingual branch of the fifth nerve and the glosso-pharyngeal nerve are the specijil
nerves of the tongue.*
The following case is no less demonstrative of the same fact ; Anf individual had com-
plete paralysis of the right half of the tongue. That side of the tongue became atrophied,
and had scarcely one third of its natural thickness. Both its tactile and gustative sen-
sibiUty were equally acute on the two sides of the organ. After the death of the person
thus afflicted, an acephalo-cyst was found in the right posterior condyloid foramen, which
had caused a complete atrophy of the right hypoglossal nerve. The corresponding half
of the tongue had undergone the fatty degeneration.
The Organ of Smell.
The organ of smell is situated in a cavity formed within the bones of the face, as, in-
deed, are most of the other senses ; it is placed at the entrance of the respiratory pas-
sages, and above the organ of taste, with which it has many points of relation. Although
situated in the median line, it is a double organ. It consists of an external apparatus,
which serves to protect the organ, to keep it in the necessary state of moisture for the
proper exercise of its functions, and to direct the air towards that part of it which is en-
dowed with the greatest olfactory sensibility : this is the nose, properly so called.
And, secondly, of two complicated and winding cavities, the nasal fossa, lined by a
mucous membrane, cedled the pituitary membrane, which is the essential seat of the sense
of smell.
The J^ose.
The nose resembles in form a three-sided pyramid, directed vertically, and projecting
from the middle of the face, so that the olfactory organ is the most anterior of all the or-
gans of the special senses.
Its numerous varieties in shape and size fall under the consideration of painters rather
than anatomists ; for these varieties have greater effect upon the physiognomy than upon
the exercise of its functions.
On each side of the nose, at its lower part, is observed a semicircular furrow, having
its concavity directed downward, and forming the upper border of the alse nasi ; from
this furrow, on either side, the naso-labial furrow of the semeiologists commences. The
lateral surfaces of the nose form, by their union, the dorsum, which is either straight,
convex, or concave, according to the subject ; differences which, in a great measure,
determine the national or individual forms of this part of the face. The term lobe of the
nose is applied to the rounded eminence in which the dorsum nasi terminates below.
The summit, or root of the nose, is separated from the nasal protuberance by a trans-
verse furrow. The base of the nose presents two elliptical or semilunar orifices, called
the nostrils (jiares) : the long diameters of these two orifices are directed horizontally
backward and outward, and they are separated from each other by an antero-posterior
septum ; they are provided with stiff" hairs, or vibrissce, which serve to arrest any small
particles floating in the air.t
The direction of the nostrils is a proof that the erect position is natural to man ; for,
if he were to assume the attitude of a quadruped, only the dorsum of the nose would be
directed towards odoriferous bodies. The situation of the nostrils above the orifice of
the mouth explains how no ^llimentary substance can be introduced into that cavity
without having been previously examined by the sense of smell.
The nose consists of a skeleton or basis, and of certain muscles ; it is covered by the
skin externally, and by a mucous membrane internally ; and it receives both vessels and
nerves.
The Structure of the Nose.
The basis or framework of the nose is composed of bone, cartilage, and fibrous tissue.
* [The result of the vast number of experiments and observations made upon this subject, by persons of op-
posite opinions, would appear to be, that the lingual nerve (a branch of the fifth), and the lingual portion of
the glosso-pharyngeal nerves, are both of them gustatory nerves, and also nerves of ordinary sensibility to the
tongue. The portion of the palate and fauces endowed with the sense of taste derives its power from the pal-
atine nerves, which are given off from a gangUon (Meckel's) connected with the second division of the fifth
nerve.]
t This use of the vibrissse becomes very evident in serious diseases ; when, in consequence of the humed
respiration, dry particles floating in the air become attached like a fine powder to these hairs. The coUectioo
of particles of dust around the nostrils often warns the practitioner of the serious nature of a disease
4M
642 NEUROLOGY.
The osseous portion occupies the upper part of the organ, and consists of the proper
nasal bones, and of the ciscending processes of the superior maxillary bones.
The cartilaginous part consists of the two lateral cartilages of the nose, to which we may
add the cartilage of the septum, although it rather forms part of the nasal fossae than of
the nose properly so called ; and, secondly, of the two alar cartilages, or cartilages of the
nostrils, making five in all. To this we must add certain cartilaginous nod^iles, situated
between the lower part of the cartilages of the alae and that of the septum. Santorini
described eleven cartilages in the nose, doubtless because he reckoned certain cartila-
ginous nodules, which are sometimes accidentally developed in the substance of the
fibrous tissue.*
The fibrous portion of the nose consists of a fibrous layer, which occupies the interval
between the lateral 'cartilages of the nose and the cartilages of the alae.
From this structure, it follows that the nose is inflexible above, flexible in the middle,
and extremely movable below. This arrangement has the threefold advantage of pro-
viding against fractures of the most prominent part of the nose, of permitting the dilata-
tion of the nostrils, and, lastly, in consequence of the solidity of the highest and narrow-
est part of the n2isal fossae, of ensuring a free passage to the air.
The lateral cartilages of the nose (a a, fig. 231) are of a triangular form ; and they are
Fig. 231. united together along their anterior margins, which are thick above, so
as to form a sharp ridge, which constitutes the dorsum of the nose.
Along the line of union there is a sort of furrow or groove, which can
be felt even through the skin. By their upper and posterior margins,
they are articulated with the nasal bones ; I say articulated, because
there is no continuity of substance, but the parts are connected by
fibrous tissue, which allows a considerable degree of motion. Their
lower margins are convex, and correspond in front to the cartilages of
the alae of the nose, and behind to the fibrous tissue which occupies the
intervals between the cartilages. The lateral cartilages are intimately
united with the cartilage of the septum, along the dorsum of the nose ;
so that we might regard these three pieces as forming a single cartilage.
The thickest part of each lateral cartilage is above and in front.
The cartilages of the nostrils are generally called, after Bichat, the filro-cartilages of
the alcR of the nose ; but we have already seen that some of the fibro-cartilages of Bichat
are thin layers of ordinary cartilage, while others consist merely of condensed fibrous
tissue. The so-called fibro-cartilages of the nostrils belong to the former kind. There
is but a single cartilage on each side {b b,fig. 231) for the ala nasi, the lobe, and the in-
ferior portion of the septum ; it consists of an irregular lamina folded upon itself into a
semi-ellipse or parabola, opening behind. We shall examine its external and internal
portions.
The external portion (b) is extremely thin, and corresponds to the ala of the nose ; it is
not situated in the substance of the ala, but is placed above it, so that its lower margin
corresponds to the curved furrow which forms the upper boundary of the ala.t
The internal portion (b,fig. 232) is thicker than the external, and is situated upon a
lower plane than it : it corresponds, on the inside, to the internal portion of the cartilage
of the opposite side, from which it is separated above by the cartilage of the septum.
The internal portions of the two alar cartilages are separated from each other by some
rather loose cellular tissue, which allows them to move upon each other, and also per-
mits the cartilage of the septum to extend between them, without interfering with them
at all. The internal portions of the cartilages of the alae do not reach the anterior nasal
spine, but terminate abruptly at a certain distance from it, by forming a projection, which
is very distinct, especially in some individuals, and which sensibly elevates the mucous
membrane at the entrance of the nostrils. At the point of union between the internal
and external portions of each alar cartilage, that is to say, at the summit of the parabola,
the cartilage itself becomes wider and excavated behind, and assists in forming the lobe
of the nose. The margins of these cartilages are irregularly notched or scolloped. The
upper margins are united to the other cartilages by means of a fibrous tissue, which al-
lows them to move frgely, both upon the cartilage of the septum and upon the lateral
cartilages of the nose.
A small cartilaginous nodule is found on either side, between the lobe of the nose and
the cartilage of the septum ; the only use of these nodules is to facilitate the movements
of the lobe upon the septum.
The cartilage of the septum nasi (c,fig. 232) occupies the triangular interval between
the perpendicular plate of the ethmoid bone and the vomer. It consists of two parts :
one, wide and free, which is that generally described ; the other, which is narrow, and
may be called the caudal prolongation of the cartilage, is received into the bony portion
• of the septum, between the two lamellae of the vomer
* See note, infra.
t [Two or three cartilaginous nodules (e e,fig. 231) are generally found appended in a curved line to the
posterior extremity of this portion of the cartilage of the ala.l
THE PITUITARY MEMBRANE. 643
The fret portion of the cartilage is thick and triangular ; it has
the same direction as the bony septum, and presents two lateral
surfaces, covered by the pituitary membrane ; an anterior margin,
of which the upper half (c, fg. 231) is blended with the lateral
cartilages along the dorsum of the nose, while its lower half is
free, convex, directed downward, and received between the two
cartilages of the nostrils ; a superior and posterir margin, which is
extremely thick and rough, and is intimately united to the corre-
sponding margin of the perpendicular plate of the ethmoid bone
(e, Jig. 232) : the mode in which this union is effected is not by
articulation, but by a continuity of tissue, like that between the
costal cartilages and the ribs ; lastly, an inferior margin, which is
received between the two plates of the vomer (»). The groove
into which it is received is very deep ; and as the two plates of
the vomer become more and more separated in extending forward, so does the corre-
sponding margin of the cartileige increase in thickness ; hence the lower extremity of
the septum frequently projects considerably into one or other of the nostrils.
The caudal prolongation of the cartilage of the septum may be seen by carefully exani
ining the retreating angle formed by the perpendicular plate of the ethmoid and the vo-
mer ; in which situation the cartilage of the septum gives off a considerable prolonga-
tion, in the form of a band, which occupies the interval between the two plates of the
vomer, and is attached to the rostrum of the sphenoid bone. This cartilaginous band is
contained entirely within the substance of the middle portion of the bony septum : its
upper margin is thin, and, as it were, toothed ; the lower margin is thick and rounded.
The two naso-palatine nerves are situated in the same canal as the cartilage, and are
placed one on each side of it.
The muscles of the nose are the pyTamid2ilis nasi, the levator labii superioris alaeque
nasi, and the transversalis nasi, or compressor narium, which we have described as a
dependance of the depressor alae nasi, or rayrtiformis : an accurate description of these
muscles is still to be desired.
The skin covering the nasal bones and the lateral cartilages of the nose has no par-
ticular character : it is thin and movable. That which covers the alae and the lobe of
the nose is very thick and extremely dense ; it crepitates under the knife, to such a de-
gree, that cartilages have been supposed to exist in the substance of the alae. We have
seen, however, that the cartilages of the nostrils are not prolonged into the alae, which
are composed essentially of the dense integument just described, and which is reflected
inward upon itself around the margins of the nostrils.
I should remark, that the antero-posterior diameter of the opening of each nostril is
much less than that of the corresponding cartilage ; this depends upon the fact that the
skin is prolonged anteriorly, and is reflected for some lines below and behind the lower
margin of the cartilage.
The skin of the nose is remarkable for the great development of its sebaceous follicles.
The orifices of these follicles are shown in many individuals by certain black points,
which are nothing more than the sebaceous matter discoloured. When forced out of
the follicles by lateral pressure, the masses of sebaceous matter resemble in form small
worms.
The skin, which is reflected upon itself around the margins of the nostrils, preserves
the character of integument as far as where it is provided with hairs, and then suddenly
assumes the characters of mucous membranes.
The Pituitary Membrane.
The pituitary or Schneiderian* membrane, the immediate seat of smell, is a fibro-mucous
membrane, which lines the whole extent of the nasal fossae, and is prolonged, with some
modifications of texture, into the different cells and sinuses which open into those fossae.
When covered with this membrane, the nasal fossae present a configuration differing
in many respects from that which they have in the skeleton. Many of the foramina and
canals are closed, and several are contracted in their dimensions. The irregularities
of the surface of the turbinated bones are, in some measure, concealed. Besides this,
the mucous membrane, where it is reflected upon itself, forms a number of folds, some
of which prolong the turns of the turbinated bones ; while others, more or less, contract
the orifices of communication between the various cells and sinuses and the nasal fossae.
The pituitary membrane, originating, then, on the one hand, from the skin, which is
reflected at the margins of the nares, and provided with hairs {h,Jig. 233), is, on the other
hand, continuous, without any line of demarcation, with the mucous membranes of the
pharynx and velum palati (at t s), of the Eustachian tubes (at m), and of the nasal ducts
(at r). In the roof of each nasal fossa {u v) it closes the foramina of the cribriform plate
* Conrad Victor Schneider (de Caiarrho) gave his name to this membrane, because he was the first to refute
•nccessfuUy the erroneous notion of the ancients, that the secretion of the nasal fossae descended from llie ven
tricles of the brain ; the common term cold in the head still remains as a vestig-e of this error
644
NEUROLOGY.
Fig. 233.
of the ethmoid bone, and those of the nasal bones, so that all the vessels and nerves
which pass through these foramina enter the mucous membrane by its external surface ;
before it enters into the sphenoidal sinus, it forms a fold around the orifice of that sinus,
by which the opening is narrowed, so as to have the form of a vertical fissure (see the
bristle marked d).
Upon the external wall of each nasal fossa (see Jig. 233)* it covers a great number of
parts, counting from below upward, viz., the
inferior meatus, at the upper and anterior part
of which it meets with the lower orifice of
the nasal duct {r,figs. 233, 234) ; around this
opening it forms a semilunar valvular fold,
the free margin of which is directed down-
ward, and which prolongs the canal of the
ducts to a greater or less distance in differ-
ent subjects ; in passing a probe into the na-
sal duct from the inferior meatus, this valve
must, almost of necessity, be torn.
From the inferior meatus the pituitary
ttiembrane is reflected upon the inferior tux'
hinated bone (c c,figs. 233, 234), which appears
longer in the recent state, in consequence
of a fold of the mucous membrane being con-
tkiued in front, and another still more marked behind the bone : this is the thickest part
of the nasal mucous membrane.
In the middle meatus (t) the pituitary membrane covers the infundibulum, at tlie lower
extremity of which is an ampulla or dilatation, where the orifice of the maxillary sinus is
generally found. This orifice (see bristle a, fig. 234) has a very different appearance
from that which it presents in the dried scull : it is extremely narrow, scarcely admit-
ting the blunt end of a common probe. It sometimes appears as if it were wanting ;
but it will then be found opposite the middle of the infundibulum ; in this case, the max-
illary sinus might be said to communicate directly with the frontal sinus. Not unfre-
quently the maxillary sinus opens both into the middle meatus and the infundibulum
The pituitary membrane is prolonged from the infundibulum into the anterior ethmoidal
cells (c e, fig. 234), and into the frontal and maxillary (m m) sinuses. If we remove the
middle turbinated bone, we find a considerable projection, which bounds the infundibu-
lum above (n, fig. 233), and corresponds to a large ethmoidal cell. Upon, the back part
of this projection, on which the middle turbinated bone is moulded, an opening (see bris-
tle) is often found leading into this great cell, and on its fore part (at e), one or more or-
ifices leading into the anterior and superior ethmoidal cells.
From the middle turbinated bone {b, figs. 233, 234), which is continued backward hy
a fold of the membrane, the pituitary membrane
passes into the superior meatus, where I have fre-
quently met with four or five openings leading into
as many of the posterior ethmoidal cells, which, in
this case, did not communicate with each other : I
have even seen the orifice of an ethmoidal cell upon
the superior turbinated bone (a).
The pituitary membrane dips into all the etlimoid-
al cells, and into the frontal sinuses, either directly
or indirectly, but it does not enter the spheno-pala-
tine foramen, which, on the contrary, is completely
closed by it.
Upon the septum the pituitary membrane is remark-
able for its thickness, being exceeded in this respect
only by the membrane covering the inferior turbinated bone. We do not find in man
that prolongation or cul-de-sac, which is so very distinct in some animals, in front of
the lower border of the septum ; but at this point the pituitary membrane closes the
two superior orifices of the anterior palatine canal.
Structure. — The pituitary membrane is a mucous membrane, and its peculiarity con-
sists in its being extended over osseous and cartilaginous surfaces. Its free surface is
smooth, red, and scattered over with foramina, from which a great quantity of mucus
maybe expressed. + Its adherent surface is intimately united to the periosteum and
perichondrium of the bones and cartilages of the nasal fossee, so that it is classed among
the fibro-mucous membranes.
* [In this figure, portions of the middle and inferior conchse are represented as cut away, to show the parts
m the middle and inferior meatuses.]
t [In the nasal fossa; the epithelium of the pituitary membrane is columnar and ciliated ; in the sinuses it
approaches the squamous in character, but yet it is provided with cilia, the movements of which have been
obserTed in the lower animals to produce currents towards the openings of the respective sinuses.]
Fig. 234.
THE ORGANS OF SIGHT. 645
The pituitary membrane is generally thicker than the other mucous membranes, so
that it is very easy to determine the highly vascular and truly erectile structure of this
membrane. If it be punctured, and the tube of a mercurial injecting apparatus intro-
duced, the mercury w^ill immediately enter the cells of the erectile tissue, and from
thence pass into the veins arising from those cells. If a more superficial puncture be
made, a lymphatic network will be injected, situated so superficially, that the mercury
exhibits all its metallic lustre. This lymphatic network has no communication with the
venous cells just mentioned.*
This lymphatic network, which is common to all the mucous membranes, gives to the
non-vascular layer by which they are covered the appearance of a serous membrane.
The pituitary membrane receives a great number of arteries, which penetrate it by sev-
eral points, and which are almost all derived from the same source, viz., the internal
maxillary artery ; as, for example, the spheno-palatine, the infra-orbital, the superior al-
veolar, the palatine, and the pterygo-palatine. Some arise from the ophthalmic arterj',
viz., the supra-orbital and the ethmoidal ; and others from the facial artery, viz., the dor-
salis nasi, the artery of the alae, and the artery of the septum.
The capillary veins are so numerous, that they in a great measure form the basis of
the pituitary membrane ; the larger veins which proceed from them follow the course of
the arteries, and enter, by very large trunks, into the internal maxillary, the facial, and
the ophthalmic veins. There are numerous communications between these last-named
veins and those of the ethmoidal region of the base of the cranium.
The spongy character of the internal surface of the nasal fossae, and more particularly
of the surface of the turbinated bones, is due to certain grooves and foramina intended
for the reception and transmission of bloodvessels.
I am only acquainted with the superficial lymphatic network already noticed. In order
to inject it, it is necessary to scratch the membrane with the injecting pipe.
Are there any glands or follicles in the pituitary membrane 1 Steno has described cer-
tain glands which I have not been able to find. The follicles in this membrane are rather
difficult to be shown.
Like all the organs of the special senses, the pituitary membrane is provided vdth a
special nerve, called the olfactory, the nerves of the two sides constituting the first pair
of cerebral nerves. Comparative anatomy shows that the development of the olfactory
nerves is in relation with the development of the sense of smell, and thus establishes, in
a most positive manner, the generally-received opinion regarding the function of this pair
of nerves. Without entering here into the description of the olfactory nerves, which
will be given hereafter, I would observe, that they pass through the foramina and canals
of the cribriform plate of the ethmoid bone, at the same time becoming enveloped in
fibrous sheaths ; that they enter the pituitary membrane by its external surface ; and
that they expand into a plexus in its substance. The branches of these nerves cannot
be traced lovi-er than the middle turbinated bones on the one hand, and the middle of the
septum on the other. Thus, while the upper and extremely narrow part of each nasal
fossa {s,fig. 234) is the essential seat of the sense of smell, the lower and much wider
part only gives passage to the air during the act of respiration.
Besides the special nerve of smell, the pituitary membrane receives other nervous fil-
aments, all of which are derived from branches of the fifth nerve, viz., from the internal
nasal and the frontal branches of the ophthalmic division of that nerve, and from the
spheno-palatine, the great palatine, the vidian, and the anterior dental branches of its
second or superior maxillary division. The experiments of modern physiologists have
shown that the integrity of these different branches of the fifth pair is necessary for the
perfect possession of the olfactory sense. This, however, is very different from saying
that the seat of that sense is in the branches of the fifth pair.
The membrane which lines the several sinuses, although it is continuous with the pi-
tuitary membrane, does not resemble it in character ; it is exceedingly thin and trans-
parent, and appears like a serous rather than a mucous membrane ; that it is a mucous
membrane, is satisfactorily established only by certain pathological f3,cts. The mucous
membrane of the sinuses has a very close resemblance to the conjunctiva.t
The Organs of Sight. .
The eyes, or the organs of sight, are situated at the highest part of the face, so that
they are enabled to explore objects at a distance.
They are two in number ; but they co-operate in their function so as to act like a sin-
gle organ. The result of this is, that vision is rendered more certain, and its field of
operation more extensive, at the same time that, from the unity of action of both eyes,
it is single.
The eyes are protected by the orbital cavities in which they are contained ; they are
covered by the eyelids, and these are surmounted by the eyebrows. They are surround-
ed by six muscles, by which they can be moved in all directions ; they are divided into
* It was in the pituitary membrane of the calf that, about ei jht vears ago, I first accidentally injected th*-
tuperficial lymphatic network. ' " t See note, p. 648.
646 NEUROLOGY.
the straight and the oblique muscles. There is also a secreting a{5paratus,tKeapparafti#
of the lachrymal passages, the secretion from which lubricates the anterior surface of the
ball of the eye, and facilitates the exercise of its functions.
The study of the organ of sight, therefore, is not limited to that of the eyes alone,
but includes that of the means of protection, viz., the orbital cavities (see Osteology),
the eyelids, and the eyebrows ; that of the muscles, or moving organs ; and that of the
lachrymal passages, or lubricating apparatus. These accessory parts, or appendages of
the organ of vision, have been collectively named by Haller the tutamina oculi. We shall
commence our description with them.
The Eyebrows.
The eyebrmjos are two arched ridges, which are covered with short stiff hairs, that are
directed from within outward, and overlap each other ; the eyebrows are situated at
the lower part of the forehead, and form the boundary of the upper eyelid. Their direc-
tion corresponds precisely with that of the orbital arch. The hairs upon them are more
numerous, and longer at the inner extremity, which is called the head, than at the outer,
which is denominated the tail of the eyebrow. The heads of the two eyebrows are sep-
arated from each other by an interval which corresponds to the root of the nose ; some-
times, however, they are blended together.
Structure. — The skin in which the hairs of the eyebrow are implanted is thick, and
very closely united beneath to a muscular layer formed by the frontalis, the orbicularis
palpebrarum, and the corrugator supercilii, the last-named muscle being situated beneath
the other two. The orbital and superciliary arches serve as a basis to support the eye-
brows ; the nerves of these parts are very numerous, and are derived from the facial and
the fifth nerves ; their vessels arise from the ophthalmic and temporal arteries.
Uses. — The eyebrows, which give a peculiar character to the human countenance, pro-
tect the eye, and, when depressed in front of it, intercept a great number of the rays of
light ; they assist in a remarkable degree in giving expression to the face.
The Eyelids.
The eyelids are two movable and protecting curtains, placed in front of the ball of each
eye, which they conceal or leave uncovered, according as they are in a state of approx-
imation or separation.
The eyelids are two in number — a superior and an inferior. In a great number of ani-
mals there is a third eyelid, of which merely a trace exists in man. The eyelids are
large enough to close the base of the orbit completely, and to intercept entirely the pas-
sage of light.
Each of the eyelids presents for our consideration a cutaneous surface, which is con-
vex, and marked with concentric semilunar folds that become effaced when the lids are
closed ; an ocular surface {fig. 235), which is concave, is accurately moulded upon the
ball of the eye, and presents a series of yellowish vertical lines, formed, as we shall see,
by the Meibomian glands ; an adherent border, which is indicated by the orbital arch in
the upper eyelid, but is less clearly defined in the lower lid, in which it is continuous
with the cheek ; lastly, a free border, or margin, which, in both eyelids, is straight when
the lids are closed, and curved when they are open : in the latter position they enclose
an elliptical space {rima palpebrarum), the dimensions of which vary in different persons,
and hence give rise to the expressions large eyes and small eyes, which have no refer-
ence to the actual size of the globe of the eye, but merely to the size of that part which
is exposed to view. The free margins of the eyelids are not cut obliquely from before
backward, so as to intercept, when they are closed, a three-sided interval or channel,
which is completed behind by the globe of the eye, and which is supposed to become
larger from without inward, in order to conduct the tears towards the larchrymal punc-
ta. On the contrary, these margins are cut horizontally from before backward (see sec-
tion,^^. 240) ; and when approximated, they leave a narrow fissure between them, which
may serve as a channel for the tears during sleep, quite as well as the three-sided canal
which is generally supposed to exist.
The margins of the eyelids, moreover, are tolerably thick, and are ftirnished at their
anterior hp with three or four rows of hard, stiff, and curved hairs, which are more nu-
merous and longer on the upper than on the lower eyelid, and at the middle than at either
end of each : these are the eyelashes. Their direction is worthy of notice : in the upper
eyelid they are at first directed downward, and are then curved upward, so as to de-
scribe an arc having its concavity turned upward ; the eyelashes of the lower lid have
just the opposite arrangement. From this it follows, that the convexities of the eye-
lashes of the two lids are turned towards each other ; and thus, when the eye is shut,
they touch each other without being able to interlace. Serious inconvenience is pro-
duced when the eyelashes deviate from their proper course, and are turned inward ;
When the eyelashes are wanting, the free margins of the lids are attacked with chronic
inflammation. Along the posterior lip of the free margin of each eyelid, or, rather, along
the angular ridge formed by the union of that margin with the posterior surface of the
THE EYELIDS. Q47
lid, are placed a very regular series of foramina {figs. 235, 236), from which the sebace
ous matter secreted by the Meibomian glands may be expressed in masses having the
form of small worms.
At the junction of the external five sixths with the internal sixth of the free margins
of the two eyelids are found two very remarkable tubercles, the lachrymal papillcB or tu-
bercles {a,fi^. 239 ; also seen in/^«. 235, 236), each of which is perforated by an open-
ing, visible to the naked eye ; these openings are the puncta lachrymalia, the orifices
of the corresponding lachrymal canals. That part of the free margin of each eyelid
which is on the inner side of the corresponding lachrymal papilla is straight, rounded,
and destitute of hairs or follicular orifices : in the space enclosed between this part of
the eyelids, and called lacv^ lachrytnalis, is situated the caruncula lachrymalis (*, fig. 239).
The upper eyelid, moreover, is twice as deep as the lower ; so that, when depressed,
it descends below the transverse diameter, or equator of the eye, to use an expression
invented by Haller. •
The terms angles of the eye, or commissures of the eyelids, are applied to the angles
formed by the junction of the extremities of the free margins of the eyelids. The ex-
ternal angle, external or temporal commissure (b, fig. 239), is also named the little angle
(canthus minor).*
The internal angle, internal or nasal commissure (e), improperly cedled the great angle
of the eye {canthus major), corresponds to the posterior border of the ascending process ol
the superior maxillary bone.
Structure of the Eyelids. — ^The constituent parts of the eyelids are, the tarsal cartilages,
a fibrous membrane, a muscular layer, two integumentary layers, one mucous and the
other cutaneous, and certain follicles, with vessels, nerves, and cellular tissue.
The tarsal cartilages, which resemble in their use the cylinders of wood attached to
the bottom of a map or diagram, to prevent it from hanging in folds, are two in number,
one for each eyelid ; they are cartilaginous plates, situated within the free margin and
the contiguous portion of the lids. The tarsal cartilage of the upper eyelid (a, figs. 235,
236) is semilunar ; that of the lower eyelid {h) has the form of a small, narrow band ;
neither of them occupies the entire length of the corresponding lid. Their anterior sur-
face is convex, and is covered by the fibres of the orbicularis palpebrarum muscle. Their
posterior surface {fig. 235) corresponds to the conjunctiva, and is closely adherent to it.
The Meibomian glands are situated between the conjunctiva and the cartilage, or, rath-
er, in the substance of the cartilage.
The adherent border of each tarsal cartilage is thin, and affords attachment to the
fibrous membrane of the lids ; the adherent border of the cartilage of the upper eyelid,
which is convex, also gives attachment to the levator palpebrae superioris muscle. The
free margins of these cartilages are their thickest parts, and occasion the thickness of
the free margins of the eyelids, t
The cutaneous layer is remarkable for its excessive tenuity and semi-transparency :
the eyelashes are appendages of this part of the integument.
The cellular layer is no less remarkable for the absence of fat than for its extreme
delicacy : it is the type, indeed, of serous cellular tissue, and is frequently the seat of
serous infiltrations.
The muscular layer is formed by the palpebral portion of the, orbicularis muscle, the
pale colour of which, as I have already noticed, contrasts with the dark-red hue of the
orbital portion of the same muscle. Besides this, the upper eyelid has an extrinsic mus-
cle, the levator palpebrce superioris {a, fig. 237), the tendon of which, however, is alone
concerned in the formation of that eyelid, by being attached to the upper border of the
corresponding tarsal cartilage.
The fibrous layer consists of a fibrous membrane, which arises from the margin of the
orbit, and is attached to the corresponding borders of the tarsal cartilages. This mem-
brane is very strong and unyielding in the outer half of the base of the orbit, but dimin-
ishes in thickness towards the inner half of that base, especially on the inner portion of
the upper eyelid, where it degenerates into cellular tissue.
The term ligament of the external canthus might be applied to a fibrous raphe, which
extends horizontally from that angle to the base of the orbit. This raphe bifurcates op-
posite the outer canthus, so as to become attached to the outer end of each tarsal car-
tilage, and it exactly corresponds to the tendon of the orbicularis palpebrarum, which is
situated at the inner canthus, and which is also bifurcated, to join the inner ends of the
same cartilages.
(hi cutting through this raphe, some very strong fibrous bundles are exposed, which
arise from the external wall of the orbit, and spread out into the substance of the upper
eyelid.
* The external commissure does not correspond to the outer extremity of the transverse diameter of th*
base of the orbit, but is situated about three lines nearer to the nose ; hence the necessity of dividing this
commissure in extirpation of the eye.
t [The substance of the tarsal cartilages differs from that of ordinary cartilage in being more opaque, and
also in having a few microscopic filaments scattered through it ; in this respect approaching in character to
fibro-cartilage.]
648 NEUROLOGY.
The expanded tendon of the levator palpebrae superioris, which is subjacent to the
fibrous layer, completes the fibrous structure of the upper eyelid. The tarsal cartilages
and the fibrous layer are situated upon the same plane.
The mucous layer, or palpebral conjunctiva, consists of a membrane which lines the
posterior surface {fig. 235) of the eyelids, and is, moreover, extended over the globe of
tig. 235. the eye. This membrane is called the conjunctiva, or tunica
adnata, because it connects the eyelids with the ball of the eye.
In order to facilitate our description, we shall suppose it to
commence at the free margin of the upper eyelid (a', fig. 240),
where it is continuous with the skin : having covered the whole
thickness of this margin, it then lines the posterior surface of
the tarsal cartilage (c'), to which it is intimately adherent, and
continues in the same direction as far as beneath the orbital
arch. At this point it is refldfcted upon the anterior surface of
the globe of the eye, so as to form a cul-de-sac between that organ and the eyelid : upon
the eyeball, where it is called the ocular conjunctiva, it adheres to the sclerotic coat by
means of cellular tissue, which is at first loose, but gradually becomes closer and closer as
it approaches the transparent cornea. Upon the cornea (d') its adhesion is so intimate
that some anatomists have denied its existence in that situation. In fact, it can only be
anatomically demonstrated in the healthy state upon the margin of the cornea, but its ex-
istence over the whole of that part of the eye is shown in some diseases. After having
covered the anterior and inferior part of the sclerotic (c"), the conjunctiva is reflected
upon the posterior surface of the lower eyelid (b'), lines its tarsal cartilage, covers its
free margin, and then becomes continuous with the skin. On the inner side of the ball
of the eye the conjunctiva forms a small semilunar fold, the plica semilunaris (e, figs.
235, 239), which has its concavity turned outward, and which may be regarded as the
vestige of the third eyelid found in animals : it is misnamed the membrana nictitans (la
membrane clignotante). On the outer side, the conjunctiva dips between the eyelids
and the ball of the eye, and forms a deep cul-de-sac. Opposite the lachrymal papillae
the conjunctiva passes into the puncta, and Hues the lachrymal passages.
From what has been stated above, it will be seen that the conjunctiva would form a
shut sac, like the serous membranes, if the eyelids were supposed to be united. Like
the serous membranes, it covers two surfaces that rub one upon the other. Its tenuity,
its transparency, and the filamentous adhesions which are sometimes observed between
its contiguous surfaces, have induced some anatomists to place this membrane among
the serous rather than the mucous membranes ; but its continuity with the skin, its ex-
treme vascularity, and its uses, which require it to be in contact with the air, prove that
it should be retained among the latter class of membranes.*
The glands found in the eyelids consist of an appendage of the lachrymal gland, which
will be described with it, of the Meibomian glands, and of the caruncula lachrymalis.
The Meibomian glands (m m, fig. 236) are situated upon the posterior surface of both
Fig. 236. eyelids, opposite the tarsal cartilages ; they resemble yellowish
vertical and parallel lines, sometimes straight and sometimes
curved ; their length is proportioned to the depth of the cartilages,
and they never project upon the inner surface of the eyelids. Each
of these lines, of which there are from thirty to forty in each eye-
lid, consists of a tortuous canal, folded upon itself a great number
of times, and having a considerable number of small follicles open-
ing into it on each side. All these canals open very regularly upon
the posterior lip of the free margin of the lid by a row of orifices
arranged in a single line. I have never seen two rows of openings, as Zinn states he
has observed. If the eyelids be compressed over the tarsal cartilages by a pair of pin-
cers, masses of a waxy substance exude from these orifices, having the form of small
worms twisted frequently upon themselves. Sometimes these small linear canals com-
municate with each other opposite the adherent border of the tarsal cartilage ; at other
times they bifurcate. It is the waxy sercetion from the Meibomian glands which pre-
vents the tears from trickling in front of the eyehds. These glands are lodged in the
deep grooves in the tarsal cartilages ; they are, therefore, as visible upon the external
as the internal surface of the cartilages.
The Meibomian glands belong to the class of sebaceous follicles, and form a transition,
as it were, from follicles to glands.
The caruncula lachrymalis {c,fig. 235,* fig. 239) consists of a small, oblong group of
follicles, situated at the inner angle of the eyelids, and on the inner side of that semilu-
nar fold of the conjunctiva, which we have spoken of as the trace of a third eyelid. It
is about the size of a grain of wheat. It is interposed between the free margins of
* The absence of villi has been stated as characteristic of the conjunctiva ; but villi or papillae are found
■pon that portion which lines the superior tarsal cartilage.
[The epithelium of the conjunctiva is squamous, and consists of several layers : according to Henl6, it i*
ciliated upon the inner surface of the eyelid ; but cilia have not been observed upon the eyeball.]
THE MUSCLES OF THE EYE. 6^
tiie eyelids, in that part of those margins which extends between the lachrymal tuber-
cles and the internal commissure ; but it is upon a plane posterior to these margins, so
that it does not prevent their mutual contact. It is covered by a fold of the conjunctiva,
which gives it a reddish aspect ; it presents a great number of openings, through which
a waxy secretion exudes, and projecting from it are several small hairs, which may be-
come so long as to produce ophthalmia. The caruncula lachrymalis is composed of se-
baceous follicular glands, of the same nature as the Meibomian glands. It was for a
long time considered to be a second lachrymal gland. In order to obtain a good view
of the orifices, and of the light-coloured and sometimes very numerous hairs of the carun-
cula lachrymalis, that body should be covered with ink or a solution of carmine, and
then examined with a lens.
Vessels and. Nerves of the Eyelids. — The arteries are the internal and external palpe-
bral branches of the ophthalmic, and the palpebral branches of the temporal, infra-orbital,
and facial arteries. I have already said that the palpebral arteries form two arches, one
for each eyelid.
The veins have the same name, follow the same direction, and open into the corre-
sponding venous trunks.
The nerves are derived from two sources, viz., the facial and the fifth nerve.
Uses. — The eyelids protect the eye from the action of light and air, and of any parti-
cles floating in the latter ; by a sweeping movement, they clean the surface of the or-
gan, over which they also spread the lachrymal fluid, which serves as a protection to the
eyeball against the action of the air. The eyelids, from their capability of being inter-
posed between the eye and external objects, place the exercise of vision under the con-
trol of the will.
The Muscles of the Eye, and the Levator Palpebrce Superioris.
The muscles of the eye are six in number, and are distinguished into the straight and
the oblique. There are four straight and two oblique muscles. With these we shall
also describe the levator palpebrae superioris.
Dissection. — Remove the roof of the orbit by two cuts with the saw, meeting each oth-
er at an acute angle opposite the optic foramen ; be careful that the inner cut does not
injure the cartilaginous pulley of the superior oblique muscle. Dissect the origins of
these several muscles from the deepest part of the orbit with the greatest care. They
are arranged completely round the optic nerve (o, figs. 237, 238) and the motor oculi
nerves. Those which arise above the optic nerve are attached to the dura mater and
periosteum, but not to the bone ; but those which arise below the nerve adhere more
closely to the bone. The inferior or small oblique muscle is the only one which does
not arise from the bottom of the orbital cavity.
The Levator Palpehra Superioris.
The levator paipebra superioris (a, figs. 237, 238), much thinner and narrower than the
rectus superior, which is subjacent to it, arises from ^^ 237.
the bottom of the orbit, at the upper part of the mar-
gin of the optic foramen, or, rather, from the fibrous
sheath given oflT from the dura mater around the op-
tic nerve. It arises by short and radiated tendinous
fibres, to which the fleshy fibres succeed, in the form
of a thin, flat muscle, that passes outward in a line
parallel with the axis of the orbit, is reflected upon
the globe of the eye, and ends in an aponeirrotic ex-
pansion, which is inserted in the upper border of the
tarsal cartilage of the upper eyelid
Relations. — It is covered by the periosteum of the
roof of the orbit, it is covered obliquely at its origin
by the ophthalmic nerve, and it covers the superior rectus muscle.
Action. — ^This muscle raises the upper eyelid, and draws it backward, so that the up-
per border of the eyelid is concealed under the orbital arch.
The Rectus Superior, or Levator Oculi.
The superior rectus (5) has two very distinct origins. The first resembles that of the
levator palpebrae superioris in being from the upper part of the fibrous sheath of the optic
nerve, but it is on a lower plane than that muscle ; the second is from the inner margin
of the sphenoidal fissure, i. e., between that fissure and the optic foramen. The latter
origin, which is continuous with those of the external rectus, appears to take place from
the sheath furnished by the dura mater to the third cranial or motor oculi nerve.
The fleshy fibres arising from this radiated tendon form a flat bundle, which passes for-
ward and outward in the direction of the axis of the orbit, and is reflected upon the eye-
ball, where it becomes converted into a broad and thin aponeurosis, and is inserted into
the sclerotic coat, at a short distance from the cornea.
This muscle, like all the other recti, is in relation with the periosteum of the orbit,
4N
«iv
650 NEUROLOGY.
from which it is separated towards the inner side by the levator palpebrae superioris ; it
covers the optic nerve and the eyeball.
The Rectus Inferior, or Depressor Oculi.
The inferior rectus (c) arises, together with the internal and external recti, by a common
tendon, called the tendon or ligament of Zinn, which is attached to the lower half of the
optic foramen, and more particularly to a depression which is seen to the inner side of
the sphenoidal fissure. Almost immediately after its commencement this tendon divides
into three branches, from the middle one of which the inferior rectus muscle arises, and
then passing horizontally forward and outward, is reflected upon the globe of the eye,
and terminates in a similar manner to the preceding muscle.
The Rectus Internus, or Adductor Oculi.
The internal rectus {d) has two very distinct origins : one from the tendon of Zinn, the
other from the inner side of the fibrous sheath of the optic nerve ; the latter origin is
contmuous with those of the superior rectus. From these points it passes forward along
the internal wall of the orbit, is reflected upon the globe of the eye, and terminates like
the preceding muscles.
The Rectus Externus, or Abductor Oculi.
The external rectus (e) also has a double origin : one inferior, derived from the liga-
ment of Zinn ; the other superior, from the fibrous sheath of the sixth cranial or abdu-
cens oculi nerve, and continuous with the external origin of the superior rectus. A
fibrous arch, under which certain veins pass, unites these two origins, and also serves
as a point of attachment to the muscular fibres. From these points the muscle passes
obhquely forward and outward along the external wall of the orbit, is reflected upon the
eyebaU, and terminates like the other recti muscles.
General Description and Action of the Recti Muscles.
The four straight muscles of the eye arise from the bottom of the orbit, and terminate
upon the eyeball, a few lines from the cornea.
They all have the same form, viz., that of a long isosceles triangle, having its base
turned forward and its apex backward. Their relations are also similar : tlius, they cor-
respond, on the one hand, to the periosteum of the orbit, and on the other to the optic
nerve and the globe of the eye, from which they are separated by some fat and vessels.
In consequence of their being inserted in front of the transverse diameter of the eye,
they are all reflected upon the eyeball ; this fact is rendered much more evident when
the eye is drawn in an opposite direction to that in which the particular muscle under
examination would act. Their tendons are surrounded with a whitish, and, as it were.,
elastic cellular tissue, by which the movements of these muscles are facilitated.*
The recti differ from each other, both in length and thickness. Thus, the internal
rectus is the shortest and thickest, the external rectus is the longest, and the superior
rectus is the smallest.
Action. — If these muscles were not reflected upon the globe of the eye, their action
would be simply to draw it forcibly backward towards the bottom of the orbit ; but, in
consequence of this reflection, they can give it a rotatory motion. Thus, the superior
and inferior recti rotate the eyeball upon its transverse axis, while the internal and ex-
ternal recti rotate it upon its vertical axis. After either of these effects is produced, the
eye is then drawn backward. The direct movement backward is produced by the si-
multaneous contraction of the four muscles.
When any two adjacent recti act together, the eye is moved in the diagonal of the two
forces exerted by those muscles ; and hence the eye, and therefore the pupil, can pass
over all the radii of the circle represented by the base of the orbit ; this arrangement is
not only highly favourable to the exploratory power of the eye, but also assists in placing
the function of vision under the control of the will, since it enables us to turn away the
eyes from any offensive object. The straight muscles of the eye, as well as the oblique
muscles, also aid in expressing the passions ; and hence the following names have been
given to them by the ancients. The superior rectus is called superbus (mirator, Haller) ;
the inferior rectus, humilis ; the external rectus, indignatorius ; the internal rectus, amor
torius seu bibitorius.
Lastly, it has been supposed that the muscles of the eye, by compressing that organ,
can alter the distance between the retina and the crystalline lens ; and a theory to ex-
plain the power we possess of adapting the eye for distinct vision at different distances
has even been constructed on the supposed possibility of this compression.
The necessarily simultaneous and co-ordinate action sometimes of the same muscle,
and sometimes of different muscles in the two eyes, is a remarkable physiological fact.
Thus, the contraction of the superior rectus of the right eye is of necessity accompanied
by contraction of the corresponding muscle of the left eye ; while the contraction of the
external rectus of one eye is accompanied by contraction of the internal rectus of the
* [Small synovial bursa have been described as existing between tbese tendons and the globe of the eye.]
THE OBLiaUE MUSCLES OF THE EYE.
651
other eye, and vice versa : the will can neither prevent nor disarrange these co-ordinate
contractions. However, even without much practice, it is possible to overcome them,
so far as to squint by endeavouring to look at the nose.
It is not uninteresting to remark, that the sixth cranial nerve, or the abducens oculi,
is destined exclusively for the external rectus muscle ; and that the third cranial nerve,
or motor oculi, supplies the three other recti, the levator palpebrae superioris, and the
obliquus minor. No other muscles in the body receive such large nerves in proportion
to their size as those of the eye.
Tke Oblique Muscles of the Eye.
These are two in number, the superior or great oblique, and the inferior or lesser oblique.
The Obliquus Superior.
Tke superior or great oblique muscle of the eye (/, fig. 238) is a long filiform muscle,
which is reflected over a pulley or trochlea, and hence has been jv^. 238.
termed the trocklearis muscle ; it arises from the fibrous sheath of the
optic nerve, between the superior and internal recti, in the same
manner and upon the same plane as those muscles ; from this point
it passes forward along the i^ngle formed by the junction of the roof
with the inner wall of the orbi, and forms a rounded muscular fas-
ciculus, which ends in a rounded tendon near the cartilaginous pulley
intended for its reception ; the tendon passes through this pulley, is i|
reflected upon itself at an acute angle, so as to be directed down- "
ward, outward, and somewhat backward ; gets beneath the superior
rectus, where it spreads out, and is then inserted into the sclerotic
coat on a level with the longest transverse diameter of the eyebsil],
and, consequently, farther back than the insertion of the recti. The
superior oblique is the longest muscle of the eye
The trochlea, or pulley of the superior oblique, is a small cartilage,
which forms five sixths of a short cylinder or ring ; the edges of this
imperfect cylinder are attached to the slight bony ridges which
bound a depression upon the superior wall of the orbit. Its attach-
ment is effected by means of loose ligamentous fibres, so that the
pulley itself has a certain degree of mobility. The gliding of the
parts is facilitated by a synovial membrane, which is reflected from the tendon upon the
pulley, and is prolonged in front of and behind the latter. Beyond the pulley, a whitish
filamentous tissue takes the place of the synovial membrane.
The relations of the superior oblique are similar to those of the superior rectus.
Action. — Like aU reflected muscles, the superior oblique must act from the point of its
reflection. It follows, therefore, that this muscle rotates the eye upon itself from with-
out inward, that is, around its antero-posterior axis. From the oblique direction of its
t^don from before backward, after it is reflected, it can draw the eye forward, and
tends to bring it out beyond the orbit. This muscle is believed to assist in the expres-
sion of the tender passions (jnusculus patheticus). The fourth cranial nerve, also called
the trochlear or pathetic nerve, is destined exclusively for this muscle.
The Obliquus Inferior.
The inferior or lesser oblique (g, fig. 237, 238) is the shortest muscle of the eye, and
the only one which does not arise from the bottom of the orbit ; it arises from the inner
and anterior part of the floor of that cavity, and, therefore, from the orbital surface of the
superior maxillary bone, immediately behind the margin of the orbit, and often even
from the lachrjnnal sac. From this origin it passes backward, in the form of a flat bun-
dle, which turns round the lower surface of the globe of the eye, situated at first between
the eyeball and the inferior rectus, then between it and the external rectus, and at
length ends in an aponeurotic expansion, which is blended with the sclerotic, near the
outer border of the superior rectus.
Its insertion into the sclerotic is farther back than that of the superior oblique, and,
therefore, much farther back than those of the recti.
Action. — It rotates the eye in the opposite direction to the superior oblique. Its turn-
ing round the lower surface of the eyeball renders its action extremely effective. From
its oblique course from before backward, it can draw the eye slightly forward.
The Lachrymal Passages.
The term lachrymal passages includes both the apparatus for secreting and that for con-
veying away the tears, consisting of a secreting organ, named the lachrymal gland ; of
excretory ducts, which pour out the tears upon the conjunctiva ; and of a second set of
ducts, intended to absorb the tears and convey them into the nasal fossae, comprising
the puncta lachrymalia, the lachrymal canals, the lachrymal sac, and the nasal ducts. Such
is the order in which we shall describe this apparatus.
6S2 NEUROLOGY.
The Lachrymal Gland. . , ^
The lachrymal gland (glandula innominata of the ancients) consists of two very distinct
parts : an orbital portion, situated in the fossa on the roof of the orbit ; and a. palpebral por-
tion, which is enclosed in the substance of the upper eyehd.
The first or orbital portion (I, fig. 207), the only part generally described, is of an irreg-
ular semi-ovoid form, having its long diameter placed transversely. It varies in size in
different subjects, but is generally about as large as a filbert.* Its upper surface is con-
vex, and corresponds to the fossa in the frontal bone, to which it adheres, especially in
front, by very distinct fibrous bands : its interior surface is concave, and is in relation
with the external rectus, and with a small part of the superior rectus. Its anterior bor-
der corresponds to the orbital arch, or, rather, to the fibrous membrane of the eyelid, im-
mediately behind which it is situated ; hence it maybe exposed by an incision along this
arch. By its posterior edge it receives its vessels and nerves.
The second or palpebral portion, though continuous with the first, is separated from it
by several fibrous bands. It forms a thin granular layer, which is covered and concealed
by a very dense lamina of fibrous tissue that appears to be prolonged into its interior.
This palpebral portion occupies the outer portion of the upper eyelid, and extends almost
as far as the upper border of the tarsal cartilage.
The Excretory Ducts of the Lachrymal Gland. — Before the discovery of these excretory
ducts, it was only by inference that the so-called glandula in7iominata was regarded as
the secreting organ of the tears. In 1661 Steno discovered these ducts in the sheep, m
which animal they are large enough to admit bristles. He described thirteen or fourteen
ducts. The difficulty of detecting these ducts in the human subject is sufficiently proved
by the fact that neither Morgagni, Zinn, nor Haller could ever find them ; the second
Monro, however, succeeded in filling them with mercury, and described them accurate-
ly. They are from ten to twelve in number ; they run parallel to each other beneath the
palpebral conjunctiva, and open upon the inner surface of the eyelid by a corresponding
number of orifices {d,fig. 235), placed very regularly about a line from the tarsal cartilage,
along its outer half. MM. Chaussier and Ribes have succeeded in filling them with mer-
cury, by injecting them from the gland towards the eyelids. Having sought in vain,
both with the naked eye and with a lens, for the orifices of the excretory ducts of the
lachrymal gland in the human subject, I thought of dipping the eye and eyelids in a so-
lution of carmine or slightly-diluted ink ; and I then saw distinctly a dozen openings ar-
ranged in a line along the point of reflection of the palpebral conjunctiva upon the eye-
ball, and occupying the outer half of the eyelid, t
The Lachrymal Puncta and Canals.
The puncta lachrymalia {a, fig. 239), two in number, one for each eyelid, are those small
Fig 239. orifices or foramina which are visible to the naked eye in the centre
of the lachrjonal papillae : they are perfectly circular, are always
open, and are directed backward, the upper one being turned do*n-
ward, and the lower one upward. These openings, which are ia^t
apart from each other by the caruncula lachrymalis, are the cjq)il-
lary orifices of two small canals, called the lachrymal canals.
The lachrymal canals {I I) are small tubes, extending from the
puncta lachrymalia to the lachrymal sac. They are two in num-
ber, a superior and an inferior, each being somewhat larger than
the corresponding lachrymal punctum. Their angular course is very remarkable. They
pass at first vertically, the superior duct upward, and the inferior duct downward, and
after a short course they bend abruptly at right angles, run inward, and open by separate
orifices, never together, into the anterior and external part of the lachrymal sac. The
direction of the second portion of each of the lachrymal canals varies according as the
eyelids are closed or open : the duct of the lower eyelid is directed somewhat obliquely
upward, that of the upper eyelid downward, even when the lids are completely closed ;
but they are both very oblique when the eyelids are separated ; and as this separation
is principally due to the elevation of the upper eyelid, it follows that the obliquity of the
upper lachrjrmal canal must be very well marked.
The coats of the lachrymal canals are dense and elastic, so that they do not collapse
when empty, and must, therefore, act as capillary tubes. We do not find any sphincter,
either at their palpebral or their nasal orifice ; they appear to be formed in the sub-
stance of the free margin of each eyelid ; they are lined by a prolongation of the con-
junctiva, and are covered by the fibres of the orbicularis palpebrarum muscle. Behind
them are found some muscular fibres, forming a dependance of a small fasciculus, called
the muscle of Horner, or the lachrymal muscle, which was believed by that anatomist to
serve in drawing the lachrymal ducts inward.
* [It has all the anatomical characters of a compound gland.]
t T find in Haller that it was in a human eye which had been macerated for some time in water tinged with
blood, that Monro (Secundus) discovered these orifices. After they have been discovered, it is easy to intro-
duce the end of the rasrcurial injecting pipe into them.
THE LACHRYMAL PASSAGES. 658
The Muscle of Homer.
Dissection. — ^Turn the eyelids inward, and carefully remove a fibrous layer which cov-
ers this muscle upon the lachrymal sac.
This small muscle arises from the vertical ridge of the os unguis, which forms the pos-
terior border of the lachrymal groove ; from this point it passes transversely outward
along the posterior tendon of the orbicularis palpebrarum, and divides into two tongues,
a superior and an inferior, which correspond to the lachrymal canals, and terminate at
the respective lachrymal puncta.
I regard these fibres as a dependance of the orbicularis palpebrarum.
The Lachrymal Sac and Nasal Duct, or Lachrymo-nasal Canal.
The lachrymal sac and nasal duct constitute a single canal, which extends from the up-
per part of the lachrymal groove to the inferior meatus of the corresponding nasal fossa.
The lachrymal sac (wi), that portion of the lachrymo-nasal canal which occupies the
lachrymal groove, represents the half of a cylinder terminating above in a cul-de-sac. It
is buried, so to speak, in the substance of the inner wall of the orbit, immediately be-
hind the margin of that cavity, and is in relation with the inner angle of the eyelids, the
caruncula lachrymalis, the adipose tissue of the orbit, and the tendon of the orbicularis
muscle. The last-named relation is one of the most important points in the anatomy of
the lachrymal sac. If a circular incision be made through the eyelids from their outer
aigle along their adherent borders, and the lids be then turned inward, by then careful-
ly dissecting the tendon of the orbicularis, it will be found that that tendon divides into
three branches ; that the anterior branch, called the straight tendon, is inserted in front
of the ascending process of the superior maxillary bone ; that the posterior branch, which
is of equal size with the anterior, is inserted into the ridge upon the os unguis, behind
the lachrymal groove ; that the middle branch ascends to be attached to the upper part
of the lachrymal groove ; and, lastly, that the lower part of the tendon gives off a fibrous
expansion, which forms the outer side of the lachrymal sac, and which may be regard-
ed as a fourth tendinous expansion. The muscle of Homer lies upon the posterior of
these tendons, and must be regarded as a portion of the orbicularis itself
The tendon of the orbicularis palpebrarum corresponds to the upper part of the lachry-
mal sac, only its cul-de-sac projecting above the tendon. The greatest part of the sac
is, therefore, situated below it.
The internal surface of the lachrymal sac presents the ordinary appearance of all ca-
nals lined by mucous membrane : a considerable quantity of mucus is often found in it.
At the anterior part of its external wall, and at about an equal distance from the top and
bottom, are the two orifices of the lachrymal canals ; above, is the narrow cul-de-sac, in
hich it terminates in that direction ; and below, it becomes continuous with the nasal
duct : in this place there is rather frequently found a semilunar, sometimes even a cir-
cular valve ; this is the kind of diaphragm spoken of by Zinn, but the existence of which
w^denied by Morgagni. Haller says that he only met with it once.
lachrymal sac consists of a partly bony and partly fibrous canal, lined by a mu-
embrane. The bony portion of this canal is formed by the groove upon the as-
ing process of the superior maxillary bone, and upon the os unguis ; the last-men-
led bone, which is thin and pierced with foramina, may be easily perforated ; and
hence the facility of making an artificial passage for the tears. The lachrymal sac is
opposite to the middle meatus of the corresponding nasal fossa.
The fibrous portion forms the external flattened wall of this canal ; it is very strong
and unyielding, unless to long-continued extension.
The slight muscular layer, described as the muscle of Horner, may be regarded as be-
longing to the lachrymal sac : this muscle is itself covered by a layer of fibrous tissue.
The lining mucous membrane of the lachrymal sac is reddish, and, as it were, pulpy,
and closely resembles the pituitary membrane ;* from its close attachment to the peri-
osteum of the walls of the canal, it might be called afibro-mucous membrane.
The nasal duct (n), which may be said to be formed in the outer wall of the corre-
sponding nasal fossa, extends from the lachrjTnal sac to the anterior part of the inferior
meatus of the nose. It is of a cylindrical shape, slightly flattened on the sides, and rath-
er narrower at the middle than at its extremities. It is directed vertically, but forms a
slight curve, having its concavity turned forward and outward. It may be also readily
conceived that the relative breadth of the root of the nose must affect the direction of
this canal.
It corresponds, on the inner side, to the middle meatus of the nose, and the inferior tur-
binated bone ; on the outer side, to the maxillary sinus, from which it is separated by a
very thin lamina of bone. This latter relation has doubtless led one anatomist to state
that the nasal canal opens both into the maxiUary sinus and the nasal fossa.
The nasal canal consists of a bony canal lined by a fibro-mucous membrane ; the bony
canal is complete, and is formed by the superior maxillary bone, the os unguis, and the
inferior turbinated bone. It is very strong in the part formed by the superior maxillary
* See note, p. 654.
654 NEUROLOGY.
bone, excepting opposite to the sinus in that bone, but it is very thin and fragile where
it is formed by the os unguis and inferior turbinated bone. Its lining membrane is of a
fibro-mucous structure ; it adheres very slightly to the walls of the canal, and is contin-
uous, on the one hand, with the mucous membrane of the lachrymal sac, and, on the
other, with the pituitary membrane.* This lining membrane is often prolonged for sev-
eral lines beyond the nasal duct, so as to form a valvular fold (o). Where this fold ex-
ists, the inferior orifice of the nasal duct (see r,fig. 233) is always closed, and, there-
fore, difficult to be detected, even when the inferior turbinated bone has been taken
away or displaced, so that, in order to discover it, it becomes necessary to introduce a
probe through the lachrymal passages from above. In catheterism of thelift|J duct
from below upward, according to the method practised by Laforest, this fold ^Btocous
membrane must of necessity be torn. ^fe
It has been stated by some authors, that the lower orifice of the nasal duct isp^e-
ded by an ampulla, or infundibuliform dilatation. I have met with this disposition, but
regarded it as morbid. I am convinced that a great many lachrymal tumours depend
upon contraction or obliteration of the lower orifice of this canal. «
The Globe of the Eye.
The globe of the eye {v,fig. 240) is situated in the fore part of the orbital cavity ; it is retain-
Fig. 240. ed in this situation by the optic nerve (o), the straight
and oblique muscles {beg), the vessels, the conjunctifa
(d), and the eyelids ; these parts, however, do not con-
fine it in a fixed position, but allow it great mobility. In
fact, the eye can be rotated around all its axes, and
can even be drawn forward and backward (see Mus-
cles of the Eye). The eyes are small in comparison to
the orbital cavities ; and they present some slight dif-
ferences as to size in different persons, which have
not yet been properly estimated. The common terms.
large and small eyes apply less to the eyeball than to
the opening between the eyelids. The eye is propor-
tionally larger in the foetus and new-born infant than'in the adult and aged.
Inform, the globe of the eye resembles a regular spheroid, to- the front of which r? at-
tached a segment of a smaller sphere {see fig. 241) : by this arrangement, the anjfero-
posterior diameter of the organ is increased to the length of eleven lines, whil^it^l^h-
er diameters are only ten lines. It is said that the form of the eyeball can '
by the contraction of its muscles, but, in consequence of the great tension of tj
the alteration produced is so slight tj^at it scarcely deserves to be mentioned.
The general relations of the eyeball are the following : in front, it is covere
conjunctiva and the eyelids, which defend it from light and from dust, rather
external violence. It results, also, from the obliquity of the margin of the orbit,'
the outer side, the eye projects considerably beyond the bones. In every other pi
its surface the eye rests upon an elastic cushion of fat (//), which separates it'
the muscles and nerves, fills up all intervals, and facilitates the movements of the or^
The absorption of this fat in emaciated individuals causes the depression of the eyej
the orbital cavity. A membranous cellular tissue, or, rather, a rudimentary sync
membrane, exists between the eye and this fat. .,
Structure. — Like all the other organs of the senses, the eye consists essentially of a
membrane provided with a special nerve, and of a particular apparatus, placed in relation
with the external agent by which the organ is to be acted upon. In the organ of vision,
the sentient membrane is the retina, which is the immediate seat of the sense of sight ;
the other parts of the eyeball form nothing more than a very comphcated dioptric instru-
ment, a dark chamber, in which the rays of light are refracted, and concentrated so as
to form a vivid image, and which is, moreover, provided with a movable diaphragm to
regulate the number of rays to be admitted.
In an anatomical point of view, the eye is said to consist of certain membranes and
humours. The membranes, counting from without inward, are the sclerotic coat and cor-
nea, the choroid coat and iris, and the retina. The humours are, the vitreous body and its
hyaloid membrane, the crystalline lens and its capsule, and the aqueous humour.
The Sclerotic.
Dissection. — Clean the globe of the eye, leaving the attachments of the muscles to the
sclerotic coat ; with a pair of strong scissors divide this coat circularly into an anterior
and posterior portion, taking care to avoid the choroid coat ; turn the one portion for-
ward and the other backward. It is easier to make this section, without injuring the
choroid, upon a slightly flaccid eye than upon one which is perfectly fresh.
The sclerotic {aK%T]pdg, hard), or the opaque cornea {b,fig. 241), is the outermost of the
* [The epithelium of the mucous membrane of all the lachrymal passages is columnar, and, according to
Henle, is provided with cilia, although Perkinj6 and Valentin failed to discover them in these situations.]
THE CORNEA. 655
coats of the eye, and forms, as it were, the shell of that organ ; it is of a pearly- white
colour, and very stroag,;. it is perforated behind to give passage to the optic nerve (o),
and presents a circular opening in front (from a to a), into which the cornea is fitted.
Its external surface forms the outer surface of the eyeball, and therefore has the same
relations. Thus, it is covered in front by the conjunctiva, which adheres to it by means
of very loose cellular tissue, that is liable to infiltration. The straight and oblique mus-
cles of the eye are implanted into it. An imperfect or rudimentary synovial capsule
separates it from the cushion of fat, and gives it a smooth aspect.
Its internal surface has a dull, rough appearance, very different from that of its exter-
nal surface : it is, moreover, of a deep-brown colour, from the choroid pigment ; it cor-
responds to the choroid coat (c), and is united to it by a very delicate cellular tissue, and
by the ciliary vessels.* The ciliary nerves run from behind forward between the scle-
rotic and the choroid, occupying slight grooves upon the internal surface of the former.
Both the ciliary vessels and nerves perforate the sclerotic coat very obliquely.
Structure. — ^The sclerotic is one of the thickest and strongest fibrous membranes in
the body^ it is not of uniform thickness throughout ; it is thickest behind, at the entrance
of the optic nerve, and thinnest in front, near the cornea. Like all the fibrous mem-
branes, it is unyielding ; and on this depends the firmness and tense condition of the
globe of the eye : it is also the cause of the intense pain produced by inflammation of
the interior of the eye and by certain cases of hydrophthalmia.
The older anatomists considered the sclerotic to be composed of two layers, the inner
of which was, according to Zinn, a prolongation of the pia mater, and, according to
Meckel, of the arachnoid. But, independently of the fact that the division of the sclerot-
ic into two layers is purely artificial, it may be stated that neither the pia mater nor the
arachnoid is prolonged upon the optic nerve. Lastly, the sclerotic has been regarded as
a continuation of the dura mater, through the medium of the neurilemma of the optic
nerve ; and this view is supported by dissection, which shows clearly that the sheath
furnished by the dura mater to the optic nerve is prolonged upon the sclerotic. It has,
moreover, been stated, but incorrectly, that the anterior part of the sclerotic has an ad-
ditional layer, formed by the union of the tendons of the recti muscles.
The sclerotic is composed of fibrous bundles which interlace in all directions.
Its use is especially to protect the globe of the eye, of which it forms the covering and
determines the shape.
.;- The Cornea.
^'
The transparent cornea {a a, fig. 241) completes the external shell of the eye in front :
in reference to the sclerotic coat, it represents a segment of a smaller sphere superadded
to a larger sphere ; its circumference is circular, or, rather, slightly elliptical, for its
transverse diameter is half a line longer than its vertical diameter.
Its anterior surface is convex, and projects forward beyond the sclerotic ; it is covered
by^he conjunctiva, which adheres to it so closely, that the existence of that membrane
v^^fm it has Been denied by some anatomists.!
■"Ij^o great a convexity of the cornea, by increasing the refracting power of the eye,
^jgftasions myopia, or short-sightedness.
■ its posterior surface is concave, and forms the anterior wall of the anterior chamber
of the eye. A thin membrane (m) covers this surface, and is called the membrane of the
aqueous humour.
The circumference of the cornea, which is fitted into the opening in the front of the scle-
rotic, is cut obliquely, so that its external surface is smaller than its internal surface ; the
oblique edge of the sclerotic, to which it corresponds, is sloped in the opposite direction.
The cornea and sclerotic adhere so closely that they were for a long time regarded as
forming but one coat ; but, independently of their difference in appearance and texture,
they may be separated by boiling or by long-continued maceration.
Structure. — The cornea is thicker than the sclerotic : it may be separated into a great
number of lamellas, united by very thin layers of cellular tissue ; but this separation is
purely artificial, so that the number of lamellae is indefinite. The thinnest layer of fluid
interposed between the lamella; is sufficient to impair the transparency of the cornea;
maceration, accordingly, gives it a milky appearance. The opacity of the cornea, which
occurs in some cases of ophthalmia, depends upon the infiltration between the lamellae
of a certain quantity of fluid, after the absorption of which the cornea recovers its ori-
ginal transparency.
No vessels can be shown in the cornea, even by the aid of the finest injections of the
arteries and veins of the eye : its superfi^cial layer, which is continuous with the con-
junctiva, contains a network of lymphatics communicating with those of the conjunc-
tiva, and capable of being demonstrated by puncturing any part of the superficial layer of
* See note, p. 656.
t A careful dissection, especially after prolonged maceration, shows the continuity of the most superficial
layer of the cornea with the conjunctiva. A malformation sometimes occurs iu which oni^ part of the cornea
is covered by a prolongation of the conjunctiva.
656
NEUROLOGY.
the cornea. It is useless to introduce the tube deeper, for the lymphatic network is en-
tirely superficial.
Uses. — The transparent cornea is the first medium through which the rays of light
have to pass ; in consequence of its density and its convexity, it refracts the rays of light,
and causes them to converge. The density of the cornea is the same in different per-
sons ; but its convexity is subject to variations, upon which depend, in a great measure,
the states of myopia (short sight), presbyopia (long sight), and natural vision.
The Choroid Coat, and the Ciliary Circle and Processes.
The choroid (indicated by the thick black hue, c,Jlg. 241), so called from its extreme
vascularity,* is the second membrane of the eye, proceeding from without inward ; it
is a vascular membrane, covered with a thick layer of pigment : it exactly lines the
sclerotic, and terminates, like it, at the circumference of the cornea.
Its external surface (c, jigs. 242, 244) adheres to the schlerotic by means of the ciliary
vessels and nerves, and by a thin and very delicate cellular tissue, which is easUy lacer-
ated, and when raised appears like a spider's web.+ This surface, when magnified, has
a fiocculent appearance.
Its internal surface is in relation with, but does not adhere to, the retina (r, fig. 241), by
which it is lined nearly throughout its whole extent.
Both surfaces of the choroid are covered with a pigment, which resembles the pigment
of the skin of negroes ; this pigment is much more abundant on the internal than on
the external surface, and less so behind than in front, where it forms a thick layer, in
the form of a zone surrounding the corona ciliaris.
Upon both surfaces are found innumerable longitudinal and contorted lines, which
correspond to the vessels of the choroid.
In a great number of animals, in the ox, for example, the pigment on the interned sur-
face of the choroid at the back of the eye is replaced by a brilliant metallic-looking sub-
stance called the tapetum. When deprived of its pigment, the internal surface of the
choroid presents a smooth aspect, and is not fiocculent like the external surface. It is
of a grayish- white colour, and anteriorly, where it is covered by a thick layer of pigment,
it becomes white and shining when the pigment is removed.
Behind, the choroid is pierced by a circular opening for the passage of the optic nerve ;
in front, it terminates in the ciliary circle and ciliary processes, which must be regarded as
appendages to it.
T'he Ciliary Circle. — The ciliary circle, ring, or ligament («, fig, 241 ; b, figs. 242,
fin. ail, 244), IS a circular zone, from a line to a
J j_ line and a half in breadth, of a grayish col-
our, and soft consistence, which bounds
the choroid coat (c c) in front. It is of con-
siderable thickness. Its external surface
corresponds to the sclerotic, to which it is
slightly adherent. Its internal surface Qpr-
responds to the ciliary processes (e, fig.
241) ; by its outer or larger border, which
is distinguished from the choroid by a slight
ridge, it receives the ciliary nerves (a a,
fig. 242), which bifurcate, and appear to
anastomose with each other before they
enter the substance of the ciliary circle :
by its lesser or inner border, wliich corre-
sponds to the iris (i), it adheres intimately
to the circumference of the cornea, exactly where that membrane is continuous with the
sclerotic (at a a, fig. 241). The older anatomists called this structure the ciliary liga-
merU. From the great number of the nerves which enter the ciliary circle, from its gray-
ish colour, and its pulpy aspect, modern anatomists have regarded it as a nervous gan-
glion (annulus gangliformis, or annular ganglion, Sammering).
Fig. 242. Some anatomists describe, under the name of the ciliary canal,
or the canal of Fontana, a very small and extremely narrow cir-
cular space (u V, fig. 241), which is formed between the ciliary
circle, the cornea, and the sclerotic. This space can be filled
with injection, and it is not certain that it is not the cavity of a
bloodvessel.
The Ciliary Processes and the Ciliary Body. — If the back part
of the sclerotic, choroid, and retina be cut away, or even if the
fc globe of the eye be merely divided into an anterior and posterior
* Choroid is synonymous with vascular.
t [A serous cavity is said by some to exist betvreen the sclerotic and choroid ;
the lining membrane of this supposed cavity is named the arachnoid membrane
of the eve.]
THE IRIS. ^7
half by a circular incision, on looking into the anterior half a perfectly regular radiated
disc {d, Jig. 241 ; a b, fig. 243) will be seen around the crystalline lens. This disc, which
has been very correctly compared to a radiated flower, is called the ciliary body, or cormia
ciliaris ; each of the rays is called a ciliary process or ray (rayon sous-irien, Chaussier).
If, after a correct idea of the arrangement of this radiated disc has been obtained, the
choroid coat be separated from the humours of the eye, it will be found that there are two
perfectly distinct discs : one of these remains attached to the choroid coat, and constitutes
the ciliary disc or ciliary body of the choroid (a b, fig. 243) ; the other remains attached to the
vitreous body and to the crystalline lens, and is the ciliary zone of pig, 243.
Zinn, which may be termed, after M. Ribes, the ciliary processes
of the vitreous body (a b,fig. 248). We shall now describe the cil-
iary processes of the choroid coat only, leaving the ciliary pro-
cesses of the vitreous body to be described together with that part
of the eye.
The ciliary processes of the choroid coat, so well described by
Zinn, who enumerates sixty of them, are regarded as so many
folds of the internal layer of the choroid. They may be divided
into great and small, the latter occupying the intervals between
the former. They all increase in size (from b to a, fig. 243) as Pcterior or imemJ view.
they approach the outer border of the iris, behind which they are prolonged without adhe-
ring to it, and are then bent forward upon themselves, to be attached to that border. These
ciliary processes, the sides of which are turned towards each other, have, therefore, a
posterior adherent or choroid portion (b), and an anterior free or iridian portion (a). The
free portion (c e, fi^. 241 ; a, fig. 244) floats among the humours of the eye like a fringe ;
,the slightest agitation of the vessel or of the liquid in which the
ciliary processes are contained is immediately communicated to
this free portion of the corona ciliaris.
The ciliary body or disc, which is formed by the union of all the
ciliary processes or rays, is in relation behind with the vitreous
body {v in the centre, ^^. 241), and advances (e,fig. 241 ; a, fig.
244, in which the iris is removed) over the circumference of the
crystalline lens. It is not simply in contact with the vitreous body,
but is rather firmly adherent to it ; and we shall afterward see that
they are dovetailed together, that is, the ciliary processes of the
vitreous body are fitted into the intervals between the ciliary pro- Anterior view-im removed
cesses of the choroid, and vice versa.
If the thick layer of pigment with which they are covered be removed, the ciliary
processes of the choroid, when examined through a lens under water, have a white colour.
In their substance are seen irregular cells which are filled with the brown pigment, and
which give them a spongy, and, as it were, jagged appearance. They are evidently con-
tinuous with the choroid, which irxmiediately around them presents a zone of a whiter
colour than the rest of the inner surface of that membrane.
Structure of the Choroid Coat and its Ciliary Processes. — The structure of these parts is
essenticdly vascular. Fine injections thrown into the carotid artery and internal jugular
vein, in young subjects, fill a beautiful network of vessels in this membrane. The vor-
ticose arrangement {v, fig. 244) of some of these vessels is then clearly displayed ; and,
indeed, this is very well indicated, without the aid of an injection, by the striae already
described as visible upon the surfaces of the choroid. The short ciliary arteries belong
exclusively to the choroid coat. From a great number of experiments made by M. Ribes,
it would appear that injections pushed into the arteries do not enter the vdli and fringes
of the ciliary body, but that their vessels may be filled from the veins ; so that, accord-
ing to this, the structure of the free and fringed portion of the ciliary processes is alto
gether venous, like the cavernous or erectile tissues.*
From the different appearance of the external and internal surfaces of the choroid,
anatomists have regarded this coat as being composed of two layers, of which the in-
ternal is called the membrana Ruyschiana, after Ruysch, who has given the best descrip-
tion of it. According to one view, which is not altogether unsupported, the internal
layer alone concurs in the formation of the ciliary processes, while the external layer
corresponds to the ciliary ring.
The Iris.
The iris {i, figs. 242, 243), so called on account of the varied colours which it presents,
is a membranous vertical septum, perforated in the centre, like the diaphragm of an op-
tical instrument. By means of this septum (i, fig. 241), the space {p) between the cornea
(m) and the crystalline lens (f) is divided into two parts or chambers, an anterior and a
posterior. The iris is circular, and perforated in its centre by an opening which consti-
tutes the pupil {p, fig. 242), vulgarly, the apple of the eye, and which is surrounded by
the lesser or inner border of the iris ; the pupil is circular in the human subject, and oblong,
* [In successful injections, arterial as well as venous ramifications are demonstrated in the ciliary processes. 1
40
658 NEUROLOGY.
either transversely or vertically, in the lower animals ; the number of luminous rays suf-
fered to impinge upon the retina are regulated by variations in the size of this opening.
We constantly find in several kinds of animals, and occasionally in the human subject,
small fringes attached to the lesser border of the iris, which float in the aqueous humour.
The outer or greater border of the iris is, as it were, fitted in between the ciliary liga-
ment, which projects beyond it slightly in front, and the ciliary processes, which encroach
upon it behind {see Jig. 241). The manner in which it adheres to these parts is not well
understood. There is a true continuity of tissue, and yet they may be separated by a
slight degree of force ; on this is founded the operation for artificial pupil by detaching the
iris. The outer border of the iris is not continuous with the circumference of the cornea.
The anterior surface of the iris {i, fig. 242), with its different shades of colour, is the
part which is seen through the transparent cornea ; it is plane, not convex. The inter-
val between it and the cornea constitutes the anterior chamber of the eye {fig. 241).
The form and size of this interval can be correctly estimated in a frozen eye ; it is filled
with the aqueous humour ; its longest diameter from before backward is about one line.
When examined with a lens, the anterior surface of the iris has a flocculent appear-
ance, more distinct than, but similar to, that of the external surface of the choroid. It
appears as if it were fissured here and there, and in the human subject presents some
very well-marked radiated bands. When the pupil is contracted these radiated banda
are straight, but during its dilatation they become flexuons. They appear to interlace,
and thus to become blended with each other near the pupil. It is generally admitted
that the membrane of the aqueous humour covers the anterior surface of the iris ; but it
cannot be demonstrated in that situation. The colour of this surface differs in different
individuals, and it has generally some relation to that of the hair ; upon these differences
depend the colour of the eyes, whether blue, black, gray, &c. Whatever may be the
colour of the iris, two shades of different intensity may be distinguished in it, and occa-
sion the appearance of two concentric coloured zones in this membrane ; the smaller and
deeper-coloured zone is situated near the pupil ; the larger and lighter-coloured one in-
cludes the two outer thirds of the membrane. It is not always easy to distinguish these
two zones.
The posterior surface {i, fig. 243) of the iris corresponds to the crystalline lens, from
which it is separated by an interval filled with the aqueous humour, and called the pos-
terior chamber of the eye {fig. 241).
The two chambers of the eye, therefore, communicate at the pupil {p).
The posterior surface of the iris is covered by a thick layer of pigment, which is con-
tinuous with the pigment of the choroid ; near its outer border it is also overlaid by the
free or iridian portion (c e) of the ciliary processes of the choroid, which can be easily
turned back so as to expose the entire posterior surface. It presents extremely well-
marked radiated bands, which can be well seen, even before the choroid pigment is re-
moved.
The aspect of the posterior surface of the iris differs essentially from that of the an-
terior surface ; it is white and smooth, and resembles in many respects the internal sur-
face of the choroid. Some anatomists are of opinion that the posterior surface of the
iris is covered by the membrane of the aqueous humour. If such be the case, it is difll-
cult to comprehend how that membrane is arranged with reference to the pigment.
Structure. — The iris is three or four times as thick as the choroid ; it diminishes in
thickness from its outer to its inner border. Its real structure is but little understood.
The old opinion of its muscularity, which was refuted by Weitbrecht and Demours, has
been revived by M. Maunoir, who admits two sets of muscular fibres, viz., radiated fibres,
which correspond to the external coloured ring, and circular fibres, which correspond to
the internal coloured ring, and form a sort of sphincter around the pupil ; but no circular
fibres can be distinguished around the pupil. An appearance as if such were the case,
is occasioned by a peculiar arrangement of the radiated fibres, which seem to bifurcate
opposite the internal coloured ring, to interlace with each other, and then terminate ab-
ruptly around the pupil ; so that the inner border of the iris, or the pupil, appears to be
formed by the blunt extremities of these radiated fibres.
In the ox and the sheep, the iris has two very distinct sets of fibres : an anterior and
circular layer, which occupies the whole of the anterior surface ; and a posterior and
radiated set of fibres, which converge from the outer to the inner border. The anterior
set of fibres does not exist in the human subject.
Another and much more plausible opinion regarding the structure of the iris is, that it
consists of a vascular or erectile texture.*
If we examine an oblique section of the iris under a lens, we find, indeed, that it has
an areolar spongy structure ; and the extreme vascularity of this part also supports the
same view.
* A case is related of a young man who could produce contraction of the pupils by holding his breath.
[The muscularity of the fibres of the iris i.s now established beyond a doubt ; the fibres of the iris of the pig
are described by Schwann as being very minute, cylindrical, and not beaded ; thev therefore resemble the
muscular fibres of organic life.]
THE MEMBBANA PUPILLARIS, ETC. 659
Arteries of the Iris. — The arteries of the iris are principally derived from the two long
ciliary arteries, which bifurcate and anastomose after they have reached the ciliary liga-
ment, and form a vascular circle, which gives off radiated vessels that converge from the
outer border of the iris towards the pupil. There are also some anastomotic arches
near the pupil.
Veins of the Iris. — The veins of the iris are much more numerous than the arteries ;
they terminate in the venae comites of the long ciliary arteries, and in the vasa vorticosa.
Nerves. — The nerves of the iris, or ciliary nerves {a a, fig. 242), are very large ; as we
have stated, they gain the ciliary circle, and then pass through it in great numbers, to
enter the iris, and be distributed in its substance. Most of these nerves are given off
from the ophthalmic ganglion : some of them are derived directly from the nasal nerve,
which is a branch of the fifth cranial nerve.
The older anatomists distinguished two layers in the iris : one anterior, which they called
the membrane of the iris ; the other posterior, covered with pigment, which they called
membrana uvea. By examining an oblique section of the iris with a lens, two layers may,
in fact, be seen, separated by the spongy tissue of which I have spoken
The Memhrana Pupillaris.
Dissection. — By opening the eye of the foetus from behind, this vascular membrane
may be easily seen through the vitreous body and the crystalline lens.
In the foetus, the opening of the pupil is closed by a membane, called the membrana
pupillaris, which was discovered and very well described by Wachendorf, but more per-
fectly so by Haller and Soemmering, and recently by M. Jules Cioquet. It may be seen
about the third month of intra-uterine life, and generally disappears towards the seventh
month. When persistent, it may occasion congenital blindness. Wachendorf and
Soemmering have demonstrated the vessels of this membrane, which are continuous
with those of the iris. During the existence of the membrana pupillaris, the membrane
of the aqueous humour forms a shut sac. From the researches of M. Jules Cioquet con-
cerning the pupillary membrane, it appears that it consists of two thin layers, between
which the bloodvessels are arranged in loops ; that the convexities of these loops are
turned towards each other, but that the loops which approach each other from opposite
sides do not anastomose together ; that between these loops, and towards the centre of
the pupil, there is a small irregular portion of the membrane which is destitute of ves-
sels, and is, therefore, weaker than any other part ; that the formation of the pupil is
effected by the rupture of this membrane, and that this rupture is occasioned by the re-
traction of the vascular loops, which ultimately occupy the lesser border of the iris.
Uses of the Iris. — The iris regulates the quantity of light that is admitted into the in-
terior of the eye. The contraction of the pupil is an active movement, and its dilatation
is passive ; facts which are opposed to the doctrine of its muscularity, but support the
idea of its being a vascular and erectile structure.
It has been stated that the movements of the iris are intended to enable us to judge
of the distance and size of objects, or, rather, to enable us to see objects at different dis-
tances : this is erroneous, for the pupil remains of the same size, under the action of a
similar quantity of light, whether the object looked at be near or distant.* The effect
of narcotics, and especially of belladonna, either applied topically, or taken internally, in
producing dilatation of the pupil, is one of the most curious facts concerning the iris.
The direct action of the rays of light upon the iris has no influence upon the size of the
pupil, the dimensions of which are altered either by the action of light upon the retina,
or in consequence of a peculiar condition of the optic nerve of the brain
The Pigment of the Eye.
It has been stated that the external surface of the choroid and the internal surface of
the sclerotic are coloured by a very thin layer of pigment ; and also that the internal sur-
face of the choroid is covered with a thicker layer, which is itself thickest on the fore
part of that surface, near the ciliary body, between the greater ciliary processes, and be-
hind the iris. By means of this pigment the interior of the eye is converted into a true
dark chamber. StUl, it may be asked why the pigment is less abundant behind than in
front.
The choroid pigment is not black, but of a very dark-brown colour, like bistre ; in this
respect resembhng the pigment of the skin of the negro ; it consists of molecules or
globules insoluble in water.
The pigment of the choroid of the iris is wanting in albinoes. as well as the cutaneous
pigment. Both have the same chemical composition, t
* [The pupil certainly dilates in looking at distant objects, and contracts under the opposite circumstances ;
but it is by no means certain that the adjustment of the eye to objects at different distances depends on these
alterations in the condition of the iris.]
t [The pigment of the eye consists of nucleated cells containing the pigment granules ; on the inner surface
of the choroid these cells are flattened and hexagonal, and their sides fit accurately together, so as to present
an appearance like mosaic work ; on the back of the iris the cells are irregularly rounded. In albinoes the
cells contain no coloured granules.]
mi
NEUROLOGY.
In some animals the pigment of the eye has a metallic lustre, and an iridescent aspect
in a great part of its extent.
The Retina.
The retina (r,figs. 241, 245), counting from without inward, is the third membrane ol
the eye ; it is the immediate seat of vision, and is an essentially nervous membrane, sit-
uated within the choroid and the sclerotic. Its external surface (jr,fi.g. 245) corresponds
to the choroid, from which it is separated by the pigment, which, in eyes that have un-
dergone slight decomposition, forms an irregular layer upon it, like a web. Dr. Jacob
(Philosoph. Trans., 1819) has described a serous membrane between the retina and the
choroid, in the cavity of which a dropsical effusion may occur, and constitute what is
called ;)os<enor staphyloma of the eye. M. Weber believes that this membrane is prolonged
forward to the circumference of the crystalline lens, and is then reflected over the pos-
terior surface of the iris, where it becomes continuous with the membrane of the aque-
ous humour. I have not succeeded in demonstrating the membrane of Jacob.*
The internal surface (r, fig. 246) of the retina is applied to the vitreous body, but does
not adhere in the slightest degree to it.
The point at which the retina terminates in front is still regarded by most anatomists
as undetermined. Several, with the older authors, describe it as extending to the cir-
cumference of the crystalline lens. Some entertain a modification of this opinion, be-
lieving that an extremely thin membrane is given off from the rim {r'r", fig. 241) in
which the retina seems to terminate, and that this membrane advances upon the inner
surface of the ciliary body to the front of the capsule of the crystalline lens, to which it
is attached. M. Duges, in an excellent work upon the comparative anatomy of the or-
gan of vision, expresses a somewhat different opinion : according to his view, the retina
having reached the ciliary processes, divides into numerous tongues, each of which passes
between two of the ciliary processes, and terminates by expanding upon the circumfer-
ence of the crystalline lens. A careful examination has proved to me distinctly that the
retina terminates by a defined edge (margo dentatus, r'r',fig. 241 ; m,fig. 245) at the
Fie 245 posterior extremities of the ciliary processes of the vitreous
body (a), to which processes it adheres rather firmly, though it
can be sometimes separated from them Avithout laceration.
Is the retina an expansion of the medullary part of the optic
nerve, or is it a special organ continuous with that nerve !
Although the former of these opinions appears more probable
than the latter, still it is liable to objections. The optic nerve
is constructed in a particular manner as it passes through the
sclerotic, and the corresponding nervous substance is so ar-
ranged that pressure upon the nerve does not force the ner-
vous substance into the interior of the eye, though pressure
upon every other part of the nerve causes a white pulpy matter to exude from its divided
surface.
The retina is semi-transparent, like a thin layer of opal : it scarcely holds together,
and can be torn with the greatest facility. It does not appear to me to be thicker be-
hind than in front.
The radiated lines stated by several of the older anatomists, and also byM. Duges, to
exist in the retina, can only be distinguished behind at the entrance of the optic nerve.
Tliis radiated character was evident in the eye of an ox which I recently examined. The
optic nerve divided into three thick diverging bundles, which expanded into a layer ; but
this filamentous arrangement was soon succeeded by what appeared, at least, to be a
pulpy structure.
Two layers are described in the retina : an external, which is pulpy and nervous ; and
an internal, which is vascular, and is formed by the ramifications ol^ the arteria centralis
retinae ; but this subdivision of the retina is purely fictitious. Soemmering has given
a good representation of the vascular network, which seems in some manner to support
the nervous substance.
The Foramen Centrale, the Fold, and the Limbus Luteua vf the Retina^ — Soemmering
was the first to describe in the retina a foramen {foramen centrale), which had escaped
the researches of Ruysch, Zinn, and Haller, doubtless because it is concealed by the folds
formed by the retina at this point.
It is doubtful whether these folds of the retina result from the collapsed condition of
the eyeball, which necessarily follows the dissection required for the examination of its
interior ; or whether they are really part of its structure, and should be regarded as the
vestige of the singular folds existing in different kinds of animals, and especially in birds,
the visual powers of which are thereby greatly increased. However this may be, the
foramen, which is always situated to the outer side of the entrance {b, fig. 246) of the
* [If the posterior part of the sclerotic and choroid be carefully removed from a fresh eye (leaving the optic
nerve untouched), and the eye be then macerated a few hours in water, portions of Jacob's membrane will
either senarate, or they ca"n easily be separated from the outer surface of tlie retina.]
THE VITREOUS BODY.
66]
optic nerve, is surrounded with a zone of a canary-yellow colour : this is the limhus lu-
teus foraminis centralis {Sammering), or the yellow spot of Sam- „.
mering (a). ^'
The foramen centrale and the limbus luteus exist in man and the
quadrumana only ; that is to say, in those cases only in which the
visual axes of the two eyes are parallel to each other, as in man.
I have not found that the yellow spot corresponds to the thick-
est part of the retina.
It should, moreover, be observed, that the foramen centrale, not
the entrance of the optic nerve, corresponds to the antero-posterior
axis of the globe of the eye, and is the true centre of the retina.
The uses of the central foramen and the yellow spot are not
known.
The yellow spot does not exist in the foetus.*
The Humours of the Eye.
The media through which the light passes in the eye, besides the transparent cornea
already described, are the vitreous body, the crystalline lens, and the aqueous humour.
The Vitreous or Hyaloid Body.
The vitreous or hyaloid body {v,Jigs. 247, 248) (from va?.oc, glass), so called from its re-
semblance to glass, is an imperfectly spheroidal, and quite transparent mass, which oc-
cupies the posterior three fourths (v,Jig. 241) of the globe of the eye ; it is covered im-
mediately by the retina {v, fig. 245), which is simply in contact with it, and indirectly by
the other coats of the back part of the eye, which are accurately moulded upon it. It pre-
sents a slight depression in front, for the reception of the posterior surface of the crys-
talline lens (/). The vitreous body and the crystalline lens together very nearly resem-
ble in form the entire globe of the eye, the projection of the crystalline lens representing
the prominence of the cornea (compare figs. 241 and 245).
The vitreous body is composed of a liquid, named the vitreous humour, i and of the hy-
aloid membrane.
The hyaloid membrane {h,fig. 241), which was first discovered by Fallopius, can be
easily demonstrated by puncturing the vitreous body, and allowing the vitreous humour
to escape. If it be then dipped in diluted nitric acid, the membrane will become opaque,
and easily distinguishable. This membrane not only forms a general investment or cap-
sule for the vitreous body, but gives off lamellar prolongations from its internal surface,
which separate the vitreous humour into an irregular number of compartments, or cells.
The existence of these cells can be easily proved by moving the vitreous body between
the fingers ; and if this body be frozen, their shape is shown by that of the masses of ice
which may be taken from them.
It is generally admitted that all these cells communicate with each other ; because,
when one of them only is punctured, all the vitreous humour will gradually escape.
Still, I have several times observed that the eye did not collapse when a part of the vit-
reous body had escaped in the operation for extracting a cataract ; this, however, might
have depended upon any farther escape being opposed by the approximation of the lips
of the incision.
The manner in which the hyaloid membrane is arranged with reference to the crys-
talline lens is still a disputed point. It is generally admitted that, about a line from the
margin of the crystalline lens, the hyaloid membrane divides into two layers, one of
which passes behind {h,fig. 241) and the other in front of the
lens. The three-sided interval (s s) which exists all round the
crystalline lens, and which has been described by Fran9ois Petit,
under the name of canal godronne, is formed between these two
layers and the lens. This circular canal, or canal of Petit, can
be very easily shown by blowing air into it (as in p,fig. 247) ;
it is then seen to be constricted at intervals, as if by small folds
or bands, so that it presents a knotted or plaited appearance.
Other anatomists, on the contrary, state that the hyaloid mem-
brane does not split into two layers, but passes altogether behind
the crystaUine lens, in order to cover the front of the vitreous body.
Fi>. 247.
It is certain that
* [From recent researches, especially those of Valentin and Hanover, the following appears to be the mi-
nute structure of the retina: 1. The membrane of Jacob consists of minute cylindrical or prismatic bodies,
placed closely together, and perpendicularly to the surface of the membrane ; among these are somewhat lar-
ger bodies, "coni gemini," which might be compared in shape to two cylinders applied to each other length-
wise. Both kinds of bodies are attached by one extremity to the inner surface of the choroid, being received
into exceedingly minute sheaths, which rise from the surface of the pigment cells. 2. The filaments of the
optic nerve spread out on the inner surface of this structure, and, according to Valentin, have a plexiform ar-
rangement, but their mode of termination seems doubtful. This nen-ous expansion is covered on its outer and
also on its inner surface by a layer of ganglionic globules.]
t [The vitreous humour, according to Ilerzelius, contains 98'4 per cent, of water ; its solid matter consists
of albumen, extractive matter, and chloride of sodium.]
662 NEUROLOGY.
a circular layer, having the form of a radiated crown, is given off from the anterior part
of the hyaloid membrane ; this circular radiated disk w^as described by Petit and Cam-
per, but it is called the corona ciliaris, or the zonula Zinni : it corresponds accurately to
the ciliary processes and ciliary body of the choroid coat.
The ciliary zone of Zinn (a, Jig. 245, b, figs. 247, 248), or the ciliary processes of the vit-
Fig.m. reous body, can be seen through that transparent body {d,fig. 241)
when the several coats are removed from the back part of the
globe of the eye : it is completely exposed to view when the cho-
roid coat and the iris are separated from the vitreous body {fig.
248). It is this structure which constitutes the beautiful radiated
crown situated in front of the vitreous body around the crystalline
lens, and which extends considerably beyond the ciliary body of
the choroid ; it consists of alternate black and transparent rays,
and is generally regarded as a reverse impression of the ciliary
processes of the choroid. The ciliary processes of the vitreous
body correspond to the black lines, and the intervals between the
processes to the transparent rays.
The ciliary processes of the vitreous body are not so thick as those of the choroid ;
but the folds of which they consist commence farther back than the ciliary processes of
the choroid, so that the radiated disc formed by them is larger than that formed by the
processes of the choroid. These folds of the vitreous body have the same spongy and
jagged appearance as those of the choroid : they have no free portion, or, rather, that
part of the zone of Zinn (a, fig. 248) which corresponds to the free portion of the ciliary
processes of the choroid is applied to the crystalline lens.
The cihary processes of the choroid and those of the vitreous body are so arranged
that those of the one are received in the intervals between those of the other. It ap-
pears to me difficult to determine whether they are simply applied to each other, or
whether their structure is continuous. However, on examining these parts through a
lens while they are being separated, it has appeared to me that a sort of cellular struc-
ture was lacerated, and that the black pigment, which had been hitherto confined, es-
caped together with a little fluid. M. Ribes believes that, during this separation, some
shreds of the hyaloid membrane are drawn away with the ciliary processes of the choroid.
The inner border (a) of the cihary zone of Zinn is in contact with the margin of the
crystalline lens (/), and adheres rather firmly to it. Around the outer border, which ex-
tends beyond the ciliary body of the choroid, are found the origins of certain radiated
folds (i), which form, as it were, the commencement of the ciliary processes. This bor-
der adheres to the anterior margin of the retina {m, fig. 245), which appears to me to be
thickened and shghtly uneven in this situation, and not to be continuous with the hya-
loid membrane.
From what has been stated, it follows that the canal of Petit is formed between the
hyaloid membrane and the zone of Zinn, and that the crystalline lens is fixed by this
zone to the anterior margin of the vitreous body ; that the anterior surface of the crys-
talline lens is not covered by a prolongation of the hyaloid membrane, besides its own
capsule ; and that the retina does not reach as far as the margin of the crystalline lens.
M. Jules Cloquet has described, under the name of the hyaloid canal, a cylindrical pas-
sage, which is formed by the reflection of the hyaloid membrane into the interior of the
vitreous body around the nutritious artery of the lens, and which, like that artery, trav-
erses the vitreous body from behind forward. I have never been able to see this canal.
No vessels have been demonstrated in the hyaloid membrane ; it does not receive
any from the retina, and yet we cannot doubt that it is provided with them. Although
the structure of the ciliary processes of the vitreous body is little known, yet, as it is
probable that it is similar to that of the ciliary processes of the choroid, and, therefore,
essentially vascular, it may be, as stated by M. Ribes, that the materials for the forma-
tion and nutrition of the lens and of the ciliary processes of the vitreous body are con-
veyed to both of these parts through the vascular ciliary processes of the choroid.
The Crystalline Lens and its Capsule.
The crystalline lens {I, figs. 241, 244, 245, 248) is a transparent body, having the form
of a lens, as its name implies ; it is situated at the junction of the posterior three fourths
with the anterior fourth of the globe of the eye, and is placed between the vitreous body,
which is behind, and the aqueous humour, which is in front {see fig. 241).
Its axis corresponds to the centre of the pupil.
It is shaped like a double convex lens, the posterior surface of which is more convex
than the anterior. From some very exact and minute investigations which have been
made upon this point by Fran5ois Petit and others, it appears that both the relative and
the absolute convexity of the two surfaces of the crystalline lens are subject to great
varieties in different individuals ; that, in general, the posterior convexity forms part of
a circle from four to five lines in diameter, while the anterior forms part of one from six
to nine lines in diameter. In some subjects the degree of curvature of the two surfaces
THE CRYSTALLINE LENS AND ITS CAPSULE. 668"
of the crystaDine lens is almost equal. In the foetus the crystalline lens approaches the
spheroidal form, which is that which it has in fishes.
The anterior surface of the crystalline lens corresponds to 'the iris, from which it is
separated by the aqueous humour. It has been incorrectly stated by Winslow that the
crystalline lens pushes the iris forward : there is a space between the crystalline lens
and the iris which constitutes the posterior chamber of the eye. The anterior surface
of the lens may be seen through the pupil, so that slight shades of difference in the col-
our of the lens may be detected. When the pupil is very much dilated, the anterior sur-
face of the lens is entirely exposed.
Its posterior surface is in relation with the vitreous body, which is depressed so as to
receive it. This surface does not adhere to the hyaloid membrane. When dissecting
a subject of twenty-seven years of age who had suffered with hydrophthalmia in both
eyes, M. Ribes found about six grains of a limpid fluid between the hyaloid membrane
and the crystalline lens ; so that the space occupied by tliis fluid might have been taken
for a third chamber.
The margin of the lens {I, fig. 248) is set (like the stone of a brooch) in the ciliary pro-
cesses (a) of the vitreous body, which cover and adhere to the fore part of that margin,
so that the lens is kept firmly in its place. Its margin is surrounded by the canal of
Petit {fig. 247).
The crystalhne lens presents different shades of colour at different periods of life. It
is reddish in the foetus, but is perfectly transparent after birth ; in the adult, it becomes
slightly opaline at the centre ; in the aged, it acquires a yellowish opacity, which ap-
proaches somewhat to the colour of amber or topaz. Morbid opacity of the lens consti-
tutes lenticular cataract.
The crystalline lens consists of a capsule, and of a proper substance enclosed within it.
The Substance of the Crystalline Lens. — When stripped of its capsule, the crystalhne
lens is found to have three degrees of consistence, at different parts : thus, at its sur-
face, it is almost of a liquid softness ; below this, it is soft and gelatinous, and may be
crushed by the finger — this is the cortical layer ; and, lastly, it is hard in the centre, which
is called the nucleus, and closely resembles a mass of gum-arabic. The most superficial
and fluid layers constitute the liquor Morgagni.
The substance of the crystalline lens consists of concentric layers {b c, Jig. 249), which
can be very easily demonstrated, even
without any previous preparation, but
are rendered most distinct by boiling,
or immersion in a diluted acid. The
crystalline lens then separates into su-
perimposed laminae or scales, like the
bulb of the onion.
The different degrees of consistence
observed in the substance of the lens
do not depend upon differences in na-
ture, but upon mere modifications. When hardened by an acid, the structure of the lens
is exactly the same throughout : even the liquor Morgagni appears to become laminated.
Each of these concentric lamina; is itself composed of radiated fibres (a. Jig. 249),
which can be readily seen without dissection, by placing one of them upon a black sur-
face, and examining it through a lens, or even by a strong Ught.
Lastly, the crystalline lens, when boiled, or submitted to the action of an acid, splits
into three, four, or even a greater number of triangular segments (ab), all of which unite
by their summits at the centre of the lens, so that its anterior and posterior surfaces
have a stellate appearance.* Pathologists have successfully applied this anatomical
fact to the explanation of the stellate forms of cataract, in which the opacity branches
out in three or more directions.
What is the nature of the crystalline lens 1 Is it the product of a secretion 1 or is it
an organized structure 1 M. Duges has recently supported by his authority and by ad-
ditional facts the opinion of Dr. Young, who believed that the crystalline lens is not only
an active organized structure, supplied with vessels and veins, but that it is even mus-
cular and possessed of contractility, so as to be able of itself to increase or diminish its
curvatures and its density, thus endowing the eye with the power of adjusting itself to
the different distances %f the objects to be seen. The substance of the lamina; of the
crystalline lens has, indeed, a linear structure ; but it does not at all resemble muscular
tissue, either in its consistence or in its regularly stratified character. I conceive,
therefore, that I am warranted in regarding the superimposed layers of the crystalline
lens as the solidified product of a secretion formed by its capsule, t
* See note, infrd.
t [The lines indicating- the divisions between the triangular segments of the lens (a, Jig- 249) are called sep-
ta; the septa of the anterior surface are placed opposite the intervals between the septa of the posterior sur-
face. The fibres of which the laminie are composed have a linear arrangement, and, as discovered by Sir D.
Brewster, are fitted into each other by indented margins {Jig. 250). Schwann has shown that those fibres
are developed from rounded, nucleated cells, which become elongated into fibres, the margins of which sub-
The capsule of the crystalline lens (jt,fig- 241) is accurately fitted to the lens itself; iff
the healthy state it is transparent, but may become opaque, and thus constitute a mem-
branous or capsular cataract.
Its external surface is free in front, where it is bathed by the aqueous humour : it is
merely in contact with the hyaloid membrane behind, but its circumference adheres in-
timately to that membrane, or, rather, to the ciliary zone of Zinn.
Its internal surface does not appear in the slightest degree adherent to the lens. If
an incision be made into this capsule in the living subject, the lens is forced out merely
by the tonicity of the coats of the eye. The anterior segment of the capsule is twice as
thick as the posterior : it might be compared to a layer of the cornea,*
It receives bloodvessels derived from the arteria centralis retinae. t These vessels,
according to Meckel, are distributed only upon the posterior half of the capsule ; those
which belong to the anterior half arise from the vessels of the ciliary processes.
Some anatomists believe that these vessels send ramifications between the different
concentric laminae of the crystalline lens for its nutrition ; but I am not aware that they
have ever been demonstrated.
No nerves have been discovered in the crystalline lens. M. Duges believes that the
retina gives off some net vous filaments which reach as far as the lens, and spread out
upon its capsule ; but, after the most careful examination, I am convinced that such is
not the case.
The Aqueous Humour and, its Membrane.
The term aqueous humour is applied to a perfectly limpid and transparent fluid, which
occupies the two chambers of the eye. These two chambers, which have been correctly
understood only since the discovery of the true seat of cataract in the crystalline lens,
correspond to that small portion of the cavity of the eye which is situated between the
cornea and the lens {see fig. 241). The space between these two parts is divided un-
equally by the iris (i) into two chambers : an anterior and larger, which is called the an-
terior chamber; and a posterior and smaller, named the -posterior chamber. These two
chambers communicate through the pupil (jpi). The existence of the posterior chamber
was long disputed, but it may easily be proved by freezing the eye ; and by the same
experiment we may obtain an approximation to the relative capacity of the two cham-
bers, which will be found as 3 to 1, the anterior being decidedly the larger.
The total quantity of the aqueous humour is about five grains ; 100 parts of it are
found to contain 981 of water, with traces of albumen and chloride of sodium.
The Membrane of the Aqueous Humour. — It is now generally admitted that the aqueous
humour is secreted by a special membrane, called the membrane of the aqueous humour, or
membrane of Demours, although it had been previously described by Zinn and Descemet.
This membrane, according to Demours, hues the posterior surface of the cornea {m,fig.
241), and is reflected upon the front of the iris. At this point, according to most anat-
omists, it is lost, and cannot be traced to the pupil ; but, according to others, it proceeds
as far as the pupil, and there terminates ; and, lastly, some believe that it is reflected
through the pupil, in order to cover the posterior surface of the iris, where it retains the
pigment in its situation.
It is easy to detach a tolerably thick and strong layer, of a cartilaginous aspect, from
the posterior surface of the cornea, either after long-continued maceration, or after slight
boiling ; but it is not shown that this is anything more than the posterior layer of the
cornea, which it resembles in appearance.
It is only from analogy that the existence of the membrane of the aqueous humour
can be admitted.
We cannot demonstrate anatomically its reflection upon the outer border of the iris ;
and, moreover, it is certain that it does not exist upon either surface of that membrane.
According to M. Ribes, the aqueous humour is supplied by the vitreous body, and is
poured into the posterior chamber by the canals said by him to exist in the substance of
the ciliary processes of the vitreous body. This opinion is founded, 1. Upon an exper-
iment which consists in carefully removing the cornea, and suspending the eye by the
optic nerve, when the vitreous humour will exude from the wound of the cornea, so that,
in less than twenty-four hours, two thirds of that body will have escaped ; and, 2. Upon
the observation of cases of imperfect iris, in which, according to M. Ribes, the aqueous
Fig. 250. •
— - sequently become dentated ; the lens, therefore, resembles some other non-vascular parts
(as the horny tissues) in its mode of growth. It consists, according to Berzelius, of 58"0
per cent, of water, 3'7 of extractive and salts, 2'4 of membrane, and 35"9 of a peculiar
Bubstanee, which, except in its colour, resembles the colouring matter of the blood.
* According to M. Ribes, whom I always have pleasure in quoting, btcause his re-
searches are worthy of every confidence, " by examining the internal surface of the crys-
talUne capsule in a good light, and with a good lens, a series of transverse fissures are
observed around its entire circumference, where the anterior and posterior segments of
the capsule unite. I could never satisfy myself whether these fissures corresponded to
the ciliary processes of the vitreous body, or to the villous fringes of the ciliary processes
of the choroid."
T Vide fig. v., pi. 6, of Soemmering's Icones Oculi Humani.
THE ORGAN OP HEARING.
Bnrhdur is contained entirely in the posterior chamber. He believes that the free por-
tion of the vitreous ciliary body has the power of absorbing this liquid.
M. Duges adopts the following modification of this opinion : the canal of Petit, accord-
ing to him, is divided into as many compartments as there are ciliary processes. It re-
sembles, therefore, a collection of short canals directed from before backward, rather
than a single circular canal ; these short canals communicate behind with the vitreous
body, and open in front by certain slits or perforations existing in the Zone of Zinn, which
enable the aqueous humour secreted by the vitreous body to escape in front of the crys-
talline lens.
Haller has stated all the opinions which have been entertained regarding the produc-
tion of the aqueous humour, which has been said to be secreted by the vitreous body,
as believed by MM. Ribes and Duges, by the ciliary processes, by the choroid, by the
iris, and, lastly, by certain special ducts proceeding from without the eye, and perfora-
ting the sclerotic at its junction with the cornea.
The Vessels and JVerves of the Eye.
The arteries of the eye are the following : a considerable number of short posterior cil-
iary arteries, which surround the optic nerve, perforate the sclerotic near it, and ramify
in the choroid, m the ciliary processes, and in the iris ; the anterior short ciliary, which
perforate the anterior part of the sclerotic, and are distributed to the iris ; the long cilia-
ry arteries, two in number, which run between the sclerotic and the choroid, as far as
the outer border of the iris, and then, bifurcating and curving inward, anastomose with
each other around that border. From the vascular circle thus formed most of the ves-
sels of the iris are given off. The central artery of the retina {arleria centralis retina) en-
ters the globe of the eye through the centre of the optic nerve (at the porus opticus, b,
fig. 246), and, sending off a branch to the crystalline lens, which traverses the vitreous
body from behind forward, covers the internal surface of the retina with its other rami-
fications.
The veins correspond to the arteries, but are much more numerous. The posterior,
or short ciliary veins, form vortices or whorls in the choroid, and are hence called vasa
vorticosa (v, fig. 244). All the veins of the globe of the eye open into the ophthalmic and
angular veins.
The nerves of the eye consist of a special nerve called the optic nerve, the origin, course,
and structure of which will be described hereafter (see Cranial Nerves) ; and, second-
ly, of the ciliary nerves, which are derived from the fifth nerve, either directly from its
nasal branch, or indirectly from the ophthalmic ganglion. These nerves (a a, fig. 242)
are distributed to the ciliary ligament, and to the iris.
The Organ of Hearing
Hearing is that sense by which we perceive the vibrations of the air, which produce
tound.
The organ of hearing is not situated in the face, like those of the other senses, but is
contained in the substance of the base of the cranium, in the petrous portion of the tem-
poral bone, its deep situation preserving it from external violence : it is composed essen-
tially of a membranous and nervous apparatus contained in an extremely complicated
osseous cavity, named the labyrinth or internal ear.
The labyrinth if, fig. 251) communicates with the exterior by means of an acoustic
trumpet formed by the auricle, or pinna (a), and external audita- p^g 251.
ry meatus (b), and named the external ear, which may be regard-
ed as an apparatus for collecting sonorous undulations.
The term middle ear, or tympanum, is applied to a cavity (d)
which is placed between the labyrinth and the external ear, and
may be considered as an apparatus for modifying sounds, the
intensity of which is increased or diminished by it, according
as they happen to be weak or loud.* It follows, therefore, that
the ear is formed by a succession of cayities, which, proceed-
ing from without inward, are, the external ear, consisting of
the auricle and external auditory meatus, of the middle ear, or
tympanum, and of the internal ear, or labyrinth. I shall de-
scribe the ear in this order, and shall thus proceed from the less to the more complica-
ted parts of this organ.
The External Ear.
The exiexnal ear resembles a funnel or ear-trumpet, the expanded part of which rep-
resents the auricle, while the contracted portion corresponds to the external auditory
meatus. +
* M. Richerand (Elemens de Physiologie, first edit.) has drawn an excellent comparison lictween the uses of
the tympanum in hearing-, and those of the iris in vision.
1 The external ear, properly speaking, only exists in mammalia- and eren among- mammalia, those -which
do not hve constantly in the air are not proirjded with it.
4P
NEUROLOGY
The Auricle.
The auricle of the ear {auricula, 'pimia), commonly called the ear, is placed at the side
of the head, behind the articulation of the lower jaw, and in front of the mastoid process ;
it is an oval elastic lamina, folded in various ways upon itself, and having an undulated
surface.
The auricle or pinna is free above, behind, and below, but is so firmly attached in front
and on the inner side, that the two ears can support the weight of the entire body.
The individual varieties in the shape, direction, prominence, and size of the auricle
are generally known. Of these varieties, some are congenital, and others acquired.
Among the latter should be noticed the effects produced by the habit of confining the
entire ear more or less closely by the head-dress. The direction or prominence of the
auricle is not without some influence upon hearing, the perfection of which sense, ac-
cording to Mr. Buchanan, depends on the kind of angle formed by the auricle with the
side of the face, and which should be from 25° to 30°.
The internal or mastoid surface of the auricle presents certain eminences and depres-
sions, which correspond inversely with those on its external surface.
The external surface is remarkable for the alternate ridges and depressions observed
Fig. 252. upon it : at its centre, but somewhat nearer to the lower than the up-
per part, we find the concha (a, fig. 252), a funnel-shaped excavation,
the form and expansion of which are familiar to all, and at the fore
part of the bottom of which is found the orifice of the external audito-
ry meatus.
The concha is bounded in front by the tragus {h ), a triangular pro-
cess, the adherent base of which is turned forward and inward, while
iM^n~JljiS^ its free apex is directed backward and outward : it advances like a
lid over the orifice of the external auditory meatus, which is com-
pletely closed by its depression. The posterior surface of the tragus,
which forms part of the concha, is covered with stiff hairs, especially
in old subjects ; whence its name of tragus, from rpdyog, a goat. The
use of these hairs is to arrest any small particles that are floating in the air.
Behind and below, that is, opposite the tragus, the concha is bounded by the anti-tra-
gus (c), a triangular tongue, which is smaller than the tragus, and is separated from it
by a wide, deep, and rounded notch, named the notch of the concha (incisura tragica).
Behind and above, the concha is bounded by the anti-helix (e), a curved fold, which
commences above the anti-tragus, being separated from that part by a slight depression,
passes upward and forward, bifurcates, and then ends in the groove of the helix. The
superior branch of the bifurcation of the anti-helix is broad and smooth, while the inferi-
or is sharp ; between them is situated a slight depression, called the scaphoid, or navicv^
lar fossa, but which would be more correctly named Vae fossa of the anti-helix (/).
The term helix {ili^, a roll, from kTiiacu, to roll around) is applied to a curved fold
{g g), which forms the external border of the auricle : it commences in the cavity of the
concha, which it divides into two unequal parts, one superior and narrow, the other in-
ferior and broader ; gradually increasing in size, it then passes upward and forward above
the external meatus, then above the tragus, from which it is separated by a very distinct
furrow : it next runs directly upward, curves backward, descends to form the posterior
margin of the auricle, and terminates by becoming continuous with the anti-helix in
front, and with the lobule {I) behind.
The groove or furrow of the helix is the groove (i) which surrounds the helix, and sep-
arates it from the anti-helix.
The lobule occupies the lower or small extremity of the auricle, from the rest of which
it is distinguished by its softness ; it is surmounted by the tragus in front, by the anti-
tragus behind, and by the notch of the concha in the middle. The lobule of the ear va-
ries exceedingly in size in different individuals, and is the part to which ear-rings are
generally appended.
The Structure of the Auricle. — The cartilage of the ear {figs. 253, 253*) constitutes the
Fig. 253.
Fig. 253.*
framework of the auricle, in a great measure deter-
mines its shape, and is the cause of its phability and
elasticity.
When the skin is removed from it, this cartilage,
therefore, presents certain eminences and depressions,
corresponding, with some exceptions, to those already
described as existing upon the surface of the auricle.
The cartilage of the ear has no part corresponding with
the lobule : again, the cartilaginous fold which consti-
tutes the helix terminates at the middle of the concha,
from whence it is continued by a fold of skin, which,
moreover, covers it throughout, and increases its prominence. Upon the cartilage of the
auricle we also observe the following parts : 1. A mammillated eminence {a, fig. 253V
THE AURICLE. 667
called the p-ocess of the helix : it is of considerable size, is very dense, and arises from
the anterior margin of the helix, above the tragus. This process gives attachment to a
ligament.
2. A tail-shaped tongue of .cartilage (5), separated from that of the anti-tragus and
concha by a very long fissure, which is occupied by ligamentous fibres. This tongue is
formed by the united ends of the helix and anti-helix, and is very thick and dense :
it may be called the caudal extremity of the helix and anti-helix ; it supports the base of the
lobule.
3. A well-marked thickening, situated opposite the concha, and characterized by a
dead white colour. This thickening occupies a vertically elongated portion of the mas-
toid surface of the concha, and terminates at the lower part of the auricular cartilage :
it seems to be intended to preserve the form of the concha, which cannot be flattened
unless this thickened portion of the cartilage is first divided. Several fissures or notch-
es are also found in the cartilage of the ear, which is thus imperfectly divided into sev-
eral pieces that are movable upon each other, and united together by ligaments. The
principal fissure, independently of that already described as existing between the anti-
tragus and the caudal extremity of the helix and anti-helix, are, a small vertical fissure
upon the anterior margin of the heUx ; another vertical fissure upon the tragus ; several
irregular notches in the helix ; and, lastly, a much more important fissure, to which I
shall have to allude in describing the external auditory meatus. It is situated between
the helix and the tragus, and is prolonged upon the outer half of the orifice of that meatus.
The skin of the auricle is remarkable for its thinness and transparency : hence the
sub-cutaneous vascular network can be seen through it without dissection ; it is no less
remarkable for its tension, and its close adhesion to the cartilage, upon which it is mould-
ed, so as accurately to reveal its form. The portion of skin which covers the concha is
especially remarkable for its great tenuity and intimate adhesion to the cartilage.
The skin upon the free border of the auricle adheres but slightly to, and projects be-
yond the helix ; the same fold of skin, when doubled upon itself and prolonged below the
helix, constitutes the lobule, which, together with the adjacent part of the free border
of the auricle, is nothing more than a duplicature of the skin, containing some soft fat.
A small quantity of fat is formed around the entire circumference of the auricle, but
none exists in other situations.
The skin of the ear is provided with sebaceous folhcles, which can be easily shown by
maceration, after the method employed by Soemmering, and which are most numerous
in the concha and the scaphoid fossa.
The ligaments of the auricle are divided into the intrinsic and the extrinsic ligaments.
The extrinsic ligaments are, the posterior ligament, which is a thick, tendinous layer, ex-
tending from the concha to the mastoid process ; the anterior ligament, which is a triangu-
lar, very broad, and very strong hgament, arising from the process of the helix and the ad-
jacent part of the border of the helix, and terminating at the zygomatic arch, where it is
blended with the superficial temporal fascia ; and, lastly, the ligament of the tragus, which
is very strong, and extends from the tragus to the adjacent part of the zygomatic arch.
The intrinsic ligaments, the object of which is to keep the cartilage of the auricle fold-
ed upon itself, are, the ligament which keeps the caudal extremity of the helix applied
to the concha ; the very strong ligament which extends from the tragus to the helix, and
. unites the outer half of the auditory meatus to the cartilage of the auricle ; some very
strong bundles, which are situated upon the mastoid surface of the auricle, and are in-
tended to preserve its convolutions, for when they are divided the auricle may be un-
folded ; lastly, those most remarkable ligamentous bundles, which occupy the fold pre-
sented by the inferior branch of the bifurcation of the anti-helix.
The three extrinsic muscles of the ear, which exist in a rudimentary condition in the
human subject, but are so highly developed in timid animals, are intended to move the
auricle as a whole (see Myology).
The intrinsic muscles move the different parts of the auricular cartilage upon each oth-
er. Like the extrinsic, they are quite rudimentary. There is no difference in their size
in savage and civilized races. They are five in number, four of them being situated on
the concave, and one only on the convex, or mastoid surface of the auricle.
The great muscle of the helix (helicis major, c, fig. 253) is situated vertically upon the
anterior part of the helix, near the tragus ; it is a narrow, oblong tongue, fleshy in the
middle, and tendinous at its extremities ; its fibres are vertical.
The small muscle of the helix (helicis minor, d), the smallest of the intrinsic muscles of
the ear, lies upon that portion of the helix which divides the concha into two parts.
The muscle of the tragus (tragicus, e) is a broad band, lying upon the external surface
of the tragus ; its fibres are directed vertically.
The muscle of the anti-tragus (anti-tragicus,/) is a tongue-like bundle, which covers
the external surface of the anti-tragus, and is inserted by a tendon to the upper part of
the caudal extremity of the helix. Its use may be to move this caudal extremity upon
the anti-tragus.
The fifth is the transverse muscle (transversus auriculae, a, fig. 353*), which is situated
4
NEUROLOGY.
on the mastoid surface of the auricle. According to Soemmering, it consists of a trans-
verse layer of fibres of unequal length, which spread out in a semicircular form from the
convexity of the concha to the ridge, corresponding to the groove of the helix. I doubt
the muscularity of these fibres, which I am inclined to regard as constituting an intrin-
sic ligament intended to preserve the fold of that portion of the anti-helix by which the
concha is bounded behind and above.
The arteries of the auricle are the posterior auricular, a remarkable branch of which
passes through the cartilage, between the caudal extremity of the helix and the concha,
so as to ramify in the cavity of the concha. All the branches of the posterior auricular
arteries turn over the free border of the helix, so as to reach the concave surface of the
auricle. The anterior auricular arteries arise from the external carotid and the tempo-
ral, and divide into inferior branches or arteries of the lobule and ascending branches.
The vei7is have the same names and follow the same course as the arteries.
The nerves of the auricle are derived from the auricular branch of the cervical plexus ;
three or four of them ramify upon the internal surface of the auricle. A remarkable branch
perforates the cartilage between the anti-tragus and the caudal extremity of the helix,
and is distributed to the skin which lines the concha.*
The External Auditory Meatus.
The external auditory meatus {b,fig. 251) is a partly cartilaginous and partly osseous
canal, extending from the concha (a) to the membrane of the tympanum (c). It fonns the
narrow portion of the ear-trumpet represented by the external ear.
It is about an inch in length. Its section represents an ellipse, of which the longest
diameter is vertical. Its direction is transverse, and it describes a very slight curve,
having its convexity turned upward. Moreover, near its external orifice it is bent at an
angle which projects upward, and hence it is necessary to draw the auricle upward and
backward, if we wish to examine the bottom of the external auditory meatus.
The external meatus is in relation with the temporo-maxillary articulation in front,
with the mastoid process behind, and with the parotid gland below.
Its external orifice, which is vertically oblong, more or less widened out in different in-
dividuals, and covered with hairs in old age, occupies the anterior and inferior part of
the concha behind the tragus, which serves as a lid for it. It is bounded behind by a
sort of semilunar ridge, which projects more or less forward in different individuals, so
as to contract its orifice to a greater or less extent. In front of the auditory meatus
there is an excavation or fossa concealed by the tragus, and named the tragic fossa of
the co7icha ; it forms, as it were, the vestibule of the meatus.
The internal orifice of the auditory meatus is circular : it is directed very obliquely
downward and inward, and is closed by the membrana tympani.
Structure. — The auditory meatus consists of an osseous portion, and of a cartilaginous
and fibrous part.
The osseous portion has been already described with the temporal bone, as the external
auditory meatus. It is wanting in the foetus, and in the new-born infant, in whicli its
place is supplied by the tympanic ring or circle. We have stated that, in the adult, this
ring forms an osseous lamina distinct from the rest of the temporal bone, that it rests
behind upon the mastoid and styloid processes, for the latter of which it forms the vagi-
nal process, and that it is separated in front from the auricular portion of the glenoid
cavity by the fissure of Glasserius ; this lamina forms both the anterior and inferior walls
of the auditory meatus and cavity of the tympanum.
The cartilaginous and fibrous portion forms the outer half of the external auditory mea-
tus, and may be separated from the cartilage of the auricle by a careful dissection. If
an incision be made over the similunar ridge which constitutes the outer border of the
orifice of the auditory meatus, it will be seen that this ridge is formed by the juxtaposi-
tion of two cartilaginous borders, one of which belongs to the concha, and the other to
the auricle, and which are united by fibrous tissue. If the dissection be continued be-
tween the tragus and the corresponding part of the helix, the auricle may be separated
from the auditory meatus, exceping below, where their continuity is established by means
of a tongue or isthmus of cartilage.
The tragus belongs essentially to the auditory meatus, the cartilage of that canal being
merely a prolongation of the tragus folded upon itself (see b,fig. 253*), so as to form- the
lower two thirds or three fourths of a cylinder. The inner end of this imperfect cylin-
der is attached to the rough external rim oi the osseous portion of the meatus by means
of a fibrous tissue, which extends farther above and behind than below and in front, and
which gives the cartilage a great degree of mobility ; there is a thick prolongation or
process at the lower and anterior part of the inner end of the cartilage of the meatus.
The fibrous portion of the auditory meatus forms the upper third or fourth of that canal,
and also fills up the large notch in the inner end of the cartilaginous portion.
* [The auricle also receives twigs from the posterior auricular branch of the facial nerve, from the auriculo-
temporal branch of the inferior maxillary division of the fifth nerve, and from a small branch of the pneumo-
fastric nerve. See description of those nerves.]
THE TYMPANOM.
Near the tragus there are two or three fissures or divisions in this cartilage, named
the fissures of Santorini, which give it some resemblance to the rings of the trachea :
these fissures are at right angles to the length of the canal, and are filled up with a
fibrous tissue, which some anatomists have conceived to be mixed with muscular fibres,
or to consist entirely of muscular fibres intended to move the small and partially separa-
ted portions of the cartilage. It is evident that the mode in which the partly cartila-
ginous and partly fibrous portion is united with the osseous portion of the canal, and also
the existence of the fissures just described, have reference to the mobility of the entire
canal.
The internal surface of the auditory meatus is lined by a prolongation of the shin,
which is remarkable for its extreme thinness. It becomes thinner and thinner in ad-
vancing from the orifice to the bottom of the meatus ; and the fineness and extreme del-
icacy of that portion of the skin which corresponds to the osseous part of the meatus
deserves special attention. The skin of the meatus is also characterized by being cov-
ered in all parts with fine downy hairs ; a fact which proves that it is of a cutaneous
structure, and not a mucous membrane. In old subjects, there are some tolerably long
hairs at the commencement of the auditory meatus, as well as upon the internal surface
of the tragus ; they prevent the entrance of dust and insects, which, moreover, get in-
volved in the ceruminous secretion.
The skin of the meatus is farther characterized by the presence of a number of se-
baceous follicles, or glands, called the ceruminous glands,* the orifices of which are vis-
ible to the naked eye, and give the skin an areolar appearance. These small glands oc-
cupy the entire inner surface of the cartilaginous and fibrous portions of the auditory
meatus : from their yellowish-brown colour, they can be readily seen in oblique sections
of the skin. They secrete a rather thick unctuous substance, resembling wax, whence
it is called cerumen {cera, wax). It is very bitter, and is partially soluble in water, with
which it forms an emulsion which leaves a greasy stain upon paper ; it sometimes be-
comes exceedingly hard from remaining long in the passage, and then acts as a mechan-
ical cause of deafness. By analysis, this substance, according to Berzelius, yields a
fatty oil, an albuminous substance, and a colouring matter, and, according to Rudolphi,
a bitter principle like that of the bile. Nature intended, says Soemmering, that there
should be a sufficient quantity of cerumen, not only to keep out insects, but also to di-
minish the intensity of sonorous vibrations. It is, therefore, a bad habit to remove it
artificially, unless there be an abnormal accumulation of this substance.
The Middle Ear, or Tympanum.
Dissection. — The cavity of the tympanum may be laid open, either from its external
wall, by removing the membrana tympani, or from its upper wjdl, by cutting away the
anterior part of the base of the petrous portion of the temporal bone with a strong scal-
pel ; the situation in which this may be done is indicated by a fissure, or, rather, a su-
ture, which exists between the petrous and squamous portions ; lastly, the tympanum
may be opened from its lower M^all, by breaking down the osseous plate of the auditory
meatus.
In order to show all the parts contained in the cavity of the tjTnpanum, several speci-
mens should be prepared in different ways. It is of importance, moreover, to study the
ear in the temporal bones of the adult subject and the fcetus, as well in macerated speci-
mens as in such as have been dried without previous maceration.
The tympanum, tympanic cavity, or drum of the ear {tympanum, a drum, d, fig. 251), is
a cavity situated between the external auditory meatus (b) and the labyrinth or interned
ear (/) ; it communicates with the pharynx, and, consequently, with the air-passages,
by means of the Eustachian tube (e, fig. 255) ; it is prolonged into the mastoid process,
by means of the mastoid cells (c), and it is traversed by a chain of small bones (1, 2, 3),
neuned the ossicula audittis.
The tympanum is placed in the anterior part of the base of the petrous portion of the
temporal bone, above the osseous lamina of the external meatus, and in firont of the
mastoid process ; it is directly continuous with the osseous portion of the Eustachian
tube, of which it seems only to be a dilatation.
From its form, which is otherwise irregular, or, rather, from the two dry membranes
formed upon its opposite walls, it has been compared to a military drum ; it is flattened
from without inward, so that its transverse diameter is the shortest. It presents for our
consideration an internal and an external wall, and a circumference.
The External Wall of the Tympanum. — This wall is formed by the membrana tympani,
and by that portion of the temporal bone in which the membrane is fitted. This portion
of the temporal bone is a compact lamina, which is flat in the human subject, but ex
tremely prominent in some animals.
The membrana tympani {c,fig. 251) is a nearly circular, semi-transparent membranous
septum, dry-looking like parchment, and vibratile ; it is situated between the external
* [The ceruminous glands consist of a long- conToluted tube, closed at one end, and opening by the other
upon the internal surface of the meatus.]
NEUROLOGY.
auditory meatus, at the bottom of which it may be seen in the living subject, and the
cavity of the tympanum. It is directed very obliquely downward and inward ; so that,
instead of passing perpendicularly across the auditory meatus, it is continuous, at a
very slight angle, with the upper wall of that canal. In consequence of this obliquity,
the membrana tympani unites with the lower waU of the meatus at an angle of about 45°,
and the meatus itself terminates in such a manner that its lower wall is much longer
than the upper.
The external surface of the membrana t)mipani is free, and is directed downward and
outward ; the internal surface is turned upward and inward, and adheres very firmly to
the handle of the bone of the ear, called the malleus, by which it is drawn inward, so
that its centre presents a funnel-shaped depression, which is concave externally and
convex within. The circumference of the membrane is fitted, like a watch-glass, into a
circular furrow formed at the inner end of the external meatus in the adult, and into the
tympanic ring in the foetus. Above and behind, near its insertion into its bony frame, the
membrana tympani is elevated by a small process (the short process) of the malleus.
Immediately on the inner side of the insertion of the membrana tympani, opposite the
posterior extremity of a line drawn across its middle, is situated a small foramen, the
orifice of a canal which transmits the chorda tympani nerve.
Is the membrana tympani perforated 1 Some anatomists have asserted that there is
an aperture between the membrane and the bone, at one point of its circumference ; and
others have believed that an oblique slit traverses the membrane. But these perfora-
tions do not exist in the natural state ; so that the membrana tympani forms a complete
septum between the tympanum and the external auditory meatus.
Notwithstanding its tenuity and transparency, the membrana tympani consists of three
very distinct layers. The external or epidermic layer is a prolongation of the epidermic
portion only of the skin which lines the external meatus.
The internal or mucous layer is a prolongation of the extremely thin mucous mem-
brane which lines the tympanum. The handle of the malleus is situated between this
and the middle layer.
The middle or proper layer, on which the strength of the membrane depends, appears
to be of a fibrous nature. According to Sir Everard Home, it is muscular ; he states
that he distinctly saw muscular fibres radiating from the centre to the circumference,
first in the elephant, and afterward in the ox, and in the human subject.*
By fine injections some very delicate vessels are demonstrated in the membrane.
The network represented by Scemmering, who only injected the arteries, is not nearly
so dense as that which may be displayed by filling the veins. If a blue injection be
thrown into the jugular vein of the foetus, the whole membrane will become of that col-
our, and will present an exceedingly fine vascular network under a lens. In a new-born
infant, which had died with inflammation of the tympanum, the membrane was found
quite red. The bloodvessels appear to be situated entirely in the internal layer ; they
run from the circumference towards the centre of the membrane ; and this arrangement
has probably led to the supposition of the existence of radiated muscular fibres.
The use of the membrana tympani is to transmit the sonorous vibrations received
through the external auditory meatus to the air contained within the tympanum, and to
the ossicula of the ear. Its obliquity, besides increasing the dimensions of this vibratile
membrane, has certainly some use in the reflection of sonorous vibrations. As it ad-
heres to one of the chains of small bones of the ear, it is influenced by their movements ;
and in this way it maybe either stretched or relaxed.
The Internal Wall of the Tympanum. — The inter-
nal wall of the tympanum {figs. 254, 255), which is
perfectly exposed when that cavity is opened from its
external wall, presents a great number of objects for
our consideration. At its upper part is situated the
fenestra ovalis if, fig. 254), the long diameter of which
is directed transversely, but rather obliquely down-
ward and forward ; the upper border of this fenestra
if, fig. 258) is semi-elliptical, while the lower border
is straight, or, rather, it projects somewhat into the
opening. The fenestra ovalis, called also the vestib-
ular orifice of the tympanum, would establish a free
communication between the tympanum and the ves-
tibule if it were not closed by the base of the stapes
{d,fig. 255 ; n,fig. 257), which is accurately fitted to it.
The fenestra ovalis is placed at the bottom of a
depression, which is named the fossette of the fe-
nestra, and the depth of which depends upon the de-
* Philosopliical Transactions, p. 23, 1823. To his paper are
annexed three plates, representing the membrana tympani in the
elephant, the ox, and man.
tig. 254.
Natural size.
(Section of the tympanam.)
THE TYMPANUM.
671
gree of projection of the aqueduct of Fallopius, which bounds it in front, by that of the
promontory, which is below, and by an osseous tongue which passes up to the pyramid
behind.
Below the fenestra ovalis is the promontory (r, figs. 254, 255), an eminence which
corresponds to the first turn of the cochlea, and has three grooves upon its surface,
that diverge above and converge below, where they terminate in a common canal,
which opens upon the lower surface of the petrous portion of the temporal bone, be-
tween the carotid canal and the groove for the internal jugular vein. This canal (ca-
nalis tympanicus, Arnold) may be called the canal ofJacobson, because it contains Jacob-
son's nerve, a branch given off from the glosso-pharyngeal, which establishes a very re-
markable anastomosis between the glosso-pharyngeal and the nervi molles derived from
the vidian and great sympathetic nerves.* The furrows upon the promontory are in-
tended to lodge this anastomosis. They are often formed into complete canals.
Behind the fenestra ovalis, and opposite its transverse diameter, is a small projection
of variable size, called the pyramid {t,figs. 254, 255). There is an opening upon it which
is distinctly visible to the naked eye, and makes the p)Tamid appear tubular. From thia
opening emerges a small cord (o, fig. 255), the nature of which is not known, but which
is called the stapedius muscle. A bristle passed into this opening enters the canal of the
pyramid, which canal is generally described as ending in a cul-de-sac, but this is not the
case. M. Huguier, prosector of the faculty, has clearly demonstrated, in a series of
preparations, that the canal of the pyramid is a long passage, which passes backward
and downward below the aqueduct of Fallopius, becomes vertical like the aqueduct, is
separated from it only by a thin lamina of bone, communicates with it by a small open-
ing, and at length abandons it below, to open upon the inferior surface of the petrous
bone, on the inner side of the stylo-mastoid foramen, at a variable distance from it.
Sometimes this canal bifurcates below ; so that two bristles introduced into the small
openings near the stylo-mastoid foramen will both enter the canal of the pyramid. A
small, very short, and horizontal passage, which terminates in the diploe of the tem-
poral bone, may be regarded as a diverticulum of this canal.
I have already stated that a fibrous-looking cord, named the stapedius muscle, emerges
from the canal of the pyramid. It is not yet known what structures are transmitted
through the divisions of this canal.
Below the fenestra ovalis, and behind the promontory, is situated the fenestra rotunda
(*, figs. 254, 255) ; it is placed at the bottom of a funnel-shaped depression, which was
well described by M. Ribes as the fossa of the fenestra rotunda, at the bottom of which
is found a partly membranous and partly osseous lamina, which is the commencement
of the spiral septum of the cochlea. In a dry bone, which has been previously macerated,
the membranous part being destroyed, the fossa of the fenestra rotunda communicates
with the vestibule. Below this compound lamina, i. e., at the lower part of the fossa
just described, is found the fenestra rotunda (*, fig. 257) properly so called, which leads
into the tympanic scala of the cochlea (l) ; whence the term cochlear orifice of the tym-
panum is applied to the fenestra rotunda, in contradistinction to the term vestibular orifice,
which is given to the fenestra ovalis.
The fenestra rotunda is closed, in the fresh state, by a membrane called the secondary
membrana tympani, which is said to be composed of three layers — a middle layer, an
external or tympanic, and an internal or cochlear layer. The two last named are mucous
membranes.}
Under the pyramid, and behind the fenestra rotun-
da, is seen a deep fossa, the sub-pyramidal fossa {v,fig,
254), remarkable for its constancy, and pierced by
several foramina at the bottom.
Upon the internal wall of the tympanum, in front
of the fenestra ovalis, somewhat above the trans-
verse diameter of that opening, and under the prom-
inence of the aqueduct of Fallopius, is the internal
orifice (n, figs. 254, 255) of the canal (m) for the internal "\
muscle of the malleus, or tensor tympani muscle. This
orifice is wide and cup-shaped, and is supported by a
hollow eminence (z, jQ. 254), which is itself sustain-
ed by several ridges ; so that there is the greatest
analogy between it and the hollow projection consti-
tuting the pyramid. Both of them transmit a tendon.
One is situated in front, and the other behind the fe-
nestra ovalis. M. Huguier, who has paid much at-
tention to this subject, has shown that the cochleari-
* This can be clearly seen in some preparations in the museum
of the Faculty at Paris.
+ [The internal or cochlear layer is merely apart of the common
lining membrane of the labyrinth, and is, most probably, a. fibre- Natural size.
lerous membrane, see p. 681.] (Section of the tympanum.)
Fig. 255.
NEURO1.0GY.
form, process of anatomists (n, fig. 255) is nothing more than the remnant of the hollow
projection (x, fig. 254) just described, one half of which is very thin and fragile, and is
sometimes destroyed by long-continued maceration. The so-called cochleariform pro-
cess, therefore, is merely the reflected canal for the internal muscle of the malleus.
The Circumference of the Tympanum. — We shall examine this circumference above, be-
low, in front, and behind.
Above, the tympanum corresponds to the projection formed on the anterior part of the
base of the petrous portion of the temporal bone. In it there is formed a recess, which
may be named the recess of the tympanum, and which is intended for the reception of the
head of the malleus {\,fig. 255), and the body and posterior ramus of the incus (2). It
is thin and spongy, and is separated from the squamous portion of the temporal bone
by a suture, which persists even to the most advanced age. This suture is traversed by a
great number of canals, through which communicating vessels pass from those of the
dura mater to those of the tympanum.
Below, the tympanum is very narrow, and has the form of a trench, in which there is
nothing particular to notice. The wall of the tympanum is here formed by the osseous
lamina of the external meatus.
At the upper and back part of the circumference of the tympanum is situated a large
opening which leads into the mastoid cells (c c, figs. 254, 255).
These cells are extremely numerous, and of very unequal size ; they occupy the whole
of the mastoid portion, and the adjacent parts of the petrous portion of the temporal
bone, and are prolonged even above the external meatus. We may therefore regard
the mastoid portion of the temporal bone as an appendage to the tympanum. The mas-
toid cells have a very regular arrangement in the ox and horse, in which animals they
are disposed in a series radiating from the surface of the mastoid process towards the
tympanum ; their arrangement is much more irregular in the human subject. Two large
cells are almost always found, one near the apex, and the other at the posterior border
of the mastoid process. In one case I found the whole mastoid process forming a single
large cell, having extremely thin parietes.
The mastoid cells are lined with a very delicate fibro-mucous membrane, which is con-
tinuous with the mucous membrane of the tympanum. They contain air, and it is only
in some cases of disease that any quantity of mucus is found in them.
The mastoid cells represent, in the auditory apparatus, the cells and sinuses which
are connected with the organ of smell. It may be easily conceived that the intensity of
sounds may be increased by being reverberated from so considerable a surface.
In the foetus there are no mastoid cells ; but there exists instead, in the base of the
petrous portion of the temporal bone, a cavity prolonged from the recess already de-
scribed in the upper wall of the tympanum, for the ossicula of the ear.
In front, the tympanum is contracted like a funnel, to become continuous with the
Eustachian tube (c, fig. 255) ; it might even be said that the tympanum and the Eustachian
tube form together a single funnel-shaped cavity, the expanded portion of which is con-
stituted by the tympanum, and the contracted portion by the tube of Eustachius.
The canal for the internal muscle of the malleus is formed in the upper wall of the Eu-
stachian tube ; it is a narrow tubular canal (m), which, having reached the anterior part
of the tympanum, becomes applied to the internal wall of that cavity ; it passes horizon-
tally backward, forming a projection upon this wall, and is then reflected outward, at a
right angle, to form the hollow eminence already described. This canal is separated
only by a very thin osseous lamina from the Eustachian tube ; so that the two passages,
placed one above the other, have some resemblance to a double-barrelled gun.
The Eustachian Tube.
The Eustachian tube (more correctly called the Eustachian trumpet, from tuba, a
trumpet, e,fig. 255), or the guttural meatus of the ear, is a straight, funnel-shaped canal,
flattened upon its outer side, and about two inches in length ; it extends from the tym-
panum to the upper and lateral part of the pharynx, where it terminates by a free, ex-
panded extremity (wi, fig. 234), directed inward and downward, named the guttural orifice,
or the mouth of the Eustachian tube. This orifice is wide and dilatable, of an oval shape,
the larger end of the ovoid being turned upward, and being exceedingly dilatable ; but
beyond its mouth the tube almost immediately contracts, and will scarcely admit an or-
dinary probe. It continues narrow as far as its tympanic orifice, where it again becomes
sensibly dUated. It is directed obliquely inward, forward, and downward ; hence the
facility with which the mucus of the tympanum flows into the back of the throat.
The Eustachian tube consists of an osseous portion and of a cartilaginous and fibrous
portion.
The osseous portion, which is about seven or eight lines in length, is situated at the re-
treating angle formed between the squamous and petrous portions of the temporal bone
A triangular cartilaginous plate, formed into a groove, constitutes the inner half of the
tube ; a fibrous layer, which is at first applied against the circumfiexus palati muscle, and
is then lodged in the groove between the petrous portion of the temporal bone and the
THE OSSICULJlf^OP THE EAR. 673
posterior border of the sphenoid, forms the external wall of the canal, which is habitu-
ally collapsed. The base of the triangular cartilage, which forms the guttural orifice of
the tube, is notched in the middle, and terminates in two thickened elongated angles ; of
these, the posterior one, which is more distinct, is movable, and may be pushed upward
and backward. The anterior angle is firmly fixed to the posterior margin of the ptery-
goid process. As catheterism and injection of the Eustachian tube have become com-
mon operations in treating diseases of the ear, it is of importance to define the exact
position of its guttural orifice ; it is situated (m, fig. 234) upon the side of the pharynx,
immediately behind, and a little above the inferior turbinated bone.
The mucous membrane •w\imY\. lines the Eustachian tube is thin, but at the mouth of the
tube it assumes the characters of the mucous membrane of the pharynx and of the pitui
tary membrane, with both of which it is continuous ; it is also continuous with the mu-
cous membrane of the tympanum ; hence the close sympathy which exists between the
lining membrane of these several parts.*
The use of the Eustachian tube is to renew the air contained within the tympanum ,
but it also gives exit to the mucous secretion of that cavity, t
Besides the orifice of the Eustachian tube, and that of the canal for the internal mus-
cle of the malleus, the anterior funnel-shaped part of the circumference of the tympanum
presents two orifices placed one above the other : the uppermost of these is the internal
orifice of the canal for the chorda tympani nerve ; the lower one is an oblique fissure,
which transmits a fibrous cord called the anterior muscle of the malleus. M. Huguier has
shown me a number of preparations in which the chorda tympani nerve does not escape
through the fissure of Glasserius, but runs in a very narrow special canal, about five or
six lines in length, which is situated on the inner side of the Glasserian fissure, and
opens at the base of the scull in the retreating angle formed between the squamous and
petrous portions of the temporal bone, upon the outer side of the Eustachian tube, be-
hind the spinous process of the sphenoid, and sometimes upon that bone itself
The fissure of Glasserius, then, merely transmits a fibrous bundle, named the anterior
muscle of the malleus, and some small arteries and veins.
We may now describe the course of the chorda tympani nerve.
In its course this nerve passes through two canals, entering the tympanum by one, and
escaping from it by the other. The canal by which it enters commences at the vertical
portion of the aqueduct of Fallopius, in which the facial nerve is situated, passes upward
and forward, and opens immediately on the inner side of the posterior margin of the
membrana tympani, on a level with the horizontal diameter of that membrane, and al-
most in the groove into which it is inserted. Having entered the tympanum through
this canal, the chorda tympani describes a curve, having its concavity directed down-
ward, passfes between the handle of the malleus and the long ramus of the incus, enters
its proper canal upon the inner side of the fissure of Glasserius, and emerges at the point
already mentioned.
The Ossicula of the Ear.
The tympanum is traversed from without inwaM by an osseous chain, which describes
several angles, and consists of four bones articulated with each other, and extended from
the membrana tympani to the fenestra ovalis. These little bones, forming the links of
the chain, are named, from their respective shapes, the malleus, or Fig. 256.
hammer {I, fig. 256) ; the incus, or anvil (2) ; the os orbicular e, or ^ a ^
round bone (4) ; and the stapes, or stirrup bone (3) : the os orbicu-
lare, however, appears to be merely a tubercle belonging to the
incus.
The Malleus. — The malleus {I, fig. 256) is the most anterior of the bones of the ear;
it is divided into a head, a neck, and a handle, and it has also two processes.
The head of the malleus (a, fig. 257) is situated in the recess of the tympanum, ir
front of the incus, and above the membrana tympani. It
is ovoid, and smooth, excepting behind and below, where
it is concave, in order to be articulated with the incus.
Soemmering has figured a small fibrous cord, which he
calls the proper ligament of the malleus, extending from
the head of this bone to the upper part of the recess of
the tympanum.
The head is supported by a constricted neck (b), which
is slightly twisted and flattened, and serves also as a
support for the two processes.
The handle (manubrium, c) is directed vertically, and, Magnified three diameters.
* [According to Dr. Henl6, the mucous membrane of the Eustachian tube, like that of the upper part of the
pharynx, is covered with a columnar ciliated epithelium ; but in the tympanum and mastoid cells the epithelium
is squamous, and not ciliated.]
t [The Eustachian tube, by establishing; a communication between the tympanum and the external air, en-
sures an equal atmospheric pressure on the two surfaces of the membrana tympani, so that the necessary con-
dition of that membrane, and of the ossicula auditOs, as conductors of vibrations, is not interfered with.]
4Q
674 NEUROLOGY.
with the head and neck, forms a very obtuse angle, which retreats on the inner side ;
it is in contact with, and adheres firmly to the internal surface of the membrana tyrn-
pani, opposite the centre of which its rounded extremity is placed ; it therefore forms a
radius to the circle represented by the membrana tympani. The lower part of the handle
of the malleus is distinctly curved, having its concave side turned outward ; this ex-
plains the funnel-shaped depression upon the external surface of the centre of the mem-
brana tympani.
The processes of the malleus are two in number : the external, or short process {d), is
directed slightly outward, and rests against the upper part of the margin of the mem-
brana tympani, so as to make it project outward ; the other, or lo7ig process, is very
slender (processus gracilis of Raw, e), and is shaped like a thorn (processus spinosus) : rt
arises from the anterior part of the neck, enters the Glasserian fissure, and affords at-
tachment to a muscular or fibrous cord. I have several times found a simple ligament-
ous cord instead of this process.
The Incus. — This bone (2, Jig. 256) has been well compared to a bicuspid tooth, the
body of which would be represented by the body of the incus, and the fangs by its two
processes.
The body (f,fig. 257) is contained in the recess of the tympanum, behind the malleus,
with which it is articulated by a very concave surface, directed forward and somewhat
upward ; so that the articulation between the head of the malleus and the body of the
incus is effected by mutual reception.
Of its two rami, the superior or short one (g) is thick, conoid, and directed horizontally
backward : it is situated upon the S£une plane as the body, and, like it, is contained in
the recess of the tympanum, in which it terminates ; its extremity does not appear to
me to be free.
The inferior, or long ramus (h), is longer and thinner than the superior one ; it passes
vertically downward, parallel to the handle of the malleus, on a plane internal and some-
what posterior to it. Its lower portion is bent into a hook, the concavity of which is
turned inward ; and at its point is formed a sort of lenticular and distinctly defined tu-
bercle (4, fg. 256 ; i, Jig. 257), which has been regarded as a separate bone, and named
the OS orbiculare, or os lenticulare ; it appears to me to be merely a dependance of the in-
cus, with which I have always found it united, even in the foBtus.
The Stapes. — ^The stapes (3, fig. 356), which is shaped like a stirrup, extends horizon-
tally from the extremity of the long process of the incus to the fenestra ovalis (see Jig.
257), and is situated upon a lower plane than the rest of the small bones of the ear.
Its head presents a small articular cavity, for the reception of the orbicular tubercle
of the incus. Its base (n) is directed inward, and consists of a thin plate exactly corre-
sponding to the fenestra ovalis, which is rather accurately fiUed up by it, and to draw it
away from which a slight force is necessary, so that it has a greater tendency to fall
into the vestibule than into the cavity of the tjTnpanum. The slight obliquity of the
long diameter of the fenestra ovalis causes an inclination of the stapes in the same di-
rection. Of its two crura, or branches (fig. 256), the anterior is the shorter and straight-
er. Upon those surfaces of the crura which are turned towards each other there is
found a groove, which appears to indicate the existence of a membrane stretched be-
tween the crura. I have found the stapes very small, and, as it were, atrophied. In
one case, the two crura of the stapes were united together.
Muscles belonging to the Ossicula of the Ear.
Most modem anatomists agree with Soemmering in admitting four muscles for the
ossicula of the ear, viz., three belonging to the malleus, and one to the stapes. The
incus has no proper muscle, because it is merely an intermediate bone between the
malleus and the stapes. It is certain, however, that only one of these muscles has been
actually demonstrated, viz., the internal muscle of the malleus; but it is so easy to fall
into error when examining such minute objects, that I feel bound to suspend my judg-
ment as to the existence or non-existence of the other muscles.
The internal muscle of the malleus, or tensor membrancB tympani of Soemmering (e, fig.
251), is an elongated, fusiform muscle, contained within the bony canal formed in the
retreating angle of the temporal bone, above the Eustachian tube, with which it exactly
corresponds in direction. It arises from the cartilaginous portion of the tube, from the
adjacent part of the sphenoid bone, behind the spinous foramen, and from the bony canal
which forms its sheath. The fleshy fibres converge around a tendon, which appears
from among them, before it passes out from the bony canal. This tendon is reflected at
a right angle, like the canal in which it is contained, and then passes directly outward,
to be inserted into the anterior and superior part of the handle of the malleus, below the
processus gracilis of Raw.
The muscularity of the band or cord named the anterior muscle or ligament of the mal-
leus, or the great external muscle of Meckel, is doubted by a great number both of pres-
ent and former anatomists.* I have never seen anything more than a fibrous cord, which
" Fu^re autem et dudum et nuper clari viri qui de veris hujus musculi fibris carneis dubitarunt, cum
THE OSSEOUS LABYRINTH. 61^
cwmmehced at the tip of tTie processus gracilis of the malleus, traversed the glenoid fis-
sure, was re-enforced by other fibres arising from that fissure, and became continuous
with a fibrous layer arising from the spinous process of the sphenoid bone, and generally
regarded as the internal lateral ligament of the temporo-maxillary articulation.
The same remarks will also apply to the small external muscle of the malleus, or small
muscle of the malleus of Casserius. This muscle is figured by Soemmering, who says
that he found it exceedingly developed in one subject. All that I have clearly seen is a
cylindrical cord, extending from the upper part of the frame of the membrana tympani
to the short process of the malleus, or, rather, below it, according to the observations of
Scemmering {ad manubrium mallei, infra brevem ejus processum). This small muscle
would relax the membrana t3TTipani ; hence it has been named by Soemmering the lax-
ater membrance tympani.
The muscle of the stapes, or stapedius muscle (o, fig. 255), which is the smallest in the
body, has, since the time of Varolius, by whom it was discovered, been regarded as a
ligament by some anatomists ; nevertheless, it is more generally admitted to be muscu-
lar than that last described. It arises from some part of the interior of the pyramid, and,
escaping from that process, passes forward, and terminates at the back of the neck, or
constricted part of the head of the stapes, behind its articulation with the incus. Soem-
mering has not only represented its fleshy belly and its tendon, but also (see fig. 20, tab.
11) a filament of the facial nerve terminating in it. It is difficult to conceive that such
a serious mistake should have been committed by this great anatomist. I have exam-
ined this cord under a lens, and have never been able to discover any muscular fibres in
it. We do not conceive how a muscle should exist in so delicate a cord. Supposing,
however, that it does exist, it must move the stapes in such a way that the posterior ex-
tremity of the base of that bone would be pushed into the fenestra ovalis, while the an-
terior extremity would be carried outward.
Movements of the Ossicula. — The chain of small bones in the ear is so arranged, that
any movement of one of its extremities is communicated to the entire chain. Their mo-
tion is precisely similar to that of a bell-crank. M. Huguier is incUned to believe that
the processus gracilis of Raw serves as a fulcrum, around which the malleus performs
a rotatory movement, the effects of which are transmitted to the stapes through the in-
cus. The contraction of the internal muscle of the malleus, or tensor membranae tym-
pani, must draw the handle of the malleus inward and its head outward ; the incus, from
its firm connexion with the head of the malleus, follows that bone, and as it swings upon
its short horizontal process, its vertical process is carried inward, and therefore presses
the stapes into the fenestra ovalis.
The Lining Membrane of the Tympanum.
The tympanum is lined by a very thin membrane, which not only covers the walls of
this cavity, but also forms a very evident investment for the ossicula, and is, moreover,
prolonged into the mastoid cells, lining them throughout, and forming small duplicatures
around the vessels by which some of the cells are traversed. This membrane is con-
tinuous with the mucQus membrane of the Eustachian tube, and therefore indirectly
with that of the pharynx.*
It serves at once as an internal lining for the tympanum, and a periosteum for the os-
seous walls of that cavity, and should therefore be regarded as a fibro-mucous membrane.
It secretes a mucus, which in the natural state simply moistens its surface, but in some
cases of disease occupies the whole cavity. The catarrhal character of the products ol
suppuration in the tympanum, the continuity of this lining membrane with the mucous
membrane of the pharynx, and its extreme vascularity, leave no doubt of its being a mu
cous membrane.
The Internal Ear, or Labyrinth.
The internal ear, or labyrinth (f,fig. 251), the deep-rooted and essential portion of the
organ of hearing, is situated on the inner side of the tympanum, in the substance of the
petrous portion of the temporal bone. It consists of the osseous labyrinth, which forms
a receptacle for the membranmis labyrinth, which is the immediate seat of the sense of
hearing. No part of the body has a more conlplex and delicate structure. The labyr
inth is composed of three very distinct compartments, which have been named the ves
tibule, the semicircular canals, and the cochlea.
The Osseous Labyrinth.
Preparation. — This is justly regarded as one of the most difficult dissections, even
when the parts are previously known. The dissection should be made upon temporal
bones from subjects of different ages, upon bones that have been macerated, upon oth-
ers that have been dried without maceration, and also upon bones in the fresh state.
inultam quidem membranam a periosteo propa^atam, sulcuin maxillje repleri viderent, et processui longissimo
circumnasci, esEterum in eo carneam naturam non deprehenderent. Neque mea erperimenta remexpediunt
Musculum quoties volui, ostendi, num veras fibras viderem, plerumqiie dub^us hxsi."— (Holier, torn, v , lib
TV., p. 218.) ■ ■ * See note, p. 673.
676
NEUROLOGY.
Commence with a foetal temporal bone, in which the labyrinth can very easily be isola-
ted, in consequence of its being surrounded only by a spongy texture, readily yielding to
the knife. In the adult, the labyrinth is, in proportion, much less developed than in the
foetus, and is surrounded with so compact a tissue, that, in order to cut it, it is necessa-
ry to use a chisel, a file, or a very strong scalpel. It is important to have a great num-
ber of temporal bones, so as to be able to make several different sections.
Preparation of the Vestibule. — Open the vestibule through its upper wall, which corre-
sponds to the upper surface of the petrous portion of the temporal bone, opposite the fe-
nestra ovalis, between the superior vertical semicircular canal and the internal auditory
meatus.
Preparation of the Semicircular Canals. — In the foetus, one of the semicircular canals
projects upon the base of the petrous portion of the temporal bone ; it is easy to isolate
it, as well as the other canals, by removing, with a strong scalpel, the spongy tissue in
which they are imbedded. It is useful to have two preparations of the semicircular ca-
nals ; one in which the canals remain entire, and another in which they have been opened.
Preparation of the Cochlea. — Remove layer by layer that part of the petrous portion of
the temporal bone which corresponds to the bottom of the internal auditory meatus. A
layer of very thin spongy tissue shows, in the foetus, that we have arrived at the coch-
lea ; remove this spongy tissue with care, and expose the cochlea, both on its upper and
lower surfaces. In one preparation, the cochlea should be merely isolated ; in another,
it should be carefully opened, and for this purpose it is sufficient to make a simple cut
into each of its turns : it is of importance not to remove the summit of the cochlea.
The Vestibule.
If a probe be passed from the tympanum through the fenestra ovalis {f,fig. 258), it
P^ 25g enters an ovoid cavity (a b t, fig. 259) called the
vestibule.
The vestible is the centre of the internal ear,
and forms an intermediate cavity or passage (fo-
rum fodinaj metallicas, Vesalius) between the
semicircular canals {op q,fig. 258), which are on
its outer side, and the cochlea (Z), which is to its
inner side. It is situated in a line with the axis
P^ of the internal auditory meatus. It is remark-
able for having a great number of both large and
small openings into it.
The large openings are seven in number: the first is the fenestra ovalis {ffigs. 258,
261), which would establish a free communication between the vestibule of the tympa-
num if it were not for the base of the stapes, which closes it hermetically, as we may
be convinced by examining it from the vestibule, when the stapes remains in its plac ♦
There are five openings (o' p' q',fig. 259 ; o' a', fig. 261) for the three semicircular canals ;
yi„. 259. and the seventh is the orifice (/) of the vestibular
scala of the cochlea. In macerated bones we
find, besides, an eighth opening, situated below
the fenestra ovalis, having an oblong shape, and
leading into the highest part of the fenestra ro-
tunda.
Of the small openings, the first is the orifice (r,
fig. 259) of the aqueduct of the vestibule, which
opens upon the posterior wall of this cavity to
the inner side of the common opening for the two
„ , ^. .V ..V w. ,, vertical semicircular canals (i. e., in the recessus
^XgJ^^'Co-iumeTer,"'" sulciformis). The aqueduct of the vestibule turns
a short distance around that common opening, and then, bending at a right angle, ter-
minates upon the posterior surface of the petrous portion of the temporal bone by an
orifice already described (see Osteology). The other small openmgs m the vestibule
are foramina for the passage of vessels and nerves ; they form the macula cribrosa, which
corresponds with the bottom of the internal auditory meatus.
The character of the vestibule is irregularly ovoid, and is divided by a cn»ta into two
fossae : one inferior and hemispherical, named the fovea hemispherica {a, fig. 259) ; the
other, superior and semi-elliptical, called the fovea semi-elliptica (h). Morgagni has de-
scribed a third groove-like fossa {recessus sulciformis), situated at the mouth of the com-
mon orifice of the two superior semicircular canals.
The Semicircular Canals.
The semicircular canals, three in number, represent three cylinders or tubes (tubaeformes
canales, Simmering), of equal diameters, and curved very regularly, so as to describe
* CThe base of the stapes is retained in its situation, and the complete closure of the fenestra ovalis is ef-
fected, by the reflection of the lining membrane of the tympanum on the one hand, and by that of the bning
membrane of the labyrinth on the other.]
THE COCHLEA. 677
portions of circles ; they are situated within the substance of the base of the petrous
portion of the temporal bone, behind the vestibule, into which they open by the five ori-
fices already described.
They have been named the great, the middle, and the small semicircular canals ; terms
which have caused much confusion, because the differences between them, in regard to
length, are not alone sufficient to distinguish them from each other.
Their direction forms a much better ground of distinction between them. Two are
vertical, and one is horizontal : there is an anterior and superior vertical, and a posterior
and inferior vertical canal ; the horizontal canal is external, and is situated between the
two others. , . ^
Tlie superior vertical canal (p, figs. 258, 260), which describes two thirds of a circle, is
placed at the highest part of the labyrinth, immediately to the outer side of the vestibule.
A plane passing through the two branches of this canal would cut the base of the petrous
portion almost at a right angle.
The convexity of this canal is turned upward, and its concavity downward. In the
foetus, its concavity is free, so that it can be seen without any dissection ; but in the
adult it is filled up with osseous tissue.
The anterior and outer extremity {f,figs. 258, 259) of this canal is dilated into an
ampulla, and opens separately at the upper and outer part of the vestibule. The poste-
rior and inner extremity unites with the corresponding extremity of the inferior vertical
canal to form a common canal (a, fig. 260), which opens without any dilatation into the
upper and inner part of the vestibule {a', fig. 261). Fig. 260
The inferior vertical canal {q, figs. 258, 260) is
placed at right angles to the preceding, and par-
allel with the posterior surface of the petrous
portion. It commences at the inner and upper
part of the vestibule, by the common canal (a,
fig. 260) already described, passes almost di-
rectly outward, curves at first downward, and
then forward, and becomes dilated into an am-
pulla {q', fig. 258) near the vestibule, into which
cavity it opens {q', fig. 259), about the distance
of a line from the point at which it commences.
This canal, therefore, describes nearly a com-
plete circle ; and hence the term canalis major
et longior, still given to it by Soemmering, in
contradistinction to the superior vertical semi-
circular canal, which he calls minor et brevior.
The horizontal canal (o, figs. 258, 260), canalis
minimus, brevissimus, sive exterior of Soemmer- fc;*^ji_
ing, commences in the vestibule {o',figs. 258,
259) between the fenestra ovalis, which is be-
low, and the ampullar opening of the superior vertical canal, which is ahove ; it becomes
dilated into an ampulla, describes a horizontal curve having its convexity turned out-
ward, and opens {o',fig. 261) upon the inner wall of the vestibule, between the common
opening (a') of the two vertical canals and the proper opening ({'') of the inferior vertical
canal.
It appears, then, that each of the three semicircular canals has one of its extremities
dilated into an ampulla, and the other not dilated ; that the two vertical canals unite by
their non-dilated extremities ; that of the five openings belonging to the semicircular
canals, two occupy the outer, and three the inner wall of the vestibule, and that the three
last consist of the common canal formed by the two vertical canals, by the ampullar ex-
tremity of the posterior vertical canal, and by the non-ampuUar extremity of the horizon-
t£il canal.
The Cochlea.
The cochlea {I, fig. 258), or snail, so called from its resemblance to the shell of that
molluscous animal, may be said to consist of a conoid tube, which is subdivided into
two cavities, called scales, by a septum extending from its base to its apex, and is coiled
upon itself into a spiral containing two turns and a half
The cochlea is the most anterior part of the internal ear ; it is situated on the inner
side, and in front of the tympanum ; its base {d, fig. 260) rests upon the bottom of the
internal auditory meatus.*
Its external surface is blended, in the adult, with the substance of the petrous portion
of the temporal bone, so that it requires much skill to carve it out vnthout breaking into
its cavity : in the foetus, on the contrary, such a dissection is extremely easy, on ac-
count of the thin layer of spongy osseous tissue by which it is separated from the rest
of the bone.
* [The summit of the cochlea is directed forward, downward, and outward. The gyri of the cochlea are
soiled in a direction from below upward, a"' ''""ti without inward.]
C78
NEUROLOGY.
The following parts of the cochlea are separately described : the tube of the cochlea or
lamina gyrorum, the lamina spiralis, the axis or columella, the two scala, and the aqueduct.
The Tube of the Cochlea. — The tube of the cochlea {canalis spiralis cochlce, or lamina gy-
rorum) is the compact lamina (l, figs. 258, 262) which forms the external walls of the
cochlea. If we imagine a hollow osseous cone, coiled spirally, cicut circa fulcrum convol-
vulus {Holler), or like a winding staircase ; and farther, that the lowest turn of the spire
embraces the turn above it, and that the walls of the different turns are blended with
each other, we shall have a correct idea of the tube of the cochlea : as before stated, the
spire thus formed describes two turns and a half
The Spiral Lamina of the Cochlea. — The spiral canal, or tube of the cochlea, is subdi-
vided lengthwise into two secondary cavities (c e, c e, figs. 263, 264), called scala. {scala, a
staircase), by a septum (a), which is named the spiral lamina of the cochlea {lamina spi-
ralis cochlea).
Commencing at the base of the cochlea {t, fig. 259 ; also fig. 263), and at the fenestra
rotunda, where it can be very easily seen, the spiral lamina winds edgewise around the
axis or columella {b b, fig. 262), and is continued without any interruption to the summit
or cupola (/) of the cochlea, the several turns of which it exactly follows. Its internal
border is applied against the axis of the cochlea, and adheres intimately to it, excepting
above, where it is free for a short distance, and leaves a communication {n, fig. 263) be-
tween the two scalae. Mar go liber lamina spiralis quo fit ut utriusque scala. sit communica-
tio {Sammering). Its external border adheres to the inner surface of the lamina gyrorum,
or tube of the cochlea. In consequence of the conical form of this tube, the lamina spi-
ralis would, if unrolled, represent an isosceles triangle, the base of which had corre-
sponded to the fenestra rotunda, and the apex to the summit of the cochlea.
The spiral lamina consists of two portions — an internal osseous and an external mem-
branous portion.*
The osseous portion {lamina spiralis ossea, d, figs. 259, 261, 262, 264) predominates in
the first turn, diminishes gradually in the second, and
ceases at the commencement of the third, where it termi-
nates in a kind of hook or beak {hamulus vel rostrum, e,fig.
262). This bony portion is thick, and consists of two la-
mellae, between which are found a great number of very
delicate canals, through which the nerves of the cochlea
v pass. These two lamellae form two distinct furrows upon
1^' the columella.
The membranous portion {lamina spiralis membranacea,
a a, figs. 263 to 265) completes the septum, forming its
Cochlea (dry) magnified four times. ^y^gj. ^^^ J^ jg narrow in the first tum of the cochlea,
becomes broader in the second, and constitutes the entire septum in the third
Fig. 263.
Cochlea (
The bony and membranous portions of the spiral lamina,
therefore, represent two isosceles triangles, so arranged
that the base of the one corresponds to the apex of the
other, and vice versa.
Moreover, as Comparetti remarks, three zones can be
distinguished in the membranous portion of the spiral lam-
ina, the consistence of which diminishes progressively
■/ from the margin of the osseous lamina towards the inter-
nal surface of the tube of the cochlea.
The Axis or Columella of the Cochlea. — From the bottom, or,
rather, from the posterior part {d, fig. 260) of the bottom of
the internal auditory meatus, arises a bony process, which is directed almost horizontally
outward ; it occupies the centre or axis of the cochlea, and around it both the tube and
spiral lamina describe their several turns. This bony process is called the axis of the
cochlea, columella, modiolus, or nucleus {b, figs. 262, 264). It extends from the base to the
summit of the cochlea, but undergoes certain changes during its course. Opposite the
first turn it is extremely thick, but becomes much thinner in the first half of the second
tum. In the second half of the second turn, and in the last half turn, it is replaced by a
cup-shaped lamella, called the infundibulum (scyphus, Vieussens, c, fig. 262), the expand-
ed portion of which is turned towards the cupola (/) of the cochlea. The modiolus or
axis of the cochlea, then, has three perfectly distinct parts.
The base of the modiolus, which is seen at the bottom of the auditory meatus, is marked
by a very distinct spiral tract {d, fig. 260), perforated with foramina, through which the
filaments of the auditory nerve are transmitted. It is the tractus spiralis foraminulentus
of Cotugno.
The apex of the modiolus, when examined in a cochlea which has been opened from
the under surface of the petrous portion of the temporal bone, presents a decidedly in-
fundibuliform figure. But in a cochlea which has been opened from its upper surface
* [In the dried cochlea [fig. 262), the two seals communicate along their whole course.]
THE COCHLEA. 679
ifig. 264), on the contrary, it has the appearance of a very slender stalk, continuous with
the rest of the modiolus, and proceeding directly to the cupola of the cochlea. This two-
fold structure depends upon the fact that the terminal lamella of the modiolus forms only
half a funnel, which half is turned towards the lower half of the cochlea. , This terminal
lamella of the modiolus, which has been very well described by Huguier, is of a triangular
form, extends through half a turn of a spiral, and adheres to the inner surface of the
tube of the cochlea by its external convex border. Its internal border or margin is straight
and free, and is the only part of this lamella which is seen when the cochlea is opened
from above, while its convex border and its surfaces are distinctly seen when the coch-
lea is opened from below. The hamulus (e, fig. 262) of the osseous portion of the lamina
spirahs terminates opposite the middle of this free border or margin.
The surface of the modiolus is marked like a screw by two furrows correspondmg
to the two lamellae of the osseous part of the spiral lamina ; this surface is pierced with
foramina for the branches of the auditory nerve.
If the modiolus be divided longitudinally (fig. 264), it wDl be seen that its centre is
traversed by a number of canals, for the passage of the branches pig. 264.
of the auditory nerve. These canals open by the foramina on
its surface. In the centre of the half funnel formed by the ter-
milial lamella of the modiolus is an opening, through which the
terminal filament of the cochlear branch of the auditory nerve
passes out ; it is the orifice of the tubulus centralis modioli.
The Scarce of the Cochlea. — The spiral lamina {d d, fig. 264) di-
vides the cavity of the tube of tne cochlea into two secondary
cavities (c e, c e), called the scala of the cochlea. They are dis-
tinguished as the external, superior, or vestibular scaia (scala ves-
tibuli, c c, figs. 263, 264), and the internal, inferior, or tympanic
scala (scala tympani, e e). The first (c c, fig. 265) communicates ^
directly with the vestibule (between t and s) ; the second, which Coehiea magnified.
commences at the fenestra rotunda (s, fig. 258), would communicate with the tympanum
if that fenestra were not closed by a membrane ; hence the term scala clausa. The
tympanic scala is decidedly larger than the vestibular. The section of either of the scalae,
at right angles to its axis, is semicircular.
The two scalae conununicate near the summit of the cochlea (at n, figs. 263, 265). Both
the situation and nature of this communication can be easily eiscertained, and have been
well described by Soenomering, and more recently by MM. Breschet and Huguier.
The lamina spirahs, which, we have seen, adheres closely to the modiolus, continues
to wind spirally around the half-funnel-shaped termination of the modiolus, but when it
arrives opposite the concavity of this half funnel, it ceases to be attached to that con-
cavity, its internal border becomes free, and is then continued on to the inner surface of
the summit of the cochlea. It follows, therefore, that the free concave border of the
lamina spiralis is opposite to the concavity of the infundibulum ; and hence there is an
interruption in the septum, in the form of a circular opening, the canalis scalarum commu-
nis of Cassebohm, the helicotrema of Breschet {n,figs. 263, 265), which establishes a com-
munication between the two scalae : moreover, this opening is not situated precisely at
the summit of the scalae, but a little below that point ; nor is the opening of communica-
tion (between t and s, fig. 265) between the vestibular scala and the vestibule situated at
the lowest part of that scala.
The Aqueduct of the Cochlea. — The aqueduct of the cochlea opens at one end {n,fig. 259)
into the tympanic scala of the cochlea, near the fenestra rotunda ; and at the other, by an
expanded extremity, upon the lower border of the petrous portion of the temporal bone,
near the jugular fossa. It does not appear to have any such use as was attributed to it
by Cotugno. Like the aqueduct of the vestibule, it is merely a canal for a vessel, and
as such was denominated by Wildberg canalis vcnosus cochlea. The liquor Cotunnii
could not pass through this canal, for it is closed by the dura mater. Ilg has taken a
very ingenious view of the structure of the modiolus and cochlea. According to that
author, the modiolus is not an osseous centre independent of the lamina gyrorum, but
rather the internal wall of the spiral tube of the cochlea, which, in describing its first
turn, intercepts a considerable cylindrical space of about two lines and a half in diam-
eter, and then a smaller, but still cylindrical space, of about half a line in diameter, in
its second turn ; while in the third turn there is no space, and therefore the axis or
modiolus is wanting, but it is replaced by the internal wall of the spiral tube of the
cochlea itself The terminal lamella of the modiolus would therefore be formed by the
internal wall of the spiral tube.
This view is supported by the structure of the bottom of the internal auditory meatus,
on which is found a turn and a half of a spiral groove, precisely corresponding to the
spire of the cochlea, and by sections of the cochlea made after Scemmering's plan, from
the apex to the base. {Vide figs. 11, 12, 13, 14, 15, of Scemmering's fourth plate.)
The Membranous Labyrinth.
The membranous labyrinth, discovered by Conipannti and .Scarpa, ha.s been correctly
NEUROLOGY.
described and figured by Soemmering. M. Breschet has recently enriched our knowl-
edge of this intricate anatomical subject with many most interesting facts. {Etudes
anatomiques et physiologiques sur Vorgane de Vouie et sur V audition dans Vhomme et Us ani-
maux vertebres, 1833.)
It is useless to attempt the examination of the membranous labyrinth in the human
subject without some previous preparation. If the labyrinth be opened, it is found to
contain a fluid ; the eye can detect nothing else. By previously macerating it in diluted
nitric acid, the twofold advantage is gained of softening the bones, so that they can be
cut with a scalpel, and of hardening and rendering opaque the nervous tissues. Before
studying the membranous labyrinth in the human subject, it should first be examined in
the large cartilaginous fishes, such as the ray and the turbot, in which it is most highly
developed. It is then seen that the semicircular canals and the vestibule contain, be-
sides a fluid, certain semi-transparent membranous tubes and sacs, the aspect of which
closely resembles that of the retina.
The membranous labyrinth (fig. 265) is not so extensive as the osseous labyrinth :
thus, it does not enter the cochlea, and its diameter is
much less than that of the bony labyrinth. It scarcely
occupies one half the cavity of the latter.
The space between the bony and membranous lab-
yrinths is filled with a limpid fluid, named, after Co-
tugno, the liquor Cotunnii, although it had been no-
ticed by several anatomists before that author. (De
aqua ductibus auris human<B inierna. Cotugno, 1760.)
It is the perilymph of M. Breschet.
There is no air in the labyrinth, and it is somewhat
Membranous labyrinth (leftside). singular that SO accuratc an anatomist as M. Ribes
should have recently defended a contrary opinion, although it has been repeatedly refuted.
The membranous labyrinth is itself filled with a fluid which was correctly described
by Scarpa, and which might be named X\\e fluid of Scarpa. M. de Blainville has com-
pared it to the vitreous humour of the eye, and has named it la vitrinc auditive : it is the
endo-lymph of M. Breschet.
The membranous labyrinth consists of membranous semicircular canals, and of a ves-
tibular portion.
The Membranous Semicircidar Canals.
The membranous semicircular canals {op q,fig. 265) were regarded as nervous cords by
Scarpa, who first described them ; they have precisely the same form as the osseous
semicircular canals, although they do not completely fill them. Soemmering improperly
calls them tubuli membrano-cartilaginosi. Each membranous canal, like the corresponding
osseous one, has its ampulla, or ovoid muscle {o' p' q').
The two vertical membranous canals unite at one end into a common canal, and,
therefijre, the three membranous semicircular canals, like their osseous investments,
open into the membranous vestibule by five distinct orifices.
The membranous vestibule consists of two very distinct parts, the common sinus and the
saccule.
The sinus communis vestibuli, or vestibular utricle (u),* as was first shown by Scarpa,
forms the confluence of the membranous semicircular canals which open into it by five
orifices. The utricle is situated in the fovea semi-elliptica of the vestibule, and floats,
as it were, in the liquid of Cotugno ; it is distended by the liquid of Scarpa, so as to re-
semble an oblong bulla. The liquid of Cotugno separates it from the base of the stapes,
as Scarpa very well pointed out.
The sacculus vestibuli, or vestibular saccule (sacculas proprius sphaericus, Soemmering,
s), is much smaller than the utricle. Its connexions with the utricle have been com-
pared by Fischer to those of the crystalline lens with the vitreous body : it occupies the
fovea hemispherica of the vestibule, and is therefore situated below the utricle. Accord-
ing to Soemmering, it does not adhere to the utricle ; that author has even represented a
small space between these two parts, t According to others, there is a communication
between them, and the saccule is merely a supplementary cavity to the utricle. I have
not yet been able to satisfy myself concerning this point.
The membranous labyrinth, then, is quite distinct from the membrane which lines the
labyrinthic cavities. This periosteal membrane, which analogy would lead us to regard
as a fibro-serous membrane, is the only membrane which is prolonged into the cochlea.
We might, however, regard that portion of the lamina spiralis which is next to the in-
ner surface of the lamina gyrorum as a portion of the membranous labyrinth.
* Alveus utriculoaiis of Scarpa, uiriculus communis of ScEmmering, Hnus midian of M. Breschet.
t Sacculus teres cum utriculo communi nuUibi cohseret, et ubi cultri apice aperitur, sphajricam ormam re-
tinet. (Explanation of fig. 2, pi. 3.) According to M. Breschet, the sacculus and utriculus adhere intimately,
and he is inclined to believe that their cavities even communicate ; but, from the extreme delicacy of tbeM
•tructures, he has been unable to confirm this supposition
THE AUDITORY NERVE, ETC. 6S1
The Calcareous Matter of the Vestibule. — ^The examination of the ear of fishes, which
has proved of such assistance in investigating the structure of the human membranous
labyrinth, has also led to the inquiry, whether there existed anything in the human ear
analogous to the solid calcareous concretions found in the labyrinth of the ear of fishes.
From the researches of M. Breschet, it appears that the labyrinthic stones, or otolitkes,
of fishes, are represented in all the mammalia, and, consequently, in man, by a cretace-
ous powder, which he has named otoconia {ovc, uroc, the ear, and Kovig, dust) ; and that
this powder exists both in the utricle and the saccule, collected together into two white
shining masses, which were seen and described by both Comparetti and Scarpa, but
were mistaken by them for the dried acoustic nerve. Does it fulfil the same uses as the
otolithes in fishes 1 or should it be regarded as a rudimentary condition of an important
structure in other animals ]
The Auditory Jferve and the Vessels of the Ear,
The auditory nerve, or special nerve of the organ of hearing, is remarkable for its soft-
ness, and hence it has been named the portio mollis of the seventh cranial nerve. The
auditory nerve arises, at least in part, from the anterior wall of the fourth ventricle ;
having reached the bottom of the internal auditory meatus, it divides into two branches :
an ajiterior and larger, distributed to the cochlea, and a posterior, intended for the vesti-
bule and semicircular canals. The anterior or cochlear branch {t,fig. 264) has a spiral
arrangement, like that portion of the bottom of the auditory meatus (d,fig. 260) to which
it proceeds, and it enters through the foramina in the tractus spiralis of the lamina cri-
brosa. One set of nervous filaments enters the small canals in the centre of the modi-
olus {b,fig. 264) ; the others are applied to the surface of the modiolus {t,Jlg. 263) ; the
latter filaments spread out upon the first turn of the lamina spiralis (<, ^^. 265), radiating
in the most regular manner, and having arrived near the outer border of the spiral lam-
ina, they each divide into two or three ramuscules, which anastomose together, so as to
form a nervous expansion.* These radiating filaments are more distinct upon the lower
than upon the upper surface of the spiral lamina.
Those filaments of the nerve which are not spread out upon the first turn of the lami-
na spiralis pass through the foramina in the centre of the modiolus, and spread out upon
the second turn, in the same manner as those already described. Lastly, the highest
filaments emerge from the opening at the apex of the modiolus, and terminate in a sim-
ilar manner. It follows, therefore, that the nerves of the cochlea successively diminish
in length, as the spiral lamina does in width ; and thus the radiating nervous filaments
resemble the strings of a harp, in becoming successively shorter and shorter. It is
probable that this arrangement is not without its influence upon the function of hearing.
In a temporal bone softened by the action of nitric acid, the auditory nerve, the modi-
olus, the spiral lamina, and the periosteal membrane which lines the cochlea, may be
dissected with the greatest facility.
The posterior or vestibular division of the auditory nerve is subdivided into three
branches, the largest of which (v, fig. 265) is distributed to the utricle {u) and to the am-
pullae {o' p') of the superior vertical and horizontal membranous semicircular canals ; the
middle-sized branch is distributed to the sacculus (s), and the smallest ends in the am-
pulla (g') of the inferior vertical membranous semicircular canal, t
Bloodvessels may be traced into the membranous labyrinth ; most of them enter by
the internal auditory meatus ; those which belong to the cochlea pass through the fora-
mina in the modiolus, and are distributed in a radiating manner like the nerves
THE CEREBRO-SPINAL AXIS.
General Observations.
The cerebrospinal axis constitutes the central portion, while the nerves form the periph-
eral portion of the nervous system.
The apparatus of innervation formed by the cerebro-spinal axis and the nerves togeth-
er, and named the nervous system, is the most important part in the animal machine ; it
is the source not only of sensation and motion, but of the universal sympathy existing
between the several parts of the animal economy; and that part of it called the brain
performs the highest function allotted to organized beings, by becoming the immediate
instrument of the soul in the exercise of the intellectual faculties.
* [According to observations made by Treviranus, Gottsche, and others, the filaments of the cochlear nerve
in animals do not anastomose, but terminate in isolated extremities, which are in some cases papillary (TVe-
viranus), and in others club-shaped (Gottsche) ."^
t [The nervous filaments proceeding- to the utricle and saccule form a, fan-like expansion upon those sacs,
per.etrate into their interior, and spread out as a nervous layer on their internal surface. EacOi of the nerves
which are distributed to the membranous ampullar apjiears to bifurcate, so as partially to embrace its corre-
sponding ampulla in a transverse direction : the nervous filaments then penetrate into the ampulla, and spread
out iip<m a transverse septum, formed in its interior by the folding inward of the walls of the cavity, and also
upon the adjacent parts of those walls. (See Steifensand, Mutter's Arch., 1835. )J
4R
682 NEUROLOGY.
The cerebro-spinal axis consists of that soft, pulpy, elongated, and symmetrical mass
of nervous substance, which, becoming enlarged at its upper part, occupies the vertebral
canal and the cavity of the cranium, and forms the centre from which the nerves of all
parts of the body take their origin, or in which they all terminate.
The structure of no other organ in the tody excites so much curiosity, and, unfortu-
nately, there is none whose structure is involved in greater obscurity. Notwithstand-
ing the real advances that have recently been made in our knowledge of the anatomy of
the brain, we must still acknowledge, with Steno, that the human mind, which has car-
ried its investigations even into the heavens, has not yet been able to comprehend the
nature of the instrument by which its own operations are performed, and that its pow-
ers seem to abandon it as soon as it turns its attention to the organ in which it resides.
Until the end of the last century, the study of the central portion of the nervous system
consisted in a simple enumeration of its parts, or, rather, in a more or less imperfect
description of its external surface, and of the different objects displayed by various sec-
tions. The nomenclature of the different parts of the encephalon* is alone enough to
show with what limited views the researches of those anatomists must have been made,
who did not suspect that this pulpy-looking mass — a sufficient definition of which they
believed to be, that it held an intermediate place between the solids and the fluids of the
body — ^was as wonderful in the delicacy and intricacy of its structure, as in the impor-
tance and elevated character of its functions. In the present day, anatomists include
in the study of the encephalon not only the topographical study of its various constituent
parts, but also the determination of the mode in which those parts are connected togeth-
er. To ascertain this latter point, apart from all questions as to origin, formation, gen-
eration, and re-enforcement, with which the subject has lately been embarrassed, should
constitute the special aim of every inquiry into the anatomy of this part pf the nervous
system.
The central portion of the nervous system consists, 1. Of the spinal cord; 2. Of the tu-
ber annulare, the ■peduncles of the cerebrum and cerebellum, and the tubercula quadrigemina ;
these together constitute a very constricted portion, which forms the bond of union be-
tween the other parts of the encephalon, and which I shalll accordingly name le naeud de
I'encephale ;t 3. Of the cerebellum ; 4. Of the cerebrum.
The cerebro-spinal axis is surrounded by three membranes or coverings, called the
meninges (from /^^vty^, a membrane), which perform some important functions in regard
to it, and which must in the very first place occupy our attention.
THE MEMBRANES OF THE CEREBRO-SPINAL AXIS.
General Remarks. — The Dura Mater — the Cranial Portion, its Structure and Uses — the
Spinal Portion. — The Arachnoid — its Cranial Portion — its Spinal Portion — the Sub-
arachnoid Fluids — their Uses. — The Pia Mater — its External Cerebral Portion.
But few parts of the body are so effectually protected as the cerebro-spinal axis ; this
protection is afforded in part by the vertebral column,^ and by the cranium, the mechan-
ism of which we have already described as being so eminently calculated to defend the
parts situated within them.
Besides the osseous case formed by the vertebro-cranial column, we find, surrounding
the cerebro-spinal axis, a fibrous sheath, named the dura mater ; a serous membrane,
called the arachnoid ; and a proper membrane, named the pia mater, in which the vessels
of the nervous centre ramify.
The Duka Matee.iJ
Dissection of the Dura Mater of the Scull. — Make either a crucial incision, or one ex-
tending from before backward, or from ear to ear, through the integuments of the head ;
turn back the flaps, taking care to remove the periosteum with the hairy scalp.
The bones of the cranium being thus exposed, the scull-cap may be removed, either
with a sort of hatchet (marteau-hachette) or a saw.
This hatchet is the most expeditious and the best instrument. There is no fear of
shaking or lacerating the brain, if the instrument be properly used ; but it is almost im-
possible to avoid cutting the brain with the saw, the only advantage of which over the
other is, that it makes an even section.
The section should be carried quite round the cranium, about a finger's breadth above
* From iv, in, and Kt<pa\ii, the head ; a convenient term, used to signify that part of the cerebro-spinal axis
which is situated within the cranium.
t [It is necessary to bear in mind that the equivalent term, nodus encephali, has been assigned by Sccmmer-
ing to the pons Varolii.]
t A vertebrated animal may also be defined to be an animal provided with an encephalon ; an inter-vertebra-
ted animal is one having no encephalon.
^ The application of the term mater to the meninges of the brain is derived from the Arabians, who regard-
ed these membranes as the origin, or mothers of all the other parts of the body ; or, perhaps, as Ilaller has ob-
lerved, this use of the term depends upon an Arabic idiom, by which the covering of any body whatsoever is
called its mother.
EXTERNAL SURFACE OF THE DURA MATER. 683
the orbital arches, the scull-cap being raised and removed by means of the narrow end
of the hatchet, or by means of a hook attached to the extremity of its liandle.
If the brain is not to be preserved, a somewhat different method of proceeding is adopts
ed. Two parallel cuts must be made with the saw, one on each side of the superior lon-
gitudinal sinus, along its whole extent. Each of these cuts should then be met by anoth-
er, carried horizontally through the corresponding side of the scull. When the two por-
tions of bone included between these sections are removed, there remains an intermedi-
ate portion of bone, about an inch wide, extending from the nasal eminence to the occip-
ital protuberance. The dura mater should then be divided along the borders of this in-
termediate portion of bone, and the brain and cerebellum removed.
If, however, it be intended to preserve the brain and cerebellum, after the entire scull-
cap has been removed in the ordinary manner, the dura mater must be divided circularly,
along the cut edge of the cranium, the anterior extremity of the falx cerebri must be di-
vided with the scissors, and the whole fibrous cap turned backward.
Another mode, and one which I prefer, is, to make an incision through the dura mater,
along each side of the superior longitudinal sinus, and then to divide the anterior ex-
tremity of the falx, and reflect that part backward.
Dissection of the Dura Mater in the Vertebral Canal. — This part of the dura mater may
be exposed, either by removing the arches of the vertebrae, or by taking away the bodies
of these bones. The latter method is but seldom adopted.
The arches of the vertebrae may be removed by means of a chisel and mallet, or, still
better, by the rachitame.
An instrument has lately been invented, consisting of two parallel saws, slightly con-
vex on their toothed edges, firmly connected together, but capable of being separated or
approximated as may be desired. Preference is justly given to the rachitome over this
complicated instrument. The important object in opening the spine is, to make the sec-
tion opposite the junction of the laminae with the transverse and articular processes.
In order to display the continuity of the cranial and spinal portions of the dura mater,
it is necessary to connect the sections already made in the head and spine, by removing
with the saw the intervening portion of the occipital bone.
A beautiful preparation of the dura mater may be made by removing the roof and sides
of the scull, and the arches of all the vertebrae ; by then taking out the encephalon and
spinal cord through incisions in the dura mater, which may be readily concealed ; and
by filling the cavity thus left with tallow, which is afterward to be dissolved out by spir-
its of turpentine, or, what is easier to do, the cavity of the dura mater may be filled with
fine sand.
The dura mater (meninx crassa, Galen; le meninge, Chauss.) is a fibrous membrane
which covers and protects the cerebro-spinal axis, and the roots of all the nerves which
arise from or terminate in that portion of the nervous system.
It is the most external of the membranes of the brain and spinal cord (meninx exteri-
or, Smmmering) ; it consist of a cranial and a spinal portion.
The Cranial Portion of the Dura Mater.
The cranial portion of the dura mater forms a fibrous sac, which lines the internal sur-
face of the bones of the cranium, forming their internal periosteum, and at the same time
serves £is a covering for the encephalon, and separates its different parts by means of
.prolongations or incomplete septa.
The dura mater in the scuU presents for our consideration an external and an internal
surface.
External Surface of the Dura Mater.
Its external surface is accurately moulded upon the internal surface of the bones of the
cranium, to which it adheres by a multitude of small fibrous and vascular prolongations,
which can be readily displayed by putting the membrane under water. These prolonga-
tions give the external surface of the dura mater a rough appearance, which contrasts
strongly with the smooth aspect of its internal surface. The ramifications of the mid-
dle meningeal arteries and veins are seen on the external surface of the membrane, and
project from it, as if they were only laid upon it.
The dura mater adheres to the parieties of the cranium with different degrees of
firmness in different situations.
Thus, it is generally less firmly adherent to the roof of the scull than to its base, where
it is impossible to separate it from the bone. The upper border of the petrous portion
of the temporal bone, the posterior border of the lesser wings of the sphenoid, and the
margin of the foramen magnum, are points to which it is very firmly attached ; but the
dura mater adheres more strongly opposite the sutures than in any other situation. Upon
the orbital plates, on the occipital fossae, and upon the squamous portion of each temporal
bone, it adheres so slightly, that it has been conceived to be altogether unattached in
those regions.*
* An erroneous opinion for a long time prevailed that the adhesions between the dura mater and the hones
6S4 NEUROLOGY.
The firmness of the adhesion between the dura mater and the bones varies at differ-
ent periods of life, and also the manner in which it is effected. Thus, in old subjects,
the parts are so closely united, that it is almost impossible to take off the roof of the
Bcull without, at the same time, removing portions of the dura mater. When this hap-
pens, there is ossification of the outermost layers of this membrane. In the new-born
infant, the adhesion is firmer than in the adult, especially opposite the sutures.
As to the mode in which this adhesion is effected, it may be stated, that in the infant
it appears to be exclusively by means of vessels ; in old age, almost entirely by fibrous
tissue ; and in the adult, by partly vascular and partly fibrous prolongations.
The dura mater is, moreover, attached to the bones of the cranium by means of the
fibrous canals formed by this membrane for the nerves and vessels which pass through
the foramina in the base of the- scull.
The most remarkable prolongations of the cranial portion of the dura mater, except-
ing that for the spinal cord, are those given off opposite the right and left sphenoidal
fissures. Each of these prolongations separates into two layers, one of which forms the
sheath of the corresponding optic nerve, while the other blends with the periosteum
lining the cavity of the orbits.
The Internal Surface of the Dura Mater.
The internal surface of the cranial portion of the dura mater appears smoothly polished,
and is constantly lubricated with serosity ; its polished appearance is owing to a layer
of arachnoid with which it is covered ; this layer is so thin that one might be disposed
to deny its existence, and it is so firmly united to the dura mater that its demonstration
is extremely difficult. Excepting at the points where the cerebral veins enter the dif-
ferent sinuses, the internal surface of the dura mater lined by the arachnoid is free, and
is in contact with the cerebral arachnoid, and indirectly with the outer surface of the
encephalon.
From this surface certain prolongations or imperfect septa are given off, by which the
cavity of the cranium is divided into several compartments. These septa are three in
number, viz., the falx cerebri, the tentorium ccrebelH, and the falx cerehelli.
The Falx Cerebri. — This is a fibrous lamina {d, fig. 220), which is placed vertically
along the median line, is shaped like a sickle, and extends from the foramen caecum to
the tentorium cerebelli. Its point, which is in front, dips into the foramen caecum, and
envelops the crista galli ; its base is behind, and rests perpendicularly upon the middle
of the tentorium cerebelli. The venous canal, called the straight sinus, is situated along
the line in which the falx and the tentorium meet. The upper border of the falx is con-
vex, and extends from the foramen caecum to the internal occipital protuberance. In
this border is placed the superior longitudinal sinus.
The lower border is concave, thin, sharp, and free, and corresponds to the corpus cal-
losum, touching that body, however, only at the back part, and, according to some anat-
omists, making a rather deep furrow upon it. This free border, which is thicker behind
than in front, contains within it a small vein, which has been named the inferior longi-
tudinal si7ius. The two surfaces of the falx correspond to the internal surfaces of the
two hemispheres of the brain. Not unfrequently the falx cerebri is found as if torn
through in some points, and I once observed the two hemispheres continuous with each
other through an opening in this septum.
The use of the falx is evidently to obviate the effects of lateral concussion of the
brain, and to prevent one hemisphere from pressing upon the other, while the person is
lying upon his side.
The Tentorium Cerebelli. — This is an imperfect horizontal septum (le septum trans-
verse, Chauss.), which is, as it were, notched in front, and which separates the cerebrum
from the cerebellum. It is constantly in a state of tension ; a condition which depends
upon the permanently tense state of the falx cerebri. These two parts, indeed, mutually
preserve each other's tension, and when either of them is cut, the other necessarily be-
comes relaxed. It is, therefore, only when the tentorium is examined in situ, and the
falx is left uninjured, that the anatomy of the former can be properly understood. It is
then seen that it represents two planes, inclined upward, and united in the middle line
at an obtuse angle, so as to form a sort of arch, upon the top of which the base of the
falx cerebri rests. The concavity of this arch corresponds to and is accurately fit ted
upon the convex upper surface of the cerebellum below ; the convexity corresponds to
the slightly concave under surface of the posterior lobes of the cerebrum.
Its outer or convex border is directed horizontally ; it corresponds behind to the posterior
portion of the lateral grooves, and in front to the upper border of the pars petrosa. The
lateral sinus occupies the whole occipital portion of this border.
Its inner or concave border is parabolic ; between it and the basilar groove, in front, a
small space is intercepted, which is occupied by the nodus encephali, being accurately
were the results of disease ; and it has even been believed that a space existed between the dura mater and
the bones of the cranium. These errors resulted from a physiological hj-pothesis, vi-hich attributed the move-
ments of the brain to contraction of the dura mater.
STRUCTURE OP THE DURA MATER. 66S
adapted to that part of the brain. The extremities of the external and internal borders
cross each other on each side like the letter X ; the extremities of the outer border are
attached to the posterior clinoid processes, and form on each side a sort of bridge, near
the apex of the pars petrosa, beneath which the fifth cranial nerve passes ; the extremi-
ties of the inner border are prolonged above those of the outer border, and are attached
to the anterior clinoid processes. They form the sides of the pituitary fossa, and con-
tain in their substance the cavernous sinuses.
The Falx Cerebelli. — This is a small falciform fold, situated vertically in the median
line (le septum median du ceverlet, Chauss.) ; Winslow remarks that it is sometimes
double. It extends from the internal occipital protuberance to the foramen magnum,
and separates the two hemispheres of the cerebellum. Its base, directed upward, cor-
responds with and is attached to the tentorium cerebelli ; its apex bifurcates upon the
sides of the foramen magnum. Its posterior border corresponds with the internal crest
of the occipital bone, and its anterior border with the bottom of the median fissure of the
cerebellum.
Structure.
The dura mater is perhaps the thickest and strongest of all the membranous invest-
ments of the viscera. It may be regarded as consisting of two veiy distinct fibrous lay-
ers : of an external or periosteal layer, which forms the internal periosteum of the bones
of the cranium ; and of an internal or proper cerebral layer, which, though blended with the
preceding throughout the greatest part of its extent, is separated from it at certain points,
in order to form both the fibrous canals, which are called the sinuses, and also the sev-
eral folds just described as projecting from the internal surface of the dura mater. Thus,
the periosteal layer of the dura mater enters into and lines the longitudinal groove, but
the central layer passes off from it on either side ; and the two laminae thus formed by
the right and left portions of the cerebral layer approach each other, so as to include
between themselves and the periosteal layer lining the groove a long three-sided inter-
val, which forms the superior longitudinal sinus.
The internal layer of the dura mater, which is essentially fibrous, must not be con-
founded with the arachnoid membrane by which its internal surface is lined, and which
will be presently described.
The dura mater is evidently composed of fibrous, not of muscular tissue, as was for a
long time believed.*
It consists of fibres which interlace in various directions
Anatomists generally describe, in connexion with the dura mater, those white granu-
lar bodies which are chiefly collected into clusters along the superior longitudinal sinus,
and which are improperly called glands (the glands of Pacchioni, from the name of the
author who first gave a good description of them).
These bodies are not found in infants, but exist almost constantly in the adult, and
are very numerous in old subjects. They are sometimes single and sometimes collect-
ed into groups ; they are, at first, formed upon the internal surface of the dura mater,
but after a time they displace the fibres of the internal layer, and separate them into
small, parallel, or reticulated fasciculi, and, in this way, insinuate themselves between
the two layers of the membrane. In this situation they form tumours, which project
upon the external surface of the dura mater, and occupy corresponding depressions form-
ed in the bones of the cranium. The rough and irregular depressions so frequently
found in the parietal bones of old subjects, and ascribed by the older anatomists to caries
of the bone, are occasioned by the clusters of these granular bodies.
These bodies often insinuate themselves along the obliquely running veins into the
substance of the walls of the sinuses, and project into the interior of the veins and si-
nuses, so as apparently to be in direct contact with the blood ; but they are, in reality,
separated from that fluid by the lining membrane of the vessels and sinuses.
Although these bodies are principally collected along the superior longitudinal sinus,
they are also found, as Haller remarks, opposite the anterior extremity of the straight
sinus. I have seen a small pedunculated mass of them, which projected into the inte-
rior of the horizontal portion of one of the lateral sinuses, and might have impeded the
circulation.
I consider that the bodies in question are seated in the sub-arachnoid cellular tissue ;
in fact, they are often found beneath the arachnoid, at some distance from the longitu-
dinal sinus, along the superior cerebral veins. They always project at first upon the in-
ternal surface of the dura mater, and then insinuate themselves into the substance of
that membrane.
What is the nature of these bodies 1 Ruysch noticed them, and considered them to
be of a fatty nature. Some authors have likened them to the granulations so frequently
* Pacchioni, who wrote a treatise of some length upon this membrane, even went so far as to admit the exist-
ence of three fleshy bellies, viz., one for each hemisphere, and a third for the cerebellum. The same author
gives a very minute description of the direction of the different layers of fibres in the dura mater. I do not
believe that there exists in the history of our science a more striking example of the misapplication of tcitu-
r;il anaton.y.
686 NEUROLOGY.
found in the choroid plexuses ; but there is not the slightest resemblance between the
two. Pacchioni regarded them as glands which secreted a peculiar lymph. He has
even described certain, so called, excretory ducts, which have been said by others to
enter the superior longitudinal sinus. Those clusters which project into the sinuses
have been supposed to act as valves. It has been said that these bodies are lymphatic
glands ; this, also, is erroneous ; and, indeed, it is better to confess our ignorance of their
nature. They occur so frequently that they cannot be regarded as morbid productions.
Their absence in the infant, and their much greater abundance in the old subject than in
the adult, are the principal features in their history.
Vessels. — In respect of the number and size of its vessels, the cranial dura mater
seems to form an exception to fibrous membranes in general, which are remarkable for
their slight vascularity. It receives, in fact, the following arteries : the middle menin-
geal, which is a branch of the internal maxillary artery ; the anterior meningeal, from
the ethmoidal artery ; and the posterior meningeal, from the ascending pharyngeal, or
pharyngo-meningeal. Nevertheless, if we consider that these vessels are situated be-
tween the dura mater and the bones, and that they are ahnost entirely distributed to the
bones, we shall be able to account for the apparent anomaly in the number and size of
these vessels.
The veins of the dura mater are two venae comites for each meningeal artery, and the
small veins which enter the sinuses ; the venous sinuses themselves are situated be-
tween the two layers of this membrane.
The lymphatics form a network upon the internal surface of the dura mater, but do not
appear to belong to the proper fibrous tissue.
Nerves of the Dura Mater. — On consulting the various writers upon this subject, it is
found to be involved in the strangest perplexity : some authors admit, while others deny
in the most positive manner, the existence of nerves in this membrane ; and those who
do admit their existence, differ altogether in regard to their origin.
Modem anatomists, with Haller, Wrisberg, and Lobstein, state that there are no
nerves in the dura mater ; on the other hand, Vieussens, Winslow, Lieutaud, Lecat, Val-
salva, and others, declare that they have observed them. Valsalva says that they are
derived from the seventh pair ; all the other authors state that they arise from the fifth ;
but they do not agree as to the exact point of origin, which, according to some, is the
Gasserian ganglion ; and according to others, either the ophthalmic, or the superior or
inferior maxillary divisions of that nerve. Chaussier admits their existence, and says
that they are derived from the ganglionic system ; but it is evident that he has been led
to this conclusion from theory, and not from actual observation.
Accident has enabled me most distinctly to demonstrate nerves in the dura mater.
In a head which had been macerated in diluted nitric acid, and afterward in water, the
dura mater having become transparent and jelly-like, I was surprised to see within its
substance certain white lines exactly resembhng nervous filaments. I cut down to these
white lines, ascertained that they were nerves, and dissected them throughout their
whole course. I recognised on each side of the middle line two nervous filaments which
came from the fifth nerves, and reached nearly to the superior longitudinal sinus. There
was a third nervous filament in the substance of the tentorium cerebelli, but I could not
ascertain its origin.*
Uses of the Cranial Dura Mater. — The dura mater serves as an internal periosteum for
the bones of the cranium, with which it has numerous vascular connexions ; and it also
covers and defends the encephalon. Its prolongations separate from each other the dif-
ferent parts of the encephalon, and in some measure prevent the effects of concussion.
It also contains within its substance certain venous canals, in which aU the blood is re-
turned from the encephalon.
The Spinal Portion of the Dura Mater.
The spinal portion of the dura mater forms a long fibrous tube, which is prolonged from
the cranial dura mater, and extends from the occipital foramen to the termination of the
sacral canal.
In order to ascertain the capacity of this fibrous sheath, it must be first distended with
an injection : it is then seen to form a funnel-shaped tube, which is of considerable size
in the cervical region, becomes contracted in the dorsal region, is again expanded in the
lumbar region, and terminates in the sacral region by subdividing into a number of sheaths
for the sacral nerves. When distended, the spinal portion of the dura mater almost en-
tirely fills the bony canal formed by the vertebral column. Why the cavity of the dura
mater (d, fig. 266, A B) should be larger than the spinal cord (s), a question the solution
of which had exercised the ingenuity of almost all anatomists, has been well answered
by Cotugno — it is for the purpose of containing a serous fluid, t
* [The tentorium receives a branch from the fourth cranial nerve (see description of that nerve).]
t " Quidciuid autera spatii est inter vaginam durae matris et meduUam spinalem, id omne plenum etiam sem
per est ; non medullft. quidem ips& in viventibus turgidiori, non nube vaporos^, quod in re adhuc obscurft sus
picantur summi ^nri ; sed aqu& ei quidem simili, quam circa cor coutinet pericardium, quae caveas cerebri ven
triculorum adimplet, quae auris labyrinth um, quae reliquas tandem complet corooris caveas, libero aeri, nequa
" — ' rjf Ischiade Nervosa, p. U.)
THE CRANIAL PORTION OF THE ARACHNOID.
The external surface of the spinal portion of the dura mater, unlike, in this respect, to
the cranial portion, scarcely adheres to the bony parietes of the spinal canal. Covered
by a plexus of veins behind, it has no attachment at all to the arches of the vertebrae, nor
to the yellow ligaments ; the intervals between those parts and the membrane is occu-
pied by a soft, reddish, adipose tissue intermixed with veins, which, in the foetus, and
during infancy, is infiltrated with serosity. This fat, which is most abundant in the sa-
cral region, may be most aptly compared to the marrow of the long bones, with which
it has so much analogy in respect of its use. In one class of vertebrated animals, viz.,
fishes, a precisely similar kind of fat is accumulated in large quantities in the cranium,
always filling up the spaces left by the contained organs.
In front, the external surface of the dura mater adheres to the posterior common ver-
tebral ligament by fibrous bands prolonged from it at intervals.
On each side, the spinal portion of the dura mater gives off fibrous sheaths {I, fig. 266 ;
h', fig. 267) for the roots of the spinal nerves (w), which sheaths accompany the nerves
beyond the inter-vertebral foramina, and are lost in the cellular tissue.
The internal surface of this part of the dura mater is smooth and moist, in consequence
of being covered by a serous layer, viz., the arachnoid (a). Down each side of this sur-
face are seen the double orifices of the several fibrous canals, which transmit the ante-
rior and posterior roots of the spinal nerves. It is very rarely found entirely free from
adhesions to the arachnoid ; and it is necessary to be careful not to confound these ad-
hesions, which are always met with at isolated points, with such as are the result of
morbid action.
The inferior extremity of the spinal portion of the dura mater is situated opposite the
bottom of the lumbar region, and it therefore extends much lower than the spinal cord ;
this extremity is formed into a large ampulla around the cauda equina, which enlarge-
ment seems to be of use only as a reservoir for the cephalo-rachidian fluid.
Its superior extremity is firmly attached to the margin of the foramen magnum, and is
continuous with the cranial portion of this membrane. In consequence of the firm ad-
hesion of this membrane to the margin of the foramen magnum, and of its attachment
to the sacrum by means of the sheaths for the sacral nerves, and to the sides of the ver-
tebred column by those for the cervical, dorsal, and lumbar nerves, it is constantly main-
tained in a state of tension highly favourable to its use as a protecting covering of the
spinal cord.
Vessels. — The vessels of the spinal dura mater are much less numerous than those of
the cranial portion ; for these belong exclusively to it, and not to the surrounding bones.
Its arteries arise from the spinal branches of the arteries of the cervical, dorsal lum-
bar, and sacral regions. Its veins terminate in the intra-spinal veins.
The lymphatic vessels observed appear rather to belong to the arachnoid.
The nerves of this membrane have not yet been demonstrated ; but experiments upon
living animals, especially upon dogs, have convinced me that the cranial, and probably,
also, the spinal portion of the dura mater, although insensible to the knife, are extreme-
ly sensible to laceration.
The Arachnoid.
The cerebro-spinal axis is surrounded by a serous membrane named the arachnoid,
which, like all membranes of this kind, forms a shut sac, adherent by its external sur-
face, but free and smooth on its internal surface. We shall first describe the cranial, and
then the spinal portion of the arachnoid.
The Cranial Portion of the Arachnoid.
Dissection. — The arachnoid may be shown upon the convex surface of the brain with-
out any preparation, if the sub-arachnoid cellular tissue be infiltrated. It can also be
very easily demonstrated by blowing air under it.
The arachnoid membrane, which, from its extreme tenuity, was for a long time con-
founded with the pia mater, was demonstrated by Ruysch upon the convex surface of
the brain by injecting air beneath it ; it was shown by Varolius upon the base of that
organ, and its arrangement in that situation was figured by Casserius. It was descri-
bed first by the Anatomical Society of Amsterdam as a special membrane covering the
brain, under the name of the arachnoid; and Bichat, reasoning from analogy, demonstra-
ted that it not only forms a covering for the brain, but is also reflected upon the dura
mater, and lines it through its whole extent. He also believed that it was continuous
with the lining membrane of the ventricles, an error which has been successfully refu-
ted by M. Magendie.
Like all serous membranes, the arachnoid presents a visceral and a parietal layer
The Visceral Layer of the Arachnoid.
The visceral layer of the cranial portion of the arachnoid requires to be exammed upon
the convex surface and the base of the brain.
Upon the base of the brain, the arachnoid is separated from this organ in a great num-
NEUEOLOGY.
ber of points, and more particularly as it is passing from one lobe to another. We shdll
-examine in detail the arrangement of this part of the membrane.
In the median line, in frmit, it dips between the anterior lobes of the brain, but only at
the fore part ; behind, it connects these lobes by passing directly from one to the other ;
it covers the lower surface of the optic nerves and optic commissure, then the tuber
cinereum and the infundibulum, for the latter of which it forms a sheath, and is then re-
flected above the pituitary body ; from the tuber cinereum it passes across to the pons
Varolii, leaving a hollow space between it and the brain, which is traversed by a few
dense fibrous filaments.
I shall call this space the anterior sub-arachnoid space ; it may be regarded as the prin-
cipal reservoir of the serous fluid of the cranium.
In the median line, lehind, the arachnoid lines the furrow between the posterior lobes
of the brain, and is reflected from the corpus callosum upon the superior vermiform pro-
cess of the cerebellum : at this point it meets with the venae Galeni, and generally forms
a circular fold around them, which was compared by Bichat to the foramen of Wins-
low in the peritoneum, and which he supposed to be the orifice of an arachnoid canal,
which opened into the third ventricle beneath the velum interpositum.
The arachnoid covers the whole upper surface of the cerebellum ; and, having reached
the great circumference of that organ, it passes like a bridge from one hemisphere to the
other, and from the cerebellum itself to the posterior surface of the spinal cord. In thus
passing from one hemisphere of the cerebellum to the other, and from the cerebellum
to the spinal cord, the arachnoid leaves a considerable space or reservoir for serosity,
which may be called the posterior sub-arachnoid space.
Laterally, the arachnoid covers the inferior surface of the anterior lobes of the cere-
brum and the olfactory nerves, which are thus held in contact with the anterior lobes ;
it then passes from the anterior to the posterior lobe, without entering the fissure of
Sylvius, and from the posterior lobe to the tuber annulare and the cerebellum. It fol-
lows, therefore, that there are certain small sub-arachnoid spaces which communicate
with the great anterior sub-arachnoid space of the brain ; so that in the dead body there
exists, between the arachnoid and the pia mater, at the base of the brain, a large space,
the centre of which corresponds to the median excavation of the base of the cerebrum,
and which is prolonged forward between the anterior lobes of the brain, laterally along
each of the fissures of Sylvius, and backward, around the peduncles of the cerebellum.
By this last-named prolongation a communication is established between the anterior
and posterior sub-arachnoid spaces. All these spaces contain serum in the natural
state, and coagulable lymph in some cases of inflanmiation of the sub-arachnoid cellular
tissue.
The arachnoid is arranged in a uniform manner in reference to all the nerves situated
at the base of the brain ; it passes over their lower surface, and therefore holds them
firmly against the under surface of the brain ; but where these nerves are separated
from the brain it furnishes a tubular prolongation around each, and again leaves them
as they are about to enter the foramina in the base of the scull, and is reflected upon the
dura mater.
Upon the upper surface of the brain, the arachnoid dips into the median fissure, and is
reflected from one hemisphere to the other immediately below the free margin of the falx
cerebri ; and as this margin is nearer to the corpus callosum behind than in front, it fol-
lows that the anterior portions of the two hemispheres are in contact with each other
for a certain distance, or, rather, they are merely separated by the pia mater.
The cerebral arachnoid adheres intimately to the arachnoid of the dura mater, along
the sides of the superior longitudinal sinus, by means of the tubular prolongations which
it forms around the cerebral veins that enter that sinus. This adhesion is also strength-
ened by the granular bodies called the glands of Pacchioni, which, as we have already
stated, lie in the substance of the dura mater.
Moreover, on the convex surface, as well as upon the base of the brain, the arachnoid,
in covering this organ, passes, like a bridge, from one convolution to another, never dip-
ping into the intermediate sulci.
The cellular tissue, which unites the arachnoid to the pia mater, is of a serous nature
and extremely delicate, so that the two membranes can be easily separated, excepting
in cases of inflammation. When air is blown beneath the arachnoid, the extreme tenu-
ity of this cellular tissue becomes evident : it is very frequently infiltrated with a serous
fluid.
The sub-arachnoid cellular tissue never contains any fat. The fat which Ruysch,
Haller, and other anatomists say they have observed, must have been that yellowish,
gelatiniform lymph so commonly met with in cases of inflammation.*
In some parts the arachnoid is lined by a fibrous tissue, which gives it great strength.
This fibrous tissue, which may be regarded as a prolongation of the neurilemma of the
spinal cord, is especially distinct in the great furrows of the brain. Thus we find it
* I onoe found in an old woman an adipose cyst, about the size of a small grape, arising by a very thin ped-
icle from the upper surface of the pituitary body.
THE PARIETAL LAYER OP THE ARACHNOID. 689
around the great anterior sub-arachnoid space, where it constitutes, as it were, a very
strong fibrous band, which surrounds the arterial circle of Willis, situated at the base of
the brain ; it also retains the different parts of the brain in their relative positions, even
when that organ is removed from the cranium, and is laid with its base uppermost.
The Parietal Layer of the Arachnoid.
The internal surface of the dura mater is lined with a very delicate and closely-ad-
herent serous membrane, which, owing to these two qualities, for a long time escaped
the notice of anatomists. It was only by reasoning analogically from the structure of
all other serous membranes, that Bichat was led to enter upon the inquiry which ended
in the discovery of the parietal portion of the arachnoid. This portion is quite distinct
from the internal layer of the dura mater, the existence of which we have admitted
with several anatomists. Upon a mere inspection, we should say that it does not exist,
because, from its transparency, the fibrous bundles of the dura mater can be seen as dis-
tinctly as if they were not covered. But if a very superficial incision be made upon the
inner surface of the dura mater, some extremely thin shreds may be detached by the
aid of the forceps. Lastly, ecchymosis not unfrequently occurs between the dura mater
and the arachnoid.* Ossilic deposites in the dura mater, especially those found in the
falx cerebri, being found beneath the arachnoid, sometimes enable us to detach this lat-
ter membrane in the most distinct manner.
It still remains, however, to describe the mode in which the parietal and cerebral por-
tions of the arachnoid become continuous with each other. It has been stated that the
arachnoid membrane forms tubular prolongations around each of the nerves which are
given off from the base of the brain, and around each of the veins which enter the dif-
ferent sinuses ; these prolongations just enter the fibrous canals formed by the dura
mater for these nerves and veins, and almost immediately terminate by being reflected
upon the dura mater itself ; so that the arachnoid forms a sort of cul-de-sac around the
cranial orifice of each fibrous sheath of the dura mater. In order to see the funnel-
shaped prolongations of the arachnoid, it is convenient to examine them when the brain
is being lifted up from before backward, in order to expose and divide the nerves which
are attached to the base of the scuU. The tubular prolongations being then dragged
upon, they become very distinct. Not unfrequently, the development of adventitious
false membrane on the base of the brain also extends along these prolongations.
The arachnoid does not enter into the interior of the ventricles, below the posterior
border of the corpus callosum. The arachnoid canal, called the canal of Bichat, does not
exist, but it is formed by the very experiment made to demonstrate it. The following
is the statement of Bichat regarding this alleged canal :
" The brain being exposed from behind and allowed to remain in its natural position,
the back part of each posterior lobe is to be raised, and drawn gently outward ; the ve-
nae Galeni are then seen emerging from the canal by which they are embraced, and the
oval orifice of which is now very apparent. Sometimes, however, the margin of this
orifice embraces the veins so closely, that it can only be recognised by a small fissure
on each side, and the parts, at first sight, would appear to be continuous. If a probe be
then glided from behind forward along these vessels, and when it has penetrated a short
distance, if it he turned all round the veins it will destroy the adhesions, and the opening vnH
become very evident.
" In order to be convinced that this opening leads into the middle ventricle of the
brain, a grooved director must be introduced below the venae Galeni and pushed gently
forward : it will enter the ventricle without difficulty. The corpus callosum and the for-
nix are then to be removed, and the velum interpjjsitum left untouched. Next, dividing
the velum on the director, the membrane will be found to be smooth and polished in the
whole of its course, and nowhere lacerated by the introduction of the director. Occa-
sionally some resistance is experienced to the entrance of the director, which may even be com-
pletely arrested : this depends upon the fact that the veins which enter the vena Galeni inter-
lace in all directions within the canal, so as to form a network, which arrests the instrument.
If this be the case, it should be withdrawn, and, in order to demonstrate the communi-
cation, some mercury should be poured into the external opening, and, by inclining the
position of the head, this fluid will flow into the middle ventricle. Air blown into the
canal will also enter that ventricle, and will pass from it into the lateral ventricles through
the openings behind the anterior pillars of the fornix. If the fornix be removed, and
the velum be exposed, the latter will be seen to be elevated each time that the air is
blown in.
" The internal orifice of this communicating canal is at the lower part of the velum
interpositum ; in order to see it, this membrane must be reflected backward, either with
the fornix, the under surface of which it covers, or after it has been separated fram that
part of the brain. The pineal gland which adheres to the velum is also to be turned
* As to the collections of blood which are said to have been met with between the arachnoid and the dnra
mater, M. Baillarget has clearly shown, in several preparations which he presented to the Anatomical Soci-
ety, that the supposed laver of arachnoid is a newly- formed membrane, having all the appearances of a serous
membrane.
4 S
690 ' VEUROLOGY.
back ; below and in front of this gland is then seen a row of cerebral granulations, ar-
ranged in the form of a triangle, having its point turned forward. The internal orifice
of the canal of the arachnoid is at the base of this triangle."
Now, if we make the dissection described by Bichat, it is easy to see that there exists
at the back part of the brain, below the corpus callosum, a circular or oval opening, lead-
ing into a sort of cul-de-sac, which is of variable depth, and is formed by the reflection
of the arachnoid around the venae Galeni : it is seen, also, that the bottom of this cul-de-
sac may be easily lacerated by a blunt probe, which may then be passed beneath th<
velum interpositum, as Bichat has pointed out ; but it is through an artificial canal.
Moreover, if a coloured liquid be injected into the ventricles, it can never be made to
escape through this imagined canal of Bichat ; and so, on the other hand, if a liquid be
thrown into the orifice of this canal, it never enters the third ventricle : mercury enters
only by lacerating the parts ; and the same is the case with air. Analogy, which has
so often conducted Bichat to beautiful and grand discoveries, has, therefore, misled him
in this particular.
Since, then, the arachnoid canal of Bichat does not exist, it will be necessary to de-
termine how the ventricles communicate with the external arachnoid cavity. This
question we shall discuss presently.*
The Spinal Portion of the Arachnoid.
The spinal cord, besides its own proper investment, is covered by a transparent mem-
brane of extreme tenuity, and only to be demonstrated properly by raising it with the
forceps, or by subjecting it to the mode of preparation above described : this is the vis-
ceral layer of the spinal portion of the arachnoid.
The visceral layer (b, fig. 266, A B) forms a membranous sheath, which is much larger
than the spinal cord (*) ; hence it is named the loose arachnoid. It is
prolonged around the bundle of nerves called the cauda equina, and forms
around each nerve a funnel-shaped sheath, which terminates in a cul-
de-sac at the corresponding inter-vertebral foramen, by being reflected
upon the inner surface of the fibrous sheath formed for the nerve by the
dura mater (see^^. 266, B).
There exists, then, between the spinal cord and the visceral portion
of the arachnoid a considerable space (e, fig. 266, A B), which can be
best displayed by inflating it, or injecting it with some liquid. This
space, as we shall immediately show, contains a serous fluid.
We have seen that, opposite the median excavation at the base of
the brain, the arachnoid adheres to the cerebral pia mater only by means
of long fibrous filaments. The spinal arachnoid also adheres to the proper covering of
the cord by means of fibrous filaments ; but in no part does there exist any delicate sub-
arachnoid cellular tissue, like that found beneath the cerebral arachnoid.!
Another peculiarity in the visceral layer of the spinal portion of the arachnoid is this,
that it adheres to the parietal layer in a number of points.
The parietal layer (a) of the spinal portion of the arachnoid is arranged precisely in the
same manner as the parietal layer of arachnoid in the scull. It becomes continuous
with the visceral layer opposite the sheaths which are formed by the latter around the
spinal nerves.
The Sub-arachnoid Fluid.
There exists around the spinal cord a serous fluid, in quantity suflicient to occupy the
interval left between the cord and the dura mater : this fluid is seated in the sub-arach-
noid space (e). A similar fluid exists in the ventricles of the brain and in the sub-arach-
noid cellular tissue, and fills the free spaces of the cranial cavity.t
The existence of the sub-arachnoid fluid was pointed out by Haller (Elcmcnta fhysi-
ologicB, t. iv., 87), and most explicitly and completely demonstrated by Cotugno (I>e ischi-
ade nervosa commcntarium), but the fact was neglected by anatomists, and the fluid re-
garded by some as the result of cadaveric exudation, and by others as that of a morbid
action. The existence of this fluid has been again confirmed by M. Magendie, who,
moreover, has clearly proved that it is seated in the sub-arachnoid tissue.
In order to prove the existence of the sub-arachnoid fluid, or cephi o-iaunoian nuid
* [The existence of the canal of Bichat is admitted by Arnold, a recent authority. Perhaps the opposite
statements of anatomists concerning this canal may depend on the fact that the canal itself, though originally
present, is sometimes closed subsequently, and at other times remains open.]
t [The spinal sub-arachnoid space is divided behind by a thin, and, in some parts, cribriform longitudinal
septum, which extends from the loose arachnoid to the posterior median fissure of the cord. This space is
probably4i>ied throughout by a serous membrane, which contains the rachidian fluid, and which might be
named the internal arachnoid. The septum just mentioned may be supposed to consist of two layers of thJB
membrane reflected from the loose arachnoid to the cord, and having the same relation to it as the mesentery
has to the intestine ; and the membrane itself may be conceived to.be prolonged through the foramen described
by Magendie at the Ijottom of the fourth ventricle (see p. 718), so as to form the lining membrane of the fourth,
third, and lateral ventricles ; and, farther, in case of the existence of the foramen of Bichat, to become con-
tinuous with the external or true arachnoid through that foramen.]
THE SUB- ARACHNOID FLUID. 691
of Magendie, it is necessary to open the lumbar region of the spinal canal in a certain
number of subjects. If an incision be very carefully made through the dura mater, it
will be seen that the serous fluid raises the visceral layer of the arachnoid, so as to make
it protrude like a hernia through the incision : if this layer of arachnoid be then divided,
the liquid will escape. Cotunni, who performed this experiment upon tw^enty subjects,
collected from four to five ounces of fluid in each case.
To the objection that this fluid is found after death, but does not necessarily exist in
the living subject, we may answer thus : There is a space between the spinal cord and
the dura mater, and the brain itself does not exactly fill the cranial cavity. Now in no
part of the animal body does there exist any vacuum ; the spaces between the solids are
always filled either with liquids or gaseous fluids. But if it be said that in this situation
the space is filled by a serous vapour, the elasticity of which might establish an equilib-
rium with the external air, it may be replied, that this vapour would not be sufficient to
produce so large a quantity of fluid as is found in the spinal canal.
Moreover, all these objections, and also the supposition that the brain and spinal cord
may be smaller after death than during life, are overthrown by the following experiment.
If the posterior cervical muscles be divided in a living dog, at their occipital attachments,
the posterior occipito-atlantoid ligament will be exposed. The parts being weU cleansed
from blood, the ligament must be cut away, layer by layer, with a scalpel held flat against
it. The ligaments will scarcely be cut through before a small hernial protrusion, con-
taining a fluid, will be seen ; this consists of the visceral arachnoid raised by the rush
of fluid. If a crucial incision be then made in the occipito-atlantoid ligament, by the aid
of a director,* a fluid as limpid as distilled water will be seen beneath the visceral layer
of the arachnoid, which fluid is agitated by two kinds of motion, one of which is isochro-
nous with the pulse, and the other with the respiratory movements. If the arachnoid
be next punctured, the fluid will immediately escape in jets, and its quantity may be as-
certained.
The difficulty of not wounding the visceral layer of the arachnoid explains why, until
recently, it was thought that the spined fluid was contained within the arachnoid cavity
{c,jig. 266), i. e., between the two layers of the arachnoid membrane, although most ob-
servers had noticed that the serous fluid in the cranium occupied the sub-arachnoid cel-
lular tissue. It follows, therefore, that besides the fluid which is exhaled from the free
surface, i. e., into the cavity of the arachnoid, a certain quantity of a similar fluid fills up
the areolar tissue of the sub-arachnoid space : in this respect the arachnoid differs es-
sentially from other serous membranes, all of which pour their secretions into their cav-
ities, and not into the subjacent cellular tissue.
This peculiarity depends simply upon the non-adhesion of the arachnoid to the spinal
cord ; it may be stated as a law, that serous membranes exhale almost indifferently
from either their internal or their external surface, when the latter surface is not adhe-
rent. The arachnoid exhales a fluid from both surfaces ; a certain quantity of fluid is
rather frequently found between its two layers ; and although, in acute inflammations,
the deposite of purulent matter or of false membranes most generally takes place in the
sub-arachnoid cellular tissue, yet these morbid products are not unfrequently found in
the cavity of the spinal arachnoid itself
The sub-arachnoid fluid exists not only in the vertebral canal, but also within the cra-
nium, in which it fills up all the spaces between the brain and the dura mater.
Now these spaces are subject to much variety in size in different individuals, or from
age or from disease : thus, in atrophy of the brain and spinal cord, from old age or dis-
ease, the interval between the dura mater and the cerebro-spinal axis is augmented, and
the quantity of fluid increases in the same proportion.
The quantity of the sub-arachnoid fluid is in a direct ratio with the progress of age ;
in aged lunatics, in whom the convolutions of the brain are much atrophied, the quanti-
ty of this fluid contained within the cavity of the cranium is very great, t
The sub-arachnoid fluid in the cranium is not distributed equally around the brain, but
is chiefly seated at its base. In order to show this fluid, it is merely necessary to raise
up the brain carefully from before backward, when it will be seen distending all the fun-
nel-shaped prolongations formed by the arachnoid around the nerves, and it will escape
as soon as the membrane is divided.
As regards quantity, the sub-arachnoid fluid at the base of the brain and the fluid of
the ventricles are always directly proportioned to each other, but are inversely propor-
tioned to the sub-arachnoid fluid upon the convex surface of the brain. Upon opening
the head of infants who have died from acute ventricular hydrocephalus, we sometimes
* It is highly important to make the transverse incision very short, in order to avoid injuring- the very large
vertebral veins ; for if these vessels be cut, the hemorrhage will be so abundant as to prevent the continuation
of the experiment.
t None of these facts escaped the notice of Cotugno :
" Nee tantnm 'axe aqua complens ab occipite ad usque imum os sacrum, tubum dun-e matris . . . sed et u
ipso redundat calcarise cavo omniaque complet intervalla quae inter cerebrum et durse matris ambitum )nven>
antur .... quantum autem magnitudinis cerebrum in his perdit, tantum a contactu subtrahitur durs matns
et quidquid loci decrescendo reliquit, aquosus vapor coUectus lotum adimplet." — (Op. cit., p. 11. 12.)
692 NEUROLOGY.
find the convex surface of the brain dry, and, as it were, adhesive. It is of importance
to determine whether the cavities containing the cephalic and the spinal fluids commu-
nicate with each other. There can be no doubt that the sub-arachnoid spaces of the
brain communicate with the sub-arachnoid space around the spinal cord ; but do the
cavities of the ventricles communicate with the sub-arachnoid space 1
Haller admitted that the fluid could flow from the ventricles into the spinal canal, and
he believed that this was effected by a communication between the ventricles and the
cavity of the arachnoid itself* Cotugno expresses the same opinion still more distinct-
ly. Both Haller and Cotugnot thought that this communication occurred at the bottom
of the fourth ventricle, but they neither indicated the exact situation, nor the mode in
which it is effected. M. Magendie has pointed out that it occurs at this very spot, near
the point of the calamus scriptorius. Bichat stated that the communication between the
ventricles and the arachnoid cavity was at the so-called canal of Bichat. The mode in
which the fourth ventricle communicates with the sub-arachnoid space will be much
better understood if stated in our description of that ventricle, t
Uses of the Arachnoid and of the Sub-arachnoid Fluid.
Uses of the Arachnoid. — Like all serous membranes, the essential use of the arachnoid
is to lubricate the surface of the brain and spinal cord, and thus facilitate their move-
ments. No other membrane more completely fulfils such a use, for the arachnoid is
moistened in both its external and internal surfaces. It would, in fact, be an error to
suppose that the serous secretion is poured out solely by that surface of the arachnoid
which is turned towards the pia mater : the fluid is exhaled upon its internal surface
also, as in all other serous membranes, so that we sometimes find serum, pus, and false
membranes in the cavity of the arachnoid itself
Uses of the Sub-arachnoid Fluid. — The sub-arachnoid fluid forms a sort of bath around
the spinal cord, which effectually protects it during the various motions of the vertebral
column. It might be said that the spinal cord, being, in reference to its delicacy, in con-
ditions somewhat analogous to those of the foetus in utero, requires a similar method of
protection ; and in this point of view the sub-arachnoid fluid exactly represents the liquor
of the amnios.
As to the other uses which have been attributed to it, they are all more or less hypo-
thetical.
If we open the spinal canal of a dog, between the atlas and the occipital bone, some
fluid will immediately gush out ; air is drawn in, which is forced out in bubbles during
expiration, and again enters during inspiration. If the animal be then left to himself, he
will stagger like a drunken man ; he will crouch into a comer, and remain in a drowsy
state for some hours. On the next day he will walk about again perfectly well. I have
repeated this operation several times upon the same dog, until at last he became accus-
tomed to it, at least as far as regards the physiological effects resulting from the remo-
val of the fluid, by which means the slight pressure usually exercised upon the spinal
cord was removed.
The Pia Mater.
The pia mater is the innermost of the three membranes of the encephalon and spinal
cord. It consists of an extremely delicate membrane, or, rather, of a vascular network,
which inunediately invests the nervous axis, and which may be regarded as the nutri-
tious membrane of the parts that are covered by it. In fact, the arterial vessels divide
into an infinite number of branches within this membrane before they enter the nervous
substance, and so, also, the veins which pass out from the brain and spinal cord unite
into small, and then into larger vessels, which form part of this same network. These
vessels are supported by a very delicate serous cellular tissue : to this is added, in some
regions, a certain amount of fibrous tissue, which converts the membrane into a very
strong fibrous structure, having all the characters of the neurilemma, or proper invest-
ment of the nerves.
The characters of the spinal portion of the pia mater are so distinct from those of the
cranial portion, that it will be better to postpone the description of the former until we
are treating of the spinal cord, of which it constitutes the proper covering.
The Cranial Portion of the Pia Mater.
This portion, or the cerebral pia mater, does not merely enclose the brain like the arach-
noid, but dips into the sulci or anfractuosities on its external surface, and penetrates into
the interior of the ventricles. That portion of the pia mater which invests the brain is
* " Qua prodit de ventriculo aqua, facili in medullse spinalis circumjectum spatium etiam parat ; earn aquam
enim difficulter omnino in tertium ventriculum et ad infundibulum redderet, quoad perpendiculum oportet a»-
cendere (Haller, torn, iv., sect. 3, p. 77) . . . Non dubito quin coUecta ex ventriculis cerebri aqua eo descen-
dere possit." — (Ibid., sect. 3, p. 87.)
t " His spinae aquis eas etiam subinde commisceri, quas, sive a majoribos cerebri ventriculis per lacunar et
Sylvii aqueductum, sive a propriis exhalantibus arteriis, cerebelli ventriculus accipiat ; cujus positio perpen-
diculata et via ad spine cavum satis patens defluxum liumoris in spinam manifest! persuadent." — {Cotugno,
p. 18, 19.) t See note, p. 960.
THE EXTERNAL CEREBRAL PIA MATER, ETC. 693
called the external pia mater, and that which is continued into the ventricles is denomi-
nated the internal pia mater.
The internal pia mater cannot be satisfactorily studied until the internal conformation
of the brain is understood, and it will therefore be described together with the ventricles.
The External Cerebral Pia Mater.
Dissection. — At the base of the brain, the pia mater is naturally separated from the
arachnoid by a considerable space, which is occupied by the sub-arachnoid fluid ; but it
is easy to separate these two membranes everywhere by introducing air or water be-
tween them. The arachnoid may be easily distinguished from the pia mater in cases
of serous or purulent infiltration into the sub-arachnoid cellular tissue.
The external pia mater is subjacent to the arachnoid, and is connected with it by a very
delicate serous cellular tissue ; it not only covers the free surface of each convolution,
but also dips into the adjacent sulci ; it passes down on one side of a sulcus, and then,
being reflected upon the other, is continued over the free surface of the next convolu-
tion, and so on. It follows, therefore, that this part of the pia mater is in contact with
itself to a great extent ; and also that its superficies is much larger than that of the
arachnoid, so that if the brain could be unfolded, as Gall supposed, its surface would be
entirely covered by the pia mater. These remarks apply equally to the pia mater of the
cerebellum, for every one of the numerous leuninae of that organ is covered on each side
by a fold of the pia mater.
The internal surface of the pia mater is in contact with the brain, and is united to it
by innumerable vessels, which penetrate into the substance of that organ. This adhe-
sion, however, is such, that the pia mater can generally be detached without injuring
the surface of the brain.
I do not think, however, with some pathologists, that the adhesion of this membrane
to such a degree that it cannot be removed without injuring the substance of the brain
is any evidence of disease.*
For displaying the vessels which pass into the substance of the brain from the pia
mater, an asphyxiated subject is very well adapted. But an injected condition of these
vessels may be produced by allowing the head of the subject to hang down for some
hours. The pia mater will then be not only black from its congested state, but it will be
infiltrated with serum ; and if it be detached slowly, an immense number of vascular
filaments, looking like hairs, will be seen emerging from the substance of the brain, re-
markable for their extreme tenuity and length, and for having no anastomoses. Some
drops of blood will indicate the points upon the surface of the brain from which the ves-
sels escape, and which, when examined through a lens, prove to be foramina.
The use of the pia mater is connected solely with the circulation of blood through the
brain. This membrane affords to the vessels a very large surface, on which the arteries
divide into their capillary branches, and the veins unite into their larger and larger
trunks. According to my observations, five sixths of the vessels of the pia mater belong
to the venous system.
The pia mater is the nutritious membrane of the brain, and may thus be regarded as
its neurilemma.
It will afterward be seen that the internal pia mater is connected with the arteries
and veins of the walls of the ventricles, ^ust as the external pia mater is with the ex
ternal vessels.
THE SPINAL CORD AND THE MEDULLA OBLONGATA.
General View of the Cord — its Limits and Situation — the Ligamentum Denticulafum. — Size
of the Spinal Cord — Form, Directions, and Relations — the Cord in its proper Membrane —
the proper Membrane, or Neurilemma of the Cord — the Cord deprived of its proper Mem-
brane.— Internal Structure of the Cord — Sections — Examination by Means of Water — and
when hardened in Alcohol — the Cavities or Ventricles of the Cord. — The Medulla Oblonga-
ta— Situation — External Conformation — Anterior Surface, the Anterior Pyramids, and the
Olivary Bodies — the Posterior Surface — the Lateral Surfaces — the Internal Structure —
Sections — Examination by Dissection, and under Water. — Development of the Spinal
Cord. — Development of the Medulla Oblongata. — Comparative Anatomy of the Spinal
Cord. — Comparative Anatomy of the Medulla Oblongata.
The spinal cord (fzvelog jidxiTTig, medulla spinalis, a b c, fig. 268)'is that white, round-
ish, symmetrical, nervous trunk, which occupies the spinal canal ; it is continuous with
the encephalon, of which it has been alternately considered the origin and the termina-
tion. It is called the medulla, in consequence of a rude analogy between it and the mar-
row of the long bones, in regard to its situation and consistence. Chaussier has sub-
* In some cases the membranes are so dry that the pia mater cannot be removed without tearing the sub
itance of the brain, even when that organ is perfectly healthy.
094 NEUKOLOGY.
stituted for this term the title of racfddian prolongation, but the generally received name
of spinal marrow, which can give rise to no error, might be retained.*
The Extent and Situation of the Spinal Cord.
Authors are not agreed as to the superior limit of the spinal cord. The natural limit
is evidently at the groove, between the medulla oblongata (a. Jig. 268) and the pons
Varolii (e), which groove, on account of the great size of the pons in man, is much more
distinctly marked in him than in those vertebrated animals in which the pons is also
found.
The spinal cord is situated in the median line, at the back part of the trunk ; it is be-
hind the organs of digestion, circulation, and respiration, t
The vertebral column, the dura mater, the arachnoid, and the pia mater form a fourfold
sheath for the spinal cord ; the first being osseous ; the second, fibrous ; the third, serous ;
and the fourth, or proper sheath, both fibrous and vascular ; this last-named membrane
is accurately adapted to the cord, so as to support it, and gently compress it on all sides.
The spinal cord is not suspended freely in the vertebral canal, but is attached on each
side by a ligament called the ligamentum denticulatum.
The Ligamentum Denticulatum.
The ligamentum denticulatum (c c, fig. 267), so called from the toothlike prolongations
Fig. 267. which proceed from its outer border, is an extremely slen-
der, fibrous band, which runs along the side of the spinal
cord, and adheres to the proper sheath of the cord by its
inner border, which is very thin. The outer edge is free,
thicker than the inner portion, and gives off certain tooth-
like prolongations, which are attached to the dura mater in
the intervals between the canals formed by that membrane
for the spinal nerves : the first denticulation of this liga-
ment, which may be regarded as its origin, is very long, and
is found opposite the margin of the foramen magnum, be-
tween the vertebral artery and the hypoglossal nerve ; the
last, which is the twentieth or twenty-first, forms the ter-
mination of the ligament, and corresponds very nearly to
"^3 the lower extremity of the spinal cord. The form, thin-
ness, and length of these toothlike processes are subject to much variety.
The ligamentum denticulatum is evidently fibrous, and cannot be regarded, as Bonn
imagined, as a prolongation of the arachnoid.^
The ligamentum denticulatum appears to answer the twofold use of assisting in fixing
the spinal cord, and of separating the anterior (a) from the posterior {b) roots of the spi-
nal nerves.
The Dimensions of the Spinal Cord.
Tlie length of the spinal cord in the adult is from fifteen to eighteen inches. Its cir-
cumference is twelve lines at the thinnest part and eighteen at the thickest. But it is
of much less importance to determine the actual dimensions of the spina] cord than to
estimate its relative size as compared with that of the brain, or in reference to the ca-
pacity of the vertebral canal, or than to examine the differences in size which it pre-
sents at different parts of its extent.
If the size of the spinal cord be compared with that of the whole body, throughout the
series of vertebrated animals, we shall perceive that it always bears a direct ratio to the
vital activity of the animal. Thus considered, the spined cord is small in fishes and rep-
tiles, and large in birds and the mammalia.
Size and Weight of the Spinal Cord compared with the Size and Weight of the Brain. — It
was while studying the spinal cord and the brain in serpents and fishes that Praxagoras,
as quoted by Galen, originated the idea that the brain was a production of the spinal cord.
All the old anatonusts, on the other hand, who studied the brain and cord in man, in
mammalia, and in birds, regarded the medulla spinalis as a prolongation or appendix of
the brain (tanquam cerebri effusionem, Rufus) ; indeed, it was for a long time consid-
* The first description of the spinal cord which is worthy of notice was given by Huber (J. Huber, De Me-
duUd Spinali, Goeltingae, 1741) ; it served as the basis for the works of Haller {Elem. Physiol., torn, iv., sect.
1) ; of Mayer, who published a l)eaTitiful plate of it in 1779; and perhaps of Alexander Monro, Secundus (06-
servations on the Structure and Functions of the Nervous System, 1783). Scsmmering-, Reil, and Gall, who
so successfully studied the other parts of the nervous system, have noticed the spinal cord in a superficial man-
ner. Chaussier (De V Encephale en general et en particulier) ; Keuffel, in his inaugural dissertation {De Me-
dulld Spinali, 1810, dedicated to Reil, his preceptor) ; and Rolando {Richerche Anatomiche sulla Strutlura dei
Midollo Spinale, Torino, 1824), have supplied many of the deficiencies in our knowledge of this part. There
is a good description of the medulla in M. OUivier's work upon the diseases to which it is subject.
t The position of the nervous axis behind the alimentary canal constitutes one of the great differences whicli
exist between the nervous system of the vertebrated and the invertebrated animals ; in the latter, the nervous
system lies below, i. «., in front of the alimentary canal.
t It is idle to inquire whether it should be considered a prolongation of the dura mater, or an eztension at
the neurilemma, or a proper ligament.
DIMENSIONS OP THE SPINAL OORD. 695
ered that the medulla was the principal nerve in the body, summus in corpote humano tier-
vus. In the present day, anatomists have returned to the opinion of Praxagoras, and
the spinal marrow is generally regarded (Reil, Gall, Tiedemann) as the fundamental
part of the nervous system, and that the brain is merely a production, an appendage, or
an expansion of the cord. I shall not here enter into these purely speculative questions
of production or emanation, origin, and relative importance, for the spinal cord no more
produces the brain than the brain produces it.
Soemmering has shovni that, in man, the spinal cord is smaller in proportion to the
size of the encephalon than in the lower animals ; and of this there can be no doubt ; but
it does not follow that the lower animals have a larger spinal cord than man in propor-
tion to the size of their bodies : on the contrary, from actual observation, I should say
thiit, if we except birds, man has a relatively larger spinal cord than any other animal.
Compare, indeed, the medulla of the horse, or of the ox, with that of man, and it will at
once be found that the last is the largest and heaviest in proportion to the rest of the
body.
According to Chaussier, the weight of the spinal cord in the adult is from the nine-
teenth to the twenty-fifth part of that of the brain, and in the newborn infant about the
fortieth part. According to Meckel, this last is also the proportion in the adult. It must
be remembered, however, that Meckel examined the cord when deprived of its proper
membrane, and, therefore, after the roots of the nerves were detached from it.
Size of the Spinal Cord compared with the Capacity of the Spinal Canal. — The spinal
cord does not, by a great deal, fill up the vertebral canal, and a considerable interval oc-
cupied by fluids exists between it and the sides of the canal. What is the object of this
disproportion 1 and why is there any interval 1 We have already stated (see Osteol-
ogy) that the dimensions of the canal are in relation, not only with the size of the cord,
but also with the extent of motion of the vertebral column. The opinion of Vieussens,
that this space is intended to allow of certain movements of elevation and depression in
the spinal cord analogous to those which have been observed in the brain, is sufficiently
refuted by the fact that, although the latter organ is affected by movements synchronous
with the respiration and with the pulse, it still fills the cavity of the cranium. *
The length of the spinal cord does not correspond with that of the vertebral canal, for
the cord terminates near the first lumbar vertebra (between 20 and 21, fig. 268), while
the canal is prolonged into the sacrum.
The position of the lower end of the spinal cord has not been determined with the pre-
cision which so important a question demands. According to Winslow, it terminates
opposite the first lumbar vertebra ; Morgagni has seen it reach down to the second ;
Keuffel has observed it to descend as low as the third lumbar vertebra in one subject,
and to terminate opposite the eleventh dorsal vertebra in another. The discrepancy be-
tween various authors upon this subject depends upon individual varieties in the point of
termination of the cord, and upon the different acceptation of the term lower extremity
of the spinal cord ; some regarding the thick swollen part as the end of the cord, while
others include in it the tapering portion also. From some experiments which I made
upon this subject by thrusting a scalpel horizontally from before backward through the
inter-vertebral substance between the first and second lumbar vertebrae, I ascertained
that there are varieties in different subjects in regard to the point of termination of the
spinal cord, and that it was influenced by the position of the body, and by the state of
flexion or extension of the head and spine, but that, in general, the widest part or base
of the cone in which the cord ends corresponds to the first lumbar vertebra, and the apex
of the cone to the second.
During the early periods of foetal life, the cord descends as low as the sacrum ; but in
foetuses at the full time, I have never found so marked a difference as has been descri
bed by some modem anatomists. +
Differences in the Size of the Spinal Cord at different Points of its Extent.— The spinal
cord is not of uniform dimensions throughout its whole extent : it is much enlarged at
* From several experiments which I have made upon this subject, it appeared that the spinal fluid seen (con-
fined in its membranes) in the cervical region, between the occipital bone and the axis, was agitated by move-
ments synchronous with the pulse and the respiration ; but that, when this fluid had been evacuated, the spi-
nal cord did not move at all. I have examined with the greatest care the tumours existing in the lumbar re-
gion in infants afilicted with spina bifida ; I could never detect in them any movement corresponding with the
pulse, but the movement of respiration exerted a manifest influence upon them ; thus, when the sac was emp-
tied by compression, the cries of the infant, excited by pain, were almost instantly followed by extreme ten-
sion of the sac. As the spinal cord is not affected by the great arteries at the base of the brain, it cannot par-
ticipate in the slightest degree in those movements which are observed in the spinal fluid at every puise of the
heart, and which are communicated to that fluid by the cerebral arteries.
t The spinal cord is capable of elongation and retraction ; it is elongated during flexion, and returns to its
original condition during extension of the vertebral column; the difference between the two states appears to
mo to be from an inch to fifteen lines.
In the body of an infant at the full time, which was affected with spina bifida in the sacral region, and died
a short time after birth, the spinal marrow descended as low as the sacrum, and there was no cauda equina
Malacarne had already observed a similar fact ; this peculiarity depends not upon an arrest of development in
the cord, but upon adhesions contracted by it at an early period of foetal life. — (See Auat. Pathol., liv. xvii.,
art Spina Bifida.) vi.,
NEUROLOGY.
its upper part, opposite the basilar groove, where it constitutes the superior or occipital
rachidian bulb, or the medulla oblongata (a) ; it becomes narrowed immediately after hav-
ing emerged from the foramen magnum. This constriction, which is named the neck of
the rachidian bulb, is regarded by many anatomists as the commencement of the spinal cord.
Another oblong enlargement, extending over a much greater length than the prece-
ding, and named the middle, cervical, or brachial rachidian bulb, or cervical enlargement (6),
commences opposite the third cervical, and terminates opposite the third dorsal vertebra.
The spinal cord again becomes considerably contracted from the first to the eleventh
dorsal vertebra, and then presents a third enlargement of less extent than either of the
other two, constituting the inferior lumbar or crural rachidian bulb, or lumbar enlargement
(c) ; it then immediately tapers like a spindle, and terminates in an exceedingly slender
semi-transparent cord, which has a fibrous, filiform aspect, is concealed among the
nerves of the cauda equina {d), and is always accompanied by a vein. This cord may
be distinguished from the surrounding nerves by its being situated in the median line,
and by its thinness, its fibrous character, and its termination. It may be traced as far
as the base of the sacrum, when it terminates in the dura mater.
In some cases the narrow portion of the inferior rachidian bulb is bifurcated, but the
two branches of the bifurcation terminate in a single fibrous cord. Huber, Haller, and
Stemmering describe the spinal cord as terminating below by two small globular enlarge-
ments, of which the superior is oval, and the inferior conical. They have evidently mis-
taken an exception for the rule.
These three enlargements of the spinal cord constitute a totally different structure
from that admitted by Gall, who, comparing with Haller the spinal cord of man, and the
vertebrata generally, to the double series of ganglia in annelida and insects, maintained
that there are as many enlargements of the cord as there are pairs of nerves. A strict
examination into facts is completely at variance with this opinion, for even in the foetus,
the temporary conditions of which so frequently resemble the permanent state of the
lower animals, we find no trace of this series of enlargements. An erroneous inference,
together with the aspect of the cord when surrounded by its nerves, have misled this
celebrated physiologist, who should have sought for the representatives of the ganglia of
insects, not in the spinal cord itself, but in the series of ganglia on the spinal nerves.*
The existence of the three enlargements of the spinal cord above described is in ac-
cordance with two general laws relating to the nervous system, viz., 1. That the size
of the spinal cord is in proportion to the size and number of the nerves which arise from
and terminate in it, and to the functional activity of the organs to which those nerves
are distributed ; and, 2. That the exercise of sensibility is connected with larger nerves
than that of muscular contractility.
Now the most numerous and the most important nervous communications take place
opposite those three enlargements. The nerves of the lower extremities correspond
with the inferior or lumbar enlargements ; those of the upper extremities, with the mid-
dle one ; and the nerves of respiration, the nerves of the tongue, and a part, or perhaps
the whole of the nerves of the face, with the superior enlargement.
The cervical enlargement, which corresponds to the upper extremities, is certainly
larger than the lumbar one, but this is because the upper extremities possess a greater
degree of muscular activity than the lower, and also because they are the organs of touch.
This explanation is completely justified by comparative anatomy, and is applicable
also to the differences in the length of the spinal cord .- thus, it is found that in the dif-
ferent species of animals, the length of the spinal cord depends, not upon that of the
vertebral canal, nor upon the presence or absence of a tail, but is proportionate to the
muscular energy, and to the degree of sensibility. Desmoulins, a young anatomist, too
soon lost to science, hsis established this fact by incontrovertible evidence.!
The Form, Direction, and Relations of the Spinal Cord.
The spinal cord has the form of a cylinder flattened in front and behind (D, fig. 269).
* These supposed enlargements are not to be found even in the spinal cord of the calf, which Gall too* as
offering the type of this structure. The committee of the institute likewise failed to discover them in the dog,
the pig, the deer, the roe-buck, the ox, and the horse, in which Gall asserted that he had found them. The
beautiful researches of Tiedemann into the development of the spinal cord have completely overthrown Gall's
opinion, which rested merely upon unsubstantiated analogies.
[It may be remarked, that though Gall's anatomical statement is not correct, his view as to the analogy is
more in accordance with received doctrines than that of the author.]
t The spinal cord of birds furnishes a striking pioof of the law which presides over the development of this
part of the nervous system. There are no movements performed by animals which require greater force and
agility than those observed in the act of flying. It is therefore not astonishing to find that the spinal cord is
enlarged opposite the nerves which go to the muscles of the wings. It would be supposed that the portion of
the cord which corresponds to the lower extremities should be much smaller than that corresponding to the
upper, but yet the inferior enlargement is equal to the one for the wings, because, according to a more inge-
nious than probable idea, the lower extremities are the organs of touch in birds.
The spinal cord of the tortoise most clearly confirms the law which we have adopted from Desmoulins. The
sort of calcareous and homy case in which the trunk of that animal is enclosed is destitute of all power of
motion or sensation ; and it is found, the enlarged part of the spinal cord which corresponds to the upper ex
tremities is united to that which corresponds to the lower by an extremely slender portion.
NEURILEMMA OP THE SPINAL CORD. 697
It exactly corresponds in direction with the vertebral column, every deviation of which
it closely follows ; and it is an interesting fact, that it escapes compression, even in an-
gular curvatures of the spine. '
The right and left halves of the spinal cord are perfectly symmetrical. There is less
symmetry between the anterior and posterior halves, and still less between the upper
and lower halves of the cord.
The spinal cord is divided by anatomists into a body and extremities. The body of the
cord requires to be examined, both when covered by its proper sheath, and after the re-
moval of that membrane.
The Body of the Spinal Cord enveloped in its Proper Membrane.
The surface of the cord everywhere presents certain transverse folds, united by oth-
ers running obliquely, so as to form zigzag folds, which were compared by Huber to the
rings of a silkworm, and regarded by Monro as so many small articulations ; these folds
are situated in the sheath of the cord, and are precisely analogous to those which have
been noticed in the tendons during relaxation of the muscles, and those which we shall
hereafter have to describe as appearing in relaxed nerves ; they are effaced by exten-
sion of the spinal cord, and are reproduced when it resumes its original length.
The existence of these folds prevents that stretching of the cord which would other-
wise occur in the different movements of the vertebral column. They endow the cord
with a certain degree of elasticity.
The spinal marrow presents for consideration an anterior, posterior, and two lateral
surfaces.
The anterior surface presents in the median line a fibrous band, which runs along the
entire length of the medulla, and conceals the anterior median groove.
The posterior surface, at first sight, presents no trace of a median groove. Many
anatomists, therefore, and especially Huber, have denied its existence ; but with a little
care we may detect a very delicate line which indicates the situation of the posterior
median groove, to which we shall presently advert. On each side of the median line,
both on the anterior and posterior surfaces of the cord, are seen the roots of the spinal
nerves (1 to 31, fig. 268), which are arranged in four regular lines down the cord, and are
divided on either side into the anterior {a, fig. 267) and the posterior {b) roots. The dif-
ferences which we shall hereafter describe as existing between these two sets of roots,
both in their number, size, and mode of attachment, enable us, at first sight, to distin-
guish between the anterior and posterior surfaces of the cord.
If these roots be detached, it will be seen that their place of insertion is marked by a
series of depressed points, which together constitute two furrows both upon the front and
back of the cord, accurately described by Chaussier under the name of the collateral fur-
rows of the spinal cord. We cannot deny the existence of the posterior collateral fur-
rows, but I do not think that the anterior collateral furrows should be admitted.
The sides of the spinal cord are rounded, and narrower than either tlie anterior or the
posterior surface : there is no furrow upon these sides, as described by some authors.
The two ligamenta denticulata are attached to them.
"We must next examine the proper membrane of the cord, or the rachidian pia mater,
which we shall name the neurilemma of the cord, from its analogy to the neurilemma of
the nerves ; we shall then describe the cord itself
J^eurilemma of the Spinal Cord, or Rachidian Pia Mater.
Dissection. — It is difficult to separate the rachidian pia mater from the cord, in the
greater number of subjects, on account of the softness of the cord itself, and of the rapid
changes which it undergoes after death. In order to succeed in doing so, it is advisable
to select the body of a person who has died from an acute disease or from an accident.
The spinal cord of new-born infants is more fitted for this purpose than that of adults, not
only from its relatively greater density at that period of life, but also from its adhesion
to the neurilemma being less firm.
In the bodies of infants, after making a circular incision through the neurilemma op-
posite the medulla oblongata, the sheath may be drawn downward, in the same manner
as an eel is skinned, or a stocking drawn off by turning it inside out. When the sheath
is more adherent to the cord, it must be very carefully divided along each side of the
median furrows, and then detached by breaking down, with the handle of a scalpel, the
cellular and vascular prolongations which connect it with the cord.
Although the proper covering of the brain, or cerebral pia mater, consists essentially of
an interlacement of vessels, the proper sheath of the spinal cord, or rachidian pia mater,
is a fibrous, and, therefore, a strong membrane, which supports and protects that part of
the cerebro-spinal axis, as the neurilemma does the nerves.
The external surface of this membrane is surrounded with a network of remarkably
tortuous bloodvessels ; and vessels are also found in its substance. The spinal cord is
visible through this semi-transparent membrane, which is naturally of a pearly-white
4T
698 NEUROLOGY.
colour, but IS sometimes dull, yellowish, blackish, or even covered with black spots, es-
pecially in the cervical region.*
This surface of the rachidian neurilemma is also rough, being covered with small cel-
lular and fibrous filaments which float under water, and are the remains of small fibrous
cords, which extended from the neurilemma to the arachnoid.
The internal surface of the neurilemma adheres to the spinal cord by a great number
of cellular and vascular prolongations, which form areolae or meshes in its interior, and
which have been well described and figured by Keuffel.
Along the anterior median furrow, the neurilemma sends off a prolongation, which, en-
tering that furrow, lines one of its walls, and is then reflected at its bottom, so as to hne
the other waU ; within the substance of the duplicature thus formed, the bloodvessels
penetrate. A simple prolongation of the neurilemma, of extreme tensity, also enters
into the posterior median furrows, and forms a line of separation between the two pos-
terior halves of the spinal cord.
The neurilemma is prolonged below the lower extremity of the spinal cord as a fibrous
filament, very well described by Huber, which is inserted into the base of the coccyx.
This filament the older anatomists regarded as a nerve, and named it the nervus impar ;
it is very strong considering its thinness ; it is always tense, and appears to be intended
to fix the lower end of the spinal cord ; in this respect serving a similar purpose with the
ligamentum denticulatum. Its upper part is hollow, and is filled with a gray and ex-
tremely soft substance.
The ligamentum denticulatum, which has been considered as a prolongation of the prop-
er membrane of the cord, is attached to the external surface of this membrane ; and the
proper neurilemma of each nervous filament is also given off from this surface.
Monro has stated that a soft layer of gray substance covers the white substance of the
spinal cord, and separates it from its neurilemma, but such a layer does not exist. t
While the other membranes of the spinal cord are much larger than the part which
they have to invest, the neurilemma of the cord is exactly moulded upon it, and even
exerts a certain degree of pressure upon it, as is evident from the manner in which the
substance of the cord protrudes when this covering is punctured ; this compression oc-
casions the apparent consistence of the cord when it is enveloped in its sheath ; a con-
dition which contrasts so strongly with its softness when that sheath has been removed.
This compression, as well as the absolute inextensibility of the neurilemma, accounts
for the rarity of effusions in the cord, and also for the fatal effects of even the slightest
effusions within its substance when they do occur.
Structure. — The proper membrane of the cord is essentially fibrous ; nor has it any
claim to be termed a vascular membrane (tunica vasculosa, Soemmering). Its component
fibres interlace in every direction, but the majority of them are longitudinal. It is quite
evident that the vessels which ramify upon its surface, and afterward penetrate it, do
not belong to the membrane itself.
Uses. — The neurilemma is essentially a protecting structure ; it constitutes the frame-
work of the spinal cord, and serves, at the same time, as a support for the nutritious ves-
sels of that organ ; in this latter respect it has been compared to the pi a mater of the
brain. The transition from the spinal into the cerebral portion of the pia mater takes
place gradually. The fibrous character of this tunic diminishes upon the medulla oblon-
gata and tuber annulare, and is entirely lost opposite the peduncles of the brain ; while
its vascular character, on the contrary, becomes gradually more and more marked as it
passes from the cord towards the brain.
It has been stated that the neurilemma is the secreting organ of the spinal cord ; one
might as well say that the testicle is secreted by the tunica albuginea, and the heart by
the pericardium.
The Body of the Spinal Cord deprived of its J^eurilemma.
When the neurilemma of the cord is removed, the spinal nerves are also taken away.
We shall hereafter have to inquire whether this fact should lead us to conclude that
the nerves do not enter into the substance of the cord, but merely come into contact
with it.
We would observe, however, in this place, that the posterior roots of the spinal nerves
arise in a perfectly regular line, while the anterior roots come off irregularly from differ-
ent points of the corresponding medullary column, t
The Anterior Median Grocwe and the Commissure. — The anterior median groove, or fissure
* These different shades of colour are much more common in certain animals, in the sheep, for example,
than in man ; they result from the deposition of a colouring matter, and are in no way connected with any
recent or previous morbid action.
t In several subjects, I have most distinctly seen a very thin yellowish layer over the medulla oblongata,
which dipped between the pyramidal bodies, and filled up the shallow groove which separates the olivary from
the pvramidal bodies.
X This mode of origin of the anterior roots is perfectly distinct in the spinal cord of the futus or new-bom
infant ; up to this period, the tract from which the anterior roots arise is still formed of gray substance. Th«
roots, which are white, emerge fmm this gray tract, and when the neurilemma is removed, their small, white,
ruptured ends which remain may be traced into the substance of the cord.
THE SPINAL CORD DEPRIVED OF ITS NEURILEMMA.
Fig. 268.
(Jig. 26R ; f, fig. 269, D), penetrates to about one
third of the thickness of the cord. At the bottom
of the groove, which is occupied by a prolongation
of the neurilenuna and a great number of vessels,
is seen an extremely thin white layer, perforated
with foramina, which is named the anterior com-
missure (commissure longitudinale, Chaussier). The
foramina in this structure are intended for the trans-
mission of tufts of vessels, which enter the sub-
stance of the cord. The alternate arrangement of
these foramina greatly increases the difficulty of
drawing out the vessels, and gives to the commis-
sure the appearance of being formed by interlacing
fibres ; and, in fact, several anatomists have not
only admitted such an interlacement, but have ex-
pressly stated that it was produced by the spinal
nerves themselves.*
According to Gall and Spurzheim, the bundles of
which this commissure consists are directed trans-
versely, and are fitted into each other like the mo-
lar teeth ; but I repeat, that the most careful ex-
amination demonstrates nothing in the commissure,
besides a white lamella, perforated for the transmis-
sion of bloodvessels.
The Posterior Median Groove. — The posterior me-
dian groove or fissure (a) not only exists, but is
much deeper than the anterior one. Its narrow-
ness, and the tenuity of the membranous prolon-
gation which enters it, have alone concealed it from
the observation of anatomists ; there is no white
band analogous to that of the anterior median fis-
sure at the bottom of this fissure, but the gray sub-
stance of the commissure is all that is seen.
As there are two median furrows, it follows that
there are really two distinct spinal cords, connected
together by an extremely thin band or commissure.
The Furrows opposite the Posterior Roots of the
Nerves, or the Posterior Lateral Furrows. — Immedi-
ately to the outer side of the line of origin of the
posterior roots of the spinal nerves, there is a gray-
ish line or furrow (i), which extends the whole
length of the cord. If a stream of water be allowed
to fall upon this line, the continuity of the cord is
soon destroyed, and the water penetrates to the
centre of the organ.
But there are no true fissures in these situations
analogous to the anterior and posterior median fur-
rows. The separation is effected by the destruc-
tion of the gray substance, a prolongation of which
reaches to the surface of the cord opposite these
points. We shall, nevertheless, suppose these fur-
rows to exist in accordance with the views of Soem-
mering and Rolando, who divided each half of the
spinal cord into two columns : a posterior column,
consisting of that portion (e) which is comprised be-
tween the posterior median furrow (a) and the posterior roots (i) ; and an antcro-lateral
column, including all that portion (rf) which is situated between the anterior median fur-
row (/) and the supposed posterior lateral furrow (r). We must also admit, with Haller,
Chaussier, Gall, and Rolando, a third column on each side ; these may be called the pos-
terior median columns, and are continuous with the projecting bundles which form the
borders of the calamus scriptorius, and which are each limited externally by a slight
groove. These small and exceedingly narrow columns, the existence of which is admit-
ted by most anatomists in the cervical region only, are prolonged through the whole ex-
tent of the spinal cord.
Is there an anterior lateral furrow ? If the line on the outer side of the attachment of
the anterior roots of the spinal nerves be closely examined, the appearance of a furrow
is seen along the whole of the cord. But if water be allowed to fall upon that line, it is
* There is uo physiological or pathological fact which demonstrates the crossing
nal cord.
eiTect of lesions of the spi
700 NEUROLOGY.
found that there is no fissure or furrow properly so called, and that the jet of water has
no more effect upon this line than on the adjoining parts ; we are therefore led to reject,
with Rolando, both these anterior lateral furrows and the lateral tracts described by
Chaussier, which would be bounded in front by the furrow of the anterior roots, and be-
hind by that of the posterior roots ; these lateral tracts have, nevertheless, become cele-
brated, since so much importance has been attached to them by Sir C. Bell and Bellin-
geri as the lateral columns of the spinal cord.
From what has been stated above, it follows that each half of the cord is composed
of two columns, a posterior and an antero-lateral, and as an appendage to the posterior
column, of a small column, which forms the border of the posterior median furrows.
Internal Structure of the Spinal Cord.
The following results regarding the structure of the cord have been obtained by va-
rious modes of investigation : by making sections of it ; by acting upon it with a stream
of water ; by hardening it in alcohol and dissecting it ; by studying its development ;
and, lastly, by a reference to its comparative anatomy, which appears to be necessary to
complete the knowledge acquired by the other means of investigation.
Sections of the Cord.
' It appears, from an examination of the external structure of the spinal cord, that it
consists of two white, juxtaposed cylinders ; that the surfaces by which these cylinders
correspond are flat, closely in contact, and united together by a median commissure ;
and that each of them may be divided into two columns, the one posterior and smaller,
of which the posterior median column is only an appendage; the other, antero-lateral,
which forms two thirds of the circumference of the cylinder.
Horizontal Sections. — If various horizontal sections be made through different parts of
Fig. 269. t^^ spinal cord, we see that each half consists of a cylinder of white
substance, containing gray substance in its interior (see Jig. 269, D) ;
that the median commissure is composed of a white layer {white commis-
sure) and a gray layer (gray commissure) ; and that in each section the
gray matter has a tolerably close resemblance in form to the letter x, the
two halves or curves of which are joined in the middle by a horizontal
line, while the extremities of the curves are directed towards the ori-
gins of the anterior and posterior roots of the nerves. The posterior
I B extremities reach much nearer to the surface than the anterior. We
perceive, also, in these different sections, that the circumference of the
cord is not perfectly regular, but is somewhat sinuous, as we shall pres-
ently mention.
The size of the central gray mass in each half of the spinal cord, the
length and thickness of the prolongations or points, which it sends off
towards the anterior and posterior roots, and, lastly, the thickness of
the gray commissure, present many varieties, according to the place of
section ;* and hence there is a discrepancy between different authors
as to the appearances of this section. Thus, Huber compared the sec-
tion of the gray matter to an os hyoides ; Monro, to a cross ; Keuffel, to
four rays converging towards a central point.
Rolando has given figures of sections of the cord at every part of its length.
From sections of the cord the general fact is established, that the white substance en-
closes the gray matter. The thin layer of gray matter on the surface of the cord ad-
mitted by Monro has been justly rejected by all anatomists. The relative situation of
the two substances in the cord, which is the reverse of what is observed in the brain,
has attracted the attention of anatomists, and various explanations, of greater or less
ingenuity, but all hypothetical, have been given of this fact.
According to Rolando, there are two kinds of gray matter in the cord, one occupying
the anterior, and the other the posterior half of the cylinder ; and these two halves are
fitted into each other by a series of indentations, like the bones of the cranium.
I have never been able to convince myself of the existence of these two kinds of gray
matter, but I have distinctly observed the denticulated appearance of the circumference
of the gray matter, which indicates that the gray and white matter mutually penetrate
into each other.
The colour of the gray substance varies considerably. In some subjects it is whitish,
and can only be distinguished from the white matter by its softness, its vascularity, and
its not having a fibrous structure. The younger the individual, the more marked is the
difference in colour between the two substances.
The two substances appear also to differ in their relative proportions in different in-
dividuals. Keuffel has ascertained that the gray matter is more abundant in man than
* I would recommend five sections of the cord, which appear to rae to give a very accurate notion of its in-
ternal structure : the first should be immediately below the decussation of the pyramids ; the second through
the middle of the brachial enlargement ; the third through the dorsal constricted part ; the fourth through the
middle of the lumbar enlargement ; and the fifth near the apex of the cone formed by the lumbar enlargement.
INTERNAL STRUCTURE OP THE SPINAL CORD. ^'Wl
in the lower animals ; and this fact would account for the pre-eminent sensibility of the
human subject, in accordance with the view of BeUingeri, who considers that the gray
matter is the seat of sensation.
These horizontal sections enable us not only to determine the relative position and
proportions of the white and gray substances, but also to distinguish the superficial fur-
rows from those which really enter into the cord ; the existence of these columns in the
spinal cord, which have already been described, is in this way fully established.
Vertical Sections. — The most important of these is one made from before backward in
the median line, so as to separate the two halves of the cord. Each of these halves may
then be unfolded like a riband, on the inner surface of which the gray matter forms a
thin layer.
A transverse vertical section, through the centre of the cord, displays the mode of
origin of the anterior and posterior roots of the nerves.
Examination of the Spinal Cord under a Stream of Water.
The different sections above mentioned expose the general internal arrangements of
the cord rather than its actual structure.
Until lately, authors had regarded the spinal cord as consisting of a semi-fluid pulp,
which oozed out when the neurilemma was divided. Several had said, incidentally, and
without distinguishing between the white and the gray substance, that the cord had a
fibrous structure, and that its fibres were directed longitudinally. Gall supposed the
cord to consist of a series of ganglia, arranged one upon the other ; but it is now gener-
ally admitted that the white matter is fibrous, and that its fibres have a linear arrange-
ment ; and this is clearly shown by examining this organ by means of a stream of water,
the force and size of which may be varied at will.
When directed upon the surface of a vertical section, made from before backward
down the middle line, the stream of water penetrates the substance of the cord through
the gray commissure, breaks down the central gray matter, and spreads the cord out
like a riband, from which it is very difficult to wash off all the gray matter. When
treated in this way, each half of the cord is almost immediately subdivided into two col-
umns, and if the stream of water be now directed upon the internal surface of the col-
umns themselves, they may be separated into a great number of wedge-shaped vertical
lamellae, directed from the circumference to the centre, the thick external backs of which
are turned towards the surface, and the thin internal edges towards the centre of the
cord. Now, as all these lamellae are not of equal depth from back to edge, their internal
edges reach to different distances from the centre ; hence the denticulated appearance
of the circumference of the gray matter in a section ; and hence, also, the mistake of
Rolando, in describing the white matter as formed by a medullary layer, folded a very
great many times upon itself*
According to my observations, each lamella is completely independent of the adjacent
ones ; and pathological anatomy fully confirms this observation, by showing that one only
may be altered or atrophied, while the others remain unaffected.
If the action of the stream of water be continued, these medullary lamellae are decom-
posed into very delicate juxtaposed filaments, which extend along the entire length of
the cord ; they are all independent of each other, and are merely connected by cellular
tissue and some vessels.
The structure of the spinal cord is therefore filamentous or fasciculated ; its filaments
are almost perfectly identical with those which constitute the proper substance of the
nerves. Each filament in the cord traverses its entire length, as each nervous filiiment
extends along the whole nerve.
The very important inference to be drawn from these facts is the independence, not
only of each lamella, but, I may venture to say, of each filament, t
* Rolando has even counted these folds : he numbers fifty in the spinal cord of the ox, opposite the origin
of the sixth pair of sacral nerves, and about thirty opposite the third pair of sacral nerves ; both of these ob-
servations refer to the anterior columns only, for in the two figures which he gives of them the posterior col-
umns appear to have no folds. Rolando made his observations upon spinal cords which had been macerated
eil'jcr in pure water or in salt and water.
t [The microscopic structure of the white and gray substances of the brain and spinal cord has been inves-
tigated by Fontana, Ehrenberg, Weber, Remak, Valentin, and others. The fibres of the white matter consist
of coherent threads of a soft, semi-transparent, tenacious substance, enclosed in an extremely delicate homo-
geneous or structureless sheath, which is very difficult of detection : these fibres are smaller than those of the
nerves ; they differ much in size, but each of them is of uniform diameter throughout ; when submitted to
the slightest pressure during examination, they have a remarkable tendency to become varicose or beaded, a
property which is peculiar to them and to the fibres of the olfactory, optic, and auditory nerves, which also re-
semble the fibres of the brain in other respects.
The gray matter of the brain and spinal cord consists of large reddish gray globules, containing a nucleus
and one or more nucleoli, and having spots of pigment upon them, in situations where the gray matter is dark-
er than usual. Surrounding and attached to these globules there are minute jointed fibres, which are marked
at intervals with granules (nuclei) ; by Ehrenberg these jointed fibres were considered to be of the same na-
ture as the fibres of the white matter, differing from them only in size ; by Miiller and Schwann they are re-
garded as organic nervous fibres, resembling those found in such abundance in the sympathetic nerves and
ganglia ; while by Valentin and others they are supposed, not only in the brain, but also in the ganglia and
nerves, to be the filaments of a delicate cellular tissue.
The mode in which the white fibres of the brain and spinal cord end in the gray substance is not well made
I9|tt NEUROLOGY.
Examination of the Spinal Cord hardened in Alcohol.
When deprived of its humidity by alcohol, the spinal marrow becomes very firm, ex-
tensible, and elastic. Its filamentous texture becomes very apparent, and the filaments
themselves, which, from the contraction of the cord, are flexuous, may be separated
from each other, either by the handle of the scalpel, or by slight traction. I have not
seen that interlacement of the fibres of the cord which is figured in the beautiful plates
of Herbert Mayo, and which, in my opinion, is only apparent, and is produced by drawing
the parts under examination in different directions.
The Cavities or Ventricles of the Spinal Cord.
Several anatomists are of opinion that there is a canal in each half of the spinal cord.*
Morgagni has slightly alluded to its existence, which he had not leisure to trace for a
greater extent than about five fingers' breadth, t
Gall relates that, in examining the body of an infant 8iffected with spina bifida, he cut
transversely through the cord, and found that it contained two canals, which he traced
into the substance of the medulla oblongata and tuber annulare, beneath the tubercula
quadrigemina, and as far as the optic thalami, where they terminated in a pouch as large
as an almond.t
It is certain that, up to the fourth month of foetal life, each half of the spinal cord con-
tains a canal precisely similar to that which exists in fishes ; but after this time the gray
matter takes the place of the gelatiniform fluid which had occupied the canal. However,
in one case I found the canal persisting after birth.
The Medulla Oblongata.
Situation. — The medulla oblongata, the rachidian bulb, or cranial enlargement, is that
conoid enlargement (a, fig. 268) which forms the upper part of the spinal cord, crowning
it like the capitsil of a column : it is situated upon the basilar groove of the occipital
bone, and connects the spinal cord with the cerebrum and cerebellum. It was named
medulla oblongata by Haller ; but it has also been called the cauda or tail of the medulla
oblongata, this term being derived from a comparison of the pons Varolii, the four pe-
duncles, and the medulla oblongata to an animal, the body of which was represented by
the tuber, the arms by the anterior peduncles, the legs by the posterior peduncles, and
the tail by the rachidian bulb.
External Conformation of the Medulla Oblongata.
The medulla oblongata is received into the deep groove on the fore part of the cir-
cumference of the cerebellum (see fig. 276), so that its anterior part only is exposed.
In man and the mammalia the medulla oblongata is bounded above and in front by the
tuber annulare or pons Varolii {a, fig. 270) ; but above and behind its limits are quite arti-
ficial, for it is prolonged upward beyond the pons, cis we shall presently see. Its limits
below are altogether arbitrary : the medulla oblongata, in fact, does not contract abrupt-
ly, as the term neck of the bulb, applied to its lower extremity, would seem to imply, but
it is very gradually narrowed, so as to become continuous with the spinal cord.
A plane, which is a tangent of the lower surface of the condyles of the occipital bone,
would correspond with the lower boundary of the medulla oblongata. ^ I think, however,
that it is more rational to fix this boundary according to the precise point where the me
dulla undergoes some decided modifications ; and this point is immediately below the
decussation of the pyramids.
The medulla oblongata is from fourteen to fifteen lines in length, nine lines in
out ; according to Valentin, they separate to admit the gray globules between them, and then unite with one
another so as to form loops.
The substance of the brain and spinal cord, according to Vauquelin, contains 80 per cent, of water ; its solid
constituents consist of albumen, stearine and elaine, phosphorus (1-5 per cent.), osmazome, some acids and
salts, and sulphur.]
* It is unnecessary to say, that the existence of the single central canal admitted by some authors, is quite
irreconcilable with the real structure of the cord.
t Adversaria Anat. ,\ol. i., p. 17. Morgagni relates that, having separated the medulla oblongata from the
rest of the spinal cord by a horizontal section, he saw in the substance of the cord, and for the space of about
five fingers' breadth (etfortasse etiam hngius siquis tunc otium habuisset ulteriorum meduUam e vertebris exi-
mendi), a cavity which admitted the end of the finger ; everything appeared to be in a natural state, except-
ing this cavity. He adds, that he had never met with so large a cavity ; which seems to imply that he had
seen cavities of this kind before. — Negue enim alias tantam out qua: huic accederet vidi.
t Spina bifida and hydrocephalus have no direct relation with the persistence of the canals of the spinal
cord ; and on this point, I can remove all the doubts expressed by Keuffel (De Medulld Spinali, 62) concerning
Morgagni's observation. " Forsan nos quoque," says Keuffel, "earn (scilicet medulla; spinalis caveam) inve-
nissemus, si medullam spinalem ex homine hydrocephalico aut spinJl l)ifid^ laborante, inquirere potuissemus.
Utinam hujusmodi opportunitas, si occurreret, a nemine negligatur, ut tandem de hJlc re certiores fiamus."
In five infants affected with spina bifida, and two who died of chronic hydrocephalus, which I examined for
this purpose, the spinal marrow was perfectly normal. Tiedemann regards the canals described by Gall as
produced by insufflation.
t) I have made experiments upon several subjects, which show that the relations of the medulla oblongata
to the foramen magnum vary according as the head is directly vertical, flexed, or extended ; an instrument
thrust horizontally between the atlas and occipital bone divides the medulla oblongata at different part* n
these various positions of the head.
THE MEDULLA OBLONGATA, ETC. 708
breadth, and six in thickness ; it is therefore much broader and thicker than the spinal
cord.
The medulla oblongata is directed obliquely, like the inclined plane of the basilar
groove, so that it forms with the spinal cord a very obtuse angle, which projects back-
ward.
In shape it resembles a cone flattened in front and behind, and having its base turned
upward and its apex downward ; it has, therefore, four surfaces, viz., an anterior, a pos-
terior, and two lateral.
Anterior Surface of the Medulla Oblongata.
This surface (fig. 270) is directed downward, and is therefore named inferior by some
anatomists ; it is convex, and is lodged in the basilar groove of
the occipital bone ; it can be properly examined only after its '^' _'
neurilemma has been dissected off, which is easily done, because
its substance is denser than the spinal cord.
On this surface we observe a median furrow (/), into which
numerous vessels enter : this furrow, which is not nearly so deep
as the anterior median furrow of the spinal cord, with which it is
continuous, is interrupted by a decussation of fibres about ten si^
lines below the pons Varolii (below n), and terminates above in
a tolerably deep fossa (le trou borgne, or foramen cacum, of Vicq
d'Azyr), at the point where the furrow meets the pons. Not un-
frequently some transverse fibres occupy the place of this median
furrow, in which case the anterior surface of the medulla ob-
longata resembles the pons Varolii ; sometimes these transverse fibres are found upon
only a part of the medulla oblongata.
On each side of this median furrow are seen two eminences, which seem as if mould
ed in relief upon the part, and which form two planes, succeeding one another like steps
from within outward. The two internal eminences are called the anterior pyramids ; the
two external are named, from their shape, the olivary bodies.
The interior Pyramids.
The anterior pyramids ( Vieussens, b b), situated on each side of the median line, and
to the inner side of the olivary bodies, are two white pyramidal bundles (bandes medul-
laires, Maiacarne), which extend through the entire length of the medulla oblongata ;
they project in relief upon the body of the medulla, and seem to emerge or originate
near its narrow portion or neck, where they separate from each other the anterior col-
umns of the spinal cord, from which columns they are quite distinct : at their point of
emergence they are closely approximated and narrow, being about a line and a half in
width ; they pass somewhat obliquely upward and outward, become more prominent,
and about three lines wide ; having reached the pons Varolii, they become rounded and
cylindrical, and are constricted before they enter the substance of the pons, in which we
shall afterward trace them.
Wniien the two pyramids are gently held apart, it is said that some transverse fibres
are seen passing from one to the other, along the bottom of the median furrow ; and it
is even stated that there is a decussation of their fibres : this, however, is only apparent,
and I cannot here too particularly caution the student against those illusive appearances,
which depend either upon the existence of foramina for the passage of vessels, or may
be produced by pulling about the scattered fibres in drawing the parts asunder. It wiU
soon be shown that there are no transverse fibres fiere, and that there is no decussation
of fibres at an acute angle along the whole length of the anterior pyramids, as was ad-
laitted by Petit, Winslow, Santorini, and others.
The two halves of the medulla oblongata are, in fact, merely applied to each other,
and agglutinated together. There is no decussation excepting at the point where the
pyramids emerge.
The Olivary Bodies.
Upon the anterior surface of the medulla oblongata, to the outer side of the anterior
pyramids, and upon a plane somewhat posterior to them, are found two white ovoid
bodies (corpora ovata), sometimes projecting in relief; these are peculiar to the human
subject, and are more prominent in the foetus and new-born infant than in the adult.
They were first described by Eustachius, and afterward more accurately by Vieussens,
who, on account of their shape, gave them the name of olivary bodies (corpora olivaria, c c) ;
they are much shorter than the anterior pyramids, being not more than six lines in
length ; they are directed obliquely downward and inward. The upper extremity of the
olivary body does not reach the pons Varolii, but is separated from it by a deep furrow ;
the lower extremity, which is less prominent than the upper, is bound down by a bundle
of arched fibres, the concave borders of which are directed upward (processus arciformes,e).
The outer border of the anterior pyramids and the series of nervous filaments which
unite to form the hypoglossal nerve (9, fig. 276) constitute the internal boundary of each
704
'NEUROLOGY.
olivary body ; and a deep furrow, directed vertically, separates them on the outer side
from the inferior peduncles of the cerebellum or the restiform bodies.*
It is of importance to observe, that that portion of the olivary body which projects on
the outer side of the pyramid is only the external half of the olivary body, its interned
half being imbedded in the substance of the medulla oblongata, so as to reach behind the
anterior pyramid, t
The Posterior SurfcLce of the Medulla Oblongata.
This surface is partly concealed by the cerebellum, being received into a groove on
Fig. 271. its under surface, and cannot be completely exposed unless the
medulla oblongata be forcibly bent forward, or the middle part
of the cerebellum be divided vertically. It is then seen that the
cord appears to open out {t,fig. 271) opposite the upper part of
this surface, and to be turned inside out, so that the gray sub-
stance is exposed. In consequence of this separation of the
posterior columns of the cord, there is left between them a shal-
low, triangular, or V-shaped depression (;?), the bottom of which
is smooth, and forms the anterior wall of the fourth ventricle ;
Herophilus named this depression, from its appearance, the cal-
amus scriptorius.
A vertical median groove corresponds to the shaft of the quill ;
while its barbs are represented by certain white medullary lines,
which vary exceedingly in number, and are not symmetrical ;
some of these lines are lost upon the walls of the ventricle, and
others turn round the lateral surface of the medulla oblongata,
and constitute, in part, the origin of the auditory nerves. The
point of the pen is represented by the very acute inferior angle
lormed by the sides of the depression, which terminates below in a cul-de-sac, the fos-
settc of the fourth ventricle, also called the ventricle of Arantius. According to some au-
thors, at the point of the calamus is situated the upper orifice of a canal, which runs
through the whole length of the spinal cord ; such a canal, however, does not exist, but
is, in fact, produced by the means employed to demonstrate it, for example, by insuffla
tion, by the introduction of a probe, or by the weight of a column of mercury. A slight V
shaped deposite of corneous matter is constantly found inserted within the corresponding-
ly-shaped bifurcation of the columns of the cord : between the branches of the V is found
the prolongation of gray substance, which is continuous with the gray matter of the cord.
The medullary columns which immediately bound the calamus on each side, and which
result from the separation of the elements of the cord, are formed by the posterior me-
dian columns {e,fig. 269, B C, and _^^. 271), already described, which become slightly
enlarged where they separate from each other, so as to form a mammillary projection,
and then terminate insensibly upon the back of the restiform bodies : we shall call the
upper part of these columns the mammillary enlargements of the posterior median columns^
and not '■^posterior pyramids. ''''%
On the outer side of these mammillary enlargements are found the restiform bodies (d,
fig. 269, C ; fig. 271), which, as we shall afterward describe, pass to the cerebellum, and
may be said to form its root ; they are also called the inferior peduncles of the cerebellum,
or processus a cerebello ad medullam ohlongatam. Ridley named them the restiform bodies,
or cord-like processes ; and others, again, call them the posterior pyramids.
Fig. 272. TheJjateral Surface of the Medulla Oblongata.
These present {fig. 272), in front, the olivary bodies (c), which we
have already seen upon the anterior surface. Behind them are the
restiform bodies (d) ; and, lastly, about three lines below the lower
extremity of each olivary body, is found an oblong projection, the
colour of which is intermediate between that of the white and that
of the gray substance : this projection is continuous with the gray
matter of the furrow, from which the posterior roots of the spinal
nerves arise ; and Rolando, who first directed attention to it, has
named it the ash-coloured tubercle (tuberculo cinereo).
The arched fibres, or processus arciformes {e,fig. 270), pointed out
by Santorini, and still better described by Rolando, are principally
found upon the lateral surfaces of the medulla oblongata ; they con-
sist of filaments of medullary substance, which vary exceedingly in
* I do not say, with some authors, that the filaments of origin of the glosso-pharyngeal and pneumogastric
nerves (8, fig. 270) bound the olivary bodies behind, for these filaments arise from the inferior peduncles of
the cerebellum, or the restiform bodies, not from the furrow between those peduncles and the olivary bodies
t In the body of a female who died at the Maternity, the left pyramidal and olivary bodies were not more
than half their usual width. It might have been supposed that they were atrophied ; but the patient had ex-
hibited no symptom indicative of so serious and uncommon a lesion. With a little attention, I could easily
see that the pyramid was divided into two portions, the anterior of which occupied the usual position, while
the posterior covered the posterior half of tlie olivary body.
I [The term posterior pyramids is, nevertheless, applied to these bodies by many modern anatomists.]
INTERNAI? STRUCTURE OP THE MEDULLA OBLONGATA. 705
number and arrangement ; they appear to arise from the anterior median furrow of the
medulla oblongata, to turn like a girdle around the pyramidal and olivary bodies, and,
having reached the restiform bodies, to pass obliquely upward and outward to terminate
upon the sides of the restiform bodies. These arched fibres sometimes seem to be en-
tirely wanting ; at other times they are collected on each side into two bundles : one
superior, which turns round the anterior pyramid, as that body is about to enter the
pons ; the other inferior, which covers and circumscribes the lower extremity of the
olivary body. Lastly, the pyramidal and olivary bodies are not unfrequently found to be
completely and regularly covered by a thin layer of circular fibres : it will be presently
shown that these fibres dip into the anterior median furrow of the medulla oblongata,
and reach as far as the posterior median furrow.*
Internal Structure of the Medulla Oblongata.
The internal structure of the medulla oblongata should be examined by means of sec
tions, by the ordinary method of dissection, by separating its elements by means of a
jet of water, and by dissecting it after it has been hardened in alcohol or boiled in oil.
Sections.
Horizontal Sections. — Following the example of Rolando, we shall examine four sec-
tions of the medulla oblongata.
The first should be made immediately below the decussation of the pyramids ; the
second, opposite the middle of the decussation ; the third, through the middle of the oli-
vary bodies ; and the fourth, immediately below the pons.
The first section presents exactly the same appearances as a section of the spinal cord.
The second presents a very different arrangemeirt : the decussating bundles of the
pyramids are of very considerable size, and occupy the anterior two thirds of the sub-
stance of the medulla : their section represents a triangle having its base turned for-
ward, and its truncated apex backward. The gray matter is not circumscribed, as in
the first section, but appears to penetrate irregularly into the white substance of which
the remaining part of the medulla consists. The white substance itself has not the pure
whiteness of medullary substance ; nor does the gray matter resemble that of the rest
of the spmal cord, but it is of a yellowish-gray colour, and is much denser.
The third section through the middle of the olivary bodies {fig. 269, C) presents, be-
sides the triangular section of the pyramidal bodies (i), the serrated section of the corpus
dentatum (c') of the olivary bodies (c) ; it enables us to form an accurate idea of the shape
and size of these bodies, which extend to each side of the median line ; it shows that
they are directed obliquely inward and backward, and that they consist of successive
layers, viz., of an external white layer, of an interrupted yellowish layer, and of a sec-
ond white layer, which lines the inner surface of the yellowish one. It is seen that the
corpora dentata of the olivary bodies are interrupted, or, rather, open on the inner side
towards the median line, so as to admit the white fibres with which their interior is
filled. The waving gray line seen on these sections depends upon the yellow layer be-
ing frequently folded inward and outward upon itself; and from this appearance the
terms corpwi dentatum, or corps festonne, have been applied to the gray substance of the
olivary bodies. The remaining part (<£) of the medulla oblongata consists of a substance
which is of the colour of coffee mixed with milk, and which offers more resistance to
the knife than other parts of the medulla, and consists neither wholly of white matter
nor wholly of gray, but of a mixture of both.
The fourth section, made immediately below the pons {fig. 369, B), presents a trian-
gular surface, on which we remark, at each of the posterior angles, a thick white bun-
dle, almost as large as the posterior pyramidal body, and which will be hereafter shown
to constitute one of the roots of the fifth nerve : these bundles are also seen upon the
third section made through the olivary bodies, but they are much smaller than in this
section. The section of the two anterior pyramids {b) is circular at this point. The
centre of this section of the medulla consists entirely of a grayish- white or coffee-col-
oured substance {d c'), covered by a white layer. The grayish-white substance belongs
specially to the medulla oblongata ; the surrounding white layer is the continuation of
the columns of the spinal cord, t
The oblique sections display appearances corresponding with those of the horizontal
section.
Vertical Section. — A very interesting section of the medulla oblongata is a vertical one,
extending from before backward through the median line. I prefer the plan of forcibly
separating the two halves of the medulla to that of dividing it with a scalpel. By
this means it may be shown that there are in the median line of the medulla some an-
* Ought we to regard as a part of this system of arched fibres a small, slender cord which surrounds the
upper part of the anterior pyramids, and which in other respects has a similar arrangement to the arched
fibres generally %
t The medulla oblongata of a child seven or eight years old is much better adapted for the examination of
these sections than that of an adult or old subject, because the two substances are blended in the latter ; a
stream of water directed upon the sections will greatly assist the examination, by makiug the colours more
iistinct
4 U
706 NEUROLOGY. •
tero-posterior fibres, which appear to me to vary in number in different subjects : fhesc
fibres (o, Jig. 274) run from behind forward through the whole antero-posterior diameter
of the medulla ; having reached the anterior median furrow, they pass horizontally out-
ward to cover the pyramids and olivary bodies, and form the arched fibres already de-
scribed. These antero-posterior fibres are limited below by the decussating fibres of the
pyramids.
Examination of the Medulla Oblongata by Dissection under a Jet of Water, and when hardened
in Alcohol.
The anterior pyramids may be separated by ordinary dissection, and a tolerably accu-
rate view obtained of their decussations ; and, moreover, the medulla oblongata may be
divided into two lateral halves, and its principal parts may then be isolated. The ex-
amination of the medulla when hardened in alcohol, or boiled in oil, or in a solution of
salt, leads to important results, by enabling us to dissect it fibre by fibre, and to trace
these fibres above and below their points of decussation. Together with these different
modes of investigation I have employed another, viz., that of acting upon the medulla
and its parts by a jet of water, the force and size of which is to be varied at pleasure,
and the drops of which insinuate themselves between the fibres and separate them from
each other.*
If a stream of water be directed upon the anterior pyramids, the fasciculated ar-
rangement of their component fibres, all of which are parallel, will be clearly demonstra-
ted ; and it will also be seen that these two bodies are not mere medullary bands, but
are two three-sided bundles occupying an angular groove between and in front of the two
ohvary bodies {fig. 269, C).
The decussation of the anterior pyramids demands attention, as one of the most impor-
tant points in the anatomy of the cerebro-spinal axis.
On examining the anterior median groove of the medulla oblongata (see^^*. 270, 276),
it will be found that, at a distance from the pons Varolii of about ten lines (Gall says an
inch and some lines), the anterior pyramids divide into three or four bundles, which al-
ternately interlace in a regular manner (below n), so as to form a plaited structure of from
two to four lines in length. Is this decussation only apparent 1 and if so, does the ap-
pearance result, as has been said, from the traction of parallel fibres in opposite direc-
tions 1 or do the pyramids commence by alternate bundles arising from each side of the
middle line, and does this alternate arrangement occasion the appearance of a decussa-
tion 1 or, lastly, do the right and left pyramids actually cross like the limbs of the letter X 1
On consulting the various authorities on this subject, it is found that the decussation
of the pyramids, first pointed out by Aretaeus, renoticed by Fabricius Hildanus, and de-
monstrated by Mistichellit and Pourfour Dupetit,t has been admitted by Santorini, Wins-
low, Lieutaud, Duverney, Scarpa, and Soemmering ; and that the opposite opinion has
been maintained by Morgagni, Haller, Vic d'Azyr, Sabatier, Boyer, Cuvier, Chaussier,
and Rolando.iJ As to Gall and Spurzheim, they do not seem to have had a decided
opinion upon this point ; for, after having appeared to admit the decussation in some
passages of their work, they say elsewhere that the small cords of the pyramids do not
form a true decussation, but merely intersect and pass over each other obliquely.
In order to settle the question of decussation, I submitted the medulla oblongata to
the action of a jet of water upon both its anterior and posterior surfaces ; and by then
examining it from behind forward, I was able to ascertain that the right and left p)Tam-
idal bundles do most evidently decussate (a, fig. 273) ; that this decussation is effect-
ed, not only from side to side, but also from before backward (i, fig. 274) ; that the left
pyramidal bundle (i) passes downward to the right side and backward (w), traverses the
gray matter of the cord, and becomes continuous with the right lateral column of the
cord, and vice versa ; and, lastly, that the anterior pyramids are not in the slightest de-
gree continuous with the anterior columns of the spinal cord.
The Olivary Bodies. — ^When the anterior pyramids are removed, it is seen that the
olivary bodies {d, figs. 273, 274) do not consist merely of the prominent masses which
project beyond and on the outer side of the anterior pyramids, but that they extend in-
ward to the median hne behind the pyramids, which are received in a slight concavity
formed by the anterior surfaces of the olivary bodies {fig. 269, C). This arrangement is
very evident, without any preparation, in anencephalous infants, or in such as are born
* If we employ a stream of water in the eiamination of a fresh medulla oblongata, it may easily be con-
ceived that the results will be much more conclusive than if we had thus examined one which had already
> been subjected to different modes of preparation that may have altered its structure.
t Trattato dell' Apoplessia, 1709. t Letters d'un Med6cin des Hdpitaux, 1710.
<t Of all who have denied the reality of the decussation, Rolando appears to me to have opposed the doctrine
vith the greatest force. He examined the subject with the greatest attention ; he made horizontal sections
■ of the medulla oblongata, but he could never see anything more than the alternate origin of the fasciculi which
. eoastitute the anterior pyramids ; he could never find that the bundles of the right side passed over to the
left, and vice versd. In reply to the objection, that without admitting the decussation it is iinpossible to ac-
■ count for the cross effects of injuries or diseases of the brain, he states that these are explained by the inti-
mate union between the optic thalanii and tubercula quadrigemina of the two sides, and between the two halves
of the pons Varolii and medulla oblongata. The error of Rolando evidently arose from his attaching such ei-
Husive importance to sections, as a means of determining the structure of the medulla ob\ongata.
INTERNAL STRUCTURE OF THE MEDULLA OBLONGATA. 707
with very imperfectly-developed brains ; the situation of the atrophied pyramids is then
occupied by two tracts of gray matter, and the olivary bodies, more developed than usual,
reach as far as the median line.
When a jet of water is directed against the median line between the olivary bodies,
it encounters a white and very dense tissue, upon which it produces little effect.*
As soon as this tissue has been removed with the knife, the water insinuates itself
mto the substance of the olivary bodies, which, as we have seen, are open towards the
inner side ; each olivary body is then spread out, its anterior half is turned outward, and
assumes the appearance of a dense yellowish layer folded upon itself, like a leaf while
within its bud ; after some white lamellae are removed by the action of the water, the
posterior half is exposed, and displays a similar appearance to that of the anterior half
Rolando compares the arrangement of this yellow folded layer, or corpus dentatum of
the olivary body, to a flattened purse {borsa appiattita), the neck of which is open, some-
what constricted, and directed backward and towards the median line.
Gall and Spurzheim regarded the olivary bodies as ganglia, but these anatomists ap-
pear to me to have singularly misappUed the term ganglion, which they have given to
such dissimilar parts as the olivary bodies, the corpora striata, and the tuber annulare.
Lastly, by directing the stream of water against the median line, and by assisting its
action by gently drawing the parts asundei. the medulla oblongata becomes divided into
two perfectly similar halves, excepting opposite the decussation. A beautiful prepara-
tion may thus be made, exhibiting the separation of the two halves of the medualla ob-
longata and spinal cord, and leaving the decussation of the anterior pyramids.
It appears, then, on the one hand, that the anterior pyramids are not formed by the
anterior columns of the spinal cord ; and, on the other hand, that the posterior columns
of the cord become separated from each other behind when they have reached the me-
dulla oblongata. What, then, becomes of the white bundles of the cord in the medulla ob-
longata 1
Having arrived opposite the neck of the bulb, the white matter of the cord is divided
into two bundles : one anterior, which forms the anterior pyramid {b. Jig. 273), and may be
called the cerebral bundle, because it passes up (i') to the brain ; the other posterior, oi
the restiform body (c e), which may be called the peduncle of the cerebellum, because it is
exclusively intended (w) for that organ ; the former is composed of white bundles, which
emerge from the interior of the spinal cord, and the latter of the anterior columns, and
of the remaining white bundles of the cord. The olivary bodies {d) are situated between
these two sets of white fibres.
When, by means of the stream of water, the anterior pyramids and the restiform
bodies have been removed, it is seen that each half of the medulla oblongata is formed
principally of a very dense nucleus, consisting of a mixture of gray and white substances.
This nucleus, or fasciculus of re-enforcement of the medulla oblongata, which we shall call
the unnamed fasciculus (faisceau innomini) of the medulla, commences opposite the de-
cussation of the pyramids by a narrow extremity, increases in size as it proceeds up-
ward, passes above {I, fig. 274), i. e., deeper than the pons, and becomes continuous, as
we shall afterward see, with the corresponding optic thalamus. Each half of the medul-
la oblongata has its fasciculus of re-enforcement, of which the internal surface, viz., that
turned towards the middle line, corresponds to the fasciculus of the opposite side, but
is separated from it by the white fibres {p,fig. 274) already described (p. 706) as passing
horizontally from before backward, in the median line of the medulla. The posterior
surface of these fasciculi {p,fig. 271) constitutes the anterior wall of the fourth ventricle.
The corresponding peduncles of the cerebellum, or the restiform bodies, embrace them
on the outside, and form, as it were, grooves for them.
On examining thoroughly the internal or median surface of each re-enforcing fascicu-
lus of the bulb, it is found that there are two vertical bands upon that surface, one an-
terior, the other posterior ; and that the fibres which pass horizontally from before back-
ward in the median line of the medulla oblongata are situated between the bands of the
right and left sides.
Each fasciculus of re-enforcement is divided above into two parts, one of which forms
the centre of the corresponding restiform body, while the other becomes continuous with
the optic thalamus above the pons Varolii.
I have not alluded to the olivary fasciculi admitted by some anatomists, for the white
bundles so called do not even come from the olivary body, but form the continuation of
the lateral columns of the spinal cord, which embrace the olivary bodies on the outer
side, without being re-enforced by any bundles derived directly from them.t
* I have frequently been led to regard the white medullary substance which is situated between the olivary
bodies, and passes into each of them, as a transverse commissure, which might be called the commissure ot
the olivary bodies.
t [The bundles, named faisccaux innommin^s in the text (fasciculi teretes of some other authors), which M.
Cruveilhier describes as taking their rise at the lower end of the medulla oblongata, are more generally con-
sideied to be prolonged from the lateral columns of the cord ; and on comparing the statements of recent in-
quirers concerning the anatomy of the medulla oblongata, the following appears to be the arrangement which
the columns of the cord undergo in passing through it, viz., the posterior columns (including the postonor me
diau fasciculi, which correspond with the posterior pyramids) separate laterally f'om one another (f,figs.Zi3,
708 NEUROLOGY.
Development of the Spinal Cord.
As soon as the spinal cord has passed through its original condition of an almost
transparent pulp, it assumes the appearance of a lamina, the edges of which are rolled
back upon themselves so as to enclose a canal, continuous with the cavity of the fourth
ventricle, which might be regarded as the expanded extremity of the canal. This canal
is narrowed along the middle by the reflection of the pia mater into it : it is thus con-
verted into two canals, the walls of which are at first thin, but afterward increase in
thickness, gradually encroach upon the caliber of the canals, which finally disappear be-
tween the sixth and seventh month. At this period a thin, white, outer layer covers the
whole medulla : the posterior median columns are very large, and of a white colour,
while the antero-lateral columns are still semi-transparent, the gray matter is soft and
diffluent, like a pulp ; and, by the slightest insufllation, a canal may be formed along the
centre of each half of the cord.
The spinal cord occupies the whole length of the vertebral canal until the third month ;
but after this time, its lower extremity becomes relatively higher up to the period of
birth, when it corresponds to the second lumbar vertebra.
The spinal cord is larger, in proportion to the brain, during the early periods of foetal
hfe, than afterward. The more rapid development of the brain, at later periods, gives
that organ the advantage.
From studying the development of the spinal cord, Tiedemann infers that the white
substance exists before the gray, and therefore that the latter cannot be the nutritious
organ or matrix of the white substance, as Gall had affirmed.
It is quite certain that the white parietes of the medullary canal are developed pre-
viously to the gray matter.
Development of the Medulla Oblongata.
During the first three months of intra-uterine life, the upper limit of the medulla ob-
longata is not defined, because there is no pons Varolii. The foetal brain, therefore, in
this condition, resembles the brains of birds, reptiles, and fishes. The transverse fibres
of the pons make their appearance during the fourth month, and the upper limit of the
medulla oblongata is then established.
The two halves of the medulla oblongata are perfectly distinct, and each half is divi-
ded into three columns : one for the brain properly so called, viz., the anterior pyramidal
bundle ; another for the tubercula quadrigemina, which may be called, with Tiedemann,
the olivary bundle, remembering, at the same time, that this term has a very diiferent
meaning from what was attached to it by Gall ; and a third or cerebellar bundle, which
is the restiform body.
The anterior pyramidal bodies are at first flattened like those of mammalia, but during
the latter months they acquire their characteristic size and prominence. In the medulla
oblongata of a foetus, from the seventh to the ninth month, the anterior pyramids are of
a reddish-gray colour, while the anterior columns of the spinal cord are as white as they
appear afterward. Those pyramids, therefore, are not the continuation of the anterior
columns of the cord.
The decussation of the pyramids is perfectly distinct after the fourth week of foetal
existence.*
The olivary bundles of Tiedemann, which are situated to the outer side of the anterior
pyramids, and, like them, traverse the pons, gain the sides of the tubercula quadrigemina,
beneath which they form an arch, which constitutes the upper wall of the aqueduct of
Sylvius. The olivary bodies, which are wanting in birds, reptiles, and fishes, do not ap-
pear until the end of the sixth or the commencement of the seventh month of foetal life.
The cerebellar bundles, or restiform bodies, are perfectly distinct from the preceding.
The small manmiillated bundles which bound the sides of the posterior longitudinal
groove can also be distinguished in the foetus.
Comparative .Anatomy of the Spinal Cord.
Mammalia. — The spinal cord of mammalia precisely resembles that of the human sub-
274), and enter the cerebellum, forming the principal part of its inferior peduncle (n). The fibres of the lat-
eral columns are disposed of in three ways: 1. A part of thfem cross the median plane to the opposite side (m.
Jig. 273), and form the chief part of the pyramidal body (A) of that side. 2. Another set join the inferior pe-
duncle of the cerebellum. 3. The remainin<f fibres are continued along the floor of the fourth ventricle l.p,fig
271), as the fasciculi innominati or fasciculi teretes. The anterior columns (a, fig. 273) of the cord, on enter-
ing the medulla oblongata, are thrown aside by the decussating fibres coming from the lateral columns, and
then one portion of each anterior column forms the outer part of the coiTesponding pyramid (i) ; another por
tion {c,fig. 274) passes partly behind and partly on the outer side of the olivary body, and is then chiefly con
tinued into the fillet (A) ; the remaining part passes into the cerebellum, joining its inferior peduncle (n)
The connexion of the cerebellum with the anterior columns of the cord was pointed out by Mr. Solly. — (Phil.
Trans., 1836, p. 567.) Arnold describes the posterior pyramids (fasciculi gracilea) as passing into the crura
cerebri. For farther details on the anatomy of the medulla oblongata, the reader is referred to Arnold's
Bemerkungen itber den Bau des Hirns und Ruckenmarks, Zurich, 1838 ; also his Icones Anatomica, fasc. i. ,
and to a paper by Dr. J. Reid in the Edtn. Med. and Surg. Journ. for January, 1841.]
* [The fourth or fifth month, accordino- to Tiedemann ; though in one part of his work " week" has been,
by an error, printed for "month."]
COMPARATIVE ANATOMY OF THE MEDULLA OBLONGATA. 709
ject : its length, its size, its enlargements, are exactly proportioned to the size and ac-
tivity of the muscles, and to the sensibility of the organs with which it is connected by
means of the nerves.
Birds. — The spinal cord in birds is proportionally both longer and larger than in other
animals ; and this has reference to the enormous muscular effort required in flying. It
presents two great enlargements ; one of these corresponds to the wings, and the other,
which is larger, and contains a ventricle, corresponds to the lower extremities ; this
ventricle was known to Steno, who described it under the name of the rhomboidal sinus.
According to Nicolai {Dissertatio de Medulla Spinali Avium, Halle, 1811) and Tiede-
mann, the spinal cord of birds contains a central canal, which is lined by a thin layer of
gray matter, not only in the embryo, but also in the adult.
Reptiles.- — In all reptiles the spinal cord contains a canal, which is lined, according to
Tiedemann, by a thin layer of gray substance. In the batrachian reptiles (the toad, frog,
&c.), the spinal cord occupies only the anterior or upper part of the vertebral canal. M.
Desmoulins says (t. i., p. 187) that the gray matter in these species surrounds the white
substance. This opinion appears to me to be erroneous.
In ophidian reptiles (serpents), the spinal cord occupies the whole length of the verte-
bral canal ; there is no gray matter,* but its place is occupied by a fluid, so that each
half of the medulla contains a canal.
In the saurians (crocodiles, lizards), the spinal cord is slender, of almost uniform size
throughout, and occupies the whole length of the vertebral canal.
The spinal cord of the chelonian (tortoises, &c.) is the most remarkable of all, as re-
gards its shape, and is peculiarly illustrative of the law which regulates the dimensions
of this organ. There are three fusiform enlargements separated from each other by two
very narrow portions ; the middle enlargement corresponds to the upper extremities, and
the inferior one to the lower extremities ; the first constriction corresponds to the neck,
the second to the thorax.
Fishes. — In all f^hcs the spinal cord occupies the entire length of the vertebral canal.
It is of uniform size in its anterior five sixths, but diminishes like a cone in the posterior
sixth. There is no gray matter,t so that the cord is hollow. According to Arsaky
(^Dissert, de Piscium Cerebro) and Tiedemann, the medullary canal is lined by a thin layer
of gray matter.
The lophius piscatorius and the male tetrodon present remarkable anatomical peculi-
arities ; in the lophius, the spinal cord is diminished in size opposite the third cervical
vertebra ; all at once it becomes extremely slender, and then terminates in a point op-
posite the eighth cervical vertebra. Twenty-six pairs of nerves arise from the enlarged
portion, and only five or six" pairs from the slender portion. In the tetrodon there is no
spinal cord, properly so called, or, rather, this part of the cerebro-spinal axis is reduced
to a medulla oblongata, from which arise thirty-two pairs of nerves.
From these facts, it follows that the length and size of the spinal cord bear an exact
proportion to the muscular power and sensibility of the parts supplied by it ; and farther,
that the gray matter of the cord is not nearly so important as the white substance, since
it is absent in a great number of species. J
Comparative Anatomy of the Medulla Oblongata.
In the mammalia the medulla oblongata is constructed upon the same plan as in the
human subject, but the anterior pyramids are much smaller, and the olivary bodies ap-
pear to be completely effaced. The tubercula cinerea of Rolando exist only in man ;
in whom alone do we find those white streaks of medullary substance upon the anterior
wall of the fourth ventricle, which are regarded as forming, at least in part, the origins
of the auditory nerves.
The medulla oblongata of birds and reptiles presents no striking peculiarities. In the
different species its size is always in proportion to that of the fifth, and especially the
eighth pair of nerves, which take their origin from this part.
In fishes a peculiar pair of lobes correspond to the medulla oblongata ; these lobes were
for a long time erroneously supposed to be the lateral lobes of the cerebellum, and have
thus led to much obscurity concerning the anatomy of the encephalon in these animals.
Desmoulins calls them the lobes of the fourth ventricle ; we shall call them the lobes of
the eighth pair of nerves. In the ray and sturgeon this lobe is so highly developed, that
it forms half of the encephalic mass. In the carp, besides the lateral lobes which are
traversed by some white fibres, there is also a median lobe. Moreover, as a general
rule, whenever the spinal cord has to furnish any nerves, there is an enlargement or a
lobe. In the torpedo, in which the eighth pair of nerves are of enom^ous size, and sup-
ply the electrical organ, these lateral lobes are in an extraordinary degree developed. In
the trigla there are certain small lobes behind the cerebellum, which correspond to the pe-
culiar digitiform prolongations serving as organs of progression in the animals in question.
* [The spinal cord of serpents forms no exception to the general rule ; gray matter has been recognised in
it, as in the cord of other vertebrated animals. The same is true of fishes.— (See Leuret, Anatoime Com-
parie du Systime Nerveux, ^c, Paris, 1839.)] t See note, siipru. t See note, supra.
71© NEUROLOGY. .
The olivary bodies are most highly developed in the human subject ; they exist also,
but are very small, in some mammalia ; they disappear in birds, reptiles, and fishes. I
consider the olivary bodies as lobes in a rudimentary state.
THE ISTHMUS OF THE ENCEPHALON.
General Description and Division. — The Pons Varolii and Middle Peduncles of the Cere-
bellum— the Peduncles of the Cerebrum — the Superior Peduncles of the Cerebellum and the
Valve of Vieussens — the Corpora Quadrigemina. — Internal Structure of the Isthmus, viz.,
of its, Inferior, Middle, and Superior Strata. — Sections. — Development. — Comparative
Anatomy.
I SHALL, with Ridley, apply the term isthmus of the encephalon to that narrowed 'and
constricted portion of the encephalic mass which is situated between the cerebrum, cere-
bellum, and medulla oblongata, which corresponds to the free margin of the tentorium
cerebelli, and comprises the pons Varolii and middle peduncles of the cerebellum, the
peduncles of the cerebrum, the tubercula quadrigemina, the superior peduncles of the
cerebellum, and the valve of Vieussens.
The isthmus of the encephalon is the common point of union between the three great
divisions of the cerebro-spinal axis, viz., the medulla spinalis, the cerebrum, and the
cerebellum. It contains within it the media by which they all communicate, or, as it
may be said, the elements of each reduced to their most simple expression.
It is of a cuboid form, and therefore presents six surfaces for our consideration :
An inferior surface (fig. 276), on which we observe the pons Varolii, or tuber annulare
(d), the middle peduncles of the cerebellum (m), and the peduncles of the cerebrum (//).
A superior surface {fig. 271), which is covered by the superior vermiform process of
the cerebellum, by the velum interpositum, and by the posterior border of the corpus cal-
losum. In order to expose this surface, supposing the brain to be with its base upward,
the cerebellum must be turned forward, and the pia mater should be separated, taking
care to lift up with it the pineal gland. Proceeding from before backward, the following
parts come into view: the tubercula quadrigemina (fg), resting upon them the pined
gland (c), the superior peduncles of the cerebellum (shown in cut at r ; also r, fig. 272),
and the valve of Vieussens il,fig. 271).
The lateral surfaces {fig. 272) are each divided into two distinct parts or stages, by a
furrow which runs from before backward (the lateral furrow of the isthmus) ; the inferior
stage consists of the pons Varolii (a) and the middle peduncles of the cerebellum (m),
while the superior is narrower, lies closer to the median line than the preceding, and
presents a triangular fasciculus (A), having its base directed downward, and its apex turn-
ed upward, so as to reach the corresponding inferior quadrigeminous tubercle or testis {g).
The anterior surface of the isthmus is continuous with the optic thalami {s, fig. 272).
The posterior surface is much narrower than the anterior, and is continuous with the
base of the medulla oblongata.
We shall examine the several parts of the isthmus in the following order : the pons
Varolii and middle peduncles of the cerebellum, the peduncles of the cerebrum, the superior
peduncles of the cerebellum, the valve of Vieussens, and the tubercula quadrigemina. The in-
ferior peduncles of the cerebellum have been already described with the rest of the medulla
oblongata, under the name of the restiform bodies.
The Pons Varolii and Middle Peduncles of the Cerebellum.
The pons Varolii, or tuber annulare,* is that white cuboid eminence {d, fig. 276) situa-
ted between the cerebrum and cerebellum, upon the base of the encephalon, and form-
ing, as it were, its centre (mesocephale, Chauss. ; nodus encephali, Scemm.). From this
centre the several parts proceed as follows : backward, the medulla oblongata (e) ; for-
ward, two thick white bundles, which pass into the brain, and form the anterior or cere-
bral peduncles {ff); laterally, two thick bundles, which enter the cerebeUum, and are
named the posterior peduncles, or middle cerebellar peduncles {m).
The pons Varolii, the cerebral and cerebellar peduncles, and the medulla oblongata
proper, are together called the medulla oblongata by some authors ; several of the older
anatomists, in fact, compared the pons to the body of an animal, of which the anterior
peduncles represented the arms ; the posterior, the legs ; and the medulla oblongata
proper, the tail ; and hence the terms still in use of the arms, legs, and tail of the so-
called medulla oblongata. It was Varolius who compared this part to a bridge, under
which the several branches of a stream, supposed to be represented by the peduncles and
the medulla oblongata, joined each other ; hence the terms pmis Varolii and pons cerebelli.
The pons is free below, but is blended above with the upper portion of the isthmus ;
it is bounded in front by the peduncles of the cerebrum, and behind by the meduUa ob-
longata ; and it is continuous, laterally, with the middle peduncles of the cerebellum {m),
* The term tuber annulare is derived from the fact that this part of the enceohalon seems to embrace tb«
several prolongations of the medulla oblongata like a ring.
THE PEDUNCLES OP THE CEREBRUM, ETC. 711
forming with them but one system of fibres ; its lateral boundaries are, therefore, alto-
gether artificial.
The size of the pons, which is very considerable in the human subject, is always in
relation with the development of the lateral lobes of the cerebellum ; comparative anat-
omy, embryology, and the study of malformations completely establish this fact.*
Its inferior surface is covered by the pia mater, which can be easily stripped off; it
rests upon the anterior part of the basilar groove, and slopes backward and downward
like the incl»ed plane of that groove.
It presents along the median line a slight furrow, which is broader in front than be-
nind, and corresponds to the basilar artery : this groove appears as if it were caused by
the presence of the artery ; nevertheless, I must say, that not unfrequently the basilar
artery is found to deviate to one side or the other, or to be more or less tortuous, and
yet that the median groove is as distinctly marked as usual.
I beUeve there is good ground for entertaining the opinion that this groove results from
the prominence of the anterior pyramids, which raise up the surface of the pons on each
side of the median line.
The inferior surface of the pons presents certain transverse bundles or fibres, which
appear to cross each other at very acute angles, and which, according to Rolando, may
be divided into three sets : superior bundles, which turn upward, to constitute the upper
part of the middle peduncles of the cerebellum ; inferior bundles, which pass transversely
outward ; and middle bundles, which are directed obliquely downward and outward, pass
in front of the inferior bundles, and then form the anterior border of the cerebellar pedun-
cles. The origin of the fifth pair of nerves is between the superior and middle sets of
fibres. Not uafrequently the middle bundles are not to be seen.
It follows, therefore, that the middle peduncles of the cerebellum are merely the trans-
verse fibres of the pons condensed and twisted upon themselves. The pons and these
peduncles of the cerebellum constitute one and the same system of fibres. We might
therefore, with Gall, designate the pons and the middle peduncles of the cerebellum as
the commissure of the cerebellum, or corpus callosum of the cerebellum.
The Peduncles of the Cerebrum.
The peduncles of the cerebrum (//, fig. 276), sometimes regarded as prolongations of
the cerebrum to the medulla oblongata ( processus cerebri ad medullam oblongatam, ad pon-
tem Varolii), sometimes as the arms, legs, or thighs of the cerebrum {brachia, crura, femo-
ra, cerebri), and by others as prolongations of the medulla towards the cerebrum (proces-
sus medullm oblongata ad cerebrum), are two thick, white, fasciculated columns, which
arise from the anterior angles of the pons Varolii, and enter the substance of the cere-
brum, after a course of about six lines.
They are cylindrical, and in contact with each other as they emerge from the pons ;
and they gradually increase in size, and become flattened as they advance forward, up-
ward, and outward. The optic tracts (s 2, fig. 272) circumscribe and bound them in front.
Their size corresponds to that of the cerebral hemispheres. They are of equal di-
mensions in a well-formed brain, but they are liable to become atrophied with their cor-
responding hemisphere, as I have had frequent occasion to observe.
Each of them is free below, and on its outer and inner side, but is blended above with
the upper portion (A ifg, fig. 272) of the isthmus of the encephalon.
Their white fasciculi are slightly divergent, and are often intersected at right angles
by certain white tracts, some of which emerge from the testes and the valve of Vieus-
sens, while others proceed from the internal surfaces of the peduncles themselves. This
arrangement Gall and Spurzheim have named the transverse interlacement of the great
fibrous bundles {see fig. 272). Owing to the oblique and diverging direction of the cere-
bral peduncles, there is left between them a triangular inter-peduncular space (between r
and t, fig. 276), which is occupied in front by the corpora manmiillaria or albicantia (z)
and the tuber cinereum (v), and in which is observed behind two white triangular bun-
dles, separated from the peduncles by a blackish line. We shall see that these inter-pe-
duncular bundles are merely the under surface of the bundles of re-enforcement of the
medulla oblongata, or the " faisceaux innomines" {I, fig. 274).
The Superior Peduncles of the Cerebellum and the Valve of Vieussens.
The superior peduncles of the cerebellum (r, figs. 271, 272, 280) are more commonly known
as the processus cerebelli ad testes, a name given to them by Pourfour Dupetit. I should
observe, however, that this name sanctions an anatomical error ; for the superior pedun-
cles of the cerebellum do not go to the testes at all, but pass under them, and are cover-
ed by the corresponding lateral triangular bundle of the istlmius ; they should rather be
called processus cerebelli ad cerebrum {Drelincourt.)
The inferior peduncles of the cerebellum consist of two lamellae, which arise from the
* Animals which have no lateral lobe of the cerebellum have no pons Varolii, and this part is small in such
as have very small lateral cerebellar lobes. In a young- girl ten years of age, who had no cerebellum, I fuund
that the pons was also wanting.
fj^tf NEUROLOGY.
interior of the cerebellum, one on each side of the median line, pass upward and forward
parallel to each other, and appear to be continuous with the testes.
Their upfer convex surface is covered by the cerebellum {see fig. 280), and is separated
from it by a double layer of the pia mater. Their inferior surface is free, and assists in
forming the upper wall of the aqueduct of Sylvius. Their external borders are each sep-
arated from the pons by a furrow, which we have already described under the name of
lateral furrow of the isthmus. Their internal borders are connected together by means of
the valve of Vieussens, which is distinguished by its colour from the peduncles.
Their inferior extremities pass deeply into the central white substance of the cerebellum.
The valve of Vieussens {valvula magna cerebri, I, fig. 271 ; v, fig. 280 ; g to w, fig. 282)
is a thin, semi-transparent lamina, which occupies the interval between the two superior
peduncles of the cerebellum ; it is the velum medullar e or velum inter jectum of Haller.
Its posterior surface is concave, and is in relation above with the superior vermiform
process ; in its lower portion it adheres to the transversely-notched imperfect lamella
(linguetta laminosa, Malacarne), in which the superior vermis ends.
The median line of this posterior surface is marked by a line {fig. 271), which Rolan-
do considers as the trace of the line of junction between the two laminae, of which, ac-
cording to him, the valve consists.
The anterior surface is convex, and forms the posterior w^ of the aqueduct of Sylvius
(leading from v to /, fig. 282).
The borders of the valve ^xe not only in juxtaposition with the corresponding borders
of the superior peduncles of the cerebellum, but appear to be continuous with them.
The superior extremity is narrow, and presents a transverse band, which may be re-
garded as the commissure of the superior peduncles of the cerebellum Euid of the fourth
pair of nerves.
The inferior extremity is broad, very thin, and continuous with the central portion ol
the median lobe of the cerebellum (w).
The Tuber cula Quadrigemina.
Dissection. — Place the brain with its base upward, turn the cerebellum forward, and
remove the pia mater.
The term tubercula quadrigemina or bigemina (corpora bigemina, Soemmering, optic lobes
of the lower animals) is applied to four tubercles {fgfg,figs. 271, 272) situated regu-
larly upon the upper surface of the isthmus, two on each side of the median line. They
form two pairs : the anterior or superior (/) are the larger, and are called the nates (emi-
nentia. natiformes) ; the posterior or inferior {g) are the smaller, and are called the testes
{eminentia testiformes).
These tubercles are placed between the cerebrum and cerebellum, and are situated
above the peduncles of the cerebrum, and, consequently, upon a plane anterior to that of
the pons, and cannot consistently be named the tubercles of the mesocephalon, as was done
by Chaussier. The anterior part of the aqueduct of Sylvius passes beneath them (.fg,fig-
282), and establishes a communication between the third (l) and fourth (v) ventricles.
They are comparatively small, indeed merely rudimentary in the human subject, for
their development in the animal series is inversely as that of the cerebrum and cerebel-
lum. The space which they occupy is a parallelogram of ten lines by eight.
The anterior tubercles are always larger than the posterior ;* they are of a gray col-
our, oblong, ellipsoid, and diverging ; their longest diameter is directed obliquely forward
and outward. The posterior tubercles are smaller, and more detached ; they are almost
hemispherical, and of a white colour ; but not so white as the fasciculated medullary sub-
stance.
A furrow, curved like a parabola opening forward, separates the anterior from the pos-
terior tubercles. The antero-posterior furrow along the median line separates the tu-
bercles of the right from those of the left side. From this furrow, a small, grayish, and
tolerably dense cord proceeds backward, and descends perpendicularly upon the valve of
Vieussens, or, rather, upon the transverse commissure by which it is surmounted, and
then divides into two or three branches. This cord might be named the pillar of the
valve of Vieussens {columella frenulum).
The lateral triangular bundle {h,figs. 271, 272) of the isthmus terminates in the poste-
rior tubercle. This fasciculus, which was pointed out by Reil (" schleife," lemniscus,
fillet), Tiedemann, and Rolando, who described it as arising from the olivary bodies, pre-
sents an anterior border, which is directed obliquely forward and outward, proceeds along
the anterior tubercle, and terminates in a small body called the corpus genicidatum inter-
num {i, figs. 271, 272). Its posterior border inclines downward, backward, and outward,
and forms a slight prominence above the superior peduncle of the cerebellum, which is
covered by it. Its base corresponds to the lateral groove of the isthmus, which separ-
ates it from the pons and the peduncle of the cerebrum. Its apex extends to the corre-
* The relative size of the tuberculii quadrigemina varies somewhat in different animals. The anterior tuber
cles are much larger than the posterior in ruminants, solipeds, and rodentia ; they are smaller than the j>os-
terior in camivora — in the dog, for example.
INTERNAL 8TRUCTUEK OP THE ISTHMUS OP THE ENCEPHALON. 713
sponding posterior tubercle or testis. The anterior tubercles or nates are continuous
with the optic thalami (a, fig. 271), being separated from them by a slight depression.
Some white fibres proceed from the anterior extremity of these tubercles, and, as we
shall afterward see, form a thin layer above the corresponding corpus geniculatum ex-
ternum (;'), and assist in the formation of the optic nerves. These white bands are gen-
erally proportioned to the size of the nates.*
The Internal Structure of the Isthmus of the Encephalon.
Dissection. — By antero-posterior and transverse sections of the isthmus. The parts
to be examined by laceration, by submitting them to the action of a stream of water, and
also after they have been hardened in alcohol, or by being boiled in oil, or a solution of salt.
The internal structure of the isthmus presents three very distinct strata placed one
upon the other : an inferior, formed by the pons, the middle peduncles of the cerebellum,
and the fasciculated portion of the peduncles of the cerebrum ; a middle stratum, form-
ed by the prolongation of the bundles of re-enforcement of the medulla oblongata ; and a
superior stratum, which consists of the triangular lateral bundles of the isthmus, the su-
perior peduncles of the cerebellum, the valve of Vieussens, and the tubercula quadri-
gemina.
iTiternal Structure of the Pons and the Peduncles of the Cerebellum.
It has been stated that the lower surface of the pons presents some white transverse
fibres (see left side, fig. 273), which twist g^ ^^^
upon each other to form the middle pedun- '^ ^^/
cles of the cerebellum. On making a very
superficial incision into the pons, we find,
beneath the external layer of white matter,
which is very thin behind, and a little thick-
er in front, a grayish-yellow substance,
which is traversed by the transverse fibres
of the pons, so that the part (m, fig. 274)
has a striated appearance.
If the handle of the scalpel be passed be-
neath the anterior border of the pons, so as
to remove all that part which projects be-
yond the level of the peduncles of the cere-
brum, it will be seen that the pons is trav-
ersed longitudinally by certain white bun-
dles of fibres {b', figs. 273, 274) ; and if, moreover, the handle of the scalpel be insinuated
beneath the posterior border of the pons, and all that part be removed which projects be-
yond the pyramidal bodies of the medulla oblongata, these white longitudinal bundles
which traverse the pons are found to be the prolongation of the pyramids (i), and are
themselves continuous with the peduncles of the cerebrum {n,fig. 282). By thus separ-
ating the pons into very thin horizontal layers, it will be found that the longitudinal {b')
and transverse (m) fibres form several alternate layers, above which we arrive at the
middle stratum of the isthmus.
The peduncles of the cerebrum are continuous with the longitudinal fibres of the pons,
and the middle cerebellar peduncles with the transverse fibres of the same part ; the
gray matter of the pons extends into the substance of%he latter, and gives them a stria-
ted appearance. At the boundary between the pons and the middle peduncles of the
cerebellum there is on each side a very considerable longitudinal bundle, which forms
the origin of the fifth nerve, and which, therefore, does not belong to the anterior pyram-
idal bodies.! m
The absolute continuity of the anterior pyramids with the peduncles of the cerebrum,
through the pons, may be regarded as a type of the structure of the nervous centre. The
two sets of fibres are intermixed in the pons, so as to intersect each other at right an-
gles, but they maintain their individuality, t
The pons presents neither a raphe nor a septum in the median line : the fibres of the
right half are continuous with those of the left. The white fasciculated fibres {b') of the
* They are very large in the sheep ; it appears that it was chiefly from the anatomy of the brain in this an-
imal that Gall founded his opinions as to the optic nerves, which he regards as arising from the tubercula
quadrigemina. This opinion is very doubtful as far as concerns the human subject.
t The most anterior and the most posterior transverse fibres of the pons have a very peculiar arrangement
the anterior are inflected {o,fig. 282) between the peduncles of the cerebrum, and completely occupy the in-
terval between them ; so that each of these peduncles is embraced by a distinct ring, formed by the fibres of
the pons ; and, again, the most posterior fibres of the pons dip between the anterior pyramids, each of which
is also embraced by a distinct ring.
t The continuity of the pyramids with the peduncles of the cerebrum, through the inferior portion of the
pons, was accurately described and figured by Varolius (Dc Nervis Opticis nonnulksque aliis, 1573), by Vieus-
sens {NeuTographia Universalis, tab. 16), by Morgagni {Adversaria Anatomica, v.), and by Vicq d'Azyr. Vieus
lens showed this continuity by lacerating the pons. Vicq d'Azyr showed it by successively removing the thin
layers of the pons by means of a cutting instrument. The plates given by Gall surpass those of his predeces-
sors in execution, but not in a scieatific point of view.
4X
'714 NEUROLOGY.
peduncles of the cerebrum, which are continuous with the anterior pyramids (A), form
part of the inferior stratum of the isthmus ; these fasciculated fibres are parallel and per-
fectly white, without any intermixture of gray matter.
Internal Structure of the Middle Stratum of the Isthmus.
When the pons, or, in other words, the successive layers of the inferior portion or
etratmn of the isthmus, have been removed, the middle stratum is exposed. This may
Fiff. 274. be very easily displayed in a brain that has been
well hardened in alcohol. It is then seen that this
middle stratum is formed by a prolongation of the
fasciculi of re-enforcement \faisceauxinnominis) of
the medulla oblongata, which becomes enlarged in
passing above the pons, and still more so opposite
the peduncles of the cerebrum, above which we
shall trace them presently. This prolongation {I,
fig. 274) then passes through the pons at right an-
gles. It was doubtless to illustrate this arrange-
ment that Varolius described the medulla, when
viewed from below, as passing beneath the pons
like the water of a canal under a bridge. This re-enforcing bundle, pointed out by Ro-
lando {Recherches sur la Moelle Alongee, 1822) under the appellation of the middle fasci-
culus, has been correctly represented by Mr. Herbert Mayo.
Those portions (c, fig. 269, A) of the bundles of re-enforcement which correspond to
the peduncles of the cerebrum are separated from the superficial part of the peduncles
themselves (a) by a layer of black or blackish matter (5) : opposite the peduncles, these
two bundles are intimately united,* but they soon diverge to enter the optic thalami.
Are they simply in juxtaposition, or do they interlace at the point in which they appear
to be blended 1 I am inclined to believe that they do interlace ; but I have not yet been
able to demonstrate this clearly, because they do not consist of very distinct bundles.
The Internal Structure of the Upper Stratum of the Isthmus.
The superior peduncles of the cerebellum are fasciculated : their lower extremities {r,jig.
274) assist in forming the central nucleus of the cerebellum ; their upper extremities (r')
expand into a great number of fibres, some of which terminate upon the anterior wall
of the fourth ventricle, on each side of the median line, while others form a loop below
the tubercula quadrigemina.
Structure of the Tubercula Quadrigemina. — Reil, who first examined the structure of
the tubercula quadrigemina, considers them as consisting of four rounded masses of
gray matter, placed upon the radiated fibres of a white bundle, which spreads out beneath
them. This white bundle (forming part of the bundle h, fig. 274), which he calls the ^Z-
let or loop, is derived (c), according to him, partly from the anterior pyramidal, and part-
ly from the olivary body (^d). It appears to me to be nothing more than the above-men-
tioned loop formed by the superior peduncles of the cerebellum, below the tubercula
quadrigemina.
The tubercula quadrigemina themselves seem to me to be rather of a laminated than
of a fasciculated structure. Mayo represents them as having a fasciculated texture.
The triangular lateral fasciculus of the isthmus (A, fig. 272) passes in one direction be
tween the upper and middle strata of the isthmus, and in another it may be traced (form-
ing the other part of the bundle h, fig. 274) downward as far a^s the olivary body. The
anterior fibres extend from the testis {g) to the corpus geniculatum internum (»), pass
beneath that body, and penetrate into the interior of the optic thalamus. This triangu-
lar fasciculus forms a layer upon the superior peduncle of the cerebellum, from which it
is perfectly distinct.
Sections of the Isthmus of the EncephaJon.
A vertical section made from before backward through the median line of the istnmus
will give an excellent view of its three portions or strata : the section should include the
medulla oblongata (see fig. 274). Upon it are seen the white and gray striated mass
(m b' m) which constitutes the pons, the re-enforcing fasciculus (/) of the medulla oblon-
gata becoming much thicker opposite the peduncles of the cerebrum than in the pons.
Transverse vertical sections will display the arrangement of the pyramidal bodies and
the re-enforcing fasciculi as they pass from the medulla oblongata into the isthmus. In
these sections a thick bundle belonging to the fifth nerve is always seen.
Sections of the tubercula quadrigemina show that they are neither distinct from each
other, nor from the external and internal corpora geniculata, nor from the re-enforcing
fasciculi of the medulla oblongata ; but that these latter fasciculi and the tubercula qua-
drigemina form a single system, surmounted by masses of nervous matter, which are
the tubercles themselves.
* IThey here constitute the so-called integumentum (c,fig. 269, A) : the black snbstance is called the locut
tiger (6), and the suj^rficial part of the peduncle is named the crust or basis (o).]
THE CEREBELLUM. 715
Development of the Isthmus Encephah.
The development of the pons and of the peduncles of the cerebellum is in relation
with that of the cerebellum ; and the development of the cerebral peduncles with that of
the cerebrum.
In the embryo of two months, the tubercula quadrigemina consist merely of two lam-
inae, which curve upward and outward, and become united at the end of the third month.
At this period the tubercula quadrigemina of the human subject are in the same con-
dition as those of the lower animals. They are as yet, indeed, only two in number, one
on each side of the middle line ; and they are hollow, as in birds. At first they are com-
pletely exposed, but are gradually covered by the hemispheres of the cerebrum, as those
parts are prolonged backward.
The transverse groove which divides the hitherto single pair of tubercles into an an
terior and a posterior tubercle on each side does not appear until about the sixth month,
at which time the cavity in their interior has been obliterated by the thickening of their
■parietes.*
Comparative Anatomy of the Isthmus.
The pons Varolii and middle peduncles of the cerebellum exist only in the human subject
and in mammalia generally ; these structures, which may be regarded as forming the com-
missure of the cerebellum, are developed exactly in proportion to the size of the lateral
lobes of that orgem ; so that they attain their utmost development in the human subject,
and are smallest in rodentia. The pons and cerebellar peduncles do not exist in the re-
maining three classes of vertebrata (birds, reptiles, and fishes), because those animals
have no lateral lobes of the cerebellum.
The tubercula quadrigemina are less developed in man than in the lower animals. It
may even be said that the development of these tubercles is inversely in proportion to
that of the lateral lobes of the cerebellum and the hemispheres of the cerebrum.
The anterior tubercles are a little larger than the posterior in the human subject : in
the ruminants, solipeds, and rodentia, on the contrary, the anterior tubercles are twice
or three times as large as the posterior. In the carnivora the posterior are somewhat
larger than the anterior.
They are covered by the cerebrum in the human subject and the highest orders of
manomalia, but are in a great measure exposed in the rodentia and cheiroptera.
In birds, reptiles, and fishes, the tubercles are only two in number (the tubercula bige-
mina), and attain their maximum development : sometimes they are even larger than
the cerebral hemispheres ; they are hollow, and form true lobes, which are called the
optic lobes, because, in fact, the optic nerves arise exclusively from them.
In birds, the optic lobes are situated at each side of the base of the cerebrum. The
optic lobes of birds are not the thalami optici, as was at first believed : in this class of
animals the optic thalami are thrown forward.
In reptiles, the tubercula quadrigemina consist, as in birds, of two large, ovoid, and
contiguous lobes.
In fishes, it is extremely difficult to determine what are the tubercula quadrigemina ;
so much so, indeed, that the lobes of which they are composed have been taken some-
times for the cerebral hemispheres, and sometimes for the optic thalami. M. Arsaky
(De Piscium Cerebro) has successfully refuted both of these errors.
THE CEREBELLUM.
General Description. — External Characters and Conformation — Furrows, Lobules," Lamina,
and Lamellce. — Internal Conformation — the Fourth Ventricle, its Fibrous Layers, its In-
ferior Orifice, and its Choroid Plexus. — Sections of the Cerebellum, Vertical and Horizon-
tal.— Examination by Means of Water, and of the Hardened Cerebellum. — General View
of the Organ. — Development. — Comparative Anatomy.
The cerebellum {TrapEyKe<j>alic, Aristotle, 1 1, fig. 276 ; h h, fig. 280), or little brain, is
that part of the encephalon which occupies the right and left inferior occipital fossae. It
exists in all animals which have a cerebrum and spinal cord, and, therefore, in all the
vertebrata.
Cases of congenital absence of the cerebellum are extremely rare.t
Though for a long time neglected, the anatomical examination of the cerebellum was
commenced with considerable talent by Petit, of Namur {Lcttre d'un Medecin des Hopi-
tava du Roi, Namur, 1710), and Malacarne {Encephalotomia nuova Universale, Torino,
1780). Vicq d'Azyr and Chaussier have described its external conformation with ex-
traordinary accuracy ; and Reil, Gall, and Rolando, have more particularly investigated
its structure.
* In a fetus of seven months, I found the tubercula qnadrig-emina not yet divided into the nates and testes,
t Vide Anat. Pathol., avec fi^., for a case of absence of the cerebellum.
#f§ NEUROLOGY.
The External Characters and Conformation of the Cerebellutn.
Situation. — The cerebellum is enclosed between the inferior occipital fossae and the
process of the dura mater, called the tentorium cerebelli. It is placed {see fig. 282) at
the top of and behind the spinal cord, and the isthmus of the encephalon. It is covered
by the cerebrum in the human subject only, whence the name cerebrum inferius. It is
posterior to the brain in the lower animals, and is therefore called cerebrum posterius.
The dura mater, the arachnoid, and the pia mater form a threefold investment around
it, the arrangement of which has been already described.
Size and Weight. — The cerebellum is larger in man than in any other species. It has
been stated by Cuvier, that its size in the human subject is so exactly proportioned to
that of the brain, that correct tables may be formed of their relative weights ; but it ap-
pears to me that facts are opposed to this view.
The mean weight of the cerebellum, including the pons Varolii and medulla oblongata,
is from four to five ounces ; the proportion between the cerebrum and cerebellum may
be estimated approximately to be as 7 to I.*
According to Gall and Cuvier, the cerebellum of the female is proportionally larger
than that of the male. Gall believes that its size is in a direct ratio with the energy of
the generative function, and that this is indicated externally by the relative size of the
inferior occipital protuberances.!
The cerebellum is proportionally much smaller in the infant than in the adult ; the
relation between the cerebrum and cerebellum in the infant is as 20 to 1.
Density. — The consistence of the cerebellum has been much studied by anatomists,
who are far from being agreed upon this subject. The great difficulty depends upon the
■want of accurate means of estimating its consistence. In fact, it may be readily con-
ceived that the conversion of its substance into a pulp, by letting weights fall upon it
from a determinate height, is at once a most inconclusive and almost inapplicable meth-
od of ascertaining the point. Another source of difficulty consists in the fact that the
cerebellum is not homogeneous ; so that results obtained in reference to the gray matter
do not apply to the white substance. Out of fifty cerebella which Malacarne compared
•with the corresponding brains, twenty-three were softer than the brains in both the me-
dullary and cortical substances ; in thirteen the cortical substance was equally firm, but
the medullary substance more consistent and elastic than that of the brain ; ten were
more dense in texture, and the remaining five were much harder than the corresponding
brains. In some cerebella one of the hemispheres was much more firm than the other.
The results of my observations are, that the medullary centre of the cerebellum is of
a firmer consistence than that of the cerebrum ; that the gray substance of the cerebel-
lum is softer than that of the cerebrum; and that the gray substance of the former be-
comes softened in the dead body with such extreme rapidity, that it is difficult to meet
with a cerebellum in which this substance is in the normal state.
Form. — The general outline of the cerebellum is that of an ellipsoid flattened from
above downward ; its long diameter is transverse, and measures from three and a half
to four inches ; its antero-posterior diameter is from two to two and a half inches, and
its vertical diameter two inches in the thickest part, and about six lines in the thinnest
part, that is, at its circumference. The figure of the cerebellum may also be compared
to that of a heart on playing cards, the notch of which is directed backward, and the
truncated apex forward ; or, rather, as was done by the old anatomists, to two flattened
spheroids, united together at their points of contact.
The cerebellum is perfectly symmetrical, but yet a marked difference between the
right and left half of this organ is not unfrequently observed.}
The cerebellum presents for our consideration an upper and a lower surface, and a
circumference.
The upper surface {h h, fig. 280) presents along the median line an antero-posterior em-
inence (d), which is rather prominent in front, but gradually disappears as it extends
backward : it is named the superior vermiform process {vermis superior). This eminence,
which covers the valve of Vieussens and the tubercula quadrigemina, should be regard-
ed, as Malacarne states, as the upper part of the median lobe of the cerebellum.
On each side {h h) the upper surface of the cerebellum forms an inclined plane. This
surface is separated from the posterior lobe of the cerebrum by the tentorium cerebelli.
* Chaassier says, " In a considerable number of comparative experiments, we sometimes found that the adult
cerebellum was -^th or ^th, and at other times, but rarely, -pn th or -ryth the weight of the cerebrum. In the
infant, at birth, we found it to be yV*-^' tV*^' PT*''' "^V^'' ^'^i ""''' '" °"® '^*'^» *^®" 3 S*^ '^^ ^"^'^^ weight
of the brain." — {De VEncephale,^.71.)
+ In my opinion, this idea can only be regarded as an ingenious hypothesis. The aptitude for the generative
act is not dependant upon the cerebellum, for all invertebrate animals are destitute of this organ ; and in cer-
tain vertebrata, where the generative orgasm is quite remarkable, the cerebellum is extremely small. Some
observations, however, are quoted, which appear to show that diminution of the occipital protuberance ha»
followed extirpation of the corresponding testicle : but it must first be proved that these observations are cor
red ; for example, that the inequality of the occipital protuberances did not exist previously to the castration,
t In four cases which have come under my own observation, atrophy of the right hemisphere of the cerebrum
coexisted with atrophy of the left hemisphere of the cerebellum ; I am, therefore, led to conclude that there
ve certain intimate relations between the opposite hemispheres of these two portions of the encephalon.
THE FURROWS, LOBULES, ETC., OF THE CEREBELLUM. 717
The lower surface of the cerebellum {figs. 275, 276) is received into the concavity oi
the occipital fossae, to which it is exactly fitted: it is divided into. two rounded, lateral
halves {h, fig. 275), the lobes of the cerebellum, by an antero-posterior fissure (a to n),
the great median fissure of the cerebellum (vallecula, Haller).
The back part of the cerebellum is completely subdivided by this fissure {see fig. 282),
which receives the falx cerebelli ; in front, the fissure opens into a wide furrow, into
which the medulla oblongata is received {see fig. 276) ; in the middle of the fissure is a
lozenge-shaped interval, at the bottom of which is seen the base of a pyramidal emi-
nence {a h c, fig. 275), divided transversely pig. 275.
into rings like a silkworm, and n£imed, ac-
cordingly, by the older anatomists, the in-
ferior vermiform process {vermis inferior, 'pyr-
amid, of Malacarne). This eminence is de-
veloped into four prolongations or branch-
es, arranged in the form of a cross ; the
posterior prolongation (c) is tapering, an(:
occupies the back part of the great median
fissure ; the two lateral processes dip (on
each side of h) into the adjacent portion of
the fourth ventricle ; and the anterior (i)
tapers from behind forward, and terminates
in a mammillary enlargement (a), which is
free, and projects into the fourth ventricle. It has been unnecessarily distinguished from
the rest of the inferior vermiform process by Malacarne and Chaussier, under the name
of the laminated tubercle of the fourth ventricle {tubercle lamineux du quatrieme ventricule).*
The inferior vermiform process is merely the lower part of the median lobe of the cere-
bellum, of which the superior vermis constitutes the upper part. The superior vermis is
continuous, without any line of demarcation, with the two hemispheres of the cerebel-
lum, so that the upper part of that organ appears undivided. The inferior vermis, which
seems at first sight to be intended to separate the two hemispheres, nevertheless forms
the means of connexion between them, as may be easily seen by drawing them apart
from each other.
The circumference of the cerebellum is somewhat elliptical, or, rather, resembles the
heart upon playing cards ; behind and in the middle line it presents a notch (n), between
the convex margins of which a triangular interval is left, into which the falx cerebelli
and the internal occipital crest are received. At the bottom of this notch the surface
of the cerebellum is transversely grooved ; this part unites the superior to the inferior
vermiform process, and belongs to the median lobe of the cerebellum.
The rounded margins of the 7iotch are continuous with the circumference of the cere-
bellum. In front, the circumference of the cerebellum appears to be formed by the pons
Varolii {d,fig. 276) and middle cerebellar peduncles (m), which are in relation with the
posterior surface of the petrous portion of the temporal bones, and are therefore straight,
and form a truncated angle, which projects forward, and corresponds to the pons Varolii.
All the bundles of fibres which connect the cerebellum with the cerebrum and spinsd
cord enter at the anterior part of its circumference : thus, besides the middle peduncles
of the cerebellum, we find in this situation its superior peduncles (r, fig. 272), or pro-
cessus ad testes, and its inferior peduncles (cut at n), or processus ad medullam oblongatam,
to which we shall presently return.
The Furrows, Lobules, Laminae, and Lamellce of the Cerebellum.
The whole surface of the cerebellum is traversed by curved lines or furrows, which
are, for the most part, concentric and horizontal, but not very regular.
These furrows are not parallel, but are inflected towards each other, and intersect at
very acute angles.
They may be divided into four sets, according to their depth. The first set of furrows
are the deepest : they reach as far as the central nucleus, and divide the cerebellum into
segments or lobules {g, h, I, fig. 275). omj
These segments are divided into secondary segments by the second set of furrows.
The secondary segments are again subdivided into lamiruB or folia, and these lamina
into lamella, by two sets of yet smaller furrows.
Pourfour du Petit, Malacarne, and Chaussier have studied the sepnents, laminae, and
lamellae of the cerebellum with great care, and have even counted them. The differen-
ces in their results! are not so much a proof of varieties in the structure of the organ
as of the want of some uniform method of enumeration.
* [The inferior vermiform process is usually described as consisting of three portions : the pyramid (.c,fig.
275), the uvula (6), and the nodulus (o).]
t Winslow admitted 3 lobules, Collins 6, Ponrfour du Petit 15, Malacarne 11, and Chaussier 16. Chaus-
sier counted 60 laminae, and from 600 to 700 lamellae ; Malacarne had previously counted from 700 to 800 la-
mellae. It is a very curious fact that Malacarne only found 324 lamells in an individual labouring under
mental alienation
718 NEUROLOOV
The segments which occupy the circumference of the organ are the largest : they rep-
resent segments of an ellipsoid, and are very broad in the middle, and narrowed at each
extremity. The segments of the upper surface are concentric, and their curvature cor-
responds to that of the entire cerebellum. The segments of the lower surface are also
concentric in each half or lobe of the cerebellum, but the curves of one side are inde-
pendent of those of the other.
The laminae or folia of the cerebellum are applied to each other like the leaves of a
book ; they are separated from each other in their whole length, and are attached to the
rest of the cerebellum by their adherent borders only. The lamellae, however, are ar-
ranged in a different manner, for they pass from one lamina to another, and even from
segment to segment. In fact, if the segments of the cerebellum be drawn asunder, the
furrows between them are seen to be traversed obliquely by a great number of lamellae,
which extend from one segment to another.
The arrangement of the segments, laminae, and lamellae in the median line deserves
particular attention. Opposite the superior vermiform process, they are not interrupted,
but are merely bent slightly, so that the middle portion of each of the anterior segments
is, as it were, drawn forward, so as to describe a curve, having its concavity turned
backward. Upon this surface some slight peculiarities are observed in the arrangement
of the parts. Along the median line there seems, indeed, to be an interchange of lam-
inae and lamellae, some of each of which become thin, and end in points, from which oth-
ers appear to originate.
Opposite the inferior vermiform process the two hemispheres of the cerebellum are
connected together by means of the latercd prolongations of that process. But in front,
i. c, opposite the medulla oblongata, the two hemispheres of the cerebellum are perfect-
ly distinct from each other (see Jig. 275). From these facts we may estimate to what
extent the comparison is correct which was drawn by HaUer between the superior ver-
miform process and the corpus callosum.
At the back part of the cerebellum, opposite the notch in that situation, the two hem-
ispheres are connected by means of certain small transverse rings, of which we have
already spoken.
The superior and inferior vermiform processes and the portion situated at the bottom
of the notch constitute together the middle lobe of the cerebellum, which Gall and Spurz-
heim named the primitive or fundamental part of the cerebellum, because it exists in all
vertebrata, and because, in a great number of them (as in birds, reptiles, and fishes),
where the lateral lobes of this organ are altogether wanting, it constitutes the entire
cerebellum. It is well to add, that the lateral lobes are relatively larger, and the medi-
an lobe smaller in man than in other mammalia.
A rudimentary median lobe, and very large lateral lobes, are the characteristics of the
human cerebellum, while a very large median lobe, and rudimentary lateral lobes, form
the characters of the cerebellum of the lower animals.
All the segments of the cerebellum, of which there are from ten to twelve, might with
propriety be distinguished by particular names. The following segments, however, re-
quire special mention : the segment or lobule of the circumference {I, fig. 275), which is the
largest ; the lobules of the medulla oblongata (lobuli medullae oblongatae), which are situa-
ted behind that part (see fig. 276), are concave on their internal surface, which is accu-
rately adapted to the medulla, and convex on their external and posterior surface, which
dips slightly into the foramen magnum. These lobules (removed from f,fig. 275), which
have been noticed by all qnatomists, are separated from one another by the inferior vermi-
form process (the uvula, b), and each of them terminates in front and on the inner side by a
mammillated extremity (called the amygdala or tonsil), which partially fills up the fourth
ventricle. The other inferior segments of each lobe of the cerebellum describe concen-
tric curves around this segment. The lobule of the pneumogastric nerve (rf) is a sort of
prominent tuft (flocculus), situated (w, fig. 276) behind the pneumogastric nerve (8), and
below the facial and auditory nerves (7).
The Internal Structure of the Cerebellum.
It is convenient to include under this head the description of the fourth ventricle, as
well as that of the substance of the cerebellum.
The Fourth Ventricle.
Dissection. — Divide the median lobe of the cerebellum vertically ; make a vertical
section of the pons along the median line ; draw asunder the medulla oblongata from
the cerebellum. By means of the first section the anterior wall of the fourth ventricle is
exposed, and by the second its posterior wall ; by drawing apart the medulla oblongata
and cerebellum, the ventricle is reached by its inferior extremity, and its whole depth
can be seen. It is important to examine the fourth ventricle in all its aspects.
The fourth ventricle {c to y, fig. 282) is that rhomboidal cavity situated between the
medulla oblongata and isthmus of the encephalon (? n), which forms its anterior wall,
and the cerebellum (w), which constitutes its posterior wall. The old anatomists follow-
THE FOURTH VENTRICLE. 719
ea Galen m calling it the ventricle of the cerehellum. Tiedemann speaks of it as the first
ventricle, because it is developed before the other ventricles, and is constant in all mam-
malia.
The fourth ventricle terminates in a point below, expands considerably in the middle,
and is again contracted at its upper part, where it becomes continuous with the third
ventricle.
. We shall consider separately its anterior and posterior walls.
The anterior or inferior wall is formed by the posterior surface of the medulla oblonga-
gata (see^. 271) and that part of the upper surface of the isthmus of the encephalon
which corresponds to the pons. In shape it resembles a lozenge or diamond, truncated
at its upper point ; the upper borders of the lozenge being represented by the superior
peduncles of the cerebellum (r to g), and the lower by the restiform bodies (e) : the poste-
rior surface of the re-enforcing fasciculi {faisceaux innomines) of the medulla oblongata
constitutes this anterior wall, which is lined by a dense and easily separable membrane.
The 'posterior or superior wall represents a vaulted roof, which is formed above by the
superior peduncles of the cerebellum (r to g) and the valve of Vieussens {l, fig. 271 ; I,
fig, 275 ; g w, fig. 282), lower down by the cerebellum (w), and below by a fibrous mem-
brane, continuous with the neurilemma of the spinal cord.
Opposite the middle, i. e., the broadest part of this posterior wall (see_^. 275), are sit-
uated three mammillary projections — one median and two lateral : the first (b, the uatu-
la) is the anterior segment of the median lobe of the cerebellum ; the other two (the
amygdcdae) are formed by the innermost laminae of the lobule of the medulla oblongata
(cut away at/). These latter are not bathed in the fluid of the ventricle, but are sep-
arated from it by the fibrous membrane lining that cavity.
The median mammillary projection (6), named by Malacarne and Chaussier the lami-
nated tubercle of the fourth ventricle, resembles a movable valve. It is attached to the
cerebellum by two white pedicles, which pass outward and backward upon the lateral
processes of the crucial eminence formed by the inferior vermis. Connected to its an-
terior extremity (the nodulus, a) are seen two broad folds {semilunar folds, e), which arise
from it, one on each side, and become continuous with the roots of the corresponding
sub-peduncular lobules or flocculi {d).
These folds, which are quite distinct from the valvulse Tarini, are extremely thin and
semi-transparent ; their convex borders adhere to the back part of the fourth ventricle ;
the concave margins and their two surfaces are free.* The two semilunar folds and
the intermediate projection, or the nodule, may be compared to the soft palate, the mam-
millary projection representing the uvula, t
Opposite the upper angle of its rhomboidal cavity, the fourth ventricle {v, fig. 282) be-
comes continuous with the third (Z), through a canal, named iter a tertio ad quartum ven-
triculum, or the aqueduct of Sylvius, which, however, had been described by Galen : this
aqueduct is formed beneath the tubercula quadrigemina {f g) and the valve of.Vieus-
sens {g w).
The lateral angles of the fourth ventricle are much elongated, and reach as far as op-
posite the inner extremity of the corpus dentatum of the cerebellum.
At the inferior angle (y) of the fourth ventricle is situated a fibrous layer, which con-
stitutes its floor, and also an orifice of communication between the ventricle and the
sub-arachnoid space.
The Fibrous Layers of the Fourth Ventricle.
Floor of the Fourth Ventricle. — On carefully drawing the medulla oblongata away from
the cerebellum, a fibrous layer is seen extending from one to the other, and forming, as
it were, the floor of the fourth ventricle. This layer, which is continuous with the neu-
rilemma of the medulla oblongata, consists of three very distinct parts : of a median
portion, shaped like a triangular tongue, which passes horizontally backward, and is ap-
pUed to the anterior extremity of the inferior vermis, to which it adheres ; and of two
triangular lateral portions, which form the sides of the orifice of the fourth ventricle, and
which were described by Tarin as the valves of the base of the fourth ventricle.
Besides this fibrous layer, there is another on each side, situated behind the roots of
the pneumogastric nerve : these layers adhere to those roots, and we shall therefore
name them the fibrous layers of the pneumogastric nerves ; they close the fourth ventricle
upon the sides of the medulla oblongata, and when they are removed the ventricle is
quite open. They extend from the restiform bodies to the lobules of the pneumogastric
nerves, and are prolonged upward upon the auditory nerves.
The Inferior Orifice of the Fourth Ventricle.
If the medulla oblongata and cerebellum be drawn apart, there is seen in the median
* [These two folds constitute the posterior medullary velum of the cerebellum, the valve of Vieussens form-
ing the anterior velum.]
t [The terms uvv.la and amygdalie, or tonsils, have, as already noticed, been applied to another series ot
three bodies which are arranged behind the nodule, the flocculi and the posterior vela, and consist of the lam-
inated tubercle of the fourth ventricle, and of the inner portions of the lobes of the medulla oblongata (see p.
718).] • s{ vj' »»i»<»««>n»^-"iTiv r- - -■
71^ NEUROLOGY.
line, between the inferior cerebellar arteries, a lozenge-shaped opening (at y, fig. 282),
bounded, in front, by the base of the calamus scriptorius ; behind, by the anterior pro-
longation of the inferior vermiform process, which is covered by the median tongue of
the fibrous layer ; and upon the sides, in front, by the ragged edges of the lateral por-
tions of the fibrous layer, and by the internal surfaces of the lobules of the medulla ob-
longata.
This opening was pointed out by M. Magendie as establishing a communication be-
tween the general ventricular cavity and the sub-arachnoid space. It has been asked,
Is it a natural opening, or is it produced accidentally by the very means employed in its
demonstration 1 The following are the arguments on both sides of the question :
In opposition to the existence of an opening in this situation, it is urged that the mar-
gin of the orifice has none of the characters of that of a natural opening, the edges of
which are generally smooth and rounded ; but in this orifice they are lacerated, and there
is almost always some membranous shreds at the point of the calamus scriptorius. If
the median triangular tongue of the fibrous layer, which is applied to the inferior vermis,
be detached, it is seen to be merely a flap of that membrane, the size of which exactly
corresponds to that of the opening, so as to close it completely. This point may be ren-
dered still more evident by tracing the membrane from before backward, after having di-
vided the pons and medulla oblongata.
Again, the fibrous layer, which forms the floor of the fourth ventricle, is entire in the
dog and sheep ; I have found it in the same condition five or six times in the human
subject ; and if it be objected that, in this case, there might have been an accidental ob-
literation of the opening, I could answer that there was no trace of disease, either in the
cerebro-spinal axis, or in the membranes.
I may also mention that, in several cases of chronic hydrocephalus, several pounds ol
fluid were found in the ventricles, and none whatever in the sub-arachnoid space.
Lastly, in the brains of several infants, who had died with all the symptoms of acute
ventricular hydrocephalus, I have found the lateral ventricles very large, but empty ; and
in these cases, it has occurred to me that the fibrous layer might have been perforated
opposite the inferior angle of the fourth ventricle, and have thus allowed the fluid to
escape, which, in the greater number of cases, is retained by this layer within the ven-
tricular cavity.
Such are the facts which appear to me to militate against the idea of the existence of
an opening in the floor of the fourth ventricle ; but, on the other hand, if we consider
that, in an immense majority of instances, whatever care may be taken in removing the
brain from the cranium, we always find this opening both in the foetus and in the adult ;
that in apoplectic effusions into the ventricles, we always find some bloody serum in the
sub-arachnoid space ; and that if a coloured fluid be injected into the ventricles of the
cerebrum, or into the sub-arachnoid space around the cord, it will in either case pass
freely /rom one into the other, we shall be led to conclude that there is a regular com-
munication between the cavity of the ventricles and the sub-arachnoid space, and that
the orifice just described is the channel of communication between them.*
The Choroid Plexuses of the Fourth Ventricle.
The choroid ■plexuses of the fourth ventricle are two in number ; they commence one on
each side, by a very slender extremity, upon the anterior surface of the sort of fibrous
tongue which is attached to the inferior vermis ; from this point they pass in a diver-
ging course upward, are then inclined outward, turn round the sides of the median emi-
nence of the fourth ventricle, pass horizontally outward behind the restiform bodies, and
then behind the fibrous layer of the corresponding pneumogastric nerve, where they be-
come considerably enlarged, and at length terminate upon the sub-peduncular lobes.
The inner surface of the fourth ventricle is smooth, in consequence of being lined by
a membrane resembling a serous membrane, which is much stronger over the posterior
surface of the medulla oblongata than at any other point.
Sections of the Cerebellum.
On cutting through the cerebellum, it is found to be composed (see figs. 273, 274) of
two substances, an external cortical or gray substance, and a central or medullary substance,
which is white ; the gray substance is soft, and is almost always torn off with the mem-
branes, however slightly the cerebellum may be altered by decomposition. The white
substance is compact, and resists a tolerably firm pressure.!
Between the gray and white substances there is seen, upon a section of the cerebellum,
a narrow yellowish band or streak, which depends on the existence of a layer of a yellow
substance, of much greater firmness than the gray matter, and strongly adherent to the
white substance. By laceration the gray matter is destroyed, and this yellow layer is
exposed. There are, therefore, three substances in the cerebellum : the gray, the yellow,
' See note on the sub- arachnoid space (p. 690).
t For an account of the minute structure of these substances, see note, p. 701.
SECTIONS OF THE CEREBELLUM. 781
and the white. I would compare the yellow layer of the cerebellum to the yellow folded
membrane of the olivary bodies.*
A question liere arises, What is the proportion between the gray and the white mat-
ter ? The most superficial examination of the cerebellum will show that the gray mat-
ter predominates ; and this can be clearly demonstrated by macerating the cerebellum
for several days. The gray matter, which is more easily decomposed, becomes con-
verted into a pulp, and the remaining nucleus of white substance scarcely represents a
third, eitlier of the weight or bulk of the cerebellum.
We shall now proceed to describe the appearance of vertical and horizontal sections
of the cerebellum.
Vertical Sections.
Upon longitudinal vertical sections of the cerebellum, the gray and white substances
present a very elegant arrangement, known by the picturesque name of the arbor vita ;
a title derived either from the importance which has been attached to this structure, or
from its resemblance in figure to the foliage of the tree so called. Upon a section maule
through the median line, the arbor vita of the middle lobe {w, fig. 282) is seen ; and upon
one made on either side, the arhor vita of the lateral lobes.
The arbor vita of the median lobe consists of a central nucleus of white substance, of a
triangular form, from which two principal branches proceed : one inferior, which is dis-
tributed to the whole of the inferior vermis and the back part of the median lobe ; the
' other superior, which passes into the whole of the superior vermis. These two branches
subdivide into six others, which vary in direction, length, and thickness, and are them-
selves subdivided into still smaller branches, and these, again, into the smallest ramifica-
tions. A slight enlargement of the white substance is always observed opposite the
points of division.
A very thin yellowish layer, and outside this a layer of gray matter, about a line in
thickness, covers each of the ramifications of the white substance, and thus forms the
lamellie, laminae, and segments of the median lobe.
This section enables us to prove the existence of the middle lobe of the cerebellum
and the continuity of the superior and inferior vermis ; it also shows the general form
of the middle lobe, which is rotate or wheel-shaped (the anterior extremity of the in-
ferior vermis, i. e., the nodule, comes into contact with the valve of Vieussens) ; the
number and arrangement of the segments, laminae, and lamellae of the cerebellum; and,
lastly, the nature of the valve of Vieussens, which is nothing more than the uppermost
subdivision of the central nucleus, and may be regarded as one half of a lamella of the
cerebellum.
The Arbor Vita of the Lateral Lobes. — A vertical section from the middle peduncles of
the cerebellum towards the circumference displays the arbor vitae of the lateral lobes.
In the centre of each lobe is seen a white central nucleus, from which fifteen or six-
teen principal branches are given off, to form the nuclei of a corresponding number of
the segments. These branches are subdivided into secondary branches, and those into
the ultimate ramifications. A yellowish layer covers each of these successive divisions,
and upon that a gray layer, about a line in thickness, is accurately moulded.
Upon sections of this kind it is easily seen that the segments of the cerebellum are
very unequal in size, in direction, and in their manner of division ; that the superior
segments are the smallest, the segments of the circumference the largest,! and the in-
ferior segments of an intermediate size ; that there is no vacant space between the seg-
ments, but that both laminae and lamellae occupy the intervals ; and, lastly, that all of
these segments curve forward upon themselves, so as to form a series of horizontal
wheels or circles, the plane of which is at right angles to that of the wheel-shaped
mass of the middle lobe.
In the centre of the white nucleus of each half of the cerebellum is the corpus rhom-
boideum, or corpus dentalum :% these bodies are of an ovoid form ; their yellowish invest-
ing layer is dense, and folded backward and forward upon itself, and exactly resembles
that of the olivary bodies ; and I have been accustomed to speak of these bodies as the
olivary bodies of the cerebellum. Gall and Spurzheim regarded them as ganglions of
re-enforcement, and called them tlie ganglions of the cerebellum. Their shortest or verti-
cal diameter is about one third of their long or horizontal diameter ; in one case, where
the latter was fifteen lines, the former was five lines : moreover, the size of the corpora
dentata of the cerebellum varies in different subjects, and is in proportion to the size of
* Rolando ( Ossemazioni suV Cervetetto, p. 187, 1823) appears to me to have been the first to establish the fact
of the existence of three substances : the medoHare, the cinereo rossigna, and the cinerea esterna e corticate.
t The segment of the circumference, which is the largest of all, immediately divides into two smaller seg-
ments ; it has liecu iucorrecUy stated that there is a horizontal fissure along the circumference of the cere-
bellum, extending from one of the middle peduncles to the other.
t In order to divide the corpus dentatum, the section must be made opposite the corresponding inferior pe-
duncle (if the cerebellum. I would recommend that one section be made to extend through the corpus denta-
lum of the cerebellum, and also through the olivary body, so that some idea may be formed of the analogy be-
tween these two |>arts.
4Y
NEUROLOGY.
the lateral lobes of that organ : they are, therefore, much less developed in the lower
animals than in man.
The peduncles of the cerebellum are six in number, three on each side, namely, a supe-
rior, a middle, and an inferior ; they all originate, or, it may be said, terminate in the cen-
tral nucleus.
The superior peduncles of the cerebellum are generally known as the processus cerebelli
ad testes ; ttiey are seen (r, fg. 280) in front of the superior vermiform process, and seem
to pass up to the tubercula quadrigemina. We shall afterward see that this is only ap-
parent.
The inferior peduncles (processus cerebelli ad medullam oblongatam) are, in fact, the resti-
form bodies ; they establish a direct and intimate communication between the cerebel-
lirni and the spinal cord.
Lastly, the middle peduncles {m, fig. 276), which are anterior to the two preceding sets,
occupy the fore part of the circumference of the cerebellum, and are continued into the
pons Varolii without any line of demarcation. They are called also the cerebellar pedun-
dea {processus cerebelli ad potitem), and the crura or legs of the medulla oblongata.
Horizontal Sections.
Horizontal sections of the cerebellum have been studied with very great care, and have
been well figured by Vicq d'Azyr ; they show that the dimensions of the central nucleus
are much greater in the horizontal than in the vertical direction.*
Upon these sections, which should be made parallel to the upper surface of the cere-
bellum, is seen the relative disposition of the laminae, which are sometimes parallel and
sometimes oblique in reference to each other, and which either extend around the entire
circumference of the organ, or terminate in tapering extremities and again commence,
and pass from one segment to another.
Lastly, these horizontal sections show the continuity of the right and left lobes of the
cerebellum by means of the middle lobe. In this middle lobe the lamellae are more ir-
regular than in the lateral lobes ; they intersect each other at various angles, and be-
come again united into new combinations, so that several anatomists have admitted the
existence of a true decussation in this middle portion of the cerebellum.
The middle lobe also has its medullary centre, which connects the lateral medullary
centre in such a manner that, by a successful section, a sort of cerebellar centrum ovale
is obtained, analogous to the centrum ovale of Vieussens in the cerebrum.
Examination of the Cerebellum by means of a Stream of Water, and Dissec-
tion of the Hardened Cerebellum.
A stream of water directed upon vertical sections of the cerebellum decomposes the
white nucleus of each lateral lobe into a great number of extremely thin leaves, which
constitute the different laminae or lamellae of the cerebellum. All these laminae and la-
mellae terminate in the central nucleus of the corresponding lobe. Each lamella is fan-
shaped, its adherent border being very narrow, concave, and applied io the central nu-
cleus, with which it is evidently continuous, while its convex margin corresponds to the
surface of the cerebellum. The arrangement of these lamellae is very beautiful and cu-
rious : some of them ascend to form the segments, lamina, and lamellae of the upper
surface of the cerebellum ; others descend to form the corresponding parts of the lower
surface, and the intermediate ones pass horizontally to the circumference, and are dis-
posed in a similar manner. Opposite each point of subdivision there seems to be an en-
largement of the white substance, but this depends not upon an actual increase of that
substance, but upon the divergence of the lamellae.
The structure of the cerebellum, therefore, considered generally, is laminated. From
the central white nucleus proceed innumerable lamina;, which, though in juxtaposition,
are never blended together, and which form groups, that are themselves subdivided again
and again, like the branches of a tree, the ultimate lamella always containing at least
two leaflets. Can anatomy teach us anything beyond this laminated arrangement 1 In
each lamella certain radiated striae are seen ; and it may be asked. Whether these prove
the existence of a linear or fibrous structure 1 It is certainly true that the lamellae may
be divided in the direction of these striae, but it is far from being evident that they con-
sist of linear fibres.
In the central nucleus, the laminae, being more firmly pressed together, are separated
by the stream of water with greater difiiculty than the laminae near the surface : the
corpora dentata of the cerebellum are peculiarly firm. The stream of water insinuates
itself into these bodies opposite their internal extremity, which appears to be naturally
open, and divides them into two halves, a superior and an inferior. It is then seen that
the dentated appearance of their section results from the reduplication of the dense yel-
lowish layer in which they are enclosed ; also, that the white substance penetrates into
the interior of these bodies at their internal surface, accompanied by a great number of
* In each lobe of the cerebellum there is a medullary centre, that is, a spot in which the section of the whit*
substance is larger than at other points.
GENERAL VIEW OF THE CEREBELLUM. 723
vessels ; and that this white substance is arranged in lamellae, which terminate at three
different points of the yellowish layer, so that each of the corpora dentata resembles a
small cerebellum.
Examination of the Hardened Cerebellum. — The examination of the cerebellum, when
hardened by alcohol, or by boiling in oil, or salt and water, or by maceration in a solu-
tion of salt and bichloride of mercury, of the strength recommended by Rolando, confirms
all the results which have been obtained by the preceding method of investigation.
These modes of preparation, moreover, enable us to examine more completely than in
any other way the relations of the central nuclei of the lobes to the peduncles of the cere-
bellum. It is seen most distinctly that these peduncles (m n. Jig. 273 ; n r, fig. 274)
emerge from or terminate in the central nuclei ( p p), but it is very difficult to ascertain
their precise arrangement within the nuclei. All that we know is the fact that, as soon
as they emerge from the central nuclei, they assume a fasciculated character, and that
all the lamellae and laminae of the cerebellum seem to terminate in the fibres of the mid-
dle peduncles.
General View of the Cerebellum.
From the preceding statements we may draw the following conclusions : The cerebel-
lum consists of two lateral lobes and a middle lobe ; the lobes are formed by a consider-
able number of segments, which are subdivided into smaller segments, and these into
laminae and lamellae ; each lobe contains a central medullary nucleus, upon which all the
segments rest, and which constitutes the termination or the origin of the several pedun-
cles ; the substance of these peduncles is fibrous or fasciculated, and that of the central
nucleus has a similar character, but not so well marked ; the medullary substance of
each segment is formed by laminae applied to each other, but not actually continuous ;
each of these laminae is fan-shaped, and those which constitute the central nucleus of
each segment become separated from each other to form the secondary segments, the
laminae, and the lamellae ; the ultimate lamellae of the cerebellum consist of two leaflets
of white matter covered externally by a very thin yellowish layer, which is itself cover-
ed by a rather thick layer of gray matter ;* the corpora dentata, or olivary bodies of the
cerebellum, consist of fibres or laminae of medullary substance, which are spread out so
as to terminate at different points upon the inner surface of the dense yellow membra-
nous layer which constitutes their external investment.
A very ingenious explanation of the structure of the cerebellum has been proposed by
Gall, and is now rather generally adopted.
The opposite directions of the inferior and middle peduncles of the cerebellum sug-
gested to him the idea of diverging and converging fasciculi, and to this he has added his
theory regarding the ganglia, which he considered as apparatuses of re-enforcement, that
is to say, as points of origin for new fasciculi.
According to Gall, then, the inferior peduncles of the cerebellum or the restiform bod-
ies (n,fig. 274), which he calls the primitive fasciculi of the cerebellum, are the roots, or
fasciculi of origin of the cerebellum. After they have penetrated a few lines into the
substance of the organ, they meet with and join the corpus dentatum, which Gall regards
as a true ganglion, or apparatus of origin and re-enforccment for a great part of the nervous
mass of the cerebellum. According to him, a principal nervous fasciculus corresponds to
each of the folds of the corpus dentatum, from which ganglion arise all those prolonga-
tions of medullary substance which, together with the gray matter upon them, consti-
tute the middle and lateral lobes of the cerebellum.
Besides the preceding fasciculi, which are named by Gall the diverging fasciculi, and
are said by him to constitute the formative system of fibres, there are certain converging
fasciculi, which constitute the uniting system of fibres, or the commissures of the cerebellum.
These are supposed to have no direct connexion either with the primitive fasciculi or
the corpus dentatum, but to emanate from the gray matter upon the surface of the cere-
bellum, and to pass in different directions (p q, fig. 273) between the diverging fasciculi,
so as to enter into and constitute the middle peduncles of the cerebellum (m) and the
pons Varolii, which Gall regarded as forming together the commissure of the cerebellum.
The superior peduncles of the cerebellum (?•', fig. 274) he considered as fasciculi o*"
communication between the middle median lobe of the cerebellum and the corpora quad
rigemina, and the valve of Vieussens as the commissure of these peduncles.
We can only regard Gall's view concerning the structure of the cerebellum as an in-
genious speculation. Why should the inferior fasciculi be the roots or primitive bundles
of the cerebellum rather than the superior 1 Who has seen the re-enforcement of these
primitive fasciculi in the corpus dentatum 1 Why should the corpus dentatum be regard-
ed as a ganglion 1 Whence is this distinction between converging and diverging fasci-
culi 1 1 and, finally. Why are figure and metaphor employed in reference to strictly ana-
tomical questions 1
* [The white substance of the laminae is said to consist of two sets of fibres — one coming from the central
mass, and passing up the centre of the laminie, and the other set lying; upon the first, and passing from one
lamina to another.]
* " These converging fibres," says Tiedemann (French translation by Jourdan, p. 169j, " are merely chimer-
724 NEUROLOGY.
Another theory regarding the structure of the cerebellum has been offered by Rolan-
do, who, by combining the results derived from an examination of the human cerebellum,
when hardened in a strong saline solution, with those furnished by the anatomy of the
brain of the shark, and those obtained by studying the development of the brain of the
fowl, was led to regard the human cerebellum as formed by the folding and refolding upon
themselves of the parietes of a large bladder or vesicle, so as to give rise to innumera-
ble laminae.*
The facts we have already stated sufficiently refute this hypothesis. It is quite cer-
tain that the cerebellum is formed by the union of one middle and two lateral lobes : the
lobes themselves are composed of a considerable number of segments, which are subdi-
vided into smaller segments, laminae, and lamellae. The general structure of the cere-
bellum is laminated, and these laminae are striated ; each lamella contains two leaflets
of white substance covered with gray matter. The cerebellum is connected with the
medulla oblongata by the inferior peduncles, and with the brain by the superior pedun-
cles ; the middle peduncles and the transverse fibres pf the pons establish an intimate
connexion between the two lobes of the cerebellum, t
Development of the Cerebellum.
The cerebellum does not appear until some time after the spinal cord : it consists, at
first, of two laminae and plates prolonged from the cord, which approach each other to-
wards the median line ; these are the inferior peduncles of the cerebellum, or the resti-
form bodies. The human cerebellum in this condition has a close resemblance to the
same organ in fishes and reptiles. At the fourth month, the cerebellum forms a sort of
uniform girdle, four lines in width, around the tubercula quadrigemina and the medulla
oblongata ; the pons Varolii is already visible ; there is a rudiment of the corpus denta-
tum, and the surface of the cerebellum is entirely devoid of fissures. At the fifth month
there are four transverse fissures : a vertical section of the cerebellum presents five
branches ; but there are as yet neither laminae nor lamellae, nor is there any distinction
between the middle and lateral parts. At the sixth month, the cerebellum is divided by
the posterior notch, the different orders of fissures are visible, and the corpus dentatum
has acquired considerable size. During the last three months of intra-uterine existence,
the lateral lobes generally acquire that predominance over the middle lobe which is found
to hold after birth.
As the development of the spinal cord precedes that of the cerebellum, and as the cer-
ebellum appears to be formed by a prolongation of the posterior fasciculi of the cord,
does it follow that that organ is a production or an expansion of the cord 1 Certainly
not ; all that we can conclude is, that they are developed in succession.
Reil and Tiefdemann have advanced the opinion that the cerebellum is secreted by the
pia mater, and that the gray matter is deposited the last ; but this is only an assertion
without demonstration.
The cortical substance is formed at the same time as the medullary, and neither of
them can be considered as the product of the other.
Comparative Anatomy of the Cerebellum.
In fishes the cerebellum is generally small, but in the ray and shark it is large, subdi-
vided into convolutions, and prolonged above the optic lobes in front, and above the lobe
of the eighth pair of nerves behind. In the silures, as Weber has observed, the cere-
bellum is relatively as large as the human cerebrum ; for it covers the posterior half of
the cerebral lobes, as the cerebrum in man covers the cerebellum. In all fishes the cer-
ebellum contains a considerable cavity. In some of Ihis class of animals it is subdivi-
ded into segments, laminae, and lamellae.J
Reptiles. — There is no cerebellum in the batrachia (as in the frog, toad) and ophidia
(serpents) ; most anatomists, however, admit its existence in a rudimentary state. It
is very small, and shaped like a roof, or vaulted, in the chelonians (tortoise) ; it is very
long in the saurians (lizard, crocodile).
Birds. — The cerebellum is very large, and represents an ellipsoid, having its long di-
ameter directed vertically. It is deeply and regularly traversed by horizontal fissures,
which are curved downward on the upper half, and upward on the lower half of the or-
ical ; for the pons Varolii, and the meilallary fibres of which it consists, are found in the foetus at the fourth
month, that is, at a period when there are no laminae nor lamells, nor even any leaflets covered with gray mat-
ter. Gall, therefore, assumes these converging- fibres to originate from parts which do not appear until after
those fibres themselves." The refutation of Tiedemami appears to me to be itself founded on an assumption,
for there is no proof that the gray matter is formed after the white.
" Osservazioni sul' Cerveletto, p. 187. In the shark, the cerebellum consists of a gray and a white layer
united together and folded a great number of times upon themselves.
t It is not yet ascertained whether the lateral halves of the cerebellum act upon the same or opposite sides of
the body ; some cases, in which atrophy of one hemisphere of the cerebrum coexisted with atrophy of the op
posite hemisphere of the cerebellum, would appear to show that the action of the latter is not crossed. The
laminated structure of the cerebellum and its twofold composition suggested to Rolando the idea of comparing
it to a voltaic pile, or electro-motive apparatus.
t [It is divided into segments by deep transverse furrows in some cartilaginous fwhe.^.1
THE CEREBRUM. 725
gan. They all tenninate opposite two small tubercles or appendages, situated one at
each extremity of the transverse diameter. Upon a section of the cerebellum of birds
is seen an arbor vitae, composed of white substance covered with gray matter.
Mammalia. — In the three classes already examined, the cerebellum has merely a mid-
dle lobe : in all mammalia there are also lateral lobes. They are at lirst small, like ap-
pendages, as in the rodentia, in which the cerebellum differs but little from that of birds ;
they gradually increase in size as we proceed upward in the scale, until they reach their
highest state of perfection in man, the development of whose cerebrum and cerebellum
exceeds that of the same parts in all the lower animals. In mammalia the size of the
lateral lobes of the cerebellum is directly proportioned to that of the oUvary bodies, the
existence of which in this class Vicq d'Azyr has erroneously denied.
THE CEREBRUM, OR BRAIN PROPER.
Definition — Situation — Size and Weight — General Form. — The Superior or Convex Surface.
— The Inferior Surface or Base — its Median Region, containing the Inter-peduncular Space,
the Corpora Albicantia, the Optic Tracts and Commissure, the Tuber Cinereum, Infundibu-
lum, and Pituitary Body, the Anterior Part of the Floor of the Third Ventricle, the reflected
Part of the Corpus Callosum, the Anterior Part of the Longitudinal Fissure, the Posterior
Part of the Longitudinal Fissure, the Posterior Extremity of the Corpus Callosum 'and Me-
dian Portion of the Transverse Fissure, and the Transverse Fissure. — The Lateral Regions,
including the Fissure of Sylvius and the Lobes of the Brain. — The Convolutions and Anfrac-
tuosities of the Brain, upon its Inner Surface, its Base, and its Convex Surface — Uses of the
Convolutions and Anfractuosities . — The Internal Structure of the Brain — Examination by
Sections — Horizontal Sections showing the Corpus Callosum, the Septum Lucidum, the For-
nix and Corpus Fimbriatum, the Velum Interpositum, the Middle or Third Ventricle, the
Aqueduct of Sylvius, the Pineal Gland, the Lateral Ventricles, their Superior and Inferior
Portions, the Choroid Plexus, and the Lining Membrane and the Fluid of the Ventricles —
Median Vertical Section — Transverse Vertical Sections — Section of Willis. — General Re-
marks on this Method of Examining the Brain. — Methods of Varolius, Vieussens, and
Gall. — Gall and Spurzheim's Views on the Structure of the Brain. — General Idea of the
Brain. — Development. — Comparative Anatomy.
The cerebrum or brain, strictly so called, is that portion of the encephalon which occu-
pies the whole of the cavity of the cranium, except the inferior occipital fossae. It forms,
as it were, the crown or summit of the spinal axis, surmounting it {cerebrum superius),
and, at the same time, lying in front of (cerebrum aiiterius) the spinal cord, as the origin
and termination of which it has been alternately regarded. By the pons Varolii and the
anterior or cerebral peduncles it is intimately connected with the cerebellum and the
spinal cord. The tentorium cerebelli completes the cavity in which it is enclosed, and
separates it from the cerebellum, wljich is situated below its posterior lobes. The cra-
oiiim, the dura mater, the arachnoid, and the pia mater form a fourfold investment for it.
Size and Weight of the Cerebrum.
The great size of the cerebrum is undoubtedly one of the most characteristic points in
the structure of man : in several animals, the entire encephalon is relatively as large,
and even larger {ex., the canary bird, the sapajou, the dolphin) ; but in reference to the
size of the brain properly so called, i. e., of the cerebral hemispheres, even the most fa-
voured animals are much inferior to man.*
In the adult, the weight of the cerebrum, detached from the cerebellum and the pons
by a section through its peduncles, varies from two to three pounds. t I believe it to be
impossible to construct a table of the comparative size and weight of the brain and of the
body. Is it not evident, indeed, that one element in the comparison, namely, the weight
of the body, is subject to great variety 1 Haller has recorded the results of all the cal-
culations which have been made upon this subject, and the diversity of those results is
the best comment that can be made upon this mode of comparison.
These remarks do not apply to the relative proportions between the cerebrum and
• The weight of the cerebrum of the horse and the oi is scarcely half that of the human cerebrum.
t [From the statements given by Tiedemanu (Htm des Negers, <fcc., p. 6, Heidelb., 1837), it appears that
the prevalent vreight of the brain (entire encephalon) in the adult male is about from 44 to 48 oz. troy : in the
adult female, from 40 to 44 oz. The results deducible from Dr. Sims's tables do not materially differ from
the above.
In thirty-nine males, varying in age from 22 to 80, Tiedemann found the minimum weight of the brain 38 oz.
20 gr., the maximum 59J oz.
In eleven females, from 20 to 80 years of age, the minimum was 32 oz. 5 drs. 50 grs., the maiimum 46 oz. 2 drs.
Th»eitremes, according to Dr. Sims's observations, were in about seventy males from 20 to 91 years, lowest,
33 oz. 80 grs. ; highest, 54 "oz. 6 drs., troy weight. In ninety females, between the ages of 20 and 89, the low-
est was 27 oz. 80 grs., the highest 51 oz. 6 drs.]
726 NEUROLOGY.
cerebellum. According to my own observations, the weight of the cerebellum is from
the twelfth to the eighth part of that of the cerebrum.*
It is important to obtain some approximation to the relative size of the brain in differ-
ent individuals in the two sexes, and at different ages.
It results, from a great number of facts, that the size of the brain is independent of the
stature of the individual ; that the size of the brain is also independent of sex, although,
since the time of Aristotle, it has been the custom to repeat that the female brain is
smaller than that of the male ; that in the fcetus and the infant the cerebellum is rela-
tively much larger than the adult ; and that in old age the brain is often atrophied like
other organs, and then does not completely fill the cranial cavity.
Can the size of the brain be increased by exercise, and diminished by inaction 1 It
cannot be doubted that the brain must, in this respect, obey the laws which regulate all
other organs ; but the bony parietes of the cranium must offer great obstruction to its
development ; indeed, examples have been recorded of compression of the brain, and
even of death, produced by hypertrophy of this organ.
If it be true that the power of an organ depends upon its size, it follows that the size
of the brain, and, consequently, the capacity of the cranium, must have a tolerably close
ralation to the development of the cerebral functions ; but the activity of these functions
is connected with so many circumstances besides the size and quantity of brain, that
any estimate of the intellectual powers founded exclusively upon these data is very often
faulty and inexact, t
The Specific gravity of the brain, as compared with that of water, is, according to Mus-
chenbroek, as 1030 to 1000. It would be interesting to determine whether its specific
gravity varies according to age and in disease, and also whether it differs in different
animals. According to Soemmering, the specific gravity of the brain in old persons is
less than in those of middle age.
General Form of the Cei'ehrum,
The form of the cerebrum corresponds exactly to that of the cranial cavity, which is,
as it were, moulded on it ; it is, therefore, variable like that of the cavity itself, which,
during early infancy, is capable of assuming all sorts of shapes from the application of
external pressure.
If the entire cranial cavity, exceping the posterior occipital fossae, be filled with plas-
ter of Paris, an exact representation will be obtained of the general form of the brain
which had been removed. The cerebrum, therefore, is like the cranium of an ovoid fig-
ure, having its large end turned backward, and its small one forward. It is divided on
its under surface into lohes, which occupy the different compartments in the base of the
cranium. The entire surface is marked by deep tortuous furrows (see Jigs. 276, 282),
called anfractuosities, which occasion an appearance like that of the convolutions of the
small intestines, and hence the term convolutions is applied to the eminences resembling
folds, by which the anfractuosities are bounded.
The Superior or Convex Surface of the Brain.
A median vertical fissure running from before backward, called the longitudinal fi^ssure,
divides the cerebrum into two exactly similar lateral halves, which are improperly called
cerebral hemispheres, for each of them resembles the fourth part of an ovoid ; but would
be more correctly designated the right and left brain, as was done by Galen.j The lon-
gitudinal fissure divides the cerebrum in its whole depth, both in front and behind (x y,
fig. 277 ; also fig. 282) ; but in the middle it is interrupted by the corpus callosum {d d).
There are two brains, as there are two spinal cords and two cerebella.^
The cerebrum is therefore symmetrical, but it is less completely so than the spinal cord ;
I should even say that a decided disproportion is very commonly observed between the
right and left hemispheres. It does not appear that this want of symmetry exerts that
influence upon the intellectual faculties which was imagined by the ingenious Bichat,
whose own unsymmetrical brain was in direct contradiction to his doctrine. It is, nev-
ertheless, possible that a want of symmetry, when carried to a certain point, may affect
the intellect ; in the brains of several idiots, their want of symmetry has been very re-
* In three young subjects I found as follows :
lb.
oz.
oz
Cerebrum .
. . 2
2
Cerebellum .
• ^
it
. . 2
8k
"
. 3J
" . .
. . 2
5
"
. 5
+ Persons endowed with strong memories have always appeared to me to have large brains ; and the part
which the memory performs in the exercise of mind is of such a nature that we cannot be surprised if the persons
alluded to are frequently men of superior intellect. I have known many persons, having heads of considera-
ble size, who had merely a good memory, but none of the characteristics of genius. Those in whom tlie braiu
is large seem to me to resist the power of disease better than sucli as have small brains.
} Chaussier applies the terra lobe to the hemispheres, reserving that of lobule for the secondary divisions.
<) Galen inquires why there should be two brains ; and replies, that it is to ensure a more perfect p^form-
*nce of the cerebral functions. I have seen several hemiplegic individuals in whom the whole of one hemi-
sphere was atrophied, but who, notwithstanding, possessed ordinary intellectual faculties.
THE BASE OF THE BRAIN.
727
markable. I have seen the longitudinal fissure of the brain deviate to the right or left
Bide at an angle of from 15° to 20° degrees from its usual direction.
Each cerebral hemisphere presents three surfaces for our consideration :
An internal surface {fig. 282), which is flat, vertical, and separated from that of the
opposite hemisphere by the falx cerebri ; but as the falx does not extend so low as the
corpus callosum, it follows that the two hemispheres are in contact below, the pia mater,
however, intervening between them. In those rare cases of absence of the falx cerebri,
the corresponding faces of the two hemispheres are in contact with each other through
out their whole extent. I have seen one case in which the falx was imperfect, and the
two hemispheres were united.
An external surface, which is convex, and resembles the surface of the fourth part ot
an ovoid, having its great end directed backward ; it corresponds to the concavity formed
by the frontal, parietal, and occipital bones.
An inferior surface, which forms part of the base of the brain in general, and will be
next described.
The Inferior Surface or the Base of the Brain.
The hase of the brain {fig. 276), admirably described and correctly figured bv Soemmer-
ing in a special treatise upon the p^^^ 276.
subject,* presents a great number
of objects for our consideration. In
order to obtain a perfect knowledge
of it, it is advisable to examine it
while the brain is still enclosed in
its membranes, and placed in the
scull-cap, with its base uppermost ;
and also upon a brain from which
the membranes have been remo-
ved, and which is placed in the
same position, but on a flat surface.
In the former case, the parts form-
ing the base of the brain are press-
ed together, and may be studied as
a whole ; and in the latter, they are
separated, and may be examined in
detail.
It is at its base that the brain i
connected with the other parts o
the cerebro-spinal axis by means
of the right and left peduncles {ff),
which may be regarded as the roots
of the two hemispheres.
The Median Region. — In the me-
dian line, opposite the centre of
the base of the brain, and in front
of the pons Varolii (d), is situated
an excavation, which may be called
the median excavation of the base of
the brain. This excavation has already been alluded to in the description of the arach-
noid membrane and the sub-arachnoid fluid, with which this excavation is filled : it is
formed by the brain being curved upon itself, and is partially effaced when that organ
is placed with its base uppermost upon a flat surface : this excavation is of a pyram-
idal form, the apex being directed upward and the base downward. The borders of
the excavation form a hexagon, and contain the arterial hexagon of the base of the cra-
nium, named the circle of Willis. The posterior borders of the hexagon are formed by
the peduncles of the brain, the lateral borders by the inner part of the posterior lobes [c,
middle lobest] of the cerebrum, and the anterior borders by the inner and back part of
the anterior lobes {a) of the cerebrum.
From the six angles of this hexagon, six furrows proceed in different directions : from
the anterior angle, the fissure which separates the anterior lobes, or the great longitudi-
nal fissure {x) of the brain ; from the two anterior lateral angles, the corresponding fis-
sures of Sylvius (y y) ; from the posterior lateral angles, the two extremities (external to
//) of the great cerebral fissure, or great transverse fissure of the brain ; and from the pos-
terior angle (r), which corresponds to the interval between the cerebral peduncles, the
longitudinal groove {d) upon the pons Varolii.
* Do basi Encephali (Luduiig, Scriptores Neurologici, t. ii.).
+ /. e., of the middle lobes of anatomists generally {c,fig. 276), which, it must be remembered, the author,
agreeing with Soimraering, does not regard as distinct from the posterior lobes (b), and to which, therefore,
he does not apply the term " middle lobes." This term is, however, for the most part added [between brack-
et*] in the translation, as it is generally used in anatomical descriptions in this country. 1
728 NEUROLOGY.
In the area of this median excavation are seen the inter-pcduncular space (above r), the
mammillary tubercles {z, corpora matnmillaria vel albicaniia), the oplic tracts («) and optic
commissure (t), the posterior part of the floor of the third ventricle, or the tuber cinereum {v),
the infundibulum (i), and the pituitary body*
In front of the median excavation are situated, counting from behind forward, the an-
terior part of the floor of the third ventricle {lamina cinerea, m,fig. 282), the under or reflect-
ed portion of the corpus callosum (e), and the inferior part of the longitudinal fissure of the
cerebrum (x, flg. 276).
Behind the median excavation is the pons Varolii, and, behind that, the middle part
(r, fig. 282) of the great transverse fissure, by which the pia mater enters (above p) the
third ventricle, the thick posterior extremity (/) of the corpus callosum, and the posterior
part of the longitudinal fissure of the cerebrum.
The Lateral Regions of the Base of the Brain. — Upon each of these regions are seen the
inferior surface of the corresponding anterior lobe (a) of the cerebrum, the fissure of Sylvius
(y), by which this lobe is separated from the posterior lobe [middle lobe of others, c], and
the inferior surface of the posterior lobe itself (c b). There is no distinct middle lobe.t
I shall now describe, successively and in detail, the several parts just enumerated,
with the exception of the cerebral peduncles and the pons Varolii, which have already
been noticed as constituent parts of the isthmus of the encephalon.
The Median Region of the Base of the Brain.
The Inter-peduncular Space.
This space (above r) is of a gray colour, it is perforated by numerous openings for the
transmission of vessels, and is termed the middle or posterior perforated spot {locus per-
foratus) ; it contains the origin of the third pair of nerves (3). A longitudinal groove
and two fasciculi, separated from the corresponding cerebral peduncle by a blackish line,
are seen in this spot. These inter-peduncular fasciculi are forrhed by a prolongation of
the fasciculi of re-enforcement {faisceaux innomines) of the medulla oblongata.
The Corpora Albicantia.
The mammillary tubercles {corpora albicantia vel mammillaria, z) are two small pisiform,
or, rather, hemispherical globules, composed externally of white, and internally of gray
substance, situated behind the tuber cinereum, which is accurately adapted to their an-
terior surface, also behind the infundibulum, and between the peduncles of the brain.
They are separated from each other by a deep fissure, excepting at their highest part,
where they are connected by means of a thin layer of gray matter, which is very easily
torn ; they correspond {z, fig. 282) to the floor of the third ventricle (/).
It will be hereafter seen that the white cov.ering of these small bodies is formed by the
termination of the anterior pillars of the fornix, and hence the name given them by Cas-
serius, the bulbs of the anterior pillars of the fornix {bulbi priorum crurum fornicis), a
name which should be preserved. The two corpora albicantia are generally of equal
size. In several cases of atrophy of one of the hemispheres of the cerebrum, I have
found the corresponding mammillary tubercles also atrophied.
We are completely ignorant of the function of these bodies.
In man and the carnivora only are there two mammillary tubercles, and in all the oth-
er vertebrata there is but one. They attain their highest state of development in fishes,
if, as stated by Vicq d'Azyr, they are represented by the two larger lobes, which occupy
a corresponding situation in that class of animals. During the early periods of foetal
life they are blended together into one tolerably large mass, and do not become distinct
from each other until about the seventh month.
The Optic Tracts and Comm,issure.
At the point where the peduncles of the cerebrum pass into the brain, each of them is
surrounded by a white band, named the optic trad, or tract of the optic nerve. Each of
those tracts commences, behind, at an eminence called the corpus geniculatum externum
{JifiS- 271), which will be seen, hereafter, to be an appendage of that part of the brain
named the optic thalamus. The corpus geniculatum internum {i,figs. 271, 272) of au-
thors is merely a tubercle inserted into the bend or knee formed by the corpus genicula-
tum externum. The optic tract (2, fig. 272), then, is the continuation of the corpus ge-
niculatum externum, from which it is distinguished by its whiteness, which contrasts
strongly with the gray colour of that body : it is at first broad, flattened, and thin, and
is applied to the corresponding cerebral peduncle, being distinguished from the peduncle
only by the direction of its fibres. It then turns horizontally around the peduncle, is de-
tached from it, and at the same time becomes narrower and thicker ; having reached
the front of the peduncle, it changes its direction, passes forward and inward {s,fig. 276),
and is united with its fellow of the opposite side, to form the commissure or chiasma {t)
of the optic nerves (2). The optic tracts may be regarded as forming a commissure to
the two optic thalami.
* [To avoid confusion in the drawinfr, the pituitary body is not represented mfig. 276 ; its point of attncb
meut is to the infundibulum (i).] + See note, p. "27.
THE BASE OF THE BRAIN. 729
These tracts and the cerebral peduncles of the two sides enclose a lozenge-shaped in-
terval, in which are situated the posterior perforated spot, the corpora albicantia, the tu-
ber cinereum, the infundibulum, and the pituitary body.
The Tuber Cinereum, the Infundibulum, and the Pituitary Body.
The terra tuber cinereum (») has been apphed by Soemmering to the soft gray mass
which occupies the triangular interval between the corpora albicantia and the optic
tracts. It is also called the floor of the third ventricle, because it closes that cavity be-
hind and below, and the base of the infundibulum, because that part is attached to it.
The infundibulum (la tige pituitaire, Lieutaud; la tige sus-sphenoidale, Chauss.) is a
reddish process (i), about two lines in length, directed very obliquely downward and for-
ward (i, fig. 282), and applied to the lower surface of the tuber cinereum : it is broad at
its upper extremity, but soon diminishes in diameter, and descends, to be inserted into,
and become continuous with, the pituitary body.
Is the infundibulum hollow, or is it a solid stem 1 The term infundibulum, or funnel,
applied to this part by the older anatomists, and the following synonymes, pelvis colatoria,
scyphus, aquce ductus, encephali sentina, afford ample evidence of both their anatomical
and physiological views regarding it. Galen and Vesalius, who are so often at variance,
are perfectly agreed upon this subject, and describe the infundibulum with a minute ex-
actness ; but since the communication supposed by Galen to exist between the nasal
fossae and the brain by means of passages through the ethmoid and sphenoid bones, and
the equally hypothetical communication admitted by Vesalius, are known to have no ex-
istence, anatomists have rejected the notion of the passage of a fluid from the brain in
this direction, and they no longer regard the infundibulum as a funnel intended for its
transmission. Haller has collected, in some learned notes, the contradictory opinions
of his predecessors, but has left the question still in doubt. Nor has Soemmering him-
self, after a long detail of investigation into the subject, arrived at a more satisfactory
result.*
A careful examination of the infundibulum has convinced me that there is, at least in
a certain number of cases, a funnel-shaped canal, precisely similar to that which was
described and figured by Vesalius : it is wide above, where it communicates with the
third ventricle, and narrow below, where it reaches the pituitary body, a body which the
ancients had not named, but which Vesalius called glan^ pituitam excipiens. In order to
demonstrate this canal, the optic tract must be turned backward, and the semi-transpa-
rent corneous lamina, which forms the anterior part of the floor of the third ventricle,
must be divided ; behind a white band, which is quite distinct from the anterior com-
missure of the brain, there is then seen a circular opening sufficiently wide to admit the
blunt end of a large probe, which may accordingly be passed through the entire length
of the infundibulum as far as the pituitary body. Again : by cutting the infundibulum
across, and then blowing upon it through a blowpipe, or letting some drops of water
fall upon it, a perfectly circular opening may be demonstrated, which cannot be produced
by the means employed in the demonstration.
Lastly, we may adopt the method of Vesalius, who filled the third ventricle with a
coloured liquid, which soon reached the pituitary body. The same experiment succeeds
still better with mercury. Nevertheless, I ought to state, that in two cases of dropsy
of the third ventricle, no fluid escaped from the infundibulum when it was cut across.
It is easy to show the structure of the infundibulum. A fibrous and vascular mem-
brane, continuous with the pia mater, forms its external covering, and this is lined by
a thin layer of gray matter, which is continuous with that of the floor of the third ven-
tricle. This gray matter forms a solid cord when the infundibulum is not tubular.
The pituitary bodyi is a small body, weighing from five to ten grains, which occupies
the sella turcica, or supra-sphenoidal fossa (appendice sus-sphenoidale du cerveau,
Chauss. ; hypophysis. Seem.). The better to appreciate its size, it is convenient to
break down, with a chisel, the quadrilateral plate which forms the posterior wall of the
sella turcica or pituitary fossa, and which is itself hollowed in front, so as to increase the
antero-posterior diameter of that cavity. J
Enclosed in the sella turcica, the pituitary body is kept in that situation on each side
by the fold of the dura mater, which constitutes the cavernous sinus, and above by a
portion of the same membrane, which forms a circular orifice around tlie infundibulum.
The coronary sinus, which is situated between the pituitary body and the margin of
the sella turcica in front and behind, and the cavernous sinuses on each side, form a
vascular circle around this body, but it is not bathed in the blood, as stated by some.
* Ludwig-, Script. Neurolog. ; Soemmering, De basi Encephali, p. 41. " Quibus omnibus absque partiwa
studio rite mecum perpensis, non potui non complecti illorura virorum sententiam, qui infundibulum, si non
perfecte solidum, certe non adeo conspicuo, uti veteres opinati sunt, canali perforatum esse, censuerunt."
Hunter and Cruickshank say that the infundibulum is sometimes solid, and sometimes tubular.
t Not shown in figs. 276, 282.
t In order to obtain a perfect examination of the pituitary body and infundibulum, it is well to sacrifice a
brain and the base of the cranium, and to remove, by a circular incision, the body of the sphenoid bone, to-
gether with the corresponding part of the base of the brain.
4Z
7^ NEUROLOGT?
The upper surface of the pituitary body is slightly excavated, still it is not unfrequent-
ly convex, so as to project more or less above the level of its fossa.
On removing the pituitary body, it is seen to be formed of two distinct lobes, of which
the anterior is the larger, while the posterior occupies the small cavity in the quadrilat-
eral plate. These two lobes have been very well described by the brothers Wenzel ;
they are not of the same colour, the posterior lobe being grayish white, like the gray
substance of the brain, and the anterior yellowish gi-ay.
If the anterior lobe be pressed between the fingers, a yellowish-white pulp escapes
from it, very nearly resembling mixed plaster of Paris. An antero-posterior section of
the pituitary body shows, also, that the two lobes are perfectly distinct, being separated
by a fibrous layer. They are provided with a great number of small vessels. It has
been stated, but not proved, that the infundibulum contains two canals, one for the an-
terior, and the other for the posterior lobe. It is extremely rare to find any hard con-
cretions in the pituitary body like those met with in the pineal gland.
It is, perhaps, not uninteresting to remark, that the pituitary body is most highly de-
veloped in fishes, in which animals it forms a true lobe ; and that it is proportionally
more developed in mammalia, birds, and reptiles, than in the human subject. It is hol-
low in all the lower animals.
It is larger at the fourth, fifth, and sixth months of foetal life than after birth, and con-
tains a cavity which communicates with the third or middle ventricle. I pnce found a
considerable cavity in the pituitary body of an adult.
The functions of the pituitary body are enveloped in the greatest obscurity. Its con-
stancy in all vertebrated animals and its great vascularity are sufficient evidence of its
importance. It certainly conamunicates with the third ventricle, but for what purpose %
Does it pour a peculiar fluid into that cavity, or does it absorb a portion of the ventricu-
lar fluid 1 Whatever may be the use of the communication just alluded to, the pituitary
body does not communicate directly with the venous sinuses around it : it is not a lym-
phatic gland, as maintained by Monro ; nor is it a nervous ganglion of the great sympa-
thetic, as some have recently conjectured, because they fancied they saw some very fine
nervous filaments anastomosing upon it. The branches of the fifth and sixth nerves,
which Litre and Lieutaud say they have seen penetrating this body, have not been de-
monstrated.
The Anterior Part of the Floor of the Third Ventricle.
The anterior part {m, Jig. 282) of the floor of the third ventricle, which cannot be well
seen until the commissure of the optic nerves is turned backward, forms an inclined
plane directed downward and backward. It consists of a fibrous layer, which is contin-
uous with the neurilemma of the optic nerves ; and of a very thin, semi-transparent, but
very strong corneous layer {lamina cimrea), from which prolongations are given off to
the upper surface of the optic commissure, and continued upon the optic nerves : these
prolongations might be called the gray roots of the optic nerves. On dividing this horny
layer, the third ventricle (I) is laid open ; and it is seen that this layer forms a part of
the general system of gray substance, which, on the one hand, is prolonged upon the lat-
eral wall of the third ventricle, and surrounds the anterior pillars of the fornix, and, on
the other, is continuous with the tuber cinereum, above the optic commissure.
The Reflected Portion of the Corpus Callosum.
In front of the anterior part of the floor of the third ventricle is a transverse white
mass, which is nothing more than the fore part (e to m) of the reflected corpus callosum.
Terminating at this cross tract are two white fasciculi, which commence on each side
at the point where the corresponding fissure of Sylvius meets the great transverse fis-
sure of the brain ; they then pass inward and forward, along the outside of the optic
tracts, form the lateral boundaries of the anterior part of the floor of the third ventricle,
and terminate by becoming applied to, but not blended with each other, behind the re-
flected portion of the corpus callosum. Vicq d'Azyr has described these bands as the
veduncles of the corpus callosum.
The Anterior and Inferior Part of the Longitudinal Fissure.
This (x, fig. 276) is situated in front of the reflected })ortion of the corpus callosum,
and can only be seen in its entire extent after the removal of a very dense fibrous layer
which connects, sometimes very firmly, the back part of the right and left anterior lobes
of the cerebrum. Not unfrequently one of these lobes is seen to encroach upon the oth-
er : the falx cerebri, which is very narrow in front, occupies only a very small portion
of this fissure.
All the parts belonging to the median region of the base of the brain, which we have
hitherto described, are situated in front of the pons Varolii ; those which remain to be
examined are placed behind it : they are, counting from behind forward, the back part of
the longitudinal fissure, the posterior extremity of the corpus callosum, and the great horizontal
or transverse fissure.
THE BASE OF THE BRAIN. 781
The Back Part of the Longitudinal Fissure.
This is bounded in front by the posterior extremity of the corpus callosum (/) ; and as
that extremity is at a greater distance from the back of the cerebrum than the anterior
extremity of the corpus callosum is from the front of the brain, it follows that the back
part of the longitudinal fissure is of much greater extent than the fore part (see Jigs. 277,
282). Moreover, this part of the fissure is free throughout its whole extent, for it is en-
tirely occupied by the base of the falx cerebri, while the fore part is only partially filled
with the apex of the falx : it might even be said that the posterior lobes have a tenden-
cy to separate from each other in this situation.
The Posterior Extremity of the Corpus Callosum, and Middle Portion of the Great Trans-
verse Fissure.
The posterior extremity {f,flg. 282) of the corpus callosum is named the bourrelet,* in
consequence of its being so much enlarged. This enlarged extremity, which we shall
afterward find is continuous with the posterior pillars of the fornix, constitutes the up-
per border of a fissure (r), the lower border of which is formed by the tubercula quadri-
gemina {f g). The pia mater (r to near k) enters at this median fissure, and forms the
velum interpositum, or tela choroidea : in this situation, also, is found the conarium or pi-
neal gland ; and it is here that Bichat described the orifice of his arachnoid canal. This
median fissure becomes continuous with a lateral fissure on each side, so as to form the
great transverse cerebral fissure.
The Great Transverse Cerebral Fissure.
The great cerebral fissure {Bichat), or the great transverse or horizontal fissure, follows a
semicircular direction, having its concavity directed forward ; it commences at the fis-
sure of Sylvius on one side {h,fig. 276 ; above 2, fig. 282), turns round the opposite cere-
bral peduncle, and ends at the opposite Sylvian fissure.
The peduncle of the cerebrum and the optic thalamus may be regarded as forming the
root of each cerebral hemisphere. Now the lateral part of the great transverse fissure
passes round the posterior half of this root, because it is in this situation that the cor-
responding cerebral hemisphere is turned inward upon itself It is this reflected and
concave surface of the hemisphere that forms the outer border of the corresponding lat-
eral portion of the transverse fissure, while the optic thalamus forms its inner border.
This fissure communicates directly with the inferior cornua of the lateral ventricles, and
through it the pia mater enters those ventricles, to form the internal pia mater of the brain.
The Lateral Regions of the Base of the Cerebrum.
The base of the cerebrum is divided on each side into two lobes, an anterior and a
posterior, separated by the fissure of Sylvius, j
The Fissure of Sylvius.
This is a fissure of considerable size (grande scissure interlobulaire, Chauss.), which
commences at the corresponding anterior extremity of the great transverse fissure, with
which it forms an obtuse angle. At the point where they meet is found a white sub-
stance,t perforated with large openings for bloodvessels ; this Vicq d'Azyr has named
the anterior perforated substance ; it is the locus perforatus anterior (h).
The fissure of Sylvius (y, fig. 276) is directed outward, and describes a slight curve,
having its convexity turned forward : it corresponds to the posterior border of the lesser
wings of the sphenoid bone, which are received into it.
The fissure of Sylvius cannot be properly examined until both the arachnoid and pia
mater have been removed. It is then found to be very deep ; it is seen that the middle
cerebral artery runs along the bottom of it, that the pia mater lines it throughout, and
that it soon divides into two branches, of which the anterior is the smaller, and contin-
ues in the original course of the fissure ; while the posterior, which is of much greater
extent, passes upward and backward, along the convex surface of the hemisphere, and
terminates after proceeding a variable distance ; the interval between these two second-
ary furrows is occupied by a sort of island (insula, Reil), which might be called the lobule
of the fissure of Sylvius, or the lobule of the corpus striatum.
This lobule is of a triangular form, having its base directed upward and its apex down-
ward ; it is marked by certain small superficial convolutions, which radiate from below
upward. It will be found immediately that this lobule corresponds to and is moulded
upon the corpus striatum, which is sometimes so large as to push the lobule beyond the
fissure, so that it reaches the surface of the brain, and appears to belong to the ante-
rior lobe.
The Anterior and Posterior Lobes of the Cerebrum.
Several anatomists describe three lobes in each hemisphere upon the base of the brain,
* Cushion, thick border.
t [Three, according to other anatomists: an anterior (a, Jig. 276), a middle (e), and a posterior (6) ; the
anterior separated from the middle by the fissure of Sylvius (y), the posterior resting- ou the cerebellum, or,
rather, on the tentorium.] " I CLight gray.]
732 NEUKOLOGT.
namely, an anterior (a), a middle (c), and a posterior (i) ; but there are only two : an ante
rior (a), which rests upon the orbital plate of the frontal bone, is moulded upon its irregu-
larities, and is received into the concavity of that bone ; and a posterior (c b), which rests
upon the corresponding spheno-temporal fossa and the tentorium cerebelli. The an-
terior third of this posterior lobe, or the portion which corresponds to the spheno-tem-
poral fossa, is convex, and projects from six to nine lines below the level of the inferior
surface of the anterior lobe. The posterior two thirds are slightly concave ; they corre-
spond to the tentorium cerebelli, and are placed upon the same level as the anterior lobe.
The convex sphenoidal portion of the posterior lobe forms what is generally called the
middle lobe, and the posterior, or cerebellar portion, what is then named the posterior lobe.
I believe that it is useful, in many respects, to apply the terms frontal horn (cornu fron-
tale) to the anterior extremity of the cerebrum, which is received into the concavity of
the frontal bone, sphenoidal horn to the anterior extremity of the posterior lobe, and oc-
cipital horn to the posterior extremity of the same lobe.
The Convolutions and Anfractuosities of the Cerebrum.
The entire surface of the cerebrum is marked by a great number of deep, winding fur-
rows, which divide it into as many oblong eminences, turned in different directions, and
themselves subdivided by secondary furrows. These eminences have some resemblance
to the convolutions of the small intestine, and have been named, on this account, convo-
lutions, gyri, meandri, processus enteroidei. The furrows by which they are separated
are called anfracluosities or sulci.
A more accurate notion of the general character of these convolutions and anfractu-
osities may be obtained by supposing a bladder to be expanded round a compact central
mass, at a certain distance from it, and in this condition too large to be contained with-
in the cranium ; and then, that by means of threads proceeding from different points of
the centre, the corresponding parts of the bladder are drawn inward, so that it is folded
upon itself, and can now be contained within the cranial cavity. The various winding
folds and furrows produced in the walls of the bladder by drawing them from above and
from all sides towards the centre, will give some idea of the arrangement of the surface
of the cerebrum.
Some of the convolutions and anfractuosities are constant, because their forms are de-
termined by those of the central mass ; others are subject to variety, and seem to de-
pend upon no determinate cause : these varieties occur not only in different brains, but
also in the two hemispheres of the same brain. In this respect the human brain differs
from that of the lower animals, in which the cerebral convolutions present much less
variety, though they are not so constant as Vicq d'Azyr has stated.
The human brain is distinguished from the brains of the lower animals, not only by
its size and weight, but also by the number and size of its convolutions. Tiedemann
has given excellent representations of the progressive diminution of the cerebral convo-
lutions (which is accompanied by a diminution of the cerebellum) from the apes to the
rodentia and edentata.* In the human subject, as in the series of lower animals, the
development of the convolutions has always appeared to me to be directly proportioned
to the development of the entire brain.
In this point of view, as in many others, the human foetus presents a similar structure
to that found in the lower animals. The furrows or anfractuosities in the brain of the
human foetus at the fifth month are neither deeper nor more numerous than those in the
brain of the rabbit ; and it is important to study these primitive furrows, because they
correspond to certain anfractuosities which ultimately regulate the whole system of con-
volutions. Thus, at the fifth month, the great anfractuosity, which is called the fissure
of Sylvius, exists, but its borders are apart from each other ; the islantl of Reil, or the
lobule of the corpus striatum, is found upon the surface of the brain, and there is a lon-
gitudinal furrow at the lower and back part of the internal surface of each hemisphere ,
it corresponds to the occipital prolongation or posterior cornu of the lateral ventricle ;
there is also a furrow above the corpus callosum ; and, lastly, the furrow of the olfactory
nerve is visible. At birth, all the convolutions exist, but they are not completely devel-
oped until about the age of six or seven years.
It is impossible to determine the number of the convolutions, for they have no appre-
ciable limits ; and although some of them end between two adjacent ones, it is easy to
see that this termination is merely apparent, and that near the point where it seems to
take place, the convolution is continued into another without any line of demarcation.
The ancient comparison, therefore, between the convolutions of the brain and those of
the intestines, not only applies to their direction, but also to their continuity.
There are several orders of convolutions. In fact, simple convolutions are seen to be
divided, excavated, and furrowed, more or less deeply ; but there are no regular and con
secutive subdivisions, as in the laminae of the cerebellum. Vertical sections made in
* [See also Leuret's figures in the work already referred to, in which will be found a comparative view of
the niunber and arrangen^nt of the convolutions of the bnun in man and mammalia.]
CONVOLUTIONS AND ANPEACTD08ITIE3 OF THE BRAIN. 73S
different directions will show the arrangement of the convolutions much better than the
most careful observations of the external surface of the brain.
Each convolution presents to our notice two surfaces, a base or adherent border, and a
free border. The surfaces of the corresponding convolutions are moulded upon each
other, and separated by a duplicature of the pia mater.
The base or adherent border of each convolution is continuous with the central portion
of the hemisphere (see section, ^^. 277).
The free border is slightly rounded, so that between any two contiguous convolutions
there is a small groove, which is very distinct in cases of purulent infiltrations or depo-
sitions of lymph in the sub-arachnoid cellular tissue.
At the points where these convolutions meet, a triangular depression is observed.
These spaces are small in the natural state, but become very evident in cases of atrophy
of the convolutions.
The free border of some convolutions is frequently marked by an oblong depression or
groove, varying in depth and extent, and following the direction of the convolutions ;
these depressions are sometimes sharp, and radiate into three or four branches ; at other
times they are superficial, or, lastly, deep and narrow. The arteries and veins which
pass over the free borders of the convolutions form grooves upon them of various depths.
The free borders of most of the convolutions generally reach the surface of the brain ;
but besides the secondary convolutions, several of which remain concealed throughout
their whole length, between two adjacent convolutions, there are some principal convolu-
tions, which descend at one of their extremities between two adjacent convolutions ; and
there are others, again, which are depressed at one or at several points of their extent.
The depth of the convolutions varies from ten to fourteen lines, but it is extremely
variable in different individuals ; moreover, there are perhaps not two convolutions, nor
two parts of the same convolution, which correspond in thickness in the same brain ;
some are considerably swollen, while others are narrow ; there is almost always an en-
largement at the point where two convolutions become continuous. Eustachius and
Vieussens have erred, then, in representing all the convolutions as perfectly similar.
It would be undoubtedly curious to describe minutely all the convolutions. Vesalius,
who appears to have entertained the idea of so doing, likened the appearance of the sur-
face of the brain to those irregular forms which are traced by unskilful painters in de-
lineating clouds. Vicq d'Azyr made an unsuccessful attempt to elucidate this subject ;
Gall and Spurzheim, who were interested in giving a minute description of each convo-
lution, abandoned the task ; I have myself attempted, and so has Rolando, to describe
and name some of them. The description, however, to be understood, would require
the assistance of figures ; I shall, therefore, content myself with noticing, in this place,
the most important convolutions upon the internal surface, upon the inferior surface, and
upon the external surface, or convexity of each hemisphere.
Convolutions and Anfractuosities upon the Internal Surface.
The convolution of the corpus callosum is one which predominates over all those of the
internal surface of the hemisphere ; it is that which embraces the corpus callosum, and
hence its name. It commences in front, below the reflected extremity of that body, to
which it adheres, passes forward and upward, turns round its anterior extremity, then
extends backward, and having reached beneath the posterior extremity of the corpus
callosum, continues its course, and is arranged, in a manner to be presently described,
upon the lower surface of the cerebrum.
It is narrow at its anterior extremity, which Rolando regards as the principal root of
the olfactory nerve ; it increases in size as it proceeds, and opposite the middle of the
corpus callosum it is elevated like a crest, becomes much broader, and is marked by sev-
eral furrows, of which some are superficial and others deep. Tlie circumference of this
broad crest is divided into several branches, which become continuous either with the
superior convolutions of the convex surface, or with the posterior and superior convolu-
tions of the internal surface of the hemisphere. Vicq d'Azyr first pointed out this crest
of the convolution of the corpus callosum, and it was named by Rolando processo enter-
oido cristato.
The internal convolution of the anterior lobe is eccentric in reference to the one just de-
scribed, upon which it is moulded, a deep anfractuosity intervening between them. It is
very large at its origin in front of the fissure of Sylvius ; it forms the internal part of the
anterior lobe of the cerebrum, and having arrived in front of the crest of the convolution of
the corpus callosum, it passes upward, and becomes continuous with the convolutions
of the convex surface of the hemisphere.
This convolution is divided throughout its entire extent by a secondary anfractuosity,
which is at first straight, and then sinuous.
Convolutions and Anfractuosities of the Digital Cavity.
A very deep longitudinal furrow, which corresponds to the digital cavity of the lateral
ventricle, and, like it, constantly exists, extends from the convolution of the corpus cal-
734 NEUROLOGY.
losum, near the posterior extremity of that body, directly backward along the posterior
lobe of the brain, which it divides into a superior and inferior portion. This anfractu-
osity of the digital cavity forms a division between the internal and inferior surfaces of the
hemisphere.
Ti\e convolutions of the digital cavity are the two longitudinal and tortuous convolu-
tions which bound this anfractuosity ; the upper convolution belongs to the internal sur-
face of the hemisphere, while the lower one forms part of the inferior surface.
Convolutions and Anfractuositics upon the Inferior Surface.
The great anfractuosity, called the fissure of Sylvius, divides the convolutions of the
inferior surface into those of the anterior and those of the middle and posterior lobe.
The convolutions of the anterior lobe constantly found are, the two small, straight, longi-
tudinal convolutions which bound the groove of the olfactory nerve {I, fig. 276), and the
flexuous convolution, which extends obUquely forward and outward, along the border of
the fissure of Sylvius, and is continuous behind with the external straight convolution
of the olfactory nerve.
The small convolutions and intervening anfractuosities are very irregular, and differ
in different individuals, and even on the two sides in the same individual ; into the de-
pressions formed between these convolutions are received the prominent ridges seen
upon the orbital plate of the frontal bone.
The Convolutions of the {Middle and) Posterior Lobe. — The convolution which runs along
the great transverse fissure is the continuation of the convolution of the corpus callosum,
and terminates in front by an unciform enlargement, which corresponds to the dilated
extremity of the comu Ammonis ; it forms the outer boundary of the great transverse
fissure. The convolution of the corpus callosum and its continuation, viz., that of the
transverse fissure, represent an ellipse, which is broken only at the fissure of Sylvius.
On the outer side of this convolution is a longitudinal anfractuosity, which corresponds
to the lower wall of the inferior comu of the lateral ventricle.
This anfractuosity is bounded by certain longitudinal convolutions, all of which pro-
ceed from the convolution of the transverse fissure, and are remarkable for their size
and windings.
The most internal of these convolutions forms the lower boundary of the anfractuosity
which I have said corresponds to the posterior comu of the lateral ventricle.
From the anterior part of the convolution of the transverse fissure some extremely
flexuous convolutions proceed from behind forward, assist in forming the sphenoidal
horn (point of the middle lobe), and become continuous with the convolutions of the ex-
ternal face of the hemisphere.
Convolutions and Anfractuosities of the Convex Surface.
The convolutions upon the convex surface of the hemisphere are, undoubtedly, the
most complicated ; on separating the borders of the fissure of Sylvius, within which the
island of Reil is contained, it is seen that the fissure is triangular, and presents three
sides : an inferior border, formed by the external convolution of the anterior lobe of the
cerebrum ; a posterior border, directed very obliquely upward and backward, which ap-
pears to receive all the occipital convolutions, and consists of a very tortuous convolu-
tion ; and a superior border, also consisting of a very winding convolution, in which the
majority of the superior convolutions terminate.
The convolutions upon the convex surface of the brain may be divided into the frontal,
the parietal, and the occipital.
The frontal convolutions are three or four in number, and are directed from before back-
ward. The parietal convolutions are three in number ; they pass in a serpentine direction
from within outward, and become continuous with the convolution which forms the su-
perior border of the fissure of Sylvius. The occipital convolutions are directed from before
backward, and proceed either from the posterior parietal convolution, or from the pos-
terior border of the fissure of Sylvius.
The occipital convolutions are the narrowest anil the most sinuous of all, so that the
sides of the sinuosities of each convolution are in mutual contact in the greatest part of
their extent, and touch the adjacent convolutions only at the points at which they are
bent.*
The frontal convolutions are also very flexuous, and have similar characters to the
occipital, but not so distinctly marked. They are larger than the occipital convolutions,
but smaller than the parietal, which are, moreover, less tortuous than either of the others.
The unusual details with which I have described the convolutions can only be justified
by the importance which has recently been attached to them. In the preceding descrip-
tion the following points have been noticed : Their general disposition, their windings,
and their mutual adaptation ; their continuity, and the impossibility of drawing any pre-
cise limits between them ; their general configuration, according to a common type, and
the want of uniformity in their details, not only in different brains, but also in the oppo-
* In senile atrophy, the occipital convolutions are chiefly affected.
FUNCTIONS OF THE CONVOLUTIONS AND ANFEACTUOSITIES. 735
site hemispheres of the same brain ; their variable dimensions in different individuals,
both in respect of depth and width, these being always directly proportioned to the size
of the cerebral hemisphere : the individual differences both in the size of the brain and
in that of the convolutions are very great.* We have also seen that the internal surface
of the cranium is exactly moulded upon the surface of the brain, the digital impressions
in the cranial bones corresponding to the convolutions, and the ridges or eminences to
the small spaces intervening between the free borders of the convolutions.
Functions of the Convolutions and A nfractuositics.
' The convolutions and anfractuosities render the surface of the brain of much greater
extent than it would otherwise have been. According to Vesalius, they are of use in
multiplying the surface, through which the bloodvessels carry nutritious matter into the
interior of the organ, t
The opinion that the anfractuosities and convolutions are intended to increase the
surface has been lately revived ; but the supposed object of this increase is very differ-
ent from that stated by Vesahus : thus, it has been agreed that, as there is an undoubt-
ed analogy between electrical phenomena and those manifested by the nervous system,
and as electrical phenomena are developed, not in proportion to the quantity of matter
concerned, but in proportion to the extent of surface, so the energy of the brain's action
may be in a direct ratio with the extent of its surface. In support of this opinion, the
phenomena of arachnitis are quoted, in which disease delirium more frequently occurs
than in inflammation of the cerebral substance itself Allusion is also made to the folds
observed in the retinae of birds, which greatly increase the intensity of vision : M. Des-
moulins, who is a principal supporter of this theory regarding the use of the convolu-
tions, states that he has observed these folds to disappear in birds which had been kept
in the dark, in the same way that the cerebral convolutions become atrophied, either
from the continued absence of all cerebral excitement, or from any other cause of intel-
lectual weakness.
The anatomists and philosophers of antiquity, considering that the convolutions were
more highly developed in man than in the lower animals, concluded that tlie intellectueil
superiority of the former was owing to this circumstance. Such was the opinion of
Erasistratus, facetiously refuted by Galen4
Gall and Spurzheim have recently revived this old opinion, and assuming, with some
philosophers, the existence of a plurality of mental functions, they have arrived at the
conclusion that there is also a plurality of material instruments or organs, by which
those functions are performed. These material organs are supposed by them to be the
convolutions, upon which they accordingly placed numbers corresponding to the differ-
ent mental faculties admitted by their philosophy : the difficulty was to settle on the
number of primitive mental faculties and their corresponding organs. According to Gall
and Spurzheim, the highest intellectual faculties of man are seated in the anterior lobes
of the cerebrum.
On the other hand, from an examination of the brains of fifty insane patients, M. Neu-
mann has been led to think that the occipital portion of the cerebrum is the seat of in-
telligence : this opinion derives some support from a fact which I have myself often ob-
served, viz., that atrophy of the brain of old persons in insanity affects the occipital
more than the frontal convolutions ; and also by the fact, that, as we descend in the ani-
mal series, the posterior part of the brain is observed to be the first to diminish, and
then entirely to disappear.
It is unfortunate for the system of Gall that the convolntions form a continuous whole,
and are not separated into distinct organs ; and it is also unfortunate that, upon the base
of the cerebrum, and upon the internzil surface of each hemisphere, there are convolu-
tions as distinctly marked as those upon the convex surface ; and yet, in the system of
Gall, the convolutions upon the base and internal surface of the hemispheres have been,
so to speak, disinherited ; for all the mental faculties have been located by him in the
convolutions of the convex surface.
The Internal Structure of the Cerebrum.
In order to make as complete an examination of the internal conformation of the brain
as is possible in the actual state of science, it should be prosecuted by means of sections
* Comparative anatomy fully confirms this fact : the convolutions of a small hemisphere are very sh'ghtly
developed, and they do not exist at all when the hemispheres are very thin, as in birds.
+ The substance of the brain, says Vesalius, is not firm enough for the arteries and veins to traverse it with
impunity ; on the other hand, it is so thick that bloodvessels distributed over its surface would not have been
sufficient to nourish the entire mass ; and, therefore, nature has provided certain deep and winding furrows
upon the brain, into which the pia mater can penetrate, so as to convey to the deep-seated parts the materials
for their nutrition ; for the same Teason, the cerebellum has been divided into laminse and lamella. Vesalius
even states that the division of the cerebrum into two hemispheres is for no other purpose (lib. vii., cap. 4,
p. 542).
t " Quum asini etiam admodum multipliciter cerebrum habent complexnra quod deccret, quantum ad mo-
rum ruditatem attinet, omnifariam simplex et minime varium nancisi cwebrum." If this theory be true, says
Galeu, the ass ought to have a brain with a smooth surface, and no convolutions ; but it has numerous and
deep convolutions : the intellectual faculties, therefore, are independent of the convolutions. The conclusion
is not obviously contained in the premises.
736
NEUROLOGY.
in different directions ; by tearing the brain, and by acting upon it with streams ol wa-
ter ; and liy dissecting brains that have been hardened by alcohol, or by being boiled in
oil or in a strong solution of salt.
Examination of the Internal Structure of the Brain by Sections.
This mode of examining the brain was the one employed by Galen ; it was revived by
Vicq d'Azyr, and is now generally adopted.
By means of these different sections it is easy to study the internal conformation of
the brain in its principal details. The other methods are more especially adapted for
determining the connexions of the several parts of the cerebrum with each other, or
with the other portions of the cerebro-spinal axis. I shall commence by an examina-
tion of horizontal sections of the brain.*
Horizontal Sections of the Brain.
On making an incision into the brain, this organ is found to consist of two substances .
a gray cineritious or cortical substance, and a ichite or medullary substance, which is sur-
rounded on all sides by the gray.t
First Section. — A horizontal section, made so as to remove the wpper half of the supe-
rior convolutions of the cerebrum, shows that each convolution consists of a central white
portion, surrounded on all sides with a layer of gray substance ; that the gray substance
is accurately moulded upon the white, the form of which determines that of the corre-
sponding convolution ; that the thickness of the gray matter varies from half a line to a
line and a half; and that it is far from being uniform, either in the same or in different
convolutions. In judging of the thickness, it is important to have regard to the direc-
tion of the section ; for it is easy to understand that an oblique section of the gray mat-
ter will give a very different result from one made perpendicularly. The section de-
scribed above also shows that the convolutions are continuous with each other, and it
enables us to comprehend their irregular, complex, and sinuous arrangement better than
could be done without cutting into the brain.
The relative proporiion of the gray and white substances in each convolution may be
determined approximately by macerating a brain for some days , the gray substance be-
ing softer and more readily decomposed, is thus converted into pulp, and may be easily
removed. The convolutions being thus reduced to the white substance only, appear
like short, white lamellas, arising from different points of the surface of the central me-
dullary mass. I estimate the gray matter at about five sixths of each convolution.
Second Section. — A horizontal section made beneath the base of the convolutions of the
convex surface of the hemispheres presents an appearance like that of a geographical
chart of a deeply and irregularly in-
dented coast ; an appearance which
cannot be described without fig-
ures. It consists of a central mass
of medullary substance, which is
narrowed like an isthmus behind:
extending from this central mass
are certain prolongations, which
may be divided into several orders,
and which are themselves subdivi-
ded, so as to form the medullary
centre of each convolution.
Third Section. — A horizontal sec-
tion, made on a level with, or, rath-
er, just above, the corpus callosum,
displays a great medullary centre in
each hemisphere (centre medullaire
hemispheral ; centrum ovale minus ;
acb, acb, Jig. 277).
The two centres of the opposite
sides, together with the corpus cal-
losum {d d), form the centrum ovale
of Vieussens.
The centrum ovale of Vieussens i«
contracted in the middle line, where
it is formed by the corpus callosum,
but is much larger in each hemi-
sphere. The anfractuosities by
which the circumference of this
section is indented are seen to be
deeper on the outside and behind, than on the inside and in front.
* The sections should be made with a very sharp instrument, a razor, for example. t See note, p. 701.
THE CORPUS CALLOSUM. 737
By the three horizontal sections just described, it is shown that eacn convolution (/ f
f) consists of a white, central portion, surrounded by a thick layer of gray substance,
having a precisely similar shape ; that it is the gray matter which predominates in the
convolutions ; that the central portions of all the convolutions are continuous with each
other, and form the most complicated windings ; that they all rest upon a hemispherical
central mass, which becomes larger and larger towards the corpus callosum, on a level
with which it attains its greatest dimensions ; that the centrum ovale of Vieussens,
which, however, is not oval, represents the largest medullary surface of the brain, and
might be regarded as a centre, from which all the radiations that enter the convolutions
are given off in one direction, and, in the other, all those which establish connexions be-
tween the brain and the other parts of the cerebro-spinal axis ; lastly, that the centrum
ov£ile and the convolutions are always developed in a corresponding ratio.
The Corpus Callosum.
If, when the brain is resting upon its base, the two hemispheres be drawn asunder, a
transverse white band is seen at the bottom of the longitudinal fissure, extending from
one hemisphere to the other, and connecting them together, and forming their commis-
sure : this band is the corpus callosum* (mesolobe, Chaussier ; commissura cerebri mag-
na, maxima, Rcil, Soemmering, d d). On removing the upper part of the two hemi-
spheres by a horizontal section made about a line or two above the corpus callosum, it
is seen that each hemisphere encroaches upon the corpus callosum, and overhangs it
without adhering to it : the interval between the hemisphere and the corpus callosum
has been improperly termed the ventricle of the corpus callosum. But there is no cavity
here, nor is there a smooth exhalant and absorbing surface ; it is merely an anfractuos-
ity, separating the corpus callosum from the convolutions, and lined by the pia mater,
like all other anfractuosities. On continuing to remove successive portions of the hem-
isphere, it is found that it can be separated without any laceration from the corpus cal-
losum, much farther than the point at which the pia mater is reflected, and that the
hemisphere and corpus callosum are simply in- contact with each other ; the fibres of
the hemisphere are seen to be longitudinal, while those of the corpus callosum are
transverse.
From this observation, it follows that the middle or free portion of the corpus callo-
sum (shown in^^. 277) is but a small part of that body.
The corpus caUosum reaches much nearer to the anterior (x) than to the posterior (y)
extremity of the cerebrum, being an inch and some lines distant from the former, and
from two to three inches from the latter.
Its length is about three inches and a half; it is broader behind than in front ; its breadth
behind varies from eight to ten lines, if we include the part which is covered by the hem-
ispheres : its thickness, which can be properly shown only upon a vertical section (see
Jig. 282), along the middle line, is not uniform throughout ; its thickest part is at the
posterior extremity (/), which is about three lines thick : in front of this extremity it
diminishes abruptly, and is scarcely a line or a line and a half in thickness (d) ; it then
^gradually increases from behind forward, and is about two lines thick at its anterior ex-
tremity, opposite the point of its reflection (c).
Inform the corpus callosum resembles an arch or vault, so that it would deserve the
*name of vault or fornix better than the»part usually so called.
Its vaulted form is distinctly shown upon a longitudinal vertical section {fig. 282), and
at the same time it is seen that the posterior extremity of the corpus callosum is rolled
up, as it were, so as to form an enlargement, while its anterior extremity is merely re-
flected downward and backward, and after its reflection becomes gradually thinner as it
descends, and terminates in a very delicate lamella.
The corpus callosum presents for our consideration a superior and an inferior surface
*and two extremities. The superior surface is convex, and, as it were, arched from be-
fore backward {medxdlaris arcus) ; it has no raphe along the median line, but presents in
that situation a slight groove (e, fig. 277), depending on the existence of two white Ion
gitudinal tracts, one on each side the middle line, which were regarded by Lancisi as
constituting a nerve, the longitudinal nerve of Lancisi.
These tracts are subject to variations : thus, they are sometimes slightly flexuous,
and contiguous to each other, and at other times they unite, and then separate. Duver-
ney has described certain ash-coloured longitudinal tracts, but their existence has been
denied by most anatomists.
The white longitudinal tracts are intersected at right angles by transverse fasciculi,
which constitute the corpus callosum.
The upper surface of the corpus callosum corresponds to the hemispheres on each
side ; it is free in the middle, where it corresponds to the arteries of the corpus callosum
and to the free margin of the falx, which has appeared to me to approach very closely to
* According to Ilaller, its name is derived from its whiteness, which has been compared to the colour of a
cicatrix ; according to others, it was given on account of the consistence of this part, which has been errone-
uslv regarded as exceeding that of other parts of the brain
5 A
NEUROLOGY.
the posterior extremity of this body, but not to touch it, so that it could not occasion
any depression upon it.
The inferior surface of the corpus callosum is concave, and is free over a greater extent
than the superior ; it forms the upper wall or roof of the lateral ventricles (t i, fg. 278,
in which figure only the anterior and posterior extremities, e and d, of the corpus callo-
sum are left).* This surface is covered by the serous membrane of the ventricles, and,
hke the superior surface, it is fasciculated.
Along the median line it corresponds, in front, to the septum lucidum {t, figs. 278,
282), and behind to the fornix (k), with which it even seems to be united at this point.
In consequence of the somewhat regular arrangement of the fibres constituting the two
posterior pillars of the fornix (r r, figs. 278, 279), which diverge in this situation, and
also of that of the transverse fibres of the corpus callosum, the back part {s,fig. 279) of
the inferior surface of the corpus callosum has received the names of lyra, corpus psal-
loides, psalterium.
The posterior extremity of the corpus callosum (bourrelet, Reit), which, as we have al-
ready stated, is its thickest part, is slightly concave transversely, but presents no other
notch, excepting the median depression, between the longitudinal tracts. t
The anterior extremity of the corpus callosum does not terminate in an enlargement, like
the posterior, but it is reflected, and embraces the anterior extremity of the corpus stri-
atum : it then passes downward and backward (e, fig. 282), and terminates insensibly in
front of the anterior portion (m) of the floor of the third ventricle. Reil applies the term
knee (genu) to the point of reflection, and that of beak (rostrum) to the posterior and thin
extremity of the reflected portion. This reflected portion of the corpus callosum is seen
upon the base of the brain, between the anterior lobes : the convolution of the corpus
callosum also accompanies its reflected portion, and, instead of being merely in contact,
becomes continuous with it, so that the gray matter rests immediately upon the corpus
callosum. The longitudinal tracts arise from the reflected portion of the corpus callo-
sum ; and the inferior peduncles of the.corpus callosum (Vicq d'Azyr), already mention-
ed, terminate upon this portion.
The right and left borders of the corpus callosum enter deeply into the substance of
the hemispheres.
Beneath the corpus callosum are situated, in the median line, the septum lucidum (t t,
fig. 278), \h& fornix (k), the velum iyiterpositum (v,fig. 279), and the median or third ven-
tricle (c to x,fig. 280) ; and at the side, the lateral ventricles (i i,fig. 278). We shall pro-
ceed to examine these different parts in the above-mentioned order. To obtain a good
idea of their form and relations, it is important to study them upon two brains, one rest-
ing upon its convex surface, and the other upon its base.
The Septum Lucidum.
The septum lucidum, or transparent septum, so called because it separates the lateral
ventricles from each other and is semi-transparent, is situated in the median line (sep-
tum median, Chauss.). It is very well seen (t,fig. 282) when the corpus callosum has
been divided longitudinally on each side of the middle line. It appears like a thin lami-
na given off from the anterior and inferior part of the corpus callosum, and passing ver-
tically downward in front of the fornix ; it is of a triangular shape, broad in front and
narrow behind ; its lateral surfaces constitute the' internal walls of the lateral ventricles ;
its upper border is continuous with the corpus callosum, its posterior with the fornix,
and its inferior with the reflected portion of the corpus callosum in front, and with the
inferior peduncles of that body farther back. Hence Vicq d'Azyr imagined that the sep-
tum lucidum was a continuation of these peduncles.
The septum lucidum is composed of two very delicate and completely distinct lamel-
lae (t t, fig. 278), between which, in front, a cavity is enclosed, containing a few drops
of a serous fluid ; this small cavity is called the ventricle of the septum, the first ventricle
{Wenzel), the fifth ventricle (Cuvier), and the sinus of the median septum (Chauss.) ; it is
not very unfrequently the seat of dropsical effusion. I have found it filled with blood in
several subjects after death from apoplexy.
As to whether this ventricle of the septum communicates with the other ventricles,
opinions are divided. Tarin describes a small fissure opening between the anterior pil
lars of the fornix, but the majority of anatomists have not. been able to demonstrate it
It appears to me that the absence of all communication is a well-ascertained fact.
Each of these lamella; of the septum lucidum consists of a medullary layer, covered
on the outside by the membrane of the corresponding lateral ventricle, and on the inside
by the membrane of the fifth ventricle. The existence of this last-mentioned membrane
is proved by the smooth appearance of the ventricle, and it may be demonstrated by re-
* The best mode of examining the lower surface of the corpus callosum is to view it by opening the ventri-
cles from the base of the brain.
t One is astonished to read, in Chaussier's work, that the notch of the posterior extremity of the corpus
■ callosum is caused by the alternate movements of elevation and depression of the brain. At each elevation,
according to him, this extremity of the corpus callosum strikes against the free margin of the falx cerebri al-
though that margin is at some slight distance from it.
THE FORNIX AND CORPUS FIMBRIATUM.
739
Fig. 278.
moving, in succession, layers from the outer surface of the lamella. The gray matter of
the third ventricle is prolonged upon the external surface of each lamella of the septum
The Fornix and Corpus Fimbriatum.
The fornix (la voute a trois piliers, k, r r, fig. 278) is a medullary arch, situated (i,
fig. 282) beneath the corpus callosum,
with which it is continuous behind,
but which it leaves in front, and then
passes perpendicularly downward, de-
scribing a curve within the curvature
of the corpus callosum. The interval
between the anterior part of the fornix
and the corpus callosum is occupied
by the septum lucidum. To the term
fornix, used by the older writers, the
epithet a trois piliers has been improp-
erly added by Winslow, inasmuch as
it expresses a mere appearance ; for
there are in reality /owr pillars, the two
anteriQf of which are closely approxi-
mated to each other, while the two
posterior are widely apart.
The fornix resembles an isosceles
triangle {trigone cerebral), having the
anterior angle very much elongated
and soon bifurcated ; its posterior an-
gles suddenly diverge, pass downward
and outward, and are prolonged (r r)
into the inferior or reflected portions
or descending cornua of the lateral
ventricles, where they constitute Che
corpora fimbriata (s) ; or, rather, the
fornix may be said to be composed of
two perfectly distinct medullary cords,
which are applied closely to each other, become broader and flatter as they proceed
backward and downward, and separate from each other opposite the reflected portions
of the lateral ventricles, into which they enter. The fornix, therefore, resembles the
letter X placed horizontally, the anterior limbs of which are close to each other (be-
tween q q) and very short, while the posterior limbs (r r) are very long and widely apart.
The term fornix is really applicable only to that portion which is applied to the corpus
callosum. Reil, who has described and figured this part better than any of his prede-
cessors, not even excepting Vicq d'Azyr and Soemmering, calls the fornix the twain-band.
The superior surface of the fornix corresponds, in the median line, to the septum luci-
dum in front, and to the corpus callosum behind : on each side it is free, and forms a part
of the floor of the lateral ventricles. The choroid plexuses (jp p) are sometimes reflect
ed upon the surface of the fornix.
In order to understand the relations of the fornix with the corpus callosum, it is ne-
cessary to bear in mind that it is composed of two flat medullary bands. Now the inter-
nal contiguous borders of these bands are turned upward, and adhere to the lower sur-
face of the corpus callosum, so as to form a small vertical septum, which is continuous
with the back part of the septum lucidum. The medullary fibres of the septum lucidum
are therefore generally considered to be continuous with those of the fornix.
The inferior surface of the fornix (r r, fig. 279) rests upon the velum, interpositum {v),
which separates it from the third ventricle (c b x, fig. 280) and the optic thalami {I I), the
internal portion of which bodies is covered by the fornix (see^o'. 278). It is upon the
posterior portion of this inferior surface, where the two medullary bands of the fornix
separate from each other to enter the descending cornua of the lateral ventricles, that
we find that regular though variable arrangement of transverse fibres (s), abutting on
certain longitudinal fibres (r r), which has been named the lyra, corpus psalloides or psal-
terium. I have already noticed this structure, which was erroneously regarded by Gall
as composed of the uniting fibres of the fornix.
The edges of the fornix are thin and free, and are bordered by the choroid plexuses.
The anterior pillars of the fornix {k, figs. 279, 280), which Vieussens, Tarin, and others
described as arising almost indifferently either from the cerebral peduncles, or from the
anterior commissure (c, fig. 280, situated in the third ventricle), can only be well seen
in a longitudinal vertical section of the cerebrum made exactly in the median line. Each
half of the cei-ebrum will contain the corresponding band of the fornix ; and it will then
be seen, as was first described by Santorini, that each anterior pillar (seen below k and
behind c,fig. 282) arises from the corpus albicans (z) of its own side : hence these bodies
740 NEUROLOGY.
have been called the bulbs of the fornix. The whole of the white covering of each of the
corpora albicantia (/, fig. 283) appears to be formed into a thick white fasciculus or cord,
which passes upward,- and may be very easily traced with the handle of the scalpel
through the soft gray matter which forms the inferior and anterior portion of the wall of
the third ventricle. While passing through this gray matter the cord describes a curve,
having its concavity turned backward, and is situated between the optic thalamus and
the corpus striatum, and behind the anterior commissure {c,fig. 282 ; m, fig. 283) ; having
emerged from the gray matter, which is still prolonged along its anterior surface and
thus reaches the septum lucidum {t), the anterior pillar is reflected backward {h, fig. 283)
in front of the optic thalamus, and becomes changed into a flat band {k,fig. 282), which
is applied to the thalamus (/), and follows the contour of that body : at the point where
the anterior pillar of the fornix changes from an ascending to a horizontal direction, it
forms half a ring (situated behind and below k,fig. 282), which is completed by the an-
terior part of the optic thalamus. This is the opening of the foramen of Monro, by which
a communication is established (opposite q q, fig. 278) between the third and the corre-
sponding lateral ventricles.
The Posterior Pillars. — Having arrived opposite the back part of the optic thalamus,
each of the lateral bands of the fornix, which had already been directed somewhat ob-
liquely outward, passes abruptly and very obliqely outward and downward (r r) into the
descending cornu (A) of the corresponding lateral ventricle, and is there divided y;ito two
parts, one of which forms the superficial medullary substance of the cornu ammonis, or
hippocampus major (m), while the other follows the concave border of the hippocampus,
and takes the name o{ corpus fimhriatum (s), corps frangi, corps borde. We shall again al-
lude to these parts in describing the lateral ventricle.
I have said that the anterior pillars arise from the corpora albicantia, but they have a
much deeper origin, which was figured by Vicq d'Azyr, and has been still better descri-
bed by Reil. According to that anatomist, they arise within the optic thalami. I have
traced them much farther than Reil, as far as the tcenia semicircularis on each side ; or,
rather, each tania semicircularis {n, fig. 278), which is situated in the lateral ventricle be-
tween the corpus striatum (i) and the optic thalamus {I), and which is continuous with
the anterior corpus quadrigeminum or natis of its own side, becomes subdivided into two
bands, which may be regarded as the roots of the corresponding anterior pillar of the for-
nix. Of these two roots, one is superficial (w), and easily seen without dissection ; the
other is deep-seated {v, fig. 283), enters into the substance of the optic thalamus, runs
forward to the corpus albicanus (/), spreads out and forms the surface of that body, and
then curves upward to constitute the anterior pillar of the fornix (A), at the point where
it emerges from the gray matter.
The two bands of the fornix also receive some other white fibres, which greatly mul-
tiply its connexions. Thus, as they are traversing the gray matter, the anterior pillars
receive additional medullary fibres, some arising from the gray matter itself, and others
from the commissure of the optic nerves ; again, just as they emerge from the gray mat-
ter to become horizontal, they receive a considerable cord, formed conjointly by the white
fibres covering the optic thalamus {g, fig. 283) by a white band, which runs longitudinal-
ly along the optic thalamus, and is continuous with the corresponding peduncle of the
pineal gland, and by the superficial fibres of the taenia semicircularis, of which I have al-
ready spoken. These three sets of fibres form a cord of considerable size, which is bent
abruptly backward, and becomes continuous with the fornix. Lastly, the fornix receives
or, perhaps, it gives origin to, the white radiated fibres of the septum lucidum.
Fig. 279. ffig Velum Interpositum.
Beneath the fornix is situated a vascu ar memorane, a pro-
longation of the external pia mater : this is the velum interposi-
tum, or tela choroidea (v, fig. 279), so named by Herophilus from
its tenuity, which he compared to that of the fcetal membrane
called the chorion.
It is thus formed : the external pia mater, having arrived be-
low the enlarged posterior extremity of the corpus callosum,
penetrates (at r,fig. 282) into the interior of the brain between
that body and the tubercula quadrigemina, and forms a sort of
triangular web {v, fig. 279), the base of which is turned back-
ward, and the truncated and bifurcated apex forward. The up-
per surface of the velum is covered by the fornix (reflected at
r r), to which it transmits a great number of vessels. Its infe-
rior surface forms the root of the third ventricle, and corresponds
on each side to the upper and to a small part of the inner sur-
face of the optic thalami (/ /). The velum is also in relation with
the venae Galeni and with the pineal gland {p, fig. 282), adhering
very closely to that body, and forming a nearly complete invest-
ment for it, so that they are almost always removed together
THE MIDDLE OR THIRD VENTRICLE.
741
Sicfiat Sescribed his so-called arachnoid canal as passing beneath the velum interposi-
tum. Upon the lower surface of the velum, which can only be properly examined from
below, are found two small trains of red granulations, precisely similar to the choroid plex-
uses of the lateral ventricles, with which they are continuous in front : they may be call-
ed the choroid plexuses of the third ventricle.
The lateral borders of the velum are continuous with the upper part of the choroid plex-
uses {pp,figs. 278, 279) of the lateral ventricles.
The anterior extremity, or apex of the velum, is bifid ; each branch of the bifurcation
passes from the third into the corresponding lateral ventricle (behind k,Jig. 282, opposite
q q, Jig. 278), behind the anterior pillar of the fornix, and constitutes the anterior extrem-
ity of the choroid plexus.
The velum interpositum is formed by the pia mater, supported by a tolerably strong
fibrous layer.
When the fornix and the velum (as in Jig. 280) are removed, we arrive at a cavity call-
ed the middle or third ventricle.
The Middle or Third Ventricle.
Dissection. — In order to expose the third ventricle from the base of the brain, the right
Fig. 280.
peduncle of the cerebrum and the right
corpus albicans should be separated
from those of the left side by a longi-
tudinal section in the median line.
There is another section, which I rec-
ommend as exceedingly well adapted
to exhibit all the parts contained in the
third ventricle ; it is made from before
backward, and on either the right or
left side of the median line, so as to
leave both of the lateral walls of the
third ventricle uninjured.
The third ventricle (c to x, figs. 280,
282) is situated in the median line, near
the base of the brain, between the op-
tic thalmi (Z I, fig. 280) and in front of
the tubercula quadrigemina {fg) : it ap-
pears like a very narrow cavity, oblong
from before backward, and of greater
extent below than above ; it is not so
much a cavity as a fissure between the
two optic thalami. Vesalius compared
this ventricle to a valley, the hills on
either side of which were very closely
approximated to each other, and uni-
ted by a sort of bridge, represented by
the commissura mollis {h).
The superior orijice of the third ven-
tricle is surrounded by a white rim or
border (s), which forms, behind and on
either side, the peduncles of the pineal
gland.
The lateral walls {I, fig. 282) are plane, smooth, and of a gray colour ; they are formed
by two very distinct parts, viz., above and behind by the internal surface of the optic
■thalamus, and below and in front by the internal surface of a gray mass, which appears
to me to deserve a particular description under the name of the gray mass of the third
ventricle.
That part of the internal wall of the ventricle which is formed by the optic thalamus
is marked off by a horizontal groove from the part formed by this gray mass.
The internal surface of this gray mass is smooth, and lined by the membrane of the
ventricle. The externed surface is continuous with the rest of the brain ; below, it forms
the tuber cinereum, or base of the infundibulum, passes around the corpora albicantia,
the anterior pillars of the fornix and their roots, is prolonged upward upon the sides ot
the septum kicidum, and downward as far as the upper surface of the optic commissure,
the posterior border of which is imbedded in this gray mass, and receives from it a short
white root on each side.
The lateral walls of the third ventricle are united together, opposite the anterior part
of the optic thalami, by a gray substance called the soft commissure, commissura rnollis (b),
the gray commissure, and also the vascular commissure of the optic thalami ; it varies much
lu size, and is very easily torn ; but I have always found the remains of it in those cases
T®! NEUROLOGY.
in which it appeared at first sight to be wanting.* I regard the soft commissure as a
prolongation of the gray mass of the third ventricle, and this substance appears to me to
be of the same nature as the gray matter of the convolutions.
The floor of the third ventricle is of greater extent than the walls of that cavity ; it is
concave upon its upper or ventricular surface, and convex below. We shall divide it
into three portions : the posterior portion of the floor (above n, fig. 282) is deeply grooved
along the median line, forms an inclined plane sloping downward and forward, and cor-
responds to the interval between the peduncles of the cerebrum ; its white colour, which
is scarcely concealed by the thin layer of gray matter upon it, contrasts strongly with
the distinct gray colour of the lateral walls. The middle portion of the floor is funnel-
shaped, and corresponds to the corpora albicantia {z), and to the infundibulum (i) ; it leads
to the canal in the infundibulum. The anterior portion of the floor (m) is inclined down-
ward and backward, and is formed by a very thin, semi-transparent layer of gray sub-
stance {lamina cinerea), which we may call, with Tarin, the pars pellucida, and which is
supported by a fibrous layer derived from the pia mater.
In front, the third ventricle presents the anterior pillars {k,fig. 280, below I, and be-
hind c, fig. 282) of the fornix, in front of which is situated a white cylindrical cord (c),
directed transversely, and visible only in its middle portion ; this is the anterior commis-
sure, beneath which the ventricle extends as far as opposite the posterior border of the
optic commissure. Beliind the anterior pillars of the fornix, and somewhat above the
anterior commissure, are the two openings by which the third ventricle communicates
with the lateral ventricles {foramen Monroi) ; these openings (of which one is seen be-
tween b and k,fig. 282) are of an oval shape, are sometimes of unequal size, and become
much enlarged in chronic effusion into the ventricles. The two divisions of the ante-
rior extremity of the velum interpositum pass through these openings, to become con-
tinuous (at q q, fig. 278; with the choroid plexuses. Haller erroneously regarded them
as accidental ; an opinion that was founded upon several pathological observations, from
which it appeared that the lateral ventricles were distented with a considerable quantity
of fluid, while the third ventricle remained empty.
At the back part of the third ventricle is seen the posterior commissure {x, figs. 280,
282), a transverse cylindrical cord, situated in front of the tubercula quadrigemina, and
below the commissure of the pineal gland, with which it is continuous. The posterior
commissure is smaller than the anterior ; it may be regarded as a white commissure of
the optic thalami, for its extremities are lost in their interior. It forms a sort of bridge
above the anterior orifice of the aqueduct of Sylvius.
The Aqueduct of Sylvius.
The aqueduct of Sylvius, or aqueduct of the corpora quadrigemina, which was descn-
oed by both Galen and Vesalius, and by the latter quite as perfectly as by the anatomist
after whom it was named, is a canal which establishes a communication between the
third and fourth ventricles {I v,fig. 282) — iter a tertio ad quartern ventriculum ; it passes
through the isthmus of the encephalon, in the median hue, below the tubercula quadri-
gemina (/^). It is directed obliquely downward and backward. Its walls are dense,
and lined by the membrane of the ventricles. This canal presents both on its upper and
its lower wall a longitudinal groove or median furrow, bounded by two small longitudi-
nal cords. The median furrow on the lower wall is continuous with the longitudinal
gioove of the calamus scriptorius. The brothers Wenzel have given a minute descrip-
tion of these two furrows, and they have also noticed two lateral furrows. It was stated
by Vieussens that the opening of the aqueduct into the fourth ventricle was provided
with a valve. But his statement is at variance with the results of observation.
It follows, therefore, from the preceding description, that the third ventricle has four
openings, two of which communicate with the lateral ventricles, the third opens into the
fourth ventricle, and the fourth (between b and x, 380) leads into the infundibulum.
The third ventricle, moreover, has three conunissures : one composed of gray matter,
viz., the commissura mollis, or commissure of the optic thalami ; the other two of white
substance, one being anterior and the other posterior.
The Conarium, or Pineal Gland.
The conarium, pineal gland, or pineal body, is a small grayish body ( p, figs. 280, 282)
situated in the median plane, behind the posterior commissure of the third ventricle, and
between the nates, upon which it rests.
It is retained in this situation by two small medullary cords, which are Ccdled its ped-
uncles, and by the velum interpositum, below which it is placed, and by which it is almost
completely invested as with a closely-adherent sheath : the adhesion between these parts
is so intimate that they are almost always removed together ; and hence some anato-
mists have regarded the conarium as a dependance of that membrane, and others, who
* Out of sixty-six brains of subjects of all ages examined by the brothers Wenzel, the soft oommissure was
found in fifty-six. It was, therefore, wanting in ten cases. The facility with which it is lacerated may have
misled these industrious investigators into a belief that its absence was more frequent than it actually is.
THE CONARIUM, OB PINEAL GLAND. /43
hare not been careful in their examinations, have declared that it is sometimes want-
ing in the human subject. This body, however, always exists in man and the mamma-
lia. It is wanting in birds and fishes, and in reptiles, with the exception of the tortoise,
in which it is so remarkably large that it forms by itself a kind of brain. — (Desmoulins,
Anat. dti Syst. Nerv., t. i., p. 211.)
This body is shaped like a cone, having its adherent base turned forward and its free
apex backward ; hence its name of conarium {Oribasius, Galen) ; it has also been com-
pared to a pine cone, and has been named the pineal gland, or jiineal body. Its form,
however, is subject to some variety ; it is sometimes spheroidal, and at other times cor-
diform, from being notched at the beise.
The pineal body is small, being only about four lines in length, and from two to three
lines wide at the beise. Its size, in the animal series, does not appear to bear any pro-
portion to the size of the cerebrum, or of the cerebellum, or of the tubercula quadrigem-
ina, so that comparative anatomy throws no light upon this obscure subject. Neither
age nor sex has any influence upon the development of this small body.
Relations. — The conarium or pineal gland, enclosed in the pia mater, Hke the cere-
brum and cerebellum, rests upon the slight triangular depression between the nates : the
venae Galeni run along its sides.
When stripped of the pia mater, it is free in all directions, excepting at its base, which
is connected with the encephalon by a transverse commissure, situated above the posteri-
or commissure of the cerebrum, and hy /our slender peduncles, two of which are superior
and two inferior. The superior peduncles (s, Jigs. 280, 282), which are the only ones gen-
erally described, form together a sort of loop, the two ends of which run along the tops
of the optic thalami ; they have been named the reins of the pineal body {habence). We
have already seen that they are continuous with the fornix. The inferior peduncles,
which are distinctly seen only upon a longitudinal vertical section through the middle of
the cerebrum, arise from the base of the pineal body, pass vertically downward upon the
back part of the internal wall of the third ventricle, and may be traced to the lower part
of that cavity.*
Colour and CoTisistence. — The reddish-gray colour of the pineal body contrasts strong-
ly with the whiteness of its commissure and peduncles. The colour and consistence of
this body exactly resemble those of the gray matter of the cerebral convolutions. If it
be compressed between the fingers, a viscid juice exudes, and certain small concretions
are found in it, which I shall notice after having described the structure of this organ.
Structure. — At the base of the pineal body are seen some white or medullary fibres,
which arise from the conuuissure and from the superior peduncles of that organ. These
white fibres spread out into a tuft, and terminate abruptly. All the rest of the conarium
consists of gray matter. On making a horizontal section of this body, it is sometimes found
to be solid, and sometimes to be hollow, and to contain a transparent, viscid fluid. The
cavity is lined by a vascular membrane, and, according to Meckel, by a layer of medul-
lary substance, which I have never seen. It has been stated that it communicates with
the third ventricle ; but I am inclined to believe, with Santorini and Gerardi, that the
conmiunicating orifice admitted by some authors is the result of traction upon the base
of the conarium in attempting to remove the pia mater.
When the pineal body contains no distinct cavity, which is not unfrequently the case,
the viscid fluid is distributed through it as through a sponge.
As to the nature of this body, it appears to consist of a soft gray substance, traversed
by a great number of bloodvessels, having a very close resemblance to the gray matter
of the brain, but none whatever to glandular tissues.
Concretions of the Conarium. — One of the most curious circumstances in regard to this
body is the existence in it of certain hard concretions, which Ruysch and others regard-
ed as small bones, an error which was successfully combated by Soemmering. The
use of them is utterly unknown.
Are these concretions constant 1 The brothers Wenzel found them wanting in six
brains out of one hundred. Soemmering states that he found them in fifteen brains,
among which were some of very young infants, and he adds that they exist in the foetus
before the full period. Meckel says they do not appear until the sixth or seventh year,
beyond which age he always found them.
These concretions sometimes form a single mass (acervulus, Sammering), resembling
a granular lump of salt ; sometimes, and most commonly, there are a great number of
them.
They appear as aggregated granules, which the Wenzels believed to be connected by
means of a proper membrane. . .' .
Seat of the Concretions. — When the pineal body is hollow, they are found in its interi-
or ; but when it is solid, they are situated upon the surface of this body. I have found
them several times upon its peduncles.
•■' Ridley describes certain white striae, arising from the pineal body, and terminating in the testes. Gall
Bays that the inferior peduncles are directed backward, and somewhat downward, to become continuou* with
the snb'acent white lamina. Plate xi., text, p. 223.
m
NEUROLOGY.
They are of an opaline yellow colour in old subjects, and are whitish in the young.
According to Pfaff, they consist of phosphate of lime, carbonate of lime, and an animal
matter.
They were incorrectly regarded as morbid deposites by Morgagni, who supposed, with-
out proof, that they might produce cerebral affections of greater or less severity.
Function of the Pineal Gland. — The hypothesis of Des Cartes concerning the function
of this body, which was so completely refuted by Steno, is a striking example of the
abuse of an imperfect knowledge of anatomy ; according to Des Cartes, the soul is seated
in the pineal gland, and it directs all the movements of the body by means of the pedun-
cles, which he regarded as the gubernacula or reins of the soul. M. Magendie thinks
that this body performs certain functions having reference to the cerebro-spinal fluid :
he has regarded it as a kind of plug, which would obstruct the orifice of communication
between the third and fourth ventricles ; but, in the first place, it is completely fixed by
the pia mater ; and in the second case, even if it were free, it could not in any case close
the orifice alluded to. Morbid conditions of this body will perhaps throw some light upon
its functions, but they have not yet been sufficiently studied. The existence of a cavity
within the pineal gland, added to the fact that it is sometimes the seat of dropsy, would
seem to indicate that its functions are connected with secretion.
The Lateral Ventricles.
Dissection. — The lateral ventricles are exposed by the same dissection as that which
we have pointed out for the examination of the fornix and septum lucidum, that is to
say, by removing the upper parts of the hemispheres and dividing the corpus callosum
on each side of the median line (as in fig. 278, on the left side). In order to trace the
reflected portion or descending cornu, it should be laid open by cutting through its outer
wall from behind forward. There is also a great advantage in studying this part of the
lateral ventricles from the base of the brain.
The lateral ventricles {fig h,fig. 278) are two in number; they are much larger than
the other ventricles ; are placed symmetrically one on each side of the median line ;
they are separated from each other, but communicate through the medium of the third
ventricle ; their upper part is nearer to the base of the brain than to its upper surface,
and they approach still nearer to the base by their reflected portion or descending cornu.
Each lateral ventricle commences (/) in the substance of the anterior lobe (a), a little
in front of the third ventricle, and behind the anterior reflected extremity of the corpus
callosum (c), by which it is bounded in front ; from this point it passes vertically upward
and backward, describing a curve with its convexity directed inward ; having reached
(r) opposite the posterior part of the third ventricle, it changes its direction, so as to
turn downward and forward round the optic thalamus (/), and then terminates (h) in the
substance of the sphenoidal portion of the posterior lobe [i. c, in the middle lobe] (c) be-
hind the fissure of Sylvius, and, consequently, a little below and behind the point (/) at
which it commences. At the point of its reflection it also sends a prolongation (g)
backward into the occipital portion of the posterior lobe (J). From this it will be under-
stood why each lateral ventricle has been compared to a capital italic £ turned upside
down, and why the cavity is said to have three cornua, viz., an anterior or frontal (/),
an inferior, descending or sphenoidal (A), and a posterior or occipital cornu (g) ; on this ac-
count the lateral ventricles are frequently denominated ventriculi tricornes.
It is also seen that the ventricles are applied to each other at their anterior extremi-
ties, but diverge behind like the limbs of the letter x.
The general form of the lateral ventricles is very well shown upon a longitudinal sec-
tion of the cerebrum through the median line ; each of these ventricles is then seen to
be nothing more than an elliptical canal or passage, which runs around the large ellip-
soid mass formed by the optic thalamus and corpus striatum. This elliptical canal is
ooly interrupted below and in front opposite the fissure of Sylvius. Anatomists describe
in each lateral ventricle a superior portion, an inferior portion, and a posterior portion or
digital cavity.
The Superior Portion of the Lateral Ventricle.
This portion, called the body of the ventricle (i), is broader in front than behind, and
presents for our consideration a superior, an inferior, and an internal wall.
The superior uall, or the roof, is formed by the under surface of the corpus callosum.
The inferior wall, or the floor, is formed by the ventricular surfaces of the corpus striatum
(i) and optic thalamus {1} ; between these two bodies are found the lamina cornea and
t(eni& scmicircularis (m).
The Corpus Striatum. — When examined from the lateral ventricle, each of the corpora
striata (i i,figs. 278, 280) appears like a pear-shaped or conoidal eminence, having its
larger end turned forward, and its other end, which is very narrow, prolonged backward,
into the reflected portion of the ventricle. Its gray colour contrasts with the whiteness
of the surrounding parts. Its free surface is covered by the lining menibruiie of the ven-
tricles, and is very regularly marked by certain large veins which run neross it.
THE LATERAL VENTRICLE. 745
The ventricular surface of the corpus striatum fonns only one portion of this body,
which has received its name from the white bundles or striee which traverse the gray
matter, of which it is principally composed.
The corpus striatum, considered as a whole, is an ovoid gray mass, lodged in a deep
excavation formed opposite the insula or island of Reil, which is situated in the fissure
of Sylvius, and which I propose to name the lobule of the corpus striatum. It will be seen,
hereafter, that the corpus striatum is covered on the outer side by the convolutions of
the insula, that it corresponds on the inner side with the optic thalamus and the gray
matter of the third ventricle, and that it is exposed below, at the back part of the ante-
rior lobes of the brain, behind the convolutions which form the sides of the furrow for
the olfactory nerve.
The aplic thalami {I I, Jig. 280), which, as we have already seen, constitute the lateral
walls of the third ventricle, form also, by their upper surface, a part {I, fig. 278) of the
floor of the corresponding lateral ventricle ; this surface, which is oblong from before
backward, conunences about six lines from the anterior extremity of the lateral ventri-
cle : it is covered by the choroid plexus ( p) and the fornix (k) : the corresponding ante-
rior pillar of the fornix turns round its anterior extremity, and the interval between the
pillar and the thalamus forms the opening of communication between the third and the
corresponding lateral ventricle. The brownish-white colour {couleur cafe au lait) of
the optic thalamus distinguishes it from the corpus striatum, which lies along its outer
side, the lamina cornea and the taenia semicircularis marking the limits between these
two bodies.
The lamina cornea is a thick, semi-transparent band, of a homy aspect, which was com-
pared by Tarin to a plate of horn, and which appears to be nothing more than a thick-
ened portion of the lining membrane of the ventricle. Beneath and protected by it is
found the vein of the corpus striatum, which receives the venous branches already de-
scribed upon the surface of that body. Beneath the vein is seen a small, white, linear
band («), to which Willis first directed attention as the limhus posterior, and which is
now called the tania semicircularis.
I would observe, that the lamina cornea and the taenia semicircularis are two very
distinct structures, which most anatomists have erroneously confounded.
More deeply, the limits between the corpus striatum and optic thalamus are marked
by a white layer, described by Vieussens as the geminum centrum semicirculare, or double
semicircular centre.
The lateral portion of the fornix and the choroid plexus (see fig. 278) must also be re-
garded as entering into the formation of the floor of the lateral ventricle. This lateral
portion of the fornix resembles a band applied upon the optic thalamus, but separated
from it by a fissure through which the choroid plexus becomes continuous with the ve-
lum interpositum :* the choroid plexus runs along the free edge of this band, and is some-
times turned up on to its upper surface.
The internal wall, or septum of the lateral ventricles, is much deeper in front, where it is
formed by the septum lucidum, than behind, where it consists of a small vertical portion
of the fornix, with which it terminates. We ought also to regard as forming a part of
the septum of the lateral ventricles a prolongation on each side of the gray matter of
the third ventricle, which passes round the corresponding anterior pillar of the fornix,
and upon the lower part of the septum lucidum.
The Inferior or Reflected Portion of the Lateral Ventricle.
Dissection. — ^As the reflected portion or descending cornu belongs to the base of the
brain, it is well to place the brain upon its convex surface, and then proceed to open it.
This cornu may also be reached from the great transverse fissure, by first removing
the pia mater which enters there, and then partially dividing the lower wall of the cornu
from the fissure of Sylvius backward, and turning back the lower wall on itself
The descending cornu {h,fig. 278) of the lateral ventricle has two walls, a superior and
an inferior. The superior wall {b,fig. 281) is concave, and, being moulded upon the pes
hippocampi or cornu ammonis (m), which forms the inferior wall, is named the sheath of
the pes hippocampi.
Upon the inferior wall are found the pes hippocampi or cornu ammonis, the corpus fim-
briatum, the fascia dentata, the great cerebral fissure, and the reflected portion of the choroid
plexus.
The cornu ammonis or ram's horn, pes hippocampi,i or foot of the sea-horse, is a conoidal
eminence {m,fig. 278)1: curved upon itself, and having its larger end turned forward, and
* [A comparison of Jigs. 1~S and 279 will facilitate the comprehension of this statement, in the latter ^^.
the fornix is reflected backward, and the continuity of the choroid plexus (p) with the velum (v) is shown.]
t [The term pes hippocampi is generally applied to the anterior part only of this structure, the whole being
usually called hippocampus major.
% 1 have not found, like Treviranus, the medullary substance of the anterior extremity of the cornu ammo-
nis either continuous or communicating in any manner with the external root of the olfactory nerve , I cannot,
therefore, admit that the functions of the cornu ammonis have any relation with those of the nerves in ques-
tion. Treviranus believes that it assists m the remembrance of olfactory impressions. It is unfortunate foi
5B
7#6 NEUROLOGY.
its small end backward. Its concave border, which is directed inward and forward, is
bounded by a narrow, thick, and dense band, which forms a continuation of the posterior
pillar of the fornix ; mis is the tccnia hippocampi, so improperly named the corpus fimhri-
atum, OT fringed body («).
On raising up the taenia hippocampi {s,Jig: 281), there is seen beneath it a band of
Fig. 281. gray matter (d), which runs along the inner border of the cornu am-
monis : this gray matter, which is, as it were, crenated by transverse
furrows, has been well described by Vicq d'Azyr, under the name of
corps godronni, or fascia dentata.
To obtain an accurate idea of the cornu ammonis, it is necessary to
examine vertical sections of it, as was done by Vicq d'Azyr, who has
given very good figures of such sections : it is then seen (as in fig.
281) that the hippocampus major {m) is formed by a reflection of the
hemisphere inward upon itself, as the brothers Wenzel have very well
shown ; and that it is composed of a convolution doubled or turned
upon itself like a horn, so that the white convex part expands in the
interior of the lateral ventricle, while the gray concave part is upon
the surface of the cerebrum.*
The surface of a vertical section of the hippocampus major also pre-
sents a white spiral line (below m), which is the section of the white
covering of this eminence, and a rather thick gray layer (a), which is subdivided into two
smaller layers by a white streak (c) ; all these are arranged in a spiral manner.
The white layer which forms the covering of the cornu anamonis is continuous, on the
one hand, with that which lines the rest of the lateral ventricle, and on the other (by
means of the corpus fimbriatum, s) with the corpus callosum and the fornix. Not un-
frequently a second pes hippocampi is found on the outer side of the first, to which it is
concentric ; it is called pes accessorius {eminentia collateralis). Meckel erroneously re-
gards it as the result of an arrested development.
The inferior wall of the descending portion of the lateral ventricle farther presents for
our consideration,
The reflected or descending portion of the choroid plexus (see Jig. 278) ; and also the great
transverse fissure, through which the choroid plexus becomes continuous (opposite s,_^^.
281) with the external pia mater : the lower border of this fissure is formed by the hip-
pocampus major and corpus fimbriatum ; and the upper border by the lower surface of
the optic thalamus, which presents in this situation the corpus gcniculatum externum (j,
fig. 271), an oblong eminence, which is continuous with the optic tract, and the corpus
geniculatum internum (i), a small rounded eminence, which is circumscribed by the corpus
geniculatum externum.
The Posterior Portion of the Lateral Ventricle.
The digital or ahcyroid cavity {uyKvpa, a hook) is the occipital portion (g, fig. 278) of
the lateral ventricle. The term digital cavity has arisen from its having been compared
to the impression which the finger would leave if pushed backward into the substance
of the brain. It commences at the point where the ventricle is reflected upon itself,
passes horizontally backward, describing a curve with the convexity turned outward, and
becomes gradually narrower, until it terminates in a point. The dimensions of this
cavity are extremely variable, not only in different individuals, but even in the same sub-
ject. Thus, a very large digital cavity is often found on the right side, while on the left
there is only a trace of it.
Acute ventricular hydrocephalus affects the digital cavity more than any other part of
the ventricle, t In some cases the bottom of the digital cavity is not more than half a
line from the surface of the brain.
In the natural state, the upper wall of the digital cavity is exactly fitted to a conoidai
eminence, which occupies the lower wall or the floor of that cavity, and which differs in
its dimensions according to the size of the cavity itself This eminence (n), which is
variously named the unciform eminence, colliculus, calcar, unguis, was very well described
by Morandjt under the name of the ergot, and is therefore generally called the ergot of
Morand.
In form it rather closely resembles the hippocampus major, so that we ought, perhaps,
to prefer, with Vicq d'Azyr, the name of hippocampus minor. There is not only a cor-
respondence in form, but also in structure, between the two hippocampi ; and the broth-
ers W^enzel appear to me to have clearly shown that the ergot of Moraad, like the hip-
this hypothesis, that the animal in which the cornu ammonis is most developed, viz., the liare, is precisely
that in which there is least evidence of memory.
* I could never perfectly understand the structure of the cornu ammonis until I had eiamined it in rumi-
nantia and rodentia, but especially in the latter, in which it is most developed. In the rodentia the reflected
portion of the hemisphere is almost as large as the hemisphere itself, and the connexions of the cornu amnio-
nis with the fornix are seen most distinctly. It is quite evident that the fornix, the curnu ammonis, and the
corpus fimbriatum, form only one system of fibres, and are continuous with each other.
t It is probable that this is simply the mechanical effect of long-continued tying upon the back.
t Mem. de I'Acad. des Sciences, 1744. Observ. Anatomiques sur Quelques Parties du Cerveau
THE CHOROID PLEXUSES, ETC. 747
pocampus major, is nothing more than a special convolution projecting into the ventri-
cle. It, in fact, consists of a white layer, enclosing a thick mass of gray substance. A
longitudinal anfractuosity, the depth of which depends on the prominence of the ergot,
denotes on the surface of the brain the situation of the digital cavity : this anfractuosi-
ty is constant, and I have already described it as the anfractuosity of the digital cavity.
There is also another circumstance which favours the analogy between the ergot and
the hippocampus major, and that is their continuity ; for there is only a depression be-
tween them, and the white layer which connects them is continuous in both cases with
the fornix.
Gredinsh as described several varieties of the ergot ; not unfrequently it is double, and,
as we have mentioned, so is the hippocampus major. The absence of the ergot is re-
garded by Tiedemann as the result of defective development.
The ergot and the digital cavity scarcely exist except in man, doubtless because he
alone has the occipital portion of the brain greatly developed.
The Choroid Plexuses.
The choroid plexuses of the brain, which have already been noticed in the descriptions
of the third and lateral ventricles, form a continuous system of vessels, as can be easily
shown by examining the brain from the base upward. Upon the under surface of the
velum interpositum, and on each side of the median line, are two small, red, granular
bands, running from behind forward, bordered by the veins of the corpora striata, and
terminating in front upon the convexity of an arch which forms the boundary of the ve-
lum in that direction. This arch is formed by the junction of the anterior extremities
of the choroid plexuses. It is situated behind the anterior pillars of the fornix, at the
point where those pillars unite, and is crossed at right angles by the veins of the corpus
striatum, which pass above it ; after this junction, the choroid plexuses again separate
and enter the lateral ventricles through the foramen (foramen of Monro) which leads
from the third to the lateral ventricles ; within each of the lateral ventricles they de-
scribe an elliptical curve {p, fig. 278), which is accurately moulded upon the optic thala-
mus, and runs along the fornix in the upper part of the ventricle, and along the corpus
fimbriatum in the descending comu or reflected portion.
The upper part of the choroid plexus is very narrow ; the lower part is three or four
times broader than the upper ; its upper and under surfaces are free, and also its outer
border, which contains a large vessel ; its inner border is continuous with the velum in-
terpostum* in the upper part of the lateral ventricle, and in the descending cornu with
the pia mater, at the base of the brain.
The lining membrane of the ventricle adheres intimately to the inner border of each
choroid plexus, so that the lateral ventricles are completely closed, and no fluid can es-
cape through the semicircular fissure which extends along their entire course.
The choroid plexuses are granular, or, rather, consist of vascular tufts, which are un-
like any other structure in the body, and their uses are quite unknown.
The Lining Membrane and the Fluid of the Ventricles.
The middle and lateral ventricles are lined by a transparent and tolerably strong mem-
brane, of which the horny lamina between the corpus striatum and thalamus opticus is
a part. On tracing this membrane from the third ventricle, it is seen to pass into the
lateral ventricles through the foramen (of Monro), behind the anterior pillar of the for-
nix. From the third ventricle it dso descends into the fourth through the aqueduct of
Sylvius.
It is extremely easy to demonstrate this membrane, especially upon the septum luci-
dum and corpora striata, and in the digiteil cavities.
In order to separate it to any extent, it must be dissected from without, by gradually
removing the layers of cerebral substance by which it is covered. This separation oc-
curs in acute ventricular hydrocephalus, in consequence of the pultaceous softening of
the surrounding tissue. In the foetus and new-born infant, this membrane can be sep-
arated with the greatest facility, on account of its density and the softness of the sur-
rounding parts.
Three questions present themselves regarding the ventricular membrane : Is it a se-
rous membrane 1 Does it communicate with the araclmoid, so that it ought to be re-
garded as a continuation of that membrane 1 How is it arranged along the fissure of
each lateral ventricle 1
That the ventricular membrane is a serous membrane is shown by the nature of the
fluid exhaled into the cavity of the ventricles ; by the structure of the membrane itself,
which consists entirely of lymphatic cellular tissue ; and by the diseases of the ventricles,
which are precisely similar to those of other serous cavities. +
* Compare figs. 278 and 279.
t The occurrence of acute aud chrouic serous eflTusions, of purulent formations, aud of miliary grannlatlOM
in the ventricles, are proofs of the serous nature of their lining membrane.
[The ventricular membrane has a ciliated epithelium on its inner surface.]
im
NEUROLOGY.
The number of veins which are situated beneath the ventricular membrane has sug-
gested the notion that it was a prolongation or continuation of the pia mater ; but these
vessels do not belong to the membrane.
The continuity of the ventricular membrane with the arachnoid on the surface of the
brain has not been demonstrated. I have already said that the so-called canal of Bichat
does not exist.
It has been stated that each lateral ventricle is divided, both in its direct and reflected
portions, by a circular fissure which turns round the optic thalamus, and through which the
pia mater becomes continuous with the choroid plexus. This fissure is closed by blood-
vessels, and some very dense cellular tissue, and in the interior of the ventricle by the li-
ning membrane, which is firmly attached on both sides of the fissure to the adherent
borders of the corresponding choroid plexus. It cannot be admitted that it passes from
one side of the fissure to the other, so as to enclose the plexus.
It is this membrane which prevents any fluid contained in the ventricles from infiltra-
ting into the sub-arachnoid cellular tissue at the base of tlie brain.
The very frequent coincidence of ventricular dropsy with the formation of false mem-
brane in the cellular tissue at the base of the brain shows the relation between that tis-
sue and the lining membrane of the ventricles, but by no means establishes the exist-
ence of any direct communication between the ventricular cavities and the cellular tis-
sue at the base of the brain.
The Ventricular Fluid. — The existence of a serous fluid in the ventricles was general-
ly admitted by the older anatomists, who named it pituita, and considered it to be an
excrementitious fluid, which was evacuated through the nasal fossae. During the last
century, anatomists were so convinced of its existence in all subjects, that they regard-
ed those cases in which it was not found as exceptions ; a recentissimis cadaveribus ahest
nonnunquam, says Haller, in speaking of an observation made by Verduc upon the brain
after death by decapitation. But the anatomists of the last century differed from the
ancients in regarding the existence of fluid in the ventricles as a post-mortem phenome-
non, depending on the condensation, by cold, of a vapour which, in their opinion, alone
exists in the ventricles during life. This vapour, the only use of which, according to
the view stated, would be to prevent adhesion of the opposite walls of the ventricles,
was compared by them to that which is found in the pleura, pericardium, and peritoneum
of a living animal.
The experiments of M. Magendie have proved the existence of a ventricular fluid du-
ring hfe ; and farther, that it may flow backward and forward into the spinal sub-arach-
noid space, through the opening (,y,fig. 282) in the lower part of the fourth ventricle.
The quantity of fluid in the several spaces found in the cranial cavity is extremely
variable, for it increases or diminishes according to the relative bulk of the brain in ref-
erence to the osseous case of the scull.
Having thus examined the brain by horizontal sections, made at different heights
from the convex surface towards the base, it is important, in order thoroughly to under-
stand the parts we have described, to study them under different aspects, either by means
of particular sections, or by the aid of the various methods adopted by different anato-
mists.
Jt Median Vertical Section of the Brain.
Upon this section {fig. 282), which divides the brain into two perfectly similar halves,
p- 2g2 a great many objects
are seen : and first,
the optic thalamus
and corpus striatum,
which might be said
to form the central
nucleus or root of the
cc-ebrum.
The optic thalamus
is now seen to be
smooth and free on its
inner surface, where
it forms the lateral
wall (0 of tlie third
ventricle ; it is con-
vex and free above,
where it forms part
of the floor of the lat-
eral ventricle, and it is also free below, where it presents to our notice the corpora ge-
niculata. Behind, it is continuous with the tubercula quadrigemina, and in front with
the corpus striatum ; on the outer side it is blended with the corresponding cerebral
VERTICAL SECTION OF THE BEAIN. 749
hemisphere, and below it is deeply notched for the reception of the corresponding cere-
bral peduncle.
The corpus striatum forms a concentric curve along the outer side of the opic tliala-
mus ; it commences in front by a large pyriform extremity, duninishes in size as it pro-
ceeds backward, and terminates in a very narrow gray band, which turns round the op-
tic thalamus as far as the termination of the descending cormi of the lateral ventricle,
I e., as far as the large end of the cornu ammonis.
The- lateral ventricle forms a circular or elliptical trench around this central nucleus,
formed by the thalamus opticus and corpus striatum (see fig. 278). It commences in the
substance of the anterior lobe of the cerebrum {anterior or frontal cornu), mounts up upon
the corpus striatum, passes horizontally backward, and, becoming widened, divides into
two prolongations : one horizontal (digital cavity, occipital or posterior cornu), which dips
into the substance of the posterior lobe, and terminates near the surface of the brain ;
the other reflected, which runs from behind forward, and terminates behind the iissure of
Sylvius, so that the lateral ventricle would describe an almost complete ellipse if it were
not for the layer of cerebral substance which forms the bottom of the fissure of Sylvius,
and which separates the commencement (/) from the termination (Ji) of the ventricle.
Upon the longitudinal section is also seen the regular curve of the corpus callosum (e
df,fig. 282), which nuis around the central nucleus. The unequal thickness of the dif-
ferent parts of the corpus callosum, its reflection in front so as to embrace the anterior
extremity of the corpus striatum, its posterior enlarged extremity or protuberance, and
its continuity with the fornix, are shown ; and farther, it is seen that the space between
the corpus callosum and the central nucleus of the brain constitutes the upper part of the
lateral ventricle, and that the interval between the cornu ammonis and the nucleus con-
stitutes its reflected portion.
In this section we also notice the septum lucidum (J,), the fornix (A), the mammillary tu-
bercle (c), the tuber cinereum, the gray commissure (i) and gray mass of the third ven-
tricle, the infundibulum (i), the optic nerve (2), the section of the anterior commissure
(c), also that of the posterior commissure {x), and the peduncle («) of the pineal gland {p).
The longitudinal section also shows that the third ventricle is formed by the juxtapo-
sition of the two central nuclei of the cerebral hemispheres ; that these hemispheres are
only connected to each other by the corpus callosum and the commissures, and there-
fore that it is by studying these parts that the system of communicating fibres between
the two hemispheres is displayed.
It is moreover seen that each hemisphere may be regarded as composed of a white
and gray covering which surrounds a central nucleus. And it is between the general
central nucleus and the hemispheres, or, rather, between the fornix and its prolongations
on the one hand, and the optic thalami on the other (as at s,fig. 281, for example), that
the ventricles would communicate with the exterior if the ventricular membrane were
not firmly attached to the choroid plexus : it is also in the same situation that the exter-
nal pia mater passes into the internal.
The Central Nucleus. — A very curious preparation may be very easily made upon this
vertical median section, to show the central nucleus separated from the other parts. If
the handle of a scalpel be introduced between the corpus striatum and the reflected por-
tion of the corpus callosum, it will be found that the ventricular membrane is the only
means of connexion between them, and that the corpus callosum forms, at this point, a
sort of outer case of medullary substance for the corpus striatum, the entire anterior
portion of which may be exposed without breaking through any connecting fibres. The
anterior part of the corpus striatum znay also be exposed from below, that is to say, by
dissecting from the base of the anterior lobe of the cerebrum towards the lateral ventri-
cle ; for this purpose, the handle of the scalpel must be inserted along a curved whitish
line, the concavity of which is turned forward, and which limits the anterior lobe behind.
The corpus striatum can be completely isolated only in front and opposite the fissure
of Sylvius, in which situation it is covered by only a slight thickness of cerebral sub-
stance, which is seen to consist of four very distinct layers, viz., the external gray layer
of the convolutions ; a very thin white layer ; an equally thin gray layer ; and, lastly,
another layer of medullary substance.
Transverse Vertical Sections.
I am in the practice of making five transverse sections of the cerebrum : the first, im
mediately in front of the corpus callosum ; a second through the largest part of the cor-
pora striata ; a third through the anterior part of the optic thalami ; a fourth through the
middle of the thalami ; and a fifth through the occipital portion of the posterior lobes. I
shall not here enter into a detailed description of these several sections, which appeal
to me to convey a more correct idea of the structure of the brain than any other sec-
tions, but which cannot be well understood without figures. They disclose, in fact, a
medullary centre giving ofll' three or four prolongations of white substance, which con-
stitute, in their turn, the medullary centres of a certain number of convolutions to which
they are distributed ; this ramified disposition of the me;iullary substance warrants the
^W NEUROLOGY.
application of the tern arbor vita of the cerebrum to the appearances seen upon these dif-
ferent sections.
The most interesting of these sections is undoubtedly that which passes through the
cerebral peduncles, and which discloses the following appearances :
Each hemisphere is formed by a medullary centre, which gives off three principal pro-
longations, around which all the convolutions are arranged, and are thus collected into
three groups, viz., a superior, an external, and an inferior group ; the last of these is con-
nected with the medullary centre by a long narrow pedicle which corresponds to the
white matter on the outside of the corpus striatum. The corpus striatum and optic
thalamus are situated opposite to this pedicle or prolongation of the medullary centre.
The medullary centres of the two hemispheres are connected together by the corpus
callosum, which forms an arch with the concavity directed downward. Moreover, either
the section of the septum lucidum, or of the fornix, is seen according to the point at which
the knife has been carried through.
The transverse section through the corpora striata and optic thalami deserves special
attention. If the section be made through the anterior part of the corpus striatum, and
therefore in front of the optic thalamus, the former body presents an oval gray surface,
dotted with white points, which are sections of medullary fibres ; the middle of this oval
surface is traversed by a series of small, parallel, white fasciculi, which are sections of
the medullary bands that pass through the corpus striatum. On the outer side of the
corpus striatum are seen distinctly the four layers formerly mentioned as corresponding
to the island of Reil. The white layer which turns round the outer surface of the corpus
striatum may be said to be reflected upward to form the septum lucidum.
Several of these sections appear to me to show that certain white fibres, which arise
in the interior of the corpora striata, pass to the circumference of the optic thalami ; or it
may be said that certain white fibres arise in the optic thalami, spread out, and are lost
in the substance of the corpora striata, beyond which it is impossible to trace them.
This beautiful section suggested to M. Foville* some ideas respecting the structure of
the brain, to which I shall presently have occasion to refer.
The Section of Willis.
Previously to the time of Varolius and Willis, anatomists were contented with making
successive horizontal sections of the brain from the vertex towards the base, and study-
ing minutely the parts thus exposed ; and each anatomist believed that he had described
different objects when chance presented him with some arrangement that had not been
previously described. Willis insisted upon the necessity of carefully removing the mem-
branes from the surface of the brain, and he objected to the usual method of examining
this organ by making sections, which destroy the connexions between its different parts ;
he considered the brain to be composed of farts folded upon themselves, collected into a
globular form, and connected to each other by mutual prolongations. He also pointed
out the importance of first examining the brains of animals, which are much more sim-
ple than the brain of man, the size and complexity of which render its study one of great
difficulty.
After having made these judicious remarks, Willis proceeds to describe the following
mode of making the section which he had contrived, for the purpose of unfolding the
cerebrum and opening out this spheroidal mass into a flat surface :t
Place the brain, completely stripped of its membranes, upon its convex surface ; turn
forward the cerebellum and the medulla oblongata ; introduce the knife into the fissure
of Sylvius, and carry it backward as far as the digital cavity ; a flap will thus be detached,
comprising all the lower wall of the descending comu of the lateral ventricle. Repeat
this section on the opposite side ; and, after having turned backward the flaps thus form-
ed, another section must be made on each side of the brain, extending from behind for-
ward along the corpus striatum, on a level with the outer border of the corpus callosum,
and reaching to the anterior extremity of the lateral ventricle. Turn forward the inter-
mediate flap, which wiU comprise the cerebellum, the pons Varolii and peduncles, the
optic thalami, and the corpora striata.
The whole of the interior of the ventricle is thus exposed, so that we can examine the
lower surface of the corpus callosum, and its continuity with the centrum ovale of each
hemisphere, or the centrum ovale of Vieussens seen from below. The continuity of the
fornix with the comu ammonis is also well displayed. J
* Note sur la Structure du Cerveau, 24e Bulletin de la Soci6t6 Anatomique. — {Nouvelle Bihliolheque Midi-
cale. )
t Tlie brains of animals being much less complicated than that of man, are more convenient for this purpose.
The brain of a sheep thus unfolded is represented by Willis in his Cerebri Analome, fig. vii.
t This section, which, however, like all similar methods, is liable to the objection that it destroys the con-
nexion of parts, suggested toM. Laurencet the idea of comparing the cerebral mass to a nervous loop, analo-
gous to the loops described by MM. Prevost and Dumas as forming the terminations of the nerves. According
to this view, the nervous system would represent an elongated ellipse, one end of which would be represented
bv the brain and the other by the extremities of all the nerves ; but both loops are equally inadmissible.
GALL AND SPURZHEIM S VIEWS OF THE BEAIN. '^?tfl
General Remarks upon the Method of examining the Brain by successive
Sections.
The method of examining the brain by successive sections has been carried farthest
by Vicq d'Azyr, whose beautiful plates are entirely devoted to the demonstration of the
objects seen upon various sections of the brain made in succession either from below or
from above. This method unfolds to us the relative disposition of the gray and white
substances, shows the manner in which the ventricles are formed, and displays to us the
real nature of parts which, in consequence of their projecting and being free at some
part of their surface, have received particular names.
But this mode of examining the brain can only be regarded as a preUminary means
calculated to give an idea of this organ as a whole ; and it tends to perpetuate the er-
roneous opinion that the brain is a pulpy mass, consisting of a semi-fluid substance, and
displaying no more evidence of contrivance in its structure than a ball of wax.
The method adopted by Varolius and Vieussens, which fell into disuse after the pub-
lication of the beautiful work of Vicq d'Azyr, and which consisted in determining the
connexion of the different parts of the brain, has been revived and improved by Gall
and Spurzheim, who have thus opened up the path which modern anatomists have so
eagerly pursued.
Methods of Varolius, of Vieussens, and of Gall, or the Examination of the
Connexions of the Different Parts of the Brain.
Varolius was the first to perceive that the essential point in the study of the brain was
to ascertain the connexion of its several parts. He was also the first who dissected the
brain from below, and who specially examined its connexion with the spinal cord ; he
described the spinal cord as originating from the brain, not opposite the foramen mag-
num, but from the lower part of the cerebral ventricles.
Vieussens traced the bundles of the pyramids through the pons Varolii to the pedun-
cles of the brain, and followed these peduncles through the optic thalami and the corpora
striata into the centrum ovale, which is named after him. But there his inquiries ended,
for, according to him, it was in this centre that the linear or radiated structure termina-
ted ; and his preconceived notion of a nervous centre (centrum ovale), from which, with
Varolius, he described all the fibres as proceeding downward, prevented him from carry-
ing his researches farther.
Gall followed up the investigations of Varolius and Vieussens, but instead of dissect-
ing the fibres from above downward, or from the brain towards the medulla, he traced
them from below upward, or from the medulla towards the brain, and followed them
through the centrum ovale as far as the convolutions.
The method adopted by Gall in order to separate the fibres of the cerebrum and show
their connexions was to scrape them with the handle of a scalpel. But, from the nature
of this proceeding, only those white fibres can be conveniently traced which pass through
gray matter, but the white fibres themselves can never be separated from each other.
Hardening the brain in strong alcohol, in nitric or muriatic acid, or by boiling it in oil, or
by macerating, or boiling it in a solution of salt, facilitates the separation of its fibres ;
but, as the results obtained in these modes might be considered as purely artificial, the
action of a stream of water is preferable to any of them.
The results obtained by acting on the brain by streams of water fully confirm those
which are arrived at by the examination of the hardened brain.
Again, the anatomy of the fcEtal brain and comparative anatomy have also aided in
throwing light upon the connexion between the different parts of the brain.
As the works of Gall were the commencement, if not the foundation, of all that has
since been done, I have thought it necessary to give a brief summary of his views re-
garding the structure of the brain ; and as a knowledge of its structure consists in a great
measure in that of its connexions with the cerebellum and spinal cord, the examination
of these two subjects cannot properly be separated.
Gall and Spurzheim' s Views of the Structure of the Brain,
Gall and Spurzheim commence by stating, 1. That as the brain consists of several
departments, the functions of which are totally different, there are several primitive fas-
ciculi which, by their development, assist in the formation of that organ. 2. That these
fasciculi are composed of medullary fibres arising successively from the gray matter,
which, with Vicq d'Azyr, they regard as the matrix or generator of the white substance.
3. That there exist in the brain a formative system of fibres, or a formative apparatus,
and systems of uniting fibres, called commissures. In the first, or formative system,
Gall describes four primitive fasciculi ; namely, the anterior pyramids, the posterior
pyramids, the olivary fasciculi, the longitudinal fasciculi, which assist in forming the fourth
ventricle, and some others which are yet imperfectly understood.*
* It win be observed that Gall's fundamental statements are hypothetical : that the brain is developed from
certain primitive fasciculi, that there is a successive increase of these fasciculi from below upward, and that
752
NEUROLOGY.
Formative Sijstem of Fibres. — The anterior pyramidal fasciculi decussate at their origin,
but the other fasciculi arise on the same side as the hemisphere to which they belong.
The anterior pyramidal fasciculi {h',figs. 273, 274) are re-enforced as they pass through
the pons Varolii (m), which is tljerefore, according to Gall's view, a ganglion, named by
him the ganglion of the anterior pyramidal fasciculi ; these pyramidal fasciculi constitute
the cerebral peduncles {x, fig. 283), and diverge (y y') so as to enter the inferior, ante-
rior, and external (i and m, fig. 284) convolutions of the anterior and middle lobes.
Gall, in his beautiful plate. No. V., shows the expansion of the fibres of the peduncles,
their distribution, their unequal lengths, and the manner in which their expanded ex-
tremities are covered with gray matter to form the convolutions.
It still i-emains to determine how the superior convolutions and those of the posterior
lobe are formed : the following are the statements of Gall on this point :
The olivary bodies of the medulla oblongata are nothing more than ganglia, from each
of which a very strong bundle, the olivary fasciculus (see p. 708), emerges, and ascend-
ing behind the pons, where it is considerably re-enforced, passes through the gray mat-
ter which lies upon the white fibres of the cerebral peduncle, where it again receives
some additional fibres ; this gray matter constitutes a rather firm ganglion on each side ;
these are the optic thalami, which, according to Gall, do not assist in the formation of
the optic nerves, and bear no proportion to them in size.
The olivary fascicuh, which are divided into very delicate filaments in traversing the
optic thalamus, are again collected together as they emerge from its upper border.
They then pass through a thick mass of gray matter, the corpus striatum, half of which
projects into the ventricular cavity, while the other half is surrounded by the convolu-
tions of the island of Reil. The radiated fasciculi {k, fig. 284) are again re-enforced in
traversing the corpus striatum, which is regarded by Gall as another ganglion, and are
then sufficient to form all the posterior convolutions, and also those which are situated
along the upper border of each hemisphere, in the median line (A h h).
It therefore follows, according Gall, that the convolutions are nothing more than the
Fig. 283.
perfecting of all the preceding structures, which
should be regarded as preparatory systems of fibres
destined to form a whole.
Uniting System of Fibres or Commissures. — Even
the oldest anatomists regarded the corpus callo-
sum as the connecting medium between the two
hemispheres ; Vicq d'Azyr, who described several
other commissures besides the corpus callosum,
regarded them as intended to establish sympathet-
ic connexions between the different parts of the
brain. Gall, taking a more comprehensive view
of this subject, attempted to determine what parts
of the brain were connected by this means, and to
discover the general law which governs the ar-
rangement of the commissures, wliich he believ-
ed to be formed by a system of fibres and bundles,
named by him faisceaux rentrans ou convergent.
We have seen that Gall traces the pyramidal
and olivary fasciculi to the gray matter of the con-
volutions. According to him, all the extremities of
the medullary fibres penetrate the gray matter,
which is therefore whiter internally than on the
surface. Gall acknowledges that he has not been
able to determine their ultimate distribution ; he
does not know whether they terminate in the gray
matter, or turn back again towards the interior.
Nevertheless, he considers it very probable that
new medullary filaments originate in this gray lay-
er, and that there is thus produced a system of fibres
which re-enforces the preceding one, and is connected
with it internally.*
the graysubstance is the matrix of the white, are so many suppositions. Of the primitive fasciculi, the anterior
pyramids alone are well defined ; the inaccuracy in the representation of the posterior pyramids disfigures his
sixth plate.
* Nothing certain appears likely to arise from this proposition, and yet Gall immediately adds (p. 202), " It
is certain that the existence of two systems of fibres in the brain can be distinctly demonstrated, and that the
converging system contains more fibres and stronger fasciculi than the radiating system." On seeking for
his proofs, we find that he infers that converging filires must necessarily exist, from the disproportion between
the white matter of the hemispheres and the fibres which come to them from the fasciculi of origin. "The con-
verging fibres,'" says he, " at the bottom of all the convolutions, are see« to enter between the diverging fibres,
and interlace with them." It is very evident, from an examination of the proofs adduced by Gall in support
of the existence of converging fibres, that the distinction between the converging and diverging fibres is purely
hypothetical.
GENERAL IDEA OF THE BRAIN.
According to Gall, the commissures are, the corpus callosum, the fornix, and the ante-
"ior and posterior commissures.
The corpus callosum {fd e,Jig. 283) is intended to unite the convolutions of the two
hemispheres. Its anterior reflected portion unites the inferior convolutions of the two
anterior lobes (fp a a). The enlarged posterior extremity (e) receives the fibres (s «)
of the posterior convolutions (b) and the middle portion of those of the middle convolu-
tions (c).
The anterior commissure, which can be so easily traced {m) through the corpus stria-
tum into the convolution of the sphenoidal extremity of the posterior [middle] lobe, is
regarded by Gall as the means of connecting certain corresponding convolutions in the
sphenoidal portions of the two posterior [middle] lobes.
The posterior commissure, which is lost in the substance of the optic thalami, and
which is much smaller than the anterior, fulfils the same purpose for those bodies.
The posterior pillars (k) of the fornix are regarded by Gall as forming a commissure
for the posterior convolutions of the two middle lobes. The fornix appears to him to
result from the connexion of these parts, and he considers the interlacement called the
lyra to be composed of the connecting filaments. His error here is evident, for the for-
nix results from the juxtaposition of two medullary cords. The fornix may be regarded
as an antero-posterior (A h), but not as a transverse commissure.
The Ventricles and Convolutions. — The formation of ventricles is considered by Gall to
be the necessary result of the divergence of some fasciculi and the convergence of others.
His description of the convolutions is entirely new, and one cannot but regret that it
should be disfigured by the hypothesis of converging and diverging fibres. The follow-
ing is his mode of describing these parts, which he regards as the completion and final
object of the organization of the brain, and as performing the nlbst elevated functions.
Gall admits two layers in each convolution ; and he finds that these two layers can
always be readily separated, but only in the median line. He successfully proves, in op-
position to the commission of the Institute, that the convolutions are not composed of a
white, soft, and pulpy matter, resembling pomade or jelly, but that they have a fibrous
or linear structure.*
Unfolding of the Cerebrum. — The idea of unfolding the brain, which is nothing more
than opening out the convolutions, was derived by Gall from his view of the structure of
the convolutions, which he regarded as formed of two layers united by very delicate cel-
lular tissue. It was eilso suggested to him by the examination of hydrocephalic brains,
in which he conceived there was no disorganization, but merely an unfolding of the con-
volutions. 'Die following is his method of unfolding the brain : after having very care-
fully removed the meninges, he introduced his fingers into the great transverse fissure
between the optic thalamus and the hippocampus major, and thus penetrated into the
lateral ventricles : he then pressed gently against the outside of the ventricles ; he broke
down the white matter of the hemispheres until he reached the base of the convolutions,
which then necessarily became unfolded, so as to be moulded upon the back of his hand ;
the astonished spectators would have wondered less if they had seen the lacerations ne-
cessary to produce this result.
The unfolding of the brain is impossible if Gall's views be correct ; for, according to
him, the white fibres of the brain are not all of equal length, and those which correspond
to the anfractuosities are much shorter than those corresponding to the convolutions ;
besides, I am convinced that, in hydrocephalus, the convolutions are not unfolded, but
are atrophied, flattened, and compressed against each other.
Such are the principal ideas of Gall regarding the structure of the brain, t His system
undoubtedly contains numerous errors and imperfections ; but, nevertheless, it has estab-
lished a new era in the study of the anatomy of this organ.
General Idea of the Brain.
1. The decussation of the pyramidal fasciculi of the medulla oblongata, their passage
through the pons Varolii, their continuity with the cerebral peduncles, of which they
form the lower portion, their passage through the optic thalamus, and their expansion
within the corpora striata {k, fig. 284), through which they may be traced (A h h) as far
as the convolutions, are incontestable facts.
2. Again : it is no less certain that the fascicuU of re-enforcement of the medulla are
* See note, p. 75S.
t The following is the completion of these ideas : 1. As the peripheral extremities of the nerves expand in
all the organs of our body to form an immense surface (and of this expansion the retina is an excellent exam-
ple), so do the primitive fasciculi of the brain, after being re-enforced in their passage through the different
masses of gray substance, finally expand in the convolutions, and receive a covering of gray matter. 2. There
are as many particular systems as there are different functions, but they are all connected together by anas-
tomoses. 3. The nervous system is double, but is united into one whole by the commissures. 4. There is
not, and there cannot be, any common centre of all the sensations, thoughts, and volitions. 5. Personal unity
will always remain a mystery.
Each of these propositions might form the subject of ample commentary. I will merely remark the incon-
gruity between the acknowledged fact of personal unity, and the singular proposition that there neither i^
nor can be, any common centre of all the sensations, tlioughts, and volitions.
5C
754
NEUROLOGY.
prolonged above tliB'JiSftS into the cerebral peduncles, of which they form the upper poi-
tion {x, Jig. 283), and become continuous, without any line of demarcation, with the optic
thalamus. Do these fasciculi decussate 1 They remain distinct until they reach oppo-
site the pons, behind the tubercula quadrigemina, where they unite ; they appear to me
to decussate, but not so evidently as the anterior pyramids, and I cannot venture to state
this positively.
3. Fasciculi of white fibres radiate in all directions (y y',Jig. 283) from every part of
Fig. 284. the surface of the optic
thalamus (g g), excepting
its inner side, which is
free, and corresponds to
the third ventricle ; the an-
terior of these fibres pass
directly forward, the mid-
dle fibres outward, and the
posterior fibres backward,
forming the radiating
crown of Reil (k,fig. 284).
As these radiating fibres
emerge from the optic tha-
lamus, they are bound
down, as it were, by cer-
tain white curved fibres,
which constitute the tsenia semicircularis.
4. All the white fasciculi of the corpora striata, excepting those which are continuous
with the anterior pyramids, proceed from the optic thalami. Some of them appear to
me to terminate in the corpora striata in the form of extremely delicate filaments, but
the greater number pass through the corpora striata without either increase or diminu-
tion, and then pass into the hemispheres. The corpora striata of Willis are, therefore,
nothing more than gray pulpy masses, which are traversed both by the white fibres ra-
diating from the circumference of the optic thalami, and by those which are derived from
the anterior pyramids. The gray matter is not arranged in alternate linear stris with
the Avhite substance. So far from thinking, with Reil, Gall, and Tiedemann, that the
fibres which emerge from the corpora striata are much more numerous than those which
enter it, I have been led to a precisely opposite conclusion, namely, that a certain num-
ber of fibres, proceeding from the optic thalami, terminate in the interior of the corpora
striata, the gray matter of which, in reference to these fibres, represents the gray sub-
stance in the convolutions.
5. From the anatomical fact that a certain number of white fibres terminate in the
corpora striata, and also from the size of those bodies being in some animals inversely
proportioned to that of the hemispheres, it appears to me to follow that the corpora stri-
ata may be regarded as internal convolutions, in which a certain number of medullary
fibres terminate.*
6. It is extremely easy, by means of a stream of water, to separate, and, as it were,
enucleate the corpus striatum from the sort of shell formed for it by the cerebrum oppo-
site the fissure of Sylvius. The corpus striatum is only connected with the cerebrum
by the radiating fibres which emerge from its upper circumference near the corpus cal-
losum.
The optic thalamus and its fasciculus of origin present no trace of a linear structure.
Nor can we discover in it the concentric layers admitted by Herbert Mayo. With a lit-
tle attention, certain extremely delicate white filaments are seen in the optic thalamus,
which cannot be separated, on account of their tenuity and the adhesion of the surrounding
tissue to them. If the term ganglion be applicable to any part of the cerebrum, it cer-
tainly is so to the optic thalamus ; for a nervous ganglion is nothing more than a pecu-
liar apparatus in which nervous filaments become separated and spread out, in order to
enter into new combinations. We must agree with Reil and Tiedemann in regarding
the optic thalami as appendages of the cerebral peduncles : Tiedemann calls them the
enlargements of the cerebral ■peduncles.
7. The essential points to be made out in the structure of the cerebrum are the ulti-
mate course of the fibres radiating from the optic thalami and corpora striata, and the
relations of those fibres with the convolutions of the brain and the corpus callosum. I
by no means agree with Reil in thinking that we must not attach so much importance to
the continuity of fibres in the cerebrum, and that their contiguity is a sufficient guide to
its anatomy : on the contrary, I regard the determination of their continuity as the key
to the structure of this organ.
8. There is no median raphe in the corpus callosum, the right half of its transverse
fasciculi being continued into the left half, without any line of demarcation.
* In several cases of chronic hydrocephalus, in which the hemispheres were reduced to a very thin lamina.
I have found the optic thalami atrophied, and the corpora striata of enormous size.
GENERAL IDEA OF THE BRAIN. 755
9. It appears, at first sight, that the fibres of the corpus callosum {edf,fig. 284), and
the white radiating fibres (k), which emerge from the optic thalami and corpora striata,
decussate (as at g) ; but on separating the fibres of the cerebrum, either after it has been
hardened in alcohol or by the action of a stream of water, it is most distinctly shown
that these two sets of fibres are continuous.
10. Again : the continuity of the fibres of the corpus callosum with those of the hem-
ispheres is no less evident ; the middle fibres {,s,fig. 283) of the hemispheres are seen
to pass transversely inward, the anterior fibres (a p) backward, the posterior fibres («)
forward, and the inferior fibres to bend and turn upward, to become continuous with the
corpus callosum.
I have in vain endeavoured to determine by actual dissection whether there is a de-
cussation of the fibres of the corpus callosum itself; I still entertain many doubts regard-
ing this subject ; we shall presently find, when speaking of the development of the brain,
that the corpus callosum does not appear until after the hemispheres ; and that compara-
tive anatomy, by showing that the corpus callosum does not exist in the three lower
classes of vertebrate animals, is opposed to the idea that the hemispheres are composed
of certain fibres which decussate in the corpus callosum.
11. The doctrine of converging and diverging fibres, advanced by Gall and Reil,* can-
not explain the continuity of the fibres of the corpus callosum with the radiating fibres
of the corpora striata and optic thalami.
Tiedemann, from his researches into the anatomy of the foetal brain, states that the
corpus callosum is formed by the reunion of the fibres of the cerebral peduncles after
they have expanded to form the hemispheres. He says that he has traced the fibres of
the peduncles as far as the median line of the corpus callosum, where those of one side
unite and are blended with those of the other ; but a careful examination of the cere-
brum, either by means of a stream of water, or by hardening it, shows that the fibres of
the corpus callosum terminate in the convolutions, without presenting any sort of re
flection, or forming any median raphe.
12. The dissections of M. Foville seem to establish the continuity of the coi-pus callo-
sum both with the radiating fibres of the corpora striata and with the fibres of the hem-
ispheres. According to his dissections, which consist essentially in transverse vertical
sections, the radiating fibres of the optic thalami and corpora striata divide immediately
into three very distinct superimposed planes.
The^rsf or superior plane is reflected upward and then inward, so as to describe a
curve with its convexity turned outward, passes horizontally inward to form the corpus
callosum, and unites with the corresponding fibres of the opposite side.
The second or middle plane, the plane of the hemisphere, ascends parallel to the corpus
callosum up to the point where the fibres of that body are reflected inward ; it then con-
tinues in an almost vertical direction, and thus reaches the gray matter.
The third or inferior plane, much smaller than either of the preceding, is extremely
thin, and follows a very different course : immediately after emerging from the common
place of origin, it descends on the outer side of the corpus striatum, turns round its low-
er part, approaches the median line, and then mounts upward, in contact with the cor-
responding plane of the opposite side, through the middle of the ventricles, where the
two juxtaposed planes form the septum lucidum.
13. Is the fornix an antero-posterior commissure 1 In support of this opinion, I may
state, that I have seen the right half of the fornix atrophied in a case of destruction of
the convolutions corresponding to the tentorium cerebelli.
14. The anterior commissure (m, fig. 283), which was regarded by Willis as the com-
missure of the corpora striata, and by Reil as intended to connect the anterior convolu-
tions of the middle lobe and some convolutions situated at the bottom of the fissure of
Sylvius, belongs to the system of converging fibres, according to Gall, who describes
them as commencing in the gray matter of the convolutions. According to Tiedemann,
this commissure is a continuation of the cerebral peduncles, each of which, after having
traversed the corpora striata, expands in the corresponding hemispheres, and gives ofl'
several radiating fasciculi which incline forward and inward, are collected together into
a cord, and unite with those of the opposite side ; the anterior commissure, therefore
according to this view, is a bond of union between the radiating fibres of the cerebra
peduncles and those of the right and left middle lobes of the brain. Chaussier had al-
ready derived the fibres of this commissure from the cerebral peduncles. All that is
certainly known regarding it is, that the cord of which it consists passes through the an-
terior portion of each corpus striatum, and expands in the anterior and inferior convolu-
tions of the sphenoidal horn of the posterior [middle] lobes, behind the fissure of Sylvius.
15. The cornu ammonis is formed by the reflection of the lower part of the hemi-
sphere : the white laminae which cover it, the corpus fimbriatum along its border, and the
* The following is Reil's statement on this subject: ;' Both of these two systems of fibres spread out into
rays and meet each other ; the cerebral peduncles ascend from below, and eipand into the form of an invert-
ed cone ; the system of the corpus callosum, on the contrary, comes from above, and its fibres insinuate them
selves between the preceding ones (see g,fig. 284), and form, as it were, tlie lid of the cup."
756 NEUROLOGY.
fornix, constitute but one system, which evidently belongs to the antero-postenor com-
missures.
16. Each convolution is composed of two precisely similar semi-convolutions ; the
two halves, which can be readily separated by a stream of water, may be decomposed
into a considerable number of striated lamellae, arranged like a fan, the margin of which
would correspond to the free border of the convolution, and the narrow end to the ad-
herent border ; these striated lamellae are separated from each other by vascular fila-
ments ; their number seems to vary in different subjects ; they seem, moreover, to be
altogether independent of each other. The stream of water detaches a corresponding
layer of gray matter with each white lamella. This layer of gray matter is also striated,
and appears to be composed of fibres implanted upon the white matter, as Mr. Herbert
Mayo has very clearly pointed out.
1 7. It follows, therefore, that in the convolutions, a lamellar striated arrangement suc-
ceeds to the fibrous or linear arrangement of the medullary centres and radiating fibres
of each hemisphere.*
These lamellae are evidently continuous with the radiating fibres of the corpus striatum
and optic thalamus. Still, there is in each convolution a proper lamella, the continuity
of which with the radiating system of the hemispheres I have not been able to trace.
18. We should not regard the convolutions as so many sinuous eminences separated
by the anfractuosities : on the contrary, the bottom of the anfractuosity forms the mid-
dle part or fold of a layer of white and gray matter, half of which layer belongs to one
convolution and half to the next convolution (n n, fig. 284). Now it is these white lamel-
lae which line the gray matter that appear to be proper to each convolution ; and be-
tween these proper lamellae are situated the white striated plates that are continuous
with the radiating fibres of the hemispheres,t which fibres are not arranged in lamellae,
but merely in lines.
It follows from all that has been stated, that there are yet several deficiencies in our
knowledge of the anatomy of the brain, which prevent us from forming a complete idea
of its structure.
Development of the Cerebrum.^
In the early periods of foetal life, about the end of the second month, the hemispheres
are represented by a very thin membrane, which is turned backward and inward, so as
to cover the corpora striata.
The optic thalami, which appear as enlargements of the cerebral peduncles, the tuber-
cula quadrigemina, and the cerebellum, are completely exposed. The corpus callosum
does not yet exist. The human brain may, then, be considered as resembling the brain
of fishes.
Towards the end of the third month, the membrane of the hemispheres has acquired
a farther development, and covers not only the corpora striata, but also the optic thalami.
The tubercula quadrigemina and the cerebellum are still exposed. The anterior lobes
only of the cerebrum are formed. The posterior lobes seem to be merely appendages.
The hemispheres, then, constitute at this period a membranous sac, which is open on the
inner side and behind, and may be regarded as representing the brain of reptiles. The
* M. Leuret has been led to the same conclusion regarding the lamellar structure of the convolutions, by
studying the brain hardened by boiling it in a solution of salt.
t iVIr. Herbert Mayo (a series of engravings intended to illustrate the structure of the brain and spinal
cord in man, 1825), who has followed the example of Reil, in examining the brain with so much care after it
hjis been hardened in alcohol, admits the existence of three sorts of fibres in each convolution, viz., fibres
■which pass from one convolution to the next (u Uyfig. 283), and also to more distinct convolutions ; fibres which
come from the commissures (s s p) ; and fibres derived from the spinal cord. According to this anatomist, the
fibres which pass from one convolution to another constitute tlje principal part of each convolution ; the othej
white fibres which form the centre of each convolution are derived partly from the commissures and partly
from the optic thalami and corpora striata.
According to him, the white fibres (/ q) which form the inferior layer of the cerebral peduncles radiate in
the substance of the cerebrum, and constitute its anterior and middle fibres. The fibres proceeding from the
optic thalami form the posterior cerebral fibres (y). There is, he affirms, one point in which the radiating
fibres evidently decussate with the fibres from tlie great commissure of the brain or corpus callosum (as at g,
fig. 284). The posterior radiating fibres do not present this decussation.
The two most remarkable fasciculi of communication between the convolutions are the following : that
which occupies the bottom of the fissure of Sylvius (I, fig. 283 ; m,fig. 284), and which unites the convolu-
tions of the anterior and posterior lobes ; and that ( p p,fig. 283 ; I, fig. 284) which runs above the corpus cal-
fosum, crossing at right angles the direction of its fibres, and connects the anterior and superior with the pos-
terior and inferior convolutions.
Rolando has not been so successful in his researches into the structure of the cerebrum as in his investiga-
tions into that of the cerebellum: the following are the results which he obtained by tearing the brain, and
by examining this organ in the foetus. According to him, the brain is composed of fibres arranged in layers in
tiie following order, proceeding from without inward: 1. A white layer reaching into the fissure of Sylvius,
and covered by gray matter ; 2. A layer from which the fibres of the external convolutions arise ; 3. A layer
which is formed by the fibres of the peduncles, and supplies the convolutions of the inner border of the hemi-
sphere ; 4. A plane which extends from the optic thalami to the parietes of the lateral ventricles, to form the
corpus callosum ; 5. A system of longitudinal fibres which form the convolutions situated upon the inner sur-
I'ace of the hemispheres ; 6. A system of medullary fibres which constitute the fornix and coniu ammonis ; 7,
Intermil and external corpora striata, to which must be added the antenor commissures, the perforated layer,
and the fasciculus of the external corpus geniculatum. X Vide Tiedemann (translated by M. Jourdan)
COMPARATIVE ANATOMY OF THE CEREBRUM. ?ST
corpus callosum begins to appear under the form of a narrow commissure, which unites
the two hemispheres in front, they being completely separated behind.
In the fourth and fifth months, the cerebrum covers the anterior part of the tubercula
quadrigemina. The posterior lobe exists, the fissure of Sylvius, which is well-marked,
separating it from the anterior lobe. We observe here and there some small depres-
sions, the traces of anfractuosities. The olfactory nerves, which are very large, and are
said to have been found hollow, as in the lower animals, appear to arise from the Sylvian
fissure. The corpus callosum is still very small, so that the optic thalami and the third
ventricle are exposed. At this period the human brain has some analogy with that of
the rodentia.
In the sixth month, the cerebrum covers the tubercula quadrigemina and the greater
part of the cerebellum. The only traces of convolutions are found upon the internal
surface of the hemispheres. The corpus callosum is prolonged backward with the hem-
ispheres, and from being vertical, now becomes horizontal.
At the seventh month, the corpora albicantia, which had hitherto formed a single mass,
as in the lower animals, become separated. The convolutions are defined, and the cere-
brum projects behind the cerebellum.
The changes occurring in the eighth and ninth months appear to be the development
of the convolutions and the perfection of the other parts of the brain. At this period
the characters of the human brain are well-defined. It may not be impossible, perhaps, to
recognise, in the rapid phases of this development, the characters of the brain in the
different orders of mammalia, but it is necessary to observe greater caution in admit-
ting these analogies than has been evinced by various naturalists.
As the corpus callosum continues to be developed backward, it ends by reaching the
anterior tubercula quadrigemina.
The corpora striata do not exhibit their white, radiating fibres until near birth, or soon
after it. The originating fasciculi of the fornix are not seen in the interior of the optic
thalami until the latter months of intra-uterine life ; and until then, also, the transverse
commissures and the white fibres of the optic commissure do not appear.*
The lateral ventricles are formed by the turning backward and inward of the membrane
which constitutes the hemispheres. And as this membrane is very thin until the end of
the third month, it follows that at this period the lateral ventricles are proportionally much
larger than they are afterward. The anterior cornua of these ventricles are developed
before the descending cornua, and these before the posterior cornua. During all this pe-
riod, the anterior cornua communicate with the cavities in the olfactory nerves. At the
sixth month, the lateral ventricles are completely closed. The choroid plexuses, which
exist in all animals provided with lateral ventricles, begin to appear as soon as these
cavities.
The distinction between the gray and white matter does not become evident until af-
ter birth. Tiedemann is of opinion that the formation of the gray matter takes place
after that of the white. This appears to me a pure hypothesis. The two substances are
formed at the same time ; but, properly speaking, they are neither white nor gray, and
they do not acquire their distinctive characters until some little time afterward.
Comparative Anatomy of the Cerebrum.
The Optic Thalami and Corpora Striata.
In analyzing the brains of the lower animals, it is of the utmost importance clearly to
distinguish the hemispheres, properly so called, from the optic thalami and corpora striata.
The optic thalami are recognised by their having a ventricle (the third) between them,
by being connected by an anterior and a posterior commissure, and, moreover, by being
continuous with the cerebral peduncles.
The size of the optic thalami is always proportioned to that of the hemispheres. In
fishes, the cerebrum appears to be almost entirely formed by the optic thalami.
There are no traces of corpora striata in fishes. Their existence in reptiles cannot
be doubted. They are of enormous size in birds, in which they constitute almost the
entire hemispheres. If it be true that, in the animal series, the size of the hemispheres
is always directly proportioned to that of the optic thalami, such is not the case with the
corpora striata, which, as I have already stated, are a kind of internal convolutions, and
are often inversely proportioned, in size, to the hemispheres, properly so called.
Thus, the corpora striata are very large in proportion to the hemispheres in the ro-
dentia : in this respect, as in many others, the brain of this order of mammalia approach-
es very near to that of birds. In the higher orders of mammalia, as the carniyora and
quadrumana, the proportion between the corpora striata and the hemispheres is neariy
the same as in the human subject.
* [Tiedemann describes fibres as distinctly appearing- in the corpus striatum in the sixth month, though
not so abundantly as afterward. He recog:nised'the anterior and posterior commissures before the end of the
third month ; at the same time, also, the anterior pillars of the fornix rising- from the united mass of the cor-
pora albicantia ; the fasciculi from the thalami to the corpora albicantia were quite distinct in the fifth month,
and could be recognised even somewhat earlier.]
758 NEUROLOGY.
The Cerebral Hemispheres and Olfactory Lobes.
In Mammalia. —Man surpasses all the mammalia in regard to the size of the cerebral
hemispheres and the number of their convolutions.
The quadrumana stand next to man. The dolphin, perhaps, exceeds the ape in both
respects, and this would tend to support the relations of travellers respecting the won-
derful intelUgence of this cetaceous animal.
In the carnivora and ruminantia the hemispheres are smaller, the occipital lobe of the
cerebrum does not exist, and the anterior part only of the cerebellum is covered. There
is no fissure of Sylvius, and no lobe of the corpus striatum. In all these animals, the
number of the convolutions and the depth of the anfractuosities have appeared to me
to be as great as they are in man, in proportion to the size of the hemispheres. I have
not observed that regularity of the convolutions which several anatomists have pointed
out as contrasting with their irregularity in man.
The lowest order of mammalia, namely, the rodentia, have the letist complicated brain.
It is shaped like the heart on playing cards, almost resembling the brain of birds. The
cerebellum is completely exposed, and the tubercula quadrigemina are but partially cov-
ered by the cerebrum. There are scarcely any traces of convolutions, and the hemi-
spheres are reduced to a membrane folded upon itself
The corpus callosum is extremely small, but the cornu ammonis is very large. These
two parts seem to be developed inversely to each other. Thus, the corpus callosum is
larger and the cornu ammonis is smaller in man than in the lower animals.
In the rodentia, the gray matter of the convolutions is reflected beneath the fornix.*
In all mammalia, excepting the dolphin, the olfactory nerves, which are so delicate in
man, form two thick pedicles lying under the anterior lobes of the cerebrum, and termi-
nating in front by large ovoid bulbs, corresponding in size to that of the ethmoidal fossae ;
these enlargements are named olfactory lobes. They are continuous with the innermost
convolutions of the sphenoidal horn of the posterior lobe, which presents, above and be-
low, certain white fibres or striae, that are continuous with the cerebral peduncles.
The olfactory lobes have no relation with the corpora striata, as Cuvier was the first
to observe. In the dolphin, as in man, the corpora striata are very much developed.
The development of the olfactory lobe is inversely proportioned to that of the cornu
ammonis.
In Birds. — The cerebral hemispheres in birds are shaped like a heart on playing cards,
as in the rodentia ; there are no lobes and no convolutions, excepting a very superficial
longitudinal furrow, situated on each side of the median line. The brain almost entire-
ly consists of the corpora striata. The hemisphere is formed by a very thin gray lamina,
upon which are observed certain white radiated fibres. This lamina commences at the
inner part of the corpus striatum, turns outward round that body, and is continued to the
upper part. The interval between this lamina and the corpus striatum forms the lateral
ventricle. There is no trace of the corpus callosum, but there is evidently an anterior
commissure, which expands in the corpora striata.
In all birds of prey, two medullary bands arise in front of the commissure of the optic
nerves, and, having reached the front of the hemispheres, are expanded to form the ol-
factory lobes. In the other tribes, as in the gallinaceae, there are no olfactory lobes, but
certain small cords, which are merely the tapered extremities of the hemispheres.
In Reptiles. — The hemispheres are larger in the chelonians (tortoise) than in birds,
though they are very similar in many respects : as in birds, there are no olfactory lobes,
but merely two bands. In the saurians (crocodile, lizard) the olfactory lobe is continued
into the tapering point of the cerebral lobe by a very long pedicle. The batrachians and
ophidians have olfactory lobes in front of the hemispheres, from which they are separa-
ted by a circular constriction.
In Fishes. — Like reptiles, fishes have sometimes a single pair, sometimes two pairs
of lobes in front of the optic lobes. When there is only one pair, it must not be conclu-
ded that they represent the cerebral hemispheres ; if that pair is continuous with the ol-
factory nerves, they constitute the olfactory lobes. Whenever there is a pair of lobes
between the olfactory and the optic lobes, such pair belongs to the hemispheres.
The olfactory lobes and the cerebral hemispheres are so independent of each other,
tliat they are often inversely proportioned in regard to size, so that the cerebral hemi
spheres are larger in man than in any of the lower animals, while the olfactory lobes are
smaller. On the other hand, the olfactory lobes are the most highly developed in the
ray ; they are united together, are hollowed in the centre, grooved on the surface, ac-
cording to the observation of Vicq d'Azyr, and present some traces of convolutions.
Now, in the ray, there are no cerebral hemispheres, at least, unless we agree with Tiede-
mann in regarding the olfactory lobes as anologous to the corpora striata. In some fish-
es the olfactory lobe is supported by a pedicle of variable length. As to the cerebral
hemisphere, it is a mere tubercle, which appears to represent the optic thalamus.
* [Mr. Owen has discovered that the brain of marsupial animals resembles that of birds, in wanting the cor-
pus callosum (see his Memoir in Phil. Trans., 1837).]
THE NERVES. 7S6
The corpus callosum, the fornix, and the septum lucidum do not exist either in birds,
reptiles, or fishes.
The corpora albicantia, which are wanting in birds and reptiles, are of enormous size
in fishes, and constitute a true lobe, according to Vicq d'Azyr and Arsaky.
The encephalon of fishes presents five pairs of lobes, which are, proceeding from be-
hind forward, 1. The lobes of the pneumogastric nerve, or lobe of the medulla oblongata ;
2. The cerebellum ; 3. The optic lobes ; 4. The cerebral hemispheres ; 5. The olfactory
lobes.
If we now generalize, with M. de Blainville, the notions'we have formed respecting
the encephalon of vertebrate animals, we may regard the different pairs of lobes of the
encephalon as so many pairs of ganglia situated upon the prolongation of the spinal cord ;
these he names ganglions saris appareil exterieur. The first or the most anterior pair
consists of the olfactory lobes, which are rudimentary in man. The second is the cere-
brum, properly so called. The third is formed by the tubercula quadrigemina or optic
lobes, which are rudimentary in man. The fourth is the cerebellum. The gangha
which constiJ;ute each pair communicate with each other ; each gangUon communicates
with that which precedes and that which follows it • and, lastly, they all communicate
with the spinal cord.*
THE NERVES, OR THE PERIPHERAL PORTION OF THE NERVOUS
SYSTEM.
General Remarks. — History and Classification. — Origin, or Central Extremity. — DiffererU
Kinds. — Course, Plexuses, and Anastomoses. — Direction, Relations, and Mode of Divis-
ion.— Termination. — Nervous Ganglia, and the Great Sympathetic System. — Conneximu
of the Ganglia with each other, and with the Spinal Nerves. — Structure of Nerves. — Struc
ture of Ganglia. — Preparation of Nerves.
General Remarks.
The nerves, which are concerned in the transmission of sensations and of motor influ-
ence, are white cords, attached to the cerebro-spinal axis by one extremity (the central
extremity), and distributed to the different organs by the other, or peripheral extremity.
They have a pearly-white aspect, like the tendons, with which they were for some time
confounded. Their surface is smooth, and presents a number of folds or zigzag marks,
which are effaced by extension.! Lastly, if a nerve be cut across, it is seen to be com-
posed of a certain number of cords, the divided ends of which project beyond the cut
surface. By these characters it will always be easy to distinguish a nerve from any
other white tissue in the body.
All the nerves are arranged in pairs : they differ from each other in their point of
junction with the central portion of the nervoiis system ; in their consistence ; in the
place at which they emerge from the cranio-vertebral cavity ; in their distribution ; and
in their functions. These points of difference have served as the foundations of the dif-
ferent classifications of the nerves proposed at various periods.
History and Classification of the JSTerves.
The nerves, which had been at first confounded with the tendons and ligaments under
the name of white tissues, were distinguished from those parts by Herophilus and Galen.
The subdivision of the nerves into the cerebral or cranial nerves, which pass out of the
foramina in the base of the scull, and the spinal or rachidian nerves, which emerge from
the inter- vertebral foramina, was so natural, that it suggested itself to the earliest anat-
omists who directed their attention to this system. The cranial nerves alone have pre-
sented some difficulties in their study and their classification. Marinus, whose work
has been long regarded £is classical, admitted only seven pairs of cranial nerves, among
which neither the olfactory nor the pathetic were included. Achillini was the first who
described the latter as a special nerve ; and it was Massa who classed the olfactory rib-
and among the nerves. Willis divided the cranial nerves (and his division is still adopt-
ed) into ten pairs, including the sub-occipital nerve. He also, like his predecessors, ad-
mitted thirty pairs of spinal nerves, and regarded the great sympathetic as forming the
forty-first pair. According to Willis, the olfactory nerves form the first cranial pair ;
the optic nerves, the second ; the common motor nerves of the eyes, the third ; the pa-
thetic nerves, the fourth ; the trigeminal nerves, the fifth ; the external motor nerves,
the sixth ; the facial and auditory nerves together, the seventh ; the pneumogastric,
glosso-pharyngeal, and spinal accessory, the eighth ; the hypoglossal nerves, the ninth ;
and the sub-occipital nerves, the tenth. This last pair, which was with so much reason
* [There is still considerable uncertainty as to the parts of the encephalon which correspond iu the higher
and lower vertebrata. For farther information on this point, as well as on the comparative anatomy of the
brain generally, see Leuret, Anatomic Comparee du Systime Nervevus, Paris, 1839.]
\ [These zig^zag folds led some anatomists to believe that the nerves have a sinuous arrangement. Monro
has even commemorated this anatomical error by a figure. The sinuous appearance common to the nerve*
and tendons disappears in both by stretching.]
760 NEUROLOGY.
classed by Haller among the spinal nerves, has been alternately and arbitrarily removed
from one to the other class of nerves. Soemmering divided the seventh pair of Wilhs
into two distinct pairs : the seventh, or the facial nerves ; and the eighth, or the audi-
tory nerves : he subdivided the eighth pair of Willis into three pairs, namely, the ninth,
or the glosso-pharyngeal ; the tenth, or the pneumogastric ; and the eleventh, or the
spinal accessory nerves of Willis. But Soemmering's modification, as well as Mala-
carne's, who admitted fifteen pairs of cranial nerves, and also Paletta's, who described
as a particular nerve that branch of the fifth pair which is distributed to the temporal
and buccinator muscles, appear to me to be faulty, because they cause a confusion of
ideas without leading to any advantage. We shall, therefore, adhere to the classifica-
tion of Willis, which is most generally adopted. Nevertheless, with Vicq d'Azyr, we
shall prefer a nomenclature founded upon the distribution of the nerves to one which is
purely numerical.
Willis conceived the grand idea of separating the nerves of voluntary from those of
involuntary motion. Bichat seized upon this idea, which had already been rendered
fruitful by Winslow and Reil ; he unfolded it even to the minutest details, and appropri-
ated to himself, in some measure, the distinction of the nerves into those of organic and
those of animal life. The cerebro-spinal nerves constitute the nervous system of ani-
mal life ; the great sympathetic nerve fonns by itself the nervous system of organic life.
This last-named nerve consists of a series of gangha, or small nervous centres, distinct
from each other and from the brain. Bichat, moreover, anticipating all the importance
of the origin of the nerves, endeavoured to class them, not according to the points at
which they emerged from the cranium, but according to their origin, viz., into the nerves
of the cerebrum, which are ten in number ; the nerves of the pons Varolii, six in num-
ber ; and the nerves of the spinal marrow, thirty-four in number ; the only disadvantage
of this classification consists in its having been premature.
Other less important, and, in general, rather physiological than anatomical subdivis-
ions of the nerves, have been established. Thus, in reference to their consistence, the
nerves have been divided into the hard, which are motor nerves, and the soft, which
are sensory ; the former are said to come from the spinal cord, the latter from the brain.
The old distinction of the nerves into nerves of sc?isatimi and nerves of motion has been
lately revived ; and we shall have occasion to recur to it, as well as to Sir Charles Bell's
classification of the nerves into the symmetrical or primitive, and the superadded or respi-
ratory system.
The nerves might also be classified according to their size, but this mode of distinc-
tion would be completely useless. Every nerve presents for our consideration a central
oxtremity, a course, and a peripheral extremity.
The Central Extremity of the Jferves.
The central extremity of the nerves is that part by which they communicate or are
connected with the cerebro-spinal axis. It is generally called the origin of the nerves.
The use of such metaphorical expressions as origin, production, and efflorescence, has
not been without disadvantage to science ; for by the majority of anatomists they are
employed not in a figurative, but in a literal sense.*
The examination of the central extremity of the nerves is, perhaps, the most impor-
tant part of their study, because the properties of the nerves depend in a great measure
upon their point of connexion with the central part of the nervous system. This point
is, in reference to each nerve, constant and invariable, not only in man, but throughout
the animal kingdom, so that its exact determination enables us to establish what are the
analogous parts of the encephalon in different species. *
Each nerve has an apparent and a real central extremity or origin. The apparent ori-
gin is the exact point at which the nerve is given off from the surface of the cerebro-
spinal axis ; but, as several nerves can be traced into the substance of the cerebro-spinal
axis to a variable depth, it is probable that all of them have a much deeper real origin.
The older anatomists proceeded on this supposition, when they described all the nerves
as originating from the cerebrum, and more particularly from the corpus callosum, or,
rather, from the optic thalami and corpora striata. We are still ignorant of any central
point, or sensorium commune, forming the point of termination or of origin to all the nerves
of the body,
In respect of their origin, we might regard all the nerves as proceeding from the spi-
nal cord : the nerves of the face, and those of the organs of respiration and deglutition,
arise from the medulla oblongata and its cranial prolongations ; the nerves of the upper
extremity proceed from the cervico-dorsal enlargement of the cord ; and the nerves of
the lower extremity from the lumbar enlargement : the nerves of the trunk arise from
the spinal cord, between its three enlargements. The optic and olfactory nerves alone
appear to form exceptions to this rule.
All the spinal nerves present the greatest uniformity in reference to their origin,
* Comparative anatomy, and the anatomy of the fcetus, prove the independent formation of the different
parts of the nervous system.
DIFFEREIVT KINDS OF NERVES. 761
course, and termination. The arrangement of the cranial nerves, which appears at first
sight to be uninfluenced by the laws which regulate the distribution of the spinal nerves,
may yet be referred to those laws to a certain extent, notwithstanding its apparent ir-
regularity and complexity.
The general remarks wiiich follow apply more particularly to the spinal nerves.
The spinal nerves arise by two sets of roots, the anterior (a, fig. 267) and the poste-
rior (b).
Gall advanced the notion that the posterior roots of the spinal nerves preside over ex-
tension, and the anterior roots over flexion of the trunk and limbs, and he explained the
predominance of extension over flexion by the greater size of the former roots.* Al-
though the fact of this predominance appears to me indisputable, Gall's explanation is
nevertheless rendered void, for it supposes a separation of the fibres of the anterior and
posterior roots in reference to their distribution, and no such a separation exists.
Sir Charles Bell, having proved by experiments that the facial nerve and the fifth
cerebral nerve had different properties, the former being devoted to motion and the lat-
ter to sensation, was led to examine whether there did not exist something analogous
in the other parts of the body ; and the double roots of the spinal nerves must have natural-
ly suggested themselves to his mind. Might not the object of this double origin be to
concentrate a double property in each pair of nerves 1 Experiments were instituted,
and they confirmed the preconceived ideas of this ingenious physiologist. They were
soon followed by the perfectly confirmatory experiments made by Magendie, who, by also
adducing facts in pathological anatomy, threw so much light upon this subject, that most
modern physiologists have admitted that the posterior roots belong to sensation, and the
anterior to motion.
Now, notwithstanding the imposing authorities which I have quoted, I must say that
I am by no means convinced of the reality of this distinction, and that, in repeating both
Bell's and Magendie's experiments, the section of the anterior and that of the posterior
roots appeared to me to produce precisely the same effects. +
I have also endeavoured to determine the question anatomically.
Some anatomists have thought that, after emerging from the ganglion, the filaments
from the two roots become so intimately mingled that the smallest nervous cord would
contain filaments from both the anterior and the posterior roots ; as far as I have been
able to ascertain, the filaments are interlaced, but never enter into a regular combination.
Again, in order to render the dissection more easy and conclusive, having macerated a
portion of a body in water containing nitric acid, and having tlius destroyed the neuri-
lemma or fibrous covering of the nerves, I endeavoured to trace some nervous filaments,
both cutaneous and muscular, to their origin ; but I never could succeed in this, so nu-
merous are the combinations into which tlie filaments enter. However, having directed
my attention more particularly to certain filaments given off from the cervical nerves to
be distributed to the scaleni muscles, I succeeded in tracing them into the correspond-
ing spinal gangli. Now the filaments which proceed directly from the spinal ganglia are,
according to the theory just alluded to, exclusively connected with sensation, and, con-
sequently, should not be distributed to the muscles.
The question of the anterior and posterior roots is connected with another more gen-
eral question, viz.. Are there different kinds of nerves 1
Different Kinds of JVerves.
The natural distinction of the nerves into those of sensation and of motion dates as
far back as Erasistratus, who described the sensory nerves as arising from the meninges,
and the motor from the cerebrum and cerebellum. This opinion was often revived and
always abandoned, and it was only when direct experiment appeared to confirm the an-
ticipations of theory that it became generally adopted.
Bichat, after the example of Winslow and Reil, divided the nervous system into two
grcErt sections, one of which belongs to animal and the other to organic life. The spinal
cord and encephalon form the common centre of the nervous system of animal life ; the
organs of the senses and the muscles are under its influence. All the organs supplied
by it are subject to volition and consciousness. The nervous system of organic life is
formed by the ganglia of the great sympathetic, which Bichat agrees with Winslow in
regarding as so many little brains. The organs of digestion, respiration, circulation,
and secretion are under its influence. All of the organs which it supplies are withdrawal
from the control of the will and of consciousness.
The subdivision adopted by Reil and Bichat prevailed in the science until Sir Charles
Bell was led back to the opinion of the ancients by some highly interesting*observations
and experiments ; he associated with that opinion the ideas of Bichat, and also estab-
* In this matter Gall has caufjht sight of a truth which I believe I have established upon incontestable evi
dencc, in describing the apparatus of locomotion ; namely, that in all parts of the body, excepting in the mus-
cles of the fingers, the extensors are more powerful than the flexors.
t [The accuracy of the experiments has now been amply confirmed ; and there is no doubt that the ante-
rior are the motor, and the posterior the sensory roots : no difference of structure has been detected between
tbem.J
5 1)
762 NEUROLOGY.
lished an entirely new class of nerves, wliicli he named nerves of expression or respiratory
nerves. According to this view, there are five kinds of nerves : nerves intended for special
sensations, as the nerves of smell, of vision, and of hearing ; nerves of common sensation;
nerves of volwntari/ motion ; nerves of the respiratory movements ; and sympathetic nerves,
which appear to unite the body into a whole in relation to its nutrition, its growth, and
its decay. By a still wider generalization. Sir Charles Bell admits two systems of
nerves, viz., the the primitive or symmetrical nerves, which exist in all animals, and by
the aid of which they feel and move ; and, secondly, the superadded, irregular, or respi-
ratory nerves, the number of which is proportioned to the perfection of the general organ-
ization. It is the latter system of nerves that regulates the partly voluntary and partly
involuntary act of respiration, and also the several movements connected with it, such
as those of speaking, laughing, sighing, and sneezing. According to Bell, these nerves
arise from a special tract in the cord, and sometimes proceed separately or distinct from
he other nerves, and are sometimes blended with them, this occurring in such a man-
ner that neither their union nor their separation in any way impedes their functions.
This theory of superadded or respiratory nerves is very ingenious, but altogether hy-
pothetical. Besides, it is only strictly applicable to the case of four nerves, viz., the
pneumogastric, the glosso-pharyngeal, the spinal-accessory, and the facial. Sir C. Bell'a
opinion concerning the existence of a column situated between the anterior and poste-
rior roots of the nerves, along the whole extent of the spinal cord, and giving origin to
certain filaments which combine with those coming from the two roots so as to cause
them to participate in the great phenomenon of respiration, is quite gratuitous.
On endeavouring to decide whether there are several kinds of nerves, by anatomical
investigation, it is found that, excepting the olfactory, optic, and acoustic nerves, which
have altogether a peculiar arrangement, and the ganglionic nerves, which are generally
grayer and more slender, there is no difference in the character and structure of the
nerves of different parts of the body. The cutaneous nervous filaments are exactly sim-
ilar to the muscular nervous filaments.
From the law of organization, that identity of structure is always connected with iden-
tity of function, I have been led to admit that the nerves are homogeneous ; that the dif-
ferent properties attributed to them belong to the organs to which they are distributed ;
and that they perform no other office in the economy than that of conductors — conductors of
sensation when they are distributed to a sensory organ, and conductors of motor influence
when they enter a motor organ.* This view of the homogeneous structure of the nerves
explains much more readily than the opposite one all the phenomena of innervation,
and, in particular, the unity of all parts of the nervous system.
Moreover, if we admit the existence of special nerves to preside over some special
phenomena, and to be distributed to particular organs, why not admit them for all special
actions and for all organs 1 There would then have to be digestive nerves, generative
nerves, and secreting nerves of different kinds.
Course^ Plexuses, and Anastomoses of the JVerves.
The course of the nerves must be examined both while they are within and while they
are outside the cranio-vertebral cavity. Within this cavity the extent of their course
is variable ; and their distribution, after they have emerged from it, is more or less com-
plicated. All, or nearly all, the cerebro-spinal nerves communicate with the great sym-
pathetic system. When the parts to which they are destined are not complicated, their
distribution is very simple, as, for example, the nerves of the thoracic and abdominal
parietes ; but when those parts are complicated, the arrangement of the nerves is pro-
portionally intricate ; and they then unite so as to form certain interlacements called
plexuses, as, for example, the thoracic and abdominal plexuses.
The nervous plexuses, which Bichat regarded as so many centres in which the branch-
es of origin of the nerves ended, and from which their terminal branches commen
ced, are Ibrmed by the division and subdivision of a certain number of nerves, wnich
enter into new combinations, and form an almost inextricable interlacement.
Within these plexuses there is generally so intimate a combination of the different
elements of which they are composed, that it is almost impossible to determine exactly
what branches of origin are concerned in the formation of any particular terminal branch.
A branch of a nerve issuing from a plexus belongs, therefore, to all the nerves which en-
ter into the composition of that plexus.
The plexuses do not consist of actual anastomoses of the nervous cords ; nor do they,
as Monro believed, contain any gray matter : they do not afford origin to any new ner-
vous frlamenfs, but they merely give off those which they have received. The most
careful examination reveals nothing more than an interchange of nervous cords, which,
although they enter into new combinations, still remain independent of each other.
* The homogeneous structure of the different nerves is proved by the anatomical fact, that the same nerv«
is distributed to a great number of organs having very diiferent functions, as, for example, the eighth pair;
and also by a fact in comparative anatomy, namely, that the same pair of nerves may, in. different species, pre-
side over totally different functions ; for example, the fifth pair.
DIRECTION OF THE NERVES. 763
The term nervous anastomoses is applied to the communications by loops, or at more
or less acute angles, which take place between the nervous filaments. The older anat-
omists, governed by the idea that there existed a fluid circulating in the nerves, sup-
posed that in the anastomoses of nerves there was a mixture of nervous fluids, nearly
similar to that which takes place in vascular anastomoses, where two different columns
of blood are intermixed. They regarded the nervous anastomoses as the most active
source of sympathies. Bichat also admits the existence of these anastomoses, in which,
he says, there is not only a contiguity, but also a continuity of nervous filaments. Be-
clard* defends the use of the term anastomosis, and endeavours to define its meaning
thus : " There is not merely an application of nervous filaments in the anastomoses, but
a true communication, a junction {abouchement) of their canals, which, in truth, contain a
fixed substance, not a circulating fluid, as was formerly believed."
But, on examining the structure of the nervous anastomoses, it is seen that there is
simply a juxtaposition of filaments derived from two different sources. The examina-
tion also proves most distinctly that the anastomoses are merely small plexuses, so that
the only difference between them is, that in the -plexuses there is an interchange of nervous
cords, while in the anastomoses there is an interchange of nervous filaments or of primitive
fibres. The anastomoses, like the plexuses, are intended to concentrate the action of
several nerves upon any given point, as on a centre, from which their action may ex-
tend to certain parts necessarily connected in function.
The nervous loops described by Bichat upon all points of the median line of the body,
and by the existence of which he supposed that he could explain the return of sensation
and voluntary motion to paralytic parts of the body, do not exist. The only anastomoses
in the middle line with which I am acquainted are those of the two pneumogastric nerves
behind the lower extremity of the trachea, that of the two solar plexuses, and that of
the cardiac nerves.
The Direction, Relations, and Mode of Division of the Jferves.
The nerves are very deeply situated at their egress from the cranio-vertebral cavity.
Thus, the brachial plexus is protected by the osseous girdle of the shoulders, and the
sacral plexus by the pelvic bones. The nerves then pass into the great cellular inter-
vals, which we have already described as existing in the limbs for the reception of the
principal vessels and nerves, and for the preservation of those parts from pressure.
The direction of the nerves is generally straight, and their length corresponds exact-
ly with the distance from their point of origin to that of their termination, so that, if the
movements of the hmbs exceed their ordinary extent, the nerves may suffer severe in-
jury by being stretched. This straight direction is, in general, an essential character of
a nerve. Nevertheless, a considerable number of nerves deviate from their primitive
direction,! so as to describe a portion of a circle, or are seen reflected upon themselves
in a direction precisely opposite to their original one. Others describe a zigzag course,
like the arteries ; but these flexuosities are effaced in certain positions of the body, or
during the distension of particular organs.
Although there is but one arterial trunk for each limb, there are always several nerves,
the number of these being variable. As the arteries often deviate from their original
direction, they describe certain turns, so as to occupy alternately the opposite sides of
a limb. Now, as the nerves pass in a straight direction, and the arteries describe cer-
tain curves, it follows that the same nerves cannot accompany the same arteries during
the whole of their course. Thus, when an artery deviates from its primitive direction,
it has two satellite nerves, one during the first, and the other during the second part of
its course. For instance, the crural nerve accompanies the femoral artery, and the
sciatic nerve the popliteal artery. When an artery bifurcates or otherwise divides, there
is often a particular nerve for each subdivision : thus, the median nerve is the satellite
of the brachial artery, the radial nerve accompanies the radial artery, and the ulnar nerve
the xdnar artery.
It follows, also, from what has been said, that the nerves have no accompanying ves-
sel for a more or less considerable portion of their course ; such is the case with the
great sciatic and the pneumogastric nerves.
The relations of the arteries with the nerves are constant, so that modem surgeons
attach great importance to these relations ; in fact, as a nerve, on account of its white-
ness, is more easily recognised than an artery, as soon as the former is exposed the
latter is immediately met with. It is important, moreover, to determine with the great-
est accuracy what nerves are contained witliin, and what nerves are situated without,
the sheath of their corresponding artery. Besides its principal nervous trunk, an artery
is also accompanied by certain nervous filaments, which are closely applied to the ves-
sels, which are very difficult to separate from it, and which often escape observation
* Anat. G6n6rale, p. 659.
t I do not think that a straight direction is necessary for the transmission of the nervous influence, for this
takes place in a lle.ve(J limb along a curved nerve, as well as in an extended limb along astraig'ht nerve , but
it is probable ihat it sliorteus the duration of this trausmission.
764 NEUROLOGY.
from their tenuity. These are the filaments which render ligature of the arteries so
painful.
Division of the Nerves. — During their course, the nerves do not divide, like the vessels,
by ramifying into smaller and smaller branches ; but they give off in succession, as they
proceed, branches to the different parts through vehich they are passing, and thus be-
come gradually exhausted, until, reduced to mere filaments themselves, they terminate
in the same manner as their branches. The subdivision of nerves, therefore, docs not con-
sist in a ramification, but in a process of separation or emission. There is one circumstance
which has attracted the attention of all anatomists, viz., that the nerves do not diminish
in size in proportion to the number of filaments given off from them : some of them
even appear to increase in size after having given off several filaments. This apparent
singularity is explained, not by the fact that new filaments are added, but by the flatten-
ing of the nerve, the separation of its filaments, the addition of a certain quantity of adi-
pose tissue, or the thickening of the neurilemma.
Termination of JVerves.
The distribution of the nerves is perfectly determinate : each nerve, indeed, has its
own distinctly limited department ; an arrangement which, connected with what has al-
ready been said regarding the anastomoses, explains why the nerves cannot supply the
place of each other. When the principal arterial trunk of a limb is tied, the circulation
is re-established by the collateral vessels ; but when a nerve is cut across, all the parts
to which it is distributed are paralyzed.
The termination of the nerves is, undoubtedly, one of the most important points in
their anatomy. In the skin, the nerves terminate in the papillae, not one of which is
destitute of them ; in the muscles, they terminate in extremely delicate filaments, which
pursue a very long course in the substance of these organs, before they become invisible
to the naked eye or to the eye aided by a lens : it has appeared to me that each nervous
filament was so arranged as to be in contact with a very great number of muscular fibres,
situated either in the same or in different planes.
It is probable that there is not a single muscular fibre which is not thus lightly touched
by a nervous filament ; this anatomical fact may suggest, instead of Reil's ingenious
hypothesis of an atmosphere of activity around each nervous filament, the important
conclusion that the nerves act upon the muscular fibre by the effect of contact.*
MM. Prevost and Dumas believe that the nervous filaments terminate by loops in the
substance of muscles ; and upon their incomplete observations they have founded a theory
of muscular contraction. Nervous loops may certainly be observed in the substance of
the recti muscles, which they selected as examples ; but these loops are not the termina-
tion of the nerves, for a number of filaments are seen to issue from them, and to be dis-
tributed in the manner just pointed out.t
The different organs vary much in regard to the number of nerves which they receive ;
the organs of the senses — the eyes, the ears, the nasal fossae, the tongue, and the skin —
stand first in this respect. Next to these rank the muscles, which receive nerves in
proportion to the number of their fibres and to their activity. The organs of nutritive
life are far removed from the preceding in regard to the quantity of nerves distributed
to them. No proper nerves have yet been discovered in cellular tissue, serous mem-
branes, tendons, aponeuroses, and articular cartilages. All the articulations are provided
with nerves, called articular, which may be traced into the ligaments, and even upon the
synovial membranes.
The long bones, in addition to their central or medullary nerve, have certain periosteal
nerves which are lost in the periosteum, and also proper nerves of the spongy tissue,
which enter the foramina at the extremities of these bones. •'•
The Nervous Ganglia and the Great Sympathetic System.
The nervous ganglia are certain grayish knots or swellings situated along the course
of the nerves, and having a rather close resemblance to the lymphatic glands or ganglia.
Considered generally, the ganglia are a kind of nervous centres, towards which a certain
number of filaments converge, and from which they again pass out under new combina-
tions. Hence arose the ingenious idea of Winslow, who compared the ganglia to little
* This hypothesis of a nen-ous atmosphere was suggested to Reil by the theory of a nervous fluid, which he
regarded as analogous to and almost identical with the electric fluid ; and also by the fact that the nervous ap-
paratus is not able to supply filaments to all the muscular fibres.
t [The loops described l)y Provost and Dumas seem to have consisted of small nervous cords ; but Valentin,
Emmert, and Burdach have observed that the ultimate filaments (primitive fibres of MiiUcr) have a loop-like
termination iu the muscles. In reference to the nerves of sensation, it has been observed by Valentin and
Burdach, that in the frog's skin the primitive fibres end in loops ; this mode of termination has also been seen
by Schwann in the tail of the larva of the toad, and in the frog's mesentery. Schwann farther states, that in
both these cases the nervous fibres gave off exceedingly small fibrils, on which minute swellings (ganglia) were
placed, and which in some situations formed a network. In the papilla: of the human skin, Breschet thought
he saw the nerves ending in loops ; and Gherber believes that he has seen these terminal loops in the skin of
quadrupeds. Observers differ in their account of the mode of termination of the optic and auditory nerves <»«*
Organs of Sight and Heaking).]
CONNEXIONS QF THE GANGLIA. 765
brains ; an idea which was revived under a modified form by Bichat, who made it the
basis of his admirable chapter upon the nervous system of organic hfe.
The nervous system of invertebrate animals is reduced to a series of ganglia and gan-
glionic nerves ; Swammerdam, Haller, and the older anatomists regarded this series of
ganglia as a spinal cord enlarged at intervals. But there is no point of comparison be-
tween these two parts ; in a word, the enlargements of the spinal cord and brain cannot
be likened in any respect to the ganglionic enlargements.
There are three series, or, as some say, three kinds of ganglia : viz., the spiTial or
rachidian ganglia ; the intercostal ganglia ; and the splanchnic ganglia ; these last are situ-
ated near the viscera for which they are intended.
The first series, or the spinal ganglia, belong to the organs of relation. They are con-
stant, regular, and symmetrical, like the nerves upon which they are placed. The other
two series are destined for the apparatus of nutritive life, and constitute the great sym-
pathetic system, improperly called the ganglionic system.
The identity in nature between the spinal ganglia and the ganglia of the great sympa-
thetic, and also between the cerebro-spinal and the ganglionic system of nerves, is de-
monstrated by the fact that in a great number of animals the ganglia are blended, or, as
it were, fused together. M. Weber {Anat. Comparee du Nerf Sympathique, 1817) has ob-
served, that in animals the development of the great sympathetic is always inversely pro-
portioned to that of the spinal cord. He has established a similar relation between the
great sympathetic and the pneumogastric nerve ; and, indeed, in certain species the latter
nerve entirely replaces the former.
The experiments of M. Legallois upon the spinal cord led him to admit that the vis-
ceral nerves are under the influence of the spinal cord, and that the roots of the great
sympathetic are in the cord.
There are as many spinal ganglia on each side as there are spinal nerves. The gan-
glia of the great sympathetic in the sacral, lumbar, and dorsal regions, are as numerous
as the spinal ganglia ; in the cervical region, there are only two or three sympathetic
ganglia to correspond to the eight spinal ganglia. The superior cervical ganglion may
be supposed to represent several ganglia.
In the cranium it is difficult to find any ganglia corresponding to the spinal ; still, the
Gasserian ganglion, and the ganglion of the eighth pair, may be regarded as analogous
to them.
On the other hand, we may regard the ophthalmic ganglion, the spheno-palatine or
Meckel's ganglion, the otic ganglion, and even the upper part of the superior cervical
ganglion, as forming the cranial ganglia of the sympathetic system.
Nevertheless, it would, perhaps, be more rational to regard the ophthalmic and otic
ganglia as quite independent of the three above-mentioned series of ganglia, and as con-
nected with certain local functions. There are a considerable number of these local
ganglia, which have received no particular names, and which I shall hereafter point out.
Connexions of the Ganglia with each other, and with the Cerebro-spinal
JSTerves.
The spinal ganglia belong specially to the posterior roots of the spinal nerves ; but it
will presently be seen that the anterior roots are not altogether unconnected with them.
From the spinal ganglia proceed three branches, viz., a middle branch, forming the
continuation of the spineil ners'e ; an anterior or ganglionic branch, proceeding to the cor-
responding ganglion of the great sympathetic ; and a posterior branch, which is distribu-
ted to the muscles and skin on the posterior region of the trunk.
Each of the ganglia of the great sympathetic receive one or several filaments from the
spinal ganglia, and also a connecting cord from the sympathetic ganglion immediately
above it ; and each of them gives off a connecting cord to the ganglion next below it,
and also certain visceral branches, which sometimes terminate directly in the viscera,
and sometunes, when their distribution is complicated, proceed to the splanchnic ganglia.
Not unfrequently the conmiunicating cords between some of the ganglia of the sym-
pathetic are wanting, and the continuity of this nerve is then interrupted. Bichat relies
chiefly upon this interruption in support of his opinion, that the great sympathetic is not
a nerve properly so called, but that each of its ganglia is the centre of a small special ner-
vous system, equally distinct from the cerebro-spinal system and from the other ganglia.
The splanchnic ganglia are the centres or points of convergence of a great number of
nerves, of which some are derived directly from the cerebro-spinal system, and others
from the ganglia of the great sympathetic. In those splanchnic ganglia which approach
the median line, the nerves of the right side become blended with those of the left by a
great number of plexiform branches, which have a ganglionic aspect, surround the vis-
ceral arteries, and are subdivided with them to enter the substance of the viscera.
It follows, then, from what has been just stated, that the great sympathetic is neither
a continuous nerve, differing from other nerves only by having enlargements, as was be-
lieved by the older anatomists, who described the right and left sympathetic as cnnsti-
766 NEUROLOGY.
tuting a special pair ; nor is it, as Bichat conceived, a linear series of small nervous
centres or little brains, which give off in all directions connecting filaments, both to the
spinal and to the visceral nerves ; it is a series of ganglia connected with one another
in their action, and originating from each of the spinal nerves given off from the cerebro-
spinal axis. It does not arise from the sixth cerebral nerve, nor from the vidian or
carotid filaments, more than from any other spinal nerve ; but it takes its origin from
the whole spinal cord ; and if it does not diminish in size as it recedes from the brain,
but even increases at some points, this is because it receives new filaments of origin
during its course.
According to an ingenious hypothesis, which is fully confirmed by anatomical facts,
the viscera, which receive their nerves from the ganglia of the great sympathetic, derive
their principle of action from the whole spinal cord, so that an affection of one nerve, or
of one visceral ganglion, must affect the whole ganglionic system, in consequence of the
intimate connexions between all the ganglia ; and also the cerebro-spinal system, from
the connexions between the sympathetic ganglia and the spinal cord. It would follow
from this, that the sympathetic and the splanchnic ganglia together constitute one vast
plexus, which connects, in an intimate manner, the several viscera with each other and
with the rest of the body. This mutual dependance and sympathy is the chief charac-
teristic of the organs of nutritive life, that is to say, of the organs which receive their
nervous filaments from the splanchnic and sympathetic ganglia.
Structure of the JVerves.
Prochaska was the first to throw any light upon the obvious structure of the nervous
cords, and to prove that they consisted of true plexuses. Reil, not being contented with
noticing the plexiform arrangement of the nervous cords, endeavoured especially to de-
termine their structure ; and he failed only because he selected the optic nerve as the
type of the other nerves, whereas its structure happens to be exceptional.
Each nerve consists of a plexus enveloped in a common fibrous sheath. If this sheath
be opened, and the small nervous cords contained within it are spread out by tearing the
cellular tissue, it is found that these small cords, which at first seem to be parallel and
in juxtaposition, anastomose in a great number of ways, so as to form an extremely
complicated plexus. It is also seen that the cords are of unequal size, not only in the
same nerve, but also in different nerves ; they are smallest in the branches of the great
sympathetic and pneumogastric, and are largest in the nerves of the arm and in the great
sciatic nerves.
On spreading out a nerve, with its component cords separated from each other, upon
a plate of wax, and keeping those cords asunder by pins stuck at intervals, the absolute
impossibility of following them through their successive subdivisions, and the multiplicity
of their combinations, will become quite apparent.
The nerves consist essentially of two parts, viz., the nervous matter properly so called,
and its envelope oi fibrous sheath, which has been called the neurilemma.
There is a common neurilemma or common fibrous sheath for each nerve. Besides
this, each small nervous cord and each fibre is provided with a proper sheath or neuri-
lermna. The neurilemmatic canals divide, subdivide, and anastomose like the small
nervous cords themselves.
The neurilemmatic canals are composed of fibrous tissue : their shining aspect (which
has caused them to be frequently mistaken for tendons), their strength, their inextensi-
bility, their low degree of vitality, in fact, all their characters, clearly prove their fibrous
nature and exclusively protective function.*
The neurilemma of the nerves is continuous with the neurilemma of the spinal cord.
Nervous Matter. — If, as was shown by Reil, a nerve be immersed in diluted nitric acid.
Its neurilemma will be dissolved (rendered transparent), while its nervous matter will
become remarkably dense and opaque. We shall hereafter see how valuable is this
double property of acids in their action upon nerves for determining the true character
of fibres supposed to be nervous. In a nerve thus prepared, it is seen most clearly, that
the nervous filaments of which it is composed are continually anastomosing by loops or
at certain angles ; and that the addition of one set of filaments to the trunk of the nerve,
or the separation of others from it, necessarily interrupts the chain of their relations at
the very point where it seemed possible to ascertain them, so that, after every few inches,
the component parts of a nerve are completely changed.
What is the structure of the nervous matter 1 It is not a pulp, but is composed of
pencils of exceedingly fine filaments, which may be compared to the fibres of raw silk :
these filaments are parallel and in juxtaposition ; they are free throughout the whole
length of the nerve, and may be distinctly separated from each other ; when not stretched,
they are flexuous like a waved line. Each nervous filament reaches the entire length
of the nerve. In each nerve, the filaments of which the fibres are composed pass con-
* It may bo said that the neurilemma owes its fitness as a protecting organ as well to its low vitality as to
its strength. This low degree of vitality of the neurilemma is the cause why nerves are constantly seen oasn
ing through inflamed or degenerated parts without being aflTected themselves.
STRUCTURE OF THE NERVES. 767
tinually from one fibre to another, and enter into an immense number of combinations,
without ever becoming blended together.
This structure, which is so evident in a nerve hardened by nitric acid, is not less dis-
tinct in nerves which have undergone no preparation.* On puncturing the neurilemma,
the nervous matter protrudes through the opening, precisely in the same way as the
substance of the spinal cord protrudes under similar circumstances. On dividing the
neurilemma along the whole length of the nerve, the nervous matter appears like long,
parallel filaments, of a milk-white colour, which float in water if the nerve be immersed
in that fluid.
Every nervous filament (and this is a fundamental point in their anatomy) has its
central extremity in the cerebro-spinal axis, and its peripheral extremity at its point of
termination. During the whole of its long course, it only enters into new combinations
without ever being interrupted.
Continuity is a law of the structure of the nervous filaments A
Can the nerves be injected 1
The doctrine of a nervous fluid, which so long prevailed in the schools, led physiolo-
gists to admit the existence of canals for the circulation of this fluid. Several experi-
mentahsts stated that they had collected the nervous fluid, and they even described its
properties ; and anatomists instituted no researches to confirm or refute these asser-
tions. Malpighi himself, who, in reference to the study of anatomy, carried to such an
extent that system of philosophical skepticism which has completely revolutionized all
science, believed that he saw the nervous fluid escape from the cut end of a nerve, like
a glutinous juice, which he compared to spirits of turpentine. t
Reil and some others have injected the neurilemma. Reil describes a very ingenious
method of injecting the optic nerve, which consists in opening the transparent cornea,
and injecting mercury into the globe of the eye : the mercury passes through the fora-
mina, which transmit the filaments of the optic nerve at the point where these become
continuous with the retina.
Such was the state of our knowledge when Bogros, prosector to the Faculty, having
accidentally punctured a nerve with the tube of a mercurial injecting apparatus, observ-
ed that the mercury ran along the punctured nervous fibre, and also into the adjacent
nervous fibres ; he repeated and varied his experiments in a great number of ways, and
soon published a memoir, in which he formally announced as a demonstrated fact that,
in each nervous fibre, there was a central caned capable of being injected ; and, in his
enthusiasm at his discovery, he thought that he had realized the desire of Ruysch,1: and
that he could henceforth trace the nerves to their very finest terminations.
The work of Bogros was in general received with little favour, and, I think, has not
been estimated at its real worth. Having renewed his experiments, I have arrived at
the following result : If, with a pair of blunt pincers, a nervous fibre be raised from the
centre of the nerve to which it belongs (from the middle of the median nerve, for exam-
ple), and if the tube of the lymphatic injecting apparatus be inserted accurately into its
centre, the mercury will be seen to run by jerks, either downward or upward, along the
centre of the nervous fibre, and to pass into a variable number of the adjacent fibres ; if
the injection be a successful one, the greater number of the fibres of the nerve will be
injected throughout their whole length. Gentle pressure with the finger, or with the
handle of the scalpel, greatly facilitates the progress of the mercury ; but it often hap-
pens that the parietes of the canal through which the mercury is passing yield at some
point, a rupture ensues, and the fluid is extravasated.
When the nervous fibre has not been punctured in the centre, the mercury is seen to
run along the injected fibre, and even into some of those near it ; but the mercurial col-
imin is never regular ; it does not occupy the centre of the fibre, but only one side of it ;
and it is soon extravasated into the neurilemmatic sheath, which in a short time bursts.
This second kind of injection, which may be made at wUl by puncturing the fibre su-
* I have also examined this structure in living animals, while endeavouring to determine the insensibility
of the neurilemma and the sensibility of the nervous filaments.
t [The nervous filaments (primitive fibres of MUUer) are simple tubes, containing a thread of a soft, semi-
transparent substance ; they are continuous with the white fibres of the brain and spinal cord at the apparent
origin of the nerves. The primitive fibres of the nerves resemble those of the brain and cord in the nature of
their contents, but they are larger, and their tubular, homogeneous sheath is much more distinct, and is firmer,
so that they do not become varicose. The olfactory, optic, and auditory nerves, however, are exceptions to
this rule ; their fibres resembling those of the brain and cord, in their size, delicacy, and liability to become
varicose. No differences have been observed between the fibres of the other cranial and spinal nerves, nor yet
between those of the motor and sensory roots. The sympathetic nerve, and all which receive fibres from it,
contain, besides the ordinary nervous fibres, a greater or less number of jointed fibres (gray fibres, MUUer ;
organic nervous fibres, Schmann ; cellular tissue, Valentin), exactly like those found in the ganglia and in the
gray matter of the brain and spinal cord.]
t But, as Haller remarks, Malpighi only saw this upon cutting through the Cauda equina, and never ob-
served it in the section of any other nerves ; now, it is extremely probable that he saw merely the serous fluid
which is most commonly found in the lower infondibuliform portion of the spinal dura mater : " Quam yehe-
menter suspicor eum clarum virum humorem vidisse viscidurn, quo infundibulum durie membrane spinalis fre-
ciuentissime plenum est, ct qui idem in spinam bifidam auctus aliit." — (Haller, Elem. Physiol., t. iv., p. 197.)
t) Ruysch sa.d that he should have nothing to desire if he could succeed in injecting the nerves as he had
done the vessels.
768 NEUROLOGY.
perficially, differs essentially from the former one, obtained by introducing the pipe into
the centre of the fibre. In the latter case, the small column of mercury is uniform and
regular, and its metallic lustre is, as it were, observed ; the fluid runs rapidly ; the ner-
vous canal is less easily ruptured ; and, when this does happen, it is preceded by a pro-
trusion of the nervous matter ; then the mercury is extravasated into the neurilemmatic
sheath, and it pursues the same course as it would have taken if the nervous fibre had
been punctured superficially in the first instance.
Where do the injections pass in these two cases ■? In the second method, that is to
say, when the nerve is punctured superficially, it is the neurilemma that is injected. But
in the method of central injection, is the nervous matter itself injected 1 Bogros be-
lieved that it was, and he even asserted that he had seen a central canal with the naked
eye ; but no such canal exists ; and the one which he showed after desiccation of an in-
jected nerve was artificially made, as we shall immediately find. How, indeed, can we
admit the existence of a canal in nervous matter, which we have shown to consist of a
pencil of parallel and juxtaposed filaments'?
If, therefore, in the central injectiouj the mercury neither enters into the nervous mat-
ter, nor is contained in the neurilemma, where is it situated 1 Is it in lymphatic ves-
sels 1 We do not know; for lymphatics have not been shown by any one. Are they
arteries or nerves 1 To this it may be answered, that the bloodvessels do not follow the
direction of the nerves.
All this is explained by the following fact : each nervous fibre, besides its common
neurilemmatic sheath, has also a proper sheath, in contact with the neurilemma by its
outer surface, and with the bundle of nervous filaments by its inner surface, which is
smooth and moist. This sheath may be demonstrated by cutting a nerve across, and
seizing one of the tufts which project beyond the retracted neurilemma ; a nervous fibre
can then generally without effort be drawn out several inches, having a smooth surface,
and being completely freed from its common neurilemma. Now this fibre consists not
only of nervous matter, but also of a proper sheath perfectly distinct from the neurilem-
ma. It may now be injected, and will then present all the characters of the central in-
jection already mentioned ; and, upon examining it with a lens, it will be seen that the
nervous filaments of which it is composed are regularly distributed around the column
of mercury.
It follows, then, that, in the central injection of a nerve, it is neither the neurilemma,
nor the nervous matter, nor the vessels that are injected, but the proper sheath of each
nervous fibre ; and that the passage of the injection from one fibre to a great number of
others depends on the canals formed by the proper sheaths anastomosing with each other.
I shall farther remark, that in this injection the mercury evidently penetrates into a
regular canal, and not into one produced by its own weight, for a column of a few lines
IS sufficient for the purpose.
Again, the mercury runs more easily from the peripheral towards the central extrem-
ity of a nerve than in the opposite direction, and when the injection is successful, the
spinal ganglia are filled with the mercury, which is then either extravasated into the cav-
ity of the dura mater, or escapes by the veins. If it be asked why the mercury does not
pass into the anterior and posterior roots of the nerves 1 I should answer, that it is not
certain that the fibres of these roots have any proper sheaths ; or, if so, they are very
readily lacerated. As to the passage of the mercury from the nervous ganglia into the
veins, it is probable that the proper sheaths terminate in the ganglia, so that the mercu-
ry is extravasated into the tissue of which the ganglia consist.
Injections afford a good means of tracing the nervous filaments into the substance ot
organs. An injection thrown into the lingual branch of the fifth nerve penetrates as far
as the papillae of the tongue.
Structure of the Ganglia.
Meckel, in his excellent monograph upon the fifth pair, advanced the opinion that the
nerves divided in the ganglia into a multitude of fibres which are intended for a great
number of parts.
Zinn (Acad. Berlin, 1755) said that the nerves not only divided within the ganglia into
a great number of fibres, and were directed by them from the centre to the circumference,
but that they were also mingled and combined in the ganglia in such a manner that a
great number of fine fibres united into a smaller number of fibres of greater diameter.
But this doctrine, however specious it may be, not resting upon any anatomical fact,
was rejected by Haller. Scarpa undertook a series of researches in order to render our
knowledge more complete regarding this subject. Instead of boiling the ganglia or ma-
cerating them in vinegar, urine, and other hquids, Scarpa was contented with macera-
ting them in pure water frequently renewed — a method practised by Ruysch in his del-
icate investigations ; by means of this simple proceeding, he was able to demonstrate
that the ganglia are formed by a number of nervous filaments sun'ounded by cellular tis-
sue, and by a gray matter which is destroyed by maceration.*
* [The gray mattf r of the ganglia consists, like that of the brain and spinal cord, of reddish nucleated glob-
DESCRIPtieSf df "THE NERVES.
He carried his researches not only into the anatomy of the spinal, but also into that
of the visceral ganglia, and he discovered a wonderful uniformity in the structure of the
one and the other. He compared their structure to that of the plexuses ; both of them
receive nerves from all sides, which nerves are then intermixed without becoming uni-
ted ; and both generally give off a greater number of nerves than have assisted in their
formation.
The injection of the nervous ganglia from the nerves has enabled me to discover that
these ganglia have a precisely similar structure to that ofthe lymphatic glands ; they
are composed of cells communicating with each other, and among which the nervous
fibres are scattered.
In attempting to draw a comparison between the nervous plexuses, anastomoses, and
ganglia, it might be said that in the plexuses there was an exchange of nervous cords,
in the anastomoses, an exchange of nervous fibres, and in the ganglia, an exchange of
nervous filaments.
Preparation ofthe Merves.
For dissecting the nerves, a very emaciated subject, either young or old, should be
chosen. Old wasted subjects appear to me at least as favourable as young subjects.
The dissection of the spinal nerves is easy. Such is not the case with the cranial
nerves, the dissection of which is undoubtedly the most difficult part of practical anat-
omy. In order to faciUtate the study of these nerves, and to aid in the distinction ofthe
nervous filaments from small vessels and portions of fibrous tissue with which they are
often confounded, I am in the habit of submitting the head to the action of dilute nitric
acid. After having macerated it for some time in this acidulated fluid, I immerse the
Pfepafation in pure water, which I renew from time to time : the tissues generally, as
/well as the neurilemma, become perfectly transparent, and like jelly ; the nervous mat-
/^ ter alone remains whiter and more consistent, and then all error becomes impossible.
Besides, the bones, when thus deprived of their phosphate of lime, may be cut like the
soft "parts. In this way I have succeeded in separating the entire cerebro-spinal nervous
system from the other organs, retaining the great sympathetic in connexion with the
rest of the nervous system.
DESCRIPTION OF THE NERVES.
General Remarks. — Division into Spinal, Cranial, and Sympathetic Nerves.
The nerves are divided into two very distinct sets : the cerebro-spinal nerves, whicn
have their origin or central extremity in the spinal cord or its cranial prolongations :
these are the nerves of relation or of animal life ; and the ganglionic nerves, or nerves of
the great sympathetic, which end in or emanate from certain ganglia : these belong to the
system of nutrition or of organic life.
The cerebro-spinal nerves are divided into the spinal or rachidian, and the cranial
nerves : the first consist of all those which emerge from the inter-vertebral foramina ;*
the second, so improperly termed the cerebral or encephalic nerves, emerge from the
foramina at the base of the cranium.
As the line of demarcation, which seems, at first sight, to separate the cranium from
the spinal column, disappears on an analytical study ofthe scull and on a comparison of
it with the vertebrae, so it will be found that the cranial nerves, notwithstanding their
apparent irregularity, approach, in many respects, to the simplicity and regularity of the
spinal nerves. From such a comparison of the cranial with the spinal nerves we shall
derive the general principle, that the situation at which the nerves emerge from their
osseous cavities is altogether of secondary importance, while the fundamental points in
their anatomy are the exact situation of their central extremity, and their mode of distri-
bution to their peripheral extremity ; we shall also find that the only ratiofial basis of a
good classification of the nerves must be derived from the consideration of their origin.
In my opinion, the only difference between the cranial and spinal nerves is, that the
former arise from the medulla oblongata and its cranial prolongations, while the latter
arise from the spinal cord below the medulla oblongata. Just as in the osteological di-
vision of this work I have described the vertebra before the cranium, so I shall now de-
scribe the spinal before the cranial nerves ; this slight modification in the order gener-
edly adopted will enable the student to pass from the simple to the complex, and to defer
the study of the very complicated nerves of the cranium until he has been accustomed
to the dissection and examination of other nerves.
The following is, therefore, the order I shall adopt in describing the nerves : the spi-
nal nerves, the cranial nerves, the ganglionic or visceral nerves.
ules, and of grray, jointed fibres, which surround and adhere to the globules, and which are most abundant in
the ganglia of the sympathetic. The white fibres in the ganglia are like those of the nerves with which they
are continuous ; they interlace among the globules, but do not anastomose ; it has been supposed that some
wh'te fibres may originate or terminate in the ganglia, but this is not established.]
* It will be recollected that we have included the sacral foramina among the invertebral.
5E
7TO NEUROLOGY.
THE SPINAL NERVES. . .. - . . •
Enumeration and Classification. — The Central Extremities or Origins of the Spinal Nerves
— Apparent Origins — Deep or Real Origins. — The Posterior Branches of the Spinal
Nerves — Common Characters — the Posterior Branches of the Cervical Nerves, their Com-
mxtn and Proper Characters — the Posterior Branches of the Dorsal, Lumbar, and Sacral
Nerves. — The Anterior Branches of the Spinal Nerves — their General Arrangement.
The number of the spinal nerves, that is to say, of the nerves which peiss through the
inter-vertebral foramina, including the sacral foramina, is entirely dependant on the
nimiber of the vertebrae.*
There are eight pairs (1 to 8,fg. 268) of cervical nerves, including the sub-occipital ;
twelve of dorsal (9 to 20) ; five of lumbar (21 to 25) ; and six of sacral nerves (26 to 31) ;
in all, thirty-one pairs.
They all have certain characters in common ; and there are also characters proper to
certain regions, and, lastly, characters proper to each nerve.
We shall proceed to examine, under these three points of view, the central extrem-
ity, the course, and the termination of the spinal nerves.
The Central Extremities or Origins of the Spinal Nerves.
The Apparent Origins of the Spinal J^erves.
Dissection. — The same as that of the spinal cord.
Common Characters.
There are very close analogies, and only slight differences, between the different spi-
nal nerves, in regard to their origin and course within the spinal canal. This circum-
stance, added to the fact that the same dissection is required to expose the origins of
the whole series of spinal nerves, has appeared to me a sufBcient reason for including
them all in one common description. Such a plan, the object of which is to study anal-
ogous parts by comparison, is infinitely preferable to one in which the origin of each
pair of nerves is separately described.
The spinal nerves arise from the spinal cord by a double row of filaments, or by two
series of roots. These roots are distinguished into the anterior (a a, Jig. 267), which
come off from each side of the anterior surface of the cord, and the posterior (h b), which
come off also from each side of the posterior surface. The latter are also named the
ganglionic roots, because they are more particularly connected with the spinal nervous
ganglia {b b).
The ligamentum denticulatum (c c) is situated between these two series of roots.
Immediately after leaving the cord, both the anterior and posterior roots are collected
Into a number of groups corresponding to the number of the spinal nerves ; the nervous
cords of which each group consists converge towards each other, the superior cords de-
scending to meet the inferior, which is soon accomplished from the latter being less ob-
lique in their direction. It follows, therefore, that the filaments of each root, situated
one above the other, widely separated from each other on the inside, and approximated
on the outside, represent a triangle, the general inclination of which to the axis of the
cord varies in each particular region. Not unfrequently the filaments, especially those
of the anterior roots, form two secondary groups.
As they are about to enter the separate fibrous canal formed for them by the dura
mater, the fibres of each of the anterior roots, and also those of each posterior root, are
collected into a flattened cord. There is one fibrous canal for each cord of the anterior
roots, and another for each cord of the posterior roots. The arachnoid membrane,
which forms a common funnel-shaped sheath for both roots of each spinal nerve, is re-
flected from them at the points where they enter the fibrous canals of the dura mater,
to which the nervous cords are rather firmly attached.
Although the corresponding groups of anterior and posterior roots approach each other
to pass through the fibrous canals of the dura mater, there is never the slightest com-
munication between them. It is curious to see the long and numerous cords or fila-
ments which constitute the cauda aquina running parallel to each other without any an-
astomoses, while, as soon as they emerge from the spinal canal, their communications
are almost continual.
Communications between the filaments of the same series, whether anterior or pos-
terior, are not rare ; they take place in several different ways : thus, sometimes two
filaments belonging to the same nerve unite, sometimes the filaments of two different
nerves are combined, and at others, again, a filament intermediate to two nerves bifur-
cates and is divided between them.
Moreover, the oblique direction of the roots of the spinal nerves, and the variable
length of their course within the spinal canal, are the necessary consequences of the
* This relation between the number of the spinal nerves and the number of the vertebrs prevails through-
.out the whole series of vertebrate animals ; and, accordingly, there are about sixty spinal nerves in certain
Hsuunmalia, and several hundred in some serpents.
APPARENT ORIGINS OP THE NERVES. wl^
relative shortness of the cord, which, as it terminates opposite the first lumhaTvertobra.
cannot give origin to adl the nerves opposite the inter-vertebral foramina, through which
they have to pass.*
The differences between the anterior and posterior roots may be collected under the
following heads :
The anterior roots arise nearer to the median line than the posterior ; they approach
nearer and nearer to that line, towards the lower part of the cord, so tba in this situa-
tion they arise from each side of the median fissure.
While all the posterior roots are given off from a longitudinal furrow of gray sub-
stance, from which they never deviate, the anterior roots arise somewhat irregularly,
and, as it were, confusedly, from a small white column about half a line in breadth.
In regard to size, the posterior roots, taken separately, are much larger than their
corresponding anterior roots ; besides this, the filaments of the posterior roots are more
numerous, so that the posterior roots, taken together, are larger than the anterior, as
Soemmering, Chaussier, and Gall have very well established. It is difficult to conceive
how some authors should have entertained the opinion that the proportion between them
is just the reverse, at least in some regions ; this error has, doubtless, arisen from the
varieties which exist in different regions of the medulla, in the relative sizes of the an-
terior and posterior roots, but which are never such as to give the advantage in point
of size to the anterior roots : opposite the inter-vertebral foramina, the series of cords
formed by the anterior roots have a different arrangement from those formed by the pos-
terior roots.
The cord formed by each of the posterior roots immediately swells out and forms an
olive-shaped ganglion, which is called a vertebral or spinal ganglion {b b, Jig. 267). Haase,
and then Scarpa, clearly proved that, in gener£il, the posterior roots alone passed into the
spinal ganglia, and hence they are often denominated the ganglionic roots : the spinal
ganglia are situated in the inter-vertebral foramina, those of the sacral region are en-
closed in the sacral canal.
Though it is generally to the nervous cord which emerges from this ganglion that the
cord of the anterior root is applied and united, yet I would hasten to observe, that the
anterior root is not so completely unconnected with the ganglion as is commonly stated ;
thus, not unfrequently the fibres of the anterior root are united either to the outer end or
to the middle of the ganglion ; and, moreover, in the lumbar and sacral regions there is
half a ganglion on each root.
There are thirty pairs of spinal ganglia, and occasionally thirty-one, when the first
pair of cervical nerves or the sub-occipital nerves are provided with them : the size of
the ganglia bears no proportion to the diameter of the inter-vertebral foramina, but de-
pends on the number and size of the filaments of origin which pass into them, and of the
nerves which are given off from them.
The cord which emerges from the ganglion is cylindrical, has a plexiform structure,
and a furrowed aspect ; it is impossible to ascertain what part of it belongs to the ante-
rior and what to the posterior root ; it gives off three sets of branches : the posterior
spinal branches, which supply the muscles and integuments of the posterior spinal region ;
the anterior spinal branches (see Jig. 268), the true continuation of the nerve, which are
distributed to the lateral and anterior parts of the trunk, and to the upper and lower ex-
tremities ; and the ganglionic spinal branches, which pass to the ganglia of the great
sympathetic (/ i u).
The ganglionic branches will be described with the ganglia of the great sympathetic.
As the posterior branches have a close analogy in their mode of distribution, and may
be exposed in the same dissection, they will be described under one head.
The anterior branches being destined for dissimilar parts, their individual distribution
is exceedingly varied and complicated, so that a particular description is requisite, if not
of the anterior branches of each nerve, at least of those of the several sets of nerves.
Such are the characters common to all the spinal nerves at their central extremities,
during their course within the vertebral canal, and at their exit from the inter-vertebral
foramina. Let us next examine the characters proper to the nerves of each region.
Proper Characters of the Apparent Origins of the Nerves.
Proper Characters of the Cervical Nerves. — The roots of these nerves (1 to 8, Jig. 268)
are much less oblique than those of the other spinsil nerves. The first cervical nerve
slopes a little upward and outward, like the cranial veins, which it resembles in this re-
spect. The second nerve is transverse ; the succeeding nerves slope downward and
outward, the lowest being the most oblique ; but their obliquity never exceeds the depth
of a single vertebra.
The proportion between the size of the posterior and anterior roots is as 3 to 1 ; and
* Gall believed that he had solved this question, by saying that the length and obliquity of the course of
he spinal nerves is a necessary result of the erect position of man. It is certain that the nerves are less ob-
ique and have a shorter course v^ithin the vertebral canal in the lovirer animals; but this difference is ex-
plained by the greater length of the spinal cord in them, and has nothing to do with the :itf;todf>.
772 NEUROLOGY.
this difference, which is much greater than is observed in any other region, obtains not
only in reference to the filaments taken altogether, but also to each particular filament.
The cervical nerves increase rapidly in size from the first to the fifth, and then main-
tain the same size to the eighth.
The first cervical nerve, so well described by Asch, has some peculiarities : its pos-
terior filaments of origin are much less numerous than the anterior, the spinal accessory
of Willis appearing to supply this deficiency ; it is also frequently without a ganglion.*
Proper Characters of the Dorsal Nerves. — Excepting the first, which has all the charac-
ters of the cervical nerves, the roots of the dorsal pairs of nerves (9 to 20) present the
following peculiarities :
A small number of filaments or roots ; so that, with the exception of the sacral, the
dorsal are the smallest of all the spinal nerves.
Uniformity in the number of the filaments, i e., in the size of their roots. The dorsal
nerves are almost of equal size, the twelfth nerve alone being somewhat longer than
the rest.
A considerable interval between their roots, and a want of regularity in this interval.
Frequently a portion of the spinal cord, from eight to ten lines in length, gives origin to
only a small pair of nerves.
A more marked slenderness of the filaments of origin than in any other region.
The slight disproportion between their anterior and posterior roots when compared
filament for filament.
The direction of their roots, which remain in contact with the cord for some distance,
and then leave it ; this circumstance is calculated to give rise to errors concerning the
precise situation of their origin.
The length of their course within the spinal canal ; this length is equal to the height
of at least two vertebrae.
Proper Characters of the Lumbar and Sacral Nerves. — The roots of these nerves form
the Cauda equina ; their characters are, the great number of their filaments of origin,
which exceeds those of the dorsal, and even those of the cervical nerves.
The extreme closeness of these filaments, which form an uninterrupted series.
The proportion between the filaments of the anterior and those of the posterior roots,
which is as 2 to 1.
The uniformity in point of size between the two sets of filaments, the anterior fila-
ments, taken individually, being as large as the posterior.
The continuance of the origin of the posterior roots to take place at the groove, while
the anterior approach nearer and nearer to the median line towards the lower part of
the cord, and almost touch those of the opposite side.
The concurrence of both the anterior and posterior roots in the formation of the spi-
nal ganglia.
The almost vertical direction of the roots, a character common to both the lumbar
and sacral pairs of nerves.
The singular length of their course before they emerge from the spinal canal.t
The Real Origins of the Spinal Jferves.
The apparent central extremity or origin of the spinal nerves is very different from their
real central extremity or real origin. On examining the spinal cord of an adult, for the
purpose of determining this important point, one is inclined to admit that the point of
contact between any nerve and the cord is the real origin of the nerve, so readily can
the latter be separated from the cord without leaving any trace of the separation.
It has even been stated by some that the nerves arise from the neurilemma of the
spinal cord.
Chaussier believed that the two series of roots arose from two lateral furrows, one
anterior and the other posterior ; but Gall has with reason regarded these furrows as
formed by pulhng off the roots.
Others agree with the older anatomists in regarding the spinal cord as a large nerve
formed by the junction of all the nervous filaments which are given off from it. But
this idea is refuted by the fact that the cord does not progressively diminish in size from
above downward, as it must have done if fonned by the junction of the roots of the spi-
nal nerves.
The ingenious and correct observation made by Vicq d'Azyr, that the gray matter is
always found in large quantity at those parts from which a great number of nerves ori-
ginate, and that it bears a proportion to the number of these nerves, and the confirma-
tory observations of Gall and Spurzheim, seem to prove that the nerves originate from
the gray matter. This presumption is also strengthened by the consideration, that the
* According to the principles of classification which I have already stated, I should range the spinal acces-
sory nerve among the cervical nerves, because it originates from the cervical portion of the spin;il cord : iu
classing it among the cranial nerves, 1 yield to general usage.
t [Lastly, the situation of the ganglia of the sacral nerves within the sacral canal, and of the lowest of
them within the cavity of the dura mater.l
POSTERIOR BRANCHES OP THE CERVICAL NERVES 773
central gray substance of the cord is more abundant opposite the posterior roots, which
are the larger, than opposite the anterior roots, which are the smaller. On examining
the spinal cord of an adult by means of a stream of water, it is seen that, after tearing
away the filaments of the nerves, a small conical depression remains where each fila-
ment had been attached, and that the real origin of the filaments is not in this depression,
but is much more deeply seated. This is all that can be discovered from an examina-
tion of the spinal cord of the adult ; but in the foetus, at the seventh or eighth month, a
considerable part of the cord is semi-transparent, so that the already white filaments by
which the nerves arise can be traced into its interior. On making a vertical section
transversely through the spinal cord of the foetus, just level with the commissure, and
then directing a strong light on the surface of the section, it will be seen that the great
number of very delicate filaments of which the anterior and posterior roots of the spinal
nerves are composed traverse the central gray matter, are arranged like the teeth of a
comb, and may be traced into the posterior median columns ; these small filaments, are,
moreover, all parallel. The white coimnissure might ahnost be regarded as the com-
missure of these nerves.
This view is very different from that of Bellingeri, who, entertaining certain physio-
logical ideas, supposes that the anterior as well as the posterior roots of the spinal
nerves consist of three sets of filaments, some of which come from the surface of the
cord, others from the interior of the white matter, while the third set traverse the white
matter, so as to reach the extremities of the cornua of the gray substance.
Lastly, some anatomists agree with Santorini in believing that the nerves decussate
at their origin ; but they have not attempted to demonstrate this.
The Posterior Branches of the Spinal Nerves.
Dissection. — Divide the integuments from the external occipital protuberance down to
the coccyx. Dissect off the skin over the spinous processes with great care, especially
opposite the trapezius. Be particularly cautious opposite the cellular interval between
the sjicro-lumbaJis and the longissimus dorsi.
Common Character's.
The posterior branches of the spinal nerves, which are generally smaller than tne anit-
rior branches, emanate from the plexiform cords which form the continuation of the cor-
responding spinal ganglia, are directed backward, and immediately pass through tlic fora-
mina, which I may regard as posterior inter-vertebral foramina.* These branches sub-
divide into several twigs, which enter the great cellular intervals between the long mus-
cles of the back, and are distributed to the muscles of the integuments. The greatest
uniformity prevails among such of these nerves as are distributed to the same kinds of
organs, and their differences depend on peculiarities in the parts to which they belong.
We shall now study in succession the posterior branches of the cervical, dorsal, and
Iimibar spinal nerves.
The Posterior Branches of the Cervical Serves.
Common Characters.
All the posterior branches of the cervical nerves (« to o', fig. 300) pass transversely
inward between the complexus and the semi-spinalis colli, haviiig first given off some
very small twigs : having reached the sides of the posterior cervical ligament, thoy per-
forate the aponeurotic attachments of the trapezius from before backward, lie close be-
neath the skin, and are directed transversely outward. The course of these branches,
therefore, is at first inward, and then outward. The posterior branch of the first cervi-
cal nerve is the only one which presents any exception to these general characters.
Proper Characters.
The Posterior Branch of the First Cervical Nerve.
The posterior branch of the first cervical or sub-occipital nerve, larger than the anterior
branch, escapes between the occipital bone and the posterior arch of the atlas, on the
inner side of the vertebral artery, with which it is in contact, below the rectus capitis
posticus major, and in the area of the equilateral triang'e formed by that with tlie two
oblique muscles ; in this situation (i, fig. 300) it is concealed by a large quantity of fatty
tissue, which renders it rather difficult of dissection ; and it immediately divides into
several branches, which may be arranged into the internal, which go to the great and
small recti muscles ; extertud, which supply the great and small oblique muscles ; and
inferior or anastomotic, which, by uniting with the second cervical nerve, assist in the
formation of the posterior cervical plexxts.
The branch to the rectus minor passes at first between the rectus major and the com-
plexus, and then reaches the rectus minor.
* Vide Osteology (vertebral column in general). Tiies-- n.ra .j. ;. are situated between the transverse
processes, and in the dorsal region are cumpliti^d on ihu .uiTs.ue ii. . MsnKrior costo-transverse ligament.
774 NEUROLOGY.
The principal branch for the inferior oblique, before ramifying in that muscle, forms
an arch or loop, which has been well described by Bichat.
It follows, therefore, that both of the recti and both of the oblique muscles are supplied
by the first cervical nerve, which gives no filament to the complexus,* and none to the skin.
The Posterior Branch of the Second Cervical Nerve.
This is the largest of all the posterior branches of the cervical nerves, and is three or
four times larger than the anterior branch of the same nerve ; it emerges («■, fig. 300)
from the spine, between the posterior arch of the atlas and the corresponding lamina of
the axis, in the same line as the posterior branch of the first nerve, immediately below
the lower border of the obliquus major, and is reflected upward between the hairy scalp
on the one hand, and the occipitalis muscle and epicranial aponeurosis on the other ; it
passes horizontally inward between the obliquus major and the complexus, perforates
this last muscle in the outer side of its digastric portion (the biventer cervicis), then
changes its direction, and turns outward between the complexus and the trapezius,
through which latter it passes to become sub-cutaneous and accompany the occipital ar-
tery ; it is here called the great occipital nerve (occipitalis major, a, fig. 285). Hither-
to cylindrical, this nerve, on becoming sub-cutaneous, is flattened, and increased in
width, and then, passing upward, spreads out into a considerable number of diverging
branches, internal, middle, and external, which cover the occipital region with their
ramifications, and may be traced even to the parietal region : the internal branches are
the shortest, and are successively lost in the skin of the occipital region.
It supplies several branches, as follows : Some anastomotic branches to the first and third
cervical nerves.
Opposite the lower border of the obliquus major, it gives off a considerable muscular
branch (w, fig. 300), which is distributed to that muscle, to the complexus, and especial-
ly to the splenius (w, fig. 298) ; the branches to the splenius are of great size, and spread
upon its deep surface into diverging twigs, which anastomose both with each other and
with branches derived from the third cervical nerve.
During its passage between the obliquus major and the complexus, and between the
last-named muscle and the trapezius, the posterior branch of the second cervical nerve
supplies these different muscles with a rather large number of nervous twigs.
Its sub-cutaneous portion is distributed exclusively to the hairy scalp. The occipi-
talis muscle, upon which it ramifies, does not receive any branch from it : as we shall
elsewhere show, this muscle is supplied by the auricular branch of the facial nerve.
The subdivisions of the sub-cutaneous portion of the second cervical nerve may be tra-
ced into the hair follicles, and several of its external branches anastomose with the mas-
toid branch of the anterior cervical plexus.
The Posterior Branch of the Third Cervical Nerve.
The posterior branch of the third cervical nerve, smaller than that of the second, but
much larger than that of the fourth nerve, and partially intended for the occipital region,
emerges between the transverse process of the atlas and that of the third cervical ver-
tebra, and, consequently, farther outward than the posterior branches of the first and sec-
ond nerves ; it is immediately curved, and passes transversely inward (t, fig. 300) be-
tween the complexus and the semi-spinalis colli. Having reached the inner border of
the complexus, it divides into two cutaneous branches : an ascending or occipital, which
perforates the innermost fibres of the complexus, passes vertically upward upon one side
of the median line, applied to the under surface of the skin, and ramifies upon the occip-
ital region, near the median line, and to the inner side of the branch from the second
cervical nerve ; and a horizontal or cervical branch, which perforates the aponeurosis of
the trapezius between the complexus and the posterior cervical ligament, and passes
horizontally outward beneath the skin, to which it adheres, and in the substance of
which it terminates
As the posterior branch of the third cervical nerve emerges from the posterior inter-
vertebral foramen, it gives off an ascending branch, which forms an anastomotic arch
with the descending branch of the second nerve : the succession of arches formed by the
anastomoses of the first, second, and third nerves, and the very numerous branches
which arise from their convexities, constitute a plexus, which may be called the posterior
cervical plexus : it is situated beneath the complexus, near its external attachments, and
it supplies both that muscle and the splenius. The direct anastomoses between the pos-
terior branches of the three superior cervical nerves appear to me to be sometimes want-
ing ; but then the branches given off from them still exist, and form a plexus between
the splenius and the complexus.
The Posterior Branches of the Fourth, Fifth, Sixth, Seventh, and Eighth Cervical Nerves.
The posterior branches of the fourth, fifth, sixth, seventh, and eighth cervical nerves are much
smaller than the preceding, and diminish in size successively from the fourth to the
* [Asch saw and has described a twig {m,fig. 300) proceeding from the posterior branch of the first cenri-
«al nerve to the complexus muscle ; Swan and Arnold Iso observed it.]
POSTERIOR BRANCHES OF THE DORSAL NERVES. TT6
seventh. Immediately after their exit from the posterior inter- vertebral foramina, they
are reflected inward and downward in the following manner : the fourth and fifth (o') in-
cline downward upon the semi-spinalis colli, between it and the complexus ; the sixth,
seventh, and eighth descend ahnost vertically beneath the lowest fasciculi of the semi-
spinalis colli, supply that muscle and the raultifidus spinae, and having reached the side
of the median line, perforate the aponeuroses of the splenius and trapezius, become ap-
plied to the skin, and ramify in it.
The Posterior Branches of the Dorsal, Lumbar, and Sacral JVerve.
The Posterior Branches of the Dorsal Nerves. — These are intended for the dorsal region of
the trunk, and resemble each other closely in their distribution, presenting only a few dif-
ferences connected with the arrangement of the particular muscular layers of each region.
The posterior branch of the first dorsal nerve has the same muscular and cutaneous re-
lations as the corresponding branches of the lower cervical nerves ; it is of the same
size, and is distributed in precisely the same manner.
The posterior branches of the second, third, fourth, fifth, sixth, seventh, and ei^A^A dorsal
nerves are destined for the thorax, properly so called, and present the greatest uniformity
in their size and distribution.
They all emerge from the posterior inter-vertebral foramina, immediately on the outer
side of the semi-spinalis dorsi and multifidus spinae, and divide into two branches. The
external or muscular branch is directed towards the cellular interval between the sacro-
lumbalis and longissiraus dorsi, and subdivides into a great number of twigs, which are
distributed to these two muscles [and to the levatores costarum]. The internal or mus-
culo-cutaneous branch has a very remarkable course. It is reflected inward over the semi-
spinalis dorsi, embracing the outer border of that muscle, and supplying it with nervous
twigs ; having reached the side of the spinous process, it is reflected backward along
that process, perforates the spinal attachments of the latissimus dorsi, and thus gains
the under surface of the trapezius ; in this situation it is reflected outward between the
latissimus dorsi and the trapezius, perforates the latter muscle very obliquely, and be-
comes sub-cutaneous ; it then passes horizontally outward in the fonn of a small nervous
riband, the distinct fibres of which do not disunite and spread out in the substance of
the skin until they have arrived at the scapular region. The cutaneous branch, which
belongs to the second dorsal nerve, always corresponds to the triangular surface on the
spine of the scapula, over which the aponeurosis of the trapezius glides.
In one subject which I examined, the musculo-cutaneous divisions of the posterior
branches of the third, fourth, and fifth dorsal nerves presented two ganglia at the point
where they bifurcated into their muscular and cutaneous branches ; in another, the
ganglia were situated upon the cutaneous branches belonging to the first and third dor-
sal nerves. All these cutaneous branches are horizontal, parallel, and separated from
each other by an interval corresponding to the height of one vertebra. Such of the pos-
terior branches of the dorsal nerves as are in relation with the trapezius always present
the preceding arrangement. But the branches lower down than that muscle are dis-
tributed in the following manner :
The posterior branches of the ninth, tenth, eleventh, and twelfth dorsal nerves are distribu-
ted in precisely the same way as the posterior branches of the lumbar nerves, and, like
them, are intended for the abdominal parietes.
There is no longer any internal or musculo-cutaneous branch, the external branch
representing both the muscular and the cutaneous branch.*
Immediately after emerging from the inter-vertebral foramina, these posterior branches
pass very obliquely downward and outward, gain the cellular interval between the sacro-
iumbalis and the longissimus dorsi, or, rather, pass very obliquely through the common
mass formed by the union of the sacro-lumbalis and longissimus dorsi, and almost al-
ways communicate with each other during their long course through the fleshy fibres ;
having arrived opposite the outer border of the latissimus dorsi, or of the common mass,
these branches, diminished fully one third in consequence of having supplied the poste-
rior spinal muscles, perforate very obliquely the aponeurotic layer formed by the union
of the aponeuroses of the latissimus dorsi and serratus posticus inferior, with those from
the internal, oblique, and transverse muscles of the abdomen, and become sub-cutaneous ;
they then divide into some very small internal cutaneous filaments, whicli are directed
inward upon the side of the spinous processes, and some large external cutaneous fila-
ments, which descend to terminate in the skin of the gluteal region. I would especially
notice several large nerves, which, either joined together, or only in contact, descend
vertically, cross perpendicularly over the crest of the ilium in front of the outer border
of the common mass of the lumbar muscles, and become applied to the integuments of the
gluteal region, upon which they may be traced as far as the great trochanter.
* iThe internal branches of the four lower nerve.s are not absent, but are much reduced in size, do not
reach the surface, and are distributed principally to the multifidus spinae: the external branches give the
cutaneous twigs. (Demonstrations of Anatomij, by G. V. Ellis, of whose labours in reference to the anatomy
of the nerves, free use has been made in this and many of the succeeding notes.)]
776 NEUROLOGT.
The Posterior Branches of the Lumbar Nerves. — These resemble in their distribution the
corresponding branches of the four lower dorsal nerves ; they gradually diminish in size
from above downward ; the fifth is extremely small, and is entirely expended in the
common mass of the lumbar muscles.
The Posterior Branches of the Sacral Nerves. — These branches emerge from the poste-
rior sacral inter-vertebral foramina. It is difficult to dissect them, because they are
extremely small, and penetrate immediately into the muscular mass which occupies the
sacral groove ; they moreover decrease in size from above downward, and are uniformly
arranged in the following manner : immediately after their exit from the posterior inter-
vertebral foramina, they form anastomotic arches with each other, from which muscular
and cutaneous filaments are given off. The former are distributed to the common mass
and the glutaeus maxiraus, and the latter are intended for the skin of the sacral region.*
The Anterior Branches of the Spinal Nerves.
The anterior branches of the spinal nerves, which are generally larger than the posterior,
are the true continuations of these nerves, and supply the lateral and anterior parts of
the trunk, and also the upper and lower extremities.
Such of these branches as are intended for the trunk of the body have an extremely
uniform and very simple mode of distribution ; to this class belong the intercostal
nerves : those, on the other hand, which are intended for the upper and lower extremi-
ties, present, in their distribution, a degree of complexity which depends on that of the
parts which they supply. To this class belong the anterior cervical, anterior lumbar, and
anterior sacral branches.
The three last-named sets of branches, almost immediately after their exit from the
spinal canal, communicate with each other, so as to form interlacements or plexuses,
from which are given off the nerves, that ultimately ramify in all parts of the body.
There are four great plexuses : two for the region of the neck and the upper extrem-
ity, viz., the cervical plexus (x,fig. 268) and the brachial plexus (h), which might be re-
garded as a single plexus, the cervico-brachial ; and two for the lumbar region and the low-
er extremity, viz., the lumbar (/) and the sacral or crural plexus (s), which also might be
regarded as one, the lumbosacral plexus.
After these preliminary observations, I shall now describe, in succession, the anterior
branches of the cervical, dorsal, lumbar, and sacral nerves.
THE ANTERIOR BRANCHES OF THE CERVICAL NERVES.
Dissection. — Anterior Branch of the First, Second, Third, and Fourth Cervical Nerves. —
The Cervical Plexus — Its Anterior Branch, the Superficial Cervical — Its Ascending
Branches, the Great Auricular and the External or Lesser Occipital — Its Superficial De-
scending Branches, the Supra-clavicular — Its Deep Descending Branches, the Nerve to the
Descendins Noni and the Phrenic — Its Deep Posterior Branches. — The Anterior Branches
of the Fifth, Sixth, Seventh, and Eighth Cervical, and First Dorsal Nerves. — The Brach-
ial Plexus. — Its Collateral Branches above the Clavicle — Its Muscular Branches, Poste-
rior Thoracic, Supra-scapular, opposite to the Clavicle, the Thoracic, below the Clavicle, the
Circumflex — Its Terminal Branches, the Internal Cutaneous and its Accessory, the Mus-
culo-cutaneous, the Median, the Ulnar, the Musculo-spiral or Radial. — Summary of the
Distribution of the Branches of the Brachial Plexus.
Dissection. — It is convenient to dissect the sub-cutaneous branches which emerge
from the cervical plexus before examining the anterior branches of the cervical nerves :
one side of the neck may be reserved for the superficial, and the other for the deep
branches.
The Anterior Branches of the First, Second, Third, and Fourth Cervical Nerves.
The Anterior Branch of the First Cervical Nerve. — This branch {u. Jig. 300) emerges
from between the occipital bone and the posterior arch of the atlas in the groove for the
vertebral artery, and beneath that vessel ; opposite the foramen in the transverse pro-
cess of the atlas, it leaves the artery, passes in front of the base of that process, is re-
flected downward, and descends to form an anastomotic arch with the anterior branch
of the second nerve. As all the branches belonging to the first nerve come off from this
anastomotic arch, they will be described with the second nerve.
The Anterior Branch of the Second Cervical Nerve. — This is much smaller than the pos-
terior branch of the same nerve ; it passes horizontally forward between the transverse
processes of the atlas and axis, is reflected in front of the axis, and divides into an as-
cending and a descending branch.
* Among the cutaneous filaments which proceed from the arch formed by the jposterior branches of the first
and second sacral nerves, there i* one wliich passes below the posterior and inferior spinous process of the
ilium, is directed vertically downward between the glutieus m:i.\iraQs and the lesser sacro-sciatic ligament,
oerforates the gluUeus muxiiuus, and is then reflected outward in noutact with the skin.
THE CERVICAL PLEXUS. 777
The ascending branch curves upward in front of the transverse process of the atlas, and
j^j^astomoses in an arch with the anterior branch of the first nerve.
., The descending branch {z, fig. 298) subdivides into two others of almost equal size : the
.'one internal (see also fig. 300), which constitutes the internal descending cervical nerve
(before s, fig. 298) ; the other external (behind s), which anastomoses with the third nerve
^.^above s), to form the superficial cervical nerve {k) and the great auricular nerve (q).
Several large filaments for the rectus capitis anticus major are given off from the angle
.of bifurcation of the ascending and descending branches.
** The anastomotic arch formed by the anterior branches of the first and second cervi-
cal nerves gives off three or four very large grayish branches and several small white
filaments, which go to the superior cervical ganglion of the sympathetic ; above these it
gives a short gray filament, which almost immediately swells into a ganglion, from which
a long, slender, descending filament proceeds to join the internal descending nerve ; lastly,
it furnishes two ascending filaments, the lower one of which joins the pneumogastric
nerve, and the upper one the hypoglossal or ninth nerve.
The Anterior Branch of the Third Cervical Nerve. — This (above s, fig. 298) is twice as
* large as the preceding ; it at first passes forward to emerge from the inter-transverse
space, then downward and outward, and having gained the under surface of the stemo-
mastoid muscle, it expands into a great number of branches, which constitute the cervi-
cal plexus properly so called, and may be divided into a superior and an inferior portion.
The superior division passes outward and backward beneath the sterno-mastoid mus-
'■■«de, and bifurcates upon its posterior borders. One of the branches of the bifurcation as-
cends, and is called the mastoid nerve (y) ; the other, which is reflected over the posterior
border of the muscle, anastomoses by one or two filaments with the anterior branch of
the second cervical nerve, and subdivides into the superficial cervical nerve {k) and the
auricular nerve (q) : both of the branches of the bifurcation anastomose with the second
cervical nerve. This superior division, moreover, gives off a small nerve, which as-
cends between the auricular and mastoid nerves ; also a communicating branch to the
superior cervical ganglion ; and, lastly, a series of branches («), which anastomose with
the spinal accessory nerve of Willis (<), some immediately, and others while v/ithin the
substance of the sterno-mastoid muscle. This superior division of the third nerve some-
times joins the lowest branch of the second nerve.
The inferior or descending portion passes vertically downward in front of the scalenus
anticus, gives off a long slender filament to the internal desccndi7ig cervical nerve, and ter-
minates partly by anastomosing with the fourth cervical nerve (below s), and partly by
becoming continuous with the clavicular nerves (w).
A considerable branch which enters the levator anguli scapulas may be regarded as be-
longing to this inferior portion. This branch for the angularis sometimes arises at the
point of bifurcation of the anterior branch of the third nerve.
The Anterior Branch of the Fourth Cervical Nerve. — This branch (below s) is of the
same size as the preceding ; it gives off the phrenic nerve (J), which sometimes arises in
the inter-transverse space ; it then passes downward and outward in contact with the
scalenus anticus for about ten lines, and divides into two terminal branches, the one in-
ternal, the other external, which soon subdivide and cover the supra-clavicular triangle
with their diverging ramifications : these branches constitute the supra-clavicular and
acromial nerves (m). Just opposite its division the anterior branch of the fourth cervi-
cal ner\'e receives a branch from the third, which appears to be shared between its two
terminal divisions.
The fourth cervical generally sends off a small communicating branch to the fifth cer-
vical nerve.
The Cervical Plexus.
The term cervical plexus is applied to the series of anastomoses (z s) formed by the an
terior branches of the first, second, third, and fourth cervical nerves.
Some anatomists call it the deep cervical plexus, in contradistinction to the superficial
branches given off from it, which, according to this view, constitute the superficial cervi
cal plexus.
This plexus, which occupies the anterior and lateral aspect of the four superior cer-
vical vertebrae, is situated beneath the posterior border of the sterno-cleido-mastoid mus-
cle, to the outer side of the internal jugular vein, between the rectus capitis anticus ma-
jor and the cervical attachments of the splenius and levator anguli scapulae : it is con-
cealed by a considerable quantity of fat, and by a great number of lymphatic glands : it
is also covered by an aponeurotic lamina, which adheres to it intimately, and is prolong-
ed upon the nerves which emanate from it.
After the example of Bichat, this plexus may be regarded as a centre in which the
anterior branches of the four superior cervical nerves terminate, and from which a great
number of branches proceed. This plexus is by no means inextricable ; it is always
easy to determine the origin of the branches which come from it.
These branches consist of one anterior branch, the superficial cervical {k) ; of ascending
5 F
778
NEUROLOGY.
branches, viz., the great mastoid (y), the small mastoid, and the great auricular (q) ; and
of descending branches, subdivided into the deep and the superficial ; the deep ones
consisting of the itUerjial descending branch (before s), the •phrenic nerve (/), and the branch-
es for the trapezius, levator anguli scapula, and rhomboideus ; the superficial descending
branches are the supra-clavicular and the acromial (m).
According to their distribution, they may also be divided into muscular and cutaneous
branches ; the muscular consist of the internal descending, the phrenic, the branches for
the trapezius, the levator anguli, and the rhomboideus ; all the others are cutaneous,
and are flattened like ribands.
The Ajiterior Branch.
The Superficial Cervical JVerve.
The superficial cervical nerve (superficialis colli, s, fig. 285), which is often double,
Pig. 285. in consequence of dividing earlier than usual, is des-
tined exclusively for the skin of the neck and lower
part of the face (sous-mentonniere, Chauss.), and is
formed by the anastomoses of the second and third
cervical nerves ; it emerges from the plexus opposite
the middle of the neck, beneath the posterior border
of the sterno-mastoid, around which it turns in the
form of a loop, and then passes horizontally forward
between that muscle and the platysma, runs at right
angles beneath the external jugular vein, and divides
into two branches — one ascending and larger, the oth-
er descending ; these two branches often form two
distinct nerves.
The descendijig branch passes downward and in-
ward between the sterno-mastoid and the platysma, is
reflected upward so as to form a loop, having its con-
cavity turned upward, perforates the platysma, and
then lies in contact with the skin, beneath which it
may be traced as far as opposite the os hyoides.
One of its twigs, which appears to me to be constant, having reached the side of the
median line, is reflected upward in front of the anterior jugular vein, ascends vertical-
ly, and may be traced into the skin of the supra-hyoid region.
The ascending branch, which sometimes arises by a common trunk with the auricular
nerve, immediately divides into four or five very slender and slightly waving filaments,
which, situated at first between the sterno-mastoid and the platysma, generally perfo-
rate the last-named muscle, to become sub-cutaneous ; two of these diverging filaments,
which remain subjacent to the platysma, are very slender, and run along the external
jugular vein, one in front of and the other behind that vessel.
Ail the other filaments pass upward and inward in contact with the skin, and subdi-
vide into a great number of filaments, which may be traced as far as the skin of the chin
and lower part of the cheek ; I have seen two of these filaments anastomose with the
facial nerve. It is important to observe, that the cervical filaments of the facial nerve
occupy a deeper plane than those of the superficial cervical nerve, and are separated
from these latter in front by the platysma.
The Ascending Branches.
The Auricular J^erve.
The auricular nerve (auricularis magnus, d, fig. 285), the ascending anterior branch of
the cervical plexus, arises from the second and third cervical nerves by a trunk which
is common to it and to the superficial cervical ; it emanates from the plexus immediate-
ly above the last-named nerve, hke which it embraces the posterior border of the sterno-
mastoid so as to form a loop with the convexity turned backward, and then passes up-
ward and a little forward between the platysma and the sterno-mastoid, and reaches the
anterior border of that muscle opposite the angle of the lower jaw. In this situation it
gives off" several facial or parotid filaments, and terminates by dividing into a superficial
and a deep branch.
The facial or parotid branches are very slender ; some of them pass between the parot-
id and the skin, with which they are in contact ; the others pass through the parotid
gland from behind forward, and from below upward, to be distributed to the skin of the
cheek ; I have traced them as far as the skin which covers the malar bone ; it has not
been shown that some of them terminate in the substance of the parotid, as has been
stated.*
The superficial auricular branch ascends vertically, in the substance of the very dense
* I have seen two of these parotid filaments terminate in a small abnormal ganglioii, from which other fil
aments were given off and distributed in the manner above described
THE SUPRA-CLAVICULAR NERVES. 779
fibrous tissue which connects the parotid to the skin ; it gains the lower part of the
concha opposite to the anti-tragus, and then divides into several filaments, the distribu-
tion of which is remarkable : the largest passes above the lobule in the fissure between
the concha and the caudal extremity of the helix, and is distributed to the skin on the
concave surface of the auricle, and especially to the skin of the concha ; another fila-
ment turns round the margin of the auricle, and gains the groove of the helix, which it
follows even to its upper part.
The deep auricular branch, which may be called the antenor mastoid, perforates the
substance of the parotid gland, and gains the front of the mastoid process ; here it
crosses at an acute angle over the auricular branch of the facial nerve, which is more deep-
ly seated, and with which it anastomoses by a rather large branch ; it then passes be-
hind the posterior auricular muscle, and divides into two secondary branches : a poste-
rior, which passes upward and backward, and may be traced as far as the outer border
of the occipitalis muscle, where it anastomoses with a very delicate filament of the ex-
ternal occipital nerve ; and an anterior, which runs upon the upper part of the cranial
surface of the auricle. The superior filaments are reflected over the upper margin of
the auricle, and are distributed to the skin which covers its external or concave surface.
From what has been just stated, it follows that the auricularis magnus gives off no
. muscular filament. The posterior auricular and occipitalis muscles are supplied entire-
" ly from the auricular branch (c) of the facial nerve.
The Mastoid or External Occipital Kerve.
The mastoid or external occipital nerve (occipitalis minor, b), the posterior ascending
branch of the cervical plexus, rises from the second cervical nerve ; it comes off from
the plexus above the preceding nerve, describes a loop with the convexity turned up-
ward upon the posterior border of the sterno-mastoid, ascends almost vertically, parallel
to the great occipital nerve and to the posterior border of the sterno-mastoid, crosses
the posterior occipital attachments of that muscle, continues to ascend upon the occipi-
fe'tal region, and then upon the parietal region, and may be traced as far as opposite the
t anterior border of the parietal bone. During this course it is situated between the sple-
jiius and occipitalis muscles and epicranial aponeurosis on the one hand, and the skin on
"the other.
This nerve gives off in the occipital region some external branches, which are distrib-
uted to the skin, and anastomose with a filament of the auricular nerve, but none of them
pass to the auricle. The term occipito-auricular (Chauss.) is, therefore, not applicable to
it ; it should rather be called the external occipital (occipitalis minor, b),* to distinguish
. it from the internal occipital (occipitalis major, a), given off by the posterior branch of
the second cervical nerve.
It also supplies some internal branches, which anastomose several times with the in-
ternal occipital nerve, and are distributed to the skin.
It gives no filament to the occipitalis muscle, nor does it anastomose with the facial
nerve. The mastoid or external occipital nerve is essentially a cutaneous nerve.
We sometimes find a small supplementary branch between the great auricular and
.external occipital nerves, which runs parallel to them, and may be called the small mas-
.. jtoid nerve (c).
The Superficial Descending Branches.
The Supra-clavicular JVerves.
The Supra-clavicular Nerves {e,fig. 285 ; u,fig. 298). — The terminating branches of the
cervical plexus are two in number : one internal, or the supra-clavicular nerve, properly
so called ; the other external, or the acromial nerve ; they come off from the plexus at
the posterior border of the sterno mastoid, descend perpendicularly towards the clavicle,
and divide into several branches, which again subdivide before reaching that bone, so
that they cover the supra-clavicular triangle with their diverging filaments. All these
branches cross over the clavicle at almost regular intervals, and are lost upon the upper
and anterior part of the thorax.
The innermost or sternal branches cross very obliquely over the external jugular vein,
then over the clavicular and sternal attachments of the sterno-mastoid, and ramify in
the skin, where they may be traced as far as the median line.
The external or acromial branches pass obliquely over the external surface of the tra-
pezius, cross the outer end of the clavicle, and are distributed to the skin over the acro-
mion and the spine of the scapula. I have followed some filaments over the top of the
shoulder as far as the lower borders of the pectoralis major.
The intermediate or clavicular branches cross the clavicle at right angles, are in con-
tact with the skin upon the upper part of the thorax, and maybe traced to within a short
distance of the nipple, t
* The name mastoid branch is bad, for this branch has no relation with the mastoid process,
t Not unfrequcntly the supra-clavicular nerve passes through a foramen in the clavicle, at the junction of
the external third with the internal two thirds of that bone ; sometimes, instead of a bony canal, there is A
t80 NEUROLOGY.
All these branches lie at first beneath the platysma, and then become sub- cutaneous.
A layer of fascia and the omo-hyoid muscle are interposed between them and the scaleni
muscles and brachial plexus. Some loose cellular tissue separates them from the clav-
icle, upon which they glide with the greatest freedom.
The Deep Descending Branches.
The Internal Descending Cervical J^erve.
The internal descending cervical nerve (before s, fig. 298), which is destined exclusively
for the muscles of the sub-hyoid region, may be considered as the inferior branch of the
bifurcation of the second cervical nerve, although the first and third nerves each give to
it a small re-enforcing filament.
It passes vertically downward, on the outer side of the internal jugular vein, along
which it runs, is joined on its inner side by a filament from the first cervical nerve, and
having reached a little below the middle of the neck, is reflected inward in front of the
internal jugular vein, and forms an anastomotic loop, which is sometimes plexiform, with
the descending branch (descendens noni, h) of the hypoglossal nerve ; this is a remark-
able anastomosis, and presents many varieties in its arrangement. The convexity of
this loop is turned downward, and from it arises a branch, which sometimes scarcely ex-
ceeds in size either of the formative branches of the loop, and which expands into sev-
eral filaments {g). One of these ascends and supplies the superior attachments of the
sterno-hyoid and omo-hyoid ; a transverse filament proceeds to the bodies of the sterno-
hyoid and sterno-thyroid muscles. Several filaments can be traced as far as the lower
part of the latter muscle, that is to say, down to opposite the second rib. The inferior
fleshy belly of the omo-hyoid is supplied by some twigs derived from the filaments which
enter its superior belly.
The Phretdc or Diaphragmatic Jferve.
The phrenic nerve {I, figs. 298, 302) is a branch derived from the fourth cervical nerve,
sometimes re-enforced by a very small filament from the third nerve, and almost al-
ways by a larger branch from the fifth.* Not unfrequently one of the formative branch-
es of the loop of the hypoglossal nerve just described joins the phrenic nerve. The right
and left phrenics are rarely of the same size.
After its origin, the phrenic nerve descends vertically in front of the inner border of
the scalenus anticus, with which it is held in contact by a fascia. It is round at first,
but becomes flattened as it passes between the sub-clavian vein and artery (I have seen
it pass in front of the vein), and is then inclined slightly inward, to enter the superior
orifice of the thorax. In the thorax (Z, fig. 302) it continues its vertical direction, runs
along the brachio-cephalic vein on the left side, and along the vena cava superior on the
right side, is then applied against the pericardium, to which it is bound down by the
pleura, and, having reached the diaphragm, ramifies in that muscle. It is accompanied
by the superior phrenic artery, which is a branch of the internal mammary, and the su-
perior phrenic vein.
The phrenic nerve gives off no branches in the thorax : at a short distance from its
origin, it anastomoses with the great sympathetic by a transverse branch : at the lower
part of the neck, it sometimes gives off a filament, which forms an anastomotic arch with
a branch derived from the fifth and sixth cervical nerves. I have never seen it com-
municate with the inferior cervical ganglion.
The distribution of this nerve in the diaphragm is curious. Some of its expanded, di-
verging, and generally very long filaments, run between the pleura and the diaphragm,
and enter the muscle from its upper surface ; others pass through the diaphragm, run
between it and the peritoneum, and enter the fleshy fibres from below ; they may be
traced as far as the costal attachments of the muscle. The right phrenic nerve termi-
nates by a transverse branch which passes behind the vena cava, and anastomoses with
certain transverse branches of the left phrenic, before it enters the pillars of the dia-
phragm, in which it terminates. I have never seen any filament of the phrenic nerv6
pass either to the oesophagus or to the solar plexus.
The Posterior Deep Cervical Branches.
These are, an anastomotic branch iv,fig. 298) from the cervical plexus to the spinal ac-
cessory nerve of Willis (t) ; it is of considerable size ; it comes off from the second nerve
at the same point as the external occipital nerve, and an2istomoses at an acute angle
tendinous arch upon the posterior border of the bone. In this case the clavicular branches are not scattered,
but closely aggregated together : the internal branches then pass horizontally inward between the clavicle and
the skin as far as the sternum ; and I have even seen a small twig enter the attachments of the pectoralis ma
jor. The external branches proceed horizontally outward upon the anterior border of the clavicle as far as the
acromion.
* The communication between the phrenic nerve and the fifth cervical nerve occurs in many different modeg.
Sometimes the phrenic supplies the communicating filament, instead of receiving it ; most commonly the
phrenic branch of the fifth arises by a common trunk with the nerve for the sub-clavius muscle, crosses in
front of the subclavian vein, between it and the cartilage of the first rib, with which it is in contact, and
•Mscs behind the internal mammary artery, to join the phrenic nerve at a very acute angle.
THE BRACHIAL PLEXUS. 781
with the spinal accessory, between the cervical fasciculi of the splenius and the sterno-
mastoid.
Also, a ira.ncM.jor the trapezius, which arises from the third nerve, passes obliquely
downward and backward to the deep surface of the muscle, and anastomoses with the
spinal accessory of Willis, which it re-enforces, and with which it may be traced as far
as the lower angle of the muscle.
Lastly, the branches for the levator anguli scapulce and the rhomboideus ; these are rath-
er small branches, which arise from the back part of the third and fourth cervical nerves,
as they emerge from between the transverse processes of the vertebrae, pass obliquely
downward and backward, turn round the scalenus posticus in contact with it, and are
distributed to the levator anguli scapulsD and the upper part of the rhomboideus. The
same branches appear to supply both muscles.
The Anterior Branches of the Fifth, Sixth, Seventh, and Eighth Cervical
AND First Dorsal Nerves.
These branches are remarkable for their size, in which respect they surpass the pre-
ceding, and are almost all equal. On emerging from the inter-vertebral foramina, they
come into relation with the two scaleni muscles, which are separated from each other,
and sometimes are perforated by them ; they give off some very slender filaments to
these muscles, and, converging, anastomose together so as to form the brachial plexus,
from which all the nerves of the upper extremity are derived.
The Brachial Plexus.
The brachial plexus {h,jig. 268) extends obliquely from the lateral and inferior part ol
the neck to the cavity of the axilla, or, rather, to the inner side of the head of the hume-
rus, where it terminates by dividing into the nerves of the upper extremity ; it is formed
in the following manner :
The fifth and sixth cervical nerves (5, 6, fig. 286) unite at a short distance from the
scaleni, and the cord thus formed passes very obliquely downward and outward, and
then bifurcates.
Again, the eighth cervical (8) and the first dorsal (1) nerves unite immediately after
converging from the scaleni, and sometimes even between those muscles ; and the com-
mon cord passes almost horizontally outward, and bifurcates near the head of the humerus.
Between these two anastomotic cords is the seventh cervical nerve (7), which pur-
sues a much longer course than the others, and bifurcates on a level with the clavicle ;
the upper branch of its bifurcation joins the lower branch of the bifurcation of the first-
named cord, and its lower branch unites with the upper branch of the second-named cord.
From these several bifurcations and subsequent anastomoses, all of which take place
at very acute angles, results the interlacement known as the brachial plexus.
The brachial plexus is broad at its upper part, contracted in the middle, and broad
again at its lower part, on account of the divergence of its terminating branches ; it com-
municates with the cervical plexus by a considerable branch, which it receives from the
fourth cervical nerve, and also by the filament which it gives to the phrenic nerve ; it is
not so complicated but that the origins of the branches which emanate from it may be
traced ; I shall take care to do this for each nerve.
Relations. — At its origin it is situated between the scaleni, which cover it for a great-
er extent below than above. A very strong aponeurosis, which extends over it and the
scaleni also, completely isolates it from the surrounding parts.
Lower down, it is situated between the clavicle and sub-clavius muscle on the one
hand, and the first rib and upper part of the serratus magnus on the other.
Still lower, it is contained in the cavity of the axilla, separated from the pectoral-
is major in front by the costo-clavicular aponeurosis, and resting upon the scapulo-hu-
meral articulation behind, from which it is separated by the tendon of the sub-scapularis.
The following are its relations with the axillary artery : Between the scaleni and be-
low them, the artery is situated upon the same plane as the brachial plexus, and lies be-
tween the plexus and the first rib. Lower down it is placed on the anterior part of the
plexus ; at the lower extremity of the plexus it passes under the angle of union of the
two roots of the median nerve, by which it is embraced ; the axillary vein always lies
in front of the artery, and therefore has less direct rela-
tions with the plexus.
The branches of the brachial plexus may be divided
into the collateral and the terminal.
The terminal branches are five in nimiber, namely, the
internal cutaneous {g, fig. 286) and its accessory, the mus-
culo-cutaneous {b), the median (c), the radial or musculo-
spiral (/), and the ulnar {d) nerves.*
The collateral branches may be divided into those giv-
* I think it right to class the circumflex nerve among the collateral branches, and not, like most authors,
among the terminal branches of the plexus.
^^2 NEUROLOGY.
en off above the clavicle, namely, the nerve for the suh-clavius, those for t^eJevator angu
li scapula and rhomboidcus, the posterior thoracic or nerve for the serratus magnus, the su-
pra-scapular nerve (a) or nerve for the supra- and infra-spinati muscles, and the superior sub-
scapular nerve ; those given off opposite the clavicle, namely, the thoracic branches ; and
those given off in the axilla, namely, the circumflex nerve (e) and the sub-scapular branches^
which comprehend the nerve for the latissimus dorsi, the nerve for the teres major, and the
inferior scapular nerve.
One hranch only, namely, the nerve for the sub-clavius muscle, arises from the front
part of the brachial plexus : all the other collateral branches are given off from the back
of the plexus.
The Collateral Branches of the Brachial Plexus.
The Branches given off below the Clavicle.
The Nerve for the Sub-clavius Muscle. — This is a small but constant branch, which
comes off from the fifth cervical nerve, immediately before its junction with the sixth,
passes vertically downward in front of the sub-clavian artery, and then enters perpendic-
ularly into the middle of the sub-clavius muscle.
This small nerve, before reaciiing the sub-clavius, always gives off a phrenic branch,
which passes obliquely inward in front of the sub-clavian vein, and anastomoses with the
phrenic nerve.
The Nerve for the Levator Anguli Scapula. — This branch arises as frequently from the
cervical as from the brachial plexus ; in the former case, it arises from the fourth cervi-
cal nerve, in the latter from the fifth. It arises from the nerve immediately after its exit
from the canal of the transverse processes, turns round the scalenus posticus to gain
the deep surface 'oi the levator anguli scapulae, enters the muscle, supplies it with a
great number of filaments, and perforates it to reach the rhomboideus, under which it
passes. One of its terminating filaments anastomoses with a filament from the proper
nerve for the rhomboideus.
The Nerve for the Rhomboideus. — ^This arises from the fifth cervical nerve, immediately
below the preceding ; I have seen it arise by a common trunk with the superior branch^,
of origin of the nerve for the serratus magnus ; it passes downward and backward be- ^
tween the scalenus posticus and the levator anguli scapulae, and then beneath the last- *
mentioned muscle, nearly as far as its scapular attachments, in order to get between the
rhomboideus and the ribs ; it may be traced as far as the lower part of that muscle. One
of its filaments perforates the rhomboideus, and anastomoses in the trapezius with the
posterior spinal nerves.
The Nerve for the Serratus Magnus {Posterior Thoracic Nerve of authors ; External Res-
piratory Nerve, Sir C. Bell). — This branch, which is very remarkable for the length of
its course, is derived from the fifth and sixth cervical nerves, immediately after their exit
from the canal of the transverse processes ; it arises by two roots, which are sometimes
equal and sometimes unequal in size ; it passes vertically downward behind the brachial
plexus and the axillary vessels, in front of the scalenus posticus, reaches the side of the
thorax (e', fig. 287), between the sub-scapularis and the serratus magnus, runs the whole
length of the last-named muscle, and ramifies in its lower portion.
During this course, it gives off a great number of filaments to the muscle : the lowest
of these may be traced as far as the lowest digitation. The branch which it gives to the .
upper part of the muscle is remarkable for its size.
I have seen a branch from the seventh cervical nerve join the external thoracic nerve ;
upon the upper part of the serratus magnus, so that this nerve would then be derived
from the fifth, sixth, and seventh cervical nerves.
The Supra-scapular Nerve, or Nerve for the Supra- and Infra-spinati Muscles. — This j
branch (a, fig. 286) is given off from the back part of the fifth cervical nerve at its junc-
tion with the sixth ; it passes obliquely backward, outward, and downward, dips beneath ,,
the trapezius, and then under the omo-hyoid, the direction of which it nearly follows,
and gradually increases in size as it approaches the coracoid notch of the scapula, and
passes by itself under the ligament which converts this notch into a foramen ; the supra-
scapular artery and vein, which had hitherto been in contact with the nerve, leave it op-
posite this notch to pass above the ligament, and then join it again in the supra-spinous
fossa.
The nerve then runs from before backward in the supra-spinous fossa, protected by a .^
thick fibrous lamella, reaches the free concave border of the spine of the scapula, against"
which it is held by a fibrous band, is then reflected inward and downward over this con- ,j
cave border to gain the infra-spinous fossa, and immediately divides into two branches, ,.^
one of which spreads out in the upper part, and the other in the lower part of the infra- ,^
spinatus muscle.
During its course through the supra-spinous fossa, the supra-scapular nerve gives off
two supra-spinous branches, one of which is detached opposite the coracoid notch, and
the other upon the spine of the scapula. They both enter the supra-spinatus muscle. »
BRANCHES BELOW THE CLAVICLE. 783
The supra-scapular nerve is exclusively destined for the supra- and infra-spinati mus-
cles. It gives no filament to the sub-scapularis.
The Superior Sub-scapular Nerve. — This is a very small branch which arises imme-
diately above the clavicle, and passes downward and forward to reach the upper border
of the sub-scapularis, and then enters that muscle.
The Branches given off opposite to the Clavicle.
These, which are named the thoracic branches,* are generally two in number, one an-
terior, the other ;?os^mor : they arise from the anterior part -of the brachial plexus, oppo-
site the sub-clavius muscle. The anterior branch, or nerve for the pectoralis major, which
is the larger, passes downward and forward between the sub-clavius muscle and the sub-
clavian vein, and divides into two branches : an external, or anastomotic, which some-
times arises directly from the brachiad plexus, and forms a loop around the axillary ar-
tery, by anastomosing with the posterior thoracic branch ; and an internal, which runs
along the deep surface of the pectoralis major, and expands into a great number of re-
markably long and slender filaments, which enter the muscle very obliquely, and may be
traced as far as its sternal attachments. A very slender filciment is constantly foimd
running along the clavicle.
The posterior thoracic branch, or nerve for the pectoralis miner, passes behind the axillary
artery, below which it curves forward, to form, with the external branch of the anterior
thoracic, the anastomotic loop of which I have already spoken. From this loop or arch,
in forming which the nervous filaments are separated from each other, two sets of
branches proceed : the one set runs between the pectoralis major and minor, closely
applied to the former muscle, which they then enter, diverging to its lowest part ; the
others pass beneath the pectoralis minor, and penetrate its deep surface ; some of them
pass obliquely through this muscle and join the anterior thoracic branches in the pecto-
ralis major.
The Branches given off below the Clavicle.
The Axillary or Circumflex Nerve. — This is no less remarkable for its great size, which
has led some anatomists to regard it as a terminal branch of the brachial plexus, than
for its reflected course : it comes off from the back of the plexus, behind the musculo-
spiral nerve, or, rather, the circumflex and musculo-spiral nerves (e and f, fig. 286) ap-
pear to be the two divisions of a trunk formed by filaments from the five branches of the
brachial plexus.
Immediately after its origin, the circumflex nerve passes downward and outward (g,
fig. 288) in front of the sub-scapularis, which separates it from the shoulder-joint, turns
obliquely round the lower border of that muscle, round the back part of the articulation,
and, lastly, round the surgical neck of the humerus, is then reflected upward, so as to de-
scribe a curve with the concavity turned in the same direction, and terminates by ram-
ifying in the deltoid.
During this curved course, the circumflex nerve, accompanied by the posterior cir-
cumflex vessels, passes at first between the sub-scapularis and the teres major, then be-
low the teres minor, on the outer side of the long head of the triceps (i. e., next to the
bone), and then lies in contact with the deep surface of the deltoid, against which it is
held by a very dense layer of fascia.
The relation of the circumflex nerve to the articulation explains the possible occur-
rence of laceration of this nerve in luxations of the humerus downward.
The collateral branches of the circumflex nerve are three in number. One branch almost
always goes to the sub-scapularis. I have already said that the sub-scapular nerves
might be regarded as branches of the circumflex.
As it turns round the lower border of the sub-scapularis, the circumflex gives off a
branch for the teres minor and the cutaneous branch of the shoulder.
The nerce for the teres minor enters that muscle by its lower border ; it almost always
arises by a common trunk with a deltoid branch, which runs upward and backward to
supply the back part of the deltoid muscle.
The cutaneous nerve of the shoulder frequently arises by a common trunk with the two
preceding, and, in this case, the circumflex nerve appears to bifurcate ; it passes under
the posterior border of the deltoid, then lies in contact with the skin covering the back
part of the top of the shoulder, and divides into diverging branches, some ascending, oth-
ers descending, and others running horizontally. A second, and sometimes a third cu-
taneous branch perforates the fleshy fibres of the deltoid, and is distributed to the corre-
sponding skin.
The terminal or deltoid branches of the circumflex nerve are given off as that nerve is turn ■
ing round the neck of the humerus, in which situation it divides into several diverging
branches, the superior of which ascends, and appears like the continuation of the nerve,
while the others descend, and may be traced as far as the insertion of the muscle into the
humerus.
* The anterior thoracic nerves of those who name the nerve for the serratus magnus the posterior thoracic
784
NEUROLOGY.
Tlie Sub-scapular Nerves. — The nerve for the latissimns dor si is the largest of the nerves
generally described as the sub-scapular ; it comes off at an acute angle from the inside of
the circumflex nerve, and descends vertically in the midst of the cellular tissue of the
axilla, between the sub-scapularis and serratus magnus, parallel to the external thoracic
nerve, which it greatly resembles in size and direction as well as in its length ; it then
passes in front of the latissimus dorsi, reaches its outer border, and may be traced down
to the lower part of that muscle.
The nerve for the teres major arises at a very acute angle from the preceding nerve, to
the inner side of which it runs ; it passes to the sub-scapularis, turns round its outer bor-
der, and enters the anterior surface of the teres major by a great number of filaments.
The inferior sub-scapular nerve {I, Jig- 288) is sometimes multiple, and presents many
varieties in its origin and number. Thus, it sometimes curves directly from the brachial
plexus ; sometimes from a common tnmk with the circumflex nerve. Again, it often
arises by a common trunk with the nerve for the teres major. Whatever be its origin,
and whether it be single or multiple, it enters immediately into the sub-scapularis, and
terminates there.
We have seen that a small branch given off from the brachial plexus above the clavi-
cle, the superior sub-scapular nerve, enters the same muscle at its upper border.
The Terminal Branches op the Brachial Plexus.
The Internal Cutaneous Jferve and its Accessory.
^- 287. The internal cutaneous nerve (g, fig. 286), the most internal
and the smallest of the terminal branches of the brachial plex-
us, arises by a common trunk with the ulnar nerve (</) and
the internal root of the median (c) : concealed at first by the
axillary artery, it descends vertically (a, Jig. 288) to the inner
side of the median nerve, and in front of the basilic vein : at
the upper part of its course it lies beneath the fascia, but it
becomes sub-cutaneous at the same time as the basilic vein
{b, fig. 287), and is then separated from the median nerve by
the brachial aponeurosis ; at the middle of the arm, it divides
into two terminal branches, an external, anterior or ulnar, and
an internal, posterior or cpitrochlear. The internal cutaneous
gives off only one branch during its course along the arm,
namely, a cutaneous branch, which varies in size as well as in
the situation at which it is given off: this cutaneous branch
arises in the cavity of the axilla, often anastomoses with an
intercostal nerve, is applied against the skin on the inner as-
pect of the arm, and may be traced as far as the elbow.*
Terminal Branches. — The anterior, external or ulnar branch,
which is the larger, continues in the vertical direction of the
trunk of the nerve, and divides into two branches, which de-
scend in front of the elbow-joint, sometimes before, and some-
times behind the median basihc vein (e), and again subdivide
into a great number of filaments which diverge, and are ar-
ranged in the following manner : the internal filaments pass
obliquely downward, inward, and backward, crossing the ul-
nar vein (m), and then the ulna, and supply the skin covering
the inner and back part of the forearm ; they can be traced
nearly as far as the region of the carpus : the external fila-
ment, which might be called median, because it follows the
median vein, descends vertically, and may be traced as far as
the upper part of the palm of the hand ; one of these filaments
always anastomoses with a twig from the ulnar nerve at the
lower part of the forearm.
The posterior, internal or epitrochlear branch (g), descends ver-
tically behind the median basilic vein, in front of the epitroch-
lea, and then below it, so as to embrace it in a sort of loop ;
it then passes very obliquely downward and backward, cross-
es the ulna below the olecranon, gains the dorsal aspect of
the forearm, and runs vertically (a, fig. 289) down to the wrist.
Around the epitrochlea, this internal branch gives off several
branches, which ramify upon the skin that covers the inner
side of the elbow-joint : one of these branches is reflected up-
ward between the epitrochlea and the olecranon, and anasto-
moses with the accessory nerve of the internal cutaneous.
* I have always found a remarkably long and slender filament arising from the internal cutaneous nerve at
the upper part of the arm ; it runs along that nerve, passes beneath the basilic vein, and then lies in contact with
the fascia, which it perforates near the epitrochlea, and is lost upon the synovial membrane of the elbow-joint.
THE MUSCULO-CUTANEOUS NEEVE. 1^5
Frequently, before reaching the epitrochlea, this branch has already given off a twig
which anastomoses with the same nerve.
Summary. — The internal cutaneous nerve, then, is exclusively intended for the skin. It
only gives one small branch to the arm : its other divisions are intended for the forearm.
One of them belongs to the dorsal, and the other to the internal aspect.
The Accessory Nerve of the Internal Cutaneous. — I have applied this term to a small
branch (cutaneus minor internus, Wrisberg), which it is difficult to discover, and which
would be more properly classed among the collateral than the terminal branches of the
brachial plexus : it arises above and sometimes below the clavicle, from the back part
of the nervous cord formed by the junction of the eighth cervical and first dorsal nerves :
it passes downward upon the sides of the thorax, and divides into two branches, an ex-
ternal and an internal.
The external branch (a', fig. 287), which is the smaller one, passes vertically downward,
and crosses the conjoined tendons of the teres major and latissimus dorsi at right an-
gles ; it lies in contact with the skin covering the inner and back part of the arm, and
may be traced as low as the elbow.
The internal branch (c) anastomoses with the second intercostal nerve, descends ver-
tically, crossing the conjoined tendons of the latissimus dorsi and teres major, becomes
applied to the skin, and divides into several very slender filaments, which correspond to
the internal, anterior, and posterior regions of the arm, and may be traced as far as the
region of the elbow ; one of these filaments anastomoses with the internal cutaneous.*
The Musculo-cutaneous JSTerve.
The musculo-cuta?ieous nerve (b, fig. 286), the most external of the terminal branches
of the brachial plexus, and, with the exception of the internal cutaneous, the smallest,
arises by a common trunk with the external root of the median nerve (c), passes down-
ward and outward, in front of the humeral insertion of the sub-scapularis, and on the
inner side of the coraco-brachialis, which is perforated by it, and is therefore called the
per/orated muscle of Casserius.f After emerging from the muscle, through which it passes
very obliquely,t the musculo-cutaneous nerve {h,fig. 288) is situated between the biceps
and the brachialis anticus, continues its oblique course, escapes from beneath the outer
border of the tendon of the biceps, and then becomes sub-cutaneous.
During its course along the arm it gives off the following branches
The branches for the coraco-brachialis are two in number : one superior, which enters the
upper part of this muscle, and is then lost in the short head of the biceps ; the other in-
ferior, which, in some subjects, after having furnished a certain number of filaments to the
coraco-brachialis, becomes applied to the trunk of the musculo-cutaneous nerve itself.
The branches for the biceps are very numerous : not uncommonly they arise by a com-
mon trunk, which then appears to result from the bifurcation of the musculo-cutaneous.
One of these branches perforates the biceps, and passes transversely outward to reach
the elbow-joint, to which it is distributed.
The branches for the brachialis anticus almost always arise by a large common trunk
which appears to result from a farther bifurcation of the nerve, already diminished one
half, after it has supplied the branches for the biceps. While these last-named branches
enter the posterior surface of the corresponding muscle, the branches for the brachialis
anticus penetrate that muscle by its anterior surface.
After having given off all these muscular branches, the musculo-cutaneous nerve, re-
duced to a fourth or a fifth of its original size, is distributed entirely to the skin ; it passes
vertically downward in front of the elbow-joint, behind the median cephalic vein {a, fig.
287), and divides into two terminal branches, of which the internal (A) runs along the
inner, and the external along the outer side of the radial vein.
These two branches, during their course along the forearm, lie between the fascia of
the forearm and the superficial fascia ; they gradually diminish in size as they give off
their filaments to the skin, and terminate in the following manner :
The external branch passes to the dorsal surface of the forearm, and may be traced as
far as the skin which covers the carpus.
The internal branch has a more extensive distribution ; it anastomoses with a branch
of the radial nerve at the lower part of the forearm, and gives off a deep or articular
branch, which divides into several twigs that surround the radial artery. One of these
twigs expands into a number of filaments which enter the fore part of the radio-carpal
articulation ; the others accompany the radial artery in its oblique course upon the outer
side of the carpus, and then spread out to terminate on the back part of the synovial
membrane of the wrist-joint. After having given off this very remarkable articular
branch,!^ the internal terminal division of the musculo-cutaneous nerve passes in front
* [And with the internal cutaneous branch of the musculo-spiral nerve.]
t [The nerve is also called perforans Casserii.l
X Not unfrequeutly the nerve does not perforate the coraco-brachialis. [It sometimes has an anastomosis
iMth the median nerve after emerging from the coraco-brachialis.]
t In one subject, the articular filaments had some gangliform enlargements on their sides precisely similar
5G^
me
NEUROLOGY.
of the tendons of the extensor brevis poUicis and abductor longus poUicis, in front of and
more superficially than the corresponding branch of the radial nerve, and then divides
into several twigs, which are intended for the skin of the thenar eminence. One of
these branches, which runs along the outer side of that eminence, may be traced into
the skin upon the first phalanx of the thumb.
Summary. — The musculo-cutaneous nerve, then, supplies certain muscular branches,
which belong exclusively to the coraco-brachialis, the biceps, and the brachialis anticus ;
the section of this nerve would, therefore, destroy the power of flexing the forearm :
certain cutaneous branches to the skin on the outer side of the forearm and hand ; and,
lastly, some articular branches to the elbow and to the wrist.
The Median Jferve.
The median nerve (c. Jig. 286), one of the terminal branches of the brachial plexus,
arises from the plexus by two very distinct roots between the musculo-cutaneous (i) on
the outer side, and the ulnar nerve {d) on the inner.* The internal root arises from a
nervous cord which is common to it, to the ulnar, and to the internal cutaneous (g).
The external root arises from a cord common to it and to the musculo-cutaneous. The
axillary artery passes between these two roots.
The trunk resulting from the union of these two roots is situated on the inner side
of the axillary artery ; it is at first grooved to receive the inner half of tho artery, but it
soon forms a rounded cord, proceeds vertically downward (c. Jig. 288), gains the middle
and fore part of the elbow-joint, dips between the muscles on the anterior region of the
forearm (rf), and passes behind the annular ligament to enter the palm of the hand (r),
where it terminates by dividing into six branches. We shall examine it in the arm, the
forearm, and the hand.
•Pifi". 288. In the Arm.
The median nerve (c), which is straight and vertical,
and the satellite nerve of the brachial artery, passes some-
what obliquely downward, forward, and outward, to the
middle and fore part of the elbow-joint.
Relations. — On the inner side it is sub-aponeurotic, so
that when the arm is held away from the side, and the
forearm is extended upon the arm, it projects below the
skin like a tense cord, which is very distinctly seen in
emaciated subjects.
On the outside, it corresponds at first to the brachialis
anticus, and is then received in the sort of groove formed
between the inner border of the biceps and the brachialis
anticus.
In front, it is covered by the inner border of the biceps,
excepting in emaciated subjects.
Behind, it is in relation with the ulnar nerve (/), and then
with the brachialis anticus.
Its relations with the brachial artery are of the greatest
importance, in reference to the application of a ligature to
that vessel. The nerve is at first situated to the outer or
radial side of the axillary artery, but soon passes in front of
the vessel, and then it crosses over slightly, so that at the
bend of the elbow it is situated about two lines to the inner
or ulnar side of the artery. This last relation is not con-
stant : I have seen the nerve on the outer side of the artery
at the bend of the elbow.
The following are its relations with the other nerves : the
internal cutaneous nerve runs along its inner side, at first
immediately in contact with it, and then separated from it
by the fascia of the arm.
The ulnar nerve runs behind it in the upper third of the
arm, and is then separated from it, so that the two nerves
bound the sides of a triangular interval, the base of which
is below and the apex above.
The median nerve does not give any branch in the
arm.t
to those which are met with on the cutaneous nerves in the palm of the
hand ; the articular filaments, moreover, have almost always the grayish
aspect of the nerves of organic life. . , , ^, ,
* These two roots of the median nerve, when united to the raiisculo-cu
taneous and the ulnar, represent very nearly a capital M. ^ot unfre
quently there is a third internal root for the median nerve.
t [Except, occasionally, an anastomotic branch to the musculo-cutane
ous, after the latter has emerged from the coraco-brachialis.]
THE MEDIAN NERVE IN THE FOREARM AND HAND. 787
In the Forearm.
TTie median nerve, like the brachial artery, to the inner side of which it is generally
situated, passes beneath the tendinous expansion of the biceps, and is separated from
the elbow-joint by the brachialis anticus.
It almost always perforates the pronator teres in such a manner as to leave only a
very small tongue of fleshy fibres behind it;* it then passes (rf, fig. 288) between the
flexor sublimis and flexor profundus digitorum, opposite the cellular interval between
the latter muscle and the flexor longus poUicis : at the lower part of the forearm it runs
along the outer border of the flexor sublimis, where it might be easily exposed between
the tendon of the palmaris longus on the inside, and of the flexor carpi radialis on the
outside. I have seen this nerve perforate the upper part of the flexor sublimis, which
formed a sheath for it.
Branches. — These are muscular, excepting the palmar cutaneous, which arises at the
lower part of the forearm : they supply all the muscles of the anterior region of the fore-
arm except a part of the flexor profundus, and the whole of the flexor carpi ulnaris,
which receive branches from the ulnar nerve. Lastly, with the exception of the palmar
cutaneous, the branches arise near the bend of the elbow.
The branch for the ^pronator teres comes off from the anterior part of the median nerve,
a little above the elbow-joint, and passes downward to enter the substance of the mus-
cle. It gives off several articular filaments, which dip from before backward, around the
termination of the brachial artery and the commencement of the radial and ulnar arter-
ies, form loops with their concavities turned upward in the angle of bifurcation of the
brachial, and then enter the articulation.
The other collateral branches of the median in the forearm arise from its posterioi
aspect : they are the branch for the superficial layer of muscles, which arises opposite the
elbow-joint, and then divides successively into several others, which enter the pronator
teres, the flexor carpi radialis, the palmaris longus, and the flexor sublimis. The filaments
for the flexor sublimis are remarkably slender, and are reflected upward below the epi-
trochlea : they belong to the upper part only of this muscle, which is also supplied by
two or three other branches, given off in succession from the median, a little below the
bend of the elbow.
The branch for the deep layer of muscles is a large trunk, which soon divides into sev-
eral branches, viz., one external, for the flexor longus pollicis, the upper extremity of
which it enters ; two internal, which enter the flexor profundus, but only supply its inner
half, the other half receiving its nerves from the ulnar ;t and a middle branch, the inter-
osseous nerve (e), which requires a particular description. It passes vertically downward,
in front of the interosseous ligament, between the flexor profundus and the flexor lon-
gus pollicis, to both of which it gives several filaments ; having reached the upper bor-
ders of the pronator quadratus, it passes behind that muscle and divides into a great
number of filaments, some of which penetrate the muscle from behind, while others de
scend to gain the lower part of the muscle. I have seen the interosseous nerve per-
forate the interosseous ligament, run a very short distance upon its posterior surface,
then pass through it again, and ramify in the pronator muscle.
The palmar cutaneous branch (i, fig. 287) comes off from the median nerve opposite the
junction of the three upper fourths with the lower fourth of the forearm, runs along the
median nerve, and divides into two branches, which perforate the fascia of the forearm
immediately above the annular ligament. The external branch is the smaller, and cross-
es obliquely over the tendon of the flexor carpi radialis, and terminates in the skin upon
the ball of the thumb ;t the internal branch, which is larger, descends vertically in front
of the annular ligament and beneath the skin, from which it is separated by a layer of
adipose tissue, and is lost in the palm of the hand, much sooner than might be expected
from its size ;^ it can scarcely be traced as far as the middle of the palm.
In the Hand.
The median nerve, while passing behind the annular ligament of the carpus, becomes
considerably wider and flattened ; it might even be said to increase gradually in size.
Immediately after it has passed below the ligament, still flattened out, it divides (r) into
two branches, one internal, the other external, which are themselves subdivided ; the in-
ternal into two, and the external into four branches, so that in aU there are six terminal
branches.
* In one case, in which the humeral attachments of the pronator teres were as high as those of the supina-
tor longus, the median nerve passed through the highest attachments of the pronator teres, and was situated
between the brachialis anticus and that muscle, which also covered it at the bend of the elbow; in this same
case, the brachial artery divided into the radial and ulnar at the middle of the arm ; and the ulnar artery ap-
plied against the nerve had the same relations as the brachial artery in ordinary cases.
t All the deep branches may be traced as far as the periosteum of the bones of tlie forearm. [Some of them
have been seen to communicate with filaments of the ulnar nerve.]
t [This tirauch anastomoses with the terminal cutaneous division of the musculo-spiral or radial nerve.]
^ This sudden mode of termination is common to all nerves of sensation, which are often Uist almost imme-
diately in the skin ; the nerves of motion, on the other hand, run a very h)nsr course as filaments licforf thev
terminate in the muscles.
788 NEUROLOGY.
Tho, terminal branches of the median nerve. Of these one only is muscular, and oe-
longs to the muscles of the ball of the thumb ; the other five are intended for the integ-
uments of the fingers, of vi^hich they form the palmar collateral nerves.
The branch for the muscles of the ball of the thumb is a recurrent nerve ; it arises from
the front of the median, passes upward and outward, forming a horizontal curve with
the concavity turned upward, perforates the superficial layers of the flexor brevis, im-
mediately gives off a descending branch to that muscle, and, continuing to ascend itself,
is divided almost equally between the abductor brevis and the opponens pollicis.
The External Collateral Branch of the Thumb* — This nerve passes obliquely down-
ward and outward, on the inner side of the tendon of the flexor longus pollicis, crosses
the metacarpo-phalangal articulation, to gain the external border of the anterior surface
of the thumb, and, running along the outer side of the tendon of the long flexor, arrives
at the ungual phalanx. On this phalanx, it divides into two branches, a dorsal or ungiud,
properly so called, which turns round the side of the phalanx, anastomoses with the dor-
sal collateral branches of the radial nerve, and is distributed to the dermis beneath the
nail ; and a palmar, which is lost in the skin covering the pulp of the thumb. Some of
these latter filaments turn round the tip of the phalanx, and are distributed to the skin
beneath the nail. None of the filaments of the external collateral branch anastomose
with those of the internal collateral.
The internal collateral branch for the thumb is less oblique in its course and larger than
the preceding ; it nins along the first interosseous space in front of the adductor pollicis,
and reaches the inner side of the anterior surface of the thumb, along the tendon of the
long flexor, and terminates like the preceding branch. This branch gives oflf a twig to
the adductor pollicis.
The external collateral branch for the index finger sometimes arises by a common trunk
with the preceding ; it runs along the first interosseous space in front of the adductor
pollicis, on the outer border of the first lumbricalis muscle, to which it gives a filament,
and then divides into two branches, a dorsal and a palmar : the dorsal branch, which is
the smaller, passes backward and downward, along the outer border of the first phalanx,
unites with the dorsal collateral branch derived from the radial nerve, gains the poste-
rior surface of the second phalanx, and terminates upon the third, near the nail. The
palmar branch, which forms the true continuation of the trunk of the nerve, is arranged
like the corresponding nerve of the thumb, and does not anastomose with the internal
collateral branch.
The common trunk of the internal collateral branch of the index finger, and external collat-
eral branch of the middle finger, passes vertically downward, in front of the second inter-
osseous space, at the middle of which it divides into two branches, one of which forms
the internal collateral branch of the index finger, and the other the external collateral branch
of the middle finger. These collateral nerves, like the preceding, divide into a dorsal and
a palmar branch, the latter of which again subdivides into a sub-ungual branch and a
branch for the pulp of the finger.
Tlie common trunk of these two collateral nerves, before bifurcating, gives ofT a twig
to the second lumbricalis.
The common trunk of the internal collateral branch of the middle finger, and external col-
lateral branch of the ring finger, passes somewhat obliquely inward, in front of the third
interosseous space, and is distributed in the same way as the preceding branches ; be-
fore bifurcating, it sometimes gives a twig to the third lumbricalis ; it receives an anas-
tomotic filament from the ulnar nerve. The bifurcation of this sixth branch takes place
a little below the metacarpo-phalangal articulations.
Relations. — The following are the relations of the palmar and digital portions of the
median nerve :
Behind the anterior annular ligament of the carpus, the median nerve is situated on the
outer side of the tendons of the flexor sublimis and in front of those of the flexor pro-
fundus : like the tendons among which it is placed, it is at first covered by the synovial
membrane in front and behind.
In the palm of the hand, the median nerve is covered by the palmar fascia, and is situ-
ated in front of all the flexor tendons. The superficial palmar arch lies in front of it,
and crosses at right angles over its three internal branches.
The collateral nerves of the fingers accompany the collateral vessels, and pass with them
from the palm of the hand opposite the intervals between the metacarpo-phalangal ar-
ticulations. Like the vessels which run along their outer side, these nerves occupy the
borders of the palmar aspect of the fingers, one on each side of the tendinous groove.
Summary. — From what has been stated, it follows, then, that the median nerve gives
off no branch in the arm ;t that, in the forearm, it gives no nerve to the skin, but sup-
plies all the muscles of the anterior region, excepting the flexor carpi ulnaris and the
inner half of the flexor profundus, which we shall see are supplied by the ulnar ; and,
lastly, that, in the hand, it supplies the cutaneous nerves of the palm, the external and
* I have seen it arise after the third branch, and upon a plane anterior to that branch, tlie oriijin of" which
It then crossed. t See note, p. 7£6.
THE ULNAR NERVE IN THE ARM AND FOREARM. 789
internal collateral nerves of the thumb, index finger, and middle fingers, and the exter-
nal collateral nerve of the ring finger, and also the muscular nerves of the ball of the
thumb and the nerves of the two outer lumbricales, and sometimes that of the third
lumbricalis.
The Ulnar Jferve.
The ulnar nerve {d, fig. 286), a little smaller than the preceding, behind which it is
situated, arises by a trunk which is common to it, to the internal root of the median
nerve (c), and to the internal cutaneous nerve (g-) ; it passes vertically downward be-
hind, and at first in contact with the median, but soon leaves that nerve, and runs some-
what backward (/, fig. 288), while the median is directed forward and outward ; it per-
forates the upper fibres of the internal head of the triceps, and enters the sheath of that
muscle, behind the internal inter-muscular septum. It thus gains the groove between
the inner condyle of the humerus and the olecranon, passes between the two origins of
the flexor carpi ulnaris, and is reflected from behind forward in this groove, and then
upon the inner side of the coronoid process : having thus reached the anterior aspect of
the forearm, it passes vertically downward (/) between the flexor carpi ulnaris and the
flexor profundus, and gains the palm of the hand (s), where it divides into its terminal
branches. As with the median nerve, we shall examine the ulnar in succession in the
arm, the forearm, and the hand.
In the Arm.
The most important relation of this nerve (/) in the arm is that at its upper part with
the median nerve and brachial artery. It runs along the inner side of the artery, while
the median nerve is situated in front of the vessel, or, rather, the artery is situated be-
tween the median and ulnar nerves, so that it may be exposed immediately below the
axilla, by separating these two nerves.
The ulnar nerve gives off no branch in the arm ; the error of those who have stated
the contrary has arisen from the fact that the branch given from the musculo-spiral
nerve to the internal portion of the triceps lies in contact with the ulnar nerve for a
great part of its extent, so that it would seem at first sight to come off from it.
The Forearm.
The ulnar nerve in the forearm (/) is at first covered by the fleshy belly of the flexor
carpi ulnaris, which separates it from the skin ; it becomes sub-aponeurotic below, where
the fleshy fibres of that muscle cease, and is found between the tendon of the flexor carpi
ulnaris on its inner side, and those of the flexor sublimis on its outer side.
Its relation with the ulnar artery is remarkable. This vessel describes a curve so as
to reach the outer or radial side of the nerve ; but the nerve and artery are in contact
in the lower third only of the forearm.
The branches of this nerve in the forearm are somewhat numerous. Between the in-
ternal condyle and the olecranon, the ulnar nerve gives several very delicate articular
filaments, which pass into the elbow-joint ; it also gives off branches for the flexor carpi
ulnaris ; one of which is very large, and may be traced as far as the lower part of the
fleshy belly of the muscle.
After its reflection, the ulnar nerve gives a branch to the flexor profundus digitorum,
subdivides, and enters the substance of that muscle. Its divisions run upon the anterior
surface of the muscle before penetrating it. This branch is intended for the two inner
portions of the flexor profundus, the two outer portions receiving their filaments from
the median nerve.*
At the middle of the forearm, a small, long, and slender branch is given off from the
anterior part of the ulnar nerve, and divides into two filaments, one of which follows the
ulnar artery (filament of the ulnar artery), while the other perforates the fascia of the fore-
arm, and anastomoses with the internal cutaneous nerve {anastomotic filament).
The internal dorsal nerve of the hand (x) is the largest of the branches of the ulnar
nerve, so that it might be regarded as a terminal branch of that nerve ; it is exclusively
intended for the skin of the dorsal region of the hand. It comes off opposite the junc-
tion of the two upper thirds with the lower third of the forearm, passes obliquely down-
ward, backward, and inward between the ulna, over which it crosses, and the flexor car-
pi ulnaris, and emerges (x, fig. 289) from below the tendon of that muscle, a very short
distance above the lower end of the ulna. It then descends vertically between the skin
and that part of the bone, runs along the inner side of the carpus, and divides into two
dorsal branches, an internal and an external.
The internal dorsal branch is the smaller ; it runs along the ulnar border of the fifth
metacarpal bone, and along the internal or ulnar side of the dorsal region of the little
finger, of which it forms the internal collateral dorsal nerve.
The external dorsal branch is much larger ; it first gives off a small anastomotic ttmg,
which crosses obliquely over the metacarpal bone, and anastomoses with a correspond-
^ [The 'Inarmay communicate in this position with filauuiit^ pf the antenor interosseous.!
"m
NEUROLOGY.
ingly oblique branch from the radial nerve, opposite the lower part of the second interos
seous space. It then descends vertically along the fourth interosseous space, and di-
vides into two secondary branches, which again subdivide to form the dorsal collateral
nerves, in the following manner : one forms the external collateral nerve of the little finger,
and the internal collateral nerve of the ring finger ; and the other the external collateral
nerve of the ring finger, and the internal collateral nerve of the middle finger.'^
In the Hand.
The ulnar nerve enters the palm of the hand {s,fig. 288), not by passing behind the an-
terior annular ligament, but in a special sheath, which is common to it and to the ulnar
artery, is situated on the inner side of the annular ligament, and has the pisiform bone
to its inner side, and unciform bone to its outer side. This sheath is completed behind
by the ligament which extends from the pisiform to the unciform bone, and in front by a
sort of annular ligament. The nerve is covered by a synovial membrane during its
passage through this sheath.
As soon as it leaves this sheath, the ulnar nerve divides into two terminal branches,
the one superficial, and the other deep.
The superficial terminal branch, or trunk of the palmar collateral nerves of the fingers, im-
mediately gives off a branch which passes beneath the flexor brevis digiti minimi, pene-
trates the deep surface of that muscle, and immediately divides into two other branches,
an internal and an external. The internal is the smaller branch ; it crosses over the
muscles of the ball of the little finger, beneath the palmaris brevis, when it exists, gains
the inner side of the anterior surface of the little finger, and forms its internal palmar col-
lateral nerve, j The external is larger; it sends a communicating twig to the median
nerve, and bifurcates to form the external palmar collateral nerve of the little finger, and the
internal palmar collateral nerve of the ring finger.
The deep terminal or muscular branch is somewhat larger than the superficial branch
Immediately after its origin, it is reflected outward below the unciform bone, perforates
the flexor brevis digiti minimi, and passes deeply into the palm of the hand, so that it
cannot be exposed without dividing all the tendons of the palmar region.
This branch describes a transverse curve or arch with the concavity directed upward,
in front of the metacarpal bones, corresponding to and situated within the curve de-
scribed by the deep palmar arterial arch, which crosses it at an acute angle.
No branch arises from the concavity of this nerve, but from its convexity a great mmi
her are given off, in the following order :
During the passage of the nerve between the pisiform and unciform bones, three branch-
es for the three muscles of the hypothenar eminence.
Two very remarkable descending filaments, which supply the palmar interossei of the
third and fourth spaces, and end in the third and fourth lumhricalcs. The first and sec-
ond lumbricales, and frequently the third also, are supplied by the median nerve.
Three perforating branches pass backward between the upper ends of the metacarpal
bones, give some branches to the palmar interossei, proceed along the cellular interval
between the palmar and dorsal interossei, supply the last-mentioned muscles, and termi-
nate by anastomosing with the dorsal collateral branches of the ulnar and radial nerves.
We may regard as terminal divisions of the deep branch, two branches, which are
given to the two portions of the adductor pollicis,t and a branch for the first dorsal inter-
osseous muscle, from which a filament is given off that enters the adductor poUicis near
its lower border.
Summary. — From what has been stated, it appears that the ulnar nerve gives off no
branch in the arm ; that in the forearm it supplies some articular branches to the elbow-
joint, certain muscular branches for the flexor carpi ulnaris, and the inner half of the
flexor profundus, and a cutaneous filament which anastomoses with the internal cu-
taneous nerve ; that it gives off to the hand a dorsal cutaneous branch, from which the
dorsal collateral nerves of the little and ring fingers, and the internal dorsal collateral of
the middle finger, proceed ; a palmar cutaneous division, which supplies the palmar collateral
nerves of the little finger, and the internal palmar collateral nerve of the ring finger ; and
a muscular division, which is distributed to the three muscles of the hypothenar emi-
nence, to aU the interossei, among which we may include the adductor poUicis,^ and to
the two internal lumbricales.
* [This latter branch often anastomoses with the dorsal cutaneous branch of the radial nerve.]
t I have observed that it supplies the palmaris brevis, when that muscle exists.
i The reader must here be reminded, that 1 have regarded all that portiou of the flexor brevis pollicis (of
authors) which is situated to the inner side of the tendon of the flexor longus pollicis, or, in other words, all
that portion which is attached to the internal sesamoid bone, as belonging to the adductor pollicis. (See
Myology, p. 190.) The distribution of the nerves favours this view ; for the flexor brevis is supplied by
the median nerve, while the two portions of the adductor receive their nerves from the ulnar. [This general
statement is not quite correct ; the outer portion of the adductor (the inner_head of the flexor brevis of au-
thors generally) also receives a small branch from the median nerve (see p. 787 ; also Swan and Ellis).]
*) It is perfectly rational to consider the adductor pollicis as the first palmar interosseous muscle, which, fw
♦hp sake of increased power of adduction, is attached to the third metacarpal bone.
MUSCULO-8PIRAL NERVE. r^Bfli^
..k. ■ ,..^ ^^% A .. Musculo-spiral JVerve. i>i-;'*'I.
The musculo-spiral or radial nerve, which is the largest of the terminal divisions of the
brachial plexus, is intended for the triceps extensor cubiti, for the muscles of the pos-
terior and external region of the forearm, and for the skin of the arm, the forearm, and
dorsal region of the hand.
It arises {f,Jig. 286) from all the five nerves of which the brachial plexus is composed,
by a trunk which is common to it and to the circumflex nerve, and it issues from the
plexus behind the ulnar nerve, to which it is closely applied. Immediately after its ori-
gin, it passes downward, backward, and outward (b, fig. 288), in front of the conjoined
tendons of the latissimus dorsi and teres major, to gain the groove of torsion or spiral
groove of the humerus, into which it enters, passing between the long head of the tri-
ceps and the bone, then between the external head and the bone ; it traverses the whole
extent of this groove, and is in relation with the profunda humeri artery and vein.
Leaving this groove, opposite the junction of the two upper thirds with the lower third
of the humerus, it lies on the external and anterior aspect of the arm, descends vertical-
ly between the supinator longus and brachialis anticus, and next between the brachialis
anticus and extensor carpi radialis longior, crosses the elbow-joint (at b), passing in front
of the outer condyle of the humerus and the upper extremity of the radius, and then di-
vides into two terminal branches.
Collateral Branches of the Musculo-spiral Nerve.
During its winding and spiral course along the arm, this nerve gives off a great num-
ber of collateral branches in the following order :
Branches given off by the Musculo-spiral Nerve before it enters the Spiral Groove. — The
first is the internal cutaneous branch (/', fig. 287) of the musculo-spiral, which is sub-
aponeurotic at its commencement, but perforates the fascia, becomes applied to the skin,
and divides into two filjiments, which pass obliquely backward, and may be traced as far
as the olecranon.*
There are several considerable branches to the long head of the triceps ; the highest of
which is recurrent, and may be traced as far as the scapular attachments of the muscle.
A very large descending branch may be traced to the olecranon.
There is a branch for the internal head of the triceps, one division of which is rather
large, and runs along the inner border of the humerus in front of the muscle, which it
does not enter until it approaches the elbow.
Branches given off by the Musculo-spiral after leaving the Spiral Groove. — These are the
external cutaneous branch of the musculo-spiral, a very large branch which perforates the
muscular fibres of the triceps and the brachial aponeurosis, then lies in immediate con-
tact with the skin of the external region of the arm, passes obliquely backward, and di-
vides into a great number of filaments, which supply the skin of the posterior region of
the forearm, and may be traced down to the carpus.
The branch for the external head of the triceps and for the anconeus, which is remarkable
for its length, descends vertically between the external and long heads of the triceps,
supplies the former of these, enters the anconeus, and may be traced as far as the lower
part of that muscle.
All these branches are remarkable for being given off at nearly the same height ; that
is to say, near the shoulder-joint, and for accompanying the trunk of the musculo-spiral
nerve.
Branches given off by the Musculo-spiral Nerve in the Forearm. — These are the branches
for the supinator longus, and those for the extensor carpi radialis longior, which enter the
inner surface of the upper part of those muscles.
Terminal Branches of the Musculo-spiral Nerve.
Reduced to one half, or less, of its original size, by the successive emission of the pre-
ceding branches, the musculo-spiral or radial nerve divides in front of the elbow (b, fig.
388) into two unequal branches, the one deep or muscular, the other superficial or digital.
The deep or muscular division of the musculo-spiral nerve, or the posterior interosseous,
is larger than the superficial division ; it immediately gives off a branch which passes
vertically in front of the extensor carpi radialis brevier, and soon dips into that muscle ;
the nerve then becomes flattened, perforates the supinator brevis, and pursues a very
oblique and spiral course around the radius and within that muscle, to which it gives
branches {branches for the supinator brevis) : it then emerges from the posterior aspect of
this muscle, and immediately divides into a great number of diverging branches, some
of which are intended for the superficial, and the others for the deep layer of muscles on
the posterior region of the forearm.
The branches given to the superficial layer are, those for the extensor communis digt-
torum, which are very numerous and diverging, the superior being also recurrent; the
branch for the extensor proprius digiti minimi ; and the branch for the extensor carpi lU-
* [Anastomosing with the accessory of the internal cutaneous.)
792
NEUROLOGY.
naris : all these branches arise by a common trunk, and enter the deep surface of the
muscles.
The branches for the deep layer also arise by a common trunk (i, Jig. 289), whicli may be
Fig. 289. regarded as the continuation of the muscular division of the mus-
culo-spiral, considerably diminished in size. This common trunk
passes vertically downward between the superficial and deep lay-
ers of muscles, gives off a branch, which enters the superficial as-
pect of the extensor longus ■pollicis, then passes between the adduc-
tor longus and extensor brevis pollicis on the one hand, and the
extensor longus pollicis on the other, runs in contact with the inter-
im/, osseous ligament, and gives off a first branch to the extensor lon-
gus pollicis, a second which enters the deep surface of the same
muscle, and a small branch which enters the outer border of the
entensor proprius indicis.
Reduced at length to a very small branch, the muscular division
of the musculo-spiral nerve enters the groove (at s) for the tendons
of the extensor communis digitorum, lying beneath them, in con-
tact with the periosteum ; it runs over the carpus, and expands into
a number of articular fdaments, which enter the radio-carpal, carpal,
and carpo-metacarpal articulations ; in this latter portion of its
course, the nerve is of a grayish colour, swollen, and, as it were,
knotted ; a condition which is observed in all articular nerves.
The superficial, cutaneous, or digital division of the musculo-spiral
nerve, or the radial nerve properly so called, forms the external dor
sal nerve of the hand, and is about half the size of the muscular di-
vision. It passes vertically downward, between the supinator lon-
gus and the extensor carpi radialis longior, along the outer side of
the radial artery : having reached the middle of the forearm, it es-
capes from beneath the tendon of the supinator longus, and runs
along the outer border of that tendon.
Situated at first beneath the fascia, it soon perforates it, becomes sub-cutaneous, runs
vertically downward, and, about an inch and a half above the styloid process of the radius,
divides into an external and an internal branch.
The external branch (o, figs. 288, 289), which is the smaller, runs along the outer side
of the styloid process of the radius, and then along the outer border of the carpus,* of
the first metacarpal bone, and of the first and second phalanges of the thumb, and termi-
nates in the skin beneath the nail ; it is the external dorsal collateral branch of the thumb.
The internal branch (e, fig. 289), which is much larger, passes obliquely behind the ra-
dius, crosses the tendons of the adductor longus and extensor brevis pollicis, and divides
into three secondary branches, namely, counting from without inward, the internal dor-
sal collateral nerve of the thumb, and the external and internal dorsal collateral nerves of thf
index finger, t
Summary. — The musculo-spiral nerve gives off, in the arm., two cutaneous branches,
one internal, the other external, the latter of which is much the larger, and may be tra-
ced as far as the carpus ; and also muscular branches to the three portions of the triceps
and to the anconeus : to the forearm, it supplies muscular branches to all the muscles of
the deep and superficial layers of the posterior and external regions ; and to the hand,
certain cutaneous branches, namely, the dorsal collateral nerves of the thumb and index
finger.
General Summary of the Distribution of the Jferves of the Brachial Plexus.
The preceding description shows that the brachial plexus supplies the skin, the mus-
cles, and the articulations of the upper extremity, including the shoulder. We shall
briefly recapitulate, first the muscular and then the cutaneous branches.
The Muscular Branches. — By its collateral branches, the brachial plexus supplies the
scaleni and all the muscles which move the shoulder, excepting the trapezius, which
receives its nerves from the brachial plexus and from the spinal accessory nerve of Wil-
lis ; by its terminal branches it supplies all the muscles of the arm, the forearm, and the
hand.
Each of the muscles which move the shoulder receive a special nerve ; thus, besides the
nervous filaments for the scaleni, there is the nerve for the sub-clavius ; the nerve for
the levator anguU scapulae ; the nerves for the rhomboideus ; the nerve for the serratua
magnus, which is better known as the external thoracic nerve ; the nerve for the latis-
simus dorsi, which is generally described as a branch of the sub-scapular ; and the nerves
for the pectoralis major and minor.
The muscles which move the arm upon the shoulder also receive their nerves from the
* [NVhere it sends an anastomotic filament to the palmar cutaneous branch of the median. J
t [It also supplies the external dorsal collateral of the middle finger, and often unites with tlie ulnar cuta-
oeius, to form the dorsal collaterals for the contiguous sides of the middle and ring fingers.]
THE NERVES OF THE BRACHIAL PLEXUS. 793
brachial plexus ; sometimes there is a separate nerve for each muscle, sometimes the
same nerve supplies two muscles. The nerve for the deltoid, or the circumflex nerve,
also supplies the teres minor. The supra-spinatus and infra-spinatus receive their fila-
ments from the same branch, viz., the supra-scapulum nerve. The teres major receives
a branch from the sub-scapular nerve.*
Of the muscles which move the forearm upon the arm. Those of the anterior region, oi
the flexors, viz., the biceps, coraco-brachialis, and brachialis anticus, receive their fila-
ments from the musculo-cutaneous nerve ; the muscle of the posterior region, the tri-
ceps, is supplied entii ely by the musculo-spiral nerve. The ulnar nerve gives no branch
in the arm.
The muscles which move the radius upon the ulna, and those which move the hand and the
fingers, are thus supplied. The interosseous division of the musculo-spiral nerve sup-
plies the muscles of the posterior region of the forearm, viz., in the superficial layer, the
common extensor, the extensor proprius digiti minimi, and the extensor carpi ulnaris ;
in the deep layer, the supinator brevis, the adductor longus, extensor brevis, and extensor
longus pollicis, and the extensor proprius indicis.
The muscles of the exterior region of the forearm, namely, the two supinators, and the
two radial extensors of the carpus, also receive their branches from the musculo-spiral
nerve.
The muscles of the anterior region of the forearm receive their filaments from the median
nerve, excepting the flexor carpi ulnaris and the internal half of the flexor profundus,
which are supplied by the ulnar nerve. The flexor profundus, then, by a peculiarity
which not unfrequently occurs in regard to compound muscles, receives its nerves from
two different sources.
The intrinsic muscles of the hand are supplied in the following manner : Those of the
ball of the thumb by the median nerve ; those of the ball of the little finger by the ulnar
nerve ; the two external lumbricales by the median nerve ; the two internal lumbricales
by the ulnar nerve ; all the interossei, including the adductor pollicis, by the ulnar nerve.
The Cutaneous Branches A — The skin which covers the shoulder on the outer side re-
ceives its nerves from the cervical plexus.
The skin of the external surface of the arm receives its nerves from the cutaneoiis
branches of the circumflex nerve, and from the external cutaneous branch of the mus-
culo-spiral. The skin of the anterior and internal regions of the arm receives its nerves
from the internal cutaneous branch of the musculo-spiral, from the accessory nerve of
the internal cutaneous, which anastomoses with the second intercostal, from a small
branch of the internal cutaneous, and from the humeral branch of the third intercostal.
The skin of the forearm receives its filaments from the internal cutaneous, which
anastomoses with the cutaneous filaments of the musculo-spiral, ulnar, and musculo-cu-
taneous nerves.
The skin of the dorsal region of the hand and of the fingers receives its filaments from
the dorsal branches of the radial nerve, in the two external thirds of that region, and
from the dorsal branch of the ulnar nerve in the internal third.
The skin of the palmar region of the hand and fingers receives its filaments from the
median nerve in the two external thirds, and from the ulnar in the internal third, or, to
speak more precisely, the median nerve supplies the external and internal collateral
branches of the thumb, the index, and the middle fingers, and the external collateral
nerve of the ring finger ; the ulnar nerve supplies the external and internal collateral
nerves of the little finger, and the internal collateral branch of the ring finger.
Some of the terminal branches of the median nerve, and the terminal divisions of the
internal cutaneous and musculo-cutaneous, are lost in the skin of the upper part of the
palm of the hand.
The palmar collateral nerves of the fingers offer the following peculiarities : the
branches which they give to the skin are placed either opposite to each other, or alter-
nately ; each of these branches tenninates separately in a pencil of filaments ; the twigs
from the internal branches do not anastomose with those from the external ; lastly, the
terminal extremities of the external and internal collateral branches do not anastomose
with each other in the pulp of the finger, but expand separately, and are distributed to
the skin of the pulp and to the skin under the nail.
The branches which supply the palmar aspect of the fingers present a very remark-
able condition,t consisting in the presence of small, grayish, gangliform bodies, always
of a crescentic form. These bodies are very numerous ; they are sometimes separate,
* The teres minor and the infra-spinatus are, therefore, supplied by two different branches, which would
induce us to describe these muscles separately, did we not see that compound, and sometimes even simpla
muscles receivo-two or more distinct nerves.-
t A beautiful preparation of the cutaneous nerves of the upper extremity may be made by removing Ihs
skin, either by turning it inside out, in the same way as an eel is skinned, or by making a longitudinal incision
along the outer side of the limb. In both cases the fascia should be removed with the skin. In the first meth-
od, by which a very fine preparation may be made, the everted skin represents a kind of glove, the inner sui-
face of which is formed by tlie epidermis, and the outer by the deep surface of the skin
X This was pointed out in one of the last concours of tlie assistants (aides) of the Faculty, by M.M. AndjaJ,
ramus, and Lacroix, who had to dissect the cutaneous nerves of the hand.
5 H
704 NEUROLOGY.
and sometimes arranged in groups ; they do not essentially belong to the nerves, but are
applied to them, and may be separated from them by slight force. They are, therefore,
not ganglia.
If we consider that these gangliform bodies occupy the palmar region only, and are
never found in the dorsal region, that they exist in the sole of the foot as well as in the
palm of the hand, that they have been found upon the nerves which surround the artic-
ulations, and, consequently, upon nerves which are subject to constant pressure, that I
have even found them upon an intercostal nerve which was reflected over the side of
the sternum, and, lastly, that they do not exist in the infant at birth, and are more numer-
ous in proportion as the palm of the hand is more callous we shall be warranted in con-
cluding that they are the result of external pressure.
THE ANTERIOR BRANCHES OF THE DORSAL NERVES, OR THE INTER-
COSTAL NERVES.
Dissection. — Enumeration. — Common Characters. — Characters proper to each.
Dissection. — Search carefully for the cutaneous branches, some of which are to be
found opposite the sides of the sternum, and others about the middle of the intercostal
spaces. Saw through the sternum in the median line, and open the abdomen through
the linea alba. Sacrifice one half of the thorax, or, rather, break the ribs through the
middle, so as to trace the nerves from within outward.
The anterior branches of the dorsal nerves, twelve in number, are intended for the parietes
of the thorax and abdomen.*
These branches offer at once a great uniformity, and a great simplicity in their distri-
bution. I shall first explain their common characters, and shall then notice the pecu-
liarities Dresented by each.
Common Characters.
The anterior branches of the dorsal nerves, or the intercostal nerves, separated from the
posterior branches by the superior costo-transverse ligament, appear like flattened cords,
which pass to the middle of the corresponding intercostal space (see^lf^. 268) ; there they
are situated between the pleura and the aponeurosis, which is continuous with the in-
ternal intercostal muscle. After proceeding for a certain distance, they pass between
the external and internal intercostal muscles, and approach the groove of the rib above,
but they are not lodged in it, for they always lie below the intercostal vessels.
At about the same situation in each space, that is to say, about half way between the
vertebral column and the sternum, the intercostal nerves divide into two branches, the
one intercostal, and the other perforating or cutaneous.
The intercostal branch is the continuation of the trunk of the nerve, and is distinguish-
ed from it only by its smaller size. It runs along the lower border of the rib above, and
then that of the corresponding costal cartilage ; it is sometimes situated on the internal
surface of the cartilage, and having reached the forepart of the intercostal space, it per-
forates this space from behind forward, runs along the sternum, is inclined somewhat
inward over that bone, and is then reflected outward, between the pectoralis major and
the skin, to which latter it is distributed. These small filaments may be called the an-
terior perforating filaments. During its course, the intercostal nerve and its continua-
tion give off a great number of nervous filaments. Not unfrequently the intercostal
nerve gives off, in the back part of the space, a small branch, which reaches the upper
border of the rib below. When this branch does not exist, its place is supplied by sev-
eral twigs which have a similar distribution, some of which even pass to the intercostal
space below, crossing obliquely over the internal surface of the rib. In like manner, we
sometimes find some small twigs proceeding from the upper side of the nerve over the
internal surface of the rib above, and reaching the next intercostal space. Lastly, from
the lower side of the intercostal nerve and its continuation a series of twigs are given
off, which divide into filaments that curve towards each other so as to form arches or
loops, from which the terminal filaments proceed. In no part of the body are there found
longer or more delicate nervous filaments ; some of them run through half the length of
an intercostal space without diminishing in size, and several evidently belong to the
periosteum.
The perforating or cutaneous branches are often larger than the intercostal branches ;
they pass very obliquely through the external intercostal muscles, and after running for
a certain distance between those muscles and the serratus magnus, each of them divides
into two smaller branches, the one anterior, and the other posterior or reflected : the an-
terior branches run horizontally forward, become sub-cutaneous by escaping between the
digitations of the serratus magnus in the eight superior intercostal spaces, and between
the digitations of the obliquus externus abdominis in the four lower spaces, and then,
* Haller only admits eleven dorsal nerves, because he considers, and not without reason, the twelfth as a
Inmbar nerve. "
ANTERIOR BRANCHES OF THE DORSAL NERVES. 795
becoming applied to the skin, spread into a number of filaments, which almost always
anastomose with the adjacent filaments of the nerves above and below.
The posterior or reflected branches immediately perforate the serratus magnus and the
obliquus externus abdominis, are reflected upon themselves, pass backward between
the latissimus dorsi and the skin, and after running horizontally for a distance of one .or
two inches, are again reflected forward, and are then lost in the skin.
Proper Characters of each of the Anterior Branches of the Dorsal J^erves.
The First Dorsal Nerve. — This nerve belongs to the brachial plexus, into which it en-
ters immediately after its escape from the inter-vertebral foramen, crossing over the neck
of the first rib at an acute angle. P'rom its size, it resembles the lower cervical nerves,
and diflfers widely from the remaining dorsal nerves. It becomes intercostal only by
giving off a small intercostal twig at its exit from the inter- vertebral foramen. This in-
tercostal branch is applied to the under surface of the first rib, which it crosses obliquely
from behind forward, so that it does not reach the first intercostal space until opposite
the junction of the rib with its cartilage ; it gains the middle of this space near the ster-
num, at which point it passes forward through the space, like the other intercostal
nerves, and ramifies in the muscles and the skin.
The Second Dorsal Nene. — This nerve crosses obliquely over the second rib, on the
outer side of its neck, to reach the first intercostal space, and then recrosses the same
rib, about its middle, to gain the second intercostal space, where it divides into two
branches : the intercostal, which follows the lower border of the second rib, and presents
nothing remarkable ; and the -perforating or cutaneous branch, which requires a special
description.
The perforating or cutaneous branch, which is destined exclusively for the skin of the
arm, is much larger than the other branches of the same kind. It emerges from the
thorax at the middle of the second intercostal space, immediately below the second rib,
passes directly through that space, is reflected at right angles over an aponeurotic arch,
runs outward, and immediately subdivides into two branches of equal size, the one ex-
ternal and the other internal.
The external or intercosto-humeral branch (to the left of d, fig. 287) traverses the axilla,
receives an anastomotic twig from the accessory nerve (c) of the internal cutaneous of
the ann, reaches and crosses over the outer border of the latissimus dorsi, and divides
into two cutaneous filaments, one of which is distributed to the skin of the posterior re-
gion of the arm, while the other lies in contact with the skin of the internal region of the
arm, runs parallel to the accessory nerve of the internal cutaneous, and may be traced
as low down as the elbow.
The internal branch crosses the outer border of the latissimus dorsi, lower down than
the preceding branch, becomes applied to the skin, and divides into internal and posterior
filaments, which are lost in the skin of the arm.
The perforating branch, therefore, of the second dorsal nerve completes the system
of cutaneous nerves of the arm.
The third dorsal nerve is precisely similar to the others, excepting in its perforating,
cutaneous, or intercosto-humeral branch, which is distributed to the integuments both of
the thorax and arm. It is much smaller than the preceding ; it emerges (d,fig. 287) from
between the digitations of the serratus magnus, is reflected backward upon itself, gives
a small branch to the mamma, crosses the outer border of the latissimus dorsi, below the
perforating branch of the preceding nerve, and having reached the upper part of the
shoulder, is reflected upon itself, describing a curve with the concavity turned upward,
and terminates in the skin of the inner and upper part of the arm.
The fourth, fifth, sixth, and seventh dorsal nerves agree exactly with the general descrip-
tion. The intercostal muscles, the triangularis stemi, the serratus magnus, the obli-
quus externus abdominis, the upper part of the recti abdominis, and the integuments of
the thorax, are supplied with nerves from these branches, in the order and manner al-
ready pointed out. I would direct attention to the considerable number of filaments dis-
tributed to the skin of the mamma in the female. The perforating branches of the fourth
and fifth dorsal nerves each give a branch to the mamma, and a posterior branch, which
crosses the latissimus dorsi, and is distributed to the skin over the scapula ; the skin of
the mamma receives nerves from the third, fourth, and fifth dorsal nerves.
The eighth, ninth, tenth, and eleventh dorsal nerves belong to the intercostal spaces form-
ed by the false ribs : they leave those spaces at the point where the costal cartilages
change their direction to bend upward ; they perforate the costal attachments of the di-
aphragm, without giving that muscle any filaments, continue their oblique course in the
substance of the parietes of the abdomen, for which they are destined, and are distribu-
ted to these parts, in the same way as the nerves in the intercostal spaces, with some
slight modifications. Thus, the perforating branches perforate the external intercostals
and the obliquus externus abdominis in the same line as the perforating branches of the
preceding nerves ; the intercostal branches, properly so called, having thus become ab-
dormnal, run between the external and internal oblique muscles, just as, in the upper spa-
fBi NEUROLOGY.
ces, they ran between the external and internal intercostals. Having reached the rec-
tus abdominis, they give off a cutanemis or perforating branch, and then enter the sheath
of that muscle, through certain openings at its outer border, and proceed between the
muscle and the posterior layer of the sheath : at the junction of the two external thirds
with the internal third of the rectus, these branches pass through it very obliquely to-
wards the middle line, and divide into muscular filaments, which are lost in the muscle,
and the lowest of wliich pass vertically downward, and cutaneous filaments, which per-
forate the anterior layer of the sheath of the rectus, on each side of the linea alba, but
not always at the same distance from it, and are reflected horizontally outward in the
sub-cutaneous cellular tissue lying immediately in contact with the skin.
The twelfth dorsal nerve {d, fig. 290) might, according to the opinion of Haller, be re-
garded as the first lumbar nerve. It is larger than the other dorsal nerves ; it emerges
from the vertebral canal between the last rib and the first lumbar vertebra, passes in
front of the costal attachments of the quadratus lumborum, runs along the lower border
of the twelfth rib, proceeds very obliquely downward, like that rib, perforates the apo-
neurosis of the transversalis muscle, and, like the preceding nerves, divides almost im-
mediately into two branches. The abdominal branch, which corresponds to the inter-
costal branch of the other nerves, passes horizontally forward between the transversalis
and obUquus internus, supplying those muscles, and almost always gives off, below, an
anastomotic branch to the abdominal or ilio-inguinal branch of the lumbar plexus, and
then penetrates the sheath of the rectus, where it is arranged like the preceding nerves.
The perforating or cutaneous branch is remarkable for being larger than the abdominal
branch, and for its distribution ; it perforates very obliquely, and at the same time gives
branches to the external and internal oblique muscles, becomes sub-cutaneous, passes
vertically downward, crosses at right angles over the crest of the ilium, and divides into
anterior, posterior, and middle branches, which are distributed to the skin of the gluteal
region.
Not unfrequently this gluteal cutaneous branch is given off by the first lumbar nerve,
and then the cutaneous branch of the twelfth dorsal nerve is arranged like those of the
preceding nerves, and ramifies in the skin between the last rib and the crest of the ili-
um. There is a mutual relationship between the twelfth dorsal and the first lumbar
nerves, so that they are often inversely developed ; they always communicate with each
other by a branch called the dorsi-lumbar, but the mode and place of communicati»n are
subject to many varieties : thus, it is sometimes effected by a winding branch which
runs along the outer border of the quadratus lumborum, at other times it takes place in
the substance of the abdominal muscles.*
Summary of the Dorsal or Intercostal JVerves,
These nerves are distributed to the parietes both of the thorax and the abdomen, which
in all respects 'may be regarded as constituting a single cavity, the thoracico-abdominal.
The muscular and cutaneous thoracic branches from the brachial plexus, some small
branches derived from the lumbar plexus, and the posterior spinal branches of the dorsal
nerves, complete the nervous system of the thoracic and abdominal parietes.
The dorsal nerves are divided into muscular nerves, for the muscles of the thoracico-
abdominal parietes, and for the muscles which lie upon them, and into cutaneous nerves.
To obtain a good idea of the latter, they should all be displayed in the same preparation.
Several rows of parallel cutaneous filaments will then be seen, in the following order,
proceeding from before backward.
The anterior perforating or cutaneous nerves, which are extremely small, emerge at the
sides of the sternum and of the linea alba, and are reflected forward.
The perforating or cutaneous nerves, which might be called middle, divide into orie set
of branches, which run parallel to each other forward, towards the sternum, and another
set, also parallel, which run backward, towards the vertebral column.
We have elsewhere stated that other posterior cutaneous branches are gren off from
the posterior branches of the dorsal nerves. They are parallel, and run outward, and
may be traced as far as on a level with the axilla.
THE ANTERIOR BRANCHES OF THE LUMBAR NERVES.
Enumeration. — The Lumbar Plexus — Collateral Branches, Abdominal and Inguinal. — Ter-
minal Branches — the Obturator Nerve — the Crural Nerve and its Branches, viz., the Mus-
culo-c^ttaneous — the Accessory of the Internal Saphenous — the Branch to the Sheath of the
Vessels — the Muscular Branches — the Internal Saphenous.
Dissection. — In order to see these nerves at their exit from the inter-vertebral forami-
na, and also to obtain a view of the lumbar plexus, it is necessary carefully to divide the
* In a subject which had a thirteenth or lumbar rib, there was a tTiirteenth dorsal nerve, of large size,
which crossed the supernumerary rib, and which corresponded in its distribution with both the twelfth dorsal
and the first lumbar nerves ; it only communicated with the first lumbar nerve by a very small filament ; it
gave off a deep perforating or cutaneous branch to the gluteal region, and also an ilio-scrolal branch. In thia
•abject there were only four lumbar nerves.
THE LUMBAR PLEXUS.
797
psoas muscle, m which they are situated ; the branches which emerge from the plexus
must be dissected with the greatest care as they are passing under the femoral arch,
and then to their final distribution.
The anterior branches of the lumbar nerves (21 to 25, fig. 268) are five in number, and
are distinguished as the first, second, third, fourth, and fifth : they gradually increase in
size from the first to the fifth, and form a continuation of the series of anterior branches
of the dorsal nerves : after having given off one or two branches to the lumbar ganglia
(tt) of the sympathetic, and some branches to the psoas muscle, they end by anastomo-
sing so as to form the lumbar plexus (Z).
The anterior branch of the first lumbar nerve (1 I, fig- 290) is the smallest of all, and ia
almost equal in size to the anterior branch of the Fig-. 290.
twelfth dorsal nerve ; immediately after emerging
from the inter-vertebral foramen, it divides into
three unequal branches ; two of these (a and above
b) are external and oblique, and constitute the ab-
dmninal branches {ilio-scrotal nerves of some authors) ;
the third is internal, vertical, and often very small ;
it is the anastomotic branch which joins the second
nerve.
The anterior branch of the second lumbar nerve is at
least twice as large as the preceding ; it passes al-
most vertically downward, and gives off an anterior
branch, the internal inguinal (genito-crural of Bichat,
b), and an external branch, the external inguinal {in-
guino-cutaneous of Chaussier, c). It is scarcely di-
minished in size by giving oif these nerves, but be-
comes flattened, plexiform, and riband-shaped, fur-
nishes some large branches to the psoas, and anas-
tomoses with the third nerve.
The anterior branch of the third lumbar nerve is
twice as large as the preceding, passes obliquely
downward and outward, and is joined by the branch
from the second nerve, which greatly increases its
size. The large trunk thus formed, after a short course divides into two unequal branch-
es, which diverge at a very acute angle, and anastomose with two branches derived
from the fourth nerve, to constitute the crural (g) and the obturator (A) nerves.
The anterior branch of the fourth lumbar nerve is a little larger than the third ; it divides
after a short course into three branches : an external, which unites with the external
bifurcation of the third to form the crural nerve ; a middle, which unites with the internal
bifurcation of the same nerve to form the obturator nerve ; and an internal, vertical, an-
astomotic branch, which joins the fifth nerve.
The anterior branch of the fifth lumbar nerve (5 1) is somewhat larger than the fourth ; it
receives the internal branch of that nerve, and with it forms a large trunk, which enters
the sacral plexus, and was named by Bichat the lumbosacral nerve (i).
The Lumbar Plkxus.
The lumbar plexus (fig. 290) (lumbo-abdominal, Bichat) is a rather complicated inter-
lacement, formed by the anastomoses of the anterior branches of the lumbar nerves. It
is narrow above, where it consists of the sometimes slender communicating cord be-
tween the first and second lumbar nerves, and it becomes wider towards its lower part,
so as to have a triangular form ; it is situated upon the sides of the lumbar vertebrae, be-
tween the transverse processes and the fasciculi of the psoas muscle.
The branches which emanate from the lumbar plexus are divided into terminal branch-
es, namely, the crural (g), obturator (A), and lumbosacral nerves (i) ; and collateral branches,
improperly named musculo-cutaneous ; these are four in number ; they run between the
psoas and iliacus and the peritoneum, and reach the femoral arch. I shall divide these
collateral branches into two sets : an abdominal set, subdivided into the great (a) and
small (above b) ; and an inguinal set, subdivided into the internal (i) and external (c).*
Of these collateral branches, the abdominal only run in the sub-peritoneal adipose tis-
sue, the inguinal branches being covered by a layer of fascia, which keeps them in con-
tact with the psoas iliac muscle.
Collateral Branches of the Lumbar Plexus.
Jlbdominal Branches.
The abdominal branches of the lumbar plexus are intended for the parietes of the abdo-
* A change in the nomenclature of the collateral branches of the lumbar plexus appeared to me to be ne-
cessary. Bichat, who first distinguished them by special names, divides them into external or musculo-cuta-
neous branches, and an internal or genito-crural branch. Of the three external branches, Chaussier named
the external the ilio-sr'o'al. and the internal the inguino-culaneous ; the intermediate one, to which he gave
no particular name, - ■ ~ its old appellation of the midd/e JrancA. ■.- •
798 NEUROLOGY.
men, and form a continuous series with the dorsal nerves, to which they are very anal-
ogous as regards their distribution.*
The great ahdominal nerve {a, fig. 270) is the most external, or, rather, the highest of
the branches which come from the lumbar plexus (it is the superior musculo-cutaneous
nerve of Bichat) ; the terms ilio-inguinal and ilio-scrotal, which are generally applied to
it, are derived from the fact of its giving a small cutaneous branch to the pubic region. +
It arises from the first lumbar nerve, of which it may be regarded as a continuation ;
it immediately perforates the psoas, becomes sub-peritoneal, runs in front of the quad-
r.itus lumborum obliquely downward and outward, through the sub-peritoneal adipose
tissue, parallel to the twelfth dorsal nerve, and thus reaches the crest of the ilium to
the outer side of the quadratus lumborum. It next passes obliquely through the aponeu-
rotic attachments of the transversalis, runs along the crest of the ilium between that
muscle and the obliquus internus, and divides into two branches, the abdominal branch,
properly so called, and the pubic branch.
The abdominal branch, properly so called, runs inward between the transversalis and
the internal oblique, parallel to the abdominal branch of the twelfth dorsal nerve, with
which it almost always anastomoses, and soon divides, like the lower intercostal nerves,
into two filaments, one of which perforates the rectus, while the other, after having en-
tered the sheath of that muscle, perforates it and ramifies upon the skin.
The pubic branch (a, fig. 292) continues in the original course of the nerve : opposite
the anterior superior spinous process of the ilium, and often much beyond that point, it
receives an anastomotic twig from the small abdominal nerve {¥), and sometimes even
the whole of that nerve, runs parallel to the femoral arch, at a variable distance above
it, meets with the spermatic cord in the male, and the round ligament in the female,
emerges from the anterior orifice of the inguinal canal {a, fig. 291), is reflected outward
upon the superior angle of that orifice, and then expands into internal or pubic filaments,
which are distributed to the skin of the pubes, and external filaments, which supply the
skin of the fold of the groin ; this pubic branch sometimes divides behind the femoral
arch into two filaments, which escape separately from the inguinal ring.
At the point where the great abdominal nerve reaches the crest of the ilium, it very
frequently divides into two branches, a gluteal cutaneous, which crosses obliquely over
the crest of the ilium, and an abdominal, properly so called, which is distributed in the
manner just described ; in this case, the great abdominal nerve has an analogous distri-
bution to that of the dorsal nerves.
The small abdominal or small musculo-cutaneous nerve (above b. Jig. 290), the second
branch derived from the lumbar plexus, counting from without inward (the middle muscu-
lo-cutaneous of Bichat), is merely an accessory of the great abdominal nerve, sometimes
arising from it, often applied to it, and always anastomosing with it. It crosses oblique-
ly over the anterior surface of the quadratus lumborum, and then over the iliacus, and is
sometimes directed obliquely outward towards the anterior superior spine of the ilium,
to join the pubic branch of the great abdominal nerve, with which it is blended ; it some-
times runs alone between the transversalis and internal oblique : having reached the
middle of the femoral arch, it anastomoses {b',fig. 291) by a single twig with the pubic
branch of the great abdominal nerve, runs along the femoral arch below and parallel to
that branch, and terminates in the same manner, that is to say, in the skin of the pubes
and groin. I have seen it give off a small branch to the lower part of the rectus ab-
dominis. The small abdominal nerve deserves the name of ilio-scrotal as much as the
great abdominal. If this denomination is to be preserved, it might be called the small
ilio-scrotal.
The Inguinal Branches.
The external inguinal, or external cutaneous nerve (c, fig. 290), the third branch of the
lumbar plexus, counting from without inward (inguino-cutaneoiis, Chauss. ; inferior mus-
culo-cutaneous, Bichat), is intended exclusively for the integuments of the external and
posterior regions of the thigh. It generally comes off from the second lumbar nerve : I
have seen it arise by a common trunk from the second and third lumbar nerves, and I
have also seen it come off from the outer side of the crural nerve. It arises by one and
often by two cords, which unite as they emerge from the psoas, or within the substance
of that muscle. In either case, the nerve passes obliquely through the back part of the
psoas, crosses the iliacus, being bound down by a layer of fascia, and then gains the an-
terior superior spinous process of the ilium, below which it emerges {cfig. 291) from the
abdomen, passing behind the femoral arch, and apparently increasing in size during its
passage.
Below the femoral arch the nerve is sub-aponeurotic, or, rather, is situated in a sheath
* The varieties ^¥hich they prpsent as to their number, origin, and divisions, render their description diffi-
cult ; I shall point out the most important varieties as we proceed.
t I have frequently found the great abdominal branch divided into two distinct branches, which anastomosed
upon the crest of the ilium, and then had a common distribution. I have seen the uppermost division lying
»o close to the twelfth dorsal nerve that it might have been taken for a branch of that nervo.
THE INGUINAL BRANCHES, ETC. 799
formed by the deepest layers of the fascia lata, and divides into two cutaneous branches
(c c,fig. 292), a posterior or gluteal,* and an anterior or femoral.
The posterior or gluteal branch turns very obliquely outward, downward, and backward,
crosses the tensor vaginae femoris, and is distributed to the skin of the posterior region
of the thigh. It is sometimes derived from the internal inguinal nerve, and then emerges
from the abdomen on the outer side of the external inguinal nerve, crossing obliquely in
front of it. When the great abdominal nerve (ilio-scrotal of authors) gives off a cuta-
neous gluteal branch, there is only a trace of this posterior branch of the external ingui-
nal nerve.
The anterior or cutaneous branch divides into two others, which diverge at an acute
angle : one is external, the other hiternal ; the external branch gives off a series of fila-
ments, which pass backward and downward, forming loops with their concavities turned
upward, and is then lost towards the lower third of the thigh ; its place is then supplied
by the internal branch, which had at first descended vertically, but now turns outward
and backward, and is distributed over the outer and fore part of the knee.
These several divisions of the external inguinal nerve lie in contact with the femoral
fascia, and their ultimate filaments are applied to the skin.
The internal inguinal nerve (branche genito-crurale, Bichat ; rameau sous-pubien,
Chauss., b. Jig. 290) arises from the second lumbar nerve, passes directly forward
through the psoas, from which it emerges at the side of the bodies of the lumbar verte-
brae, runs vertically downward upon the anterior surface of the muscle covered by a very
thin layer of fascia, and having arrived within a greater or less distance from the femo-
ral arch, divides into two branches, an internal or scrotal, and an external ot femoral cuta-
neous branch (e). Not unfrequently this division takes place as the nerve emerges from
the psoas. Sometimes, indeed, the genito-crural nerve is double, but this arises merely
from its early subdivision. During its course, the internal inguinal nerve is crossed by
the ureter and covered by the spermatic vessels. +
The internal or scrotal branch (e, fig. 290) crosses over the front of the femoral artery,
gains the internal orifice of the inguinal canal, crosses the epigastric artery, and, before
entering the inguinal canal, gives off several filaments, which are reflected upward, and
dip into the substance of the internal oblique and transversalis ; the scrotal branch is
placed below the spermatic cord, from which it is perfectly distinct, runs with it through
the whole length of the inguinal canal {b,fig. 291), rests upon the reflected portion of the
femoral arch or Gimbernat's ligament, and emerges from the external orifice of the in-
guinal canal, opposite the lower end of the external pillar : at this point it is reflected,
passes vertically downward behind the cord, and ramifies in the skin of the scrotum of
the male, and of the labia majora in the female.
The femoral cutaneous branch gains the crural ring ; but before entering the ring, it
gives off a great number of very delicate filaments, which are reflected upward behind
the arch, to be distributed to the lower part of the psoas-iliac and transverse muscles :
it then passes through the crural ring, in contact with its outer angle, and crosses the
circumflex ilii artery at its origin, just as we have shown that the scrotal nerve crosses
the epigastric artery ; after leaving the crural ring (e, figs. 291, 292), it lies beneath the
fascia, but soon becomes sub-cutaneous, anastomoses with a cutaneous branch of the
crural nerve, and may be traced beyond the middle of the thigh, t
I have already stated, in describing the external inguinal nerve, that the posterior or
gluteal cutaneous branch of the external inguinal nerve is often given off by the internal
inguinal nerve. In that case, this branch runs outward, crosses the external nerve at a
very acute angle under the femoral arch, and escapes from below the arch on the outer
side of that nerve to turn round the tensor vaginae femoris. Not unfrequently the fila-
ments for the lower part of the internal oblique and transverse muscles arise by one or
more distinct branches.
, The Terminal Branches of the Lumbar Plexus.
These are three in number, viz., the obturator nerve, the crural nerve, and the great
communicating branch between the lumbar and sacral plexus, called the lumbosacral
trunk or nerve, which I regard as a dependance of the sacral plexus.
The Obturator JVerve.
The obturator nerve (A, fig. 290), which is distributed exclusively to the external obtu-
* Not unfrequently the external inguinal nerve gives off a third and very small internal branch, which lies
immediately in contact with the skin of the anterior region of the thigh, and may be traced as far as the lower
third of that region. This branch always anastomoses with a cutaneous branch of the crural nerve.
t Sometimes a small filament comes off from the genito-crural nerve while it is still within the substance
of the psoas, descends vertically on the inner side of this nerve, gives off a filament which is lost upon the ex-
ternal iliac artery, and then again becomes united with the nerve from which it had been given off.
t In order to assist the memory, by connecting these nerves with important parts, I am in the habit of call-
ing the femoral cutaneous branch of the internal inguinal nerve the branch of the crural ring, and the scrotal
branch, the branch of the inguinal canal. The scrotal branch may be cut, in relieving the stricture in inguinal
hernia, by the division of Gimbernat's ligament ; and the femoral cutaneous branch may be wounded when the
external angle of the crural ring is divided for the relief of femoral hernia.
800
NEUROLOGY.
rator muscle, to the three adductors of the thigh, and to the gracihs, is the smallest of
Fig. 291.
I'^'N-
\ m
the terminal branches of the lumbar plexus ; it arises from the
third and fourth lumbar nerves by two equal branches, which
unite at an acute angle ; it perforates the psoas, passes under the
angle of bifurcation of the common iliac artery and vein, runs
along the inner surface of the psoas, crosses very obliquely over
the sides of the brim of the pelvis, and is then placed below
the external iliac vessels, with which it forms an acute angle,
and above the obturator artery : throughout the whole of this
course, it is enveloped in the sub-peritoneal cellular tissue of that
region, and, thus flattened and enlarged, reaches the internal ori-
fice of the obturator or sub-pubic canal, on emerging from which
it expands into diverging branches (A, fig. 291) for the adductors
and the gracilis muscle of the thigh.
Collateral Branch. — The obturator nerve gives off no branch in
the pelvis : during its passage through the obturator or sub-pubic
canal, it gives two filaments to the obturator cxternus ; one of these
penetrates the upper border of the muscle, and the other enters
at its anterior surface.* The obturator intemus receives no fila-
ment from the obturator nerve.
Terminal Branches. — These are four in number ;t three of them,
constituting a superficial set, pass under the pectineus, and are dis-
tributed as follows : the internal to the gracilis, the external to the
adductor longus, and the middle to the adductor brevis ; the fourth,
which is more deeply seated, belongs to the adductor magnus.
The branch for the gracilis expands, as it enters the muscle, into
several filaments, the largest of which (r,fig. 291) runs for some
distance upon the internal surface of the muscle before termi-
nating in it.
The branch for the adductor longus enters the upper border and
deep surface of the muscle : a rather large division (q) of this
branch, taking a different course, passes sometimes in front of
and sometimes behind the muscle, which is crossed by the nerve
in the first case, and perforated by it in the second ; the nerve
then divides into several filaments, some of which anastomose
with the accessory branch (at m) of the internal saphenous nerve,
while another anastomoses with the saphenous nerve itself, and
a third terminates in the synovial membrane of the knee-joint :
this is an articular nerve ; it may unite with the articular branch
of the nerve for the vastus internus. The anastomotic division
of the branch for the adductor longus is sometimes as large as the
musculfu: branch itself t
The branch for the adductor brevis crosses the upper border of
that muscle, expands upon it, but does not enter it until it reaches
the middle ; there is almost always an anastomotic twig, which
joins the internal saphenous branch of the crural nerve.<J
The fourth branch, or branch for the adductor magnus, is the deep'
est ; it passes between the adductor brevis and magnus, and ram-
ifies in the last-mentioned muscle. II
* [It also gives off, in this situation, articular filaments to the hip-joint ; these
are small or absent when the articular branches of the accessory to the obturator
are large.] ... .
t [Before dividing into its terminal branches, the obturator is joined by its ac-
cessory nerve (see notes, infra) ; it supplies a separate branch to the pectineus
■when that from the accessory nei-ve is wanting.]
t See note, tn/rd. ,. l_,
^ In a great number of subjects I have found a small nervous cord, which sometimes came oit from the third
lumbar nerve, sometimes from the obturator itself, and which may be called the accessory of the obturator
nerve, or the nerve of the coxo-femoral articulation ; it perforates the psoas to reach its inner surface, runs par-
allel to and above the obturator nerve, gains the pul)es, which it crosses on the inner side of the ilio-pectineal
eminence, with which it is in contact, dips beneath the pectineus, and anastomoses with the internal saphenous
nerve, passing into the angle of bifurcation of the femoral artery, where it gives off the profunda. Opposite
the pubes it gives off several branches, which perforate the fibrous capsule of the coxo-femoral articulation,
and are distributed to the synovial membranes. [This small accessory nerve was first described by Schmidt.
As it passes under the pectineus it partially supplies that muscle ; its anastomotic branch is described as uni-
ting with the obturator nerve beneath the pectineus, and not with the internal saphenous (see also notes p.
infra, et 803). The articular branch was believed by Schmidt to end in the fat near the acetabulum, w heii tne
accessory nerve is small, the articular filaments and the branch to the pectineus are replaced by others from
the trunk of the obturator itself In the pelvis the nerve has been seen to give filaments to the levator am.—
(Schmidt. I)e Ncrvis Lumbalibus eorumque Plexu, 1794 ; Dr. Alex. Thomson, Lond. Med. and Surg. Journal,
tios. 95, iXi : 'E]V\s, Demonstrations of Anatomt/).'i
II [In the dissections of Schmidt, Thomson, and Ellis, the branches of the obturator nerve were found to
have a much more extensive distribution than that described in the text. According to their observations,
»ne of the superficial branches, which is named the long cutaneous nerve (q,fig. 291), and which corresponds
THE CRUKAL NERVE. 8QJ
^
^^;. • . yv.i. .„>r,i- The Crural J^erve. . ^♦.rr**^;r:;. ' -
The crural nerve {g,]ig. 290) is the external terminal hraiu^'.i ol' the lumbar plexus;
the third and fourth lumbar nerves arc almost entirely devoted to the formation of thja
large branch, which supplies all the muscles of the anterior region of the thigh, and the
integuments of the anterior regions of the thigh, leg, and foot.
After emerging from the psoas, the crural nerve is lodged in the groove betw^een the
psoas and iliacus ; it escapes from the pelvis with this muscle, in the sheath of which
it is contained : having arrived below the femoral arch (^, jig. 291), it turns slightly out-
ward, becomes flattened and widened, and immediately divides into a great number of
diverging branches. The nerve sometimes bifurcates, and then gives off these different
branches.
Relations. — In the iliac fossa, the crural nerve is covered by the iliac fascia, and is
separated by the psoas from the external iliac artery and vein. Opposite the femoral
arch it always occupies the groove between the psoas and iliacus, and is situated on the
outer side of the femoral artery, being separated from the vessel by the psoas, which is
very narrow at that point. It is of importance to remark, that the crural nerve is not
contained in the sheath of the femoral vessels, but is separated from them by the iliac
fascia (see ^^. 136).
Collateral Branches. — ^In the pelvis, the crural nerve gives off from its outer side a
great number of small branches {iliac branches), which enter separately into the iliacus
muscle, after having run for some distance obliquely downward and outward upon the
surface of that muscle. Only one branch enters the psoas. One of the branches for the
iliacus is very long, and descends vertically in front of that muscle, into which it enters,
after having turned round its outer border. I have already said that the external ingui-
nal nerve {ingiiino-cutaneous of authors) not unfrequently arises from the crural nerve.
Of the terminal branches of the crural nerve there are two which arise in front of the
others : these are, the musculo-cutaneous nerve, and the small nerve for the sheath of the
femoral vessels.* The Other branches are, proceeding from without inward, the branch
for the rectus, the branches for the vastus externus, the branches for the vastus internus, and
the cutaneous branch, called the internal saphenous nerve.
The Musculo-cutaneous Crural Nerve.
This nerve passes obliquely downward and outward between the sartorius and the
psoas and iliacus, and immediately expands into muscular branches, distributed exclu-
sively to the sartorius, and cutaneous branches.
The muscular branches may be divided into the short, which enter the upper part of the
sartorius, and the long, which run for some distance upon the deep surface of that mus-
cle, before passing into it.
The cutaneous branches are three in number ; two of them perforate the sartorius at
different points, and may be called •perforating branches. I shall call the third the acces-
sory branch of the internal saphenous nerve.
The superior perforating cutaneous or middle cutaneous nerve {f,fig. 291) passes, very
obliquely, through the upper part of the sartorius, and often, as it emerges from that
muscle, anastomoses with a branch from the internal inguinal (genito-crural) nerve ; it
then passes vertically downward, parallel to and on the inner side of the external ingui-
nal (external cutaneous) nerve ; it Hes in contact with the femoral fascia (/, Jig. 292),
or, rather, is contained in a proper fibrous sheath. During its course, the superior per-
forating cutaneous nerve gives off internal and external cutaneous filaments, and bifur-
cates, opposite the middle of the thigh, into two branches of equal size, which run par-
allel to each other, gradually diminishing in size, and may be traced down to the skin
over the patella.
io the anastomotic division of the branch for the adductor longus, gives off cutaneous branches (q,fig. 292),
which perforate the fascia to the inner side of the sartorius muscle, and supply the skin on the inner part of
the thigh ; it also gives anastomotic branches to the plexus (m, Jig. 291 ) formed in the middle of the thigh, and
sometimes an articular filament to the knee {these anastomotic and articular branches are described in the
text, p. 800) ; it then ends in a descending cutaneous branch, which perforates the fascia near the knee (r,fig.
292), communicates with the intern.al cutaneous and internal saphenous nerves, and is distributed to the skin
on the inner and back part of the two upper thirds of the leg. The deep branch of the obturator gives off
within the upper part of the adductor magnus an articular filament destined for the knee-joint ; this filament
descends in the substance of the adductor near the linea aspera, and enters the popliteal space, either by per-
forating the tendinous insertion of the muscle about its lower third, or by coming forward on the front of that
insertion, and then passing backward through the opening for the femoral artery : having reached the popli
teal space, it surrounds the artery with small filaments, and enters the back part of the knee-joint.
The cutaneous branches just stated to be given off by the superficial part of the obturator to the thigh and
leg, and the articular filament given by the deep branch of the obturator to the knee-joint, correspond, in their
dittnbulion, with the three collateral branches described by M. Cruveilhier {p. 803) as arising from the in-
ternal saphenous nerve after it has received a remarkable branch of origin from the obturator nerve, opposite to
the commencement of the profunda artery : these collateral branches of the internal saphenous were never
met with in Mr. Ellis's dissections. In some cases, then, it seems that part of the obturator joins the internal
saphenous, which afterward gives off cutaneous branches to the thigh and leg, and an articular filament to the
knee ; in other c:»ses, again, the obturator does not join the internal saphenous, the above-mentioned branches
arise directly from the obturator, and the internal saphenous gives no collateral branches.]
' LThe crural nerve also gives some small branches (s,_^^. 292), which pass inward behind the femoral
vessels, enter the pectineus muscle, and sometimes the psoas also.1
51
802 NEUROLOGY.
Tlie inferior perforating cutaneous or internal cutaneous nerve {I, fig. 291) run along
the inner border of the sartorius, enclosed in its sheath, passes obliquely through the
muscle at the middle of the thigh, but perforates the femoral fascia much lower down {I,
Jig. 292) ; it descends vertically, in contact with that fiiscia, and having arrived opposite
the internal condyle of the femur, is reflected forward upon itself, describing a loop with
the concavity turned upward ; it thus gains the patella, runs between the skin and the
sub-cutaneous bursa, and expands into a number of diverging filaments, which anasto-
mose with the reflected branch (/ 1) of the internal saphenous nerve on the inner side of
the patella. A small filament often remains in the sheath of the sartorius, anastomoses
upon that muscle with a branch from the accessory of the internal saphenous nerve, per-
forates the sheath of the sartorius opposite the knee, and anastomoses, on the inner side
of the joint, with the reflected branch of the internal saphenous.
The accessory cutaneous branch of the internal saphenous nerve arises from the mus:. Ulo-
cutaneous nerve on the inner side of the perforating branches, descends vertically, and
divides into two branches. The smaller of these is superficial (n, fig. 291) ; it enters the
sheath of the sartorius, runs along the inner border of the muscle, escapes from the
sheath below the middle of the thigh, crosses the adductor and the gracilis, and is in
contact with the internal saphenous vein until it reaches the inner side of the knee,
where it anastomoses with the internal saphenous nerve. The other branch, the satel-
lite nerve of the femoral artery, crosses obliquely over the nerve for the vastus internu*
and the internal saphenous nerve, and is situated in front of the latter, runs along the
femoral artery, covering the lower fourth of that vessel, and crosses very obliquely over
it, then passes over the tendon of the adductor magnus, and, having reached the fibrous
ring through which the femoral artery passes, it expands into a great number of fila-
ments, of which one anastomoses with the preceding branch (w), another joins the obtu-
rator nerve (at m), and a third unites with the internal saphenous nerve ; a sort of plex-
us is thus formed which gives origin to several nerves that cross obliquely over the gra-
cilis, to be distributed to the skin upon the posterior region of the leg.
The Small Nerve for the Sheath of the Femoral Vessels.
This branch, which often comes oflT separately from the lumbar plexus, is situated,
like the musculo-cutaneous, in front of the other branches of the crural nerve ; it then
expands into a great number of very slender filaments, which surround the femoral ar-
tery and vein. Two of these filaments, of which one passes in front of and the other
behind the femoral artery, unite to form a small nerve {p,fig3. 291, 292), that escapes by
the opening (p) for the internal saphenous vein, and accompanies the vein for a great
part of its course. Not unfrequently, the filaments which have passed between the ar-
tery and vein perforate a lymphatic ganglion. Two other filaments are distributed to
the adductor brevis and adductor longus ; several of them turn round the deep femoral
artery and vein, to become sub-cutaneous, and anastomose with other accompanying
branches of the femoral vessels, and more particularly with the internal saphenous nerve.
This small branch presents many varieties. I have seen it arise separately from the
fourth lumbar nerve, and it then runs along the anterior surface of the crural nerve.
The Nerve for the Rectus Femoris.
The nerve for the rectus femoris arises on the inner side of the preceding, enters the
upper part of the deep surface of the muscle, and divides into a superior or short branch,
which passes horizontally outward in the substance of the muscle, and an inferior or long
branch, which lies in contact with its inner border, and enters the muscle at the middle
of the thigh.
The Nerve for the Vastus Externus.
The nerve for the vastus externus sometimes arises by a common trunk with the pre-'
ceding, passes obliquely downward and outward beneath the rectus, to which it gives &.,
filament, and then divides into two branches : one of these immediately enters the upper
part of the vastus externus, and gives off, before penetrating it, a cutaneous branch,
which perforates the fascia lata and lies in contact with the skin of the external region
of the thigh : the other is longer, dips between the vastus externus and internus, and
enters the middle of the former muscle. This last branch almost always gives off a
sm8dl twig to the vastus internus.
The Nerves for the Vastus Internus.*
These are two in number ; the one is external, and descending vertically, enters that
portion of the vastus internus which corresponds to the anterior surface of the femur
(the crureus of authors), and may be traced as far as the lower part of the muscle : this
nerve furnishes several periosteal and articular filaments ; the other is internal, and much
larger ; it often arises by a common trunk with the internal saphenous nerve, runs ver-
tically downward in front of the vastus internus, parallel to and on the outer side of the
* It will be remembered that, according to my views, the portion of the triceps which is called the crurau
is not distinct from the vastus internus (see Mvojlooy).
THE INTERNAL SAPHENOUS NERVE.
m
femoral artery, being in contact with that vessel above, but separated from it below,
where it enters the vastus intemus. Before penetrating it, it gives off a very remark-
able articular and periosteal branch, which runs along the surface of the muscle, to the
aponeurosis of which it is applied :* opposite to the knee-joint it is reflected forward,
perforates the thick fibrous layer which invests the inner side of the joint, and divides
into two filaments, of which one, the articular, is lost behind the ligamentum patellae in
the quantity of adipose tissue which is found there ; while the other, or the periosteal,
gains the anterior surface of the patella, and is lost in the periosteum. This last filament
is re-enforced upon the inner border of the patella by another which passes out from the
substance of the vastus intemus.
The Internal Saphenous Nerve. ^- 292.
The internal saptienous nerve {t t',fig. 291), the satellite nerve .;
of the femoral artery in the thigh, and of the internal saphenous
vein in the leg, is at first situated on the outer side of the ar-
tery, but soon passes in front of that vessel, and is contained in
the same fibrous sheath ; when the artery passes through the
tendon of the adductor magnus to enter the popliteal space, the
nerve continues its vertical course in front of that tendon, and
crossing it very obliquely from before backward, gains the back
of the internal condyle of the femur, situated in front of the ten-
don of the gracilis, and separated from the skin by the sartorius ;
it then divides into two terminal branches (m, t',figs. 291, 292).
This division often takes place £is the nerve is crossing the ten-
don of the adductor magnus.
Collateral Branches. — At its upper part, the internal saphenous
nerve receives from the obturator nerve a remarkable branch of
origin, which passes from behind forward in the angle formed by
the femoral artery and the profunda.! It then gives off from its
inner side, at the middle of the thigh, a cutaneous femoral branch,
which passes between the sartorius and the gracilis, runs back-
ward and downward, and is distributed to the skin of the poste-
rior and internal region of the thigh. Several filaments continue
their course to the inner and back part of the knee, anastomose
with some branches given off from the saphenous nerve in the
leg, and are distributed to the skin of the internal and posterior
region of the leg.
At the point where the femoral artery perforates the adduc-
tor magnus, the internal saphenous nerve gives off a second or
tibial cutaneous branch, which passes between the sartorius and
gracilis, turns round the inner border of the latter muscle, pass-
es vertically downward parallel to the saphenous nerve, and di-
vides into several filaments, some of which anastomose with
that nerve, while the others are distributed to the skin upon the
internal and posterior region of the leg.
In the sheath of the adductor magnus the saphenous nerve
gives off an articular filament, which passes vertically downward
in the substance of the internal inter-muscular septum, gains the
knee-joint, perforates the fibrous layer, and may be traced into
the synovial adipose tissue. t
Terminal Branches. — The anterior, reflected, or patellar branch
(u, figs. 291, 292) perforates the sartorius^ opposite to the back
of the internal condyle, is reflected forward and downward in
a flattened form upon the inner side of the knee-joint, parallel
to and above the tendon of the sartorius, and expands widely
into ascending filaments, which pass in front of the ligamentum
patellae, and turn round the lower and then the outer borders of
the patella ; into descending filaments, which cross obliquely over
the crest of the tibia, and ramify in the skin which covers the
external region of the leg ; and into middle filaments, which oc-
cupy the space between the two preceding sets ; they are all dis-
tributed to the skin, and several of them anastomose with the cu-
taneous filaments upon the external region of the patella.
* [In this situation it sometimes receives the articular filament of the anasto-
motic or long cutaneous branch of the obturator nerve.]
t [This junction of part of the obturator with the internal saphenous nerve was never seen in the dissec-
tions of Mr. Ellis, nor did the saphenous give any collateral branch in the thigh ; but branches correspond-
ing in their distriliution to the three collateral branches described in the text arose from the obturator itself
(see also note, p. 800.)] % See note, p. 800.
^ The sartorius is, therefore, perforated in succession by three cutaneous branches, namely, two pprf.ii.i-
ting branches from the musculo-cutaneous nerve, and one from the internal st' •nous.
804 NEUROLOGY.
The posterior or straight branch {t') is larger than the preceding, and continues in the
original course of the nerve ; it almost always receives an anastomotic branch from the
obturator nerve, passes in front of the tendon of the gracilis, then between the sartorius
and that tendon, which it crosses very obliquely, to meet the internal saphenous vein («),
whose direction it then follows : having arrived opposite the junction of the three upper
fourths with the lower fourth of the leg, it divides into two branches ; the one, posterior
and smaller, passes vertically downward in front of the internal malleolus, upon which
it ramifies, some of the filaments reaching as far as the skin upon the inner side of the
sole of the foot ; the other branch, which is anterior and larger, runs along the internal
saphenous vein, like it, is situated in front of the internal surface of the tibia, then in
front of the internal malleolus, and expands into articular branches, which enter the tib-
io-tarsal articulation, and into cutaneous filaments, which ramify in the skin upon the
inner side of the tarsus.
The following are the relations of the saphenous nerve with the internal saphenous
vein : the nerve is at first placed in front of the vein, then crosses obliquely under it to
get behind it, and, lastly, it again returns to its position in front of the vessel.
During its course along the leg, the posterior branch of the saphenous nerve gives off
some internal and some external branches : the internal branches are very small ; the up-
per ones anastomose with the tibial cutaneous branch of the trunk of the internal saphenous
nerve, and concur with it in supplying filaments to the skin of the back of the leg. The
external branches, three or four in number, are large, and, in this respect, diminish from
above downward ; their direction is obliquely downward and outward, in front of the tibia,
which they cross ; their course is a long one, and they are distributed extensively to dif-
ferent portions of the skin of the leg. All these divisions are parallel to each other, and
to the anterior reflected or patellar branch of the saphenous nerve.
THE ANTERIOR BRANCHES OF THE SACRAL NERVE.
Dissection. — Enumeration. — The Sacral Plexus. — Collateral Branches, viz., the Visceral
Nerves — the Muscular Nerves — the Inferior Hemorrhoidal — the Internal Pudic and its
Branches — the Superior Gluteal Nerve — the Inferior Gluteal, or Lesser Sciatic Nerve —
the Nerves for the Pyramidalis, Quadratus Femoris, and Gemelli. — Terminal Branch of
the Sacral Plexus, or the Great Sciatic Nerve. — The External Popliteal and its Branches
— the Peroneal Saphenous, Cutaneous, and Muscular Branches — the Musculo-cutaneous —
the Anterior Tibial. — The Internal Popliteal and its Branches — the Tibial or External
Saphenous — Muscular and Articular Branches — the Internal Plantar — the External Plan-
tar.— Summary of the Nerves of the Lower Extremity. — Comparison of the Nerves of the.
Upper with those of the Lower Extremity.
Dissection. — Make an antero-posterior section of the pelvis, as in dissecting the inter-
nal iliac artery.
The anterior branches of the sacral nerves (26 to 3\,fig. 268), which are six in number,
communicate with the sacral ganglia of the sympathetic, after they have emerged from
the sacral foramina, and present the following arrangement :
The first nerve (I, fig- 290), which is very large, passes obliquely downward and out-
ward, in front of the pyriformis, and is joined at a very acute angle by the lumbo-sacral
nerve (i), to assist in the formation of the sacral plexus.
The second nerve, which is as large as the preceding, passes much more obliquely
downward and outward, and immediately enters the sacral plexus.
The third nerve (3), which is scarcely one fourth as large as the second, passes more
horizontally outward to enter the sacral plexus. A considerable interval, in which is a
large part of the pyriformis, separates it from the second nerve. A filament stretched
in front of this muscle passes from the second to the third sacral nerve.
The fourth nerve (4), which is only one third the size of the third, is divided and dis-
tributed in the following manner : One of its divisions assists in forming the sacral
plexus ; it gives off several viscer^d branches, which enter the hypogastric plexus ; it
communicates with the fifth sacral nerve by another division ; it gives off one or two
branches to the coccygeus muscle ; and, lastly, it gives a cutaneous coccygeal branch,
which runs along the border of the sacrum, penetrates the great sacro-sciatic ligament,
crosses that ligament very obliquely, and turns round its lower edge, perforates the coc-
cygeal attachments of the glutseus maximus, passes very obliquely through the muscle,
gives branches to it, and then ends in the integuments.
The fifth and sixth nerves, which have no connexion with the sacral plexus, are ex-
tremely small ; the fifth is not more than half the size of the fourth ; the sixth is so very
slender a filament, that it has often escaped the notice of anatomists, and hence the in-
correct but prevalent opinion that there frequently exist only five sacral nerves.
The fifth nerve, at its exit from the anterior sacral foramen, divides into an ascending
branch, which comnaunicates with the fourth, and a descending branch, which passes di-
COLLATERAL BRANCHES OF THE SACRAL PLEXUS. 805
recfty downward to anastomose with the sixth, of which it appears to form the ascend-
ing branch.
The sixlh nerve consists of a mere filament, which divides, while still contained within
the sacral foramen, into an ascending or anastomotic branch, which is merely the de-
scending branch of the fifth ; a descending or inferior coccygeal branch, which passes ver-
tically downward along the coccyx in the substance of the sacro-sciatic ligament, and is
distributed to the skin ; and certain external branches, which perforate the sacro-sciatic
ligament, and terminate in the glutaeus maximus.
The Sacral Plexus.
The sacral plexus {Jig. 290) is formed by the four upper sacral nerves (1 to 4) and the
lumbo-sacral nerve (i) from the lumbar plexus ; the three superior sacred nerves pass
entirely into this plexus ; the fourth nerve only sends one of its divisions to it. The
lumbo-sacral trunk or nerve, which emanates from the lumbar plexus, is formed by the
whole of the fifth lumbar nerve add0 to a branch from the fourth. This great nervous
trunk establishes a free connexion between the lumbar and sacral plexuses, which, in
fact, constitute only one plexus, which may be called the lumbo-sacral. I would here
recall to mind that there is a precisely similar arrangement with regard to the cervical
and brachial plexuses, to which the lumbar and sacral plexuses have an undoubted an-
alogy.
The sacral plexus is distinguished by its simplicity from most other plexuses, which
are always more or less complicated. It is formed by the convergence of five cords to-
wards the sciatic notch. As the lumbo-sacral cord is vertical, and the third and fourth
sacral nerves are horizontal, it follows that the form of the sacral plexus resembles a
triangle, the base of which measures the entire length of the sacrum, while its apex
corresponds to that portion of the sciatic notch which is situated above the spine of the
ischium. The great sciatic nerve («) is the continuation of this plexus, which, as Bichat
judiciously remarked, is merely the sciatic nerve itself flattened from before backward,
the intricacy of arrangement so evident in the plexus representing that which exists in
all nervous cords.
The following are the relations of the sacral plexus : It rests behind upon the pyri-
formis, and it corresponds in front to the internal iliac vessels, from which it is separa-
ted by a layer of fascia : these vessels also separate the plexus from the rectum and
peritoneum.
Of the collateral branches, some are anterior, namely, the visceral nerves, which enter
the hypogastric plexus ; the nerve for the levator ani ; the nerve for the obturator inter-
nus ; the internal pudic nerve : the other collateral branches are posterior, namely, the
superior gluteal nerve ; the inferior gluteal or lesser sciatic nerve ; the nerve for the
pyriformis ; the nerve for the geraelli ; and the nerve for the quadratus femoris. The
great sciatic nerve is the only terminal branch of the sacral plexus.
The Collateral Branches of the Sacral Plexus.
The Visceral Jferves.
Dissection. — After having made a section of the pelvis at one side of the symphysis,
turn the bladder and the rectum over to the same side ; carefully detach the peritoneum,
which is reflected from the pelvis upon these viscera ; lacerate the cellular tissue to
reach the branches given off" from the fourth nerve ; and then trace the rectal and vis-
ceral nerves, following the annexed description. It is advantageous to empty the large
veins of the pelvis, and to soak it in water for some time previously to dissecting these
nerves.
The visceral nerves do not, properly speaking, come from the sacral plexus, but rather
directly from the fourth and fifth sacral nerves ; they are three or four in number, and
pass upward upon the sides of the rectum and bladder in the male, and of the rectum,
vagina, and bladder in the female ; some of them are distributed directly to those organs,
but the greater number (y, fig. 302) enter the hypogastric plexus (m), which will be de-
scribed with the sympathetic system.
The JSTervesfor the Levator Ani.
Besides several rectal and vesical filaments which go to the levator ani, this muscle
receives two filaments directly from the fourth sacral nerve (4, fig. 290) : the larger of
these filaments enters the middle of the muscle ; the other, which is smaller, passes
upon the sides of the prostate in the male, and of the vagina in the female, and termi-
nates in the anterior portion of the muscle.
The Nerve for the Obturator Internus.
It arises from the anterior part of the sacral plexus, and more particularly from that
portion which belongs to the lumbo-sacral cord and the first sacral nerve ; it passes im-
mediately behind the spine of the ischium, is reflected forward through the small sciatic
806 NEUROLOGY.
notch, and expands into three diverging branches, which are distributed within the mus-
cle. In order to expose this nerve, the lesser sacro-sciatic ligament may be divided.
The Inferior Hemorrhoidal J^erve.
This nerve, which is intended for the sphincter ani and the adjacent skin, arises (from
4, Jig. 290) on the inner side of the internal pudic nerve, of which it is sometimes a
branch, passes, like that nerve, behind the spine of the ischium, and then between the
two sacro-sciatic ligaments, reaches the front of that portion of the glutaeus maxiraus
which projects below the great sacro-sciatic ligament, communicates with the superfi-
cial nerve of the perineum, gains the side of the rectum, and opposite the upper border
of the sphincter expands into a great number of branches ; of these, some are anterior,
and often anastomose with one of the divisions of the superficial perineal nerve ; others
are median, and pass upon the sides of the sphincter ani as far as the skin, in which they
terminate ; lastly, others are posterior, and proceed to the back part of the sphincter.
The hemorrhoidal or anal nerve is sometimes di^pbuted exclusively to the skin round
the anus ; it may then be named the anal cutaneoits nerve.
The Internal Pudic JVerve.
Dissection. — It is convenient to commence the dissection of this nerve from within
outward, by dividing the lesser sacro-sciatic ligament, and separating the obturator fas-
cia from the obturator internus muscle. The superior branch of the nerve upon the dor-
siun of the penis may then be traced without taking it away. The perineal branches
must then be very carefully dissected, and the continuity of these branches with those
already dissected within the pelvis should be made out.
The internal pudic nerve (d. Jig: 293) arises from the lower border of the flattened
band formed by the nerves of the sacral plexus opposite to their junction ; it passes be-
hind the spine of the ischium, and then enters the ischio-rectal fossa through the lesser
sciatic notch, that is, between the two sacro sciatic ligaments, on the inner side of the
internal pudic artery, and divides into two branches (/, Jig. 290), the injcrior branch, or
'perineal nerve, and the superior or deep branch, or the dorsal nerve oj the penis.
The Perineal Nerve.
The inferior branch or perineal nerve corresponds to the trunk of the internal pudic ar-
tery, and to all its divisions, excepting the dorsal artery of the penis. It is the true con-
tinuation of the nerve, and accompanies the trunk of the internal pudic arterj", being sit-
uated below that vessel ; it runs forward and then upward between the obturator inter-
nus and the obturator fascia, describes a curve having its concavity directed upward, and
placed on the inner side of the tuberosity of the ischium, perforates the obturator fascia,
opposite to the junction of the tuberosity with the ascending ramus of the ischium, and
immediately divides into two branches : an inferior or anterior superficial perineal, which
corresponds to the superficial artery of the perineum ; and a superior, which corresponds
to the artery of the bulb, but which has a much more extensive distribution ; I shaU
call it the bulbo-urethral nerve.
The Collateral Branches of the Perineal Nerve. — During its course, the perineal nerve
gives off a branch which might l>e called the external perineal ( posterior superficial perin
eal) ; this branch perforates the great sacro-sciatic ligament, passes by the internal sur
face of the tuberosity of the ischium, turns inward and downward, and then beneath
the tuberosity, runs along the crus of the corpus cavernosum, and is lost in the dartos
and scrotum in the male, and in the substance of the labia majora in the female. I have
seen this nerve give a branch to the coccygeus, and two branches to the sphincter.
This external perineal branch, moreover, presents many varieties. In some cases it
terminates by anastomosing with the superficial branch of the perineum. In one case,
in which the external perineal branch was very small, it was re-enforced by a branch from
the inferior gluteal or lesser sciatic nerve, which crossed the outer side of the tuberosity
of the ischium, and united, in front of that tuberosity, with the external perineal branch.
The Terminal Branches of the Perineal Nerve. — The superjicial {anterior superjicial) pe-
rineal nerve follows the superficial artery of the perineum, passes, like it, obUquely in-
ward and forward, through the cellular interval between the ischio-cavernosus, and
bulbo-cavernosus, receives a rather large filament from the external perineal branch, and
almost always divides into several remarkably long filaments, which pass through the
dartos, some reaching the bottom of the scrotum, while others, running along the lower
surface of Uie penis, are distributed to the skin of that organ, and may be traced as far
as the prepuce.
The bulbo-urethral nerve, the second terminal branch of the perineal nerve, passes
above and sometimes through the fibres of the transversus perinei muscle, supplies some
small branches to the anterior part of the compressor urethrae and the posterior part of
the bulbo-cavernosus, furnishes a bulbar branch which dips into the substance of the
bulb, and then expands into very delicate filaments on the corpus spongiosum.
DEEP BRANCH OF THE INTERNAL PUDIC, ETC. "gOV
The Deep Branch of the Internal Pudic, or the Dorsal Nerve of the Perns.
This is the highest of the terminal divisions of the internal pudic nerve, and corre-
sponds to the deep branch of the internal pudic artery. It is at first applied, together
with that vessel, against the internal surface of the tuberosity of the ischium, and pass-
ing upward between the levator ani and obturator internus, gains the arch of the pubes ;
it then runs forward among the sub-pubic veins through the several ligamentous struc-
tures below the arch, and reaches the dorsum of the penis, where it is situated at the
side of the suspensory ligament. Having now become the dorsal nerve of the penis, it
runs along that organ in the median line, like the dorsal artery, but superficially to that
vessel, and divides into an internal and an external branch.
The internal branch, or branch for the glans penis, continues in the original course of
the nerve upon one side of the median line, becomes more deeply seated as it runs for-
ward, but without entering the corpus cavernosum, and thus arrives at the corona glan-
dis ; at this point it expands and passes deeply between the base of the glans and the
corpus cavernosum, gives no filament to the latter, but is entirely distributed to the glans,
penetrating that part by extremely delicate filaments, which traverse the spongy tissue,
and may be traced, at least in a great measure, to the papillae on the surface of the glans.
The external or cutaneous branch, which is more superficial, comes off from the prece-
ding at a very acute angle, passes obliquely upon the sides of the penis, and expands
into a number of very long and slender filaments, some of which lie in contact with the
corpus cavernosum, and supply it with very slender filaments, "while others run into the
sub-cutaneous cellular tissue, and are distributed to the skin of the penis ; a considera-
ble number terminate in the prepuce. The external branch of the dorsal nerve of the
penis supplies the skin upon the three upper fourths of the circumference of the penis.
The perineal branches supply that of the lower fourth. I have not found any branch of
the internal pudic nerve corresponding to the artery of the corpus cavernosum.
In the female, when this nerve reaches the clitoris, it becomes very small ; it passes
under the arch of the pubes, between it and the cms of the clitoris ; it runs along that
crus, becomes curved like the clitoris itself, upon the side of which it expands into fila-
ments, and then ramifies in the substance of that organ ; several of the filaments run
forward to the skin of the anterior part of the labia majora.
The superficial perineal branch passes between the constrictor muscle and the bulb of
the vagina, and then terminates in these parts.
, The internal pudic nerve in the female does not appear to me to be half the size of the
internal pudic nerve of the male. In one case I found that it consisted only of the branch
for the clitoris, the superficial branch being supplied by the inferior gluteal nerve.
The Superior Gluteal JSTerve.
The superior gluteal nerve, which is intended for the glutaeus medius and minimus, and
the tensor vaginae femoris, arises from the back of the lumbo-sacral trunk, before its
junction with the first sacral nerve. I have seen it arising by two roots, of which one
came from the lumbo-sacral nerve and the other from the posterior surface of the plex-
us : it emerges from the pelvis (a, fig. 293) by the upper and fore part of the great sci-
atic notch, in front of the pyriformis, is reflected upon this notch to pass between the
glutaeus medius and minimus, and divides into two branches ; the one ascending, which en-
circles the origin of the glutaeus minimus, like the corresponding branch of the gluteal ar-
tery ; and the other descending, which passes obliquely downward and outward, between,
the glutaeus medius and minimus, to which it gives off numerous filaments, and thus, grad-
ually diminished in size, it embraces, as it were, the posterior surface of the glutaeus min-
imus, and having reached the external border of that muscle, it passes downward, and
enters the sheath of the tensor vaginae femoris, in which it terminates. Before entering
the sheath of the tensor vaginae it gives off a remarkable branch, which turns round the
anterior border of the glutaeus minimus, and ramifies in that muscle.
The JVervefor the Pyriformis.
This little nerve arises separately from the posterior surface of the sacral plexus, and
more particularly from the third sacral nerve ; it divides into two branches, which im-
mediately enter the anterior surface of the muscle.
The Inferior Gluteal JVerve. >
The inferior gluteal nerve (Bichat), or the lesser sciatic nerve {Boyer), is intended for the
glutaeus maximus, the integuments of the posterior region of the thigh, and for a part of
the skin of the leg. It arises from the back of the sacral plexus, sometimes by one
cord, sometimes by several very distinct cords. It emerges from the pelvis (near c,fig.
293), below the pyriformis, together with and on the inner side of the great sciatic nerve,
to which it may be regarded as an accessory ; it passes behind that nerve, and divides
into two sets of branches, viz., muscular and cutaneous.
The muscular branches (c) are numerous, although exclusively intended for the glutaeus
maximus ; they divide into ascending and external branches, which run along the ante-
808 NEUROLOGY.
rior surface of the muscle, spread out upon it, and may be traced as far as its upper oor-
der, and descending and internal branches, which pass between the tuberosity of the is-
chium and the muscle, and then enter the latter.
The cutaneous branch (b) continues in the original course of the nerve, behind the great
sciatic, and in front of the glutajus maximus ; it crosses obliquely, downward and in-
ward, over the tuberosity of the ischium and the origins of the biceps and senii-tendi-
nosus muscles ; considerably reduced in size, from having given off several branches, it
assumes the name of lesser sciatic (/), runs vertically downward, becoming smaller and
smaller, and may be traced down to the posterior region of the leg.
The cutaneous branch, as it emerges from the glutaeus maximus, gives off a consid-
erable recurrent branch (e), which might be regarded as a terminal branch of the nerve.
This branch is reflected upward so as to describe a curve having its concavity turned
upward, and subdivides into two secondary branches, an internal and an external : the
external branch is the larger, and ramifies in the skin of the gluteal region ; the internal
or scrotal branch (pudendalis longus inferior, Sammering) is a very remarkable one ; it is
reflected forward upon the under surface of the tuberosity of the ischium, runs along at
some distance from the ascending ramus of the ischium and the descending ramus ot
the OS pubis, anastomoses with the superficial perineal nerve, reaches the scrotum above
the testis, and divides into two branches — an external, which passes on the outer side,
and an internal, which runs on the inner side of the testis ; having embraced this organ,
they are distributed to the skin of the anterior part of the scrotum and the lower part oi
the penis. In the female, this branch belongs to the labia majora.
All along the thigh, the cutaneous branch of the inferior gluteal nerve gives off some
very small external branches, and some larger internal branches, which are reflected
forward, describing curves having the concavity turned upward, and supply the skin of
the internal region of the thigh.
In the pophteal space, the cutaneous branch divides into two filaments, one sub-cuta-
neous, which may be traced, notwithstanding its extreme tenuity, as far as the middle of
the posterior region of the leg ; and the other sub-aponeurotic, which perforates the fas-
cia of the leg, runs along the external saphenous vein, and anostomoses with the exter-
nal saphenous nerve.
The Jferves for the Quadratus Femoris and the Gemelli.
The superior gemellus receives a special nerve from the anterior part of the sacral plexus.
The nerve for the inferior gemellus is a branch of the nerve for the quadratus femoris.
The nerve for the quadratus femoris is remarkable. It arises from the front of the sa-
cral plexus, or, rather, from the limit between this plexus and the great sciatic nerve,
passes vertically downward in front of the gemelli and obturator internus, by which it is
separated from the great sciatic nerve, and it is placed in contact with the os innomi-
natum, to the outer side of the tuberosity of the ischium. It gives off some external pe-
riosteal and osseous branches, which enter the foramina in the tuberosity of the ischium ;
some internal or articular branches, which perforate the fibrous capsule of the hip-joint ;
a branch for the inferior gemellus ; and then terminates in the quadratus femoris, which
it enters by its anterior surface.
The Terminal Branch of the Sacral Plexus, or the Great Sciatic Nerve.
The great sciatic nerve (grand femoro-poplite, Chauss.) is intended for the muscles of
the posterior region of the thigh, and for the muscles and integuments of the leg and
foot : it is the termination (s, fig. 290) of the sacral plexus, or, rather, it is the sacral
plexus itself condensed into a nervous cord. The fifth lumbar nerve, a branch of the
fourth lumbar, the three superior sacral nerves, and a branch from the fourth, form the
origins of this great nerve, which is the largest in the body.
It emerges from the pelvis, through the great sciatic notch, below the pyriformis im-
mediately above the spine of the ischium, passes vertically downward (s, fig. 293) be-
tween the tuberosity of the ischium and the great trochanter, both of which project so
as to separate it from the skin, or, more exactly, it runs along the outer side of the tu-
berosity of the ischium, in a very deep groove between that process and the margin of
the cotyloid cavity. At its exit from the pelvis, it is a flat, riband-shaped nerve, six
lines in breadth, but it soon becomes rounded, runs vertically downward along the back
of the thigh, sloping, however, a little outward ; having arrived about three or four fin-
gers' breadth above the knee-joint, it divides into two branches, which are called the
external popliteal sciatic or the peroneal nerve (i), and the internal popliteal sciatic or tibial
nerve (A).
The sciatic nerve sometimes divides at its exit from the pelvis, but it may do so at
any other point between that and the popliteal space. This premature division is of
no importance ; in fact, it always exists ; for when there is apparently only one trunk,
the two branches of the bifurcation are perfectly distinct through the whole length of
ihe thigh, and are merely in contact with each other.*
* When the great sciatic nerve divides within the pelvis, the upper division perforates the pyriformis, while
'He lower emerges from below that muscle.
THE GREAT SCIATIC NERVE, ETC.
809
Relations. — Behind., the great sciatic nerve is covered by the Fig. 293.
glutaeus maximus, and then by the long head of the biceps and
the semi-tendinosus ; lower down it occupies the cellular inter-
val between these two last-named muscles, and when they sep-
arate from each other to form the borders of the popliteal space,
it becomes sub-aponeurotic.
In front, it corresponds to the gemelli and obturator internus,
by which it is separated from the os coxffi, to the quadratus femo-
ris and the adductor magnus. During its course it is surround-
ed by a large quantity of adipose cellular tissue, but has no ac-
companying vessel.*
Collateral Branches of the Cheat Sciatic. — The great sciatic
nerve gives off in the thigh five muscular and three articular
branches ; they sometimes arise separately, sometimes by a
common trunk. They are the following :
The nerve for the long head of the biceps, which divides into two
ascending branches for the origin of that muscle from the ischium,
and descending branches, which run for a long time in front of the
muscle, and then enter it by a series of filaments.
The nerve for the semi-tendinosus, which runs upon the anterior
surface of the muscle, and does not enter it until it reaches the
lower third of the thigh.
The nerves for the semi-membranosus are two in number ; they
almost always anastomose and enter the internal surface of the
muscle at two different points.
A nerve for the adductor magnus, which runs forward and then
inward, and enters near the inner border of the muscle. We
have seen that the adductor magnus receives most of its nerves
from the obturator nerve. All the preceding branches arise from
the upper part of the sciatic nerve, opposite to the quadratus femo-
ris, and often by a common trunk.
A nerve for the short head of the biceps sometimes arises at the
same height as the preceding, but is most commonly given off
from the sciatic nerve at the middle of the thigh. When the sci-
atic nerve divides prematurely, the branch we are now descri-
bing comes from the external popliteal. This nerve enters the
upper extremity of the muscle, expanding into diverging fila-
ments.
An articular nerve of the knee, which often arises by a common
trunk with the preceding, and is not unfrequently given off from
the external popliteal ; it passes vertically downward in front of
the great sciatic nerve, through some adipose tissue, to gain the
outer side of the joint ; having arrived above the external con-
dyle, it turns and divides into several filaments, which perforate
the fibrous tissue of the joint, and are distributed to the articular
adipose tissue, where they are scattered, some above, others be-
low, and others on the outer side of the patella, t
The External Popliteal Sciatic or Peroneal J^erve.
The external popliteal sciatic, external popliteal, or peroneal nerve
{i,fig. 293), the external terminal branch of the great sciatic, is
intended for all the muscles of the anterior and external region of
the leg, and for the skin on the leg and on the dorsum of the foot.
It is scarcely half the size of the internal popliteal ; it runs obliquely downward and out-
ward, behind the external condyle of the femur through the popliteal space, and is pla-
ced nearer to the surface than the internal popliteal nerve, which is lodged in the inter-
condyloid fossa ; it then crosses obliquely over the origin of the outer head of the gas-
trocnemius, passes behind the head of the fibula, from which it is separated by the ori-
gin of the soleus, turns horizontally upon the neck of that bone (at v), between it and the
peroneus longus, and expands into four branches, two superior or recurrent, for the tib-
ialis anticus, and two inferior and larger, which form the true terminations of the nerve.
Collateral Branches.
During this course, the external popliteal nerve gives off two superficial collateral
* In three instances I have found the great sciatic accompanied by a large vein, which was continuous with
the popliteal vein, and perforated the upper part of the adductor magnus, like the profunda artery. In two of
these cases the sciati* nerve divided at its exit from the pelvis. I did not note the arrangement of the nerve
in the third case. It was a remarkable circumstance that there was another popliteal vein accompanying the
artery : in one of the cases the vein was in front instead of behind the artery. t See note, p. 812.
5K
810 NEUROLOGY.
nerves : a saphenous nerve, which we shall call the peroneal saphenous^ to distinguish it
from the tibial saphenous, and the peroneal cutaneous branch.
The Peroneal Saphenous Nerve.
The peroneal saphenous nerve {n) presents many varieties in different subjects, both in
regard to its size and origin. It is generally smaller than the tibial saphenous (/), of
which it may be regarded as an accessory ; it arises in the popliteal space, descends
vertically beneath the fascia, between the external and internal popliteal nerves, perfo-
rates the fascia opposite the middle of the leg, to join the external saphenous vein,
with which it runs along the tendo Achillis, and terminates upon the outer side of the
OS calcis. During this course, it gives off" several cutaneous filaments and a communi-
cating branch to the tibial saphenous nerve : this branch is of considerable size, and
comes off" while the nerve is still beneath the fascia. Having become very slender after
giving these branches, the peroneal saphenous nerve subdivides opposite the lower part
of the tendo Achillis, and upon the outer side of the os calcis, into several calcaneal
branches, one of which turns obliquely round the posterior surface of the os calcis, while
the others descend vertically, are reflected upon the under surface of that bo^e, and are
distributed to the skin of the heel. Not unfrequently the peroneal saphenous nerve gives
off a malleolar branch, which passes between the external malleolus and the skin, and
anastomoses in front of the ankle-joint {y,fig. 291) with a twig from the muscuJo-cuta-
neous nerve. This malleolar branch, which often comes from the last-mentioned nerve,
is, moreover, remarkable, like all nerves which are subjected to strong pressure, for its
thickness, its grayish colour, and, lastly, for its knotted, and, as it were, ganglionated
appearance.
The peroneal saphenous nerve is often very small, and is lost in the skin upon the
middle of the leg : its place is then supplied in the lower two thirds of the leg by the tib-
ial saphenous nerve, the size of which is always in an inverse ratio to that of the pero-
neal saphenous.
No nerve presents more varieties than the peroneal saphenous ; they relate to its size
and to the point at which it anastomoses with the tibial saphenous. One of the most
remarkable varieties is that in which the peroneal and tibial saphenous nerves, those call-
ed communicating saphenous branches {communicans fibula, n; communicans tibia, I) unite
in the popliteal space into a single trunk, the external saphenous {p), the distribution of
which corresponds to the ordinary distribution of the two nerves.
The Peroneal Cutaneous Branch.
This comes off from the external popliteal nerve, behind the outer condyle of the fe-
mur, passes vertically downward along the fibula, in contact with the skin, and divides
into ascending and descending branches, the latter of which may be traced as far as the
lower part of the leg.
The Terminal Branches of the External Popliteal J^erve.
The Branches for the Tibialis Anticus.
The two superior or recurrent branches, resulting from the subdivision of the external
popliteal, pass horizontally inward, behind the extensor communis digitorum, and are
distributed to the tibialis anticus ; one of these branches supplies the peroneo-tibial ar-
ticulation.
The Musculo-cutaneous Branch, or External Peroneal Nerve
The musculo-cutaneous branch {x,fig. 291), the lowest of the terminal branches of the
external popliteal, is intended for the muscles of the externail region of the leg, and for
the skin upon the dorsum of the foot (pretibio-digital, Chauss. ; peroneus externus, Saemm.).
It passes at first obliquely, then vertically downward in the substance of the peroneus
longus, turns forward to enter between the extensor longus digitorum and the peroneus
longus and brevis, and perforates the fascia of the leg, above the ankle-joint : having
thus become sub-cutaneous, it passes obliquely downward and inward, following the di-
rection of the extensor longus digitorum, becomes flattened and widened, and divides a
little below the tibio-tarsal articulation into an internal and an external branch ; the lat-
ter subdivides into three other branches, so that there are in all four terminal branches,
which form the dorsal collateral nerves of the toes.
Not unfrequently the musculo-cutaneous nerve bifurcates as it escapes from beneath
the fascia of the leg, and its two branches reunite opposite to the tibio-tarsal articula-
tion, so as to describe an elongated ellipse.
Collateral Branches. — There are two branches for the peroneus longus, of which one
comes off from the nerve immediately after its origin, while the other arises lower down,
and runs a very long course in the substance of the muscle ; there is also a branch for
the peroneus brevis,' which often arises by a common trunk with the preceding.
In its sub-cutaneous portion, the musculo-cutaneous nerve supplies several filaments
to the skin, among which we should distinguish an external malleolar filament, which passes
between the external malleolus and the skin, increases considerably in size, and becomes
THE ANTERIOR TIBIAL NERVE, ETC. 811
grayish and knotted, like all nerves subjected to pressure. This filament often anastomo-
ses with the malleolar branch of the peroneal saphenous nerve, and sometimes supphes
the place of that malleolar branch.
Terminal Branches. — There are four terminal branches of the musculo-cutaneous nerve,
distinguished numerically as the first, second, third, and fourth (see^^. 291). The^r«(
or internal branch passes very obliquely forward and inward, to form the internal dorsal
collateral nerve of the great toe ; this nerve, like all nerves subjected to pressure, increas-
es in size and becomes grayish, and, as it were, knotted opposite the metatarso-phalan-
gal articulation. The second branch, which often arises by a common trunk with the
first, supplies the external dorsal collateral nerve of the great toe, and the internal collateral
nerve of the second toe. The third branch supplies the external collateral nerve of the sec-
ond, and the internal collateral nerve of the third toe. These two large branches are
often replaced by one (») from the anterior tibial nerve, with which they anastomose.
The fourth terminal branch or internal branch supplies the external dorsal collateral nerve
of the third, and the internal dorsal collateral nerve of the fourth toe.
All the filaments from these branches are distributed to the skin upon the dorsal re-
gion of the foot and digital phalanges.
In a great number of subjects, the tibial or external saphenous nerve supplies the in-
ternal collateral nerve of the little toe, and the external collateral nerve of the fourth
toe ; but in others, these nerves are furnished by an additional terminal branch of the
mosculo-cutaneous nerve ; in all cases the nerves anastomose with each other.
The Anterior Tibial, or Interosseous Nerve.
The anterior tibial or interosseous nerve (v v,fig. 291), intended for the muscles on the
anterior region of the leg, for the extensor brevis digitorum, and for the interosseous
muscles in the foot, is as large as the musculo-cutaneous nerve just described ; it runs
to the inner side of that nerve, beneath the extensor communis digitorum, and passes
along the interosseous ligament, together with the anterior tibial artery lying in front of
that vessel. It is placed, like the artery, between the tibialis anticus and the extensor
communis digitorum, from which it is separated below by the extensor proprius pollicis
pedis ; it supplies a great number of filaments to all these muscles, passes with the ar-
tery under the annular ligament of the tarsus, in the sheath of the extensor proprius pol-
licis, and divides into two branches :
The internal deep branch of the dorsum of the foot (v), which is the true continuation of
the nerve, passes horizontally forward, under the arteria dorsalis pedis, over the first in-
terosseous space, gives off a small twig to the muscles of that space, and divides into
two branches, which form the deep external dorsal collateral nerve of the great toe, and the
internal dorsal collateral nerve of the second toe. These branches communicate with the
superficial dorsal branches of the musculo-cutaneous nerve, and sometimes supply their
place.
The external and deep nerve of the dorsum of the foot runs outward between the tarsus
and the extensor brevis digitorum, in which it terminates ; it gives off in front, opposite
the interosseous spaces, a series of very delicate filaments, which enter the posterior
extremities of those spaces. The filaments for the fourth and fifth spaces often arise
by a common trunk. They are extremely delicate, and are closely applied to the tarsus.
The Internal Popliteal Sciatic^ or Tibial JVerve.
The internal popliteal sciatic, internal popliteal, or tibial nerve (h, fig. 293), is intended
for all the muscles of the back of the leg, and for the skin of the sole of the foot ; both
in direction and size it appears to be the continuation of the great sciatic nerve. It pass-
es vertically downward in the inter-condyloid fossa of the femur ; it is at first placed be-
tween the heads of the gastrocnemius, it then passes under that muscle and under the
arch formed by the soleus, descends, under the name of the posterior tibial nerve {k), be-
tween the soleus and the deep layer of muscles, inchnes a little inward, and, having
reached the termination of the fleshy belly of the soleus, gains the inner side of the ten-
do Achillis ; lower down, it passes behind the internal malleolus, against which it is flat-
tened and widened, and divides into the internal and external plantar nerves (a, b, and c,
/«■• 294).
In the popliteal space it is sub-aponeurotic, in the fleshy portion of the leg it is sep-
arated from the fascia by the double layer formed by the gastrocnemius and the soleus,
and it again becomes sub-aponeiirotic along the tendo Achillis. It is in relation, in
front, with the popliteal and posterior tibial vessels, which separate it, above, from the
knee-joint and popliteus muscle, and lower down, from the deep layer of muscles in the
leg.* Behind the internal malleolus, and under the groove upon the os calcis, it is en-
closed in a common fibrous sheath with the posterior tibial vessels, which are placed in
front of it ; this sheath is behind that for the tendons of the tibiahs posticus and flexor
communis digitorum.
* [The nerve is at first at a short distance to the outer sid« of the artery ; lower down it lies immediately
behind the vessel, and still lower croises to the imier side of the artery, and is separated from it by the vein.]
NEXJEOLOGY.
Its coilaieral 'IfrancMs are very numerous. I shall div'de them info Itliose ^ven'ra^dp-
posite the knee-joint, and those supplied along the leg.
The Collateral Branches of the Internal Popliteal Jferve, behind the Knee- Joint.
These are six in number, namcl}', two anterior, which are very small, one for the
plantaris longus, and one for the knee-joint ; two internal, namely, the tibial saphenous
nerve, and the nerve for the inner head of the gastrocnemius ; two external, namely, the
nerve for the outer head of the gastrocnemius, and the nerve for the soleus.
The Tibial Saphenous Nerve.
This is generally known as the external saphenous. It is much larger than the pero-
neal saphenous, which always anastomoses with it. I have already said that the mode
and situation of this anastomosis present many varieties. The tibial saphenous nerve
{communicant tibia, I, Jig. 293) arises in the popliteal space, passes vertically downward
between the two heads of the gastrocnemius, and then upon their posterior surface,
along their fibrous septum, between them ; it is here situated in a small fibrous canal
common to it and to a small artery and vein ; it receives, at a variable height in the leg,
a more or less considerable filament from the peroneal saphenous nerve (or communicans
fibulce, n) ; it then becomes sub-cutaneous, forming the external saphenous nerve (p),
runs along the outer side of the tendo Achillis, just as the posterior tibial runs along its
inner side ; it now accompanies the external saphenous vein, which is accompanied
above this point by the peroneal saphenous nerve ; it is reflected behind the external
malleolus, in the same manner as the tibial nerve is reflected upon the internal malleolus,
then runs forward and downward {y,fig. 291) upon the outer side of the os calcis, where
it gives off several very large external calcaneal nerves, and terminates difTerently in va-
rious subjects. In some it terminates by forming the dorsal collateral nerve of the fifth •
toe ; in others it is larger, and divides into two branches, of which the external forms the
external collateral nerve of the fifth toe, while the internal, which receives an anasto-
motic branch from the musculo-cutaneous nerve (z), passes horizontally forward, crosses
the extensor brevis digitorum, and the tendons of the long extensors, and divides into
two secondary branches, of which one constitutes the internal dorsal collateral nerve of
the little toe, and the other the external dorsal collateral nerve of the fourth toe. I may
point out the thickening, the gray colour, and the knotted, and, as it were, ganglionated
structure of the external collateral nerve of the little toe opposite to the articulations.
The cxtertMl calcaneal nerves, which may be regarded as forming the termination of
the tibial saphenous, are very remarkable ; they pass vertically along the outer side of
the OS calcis, expand into several filaments, which are reflected upon the ridge which
separates the external from the inferior surface of that bone, and are distributed to the
skin upon the heel.
During its course along the leg, the tibial saphenous gives off scarcely a single fila-
ment, but along the outer border of the foot it supplies a great number, which run down-
ward and forward, and terminate in the skin covering the external plantar region.
The size of the tibial saphenous nerve is inversely proportioned to that of the pero-
neal saphenous and musculo-cutaneous nerves. Thus, when the peroneal saphenous
nerve is large, it furnishes most of the external calcaneal branches ; and when the mus-
culo-cutaneous nerve is large, it supplies, besides the external calcaneal, the internal
dorsal collateral nerve of the little toe, and the external dorsal collateral nerve of the
fourth toe.
The Nerves for the two Heads of the Gastrocnemius and for the Soleus.
The nerve for the inner head of the gastrocnemius often arises by a common trunk
with the tibial saphenous ; again, the nerves for the outer head of the gastrocneniius
and for the soleus often arise by a common trunk : the nerves for the gastrocnemius en-
ter the anterior surface of the head of that muscle, and immediately ramify. The nerve
for the soleus is the largest, and enters the muscle at its upper arch ; all these nerves
ramify as soon as they enter the muscles which they supply.
The Articular Nerve and Nerve for the Plantaris Longus.
The posterior articular nerve of the knee runs forward to enter the posterior ligament
of the articulation : one of its filaments follows the direction of the internal articular ar-
tery, and is lost in the popliteus.*
* [From the dissections of Mr. EUjs, it appears that there is an articular nerve to the knee-joint with each
articular artery. The superior external articular nerve is the one described at p. 809 ; it most commonly
arises from the extertial popliteal. The inferior external articular also arises from the external popliteal, and
sometimes from the ioiatic nerve ; it is a long branch which descends towards the external condyle, passes be-
low it on the outer side of the joint, and perforates the capsule. The superior internal articular is very small,
and is not constant ; it arises from the internal popliteal nerve, and passes on the outer side, and then in front
of (t. e., deeper than) the popliteal vessels, and reaches with its artery the inner side of the joint. The infe-
rior internal articular is the largest of all : it arises from the internal jiopliteal above the joint, descends on the
outer side, and then in front of the popliteal vessels, is applied to the corresponding artery upon the popliteus
muscle, passes beneath the mternal lateral ligament, and enters the inner side of tlie joint. The posterior ar-
ticular, or azygos, is given off opposite the joint from the internal popliteal, or from the inferior internal ar-
ticular ; it perforates the postferior ligament. — {Ellis's Demonstrations of Anatomy, p. 675, 67(1.)]
THE INTERNAL PLANTAR NERVE.
813
Tlie nerve for the ■plantaris longus always arises separately from the posterior tibial
nerve, and immediately dips into the substance of the muscle.
Collateral Branches of the Internal Popliteal Jferve in the Leg.
There are three sets of collateral branches given off by the posterior tibial nerve in
the leg: namely, the nerve for the popliteus ; the nerves for the deep layer of muscles ;
the internal calcaneal nerve. Lastly, several very small filaments come off from the
nerve, run along the posterior tibial artery, and, after a course of variable length, perfo-
rate the aponeurosis and ramify in the skin.
The nerve for the popliteus arises opposite the knee-joint, runs forward on the outer
side of the popliteal vessels to gain the lower border of the muscle, around which it
# turns ; before entering the muscle, the nerve expands into several branches, all of
which pass horizontally forward opposite to the interosseous ligament, which they ap-
pear to perforate. But with a little care it is seen that almost all of these filaments are
lost in the muscle. I have, however, seen one of them perforate the interosseous liga-
ment together with the anterior tibial artery, and then, leaving that vessel, return
through the substance of the ligament, and terminate in the tibialis posticus ; several
filaments of the popliteal nerve are also evidently distributed to the peroneo-tibial artic-
ulation, and to the periosteum of the tibia and fibula.
The nerves for the deep layer of muscles of the leg consist of two sets. The nerve for the
tibialis posticus almost always arises by a coimnon trunk with the preceding, runs down-
ward and forward, is applied to the posterior surface of the muscle, to which it gives a
series of filaments from its anterior aspect ; the continuation of the nerve enters the
muscle about its middle, and maybe traced in it as far as its lower part. The nerves for
the flexor longus pollicis and for the flexor communis arise by a common trunk a little be-
low the preceding ; the nerve for the flexor longus pollicis, which is larger than those
for the flexor communis and tibialis posticus, accompanies the peroneal artery as far as
the lower part of the leg.
The Internal Calcaneal Nerve. — ^This is a large branch which comes off from the inner
side of the posterior tibial nerve, and which, in cases of premature bifurcation of that
nerve into the internal and external plantar, comes from the externeil plantar ; it passes
vertically downward, on the inner side of the os calcis, and divides into two diverging
branches, which are applied to the inner side of the bone, are reflected upon its lower
surface, and are distributed to the skin of the heel, one in front, and the other behind.
The Terminal Branches of the Internal Popliteal Jferve.
The Internal Plantar Nerve.
The internal plantar nerve, which is intended for the muscles and skin of the sole ol
the foot, is larger than the external plantar ; at its origin it is situated behind the inter-
nal malleolus, in front of the posterior tibial vessels, which cross it at an acute angle,
and occupies a groove which is common to it and to those vessels, and which is quite
distinct from and lies behind the groove for the tendons. It is reflected beneath the in-
ternal malleolus, becomes horizontal, reaches the calcaneal groove, perforates the pos-
terior extremity of the flexor brevis digitorum, and during this passage through the
groove is protected by a fibrous canal, which is subjacent to the grooves for the tendons.
At its exit from this fibrous canal, the internal plantar nerve is situated upon the
boundary, between the internal and middle plantar regions, between
the flexor brevis pollicis on the inside, and the flexor brevis digi-
torum on the outside ; having given off a considerable branch (a,
fig. 294), which becomes the internal plantar collateral nerve of the
great toe, it perforates the aponeurosis of the flexor brevis digitorum
to enter the same sheath as that muscle, and runs (J) along its in-
ner border. Having reached the posterior extremity of the meta-
tarsal bones, it divides into three branches, which form the collateral
nerves of the toes. Sometimes there is a fourth branch (d), which
passes outward, to anastomose with the external plantar nerve.
The collateral branches are very numerous. Some of them are
cutaneous, and perforate the plantar fascia to ramify in the skin.
The most remarkable are, a small calcaneal cutaneous nerve, which
crosses the posterior tibial vessels, to supply the skin upon the in-
ner side of the os calcis ; and s. plantar cutaneous nerve, which emerges
between the flexor brevis pollicis and the flexor brevis digitorum,
and divides into two small cutaneous branches, one of which pro-
ceeds forward, while the other runs backward, like a recurrent
nerve. There are cilso some muscular collateral branches, namely,
far the flexor brevis pollicis, the abductor pollicis, and the flexor brevis
digitorum. Lastly, the internal plantar collateral nerve of the great
toe {a), which is so large that it might be regarded as a terminal
branch of the internal plantar nerve ; it comes off from the last-
Fig. 294.
I
814 NEUROLOGY.
named nerve, at its exit from the covered canal formed for it by the flexor brevis poUicis,
passes forward along the outer side of the tendon of the flexor longus poUicis, below, i. e.,
superficial to the inner portion of the adductor poUicis (oblique adducteur, Crnveilhier),
and gains the inner and under surface of the metatarso-phalangal articulation of the
great toe ; in this place it is situated in the furrow between the internal and external
sesamoid bones of that articulation ; it runs forward below the inner border of the former,
and then of the second phalanx of the great toe, and, having arrived below that bone, it
divides, like the collateral nerves of the fingers, into two branches, the one dorsal or un-
gual, and the other plantar.
The terminal branches of the internal plantar nerve are three in number, and are distin-
guished as the first, second, and third, counting from within outward. i
The first terminal branch, which is the largest, runs along the outer side of the tendon
of the flexor longus poUicis, gives filaments to that muscle, passes between the meta-
tarso-phalangal articulations of the first and second toes, under an arch which is com-
mon to it and the corresponding vessels, and divides into two secondary branches, which
form, the external collateral nerve of the great toe, and the internal collateral nerve of the
second toe. Not unfrequently this branch gives an anastomotic filament to the internal
coUateral nerve of the great toe, which passes beneath the metatarso-phalangal articu-
lation of that toe.
The first terminal branch of the internal plantar nerve gives off the filament for the
first lumbricalis ; it then supplies several articular twigs to the metatarso-phalangal artic-
ulation of the great toe, and a very numerous series of cutaneous filaments.
The second terminal branch, much smaller than the preceding, passes somewhat out-
ward, crossing below, i. e., superficial to the flexor tendon of the second toe, and then
forward, and bifurcates opposite the metatarso-phalangal articulations, to constitute the
external plantar collateral nerve of the second toe, and the internal plantar collateral nerve
of the third.
During its course, this branch supplies filaments to the second lumbricalis, to the meta-
tarso-phalangal articulation of the second toe, and also to the integuments.
The third terminal branch passes very obliquely outward, crosses below the flexor
tendon of the third toe, and bifurcates to form the external collateral nerve of the third and
the internal collateral nerve of the fourth toe.
This branch supplies the metatarso-phalangal articulations of the third and fourth toes,
and the corresponding integuments.
Summary. — The internal plantar nerve, therefore, supplies branches to the skin on the
inner part of the sole of the foot, also the plantar collateral nerves of the first, second,
and third toes, and the internal collateral nerve of the fourth toe, aU of which are cu-
taneous branches.
It gives muscular branches to the flexor brevis poUicis, the abductor poUicis, the flexor
brevis digitorum, and to the two internal lumbricales.
Lastly, it gives off a great number oi articular filaments to the tarsal, tarso-metatarsal,
metatarso-phalangal, and phalangal articulations.
The External Plantar Nerve.
The external plantar nerve (c, fig. 294), which is smaller than the internal, is placed
with it in the groove of the os calcis, and perforates the flexor brevis, under an arch dis-
tinct from that for the internal plantar, and which is common to it and the external
plantar vessels ; it then runs downward and outward, between the flexor brevis and flexor
accessorius, is reflected forward, and divides into two branches, a superficial and a deep.
Collateral Branches. — During its course, the external plantar nerve gives off, immedi-
ately after its origin, one large branch, which runs horizontally outward, in front of the
tuberosities of the os calcis, passes under the flexor accessorius, and is reflected for-
ward to enter the abductor minimi digiti. At the point of its reflection, it gives off a
transverse branch, which is lost in the posterior attachment of the muscle. The exter-
nal plantar also supplies the nerve or nerves for the flexor accessorius.
Terminal Branches. — The superficial terminal branch (c, fig. 294), which is the continu-
ation of the trunk of the nerve, divides into two others, one external, the other internal.
The external branch passes very obliquely outward, below the flexor brevis digiti min-
imi, crosses the tendon of the abductor brevis obliquely, then runs along the outer side
of the fifth metatarso-phalangal articulation, and forms the external collateral nerve of the
little toe. It supplies a great number of cutaneous nerves, also the nerves for the_^ea;or
brevis digiti minimi, those for the interosseous muscles of the fourth space, and, lastly,
some articular filaments.
The internal branch passes forward, below the flexor tendon, foUowing the original di-
rection of the superficial branch of the external plantar, and, after a rather long course,
bifurcates to form the internal collateral nerve of the little toe, and the external collateral
nerve of the fourth toe ; hke the external branch, it also gives off some cutaneous and ar-
ticular nerves.
The deep terminal branch of the external plantar passes above, i. e., deeper than the
THE EXTERlPrAt PLA>rTAR NERVE. 81§
flexor accessorius, changes its direction, so as to describfe an arch, having its concavity
turned inward and backward, and the convexity outward and forward, enters, together
with the external plantar artery, above which it is situated, between the adductor polli
cis and the interossei, and is lost in the former muscle.
Before reaching the adductor pollicis it gives off some articular filaments to the meta
tarsal and tarso-metatarsal articulations, and also a filament for the fourth lumbricalis.
Beyond the adductor pollicis the nerve gives off the ^amcw^ /or the third lumbricalis ; this
filament, which is remarkable for the length of its course, passes horizontally forward,
opposite to the third interosseous space, and passes through the fibres of the transversus
pedis, to reach its destination ; it then gives off the filaments for the transversus, and
those for the interosseous muscles of the third, second, and first spaces.
Summary of the External Plantar Nerve. — The external plantar nerve, therefore, sup
plies cutaneous filaments to the outer side of the sole of the foot, to the fifth toe, of which
it forms both collateral nerves, and to the fourth toe, of which it forms the external col-
lateral nerve. It also gives off muscular nerves to the flexor accessorius, the flexor bre-
vis, and abductor digiti minimi, to the adductor pollicis, and transversus pedis, to all the
interossei, and to the two external lumbricales. Lastly, it furnishes some articular
filaments.
Summary of the Nerves of the Lower Extremity. — The lower extremity is supplied with
nerves from the lumbar and sacral plexuses.
The Lumbar Plexus. — The lumbar plexus gives almost all its branches to the lower
extremity, viz., the external and internal inguinal nerves, the obturator nerve, and the
crural nerve ; the lumbo-sacral cord is also distributed to the lower extremity through
the medium of the sacral plexus.
The external and internal inguinal nerves are the principal cutaneous nerves of the
anterior and external regions of the thigh ; the obturator nerve is a muscular nerve in-
tended for the obturator externus, the three adductors, and the gracilis.*
The crural nerve is a musculo-cutaneous nerve which supplies the following parts :
its cutaneous portion is distributed to the skin upon the anterior region of the thigh,
upon the internal region of the leg, and internal dorsal region of the foot ; its muscular
portion supplies all the muscles of the anterior region of the thigh ;t it also gives several
articular nerves to the hip and knee joints.
The Sacral Plexus. — The sacral plexus is entirely distributed to the lower extremity,
excepting the internal pudic nerve and certain rectal and vesico-prostatic branches in
the male, and rectal, vaginal, and uterine branches in the female.
The obturator internus, the pyriformis, the gemelli, and the quadratus femoris, are
each provided with a special nerve from the sacral plexus ; the glutaeus medius and min-
imus, and the tensor vaginae femoris, are especially supplied by the superior gluteal
nerve, and the glutaeus maximus by the inferior gluteal or lesser sciatic nerve. The
last-named nerve also furnishes the cutaneous nerves of the posterior region of the thigh.
The great sciatic is the nerve of the posterior region of the thigh, and of the entire
leg and foot. It supplies all the muscles of the posterior region of the thigh ; thus, its
external popliteal or peroneal division supplies the muscles of the external region of the
leg by its musculo-cutaneous branch, and the muscles of the anterior region by its in-
terosseous branch ; it also supplies the external region of the leg, and the dorsal region
of the foot.
Its internal popliteal or tibial division supplies all the muscles of the posterior region
of the l6g, the skin upon the internal and external calcaneal regions, and that upon the
external dorsal region of the foot.
Of its terminal branches, the internal plantar nerve is distributed to the muscles of the
internal plantar region of the foot, to the flexor .brevis digitorum, to the two internal
lumbricales, and to the skin of the internal plantar region ; lastly, it gives off the col-
lateral branches of the toes, excepting the two for the fifth toe, and the external collat-
eral branch of the fourth.
The external plantar nerve is distributed to the muscles of the external plantar region,
to the flexor accessorius, to all the interossei, to the two external lumbricales, to the
adductor pollicis and transversus pedis, and to the skin of the external plantar region :
it also gives the internal and external collateral nerves of the fifth toe, and the external
collateral nerve of the fourth.
Comparison of the Nerves of the Upper and Lower Extremities.
The lumbo-sacral plexus, which supplies the whole of the lower extremity, precisely
corresponds to the cervico-brachial, which supplies the- upper extremity. The lumbar
corresponds to the cervical, and the sacral to the brachial plexus. The connexion, or
sort of fusion of the cervical with the brachial plexus, and of the lumbar with the sacral
plexus, explains why it is found, on comparing the nerves of the upper and lower extrem-
* [The obturator also supplies part of the pectineus, and sometimes gives cutaneous branches to the thigh
,»nd leg, and an articular filament to the knee (see note II, p. 800).]
fAnd also a few filaments to the iliaciu, psoas, and pectineus.]
816 NEUROLOGY.
ity, that several of the nerves arising from the brachial plexus are represented by nerves
from the sacral plexus, and that several of those from the cervical plexus have their
representatives in nerves derived from the lumbar plexus. It will be seen, moreover,
that this analogy ought not to be carried too far, and that it is necessary, in making the
comparison, to exclude all nerves which belong to peculiar organs in both regions.
Thus, the phrenic, occipital, and auricular nerves, branches of the cervical plexus, have
no representatives in the lower extremity, nor is there any nerve in the upper extremity
corresponding to the internal pudic.
On the other hand, there is no objection to admitting that the external and internal
inguinal nerves in the lower extremity are represented by the clavicular nerves in the
upper extremity.
The crural nerve, a branch of the lumbar plexus, has no corresponding branch in those
of the cervical plexus, but its muscular branches are represented by the brachial portion
of the musculo-spiral nerve, and its cutaneous branches by the internal brachial cutane-
ous. The crural nerve, in fact, supplies the muscles which extend the leg upon the
thigh, in the same way that the musculo-spiral nerve supplies the muscles which ex-
tend the forearm upon the arm ; the internal saphenous nerve supplies the skin of the
leg, just as the internal brachial cutaneous is distributed to the skin of the forearm.
The obturator nerve, which supplies the adductors of the thigh, is represented by the
thoracic nerves and the nerve for the latissimus dorsi, which supply the pectoralis ma»
jor and latissimus dorsi, the adductor muscles of the arm.
The gluteal nerves are analogous to the supra-scapular and circumflex nerves. The
superior gluteal, which is distributed to the glutaeus medius and minimus, corresponds
to the supra-scapular, which belongs to the supra- and infra-spinatus ; and the inferior
gluteal or lesser sciatic nerve, which supplies the glutaeus raaximus and the skin of the
thigh, corresponds to the circumflex nerve, which is distributed to the deltoid, and the
skin of the arm.
The trunk of the great sciatic nerve represents by itself the musculo-cutaneous, the
ulnar, and the median nerves, and the musculo-spiral in the forearm.
The muscles of the anterior region of the arm, that is to say, the muscles that flex the
forearm upon the arm, receive their branches from the musculo-cutaneous nerve, just as
the muscles of the posterior region of the thigh, or the flexors of the leg upon the thigh,,
receive theirs from the great sciatic.
The external popliteal nerve represents the musculo-spiral in the forearm : the former,
supplies the muscles of the anterior and external regions of the leg, while the latter is
distributed to the muscles of the posterior and external regions of the forearm ; the for-
mer gives off the dorsal cutaneous nerves of the foot, and the latter furnishes the dorsal
cutaneous nerves of the hand.
The internal popliteal nerve represents the median and ulnar nerves together. The
muscles of the posterior region of the leg are supplied by the internal popliteal, as the
muscles of the anterior region of the forearm are supplied by the median and the ulnar.
The internal popliteal nerve completes the series of dorsal cutaneous nerves of the>
foot, just as the ulnar nerve completes the dorsal nerves of the hand.
Lastly, the internal plantar nerve gives off all the plantar collateral nerves of the toes,;
excepting those for the little toe, and the external plantar collateral of the fourth toe ;
it therefore represents the palmar portion of the median nerve ; and so the external plan-
tar represents the palmar portion of the ulnar nerve, and completes the series of plantar
collateral nerves. .;
THE CRANIAL NERVES.
Definition and Classifi/:ation. — The Central Extremities of the Cranial Nerves — viz., of.
the Olfactory — of the Optic — of the Common Motor Oculi — of the Pathetic — of the Tn-^
geminal — of the External Motor Oculi — of the Portio Dura and Portio Mollis of the Sev-
enth— of the Glosso-pharyngeal, Pneumo-gastric, and Spinal Accessory Divisions of the
Eighth — and of the Ninth Nerves.
The cranial nerves are those which pass through the foramina in the base of the cra-
nium, not those which arise from the brain, as the rather generally adopted terms cere-
bral nerves and encephalic nerves would seem to indicate.
We shall follow Willis and the majority of anatomists in admitting nine pairs of cra-
nial nerves, which are almost indifferently named, either numerically, from the order of
their origin, counting from before backward, or they are named from their distribution
and uses. The following exhibits their nomenclature upon both principles :
First pair, or olfactory nerves.
Second pair, or optic nerves.
Third pair, or common motor nerves of the eyes.
Fourth pair, or pathetic nerves, nervi trochleares.
Fifth pair, or trifacial nerves, nervi trigemini
CENTRAL EXTREMITY OP THE OLFACTORY NERVE. 817
Sixth pair, or external motor nerves of the eyes, nervi abducentes.
c. »u • J -J J • * ( portio mollis, or auditory nerve,
Seventh pair, divided mto { ^^-^ ^^^^^ ^^ f^^i^, ^^^^
I pneumogastric nerve, or par vagum.
Eighth pair, divided into < glosso-pharyngeal nerve,
( spinal accessory nerve of Willis.
Ninth pair, or hypoglossal nerve.
Scemmering has introduced the following modification of this nomenclature. He has
divided the seventh pair into two, viz., the facial nerves, which form his seventh pair,
and the auditory nerves, which he calls the eighth ; and then he has divided the eighth
pair into three others, namely, a ninth pair formed by the glosso-pharyngeal nerves, a
tenth formed by the pneumogastric nerves, an eleventh by the spinal accessory nerves ;
the hypoglossal nerves, therefore, constitute his twelfth pair.
This modification is founded on the separation of nerves so completely distinct as the
fiicial and the auditory, which have only been described together because they enter the
same canal in the base of the cranium, namely, the internal auditory meatus.
Still, this modification is a useless one, and it has the greater inconvenience of render-
ing the language employed obscure, from giving a double acceptation to the same terms.
It would be more philosophical to name and describe the cranial nerves from behind
forward, so that the hypoglossal nerves would constitute the first pair, and the olfactory
the last.
The indisputable analogy which exists between the posterior cranial and the spinal
nerves, and, moreover, the example of J. F. Meckel, would fully warrant this innovation
Nevertheless, I think it right to retain the old usage, and to proceed from before back-
ward, in the enumeration as well as in the description of the nerves.
As the origins or central extremities of all the cranial nerves and their course within
the cranium can be studied upon the same brain, I have thought it right to describe, in
one article, all these origins or central extremities, which will mutually illustrate each
other by their differences and their anadogies ; the experience of the dissecting-room
proves, moreover, that, from want of a sufficient number of brains to study the origin of
each nerve in particular, this part of anatomy is generally neglected.
The Central Extremities of the Cranial Nerves.
Dissection. — Two preparations are required, namely, a brain removed from the crani-
um, together with the origins of the nerves perfectly preserved ; and the base of a crani-
um, together with those parts of the brain which are near the origin of the nerves. The
first will serve for the examination of the central extremities of the nerves ; and the sec-
ond for tracing their course within the cranium.
While the origin of all the spinal nerves is uniform and regular, that of the cranial
nerves appears to be subject to no rule ; so that the cranial nerves diflfer as much from
each other in regard to their origin as they differ collectively from the spinal nerves in
the same particular. We shall see presently, however, that the origins of all but the
special nerves of the head may, to a certain extent, be referred to the same law of double
roots (one of which is ganglionic) which presides over the origin of the spinal nerves.
The Central Extremity of the Olfactory JVerve.
The olfactory nerves, or the first pair of cranial nerves (nerfs ethmoidaux, Chauss., 1,
fig. 276) are two bands, composed of white and gray substance, which arise from the
hindermost convolution of the anterior lobe of the brain, run forward in the anfractuosity
already described as the anfractuosity of the olfactory nerves, and expand in the ethmoidal
groove into a sort of ganglion or bulb, from which filaments are given off to be distribu-
ted to the pituitary membrane.
In regard to their central extremity and their course within the cavity of the cranium,
the olfactory nerves are singular, and their peculiarities justify the uncertainty which
has for a long time prevailed, and still prevails, concerning their true character. The
old anatomists did not regard them as nerves, but as prolongations of the brain, named
by them caruncula: or processus maxillares, and believed to be intended to drain off the
mucosity of that organ : it was Massa, according to Sprengel, and Zerbi, according to
Haller, who first connected them with the other cranial nerves as the first pair. Com-
parative anatomy, which probably suggested to the older anatomists the opinion which,
they held concerning these nerves, has now caused some doubts as to the propriety of
considering them as nerves, and has given rise to the opinion that they are the repre-
sentatives of the olfactory lobes of the lower animals.* Without entering here into dis?
cussions which belong to philosophical anatomy, let us examine the most remarkable-
circumstances connected with the origin and cranial course of this nerve.
Apparent Origin. — The olfactory nerves arise from the cerebrum, and this is a char-
* When speaking of the comparative anatomy of the brain, it was mentioned that in a great number of anK
mals there existed, in front of the cerebral lobes or hemispheres, a pair of lobes (olfactory lobes), which were-
^.ontinuous with the nerves distributed to the pituitary membrane, and the development of which oorresponde<li
to the size of those nerves, and to the relative state of perfection of the sense of smell.
5L
i^m
NEUROLOGY.
acter which belongs exclusively to them ; they are the only cerebral nerves, properly so
called.
They arise from the hindermost convolution of the anterior lobe, in front of the ante-
rior locus perforatus {h,fig. 276), which is situated behind that convolution. This origin
consists of a mammilla or pyramidal enlargement, gray pyramid, which is regarded as the
gray root of the nerve. This grayish enlargement, which can be very well seen by re-
flecting the nerve backward, is prolonged as a linear tract of gray substance upon the
upper surface of the nerve.
Besides this gray enlargement or origin, which was so well described by Scarpa, there
are two or three white roots, or, rather, certain white striae, very accurately represent-
ed by Vicq d'Azyr ; these are the external- or long root, which is concealed in the fissure
of Sylvius, and appears to me to arise from the posterior lobe [middle lobe] of the cere-
brum, or, more exactly, from the posterior lip of the fissure of Sylvius ; and the internal
or short root, which arises from the innermost convolution of the anterior lobe and joins
the long root at an acute angle ; between these roots we often see one, two, or even
three striae, which come from the back part of the anterior lobe. It would be both use-
less and tedious to describe all the varieties of this origin.
Real Origin. — Anatomists have not confined themselves to the investigation of the
apparent origin of the olfactory nerves, but have also endeavoured to ascertain their
deep or real origin. Willis described them as arising from the medulla oblongata, Rid-
ley from the corpus callosum, Vieussens, Winslow, and Monro from the corpora striata.*
If, after the example of Scarpa, a transverse perpendicular section of the brain be
made opposite the junction of the gray and white roots of the olfactory nerves, or if a
stream of water be directed upon the pyramidal mammilla above described, or, lastly, if
Herbert Mayo's method be adopted, and the origin of this nerve be examined in a brain
hardened in alcohol, it will be seen that, besides the white superficial striae, there are a
great number of deep and diverging white roots, which appear to me to come from the
anterior commissure, and not from the corpus striatum.!
It would follow, therefore, that the olfactory nerves arise by a commissure like the
optic nerves.
Cranial Course. — Having arisen in this manner by a sort of bulb or gray enlargement
{enlargement or bulb of origin), the olfactory nerve immediately tapers, and is received
into the antero-posterior sulcus intended for it, which conducts it as far as the ethmoidal
groove or fossa {I, fig. 296), where it forms an enlargement or bulb, named the ethmoidal
bulb, which is analogous in many respects to its bulb of origin.
When seen from below, the olfactory nerve has the appearance of a soft, smooth band,
grooved longitudinally along the middle. t
But, on reflecting the nerve backward, it is found to be prismatic and triangular, that
its two lateral surfaces are concave and correspond to the convolutions which bound the
antero-posterior sulcus for the nerve, and that its upper ridge is formed by a Unear tract
of gray matter which connects the gray substance of its bulb of origin with that of the
ethmoidal bulb.
The arachnoid has a peculiar arrangement in relation to this nerve : instead of im-
mediately forming a sheath for it, the arachnoid passes below it, and maintains it in
contact with its protecting sulcus ; while the pia mater passes above it, and lines the
sulcus. The nerve is not entirely separated from the brain until about a few lines from
the ethmoidal bulb.
In the human subject the olfactory nerve is not hollow in its centre, as in the mam-
malia ; when hardened by alcohol, it may be decomposed into white parallel fibres, ex-
actly similar to the fibres of the white substance of the brain.
The Ethmoidal Bulb or Enlargements. — The olfactory nerves, converging towards each
other, reach the ethmoidal fossae, where each immediately expands into an olive-shaped,
ash-coloured, and extremely soft bulb (the ethmoidal bulb, I, fig- 276), to which Mala-
carne first applied the term ganglion, and which is formed in the following manner :
The white filaments of which the olfactory band or prism is composed spread out like a
palm branch as they are about to enter the bulb, and dip into the gray or ash-coloured
substance, which occupies the intervals between them : this substance is precisely anal-
ogous to the gray matter of the brain, but is less consistent ; it also resembles the sub-
stance of the nervous ganglia, so that Scarpa does not hesitate to regard the ethmoid
bulb as a ganglion. From this enlargement are given off" the olfactory nerves properly
so called, which seem as if they were pressed through the foramina of the cribriform
* Chaussier, ■who adopted the latter opinion, called the corpora striata the olfactory lobes, in contradistinc-
tion to the optic thalami, which he terms the optic lobes. But comjiarative anatomy shows that there is nc
relation in point of development between the corpora striata and the olfactory nerves.
t Scarpa says th«t the deep roots come from a white cord placed in front and below the corpora striata.
Herbert Mayo, in his beautiful plates, has represented these roots as coming from the corpora striata.
% Willis ami Santorini have noticed this groove. Scarpa has observed three grooves, which he regards as
con-esponding to as many lines of gray substance. M. Hippolyte Cloquet {Anat. Descript., t. ii., p. 88) goes
still farther than Scarpa, and describes seven longitudinal strise, three of which are gray, and four white.
Scarpa has very justly remarked, that the proportion of ash-coloured or gray substance is much more consid-
"^ble in the ftetus, that it diminishes in the adult, and that it scarcely, if at all, exists in the old smbject
CENTRAL EXTREMITY OP THE OPTIC NERVE. 819
plate of the ethmoid bone. It is said that the gray matter sends prolongations through
these foramina, bul this has not been demonstrated.
The Central Extremity of the Optic J^erve.
The optic nerves, or second pair (2, Jig. 276), present certain peculiarities in their tex-
ture, and in their cranial course, which distinguish them from all other nerves.
They have this peculiar character, that they arise by a commissure (the optic com-
missure), or, rather, the two optic nerves unite before they pass to their respective des-
tinations.
On turning the cerebellum forward, it is seen that the optic tracts (2, fig. 295) are
continuous with the corpora geniculata externa (i), and, consequently, take their origin
from the optic thalami (a), of which these bodies are a dependance. In some cases,
the white riband-like band, or optic tract, which constitutes the origin of the optic nerve,
is also continuous with the corpus geniculatum internum (c). In the human subject, the
optic nerves never arise, either entirely or in part, from the anterior tubercula quadri-
gemina (nates) ; it is only by induction that this mode of origin has been admitted in the
human subject.*
The optic tract (2, fig. 272), having arisen from the corpus geniculatum externum
(above i), with which it is continuous, without any other line of demarcation excepting
the difference of colour, assumes the appearance of a thin and broad riband, which turns
round the cerebral peduncle (v), parallel to and on the inner side of the great transverse
fissure of the brain. During this course, it lies in contact with the peduncle of the cere-
brum, from which it may be separated without laceration, excepting at its outer border,
by which it adheres so intimately that the peduncle has been supposed to supply it with
several roots.
As soon as it gets beyond the peduncle, the optic tract (», fig. 276) is condensed into
a flat cord, which leaves the peduncle, passes inward and forward, and unites with its
fellow of the opposite side to form the chiasma (square space of Zinn, t), or, rather, to
form, with the optic tract of the opposite side, a commissure which is convex in front
and concave behind.
On leaving the commissure, it completely changes its direction (2), passing forward
and outward, to enter almost immediately into the optic foramen (2, fig. 296).
During its course in front of the peduncle of the cerebrum, it is in relation with the
following parts : behind, with the tuber cinereum (v), from the interior of which some
white fibres arise, and pass to the chiasma ; in front, with the membrane which forms
the anterior portion of the floor of the third ventricle, and which is prolonged upon the
upper surface of the chiasma. ^
An important question here presents itself, viz.. Is there a cOTlplete or partial decus-
sation of the optic nerves in the commissure 1 Do these two nerves irterlace without
decussating, or, rather, is there an intimate mixture of their fibres 1 Are the nerves
placed in simple juxtaposition and united by a transverse band 1 Lastly, does the chi-
asma constitute a commissure in wliich the two optic tracts terminate, or, rather, which
serves as a point of origin for the optic nerves T All these opinions have found sup-
porters, and facts have been quoted in favour of each ; a circumstance which proves,
not that there are anatomical varieties in the structure of the chiasma, but that its struc-
ture is of a complex nature.
Comparative anatomy proves that the optic nerves decussate in the commissure : in
fishes, the two nerves cross without uniting : it is also proved by pathological facts ; in
a great number of cases of atrophy of one eye, atrophy of the nerve extended, beyond
the commissure, to the opposite optic tract.
On the other hand, in an equally large number of cases of atrophy of one eye, the dis-
ease affected the optic tract of the same side, so that this would seem to show that there
was no decussation.
Lastly, in all cases of atrophy ctf one eye, the disease affects one of the optic nerves
in particular, but the other has always appeared to me to be evidently reduced in size.
On attempting to determine the point, either by the dissection of optic nerves harden-
ed in alcohol, or unravelled by means of a stream of water, it is seen that these nerves
present the following threefold arrangement at the commissure : The external fibres of
* The origin of the optic nerves varies in the different classes of animals. In birds, in which these nerves
are at their maximum development, they arise entirely from the tubercula quadrigeraina, which are the optic
lobes in these animals, and are transposed from the side to the base of the brain. The optic thalami do not
assist in forming these nerves. In rodentia, a small number of fibres from the optic thalami join the mass of
those which are derived from the nates. In canUTora, the number of filaments from the tubercula quadri-
gemina and from the optic thalami are almost equal. Moreover, if it be remembered that the tubercula quad-
rigemina, the corpora geniculata externa ai^ i|lt0ma, and the optic thalami th^iulves, belong to the same
system of organs, and form a continuation of th^'te-enforcing fasciculi (faisceimtSl^mnis) of the medulla ob-
longata ; and if other facts confirmatory of the preceding also be taken into conside^n^n, namely, that a white
band proceeds on each side from the natis to the corpus geniculatum exter""- -"■'< tnother from the testis to
the corpus geniculatum internum, it wiU be easy to account for these vu n. which can all be re-
duced to the same type. It is of some importance in regard to this quf ' great number of ciases
of atrophy of the optic nerve, which I have had occasion to examine in t! - jeo'i tl"- coipus t'cnicu-
'itum was affected, and not the natig.
dl
820 NEUROLOGY.
the commissure do not decussate ; the internal fibres (and these are the most numerous;
do decussate ; and the posterior fibres are continued from one side to the other like a
commissure.
Structure. — The optic nerve has a peculiar structure. It does not commence by fila-
ments of origin or distinct cords, like the other nerves, but the optic tracts and the optic
commissure are composed of two medullary bands, the fibres of which are parallel and
in immediate contact with each other, precisely as in the olfactory nerves, and in the
cerebral substance ;* after leaving the commissure, the optic nerves are enveloped in a
neurilemmatic sheath, from the internal surface of which certain prolongations or septa
are given off, which divide the interior of the nerve into longitudinal canals, in which the
medullary substance is contained.
I'he optic nerve, therefore, does not consist, like other nerves, of a plexiform group
of nervous filaments or cords, but of a collection of canals dosely applied to each other,
so that it has the appearance of the pith of the rush ; hence, doubtless, the opinion of
Eustachius and some other authors who conceived that the optic nerve was traversed
by canals ; and hence, also, the error of Reil, who, having taken the structure of the op-
tic nerve as the type of that of all nerves, regarded each nervous cord as containing a
central canal, t
The Central Extremity of the Common Motor JVerve of the Eye.
The apparent origin of the motor nerves of the eyes (3, fig. 276), motores oculorum, com-
mon oculo-muscular nerve, or third pair, have a penicillate character ; these origins con-
sist of a linear series of very delicate filaments proceeding from the fasciculi found be
tween the peduncles of the cerebrum, in the depression between the pons Varolii and
the corpora albicantia. Some filaments converge from the cerebral peduncles them-
selves.t This origin extends about a line and a half, in a direction obliquely inward
and forward. The internal filaments of origin reach the middle line, so that Varolius
and Vieussens believed that the nerves of the right and left sides are continuous, and
xplained the simultaneous action of the two eyes by this anatomical arrangement.
Real Origin. — In a brain hardened by alcohol, or, still better, in the brain of a foetus,
Fig. 295. the filaments of origin of the nerve (3, fig. 295) can be easily
traced into the substance of the median fasciculi (d) found between
the peduncles of the cerebrum, and which have already been shown
to be prolongations of the fasciculi of re-enforcement {fai-sceaux
innomines) of the medulla oblongata. The filaments of the nerves
traverse these fasciculi in a diverging manner, and descend to
aJevel with the pons, beyond which I have not been able to trace
<ftm, on account of their slenderness and divergence. I have
never observed any of them running towards the corpora albican-
tia, and reaching the walls of the third ventricle or the anterior
commissure, as has been stated by some. Nor have I found that
they are re-enforced, as Gall believed, in the blackish substance
{locus niger) which separates the peduncles of the cerebrum, prop-
erly so called, from the prolongations of the re-enforcing fasciculi
of the medulla oblongata.
Cranial Course. — Having arisen in this manner, the fibres of the
motor oculi nerve converge into a flat bundle, which passes be-
tween the posterior cerebral and the superior cerebellar arteries,
upon which latter it is reflected : on emerging from the interval
between these two vessels it becomes rounded, and then passing
upward, outward, and forward, enters the reticular sub-arachnoid
cellular tissue at the base of the brain, and gains the side of the
sella turcica (3, fig. 296), where it enters a proper sheath formed for it by the dura mater.
The Central Extremity of the Pathetic Nerve.
The ncrvi pathetici (4, fig. 276), nerves of the superior oblique muscle of the eyes, nervi
trochleares, the internal and superior oculo-muscular nerves, or the fourth pair, as they are
variously called, are the smallest of the cranial nerves, and are as remarkable for being
* See note, p. 767.
t In most fishes, whose faculty of vision is exercised in a less transparent medium than air, the optic nerve
IS iformed by a membrane folded upon itself. In birds of prey, the membrane is sometimes folded like a fan,
sometimes like the leaves of a book. These folds are intended to increase the extent of surface, and to aug-
ment the power of vision. Malpighi first made this observation upon the optic nerve of some fishes. Des-
moulins, who has studied the point more carefully, has shown that it is in relation with the perfection of the
sense of sight. The same thing is also observed in the retina: thus, in the eagle, the retina presents two,
three, or four superimposed folds, so that each luminous ray acts upon sixteen surfaces instead of upon two.
t In fact, the exterml fflaments often arise from the inner border, and even from the lower surface of the
cerebral peduncle, at a certain distance from the inner border ; in this case, they do not arise from the pedun-
f.les, but merely pass throQgh them. The same is doubtless the case with the filaments of origin which Rid-
ley and Molinelli state that they have seen coming from the pons. I have never met with this origin from
llie pons, nor with that accessory nerve which Malacarne has described as proceeding from the upper part of
'lie jiedunclo of the cerebellum, turning round the border of the pons, and joining the motor oculi nerve.
CENTRAL EXTREMITY OP THE TRIGEMINAL NERVE. 821
exclusively distributed to the superior oblique muscle of the eyes, as for their origin and
for the length of their course within the cranium. The term patheticus is derived from
the opinion that the superior oblique muscle is especially concerned in the expression of
love and of compassion. According to Bell, this nerve is the respiratory nerve of the eye.
The apparent origin of this {i,fig. 280) nerve is below the tubercula quadrigemina, on
each side of the valve of Vieussens, sometimes by one, sometimes by two, and even by
three or four roots. Occasionally there are several roots on one side, and only a single
root on the other. The nerves of the two sides are often united by some white streaks,
which form a transverse commissure ; at other times they do not arise at the same level.
Real Origin. — It has been supposed that some fibres come from the testes, others from
the cerebellum, and that others commence much lower down than the apparent origin ;
all that can be seen is, that these nerves {i,fig. 295) arise from the vdve of Vieussens,
to which they adhere so slightly that the least force is sufficient to detach them.
Cranial Course. — Immediately after its origin, the pathetic nerve turns forward and
downward, around the isthmus of the encephalon, in front of the anterior border of the
cerebellum, and thus reaches the base of the cranium (4, fig. 276), accompanied by the
superior cerebellar artery, between the fifth and third cranial nerve, but much nearer to
the fifth ; it then passes directly forward upon the side of the sella turcica (4, fig. 296),
and perforates the dura mater, considerably below the third nerve. During its whole
course, it is situated between the arachnoid and the pia mater, in the reticular cellular tis-
sue found in this region.
Wrisberg says that the right pathetic nerve is larger than the left. Ruysch states
that he found this nerve double, which it is difficult to believe, unless he meant to say
that it bifurcated at its origin. Vesalius regarded this nerve as a root of the third cra-
nial nerve ; other anatomists have considered it as a dependance of the fifth.
The Central Extremity of the Trigeminal J^erve.
Apparent Origin. — The trigeminal or trifacial nerves (5, fig. 276), the middle sympathet-
ic, or the fifth pair, are the largest of the cranial nerves, excepting the optic : they arise
at the sides of the pons Varolii, at the point where the pons becomes continuous with
the corresponding peduncles of the cerebellum, and exactly where the middle fibres of
the pons cross in front of the inferior, to form that peduncle, so that the fasciculi of ori-
gin appear to converge from a narrow slit in the pons itself. This origin (^,fig. 295)
consists of two roots, the large and the small root, which have a small prominence be-
tween them. The large or ganglionic root is a thick, fasciculated mass, which is, as it
were, constricted at its point of emergence, but immediately expands into a thick, flat
bundle, in which we may count about 100 fibres. On tearing off this bundle, all the fibres
do not give way opposite the same place, and a sort of mammillary prominence is left,
which Bichat regarded as belonging to the pons, as intended for the nerve to arise from,
and as having the effect of multiplying the surfaces of origin, in consequence of its con-
vexity. •
The small root, which is non-ganglionic, is composed of small and very distinct bun-
dles, which arise from the pons, above and behind the great root, by several cords ; it
emerges from the pons through a fissure distinct from that for the great root, and gains
the upper border of that root.
It will hereafter be seen that the small root has no share in the formation of the gan-
gliform plexus known by the name of the semilunar or Gasserian ganglion, and that it
goes exclusively to assist in forming the inferior maxillary division of the fifth nerve.
Real Origin. — Until modem times, the origin of the fifth nerve had not been traced be-
yond the point of its emergence. Late authors have described its real origin with so
much detail that little remains to be desired. Gall, while examining the fifth nerve, first
in mammalia and then in the human subject, saw that in many the origin of the nerve is
concealed by certain transverse fibres of the pons which do not exist in the lower ani-
mals. Having traced the nerve by clearing off" the fibres of the pons, he thought he ob-
served that the great root divided into three principal fasciculi, which he conceived arose
in succession from the gray matter of the pons, and which he succeeded in tracing as far
as to the outer side of the olivary body.*
Rolando, by successive sections made through the pons towards the medulla oblongata,
has clearly shown that the great root of the fifth nerve consists of only one fasciculus,
which runs downward and backward, under the form of a thick cord (see fig. 295), in the
substance of the pons, or, rather, at the boundary between the pons and the middle ped-
uncle of the cerebellum, parallel to the fasciculi of the anterior pyramid, and that it pro-
gressively diminishes in size, until it disappears opposite to the inferior angle of the fourth
ventricle. The examination of this origin in a brain hardened by alcohol, or, still better,
in the foetal brain, confirms Rolando's observations, and proves that the great root of the
* In the human subject, the origin of the fifth nerve is extremely deep-seated ; it is not so deep in the car-
nivora, and still more superficial in ruminantia. In oviparous animals, which have neither a pons Varolii, nor
lateral lobes of the cerebellum, nor pyramids, nor olivary b xiii s, the origin of the fifth pair is seen without
any dissection.
«^
NEUROLOGY.
^g- 296. fifth nerve comes from the back part of the mednHa ob-
longata, from the interior of its fasciculi of re-enforce-
ment {faisceaux innominis).* As to the small root, it
cannot be traced beyond the surface of the pons.t
Cranial Course. — After emerging from the pons, the
fifth nerve passes upward, outward, and forward, under
the form of a flattened bundle, gains the upper border
of the petrous portion of the temporal bone {5, Jig. 296),
on which there is. a depression that is converted into a
canal for the nerve by a fold of the dura mater ; the
nerve is reflected upon this border, and proceeds as will
presently be described.
The Central Extremity of the External Motor
Jferve of the Eye.
The external motor nerves of the eye (6, fgs. 276, 295),
external oculo-muscular nerves, nervi abducentes, or the sixth pair, which are distributed
exclusively to the external rectus or abductor muscle of each eye, and which are so re-
markable for their communications with the sympathetic system, are smaller than all
the cranial nerves, excepting the pathetic.
Apparent Origin. — The statements of authors regarding the apparent Origin of this nerve
have been singularly various : some, with Morgagni, describe it as arising both from the
pons and the anterior pyramids ; others, with Vieussens, from the pons alone ; and others,
with Lieutaud, from the anterior pyramids only. Winslow states that it arises between
the pons Varolii and the olivary body, and Haller, that it proceeds from the furrow be-
tween the anterior p3rramid and the pons.
The fact is that this nerve, among some varieties of origin, presents two very distinct
roots (see Jig. 276) : one internal and smaller, which arises from the pons, either at or
near its lower border ; the other external and larger, which appears to emerge on the
outer side of the upper part of the anterior pyramid. These two roots are fasciculated :
not unfrequently some fibres are seen arising from the olivary body, or from the furrow
between the two p)Tamids.
Real Origin. — This is more easily seen in mammalia generally than in man. In the
former, Gall has traced it along the side of the pyramids. Mayo believes that the fibres
traverse the pons, and pass to the back part of the medulla oblongata. From the tenu-
ity and whiteness of the fibres of this nerve, I have not been able to trace their course
in the substance of the medulla.
Cranial Cmirse. — This nerve runs upward and a little outward, on the side of the basi
lar groove, and perforates the dura mater (6, Jig. 296) opposite to and above the apex of
the petrous portion of the temporal bone, to enter the cavernous sinus : the two roots of
the nerve often unite before perforating the dura mater, but they usually pass separately
through it and unite within the sinus.
The Central Extremity of the Seventh JVerve.
The central extremity of the facial nerve, or portio dura of the seventh nerve (7, Jig. 270,
276). The facial nerve (on the inner side of 7) arises in the deep depression between
the middle peduncle of the cerebellum and the pons in front of the auditory nerve (on the
outer side of 7) : it emerges from the front of the restiform body, under the form of a
fasciculated band, some fibres of which are at first situated at a distance from the gen-
eral mass, but soon join it ; it then turns round the lower borders of the peduncle of the
cerebellum, against which it is closely applied, and then becoming free, passes outward
and upward. It has no neurilemma up to the point where it becomes free.
The real origin of this nerve (7, Jig. 295) is much deeper ; it may be traced through
the restiform body into the fasciculus of re-enforcement, near the median furrow of the
calamus scriptorius.
The Central Extremity of the Auditory Nerve. — The auditory nerve, or portio mollis of the
seventh (on the outer side of 7, fig. 275), is riband- shaped, and non-fasciculated at its origin :
it arises (7',Jig. 295) in the same depression as the facial nerve, but behind that nerve, and
opposite to the restiform body : it presents two very distinct roots : an anterior, which
is arranged like the facial nerve ; and a posterior, which turns horizontally round the
back part of the restiform body, appears upon the posterior surface of the medulla ob-
longata (see ^o-. 271), and separates into fibres, which may be traced as far as the me-
* Vicq d'Azyr says that the roots of this nerve extend as far as the cerebellum, but this assertion has not
been verified. The same anatomist declares that he has often seen the fifth nerve of the right side larger than
that of the left.
t According to Dr. Alcock, there is a slight enlargement at the origin of the large root of the fifth nerve, in
the lower part of the floor of the fourth vRntricle ; he has also traced the small root to this enlargement, from
which he states that two cords descend, one to the anterior, the other to the posterior column of the cord.—
{Cyclop, of Anat. and Phys., art. Fifth Pair of Nf.rves.)
CENTRAL EXTREMITY OF THE EIGHTH NERVE. 823
dian furrow of the calamus scriptorius, and which represent some of the barbs of the
quill. It is very generally admitted that the auditory nerves have a tranverse commis-
sure, but this does not appear to me to be clearly demonstrated.
The portio dura and the portio mollis of the seventh nerve, which arise so near to each
other, follow the same cranial course : they arise at the same height from the medulla
oblongata, pass outward and upward in front of the pneumogastric or sub-peduncular
lobule of the cerebellum, and enter the internal auditory meatus {7, fig. 296). During
this course, the portio dura always lies in front of the portio mollis.
The auditory nerve is the softest of all the cranial nerves ; the difference between it
and the facial nerve, in this respect, has led, in a great measure, to the subdivision of
the nerves into the soft or sensory, and the hard or motor.
The Central Extremity of the Eighth Jferve.
Of the three nerves on each side which together constitute the eighth nerve (8, figs.
370, 276, 295), the glosso-pharyngeal is the highest, the pneumogastric is the next, and the
spinal accessory is the lowest.
The Central Extremity of the Glosso-pharyngeal and Pneumogastric Nerves. — ^The glosso-
pharyngeal and pneumogastric nerves have a common origin. They arise, like the spinal
nerves, by a hnear series of funiculi (see fig. 270), which come off, not from the furrows
between the olivary and restiform bodies, but from the restiform body itself, on a hne
with the auditory nerves. Soemmering states that he has seen some of these funiculi
arise from the anterior wall of the fourth ventricle.
Moreover, as in the spinal nerves, each funiculus of origin is formed by the union of
two or three converging filaments ; the funiculi of the glosso-pharyngeal nerve, which
are the highest, and which come off immediately below the auditory nerve, are not dis-
tinct at their origin from those of the pneumogastric ; nor, as will presently be stated,
are the funiculi of origin of the pneumogastric distinct from those of the spinal acces-
sory. The division into the three nerves cannot be made until after the funiculi are
finally grouped.
It has been stated, but without proof, that the fibres of the glosso-pharyngeal and
pneumogastric nerves might be traced through the restiform body as far as the back of
the medulla oblongata. The funiculi of origin of these nerves, which are enveloped by
the neurilemma at the point where they emerge from the medulla, are so small that,
when torn off, scarcely any trace of their points of attachment can be detected even by
the aid of a lens.
The Central Extremity of the Spinal Accessory Nerve of Willis. — The origin of the spiTial
accessory nerve (.s,fig. 295) is quite peculiar, and has obtained much notice from modem
anatomists.
It arises from the sides of the cervical region of the spinal cord, between the anterior
and posterior roots of the cervical nerves, and behind the ligamentum denticulatum.
Sir C. Bell, who classes it among the respiratory nerves, strongly insists upon its ori-
gin from that column of the cord which is situated between the anterior and posterior
columns, in a line with the pneumogastric and facial nerves, which column (the respira-
tory tract) he assumes to give origin solely to the respiratory nerves. The funiculi of
origin of the spinal accessory vary much both in number and size, and are widely separ-
a.ted from each other : the lowest as well as the highest funiculi appear to me to be con-
tinuous with the posterior roots of the spinal nerves ; and, again, the -liighest are con-
tinuous above with those of the pneumogastric nerve, and appear to me to establish a
transition between the origin of that nerve and the posterior roots of the spinal nerves.
The lowest funiculus of the spinal accessory is generally situated not lower than the
fifth cervical nerve ; it has been seen to arise opposite the sixth, and even the seventh
cervical nerve ; the latter is the normal condition in the ox.
It is of importance to remark the connexion which exists between the spinal acces-
sory nerve and the first cervical or sub-occipital nen^e. Almost always one or two, and
frequently all of the posterior funiculi of the sub-occipital, join the spinal accessory. Not
unfrequently a small funiculus joins the spinal accessory from the second cervical nerve.
Opposite its connexion with the sub-occipital nerve, the spinal accessory sometimes pre-
sents a gangliform enlargement, which was well described by Huber (in ganglion vix
hordeaceum intumescit ncrvus accessorius). In some cases a filament proceeds from this
ganglion and joins the anterior roots of the sub-occipital nerve. Winslow believed that
the funicuh of origin of the spinal accessory communicated with the hypoglo.ssal : this is
an error. The greater number and even the whole of the funiculi of the sub-occipital
nerve have been seen to join the spinal accessory, in which case, filaments from the latter
nerve always supply the place of those which are usually furnished by the first cervical.*
The Cranial Course of the Glosso-pharyngeal and Pneumogastric Nerves. — They pass
horizontally outward, in contact with the lateral fibrous layer of the fourth ventricle,
forming two groups having a very small interval between them. The two, three, or
four small bundles which constitute the glosso-pharyngeal nerve pass through a special
* Lobstein, De Ntrvo Spinali. Vide Scriptor. Neurol., Minor de Ludwig., t. ii.
824 NEUROLOGY.
opening m the upper part of the foramen lacerum posterius (8, Jig. 296). The bundles
which form the pneumogastric nerve are collected together and pass through the same
foramen, but by a distinct opening from the preceding one.
The cranial, or, rather, the vertebral course of the spinal accessory nerve of Willis, is re-
markable. This nerve, which is very small below, where it is formed by one or two
funiculi, ascends vertically upon the side of the cervical region of the spinal cord, to
which it is closely applied below, just behind the ligamentum denticulatum, and from
which it is separated above, where it is immediately in front of the posterior roots of the
cervical nerves ; it goes on increasing in size as it receives additional funiculi, which are
blended with it ; having arrived a few lines below the posterior lacerated foramen, it
passes upward and outward to enter the same opening as the pneumogastric, being situ-
ated below that nerve, and emerging with it from the cranium.
The Central Extremity of the Hypoglossal Jferve.
The hypoglossal nerves {9, figs. 276, 295), or ninth pair, arise on each side, from the fur-
row between the olivary and pyramidal bodies, in the same manner as the spinal nerves,
i. e., by a linear series of funiculi placed one above the other.
The furrow from which the funiculi of the ninth nerve arise is continuous with the
line formed by the origins of the anterior roots of the spinal nerves ; no funiculus arises
from the line formed by the posterior roots.* The relation of the origin of the ninth
nerve with the vertebral artery in front, and the vascular ramifications which surround
the funiculi of this origin, require to be mentioned.
The real origin of the ninth nerve cannot be traced beyond its apparent origin. It is
certain that no fibres come from the pyramids ; it has appeared to me that the fibres en-
tered the substance of the olivary bodies, in which they could not be traced to any depth.
Cranial Course. — All the funiculi of origin of the hypoglossal nerve commence by two
or three filaments, which are immediately covered by the neurilemma ; they are then
grouped into two or three bundles, which pass horizontally outward to the anterior con-
dyloid foramen, through which (9, fig. 296) they almost always pass separately. Thus
the dura mater forms two and sometimes three distinct canals for the hypoglossal nerve.
DISTRIBUTION OF THE CRANIAL NERVES.
The First Pair or Olfactory Nerves. — The Second or Optic Nerves. — The Third or Common
Motor Nerves. — The Fourth or Pathetic Nerves. — The Fifth or Trigeminal Nerves — the
Ophthalmic Division of the Fifth, and its Lachrymal, Frontal, and Nasal Branches — the
Ophthalmic Ganglion — the Superior Maxillary Division of the Fifth, and its Orbital Branch
— the Spheno-palatine Ganglion, and its Palatine, Spheno-palatine, and Vidian Branches —
the Posterior and Anterior Dental, and the Terminal Branches of the Superior Maxillary
Nerve — the Inferior Maxillary Division of the Fifth — its Collateral Branches, viz., the
Deep Temporal, the Masseteric, Buccal, and Internal Pterygoid, and Auriculo-temporal —
its Terminal Branches, viz., the Lingual and Inferior Dental — the Otic Ganglion. — The
Sixth Pair or External Motor Nerves. — The Seventh Pair — the Portio Dura or the Facial
Nerve — its Collateral Branches — its Terminal Branches viz., the Temporo-facial and
Cervico-fascial — the Portio Mollis or Auditory Nerve. — The Eighth Pair — its First Por-
tion of the Glosso-pharyngeal Nerve — its Second Portion or the Pneumogastric Nerve, di-
vided into a Cranial, Cervical Thoracic, and Abdominal Part — its Third Portion, or the
Spinal Accessory Nerve. — The Ninth Pair or the Hypoglossal Nerves. — General View of
the Cranial Nerves.
The First Pair, or the Olfactory Nervks.
Dissection. — Harden the nerve in dilute nitric acid. Examine the pituitary membrane,
not from its free surface, but from the surface which adheres to the periosteum. The
nerve ramifies between the periosteum and the pituitary membrane.
Before the time of Scarpa, the olfactory pedicles or bands and the ethmoidal bulb were
the only parts well known ; the passage of the olfactory nerves through the foramina of
the cribriform plate, and their distribution in the pituitary membrane, were scarcely
noticed.
Passage of the Olfactoy Nerves through the Cribriform Plate. — I must here remind the
student that the cribriform plate of the ethmoid bone is perforated by foramina, or, rather,
by different sets of canals which ramify in its substance ; that some of these canals ter-
minate directly upon the roof or upper wall of the nasal fossae, and that the others are
divided into an internal set, which pass along the septum and end by becoming grooves,
and an external set, which descend on the superior and middle turbinated bones, and on
the rough quadrilateral surface in front of them.
The olfactory nerves arise from the ethmoidal bulb {I, figs. 296, 297) by a considera-
* tin the ox and dog Mayer discovered a small posterior root with a ganglion for this nerve ; and he states
that he once found a small posterior root on one side in the human subject.]
THE OPTIC NERVES. 825
Ftg 297. ^^^ number of white bundles, which immediately pass through the
" cribriform plate, and divide and ramify {i.,jig. 297) in the same
way as the bony canals themselves ; the dura mater forms a
sheath for each of the subdivisions of the nerve, and supports
their soft substance. All these nervous filaments are distributed
upon the septum (cZ) and upon all the external wall (a, fig. 299) of
each nasal fossa ; the anterior run forward, the middle vertically
downward, and the posterior backward. Some of them only in-
terlace as they leave the cribriform plate. They all expand into
very delicate pencils. They are situated between the periosteum
and the pituitary membrane, and none of them reach either the
inferior turbinated bone, or the maxillary, sphenoidal, or ethmoidal sinuses ; on the inner
wall of each fossa they do not pass lower than the middle of the septum ; and on the
outer wall they do not descend below the middle turbinated bone.*
With regard to the ultimate termination of the fibres of the olfactory nerve, there has
been a difference of opinion ; some believe that they terminate in papillae like those of
the skin ; and others imagine that they expand into a membrane, like the optic nerve in
the retina and the auditory nerve in the membranous labyrinth. I have never seen
them terminate otherwise than by pencils of extremely delicate filaments very closely
apphed to each other.
Function. — The olfactory nerves are the essential organs of smell. Their distribution
proves that the sense of smell resides essentially and exclusively in the roof of the nasal
fossae and the immediately adjacent parts.
The Second Pair, or the Optic Nerves.
The optic nerves have already been described from their origin to the optic commis-
sure, and from the commissure to the optic foramina (2, Jig. 296) ; they pass through
these foramina together with the ophthalmic arteries which are below them ; they are
also accompanied by a sheath formed by the dura mater and by a prolongation of the
arachnoid, the latter being immediately reflected from them.
The optic nerve, which is flattened up to this point, becomes rounded on emerging
from the optic foramen, and is received in a fibrous ring formed by the origins of the
muscles of the eye ; it here, also, changes its direction shghtly, for, instead of passing
obliquely forward and outward, it runs almost directly forward to the globe of the eye,
which it enters behind, and somewhat below, and to the inner side (see o, Jigs. 237, 238,
240). There is a very evident circular constriction at the point where the optic nerve
enters the eye.t
During its course in the orbit, the optic nerve is surrounded by a great quantity of
adipose tissue, which separates it from the muscles and nerves. The ophthalmic gan-
glion and the ciliary nerves and vessels are in immediate contact with it. It is accom-
panied, as far as the sclerotic, by a fibrous sheath given off from the dura mater, so that
this nerve differs from all others, in being provided with two protecting sheaths, name-
ly, a proper neurilemma, and a sheath formed by the dura mater. A section of the optic
nerve also presents throughout its course that peculiar appearance resembling the pith
of the rush, which we have already described as commencing at the commissure (see
Central Extremity of the Optic Nerve).
As it enters the ball of the eye the nerve loses its two sheaths, which appear to be-
come continuous with the sclerotic, and is thus reduced to its pulp, which spreads out
to form the retina. In some subjects the retina presents a distinctly radiated appear-
ance around the abrupt termination of the nerve (see Globe of the Eye — Retina).
Function. — The optic nerves are the nerves of vision ; their continuity writh the retina
leaves no doubt of this being their function.
The Third Pair, or the Common Motor Nerves of the Eyes.
Dissection. — All the nerves of the orbit should be studied together. The frontal and
lachrymal branches of the ophthalmic nerve and the fourth nerve may be first examined ;
then the orbital portion of the nasal branch of the ophthalmic, which will afterward be
traced into the nasal fossae ; next, the common and external motor nerves ; and, lastly,
the ophthalmic ganglion and the optic nerve.
The common motor nerve has already been traced {^,Jigs. 298, 301) from its origin with-
in the peduncles of the cerebrum to the side of the quadrilateral plate of the sphenoid
bone, below and to the outer side of the posterior clinoid process ; in this situation (3,
Jig. 296) it is received into a groove formed for it by the dura mater ; it then perforates
that membrane, enters the cavernous sinus, passes through it from behind forward and
* In mammalia, and particularly in the horse, a cord arises from the olfactory nerve, runs downward and
forward alon? the septum, parallel to and in front of the naso-palatine nerve, and terminates in the small in-
cisory cavity which exists in the arch of the palate in the lower animals, and is thought by M. Jacobson to be
the seat of a sixth sense.
t M.Arnold, in his beautiful plates of the nerves of the head, has represented two very delicate filament*
as establishing a communicativ^n between the suoorior maxillary and the optic nerves.
5M
826 NEUROLOGY.
a little outward, and before entering the orbit divides into two branches of unequal size,
of which one is superior and the other inferior.
The following are its relations in the cavernous sinus : it is situated in the substance
of the external wall of the sinus, to the outer side of the internal carotid artery, above
the external motor nerve, and to the inner side of the fourth nerve and of the ophthalmic
branch of the fifth ; it enters the orbit at the innermost, and, consequently, the widest
part of the sphenoidal fissure.
It has no immediate relations with the other nerves that pass through the cavernous
sinus, until it is about to enter the orbit ; at this point it receives some very delicate fil-
aments from the cavernous plexus of the sympathetic, and an equally small filament
from the ophthalmic branch of the fifth nerve; after which, the external motor nerve*
becomes situated below the common motor, while the frontal and pathetic nerves cross
above it ; the nasal branch of the ophthalmic is in contact with its outer side, and then
passes between its two divisions.
As the common motor nerve passes through the sphenoidal fissure, the tendon of the
external rectus forms a fibrous ring around it, which is quite distinct from the ring be-
longing to the optic nerve ; this fibrous ring also surrounds the external motor nerve
and the nasal branch of the ophthalmic.
The superior terminal division of the third nerve is much smaller than the inferior ; it
passes below the superior rectus of the eye, and immediately expands into a great num-
ber of filaments, one of which is very large, and runs along the outer border of that mus-
cle. Almost all these filaments are intended for the superior rectus, which they enter
by its under surface. Several of them are very small, and run along the inner border
of the superior rectus, to be distributed to the levator palpebrse superioris. The fila-
ments for this last muscle are proportionally much smaller and less numerous than those
for the superior rectus.
The inferior terminal division is the true continuation of the nerve both as regards its
size and direction ; it runs between the optic nerve and the external motor nerve, which
is in contact with it, and which lies between it and the external rectus muscle, and al-
most immediately subdivides into three branches : an internal, which, passing beneath
the optic nerve, gains the internal surface of the internal rectus, and ramifies in that
muscle ; a median, which penetrates the inferior rectus ; and an external branch, which
is the smallest, and runs along the outer side of the inferior rectus as far as the inferior
oblique, and enters that muscle at its posterior border, and almost at right angles. The
short, thick filament which enters the ophthalmic ganglion proceeds from the branch for
the inferior oblique muscle. This filament for the ganglion sometimes arises separately,
and appears to be a fourth branch of the inferior division of the third nerve. t
Function. — The common motor nerve supplies all the muscles of the eye, excepting
the superior oblique and the external rectus. It is remarkably large, and is proportion-
ed to the activity and frequency of contraction in these muscles. That the muscular
nerves do not terminate in loops or arches may be well seen in these muscles.
The Fourth Pair, or the Pathetic Nerves.
The pathetic nerve {4:, figs. 298, 301) is remarkable for its extreme slenderness, for its
origin upon the side of the valve of Vieussens, for the length of its cranial portion, and
for its winding course around the peduncle of the cerebrum ; it enters (4, Jig. 296) an
opening in the dura mater upon the anterior extremity of the inner or concave border of
the tentorium cerebelli, on the outer side of the common motor nerve ; it runs in the sub-
stance of the external wall of the cavernous sinus, to the outer side and a little below
the level of the common motor nerve (3), and directly above the ophthalmic division (a)
of the fifth, to which it sends otf a filament, and then, running along the upper surface
of that nerve, communicates with it by several twigs ; it then enters the orbit together
with the frontal nerve, the principal branch of the ophthalmic, through the widest part
of the sphenoidal fissure, passes inward and forward, leaves the frontal nerve, crosses
obliquely over the superior branch of the common motor nerve and the back part of the
levator palpebra; superioris and superior rectus of the eye, to reach the superior oblique,
and, having previously ramified, enters the upper border of that muscle. During its course
in the orbit, this nerve, like the frontal branch of the ophthalmic, is in contact with the
periosteum.
The union of the ophthalmic branch and the pathetic nerve is so intimate that it has
been imagined that the lachrymal nerve is always derived entirely from the pathetic, and
not from the ophthalmic itself But a careful dissection shows that this is generally in-
correct. However, I have found the pathetic nerve in several subjects giving offa branch,
* It appears to me that there is a communication between the common and external motor nerves in the
cavernous sinus.
t I have seen the branch for the inferior rectus arise by two roots, one from the branch for tlie internal
rectus, and the other from the branch for the inferior oblique. I have seen the branch for the inferior oblique
give off a supernumerary branch to the inferior rectus. Lastly, sometimes the branches for the inferior
oblique and inferior rectus are united, so that the inferior division of the third nerve was subdivided into two
branches onlv
THE TKIGEMINAL NERVES.
which united with another from the ophthalmic nerve to constitute the lachrymal nerve
This anastomosis took place at the bottom of the orbit. Another and well-founded view re-
gards the pathetic nerve and the ophthalmic branch of Willis as forming a single nerve ; in
fact, in certain subjects they interlace so intimately that it is impossible to separate them.
The Branch for the Tentorium Cercbelli. — The pathetic nerve, while still contained in
the substance of the external wall of the cavernous sinus, gives off a branch which runs
backward in the substance of the tentorium cerebelli, and may be traced as far as the
lateral sinus, near which it divides into two or three filaments. In several subjects I
found that the branch for the tentorium was formed by a twig which arose from the oph-
thalmic nerve, became applied to the pathetic nerve, then divergpd from it,- and passed
backward in the substance of the tentorium. It appears, then, that the nerve of the ten-
toriarti has a retrograde course.*
Function. — The fourth pair of nerves is intended for the superior oblique muscle only
of the eye. It has been supposed that this muscle has a special nerve to enable it to ex-
press certain mental emotions, and especially love and pity ; but, as Soemmering remarks,
it exists in all mammalia, in birds, and even in fishes.
Camper states that the vital functions of the pathetic survive those of the other nerves,
and that this circumstance influences the direction of the eyes in dying persons.
According to Sir C. Bell, the pathetic is the respiratory nerve of the eye. Its origin
is situated at the highest part of the respiratory tract. According to the same physi-
ologist, it is the nerve of expression ; it associates the muscles of the eye, and estab-
lishes certain relations between the eye and the respiratory system.
The Fifth P.ur, or the Trigeminal Nerves.
The Twrvu$ trigeminus (trifacial, Chauss., 5, fig. 296), which, as already stated, arises
from the side of the pons Varolii by two distinct roots, gains the upper border of the pe-
trous portion of the temporal bone, over which it is reflected, and near the apex of which
there is a depression for the reception of the nerve : a bridge-like fold of the dura ma-
ter converts this depression into a canal. The nerve, which increases in width as it
passes over the upper border of the petrous bone, continues to get wider while upon the
upper surface of the same bone, and runs downward, forward, and outward ; its fibres
inunediately spread out and interlace to enter the concave surface of a grayish semilu-
nar enlargement called the semilunar or Gasserian ganglion. All the fibres of origin of
the fifth nerve do not assist in the formation of this ganglion ; for, on reflecting the nerve
from within outward, a flat cord {b, fig. 299) is seen below the ganglion, and giving no
fibre to it ; and, on tracing this cord upon the side of the pons Varolii, it is found to con-
sist of the small root of the fifth nerve, which is at first placed on the inner side of this
nerve, and then turns round it to gain its under surface.
This very remarkable disposition estabhshes a complete analogy between the fifth cra-
nial nerve and the spinal nerves, which, as we have seen, have ganghonic roots (the
posterior roots) and non-ganglionic roots (the anterior).
The Gasserian ganglion (behind a b c, fig. 298 ; c, fig. 299) is lodged in a special de-
pression in the petrous portion of the temporal bone {fig. 296), and it adheres so closely
to the dura mater that it is impossible to separate the ganglion without tearing it. From
its convex surface, which is directed forward and outward, proceed three plexiform ner-
vous trunks, which diverge like the toes of a bird ; these are, proceeding from before
backward, the ophthalmic nerve of Willis (a, figs. 296, 298, &c), the superior maxillary nerve
(i), and the inferior maxillary nerve (c) : the non-ganglionic root (J, fig. 299) of the fifth
nerve goes directly to the inferior maxillary division (c) of the nerve : the opiithalmic and
the superior maxillary divisions often arise by a common trunk. Several scattered fila-
ments are given ofl!" from the three divisions of the 2i^_._ 398.
nerve, but soon join them again. Communicating
filaments are sometimes seen between the superi-
or and inferior maxillary divisions as these latter
enter their respective foramina.
The ganglionic nature of the Gasserian gangli-
on cannot be doubted ; for, like all ganglia, it con-
sists of a grayish, pulpy matter, in which the ner-
vous fibres are spread out, and, as it were, entan-
gled, to enter into new combinations.
The Gasserian gangliont gives off" several fila-
ments for the dura mater, which may be traced
into the substance of the tentorium cerebelli: a
<^rtain number of filaments appear to be destined
* Arnold has described the branch {f,Jig. 296) for the ten-
torium cerebelli, which is derived from the fifth nerve, and not
that which comes from the pathetic.
t The Gasserian ganglion might serve as a type for demon-
strating the structure of all ganglia, so easy is the separation
of the gray matter and white fibres.
NEUROLOGY.
for that part of the dura mater which covers the petrous portion of the temporal bone
and the sphenoid bone. In order to demonstrate these twigs, the dura mater must bt
previously rendered transparent by maceration in diluted nitric acid.
The Ophthalmic Division of the Fifth J^erve.
The ophthalmic nerve of Willis, or ophthalmic division of the fifth nerve (nerf orbitaire,
Winslow; orbito-frontal, Chauss., a, fig. 296, &c.), is the highest and smallest of thfl
three divisions : it passes forward, outward, and upward, in the substance of the exter-
nal wall of the cavernous sinus, in which situation it has a plexiform structure. It is
there divided into an external branch, called the lachrymal nerve {e, fig. 296), a middle
branch, the frontal nerve (continuation of a), and an internal hranch, or the nasal nerve ;
these three branches enter the orbit through different parts of the sphenoidal fissure.
Before this division, the ophthalmic nerve gives off a retrograde filament (nervus recur-
rens inter laminas tentorii, Arnold, f,fig. 296), which passes backward, closely applied
to the twig furnished by the pathetic nerve to the tentorium cerebeUi, and running paral-
lel to that twig, enters the tentorium.
The Lachrymal or Lachrymo-palpebral Nerve.
Dissection. — First expose the nerve in the orbit, and then trace it backward to its ori-
gin. This dissection is difficult, unless the parts have been macerated in diluted nitric
acid. The nerve is then to be traced into the substance of the upper eyelid.
The lachrymal nerve (c, fig. 296), the smallest of the three branches of the ophthalmic,
comes off from the outer side of that nerve, in the substance of the external wall of the
cavernous sinus, where it is difficult to discover its origin and course, on account of its
intimate adhesion to the dura mater ; it enters the orbit through the narrowest part of
the sphenoidal fissure, runs along (below s,fig. 300) the upper border of the external rec-
tus, passes through the lachrymal gland, to which it gives several filaments, pierces the
fibrous layer of the upper eyelid, descends vertically within that eyelid, between its
fibrous layer and the orbicularis muscle, and divides into two principal cutaneous fila-
ments : a palpebral, which runs along the lower border of the tarsal cartilage ; and an as-
cending temporal, which is lost in the integuments upon the anterior temporal region.
During its course, the lachrymal nerve gives off a malar branch, which may be regarded
as resulting from a bifurcation of the nerve. This branch perforates the malar bone,
and anastomoses with the facial nerve upon the cheek.*
The lachrymal branches, properly so called, are extremely small. The real termination
of the lachrymal nerve is in the upper eyelid, and hence the term lachrymo-palpebral has
been given it.
I have already said that the lachrymal nerve not unfrequently arises by two filaments,
one of which is derived from the ophthalmic of the fifth, and the other from the pathetic
nerve (Mr. Swan describes this as the usual condition). In a specimen which I have
now before me, there are two lachrymal nerves, one of which arises in the ordinary
manner, that is to say, from the ophthalmic division of the fifth, while the other, which
is external and smaller, arises both from the pathetic and the frontal nerve. These two
lachrymal nerves anastomose with each other.
The Frontal Nerve.
The frontal nerve (fronto-palpebral, Chauss.) may be regarded as the continuation of
the ophthalmic (a, fig. 296) both in size and direction ; it enters the orbit at the highest
and broadest part of the sphenoidal fissure, together with the pathetic nerve. t
It passes horizontally forward, between the periosteum and the levator palpebrae su-
perioris, crossing that muscle at an acute angle, and divides at the bottom of the orbit
into two unequal branches, which do not diverge until they reach the front of that cavity ;
these are the internal frontal and the external frontal.X
The External Frontal or Supra-orbital Nerve (r,figs. 296, &c.). — This is larger than the
internal branch ; it passes out of the orbit through the supra-orbital foramen, and ex-
pands into ascending or frontal, and descending or palpebral branches. The palpebral
branches are very numerous, and descend vertically in the substance of the upper eye-
* Authors speak of a filament from the lachrymal nerve which anastomoses with the superior maxillary
nerve near the anterior extremity of the infra-orbital fissure. I have never seen this filament.
[Before reaching the lachrymal gland, the lachrymal nerve may give off one or two communicating filaments,
to join the temporal filaments of the orbital branch (t,fig. 300) of the superior maxillary nerve, before these
latter perforate the outer wall of the orbit.]
t The orbital nerves which enter the sphenoidal fissure are divided into two sets : those which pass thro'igh
the fibrous ring of the external rectus, namely, the common motor nerve, the nasal branch of the ophthalmic,
and the external motor nerve ; and those which pass above and to the outer side of the preceding, immediately
below the lesser ring of the sphenoid bone, between the periosteum and the superior rectus, namely, the fron-
tal branch of the ophthalmic, the pathetic, and the lachrymal branch of the ophthalmic ; the latter nerve pass-
es separately through the sphenoidal fissure.
X Not unfrequently a third branch arises from the inner side of the frontal nerve ; this might be called the
fronto-nasal ; it passes obhquely inward and forward, crosses over the superior oblique, anastomoses with the
external nasal nerve, emerges from the orbit below the pulley for the tendon of the superior oblique, and ter-
minates with the external nasal nerve in the upper eyelid. [This fronto-nasal branch may arise from the in-
ternal frontal nerve.]
THE NASAL NERVE. 829
lid ; one of these branches runs horizontally outward under the orbicularis palpebrarum,
to anastomose with the branches of the facial nerve. The frontal hraiKhes are generally
two in number, an external and an internal. They form the true continuation of the ex-
ternal frontal nerve, which almost always bifurcates as it passes through the supra-orbi-
tal foramen ; they are reflected upward ; the external, which is the larger, passes between
the frontal muscle and the periosteum ; the internal {h, Jig. 285) lies between the muscle
and the skin ; they both run somewhat obliquely upward and outward, spread out into
ramifications, which diverge from each other at acute angles, and may be traced as far
as the lambdoidal suture. Almost all these ramifications are distributed to the skin.
Some of them are periosteal, and these require for their proper demonstration that the
parts should be macerated in diluted nitric acid : it is doubtful whether any of them ter-
minate in the frontal portion of the occipito-frontalis muscle. In some subjects there is
a very remarkable osseous frontal branch, which enters an opening in the supra-orbital fo-
ramen, and passes along a canal formed in the substance of the frontal bone ; it as-
cends vertically like the canal, gives off a succession of small periosteal filaments, and at
length, emerging from the canal opposite to the frontal eminence, becomes sub-cutaneous.
The Internal Frontal or Supra-trochlear Nerve is,Jigs. 296, 301). — This is almost always
smaller, but is sometimes as large as the external frontal ; its size appears to me to be
inversely proportioned to that of the external nasal and external frontal nerves togeth-
er ; it is often divided into two branches ; it passes out of the orbit between the supra-
orbital foramen and the pulley of the superior oblique (hence it is called the supra-troch-
lear nerve), and divides into ascending- or frontal filaments, which ramify in all that portion
of the integuments of the forehead which lies between the branches of the right and left
external frontal nerves, and into descending or palpebral and nasal filaments, which de-
scend vertically ; the former set in the upper eyelid, and the latter upon the dorsum of
the nose, where they anastomose with the branches of the nasal nerve.*
When there are two internal frontal nerves, the inner one of them enters a fibrous
ring formed in the upper part of the pulley for the superior oblique, and divides into pal-
pebral and nasal twigs, while the outer one supplies the frontal filaments. This outer
nerve sometimes perforates the orbital arch from behind forward in a special canal : I
have seen it pass from without inward to enter the frontal sinus, then run along the an-
terior wall of the sinus, and finally emerge through a special foramen at the side of the
nasal eminence. This nerve gave no branch in the sinus, although it was situated be-
tween its anterior wall and the lining membrane.
I have seen the frontal nerve divided, from its entrance into the orbit, into four branch-
es, of which the two outer ones corresponded to the external frontal, and the two inner
ones to the internal frontal nerve.
The Nasal Nerve.
Dissection. — The orbital portion of this nerve is easily exposed between the optic nerve
and the superior rectus. The external nasal branch can also be easily traced upon the
frontal region. In order to see the internal nasal branch in the corresponding nasal fos-
sa, an antero-posterior vertical section of the head must be made on one side of the sep-
tum nasi ; this section will also serve for the demonstration of all the deep nerves of the
face.
The nasal nerve (above t,fig. 301), which is intermediate in size between the other
two branches of the ophthalmic, viz., the frontal and lachrymal nerves, arises from the
inner side of the ophthalmic, sometimes even as that nerve is entering the cavernous si-
nus ; it is at first applied to the inner side of the ophthalmic nerve, and then to the outer
side of the common motor nerve, together with which it enters the orbit, passing be-
tween the superior and inferior branches of that nerve. It then runs inward and for-
ward, crosses obliquely over the optic nerve, passes below the superior rectus, then be-
low the superior oblique, gains the internal wall of the orbit, and divides, near the upper
border of the internal rectus, into two branches, named the internal and the external na-
sal nerve.
Before its entrance into the orbit, the nasal nerve gives off a long and slender filament
(sometimes two), which enters the ophthalmic ganglion ; it also furnishes one or more
ciliary nerves, which run on the inner side of the optic nerve, and are distributed like
the ciliary nerves derived from the ophthalmic ganglion.
The external nasal nerve (palpebral, Chauss.). This branch it,Jigs. 296, 301) runs for-
ward, following the original direction of the nerve below the superior oblique, and emer-
ges from the orbit by passing under the cartilaginous pulley for the tendon of that mus-
cle (infra-trochlearis nerve, Arnold) • it is sometimes joined by that division of the fron-
tal nerve which I have named the fronto-nasal (note, p. 828),t and divides into the fol-
lowing branches : palpebral filaments, which run downward and outward in the orbicu-
laris palpebrarum, and form anastomotic arches at the free margin of the upper eyelid ;
a great number of nasal twigs, which pass upon the dorsum of the nose, and anastomose
* [The supra-trochlear nerve supplies filaments to the cornigator sapercilii, and to the orbicularis.!
t I hare seen the external nasal nerve give off a branch which ran inward, anastomosed with the fronto-na-
nal, perforated the roof of the orbit, ran for about an inch beneath the dnrn mater, pcrfonited the frontal bonf
ab)ve and to the outer side of the frontal sinus, and was distributed to t'l ■ -i';ui up'i;i 'i ■ '•>rfhead.
S30 NECROLOGY.
with the filaments of the facial nerve, which accompany the angular vein ; ani frontal
twigs, which anastomose with those of the internal frontal nerve.*
The Internal Nasal or Ethmoidal Nerve (u, fig. 296). — The course of this nerve is very
remarkable. It enters the anterior internal orbital canal, which conducts it into the eth-
moidal groove, on the internal surface of the basis cranii ;t it is then reflected forward
upon the side of llie crista gaili, passes through the ethmoidal fissure into the corre-
sponding nasal fossa, becomes sensibly increased in size, and divides into two filaments,
in internal, or nerve for the septum, and an external, or naso-lobar nerve.
The internal filament, or anterior nerve of the teptum nasi {a, fig. 297), enters the fibro-
mucous membrane upon the anterior part of the septum, and divides into several very
slender filaments, which may be traced below the middle of the septum.
The external filament, or nerve of the external wall of the nasal fossa (u, fig. 299), runs
along the anterior border of the septum, and divides into two terminal filaments, one of
which passes upon the fore part of the external wall of the nasal fossa, and ramifies upon
the turbinated bones ; while the other and larger filament (e, naso-lobaire, Chauss.) fol-
lows the original course of the nerve, and passes behind the nasal bone, which is mark-
ed with a groove, and frequently even by a canal for the reception of the nerve ; from
this latter filament several twigs proceed, which perforate the nasal bone more or less
obliquely, and are distributed to the skin of the nose ; having reached the lower border
of the nasal bone, it passes forward, increasing in size, through the fibrous tissue which
unites the bone to the lateral cartilage of the nose, and then ramifies in the skin cover-
ing the ala and lobe of the nose, where I have seen it anastomose with the facial nerve.
While within the cavity of the cranium, the internal nasal nerve lies beneath the dura
mater, and is perfectly distinct from the olfactory nerve, with which it never anastomoses.
The Ophthalmic Ganglion and its Branchcs.X
Dissection. — The ophthalmic ganglion may be exposed in several ways : for example,
♦jither in dissecting the branch given by the common motor nerve to the inferior oblique
anuscle, or directly by removing the adipose tissue between the external rectus and the
»ptic nerve. The long branch from the nasal nerve to the ophthalmic ganglion and the
;iliary nerves can also be exposed with the greatest ease.
The ophthalmic or ciliary ganglion (behind i,fig. 298) is a small, grayish, and flattened
enlargement, of a lenticular form (the lenticular ganglion), applied to the outer side of the
optic nerve, and situated about two or three lines from the optic foramen, in the midst
of a great quantity of adipose tissue, which renders its dissection difficult. It varies
much in size, and sometimes consists of a simple miliary enlargement, which forms a
point of origin and termination for a certain number of nerves. For the convenience of
description, this ganglion is said to have four angles, two posterior and two anterior ;
by its posterior and superior angle it receives a long slender branch {its long root), given
off from the nasal nerve while still contained within the cavernous sinus. Not unfre-
quently a second long, but extremely slender root, is furnished by the nasal nerve to the
ophthalmic ganglion. By its posterior and inferior angle it receives a short, thick branch,
which comes from the inferior division of the common motor nerve {its short root). From
its two anterior angles it gives off two small bundles of nerves, named the ciliary nervet
{i, fig. 298 ; x, fig. 301). Lastly, the ophthalmic ganglion has a ganglionic or soft root, or,
rather, a communicating filament, between this ganglion and the superior cervical gan-
glion of the sympathetic ; this soft root arises frohi the cavernous plexus, and passes
.■sometimes to the long or nasal root of the ophthalmic ganglion, and sometimes to the
ophthalmic ganglion itself
The ciliary nerves are remarkable for their tortuous course, in which respect they re-
semble the ciliary arteries ; and also for being collected into two bundles, the one supe-
rior, which is generally composed of four filaments, and the other inferior, composed of
five or six. The ciliary nerves do not anastomose before they reach the globe of the
eye, with the exception, however, of the ciliary nerve, which is derived directly from
the nasal nerve, and which anastomoses with an inferior ciliary nerve from the ophthal-
mic ganglion. Having reached the sclerotic, the ciliary nerves perforate the coat more
or less obliquely, around the entrance of the optic nerve, excepting two or three, which
enter the globe of the eye near the attachment of the muscle ; after having perforated
the sclerotic, they become flattened or riband-shaped, and run forward {a, fig. 242) par-
allel to each other, between the sclerotic and the choroid coats, slightly adhering to the
former of these membranes, on which grooves exist for their reception ; on approaching
the ciliary circle or ligament (h), they bifurcate, and divide into filaments, which anasto-
mose with the neighbouring filaments, and appear to be lost in the ciliary circle, which
* [It also supplies branches to the lachrymal sac and caruncula, and to the parts of tha inner canthns.]
t Not unfrequently the internal nasal nerve, while within the ethmoidal groove, gives off a recurrent net*
vous twig, which enters the orbit by a small canal, in front of the anterior internal orbital canal, and anasto-
moses with the external nasal or infra-trochlear nerve. I have seen this small nerve anastomose with the
tronto-nasal branch, which I have already described (note, p. 828) as an unusual branch of the frontal nerve.
t The connexions of the ophthalmic ganglion with the nasal nerve, as well as with the common motor nerve,
have induced me to describe it here.
SUPERIOR MAXILLARY DIVISION OP THE FIFTH NERVE. 831
has been, and not without some reason, considered by modern anatomists as a nervous
ganglion, ganglion annulare (annulus gangliformis seu ganglion annulare, Sammering). I
have seen some of these ciliary nerves pass through the ciliary circle and enter the iris ;
they are not distinctly seen to enter the ciliary processes.*
The Superior Maxillary Division of the Fifth Merve.
Dissection. — Saw through the zygomatic arch, turn down the masseteric muscle, and
remove the roof of the orbit ; first dissect the lachrymal, malar, and temporal twigs of
the orbital branch of the nerve ; then clean out the orbital cavity, remove the upper wall
of the zygomatic fossa to reach the spheno-maxillary fossa by means of two cuts joined
at an acute angle in the foramen rotundum. Detach the origins of the pterygoid mus-
cles ; lastly, trace the nerve into the infra-orbital canal and on the face.
The superior maxillary nerve Q),figs. 298, 300, 301), the second or middle division of
the fifth nerve, both in position and size, runs forward to enter, after a very short course,
the foramen rotundum, by which it is conducted into the spheno-maxillary fossa ; from
thence it passes into and traverses the whole length of the infra-orbital canal, where it
is named the infra-orbital nerve (/) ; having reached the fore part of that canal, it bends
downward, and ramifies in the cheek. It is plexiform at its origin and in the foramen
rotundum, but is fasciculated throughout the rest of its course.
Its collateral branches, taken in the order of their origin, are the orbital nerve ; certain
nerves which are given off from the enlargement called Meckel's ganglion, namely, the
palatine, spheno-palatine, and vidian or pterygoid nerves ; the posterior dental nerves,
and the anterior dental nerve ; lastly, several small filaments come off either from the
ganglion of Meckel or from the superior maxillary nerve itself, and, surrounding the in-
ternal maxillary artery, assist in the formation of its plexus.
The Orbital Nerve.
This branch [t, jig. 300) comes off immediately in front of the foramen rotundum, from
the upper side of the superior maxillary nerve, passes through the spheno-maxillary fis-
sure, along which it proceeds to enter the orbit ; it then runs along the floor of tl>e orbit,
and divides into two branches : the one ascending, the lachrymal branch of the orbital
nerve, which enters the lower surface of the lachrymal gland, anastomoses with the
lachrymal branch (s) of the ophthalmic nerve (a), and sends off some branches to the
upper eyelid, near its external angle ; the other branch is the temporo-malar, which pass-
es horizontally forward, enters a small canal in the malar bone, and subdivides into a
malar filament, which perforates the bone, and is distributed to the skin upon the malar
region,! and a temporal filament, which perforates the orbital portion of the malar bone,
and dips into the anterior part of the temporal muscle, in which it anastomoses with the
anterior deep temporal nerve, a branch of the inferior maxillary. I have sometimes
seen two temporal filaments pass through the malar bone at two different points.^
The Spheno-palatine Ganglion and its Branches.
After having given off the orbital nerve, and while it is still contained in the spheno-
maxillary fossa, the superior maxillary nerve gives off from its lower side a thick branch,
frequently two, and occasionally several branches, from which a great number of diver-
ging nerves immediately proceed ; these are the three palatine nerves, the spheno-pala-
tine nerves, and the vidian nerve ; at the point where these nerves diverge is found an
enlargement which the elder Meckel,^ whose name is connected with the description of
the fifth pair, regarded as a ganghon, and which is, therefore, called Meckel's ganglion,
or the spheno-folatine ganglion (situated before s,fig. 299 ; below b,fig. 301).
In a certain number of cases, I have sought in vain for the ganglionic structure in this
enlargement, i. e., for gray matter with white filaments scattered through it. It appear-
ed then to be nothing more than the common trunk or starting-point of a great number
of nerves ; in the majority of cases, however, a quantity of gray matter certainly exists,
but is so arranged that the nerves may generally be traced quite through the enlarge-
ment, so that they clearly are not given off from the ganglion itself, but come directly
from the superior maxillary nerve. II
* Tiedemann, from the results of observations in comparative anatomy, believes that the arteries vv'hich ram-
ify in the retina are accompanied by very delicate nervous filaments, derived from the ophthalmic ganglion and
the ciliary nerves : he has seen a nervous filament penetrate the optic nerve with the arteria centralis retinje ;
and he states that the ciliary arteries are accompanied by very delicate nervous filaments, which he has tra-
ced into the retina as far as the zone of Zinn. Tiedemann also says that he has seen, only once, it is true, a
rather large nervous filament proceed from Meckel's ganglion, and join the thick and short branch which is
pveu oflFfrom the third pair to assist in the formation of the ophthalmic ganglion.
t It is said that this twig anastomoses with the facial nerve in the malar region ; I have never been fortu-
nate enough to discover this anastomosis.
X [Both of these temporal filaments maybe joined by communicating twigs from the lachrymal nerve withia
the orbit ; one of them anastomoses with the anterior deep temporal nerve, as above mentioned ; the other,
having entered the temporal fossa through the malar bone, ascends on the temporal surface of that bone, turns
outward, perforates the temporal fascia about an inch above the zygoma, anastomoses with filaments of the
facial nerve, and of the auriculo-temporal branch of the inferior maxillary nerve, and is lost in the skin on the
temple.] t) Mem. de I'Acad. de Berlin, 1749
II In one case the ganglion of Meckel was in contact with the internal surface of the superior maxillary
nerve In the same case a filament proceeded from the upper part of the ganglion, and joined the branch
.flB NEUROLOGY.
I shall now describe, in succession, the branches which proceed from Meckel's ganglion.
The Palatine Nerves.
These nBrves {gg,fig- 299; g,Jig. 301) are three in number: an anterior palatine,
which is the largest, a posterior palatine [the middle of some authors], which is the next
in size, and an intermediate nerve [the posterior of some authors], which is the smallest ;
these nerves are continuous with Meckel's ganghon ; it is most evident that, in the
greater number of cases, they arise directly from the lower part of the superior maxil-
lary nerve.
The anterior or great palatine nerve immediately enters the posterior palatine canal,
through the whole length of which it passes, and, having reached the lower orifice of
that canal, is reflected forward, and terminates by bifurcating on the hard palate.
During its course, it gives off an inferior nasal branch (lower f, Jig. 299), which is dis-
Fig. 299. tributed over the middle meatus and the middle and inferior
turbinated bones : the twig for the inferior turbinated bone
may be traced to the fore part of that bone ; it also gives off
the anterior palatine, and several small twigs, which perfo-
rate the inner wall of the maxillary sinus, and are distributed
to the last molar teeth ; lastly, at its exit from the posterior
palatine canal, and even sometimes while yet within that
canal, it sends off a staphyline branch, which spreads into
several filaments, all of which run backward in the soft pal-
ate, and divide into superior filaments distributed to the mu
cous membrane on the nasal surface ; and inferior, which run beneath the mucous mem-
brane on the buccal surface of the soft palate. Of the two terminal branches of the an-
terior palatine nerve, both of which occupy the hard palate, the external runs near the
alveolar border, and the internal near the median line ; they enter into the midst of the
glandular layer of the palate, and are ultimately distributed to the glands, to the mucous
membrane of the hard palate, and to the gums.
The posterior [middle] palatine nerve, the next in size, enters a special canal : on es-
caping from which it passes backward, beneath the mucous membrane of the nasal sur-
face of the soft palate, to which it is distributed.
The same is the case with the intermediate [posterior] or small palatine nerve, which
is extremely slender.
I have seen a palatine nerve enter the maxillary sinus, run beneath its lining mem-
brane, pass vertically through the maxillary tuberosity behind the last molar tooth, and
ramify upon the hard palate.
The Spheno-palatine or Posterior Nasal Nerves.
Dissection. — ^Make a vertical section of a head, previously macerated in dilute nitric
acid, strip off the pituitary membrane lying upon the septum and the turbinated bones,
and examine the nerves from the internal or deep surface of that membrane.
The spheno-palatine nerves are very slender ; they enter the corresponding nasal
fossae through the spheno-palatine foramen, and have been traced by Scarpa with his
customary exactness. They are all situated in the pituitary membrane, or, rather, be-
tween the periosteum and the mucous membrane, and cannot be readily seen until this
fibro-mucous membrane has been removed from the bones which it covers ; the nervous
filaments are then seen through the semi-transparent fibrous layer. For this purpose,
preparations macerated in diluted nitric acid are indispensable. The spheno-palatine
nerves are distributed to the septum nasi and the external wall of the corresponding na-
sal fossa ; they are divided into internal and external.
There is only one internal spheno-palatine nerve, viz., the nerve of the septum nasi, or
ine naso-palatine of Scarpa {b,fig. 297) ; it passes inward, in front of the sphenoidal si-
nus, and below the orifice of that sinus, to gain the septum nasi ; it is then directed at
first almost vertically downward, but afterward almost horizontally forward, as far as
the superior orifice of the anterior palatine canal, which it enters, and then passes into
a special canal, quite distinct from the anterior palatine canal, and parallel to the one
for the naso-palatine nerve of the opposite side. According to M. Hippolyte Cloquet,
the two naso-palatine nerves terminate in the upper part of a ganglion, which he calls
the naso-palatine, and do not reach the mouth ; but in some researches which I have
made on the subject, I have failed in detecting this ganglion. t
The nerves can be distinctly seen to enter the mucous membrane of the hard palate
behind the incisor teeth, and upon that prominence of the mucous membrane against which
the point of the tongue is so often applied. I have never seen any anastomoses either
between the two naso-palatine nerves, or between these and the anterior palatine nerves.
given by the external motor nerve to the sympathetic. I have not been able to discover the filaments which
are said to establish a communication between Meckel's ganglion and the optic nerve.
t I find that it is stated by Arnold, whom I have so often quoted, because his works are above all praise fijr
their rigorous accuracy, that the spheno-palatine ganglion docs not exist ; and he observes, with reason, that
the subjoined description of M. Hippolyte Cloquet is very imperfect. " It consists of a small , reddish, fungous
mass, rather hard, as if fibro-cartilaginous, and surrounded by adipose cellular tissue "
THE PTERYGOID NERVE, ETC. 833
Anatomists are not agreed as to whether the naso-palatine nerve gives off any fila-
ments upon the septum. I have failed in detecting any ramification of the nerve in a
great number of preparations, in which tlie pituitary membrane had been rendered trans-
parent by long maceration in diluted nitric acid. Rather frequently a filament was given
off from the upper part of the nerve, and then joined it again. Three times only did I
observe a twig running upward from the anterior part of the nerve.
The external spheno-palatine, or superior nasal nerves (upper /, fig. 299), so called to
distinguish them from thfe inferior nasal branch of the anterior palatine nerve, are three
or four in number ; they are directed vertically along the back part of the outer wall of
the corresponding nasal fossa, and spread out into filaments, which extend over the tur-
binated bones and the meatus ; these filaments can only be seen from the deep surface
of the pituitary membrane.*
I have never been able to find the anastomoses between the internal and external
spheno-palatine nerves and the divisions of the olfactory nerve, which are admitted by
some anatomists.
The Vidian or Pterygoid Nerve.
The vidian nerve {v,figs. 300, 301) arises from the back part of Meckel's ganglion, and
enters the vidian or pterygoid canal, after emerging from which it perforates the carti-
laginous plate of the foramen lacerum anticus, and divides into a superior cranial branch,
the great superficial petrosal nerve, and an inferior, deep, or carotid branch. The subdivis-
ion of the pterygoid nerve often occurs at its origin from Meckel's ganglion.
The inferior or carotid branch, which is much larger than the superior, forms the con-
tinuation of the nerve : it enters the carotid canal, and is applied to the outer side of
the carotid artery, where it anastomoses with the nerves which establish a communica-
tion between the superior cervical ganglion and the external motor nerve of the eye,
and assists in the formation of the carotid plexus ; a flattened gangliform enlargement
is seen at the point of anastomosis. I have sometimes seen two carotid branches, one
of which was very small.
The superior or cranial branch, the great superficial petrosal nerve, enters the cranium
between the temporal and sphenoid bones, runs backward and outward {v, fig. 296) be-
neath the dura mater, in a groove on the upper surface of the petrous portion of the
temporal bone, passes through the hiatus Fallopii into the aqueductus Fallopii or canal
for the facial nerve (part of 7), and anastomoses with that nerve. t I say that it anasto-
moses, because there is a sort of fusion of the two nerves, and not a simple juxtaposi-
tion. The branch called the chorda tympani, which comes off from the facial nerve at
some distance from the point of fusion, should not be regarded as a prolongation of the
superficial petrosal nerve, supposed in that case to be merely applied to the facial nerve.t
The Posterior Dental Nerves.
Dissection. — These nerves can be readily seen without any dissection through the
bone, when this is rendered transparent by nitric acid. They must be examined both
from the external surface of the bone, and from the interior of the sinus.
The posterior dental or alveolo-dental nerves (e,figs. 298, 300, 301) are two in number,
a superior and an inferior ; sometimes there are three ; they arise from the superior
maxillary nerve, sometimes by a common trunk, sometimes separately, just as that
nerve is about to enter the infra-orbital canal : they run forward and downward, at first
in contact with the maxillary tuberosity, and give off some filaments to the buccinator
muscle, and to the gums, and some which are distinctly distributed to the mass of fat in
the cheek ; they then enter certain canals in the substance of the maxillary tuberosity,
and become flattened or riband-shaped.
The posterior and superior dental nerve passes from behind forward, through the base
* Bock, and Arnold after him, have described, under the name of the pharyngeal branch, a rather large
branch, which may be regarded as belonging to the external spheno-palatine nerves ; it enters into the ptery-
go-palatine canal, formed between the under surface of the sphenoid and the sphenoidal process of the palate
bone, passes backward and inward, and divides into several filaments, which are distributed to the upper part
of the pharynx. [Some of these superior nasal branches are said to supply the lining membrane of the pQS<.e-
rior ethmoidal and the sphenoidal sinuses.]
t I have seen the superior branch of the vidian formed by three very distinct filaments: anatomists are still
undecided as to whether the inferior or carotid branch is derived from the ganglion of Meckel, or from tlie su
perior cervical ganglion. According to Arnold, it resembles the organic system of nerves in its colour, soft-
ness, and structure. I cannot coincide in this opinion, for it appears to me that the cranial and carotid branch,
es of the vidian are analogous in every respect.
t Arnold, who regards this opinion of Hippolyte Cloquet, which is adopted by Hirsel, as erroneous, states
that, at the junction of the cranial branch of the vidian with the facial nerve, there is a gangliform swelling,
in which he finds some analogy to the inter- vertebral ganglia, and which he considers to be a transition be-
tween a gangliform stalk and a true ganglion.
According to Arnold, the superficial or cranial branch, and the deep or carotid branch of the vidian, do not
come from a common trunk, but are merely juxtaposed, and are distinct throughout their entire extent. The
carotid branch is soft and reddish, presents all the characteristics of the ganglionic nerves, and is intended to
establish a communication between the superior cervical and the spheno-palatine ganglion. The cranial or sui
perficial petrosal branch, on the contrary, presents all the characters of the cerebro-spinal nerves ; it i«of t
white colour and firm consistence.
5N
834 NEUROLOGY.
of the malar eminence of the superior maxillary bone, and anastomoses on a level with
the canine fossa with a filament from the anterior dental nerve.
The posterior and, inferior dental nerve, which is larger than the preceding, runs in a
curved direction below the malar eminence, the concavity of the curve being directed
upward, and anastomoses with the posterior and superior dental nerve, on a level with
the canine fossa. No filament is given off from the upper side of these nerves, but they
give off a great number of filaments downward, which anastomose, and form a series of
very remarkable meshes or areolae ; these meshes, and the 'dental nerve which come
from them, are situated within the substance of the bone, but are much nearer to the
sinus than to the outer surface of the bone. It is from these meshes that the extremely
delicate filaments arise which form the dental nerves of the molars and bicuspids ; their
number corresponds to that of the fangs of these teeth.*
Some filaments evidently terminate in the substance of the superior maxillary bone ;
no other bone in the body has so large a number of proper filaments.
The Anterior Dental Nerve.
The anterior dental or alveolo-dental nerve {j,fig. 298) is the only branch given off by
the superior maxillary nerve while within the infra-orbital canal ;t it arises about five or
six lines from the anterior orifice of that passage. It is so large that it may be regarded
as resulting from the bifurcation of the infra-orbital nerve. It soon enters a special ca-
nal formed for it in the superior maxillary bone, gives off on the outer side a small
branch which anastomoses with the posterior and superior dental nerve, passes at first
horizontally inward, and then vertically downward, turning round the margin of the an-
terior opening of the corresponding nasal fossa, and is reflected upon the floor of that
fossa ; during the whole of this course, it is situated within the substance of the superior
maxillary bone ; its horizontal portion is superficial, and its vertical portion is deep-
seated, having merely a thin bony lamella between it and the pituitary membrane.
Having arrived on a level with the floor of the nasal fossa, about two lines from its an-
terior opening, it expands into a great number of ascending and descending filaments ; the
aseending filaments are reflected upward within the anterior nasal spine, where they ter-
minate. They appear to me to send off a small ramification to the pituitary membrane.
The descending filaments terminate by supplying the dental nerves for the incisor, canine,
and first bicuspid teeth. A great number of filaments are also lost in the substance of
the bone.
I have never seen any filaments from the dental nerves entering the membrane of the
maxillary sinus.
The Terminal Branches of the Superior Maxillary Nerve.
Having reached the anterior orifice of the infra-orbital canal, the superior maxillary
nerve, the component bundles of which had been merely in juxtaposition, immediately
expands {i,fig. 301) into a pencil of diverging filaments beneath the levator labii supe-
rioris. These filaments {i,fig- 285) may be divided into ascending or palpebral, which
pass upward and outward beneath the orbicularis palpebrarum, and are distributed to the
skin and conjunctiva of the lower eyelid ; a great number of internal or nasal filaments,
which run upon the side of the nose, and are distributed to the skin of that organ ; one
of them runs along beneath the septum ; and, lastly, into descending or labial filaments,
which are the most numerous, and which enter the substance of the upper lip, and are
distributed to the skin and the mucous membrane : all these filaments, and especially the
labial, interlace and anastomose with the facial nerve, so as to form a plexus, named the
infra-orbital, to which we shall return in describing the facial nerve.
I have seen the nasal and the palpebral filaments arise together from the superior max-
illary nerve, before it had given off the anterior dental, enter a special canal situated on
the inner side of the infra-orbital canal, emerge opposite the line of demarcation between
the cheek and the nose, and then expand into their nasal and palpebral divisions ; while
the labial filaments had their usual arrangement.
The Inferior Maxillary Division of the Fifth J^erve.
Dissection. — As this nerve must be examined both upon its internal and its external
aspect, it must be dissected in both directions. An antero-posterior section of the head
in the median line will enable us to see, on the internal surface of the nerve, the chorda
tympani, the otic ganglion, and the origins of all the other branches which come from
the inner side of the inferior maxillary nerve, viz., the nerve of the internal pterygoid,
the lingual nerve, and the dental nerve. In order to see the distribution of the deep
temporal, the masseteric, the buccal, the internal pterygoid, and the auriculo-temporal
nerves, the inferior maxillary nerve must be exposed from its outer side, by breaking
down the zygomatic arch, reflecting down the masseter, which is to be detached as far
* In those molar teeth which have two or three roots, the nervous filaments snbdiii'ide and anastomose with
each other in the substance of the dental pulp.
t Sometimes, however, I have seen the posterior and superior dental nerve arise within the infra-orbital
'lanal.
THE DEEP TEMPORAL NERVE, ETC. 835
back as the sigmoid notch, by sawing through the base of the coronoid process, and
turning the temporal muscle upward, and then by carefully dividing the external ptery-
goid muscle, through which the buccal nerve passes.
The inferior maxillary nerve (c, figs. 296, &c.), the most posterior and the largest di-
vision of the fifth nerve, passes outward and a little forward, and, after a very short
course within the cranium, escapes through the foramen ovale into the zygomatic fossa,
where it divides successively into seven branches. The non-ganglionic root (i, fig. 299)
of the fifth nerve is connected exclusively with the inferior maxUlary division (c) of its
other root, beneath which it lies, from which it can be distinguished by not having a
plexiform structure, with which it is not blended until it emerges from the foramen ovale.
Of the seven branches of the inferior maxillary nerve, three are external, namely, the an-
terior and posterior deep temporal, the masseteric, and the buccal ; one is posterior, name-
ly, the auriculo-temporal ; one is internal, the internal pterygoid ; and two are inferior, the
lingual or gustatory, and the inferior dental. These nerves may also be divided into col-
lateral branches, including the first five, and the terminal branches, namely, the lingual and
the inferior dental ; the otic ganglion, described by Arnold, is connected vidth this nerve.*
The Collateral Branches of the Inferior Maxillary Nerve.
The Deep Temporal Nerve.
The first external branch, or the deep temporal -nerve, arises from the outer side of the
inferior maxillary nerve, passes horizontally outward and forward between the roof of the
zygomatic fossa, with which it is in contact, and the eternal pterygoid muscle. Having
arrived at the ridge which separates the temporal from the zygomatic fossa, it anasto-
moses with several temporal branches derived from the buccal and masseteric nerves,
and forms a sort of plexus with them. The branches which emerge from this plexus
ascend vertically in the deep layers of the temporal muscle, in which most of them ter-
minate.
Some twigs anastomose with the temporal filaments derived from the lachrymal branch
of the ophthalmic nerve, and from the orbital branch of the superior maxillary nerve. t
One and sometimes two filaments perforate the temporal fascia, about a finger's breadth
above the zygomatic arch, and then ascend beneath the skin, to anastomose with the
auriculo-temporal and the facial nerves.t
The Masseteric Nerve.
The second external branch, or the masseteric nerve, arises from the same point as the
last nerve, and greatly exceeds it in size ; it comes off at an acute angle, passes horizon-
tally backward and outward in contact with the roof of the zygomatic fossa, between it
and the external pterygoid muscle ; it is then reflected downward over the upper part of
that muscle to gain the sigmoid notch of the lower jaw, upon which it is again reflected,
and then descends vertically, between the rcimus of the jaw and the masseter, or, rather,
in the substance of the deep layers of that muscle, down to the insertion of which it may
be traced. During its course along the upper wall of the zygomatic fossa, the masse-
teric nerve gives off a small, deep temporal branch, which runs along the periosteum,
passes into the temporal fossa, and sends off an articular branch to the temporo-max-
illary articulation.
The Buccal or Bucco-lahial Nerve.
The third external branch {g, fig. 300), the buccal, or, rather, the bucco-lahial nerve
(Chauss.), is very remarkable on account of its size and the extent of its distribution,
which gives it some resemblance to the corresponding portion of the facial nerve. It
arises from the outer side of the inferior maxillary nerve, by one, two, and sometimes
three roots, which perforate the external pterygoid, and join together as they emerge from
that muscle ; from thence it runs downward between the coronoid process of the lower
jaw and the tuberosity of the upper jaw, gives several twigs to the external pterygoid
muscle, and also some branches to the temporal muscle, of which one ascends and an-
astomoses with the deep temporal nerve, whUe another descends and is distributed to
the same muscle, near its insertion into the coronoid process ; the buccal nerve itself
sometimes perforates the lowest part of the insertion of the temporal muscle, and having
reached the back part of the buccinator, it expands into a great number of diverging
branches, like the facial nerve.
The ascending branches are distributed to the skin of the malar and buccal regions j
one of them forms an anastomic arch with the facial nerve behind the duct of Steno.
This anastomosis is very remarkable. The middle branches pass horizontally forward
on a level with the commissure of the lips, and terminate in the skin ; several of them
form a sort of plexus around the inferior coronary artery of the lip. The lowest of the
descending branches pass vertically downward, and even a little backward, upon the outer
surface of the buccinator, also beneath the deep surface and upon the outei" surface of
* We sometimes find a communicating filament between the superior and inferior maxillary nerves imme-
diately before they enter their respective foramina.
+ [There is hence a communication between the branches of the three divisions of the fifth nerve.]
i [This cutaneous filament is one of the temporal filaments of the orbital branch of the superior maxillary
Qerve. — lEllis's VemonstraUons ; see note, p. 8.31.)]
«36
NEUROLOGY.
the triangularis oris, and are entirely lost either in the skin or in the mucous membrane
It is doubtful whether the buccal nerve partially terminates in the orbicularis oris, the
triangularis oris, and the zygomaticus major. AH the filaments which enter these mus-
cles, and which appear at first sight to terminate in their substance, pass through them
to supply the mucous membrane ; their branches anastomose with the mental nerve be-
neath the triangularis oris ; several filaments are lost in the buccinator.
The Internal Pterygoid Nerve.
The internal collateral branch (<, fig- 299), or nerve for the internal pterygoid muscle,
which is very slender, comes off from the inner side of the inferior maxillary nerve in
contact with a grayish body, named the otic ganglion, runs downward and inward along
the inner surface of the internal pterygoid muscle, and ramifies in it.
The Auricula-temporal Nerve.
The posterior collateral branch, or the auricula-temporal nerve (the auricular or superfi-
cial temporal nerve of authors), is very large, flattened, and plexiform at its origin (be-
hind c, fig. 298 ; r, fig. 299) ; it sometimes arises by a great number of distinct roots ; it
passes backward and a little downward behind the neck of the condyle of the lower jaw,
and divides into two branches, a superior or ascending, and an inferior or descending branch.
The superior or ascending branch, the superficial temporal nerve, turns round the back
of the neck of the condyle, and ascends vertically between the articulation and the ex-
ternal auditory meatus ; having become sub-cutaneous, it divides into several filaments
(r, fig 285), which may be traced up to the highest part of the temporal fassa.
During its course this nerve gives off a very remarkable anastomotic branch, which
arises behind the neck of the condyle, and is reflected upon it so as to run forward be-
neath the facial nerve, with which it is blended opposite to the posterior border of the
masseter. This anastomotic branch is sometimes double. It may be regarded as one
of the origins of the facial nerve, which increases considerably in size after having re-
ceived it.
This branch is one of the principal communications between the facial nerve and the
fifth nerve, and modern physiologists have justly attached great importance to it.
The ascending branch also gives off some plexiform branches to the temporo-max-
illary articulation, and several filaments to the auditory meatus and the auricle. In the
temporal region it anastomoses with a very small filament, which is derived from the
deep temporal nerve, and which perforates the temporal fascia.*
It accompanies the temporal artery, for which it forms a sort of plexus, and then di-
vides into cutaneous filaments, which reach the crown of the head.
The inferior, descending, or auricular branch is as large as the preceding ; it forms a
plexus around the internal maxillary artery, behind the condyle, and sometimes presents
small ganglia ; it divides into several branches, some of which pass through the parotid
gland and are distributed to the lobe of the ear, while the others anastomose with some
filaments of the auricularis magnus nerve derived from the cervical plexus. One of
these branches joins the dental nerve, before that nerve enters the dental canal ; an-
other branch terminates in the temporo- maxillary articulation.
The Terminal Branches of the Inferior Maxillary Nerve.
The Lingual Nerve.
The lingual or gustatory nerve {n,figs. 298, 300; n n',fig. 301) passes downward and
Fig. 300. forward : it is at first situated between the exter-
nal pterygoid muscle and the pharynx, but it soon
passes between the two pterygoids {fig. 300), then
between the internal pterygoid and the ramus of
the lower jaw {fig. 298), and then runs forward
along the upper border of the sub-maxillary gland,
between it and the buccal mucous membrane, and
above the mylo-hyoid muscle ; it then passes be-
neath the sub-lingual gland, which it crosses, to
pass to its inner side, and, accompanied by the
Warthonian duct, which lies to its inner side and
crosses it at a very acute angle, it gains the corre-
sponding border of the tongue, and ramifies in the
substance of that organ.
During its passage between the two pterygoids
the lingual nerve is joined by that branch of the fa-
cial nerve which is known as the chorda tympani {x,
fig. 298), and which unites to it behind, forming a
very acute angle opening upward ; this branch of the
facial, which may be regarded as one of the roots
* tThis perforating cutaneous fUament is one of the temporal filaments of the orbital branch of the superior
maxillary nerve (see notes, p. 831, 835J.1
THE INFERIOR DENTAL NERVE, ETC. 837
of the lingual, remains in contact with that nerve for some time, and is at last blended
with it.
The lingual nerve also receives, sometimes before, and sometimes after being joined
by the chorda tympani, a very considerable anastomotic branch from the inferior dental :
this branch is rarely wanting.
After receiving these two branches, the lingual nerve becomes considerably increased
in size, and during its course gives off several filaments to the tonsils, the mucous mem-
brane of the cheeks and the gums.
Opposite the sub-maxillary gland, the lingual nerve presents a very remarkable gan-
glion, generally described as the sub-maxillary ganglion {aitVLdtei behind X, fig. 300); the
trunk of the nerve does not enter into its formation, but it appears to be formed only by
its inferior filaments. It has been gratuitously supposed that this ganglion is formed
exclusively by the chorda tympani, which, according to such a view, after running in
mere contact with the lingual nerve, becomes detached from it (opposite n) to enter the
ganglion (x) : we have stated that there was equally little reason to suppose that the
chorda tympani was the continuation of the cranial branch of the vidian. The sub-max-
illary ganglion, the size of which is very variable, gives off a great number of filaments,
most of which are distributed to the sub-maxillary gland ; one of these filaments accom-
panies the Warthonian duct.
Having reached the sub-lingual gland, the lingual nerve supplies that gland with a
great number of filaments, which dip into it and form a plexus of very delicate meshes.
In the tongue, the lingual nerve is situated at the lateral border of that organ, and on
a plane above that of the hypoglossal nerve, with which it communicates by an anasto-
motic branch, forming a loop. It becomes gradually diminished in size by giving off a
very numerous series of filaments {n',fig. 301), which turn round the border of the tongue,
pass forward and upward, perforate the muscles of that organ, and spread out into pen-
cils, the filaments of which may be traced into the papillae of the mucous membrane.
The nerve, reduced to a single filament, terminates at the point of the tongue
The Inferior Dental Nerve.
The inferior dental nerve {m,fig. 298), larger* than the lingual, descends with it, at first
between the two pterygoid muscles, and then between the internal pterygoid and the ra-
mus of the lower jaw : in this situation it is kept in contact with the bone by a layer of
fibrous tissue, which is improperly called the internal ligament of the temporo-maxillary
articulation, and which separates the nerve from the lingual nerve and the internal pter-
ygoid muscle ; it soon enters the dental canal, which it traverses (m) throughout its
entire extent, accompanied by the inferior dental artery, and protected by a fibrous ca-
nal ; during its course it supplies the molar and the bicuspid teeth, giving a twig to each
prong, and having reached the mental foramen, divides into a mental and an incisor branch.
The Myloid Branch. — As it enters the inferior dental canal, the nerve gives off a small
branch, the myloid branch {z, fig. 300), which arises from its posterior border, opposite
the corresponding artery, is received into a furrow upon the inner surface of the ramus
of the jaw, against which it is retained by a layer of fibrous tissue, and then, emerging
from this furrow, passes upon the upper surface of the mylo-hyoid muscle, in which it
ramifies. A great number of filaments from the myloid nerve enter the anterior belly of
the digastric muscle. t
The mental branch {t,fig. 285), the continuation of the inferior dental nerve, as far as
size is concerned, passes through the mental foramen, and expands into diverging fila-
ments, which are distributed, in reference to the lower lip, in the same way as the infra-
orbital branch is to the upper lip. These filaments interlace with the facial nerve, and
form with it a sort of mental plexus ; they are intended for the skin and the mucous
membrane of the lower lip : most of them pass to the free border of that lip.
The inrisor dental branch, which is extremely small, continues in the original course
of the inferior dental nerve, and subdivides to supply the canine and two corresponding
incisor teeth.
The inferior dental nerve represents in the lower jaw the infra-orbital portion of the
superior maxillary nerve in the upper jaw.
The Otic Ganglion.
I cannot terminate the description of the inferior maxillary nerve without noticing a
ganglion recently described by Arnold, under the name of the olic ganglion, which he
compares to the ophthalmic ganglion, and which has served him as the basis of an inge-
nious theory respecting the nerves of the head. The following is the position of the
ganglion, as indicated by Arnold : "The otic ganglion is situated (behind I, fig. 299) im-
mediately below the foramen ovale, on the inner side of the third or inferior maxillary
* I have observed that thi.s nerve was much smaller in old than in young- subjects.
t [Filaments are also given to the sub-maxillary gland ; according to Ellis, some branches pass through
the mylo-hyoid muscle and enter the genio-hyoid ; and it is stated bv Alcock that a branch reaches the de-
pzecsor labii inferioris.]
888 NEUROLOGY.
division (c) of the fifth nerve, a little above the origin of the superficial temporal or au-
ricular nerve (auriculo-temporal), at the spot where the inferior maxillary nerve gives off
from its external surface the deep temporal and buccal nerves, and where the small root
of the fifth unites intimately with the large root. On the inner side, this ganglion is
covered by the cartilaginous portion of the Eustachian tube, and by the origin of the ex-
ternal peristaphyline {circumflexus palati) muscle ; behind, it is in contact with the mid-
dle meningeal artery. Its external surface rests upon the inner side of the inferior max-
illary nerve."
There can be no doubt that in the situation indicated by Arnold, there is a thin and
not very well-defined layer of reddish, pulpy tissue, placed upon the inner side of the in-
ternal pterygoid nerve, and which presents the chief characters of ganglionic tissue ; for
it is traversed by nervous filaments, which proceed from it as from a centre, and run in
various directions.
Its connexions with the inferior maxillary nerve are effected by its direct adhesion to
that nerve, which adhesion, according to Arnold, takes place by means of several very
short, nervous filaments {short root), which appear to come from the small root of the fifth
pair, and also by its adhesion to the internal pterygoid nerve ; so that, at first sight, the
ganglion would appear to originate from that nerve, or the nerve from the ganglion.
The otic ganglion is also connected with the glosso-pharyngeal by means of a filament,
which Arnold describes under the name of the small superficial petrosal nerve, to distin-
guish it from the great superficial petrosal, or cranial branch of the vidian. This fila-
ment, which proceeds from the nerve of Jacobson, or tympanic branch of the glosso-pha-
ryngeal, is compared by Arnold to the Imig root of the ophthalmic ganglion : it passes
out of the cavity of the tympanum by a special canal, in front of the hiatus Fallopii, runs
forward and outward (from 7 towards c, fig. 296), emerges from the cranium through a
special foramen, between the petrous portion of the temporal bone and the spinous pro-
cess of the sphenoid, and proceeds (above I, Jig. 300) to enter the otic ganglion.* Ar-
nold admits a third root for the otic ganglion, namely, a soft root, which he traces from
the nervous plexus that surrounds the middle meningeal artery, and is derived from the
great sympathetic.
The preceding filaments may be regarded as the filaments of origin of the otic gan-
glion.t
The Branches which proceed from the Otic Ganglion. — The principal filament from the
otic ganglion runs backward and upward towards the canal which contains the internal
muscle of the malleus, and is lost in that muscle. This twig must be carefully distin-
guished from the small superficial petrosal nerve, which is placed above it. Some other
filaments join the auriculo-temporal nerve, which generally arises by two roots.
Lastly, the otic ganglion sends off a twig to the circumflexus palati muscle.
The Sixth Pair, or External Motor Nerves of the Eyes.
The very simple distribution of the external motor nerve of the eye, or sixth crania}
nerve, contrasts strongly with that of the fifth nerve ; it arises from the furrow between
the pons Varolii and the medulla oblongata, immediately forms two fasciculi or roots, a
large and a small, which unite in the cavernous sinus ; they pass vertically upward, per-
forate the dura mater {b, fig. 296) at the side of the basilar groove by one or two open-
ings, to the inner side of and below the fifth nerve, gain the apex of the petrous portion
of the temporal bone, over which they turn, and then pass horizontally forward to enter
the cavernous sinus. During the course of the nerve through that sinus, it rests upon
its lower wall, crosses (above 6, fig. 301) on the outer side of the vertical portion of the
internal carotid artery, around which it turns, and then runs along its horizontal portion.
The sixth nerve forms a most important anastomosis, on account of which it was for a
long time regarded as the origin of the great sympathetic. As it crosses the internal
carotid in the cavernous sinus, it communicates by one or two filaments with the supe-
rior cervical ganglion. It also communicates, at the same point, with the ophthalmic
division of the fifth nerve.
Lastly, it enters the orbit through the widest part of the sphenoidal fissure, passes
through the fibrous ring which is common to it and to the inferior division of the com-
mon motor nerve, crosses, at an acute angle, beneath the ophthalmic nerve, and gains
the inner surface of the external rectus, and penetrates that muscle, after having ex-
panded into a pencil of very delicate filaments.
We shall again advert to the communication between this nerve and the superior cer-'»
vical ganglion.
* This small superficial petrosal nerve is very distinct from the great superficial petrosal nerve, being situ
ated in front of and parallel to that nerve. In a subject which I dissected in J826, I found this small nerve
presenting the following peculiarity : it had a well-marked nodule or ganglion, which gave off a filament to
the middle meningeal artery, and some small twigs, which appeared to me to be lost in the substance of the
sphenoid bone ; but I did not discover the connexions of this nerve.
t Arnold admits an indirect communication between the otic gan!>;lion and the acoustic nerve through the
intervention of the facial nerve. The existence of this communication appears to me very doubtful, as well
as the communication of the otic ganglion with the great sympathetic, by means of the twigs on the middle
meningeal artery
THE FACIAL NERVE. 839
The Seventh Pair of Nerves
The Portio Dura, or the Facial JVerve.
We have already traced the facial nerve, or the portio dura of the seventh, from its on
gin to the internal auditory meatus, which it enters together with the auditory nerve (7,
Jig. 296), which nerve lies below and behind the facial, and forms a groove for its recep-
tion. Having reached the bottom of the internal auditory meatus, this nerve follows the
long course of the facial canal,* or aqueduct of Fallopius, a winding passage which is
formed in the petrous portion of the temporal bone, and which opens by one end into the
internal auditory meatus, and, by the other, upon the lower surface of the pars petrosa
at the stylo-mastoid foramen.
The facial nerve traverses this canal, which is exclusively appropriated to it ; it is at
first directed outward (n, fig. 296), and, after proceeding for about a line, bends sudden-
ly, and runs backward, in the substance of the internal wall of the cavity of the tympa-
num, above the fenestra ovalis. Having reached the back of the tympanum, it forms
another bend, and passes vertically downward (o, figs. 298, 300) to the stylo-mastoid fo-
ramen. It follows, therefore, that the facial nerve describes two curves, like the aque-
duct of Fallopius, and is horizontal in its first two portions and vertical in the third.
On emerging from the stylo-mastoid foramen, the facial nerve runs forward in the
substance of the parotid gland, and, after a course of about five or six hues, divides into
two terminal branches, the temporo-facial (g, fig. 285) and the cervico-facial (/), which
expand into a great number of diverging filaments, and cover the temples, the whole of
the face, and the upper part of the neck, with their radiations and anastomoses.
The facial nerve gives off and receives certain collateral branches before and others
after its exit from the stylo-mastoid foramen.
The Collateral Branches of the Facial Nerve, before its Exit from the Stylo-mastoid Foramen.
In the internal auditory meatus the facial nerve receives some twigs from the auditory,
a remarkable anastomosis, which deserves the attention of physiologists.
Opposite to the hiatus Fallopii, i. e., at the first bend formed by the Fallopian aque-
duct, the facial nerve is joined by the cranial branch of the vidian, or the great super-
ficial petrosal nerve (c> figs. 296, 300). According to MM. Ribes, Hippolyte Cloquet,
and Hirzel, this branch is applied to the facial nerve, but does not anastomose with it,
and is detached from it lower down to constitute the chorda tympani nerve ; and as the
cranial branch of the vidian arises from the spheno-palatine ganglion, and the chorda
tympani is supposed to enter the sub-maxillary ganglion, it is seen that, according to
this view, the cranial branch of the vidian and the chorda tympani, which is regarded
as its prolongation, would establish a communication between the spheno-palatine and
sub-maxillary ganglia. It is by no means proved, however, that the chorda tympani en-
ters the sub-maxiUary ganglion ; and, again, the supposed connexion between the cra-
nial branch of the vidian and the chorda tympani is opposed to facts. The cranial
branch of the vidian and the facial nerves, indeed, are not in mere juxtaposition, but
anastomose and are blended with each other, and the chorda tympani has no sort of re-
lation to the former of these nerves. This independence of the branch of the vidian
nerve and the chorda tympani can be most clearly seen when the parts have been ma-
cerated in diluted nitric acid.t
If an explanation must be given of this remarkable anastomosis between the vidian
and facial nerves, I would say that the cranial branch of the vidian may be regarded as
a remote origin or a re-enforcing branch of the facial nerve.
The facial nerve, according to Soemmering and those who have followed him, gives
off a twig to the internal muscle of the malleus, and another to the small muscle of the
stapes ; but, in the first place, the existence of a stapedius muscle is doubtful, and, con-
sequently, the existence of a corresponding nervous twig must also be so, and, in the
second place, the internal muscle of the malleus is not supplied from the facial nerve,
but from the inferior maxillary division of the fifth nerve, and more especially from that
pulpy, reddish tissue, named by Arnold the otic ganglion.
Before leaving the aqueduct of Fallopius, the facial nerve (n,fig. 296) gives a remark-
able filament, named the chorda tympa7ii, which pursues a recurrent course (y) from be-
low upward in a peculiar canal, parallel to the aqueduct of Fallopius, enters the cavity
of the tympanum through an opening to the inner side of and behind the attachment of
the membrana tympani, passes downward and forward through the cavity of the tym-
* For what purpose is this long- course within the petrous portion of the temporal bone ? Those physiolo-
gists who believe the facial nerve to be of a mixed nature, that is, both sensory and motor, have laid great
stress upon this point, which they conceive to be favourable to their views ; but there is not the slightest
shadow of a proof that the facial nene possesses these two properties.
t Arnold has pointed out, at the junction of the cranial branch of the vidian with the facial nerve, a gangli-
form swelling, which he regards as a transition between a gangliform enlargement and a true ganglion ; from
this swelling, which he compares to the ganglia of the posterior roots of the spinal nerves, he says a filament
is given off to anastomose with the auditory nerve at the bottom of the internal .auditory meatus. I have not
been fortunate enough to discover this filament ; nor have I ever seen any gangliform appearance at the junc-
tion of the vidian and facial nerves.
840 NEUKOLOGY.
panum, between the handle of the malleus and the vertical ramus of the incus, and
emerging from that cavity {x,fig. 298), not through the Glasserian fissure, but through a
special opening already described (see Organ of Hearing — Cavity of the Tympanum), is
applied to the lingual nerve («), of which it may be regarded as a late origin, or re-enfor-
cing branch.
The facial branch also receives, in the aqueduct of Fallopius, opposite to where it gives
off the chorda tympani, a very remarkable branch from the pneumogastric nerve, which
Arnold has named the auricular branch of the pneumogastric.
The Collateral Branches of the Facial Nerve, after its Exit from the Stylo-mastoid Foramen.
Before its terminal division, the facial nerve gives off two branches, the posterior
auricular and the styloid. I have never seen any parotid branch, properly so called.
The posterior auricular, which would be better named the auriculo-occipital, comes ofl
from the nerve within the stylo-mastoid foramen, and is immediately applied against the
mastoid process, turning round over its anterior and then its outer surface ;* as it lies in
front of the mastoid process, it anastomoses with a remarkable twig from the deep auric-
ular branch of the auricularis magnus from the cervical plexus ;t after this, it divides
into two branches : an ascending or auricular branch {m, fig. 299), properly so called,
which, having first supplied, then perforates the posterior auricular muscle, turns round
the auricle, and terminates in the superior auricular muscle ; and a horizontal or occipital
branch («, fig. 285), which is larger, and forms the continuation of the nerve ; it passes
immediately beneath the posterior auricular muscle, to which it gives some filaments,
then runs exactly along the superior semicircular line of the occipital bone, and termi-
nates by giving off from its upper side a series of small filaments, which are lost in the
occipital portion of the occipito-frontalis : they can be traced as far as the median line,
but none of them are distributed to the skin.
The styloid branch arises from the back of the facial nerve, at its exit from the stylo-
mastoid foramen, and enters the stylo-hyoid muscle, after having run along its upper
border.
The posterior mastoid or digastric branch often arises by a common trunk with the pre-
ceding, enters the posterior belly of the digastric muscle, and sends off an anastomotic
twig to the glosso-pharyngeal nerve.
The Terminal Branches of the Facial Nerve.
The Temporo-facial Nerve.
The temporo-facial nerve {g, fig. 285) passes upward and forward in the substance of
the parotid, forming, with the trunk of the facial nerve, an arch having its concavity
turned upward ; it crosses the neck of the condyle of the lower jaw, and receives in this
situation, by its deep surface, one, or sometimes two branches from the auriculo-tempo-
ral nerve, a branch of the inferior maxillary. This anastomotic branch establishes a
very important connexion between the fifth and facial nerves.
The temporo-facial nerve, which is flattened and plexiform where it is joined by the
branch from the fifth, afterward expands into a number of filaments, which anastomose
with each other, so as to form arches, from the convexity of which a number of diverging
filaments of unequal size proceed like rays, and cover the whole space comprised be-
tween a vertical line drawn in front of the ear, and a horizontal line corresponding to the
base of the nose.
All these branches, which anastomose several times with each other, and form a suc-
cession of arches somewhat resembling those of the mesenteric arteries, may be divided
into the temporal, the orbital, and the infra-orbital or buccal branches.
The temporal branches ascend, cross over the zygomatic arch at right angles, and cov-
er with their ramifications the whole of the temporal and frontal regions, anastomosing
with filaments from the frontal branch of the first [from the orbital branch of the second],
and from the auriculo-temporal branch of the third division of the fifth nerve.
All these branches lie between the skin and the temporal aponeuroses ; some of them
supply the skin, but* the majority are distributed to the frontal portion of the occipito-
frontalis muscle, below which they are situated, and may be traced as far as the median
line.
The orbital branches may be divided into the superior palpebral, which are remarkably
long, and pass beneath the orbicularis palpebrarum, to ramify in that muscle and the
corrugator supercilii. Several of these anastomose with twigs from the supra-orbital
nerve : the middle palpebral branches. Which gain the outer angle of the eyelids, and are
distributed between the upper and lower eyelids, and the superior palpebral branches,
which are generally named the malar branches ; they pass horizontally forward, opposite
to the lower part of the orbicularis palpebrarum, and are reflected upward, to enter the
* This little nerve is lodged in the furrow between the mastoid and vaginal processes (see Osteology,
p. 43).
t [It is also joined, according to Arnold, by a filament from the auricular branch of the pneumogastric (sea
note, p. 844).
THK CERVICO- FACIAL NERVE. 841
substance of the lower eyelid, between the palpebral aponeurosis and the palpebral por-
tion of the orbicularis, in which they terminate.
They may be traced as far as the free border of the tarsal cartilage, where they anas-
tomose with each other.
The infra-orbital or buccal branches of the temporo-facial are given off from one or two
large branches which accompany the Stenonian duct ; they expand into a great number
of filanients, which may be divided into a superficial and a deep set : the superficial branch-
es ran beneath the skin, and above the orbicularis oris, the two zygomatic, and the le-
vator labii superioris, all of which they supply ; there can be no doubt that they also
give cutaneous filaments ; these are very small, and very long, and may be followed as
far as the hair follicles in the upper lip ; some of these superficial branches reach the
lower eyelid, several accompany the facial and angular veins, anastomose with twigs
from the infra-trochlear branch of the nasal nerve, and ascend as far as the pyramidalis
nasi, in which they terminate.
The deep branches pass beneath the levator labii superioris, send off numerous fila-
ments to that and the levator anguli oris, and form, together with the terminal divisions
of the infra-orbital branch of the superior maxillary, a very remarkable plexus, which
may be called the infra-orbital.
This plexus is formed by the interlacement of the radiating branches of the facial
nerve with those of the infra-orbital branch of the superior maxillary division of the fifth
nerve. Now, as the facial nerve radiates from without inward, and the infra-orbital
from above downward, it follows that the branches of these two nerves meet each other
at right angles. This arrangement can be rendered more evident by pulling the two
sets of nerves in the direction of their length. Most of these branches interlace with-
out anastomosing, and proceed directly to their destination. The destination of the
facial nerve is evidently rather to the muscles than to the skin ; that of the infra-orbital
branch of the fifth nerve is rather to the skin and mucous membrane than to the mus-
cles ; nevertheless, it cannot be doubted that the facial nerve supplies some cutaneous
filaments, and that the fifth nerve gives some twigs to the muscles. Besides, there are
some undoubted anastomoses between these two nerves. The facial also communicates
very freely with the buccal nerve, a branch of the inferior maxillary.
The infra-orbital branches of the temporo-facial nerve supply the two zygomatics, the
levator labii superioris, the levator labii superioris alaeque nasi, the depressor alae nasi,
the transversalis nasi, the levator anguli oris, and the orbicularis oris. I would also
point out a very remarkable branch, which enters the substance of the ala of the nose,
and appears to be intended for that sort of sphincter muscle found in the cutaneous fold
of the alae. This branch anastomoses with the naso-lobar branch of the internal nasal
nerve.
The infra-orbital branches of the fifth nerve are distinguished from the infra-orbital
branches of the facial nerve, by their direction ; by being more deeply seated ; by being
much larger ; and by being arranged in successive layers, which are three in number :
a sub-cutaneous, a sub-mucous, and a muscular ; this last set perforates the orbicularis
oris, in which some filaments appear to terminate. Among the infra-orbital branches
of the fifth nerve, there is one which may be called the nerve of the sub-septum, which
runs on the side of the median line, as far as the tip of the nose, where it terminates.
Lastly, the infra-orbital branches of the fifth give a dorsal branch for the nose, and two
ascending palpebral branches, which can be easily distinguished from the palpebral
branches of the facial nerve.
The Ccrvico-facial Nerve.
The ccrvico-facial nerve (/, fig. 285), which is smaller than the temporo-facial, follows
the original course of the facial nerve, and, like it, runs downward and forward in the
parotid gland ; opposite to the angle of the lower jaw it divides into three or four branch-
es, which subdivide into secondary branches, which may be arranged into the buccal, men-
tal, and cervical sets.
The buccal branches run horizontally forward in front of the masseter, to which they
give off" some small filaments, and then anastomose with each other and with the infra-
orbital branches of the temporo-facial nerve. A very beautiful anastomosis is found be-
tween the buccal branch of the inferior maxillary and one of these buccal branches of
the cervico-facial nerve : we have already pointed out a similar anastomosis between
an infra-orbital branch of the temporo-facial and this same buccal branch of the inferior
maxillary.
The mental branches are intended for the lower lip. They are reflected upward, so as
to describe an arch having its concavity directed upward ; they are at first situated be-
neath the platysma myoides, then pass beneath the triangularis oris, and form, with the
mental branch of the inferior maxillary division of the fifth nerve, an interlacement or
mental plexus, which has a close analogy with the interlacement of the infra-orbital
branches of the facial with those of the superior maxillary division of the fifth nerve, but
is less comnlicated.
50
842 NEUROLOGY.
Thus, the mental branches of the facial nerve are more superficial than those of the
fifth, and their filaments are smaller ; the radiating branches of the facial nerve run at
first forward and then upward, while those of the fifth nerve run directly upward. The
mental brandies of the facial nerve perforate the quadratus rnenti and the orbicularis
oris, to which muscles they are almost entirely distributed ; they also send several long
and slender filaments to the point of the chin, some of which are cutaneous. The men-
tal branches of the fifth nerve are chiefly situated between the muscles and the mucous
membrane, to w hich latter they are distributed, more especially to the free borders of
the lower lip.
The cervical branches of the cervico-facial run forward in the supra-hyoid region, be-
neath the platysma, and, describing arches with their concavities turned upward, they
pass upward and forward to terminate near the chin. Among these branches, there is
one which passes vertically downward to anastomose with the superficial cervical nerve
of the cervical plexus.
The cervical branches of the facial nerve are separated from the cervical branches of
the cervical plexus by the platysma, and they are all distributed to that muscle and the
levator labii superioris.
Summary. — The facial nerve supplies all the cutaneous muscles of the cranium and
of the face, and, therefore, section and compression of this nerve cause complete paral-
ysis of these muscles : it is the nerve of expression, or the respiratory nerve of the
face {Bell) ; it also evidently gives off some cutaneous filaments, especially near the
commissure of the lips, and this may explain the numbness which I have known to oc-
cur in individuals affected with hemiplegia of the face ; lastly, it furnishes a great num-
ber of anastomotic filaments (whence it has been called the small sympathetic) ; these
are given to the branches of the cervical plexus, to the auditoiy nerve, to the pneumo-
gastric, and more especially to the fifth nerve.
The anastomoses of the facial with the fifth nerve merit special notice ; they are ef-
fected with the frontal and nasal nerves of the ophthalmic or first division of the fifth ;
with the superior maxillary or second division by means of the infra-orbital nerves and
the cranial branch of the vidian, which latter I even regard as one of the origins of the
facial nerve ; and with the inferior maxillary or third division of the fifth by means of
the mental nerve, the buccal nerve, and more especially the auriculo-temporal nerve.
The branch given by the auriculo-temporal to the facial nerve may be regarded as one
of the origins of the last-mentioned nerve.
Notwithstanding these numerous anastomoses, the facial nerve and the fifth nerve
cannot supply the place of each other. Anatomy shows no difference in the structure
of these nerves, but a great difference in their distribution ; the facial nerve being in-
tended for the muscles, while the fifth is distributed to the integuments and the organs
of the senses.
Function. — The facial is a nerve of motion. This fact may be deduced from its ana-
tomical description no less than from physiological experiments and the effects of disease.
The Portio Mollis, or the Auditory J^erve.
The auditory nerve (7, figs. 296, 301), which we have already traced as far as the in-
ternal auditory meatus, enters that canal with the facial nerve, for which it forms a
groove, and divides into two cords, which remain distinct throughout the whole extent
of the passage, but continue in contact with each other, and at length pass through the
foramina in the cribriform plate already described as existing at the bottom of the meatus
(see Osteology).
In order to understand the farther distribution of the auditory nerve, the cribriform
plate of the auditory meatus must be examined with the same attention as was devoted
by Scarpa to the cribriform plate of the ethmoid, with which it has so many analogies.
As the cribriform plate of the ethmoid presents a particular fissure for the passage of the
ethmoidal branch of the ophthahnic nerve, so the cribriform plate of the internal auditory
meatus presents a special opening for the passage of the facial nerve ; and again, the
auditory, like the olfactory nerve, seems as if it were pressed through the foramina of
the cribriform plate to enter the internal ear.
Of the two terminal branches of the auditory nerve, the anterior is intended for the
cochlea, the posterior for the vestibule and semicircular canals.
The cochlear branch turns spirally, like that part of the bottom of the auditory meatus
to which it belongs, and which is called the tractus spiralis. It then turns upon itself,
as observed by Valsalva, and presents somewhat of a ganglionic appearance. From this
sort of enlargement the cochlear filaments proceed ; those which belong to the first turn
of the cochlea run along the surface of the modiolus ; the others enter the canals of the
modiolus, and are distributed on the second, and the succeeding half turn at the summit
of the cochlea. I have already described the very regular manner in which these fila-
ments spread upon the spiral septum, the subdivision of each of them into two or three
filaments, which anastomose with each other lite the ciliary nerves, and the gradual dim-
inution in the length of these filaments from the base to the apex of the cochlea ; so that,
THE GLOSSO-PHARYNGEAL NERVE.
it we suppose the spiral septum spread out, it might be compared to a harpsichord, the
longest strings of which would be represented by the filaments at the base of the trian-
gle formed by the septum, and the shortest by those at its apex (see Internal Eae, p. 681).
The vestibular branch divides into three parts, the largest of which enters the utricle
and the ampullce of the superior vertical and horizontal membranous canals, the middle,
sized branch passes to the sacculus, and the smallest branch to the ampulla of the pos-
terior or inferior vertical semicircular canal.
Function. — The auditory nerve is exclusively the nerve of hearing.
The Eighth Pair op Nerves.
The First Portion, or Glosso-Pharyngeal JVerve.
Dissection. — Remove, by a triangular section, the posterior half of the border of the
foramen lacerum posterius ; carefully detach the jugular vein, in front of which the
nerves are situated, examine the connexions of the glosso-pharyngeal with the pneumo-
gastric and spinal accessory nerves.
The glosso-pharyngeal nerve {pharyngo-glossal), the anterior portion of the eighth nerve
(8, Jigs. 296, 301), the ninth nerve of some authors, is intended for the pharynx and the
tongue.
Having arisen from the restiform body, above and on a line with the pneumogastric,*
by a series of roots which are continuous with the roots of that nerve, the glosso-pharyn-
geal emerges from the foramen lacerum posterius through a fibrous canal which is prop-
er to it, and which is situated in front of the canal that is common to the pneumogastric
and spinal accessory nerves ; it is placed to the inner side of the internal jugular vein,
from which it is separated by a cartilaginous and sometimes osseous lamina.
During its passage through this canal it presents a ganglionic enlargement, which was
described by Andersh under the name of ganglion petrosum, and is now more generally
known as the ganglion of Andersh.
This ganglion is situated in a depression on the petrous portion of the temporal bone
{receptaculum ganglii petrosi) ; from it the nerve pro- Pig. 301.
ceeds as a rounded cord, which descends vertically
(I, fig. 301) behind the styloid muscle in front of the
internal carotid, then between the stylo-pharyngeus
and the stylo-glossus, and passing forward so as to
describe a curve with its concavity turned upward,
runs in front of the posterior pillar of the fauces and
behind the tonsil, and then passing beneath the hyo-
glossus muscle (2), ramifies, to enter the base of the
tongue and supply the mucous membrane.
During this course it gives off the nerve of Jacob-
son, and an anastomotic twig to the facial nerve ; it
communicates with the spinal accessory and the
pneumogastric ; it gives off a muscular branch to
the digastricus and stylo-pharyngeus, and it supplies
some carotid filaments, and some pharyngeal and
tonsillar branches.
The Nerve of Jacobson. — In order to facilitate the
study of the course of this nerve, I shall first de-
scribe the canals through which it passes :
Upon the ridge which separates the jugular fossa
from the carotid canal, to the outer side of the aqueduct of the cochlea, is found an open-
ing, which is the inferior orifice of the canal of Jacobson. This canal runs backward
and upward into the substance of the internal wall of the cavity of the tympanum, in
front of the fenestra rotunda ; there it branches into three canals : one descending, which
opens into the carotid canal ; and two ascending canals, an anterior, which runs forward
and upward, and opens into the groove for the great superficial petrosal or cranial branch
of the vidian nerve, and a posterior, which at first ascends vertically behind the fenestra
ovalis, then curves suddenly and becomes horizontal, and opens upon the upper surface
of the pars petrosa in a groove parallel to and on the outer side of the groove for the
cranial branch of the vidian nerve.
The nerve of Jacobson, which comes off from the petrosal ganglion, or ganglion of An-
dersh, enters this canal. In one subject I found it to consist of two filaments, one from
the pneumogastric, and the other from the glosso-pharyngeal. t
This nerve soon divides into three filaments corresponding to the three branches of the
* Several modern physiologists, believing the glosso-pharyngeal to be a mixed nerve, sensory in its lingual
portion, and motor in its pharyngeal, have, therefore, supposed it to have tviro distinct roots : a larger, which
is near the par vagum, and a smaller, v^hich lies near the facial nerve ; and, from analogy, they regard the
former as the sensory, and the latter as the motor root.
t In another subject it was formed by the anastomoses of a twig from the auricular branch of the pneumo-
gastric with a twig from the glosso-pharyngeal.
844 ■.i''.i:.: il/ NEUROLOGY.
canal ; the descending filament joins the carotid plexus ; of the two ascending lilaments,
one anastomoses with the cranial branch of the vidian, or the great superficial petrosal
nerve {v, Jig. 300), while the other constitutes the small superficial petrosal nerve, which
reaches the upper surface of the pars petrosa in front of the preceding, and terminates
in the reddish tissue known as the otic ganglion.*
It follows, therefore, that the nerve of Jacobson connects the glosso-pharyngeal nerve
with the superior maxillary division of the fifth nerve (especially with the spheno-pal-
atine ganglion through the intervention of the vidian nerve), with the otic ganglion of
the inferior maxillary division, and with the superior cervical ganglion of the sympathetic.
The anastomotic branch to the facial nerve arises from the ganglion of Andersh imme-
diately below the nerve of Jacobson ; it runs downward and outward behind the styloid
process, is then reflected upward, so as to describe a loop with its concavity turned up-
ward, and anastomoses with the facial immediately after the exit of that nerve from the
stylo-mastoid foramen. This branch appears to me to be the remaining trace of a con-
siderable branch of the facial nerve, which I have seen partially supplying the place of
the glosso-pharyngeal (see the Tongue, p. 646).
The Anastomosis of the Glosso-pharyngeal with the Spinal Accessory and Pneumogastric
Nerves. — Most commonly the glosso-pharyngeal runs along the pneumogastric, or, more
correctly, along the anastomotic branch of the spinal accessory. Sometimes it is com-
pletely separated from these nerves, and merely communicates with them by means of
its pharyngeal branches.
The Branch for the Bigastricus and Stylc-hyoideus. — This branch comes off from the outer
side of the nerve, and bifurcates ; one of its divisions enters the posterior belly of the digas-
tricus, and the other supplies the stylo-pharyngeus and stylo-hyoideus. It has already been
stated that this branch anastomoses with the facial nerve in the digastric muscle.
The Carotid Filaments. — These are very numerous ; they descend along the internal
carotid artery, and, having reached the point of bifurcation of the common carotid, anas-
tomose with the carotid filaments of the superior cervical ganglion, and assist in form-
ing the arterial plexus. I have not been able to trace them below the bifurcation of the
common carotid. Some of these filaments are described as joining the cardiac nerves.
The Pharyngeal Branches. — These are two or three in number ; they anastomose with
the pharyngeal branches of the pneumogastric, to constitute the pharyngeal plexus. These
branches evidently supply the middle and superior constrictors. The filaments for the
latter muscles are reflected upward upon the posterior surface of the pharynx.
The tonsillar branches are very numerous, and form a sort of plexus.
The Lingual Branches. — After having given off the different branches above mentioned,
the glosso-pharyngeal, reduced to half its original size, enters the base of the tongue, and
then r-amifies ; some of its lingual branches lie close beneath the mucous membrane ;
others traverse the upper layers of the muscular substance of the tongue to proceed to
the mucous membrane in front of the preceding branches ; they are all intended for the
mucous membrane ; the internal branches proceed from without inward at the side of the
median line, while the external runs along the border of the tongue ; I have never seen
any filament terminating in the muscular fibres.
Function. — From its distribution, this nerve must be regarded as a motor nerve for the
pharynx, and a sensory nerve for the base of the tongue.
The Second Portion of the Eighth J^erve, or the Pneumogastric Jferve.
Dissection. — Lay open the back part of the foramen lacerum posterius, and afterward
examine the nerve in the different parts of its course successively.
The pneumogastric nerve, called also the vagus nerve, the par vagum, and the tenth era/-
niaX nerve of some modern authors, is the principal branch of the eighth nerve (8, fig. 301),
and is one of the most remarkable nerves in the body, both on account of the extent of
its distribution, and of the importance of the organs supplied by it. It supplies branches,
on the one hand, to the larynx, the lungs, and the heart ; and, on the other, to the pharynx,
the oesophagus, the stomach, and the solar "plexus.
It has already been stated that this nerve arises from the upper part of the medulla ob-
longata, upon the restiform bodies, and in a line with the posterior roots of the spinal
nerves ; that its filaments of origin converge, and then unite at first into seven or eight
fasciculi, and then into a single cord, which passes towards the foramen lacerum poste-
rius, through which it emerges from the cranium. The pneumogastric nerve then mns
vertically {p,fig. 301) in the neck along the vertebral column, enters the thorax, runs
along the oesophagus, with which it passes through the diaphragm, and terminates on
the stomach and in the solar plexus.
We shall now proceed to examine this nerve while it is within the foramen lacerum
* Arnold admits six filaments for the nerve of Jacobson, and, consequently, six small ducts as branches of
the canal of Jacol)son ; these six filaments consist of the three described in the text above, and of a twig for
the fenestra rotunda, one for the fenestra ovalis, and one for the Eustachian tube. I have distinctly seen the
twig for the fenestra ovalis, that is to say, a twig which reaches the margin of the fenestra ovalis, but cannot
be traced any farther. I have also seen the twig which passes to the Eustachian tube ; but I have not yet
been able to find the twig for the fenestra rotunda.
THE PNEUMOGASTEIC NERVE. 845
posterius ; as it is emerging from that foramen ; and as it descends in the neck, in the
thorax, and in the abdomen.
The Pneumogastric Nerve witfdn th£ Foramen Lacerum Posterius.
At the foramen lacerum posterius, the pneumogastric nerve passes through the same
opening as the spinal accessory, which lies in contact with it ; a fibrous, cartilaginous,
or bony septum separates it from the glosso-pharyngeal, which lies in front of it ; and an-
other cartilaginous and often bony septum separates it from the internal jugular vein.
As it is passing through the foramen it presents a well-marked ganghonic structure ;
I would say, rather, a gray substance containing white nervous filaments, but without any
observable swelling : hence most anatomists have denied the existence of a ganglion at
this spot.
To this ganglion, the ganglion of the pneumogastric, which may be compared to the
Gasserian ganglion and to the inter-vertebral ganglia, the spinal accessory nerve is ap-
phed, and is connected with it by several very delicate filaments. I have already sta-
ted that, not unfrequently, the highest roots of the spinal accessory nerve join the pneu-
mogastric directly.
This ganglion gives off an anastomotic twig, which enters the petrosal ganglion of the
glosso-pharyngeal : I have not always found this filament ; it also gives an anastomotic
branch to the facial nerve, viz., the auricular branch of the pneumogastric of Arnold. This
branch might be called, the branch of the jugular fossa ; it can be very well seen through
the coats of the jugular vein when that vessel is laid open. It runs along the anterior
part of the jugular fossa, between it and the internal jugular vein, gives off an anasto-
motic twig to the nerve of Jacobson, enters the temporal bone through an opening in the
jugular fossa, near the styloid process, and traverses a very short canal, which conducts
it directly into the Fallopian aqueduct, in which it anastomoses with the facial nerve.*
The Pneumogastric Nerve, at its Exit from the Foramen Lacerum Posterius.
At its exit from the foramen lacerum posterius, the pneumogastric nerve presents the
appearance of a plexiform cord, which is often accompanied by the gray matter of the
ganglion for the space of about six lines or an inch. This plexiform cord has certain
important connexions with the spinal accessory, the ninth or hypo-glossal nerve, the glos-
so-pharyngeal nerve, and the superior cervical ganglion.
It is joined by one of the branches of bifurcation of the spinal accessory, which we
shall name the internal or anastomotic branch ol the spinal accessory nerve ; it becomes
applied to the pneumogastric nerve, and may be distinguished from it for a considerable
distance.
It also anastomoses with the hypo-glossal, at the point where it is crossed by that
nerve, and at other times above that point. This anastomosis, moreover, is subject to
great variety ; sometimes it takes place by a very small filament, at other times by two
or three twigs, which form a sort of plexus.
It also anastomoses with the glosso-pharyngeal. The examination of this anastomo-
sis, after the parts had been macerated in diluted nitric acid, enabled me to see that it
is not, properly speaking, effected with the pneumogastric nerve, but with the anasto-
motic branch of the spinal accessory. Nothing can be more variable than these anasto-
moses, which are sometimes wanting on one side, and which are rather frequently ef-
fected through the intervention of the pharyngeal branches.
Lastly, the pneumogastric nerve commu)iicates with the great sympathetic by one or
two branches in man and some mammalia ;t in the- other classes of animals the con-
nexion is so intimate that it is altogether impossible to separate the pneumogastric from
the superior cervical ganghon.
The connexions of the pneumogastric with the spinal accessory and superior cervical
ganghon are two very important points in its anatomy, t
The Pneumogastric Nerve in the Neck.
In the cervical region, the pnemnogastric nerve {p,figs. 298, 300, 301) is situated in
front of the vertebral column, the praevertebral muscles intervening between them, upon
the side of the pharynx and oesophagus, and between the internal and then the common
carotid, which are on its inner side, and the jugular vein, which is on its outer side ; it is
placed behind these vessels. It is closely applied to the carotid artery, being in the same
* I have seen this branch, immediately after its origin, enter the sheath of the glosso-pharyngeal nerve, run
along its ganglion, and then curve backward to enter the jugular fossa. Arnold, who first described this anas-
tomotic branch, represents it as divided into three filaments : an ascending, which anastomoses with the trunk
of the facial nerve ; a descending, which anastomoses with the posterior auricular branch of the same nerve ;
and a middle {u,fig. 299), which ramifies upon the external auditory meatus.
t I have seen the pneumogastric nerve communicate with the great sympathetic, by filaments which come
off at different heights from the cervical ganglion ; two proceeded from tlie upper part of the superior cervical
ganglion, and then ascended ; and two came from the lower part of the ganglion, and descended to unite with
the pneumogastric. I have met with a case in which the superior cervical ganglion was applied in its whole
extent so closely to the pneumogastric that it was impossible to separate them.
t [The pneumogastric also receives a filament from the anastomotic loop of the first and second cervical
iif rvcs (see p. 777). J
846 NEUROLOGY.
sheath : it is separated from the cervical portion of the great sympathetic (i), which lies
behind and to the outer side of it, by a great quantity of cellular tissue.
During this course it supplies the pharyngeal branch, the superior laryngeal nerve, and
the cardiac filaments.
The Pharyngeal Branch, or Small Pharyngeal Nerve. — This is often double, and is then
distinguishable into a superior and an inferior ; it comes off at a little distance from the
foramen lacerum posterius, but its real origin is variable. In some cases it arises ex-
clusively from the pneumogastric ; at other times exclusively from the anastomotic
branch of the spinal accessory, which, as already stated, does not become immediately
blended with the pneumogastric ; and it often arises both from the pneumogastric and
the spinal accessory : lastly, the glosso-pharyngeal sometimes gives it a filament. It
passes behind the internal carotid, gives off" some carotid filaments, which join the more
numerous twigs from the glosso-pharyngeal, and then anastomoses with the ramifica-
tions of the glosso-pharyngeal, and with several large branches from the superior cervi-
cal ganglion, to form the pharyngeal plexus, which is one of the most remarkable plex-
uses in the body, and to which the varied and frequent nervous phenomena observed in
that region must be referred. I shall recur to this plexus when describing the great
sympathetic.
The Superior Laryngeal Nerve {x',fig. 301). — This is larger than the pharyngeal branch ;
it comes off" from the inner side of the pneumogastric* as a rounded cord, which may be
traced as high as the ganglion of the nerve ; it passes downward and inward upon the
side of the pharynx, behind the internal and external carotid arteries, which it crosses
obliquely : it then turns forward and inward to gain the thyro-hyoid membrane, passing
above the upper margin of the inferior constrictor of the pharynx ; it runs for some
time between the thyro-hyoid muscle and the thyro-hyoid membrane, perforates the lat-
ter at the side of the median line, and then enters the substance of the ar)rteno-epiglot-
tid fold of mucous membrane, where it terminates by dividing into a great number of fil-
aments.
During its course, it gives off a branch which is called the external laryngeal (y), and
which I have seen arise directly from the pneumogastric itself; this branch communi-
cates with the superior cervical ganglion by one or two filaments, and passes inward and
downward upon the side of the larynx. It gives off one or two filaments, which anasto-
mose with the superior cardiac nerve, behind the common carotid ; Haller calls this
communication between the external laryngeal and the great sympathetic the laryn-
geal plexus. \ The external laryngeal nerve also gives off several branches to the infe-
rior constrictor of the pharynx, some to join the pharyngeal plexus, and some twigs to
the thyroid gland ; it then passes downward and forward between the inferior constric-
tor and the thyroid cartilage, and terminates by ramifying in the crico-thyroid muscle.
The terminal expansion of the superior laryngeal nerve is remarkable for its radiated
arrangement ; it is preceded by a flattening and thickening of the nerve. These ex-
panded branches are all sub-mucous, and may be arranged into the anterior or epiglottid,
and the posterior.
The anterior or epiglottid branches are numerous and small ; they run upon the margin,
and on the fore part of the epiglottis ; some of them reach its free extremity, others run
between the fibro-cartilage of the epiglottis and the adipose tissue, called the epiglottid
gland ; some of them perforate the epiglottis, and ramify upon its posterior surface.
Among these anterior terminal filaments of the superior laryngeal nerve there is at
least one which runs forward under the mucous membrane covering the base of the
tongue, and may be traced as far as the two rows of glands, which are arranged like the
letter V. These filaments of the superior laryngeal nerve to the tongue are placed be-
tween the lingual branches of the right and left glosso-pharyngeal nerves, with which
they have probably been confounded.
The posterior or laryngeal filaments contained in the aryteno-epiglottid fold are more
numerous than the anterior branches ; they are divided into the mucous filaments, the
arytenoid filament, and the anastomotic or descending filameiit.
The mucous filaments are very numerous, and run upward in the aryteno-epiglottid
fold ; some of them lie beneath the external, and others beneath the internal layer of
mucous membrane of this fold. They are intended for these two layers, and they ter-
minate, for the most part, at the superior orifice of the larynx : their number explains
the exquisite sensibility of this opening. Some of these mucous filaments may be traced
into the substance of the arytenoid glands.
The filatnent for the arytenoid muscle is very liable to be confounded with the mucous
* It arises, therefore, on the opposite side to the anastomotic branch of the spinal accessory, which has not
appeared to me to assist in its formation. I have seen the superior laryngeal arise by two roots, the larger of
which came from the pneumogastric, while the other, which was very small, came from the glosso-pharyn-
geal. It appears to me that M. BischofTs remarks concerning the origin of the superior laryngeal nerve on a
level with tlie spinal accessory, would apply to the pharyngeal branch of the pneumogastric.
t The superior laryngeal nerve (x',Jig. 301) forms a loop behind the carotids, like tliat formed by the hypo-
glossal (d) in front of them, but lower down in the neck ; that portion of the nerve which runs between the
thyro-hyoid membrane and the thyro-hyoid muscle is exceedingly tortuous in some positions of the larynx.
THE PNEUMOGASTRIC NERVE IN THE THORAX, ETC. 847
filaments ; it perforates the muscle from behind forward, and is partly distributed to it
and partly to the lining membrane of the larynx.
The descending or anastomotic filament, which is small, but of variable size, descends
vertically, between the mucous membrane on the one hand, and the thyro- and crico-
arytenoid muscles on the other, gains the posterior surface of the cricoid cartilage, and
anastomoses upon it with the recurrent laryngeal nerve. This remarkable anastomosis
was known to Galen.*
Thus, the superior laryngeal nerve chiefly belongs to the mucous membrane of the
larynx ; but it gives branches to the arytenoid and crico-thyroid muscles : the branch
for the latter comes from the external laryngeal division of this nerve.
The Cardiac Branches of the Pneumogastric Nerve of the Neck. — These vary both in
number and size in different subjects, and even upon the two sides of the same body :
they come off at different heights from the trunk of the pneumogastric ; some of them,
after a course of variable extent, join the superior cardiac nerves, either in the neck or
in the thorax ; the others pass directly to the cardiac plexus. The most remarkable of
the cervical cardiac branches of the pneumogastric is that which comes off at the lower
part of the neck, a little above the first rib ; on the right side, it descends in front of the
common carotid, and then in front of the brachio-cephalic artery, below which it anasto-
moses with the superior cardiac nerve. On the left side, it passes in front of the arch
of the aorta, and anastomoses below that vessel with the superior cardiac nerve of that
side. This branch sometimes goes directly to the cardiac plexus : it is sometimes double.
The Pneumogastric Nerve in the Thorax.
The thoracic portion of the pneumogastric nerve presents this peculiarity, that it differs
remarkably on the right and left sides.
On the right side, the nerve {p,fig- 302) enters the thorax between the sub-claviaa
vein and artery : lower down, it passes behind the brachio-cephalic vein and the supe-
rior cava, and behind the phrenic nerve, at the side of the trachea, or, rather, in the
groove between the trachea and oesophagus : it then passes behind the root of the lung,
where it becomes flattened and enlarged, gives off a great number of branches, and ap-
pears to expand, in order to unite in a different arrangement. Below the root of the
lung the right pneumogastric is always divided into two flattened branches, which run
along the right side of the cesophagus, join together at a short distance from the dia-
phragm, and pass behind the cesophagus, with which canal the common trunk enters the
abdomen.
On the left side, the pneumogastric enters the thorax between the common carotid and
the sub-clavian artery, in the triangular interval between those vessels, internal to and
then behind the phrenic nerve, behind the brachio-cephalic vein, and to the left of the
arch of the aorta ;t it then passes behind the left bronchus, upon which it ramifies, and
unites again into one or two branches, which pass in front of the oesophagus, and enter
the abdomen with it.
In the thorax the pneumogastric gives off the recurrent or inferior laryngeal nerve, a
cardiac branch, some tracheal and oesophageal branches, and branches to the anterior and
posterior pulmonary plexuses.
The Recurrent or Inferior Laryngeal Nerve.t
This nerve (r, fig. 302), so called on account of its reflected course, arises in front of
the arch of the aorta on the left side, and of the sub-clavian artery on the right side : it
is sometimes so large that it may be regarded as resulting from the bifurcation of the
pneumogastric : it is reflected below and then behind the arch of the aorta on the left
side, and the sub-clavian artery on the right, so as to form a loop or arch, which has its
concavity turned upward, and which embraces the corresponding vessel. Having thus
changed its course from a descending to an ascending one, the recurrent nerve enters
the groove {q,fig. 301) between the trachea and the oesophagus, and continues to ascend
as high as the lower border of the inferior constrictor muscle of the pharynx ; it then
passes beneath that muscle, gives some filaments to it, runs behind the lesser cornu of
the thyroid cartilage and the crico-thyroid articulation, along the outer border of the
posterior crico-arytenoid muscle, and terminates by ramifying in the muscles of the
larynx.
During its course, the recurrent nerve gives off the following collateral branches : at
the point of its reflection, it gives several cardiac filaments, which unite with the cardiac
branches of the pneumogastric and great sympathetic. It is important to remark the
intimate connexion which exists between the recurrent and the cardiac nerves : some
very considerable anastomoses are almost always found between the superior and infe-
* See note, p. 848.
t The relation of the pneumogastric with the arch of the aorta explains the stretching and atrophy of this
nerve in aneurisms of that portion of the vessel.
1 Those anatomists who regard the superior laryngeal nerve as a dependance of the spinal accessory be-
lieve that the inferior or recurrent laryngeal has a similar origin. I may repeat, and with still more reason, in
reference to this nerve, what I have already stated in regard to the superior laryngeal, that it is impossible to
'«monstrate this continuity by dissection.
848 NEUROLOGY.
rior cardiac nerves and the recurrent nerve : sometimes, indeed, the recurrent nerve
forms the point at which the superior and middle cardiac nerves meet, and from which
the inferior cardiac nerve is given off; the anastomoses between the recurrent and car-
diac nerves sometimes form a true plexus.
The recurrent also gives oesophageal branches, which are much more numerous on the
left than on the right side, so that the left recurrent nerve is much smaller in the larynx
than the right nerve.
It also gives tracheal branches, which chiefly supply the posterior or membranous por-
tion of that canal.
And, lastly, some pharyngeal filaments, all of which are destined for the inferior con-
strictor.
Excepting an anastomotic branch* for the superior laryngeal nerve, all of the terminal
branches of the recurrent nerve are intended for the muscles of the larynx, and are thus
distributed :
The branch for the posterior crico-arytenoid simply enters that muscle.
The branch for the arytenoid, runs between the cricoid cartilage and the posterior crico-
arytenoid muscle, and then ramifies in the arytenoid. It has already been stated that
the last-named muscle is also supplied by the superior laryngeal nerve.
The branch for the lateral crico-arytenoid and thyro-arytenoid muscles is the true termina-
tion of the nerve ; it passes on the outer side of these two muscular bundles, which, as
formerly stated, constitute a single muscle in the human subject, and then enters them
by very delicate filaments. I have distinctly seen a very delicate filament entering the
crico-th)Toid articulation.
After the pneumogastric has given off the recurrent nerve, and often before doing so,
it furnishes certain cardiac branches (thoracic cardial) ; these are subdivided into the
pericardial, which run upon the outer surface of the pericardium, and are lost in it and
in the cellular tissue which replaces the thymus ; and into the cardiac branches, properly
so called, which assist in the formation of the cardiac plexus.
The pneumogastric also gives off certain anterior pulmonary branches, which run in
front of the bronchus and of the pulmonary arteries and veins, cross obliquely over them,
and then enter the substance of the lung, following the ramifications of the air-tubes and
bloodvessels ; these pulmonary branches form what is called the anterior pulmonary plex-
us. I have seen several of them extend some considerable distance beneath the serous
membrane, covering the inner surface of the lungs, before they entered the substance
of those organs.
Behind the bronchus, and along the oesophagus, the pneumogastric nerve gives off
posterior branches, consisting of a great number of esophageal branches ; of some tracheal
branches, which principally supply the back or membranous portion of the trachea ; and,
lastly, of posterior pulmonary or bronchial branches, which form the posterior pulmonary
plexus.
The posterior pulmonary plexus is one of the most remarkable in the body ; in it the
pneumogastric nerve appears to be decomposed and expanded ; there is a right and a
left pulmonary plexus. The left is much larger than the right. The two plexuses are
not independent of each other, but are connected by free anastomoses : this remarkable
disposition establishes a community of function between the two nerves, and explain*
how one of them may supply the place of the other.
The pulmonary plexuses, which are completed by filaments from the great sympathetic,
are situated behind the root of each lung, or, to speak more exactly, behind the bronchi
(whence the name of bronchial plexuses). A few of the twigs emerging from them follow
the pulmonary arteries, and appear to be lost in their coats ; the others accompany the
bronchi, some of them passing behind these canals, and others, being reflected forward
in the angles formed by their bifurcation, run along their anterior aspect, and terminate
in their parietes. They may be traced as far as the ultimate ramifications of the aii-
tubes. In large animals they can be easily seen entering the circular muscular fibres
which surround the bronchial tubes, t
Below the pulmonary plexus, the pneumogastric merely gives off certain cesophagcal
branches, which surround the oesophagus in very great numbers. The right and left
pneumogastric nerves anastomose with each other ; but the communicating arches do
not constitute those circular anastomoses, which have been so decidedly said to explain
the pain caused by swallowing too large a morsel of food.
The Pneumogastric Nerve in the Abdomxn.
The two pneumogastrics enter the abdomen with the oesophagus, the left nerve being
in front and the right nerve behind that canal, and are distributed in the following manner :
* [This anastomotic branch is superficial, and joins the descending filament from the superior laryngeal
nerve, beneath the mucous membrane on the back of the larynx, and sometimes sends filaments into the ary-
tenoid muscle ; there is, generally, a second anastomosis between the superior and inferior laryngeal nerves
on the side of the larynx, between the thyroid cartilage and the thyro-arytenoid muscle.]
t I have seen a nerve from the pulmonary plexus pass through some of the fibres of the oesophagus and ram-
ify iu the aorta.
SPJNAL ACCESSORY NERVE OF WILLIS. 849
The left nerve {q,fig. 302), which is situated in front of the cardia, expands into a very-
great number ot diverging filaments, some of which extend over the great cul-de-sac,
and others over the anterior surface of the stomach ; but the greater number gain the
lesser curvature, and divide into two sets or groups ; one of these leaves the lesser cur-
vature, enters the gastro-hepatic omentum, is conducted by it to the transverse fissure
of the liver, and enters that gland. The other group continues in the lesser curvature,
and may be traced as far as the duodenum.
The right pneumogastric (p'), situated behind the cardia, gives a much smaller number
of branches to the stomach than the left, and joins the solar plexus (z), of which it may
be regarded as one of the principal origins.
Summary of the Distrilmtion of the Pneumogastric Nerve. — This nerve, it wiU be seen,
has an extremely complicated distribution.
Within the foramen lacerum posterius, it anastomoses with the spinal accessory ; with
the facial nerve by means of the auricular branch of Arnold, or the branch of the jugular
fossa ; and with the nerve of Jacobson, and, therefore, with the glosso-pharyngeal nerve,
by a twig from the same auricular branch.
At its exit from the foramen lacerum posterius, it anastomoses with a Isirge branch of the
spinal accessory ; with the hypo-glossal ; with the glosso-phyrangeal ; and with the su-
perior cervical ganglion.
In the neck, it gives off the pharyngeal branch or small pharyngeal nerve, the superior
laryngeal nerve, and the superior cardiac branches of the pneumogastric.
In the thorax, it gives off the recurrent or inferior laryngeal nerve, which supplies
some cardiac, oesophageal, pharyngeal, tracheal, and laryngeal branches ; the inferior
cardiac branches ; and the pulmonary or bronchial branches.
In regard to its structure, the pneumogastric differs essentially from the other cerebro-
spinal nerves, by the tenuity of its filaments and by their plexiform arrangement ; and
in both of these particulars, as well as in its distribution, it rather resembles the nerves
of organic than those of animal life. In the description of the sympathetic it will be
seen how intimate are its relations with the pneumogastric nerve.
Functions of the Pneumogastric. — From the manner in which the pneumogastric is dis-
tributed, it follows that it is a nerve both of sensation and ot motion ; for it supplies
both the lining membrane of the respiratory and digestive passages, and the muscles
and muscular coats of the same canals. Anatomy does not confirm the ingenious idea
of Bischoff, that the pneumogastric is essentially a nerve of sensation, and that the por-
tion which appears to be motor really belongs to the spinal accessory. Physiologists
have studied the influence of the pneumogastric upon the larynx, the lungs, the heart,
and the stomach in an infinite variety of ways ; it appears, from some experiments
which I made upon this subject, that animals in which both pneumogastrics are simul-
taneously cut die almost immediately, when they are permitted to eat as much as they
please ; for, the contractility of the stomach and oesophagus being destroyed, the food,
after having filled the stomach, distends the oesophagus, and passes from it into the larynx.
The Third Portion of the Eighth Jferve, or the Spinal Accessory JN'&rve oj
Willis.
We have already described the very remarkable origin of the spmal accessory nerve
at the side of the cervical portion of the spinal cord, between the anterior and posterior
roots of the spinal nerves, or, rather, immediately in front of the posterior roots, of
which it appears to be a dependance : we particularly alluded to the arrangement of its
highest filaments of origin, which come from the restiform bodies, and are continuous
above with the roots of the pneumogastric, so that they sometimes even join that nerve,
and below with the posterior roots of the spinal nerves.
Lastly, we have pointed out the varieties of its origin, its connexions with the first
pair of cervical nerves, of which it almost always forms the posterior roots, its ascend-
ing course to the foramen magnum, through which it enters the cranium, and its exit
from the scull by the foramen lacerum posterius.
It emerges from the foramen lacerum posterius by an opening quite distinct from that
for the glosso-pharyngeal, but common to itself and the pneumogastric nerve, behind
which it is situated {9, fig. 301). While passing through the foramen lacerum poste-
rius, it lies in contact with the ganglionic enlargement of the pneumogastric, and is con-
nected with the ganglion by very delicate filaments, but it neither assists in the forma-
tion of that enlargement, nor is blended with it : at its exit from the foramen it divides
into two branches of equal size ; an internal or anastomotic, which remains in contact
with the pneumogastric, and is distributed with it, and a muscular branch* (cut off in
%. 301).
The Anastomotic Branch. — So intimately are the spinal accessory and pneumogastric
nerves connected, or, as it -were, fused together, that, up to the time of Willis, they were
" It is well to observe, that as they are passing through the foramen lacerum posterius, the pneumogastric
and spinal accessory nerves adhere to the dura mater, in the iame manner as the Gasserian ganglion.
5 P
850 NEUROLOGY.
regarded as a single nerve. Willis first described the former, perhaps erroneou§^^, as a
separate nerve, under the name of nervus accessorius ad par vagum, sive nerviis spinalis.
In an excellent thesis, published in 1822,* M. Bischoff endeavoured to prove that the
pneumogastric or par vagum and spinal accessory form but a single nerve, analogous to
the spinal nerves in every respect ; the spihal accessory being the nerve of motion, and
the par vagum the nerve of sensation : " Nervus accessorius Willisii est nervus moto-
rius, atque eandem habet rationera ad nervum vagum quam antica radix nervi spinalis
ad posticam. Omnis motio cui vagus praeesse videtur, ab ilia portione accessorii quae
ad vagum accidit, efEcitur. Itaque vox quoque, sive musculorum laryngis et glottidis
motus, ab accessorio pendet, et eo nomine accessorius nervus vocalis vocari potest."
To this view there are serious objections : in the first place, it is opposed to the law
that the anterior roots preside over motion and the posterior over sensation ; for the
filaments of origin of the spinal accessory evidently form part of the posterior roots.
Again, how can it be supposed that two nerves, which, like the spinal accessory and
pneumogastric, arise so distinctly from the same line, that it is often difficult to separate
them, can have such opposite functions !
Must we suppose that the law which regulates the anterior and posterior roots of the
spinal nerves ceases to operate at the medulla oblongata 1 or must we admit, with Ar-
nold, that there is not only a decussation of fibres from side to side in the medulla ob-
longata, but also from before backward, so that the posterior columns of the medulla ob-
longata become the motor and the anterior the sensory 1 Still, even with this hypothe-
sis, it must be remembered that the spinal accessory arises in part below the point where
this antero-posterior decussation is supposed to exist. There evidently is an antero-
posterior decussation opposite to the two anterior pyramids, as I have elsewhere stated
(see Medulla Oblongata), but the other columns of the spinal cord are not concerned in it.
However this may be, the anastomotic branch of the spinal accessory may be traced,
after maceration in dilute nitric acid, along the outer side of the pneumogastric. In a
great number of cases, it evidently gives off the small pharyngeal nerve, which sometimes
arises exclusively from the pneumogastric, and sometimes from both the pneumogastric
and the spinal accessory. Scarpa declares the last arrangement to be constant and
normal, and has represented it in several figures. In some subjects, the spinal accessory
appears to have no share in the pharyngeal nerve, but then its anastomotic branch be-
comes applied to the pneumogastric below the origin of the pharyngeal nerve.
The anastomotic branch appears to me to have no share in the formation of the supe-
rior laryngeal nerve ; and the same is the case with regard to the recurrent nerve. It
appears to me anatomically impossible to prove the continuity of the spinal accessory
and the superior and recurrent laryngeal nerves ; I cannot, therefore, admit that the spi-
nal accessory supplies the intrinsic muscles of the larynx.
The spinal accessory generally gives off a number of twigs, which unite in front of the
reddish, and, as it were, ganglionic trunk of the pneumogastric nerve, to form a small
plexus, which adheres to that nerve, and ends in the hypo-glossal nerve.
Lastly, there are so many varieties in the mode of communication between the pneu-
mogastric and spinal accessory nerves, that it is extremely difficult to refer them to any
general law.
The Muscular Branch. — This nerve descends vertically between the internal jugular
vein and the occipital artery, beneath the digastric and stylo-hyoid muscles ; it runs back-
ward and outward {t, figs. 285, 298), beneath the sterno-mastoid, generally perforating
that muscle, but sometimes merely running along its deep surface, passes obliquely
across the supra-clavicular triangle, and terminates in the deep surface of the trapezius.
While perforating the sterno-mastoid, the spinal accessory nerve gives several branches
to that muscle, which anastomose with others from the third cervicd nerve, and form a
sort of plexus within the muscle.
On emerging, somewhat reduced in size, from the sterno-mastoid, it receives a branch
{v, fig. 298) from the anastomosis, between the second and third cervical nerves, by which
its size is greatly increased : it assists in the formation of the cervical plexus, and some-
times of the posterior auricular nerve.
Having reached the anterior surface of the trapezius, it receives two considerable
branches, derived from the third, fourth, and fifth cervical nerves, which appear to me
to re-enforce it. It gives off ascending filaments to the occipital portion of the muscle ;
and descending filaments, which continue in the original course of the nerve in front of
the muscle, approach its scapular attachments, and may be traced down to its inferior
angle. The muscular branch of the spinal accessory belongs exclusively to the sterno-
mastoid and trapezius muscles. It has been incorrectly stated that it supplies other mus-
■des, such as the rhomboidei, the levator anguli scapulae, the complexus, the splenius,
and the sub-scapularis, and that it is also distributed to the skin.
In front of, or, rather, in the substance of the trapezius, the spinal accessory anasto-
fjoaoses with the posterior branches of the spined nerves.
* Ne-vi Accessorii Willisii Anatomia etPhysiologia. Bischoff. Darmstadii.
THE HYPO-GLOSSAL NERVE. 851
Summary. — ^The spinal accessory gives branches to the stemo-mastoid, the trapezius,
and the phar)Ttx ; it is believed also to send some to the larynx by means of its anasto-
motic branch with the pneumogastric. It communicates with the second, third, fourth,
and fifth cervical nerves.
Function. — In reference to its muscular branch, Sir C. Bell has classed the spinal ac-
cessory among the respiratory nerves, under the name of the superior respiratory nerve of
the trunk ; for, according to that anatomist, it arises from the lateral column of the cord,
between the anterior and posterior columns.
With regard to the anastomotic branch of this nerve, which becomes blended with the
par vagum, M. BischofT lays down the following proposition (page 95) : " Nervum acces-
sorium nimirum nervum motorium esse, ideoque in partes vagi adscisci, ut motus, qui-
bus hie qui sensificus tantummodo nervus est, praeesse videatur, ipse perficiat : eundem
ergo praeesse motibus quoque musculorum laryngis, indeque nerviun esse vocalem.".
This idea, which was suggested to him by theory, he endeavoured to confirm by experi-
ment. The section of all the roots of the spinal accessory proved to be very difficult ;
but, after many fruitless attempts, he at length succeeded in dividing them on both
sides. The hoarseness produced by section of all the roots of the right side gradually
increased as he divided those of the left side, and when all had been cut, the natural
voice of the animal was changed to a very hoarse sound, which could not be called the
voice.
I have already said that anatomy affords no proof that the laryngeal nerves are derived
from the spinal accessory ; nor does it show that the muscular fibres of the bronchi,
oesophagus, and stomach, receive their filaments from it.
The Ninth Pair, ok Hypo-glossal Nerves.
The hypo-glossal, or great hypo-glossal nerve, the ninth cranial, or the twelfth nerve
of some modem authors, arises on each side from the furrow between the olivary and
pyramidal bodies, by a row of filaments collected into two very distinct fasciculi, which
proceed to the anterior condyloid foramen (q, fig. 296), perforate the dura mater separ-
ately, and join together so as to emerge from the canal in the form of a rounded cord.*
After leaving the anterior condyloid canal, the hypo-glossal nerve (d, fig. 301) descends
vertically between the internal carotid, which is on its inner side, and the internal jugu-
lar on its outer side. At first it lies behind the pneumogastric (8 to p) ; it then crosses
very obliquely over the outer side, and lower down it gets in front of that nerve, around
which, therefore, it describes a semi-spiral.
Having arrived below the posterior belly of the digastric muscle, the hypo-glossal
changes its direction and runs forward and downward {d, fig. 300), crossing in front of
the internal and external carotids [and hooking beneath the occipital artery] ; it is then
reflected upward to reach the under surface of the tongue {d, near x), and thus describes
a loop having the concavity turned upward, parallel to and below the digastricus, and
almost ten lines above the os hyoides.
Relations. — It is situated deeply in its vertical portion, where it runs along the verte-
bral column, becomes superficial in its middle portion (d, fig. 298), where it is merely
separated from the skin by the platysma and the prominence of the sterno-mastoid, and
again becomes deep-seated anteriorly, where it rests on the hyo-glossus muscle, and is
covered by the anterior belly of the digastricus and by the stylo-hyoideus, and then by
the sub-maxillary gland and the mylo-hyoideus, after which it enters the genio-glossus,
and is lost in the substance of the tongue.
The relations of the hypo-glossal nerve and the lingual artery are worthy of remark.
The nerve is at first parallel to and above the artery, is soon separated from it by the
hyo-glossus, and then rejoins it in front of that muscle. In the substance of the tongue,
the artery lies to the outer side of the genio-glossus, while the nerve runs forward
through the fibres of the muscle.
The Collateral Branches of the Hypo-glossal Nerve.
Some of these are anastomotic. Thus, as it crosses the three divisions of the eighth
nerve, the hypo-glossal lies in contact with the pneumogastric nerve, with which it
sometimes communicates by very delicate filaments. Most commonly the anastomosis
between these two nerves forms a true plexus, t This communication is sometimes
eftected with the anastomotic branch of the spinal accessory, sometimes with the pneu-
mogastric itself
The hypo-glossal is also connected by a very small anastomotic twig to the superior
cervical ganglion.
It also receives three filaments from the nervous loop formed by the union of the first
and second cervical nerves, namely, two from the first nerve and one from the second.
The superior filament from the first nerve ascends, an arrangement which it is difficult
to understand, for it passes in a direction towards the roots of the hypo-glossal ; if it be
* The vertebral artery is situated in front nf the filaments of the hypo-glossal.
t [In connexion with this fact, it may be observed that the descendens noni (a branch of the hypo-|floaaal
ttBr\-ol sometimes arises in part or entirely from the pneumogastric, lower down in the neck.]
85S NEUROLOGY.
supposed that this filament is derived from the hypo-glossal, then it is directed towards
the roots of the first cervical nerve.
Opposite to the anterior border of the hyo-glossus it gives off a very remarkable anas-
tomotic branch, which forms an arch with the lingual nerve.
The other collateral branches which it gives off are the descending branch ; a small
muscular infra-hyoid branch ; and the branches for the hyo-glossvs and stylo- glossus.
The descending branch {ramus descendens noni, h,figs. 298, 300, 301). This is the most
remarkable branch of the hypo-glossal nerve.* It comes off at the point where the
nerve changes its direction, descends vertically in front of the internal carotid and then
of the common carotid, curves outward, and anastomoses upon the internal jugular vein
with the descending branch of the cervical plexus {z,fig. 298), so as to form a loop, hav-
ing its concavity turned upward. From the convexity of this loop two branches proceed,
.of which one is distributed to the omo-hyoid, while the other (5^) divides into two twigs,
one of which enters the outer border of the stemo-hyoid, while the other penetrates the
deep surface of the sterno-thyroid muscle. I have seen one of these branches come di-
rectly from the hypo-glossal. t
It is equally important to study both the mode of origin and anastomosis of the de-
scending branch of the ninth ner^'e.t The origin of this branch is, in fact, almost en-
tirely from the anastomotic branches of the first and second cervical nerves, which, after
having been in contact with the hypo-glossal, are given off from it to constitute the de-
scending branch. This arrangement is especially evident in preparations that have been
macerated in diluted nitric acid. I should state, however, that it is not equally evident
in all subjects ; and that some filaments, derived from the hypo-glossal itself, always join
those from the cervical nerves. It has appeared to me that the most internal of the fila-
ments derived from the hypo-glossal nerve itself followed a retrograde course ; that is to
say, that it ran from below upward, as if it arose at the terminal extremity of the hyi^o-
glossal, and then left that nerve to join the descendens noni at the point where that
branch is given off.
The branches from the first and second cervical nerves to the hypo-glossal should be
regarded as late origins of that nerve, which is sensibly increased in size after being
joined by them. I have seen the third and even the fourth cervical nerve assist in the
formation of the descendens noni ; the branch from the fourth nerve arose partly from
the phrenic.
The mode of anastomosis of the descendens noni with the descending branch of the
cervical plexus, or, rather, of the third cranial nerve, is subject to much variety.
The following is the most frequent arrangement :
All the filaments composing these two descending branches unite together, with the
exception of the uppermost filament, which describes a loop having its concavity turned
upward, and resembhng a vascular anastomosis : so that, if we suppose it to be derived
from the loop of the Kypo-glossal, it would be directed towards the origin of the cervical
nerves ; and if, on the contrary, we suppose it to arise from the cervical nerves, it would
be directed towards the origin of the hypo-glossal. This arrangement, which I have had
the opportunity of observing in many parts of the nervous system, appears to me to con-
stitute a mode of anastomosis well worthy the attention of physiologists. I am induced
to regard it as intended to establish connexions between the different points of the spinal
cord.^
* See note, last page.
t [Another branch is described and figured by Arnold as descending in front of tlie vessels, and joining the
cardiac nerves in the thorax.]
X There are certain cases in which the descendens noni is analyzed by nature ; namely, when the branch
from the second cervical nerve is not applied to the hypo-glossal, but remains at a distance from it. In this
case, the filaments derived from the hypo-glossal join themselves to this branch ; one of them ascends towards
the origin of the second cervical nerve, and the others proceed towards its termination. In one case, the hypo-
glossal gave a very small twig to the first cervical nerve, before receiving its accustomed branch from that
nerve ; the descending branch from the cervical plexus was replaced by tEree branches derived from the first,
second, third, and fourth cervical nerves, which formed, together with the descendens noni and its branches, a
succession of loops, in front of the external and common carotids. In another case, the three superior cervical
nerves assisted in forming the descendens noni. The following is a detailed description of that case, which
throws considerable light upon the connexions between the hypo-glossal and cervical nerves. One large branib
proceeded from the anastomotic arch of the first and second cervical nerves ; this large branch, as soon as 't
reached the hypo-glossal nerve, divided into three filaments of unequal size : an ascending, which was directed
towards the origin of the hypo-glossal nerve ; a middle, which became blended with that nerve ; and a descend-
ing, which was the largest, and which merely ran along in contact with the same nerve. At the point where
this last-named filament left the hypo-glossal to form the descendens noni, it evidently received a twig from
the hypo-glossal itself, which came from the lower part of that nerve, and was reflected upon the descendens
noni in a retrograde manner, so that this twig, derived from the hypo-glossal, had one end at the terminal ex-
tremity of that nerve, i. e., in the muscles of the tongue, and the other end in the muscles of the infra-hyoid
region. In this same case, the descending branch of the second cervical nerve divided into three filaments,
one of which joined the hypo-glossal nerve, another formed an anastomotic arch with the third cervical nerve,
while the third filament passed downward to assist m forming the descending branch of the cervical plexus.
Lastly, the third cervical nerve in this case gave off an ascending branch, which anastomosed with the seo(md,
and a descending branch, which assisted in forming the descending branch of the cenical plexus ; there were
therefore two loops or arches, one internal and the other external ; they were situated opposite to the bifurca-
tion of the common carotid artery.
i, This mode of anastomosis may, perhaps, have some relation to that reflex action of the spinal cord, which
GENERAL VIEW QF THE CRANIAL NERVES, 853
The Small Muscular Branch of the Infra-hyoid Region. — This nerve comes off at the
posterior border of the hyo-glossus, and ramifies in the upper part of the muscles of the
infra-hyoid region ; a small transverse filament runs along the hyoid attachments of these
muscles. This small nerve may be regarded as an accessory to the descendens noni.
'The Branches for the Hyo-glossus and Stylo-glossus. — As the hypo-glossal nerve comes
into contact with the hyo-glossus, it becomes flattened and widened, and gives off sev-
eral ascending branches, most of which ramify in the hyo-glossus, though several end in
the stylo-glossus.
The Terminal Branches of the Hypo-glossal Nerve.
Opposite to the anterior border of the hyo-glossus the hypo-glossal nerve gives off
some twigs to the under surface of the genio-hyoideus ; it then enters the genio-hyo-
glossus, and expands (d, near x, fig. 300) into a great number of filaments, which run for-
ward, perforate that muscle at successive points, and are lost in the substance of the
tongue. It is impossible to follow these filaments to the papillary membrane of the
tongue. Some of them anastomose with the lingual («) nerve, a branch of the inferior
maxillary division of the fifth ; several accompany the lingual artery.
The relations of the lingual portions of the hypo-glossal nerve with the lingual of the
fifth are worthy of attention. The lingual nerve occupies the under part of the border
of the tongue, runs along the stylo-glossus, and may be traced as far as the apex of the
organ : it is sub-mucous in the whole of its extent. The hypo-glossal nerve is situated
on a much lower plane, and occupies the under surface of the tongue, on each side of
the median Une.
Function. — The hypo-glossal is a muscular nerve : it regulates the movements of the
tongue, while the lingual of the fifth and the glosso-pharyngeal confer sensibility upon it.
This fact is most clearly established by anatomical, physiological, and pathological ob-
servations. Like all nerves having a simple distribution, the hypo-glossal has not a
plexiform structure.
General View of the Cranial Nerves.
All the spinal nerves present the greatest regularity in arising from two series of roots,
in having a ganglionic enlargement on their posterior roots, and even in their course
and termination, the differences or modifications of which depend on the different struc-
ture of the parts to which they are distributed ; but the greatest irregularity appears to
prevail in reference to the origin, the course, and the termination of the cranial nerves.
From the comparison which has been made between the scull and the vertebrae, and
from the possibility of resolving the bones of the cranium into a certain number of cra-
nial vertebrae, anatomists have entertained the idea of drawing a parallel between the
cranial and the spinal nerves. It has been conceived that the number of cranial nerves
ought to be regulated by the number of cranial vertebras admitted by different anato-
mists ; and, moreover, that in order to draw a fair comparison between these two sets
of nerves, the special nerves of the face, namely, the olfactory, the optic, and the auditory
nerves, should be entirely disregarded.
Now we have already shown (see Osteology) that there are three cranial vertebrae,
between which there are two inter- vertebral foramina ; that the anterior inter-vertebral
foramen is represented by the sphenoidal fissure, to which we must annex the foramen
rotundum and the foramen ovale ; and that the posterior inter- vertebral foramen is rep-
resented by the foramen lacerum posterius, together with the anterior condyloid foramen.
This being premised, we shall admit two pairs of cranial nerves, an anterior and a
posterior.
The posterior cranial pair consists on each side of the eighth and ninth nerves, namely,
of the pneumogastric, glosso-pharyngeal, spinal accessory, and hypo-glossal nerves.
The pneumogastric and the glosso-pharyngeal, each of which has a ganglion analogous to
the inter- vertebral ganglia, represent the posterior roots of a spinal nerve, while the spi-
nal accessory and the hypo-glossal, which have no ganglion, represent the anterior root.
The two last-named nerves are exclusively motor, while the pneumogastric and the
glosso-pharyngeal appear to me to be mixed nerves, that is, both sensory and motor.
The anterior cranial pair is composed on each side of the fifth nerve, the ganglion of
which is quite analogous to the inter- vertebral ganglia, and the large portion of the root
of which accurately represents the posterior root of a spinal nerve ; and of the third or
conmion motor nerve of the eye, of the fourth or pathetic nerve, of the sixth or exter •
nal motor nerve of the eye, of the portio dura of the seventh, and, lastly, of the non-
ganglionic portion of the fifth. All these last-named nerves are the nerves of motion ;
while the ganglionic portion of the fifth is the nerve of sensation.
Moreover, as the spinal nerves communicate with the ganglia of the great s3Tnpa-
thetic, it is of importance, for the completion of our comparison, to determine the com-
munications of the two cranial pairs of nerves with the same system of ganglia. Now
Dr. Marshall Hall believes to be the cause of certain instinctive motions. (" On the Reflex Functions of the
.Medulla Oblongata and MeduUa Spinalis."— PAtZ. Trans.. 1833.)
854 NEUROLOGY.
I regard the superior cervical ganglion of the great sympathetic as common to the ivm
supposed cranial pairs and to the three superior cervical pairs ; in fact, the superior cer
vical ganglion communicates with all the branches of the posterior cranial pair, except-
ing the spinal accessory, viz., with the pneumogastric, the glosso-pharyngeal, and the
hypo-glossal ; and it also communicates with the anterior cranial pair, and more partic-
ularly with the fifth and sixth nerves.
As to the ophthalmic, spheno-palatine, otic, and sub-maxillary ganglia, which Arnold
regards as annexed to the organs of the senses, viz., the ophthalmic to the eye, the
spheno-palatine to the nose, the otic to the ear, and the sub-maxillary to the organ of
taste, and which Bichat described as the cephalic portion of the great sympathetic, [ am
of opinion that they are mere local ganglia, which do not form part of the general sym-
pathetic system : besides, the ophthalmic and the otic ganglion only can be shown to be
connected with the organs of any sense : it is impossible to show that the spheno-pala-
tine ganglion, the very existence of which as a ganglion is often doubtful, has any con-
nexions with the organ of smell, or that the sub-maxillary ganglion, which is much
more closely connected with the sub-lingual gland, has any relations with the organ of
taste.
THE SYMPATHETIC SYSTEM OF NERVES.
General Remarks. — The Cervical Portion of the Sympathetic. — The Superior Cervical Gan-
glion— its Superior Branch, Carotid Plexus, and Cavernous Plexus — its Anterior, Exter-
nal, Inferior, and Internal Branches. — The Middle Cervical Ganglion. — The Inferior Cer-
vical Ganglion. — The Vertebral Plexus. — The Cardiac Nerves : Right, Superior, Middle,
and Inferior, Left. — The Cardiac Ganglion and Plexuses. — The Thoracic Portion of the
Sympathetic. — The External and Internal Branches. — The Splanchnic Nerves, Great and
Small. — The Visceral Ganglia and Plexuses in the Abdomen, viz., the Solar Plexus and
Semilunar Ganglia. — The Diaphragmatic and Supra-renal ; the Coeliac, the Superior
Mesenteric, the Inferior Mesenteric, and the Renal, Spermatic, and Ovarian Plexuses. —
The Lumbar Portion of the Sympathetic. — The Communicating, External, and Internal
Branches. — The Lumbar Splanchnic Nerves and Visceral Plexuses in the Pelvis. — The
Sacral Portion of the Sympathetic. — General View of the Sympathetic System.
We have seen that the nerves arising from the cerebro-spinal axis are distributed to
the organs of the senses, to the skin, to the muscles, in short, to all the organs of ani-
mal life. The pneumogastric nerve alone is distributed to the organs of respiration, and
the upper part of the alimentary canal, viz., the pharynx, the oesophagus, and the stom-
ach. We shall now see that all the internal organs, which are beyond tlie influence of
volition and consciousness, are provided with a special nervous apparatus, which is call-
ed the great sympathetic, the sympathetic system, the ganglionic system, or the nervous sys-
tem of organic or nutritive life.
The sympathetic system consists of two long, knotted cords (/to v,fig. 268, in which
figure these cords are represented as if drawn outward away from their natural position)
extended one on each side of the vertebral column, from the first cervical to the last
sacral vertebra ; these cords are enlarged opposite each vertebra, to form a series of
ganglia, which communicate with all the spinal and cranial nerves on the one hand, and
give off all the visceral branches on the other. The sympathetic system consists es-
sentially of two distinct parts : of a central portion, formed by the two cords ; and of a
visceral, median, or prevertebral portion, consisting of certain plexuses and ganglia, which
communicate with the central cords, surround the arteries as if in sheaths, penetrate
the viscera with them, and establish a communication between the sympathetic cords
of the right and left sides. We cannot pay too much attention to the connexion be-
tween the ganglionic nerves and the arteries, which always serve as a support for these
nerves, and for which, according to some anatomists, the nerves are exclusively des-
tined.
Each half of the sympathetic system may be described in two ways : either as a con-
tinuous cord, having ganglia at intervals upon it, or as a series of ganglia or centres,
which may first be examined independently of each other, and around which all the fila-
ments that enter or emerge from them may then be arranged.
The first method, which is the more natural one, was adopted by the older anato-
mists, who described the sympathetic in the same way as other nerves ; according to
the second method, which is the one adopted by Bichat, all the ganglia, whatever situa-
tion they may occupy, are included in the sympathetic system ; the ophthalmic, the
spheno-palatine, and other cranial ganglia would, according to this view, be comprised
in the sympathetic system.
I believe that the better mode of description is one which associates the idea of a
centre with that of a cord. In fact, as the sympathetic system consists of a double line,
it is natural to describe it as a nervous cord, having two extremities, one cephalic, the
other pelvic ; and as each ganglion forms the point of termination or of origin to a great
THE SUPERIOR CERVICAL GANGLION.
856
number of nervous filaments, these bodies may very properly be regarded as central
points. The visceral portion of the sympathetic nerves will be described with the gan-
glia to which they are connected. *
I shall describe in succession the cervical, the thoracic, the abdominal, and the pelvic
portion of the s}aTipathetic. I have already said that I do not recognise any proper ce-
phalic portion of this system of nerves, for the ophthalmic and the other cranial ganglia
seem to me to belong to a totally different class
The Cervical PortioiWf the Sympathetic System.
The cerw:a„ portion of the sympathetic {ft, fig- 302) has this peculiarity, that, instead
of being composed of as many ganglia as there are j?i^. 302.
vertebrae, it has only two or three. This may be
explained by supposing that the superior cervical
ganglion represents by itself the ganglia which are
wanting. It will hereafter be seen that the lumbar
ganglia are rather frequently fused in a similar man-
ner. The cervical portion of the sympathetic is
situated on the anterior region of the vertebral col-
umn, behind the internal and common carotid ar-
teries, the internal jugular vein, and the pneumo-
gastric nerve (p). It is connected to all these parts,
and to the praevertebral muscles, by some very
loose cellular tissue, a layer of fascia intervening
between them ; it commences by a large fusiform
ganglion, the superior cervical ganglion (/) ; this is
succeeded by a nervous cord of variable size, which
terminates in the middle cervical ganglion (a) when
that exists, but when it is absent in the inferior cer-
vical ganglion (t), which is continuous with the first
thoracic ganglion, either directly or through the
medium of two or three very remarkable nervous
loops, or frequently by both methods of connexion.
We shall proceed to examine the three cervical
ganglia.
The Superior Cervical Ganglion.
Dissection. — Remove the corresponding ramus of
the lower jaw ; separate the ganglion very careful-
ly from the pneuraogastric, glosso-pharyngeal, and
hypo-glossal nerves, behind which it is placed. In
order to trace the superior or carotid branch, make
an antero-posterior median section of the head ;
open the foramen lacerum posterius from behind,
in the manner indicated for exposing the pneumo-
gastric, and then examine the ganglion and its su-
perior branch from the inner side.
The superior cervical ganglion (/) is olive-shaped
or fusiform : it is situated in front of the second
and third cervical vertebrae, from which it is sep-
arated by the rectus capitis anticus ; it is behind
the internal carotid artery, and the glosso-pharyn-
geal, pneumogastric, and hypo-glossal nerves ; its
upper extremity is about ten or twelve lines distant
from the lower orifice of the carotid canal ; it is
said to have been found two inches from it.
It is larger than the other cervical ganglia {gan-
glion cervicale magnum), but it varies much both in
its length and its other dimensions ; thus, its low-
er extremity has been seen to reach the fourth,
fifth, and even the sixth cervical vertebra. Its col-
our is grayish, and its surface smooth : not unfre-
quently it is bifurcated at its lower extremity ; it
is rather often double. Lobstein has figured a case of this kind ; and there were also two
superior cervical ganglia, one placed above the other, in a case of hypertrophy of these
ganglia, examined and represented by myself — (Anat. Path., liv. i., pi. 3.)
These cases of a double superior cervical ganglion evidently depend on subdivision ol
the single ganglion usually existing.
The branches which end in or emerge from the superior cervical ganglion may be di-
' vided into superior, inferior, external, internal, and anterior. I shall divide them into those
856 NEUROLOGY.
which communicate with the cranial and cervical nerves, those which communicate
with the other cervical ganglia, and into arterial and visceral branches. The superior
cervical ganglioR also gives off several twigs to the muscles of the prevertebral region.
The superior cervical ganghon communicates with the cranial nerves by means of its
superior or carotid branch and its anterior branches. It communicates with the cervical
nerves by its external branches. It communicates with the other cervical ganglia by
its inferior branch. Its visceral and arterial Ranches are the pharyngeal, the cardiac,
and the branches for the external carotid, ^j^
The Superior or Carotid Branch from the Inferior Cervical Ganglion.
The superior or carotid branch, or the branch of communication with the nerves which
constitute the anterior cranial pair, has been for a long time regarded as the origin of
the sympathetic nerve ; and as, previously to the time of Meckel, the anastomosis of
this carotid branch with the sixth cranial nerve, or external motor of the eye, was the
only one known, it was supposed that the sympathetic arose from the sixth nerve ; the
discovery of the vidian nerve by the elder Meckel has led to the admission of two ori-
gins or roots of the sympathetic, namely, one from the fifth and another from the sixth
cranial nerve.
Since the researches of modern anatomists, the study of the superior or carotid branch
of the superior cervical ganglion has become one of the most complicated points in the
anatomy of the nervous system.
This carotid branch appears to be a prolongation of the superior cervical ganglion ; it
tapers as it approaches the carotid canal, into which it enters, after having divided into
two branches, one of which runs on the inner side and the other on the outer side of
the artery. These branches communicate with each other, subdivide, and unite to form
the carotid plexus, and having reached the cavernous sinus, form a plexus, named the
cavernous plexus, which gives off the communicating branches to the sixth and fifth nerves,
and also the small plexuses which surround the internal carotid and its branches.*
Laumonier, and after him Lobstein and several others, described a ganghon, named
the carotid ganglion, in the first turn of the carotid canal ; but it is in vain to search for
it, unless some slight enlargements on the external and internal branches, wherevei
they give off or receive twigs, are to be regarded as ganglionic. +
During their course in the carotid canal, the external and internal divisions of the ca-
rotid portion of the sympathetic give off the following branches :
An Anastomotic Twig to the Nerve of Jacobson. — This comes off from the external
branch, and is very small ; it perforates the external wall of the carotid canal, enters
the cavity of the tympanum, and anastomoses with the nerve of Jacobson, a branch of
the glosso-pharyngeal.
An Anastomotic Twig to the Spheno-palatine, or McekeVs Ganglion. — This, like the pre-
ceding, comes from the external division of the carotid branch of the sympathetic, and
passes to the vidian or pterygoid branch of the superior maxillary nerve. We have al-
ready spoken of this twig, under the name of the carotid or deep branch of the vidian
nerve. Anatomists differ as to whether it should be regarded as passing from the fifth
nerve to the superior cervical ganglion, or from the superior cervical ganglion to the
fifth nerve. Arnold, on account of its grayish colour and slight consistence, regards it
as coming from the superior cervical ganglion, while he believes the great superficial
petrosal nerve, i. e., the cranial branch of the vidian, also from its colour and consist-
ence, to belong to the cerebro-spinal system of nerves, and to be a branch of the fifth
nerve. I have already said that I have never found sufficient difference between the
superior petrosal and carotid branches of the vidian to warrant this distinction. These
two nerves are, moreover, perfectly distinct from each other as far as the spheno-pala-
tine ganglion, in which they terminate.
It is important to observe that the two branches of the vidian nerve terminate in the
enlargement called the spheno-palatine, or Meckel's ganglion : the connexion of this
ganglion with the superior cervical ganglion has not been overlooked by those anato-
mists who regard the spheno-palatine enlargement as a ganglion, and who consider the
cranial ganglia as forming part of the sympathetic system.
Anastomotic Branches to the Sixth Nerve. — Several branches, generally three, turn round
the convex side of the second curve of the internal carotid, reach the outer side of that
artery, and anastomose, either separately, or, after having united together, with the sixth
or external motor oculi nerve. The nerves join at an acute angle opening backward,
within the cavernous sinus, and at the point where the sixth nerve crosses the carotid ;
as this nerve becomes flattened and widened opposite to the artery, it has been imagined
that it was really enlarged, and that this augmentation was due to the addition of fila-
ments from the sympathetic nerve ; but the enlargement is only apparent, and, notwith-
standing the difference in colour, I should be inclined to admit that the communicating
* The carotid branch is sometimes single, and turns spirally around the artery, being: placed at first behind,
then on the outer side, next on the inner, and a^ain on the outer side of the vessel.
t Arnold, whose authority upon such a subject is of great weight, has never seen this ganglion ; he very
properly remarks, that even those anatomists vho admit the existence of it aro not agreed as to its situation
THE CAVERNOUS PLEXUS, ETC.
filaments between the sixth nerve and the carotid branches of the sympathetic are fur-
nished by the sixth nerve, and have a reflected course. I have seen the three commu-
nicating filaments between the upper part of the sympathetic and the sixth nerve form
a ganglifonn enlargement as they were about to join the latter ; and it was this gangli-
form enlargement which gave origin to the plexus surroimding the internal carotid ar-
tery and its branches.
The Cavernous Plexus.
The cavernous plexus, in which the two divisions of the carotid branch of the superior
cervical ganglion at length terminate, is situated on the inner side of the carotid artery,
at the point where that vessel enters the cavernous sinus. From this grayish plexus,
which is intermixed with small vessels (plexus nervoso-arteriosus, Walter), a consider-
able number of filaments proceed, some of which establish a communication between it
and the fifth nerve, while others surround the internal carotid, and accompany all its
ramifications. The following very numerous branches emerge from the cavernous
plexus :
Some communicating Filaments to the Third Nerve or External Motor Oculi, before the Di-
vision of that Nerve. — These filaments pass above the sixth nerve, to which they appear
to be applied.*
A Filament of Communication with the Ophthalmic Ganglion. — This arises from the an-
terior part of the cavernous plexus, enters the orbit between the third nerve and the oph-
thalmic division of the fifth, and unites sometimes with the long root of the ophthalmic
ganglion, which we have stated to be derived from the nasal branch of the ophthalmic,
and sometimes with the ophthalmic ganglion itself
This root had been described and figured by Lecat, before Bock, Ribes, and Arnold
recalled the attention of anatomists to it.
It follows, from the arrangement just described, that the ophthalmic ganglion has three
roots, two cerebro-spinal and one ganglionic.
Communicating Filaments of the Fifth Nerve. — Some of these pass to the Gasserian gan-
glion, and others to the ophthalmic division of the fifth.t
The Filaments which accompany the Internal Carotid Artery and its Branches. — These
are extremely delicate, but they are beautifully distinct in some subjects. They may
be followed even upon the branches of the internal carotid.
Anatomists admit the existence of a plexus for the ophthalmic artery, and for each of
its subdivisions. It is even supposed that there is one for the arteria centralis retinae. t
Several authors have described a certain number of filaments proceeding from the
cavernous plexus to the pituitary body (filets sus-sphenoidaux, Chaussier). I have nev-
er been fortunate enough to discover them, nor yet the ganglion (the ganghon of Ribes)
which is said to exist upon the anterior communicating artery of the brain, and which
is found at the point of junction of the right and left trunks of the sympathetic.
It follows, from what has been stated, that the superior cervical ganglion, by means
of its upper or carotid branch, communicates with most of the nerves of the anterior cra-
nial pair ; namely, with the fifth nerve, by means of the Gasserian ganglion, of the oph-
thalmic division of the fifth, and of the ophthalmic ganglion, either directly or indirectly ;
also by means of the superior maxillary division of this nerve, through the intervention of
the spheno-palatine ganglion ; secondly, with the third nerve ; and, lastly, with the sixth.
The Anterior Branches from the Superior Cervical Ganglion.
The anterior branches of the superior cervical ganglion establish a communication with
the different nerves of the posterior cranial pair, excepting the spinal accessory nerve,
which does not appear to have any direct communication with it.
The glosso-pharyngeal and pneumogastric nerves communicate with the superioi
cervical ganglion at two different points, viz., at their ganglia, and by their branches.
The communication of the superior cervical ganglion with the ganglia of the glosso-pha
ryngeal and pneumogastric nerves has been pointed out by Arnold ; it is difficult to dem
onstrate it through the dense tissue which surrounds these ganglia.
On the contrary, it is extremely easy to demonstrate the communications of the glos-
so-pharyngeal nerve and the plexiform cord of the pneumogastric with the superior cer-
vical ganglion. I have already said (see Pneumogastric Nerve) that in one case I found
the pneumogastric so closely applied to the whole length of the superior cervical gangli-
on, that it was impossible to separate them. The communication of the superior cervi-
cal ganglion with the hypo-glossal is quite as evident as the preceding.
The filaments of communication with the nerves forming the posterior cranial pair do
not always proceed from the superior cervical ganglion itself, but sometimes from its ca.
rotid branch.
* I have never seen the communication between the superior cervical ganglion and the facial nerve noticed
by some anatomists.
t I may here again notice, that in two subjects I have seen a twig from the spheno-palatine ganglion join
the communicating branches between the sixth nen-e and the sympathetic.
t M. Ribes, Miimoires de la Societfi Medicale d'EmuIatiun, t. vii.
.5Q
NEUROLOGY.
The External Branch from the Superior Cervical Ganglion
The external branches of the superior cervical ganglion establish a communicatton be-
tween it and the first, second, and third cervical nerves ; they are large, have a gray colour,
and a ganglionic structure ; we may regard them as true prolongations of the superior
cervical ganglion ; the principal of them enter the angle of bifurcation of the second cer
vical nerve, into its ascending and descending branches ; the others, which are very
small, join the first cervical nerve. They constitute a true ganglionic plexus, and often
form two distinct groups.
Frequently the superior cervical ganglion communicates only with the first and sec-
ond cervical nerves. At other times it also communicates with the third and fourth
nerves by means of a long and very oblique branch. In one case it communicated di-
rectly with the phrenic nerve.
The Inferior Branch from the Superior Cervical Ganglion.
The inferior branch from the superior cervical ganglion, or the branch of communica
tion with the middle cervical ganglion, is a white cord, resembling a spinal nerve, ex-
cepting in a few cases, in which it appears to be a prolongation of the tissue of the ganglion
itself: when the lower extremity of the superior cervical ganglion is divided into two
parts, its inferior branch arises from the external division. It varies much in size in
different subjects : it descends vertically in front of the spinal column, behind the com-
mon carotid, the internal jugular vein, and the pnemnogastric nerve, to which it is uni-
ted by a very loose cellular tissue.
Having reached the inferior thyroid artery, the cord of the sympathetic passes behind
that vessel, and enters the middle cervical ganglion, when that exists ; but when it is ab-
sent, the cord continues on to join the inferior cervical ganglion. As it descends, it most
commonly receives some twigs from the third and fourth cervical nerves, which twigs we
have already said occasionally enter the superior cervical ganglion. At its origin, it
gives off on the inner side two filaments, which join the superior cardiac nerve, and in-
crease its size ; and an anastomotic twig to the external laryngeal nerve, a branch of
the superior laryngeal. Not unfrequently the superior cardiac nerve arises entirely from
the communicating branch between the superior and middle cervical ganglia, that branch
appearing to bifurcate.
The communication between the superior and middle cervical ganglia is subject to
much variety. I have seen a small ganglion upon it opposite to the inferior thyroid ar-
tery ; from this ganglion, which rested upon the artery, and which might be regarded as
the vestige of a middle cervical ganglion; two cords proceeded, an anterior, which join-
ed the cardiac nerve, and a posterior, which ended in the inferior cervical ganglion :
both of these had a gangliform structure. The cord of the sympathetic is not uncom-
monly found enlarged at intervals into ganglionic nodules.
The Internal Branches, or Carotid and Visceral Branches.
The internal branches from the superior cervical ganglion are divided into those which
accompany the external carotid and its ramifications, and those which are distributed to
the viscera.
The Carotid Branches. — It has been stated that from the upper extremity of the supe-
rior cervical ganglion certain branches are given off, which surround the internal carot-
id, and are prolonged upon its ramifications.
From the inner border of the same ganglion other branches proceed, which embrace
the external carotid and the ramifications of that vessel.
These nerves are of a gray colour (subruji), of a soft texture (nervi molles et pene mu-
cosi, Scarpa), and of a knotted and gangliform structure (rami gangliformes, Neubauer) ;
they come off from the ganglion opposite to the origin of the facial artery ; they pass in-
ward behind the external and internal carotids, and form a sort of gray plexus, which ex-
tends as far as the origin of the internal and external carotid ;* they turn like a loop
around the former of these vessels, and anastomose with the carotid filaments from the
glosso-phaiyngeal, and from the pharyngeal and superior laryngeal branches of the pneu-
mogastric. None of the branches from this plexus are prolonged upon the conmuon ca-
rotid ; they all pass upon the external carotid and its different ramifications, forming as
many plexuses as there are vessels, and are distributed with those vessels to the neck
and the face. Thus, there is a thyroid plexus, which surrounds the superior thyroid ar-
tery, and may be traced into the thjToid body ; a lingual plexus, which enters the sub-
stance of the tongue, and is supposed to anastomose with the lingual branch of the infe-
rior maxillary division of the fifth, and even with the hypo-glossal nerve ; and & facial
plexus, which is supposed to anastomose with the facial nerve. Anatomists have par-
ticularly directed their attention to the branches which enter the sub-maxillary gland ;
some imagining, and others regarding it as certain, that these branches communicate
with the sub-maxillaiy ganglion. I have never been fortunate enough to discover this
communication.
* At this division there is frequently a gangliform enlargement, which Arnold proposes to call the inter-ca-
rotid ganglion.
THE MIDDLE AND INFERIOR CERVICAL GANGLIA. 8S9
There is, moreover, a pharyngeal plexus, an occipital plexus, and an auricular plexus :
the elder Meckel* has even described an anastomosis between the facial nerve and the
sympathetic filament which accompanies the posterior auricular artery. Lastly, the
temporal artery, and the internal maxillary artery and its divisions, are also surrounded
(hederae ad modum, Scarpa) by small nervous plexuses ; these plexuses are sometimes
so well developed, that the elder Meckel states that the arteries of the face have larger
nervous plexuses than any others in the body. These plexuses appear to me to be pe-
culiarly remarkable for containing a mixture of white fibres and nervi molles, which
proves their double origin.
All these plexuses present gangliform enlargements at various points, as is shown in
the splendid plate in Scarpa's work.t This author has figured, after Andersh, a gangli-
on which he believes to be constant at the division of the external carotid and temporal
arteries. A twig from the facial nerve terminates in this ganghon.f
The Visceral Branches. — All these come off from the inner side of the ganglion, and
divide into pharyngeal, laryngeal, and cardiac branches.
The pharyngeal branches are certain thick ganglionic cords which arise from the upper
and inner part of the superior cervical ganglion, pass transversely inward, and combine
with the pharyngeal branches of the glosso-pharyngeal and pneumogastric nerves to
form one of the most remarkable plexuses in the body, which is distributed to the pha-
rynx. To this plexus must be relterred all those highly important nervous phenomena
which are manifested in connexion with the pharynx, more particularly the sensation of
thirst.
• The laryngeal branches unite with the superior laryngeal nerve and its divisions. In a
case in which the external laryngeal nerve arose separately from the pneumogastric and
not from the superior laryngeal, it had as many filaments of origin from the superior
cervical ganglion as from the pneumogastric itself
The cardiac branches form the superior cardiac nerve, to which I shall recur after hav
ing described the middle and inferior cervical ganglia.
The Middle Cervical Ganglion.
The middle cervical ganglion {a, Jig. 302) is wanting in a great number of subjects, and
then the branches usually given off from and received by it are given off and received
by the cords which connect the superior and inferior cervical ganglia, or by the inferior
cervical ganglion itself The middle cervical ganglion is sometimes double ; at othe''
times it is in quite a rudimentary state.
It is situated on a level with the fifth or sixth cervical vertebra, in front of the inferior
thyroid artery, opposite to the first curve of that vessel, and sometimes behind it ; its
relation to this artery, which is very nearly constant, induced Haller to name it the thy-
roid ganglion : however, I have frequently seen it eight lines above that artery. Its
form and size are extremely variable, not only in different subjects, but even upon oppo-
site sides of the same subject.' Sometimes it is a simple gangliform enlargement.
Scarpa has figured a middle cervical ganglion almost as large as the superior, and, like
it, olive-shaped. I have never seen it as large as this.^
The middle cervical ganglion, when it exists, receives,
Above, the cord which communicates with the superior cervical ganglion ; below, the
cord of communication, often multiple, with the inferior cervical ganglion ; on the out
side, three branches, derived from the third, fourth, and fifth cervical nerves : not un-
frequently the communicating branch from the fourth cervical nerve belongs to the
phrenic ; on the inside, the middle cardiac nerve, or great cardiac of Scarpa, which I shall
presently describe.
The size of the middle cervical ganglion has always appeared to me to be proportioned
to that of its filaments of communication with the cervical nerves.
The Inferior Cervical Ganglion.
Neubauer has given an excellent description of the inferior cervical ganglion, under
the name of the first thoracic ganglion, rather an appropriate title for it, because it is fre-
quently continuous with the first thoracic ganglion (as at i, fig. 302) ; and, secondly, be-
cause it is situated in front of the transverse process of the seventh cervical vertebra
and of the head of the first rib. This ganglion is constant ; it is deeply seated behind
the origin of the vertebral artery, by which it is completely concealed. Ii
* M6moires de I'Acad. de Berlin, 1752. t Tabulae Neurologicae, tab. iii., 1794.
T Arnold has described and figured a twig from the plexus which surrounds the middle meningeal or spheno-
spinous artery, and which, according to this laborious inquirer, terminates in the otic ganglion ; he also de
scribes some nervous twigs passing from the plexus of the ascending palatine artery to the sub-maxillary
ganglion. In this way he establishes a connexion between the sympathetic system and these two cranial gan-
glia. I have devoted great care to this subject, but have never been able to make out these communicating
filaments, even though all the difficult dissections have been made upon specimens previously macerated in
diluted nitric acid.
1) I believe that it is incorrect to regard as a middle cervical ganglion those ganglionic nodules, without
either afferent or efferent filaments, which are rather frequently found at various points on the trunk of the
sympathetic.
H It is not rare to see the inferior cervical ganglion describe around the vertebral artery a half ring, which
is completed in front by a gray cord extended from one end of the ganglion to the other.
860 NEUROLOGY.
It is of a semilunar shape, its concave border being turned upward and its convex one
downward ; at its internal extremity it receives the trunk of the sympathetic ; at its ex-
ternal extremity it receives a large nerve which accompanies the vertebral artery, and
which may be called the vertebral nerve ; at the same extremity it also receives some
communicating branches from the fifth, sixth, and seventh cervical nerves, and often
from the first dorsal. Several branches proceed from its convex border, which is turned
downward ; some pass in front of and others behind the sub-clavian artery, which they
embrace like loops. Most of these inferior branches are the communicating branches
between the inferior cervical and the superior thoracic ganglion, and they exist even
when the two ganglia are directly continuous with each other. One of the branches
sometimes joins the recurrent laryngeal branch of the pneumogastric ; the most remark-
able of the inferior branches constitutes the inferior cardiac nerve, which is rather fre-
quently derived from the superior thoracic ganglion.
To complete the description of the cervical portion of the sympathetic, we have now
only to speak of the vertebral nerve and of the cardiac nerves.
The Vertebral Plexus.
The vertebral plexus or vertebral nerve occupies the canal which is formed for the verte-
bral artery in the transverse processes. It is generally said that this nerve arises from
the inferior cervical ganglion ; that it traverses the entire length of the canal formed for
the vertebral artery, enters the cranium with that vessel, and then unites with its fel-
low of the opposite side to form the basilar plexus, which divides and subdivides around
the terminal ramifications of the basilar artery, like the plexuses which are formed
around the internal carotid ; but such is not a correct description of the nerve. It ap-
pears to me to be formed by the junction of filaments derived from the third, fourth, and
fifth cervical nerves, gradually to increase in size from above downward as it receives
new filaments, then to pass behind the artery, to emerge from the canal also behind the
vessel, and, finally, to enter the inferior cervical ganglion. I conceive that this branch
is intended to establish a communication between the third, fourth, and fifth cervical
nerves and the inferior cervical ganglion. I have never found upon these branches the
swellings or gangli which, according to M. Blainville's ingenious idea, might be intend-
ed to supply the place of the cervical sympathetic ganglia, and to destroy the appear-
ance of irregularity which exists in the cervical region in this respect.
The Cardiac Jferves.
Dissection. — This comprises the dissection of the cardiac nerves, from their origin to
the point where the aorta and pulmonary artery cross each other ; and from that point
to the extreme divisions of the nerves. For this purpose, after having previously ex-
posed the cervical ganglia and the cardiac nerves, the preparation should be macerated
in diluted nitric acid ; all the internal nerves which proceed from the ganglion should
then be carefully dissected, so as to preserve their relations with the cardiac branches
of the pneumogastric and recurrent nerves ; we must then examine the nerves which
pass in front of the aorta, those which run between that vessel and the pulmonary ar-
tery and trachea, and, lastly, those which pass behind the pulmonary artery ; we should
study, at the same time, their relations with the anterior and posterior cardiac plexuses.
The cardiac nerves, or nerves of the heart, which are distinguished into the right and
the left,* arise essentially from the cervical ganglia. These ganglionic nerves are then
joined by several branches from the pneumogastric ; they all converge upon the origin
of the aorta and pulmonary artery to form the cardiac plexuses, which give off the right
and left coronari/ plexuses ; these latter plexuses surround the coronary arteries, and their
branches are scattered over the surface of the heart, but do not enter its substance un-
til they have advanced a considerable distance beneath the serous membrane by which
the heart is covered.
Such is the most general idea that can be given of the cardiac nerves and plexuses,
which afford one example of the most remarkable of the median anastomoses. Scarpa
first described and figured them correctly in his plates, which will always be models for
anatomical drawings. No nerves present so many varieties, in number, size, and ori-
gin, as the cardiac nerves ; and on this subject especially, the want of a work upon ana-
tomical varieties is especicilly felt. For my part, I declare that I have never found the
cardiac nerves in my dissections as they are represented in Scarpa's magnificent plates,
* The history of flie nerves of the heart is singular. The ancient philosophers, with Aristotle, influenced
by certain preconceiited ideas, staled that the heart was the source of all the nerves in the body. Galen re-
futed this opinion, and J^dmitted that the heart had but one very small nerve, which descended from the brain.
Vesalius considered that this slender nerve came from the recurrent, and represented it in a figure. Fallo
pius first described the nerves of the heart, and says that he showed his audience " insignem nervorum plexum
» quo ahundans copia nervosa materia totam cordis basim complexatur, pergue ipsam plures propagines parvo-
rum nervorum dispergit." Behrends, in 1792, defended a thesis in which he endeavoured to demonstrate that
the heart has no nerves, cornervis carere. Such was the amount of knowledge on this subject when, in 1794,
Scarpa published his splendid work, and settled the state of science on this point. — (.Tabulae Neurohgicee ad
Illustrandam Anatomiam Cardiacorum Nervorum, Noni Nervorum Cerebri, Glosso-pharyngax et Pharynga:i ex
Octavo Cerebri.)
THE RIGHT CARDIAC NERVES. Wfl
which have served as the type for all descriptions. I have minutely described the cardiac
nerves in eight different subjects ; these eight descriptions present very great differen-
ces, at least, until one arrives at the account of the cardiac plexuses ; the ultimate dis-
tribution of the nerves of the heart appeared to be the same in all these subjects.
All the cardiac nerves are gray, but they are not all soft, as declared by Scarpa, who
called them nervi molles. Sometimes the right, and sometimes the left cardiac nerves,
are the larger ; the nerves of the two sides are inversely proportioned to each other in
this respect, and there is evidently a mutual dependance between them. In one case, in
which tlie middle and inferior cardiac nerves of the right side were wanting, and the
superior cardiac nerve very small, their places were supplied by some large branches
from the right recurrent nerve, and by the left cardiac nerves, which were largely de-
veloped.
Anatomists follow Scarpa in describing three cardiac nerves on each side : a superior,
named by him the superficial cardiac nerve, which is derived from the superior cervical
ganglion ; a middle, called by him the great or deep cardiac nerve, which arises from the
middle cervical ganglion ; and an inferior, or small cardiac nerve, proceeding from the
inferior cervical ganglion. Although this is the usual arrangement, it is often impossible
to distinguish three nerves, in consequence of the anatomical varieties which I have al-
ready mentioned. There is frequently no middle cardiac nerve properly so called ; at
other times there is no inferior cardiac nerve, or, rather, they are both in a rudimentary
state ; lastly, the superior cardiac nerve, if not entirely wanting, may be extremely small,
and may join the middle cardiac nerve. Sometimes all the cardiac nerves of one side
unite into a single trunk, or else into a plexus situated behind the sub-clavian artery,
upon the side of the trachea ; the recurrent nerve assists in forming this plexus, from
which three, four, or more branches are given off to be distributed to the heart in the
usual manner. One of the most important points in the history of the cardiac nerves is
their sort of fusion with the pneumogastric, which is so intimate that the cardiac branch-
es of the pneumogastric, and those which come from the ganglia, form a single system.
There is a similar fusion between the superior, middle, and inferior cardiac nerVes of
each side, and between the nerves of the two sides.
The recurrent nerve, in particular, appears sometimae to be distributed equally to the
larynx and the heart, so large and numerous are the cardiac branches given off from it ;
it will hereafter be seen that there is an equally intimate connexion between the pneu-
mogastric nerve and the solar plexus.
I shall first describe in detail the right cardiac nerves, and shall then briefly point out
the differences between them and the left cardiac nerves.
The Right Cardiac Nerves.
The Superior Cardiac Nerve. — Its origin is very variable. Most commonly, it arises
from the internal division of the bifurcated lower extremity of the superior cervical gan-
glion, the cord of communication between the superior and the next cervical ganglion
forming the external division. At other times it arises from the communicating cord.
In a great number of cases it has several origins, being formed by two or three very
small filaments, which come from the inner side of the superior cervical ganglion ; by a
branch, often a large one, from the cord of communication ; and by two filaments from
the pneumogastric nerve. In one of these latter cases the cardiac branch from the cord
of conmiunication presented a very distinct ganglion.
Whatever may be its origin, the superior cardiac nerve passes obliquely doTvnward and
inward, behind the common carotid, from which it is separated by a very thin layer of
fascia, so that it is almost impossible to include it in applying a ligature to that artery ;
it runs along the trachea, very often receives a branch from the trunk of the sympathet-
ic, and crosses in front of the inferior thyroid artery, or sometimes divides into two branch-
es, one of which, the anterior, passes in front of the artery, while the posterior joins the
recurrent nerve.* At the lower part of the neck the superior cardiac nerve runs along
the recurrent laryngeal nerve, with which it may be confounded ; it enters the thorax,
passing behind and sometimes in front of the sub-clavian artery,t runs along the brachio-
cephalic trunk, gains the back of the arch of the aorta, gives off a certain number of fila-
ments, which pass in front of that part of the vessel, then runs obliquely downward and
to the lelt between the arch of the aorta and the trachea, anastomoses very fi-equently
with the middle and inferior cardiac nerves and with the branches of the recurrent, and
divides into two sets of filaments ; some of these pass between the aorta and the pul-
monary artery, and others between the right puhnonary trunk and the trachea ; they both
* The trunk of the sympathetic, havin? reached the inferior thyroid artery, sometimes divides into two
branches, one of which passes in front of that artery, to join the superior cardiac nerve, while the other passes
behind it to the inferior cervical ganglion ; not nnfrequently the superior OM-diac nerve presents a ganglionic
enlargement, which occupies the whole or a part of the thickness of the nerve.
t The superior cardiac nerve often bifurcates so as to embrace the sub-clavian artery in a complete ring.
At other times the superior cardiac nerve passes liehind the sub-clavian artery, and the cardiac branch of the
pneumogastric in front of it, so as to form beneath the sub-clavian an anastomotic loop, which lies to the inner
side of the one formed by the recurrent nerve. Most commonly the cardiac branch of the pneumogastric anas
tomoses with the superior cardiac nerve, between the arch of the aorta and the trachea.
862 NEUROLOGY.
anastomose with the left cardiac nerves, and are arranged as we shall soon describe. In
some rare cases, the right superior cardiac nerve goes directly to the cardiac plexus,
without anastomosing with the middle and inferior cardiac nerves.
During its course along the neck, the right superior cardiac nerve receives the small
superior cardiac branches of the pneumogastric, and gives off several filaments, some to
the pharynx, others to the trachea and the thyroid body, while several assist in forming
the plexus of the inferior thyroid artery ; it often gives off three or four branches which
anastomose with the recurrent nerve.
In the thorax, the superior cardiac nerve is joined by the cardiac branch given off by
the pneumogastric in the lower part of the neck, and which is sometimes of very consid-
erable size, and evidently re-enforces the cardiac nerve ; this branch of the pneumogas-
tric sometimes terminates directly in the cardiac plexus.
The Middle Cardiac Nerve. — This nerve arises from the middle cervical ganglion, or,
when that is absent, from the trunk of the sympathetic, at a variable distance from the
inferior cervical ganglion. It is rather frequently the largest of the cardiac nerves, and
has, therefore, been called by Scarpa the great cardiac nerve {magnus, jirofundus). At
other times it is in a rudimentary state, and is replaced either by the superior or the in-
ferior cardiac nerve, or by branches from the recurrent : it frequently divides into sev-
eral twigs, between which the sub-clavian passes ; it almost always anastomoses with the
superior and inferior cardiac nerves of the same side, runs along the recurrent nerve, for
which it might be mistaken, and with which it is always connected, and then terminates
in the cardiac plexus.
The Inferior Cardiac Nerve. — This is generally smaller {cardiacus minor) than the pre-
ceding nerve, though it is sometimes larger ; it usually arises from the inferior cervical
ganglion, but rather fequently from the first thoracic ; it accompanies the middle cardi-
ac nerve, anastomoses with that nerve, and, like it, descends vertically in front of the
trachea, and terminates in the cardiac plexus.
The connexion of the middle and inferior cardiac nerves with the recurrent nerve de-
mands especial attention. Sometimes the recurrent sends off certain large branches
which join the cardiac nerves, and form their principal origin. I have seen the middle
and inferior cardiac nerves united together, crossing over the recurrent nerve at right
angles, and adhering intimately to it without presenting that admixture of filaments which
constitutes an anastomosis.*
The Left Cardiac Nerves.
The peculiarities of the left cardiac nerves maybe stated in a few words :t in the neck,
they are situated in front of the oesophagus, on account of the position of that canal.
The connexions between the cardiac nerves and the recurrent on the left side appear to
me more numerous than those on the right. In one case, the superior and inferior car-
diac nerves gave off a series of four rather large filaments, which ran along the recur-
rent, left that nerve opposite to its point of reflection, and then terminated in the usual
manner. I ascertained that, in this case, the two nerves were merely in contact, and
did not anastomose.
In the thorax, the superior and middle cardiac nerves of the left side descend between
the carotid and sub-clavian, and then run upon the concavity of the arch of the aorta ;
the inferior cardiac nerve, which is the largest of all the cardiac nerves in a subject
which I have now before me, passes to the left of the trunk of the pulmonary artery,
turns round its back part, and embraces it in a loop, so as to enter that portion of the
cardiac plexus which is situated between the aorta and the right division of the pulmo-
nary artery. Lastly, on the left side, more commonly than on the right, the anterior
pulmonary plexus sends off some filaments to this same part of the cardiac plexus.
The Cardiac Ganglion and Plexuses.
We have seen that the cardiac nerves of the same side anastomose with eacn other
on the sides or in front of the trachea. Besides this, the right cardiac nerves anasto-
mose with the left upon the concavity of the arch of the aorta ; also in front of the tra-
chea, above the right pulmonary artery ; and, lastly, in the anterior and posterior coro-
nary plexuses.
Wrisberg was the first to describe a ganglion in the situation of the first-named anas-
tomosis, that is to say, upon the concavity of the arch of the aorta, between that vessel
and the pulmonary artery, to the right of the remains of the ductus arteriosus. This
ganglion, which is by no means constant, is named the cardiac ganglion ; it is joined [so
as to form the superficial cardiac plexus] by the superior cardiac nerve of the right side,
* It is especially in these anastomoses between the cardiac and recurrent nerves that I have been able,
from the different aspect of the iiljuaents of each, to ascertain that the anastomoses of nerves are often mere-
ly apparent, and consist of a simple^uxtaposition of two nerves without any communication of their component
fasciculi, which can be traced uninterruptedly from their entrance to their emergence. The same observa-
tion applies also to some of the anastomoses between nerves of the same kind.
t In one subject, three filaments arose from the left superior cervical ganglion, and united in a small gan-
glionic nodule, which also received a twig from the laryngeal nerve. This ganglionic nodule gave off several
pharyngeal twigs, and also the superior cardiac nerve
THORACIC PORTION OP THE SYMPATHETIC SYSTEM. 863
by the same nerve of the left side, and sometimes also by the right and left cardiac
branches given off from the pneumogastric nerves in the lower part of the neck.
The second anastomosis, or that which takes place in front of the trachea, above the
right pulmonary artery, and behind the arch of the aorta, has been known, since the time
of Haller, as thJB great cardiac plexus (magnus, profundus plexus cardiacus, Scarpa). A
ganglionic enlargement is not unfrequently found at the junction of the principal branch-
es. This great cardiac plexus is chiefly formed by the middle and inferior cardiac nerves
of both sides : [it also receives part of the right superficial nerves.] Lastly, all the car-
diac nerves end in the third set of anastomoses, namely, those upon the anterior and
posterior coronary arteries around the root of the aorta.
Great as the variety may be in the course and size of the cardiac nerves up to the
origin of the great vessels from the heart, there is as constant a uniformity in their ar-
rangement around those vessels, and in their ultimate distribution to the heart.
Upon the origin of the great vessels, the cardiac nerves are arranged in three layers
or sets.
The superficial layer of nerves is the smallest ; it occupies the anterior surface of the
arch of the aorta, and especially its right side ; the nerves are visible without any dis-
section through the transparent pericardium ; they all pass {v) to the anterior coronary
artery, to the right side of the infundibulum of the right ventricle. In this superficial
layer, the superficial cardiac plexus, may be included the ganglion of Wrisberg, when it
exists, and its several branches, which in a great measure assist in forming the anterior
coronary plexus.
The middle layer of nerves is composed of two very distinct parts, viz., of the great or
deep cardiac plexus of Haller, which is situated between the trachea and the arch of the
aorta, above the right pulmonary artery ; and of a much smaller part, situated below the
great cardiac plexus, from which it is derived, and between the right pulmonary artery
and the arch of the aorta. In order to obtain a good view of this layer, the arch of the
aorta must be cut through.
The deep layer of nerves is situated between the right pulmonary artery and the bifur-
cation of the trachea. The trunk of the pulmonary artery must be divided in order to
expose it.
The Anterior and Posterior Coronary Plexuses. — ^The whole of the superficial cardiac
plexus or superficial layer of nerves ends in the anterior coronary plexus (») which sur-
rounds the right coronary artery. The middle and posterior layers unite below the right
pulmonary artery, in front of the auricles, to form a plexus, which might more properly
be named the great or deep cardiac plexus than the interlacement so called by Haller.
From this plexus, into which the left inferior cardiac nerve enters directly, the follow-
ing branches proceed : anterior auricular branches, which are very numerous ; certain
branches which pass between the aorta and the pulmonary artery to gain the right side
of the infundibulum, and join the anterior coronary plexus, which, as we have seen al-
ready, is derived from the superficial cardiac plexus ; lastly, the branches for the poste-
rior coronary plexus, which surrounds the origin of the left coronary artery, and divides,
like that vessel, into two secondary plexuses, one of which runs round the left auriculo-
ventricular furrow, while the other (»') enters the anterior ventricular furrow.
The nervous filaments from these plexuses soon leave the ramifications of the arter-
ies ; they proceed separately ; they are all equally small, and can be seen without any
dissection, like white lines, extending from the base towards the apex of the heart.
They all belong to the ventricular portion of the heart ; a few of them, however, ascend
on the posterior surface of the auricles, which are much more abundantly supplied upon
their anterior surface.
The cardiac nerves are not entirely distributed to the heart ; several of them are lost
in the coats of the aorta, some join the anterior pulmonary plexus, and some ramify in
the pericardium.
The Thoracic Portion of the Sympathetic System.
In the thorax, the trunk of the sympathetic (i t, fig. 302) consists, on each side, of a
grayish cord, having as many nodules or ganglia upon it as there are vertebrae. This
cord is situated, not in front of the dorsal vertebrae, but in front of the heads of the ribs,
to which the gangUa for the most part correspond : the two superior thoracic ganglia
are the largest, and are almost always united ; the succeeding ganglia are almost of
equal size, the twelfth being next in size to the first and second. The ganglionic struc-
ture is observed throughout the whole extent of this part of the sympathetic, so that
the cords of communication between the ganglia may be said to be merely prolongations
of the ganglia. In some subjects the ganglia cannot be distinguished from the portions
of the sympathetic trunk above and below them, except by the branches which enter
and converge from those points ; it would, therefore, be a serious anatomical error to
regard the portions of the trunk between the ganglia as mere filaments of communica-
tion. In some subjects the cords between the ganglia are divided into two or three fila-
ments. The varieties observed in the number of the thoracic ganglia are rather appa-
864 NEUROLOGY.
rent than real : tliey depend, some upon fusion of the first thoracic ganglion with the
inferior cervical ganglion, or of the first and second thoracic ganglia ; others upon fusion
of two central ganglia, or upon that, which is more common, of the last thoracic with
the first lumbar ganglion ; upon a transposition of the last thoracic ganglion, which is
then found upon the first lumbar vertebra ; and, lastly, upon the two inferior thoracic
ganglia being situated in the last intercostal space. Besides this, the three lowest tho-
-acic ganglia are subject to much variety, both in situation and in shape ; and the same
may be said of the mode of connexion between the twelfth thoracic and the first lumbar
ganglion.
The thoracic portion of the sympathetic lies beneath the pleura and the very thin
fibrous layer by which that membrane is strengthened. It can be distinctly seen with-
out any dissection, in consequence of the transparency of these layers. The intercos-
tal arteries and veins pass behind it ; on the right side, the vena azygos runs along it.
The thoracic portion of the sympathetic gives off external branches, or branches of
communication with the dorsal nerves ; and the internal branches, which are intended
for the aorta and the abdominal viscera.
The External or Spinal Branches.
There are at least two spinal branches from each ganglion, one superficial and larger,
which is connected to the outer angle of the ganglion ; the other deep and smaller,
which is attached to its posterior surface : there is sometimes a third filament of com-
munication. Not unfrequently these branches unite into a single trunk, before reaching
the ganglion.
I regard these anastomotic branches (e e), between the spinal nerves and the ganglia
of the sympathetic, not as branches furnished by the ganglia to the spinal nerves, nor
simply as means of communication between one and the other, but rather as branches
of origin of the sympathetic : this, indeed, is clearly demonstrated by the arrangement
of these spinal branches of the sympathetic, which are always proportioned to the size
of the ganglia from which they arise. In general, each ganglion communicates only
with the corresponding spinal nerve ; not unfrequently, however, a ganglion receives a
twig from the intercostal nerve immediately below it.*
The branches of conununication from the dorsal nerves to the thoracic ganglia of the
sympathetic are horizontal, or, rather, they are inclined obliquely downward and inward,
excepting those which ascend to the first thoracic ganglion, and those which descend to
join the last thoracic ganglion. These branches are white, like the nerves of the cere-
bro-spinal system, and not gray, like the ganglionic nerves. On examining their ulti-
mate distribution in the sympathetic ganglia, and their connexions with the dorsal and
intercostal nerves, after the parts have been macerated, first in diluted nitric acid and
then in water, it is seen that these branches are evidently reflected funiculi of the spi-
nal nerves ; and that the nerves, immediately after having given off these branches, are
proportionally diminished in size ; that, having reached the ganglia, the communicating
branches divide into filaments, of which some ascend, and may be traced upon the trunk
of the sympathetic above the ganglion, and appear to be continuous with the descending
filaments derived from the spinal nerve above, while the others descend to pass upon the
portion of the sympathetic trunk below the ganglion ; and, lastly, that these white fila-
ments run upon the surface of the sympathetic, and contrast with the gray colour of the
central portion of that nerve.
The Internal, or Aortic and Splanchnic Branches.
The internal branches of the first five or six thoracic ganglia are exclusively intended fo~
the aorta ; some of them appear to enter the pulmonary plexus.
Some of the internal branches of the last six thoracic ganglia are intended for the aorta,
and the remainder, which are the principal, unite to form the splanchnic nerves or nerves
of the abdominal viscera. I have never seen any of them pass to the oesophagus.
The Aortic Branches. — The aortic branches consist of very small filaments, of which
two or three proceed from each ganglion. They accompany the intercostal arteries,
around which they form small plexuses. These filaments are much longer on the right
than on the left side, on account of the position of the aorta ; they pass, some in front
and others behind that vessel, upon which it soon becomes impossible to follow them.
The aortic branch from the fourth thoracic ganglion is the only one of any considerable
size ; it appears to be shared between the aorta and the pulmonary plexus. A number
of these aortic filaments sometimes converge towards certain small knots or ganglia,
which are arranged in front or along the sides of the aorta, and give off a number of fil-
aments.
The first thoraci© ganglion sends some twigs to the cardiac plexuses ; and not unfre-
* In one subject I found a yery remarkable disposition of the branches for the four inferior thoracic gang-lia.
Some small twigs from these four ganglia terminated in a minute gangliform structure, which gave off the
branches to the spinal nerves. It will be seen that the same arrangement frequently occurs in the lumbal
region.
THE SPLANCHNIC NERVES. ISIJJJ
quently the inferior cardiac nerve proceeds from this ganglion. Some filaments from the
same ganglion are distributed to the lower part of the longus colli muscle.
Lobstein (De Nerco Magna Sympathetica, p. 19) describes a very delicate filament from
this ganglion, which perforates the anterior common vertebral ligament, and enters the
substance of one of the vertebrae. A similar filament appears to me to be given off by
all the cervical, thoracic, lumbar, and sacral s)Tnpathetic ganglia. The vertebrae like the
other bones, are provided with nerves, which are overlooked in a hasty examination
from their excessive tenuity.
The Splanchnic Branches. — ^These constitute the splanchnic nerves, which require a
separate description.
The Splanchnic Jferves.
The splanchnic nerves are divided into the great splanchnic and the small splanchnic
or renal *
The Great Splanchnic Nerve. — ^The great splanchnic is a white nerve, and has no re-
semblance to the ganglionic nerves. It is formed in the following manner : a thick
branch derived from the sixth and seventh thoracic ganglia, sometimes also from the
fifth, and even from the fourth ganglion (see fig. 302), passes downward and inward upon
the side of the dorsal vertebrae : this branch is joined by a series of three or four smaller
branches given off not only from the succeeding thoracic ganglia, but also from the com-
municating cords between them ; these branches {g g) are parallel to each other, and
pass obliquely downward and inward. The eleventh and twelfth thoracic ganglia never
assist in the formation of the great splanchnic nerve.
The branches just mentioned unite on each side to constitute the great splanchnic
nerves, which have the same relation to the thoracic ganglia that the cardiac nerves
have to the cervical ganglia : it is important to remark that the ganglionic nerves of the
thoracic viscera are derived from the cervical ganglia of the sympathetic, and that the
ganglionic nerves of the abdominal viscera are given off from the thoracic ganglia.
In general, the great splanchnic nerve arises by four roots ; but not unfrequently it
arises only by two, which then represent the four origins.
If, after having macerated the parts in diluted nitric acid, an attempt be made to de-
termine exactly the highest point from which the great splanchnic nerve originates, it
will be seen that the white filaments of which this nerve is composed are already dis-
tinct opposite the third thoracic ganglion, and, moreover, that they are merely in contact
with the trunk of the sympathetic and with the ganglia, and are continuous with the
coomiunicating branches from the spinal nerves. Anatomy, therefore, most clearly
proves that the splanchnic nerve is continuous with the spinal nerves.
Thus formed and completed opposite to the eleventh rib, the great splanchnic nerve
passes downward and inward in front of the vertebral column ; it becomes flattened and'
widened, perforates the diaphragm, the fibres of which separate to allow it to pass
through, and immediately terminates in the semilunar ganglion {x). An oUve-shaped
ganglion is not unfrequently found upon the great splanchnic, at a short distance before
the nerve passes through the diaphragm.*
The Small Splanchnic, or Renal Nerves.-^ think it proper to include in the same de-
scription the lesser splanchnic nerve of authors, and the posterior renal nerves of Walter,
the distinction between these nerves appearing to me to be quite arbitrary. They are
two, ani sometimes three in number. The highest is named the small splanchnic (h) ; it
arises from the eleventh thoracic ganglion, and sometimes from both the tenth and the
eleventh. The lowest, which is the renal nerve of authors, is larger than the preceding,
and is derived from the twelfth thoracic ganglion (f) : it often gives off a small fileunent
to the first lumbar ganglion, and in a great number of cases this is the only means of
communication between the thoracic and the lumbar ganglia of the sympathetic. In
such a case, the series of ganglia is said to be interrupted ; but a complete interruption
never exists.
The small splanchnic or renal nerves exactly resemble the separate or single origins
of the great splanchnic, with which they form a continuous series. They arise in the
same manner, from the two or three inferior thoracic ganglia. They pass inward and
downward, parallel to and on the outer side of the great splanchnic, perforate the crus
of the diaphragm either to the outer side of or at the same point as the great nerve, and
enter the renal and aortic plexuses ; they are often shared between these two plexuses
and the great splanchnic nerve. The highest of the small splanchnic nerves rather fre-
quently anastomoses with the great splanchnic, or even becomes entirely blended with it.t
* Lobstein has recorded a case (p. 2) mwhich this unusual ganglion on the great splanchnic was of a semi-
lunar shape, and gave off, from its convex side, seven or eight slender filaments, which accompanied the aorta
and were all lost in the diaphragm ; he has also mentioned another case, in which three filaments arose from
this ganglion, two going to the solar plexus, and the third to the mesenteric plexus.
t Among the numerous varieties which I have observed in the formation of the small splanchnic nerves, I
would especially notice the following: a twig from the eleventh thoracic ganglion, and one from the great
splanchnic nerve, terminated in a small ganglion ; from this ganglion were given oflf several filaments that
were lost ni)on the aorta, and also a small cord which joined with a twig from the twelfth thoracic ganglion,
and was di.itributed in the ordinary manner.
5R
866 NEUROLOGY.
The Visceral Ganglia and Plexuses in the Abdomen.
As the semilunar ganglia and the visceral plexuses in the abdomen form the continuation
of the splanchnic nerves, it is not only theoretically, but practically convenient to enter
upon their description now.
The central point of all these ganglia and plexuses is situated at the epigastrium, and
is formed by a ganglionic plexus, named the solar or epigastric plexus.
The Solar or Epigastric Plexus.
The solar plexus (opposite x,fig. 302) is formed by an uninterrupted series of ganglia,
extending from the great splanchnic nerve of the one side to its fellow of the opposite side.
From this point as from a centre proceed a great number of branches, which have been
compared to the rays of the sun, and hence the term solar plexus.
This solar plexus, which is regarded by physiologists as the centre of the nervous sys-
tem of nutritive life, is deeply seated in the epigastric region, and might therefore be
called the epigastric nervous centre ; it is situated in the median line, in front of the aorta,
around the coeliac axis, and above the pancreas ; it is bounded on each side by the supra-
renal capsules, and is of too irregular a shape to be clearly defined. The ganglia of
which it is composed, the solar ganglia, are as irregular and variable as the plexus it-
self They consist of thick and swollen cords, or ganglionic arches or circles, arranged
in a network, in the meshes of which are found some lymphatic glands easily distin-
guishable from the nervous ganglia and cords. Anatomists, in general, describe only the
two extreme ganglia of the solar plexus, in which the great splanchnic nerves terminate ;
these are the semilunar ganglia (x), so called from their shape, but which are subject to
much variety both in form and size. Their convex border, which is turned downward,
is divided into several teeth, from each of which a pencil of nerves is given off; a great
number of filaments are also given off from their concave border, which is directed up-
ward. These ganglia are situated close to the supra-renal capsules ; they are often
without any regular form, and, as it were, divided into fragments.
A single glance at the solar plexus will suffice to convince us of the impossibility of
extirpating it, as some experimenters pretend to have done, in living animals.
The great splanchnic nerve of each side (g), a part of the small splanchnic nerves (A),
and the right pneumogastric nerve (j)'), end in the solar plexus. I have also seen the
right phrenic enter this plexus.
From it, as from a centre, plexuses are given off for all the arteries arising from the
fore part of the aorta, and also for the renal and spermatic arteries. The plexuses for
the renal arteries and the inferior mesenteric artery are completed by the visceral nerves
derived directly from the lumbar ganglia. There are two diaphragmatic plexuses, a coeliac
plexus, a superior and an inferior mesenteric plexus, renal plexuses, spermatic or ova-
rian plexuses, and supra-renal plexuses.
All the nerves given off from the solar ganglia are gray, and very small ; they are al-
ways plexiform, and are generally strong on account of the thickness of their neurilemma.
The Diaphragmatic and Supra-renal Plexuses.
The diaphragmatic or phrenic plexuses are small ; they are given off from the upper part
of the solar plexus, and reach the phrenic arteries, with which they enter the diaphragm ;
they at first lie beneath the peritoneum, but afterward dip into the substance of the fleshy
fibres of the muscle, and do not exactly follow the course of the vessels. In some cases
I have been able to ascertain that they anastomose with the filaments of the phrenic
nerve : they always run in nearly the same direction.
The diaphragmatic plexus of the right side is larger than that of the left. I have seen
two ganglia, upon the right cms of the diaphragm, which formed the origin of the right
diaphragmatic plexus and of some hepatic nerves.
I arrange the plexuses of the supra-renal bodies with the preceding, because they have
so many relations with them. They arise directly from the semilunar ganglia, by two
very delicate pencils of nerves, which reach the back of the supra-renal arteries, and are
lost in the substance of the supra-renal bodies. Several filaments from the diaphrag-
matic plexuses join them, passing in front of the arteries. The supra-renal plexuses are
large in proportion to the size of the organs they supply.
The Cceliac Plexus.
The coeliac plexus is one of the principal divisions of the solar plexus, of which it is
• the immediate prolongation, so that it is almost impossible to distinguish one from the
■ other ; it surrounds the coeliac axis, and immediately divides, like it, into three plexuses,
.the coronary of the stomach, the hepatic, and the splenic.
The Coronary Plexus of the Stomach. — This is given off from the upper part of the solar
t plexus ; it receives some filaments from the right pneumogastric, before that nerve joins
;. the solar plexus ; of these filaments, some ramify upon the cardia, while the remainder
follow the coronary artery along the lesser curvature of the stomach, and anastomose
■jwith the pyloric filaments of the hepatic plexus. It follows, therefore, that the stomach
THE SUPERIOR MESENTERIC PLEXUS. 867
is principally supplied by the pneuraogastric nerve. The filaments from the coronary
plexus of the stomach, as well as those of the pneumogastric nerve, after having run for
some distance beneath the peritoneum, perforate the muscular coat of the stomach, and
appear to be partly lost in it and partly in the mucous membrane.
The hepatic plexus is of very considerable size, and might be divided, after the example
of Lobstein, into an anterior and a posterior plexus. The anterior accompanies the hepat
ic artery, and is formed by some twigs from the right pneumogastric, and by seven or
eight large gray, cylindrical filaments from the left semilunar ganglion, which are joined
by two or three branches from the right semilunar ganglion.
The posterior hepatic plexus accompanies the vena portae, and is derived almost entirely
from the right semilunar ganglion ; it is also composed of grayish, thick, cylindrical cords.
I would especially notice one cord, which is remarkable both from its size and its course ;
it arises directly from the solar ganglion of the right side, passes in a horizontal and
curved direction to reach the gastro-hepatic omentum, and continues horizontally be-
tween the layers of that omentum, in front of the lobulus Spigelii ; it then ascends to
the transverse fissure of the liver, becomes situated beneath the vena portae, and may
be traced along that vein into the interior of the liver. I have seen this great he-
patic branch come directly from two ganglia situated upon the right crus of the dia-
phragm.
Before reaching the liver, the hepatic plexus gives off a secondary plexus of consider-
able size, around the right gastro-epiploic artery, the right gastro-epiploic plexus ; it is
considerably augmented by filaments which are derived immediately from the solar
plexus, and perforate the pancreas.
The hepatic plexus also furnishes branches to the pylorus and the lesser curvature of
the stomach, to the pancreas, to the great curvature of the stomach, and to the great
omentum. The pylorus, therefore, and the great curvature of the stomach, are supplied
almost exclusively by the hepatic plexus.*
The hepatic plexus likewise gives off a small cystic plexus, which is easily seen beneath
the peritoneum, surrounding the cystic artery as far as the gall-bladder.
Diminished in size, from having given off a series of branches and plexuses, the he-
patic plexus gains the transverse fissure of the liver, divides like the hepatic artery and
vena portae, and may be traced for some distance in the capsule of Glisson.
All the nerves of the liver are gray, but very strong.
The Splenic and Pancreatic Plexuses. — The splenic plexus is not so remarkable for the
number as for the size of the filaments of which it is composed ; it surrounds the splenic
artery, furnishes some twigs to the pancreas, and it also gives off the left gastro-epiploic
plexus, which is smaller than the right, is situated upon the great curvature of the stom-
ach, and supplies that organ and the great omentum. The splenic plexus also gives off
nervous filaments to the great cul-de-sac of the stomach, and being thus very much di-
minished in size, reaches the hilus of the spleen, within which organ it can be easily tra-
ced in man, and still more easily in the larger animals, along the ramifications of the
bloodvessels.
These nerves are gray, and very strong. The numerous filaments which pass to the
pancreas, and form a plexus around its arteries, constitute the pancreatic plexus, which
may be regarded as a dependance of the splenic plexus.
The Superior Mesenteric Plexus.
The superior mesenteric plexus, which may be regarded as the lower division of the bi-
furcation of the epigastric plexus, is the largest of all the abdominal plexuses ; it sur-
rounds the superior mesenteric artery, forming an extremely thick plexiform sheath for
it ; it passes below the pancreas, enters the substance of the mesentery {w) with the
artery, and divides, like that vessel, into a great number of secondary plexuses, which
are distributed to all the parts supplied by the artery, namely, to the whole of the small
intestine, excepting the duodenum, and to the right portion of the great intestine.
Without entering into tedious and useless details, I shall content myself with a few
remarks upon the general distribution of these nerves.
The mesenteric nerves are remarkable for their length, their number, and their
strength. I am certain that their neurilemmatic sheath is proportionally much thicker
than that of other nerves. They are placed at variable distances from the vessels, and
proceed in a straight line in the substance of the mesentery towards the intestine, with-
out giving off any filaments : at a short distance from the concave border of the intes-
tine, they either pass directly to the bowel, or else they anastomose at an angle or in
an arch ; from the convexity of these anastomotic arches the filaments for the intestine
are given off.
There is never more than one series of anastomotic nervous arches in the mesentery,
whatever may be the number of rows of vascular arches ; the single nervous arch al-
* The cardia and the lesser curvature of the stomach are the parts which are the most abundantly provided
with nerves. The pylorus, to which we attribute such great .".ensibility, has incomparably fewer.
NEUROLOGY.
ways cdiTesponds fb the vascular arch nearest to the intestine : the filaments ■which
proceed from it are exceefl'ngly minute.*
The nervous filaments pt netrate the intestine by its adherent border, run for some
time between the serous ai .d muscular coats, perforate the latter, to which they give
some twigs, then spread out lO the fibrous coat, and finally terminate in the mucous mem-
brane
The Inferior Mesenteric Plexus.
The inferior mesenterf pit ms (n) is formed by some twigs from the epigastric plexus,
:r, rather, from the sup( ric; mesenteric plexus, with which it is continuous on the front
lif the abdominal aorta ; ai l, secondly, by some branches from the lumbar sympathetic
4;anglia, which, as hereai'^tr stated, constitute the lumbo-aortic plexus. The meshes of
..he inferior mesenteric plexus are by no means so close as those of the superior mesen-
teric plexus.
The inferior mesenteric plexus, like the artery by which it is supported, supplies the
Left half of the transverse arch of the colon, the descending colon, the sigmoid flexure,
and the rectum : of its filaments, those which accompany the left colic arteries are re-
markable for their tenuity, their length, and for giving no branches in their course to
the intestine. I would particularly notice the twig which accompanies the left superior
colic artery. It is not uninteresting to remark, that these nerves are more numerous in
the iliac meso-colon, which supports the sigmoid flexure, than at any other point.
The inferior mesenteric plexus, thus diminished by having given off other smaller
plexuses, terminates, like the inferior mesenteric artery, by bifurcating ; the two divis-
ions of this bifurcation are called the hemorrhoidal plexuses ; they surround the two divis-
ions of the artery, viz., the superior hemorrhoidal arteries, and terminate partly in the
hypo-gastric plexus and partly in the rectum.
The Renal and Spermatic, or Ovarian Plexuses.
The renal plexuses are extremely complicated : they are formed by branches from the
solar plexus, and by the two or three small splanchnic or renal nerves, and terminate
almost exclusively by surrounding the renal artery.
The two spermatic plexuses in the male, and ovarian plexuses in the female, are derived
principally from the renal plexuses. The spermatic plexuses are destined exclusively for
the testicles ; the ovarian plexuses, like the arteries of the same name, are distributed
both to the ovaries and the uterus. The intimate connexions between the nerves of the
kidneys and testicles in the male, and those of the kidneys, ovaries, and uterus in the
female, deserve the most particular attention of anatomists.
The Lumbar Portion of the Sympathetic System.
The lumhar portion of the trunk of the sympathetic {II, fig- 302) is situated in front of the
vertebral column, along the inner border of the psoas muscle. The ganglia of this re-
gion are therefore nearer the median line than the thoracic ganglia ; but the inferior lum-
bar ganglia not unfrequently deviate from their ordinary position, and approach the lum-
bar nerves as these emerge from the spinal canal : in this case, they are concealed by the
psoas muscle. The lumbar ganglia of the sympathetic vary much in size ; some of them
are so small that they would escape notice, if their grayish colour did not distinguish them
from the rest of the trunk of the sympathetic.
The number of these ganglia is also variable ; there are rarely more than four.
Two or three ganglia are often blended into a gangliform cord ; this fusion may be easily
recognised by the arrangement of the communicating filaments between it and the lum-
bar spinal nerves.
In one subject, the twelfth thoracic ganglion on the right side was blended with the
first lumbar ganglion : a small filament, corresponding in length to the thickness of two
vertebrae, established a communication between this ganglion aiid a large gangliform
cord, which represented by itself the four inferior lumbar ganglia. On the left side, the
second and third lumbar ganglia were united, and the fifth was blended with the first
sacral. This fusion of the lumbar ganglia almost constantly exists, and it establishes a
close analogy between the lumbar portion of the sympathetic and the cervical portion,
which, as we have already seen, has only three, and frequently only two ganglia. It
proves that the superior cervical ganglion may be regarded as representing five superior
cervical ganglia and the ganglia corresponding to the two sets of cranial nerves, and
that the inferior cervical ganglion may be viewed as the representative of two lower cer-
vical ganglia, when the middle ganglion is wanting.
Moreover, the trunk of the sympathetic is not unfrequently interrupted either between
the twelfth thoracic and the first lumbar ganglion, or between the last lumbar and the
' In one case I found a very remarkable anastomosis. Four filaments, proceeding from four opposite points,
converged towards a common centre ; but, as they were about to cross, they diverged from one another so as
to intercept a lozenge-shaped space. Two of these might lie regarded as filaments of origin, and the other
two ;i5 terminating filaments
LUMBAR PORTION OF THE SYMPATHETIC SYSTEM. 869
first sacral ganglion : this interruption is, however, more apparent than real, for. as I
have already stated, the continuity between the twelfth thoracic and the first lumbar
ganglion is always established by means of a small twig from the renal nerve.
The branches of the lumbar ganglia may be divided into the branches of communi-
cation between the ganglia ; the external branches, and the internal branches : besides
these, there are some small and very delicate filaments, which enter the bodies of the
yertebrse.
The Communicating Branches between the Ganglia.
These communicating branches consist of one or more white cords extending between
every two ganglia ; they scarcely ever have the gray appearance and ganglionic struc-
ture usually found in similar branches of conununication : the communicating filament
between the fourth and fifth lumbar ganglion is often wanting.
The External Branches.
These are the branches (at d) which communicate with the lumbar nerves. I c6n-
ceive that they are furnished by the lumbar spinal nerves to the lumbar ganglia of the
sympathetic. There are generally two, but sometimes three for each ganglion ; they
arise from the anterior branches of the several lumbar nerves, as they emerge from the
inter- vertebral foramina ;* they accompany the lumbar arteries, along the grooves upon
the bodies of the lumbar vertebrae, and terminate in the corresponding ganglia ; they are
usually directed obliquely downward.
In general, each ganglion receives branches not only from the corresponding lumbar
nerve, but also from the nerve next above it. Thus, two branches end in the second
lumbar ganglion, one from the first, and another from the second lumbar nerve ; the
third ganglion receives filaments from the second and third lumbar nerves ; when one
ganglion is wanting, its place is supplied by the next, which receives its own proper
branches, and also those belonging to the absent ganglion. One ganglion not unfrequent
ly communicates with three lumbar nerves.
When several ganglia are united into one, it is easy to conceive that this single gan-
glion must receive aU the filaments corresponding to those ganglia. It is also easy to
understand that these filaments must be directed more or less obliquely either upward
or downward, and that they will correspond in length to the distance between the lum-
bar nerves and the single ganglion, the superior filaments being directed downward,
and the inferior filaments upward.
A very remarkable condition of the branches of communication between the lumbar
nerves and the sympathetic ganglia consists in the existence of certain ganglia or swell-
ings upon them ; and the ahnost indefinite anomalies observed in this particular are no
less remarkable. I have found as many as three ganglionic nodules upon the same
communicating branch: sometimes, when the two or three communicating branches
reach the side of a vertebra, they unite in a ganglion, from which two or three other
branches are given off to the proper sympathetic ganglion, t
Moreover, these ganglia, like all the irregular ganglia, rarely present that peculiar
character which is common to the regular ganglia, namely, that of forming a centre in
which a certain number of filaments end, and from which others are given off.
The Internal, or Aortic and Splanchnic Branches.
The internal branches from the lumbar ganglia are the aortic and the lumbar splanchnic
branches, and form a continuous and uninterrupted series with the aortic and splanchnic
branches from the thoracic ganglia ; so that the internal branches from the first (/) and
sometimes from the second lumbar ganglion join the branches from the eleventh and
twelfth thoracic ganglia, to form a small splanchnic nerve, which is shared between the
solar and the renal plexus. Some small gangliform nodules are occasionally found upon
the course of these branches, among which are some very delicate filaments, which evi-
dently pass into the bodies of the lumbar vertebrae. All these internal branches assist
in the formation of the lumbar splanchnic, or pelvic visceral nerves.
The Lumbar Splanchnic Serves and the Visceral Plexuses in the Pelvis.
The lumbar splanchnic nerves (at k) pass inward in front of the aorta, below the su-
perior mesenteric artery, and anastomose with each other and with those of the opposite
side to form a very complicated plexus, which is completed by a very considerable pro-
longation from the superior mesenteric plexus.
This plexus (n), which may be called the lumbo-aortic plexus, surrounds all that por-
tion of the aorta which is included between the superior and inferior mesenteric arteries ;
in the intervals between the nervous filaments are found lymphatic glands, which should
be carefully distinguished from some nervous ganglia which form part of the plexus.
The lumbo-aortic plexus is bifurcated below ; one portion of it passes upon the infe-
* These communicating branches frequently arise in the substance of the psoas muscle from twigs derived
from the lumbar plexus.
f This dispositiou is well seen in the beautiful plate of the sympathetic published by M. Manec.
NEUROLOGY.
rior mesenteric artery to constitute the greater part of the inferior mesenteric plexiis
(below n) ; while the other portion descends upon the aorta, and even a little below the
bifurcation of that vessel, and ends between the common iliac arteries, in front of the
sacro-vertebral angle, from which it is separated by the common iliac veins. Some fila-
ments are prolonged around the common iliac and the external and internal iliac arter-
ies and their branches.
The aortic portion of the lumbo-aortic plexus bifurcates below into two secondary plex
if arm cords, one right and the other left, which pass downward upon the sides of the rec
turn and bladder, and enter the right and left hypogastric plexuses, which are almost
entirely formed by these cords.
The Hypogastric Plexuses.
The hypogastric plexuses (m) are among the great plexuses of the body ; they supply
the rectum and the bladder in both sexes, and also the prostate and testicle in the male,
and the vagina, uterus, and Fallopian tubes in the female.
There are two hypogastric plexuses, one on the right, the other on the left side. They
are situated upon the lateral and inferior surfaces of the rectum and bladder in the male,
and of the rectum, vagina, and bladder in the female ; they are distinct from each other,
and are connected not by median anastomoses, which I have never been able to detect,
but through the lumbo-aortic plexus, by the bifurcation and spreading out of which they
may be said to be formed. The hypogastric plexuses, from the enlargement and areolar
disposition of their component cords, very closely resemble the solar plexus.
Each plexus is formed essentially by one of the two divisions of the lumbo-aortic
plexus ; it is also joined by some filaments from the inferior mesenteric plexus, by some
very small twigs from, the sacral ganglia, among which those derived from the third sa-
cral ganglion are especially remarkable ; and, lastly, by some twigs from the anterior
branches of the sacral nerves (see Sacral Nervks).
Formed by a combination of filaments from these different sources, each hypogastric
plexus gives off a hemorrhoidal, a vescical, a vaginal, a uterine, and a spermatic or ova-
rian plexus ; all of these plexuses, like the hypogastric plexus itself, are found on each
side of the body.
The inferior hemorrhoidal plexuses are blended with the superior hemorrhoidal plex-
uses, which, as already stated, are the terminations of the inferior mesenteric plexus ;
they pass behind and in front of the rectum. The filaments belonging to the anterior
branches of the sacral nerves may be distinguished from those belonging to the sympa-
thetic system by the difference in the colour of the two kinds of nerves.
The vesical plexuses are composed of a great number of exceedingly small filaments.
They are situated upon the sides of the posterior fundus (bas-fond) of the bladder, on the
outer side of the ureters, and are divided into two sets, viz., ascending vesical nerves,
which pass upward upon the sides of the bladder, embrace the outer and inner surfaces
of the ureters, and ramify upon the anterior and posterior surfaces of the bladder ; and
horizontal vesical nerves, which run forward upon the sides of the fundus of the bladder,
externally to the large plexus of veins found in that situation, and spread out into ex-
tremely delicate filaments, of which some enter the substance of the bladder, especially
at its neck, while the others, in considerable numbers, turn round the prostate gland,
and are distributed within it ; one of the prostatic filaments may be traced into the mem-
branous portion of the urethra.
The Plexuses for the Vesictila Seminales, and Vasa Deferentia, and Testicles. — Some of
the filaments situated on the inner side of the ureters surround the vesiculae seminales,
and are lost in them ; these are very small ; two or three remarkably large filaments run
upward along each vas deferens ; having reached the inguinal ring, they unite with the
corresponding spermatic plexus, which is a production of the renal plexus, and descend
to the testicle.
The branches for the prostate, vesiculae seminales, vasa deferentia, and testicles, are
represented in the female by the utero-vaginal, ovarian, and tubal nerves.
The Uterine Nerves. — Notwithstanding the figures of the sympathetic published by
Walter, in which the nerves of the uterus are well represented, and notwithstanding the
still more explicit description given of them by Hunter, most anatomists continue to en-
tertain doubts regarding the existence of the uterine nerves. Lobstein, in his work on
the Sympathetic, published in 1822, even denied them altogether ; but Tiedemann, in the
same year, published two beautiful figures, representing the nerves of the gravid uterus.*
The uterine nerves are derived from several sources. I have already stated that the
plexuses surrounding the ovarian arteries, which are productions of the renal plexuses,
are distributed, like the vessels by which they are supported, both to the uterus and the
ovaries.
It appears to me that the ovarian nerves and vessels have a similar arrangement, that
is to say, that the uterine branches derived from the ovarian plexuses are larger than the
ovarian nerves properly so called.
* Tabula Nervorum Uteri, Heidelberg, 1822, folio.
GENERAL VIEW OF THE SYMPATHETIC SYSTEM. 8H
The tubal nerves are also derived from the ovarian plexuses.
The uterine nerves derived from the hypogastric plexuses are divided into ascending
branches, which run upward along the lateral borders of the uterus, pass forward and
backward upon the surfaces of that organ, and terminate in its substance ; and into de-
scending branches, which run along the sides of the vagina, and terminate in it. These
vaginal nerves appear to be inseparably blended with the vesical and hemorrhoidal
nerves.*
Such are the divisions of the hypogastric plexuses ; analogy, rather than direct obser-
vation, has led to the admission of the existence of gluteal, ischiatic, and internal pudic
plexuses ; in fact, of plexuses around all the branches of the internal iliac arteries.
The Sacral Poetion of the Sympathetic System.
The sacral portion of the sympathetic (s s, fig. 302) is formed on each side by a cord en-
larged at intervals, and situated on the inner side of, and along the anterior sacral fo-
ramina.
It forms a continuation of the lumbar portion of the sjnnnpathetic ; but sometimes there
appears to be an interruption in the ganglionic chain, between the fifth lumbar ganglion
and the first sacral. This interruption is merely apparent ; it is never complete. The
sacral trunks of the sympathetic of the right and left sides gradually approach each other
as they descend, corresponding in this respecf to the anterior sacral foramina.
The sacral ganglia, which are rarely five, more commonly four, and sometimes three
in number, are occasionedly collected into a small gangliform enlargement, situated be-
tween the first and second anterior sacral foramen ; the first sacral ganglion is some
times double, and at other times it rather resembles a gangliform cord than a true gan-
glion.
The mode of connexion between the first sacral and the last lumbar ganglion is sub-
ject to much variety. + The manner in which the sacral portion of the sympathetic terr-
minates is also somewhat variable. The following is the arrangement most generally
admitted : a filament proceeds from the last sacral ganglion, which is usually the fourth,
and forms an anastomotic arch with its fellow of the opposite side, in front of the base
of the cocc)rx. At their point of junction is often found a small ganglion (ganglion inp-
par, c), from which certain terminal filaments are given off. Sometimes there is neither
a coccygeal ganglion nor any anastomosis, properly so called, but the terminal filaments
are distributed in the usual way. I have not been able to trace these filaments beyond
the periosteum of the coccyx and the sacro- sciatic ligaments.
Like the other ganglia of the sympathetic, the sacral ganglia present communicating
branches with each other ; rather large external branches derived from the corresponding
sacral nerves ; internal branches, which anastomose with those of the opposite side, in
front of the sacrum, and surround the middle sacral artery. Some of these filaments I
have distinctly seen entering the substance of the sacrum ; and^ lastly, very small ante-
rior branches (y), some of which join the hypogastric plexuses, while the others termi
nate directly upon the rectum.
General View of the Sympathetic System.
The following dissection is necessary, in order to present a correct general idea of the
S)mapathetic system.
Take a spinal column which has been macerated in diluted nitric acid, remove the
bodies of the vertebrae, leaving, if it be wished, the inter- vertebral substances ; be very
careful to preserve the branches of communication between the sympathetic and the cra-
nial and spinal nerves.
It is then clearly seen that the two gangliated trunks of the S3rmpathetic are connect-
ed with the cerebro-spinal axis by as many roots, or small groups of roots,t as there are
cranial and spinal nerves ; it is, moreover, no less evident that the communicating
branches between the ganglionic chain and the spinal nerves do not proceed from the
ganglia, but from the spinal nerves ; so that it may be stated as a demonstrated ana-
tomical fact, that the sympathetic system has its origin in the cerebro-spinal system <)
* [Dr. Lee has recently examined minutely the distribution of the nerves of the unimpregnated and fravid
uterus. He has described (Anatomy of the Nerves of the Uterus, with plates, 1841, and Proceedings of the
Royal Society, No. 49) several large uterine plexuses ; also, several " large ganglia on the uterine nerves, and
on those of the vagina and bladder ;" and, farther, '' two great ganglia situated on the sides of the neck of the
uterus."] 1 • • J u
t In one case, the continuation of the lumbar portion of the sympathetic deviated outward, and joined the
fifth lumbar nerve ; a very small filament only formed the communication between the last lumbar ganglion
and the first sacral. In another case, these two filaments proceeded from the last lumbar ganglion of the right
side, t'ae inner of which joined the first sacral ganglion of the opposite side, crossing over the sacro-vertebral
t It must be remembered that there are always two, and sometimes three communicating branches between
the sympathetic and each of the spinal nerves.
4 These facts in human anatomy are in perfect accordance with the observations in comparative aiiatomr
made by Meckel and Weber, namely, that the development of the sympathetic system is in direct ratio with
that of the cerebro-spinal system ; tliat the former is more developed in man than in any other animal, and 19
proportionally larger in the fietus than in the adult.
872 NEUROLOGY.
The sympathetic trunks of the right and left side generally anastomose below in front
of the coccyx ; it has been somewhat hastily affirmed that they anastomose above, either
upon the pituitary body, or upon the anterior communicating artery of the brain ; the
true anastomoses of the two halves of the sympathetic system are in the central and
median plexuses.
If, after having acquired this general idea of the trunks of the sympathetic, its neuri-
lemma be removed by continued maceration in water, the connexions of the branches
given from the spinal nerves to the ganglia, with the branches given from the ganglia to
the viscera, may then be ascertained : it then becomes evident, that the greater number
of the branches from the spinal nerves do not penetrate to the centre of the ganglia, but
expand, as it were, upon their surface, and divide into two sets of filaments ; of these,
some are applied to the surface of a ganglion, and proceed directly to form the internal
or visceral branches ;* while the others assist in forming the cords of communication
between one ganglion and another, and divide into ascending and descending filaments,
of which the latter are the more numerous. They all run along the outer side of the cords
of communication, and afterward become visceral branches themselves ; it is doubtful
whether any filament arises in the interior of a ganglion ; the continuity of them all can
be traced completely through these bodies.
It follows, therefore, that it is anatomically shown that the visceral nerves given off
from the sympathetic are connected or belong to a very great nimiber of spinal nerves
at once, and always to spinal nerves much higher than that portion of the sympathetic
from which the visceral branches are immediately given off; and again, that the vis-
ceral or splanchnic nerves, the actual origins of which we have seen to be so complica-
ted and so remote from their apparent origins, always run a very long course before
reaching their destination. Thus, the splanchnic nerves of the thorax or the cardiac
nerves are derived from the cervical ganglia ; the splanchnic nerves of the abdomen are
given off, for the most part, by the thoracic ganglia ; and most of the splanchnic nerves
of the pelvis proceed from the lumbar ganglia. Nevertheless, the proper ganglia of each
splanchnic cavity complete the visceral nerves belonging to that cavity. Thus, the first
thoracic ganglion assists in the formation of the cardiac nerves ; the superior lumbar
ganglia in that of the visceral nerves of the abdomen ; and the sacral ganglia in that of
the pelvic nerves.
The visceral nerves sometimes pass directly to the viscera from the ganglia of the
sympathetic, and sometimes indirectly, after being mingled and combined in plexuses.
There is no relation between the branches which enter and those which pass out of
the several visceral plexuses, so that the branches which proceed from the ganglia and
trunk of the sympathetic to those plexuses must be regarded, not as branches of forma-
tion, but as branches of communication.
The visceral plexuses are also formed in a very peculiar manner, not only by inter-
laced nerves, but by nerves and ganglia, and these nerves themselves present a gangli-
onic structure altogether different from the fasciculated and plexiform structure of other
nerves.
There are four great visceral plexuses : the pharyngeal plexus, the cardiac plexus, the
solar plexus, and the hypogastric plexus ; the largest of all these is the solar plexus,
which, both in an anatomical and in a physiological point of view, deserves the title of
the abdominal brain, which was given to it by Wrisberg. These four great plexuses
may also be very properly regarded as nervous centres, to which all the physiological
and pathological phenomena of the nutritive system are singly or collectively referred.
These visceral plexuses differ as much from the ganglionic chain formed by the two
trunks of the sympathetic as these trunks differ from the spinal cord itself : in these
plexuses a sort of fusion is effected between the cerebro-spinal and the sympathetic sys-
tems, and also between the trunks of the sympathetic belonging to the two sides of the
body.
The pneumogastrie assists in the formation of three of these jdexuses ; namely, the
pharyngeal, the cardiac, and the solar plexus. In man there is a tendency to fusion of
the pneumogastrie with the sympathetic, and in the lower animals this fusion is still
more complete ; it is in those animals in which the sympathetic is the least developed
that the par vagum acquires its greatest development, and supplies the place of the for-
mer in reference to the intestinal canal.
The glosso-pharyngeal nerve also assists in the formation of the pharyngeal plexus,
and the sacral nerves contribute to that of the hypogastric plexus.
The visceral plexuses differ essentially from those formed by the cerebro-spinal nerves.
In the latter, the branches which emerge from the plexus are precisely the same branch-
es that entered it, only combined in a different manner. However inextricable they
may be, the plexuses of the spinal nerves are merely points in which a number of affe-
rent branches converge and combine together. In the visceral plexuses, on the contra-
ry, there is no relation, either in size or structure, between the afferent branches and
the plexuses themselves.
* Some filaments from the spinal nerves are seen to croFS at right angles over the anterior surface of the
gang^iia, and then to join the visceral nerves ilirectlv.
GENERAL VIEW OF THE SYMPATHETIC SYSTEM.
873
The nerves derived from the sympathetic system differ eilso in their mode of distribu-
tion from the nerves of the cerebro-spinal system. In general, they form a plexiform
sheath around the vessels, and enter with them into the substance of organs. This ar-
rangement has induced some anatomists to believe that the sjrmpathetic nerves belong
essentially and exclusively to the vascular system, and are lost upon the coats of the
arteries ; others hold an opposite opinion, and deny altogether that the sympathetic
nerves enter the coats of those vessels. From some researches which I have made on
this subject, I believe that there are proper filaments for the coats of the vessels, but
that these are very few in number, and that by far the larger number of the nervous fila-
ments are intended for the several organs. It is not uninteresting to remark, that the
s)Tnpathetic nerves always accompany the arteries, and never the veins ; the trunk of
the vena portae forming the only exception to this rule.
A gray colour and a soft texture are not, as is generally stated, the peculiar character-
istics of the nerves of the sympathetic system ; the gray colour is observed only in a
portion of this system ; and the softness, which only very rarely accompanies the gray
colour, is confined to a very minute portion of it indeed.
There are gray cords, which are nothing more than prolonged ganglia, and are not
nerves, properly so called ; when examined they present no nervous structure, that is
to say, they contain no white funiculi which can be decomposed into primitive filaments
as fine as the silk fibre. Almost all the sympathetic nerves are of a white colour, which
is sometimes conceeiled by an unusually thick neurilemma. The structure of the white
nerves of the sympathetic system does not differ from that of the cerebro-spinal nerves ;
except that the funicidi of the former are smaller, and their arrangement is more deci-
dedly plexiform.* Lastly, there are some mixed nerves, partly gray and partly white,
which partake of the structural characters of both the gray and the white nerves, t
* See note, p. 840.
+ I am much indebted to M. C.Bonamy, my private prosector, for the zeal and ability with which he ha»
assisted me in the numerous dissections required for the compilation of this work.
SOURCES FROM WHICH THE ILLUSTRATIVE ENGRAVINGS HAVE BEEN TAKEN.
Figs. 1 to 7, 8t, 9 to 20, 24, 25, 28 to 30, 33, 34, 36,
38, 41 to 45, 47, 48t, 49 to 53, 57 (Sue).
Figs. 21 to 23, 37 (Gordon).
Figs. 26, 27, 35, 58t to 60t, 61 to 70, 71t, 72 to 84,
106 to 110, lilt, 112, 113, 114t, 115, 116t to 123t, 124
to 126, 127t, 128 to 133, 141t, 147t, 155, 161, 163t,
169t, 170, 171t, 191t, 192, 194, 195 (Bourgery).
Figs. 39, 40, 46t, 54 to 56 (Ckeselden).
Figs. 85 to 94 (Hunter).
Fig. 95 (d.) (Retzius).
Fig. 97 (d.) (Goodsir).
Fig. 98 (Serres).
Figs. 99, 101, 102 (Blake).
Fig. lOO (T. Bell).
Figs. 103 (d.) to 105 (d.), 286 (Cloquet).
Figs. 136t, 138, 181 (Morion).
Fig. UOf (Watts).
Figs. 142, 173 to 175, 178, 231, 233, 234, 257 (Sam-
mrring).
Figs. 145, 160, 182, 187, 189,220,221,223t(We6er).
Figs. 152, 153 (Boyd).
Figs. 154t, 198 to 206, 208 to 218 (Tiedemann).
Fig. 156 (No. 2) (Krause).
Fig. 156 (No. 3) (Dallinger).
Figs. 157 to 159, 162 (Boehm).
Fig. 172 (Reisseissen).
Fig. 180 (d.) (Wagner).
Fig. 183 (A. Cooper).
Fig. 185 (Holier).
Figs. 207, 232t, 235 to 240, 242 to 246, 248, 249,
251t, 252 to 256, 258 to 265, 266, 269 to 275, 284, 285,
296tto301t (Arnold).
Fig. 219t (Walter).
Fig. 222t (Caldani).
Fig. 226 (Harvey).
Figs. 227, 228 (Gurlt)
Fig. 250 (Brewster).
Fig. 268 (Cruveilhier).
Figs. 281t, 283, 295 (Mayo).
Figs. 289t, 290t (Saan).
Fig. 302t (Manec).
Figs. 143 (d.), 144 (d.), 164* (d.), 179 (d.), 193+,
197, 241 (d.), 276 to 280, 282 (Models, Castt, and Di
agrams in the Museum of Anatomy, University College).
Figs. 31, 32, 96, 98* (d.), 134 (d.), 135 (d.), 137 (d.),
139 (d.), 146 (d.), 148 (d.), 149 (d.) to 151 (d.), 156
(No. 1, d.), 164, 176 (d.) to 178 (d.), 184 (d.), 186 (d.),
190 (d.),196 (d.),218* (d.),224 (d.),225 (d.),229 (d.),
230 (d.), 247 (d.), 267 (d.), 287 (d.), 288 (d.), 291 (d.)
to 293 (d.) (Original).
Figs. 165 to 168 (Kieman).
The mark (t), affixed to the number of a figure, indicates that such figure differs in some respects from the
(aiginal. The letter (d.), similarly aflixed, signifies that the figure is intended as a diagram or plan. Th«
asterisk (*), used occasionally, serves to distinguish between two figures bearing the same number
5S
««#***'<'
'*ll^-
INDEX.
Abdomen, aponeurosis of, anterior, 300.
posterior, 305.
superficial, 297.
regions of, 352.
Abducens, nerve. See Nerve, Motor Ocul.
Abductor muscles. See Muscles.
Accessory ligaments. See Ligaments.
nerves. See Nerves.
Acetabulum, 88.
Acini of glands. See those glands.
Acromion process, 76.
Adductor muscles. See Muscles.
Adipose tissue, 175.
Alee of sphenoid bone, lesser, 37.
greater, 37.
vespertilionis, 475.
Alimentary canal, 322.
appendages of, 384.
coats of, 322.
direction and situation of, 323.
divisions of, 322.
—————— dimensions of, 323.
form of, 323.
• membranes of, 323.
' muscular fibres of, 323.
structure of, 323.
Alveoli, 53, 58.
Amphiarthroses, 113.
■ characters, ligaments, and motions, 113
Ampulla of semicircular canals, 677.
Amygdala, 333. See Tonsils.
Amygdaloid fossa, 331.
Anastomoses of arteries, 496.
lymphatics, 614.
nerves, 762.
veins, 574.
Anastomotic artery, brachial, 544.
femoral, 565.
ATUitomy, objects and divisions of, 1, 2.
descriptive, 1.
general, 1, 2.
Anfractuosities. See Cerebrum.
Angeiology, 479,
Angle, sacro-vertebral, 26.
of the femur, 93.
facial, of Camper, 45.
occipital, of Daubenton, 45.
of the jaw, 58.
changes daring growth, 59.
of the pubes, 89.
Angles of bones, 9.
AtucIc joint, 168.
ligaments of, 169.
Ankle. See Tarsus.
Annular ligaments. See Ligament!.
Anti-helix, and its fossa, 666.
tragus, 666.
Antrum Highmori, 52.
pylori, 355.
Anus, 380.
muscles of, 380.
structure of, 380
Aorta. See Arteries.
Aponeurology, 294.
Aponeuroses in general, 294.
classification of, 294.
containing, 294.
definition of, 294.
functions of, 296.
insertion of, 294.
structure of, 296.
■ tensor muscles of, 295.
Aponeuroses in particular, 297.
————— abdominal anterior, 300.
layers of, 301.
Aponeuroses, cervical, superficial, 299.
cephalo-pharyngeal, 346.
costo-clavicular, 137.
of the cranium, 299.
cremasteric, 302.
cribriform, 309.
deltoid, 315.
dorsal of the foot, 314.
metacarpus, 318
interosseous, of foot, 314.
hand, 318.
■ epicranial, 298.
■ external oblique, 301
■ of the eyehds, 647.
face, 299.
■ femoral, 309.
septa of, 310.
sheath for vessels, 310.
' muscles, 311.
posterior, 305.
superficial, 297.
brachial, 316.
buccinator, 298.
buccinato-pharyngeal, 235.
cervical, deep, 299.
- of the fore-arm, 316.
-gluteal, 311.
- hypothenar, 319.
• iliac, 306.
• infra-spinous, 315.
• intercostal, 360.
■ inter-muscular of thigh, 310.
• of internal oblique, 304.
■of the leg, 312.
lower extremity, 309.
superficial, 297.
■ lumbar, or posterior abdominal, 30i6.
• lumbo-iliac, 306.
- masseteric, 298.
- of the neck, 299.
- obturator, 309.
- occipito-frontal, 298.
- occipito-pharyngeal, 346.
-palmar, 319.
-parotid, 298.
■ pedal, 314.
■ pelvic lateral, 308.
superior, 308.
■ of the pelvis, 306.
proper, 307.
• perineal, deep, 307.
superficial, 306.
■ petro-pharyngeal, 346.
■ of the pharynx, 346.
' plantar, external, 314.
internal, 314.
■ interosseous, 315.
middle, 314.
— prasvertebral, 299.
— of the quadratus lumborum, 306.
— recto-vesical, 308.
— of the serratus posticus, 300.
shoulder, 315.
• spermatic cord, 304.
sub-peritoneal, 305.
sub-scapular, 315.
superficial, 2i97.
of abdomen, 297.
supra-clavicular, 299.
supra-spinous, 315.
temporal, 298.
thenar, 319.
of the thorax, 300.
of transversalis, 305.
of the upper extremity, 316.
superficial, 297.
■ of velum palati, 346.
- vertebral, 205.
■ vesical, 309.
Aponeurotic sheaths for muscles, 296.
tendons, 296.
vessels, 296.
Apparatus, hyoid, 109.
Apparatttses of human body, general view of, 3, 4.
Appendices epiploicse, 372.
Appendix, ensiform, or xiphoid, 65.
vermiformis, 373
876
INDEX.
Appendix, vermiformis, development of, 384.
structure of, 373.
Aqueductus Fallopii, 43, 839.
vestibuli, 44.
cochlea;, 44.
Sylvii, 719, 742
Aqueous humour, 65.5.
membrane of, 655.
Arachnoid, 687.
canal (of Bichat), 687.
cranial portion of, ©7.
internal, 691.
loose, 690.
membrane of eye, 656 (note).
spinal portion of, 690.
uses of, 692.
Arbor vitas uterina, 465.
Arch, aortic, 502.
of colon, 374.
crural, 302.
femoral, 302.
gluteal, 3U.
orbital, 36.
palatine, 329.
pubic, 89.
sub-pubic, 307.
■ zygomatic, 61.
Arches, alveolar, 174.
dental, 174.
zygomatic, 61.
Arm, bone of, 78.
compared -with thi^h bone, 107.
Arteries in general, 496.
anastomoses of, 496.
branches of, 497.
coat of, external or cellular, 498.
internal, 498.
. middle, proper, or elastic, 498.
— ..— - — course or direction of, 496.
definition of, 496
division of, 496.
form of, 496.
nerves of, 497.
nomenclature of, 495.
origin of, 496.
preparation of, 497.
relations with other parts, 497.
retia mirabilia of, 496.
satellite muscles of, 497.
sheaths for, 499.
structure of, 499.
termination of, 498.
varieties of, 496.
vasa vasorum of, 499.
venae comites of, 497.
vessels of, 499.
Artery or Arteries in particular, 497.
of particular organs or tissues.
gans, Sec.
acromial, descending, 542.
supra-scapular, 538.
transverse, 542.
acromio-thoracic, 542.
of ala nasi, 518.
alar thoracic, 542.
alveolar, 524.
anastomotic, brachial, 544.
- great, of thigh, 564.
See those or-
angular, of face, 517, 529
aorta, 501.
abdominal, 503.
arch of, 502.
ascending, 503.
branches of, 503
descending, 503.
sinuses of, 501.
thoracic, 503.
valves of, 486.
arising from abdominal aorta, 606.
'■ — arch of aorta, 513.
varieties of, 513.
origin of aorta, 504.
termination of aorta, 552.
thoracic aorta, 505.
articular, of hip, 564.
knee, inferior, 565.
middle, or azyg»s, 565.
superior, 565.
- ascending cervical, 538
pharyngeal, 520.
Arteri; auricalar, anterior, 521.
posterior, 519.
aiiliary, 531, 542.
axis, coeliac, 507.
thyroid, 535.
azygos, or middle articular of knee 565.
basilar, 534.
brachial, 543.
brachio-cephalic, 531.
bronchial, 505.
' distribution of, 421.
buccal, 524.
of bulb, 558.
calcaneal, external, 570.
inferior, 571
capsular, inferior, 513.
middle, 513.
superior, 513.
cardiac, 503.
carotid, common, left and right, 514.
general distribution of, 530.
■ external or facial, 515.
- internal, 525.
• superficial, 515.
carpal, radial, anterior, 546.
posterior dorsal, 546.
ulnar, anterior, 549.
posterior dorsal, 549.
central of retina, 597, 665.
cerebellar, inferior, anterior, 534.
posterior, 534.
■ superior, 635.
cerebral, anterior. 529.
■ communicating anterior, 529.
• posterior, 529.
middle, 530.
posterior, 537.
cervical, ascending, 538.
deep, 540.
princeps, 519,
superficial, 539.
cervico-spinal, 538.
choroid, anterior, 530.
posterior, 536.
ciliary, anterior, 527.
middle, or long, 528.
posterior, or short, 528, 665.
circle of Willis, 536
circumflex, femoral, external, 564.
internal, 563.
iliac, 560.
humeral, anterior, 543.
posterior, 543.
of clitoris, 558.
coccygeal, 552.
coeliac (axis), 507.
colic, left, 511.
right, 510.
collateral, of fingers, radial, 547.
ulnar, 549.
humeral, external, 543.
internal, 543.
of knee. See Articular.
of toes, from external plantar, 57
internal plantar, 572
comites. See Satellite.
communicating, cerebral, anterior, 529.
posterior, 529, 535
palmar, 548.
plantar, 572.
of Willis, 529.
coronary of heart, left or anterior, 504.
right or posterior, 504.
• lips, inferior, 5l7.
superior, 518.
• stomach, 507.
of corpus callosum, 529.
cavemosum, 558.
cremasteric, 560.
crural, 560.
cystic, 508.
deep, brachial or humeral, 544.
cervical, 540.
femoral, 563.
temporal, 522.
deferential, 452.
dental, anterior, 524.
inferior, 523.
superior, 524.
■ diaphragmatic, inferior, 506.
INDEX.
877
Artery, diaphragmatic, superior, 539.
digital, collateral, radial, 547
ulnar, 549.
of foot, 572.
dorsal, carpal, radial, 547.
ulnar, 549.
■ of foot, 568.
— index finger, 548.
metacarpal, radial, 547.
ulnar, 549.
• metatarsal, 569.
• of nose, 529.
— penis, 558.
— scapula, 538.
— tarsus, 572.
— thumb, 548.
— toe, great, 572.
tongue, 518.
- dorsi-spinal, of inferior intercostals, 507.
superior intercostals, 540
- emulgent, 512.
■ epigastric, 559.
Superficial, 562.
■ epiploic, 510.
■ ethmoidal, anterior, 528.
posterior, 528. •
■ facial, 517.
• femoral, 559.
deep, 563.
Artery, magna pollicis, of hand, 547.
malar cutaneous, 521.
malleolar, externa], 567.
internal, 567.
mammary, external, 542.
internal, 539.
■ masseteric, 521, 523.
' mastoid, 520.
posterior, 519.
maxillary, external, 517.
internal, 522.
general distribution of, 525.
of median nerve, 549.
mediastinal, 540.
medullary, 506.
meningeal, anterior, 528.
middle or great, 522.
of ascending pharyngeal, 620.
posterior, 519, 514.
small, 523.
- of fissure of Sylvius, 529.
-of fraenum lingua;, 519.
- frontal, 529.
of temporal, 520.
• gastric, inferior, 509.
superior, 509.
■ gastro-duodenal, 508.
epiploic, left, 509.
right, 508.
hepatic, 508.
• gluteal, inferior, 556.
superior, 556.
• hemorrhoidal, 557.
inferior, 557.
middle, 554.
-superior, 511.
- helicine, 456.
■ hepatic, 508.
— in the liver, 391, 392.
■ humeral, 543.
deep, inferior, 544.
deep, superior, 544.
■hyoid, of lingual, 518.
superior thyroid, 515 (note).
• hjrpogastric, 553.
• iliac, common, 552.
external, 559.
internal, 553.
general distribution of, 558.
— mental, 523.
-- mesenteric, inferior, 511.
• superior, 510.
metacarpal, radial, 546.
■ ulnar, 549.
• metatarsal, 569.
■ muscular, of orbit, 528.
thigh, 562.
• musculo-phrenic, 540.
for mylo-hyoideus, 523.
nasal, 528.
• dorsal, 529.
-- lateral, 518.
— of pterygo-palatine, 524.
of septum, 518.
nutritious, of femur, 542.
fibula, 570.
humerus, 545.
tibia, 569.
■ obturator, 554.
• occipital, 519.
• (Esophageal, 505.
• omphalo-mesenteric, 511.
ophthalmic, 525.
' orbital, of temporal, 521.
ovarian, 512.
palatine, inferior, 517.
— superior, 524.
■ ileo-colic, 511.
■ ilio-lumbar, 555.
■ incisory, inferior, 523.
superior, 524.
• infra-orbital, 524.
or sub-scapular, 542.
spinous, 542.
' innominate, 531.
■ intercostals, anterior, 540.
aortic or inferior, 505.
superior, 540.
• interlobular, of liver, 391.
• interosseous, dorsal, of foot, 569.
— hand, 547.
of forearm, anterior, 548.
posterior, 549.
palmar, 547
■ plantar, 572.
recurrent, of forearm, 549.
■ of the intestines, great, 511.
■ small, 510.
intra-spinal, 534.
ischiatic, 556.
of labia pudendi, 558.
labial, inferior, 517.
superior, 517.
lachrymal, 526.
laryngeal, inferior, 516.
superior, 516.
lingual, 518.
lumbar, 506.
magna pollicis, of foot, 572.
■ palmar, deep, 546.
' palmar, interosseous, 548.
superficial, 547.
■ recurrent, 547.
• palpebral, inferior, 528.
superior, 528.
• pancreatic, great (from splenic), 509.
small (from mesenteric), 510,
• pancreatico-duodenal, 508.
■ parietal, 519, 521.
■ parotid, 520.
• of penis, 558.
dorsal, 558.
' perforating, of forearm, 549
palmar, 548.
peroneal, 570.
plantar, anterior and posterior, 569.
572.
• of thigh, 564.
• pericardiac, 495.
perinaeal, superficial, 557.
transverse, 557.
peroneal, 570.
anterior, 570.
• perforating, 570.
■ pharyngeal, ascending or inferior, 520.
■ pharyngo-meningeal, 520.
• phrenic, inferior, 507.
■ superior, 539.
■ for phrenic nerve, 539.
■ plantar, external, 571.
' internal, 571.
■ popliteal, 564
• prevertebral, 520.
• princeps cervicis, 519.
— pollicis, 547.
profunda cervicis, 549.
femoris, 563.
humeri, inferior, 545.
superior, 544.
pterygoid, of facial, 517.
internal maxillary, 523.
INDEX.
Artery, pterygo- palatine, 524. "^tffl^
pudic, external inferior; 562.''
superior, 56?.
internal, 557.
— in the female, 558.
pulmonary, 500.
'~ left branch of, 501.
right branch of, 501.
' distribution of, 431.
pyloric, inferior, 508.
superior, 508.
radial, 546.
■ collateral of fingers, 547.
recurrent, 540.
radialis indicis, 548.
radio-cubital, 549.
palmar, 547.
ranine, 518.
of receptaculum, 525.
— recurrent interosseous, of forearm, 549.
palmar, 547.
radial, 546.
tibial, anterior, 668.
internal, 569.
' ulnar, anterior, 549.
' posterior, 549.
■ renal, 512.
distribution of, 439.
■ of retina, central, 527.
■ sacral, lateral inferior, 556.
superior, 556.
middle or anterior, 552.
satellite of median nerve, 549.
phrenic, 540.
sciatic, 556.
ulnar, 548.
• scapular, inferior, 542.
posterior, 538.
■ superior, 538.
— sciatic, 556.
— for sciatic nerve, 556.
scrotal, 557.
— of septum of nose, 518.
' ventricles of heart, 504.
— short, of stomach, 511.
— sigmoid, 511.
spermatic, 511.
— spheno-palatine, 524.
spinous, 522.
— spinal, 534, 609.
anterior, 534.
■ general distribution of, 609.
Artery, thoracic htuneral, or deltoid, of acromio-tbora
cic, 542.
inferior, 542.
long, 542.
- thymic, 540.
- thyroid axis, 537.
inferior, 537.
middle, 515.
of Neubauer, 537.
superior, 516.
• tibial, anterior, 567.
posterior, 570.
recurrent, 567.
• tibio-peroneal, 569.
' tonsillar, 521.
■ transverse, of perineum, 556.
neck, 539.
face, 521.
• shoulder, 538.
■ tympanic, 522.
• ulnar, 548.
collateral, 543.
of fingers, 649.
recurrent, anterior, 549.
posterior, 549.
' umbilical, 553.
• uterine, 554.
■ vaginal, 554.
• of liver, 392.
■ vasa brevia, of stomach, 609.
• for vertebrae, 504.
• vertebral, 533.
• vesical, 553.
■ vidian, 524.
Arthrodia, 114.
characters, ligaments, and motions, 115
Arthrology, 111.
Articular surfaces, in general, 111.
- of particular articulations,
those articulations.
Se«
posterior, 534.
re-enforcing, cervical, 534.
lumbar, 504.
thoracic, 504.
of spinal cord, 504, 634.
— ^ — splenic, 509.
in spleen, 405.
for sterno-mastoid, 516, 519.
stylo-mastoid, 519.
sub-clavian, left and right, 531.
sub-diaphragmatic, 504.
sub-lingual, 518.
■ for sub- maxillary gland, 517.
—— — sub-mental, 517.
— — — sub-scapular, 542.
superciliary, 527.
superficial, of neck, 546.
palm, 547.
perineum, 556.
superficialis voIk, 547.
supra-orbital, 527.
renal, inferior, 512.
middle, 512.
■ superior, 512.
. sural, 565.
scapular, 538.
' spinous, 538.
tarsal, dorsal, or external, 568.
internal, 568.
temporal, 521.
■ deep anterior, 524
middle, 521.
• posterior, 523.
superficial, 521.
testicular, 511.
■ distribution of, 536.
thoracic acromial, 542.
alar, 542 (note).
• borders, 112,
structure of, 177.
■ cartilages. 111.
structure of, 177.
■ cavities, 10.
supplementary, 128.
processes, or eminences, 10.
of Tertebrse, 20, 22.
— union of, 116.
Articular arteries. See Arteries.
nerves. See Nerves.
Articulations in general, 111-116.
■ amphiarthroses, 113.
arthrodia, 1 14.
classification of, 113.
condylarthrosis, 114.
definition of. 111.
diarthroses, 113.
enarthrosis, 114.
ginglymus, 114.
gomphosis, 114.
harmonia, 114.
— ■ immovable, 113.
— - meningoses, 113
mixed, 113.
movable, 113.
movements of, 113.
— by mutual reception, 113.
schindylesis, 114.
— sutures, 114.
— symphyses, 114.
— synarthroses, 114.
— synchondroses, 113.
— syneuroses, 113.
— syssarcoses, 113.
— trochlear, 114.
• trochoid, 114.
Articulations in particular, 113.
acromio-clavicular, 135.
mechanism of, 136.
' of ankle. See Tibio-tarsal,
■ astragalo-scaphoid, 171.
' of astragalus with os calcis, 170.
■ movements of, 153.
atlanto-axoid, 117.
' mechanism of, 124.
'odontoid, 117.
' of atlas and axis, 117.
articular processes of,
118
INDEX.
879
Arttculations, calcaneo-cuboid, 173.
carpal, in general, 147.
. — mechanism of, 148.
of each row, 147.
of two rows together, 147.
■ pisiform and cuneiform, 147.
■ carpo- metacarpal, in general, 149
mechanism of, 150.
first, 149.
mechanism of, 150.
fifth, 150.
mechanism of, 150.
second, third, & fourth,
150.
• carpo-metacarpal, of the thumb, 150.
■ mechanism of, 150.
■ chondro-costal, 132.
• sternal, in general, 131.
in particular, 131.
movements of, 133.
■ coccygeal, 120.
■ condyloid, of occiput and atlas, 116.
• coraco-clavicular, 135.
• mechanism of, 136.
' of the costal cartilages, 132.
• movements of, 132.
■ costo-clavicular, 138.
mechanism of, 138.
■ costo-transverse, 131.
vertebral, 131,
in general, 131.
in particular, 131.
movements of, 131.
proper, 131.
of first rib, 131.
of eleventh and twelfth
ribs, 131.
• coxo-femoral, 159.
movements of, 161.
• cranial, 124.
■ mechanism of, 125.
— cranio-vertebral, 120.
mechanism of, 123.
— crico-arytenoid, 426.
thyroid 426.
— of the elbow, 143.
— of the extremities, upper, 135.
lower, 153.
— of the face, 126.
— of the fingers, in general, 151.
— of the head, with vertebral column.
Cranio-vertebral.
— of the hip. See Coxo-femoral.
— humero-cubital, 141.
• movements of, 142.
■ of jaw, lower. See Temporo-maxillary,
128.
upper, 126.
with cranium, 126.
• of the knee, 162.
mechanism of, 166.
• of larynx, 425.
■ of metacarpal bones, carpal ends of, 148.
digital ends of, 149.
with carpus, 149.
• metacarpo-phalangal, 151.
movements of, 152.
• of metacarpus in general, 148.
■ of metatarsal bones, tarsal ends of, 175.
digital ends of, 175.
' mechanism of, 175.
■ metatarso-phalangal, 175.
movements of, 177.
■ occipito-atlantoid, 116.
• mechanism of, 122.
axoid, 117.
■ peroneo-tibial, inferior, 167.
middle, 168.
superior, 168.
mechanism of, 168.
■ of the pelvis, 154.
mechanism of, 156.
' phalangal, of fingers, 153.
movements of, 153,
toes, 177
movements of, 177.
Articulations, radio-cubital, mechanism of, 144.
inferior, 142,
movements of, 144.
— middle, 143.
movements of, 143.
— — superior, 142.
• movements of, 144.
• sacro-coccygeal, 120.
iliac, 154.
sciatic, 155.
vertebral, 120,
• scapulo-humeral, 138.
-—- movements of, 139.
• of the shoulder, 135.
■ sterno-clavicular, 136.
mechanism of, 137.
■ syndesmo-odontoid, 117.
' tarsal, in general, 170.
• mechanism of, 173
of first row, 171.
of second row, 171.
movements of, 173.
of two rows together, 172.
movements of, 173.
-- tarso-metatarsal, in general, 174.
movements of, 173.
in particular, 173.
— temporo-maxillary, 128.
• mechanism of, 129,
• of the thorax, 130.
' mechanism of, 132.
■ movements of, 134.
■ thyro-hyoid, 425.
tibio-tarsal, 168.
mechanism of, 169, 170.
tracheo-cricoid, 426,
of the vertebral column, 115.
mechanism
121-123.
movements
122.
of,
■ of the vertebris with each other, 115.
bodies of, 115.
articular processes of, 116.
laminae of, 116.
spinous processes of, 116.
-^— ^— — — peculiar, 1 16.
■ of the wrist, 145. See Radio-carpal
Astragalus, 100,
Atlas, 23,
Auditory process, 44.
meatus, internal, 44.
external, 44,
nerve. See Nerve, portio molHt.
Auricle or auricula of ear, 666. See Ear.
Auricles of heart. See Heart.
Auricular surface of os coxse, 91.
Axis (vertebra), 24,
Basilar process, 34,
groove, 35.
Bicipital groove, 78,
tuberosity, 81,
Bi-parietal suture, 46,
Biventer cervicis, 205,
maxiOae inferioris, 245,
Bladder, 440.
bas-fond of, 442.
coats of, 442.
development of, 443.
functions of, 444.
fundus, inferior, 442,
superior, or summit. 443.
— ligaments of, anterior, 441,
■ posterior, 441.
sacculated and fasciculated, 444.
sphincter of, 443.
structure of, 443.
trigone of, 443.
uvula of, 443.
■ vessels and nerves, 444,
•j)ubic, 155,
■ radio-carpal, 145,
• movements of, 145
- cubital, 142.
Bones in general, 5-18.
- arteries of, three kinds, 14, 15.
- asymmetrical, 8.
- broad or flat, 9.
diploe of, 13.
ossification of, 17.
structure, internal, 13.
tables of, 13.
vitreousi 35.
880
INDEX.
flonei, eavities of, 9, 10.
'■ articular, 10.
alveolar, 10.
cotyloid, 10.
glenoid, 10.
trochleae, 10
non-articular, 10.
canals or conduits, iO.
fosse, 10.
furrows, grooves, or chan-
nels, 10.
notches, 10.
sinuses or cells, 10.
Bones, coronal, 35,
costae. See Ribs.
of cranium, 33.
cubital, 79.
cuboid, 101.
cuneiform, carpal, 83.
tarsal, external, 102.
internal, 102.
middle, 103.
ossification of, 17.
— changes in, after maturity, 18.
— chemical composition of, 14.
-- description of, mode of, 11.
— development of, 15.
cartilaginous stage, 15.
— mucous stage, 15.
osseous stage, 16.
symmetry of, 17.
■ direction of, absolute and relative, 7.
• eminences of, 9.
articular, 9.
condyles, 9
■ heads and necks, 9.
-non-articular, 9
apophyses, 9.
epiphyses, 9.
- marginal, 18,
-ossification of, 16.
• lines and crests, 9,
■ mammillary process-
es, 9.
■ processes, 10.
■ prominences, 9,
• spines or spinous pro-
cesses, 9.
• tuberosities, 9.
— foramina of, 11.
~ growth, mode of, 18.
-- long, 8.
extremities and shafts of, 9.
marrow or medulla of, 10.
medullary canal of, 10.
membrane of, 13.
-structure of, internal, 10.
•ossification of, 16.
~ nerves of, 14.
nomenclature of, 6.
number of, 6.
• nutrition of, 18.
ossific points of, 16.
ossification of, 16, 17.
eminences and cavities of, 17.
■ three kinds of, 17.
regions of, 9.
shape and symmetry of, 8.
short, 9.
ossification of, 18.
structure, internal, of, IS.
situation of, general, 6.
size, weight, and density of, 7.
structure of, internal, 13.
-microscopic, 11.
— of ear, 673.
— epactal, 50.
— ethmoid, 40.
development of, 41.
— efface, 51.
— femur, 93.
development of, 95
— fibula, 98.
development of, 99.
— of fingers. See Phalanges.
— of foot, 99.
— of forearm, 79, 80.
— frontal, 35.
development of, 36.
•of hand, 82.
■ of haunch, 89.
■ humerus, 78.
development of, 79.
■ hyoid, 109.
development of, 111.
■ ilium, 89.
• incus, 674.
■ ischium, 89.
■ of jaw, lower, 57.
upper, 61.
jugal, 54.
lachrymal, 56.
development of, 56.
• of leg, 96.
• lenticular, 674.
• malar, 54.
- development of, 55.
malleus, 673.
maxillary, inferior, 57.
development of, 58
superior, 51.
• development of, 53.
substance of, areolar, 11.
cancellated, or spongy, 11.
■ compact, 11.
reticulated, 11, 13.
surfaces, angles, and bordeni of, 8,
symmetrical, 8.
torsion of, 99.
veins and lymphatics of, 14.
Bones in particular, 18-111.
of arm, 78.
astragalus, 100.
atlas, 23.
development of, 31.
axis, 24.
- development of, 31.
— calcaneum, 100.
— of carpus or wrist, 82.
development of, 84.
first row of, 83.
second row of, 83.
— clavicle, 74.
development of, 75.
coccyx, 20.
development oi, 31.
■ of metacarpus, 84.
development of, 85.
: first, 85.
second, third, and fourth, 85.
fifth, 85.
■ of metatarsus, 103.
development of, 104.
first, 103.
second, third, and fourth, 103
■ fifth, 103.
• nasal, 55.
development of, 56.
• navicular, of carpus, 83.
> tarsus, 101.
• occipital, 33.
development of, 34.
• orbicular, 674.
• OS calcis, 100.
carinse, 33.
hyoides, 110.
iimominatum, I
• development of, 90.
- magnum, 83.
• planum, 40.
• prorae, and os puppis, 33.
quadratum, 53
■ unguis, 55
- ossa triquetra, or Wormiana, 50
- ossicula auditfis, 673.
• palate, 63.
development of, 54.
■ parietal, 41.
development of, 42.
' patella, 95.
development of, 96.
• of pelvis, 87.
• perone. See Fibula.
■ phalanges of fingers, 86.
• development of, 87
■ pisiform, 83.
■ of pubes, 90.
■ radius. 81.
■ toes, 104.
- development of, 104
JXBBX
881
BoHtM, radius, development of, 89.
ribs, 67.
— ^-^— ^ development of, 68.
false and true, 67.
rotula, 95.
sacrum, 26.
- development of^ SS.
scaphoid of carpus, 83.
tarsus, 101.
' scapula, 75.
' development of, 75.
- semilunar, 83.
sesamoid, 96.
of foot, 176.
of gastrocnemius, 165.
of hand, 153.
' of knee or patella, 06.
of shoulder, 73.
sphenoid, 36.
development of^ 38.
- spheno-occipital, 36.
- spongy. See Turbinaitd.
- sternum, 64.
development of, 65.
- styloid, 43.
- of tarsus, 99.
development of, 103.
first row of, 100.
second row of, 101.
temporal, 42.
development of, 44.
mastoid portion of, 43.
petrous portion of, 43.
squamous portion of, 43.
Condi, for anterior muscle of malleus, 679.
— arachnoid, of Bichat, 978.
— carotid, 43.
— for chorda tympani, 67S.
— crural, 310.
— dental, inferior, 50
— of Fontana, 656.
— godronn6, 661.
— hyaloid, 661.
— incisive, 52.
— infra-orbital, 51.
— inguinal, 306.
— for internal muscle of malleus, 43, 679.
— of Jacobson, 671.
— maxillary, superior, 51.
inferior, 60.
— medullary of long bones, 13.
— nasal, 653.
— of Nuck, 465.
— palatine, anterior, 53.
posterior, M.
• of thigh, 93.
• of thorax, 64.
' tibia, 96.
development of, 98
' of toes. See Phalanges.
■ trapezium, 63.
■ trapezoid, 83.
' turbinated, ethmoidal, 41.
inferior, 56.
' development of, 56.
middle, 41.
sphenoidal, 37.
superior, 41.
tympanic, 45.
ulna, 79.
development of, 81.
unciform, 83.
of vertebral column. See Vertebra, Vertebra,
and Vertebral Column.
vomer or ploughshare, 57.
— ' development of, S7.
Wormian, 50.
zygomatic, 54.
Borsa appiattita, 706.
Brain. See Cerebrum, Cerebellum, IsthmtU, and Me-
dulla Oblongata.
Bronchi, 417.
structure of, 420.
Bronchia or bronchial tubes, 418.
relations of, with lobules, 418.
structure of, 420.
Bronchial arteries, 420.
ultimate distribution, 490
glands (lymphatic), 430.
tubes, 418.
veins, 420.
ultimate distribution, 430
mucous membrane, 342.
characters of, 343.
fiucco-labial furrow, 326
Bulbs of fornix, or corpora albicantia, 728.
Bulbus arteriosus, 494.
Bursa synovial of tendo Achillis, 283.
of ligamentum patella, 164.
over patella, 311.
Bursa mucosse (so called), 175.
synovial, 175.
around eyeball, 649.
near shoulder joint, 143.
" hip joint, 161.
knee joint, 164.
• sub-cutaneous, 630.
Calamus scripforius, 703.
Calcaneum, 100.
Calcar, 736.
Canal, alimentary See Alimentary Canal.
of Petit, 661.
pterygo- palatine, 38.
pterygoid, 38.
sacral, 27.
for tensor tympani muscle, 43, 87L
tympanic, 673.
vertebral, 30.
vidian, 38.
of Wirsung, 401.
zygomatic, 55.
Canals of bones, 12.
dental, superior, 51.
lachrymal, 652.
palatine, accessory, 54.
semicircular, 576. See Semicireuha- Cmak.
Canine fossa, 51.
Canthi of eyelids, 647.
Capitula laryngis, 426.
Capitulum costae, 68.
ligaments. See Ligament
Capsule of GUsson, 478.
lens, 663.
Capsules, synovial, 1 14.
of particular joints.
See those joints.
supra-renal, 445. See Supra-renal Capsule*.
atrabiliary, 445.
Caput coecum coli, 37l
gallinaginis, 464<
Cardia, 442.
nerves
Carotid arteries.
-— nerves.
See Nerves.
See Arteries.
See Nerves.
See Arteries.
Carpal arteries.
Carpus, bones of, 82.
bones of first row of, 83.
compared with first t
of tarsus, 108.
second row of, 83.
compared with second!
of tarsus, 108.
■ compared with tarsus, 107.
' sheaths for tendons on, 316.
Cartilage, chemical composition of, 174.
cricoid, 423.
of ear, 666.
ensiform, 65.
structure of, 174.
thyroid, 433.
xiphoid, 65.
Cartilages, articular, 111.
characters of, 111.
structure of, 174.
— chemical composition of, 174.
■ arytenoid, 424.
- costal, 69.
articulations of, 133.
■ falciform, of knee, 162.
' inter-articular, 1 12.
structure of, 174.
temporo-maiillary, 128.
-^-— ~^>— .-.- acromio-clavicular, 136
stemo-clavicular, 137.
of wrist, 143.
of knee joint, 168.
' inter-osseous, 113.
• structure of, 174.
5T
■ of larynx, 423.
ossification of, 435.
of nose. See Nose.
882
INDEX.
Cartilages, semilunar, of knee, 163.
tarsal, of eyelids, 647.
Caruncula lachrymalis, 647.
Carunculx myrtiformes, 468.
Cauda equina, 770.
Caudal extremity of helix and antihelix, 667.
Cavernous body. See Corpus Cavemosum.
Cavity, coronoid, 80.
cotyloid, 88.
digital or ancyroid, 947.
glenoid, of scapula, 76.
temporal bone, 43.
olecranoid, 80.
of omentum, 478.
sigmoid, great and lesser, 81.
supplementary, of temporo-maxiUary articula-
tion, 128.
' of shoulder joint, 139.
• trochanteric, 95.
Cavities, articular, 10.
supplementary, 128.
orbital, 62.
glenoid, of tibia, 97.
• nou-articular, 11.
Cells of bones, 11.
ethmoidal, 42.
frontal, 36.
sphenoidal, 39.
Cellular tissue, 298.
lymphatics of, 613.
Central foramen of retina, 661.
Centrum ovale minus, 736.
of Vieussens, 736, 752.
semicirculare geminum, 746.
Cerebellar arteries. See Arteries.
veins. See Veins.
Cerebellum, 715.
arbor vitie, lateral and median, 721.
commissures of, 723.
comparative anatomy, 724.
corpus callosum of, 711.
dentatum or rhomboideum, 721.
development of, 724.
falx of, 684.
fasciculi, converging and diverging, 724.
fibres of, formative and uniting, 724.
fissure of, median, 717.
furrovrs of, 717.
Gall's views of, 724.
ganglia of, 721.
general view of, 724.
internal structure of, 718.
examined by hardening, 722.
• ■ sections, 721.
water, 722.
Cerebrum, anfractuosities, uses of, 735.
arbor vitae of, 750.
base of, 727.
lateral regions, 731.
median excavation of, 727.
region, 727.
commissures, 753. See Commissur*
comparative anatomy of, 757.
convolutions or gyri, 732.
of digital cavity, 733.
inferior surface, 733.
superior surface, 734.
internal surface, 733.
■ structure of, 755.
• uses of, 734.
Gall's views of, 754
• crura of, 723.
• development of, 756.
• falx of, 684.
- fibres of, formative or diverging, 752.
radiating, 754.
uniting or converging, 752.
general idea of, 754.
- fissure, longitudinal, 726.
Sylvian, 727.
transverse, great, 727.
' ganglia of, 752.
hemispheres of, 726.
• nuclens of, 749
• internal structure of, 735.
examined by hardening, 75ff.
sections of, 736.
■— water, 750
laminae and lamellae of, 717.
structure of, 722 (note).
lobe, sub-peduncular, 718.
lobes, lateral and median, 717.
lobule of circumference, 718.
medulla oblongata, 718.
pneumogastric nerve, 718.
lobules or segments, 717.
medullary centre of, 722.
peduncles of inferior, 704, 722.
middle, 710, 722.
superior, 711, 722.
sections of, 720.
— horizontal, 722.
vertical, 721.
size and weight of, 716.
substances, gray, white, and yellow, 721.
surface, upper, 716.
lower, 717.
- tentorium pf, 684.
ventricle of. See Ventricle, fourth.
Cerebr jI axteries. See Arteries.
— —- nerves. See Nerves, cranial.
peduncles, substance, &c. See Cerehrvm.
veins. See Veins.
Cereiro-spinal axis, 681.
. • divisions of, 682.
membranes of, 682. See Arachnoid,
Dura Mater, and Pia Mater.
Cerebrum, 725.
anfractuosities or sulci, 732.
of digital cavity, 733.
inferior surface, 733.
internal surface, 734.
superior surface, 734.
Foville's views of, 755.
Gall's views of, 751.
general idea of, 753.
Mayo's views of, 754
Rolando's views of, 759.
■ lobes of, 731 (note), 735.
• medullary centres of, 737.
• peduncles of, 710.
transverse fibres of, 711.
course of, in brain, 753.
■ structure of, 713.
■ section, vertical median, 748.
-Willis's, 750.
• sections of horizontal, 736.
vertical, transverse, 750.
general remarks on, 751
■ size and weight, 725.
compared to that of ceio
bellum, 725.
• substance, gray or cortical, 702 (note).
• white or medullary, 702 (note^
■ surface, inferior, or base, 727.
■ superior, or convex, 727.
unfolding of, by Gall, 753.
ventricles of, 753. See Ventricle.
Cervical arteries. See Arteries.
■ ganglia. See Ganglion.
■ nerves. See Nerves.
■ plexuses. See Plexuses.
vertebrce. See Vertebra and Vertebra
Cervix uteri, 465.
Cheeks, 328.
development of, 328.
muscles of, 328.
structure of, 328.
vessels of, 328.
Chemical composition of tissues, &c. See thoM t»
sues, &c.
Chiasma, optic, 728, 819.
Chorda tympani nerve, 836.
- canal for, 672.
Chorda tendineae, 483.
vocales, 426.
inferior or true, 427.
superior or false, 427.
Chorion, 631.
Choroid coat of eye, 657.
structure of, 657.
• pigment, 659.
■ plexuses, 747. See Plexuses.
■ veins of brain, 586.
eye, 657.
Ciliary body, crown, or disc, 656.
canal, 656.
circle, ligament, or ring, 656.
processes of the choroid coat, 656
zone of Zinn, 657.
INDEX.
883
OfrcteofWilliB, 727.
Circular sinus of Ridley, 587.
Circumflex arteries. See Artenei,
veins. See Veins.
Clavicle, 74.
Clitoris, 471.
artery of, 558.
crura, glans and prepuce of, 471.
ligaments and muscles of, 471.
— nerve of. 807.
Cochlea, 677.
aqueduct of, 679.
axis, columella, or modiolus of, 678.
lamina gyrorum, or tube of, 678.
• spiralis of, membranous and osseous,
678
nerves of, 681.
■ scalae of, tympanic and vestibular, 677.
Cochleariform process, 44.
Coccygeal vertebrse, 18, 27.
Coccyx, 27.
Ccecal appendix, 373.
Cacum, 371.
appendix vermiformig of, 373.
development of, 383.
• internal surface, 373.
structure, 378.
Collateral arteries. See Arteries.
nerves. See Nerves.
Colon, 373.
arch of, 374.
ascending, 374.
— — - descending, 374.
— — development of, 384.
' flexures of, iliac and sigmoid, 371.
— — internal surface of, 376.
longitudinal bands of, 374.
lumbar, left and right, 374.
structure of, 378.
transverse, 375.
Columella of cochlea, 708.
valve of Vieussens, 712.
Columnce cameae, 483.
of rectum, 377.
Columns, fronto-nasal, 127.
zygomato-jugal, 127.
jugal, 127.
pterygoid, 127.
• of face, 127.
of vagina, 469.
• of spinal cord. See Spinal Cord.
Comites, arteriae. See Arteries, satellite.
nervi. See Nerves, satellite.
venae, 572.
Commissura mollis, 740.
Commissure, anterior, of brain, 741.
antero-posterior, 753.
external and internal, of eyelids, 647.
■ great transverse, of brain, 735.
of lips, 326.
longitudinal, of brain, or fornix, 737.
optic, 729.
' of pineal body, 742.
posterior, of brain, 742.
soft or gray, 741.
of spinal cord, anterior, 698.
gray and white, 699.
at Sylvian fissure, 746.
Commissures of brain, 742. See Commissure.
Common mass of posterior spinal muscles, 201.
Communicating arteries. See Arteries.
nerves. See Nerves.
Comparison of arm-bone with thigh-bone, 105.
■ arteries of upper and lower extremities,
572.
bones of upper and lower extremities,
105.
carpus and tarsus, 107.
development of upper and lower extrem-
ities, 109.
enamel and ivory of teeth, 183.
first rows of carpus and tarsus, 108.
hand and foot, 107.
■ leg with forearm, 105.
lower parts of radius and tibia, 107.
metacarpus and metatarsus, 108.
■ nerves of upper and lower extremities,
815.
permanent and temporary teeth, 187.
phalanges of fingers and toes, 109.
Comparison of second rows of caipus and tarsus, 108.
shoulder with pelvis, 105.
■ teeth and bones, 177.
epidermoid appendages, 177
upper and lower molar teeth, 181
upper parts of ulna and tibia, 107,
Compressor muscles. See Muscles.
Conarium, 742.
Concha of ear, I
■ tragic fossa of, I
■ nose, inferior, 56.
middle, 41.
■ superior, 41.
Concha, ethmoidal, 41.
Condylarthrosis, characters, &c., 114.
Condyle, 10.
humeral, 78.
Condyles, occipital, 34.
of lower jaw, 58.
femur, 95.
tibia, 97
Condyloid foramen, anterior, 34.
— posterior, 34.
fossa, 34.
Confluences of the sinuses, 588.
Coni vasculosi testis, 452.
Conjunctiva, 648.
Constrictor muscles. See Muscles.
Conus arteriosus, 481.
Convolutions of brain. See Cerebrum.
small intestines, 364.
Coracoid process, 76.
Cordiform tendon of diaphragm, 213.
Cornea, opaque, 655.
transparent, 655.
Comicula laryngis, 424.
Comu Ammonis, 745.
Cornua of hyoid boue, 109.
lateral ventricle. See Ventrieh
styloid, 109.
thyroid cartilage, 424.
Corona ciliaris, 656.
radians of Reil, 755.
of glans penis, 461.
Coronal bone, 35.
Coronary arteries. See Arteries.
ligaments. See Ligaments.
veins. See Veins.
Coronoid cavity, 80.
process of lower jaw, 58.
ulna, 80.
Corpora albicantia, 728.
structure of, 738.
Arantii, 486.
bigemina, 712.
lutea, 462.
mammillaria, 728.
olivaria, or ovata, 706.
quadrigemina, 712.
restiformia, 707.
Corpus bulbosum, 461.
artery of, 558.
nerve of, 806.
— callosum, artery of, 529.
■ — bourrelet or cushion of, 731
of cerebellum, 711.
extremity, anterior, 737.
posterior, 731.
■ genu or knee, 737.
- peduncles of, 730.
■ reflected portion, anterior, 730.
■ rostrum or beak, 737.
• convolution of, 733.
■ ventricle of, 737.
■ longitudinal tracts of, 737
■ fibres of, 753.
— cavernosiun penis, 455.
1 crura of, 455.
nerves, 456.
structure, 455.
■ vessels, 456.
■ dentatum cerebeUi, 721.
meduUae, 705.
fimbriatum, 739.
— uteri, 464.
geniculatum externum, 728.
internum, 712.
Highmori, 450.
luteum, 462.
• mucosuiD of skin, 635-
INDEX.
Corpus papillare of skin, 689.
psalloides, 738.
. reticulare of skin, 635.
I spongiosum urethrse, 460.
striatum, 744.
fibres of, 753.
lobule of, 731.
rein of, 745.
Costal cartilages, 69.
Costa, 67. See Ribs.
of scapula, 76.
Cotyloid cavity, 88.
cavities in general, 11.
Crania, national, 44.
Cianial nerves, in general. See Nerves.
in particular. See Nerves.
— — ganglia. See Ganglia.
arachnoid. See Arachnoid.
dura mater. See Dura Mater.
Cranium, aponeuroses of, 299.
area of, 45.
articulations of, 125.
— base of, exterior of, 45.
interior of, 46.
——— bones of, 34.
circulation of, arterial, 531.
— venous, 562.
- development of, 50.
- external surface o.'', 45.
■ lymphatic system of, 627.
- in general, 45.
- internal surface of, 46.
- mechanism of, 126.
■ regions of, 45.
■ sutures of, in general, 154.
particular. See Sutures.
-varieties of, 45.
- vault of, 45.
Crest of ilium, 89.
pubes, 89.
tibia, 97.
urethra, 459.
Crests, occipital, 35.
Cribriform plate of ethmoid bone, 40.
Crijtta gaUi, 40.
ilii, 89.
vestibuli, 676.
Crura of clitoris, 471.
corpus cavemosum, 455.
diaphragm, 212.
cerebri, 711.
Crural arch, 309.
ring, 310.
septum, 310.
Crust of cerebral peduncles, 713 (note).
Crusta petrosa, 182.
Crypts of Lieberkuhn, 369.
Cuneiform bone of carpus, 83.
Cutaneous nerves. See Nerves.
Cuticle, 633.
Cutis, or cutis vera, 631.
anserina, 630.
Cystic duct, 397.
Cijslis fellea, 396.
Uo'tns, 446.
tissue of, 446 (note).
Deltoid impression, 78.
Wfrt/a; arteries. See Arteries.
— — canal, inferior, 57.
canals, superior, 31.
nerves. See Nerves,
veins. See Veins.
Dentata (vertebra), 24.
Denies. See Teeth.
Depressor muscles. See Muscles.
Development of particular bones, organs, or parts
body. See those bones, organs, &c.
Diaphragm, 218.
Diarthroses, 114.
Digastric fossa, 43.
groove, 43.
Digestive apparatus, general view of, 3.
D^tal arteries. See Arteries.
nerves. See Nerves.
Diploe, 14.
Diploic canals. 591.
veins, 585, 591.
Dissection of different parts. See those parts.
Oorsal arteries. See Arteries.
Dorsal ligaments. See Ligament*.
nerves. See Nerves.
veins. See Veins.
vertebrae. See Vertebra and Verttirtt.
Dorsum ilii, or external iliac fossa, 88.
lingua;, 337.
manus, 82.
nasi, 64l.
——pedis, 99.
Duct, common biliary, 398.
' internal surface, 399.
structure, 399.
• cystic, 397.
structure, 399.
' ejaculatory, 452.
' hepatic, 395.
internal surface, 3W.
structure, 399.
— lymphatic, right, 619.
— nasal, 653.
— pancreatic, 402.
— parotid, 341.
— Stenonian, 341.
— thoracic, 618.
■ right, 619.
Warthonian, 342.
Ducts, biliary, 398.
lactiferous or galactophorona, 473.
prostatic, 458.
of Rivinus, 342.
Ductus arteriosus, 500.
communis choledochus, 398.
ejaculatorius, 452.
venosus, 600.
Duodenum, 361.
curvatures of, 362.
~ glands of, 370.
— lymphatic glands of, 625.
• structure of. See Smalt Intestine.
Dura mater, 682.
cranial portion of, 683.
cranial nerves of, 686.
sinuses of, 584.
structure of, 685.
uses of, 686.
vessels of, (
dissection of, 682.
spinal portiou of, 686.
vessels of, 687.
Ear, auricle of, 666.
cartilage of, 666.
ligaments of, 667.
muscles of, extrinsic. See MtudUf
auricular.
intrinsic, 668.
skin of, 668.
vessels and nerves, 668.
• drum of. See Tympanum.
external. See auricle and meatus of.
general view of, 666.
internal, or labyrinth of See Labyrinth.
meatus of external, 668.
cartilaginous and fibrous portion of, 688.
— glands of, 669.
osseous portion of, 44.
— skin of, 6.
— internal, 44.
. bottom of, 680.
middle. See Tympanum.
ossicula of, 673.
movements of, 674.
muscles belonging to, 674.
tympanum of. See T)/mpanum.
vessels of, 680.
Eighth cranial nerve. See Nerves, glosso-pharyngsal,
pneumogastric, and spinal accessory.
J^aeulatory duct, 452.
Elastic tissue, structure of, 174.
chemical composition of, 174.
ligaments, general characters of. 112.
■ of vertebrsB, 115.
Elbow-joint, 143.
Eminence, jugular, 34.
nasal, 35.
frontal, 35.
ilio-pectineal, 89.
hypothenar, 261.
thenar, 260.
unciform of lateral ventricle, 730
INOB2.
88$
Eminenlia collateralis, 746.
EminentitB natiformes, 712.
testiformes, 712.
Enamel of teeth. See Teeth.
Enarlhroses, 114.
Encephalic nerves. See Nerves, craniai.
Encephalon, arteries of, in general, 535.
isthmus of. See Isthmus.
£mio-cardium, 488.
lymph, 680.
Ensiform process, cartilage or appendix, 65.
Epactal bones, 50.
Epicondyle, 79.
Epidermis, 633.
Epididymis, 451.
globus major, 451.
— minor, 451.
- structure, 451.
Epigastric region, 352.
Epiglottis, 425.
Epiploon, i78. See Omentum.
Epithelium ciliated, 323.
columnar, 323.
squamous, 323.
of particular membranes. See those mem-
branes.
Epitrochlea, 80.
Erectores muscles. See Mutdt*.
Ergot, 736.
Ethmoid bone, 40.
Ethmoidal bulb, 818.
cells or sinuses, 40.
— fossa, 48.
groove, 40.
labyrinth, 40.
EustacJaaa tube, or trumpet, 672.
cartilaginous and fibrous portion, 672.
mucous membrane, 673 (note}.
osseous portion, 44, 672.
Extensores muscles. See Muscles.
Extremities, lower, aponeuroses of, 306.
articulations of, 153.
arteries of, 557.
7 bones of, 87.
development of, 104.
lymphatic system of, 619.
nerves of, 797.
veins of, 603.
upper, aponeuroses of, 315.
arteries of, 531.
■ articulations of, 135.
bones of, 74.
——— development of, 87.
■ lymphatic system of, 628.
nerves of, 781.
•^— ^— veins of, 593.
upper and lower, arteries of, compared, 572.
bones of, compared, 105.
— — ^— — developmont of, compa-
red, 109.
aeires of, oMnpared, 815.
Eye, 645.
appendages of, 646.
— — brows, 646.
— — chamber of, anterior, 658.
■ posterior, 658.
globe of, 654.
humours of, aqueous, 664.
crystalline, 662.
■ vitreous, 66l.
■ lashes, 646.
' Uds. 646.
cartilages of, 647.
commissures or canthi, 647.
glands, 648.
mucous membrane, 647.
muscles of, 647.
uses of, 647.
vessels and nerves, 648.
■ membranes of, 654.
of aqueous humour, 655.
arachnoid of, 656 (note).
• capsule of lens, 662.
choroid coat, 656.
cornea, 655.
hyaloid, 661.
■ — iris, 657.
Jacob's, 661.
pupillary, 659.
retina, 660.
Eye, membrane, Raysch's, 659.
sclerotic coat, 654.
of vitreous humour, 661.
muscles of, oblique, 651.
recti, or straight, 651.
action of, 651
nerve of. See Nerve, optic.
pigment of, 660.
vessels of, 665.
Face, area of, 46.
bones of, 51.
cavities of, 62.
circulation of, arterial, 530.
venous, 593.
' development of, general, 63.
regions of, 63, 64.
in general, 60.
lymphatic system of, 626.
movements of, 238.
muscles of, 231.
regions of, 60.
Facial angle of Camper, 45.
nerve. See Nerve, portio dura.
Fallopian aqueduct, 43.
hiatus, 44.
ligament, 302.
tubes, 463.
fimbriae of, 463.
structure and uses of, 463.
Fascia.
Fall of umbilical vein, 475.
cerebelli, 684.
cerebri, 684.
See Aponeurosis.
— cervical, 209.
— cremasteric, 302.
— cribriform, 309, 621.
— dentata, 476.
— iliac, 302.
— infundibuliform, of cord, 302.
— intercolumnar, of inguinal ring, 301.
— lata, 309.
iliac portion, 310.
pubic portion, 311.
structure, 311.
obturator, 308.
propria (sub-peritoneal fascia), 803-30$
recto-vesical, 308.
spermatic, 304,
superficial, 297, 630.
tensor muscles of, 294.
transversalis, 305.
Fasciculi, muscular, 193.
of medulla. See MeduUa.
Fauces, arches of, 330.
isthmus of, 330.
pillars of, 330.
Femur, 93.
Fenestra ovalis, 670.
rotunda, and its fossa, 671
Fibres, muscular, involuntary, 324.
voluntary, 193.
nervous, 767.
Fibrous tissue, 298.
fV6ro-cartilage of epiglottis, 425.
cartilages, 177.
of particular joints. See those joiata
FOula, 98.
Fifth cranial nerve. See Nerve, trifacial
Filaments, muscular, 193.
nervous, 767.
FiOet, 712.
FinU>ri<B of Fallopian tubes, 463.
Fingers, 86.
phalanges of, 86.
— >- and toes, phalanges of, compared, 130.
First cranial nerve. See Nerve, olfactory.
Fissure, Glasserian, 43.
glenoidal, 43.
incisive, 53.
orbital, 63.
pterygo-maxillary, 55.
spheno-maxiUary, 39, 52, 55.
- sphenoidal, 39.
Sylvian, 730.
Fissures of brain, liver, etc. See tbose oigani*
Flexor muscles. See Muscles.
Flocculus, 718.
Fluid, ventricular, 744.
of Scarpa, 680.
886
INDEX.
Fluid, sub-arachnoid, 144.
Folds, aryteno-epiglottid, 433.
glosso-epiglottid, 336.
pharyngeo-epiglottid, 426.
Follicles, dental, 184.
of Goodsir, 183.
intestinal. See Intestines.
Lieberkuhn's, 379.
sebaceous, 635.
— solitary, 370.
of stomach, 360.
tubular, 360.
uterine, 471.
Fontanelles of scull, 49.
Foot, bones of, 99.
compared with hand, 106.
Foramen, of Bichat, 688.
ofBotal, 486.
centrale of retina, 660.
caecum of frontal bone, 36.
Morgagni {in tongue), 333.
' medulla oblongata, 703-
condyloid, anterior, 34.
posterior, 34.
infra-orbitary, 59.
lacerum superius, 39.
posterius, 44, 47, 49.
anterius, 47.
magnum, 34.
mastoid, 43.
mental, 57.
of Monro, 740.
nutritious of humerus, 78.
ulna, 79.
radius, 81.
femur, 93.
tibia, 96.
fibula, 99.
obturator, 88.
occipital, 34.
optic, 37.
orbital, internal anterior, 36.
posterior, 36.
ovale of heart, 487.
■ sphenoid bone, 38.
parietal, 42.
rotundum, 38.
spheno-palatine, 54.
spheno-spinosum or spinosun, 38.
Etylo-mastoid, 43.
superciliary, 36.
supra-orbitary, 36.
vertebral, 20, 21.
of Winslow, 476.
Foramina Thebesii, 488.
malar, 54.
of bones, 11.
inter-vertebral, 20, 30.
posterior, 775 (note).
sacral, 27.
Forearm, bones of, 79.
compared vdth leg, 105.
Fornix, 739.
• bulbs of, 740.
pillars of anterior, 739.
— posterior, 740.
Fossa, amygdaloid, 331.
canine, 51.
digastric, 43.
ethmoidal, 48.
iliac, external, 88.
internal, 88.
infra-spinous, 76.
ischio-rectal, 309.
jugular, 43.
lachrymal, 36.
mental, 58.
myrtiform, 49.
navicularis of urethra, 461.
vulva, 470.
ear, 670.
■ ovalis of heart, 488.
■ parietal, 43.
■ perineal, 309.
■ pituitary, 37, 48.
• pterygoid, 38.
■ scaphoid. See Navicularis.
■ spheno-maxillary, 60.
• sub-lingual, 57, 60.
■ sub-maxillary, 57, 60.
Fossa, ffub-pynmidal, 671.
sub-scapular, 75.
supra-sphenoidal, 37.
supra-spinous, 76.
temporal, 47.
zygomatic, 60.
Fossa of bones, II.
- condyloid, 34.
- frontal, 36.
- internal iliac, 91.
- nasal, 63.
- middle lateral, or spheno-temporal, 48
- occipital, 35.
Fourchette of sternum, 65.
vulva, 470.
Fourth cranial nerve. See Nerve, pathette.
Fovea hemispherica, 676.
- semi-elliptica, 676.
Frcenum labii, 324.
lingus, 336.
prsputii, 455.
Frontal bone, 35.
cells or sinuses, 37.
eminence, 35.
fosss, 36.
Fronto-JMgaH suture, 48.
maxillary suture, 59.
nasal suture, 59.
— columns, 127.
parietal suture, 45, 47.
sphenoidal suture, 48.
Fundus of stomach, bladder, Ac. See those organ*.
Furrow, mylo-hyoidean, 57.
mento-labial, 326.
bucco-labial, 326.
Furrows of heart and spinal cord. See those organa.
Galactophorous ducts, 473.
Galea capitis, 208.
Gai2-bladder, 396.
structure of, 397.
use of, 400.
Ganglia, lymphatic. See Lymphatic Glands.
Ganglia, nervous, in general. See Nerves, ganglia oj
Ganglia, nervous, in particular, 765.
abdominal, 865.
of brain, 753.
cervical, sympathetic. See Ganglion.
cranial, 765.
• sympathetic, 854.
- intercosttj, 765.
■ lumbar, sympathetic, 868.
external and intemtl
branches of, 860.
- spinal or rachidian, 765.
- splanchnic, 765.
- sympathetic, 765.
— — connexions of, 766.
structure of, 768.
-thoracic, 864.
external branches, 864.
' internal branches, 804.
-vertebral, 761.
Ganglion of Andersh, 843.
annulare (of eye), 831.
cardiac, 862.
carotid, 856.
of cerebellum, 722.
cervical, inferior, 859.
middle, 859.
superior, 855.
^ — branches of, anterior, 857.
. external, 858.
inferior, 858.
— internal, 858.
—— superior, 856.
■ ciliary, 830.
— Gasserian, 827.
— of glosso-pharyngeal, 843.
— impar, 871.
— inter-carotid, 858.
— lenticular, 830.
— Meckel's, 831.
— naso-palatine, 831.
— ophthalmic, and branches, 830.
— otic, and branches, 837.
— petrosal, 843.
— of pneumogastric, 845.
— of Bibes, 857.
— of root of hypoglossal, 823 (note).
INDEX.
887
(hmglioH of root of spinal accessory, 823.
semilunar abdominal, 866.
of fifth nenre, 827.
solar, 866.
' spheno-palatine, and branches, 831.
sub-maxillary, 837.
thoracic, first, 859.
thyroid, 859.
Gasserian ganglion, 827.
Genial processes, 58.
Ginglymus, angular and lateral, 114.
Glabella, 35.
*iland, accessory, of parotid, 341.
epiglottid (so called), 430.
lachrymal, 652.
• parotid, 340. See Parotid Gland.
pineal. See Pineal Gland.
pituitary, 729.
prostate, 459.
• structure, 459.
sub-lingiial. See Sub-lingual Glana.
sub-maxillary, 342. See Sub-maxillary Gland.
thymus, 415.
• thyroid, 433.
Glands, agminated, 370.
arytenoid, 433.
Brunner's, 370.
buccal, 329.
ceruminous, 669.
conglobate (lymphatic), 614.
Cowper's, 460.
duodenal, 370.
epiglottid, 430.
of Havers, 113.
— in knee, 163.
intestinal. See Intestines.
labial, 328.
laryngeal, 432.
lingual, 337.
lymphatic, in general, 616.
particular.
Glands.
Groove, superior petrosal, 44.
of torsion, of humertu, 78.
Grooves of bones, 12.
calcaneal, 100.
carotid, 37.
cavernous, 37.
for lateral sinuses, 34.
on back of radius, 81.
sacral, 92.
of spinal cord. See Spinal Cori,
vertebral, 29.
Gubemaculum dentis, 189.
testis, 44«.
Gula, 344.
Gulf of the internal jugular, 583,
Gums, 329.
HabentB of pineal body, 742.
Hamular process of sphenoid bone, 37.
cochlea, 678.
Hand, bones of, 82.
compared with foot, 107.
Hairs, description of, general, 638.
follicles of, 638.
structure and growth, 638 (note).
Harmonia, 114.
Harmonic sutures, 114.
Haunch bone, 89.
Heads of bones, 9.
particular. See those bonoa.
See Lymphatic
mammary, 472.
Meibomian, 648.
molar, 329.
odoriferous, of prepuce, 453.
oesophageal, 352.
of Pacchioni, 585, 685.
palatine, 329.
Peyer's, 370.
salivary, 340. See Salivary Glands.
solitary, 370.
sudoriferous, 633.
synovial (so called], 113.
of trachea, 416.
tubular, 360, 370.
Tyson's, 454.
of uterus, 467.
of Vesalius (bronchial), 625.
Glandula socia parotidis, 341.
Glans clitoridis, 471.
penis, 460.
corona of, 460.
— - structure of, 461.
Glasserian fissure, 43.
Globuli Arantii, 486.
Globus major, 451.
minor, 451.
Glomeruli, 437.
GJoMo-epiglottid folds or ligaments, 430.
pharyngeal nerve. See Nerve.
Glenoid cavities in general, 11.
ligaments. See Ligaments.
Glottis, 430.
differences in size of, 435,
Gomphosis, 114.
Groove, basilar, 34.
bicipital, 78.
cuboid, 100.
dental primitive, 184.
■ secondary, 184.
■ digastric, 43, 47.
- ethmoidal, 40.
- inferior petrosal, 49.
- lachrymo-nasal, 51.
■ longitudinal, of cranium, 47
■ mylo-hyoidean, 50.
• obturator, 88.
- optic, 37.
■ sub-pubic, 88.
Heart, 479.
auricles of, external surface, 482.
interior of, 486.
muscular fibres of, 490L
musculi pectinati, 404.
orifices of, 484.
' auriculae of, 482.
— interior of, 487.
• bone in, 489.
■ cellular tissue, 493.
■ chordae tendineee, 483.
- columnae cameae, 483.
■ conformation of, external, 480.
internal, 482.
■ development of, 492.
■ fibrous framework of, 488.
' foramen of Botal, 486.
ovale, 486.
' remains of, 486.
■ foramina Thebesii, 487.
- fossa ovalis, 486.
- function, 492.
- furrow, auriculo-ventricular, 481.
inter-auricalar, 482.
ventricular, anterior and port*-
nor, 481.
. muscular fibres of, 488.
structure of, 488.
■ nerves of, 492.
• separation of, into right and left hearts, 490.
■ septum, inter-auricular, 482.
ventricular, 481.
• serous coat, external, 487.
internal, 487.
sounds of, 493.
• structure of, 487.
■ tubercle of Lower, 486,
• valve, Eustachian, 486.
mitral, 484,
of Thebesius, 486,
tricuspid or Iriglochin, 484,
■ valves of, auriculo-ventricular left, 484,
right, 485,
— ^ semilunar. See Sigmoid.
■ sigmoid, aortic, 484.
pulmonary, 484.
ventricles of, external surface, 480,
interior of, 483.
muscular fibres of, 488.
. musculi papillares, 484.
orifices of, 483.
vessels of, 491.
zones, fibrous, of, 488.
Heel, bone of, 100.
Helicotrema, 679.
Helix, and its furrow or groove, 666.
cartilaginous process of, 667.
Hemorrhoidal arteries. See Arteries.
nerves. See Nerves.
Hepatic artery, in the liver, 394, 395.
888
INDEX.
Hepatic duct, 395.
in the liver, 394, 395.
Hiatus Fallopii, 44.
Hilus of spleen, <fcc. See those organs.
Hip-joint, 1S9.
ligaments of, 160.
Horizontal plate of palate bone, 53.
Human body, general view of, 1-4.
Humerus, 78.
Humours of eye. See Eye.
Hymen, 469.
Hyoid bone or apparatus, 109.
■Hypo- glossal nerve. See Ntne.
/ieo-coscal valve, 372.
development of, 384.
structure of, 373.
uses of, 373.
colic valve, 372.
Ileum, 362.
structure of. See Intestine, small.
Iliac arteries. See Arteries.
flexure, 371.
fossa, external, 88.
internal, 88.
region, 352.
veins. See Veins.
/Ko-pectineal eminence, 89.
Ilium, 89.
Impression, deltoid, 78.
Incisive canal, 52.
fissure, 53.
Incisura tragica, 666.
Incus, 674.
Indented sutures, 115.
/n/ra-orbital canal, 51.
foramen, 59.
nerves. See Nerves.
spinous fossa, 76.
Infundibula of kidneys, 439.
Infundibulum of base of brain, 729.
cochlea, 678.
nasal fossa, 41, 62.
right ventricle of heart, 481
Inguinal canal, 304.
ring, 303.
Insula of Reil, 745.
Iniegumentum, 713 (note).
/nier-articular cartilages. See Cartilages.
auricular furrow, 482,
septum, 482.
columnar fascia, 301.
condyloid notch, 95.
costal arteries. See Arteries.
nerves. See Nerves,
spaces, 71.
lobular fissures, spaces, and vessels of liver, 301
of lungs, 414.
osseous arteries. See Arteries,
cartilages, 112.
ligaments. See Ligaments.
muscles. See Muscles.
• nerves. See Nerves.
spaces of hand, 84.
foot, 106.
• peduncular space, 711, 728.
spinous ligaments, 119.
■ trochanteric line, 94.
• ventricular furrow, 480.
septum, 480.
• vertebral foramina, 20, 30.
■ substance or disc, 115.
ligaments, 115.
Intestine, laxge, 370.
. coats of, 378, 379.
development of, 383.
divisions of, 371.
■ follicles of, 379.
functions of, 382.
lymphatic glands and vewek, 379.
structare of, 378.
tubuli of, 379.
vessels and nerves of, 379,
Intestine, small, 361.
coats of, 366,
convolutions of, 364.
crypts of, 370.
development of, 383.
divisions of, 361.
follicles of, agmiuated, 369.
Intestine, small, follicles of, Lieberkuhn'a, 37ft>)i|N^-
solitary, 369. «^ '
functions of, 370,
glands of, 366.
■ lymphatic glands of, 624.
lymphatics of, 624.
papillae of, 367.
• properly so called, 363.
structure of, 365.
tubuli of, 370.
valves of, 366.
vessels and nerves of, 370.
villi of, 367.
Intestines in general, 361.
development of, 383.
JnZra-lobular veins of liver, 395 (note).
spinal veins. See Veins.
Iris, 657.
layers of, 659.
muscular fibres of, 658 (note).
structure, 658.-
uses of, 659.
vessels and nerves of, 659.
Ischiadic notch, 89.
Ischio rectal fossas, 308.
Ischium, 89,
Island of Reil, 745.
Isthmus faucium, 325.
ovalis (heart), 486.
of the encephalon, 710.
comparative anatomy, 715.
■ development of, 715.
divisions of, 710.
fasciculus of, triangular, 710-711.
furrow, lateral, of, 710.
internal structure of, 713.
lower stratum, 713,
-- middle stratum, 713.
upper stratum, 713.
sections of, 713,
Iter dentis, 188,
Ivory of teeth. See Teeth.
Jacob's membrane, 660,
structure of, 661.
Jaw, lower, 57.
articulations of, 128,
upper, bones of, 51,
— articulations of, 126,
Jejunum, 362.
— ; structure of. See Small Intestme.
Joints. See Articulations.
Jugal columns, 127.
bone, 54.
Jugular eminence, 34.
fossa, 43.
veins. See Veins.
internal, sinus of, 583.
Kidneys, 436,
- acini, 438,
-- adipose capsule of, 437
- calyces of, 439,
- coat of, 437.
- cortical substance of, 438.
- development of, 440.
- functions of, 440.
- glomeruli, 437.
- hilus or fissure, 436.
- papillae, 437.
■- pelvis of, 440.
- pyramids of, Ferreim'a, 437,
Malpighi's, 437.
■ tubes of, convoluted, 437,
' straight, 437.
tubular portion, 438.
— structure of, 438,
• vessels and nerves, 438,
See thoM
Knee-joint, arteries, ligaments, and nerves,
parts.
Labia pudendi, 470.
Labyrinth, ethmoidal, 40,
fluids of, 679.
lining membrane of, 680.
membranous, 679.
osseous, 675. See Cochlea, Semi-ciraikm
Canals, and Vestibule.
Lacerated, foramen anterior, 47.
posterior, 44.
IKDEX.
Lacerated, foramen superior, 39.
Lacerti teretes of heart, 483.
Lachrifmal bone, 56.
canals, 651.
caruncula, 647.
gland, 651.
groove, or fossa, 36, 651.
papills, or tubercles, 645.
passages, 651.
mucous coat of, 654.
■ puncta, 652.
sac, 653.
Lachrymo-aasal groove, 51.
canal, 652.
Lacteals, 611.
of intestines, 612.
Lactiferous ducts, 473.
Lacuna magna, 460 (note).
Lacuna of urethra, 460.
Lacus lachrymalis, 647.
Lambdoidal suture, 46.
Lamina cinerea, 730.
of cornea, 745.
cribrosa of ethmoid, 40.
of internal auditory meatus, 678, 680.
gyrorum, 677.
papyracea, 41.
spiralis, membranous and osseous, 677.
Laryngeal nerves. See Nerves.
Larynx, 422.
articulations of, 426.
cartilages of, 423.
ossification of, 435.
Ligaments of auricle, intrinsic, 667.
of bladder, anterior, 308, 440.
■ posterior, 440, 475.
broad, of liver, 386.
uterus, 465.
' calcaneo-cuboid, inferior, 173.
internal, 173.
superior. 172.
• scaphoid, inferior, 172.
superior, 172.
of canthus, external, 647.
capsular, acromin-clavicular, 135.
atlanto-axoid, 119.
carpo- metacarpal of thumb, 150.
■of little finger, ISO.
hip-joint, 160.
knee-joint, 166.
occipito-atlautoid, 118.
axoid, 119.
- development of, 435
• functions of, 435.
• glottis, 430.
• m general, 429.
• ligaments of, 425.
• mucous membrane and glands of, 475.
• muscles of, 427.
' sinus of, 434.
' surface, external, 429.
internal, 430.
■ ventricle of, 427.
' vessels and nerves, 435.
Leg, articulations of, 168.
bones of, 96.
compared with forearm, 105.
fascia of, 311.
Lemniscus, 711.
Lens. See Crystalline Lens.
Levator muscles. See Muscles.
Levers, three orders of, in body, 199.
Ligamenta-lsXs. of uterus, 475.
subflava, general characters, 112.
of vertebral column, 115.
Ligaments in general, 1 13.
articular, 112.
capsular, 1 12.
interosseous, 112.
membranous, 112.
structure of, 174.
yellow or elastic, 112.
Idgaments in particular, 113.
accessory, of shoulder-joint, 139.
hip-joint, 160.
knee-joint, 165.
• Weitbrecht, 144.
' alar, of axis (or odontoid), 119.
of knee, 165.
' of ankle-joint, lateral, anterior external, 1 69.
external proper, 169.
internal, 169.
posterior, 169.
annular, of radius, 142,
atlas, 117.
carpus, anterior, 318,
dorsal, 318.
tarsus, dorsal and lateral, 313.
arjrteno-epiglottid, 426.
astragalo-calcaneal, interosseous, 171.
• external, 171.
posterior, 171.
scaphoid, superior, 172.
atlanto-axoid, anterior, 117.
■ posterior, 117.
capsular, 117.
odontoid, transverse or annular, 117,
crucial, 117.
scapulo-humeral, 137.
sterno-clavicular, 136.
■ of each row of carpal bones, 147.
- two rows of carpal bones, 147.
carpo-metacarpal, dorsal, 150.
palmar, 150.
interosseous, with os mag
num, 150.
of little finger, 150.
thumb, 150.
cervical, posterior, of quadrupeds, 117.
check, of axis (or odontoid), 119.
chondro-sterual, anterior, 131.
interosseous, 131.
posterior, 131.
■ superior and inferior, 131
' xiphoid, 131.
ciliary, 656.
conoid, 135.
coraco-acromial. 140.
clavicular, anterior, or trape7oid, 136
posterior, or conoid. 136
coraco-humeral, 139.
— coracoid, 139.
— costo-clavicular, 138.
coracoid, 1 39.
■ transverse, interosseous, 131
posterior, 131.
— superior, 131.
■vertebral, anterior, 131.
inferior, 131.
interosseous, 131.
stellate, 131.
superior, 131.
cotyloid, of hip-joint, 159.
crico-arytenoid, 426.
thyroid, middle and lateral, 436
crucial, of atlas, 117.
knee-joint, 164.
of cuneiform bones of tarsus, 170.
and scaphoid, 171
third and cuboid, l7l
deltoid, 169.
dorsal, annular, of carpus, 318.
■ tarsus, 313.
carpo-metacarpal, 149.
• of carpus, 149.
— metacarpus, 149.
— metatarsus, 175.
■ tarso-metatarsal, 175.
• of tarsus, 171.
elbow-joint, external lateral, 141.
internal lateral, 141.
anterior, 141.
■ posterior, 142.
falciform, 303
Fallopius's, 302
of Ferr^in, 427.
Gimbernat's, 303.
glenoid, carpal anterior, 148.
■ posterior, 148
metacarpo-phalangal, 152.
metatarso-phalangal, 175.
phalangal, of fingers, 153.
toes, 176.
scapulo-humeral, 138.
of auricle, anterior and posterior, 667.
5U
glosso-epiglottid, 425.
of hip-joint, anterior superior, 160.
— accessory. 160.
cotyloid, 160.
iuter-articular, 161.
890
Ligaments of hip-joint, round, 161.
capsular, 160.
— I of humero-cubital, 141.
hyo-epiglottid, 425.
ilio-lurabar, 156.
inter-articular, acroinio-claTicular, 135.
of hip-joint, 160.
of shoulder-joint, 137.
sterno-clavicular, 136.
temporo-maxillary, 128.
of wrist, 143.
osseous, astragalo-calcaneal, 171.
of carpal bones, 147.
carpo-metacarpal, 149.
costo- transverse, 131.
vertebral, 131.
of forearm, 144.
— knee-joint, 164.
— leg, 169.
— OS magnum and metacar-
pus, 149.
■ metacarpal, 149.
■ metatarsal, 175.
peroneo-tibial, 168.
pubic, 156.
radio-cubital, 143.
sacro-iliac, 155.
tarsal, of first row, 171.
■ second row, 171.
tarso-metatarsal, 175.
vertebral, 115.
clavicular, 137.
spinous, 116.
vertebral, 115.
of knee-joint, 163.
accessory, 166.
adipose (so called), 166.
alar, 166.
anterior, 163.
capsular, 163.
crucial anterior, 164.
• posterior, 163.
■ inter-articular, 163.
osseous, 164.
lateral, external, 163.
internal, 163.
■ mucous (so called), 166.
• posterior, 163.
transverse, 163.
of laryni, 425.
— malleus, 673.
metacarpo-phalangal, glenoid, 152.
lateral, 152.
■of thumb, 152.
of metacarpus, 148.
metatarso-phalangal, glenoid, 176.
— lateral, 176.
of metatarsus, 175.
occipito-atlantal anterior, superficial, 116.
deep, 116.
capsular, 117.
lateral, 117.
posterior, 116.
' axoid, lateral, 120.
middle, 120.
odontoid, lateral, 120.
middle, 120.
orbicular, of acromio-clavicular articula-
tion, 137.
■ of hip-joint, 158.
scapulo-humeral, 139.
sterno-clavicular, 137.
palmar of carpo-metacarpal joints, 149.
carpus, 147.
- metacarpus, 148.
of patella, 164.
perineal, 307.
peroneo-tarsal, anterior external, 170.
external, 170.
posterior, 170.
— of peroneo-tibial articulations, 167, 168.
— perpendicular, 170.
— phalangal of fingers, glenoid, 153.
■ lateral, 153.
toes, glenoid, 177.
lateral, 177.
of pisiform and cuneiform bones, 147.
plantar inferior, 174.
of metatarsus, 176.
tarso-metatarsal, 176.
Ligaments, plantar of tarsus, 172
Poupart's, 302.
proper, of scapula, anterior, 140.
posterior, 140.
- pterygo-maxillary, 235.
- pubic anterior, 155.
inferior, 155.
interosseous, 155.
posterior, 155.
superior, 155.
triangular, 155.
■ radiated chondro-sternal, 133.
■ of radio-carpal articulation, 145.
cubital articulations, 144.
■ recto-uterine, 467.
■ round, of forearm, 144.
hip-joint, 161.
■ uterus, 466.
■ sacro-coccygeal, anterior, 120.
posterior, 120.
■ iliac, anterior, 154.
interosseous, 154.
posterior vertical, 155.
superior, 154.
sciatic, great, 155.
small, 155.
vertebral, 120.
— scaphoid and cuboid, 172.
— of shoulder-joint, 136.
— spheno-maxillary, 129.
— stellate, costo-vertebral, 130.
' or radiated, chondro-stemal, 13L
• stylo-maxillary, 129.
mylo-hyoid, 129.
■ sub-pubic, or inferior pubic, 156.
• supra-spinous, 119.
■ suspensory of clitoris, 471.
' penis, 456.
— liver, 386, 475.
— of first row of tarsal bones, 171 .
second row of tarsal bones, 171.
— tarso-metatarsal, dorsal, 174.
interosseous, 174.
oblique of fifth toe, 175.
plantar, 174.
— of temporo-maxillary articulation, lateral
external, 128.
— internal, 129.
— thyro-arytenoid, or chords vocales, 427.
epig:lottid, 425.
hyoid, middle and lateral, 425.
— tibio-tarsal, anterior, 169.
internal, 169.
posterior, 169.
■ of tragus, 667.
• transverse of atlas, 117.
knee, 163.
metacarpus, 149.
• trapezoid, 136.
■ triangular of perinaeum, 307.
penis, 455.
symphysis pubis, 156.
urethra, 307.
wrist, 143.
■ of two rows of tarsal bones, 171.
■ vertebral, anterior common, 116.
interosseous, 116.
• posterior, 116.
— yellow elastic, 117.
- vesico-uterine, 467.
- of Weitbrecht, 144.
— Winslow, 164.
— wrist-joint, external anterior, 146.
— internal anterior, 146.
middle anterior, 146.
■ external lateral, 146.
. internal lateral, 146.
posterior, 146.
of Zinn, 650.
Ligamentum arcuatum of diaphragm, 213
denticulatum, 694.
fibulae anterius, 170.
medium, 170.
perpendiculare, 170.
posterius, 170.
gastro-phrenicum, 354.
latum pulmonis, 413.
longum plantae, 173.
mucosum of knee-joint, 164.
nnchffi, 202.
INDEX.
891
Ligamentum-piteXIs, 164.
phrenico-lienale, 403.
proprium anterius scapuls, 140.
posterius scapula, 140.
teres of forearm, 144.
■ '■ hip-joint, 161.
lambs. See Extremities.
Limbus luteus, 660.
Line, inter-trochanteric, 94.
mylo-hyoidean, 57.
naso-labial, 327.
Lines, semicircular of occipital bone, S3>
-— ^— — ^— OS cuxse, 88.
Litua alba, 301.
cervical, 300.
aspera, 94.
Ups, 325.
— — development of, 326.
movemeuts of, 238
muscles of, 326.
structure of, 326.
uses of, 327.
vessels of, 327.
Liquor Cotunni, 680.
• Morgagni, 663.
of Scarpa, 680.
Liver, 385.
acini of, 390.
circumference of, 389.
• coats of, 390.
colour and fragility, 389.
development of, 399.
ducts of, 391 (notes).
excretory apparatus of, 395.
figure, 386.
fissures, 387.
functions, 400.
groove for vena cava, 389
hilusof, 388.
ligament, broad or suspensory, 386.
coronary, 390.
falciform, 386.
triangular, left and right, 390
lobes, 387.
lobules or granules, 388.
arrangement of, 391.
' structure of, 394 (note).
- lymphatics of, 393.
-nerves of, 393.
-porta of, 388.
- proper tissue, 390 (note).
■ situation, 385.
■ size, 385.
-structure of, 390.
- surface, inferior or plane, 386.
• superior, 386.
Lungs, vessels and nerves of, 421.
weight of, absolute and specific, 410.
Lymphatic duct, right, 619.
- glands in general, 616.
preparation of, 617.
structure of, 617.
in particular, 619.
axillary, 628.
bronchial, 625.
cervical, deep, 628.
superficial, 627.
■ of cranium, 626.
• duodenal, 624.
■ of face, 626.
■ ileo-colic, 624.
• iliac, external, 622.
internal, 622.
■inguinal, 619.
■ intercostal, 625.
■ of intestine, great, 624.
— small, 624.
of liver, 623.
of lower extremity, 620.
lumbar, 621.
mammary, 625.
mediastinal, 625.
mesenteric, 625.
meso-colic, 624.
of pancreas, 624.
parotid, 627.
of pelvis, 621.
popliteal, 619.
pulmonary, 625.
sacral, 621.
of spleen, 624.
of stomach, 624.
.sub-maxillary, 627.
sub-sternal, 625.
tibial anterior, 619.
tracheal, 627.
of upper extremity, 628.
■ part of trunk, 628.
■ hearts of lovfcr animals, 617.
' networks, superficial and deep, 613.
■ plexuses, 612.
system, 611.
vessels of, 392.
arrangement of, 393.
Lobes and lobules of organs. See thorn organs.
Lobule of ear, 666.
Lobulus caudatus, 389.
quadratus, 389.
SpigeUi, 389.
Locus niger, 751.
perforatus anterior, 731.
middle or posterior, 727.
Longissimus dorsi. See Muscles.
Longitudinal fissures of liver, &c. See those organs.
vein of spine. See Vein*.
Luette of bladder, 459.
Lumbar nerves. See Nerves.
region of abdomen, 352.
veins. See Veins.
vertebne. See Vertebra and Vertebra.
Lungs, 409.
air-ceUs of, 415.
air-tubos of, 416.
cellular tissue of, inter-lobular, 415.
development of, 421.
external conformation of, 411.
^, fissures of, inter-lobular, 411.
foetal, 421.
functions, 422.
lobes of, 411.
lobules of, 415.
structure of, 419.
lymphatic system of, 421.
root of, 412.
size of, 409.
■ structure of, 413.
vessels in general, 611.
aflferent, 614.
' anastomoses of, 614.
branches of, 614.
coat of external, 616.
' internal, 616.
course and direction, 614.
' deep and superficial sets of, 618.
■ efferent, 614.
origin of, in different tissues, 612.
• preparation of, 617.
structure of, 616.
terminations of, 614.
valves of, 617.
vessels of, 616.
in particular, 618.
of bones, 16.
of brain, 628.
of cellular tissue, 613.
cervical, 628.
' posterior, 639.
of cranium, 637.
dorsal, 629.
of dura mater, 627.
epigastric, 622.
of external genitals, male and &•
male, 620.
of face, 627.
gluteal, 620.
of heart, 626.
ilio-lumbar, 622.
intercostal, 626.
of intestines, great, 625.
■ small, 625.
of kidneys, 622.
of lining membrane of bloodvessels,
613.
of liver, deep, 623.
superficial, 623.
' of lower extremity, deep and super*
ficial, 619.
lumbar, lateral, 622.
■ superficial, 620.
of lungs, deep and superficial, 626.
892
INSEJX.
Lymphatic vessels, mammary, internal, 626.
meningeal, 627.
of mucous membranes, 612.
occipital, 627.
of pelvis, 621.
pericardiac, 626.
periuaeal, 620.
peroneal, 620.
of serous and sysovial tissues, 613,
of skin, 613.
of spleen, 624.
of stomach, 624.
sub-sternal, 626
supra-renal, 622,
temporal, 626.
of testicles, 622.
thorax, 625.
thymic, 626.
thyroid, 627.
tibial, anterior and posterior, 620.
of upper extremity, 628.
• part of trunk, 628.
uterine 628.
Lyra, 738.
Macula cribrosa, 676l
Malar foramina, 54.
process, 51.
bone, 54.
Malleolus, external, 97.
internal, 98.
Malleus, and ligament of, 673.
muscles of, 673.
Mamma, 471.
adipose tissue of, 473.
development of, 474.
fibrous tissue of, 473.
glandular tissue of, 473.
lactiferous ducts of, 473.
■ of the male, 473.
vessels and nerves of, 474.
Mammary gland. See Mamma.
Mammillm. See Nipples.
Mammillary enlargements of posterior median colunms
of spinal cord, 704.
of inferior vermis, 716, 718.
tubercles, 426.
Manubrium of malleus, 673.
of sternum, 65.
Marrow of bones, 12.
Massa camea Jacobi Sylvij, 291.
Mastoid foramen, 43.
portion of temporal bone, 43.
process, 43.
Maxillary arteries. See Arteries.
bone, inferior, 57.
superior, 51.
canal, superior, 51.
inferior, 58.
nerves. See Nervet.
tuberosity, 51.
Jlfar^o-dentatus, 660.
MeeUus of nose, inferior, 54.
middle, 41.
• superior, 41.
auditorius externus, 44.
iutemus, 44.
urinarius, female, 471.
male, 461.
See Bar.
See Ear.
Mechanism of particular joints.
Mediastinum, anterior, 414.
posterior, 413.
See those joints.
Medulla oblongata, 702.
comparative anatomy of, 709.
development of, 708.
external conformation of, 702.
anterior surface, 703.
lateral surfaces, 704.
— posterior surface, 704.
' faisccaux innomines of, 706.
at base of brain, 706.
• in isthmus, 715.
fasciculi graciles, 708 (note).
olivary, 708 (note).
re-enforcing, 708.
teretes, 708 (note).
• pyramidal, 702, 704, '
fibres of, antero-posterior, 707.
arched, 704.
decussation of, 706.
MeduUa oblongata, foramen caecum of, 703.
furrow of median, anterior, 703.
posterior, 704.
■ internal structure of, 706.
— neck of, 702.
sections of, 705.
of long bones, 12.
spinalis. See Spinal Cord.
examined by hardening, 706.
sections, 705.
water, 706.
Medullary canal of long bones, 13.
membrane, 14.
Meibomian glands, 648.
Membrana nictitans, 648.
pupillaris, 659.
Ruyschiana, 657.
sacciformis, 143.
tympani, 669.
secundaria, 670.
uvea, 659.
Membrane, hyaloid, 661.
obturator, or sub-pubic, 155.
Membranes of cerebro-spinal axis. See ATodmotd,
Dura Mater, and Pia Mater.
of eye. See Eye.
fibro-mucous See Tibro-mucous Mem-
branes.
— fibro-serous. See Fibro-serous Membranes
— — — ^ mucous. See Mucous Membranes.
— ^^^— serous. See Serous Membranes.
^— — ^— synovial. See Synovial Membranes.
Membranous labyrinth, 679,
part of urethra, 458.
Meningeal arteries. See Arteries.
Meninges, 681.
Meningoses, 113.
Meniscus, 113.
Mental fossa, 57.
foramen, 57.
process, 56.
Mesentery, 364, 477.
left layer, 475.
right layer, 475.
Meso-cxcxim, 471.
■ colon, iliac, 475.
left and right, 475.
transverse, 375.
layer, inferior, 476.
— superior, 477
' ■ - ga-strium, 478.
— — rectum, 475.
Metacarpus, bones of, 84.
■ differential characters, 89.
general characters, 85.
■ compared with metatarsus, 109.
Metatarsus, bones of, 103.
characters, general, 103.
differential, 102.
compared with metacarpus, 109.
Milk teeth. See Teeth.
Modiolus of cochlea, 678.
Mom Veneris, 470.
Morsus diaboli, and fimbriie of Fallopian tube, 463.
Motores oculi nerves. See Nerves.
Mouth, component parts of, 422.
situation, dimensions, &c., 422.
Movements of joints. See Articulations.
in general, 148.
lips and face, 238.
Mucous bursae (so called), 175.
membranes, in general, 421.
chemical composition, 42L
epithelium, 421.
■ of particular organs. See thoa
organs.
— structure, 421.
Mucro, 65.
MultifiduM spinae. See Muscles-
Muscles in general, 190.
action of, 194.
angle of incidence on bones, 195.
antagonist, 196.
aponeuroses of, 193.
arrangement, physiological, of, 291.
attachments of, 192.
— fixed, 191
movable, 193.
broad, 190.
conge.nen<ns. 197.
IKDEX.
Miuehs, direction of, 191.
' figure of, 191.
insertion of, into other puts, 19t.
long, 191.
momeutum of, 195.
nerves of, 763.
nomenclature of, 190.
number of, 190.
orde' of description of, 197.
origin and termination of, 198.
preparation of, 197.
relations of, to other ports, 101
satellite, 192.
sheaths for, 296.
short, 191.
structure of, 193.
tendons of, 193.
uses of, 194.
volume of, 190.
in particular, 196-291.
——^— of particular organs, parts, or regions,
those organs, parts, or regions.
' abductor brevis pollicis, 260.
digiti minimi, 262.
pedis, 289.
See
' indicia, 264.
' longus pollicis, 258.
• oculi, 650.
■ pollicis, 287.
— pedis, 277.
• accelerator urinse, 456.
' accessorious pedis, 280.
ad sacro-lumbalem, 877.
• adductor brevis femoris, 276.
digiti minimi (opponens), 281.
longus femoris, 276.
magnus femoris, 276.
oculi, 650.
pollicis manOs, 288.
pedis, 288.
anconeus, 258.
anterior auriculs, 230.
antitragieus, 667.
articulo-spinalis, 201.
arytenoideus, 429.
obliquus, 429.
transversus, 430.
• aryteno-epiglottideus, 430.
' attoUens auriculam. 231.
• oculum, 650.
— attrahens auriculam, 231.
— auricularis anterior, 231.
posterior, 231.
-- superior, 231.
• azygos uvulie, 332.
' basio-glossus, 338.
biceps cruris vel femoris, !
flexor cubiti, 245.
— biventer cervicis, 201.
— brachialis anticus, 246.
— buccinator, 235.
— bulbo-cavernosus, 456.
— caninus, 236.
— cerato-glossus, 338.
— chondro-glossus, 338.
— ciliaris, 232.
— circumflexus palati, 332.
— coccygeus, 381.
— complexus, 205.
minor, 205.
— compressor narium, 233.
nrethrffi, 460.
in the female, 470.
— vente dorsalis penis, 460.
- constrictor inferior, 346.
iiiedius, 347.
superior, 347.
— vagince, 469.
— coraco-brachialis, 246.
— coTrngator supercilii, 232.
— cremaster, 210,450.
— crico-arytenoideus lateralis, 428.
posticus, 428.
CBsophageus, 352.
thyroideus, 421.
— crotaphyte, S40.
— crureus, 273.
— cutanei, 294.
— deltoideus, 241.
— depresssor alae nasi, 334.
Muscles, depressor angali oris, 837.
labii inferioris, 237.
superioris alsque nasi, 234.
oculi, 650.
urethrjE (Santorini), 460.
in the female, 470.
diaphragma, 218.
digastricus, 228.
elevatores nrethno (Santorini), 400.
erector clitoridis, 471.
penis, 456.
spinee, 202.
extensor brevis digitorum pedis, 286.
pollicis, 259.
carpi radialis brevior, 255.
longior, 355.
' ulnaris, 258.
— communis digitorum, 866.
— digiti minimi, 257.
— indicis, 259.
— longus digitorum pedis, 278.
pollicis, 259.
— ossis metncarpi pollicis, 258.
— primi internodii pollicis, 258.
— proprius auricularis, 256.
indicis, 259.
— pollicis pedis, 279.
secundi internodii pollicis, 958.
flexor accessorius, 290.
brevis digiti minimi, 262.
minimi pedis, 289.
digitorum pedis, 389
pollicis, 262.
■ pedis, 287.
carpi radialis, 850.
ulnaris, 250.
longus digitorum pedis, 335.
pollicis, 253.
pedis, 886.
perforans, 251.
' pedis, 285.
perforatus, 252.
pedis, 390.
profundus digitorum, 252.
sublimis digitorum 331.
frontalis, 230.
gastrocnemius, 281.
• gemellus inferior, 267.
superior, 267.
genio-hyoglossus, 338.
hyoideus, 229.
glosso-staphylinus, 332.
glutseus niaximus, 264.
medius, 265.
minimus, 266.
gracilis, 275.
helicis major, 667.
minor, 667.
Homer's, 653.
Houston's, 457.
hyo-glossus, 338.
iliacus, 215.
indicator, 260.
infra-costales, 232.
spinatus, 243.
intcr-costales externi, 222.
intemi, 222.
■ ossei manAs, 263.
dorsales, 264.
' palmares, 264.
■ pedis dorsales, 290.
plantares, 290.
■ spinales colli, 286.
■ transversales colli, 917.
— lumborum, 218
ischio-bulbosus, 457.
in the female, 470.
cavernosus, 456.
in the female, 471.
coccygeus, 380.
latissimus dorsi, 198.
laxatOT tympani, 675.
levator anguli oris, 236.
scapulae, 201.
ani, 380.
labii inferioris, 237.
superioris, 236.
alasque nasi, 333
menti, 237.
oculi, 640.
894
INDEX.
Muscles, levator palati, 332.
palpebrae superioris, 233, 648.
— — — — prostatae, 382.
UTulte, 337.
levatores costarum breviores, 222.
— longiores, 222.
Muscles, rectus oculi superior, 649.
retrahens auriculam, 230.
rhomboideus major, 200.
minor, 200.
lingualis (Albinus and Douglas), 337.
inferior, 337.
superficialis, 337.
- longissimus dorsi in tie loins, 208.
1 neck, 203.
• thorax, 203
-longus colli, 218
- lambricales manOs, 253.
• pedis, 290
accessory fibres to, 203, 204.
- mallei externus magnus, 673.
parvus, 673.
intemus, 674.
- masseter, 239.
- multifidus spins in the loins, 202, (note).
__ back, 203.
■ neck, 204.
-mylo-hyoideus, 229.
-mjrrtiformis, 234.
- naso-labialis, 234.
- obliquus abdominis extemus, 208.
■ intemus, 209.
- capitis inferior, 206.
superior, 206.
- oculi inferior, 651.
superior, 651.
- obturator extemus, 268.
■ intemus, 267
occipitalis, 230.
occipito-frontalis, 230.
pharyngeus, 338.
- omo-hyoideus, 226.
- opponens digiti minimi, 262.
— poUicis, 260.
- orbicularis oris, 235.
' palpebrarum, 231.
- palato-glossus, 332.
pharyngeus, 332.
staphylinus, 332.
-palmaris brevis, 261.
longus, 250.
- palpebralis, 231.
- patheticus, 651.
-pectineus, 275.
-■ — pectoralis major, 220.
minor, 221.
perforatus Casserii, 253.
peri-staphylinus extemus, 332.
intemus, 332.
peroneus brevis, 280.
longus, 280.
tertius, vel anticus, 279.
petro-pharyngeus, 348.
pharyngo-staphylinus, 332.
plantaris, 282.
platysma myoides, 224.
popliteus, 283.
pronator quadratus, 253.
radii teres, 249.
rotundas, 249.
psoas-iliacus, 214
magnus, 215
parvus, 216.
pterygoideus extemus, 241
internus, 240.
pterygo-pharyngeus, 347.
pubio-urethralis, 457.
pyramidalis abdominis, 212.
nasi, 233.
- pyriformis, 266.
- quadratus femoris, 268.
- lumborum, 216,
— meuti, 237.
- rectus abdominis, 210
capitis anticus major, 218.
- minor, 218.
lateralis, 217.
posticus major, 206.
minor, 206.
• femoris, 270.
intemus, 272.
• oculi extemus, 650.
internus, 650.
inferior, 650.
-risorius Santorini, 284.
- sacro-lumbalis, in the loins, 203.
in the thorax, 204.
on the chest, 204.
- salpingo-pharyngeus, 338.
■sartorius, 272.
- scalenus anticus, 217.
posticus, 218.
-scalptor ani, 275.
scapulo-hyoideus, 226.
semi-spinalis colli, 204 (note).
dorsi, 204 (note).
■ membranosus, 270.
' tendinosus, 270.
- serratus anticus, 223.
- parvus, 223.
■ magnus, 221.
- posticus inferior, 201 .
■ superior, 201.
• soleus, 282.
- spheno-pharyngeus, 338.
■ sphincter ani extemus, 380.
■ intemus, 380.
(esophagi, 350.
vaginse, 470.
vesicae, 442.
-spinales posteriores, 201.
■ action of, 203.
' general view of, 203.
in the loins, 201.
neck, 204.
' thorax, 204.
■ spinalis dorsi, 204.
• cervicis, 204.
- splenius capitis, 202.
-colli, 202.
■stapedius, 671.
■ sterno-cleido-mastoideus, 224.
hyoideus, 226.
thyroideus, 227.
- stylo-glossus, 337.
hyoideus, 229.
alter, 230.
pharyngeus, 346.
- sub-clavius, 221.
scapularis, 244.
- super-ciliaris, 232.
■ supinator radii brevis, 256.
longus, 254.
- supra-costales, 221.
spinatus, 243.
-suralis, 281.
- temporalis, 239.
- tensor palati, 332.
tarsi, or Homer's, 653.
tympani, 671.
vagina; femoris, 271.
- tensors of fasciae, 296.
- teres major, 198.
minor, 243.
- thyro-arytenoideus, 428.
epiglottideus, 428.
hyoideus, 227.
- tibialis anticus, 278.
- posticus, 284.
• trachelo-mastoideus, 204.
■tragicus, 667.
■ transversalis abdominis, 210.
-cervicis, 205.
— colli, 204.
- nasi, 234.
■ transverso-spinalis, 202.
— in the loins, 202.
in the neck, 204.
in the thorax, 204
transversus auriculae, 667.
nasi, 234.
pedis, 290.
perinaei, 381.
■ alter, 457.
' pollicis pedis, 290.
-trapezius, 198.
- triangularis nasi, 234.
oris, 237.
stemi,
- triceps adductor femoria^ 274.
INDEX.
Muscles, triceps extensor cruris, 273.
cubiti, 247.
femoralis, 272.
- femoris (auctor), 272.
suralis, 281.
- trochlearis, 651.
- of the ureters, 445.
vastus externus, 273.
intemus, 273.
Nerves, sensory, common, 759, 7fl8.
— special, 762.
spinal, 759.
structure of, 766.
symmetrical, 760.
sympathetic, 762, 764.
structure of, 767.
• Wilson's, 457.
- which move the arm upon the shoulder, 292.
fingers, 293.
foot upon the leg, 293.
forearm upon the arm, 293.
hand upon the forearm, 293.
leg upon the thigh, 292.
lower jaw, 292.
OS hyoides, 292.
pelvis, 292.
radius upon the ulna, 293.
ribs, 292.
: shoulder, 292.
skin, 293.
thigh upon the pelvis, 292.
toes, 293.
■ vertebro-cranial column, 292,
— walls of thorax and abdomen,
292.
• zygomaticus major, 236.
■ minor, 236.
Muscular fibres, filaments, and fasciculi, 198 (note).
fibres of particular organs. See those organs,
sheaths, 296.
tissue, involuntary, 198.
structure, 322.
voluntary, 198.
— — ^ chemical composition, 199.
structure, 198.
Musculi pectinati, 486.
papillares, 484.
Musculo-cutaneoMs nerves. See Nerves.
Myology, 190.
Nails, 636.
lunule of, 636.
matrix, 636.
structure and growth of, 637.
Nares, anterior, 60.
posterior, 60.
Nasal arteries. See Arteries.
bone, 55.
•■ cartilages. See Nose.
duct and canal, 653.
■- eminence, 35.
fossie, 62.
meatuses, 41.
nerves. See Nerves.
process, 51.
spine, anterior and posterior, 82, 54.
Nates (of brain), 712.
Navicular fossae. See Fossa.
Necks of bones, 10.
particular. See those bones.
Nerves in general, 759.
anastomoses of, 762.
of animal life, 761.
central extremity of, 760.
classification of, 759.
course of, 762.
cranial, 759.
different kinds of, 761.
direction of, 763.
division of into sets, 769.
fibres and filaments of, 767.
' ganglia of, 765.
connexions of, 765.
different kinds of, 765.
structure of, 768.
ganglionic, 764.
mode of division of, 764.
motor, 759.
neurilemma of, 766.
of organic life, 761.
origin of, apparent and real, 758.
plexuses of, 762. See Plexuses
preparation of, 769.
relations of, 763.
respiratory, 760, 762.
roots of, anterior or motor, 762.
posterior or sensory, 762.
termination of, 764.
in particular, 769.
abdominal, great, 798.
small, 799.
abducens oculi. See Motor Oculi, extemai.
accessory, of internal cutaneous, 785.
saphenous, 801.
' obturator, 801 (note).
' spinal, distribution of, 849.
function of, 851.
■ ganglion of, 824.
— origin of, 823.
— vertebral course, 824.
acromial, 778.
alveolo-dental, anterior, 834.
posterior, 834.
anal cutaneous, 806.
aortic, sympathetic, 863.
articular of ankle, 812.
of elbow, 785, 786.
hip-joint, 800.
of knee, anterior, 802.
external, 808.
of wrist, 785.
auditory. See Portio Mollis.
auricular, anterior, 836.
■ great, 778.
• internal, 812.
• from obturator, 801.
■ recurrent, 809.
■ posterior, or azygos, 6U.
of pneumogastric, 845.
■ posterior, 840.
auriculo-occipital, 840.
■ temporal, 836.
axillary, or circumflex, 783.
azygos, of knee-joint, 813.
buccal, 835.
of facial, 841.
bucco-labial, 835.
bulbo-urethral, 806.
calcaneal, external, 812.
' internal, 813.
cardiac, great, 861.
inferior, left, 861.
right, 861.
lesser, 861.
middle, left, 862.
right, 861.
of pneumogastric, in neck, 647.
in thorax, 837.
• of recurrent laryngeal, 837.
— superficial, 861.
— superior, left, 861.
- right, 860.
of sympathetic, 860.
carotid branch of vidian, 833.
of sympathetic, 765.
cerebral. See Cranial.
cervical, branches of, anterior, 776, 781.
posterior, 773.
■ number of, 771.
•roots of, 771.
cervical, first, anterior branch of, 776.
posterior branch of, 773.
second, anterior branch, 776.
posterior branch, 774.
— third, anterior branch, 777.
posterior branch, 774.
— fourth, anterior branch, 777.
posterior branch, 774.
— fifth to eighth, anterior branches, 781
posterior branches, 774
-of facial, 841.
— internal descending, 780.
— superficial, 778.
cervico-facial, 839, 841.
chorda tympani, 836.
. canal for, 672.
ciliary, 659, 830.
nasal, 830.
ophthalmic, 830.
circumflex, 782.
«96
Nerves, clavicular, 783. "^''^ " ^ . W
of clitoris, 807.
for cochlea, 842.
collateral dorsal of fingers, 790.
. of thumb, 798.
of toes, 811.
palmar of fingers, 788, 790.
■ thumb, 788.
rNDEX.
• comnmnicating fibular, 811.
tibial, 811.
for complexus, 773.
for coxo-femoral articulation, 800 (note).
cranial, in general, 816.
central, extremities of, 817.
classification of, 816.
distribution of, 832.
general view of, 853.
nomenclature of, 817.
cranial, in particular, 832.
first. See Olfactory.
second. See Optic.
third. See Motor UcuH, common.
fourth. See Pathetic.
fifth. See Trifacial.
sixth. See Motor Oculi, external.
seventh. See Portio Dura and Pord'o
Mollis.
eighth. See Pneumogastric, Glosso-
pharyngeal, and Spinal Accessory.
ninth. See Hypo-glossal.
crural, 801.
for crureus, 802.
cutaneous, accessory of saphenous, 801 .
— anal, 806.
external, of arm, 785.
' of musculo-spiral, 791.
■of thigh, 799.
• of intercostal, 794.
■ internal, of arm, 784.
accessory of, 785.
of musculo-spiral, 791.
of thigh, 801.
■ of Wrisberg, 785.
■long, of obturator, 801 (note),
-middle, of thigh, 801.
• of musculo-cutaneous of arm, 785.
■palmar, 787.
■ perforating, of intercostal, 794.
of thigh, 803.
— plantar, 813.
— radial, 792.
— of shoulder, 784.
— of S(Emmering, 807.
— tibial, 803.
■ ulnar, dorsal, 789.
deep palmar, 789.
■ plantar, 814.
temporal, 835.
dental, anterior, 834.
inferior, 837.
posterior, 833.
descendens noni, 853.
descending cervical, 779.
internal, 777.
diaphragmatic, 780.
digastric, 840.
digital, of median, 788
of radial, 792.
of ulnar, 789.
dorsal, branches of, anterior, 794.
- posterior, 77S
~ number of, 771.
— roots of, 772.
— collateral of fingers, 790, 792.
— toes, 8)1.
— of foot, deep external, 811.
— internal, 811.
— of hand, external, 792.
internal, 790.
— intercostal. See Intercostal.
— of penis, 806.
■ dorsi-lumbar, 796.
- to dura mater, 835.
• encephalic. See Crtmidl.
■ ethmoidal, 830.
■ facial. See Portio Dvra.
branches, collateral, 839.
summary of, 848.
• to femoral artery, 802.
- frontal, 828.
Nerves, frontal, external, 829.
— internal, 829
— osseous, 829
- fronto-nasal, 829 (nole^
- for gastrocnemius, 812.
- for gemelli, 808.
- genito-crural, 799
■ glosso-pharyngeal, distribution of, 843.
function of, 845.
ganglion of, 844.
origin and cranial course,
823.
■ gluteal, inferior, 807.
• superior, 807.
• gustatory, 836.
• hemorrhoidal, inferior, 806.
■ to hip-joint, 800 (note),
-hypo-glossal, distribution, 851.
function, 853.
ganglion, 823.
origin and cranial course, 824
- ilio inguinal, 798.
scrotal, 798.
small, 798.
- incisor, 837.
• infra-hyoid, of hypo-glossal, 852.
orbital, 831, 841.
of facial, 841.
trochlear, 830.
■ inguinal, external, 797.
■ internal, 797.
■ ingnino-cutaneous, 797.
■ intercostal, 794.
muscular, 794.
perforating, 794.
summary of, 796.
■ costo-humeral, 795.
■ osseous, anterior, of forearm, 79d.
of leg, 811.
■ posterior, of foreann, 790.
■ ischiadic, 802.
lesser, 802.
■ of Jacobson, 838.
■ lachrymal, 828.
of orbital, 831.
lachrymo-palpebral, 888.
• laryngeal, anastomotic, 847.
external, 846.
inferior, or recurrent, 847.
superior, 846.
' of sympathetic, 859.
■ to latissimus dorsi, 784.
■ levator angul i scapulae, 782.
• ani, 805.
■ lingual, 836.
• of glosso-pharjmgeal, 844.
■ longitudinal, of Lancisi, 737.
■ lumbar, branches of, anterior, 796.
posterior, 776.
number of, 772.
roots of, 772.
■ lumbo-sacral, 797.
' malar, 831.
of facial, 840
■ masseteric, 835.
■ mastoid, great, 779.
■ small, 780.
• maxillary, inferior, 834.
superior, 831.
terminal blanches of, 834L
■ median, 786.
in arm, 786.^
in forearm, 787.
■ in hand, 787.
- mental, 837
of facial, 841.
■ motor oculi, common, distribution of, 825.
function of, 826.
origin and cranial course,
820.
external, distribution, 838.
origin and cranial course.
822.
• musculo-cutaneous, brachial, 786,
. crural, 801.
— dorsal, 775.
■ of leg, 810.
- lumbar, inferior, 798.
— middle, 798.
superior, 798
INDEX.
Nerves, musuulo-spiral, 786, 791.
myloid, 837.
nasal, 829.
• external, 829.
internal, 830.
— — posterior, 832.
superior, 833.
■ of nasal fossa, external, 830.
naso-lobar, 830.
palatine, 832.
obturator, 799.
accessory of, 800 (note).
articular of, to hip, 800.
' knee, 801 (not«).
' long cutaneous, 801 (note).
■ to obturator iiitemus, 805.
■ occipital, external, 779.
great, 777.
- small, 780.
■ oculo-muscular. See Motor Oculi and Pathetic.
■ oesophageal, 847.
■ olfactory, bulb of, 817.
distribution of, 824.
function of, 825.
origin and cranial conrse, 818.
structure of, 818.
■ ophthalmic, 827.
■ optic, chiasma or commissnre of, 819.
distribution of, 825.
function, 825.
origin and cranial course, 819.
roots of, gray, 608.
' structure, 820.
Nerves, popliteal, sciatic, external, 808.
internal, 811.
portio dura, distribution, 839,
function, 843.
"^ ■ origin and cranial course, 82S.
mollis, distribution, 681, 842.
function, 842.
origin and cranial course, 63S.
structure, 768.
• pterygoid, 833
internal, 836.
• pudendal, long, 808.
• pudic, internal, 806.
■ in female, 807
pulmonary, anterior and posterior, 848.
to pyrifonnis, 807.
for quadratus femoris, I
— radial, or musculo-spiral, 790.
proper, 791.
— to rectus femoris, 802.
— recurrent, of knee, 810.
^— ^— ^^— laryngeal, 648.
lesser sciatic, 8081
-- terminations of, 671.
tracts of, 819.
■ orbital, 831.
of facial, 840.
' palatine, anterior, 832.
middle, 832.
posterior, 832.
■ palmar collateral, 769, 790.
' cutaneous, 768.
• palpebral, inferior, 840.
■ superior, 840.
of particular organs, parts, or tissues. See
those organs, &c.
par Tagnm. See Pneumogastric.
pathetic, distribution, 826.
function, 826.
origin and cranial course, 820.
to pectineus, 801 (note), 802 (note).
■ pectoralis major, 783.
• minor, 783.
• perforans Casserii, 786.
■ perforating, of hand, 790.
cutaneous, of inter-costalsj
thigh, 802.
' perineal, 806.
superficial, anterior, 806.
posterior, 806.
- peroneal, 808.
cutaneous, 810.
external, 810.
saphenous, 810.
' petrosal, superficial, great, 833.
small, 838.
■ pharyngeal, of glosso-pharyngeal, 844.
' pneumogastric, 646.
small, 846, 850.
of spheno-palatine, 833 (note).
sympathetic, 859.
■ phrenic, 780.
■ plantar, collateral, 813, 814,
external, 814.
■ deep, 814.
internal, 813.
' for plantaris longus, 812.
' pneumogastric, in abdomen, 846.
anastomoses of, 845.
cranial course, 823.
fibrous layers of, 719.
in foramen lacerum, 645.
functions of, 849.
ganglion of, 845.
in neck, 845.
origin of, 823.
summary of, 849.
in thorax, 847.
■ popliteal, external, 808.
internal, 812.
■ renal, 865.
• respiratory, external, 782.
of eye, 891.
superior, of trunk, 850.
■ to rhomboideus, 782
■ sacral, branches of, anterior, 804.
posterior, 777.
— number of, 772.
roots of, 772.
' saphenous, external, 812.
internal, 803.
accessory, of, 802
— peroneal, 810.
' satellite, of femoral artery, 803.
• ulnar artery, 790.
■ sciatic, great, 808.
lesser, 801.
■ of septum nasi, anterior, 830.
posterior, 832.
■ to serratus, '
■ of sheath of femoral vessels, SOS,
■ soft (nervi molles), 845.
■ spheno-palatine, external, 833.
— internal, 832.
• spinal, 770.
— accessory of Willis.
— branches of, in general, 771
anterior, 771.
ganglionic, 771.
posterior, 773.
See AcctMorf,
■ classification of, 770.
■ number of, 770.
• origin of, apparent, 770.
real, 772.
plexuses of, 776.
— roots of, anterior, or non-ganglionic, 77L
— roots of, posterior, or ganglionic, Til
' splanchnic, great, 865.
lesser, 865.
lumbar, 869.
■ splenic, 867.
- to splenius, 843.
■ sternal cutaneous, 780.
• styloid, 840.
■ to sub-clavius, 782.
■ sub-occipital, anterior branch, 778.
• posterior, 776.
■ scapular, inferior, 784.
superior, 783.
■ of sub-septum, 841.
superficial cardiac, 862. •
cervical, 776.
petrosal, great, 633.
lesser, 637.
■ temporal, 835.
• supra-clavicular, 779.
orbital, 828.
scapular, 782.
' trochlear, 829.
5X
to supra and infra-spinati, 782.
sympathetic, in general, 761.
characters of, 871.
structure of, 766.
in particular, 854.
abdominal, 851.
I cervical, 855.
lumbar, 848.
898
INDEX.
Nervei, sympathetic, sacral, 871.
— thoracic, 868.
temporal, deep, 835.
of facial, 839.
-- superficial, 836.
• temporo-facial, 839.
malar, 831.
' to tensor tympani, 837.
vagins femoris, 807.
• tentorium cerebelli, ffl7.
■ teres major, 874.
minor, 783.
• thoracic, 783.
anterior, 783.
— posterior,782.
-tibial, 811.
anterior, 811.
cutaneous, 802.
posterior, 811.
saphenous, 813»
• to trapezius, 781.
• trifacial, distribution of, 827.
divisions of, 827.
ganglion of, 821.
' origin and cranial course, 821.
root of, large, 821.
small, 821.
■trigeminal. See Tfifaeiat.
■ trochlear. See Pathetic.
■ tympanic, of Jacobson, 838.
• ulnar, 789.
in the arm and fo(re8rm> 789.
- hand, 790.
- for ulnar artery, 790.
- uterine, 870.
- vaginal, 870.
- for vasti femoris, 802.
- vertebral (sympathetic), 860.
■ vesical, 870.
■ vestibular, 843.
■ vidian, 833.
■ visceral, abdominal, 866.
cervical, 845.
pelvic, 869
■ sacral, 805
Nervi moUes, 845.
Nervous system, central portion, 681.
peripheral portion, 769.1
Nervut impar, 698.
Neurilemma of nerves, 766.
spinal cord, 697.
Neurology, 629.
Ninth nerve. See Nerve, hypoglossal.
Nipples, 472.
glands and papillte of, 473.
Noduli Arantii, 479.
Nodulus of cerebellum, 716 (note).
Nodus encephali (Soemmering), 844-
Ncsud de I'encephale, 844.
Nost, general description, 641.
bones of, 55, 641.
cartilages of, 641.
mucous membrane of« MStt
' muscles of, 643.
septum of, 56, 642.
skin of, 643.
Nostrils, 641.
cartilages of, 641.
Notch, inter-cocSyloid, 91.
ischiatic, 89.
-—^— sacro-sciatic, 89.
great, 15S.
small, 156.
sciatic, 89.
' sigmoid, 57.
Notches, vertebral, 20, 31.
Nutritious arteries. See Arteries.
foramina of bones. See Fontmen.
Nympha, 471.
■Obligue muscles. See Musclet.
'Obturator foramen and groove, 88.
nerve. See Nerves.
' Occipital angle of DaubentOB, 45.
bone, 33.
condyles, 33<
crests, 34.
foramen, 34.
fossae, 34.
' nerves. See iVerM*.
Occipital protuberances, 34.
veins. See Veins.
Occt7>ito-atlantoid articulations, 118
ligaments, 118.
' axoid articulations, 119.
' ligaments, l20.
parietal suture, 46,
OcuZo-muscular nerves. See Nenitt, Motwr Oaii tad
Pathetic.
Odontoid process, 26.
Odontogeny, 184.
Odontology, 177.
(Esophagus, 350. •
glands of, 352.
ihooous membrane, 352.
muscular coat, 351.
structure of, 351.
uses, 352.
vessels and nerves, 3S3,
OUcranoid cavity, 80,
Olecranon process, 80.
Olfactory nerve. See Nervtt
■ lobes, 758.
Olivary process, 37,
bodies, 703.
corpus dent&taiB of, 704.
sections of, 704.
structure of, 706.
fasciculi, 705.
Omentum, colic, 478 (note).
- gastro-colic, 478.
hepatic, 476.
— splenic, 408.
■ great, 476.
layers of, anterior, 476.
-posterior, 476.
«ac of, 477.
vessels and nerves of, 478.
lesser, 476.
layer of, anterior, 476.
posterior, 476.
Operculum laryngis, 426,
Ophthalmic nerve, 828.
Optic thalami, 727, 745.
fibres of, 746,
tracts, 820.
Orbicular ligaments of joints.- See Ligaments.
Orbital arch, 36.
cavities, 6
fissure, 53.
foramina, internal, 36.
process of palate bone, 6S.
processes of frontal bone, 36.
plate, 36.
Orbits, 62.
Organ of hearing, 665. See Ekir.
sight, 645, See Eye.
smell, 641, See Nose, &aA Pituitary Mttnbrcoi*.
taste, 639. See Tongue.
touch, 629. See Skin.
the voice, 422. See Larynx.
Organs, anatomical elements of, 320.
colour and consistence of, 321.
development of, 321,
of digestion, 322,
direction and relations of, 3S1.
dissection of, 322,
functions of, 322,
of generation, female, 46],
male, 446.
genito-urinary, 435,
nomenclature, 320,
number, 320.
of respiration, 409.
of the senses, 629.
situation, 320.
size and figure, 321.
structure of, 321.
urinary, 435.
Os, bone. See Bone, oi.
tincsE, 465.
uteri, 465.
Ossa pisiformia, or lingualia. 111.
triquetra, or Wormiana, 50.
Ossicula auditOs, 669.
movements of, 675.
muscles belonging to, 674.
Ossification of bones. See those bones
Osteology, 5.
Osteogeny, 16.
INDEX.
899
Ottia of Fallopian tube, 463.
Ottium internum of uterus, 465.
Otoconia and otolithes, 843.
Ova of Naboth, 466.
Ovarian vesicles, 463.
Ovaries, 461.
• ligaments of, 461.
- structure, 463.
Ovum, 462
Palate, bone, 53.
hard, 330.
development, 330.
structure, 330.
uses, 330.
soft, 330.
- aponeurosis of, 331.
————— development of, 333.
glands of, 333.
— — — — mucous membrane of, SSS.
muscles of, 331,
pillars of, 331.
■ structure of, 331
— uses of, 331.
— vessels, &c., of, 333.
Palatine aponeurosis, 331.
arch, 329.
canals, 52, 54.
accessory, 53, 54.
glands, 330.
• process, 52.
Palm of hand, 83.
Palmar arteries. See Arteries.
ligaments. See Ligament*.
nerves. See Nerve*.
Pancreas, 400.
development of, 409.
duct of, 402.
function of, 402.
lesser, 402.
structure of, 401.
1 vessels and nerves of, 408.
Panniculus adiposus, 629.
camosus, 629.
Papula, conjunctival, 648.
dental, 181.
(Goodsir), 183.
of kidney, 437.
— — — lachrymal, 646.
of skin, 630.
~ of small intestine, 367.
of stomach, 361.
of tongue, 333.
Par vagum. See Nerve, pneumogoitric
Parietal bone, 41.
foramen, 41.
■- fossa, 41.
protuberance, 41.
Parotid dnct, 341.
gland, 340.
development of, 340 (note).
structure of, 340.
Pars mastoidea of temporal bone, 43.
petrosa of temporal bone, 43.
squamosa of temporal bone, 43.
Patella, 95.
ligament of, 97.
Pathetic nerve. See Nerve*.
Patte d'oie, 270, 271.
Peduncles of cerebellum and cerebram.
gans.
Pelvis, aponeuroses of, 306.
articulations of, 154.
•^—^ axes of, 90.
• circumferences of, 92.
• compared with shoulder, lOS.
. development of, general, 93.
' in general, 90,
■ great or false, 90.
of the kidney, 439.
: structure of, 439.
little or true, 90.
brim of, 92.
strait, superior, 92,
■ inferior, 92.
See those or-
mechanism of, 158-159.
regions of, 90.
' varieties of, sexual, 90.
excavation or cavity of, 12S.
outlet of, 92.
Penis, 454.
corpus cavemosum of, 455.
glans of, 461.
ligament, suspensory or triangular, 45A
muscles of, 457.
Perforated spot, anterior, 734.
■ posterior, 730.
Perforating arteries. See Arteries.
nerves. See Nerve*.
Pert-cardium, 494.
structure, 494.
vessels, 495.
Peritoneum, 474.
folds of, 478.
general description of, 478.
portion of, parietal, 478.
sub-umbilical, 474.
supra-umbili(^, 474
visceral, 477.
structure of, 479.
Permanent teeth. See Teeth.
Perone, 98.
Peroneal arteries. See Arteries.
See Nerve*.
Pes accessorius, 746.
hippocampi, 745.
Petrosal nerves. See Nerves. ^
Petrous portion of temporal bone, 4S.
process, 43.
' glottis, 640.
• lymph, 679.
' osteum, 296.
' alveolo-dental, 338.
Pharyngeal nerves. See Nerve*.
Pharynx, 344.
aponeuroses of, 346.
development of, 349.
mucous membrane of, 319.
muscles of, 346.
extrinsic, 346.
intrinsic, 346.
supernumerary, 346.
uses, 349.
vessels and nerves, 349.
Pia mater, 692.
cerebral, 692.
spinal, or rachidian, 697.
Pigmentum of skin, 632 (note)
eye, 659,
Pillar of valve of Vieussens, 712.
Pillars of diaphragm, 212.
- fauces, or palate, 331.
fornix, 740.
Pineal gland or body, 742.
- commissure and peduncles of, 743.
- concretions, 743.
function of, 744.
Pisiform bone, 83.
Pt<utM, 749.
Pituitary body or gland, 729.
- fossa, 37.
— membrane, 643.
follicles of, 645.
nei ves of, 645.
structure, 644.
vessels of, 645.
Plantar ligaments. See Ligaments.
nerves. See Nerves.
Plaques gaufries, '.
Plate, cribriform, of ethmoid bone, 40.
- horizontal, of palate bone, 53.
- orbital, 35.
- perpendicular, of ethmoid bone, 41.
Pleura, costal, diaphragmatic, mediastinal, and polnto
nary, 413.
structure and uses of, 413.
Pleura:, 413.
Plexuses of lymphatics, 614.
of nerve, 762, et infra.
auricular, 858.
brachial, 781.
general view Ofnerrei of, 79S>
' bronchial, 848.
• cardiac, deep, 860.
great, 863.
' carotid, 856.
■ superficial, 862.
— cavernous, 856.
— cervical, 777.
deep, 777.
900
INDEX.
Plexuses, cervical, posterior, 774.
superficial, 777.
— ■^-— cervico-brachial, 77(i
coeliac, 866.
coronary, of heart, anterior and posterior, 863,
of stomach, 866.
' diaphragmatic, I
' epigastric, 866.
' facial (sympathetic), 858.
' gastro-epiploic, left, 868.
• right, 867.
— hemorrhoidal, inferior, 890.
snporior, 868.
■ hepatic, 867.
• hypogastric, 870.
■ infra-orbital, 841.
• laryngeal, 846.
' lingual, 858.
' lymphatic, 612,
. lumbar, 797.
' lumbo-aortic, 868, 869.
sacral, 776.
' mental, 837.
' mesenteric, inferior, 868.
superior, 867.
■ nervous, 762.
■ occipital, 859.
■ ovarian, 868.
• pharyngeal, 846, 859.
• phrenic, 866.
■ pulmonary, anterior and poBtraior, 848.
• renal, 868.
■ sacral, 805.
• solar, 866.
■ spermatic, 868.
■ splenic, 867.
' supra-renal, 866.
• thyroid, 858.
• tympanic, 843.
• uterine, 870.
' vertebral, 860.
vesical, 870.
visceral of abdomen, 866.
pelvis, 805, 869
■ of veins, 575, et infrd.
alveolar, 589.
choroid, of brain, 747.
fourth ventricle, 730.
■ third ventricle, 741.
- reflected portion of, 746.
■ hemorrhoidal, 601.
■ intra-spinal, 609.
• lingual, 590.
■ masseteric, 590.
• pampiniform, 598.
' pharyngeal, 591.
• pterygoid, 590.
■ spermatic, 598.
' spinal, deep, 609.
■ longitudinal, 609.
- transverse, 609.
' tonsillar, 333.
' uterine, 602.
' vaginal, 60S.
■ vesico-prostatic, 601.
urethral, 602.
Plica semilunaris, 648.
Pneumo-gastric nerve. See Nene.
Pomum Adami, 424.
Pons Varolii, or cerebelli, 710.
internal structure rf, 718.
Porta, 388.
Portia dura nerve. See Nerve.
mollis nerve. See Nerve.
Prepuce, 454.
of clitoris, 471.
frcenum of, 454.
Process, acromion, 76.
auditory, 44.
basilar, 34.
cochleariform, 44, 673.
- coracoid, 76.
— — — coronoid, of lower jaw, 58.
of ulna, 80.
ensiform, 65.
of fifth metatarsal bone, 104.
' genial, 58.
— gracilis of Raw, 673.
— hamular, of sphenoid bone, 37.
of cochlea. 678.
Process, of helix, 667.
■ malar, 51.
■ mastoid, 43.
■ mental, 58.
■ nasal, 51.
■ odontoid, 26.
' olecranon, 80.
— olivarv, 37.
— orbital, external, 36.
■ internal, 36.
— of palate bone, M.
palatine, 52.
' petrous, 43.
' pyramidal, 54.
' scaphoid, 101.
' styloid, of temporal bone, 4S.
ulna, 80.
■ radius, 81.
fibula, 99.
' vaginal, of temporal bone, 44.
— vermiform, inferior, 716.
■ superior, 716.
' zygomatic, of temporal bone, 43.
of malar bone, 55.
Processes of bones, 9.
ciliary, of choroid coat, 656.
vitreous humour, 661
calcaneal, 101.
clinoid, 37.
pterygoid, 37.
spinous, of ilium, 89.
spinous, of vertebne, 21.
Processus a cerebello ad meduUam, 704.
pontem, 721.
testes, 711.
' a cerebro ad meduUam, 710.
• arciformes, 703.
— gracilis of Raw, 673.
Profunda artery. See Arteries.
vein. See Veins.
Promontory of sacrum, 26, 92.
tympanum, 671.
Pronator muscles. See Musclet,
Protuberances, occipital, 34.
parietal, 42.
Psalterium, 738.
Pterygoid canal, 37.
columns, 126.
fossa, 37.
processes, 37.
P/ery^o-maxillary fissure, 52.
palatine canal, 38, 52.
Pubes, 90.
Pubic arch, 89.
Pudic arteries. See Arteries.
Pulmonary arteries. See Arteries.
veins. See Veins.
Puncta lachrymalia, 647.
Pupil of eye, 657.
Pupillary membrane, 659.
Pyloric valve, 355.
Pylorus, 354.
antrum of, 354.
Pyramid of cerebellum, or of Malacame, 717.
of tympanum, and its canal, 671.
Pyramids, anterior, 703.
decussation of, 706.
sections of, 706.
■ of kidney, 437.
posterior, 704.
sections of, 706.
Quadrati muscles. See Muscles.
Rachis. See Vertebral Column.
Rachidian bulb, proper. See Medulla Oblongata.
bulbs, 697.
veins. See Veins, spinal.
Radial nerve. See Nerve.
Radiating crown of Reil, 744.
Radius, 81.
^ and tibia, lower parts of, compared, 107.
Ra/ni of lower jaw, 57.
Ramus of pubes, 90.
ischium, 91.
Receptaculi arteriie, 525.
Receptaculum chyli, 618.
ganglii petrosi, 843.
Recess of tympanum, 672.
Recessvs sulciformis, 676.
INDEX.
901
Recti muscles. See Muteltt,
Rectum, 376.
columns of, 377.
curves of, 377.
■ internal surface, 378.
muscular coat of, 377.
structure of, 377.
Recurrent arteries. See Arteriet.
nerves. See Nerves.
Renes. See Kidneys.
succenturiati. See Supra-renal Capsules.
Respiratory apparatus, 409.
nerves, in particular. See Nerves.
Restiform bodies, 704.
Rete of Malpigbi, 640.
mucosum, 640.
of tongue, 646.
yasculosum testis, 451.
Reiia mirabilia, 496.
Retina, 660.
artery of, 660.
folds of, 660.
foramen centrale, and limbnt Inteua of, 660.
• margo dentatus, 660.
structure of, 660 (note).
termination of, 660 (note).
Ribs, angles of, 68.
characters of, general, 67.
— special, 68.
false, 67.
movements of, 134.
supernumerary, 32.
true, 67.
torsion of, 67.
tubercle of, 68.
Rima glottidis, 434.
palpebrarum, 646L
Ring, crural, 310.
inguinal, 310.
umbilical, 308.
Rostrum of cochlea, 676.
of corpus callosum, 787.
Rotula, 95.
Rugee, vaginal, 468.
Sac, lachrymal, 652.
Sacculus vestibuli, 680.
or sinus laryngis, 434.
Sacral arteries. See Arteries.
canal, 27.
foramina, 27.
nerves. See Nerves.
vertebne. See Vertebra and Vertebra..
Socro-coccygeal vertebne, 26.
sciatic notch, 92.
vertebral angle, or promontory, 90.
Sacrum, 26.
promontory of, 26.
— — — small comua of, 27.
Saliva, 396.
Salivary glands, 340.
Saphenous nerves. See Nerves,
Satellite arteries. See Arteries.
• — nerves. See Nerves.
Scaphoid bone of carpus, 83.
of tarsus, 101.
' process, 101.
Scapula, 75.
Scapular arteries. See Arteries.
Schindylesis, 114.
Sciatic notch, 89.
spine, 89.
Scrobiculis cordis, 354, 482.
Scrotum, 447.
Second cranial nenre. See Nerve, optic.
Sella turcica, 37.
Semen, 453.
Semi-circular canals, and their ampulle, 677.
membranous, 680.
lines of occipital bone, 33.
lunar bone, 83.
■ ganglion, of fifth nerve, 843.
Seminiferous tubes, 454.
Septa, inter-muscular, 294.
— ^— — ^-^— — ^— — of arm, 315.
of thigh, 306.
Septum crarale, 303.
of dartos, 446.
inter-auricular, 482.
Seytum, inter-ventricular (of brain), 518.
(of heart), 481
• lucidum, 738.
layers of, 738.
ventricle of, 738.
nasal, artery of, 518.
cartilaginous, 642.
osseous, 56, 62.
pectiniforme, 454,
Serrati muscles. See Muscles.
Sesamoid bones, 96.
of hand, 153.
of foot, 177.
of gastrocnemius, 164.
Seventh cranial nerve. See Nerve, Portio Dura, aiui
Portio Mollis.
Sheath of brachial vessels, 316.
- femoral vessels, 310.
- for muscles, 296.
of arm, 316.
thigh, 311.
■ synovial, 178.
■ for tendons, 397.
around carpus, 319.
- - tarsus, 314.
• for vessels, 396.
' structure of, 397.
Shoulder, aponeuroses of, 315.
bones of, 73.
compared -with pelvis, 105.
development of, general, 77.
in general, 77.
Sigmoid cavities, great and small, 80.
- flexure, 371.
- notch, 57.
- valves, 484.
Sinus, or sinuses, aortic, 498.
basilar, 587.
of bones, 1 1 .
of bulb of urethra, 459.
cavernous, 587.
circular, of Ridley, 588.
common, of vestibule, 680.
confluences of, 588.
■ coronary, of heart, 577.
of Ridley, 587.
of dura mater, 583.
ethmoidal, 43.
frontal, 36.
of internal jugular, 583
lateral, or transverse, 584.
of larynx, or sinus of Morgagui, 584-
longitudinal, inferior, 586.
superior, 584.
— maxillary, 52.
-^ of Morgagni, 461.
— occipital, anterior, 587.
posterior, 587.
' ophthalmic, 587.
' petrosal, inferior, 586.
superior, 566.
— prostatic, 459.
— sphenoidal, 40.
— straight, 585.
— transverse, or lateral, 984.
— of urethra, 459.
— uterine, 602.
>- of Valsalva, 498.
— of veins, 575.
— of vena ports, 599.
— venosus (heart), 492.
Sixth cranial nerve. See Nerve.
Skeleton, general view of, 5.
natural, 5.
artificial, 5.
Skin, 629.
appendages of, 635.
characters, external, 629.
Spine, cutis or dermis of, 630.
epidermis of, 632 (note).
follicles, sebaceous, 627.
functions of, 627.
glands, sudoriferous, 632.
lymphatics of, 631.
papilla of, 639.
pigmentum of, 631, 632 (note).
pores of, 632.
rete mucosum, 633 (note).
structure of, 630-634.
true, 630.
^P^2
Skull, 33 See Cranium and Face.
Socio parotidis, 341.
Sole of foot, 102.
Solitary glands. See Glands.
Space, inter-peduncular, 711, 728.
Spaces, inter-costal, 71.
osseous, hand, 84.
foot, 106.
INDEX.
' sub-arachnoid, 688.
Sphenoidal cells, or sinuses, 39.
fissure, 39.
Sphenoid bone, 37.
S;)Aeno-frontal suture, 47.
jugal suture, 47.
maxillary fissure, 39, 5S.
' fossa, 60.
■ occipital bone, 36.
~ suture, 47.
palatine foramen, 54.
parietal suture, 47.
spinous foramen, 39.
temporal fossae, 48.
suture, 47.
Sphincter muscles. See Muscles.
Spinal accessory nerre. See Nerve, accessory.
arteries. See Arteries.
cord, 693.
— ■ arachnoid of, 690.
enlargements of, cervical, lumbar, and oc-
cipital, 697.
■ enveloped in its proper membrane, 697.
extent and situation of, 694.
form, direction, and relations of, 696.
furrows or grooves, 698.
— ^— — ^— membrane proper, or neurilemma of, 697.
pia mater of, 697.
■ sections of, 700.
structure of, internal, 700.
examined by hardening, 702.
■ sections, 700.
water, 701.
substance, gray and white, 702.
• minute structure, 702 (note).
• ventricles of, 702.
See Vertebral Column.
muscles, posterior. See Muscles.
nerves. See Nerves.
veins and plexuses. See Veirts.
Spine, nasal, anterior, 52.
posterior, 54«
of ischium, 89.
of pubes, 89.
of scapula, 75.
sciatic, 89.
or spinal column, 18.
of tibia, 97.
Spinous foramen of sphenoid, 39.
processes of ilium, 89.
of vertebrsE, 19, 31.
Splanchnic nerves. See Nerves.
Splanchnology, 320.
Spleen, 403.
cells of, 405.
coats of, 405.
• corpuscules of, 407.
development of, 407.
• fissure, or hilus, 405.
functions, 408.
lymphatics of, 407.
size of, differences in, 403.
■ structure of, 405.
vessels and nerves, 405, 408.
Spleens, supernumerary, 403.
Splenic artery, 406.
omentum, 405.
veins, 406.
Spongy bones. See Bone*.
Stapes, 674.
Stenonian duct, 341.
Sternum, 64.
Stomach, 352.
alveoli of, 361.
coat of, cellular or fibrous, 357.
mucous, 356.
muscular, 356.
nervous (so called), 356,
- serous, or peritoneal, 357.
culs-de-sac of, 354.
curvatures of, 354.
development of, 361.
extremities of, 354.
Stomach, follicles of, 360.
function, 361.
glands of, 360.
granular appearance of, 397.
' lymphatic system of, 360.
' orifices of, 355.
' papillse or villi, 359.
■ structure of, 356.
' surface of, external, 353.
' internal, 355.
tuberosity of, 355.
tubnli of, 360.
vessels and nerves of, 360.
Structure of tissues and organs. See those organs and
tissues.
Styloid bone, 43.
process of temporal bone, 43.
fibula, 99.
radius, 81.
ulna, 80.
Sui-arachnoid fluid, 690.
uses of, 692.
■ space, cranial, anterior, 688.
' posterior, 686.
spinal, 689 (note).
lingual fossa, 58.
gland, 343.
ducts of, 343.
maxillary fossa, 58.
gland, 342.
duct of, 342.
synovial adipose tissue, 113.
Sulci. See Cerebrum, anfractuositiet of.
Super-ciliary foramen, 36.
ridge, 35.
Superficial petrosal nerves. See Nerves.
Supplementary cavity of shoulder-joint, 139.
of temporo-maxillary joint, 138.
Supro-orbitary foramen, 36, 59.
renal capsules, development of, 445.
structure, 446.
sphenoidal fossa, 37.
spinous fossa, 76.
Sustentaculum tali, 101.
Suture, coronal, or fronto-parietal, 45, 47.
ethmoido-frontal, 48.
ethmo-sphenoidal, 48.
fronto-jugal, 48, 59.
maxillary, 59.
nasal, 59.
sphenoidal, 48.
lambdoidal, or occipito-paxiet^, 40.
maxiUary, 59.
palatine, 60.
petro-occipital, 47.
sphenoidal, 48.
■ sagfittal or bi-parietal, 46.
■ spheno-frontal, 47.
jugal, 47.
parietal, 47.
temporal, 48.
■ squamous, 47.
■ temporo-parietal, 47.
■ transverse or spheno-occipital, 46, 49.
Sutures, 114.
indented, squamous, and harmonic, 114.
cranial, in general, 154.
Sympathetic ganglia in particular. See Ganglia^
nerves. See Nerves.
plexuses, in particular. See Plexuset,
system, in particular. See Ganglia and
Nerves.
Symphyses, characters of, 114.
Sympftysis menti, 57.
pubis, 89, 155.
sacro-iliac, 155.
Synarthroses, 114.
characters, ligaments, and motioni, llSk
Synchondroses, 113.
Syndesmology, 111.
Syneuroses, li3.
Synovia, 112.
Synovial bnrsae, 178.
capsules, 113.
of particular joints. See thov joints
' fringes, 112.
■ in the knee, 164.
■ glands (so-called), 112.
membranes, articular, general characters of,
112.
INDXX.
903
Synovial membranes, bursal, 178, 298.
■ minute structure of, 178.
vaginal, 178, 299.
sheaths for tendons, 178, 298.
Syssarcostf, 114.
Taenia hippocsunpi, 746.
semicircularis, 740, 745.
Tarsus, bones of, 99.
• first row of, 100.
• ^_^____ compared with first row
of carpus, 107.
-^————— second row of, 101.
' compared with second
row of carpus, 107.
■ compared with carpus, 108,
sheaths for tendons on, 313.
Teeth, 177.
arteries of, 182.
bicuspid, 179.
bulbs of, 181.
canine, 180.
cement of, 182.
changes in, after eruption, 190.
■ characters of, general, 179.
— differential, 179.
classification of, 178.
compared with bones, 183 (note).
epidermoid appendage*, 177.
- compound, 182.
- conformation of, external, 179.
— internal, 181.
- cortical portion of, 181.
substance of, proper, 182.
■ crowns of, 179.
- crusta petrosa of, 182, and note.
■ cuspid, 179.
- development of, 183.
different stages of, 184.
■ distinguished from bones, 177.
■ enamel of, 182.
chemical composition of, 183.
development of, 186.
structure of, 183 (note).
■ fangs of, 178.
■ formation of, 186.
Teeth, wisdom, 181.
uses of, 189.
two sets of, 189.
Tela choroidea, 731.
Temporal arteries. See Arteriei.
bone, 42.
fossa, 47.
nerves. See Nerves.
Temporo-pditietaX suture, 47.
Tendo AchiUis, 283.
Tendon of Zinn, 650.
straight of orbicularis palpebranun, 053
Tendons of muscles, 193.
structure of, 299.
Tensor muscles. See Muscles.
Tentorium cerebelU, 684.
Testes (of brain), 712.
Testicles, 446.
coverings of, 446.
excretory duct of, 452.
proper coat of, 449.
structure of, 449.
tubuli of, 450.
tunica albuginea, 449.
erythroides, 447.
propria, 449.
vaginalis, 447,
- vessels and nerves of, iSl.
Testis, coni vasculosi of, 452.
mediastinum, 450.
rete vasculosum, 451.
tubuli, 450.
Testicular artery, 451.
Thalami optic, 742.
structure of, 744.
TAt^Abone 93.
compared with arm bone, lOS.
nird cranial nerve. See Nerve.
Thoracic arteries. See Arteries.
Thorax, aponeuroses of, 300.
- articulations of, 130.
- bones of, 64.
development of, geikersl, 73.
- follicles of, 185.
(Goodsir). 183 (note).
- general idea of, 190.
- incisor, 179
- ivory of, 183. ~
chemical compomtion of, 182.
development of, 165.
structure of, 183 (note).
-milk. See Temporary.
' molar, 180.
great and small, 180.
upper and lower compared, 181.
■ multi-cuspid, 181.
■ nerves of, 181.
• number of, 177.
■ permanent, 177.
decadence of, 190.
development of, 190.
differences of, from temporary, 190.
eruption of", 189.
— ■ follicular stage of, 184.
origin of pulps and sac* of, 164.
papillary stage of, 184.
— saccular stage of, 185.
■ provisional. See Temporary.
■ pulps of, 181.
• origin of, 184.
■ quadri-cuspid, 181.
- sacs of, 186.
origin of, 184.
- simple, 183.
■ structure, general, 181.
— minute, 183.
■ supernumerary, 187.
tartar of, 183.
• temporary, 177.
development of, 183.
differences of, from permanent, 190.
■ eruption of, 183.
follicular stage of, 180.
origin of pulps and sacs of, 184.
papillary stage of, 184.
saccular stage of, 184.
shedding of, 188.
- general description of, 70.
- mechanism of, 132.
- movements of, in general, 134.
one rib of, 132.
7%yro-arytenoid ligaments. See Chords Yoctiei
Thyroid arteries. See Arteries. •
— — veins. See Veins.
Tibia, '
and ulna, upper parts of, compared, 107.
radius, lower parts of, compared, 107.
Tibial arteries. See Arteries,
nerves. See Nerves.
Tissue, adipose, 175.
bony, 12, 13.
cartilaginous, 174.
ceUular, 298.
elastic, 174.
fibro-cartilaginoni, 17i.
cellular, 298.
fibrous, 298.
ligmmentous, 174.
muscular, 198.
nervous, 757.
tendinous, 289.
Toes, articulations of, 174.
bones of, 104.
phalanges of, 104.
Tongue, 332.
bone of, 333.
development of, 336.
dorsum of, 332.
frsnum of, 333.
lymphatics of, 646.
median cartilage of, 333.
mucous membrane of, 646.
muscles of, 333.
extrinsic, 334.
intrinsic, 334.
— nerves of, 646.
— papills of, 333.
— rete mucosum of, 646.
— structure of, 334.
— uses of, 339.
■ vessels, 339.
Ton-tils, 333.
of cerebellum, 718.
Torcular lIeroi)hili, 5S8.
INDEX.
TrabecuJa of corpus cavernosum, 455.
————— spleen, 405.
Trachea, 416.
cervical portion, 416.
glands of, 416.
structure of, 416.
thoracic portion, 416.
- vessels and nerves, 416.
Tractus spiralis foraminulentus, 678.
Tragic fossa, 668.
Tragus, 666.
■ - ligament of, 666.
Transversahs muscles. See Muscles.
Transverse arteries. See Arteries.
muscles. See Muscles.
suture, 46, 47.
veins. See Veins.
7V«njti«rjo-spinalis muscle. See MuseU.
Trapezium, 83.
Trapezoid bone, 83.
ligament, 136.
Triangulares muscles. See Muscles.
Triceps muscles. See Muscles.
Trifacial, or trigeminal nerve. See Nerve.
Trochanteric cavity, or fossa, 95.
Trochanters of femur, 95.
of humerus, 79. '
Trochlea, femoral, 95.
humeral, 79.
of orbit, 651.
Trochlear articulations, characters of, &c., 114.
nerve. See Nerve, pathetic.
Trochoid articulations, characters of, &c., 114.
Tube, Eustachian. See Eustachian Tube.
Fallopian, 463.
T^ber annulare. See Pons Varolii.
cinereuni, 729.
Tubercle, ash-coloured, of Rolando, 703.
lachrymal, 645.
laminated, 717.
of Lower, 488.
Tidtercles of Santorini, in larynx, 424.
in nose, 640.
Tuberrula quadrigemina, or bigemina, 712,
structure of, 714.
T\iberosities, calcaneal, 102.
of femur, 95.
of humerus, 79.
■ of tibia, 97.
Tuberositi/, bicipital, 81.
of ischium, 89.
maxillary, 51.
Tubes of Bellini, 437.
TViu/t of intestine. See Intestine.
recti, of kidney, 437.
of testicle, 452.
seminiferi, 452.
' of stomach, 361.
' uriniferi, convoluted, 437.
straight, 437.
T\ibulus centralis modioli, 679.
Ttmica adnata, 648.
albuginea testis, 449.
conjunctiva, 648.
erythroides, 448.
propria testis, 449.
Ruyschiana, 657.
sclerotica, 654.
vaginalis testis, 448.
vasculosa testis, 449 (note).
Tunics of eye. See Eye.
Turbinated bone, inferior, 56.
- middle, 41,
superior, or ethmoidal, 41.
' sphenoidal, 38.
Ti/mpanic bone, circle, or ring, 45
T)/mpanum, bones in, 674.
circumference of, 672.
lining membrane of, 670.
membrane of, 675.
secondary, 671.
• orifice of, cochlear, 671.
vestibular, 670.
— recess of, 672.
— wall of, external, 669.
internal, 670.
Ulna, 79.
and tibia, upper parts of, compared, 107,
Vmbilicus, 308.
Unciform bone, 83.
eminence, 730.
Unguis, 730.
Urachus, 443.
Ureter, 440.
structure of, 441.
orifices of, 444.
muscles of, 445.
valve of, 444.
Urethra, female, 469,
muscles of, 470,
male, 457.
bulb of, 459.
dilatations, or sinuses, 459.
internal surface, 459.
lacunee, 460.
membranous portion, 459.
muscles of, 457.
prostatic portion of, 457.
spongy portion of, 459.
structure of, 460.
Urinary apparatus, 435,
Uterine veins, 467.
Uterus, 464.
cavity and mouth of, 465,
cervix or neck of, 465,
coat, mucous, 467,
- serous, 467,
• development, 468.
■ follicles of, 466.
• functions of, 468.
■ fundus of, 466.
• glands, tubular, of, 468 (note).
■ gravid, fibres of, 467.
sinuses of, 467.
- vessels and nerves of, 464.
■ ligaments of, broad, 466.
round, 466.
• nerves of, 468.
• structure of, 466.
vessels of, 468.
Utriculus vestibuli, 681.
Uvea, 670.
Uvula, 332.
vesicae, 459.
cerebelli, 715 (note).
Vagina, 468.
bulb of, 469.
— columns and rugse of, 468.
— development of, 469.
— mucous membrane of, 469.
— muscles of, 469.
structure of, 468.
Vaginal process of temporal bone, 44.
Valve of Bauhin, 372.
• Eustachian, 486.
• ileo-ccecal, 372.
colic, 372,
■ mitral, 484,
■ pyloric, 352,
■ of Thebesius, 486.
■ tricuspid, 484.
■ of Vieussens, 711.
' columella of, 71S.
Valves of Kerkringius, 365.
of heart. See Heart.
of intestines. See Intestine
of lymphatics, 617.
semilunar, or sigmoid, 464.
of Tarin, 720.
of veins, 575.
Valvula conniventes, 365.
Vas aberrans, 452.
deferens, 452.
structure, 452.
Vasa afferentia, lymphatic, 614.
brevia, arterial, 509.
venous, 599.
■ efferentia of epididymis, 451.
• lymphatic, 614,
' sudatoria, 634.
• vasorum of arteries, 520,
of veins, 576,
— vorticosa, 587. 665.
Veins, in general, 573,
— anastomoses of, 574,
branches of, 575.
— coats of, 576.
— course of, 574.
INDEX.
905
Veins, deep, 574.
method of description of, 577.
nerves of, 576.
^^— origin of, 574.
plexuses of, 574.
preparation of, 576.
relations of, with arteriei, 575.
satellite, 574.
sinuses of, 575.
structure of, 576.
sub-cutaneous, 574.
superficial, 574.
termination of, 575.
valves of, 575.
varieties of, 575.
vasa vasorum of, 575.
vessels of, 575.
in particular, 577.
abdominal sub-cutaneoiu, 604.
of ala of nose, 588.
alveolar, 589.
angular, 588.
of the arm, superficial, 594.
articular, of knee, 603.
ascending cervical, 580.
lumbar, 606.
auricular anterior, 590.
posterior, 590.
axillary, 593.
azygos, general remarks on, 60)
great, 605.
lesser, 606.
lumbar, 607.
■ basilic, 595.
■ brachial, 597.
• brachio-cephalic, left and right, *; *
■ bronchial, left, 420.
right, 420, 606.
- distribution of, 421.
' buccal, 589.
■ calcaneal, internal, 604.
■ capsular, inferior and middle, 591
■ cardiac, great, 578.
small, 578.
cava, ascending or inferior, 596.
descending or superior, 51H
cephalic, 595.
■ of thumb, 594.
• cerebral, inferior, anterior, 587.
lateral, 584.
' median, 586.
internal, 585.
superior, 585.
■ median, SSC
■ cerebellar, anterior lateral, 58*
inferior lateral, 5Sa
' cervical, ascending, 580.
deep, 580.
■ choroid, 586.
of eye, 658.
• ciliary, 587.
' circumflex, brachial, 598.
femoral, 603.
• iliac, 603.
' colic, left and right, 599.
■ coronary of the heart, anterior, 578.
great, 578.
lips, inferior, 589.
— superior, 589.
stomach, 362.
• of the corpus cavemosum, 601.
striatum. 586.
deep cervical, 580.
— femoral, 603.
• dental, anterior, 589
inferior, 590.
superior, 589
■ diaphragmatic, 601.
' diploic, 585, 591.
• dorsal of the foot, deep, 602.
external, 603.
internal, 603.
' nose, 588.
- penis, 601.
' dorsi-spinal, 608.
■ of the dura mater, 583.
■ at the elbow, 595.
• emulgent, 598.
■ epigastric, deep, 603.
superficial, 60S
Veins, facial, 588.
posterior, 589,
of the falx cerebri, 586.
• femoral, 603.
deep, 603.
• frontal, 587.
■ of Galen in brain, 584.
■ heart, 577.
• gastro-epiploic, 361.
■ gluteal, 601.
• of hand, superficial, 594.
• hemorrhoidal, inferior, 601.
' middle, 601.
--superior, 601.
— head, general remarks on, 592.
— hepatic, 600.
in the liver, 391, 398.
— hypo-gastric, 601.
— iliac, common, 600.
eriemal, 603.
internal, 601.
— ilio-lumbar, 607.
— infra-orbital, 589.
— innominate of Meckel, 579.
■ of Vieussens, 578.
■ inter-costal, 607.
superior, left, 606.
right, 606.
lobular, of liver, 391 (note).
— of intestines, 599.
— intra-lobular, of liver, 393 (note).
spinal, 609.
anterior, longitudinal, 609.
■ transverse, 609.
- lateral, 610.
— posterior, longitudinal, 610.
• transverse, 610.
■jugular, 581.
anterior, 582.
external, 581.
compared with cranial, 610.
— internal, or deep, 583.
posterior, 607.
• laryngeal, inferior, 580.
— superior, 582.
' lingual, 590.
' longitudinal of scull, inferior, 586.
spine. See Intraspinal.
■ of lower extremity, deep, 602.
superficial, 603.
lumbar, or vertebro-lumbar, 5'17.
ascending, 606.
azygos, 607.
' mammary, internal, 580.
masseteric, anterior, 589.
• posterior, 590.
' mastoid, 584, 590.
■ maxillary, external, 588.
' intornal, 589.
— median of the fom, 595.
basilic, 595.
cephalic, 595.
— mediastinal, 580, 60C.
— medullary, 610.
— meningeal, 591.
■ middle, 590.
■ mesaraic, 599.
' mesenteric, inferior or smaL, &(*^
superior or gre. t, 59^
' nasal, 588.
• obturator, 601.
■ occipital, deep, 590.
superficial, 589.
■ (esophageal, 606.
■ omphalo-mesenteric, 599.
■ ophthalmic, 587.
■ orbital, external, 589.
■ ovarian, 598.
• palatine, inferior, 589.
su-perior, 589.
palmar, 593.
' palpebral, external, 589.
' inferior, 588.
• pancreatic, 402.
• parotid, 590.
• of particular organs or tissues.
gans or tissues.
• of pelvis, in female, 602.
male, 601.
of penis, 601.
5Y
906
INDEX.
Veins, pericardiac, 580.
peroneal, 602.
pharyngeal, 591.
phrenic, inferior, 598.
. superior, 580.
plantar, 602.
popliteal, 602.
portal, or vena porta, 597, 599.
branches of origin of, 598.
in the liver, 390.
■ sinus of, 599.
profunda cervicis, 580.
femoris, 603.
— pterygoid, 590.
— pudic, external, 604.
internal, 601.
— pulmonary, 577.
' distribution of, 421.
■ rachidian. See Spinal.
■ radial cutaneous, 595.
deep, 594.
• ranine, 590.
■ renal, 597.
' sacral, lateral, 607.
middle, 607.
' salvatella, 594.
' of Santorini, 585.
' saphenous, external, 605.
' internal, 603.
' second, 604.
' satellite, of lingual nerve, 590.
■ scapular, superior, 582.
posterior, 582.
^— sciatic, 601.
scrotal, 601.
semi-azygos, 606.
short, of stomach, 599.
spermatic, left and right, 598.
spheno-palatine, 589, 591.
spinal, 605.
'— deep. See Intraspinal.
general remarks on, 611.
posterior, deep. See Inira^spinal.
■ superficial, 608.
■ superficial, 60S.
in neck, 608.
— posterior, 608.
■ of spinal cord, 610.
• splenic, 599.
■ distribution of, 406.
■ stylo-mastoid, 590.
sub-clavian, left and right, 593.
mental, 589.
supra-orbital, 588.
renal, inferior and middle, 598
scapular, 581.
sural, 603.
temporal, 589.
deep, 590.
middle, 589.
• superficial, 589.
• temporo-maxillary, 589.
■ofThebesius, 578.
• thymic, 580.
• thyroid, inferior, 580.
middle, 591.
superior, 591.
• tibial, anterior, 602.
-posterior, 602.
tibio-peroneal, 602.
tonsillar, 333.
transverse, cervical, 582.
facial, 590.
humeral, 582.
■ ulnar cutaneous, anterior, 595.
— posterior, 595.
■ deep, 592.
• umbilical, 600.
■ of upper extremity, deep, 592.
superficial, 593.
• uterine, 467, 601, 602.
■ vaginal, 602.
• vasa brevia, 599.
vorticosa, 587.
■ ventricular, cerebral, 586.
■ of vertebra, 610.
■ vertebral, 581.
• vertebro-costal, inferior, 606.
superior, left, 606.
— i right, 605
Veins, vertebro-lumbar, 607.
vesical, female, 602.
male, 601.
vidian, 589.
Velum interpositum, 731, 740.
meduUare, anterior, 713.
posterior, 718 (note).
palati, 331. See Palate, soft.
pendulum palati, 331.
Vena cava inferior, or ascending, 596.
superior, or descending, 578.
Venm comites, 572,
minimse, 508.
Venous plexuses. See Plexuses.
system generally, 572.
Venter ilii, or internal iliac fossa, 88.
Ventricle of Arautius, 704.
of corpus callosum, 737.
fifth, 738.
fourth, 718.
choroid plexuses of, 720.
— fibrous layers of, 719.
-- fossette of, 704.
■ laminated tubercle of, 717
• orifice, inferior, 719.
■ semilunar fold of, 719.
valves of base of, 719.
■ of larynx, 424.
■ lateral, 744.
body of, 744.
comu anterior, 744.
descending, 744.
posterior, 744.
■ of septum lucidum, 738.
•third, 729, 741.
choroid plexuses of, 741.
commissure of, anterior, 742.
posterior, 742.
- soft or gray, 729, 741.
■ floor of, anterior part of, 729.
middle and posterior part of,
729.
• openings of, 742.
Ventricles, cerebral, fluid of, 744.
lining membrane of, 747.
Gall's views regarding, 750.
— — of heart. See Heart.
of spinal cord, 701.
Ventriculus, 352.
succenturiatus, 362.
Vermiform appendix, 373.
process, inferior, 716.
superior, 716,
Vertebra, cervical, first, 23.
second, 24.
seventh, 25.
dentata, 24.
dorsal, first, 25.
eleventh and twelfth, 85.
general description of, 19.
lumbar, fifth, 26.
prominens, 25.
Vertebra, articular processes of, in different regiou, S8»
articulations of. See Articulatiom.
bodies of, in different regions, 20.
cervical, 19.
• characters of, general, 19.
distinctive, 20.
proper, 22.
— coccygeal, 19.
— development of, 31.
— dorsal, 19.
— false, 19.
— foramen of, in different regions, 19.
— internal structure of, 31.
— laminse of, in different regions, 20.
— ligaments of. See Ligaments.
— lumbar, 19.
— notches of, in different regions, 80.
-- number of, 19,
— sacral, 19,
-► sacro-coccygeal, 26.
union of, 32.
spinous processes of, in different regions, SS,
transverse processes of, in diflferent region*,
23.
■true, 19.
Vertebral canal, 30.
column, 19.
articulations of, 115-123.
INDEX.
90*2
Vertebral column, curvatuiea of, 28.
deTelopment of, 32.
' dimensions of, 28.
figure and aspects of, 29.
' moTements of entire, 121-123.
grooves, 20.
ligaments.
See Ligaments.
See Veins.
Vertebro-costaX veins.
Yerumontanum, 461.
Vesica fellea, 394.
urinaria, 440.
Vesicles, Graafian, 461.
Vesicula seminales, 453.
efferent duct of, 454.
structure, 454.
Vestibule of ear, 676.
aqueduct of, 676.
calcareous matter of, 681.
crista of, 676.
■ fovea and recessus sulcifonnis, 676.
membranous, 680.
openings into, 676.
sacculus of, 680.
— ; sinus, common, or utricle of, 680.
Visceral nerves. See iferves.
Vitreous table of cranial bones, 35.
Vocal cords, 426.
Vomer, 57.
Vulva, 470.
development of, 471.
fourchette, 470.
mucous membrane, 471.
parts of, 470.
Wings of sphenoid bone, lesser, 37.
great, 38.
Ingrassius, 37
Womb. See Uterus.
Wormian bones, 50.
Wrist. See Carpus.
Xiphoid cartilage, or appendix, 65.
Zinn, zone of, 655.
Zonula Zinni, 655.
Zygoma, 61.
Zygomatic arch, 61.
bone, 54.
canal, 55.
- fossa, 61.
- process of temporal bone, 42.
malar bone, 55.
THE END.
THE LIBRARY
UNIVERSITY OF CALIFORNIA
San Francisco Medical Center
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