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POSTILLA

PEABODY MUSEUM
YALE UNIVERSITY

NUMBER 140. 3 DEC. 1969

THE ANATOMY AND INTERNAL
ARCHITECTURE OF THE MUS-
CLES OF MASTICATION IN DIDEL-
PHIS MARSUPIALIS

KAREN HIIEMAE
FARISH A. JENKINS, JR.

POSTILLA

Published by the Peabody Museum of Natural History, Yale University

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in exchange for relevant publications of other scientific institutions
anywhere in the world.

THE ANATOMY AND INTERNAL ARCHITECTURE
OF THE MUSCLES OF MASTICATION IN DIDEL-
PHIS MARSUPIALIS

KAREN HIIEMAE

Department of Biology, Yale University

Unit of Anatomy in Relation to Dentistry, Anatomy
Department, Guy’s Hospital Medical School, London

FARISH A. JENKINS, JR.

Department of Anatomy, College of Physicians and Surgeons,
Columbia University

ABSTRACT

The anatomy and internal architecture of the jaw musculature in Didelphis
marsupialis, the American opossum, was studied using a combination of
dissection and thick sectioning techniques. Since the purpose of this investi-
gation was to provide detailed anatomical information as a basis for
subsequent functional studies of jaw activity, all muscles associated with
normal feeding and ancillary oral behaviour are described. These muscles
are the temporal, masseter, pterygoids, digastric, mylohyoid, the remaining
suprahyoid muscles and part of the extrinsic tengue musculature.

In mammals, the jaw muscles medial to the superficial masseter are
classically regarded as the temporal, masseter and zygomatico-mandibular;
however, no structural justification for such a division can be found in
Didelphis. With the exception of the outermost layer of the adductor
mass which is differentiated as a discrete superficial masseter, the temporal
and masseteric part of the adductor musculature is a single unit converging
from an extensive origin on bone and fascia to insert onto the coronoid
process or its associated tendon. This musculature is described as con-
sisting of three parts: an external adductor originating from the temporal
fascia, the zygomatic arch and the masseteric fascia and inserting onto the
external surface of the coronoid process, its tendon and the ramus of the
lower jaw; an internal adductor originating primarily from the wall of
the cranium and inserting onto the inner surface of the coronoid process;
and a posterior adductor, the fibers of which pass anteriorly from the
cranium posterior to the temporo-mandibular joint to insert onto the
posterior border of the coronoid process and the most posterior part of
its tendon. The fibers in each part have a different orientation but are not

POSTILLA 140: 49 p. 3 DECEMBER 1969.

2 POSTILLA

separated into discrete muscles. This division is for descriptive purposes
only and no homologies are implied with the similarly named muscles of
reptiles.

The superficial masseter is a large, fan-shaped muscle extending from
a tendinous origin on the maxilla to the inferior surface of the inflected
mandibular angle where it has a thick, fleshy insertion.

The remainder of the adductor musculature in the opossum consists of
a very small external and a thick internal pterygoid muscle. The former
inserts into the articular capsule of the temporo-mandibular joint as well
as into the condylar neck. The latter has a long, almost linear cranial
Origin extending posteriorly from the palate toward the temporo-mandibular
joint. The fibers pass inferolaterally to insert on the upper surface of the
inflected angle.

The anatomy of the suprahyoid muscles in the opossum is essentially
the same as in eutherian mammals. All the muscles gain part, if not all,
of their attachment to the hyoid through a thick, crescentic tendon formed
by the fusion of the central tendons of both digastrics.

No definite conclusions can be drawn as to the exact function of these
muscles on the anatomical evidence alone. However, their position, internal
architecture and relative size are suggestive: the external and internal
adductors probably have the dual function of suspending the lower jaw
from the cranium and adducting the jaw against resistance. The nearly
horizontal orientation of much of the posterior adductor is evidence that
it can, in addition, act as an effective retractor, with the superficial mas-
seter as its antagonist. In addition to protracting the mandible, the super-
ficial masseter may have a role in producing lateral movement in conjunc-
tion with the pterygoids or the adductors. Finally, the suprahyoid mus-
culature in Didelphis probably functions, as in other mammals, to control
the movement of the hyoid apparatus, the larynx and epiglottis, and the
lower jaw relative to the hyoid. In addition, the mylohyoid, geniohyoid and
genioglossus have an important action in elevating and depressing the
floor of the mouth and the tongue.

MASTICATION MUSCLES IN DIDELPHIS MARSUPIALIS 3

INTRODUCTION

Didelphis marsupialis belongs to an ancient family of marsupials
that first appeared in Late Cretaceous time (Clemens, 1968). An
understanding of both the anatomy and function of its jaw mus-
culature may aid in interpreting this system in Mesozoic mammals
and in reconstructing the basic plan from which the jaw mus-
culature of Eutheria differentiated. The primary purpose of this
paper is to provide a full description of the anatomy and internal
architecture of the jaw musculature in Didelphis as a basis for
later consideration of its functional and evolutionary contexts.

The group of muscles innervated by the fifth cranial nerve, the
trigeminal, and often referred to as “the muscles of mastication’,
constitutes the greater part of the jaw musculature in mammals.
These muscles are the M. temporalis (temporal), the M. mas-
setericus (masseter, normally divided into two parts, the M.
massetericus superficialis or superficial masseter and the M. mas-
setericus profundus or deep masseter), the M. pterygoideus in-
ternus (internal or medial pterygoid), the M. pterygoideus ex-
ternus (external or lateral pterygoid) and two smaller muscles,
the M. mylohyoideus (mylohyoid) and the anterior belly of the
M. digastricus (digastric). For practical purposes the whole
digastric is regarded as a muscle of mastication. All these muscles
act in the initiation and control of the movements of the lower
jaw and so are responsible for most masticatory activity involving
mandibular movement. However, the mechanisms of ingestion,
mastication and deglutition are also dependent on other (“acces-
sory”) muscles of mastication. These can be broadly divided into
two groups. The first includes the M. geniohyoideus (geniohyoid),
the M. genioglossus (genioglossus), the M. buccinatorius (buc-
cinator) and the M. orbicularis oris (orbicularis oris). All these
muscles are attached to one or both jaws. The second group, the
remaining supra- and infrahyoid muscles, have a less direct action
but are particularly important in deglutition because they control
the position of the hyoid complex and its attached soft tissues.
Since this paper is primarily concerned with the functional anatomy
of the jaw musculature, only the muscles of the first group are
included in this account.

Although frequent references to Didelphis are found in the
comparative anatomical literature and particularly where the

4 POSTILLA

phylogeny of jaw musculature is discussed (Dobson, 1882; Adams,
1919; Edgeworth, 1935; Fox, 1964; Barghusen, 1968), the only
available general description of this region in the opossum was
published by Coues in 1872. This account, although comprehen-
sive in its coverage, includes little detail on the attachments and
internal structure of the muscles. More recently, Turnbull (in
press) has prepared an account of the jaw muscles in Didelphis as
a part of a general functional survey of jaw muscles in mammals.

Some explanation of the approach used in this study is necessary
as it differs from that commonly adopted by anatomists. Fiedler
(1952) and Frick (1957) regarded the jaw musculature in mam-
mals as a single unit (M. adductor mandibulae) as did Adams
(1919) and Lubosch (1938) although the latter two excluded
the digastric. However, the musculature is rarely described as such
despite Fiedler’s and Frick’s assertion that any division between
the temporal, masseter and the pterygoids is both arbitrary and
artificial. If Fiedler and Frick could be described as belonging
to the “lumping” school, using Simpson’s (1945) neologism, then
many classical anatomists are “splitters”. For example, the mas-
seter has been described as having as many as four layers (Allen,
1880) one of which is often separately designated as the M.
zygomatico-mandibularis (Parsons, 1899; Fiedler, 1952; Becht,
1954; Schumacher and Rehmer, 1962). The criteria on which
these authors base this division of the masseter into “layers” or
“parts” are rarely stated or justified. The large mass of muscle
tissue extending from the zygomatic arch to the masseteric fossa
on the lateral surface of the coronoid process and ramus of the
mandible often seems to have been divided into a variable number
of elements on the basis of vague fascial planes, intramuscular
neurovascular bundles or on the arbitrary delineation of limits of
origin or insertion. However, the deeper fibers of the masseter
are often continuous with and adherent to those of the temporal
(Allen, 1880; Parsons, 1896; Tullberg, 1899; Toldt, 1905; Adams,
1919; Becht, 1954) making separation difficult. While the recog-
nition of parts within muscles or even within muscle masses may be
valuable in purely anatomical or phylogenetic terms, it does not
facilitate functional studies unless this division reflects changes in
fiber orientation and therefore differences in action. In this respect
description of the gross anatomy and internal architecture of the
jaw musculature of Didelphis marsupialis constitutes a problem.

MASTICATION MUSCLES IN DIDELPHIS MARSUPIALIS 5

In Didelphis a large compact mass of muscle homologous with
the temporal and masseter of other mammals fills the temporal
fossa and ensheathes the coronoid process. This mass has a com-
plex internal architecture but contains no natural divisions to
justify recognition of separately named muscles. Such a muscle is
difficult to describe, particularly in view of its complicated internal
architecture. In this account the mass is called the adductor com-
plex. Description of the internal architecture of the adductor com-
plex is here facilitated by the use of the terms “posterior”,
“internal” and “external adductor”; these terms are intended solely
in reference to parts of the adductor complex which have a
characteristic fiber orientation. No homologies with the similarly
named jaw muscles of reptiles are implied.

The large mass of muscle ensheathing the coronoid process of
the lower jaw and taking origin from the lateral margin, roof and
medial wall of the temporal fossa in mammals has been variously
divided. The simplest and most usual division is into a M. tem-
poralis and a M. massetericus which broadly correspond with the
internal and external adductor musculature of mammal-like reptiles
(Barghusen, 1968). Some authors (Parsons, 1898; Fiedler, 1952;
and Davis, 1964, among others) recognize a third basic element,
the M. zygomatico-mandibularis, described by Becht (1954) as
“an independent member of the group with a history of its own.”
Within this basic division, further elements are sometimes recog-
nized. The temporal is usually divided into deep and superficial
parts separated in the plane of the coronoid process by its ten-
dinous extension into the body of the muscle (Davis, 1964). Becht
(1954) describes a separate anterior temporal muscle in Carnivora
originating in the orbits and varying in size according to the devel-
opment of the postorbital ligament. In addition, a pars supra-
zygomaticus, passing horizontally forward over the zygomatic arch
to insert into the anterior border of the coronoid process,
is recognized by many authors. The divisions of the masseter are
even more complicated. It is variously described as consisting of
two, three or four layers depending on whether or not the author
recognizes a separate M. zygomatico-mandibularis. The most
external of these layers may or may not be regarded as a separate
muscle, the superficial masseter, although its great development
in the Rodentia has made this recognition usual in that group
(Parsons, 1894, 1896). Sicher (1944) and Davis (1964) de-

6 POSTILLA

scribe a distinct superficial masseter in several genera of bears
and the giant panda, and Miller et al. (1964) describe a superficial
layer of the masseter in the dog, as does Allen (1880). Many
authors regard the deeper element as a single deep masseter but if
the zygomatico-mandibular is also recognized, the deeper element
is automatically divided into two layers. According to Becht
(1954), who does distinguish the zygomatico-mandibular, the
deep masseter consists of two layers in Rodentia and three in the
‘“Ruminantia”. Even if the deepest layer is not elevated to the
status of a separate muscle, the deep masseter is still reported
as having two layers in many mammals including the dog (Miller
et al., 1964).

The plethora of terms, not all of which have been detailed
above, used to describe the jaw musculature in mammals is not
applicable to Didelphis where no real division exists. If Didelphis
is a relatively generalized survivor of a Cretaceous marsupial
radiation, then the anatomy of the jaw adductors may substantially
represent the basic arrangement in early mammals. Moreover, if
Adams (1919) is justified in stating that the anatomy of the mus-
cles of mastication in mammals has remained remarkably uniform
overall with only minor adaptive changes, then there are no rea-
sonable grounds for maintaining or adding to the existing complex
nomenclature.

MATERIALS AND METHODS

The anatomy of the jaw musculature of Didelphis marsupialis
was examined by dissection of fresh, unfixed heads as well as heads
fixed in 12% Formal-saline. The internal architecture of the mus-
cles was studied by sectioning frozen heads with a band saw in
either coronal, horizontal or sagittal planes; the sections were then
stored in 10% Formal-saline before examination under a dissect-
ing microscope. This method revealed the precise distribution and
orientation of internal tendons and muscle fibers.

OBSERVATIONS

The greater part of the jaw musculature is confined within the
area of the temporal fossa (Figs. 1, 2, 4, and Appendix 1). This
musculature consists of three major components: the adductor

MASTICATION MUSCLES IN DIDELPHIS MARSUPIALIS 7

complex (broadly corresponding to the temporal and deep mas-
seter of Eutheria), the superficial masseter and the pterygoids.
The temporal and masseteric fascia, an intrinsic although non-
muscular part of the system, are described first in view of their
intimate relation to the adductor musculature.

THE TEMPORAL AND MASSETERIC FASCIA

The superficial surface of the adductor musculature both above
and below the zygomatic arch is covered by a well-defined layer
of fascia. Variable in thickness, it extends over the entire lateral
surface of the head from the nuchal and sagittal crests above to
the lower border of the mandible below. This fascia is divided into
two parts by the zygomatic arch; in mammals the upper is nor-
mally termed the temporal! fascia and the lower, the masseteric
fascia. Although the underlying musculature in Didelphis is not
distinguished by these names in this paper, the terms temporal and
masseteric are retained in reference to the fascia in the comparable
position to that in mammals.

The Temporal Fascia

The temporal fascia extends from the sagittal and nuchal crests
to the zygomatic arch where it fuses with the periosteum. Ante-
riorly the fascia terminates as a thick band of fibrous tissue con-
necting the postorbital processes of the frontal and jugal bones,
thus defining the posterior superficial margin of the orbit. A thin,
inferior extension of this band separates the anterior wall of the
adductor musculature from the orbital tissues. With the excep-
tion of its anterior border, the temporal fascia is attached to bone
at all its margins.

Much of the temporal fascia is very dense, completely aponeu-
rotic and extremely difficult to separate from the underlying muscle
fibers that take origin from it. In its lower part (along the upper
border of the zygomatic arch and over a small area adjacent to
the postorbital process of the frontal) the fascia is an important
origin for adductor muscle fibers. The fact that a substantial pro-
portion of the adductor musculature takes origin from the fascia

8 POSTILLA

is correlated with the relatively large size of the muscle and the
relatively small area available for its attachment. The temporal
fascia is a functional replacement of the original bony roof of
the temporal fenestra but has the advantage of accommodating the
expansion of the musculature accompanying contraction.

The Masseteric Fascia

The temporal fascia continues inferiorly as the masseteric fascia.
Attached above to the periosteum of the outer surface of the
zygomatic arch, it passes inferiorly over the adductor musculature
and over the superficial masseter to merge with the connective
tissue covering the digastric and suprahyoid muscles at the lower
border of the jaw. With the exception of the upper one third, which
overlies the adductor musculature, the fascia is neither thick nor
aponeurotic. Anteriorly its border merges with the periosteum of
the maxilla immediately in front of the tendinous origin of the
superficial masseter and with the fascia surrounding the buccinator.
Below the buccinator, the fascia continues toward the lower
border of the jaw but is less distinct and fades out close to the
anterior free border of the superifical masseter behind and below
the last molar. Posteriorly, in the region of the temporo-man-
dibular joint, the fascia blends with the joint capsule over its
lateral surface.

The greater part of the masseteric fascia represents the thin
layer of connective tissue normally covering muscles. In its thick
and predominantly aponeurotic upper third, the fascia provides
an attachment for the lower external fibers of the adductor mus-
culature and is difficult to separate from them.

THE ADDUCTOR COMPLEX

The adductor complex has a multiple origin from both bone and
fascia which can be divided into medial, lateral, superior and in-
ferior areas relative to the temporal fossa.

The medial origin covers the lateral wall of the cranium (Fig.
4A, C) extending from the posterior margin of the orbit to the
nuchal crest behind, and from the sagittal crest above to the

MASTICATION MUSCLES IN DIDELPHIS MARSUPIALIS 9

alisphenoid and the root of the zygomatic process of the squamosal
below (Appendix II).

The lateral origin of the adductor complex can be divided into
three areas. The largest of these is the entire medial surface of
the zygomatic arch from immediately behind its postorbital process
to the point at which its squamosal element curves medially to
join the cranium. The second area is on the inferior border of
the zygomatic arch and extends from the jugo-maxillary suture to
the posterior tip of the jugal. This area faces slightly outward as
well as downward (Fig. 3). Finally, fibers take origin from the
masseteric fascia as it extends ventrally toward the upper border of
the superficial masseter.

The superior origin is from the lateral half of the temporal fascia
and from a triangular area overlying the postorbital constriction of
the cranium.

The inferior origin is the smallest and most clearly delimited. It
corresponds exactly with the upper surface of the zygomatic
process of the squamosal and with the superior surface of the
bone overlying the temporo-mandibular joint.

The areas of insertion of the adductor complex are on the
coronoid process and mandibular ramus (Fig. 4A, B). The medial
insertion extends downward over the entire inner surface of the
coronoid process as far as a near horizontal line connecting the
alveolus of the last molar, the upper border of the inferior dental
foramen, and the junction of the posterior border of the coronoid
process with the condylar neck. The lateral insertion is only slightly
more extensive. It covers the lateral surface of the coronoid
process and the masseteric fossa on the ramus of the mandible
and continues posteriorly onto the outer, slightly forward-facing
surface of the condylar process below the sigmoid notch (Fig.
4A). In addition, many fibers originating from the posterosuperior
area of the lateral wall of the braincase insert on the aponeurotic
continuation of the coronoid process. This is a tendon of insertion,
the ‘“planum tendineum temporalis” or tendo m. temporalis
(Davis, 1964), extending upward within the body of the muscle
to a point approximately level with the base of the sagittal crest,
and extending posteriorly almost to the nuchal crest. In its shape
this tendinous sheet corresponds to a continuation both posteriorly
and superiorly of the recurved upper portion of the coronoid
process.

10 POSTILLA

The Internal Architecture of the Adductor Complex

The adductor complex can be regarded as consisting of three
basic parts on the basis of fiber orientation: an internal adductor,
an external adductor and a posterior adductor. The first two are
also more or less demarcated by the sites of origin of their fibers;
the delineation of the posterior adductor on this criterion alone is
somewhat arbitrary. However, the internal architecture of the
of the muscle mass as shown in Figures 8, 9 and 10 demonstrates
the basically dissimilar orientation of the posterior fibers as com-
pared with the internal and external adductor groups.

The Internal Adductor

This part broadly corresponds to the deep temporal of other
authors and includes, in its anterior part, a small element of the
superficial temporal. Almost all its fibers pass laterally and in-
feriorly from their origin on the lateral wall of the cranium anterior
to the temporo-mandibular joint (IA, Fig. 4A, C) to insert
either into the medial surface of the internal tendon or onto
the medial surface of the coronoid process (Fig. 4A, B). The
orientation of these fibers (in the parasagittal plane) as they pass
to their insertion is not uniform. Fibers originating anterior to the
coronoid process pass slightly posteriorly, those arising in the
central area pass vertically downward, and those behind the
process pass slightly forward to their insertion. (For a detailed
account see Appendix II). In some but not all specimens, the
organization of the most superior fibers included in the internal
adductor is complicated by a mesh of internal tendon plates (Fig.
8C). Short fibers insert into these plates which then insert into
the internal tendon, giving this part of the muscle a multipennate
structure.

The External Adductor

In many respects the internal architecture of the external
adductor is a mirror image of the fiber pattern of the internal
adductor. The external adductor takes origin from the temporal

MASTICATION MUSCLES IN DIDELPHIS MARSUPIALIS 11

fascia (but not its aponeéurotic area posterosuperior to the orbit),
the zygomatic arch and the masseteric fascia. All external adductor
fibers pass medially and more or less inferiorly to insert onto
the coronoid process or the internal tendon. Those fibers originat-
ing from the temporal fascia are arranged in substantially the
same pattern as those of the internal adductor except that their
course is, in general, shorter and nearer the horizontal. Anteriorly,
fibers of the external and internal adductors form the muscular
posterior wall of the orbit and here the two muscles have about
the same bulk (Figs. 8D, 9A, B). Occasionally small tendon plates
are found in the posterosuperior part of the external adductor
and serve as both origin and insertion for the muscle fibers (Figs.
8C right, 10E).

A gradual change in the orientation of the external adductor oc-
curs between the fibers from superior and inferior limits of the mus-
cle (Fig. 8). The majority of fibers which arise from the temporal
fascia above the zygomatic arch, pass inferomedially with a slight
anterior inclination. The block of fibers attached to the medial
surface of the zygomatic arch pass directly inferomedially to their
insertion into the masseteric fossa (Fig. 8C, D) as do most of
those originating from its inferior border. However, the fibers
attached to the posterior third of the inferior border of the
zygomatic arch pass posteriorly as a thick band to attach to the
condylar process and lower border of the mandible just anterior
to the temporo-mandibular joint (Figs. 6, 8B left). The most
external fibers, originating from the masseteric fascia, also have
a slightly posterior as well.as inferomedial orientation. The external
and internal adductors almost fuse anteriorly where they form
the dense, muscular posterior wall of the orbit (Figs. 9A, B, 10B,
C). Such separation as is anatomically recognizable is provided
by a small tendon extending the coronoid process anteriorly and
fusing, in part, with the postorbital fascial wall.

The architectural differences between the external and internal
adductors relate to the more extensive insertion of the external
adductor and to its two small internal tendons. These tendons
could be used to demarcate a zygomatico-mandibular or two layers
of a deep masseter, although neither extends completely through
the muscle. The larger and the better developed of these tendons
extends inferiorly from its origin at the junction of the medial
and inferior surfaces of the central part of the zygomatic arch

12 POSTILLA

(Fig. 8C). The other tendon is less distinct; it projects laterally
and superiorly from the sharp lower border of the masseteric
fossa below and anterior to the condylar process (Figs. 8C right,
9C). As the superficial fibers of the external adductor insert by
means of this tendon, it separates the outer surface of the adductor
from the deep surface of the superficial masseter in this area.

The Posterior Adductor

The posterior adductor has its main axis in the horizontal
rather than in the vertical plane. Unlike the other parts of the
adductor complex, the posterior area of insertion of the adductor
is much smaller than its origin so that its fibers converge on their
insertion. The bulk of the posterior adductor takes origin from the
posterosuperior area of the temporal fossa and the adjacent parts
of the sagittal and nuchal crests. These fibers pass outward, for-
ward, and either downward or horizontally to converge on the
internal tendon or the posterior border of the coronoid process
(including the sides of its recurved tip). There are two small slips
of this muscle, the suprazygomatic and the fibers originating from
the bony roof of the joint, which pass horizontally forward
(see Appendix II).

As is shown in Figures 8A and 10E, the internal architecture of
the major part of the posterior adductor is, in some specimens,
complicated by a dense mesh of internal tendon and aponeuroses.
The posteroexternal fibers are more clearly organized and pass
predominantly anteroinferiorly to insert into the internal tendon
of the coronoid process. Near the anterior margin of the posterior
adductor, above the joint, the fibers run more evenly anteroin-
feriorly to attach to the tendon and so to the coronoid process
(Fig. 8B right).

The posterior adductor is not divisible into true “superficial”
and “deep” parts. Although the coronoid process and its extension
tendon separate the insertion of the muscle into outer and inner
areas, this division does not completely divide the muscle. The
fiber orientation of this muscle mass suggests that it is a single
functional unit and one basically different from either the internal
or external adductors.

MASTICATION MUSCLES IN DIDELPHIS MARSUPIALIS 13
Discussion

The question arises as to whether a relatively undifferentiated
muscle mass such as the adductor complex in Didelphis can exhibit
the same type and range of movement as a group of recognizably
separate muscles. Anatomical evidence alone cannot provide an
answer but the internal structure of the adductor complex is sug-
gestive. Although there are no distinct anatomical boundaries to
distinguish the internal, external and posterior adductors, the
substantial shift in fiber orientation is indicative of a basic dif-
ference in their effect on contraction.

The adductor musculature functions to maintain the integrity of
the jaw apparatus and to initiate and control movements of the
lower jaw. The first is achieved in conjunction with tendons and
ligaments and particularly of the joint capsule. However, the major
factor in regulating the position of the lower jaw is the activity
of the tonic musculature. The anterior temporal and the deep
masseter were found to suspend the lower jaw from the cranium
in the rat (Hiiemae, 1966) and to be in large part responsible for
the stability of the system. As can be readily seen in the coronal
sections in Figure 8, the external and internal adductors in Didel-
phis also “sling” the mandible between them by ensheathing almost
the entire mandibular ramus and the coronoid process in muscle.

The most important phasic action of the adductor complex is
elevation or adduction of the lower jaw. In addition, since both
internal and external adductors have a substantial transverse com-
ponent, contraction of the external adductor of one side with
relaxation of the other could produce lateral movement. This
action is unlikely to be the main mechanism for producing lateral
jaw movement in Didelphis although such an action may be
synergistic.

The precise function of the posterior adductor is less readily
elucidated on purely anatomical grounds. In many mammals, in-
cluding man, the analogous musculature is regarded as primarily
a mandibular retractor and elevator and in addition as a synergist
in the production of lateral movements (Kawamura, 1964;
Hiiemde, 1966). Mandibular elevation and retraction are very
probably functions of the posterior adductor in Didelphis also.
In addition, the posterior adductor in Didelphis has a small
transverse component which may be capable of pulling the

14 POSTILLA

coronoid process of the same side posteromedially, so moving the
lower jaw toward the contralateral side. Such an action could be
of considerable importance in the production of “Bennett
movements”?, if they occur.

THE SUPERFICIAL MASSETER

Phylogenetically the superficial masseter is derived from the
adductor complex (Barghusen, 1968), and in Didelphis it is
sufficiently differentiated from the external adductor to justify its
recognition as a separate muscle. However, some intermingling
of fibers is found and in many specimens the separation of the
upper part of the deep surface of the superficial muscle from the
outer surface of the adductor is somewhat arbitrary. Nevertheless,
the two are different functional entities in view of their fiber length
and orientation.

The superficial masseter is a fan-shaped, unipennate muscle
(Fig. 5) with an effective length some three times that of the
external adductor and with a long axis near the horizontal. It takes
origin as a thick but slightly flattened tendon from a small
prominence on the maxilla immediately below and in front of the
lower border of the jugo-maxillary suture. This tendon passes
posteroinferiorly and after a short course broadens out into a
triangular aponeurosis. The upper border of the aponeurotic area
more or less coincides with the upper border of the muscle and
is almost straight, passing posteriorly toward the external auditory
meatus and fading out on the superficial surface of the muscle
below the temporo-mandibular joint. The lower border is very
much shorter; it passes more sharply downward, exposing muscle
fibers anterior to it (Fig. 5) and again fades out on the outer sur-
face of the muscle. This aponeurosis serves as the origin for the
superficial masseter which arises from its deep surface and fans
out to wrap around the lower border of the jaw. The muscle inserts
on the expanded lower surface of the jaw and onto the fascial layer
separating the internal pterygoid from the superficial masseter.
A few fibers, however, take origin from the tendon or even from

1 Bennett (1908) stated that the mandibular condyle in man would,
in certain circumstances, be translated laterally (or medially) across the
glenoid fossa. Any such linear movement is known as a Bennett movement.

MASTICATION MUSCLES IN DIDELPHIS MARSUPIALIS 15

the maxilla and pass directly downward to insert on the medial
surface of the lower border of the mandible where they are
closely related to the insertion of the anterior belly of the digastric.
These fibers are clearly seen in Figures 5 and 13. This part of the
muscle overlies, but does not attach to, the convex, smooth area
separating the masseteric fossa and the lower border of the jaw.
It appears that this area functions as a pulley around which the
superficial masseter contracts.

The bulk of the fibers insert into the broad medial expansion
of the lower border of the jaw and the inflected angle (Fig. 4A,
B, D). A few fibers insert into the fascial layer linking the medial
border of the condylar process with the angle and so pass around
the joint immediately external to the lower part of the joint capsule.
A number of the most superficial fibers insert onto the fascial plane
formed by the fusion of the fascia covering the internal pterygoid
and the superficial masseter, which is itself attached to the extreme
medial edge of the angular process. As the muscle approaches its
insertion it becomes extremely thick and gives a rounded appear-
ance to the angular region of the jaw.

Discussion

By virtue of its nearly horizontal orientation the superficial
masseter probably functions as a protractor of the lower jaw and
therefore could act as an antagonist to the posterior adductor.
However, the superficial masseter also wraps around the lower
border of the jaw and the inflected angle. This relationship indi-
cates the possibility that the superficial masseter rotates the jaw
about its long axis (i.e., moves the lower border laterally and
dorsally). Conversely, it is possible that the torque of the super-
ficial masseter is balanced by an opposing torque of the pterygoids.
Experimental data, rather than anatomical evidence, is necessary
to solve this problem.

THE PTERYGOID COMPLEX

The two muscles which form the mammalian pterygoid complex,
the internal pterygoid (M. pterygoideus internus or medialis) and
the external pterygoid (M. pterygoideus externus or lateralis)

16 POSTILLA

have probably had quite different phylogenetic histories. Crompton
(1963) has shown that the former, together with the M. tensor
tympani, is derived from the anterior pterygoid musculature of
reptiles, while the external pterygoid developed from a slip which
separated from the deep surface of the medial part of the reptilian
adductor mass.

The Internal Pterygoid

The internal pterygoid is a thick, short muscle that appears
almost trapezoid in shape when viewed from the interomedial
aspect (Fig. 11). It originates from a long, approximately trian-
gular area on the cranium (Figs. 4A, 8B, C) below the lower
border of the origin of the internal adductor and is separated from
it by the first and second divisions of the trigeminal nerve. The
triangle has its base anteriorly on the palatine bone behind the
sphenopalatine foramen and extends onto the pterygoid and its
wide transverse process (Figs. 4A, 8C left). The remaining area
of origin is much narrower and extends posteriorly from the ptery-
goid process along a ridge of the alisphenoid.

In contrast, the area of insertion is large. The limit of its attach-
ment is along the condylar notch to immediately above the inferior
dental foramen and from there down onto the medial surface of
the lower jaw. The superior limit of its attachment is along a line
extending from the base of the condylar process to immediately
below the inferior dental foramen; from there the line passes down
to the lower border of the ramus where the inflected angle narrows
to become a rounded margin (Fig. 4B). From this line the inser-
tion extends inferiorly and medially over the entire surface of the
angle and the angular process as well as the adjacent area of the
fascia linking the angular and coronoid processes. In addition, some
fibers insert into the common fascial plane shared by the internal
pterygoid and the superficial masseter. It should be noted, how-
ever, that anteriorly the attachments of the two larger muscles
diverge, leaving a small area of bone for the attachment of the
mylohyoid (Fig. 11).

The fibers of the internal pterygoid pass downward, laterally
and posteriorly to their insertion. Those fibers originating on the
palatine or pterygoid process insert near the anterior limit of the

MASTICATION MUSCLES IN DIDELPHIS MARSUPIALIS 17

inflected angle and those originating posteriorly from _ the
alisphenoid insert onto the angular process. In fact the muscle has
a partly fibrous, partly tendinous origin. The thick, free anterior
border of the internal pterygoid is fleshy but posteriorly the deeper
fibers (superficial in Figs. 11 & 12) take origin from an aponeu-
rosis extending over the upper and posterior quarters of the
muscle surface (Fig. 10C). In this area, the origin of the muscle
is never entirely aponeurotic; some fibers take origin from the
alisphenoid but the considerable bulk of the internal pterygoid
can be partly attributed to the additional area for fiber attachment
afforded by the tendon. In addition to this aponeurosis, the body
of the muscle is more or less divided along its length by an internal
tendon of variable extent and position (Figs. 8B, C, 9D, 10C).
As the orientation of the muscle fibers superficial and deep to
the tendon is essentially the same, it seems likely that the tendon
serves as an internal area of origin and insertion rather than
dividing the muscle into two different functional units.

The External Pterygoid

This muscle, barely more than a slip, originates from a small
area on the alisphenoid above and behind the foramen rotundum
(Fig. 4D). It then passes posteriorly, laterally and slightly down-
ward to insert into a small depression on the superomedial surface
of the condylar process and into the capsule of the squamodentary
joint (Figs. 4B, 10B). When dissected from the inferomedial
approach (Fig. 12) it is seen as a thin, rounded fasciculus with a
thin aponeurosis on its (deep) surface. Removal of this deep
belly exposes a second, thinner, fasciculus partly separated from
the first. The larger belly inserts into the condylar process and the
smaller into the joint capsule.

Discussion

While the anatomical relations of the internal pterygoid can be
clearly seen (Figs. 8B, C, 9C, D, E, 10C, E), the functional
relationships of the muscle to the superficial masseter is not clear.
Although the two occupy similar positions in Didelphis and in
eutherian mammals, the inversion of the angular process must alter

18 POSTILLA

their functional relationships. First, the actual length of the super-
ficial masseter in Didelphis is thereby increased and that of part of
the internal pterygoid reduced. Second, part of the attachment of
the internal pterygoid is moved medially. On contraction this mus-
cle will tend to invert the lower border of the mandible (as well
as pull it medially and forward) and is thus capable of inducing a
rotation of the mandible about its long axis. It has already been
suggested that the superficial masseter might be capable of produc-
ing lateral movement of the mandible coupled with a similar type
of rotation. Whether or not this is the case, it remains likely that
the two muscles act as mutual antagonists and also probably as
synergists, i.e., the internal pterygoid of one side acting in concert
with the contralateral superficial masseter.

In Didelphis, the external pterygoid may initiate mandibular
depression by rotating the condyle forward, thus tilting the lower
jaw downward. It also may act with the internal pterygoid in
producing lateral jaw movement. Positive experimental confirma-
tion of these actions is not yet available; however, its very small
size suggests that no powerful action can be produced by its con-
traction and that its role in the generation of mandibular move-
ment is probably supplementary to that of the other muscles.
The position of both internal and external pterygoids in mammals
has led to the suggestion that they both act primarily to produce
lateral movement of the lower jaw. Whether or not this is their
principal function in Didelphis is not known, but the development
of the “marsupial flange” and the consequent alteration of the
position of the internal pterygoid must reflect some functional
difference.

THE SUPRAHYOID MUSCULATURE

There are three important muscles linked to the hyoid apparatus
and functioning as muscles of mastication: the M. digastricus
(digastric), the M. mylohyoideus (mylohyoid) and the M. genio-
hyoideus (geniohyoid). In addition, two muscles of the tongue,
the M. genioglossus (genioglossus) and the M. hyoglossus (hyo-
glossus) can be included in this group as they are attached to the
lower jaw and the hyoid, respectively, and are functionally asso-
ciated with the other accessory muscles,

MASTICATION MUSCLES IN DIDELPHIS MARSUPIALIS 19
The Digastric

As in most, but not all, mammals the digastric in Didelphis is
formed of two fleshy bellies linked by a central tendon. This
tendon, arising as an aponeurosis on the deep surface of the pos-
terior belly, forms part of the “expansion aponeurotique de digas-
trique” described by du Chaine (1914). Du Chaine demonstrated
a tendinous arcade, formed largely by the paired central tendons
of the digastric but with contributions from the mylohyoid and
geniohyoid, which serves as a common attachment for all these
muscles and is itself attached to the hyoid bone. In effect, the
major suprahyoid muscles have a common insertion into the
median expansion of the central tendons of the paired digastric.
This arcade is well developed in Didelphis as a narrow, almost
crescentic band of tendon, convex anteriorly, which crosses the
midline in front of the trachea and arches posteriorly toward the
angles of the lower jaw at each side.

The posterior belly of the digastric in Didelphis has a fleshy
origin from the paraoccipital process and is closely related to the
cranial attachments of the M. styloglossus and M. stylohyoideus.
As it passes anteriorly it lies in a gutter between the fibers of the
superficial masseter laterally and the internal pterygoid dorsome-
dially and in fact overlies the common fascial insertion of these
muscles. At about the level of the angular process the posterior
belly begins to change from an entirely fleshy mass of ovoid cross-
section into a narrow, tendinous band. The fibers of the posterior
belly insert either into the aponeurosis on its deep surface, which
forms the most posterior extension of the central tendon, or
directly into that tendon.

The anterior belly of the digastric has a long origin from the
central tendon and a long linear insertion into the lower jaw
(Fig. 4B, D). It is a thin sheet of muscle, broadly triangular in
shape with its origin and insertion forming the base and one side
of the triangle (Fig. 13), the other side being its long medial free
border. The fibers of the anterior belly run directly anteroposte-
riorly so that the more lateral the fiber, the shorter its course. The
medial fibers pass anteriorly for a considerable distance to attach
to the jaw just below the first molar. The medial edge of the
anterior belly is bound down to the underlying mylohyoid and to
its pair on the other side by a fairly dense layer of fascia.

20 POSTILLA

The digastric in Didelphis is similar to that of most mammals
and in all probability serves the same functions.

The Mylohyoid

The mylohyoid, like the digastric, is a paired muscle but is
fused in the midline to form a single functional unit. It is a thin
sheet arching downward and medially from one half of the lower
jaw, across the midline and up to its attachment on the other.
The bony insertion of this muscle is linear and lies on the medial
aspect of the lower border of the jaw (Fig. 4B, D). The posterior
fibers of the mylohyoid take origin from a narrow area of bone
below the inferior dental foramen and on the medial surface of
the inflected angle between the insertion of the internal pterygoid
and the superficial masseter. At the level of the anterior border
of the internal pterygoid, the attachment of the mylohyoid curves
upward (dorsally) and then passes anteriorly. Over the anterior
half of its length the attachment of the mylohyoid is closely related
to the insertion of the anterior belly of the digastric (Fig. 4B) but
is always separated from it by smooth bone. The anterior limit of
mylohyoid origin is at approximately the level of the first molar.

There is no obvious central raphe in the mylohyoid of Didelphis.
The majority of fibers seem to pass directly across the midline.
Not all, however, have a straight course; those originating near
the inferior dental foramen pass slightly anteriorly as well as
medially. Over the central third of the posterior border, the
mylohyoid is attached to the tendinous arcade and so gains inser-
tion into the hyoid apparatus. The short anterior border of the
mylohyoid is bound down by fascia.

The Geniohyoid

This muscle is the largest of the supra-hyoid group. A powerful,
unipennate muscle, the geniohyoid originates from the inferior lip
of the genial depressison on each half of the lower jaw and im-
mediately behind the symphysis as a tough but flattened tendon.
This passes posteriorly for a short distance and then is continued as
the thick, rounded fleshy belly which inserts into the deep part

MASTICATION MUSCLES IN DIDELPHIS MARSUPIALIS 21

of the tendinous arcade and into the hyoid bone itself. There is
no constriction of the belly of the geniohyoid as it approaches its
insertion. The muscles of the right and left sides are in contact
medially but do not fuse. Throughout its length the belly of
the geniohyoid is covered superficially by the mylohyoid. The
geniohyoid in turn covers the genioglossus (Fig. 14).

Discussion

The digastric, mylohyoid and geniohyoid are regarded as acces-
sory muscles of mastication for two reasons. First, they control
(with the assistance of the remaining supra-and infra-hyoid mus-
cles) the position of the hyoid bone and its associated structures
in relation to the cranium and the lower jaw. In swallowing, the
hyoid moves upward carrying the larynx with it so that the epi-
glottis can effectively seal the airway. On completion of deglutition,
the hyoid apparatus drops or is pulled back. The stylohyoid and
the posterior belly of the digastric suspend the hyoid from the
cranium; the mylohyoid, geniohyoid and the anterior belly of the
digastric control its position in relation to the lower jaw and the
infra-hyoid muscles connect it with the sternum and the scapula.
Second, the anterior belly of the digastric, the mylohyoid and the
geniohyoid can all lift the floor of the mouth and so act as
elevators of the tongue. The mylohyoid, in view of its orientation,
is probably the most effective of the group in this respect; however,
their common tendinous insertion coupled with their close fascial
connections means that all three muscles are likely to be involved.

The Genioglossus

This muscle is one of the larger extrinsic muscles of the tongue
and has an important action in controlling its shape and position.
Taking origin as a fleshy bundle from the genial depression, it
passes posteriorly beneath the geniohyoid as a_ progressively
widening band, fading out in front of the hyoid apparatus. Its most
superficial fibers curve upward to their insertion into the dorsum
of the tongue (Fig. 14). Viewed in sagittal section (Fig. 10D)
the genioglossus can be seen as a broad fan of muscle fibers pas-

22 POSTILLA

sing posterosuperiorly into the body of the tongue from their
origin on the lower jaw. The genioglossus can pull the tongue
bodily forward or can depress its middle or posterior thirds.

The Hyoglossus

Like the genioglossus, the hyoglossus is a large muscle. It
originates as a fleshy mass from the hyoid bone deep to the
insertion of the geniohyoid and then passes forward, laterally and
upward around the posterior part of the genioglossus (Fig. 14)
to insert as a fan of fibers into the lateral part of the body of
the tongue in its posterior two-thirds. This muscle acts to retract
the tongue, or, like the genioglossus, to alter its shape.

Discussion

The tongue is an extremely mobile organ and has an essential
role in ingestion, mastication and deglutition. These two muscles,
together with the styloglossus and its intrinsic musculature, are
responsible for movement of the tongue and for producing the
local changes in shape essential to efficient mastication.

THE FACIAL MUSCULATURE

In addition to the muscles which initiate and control mandibular
movement, there are other smaller muscles which function in
normal feeding activity. The most important of these is the buc-
cinator (M. buccinatorius) which, with the orbicularis oris (M.
orbicularis oris), forms the body of the lips and the cheek.
The opossum, like many mammals, has very short functional lips.
The angle of the mouth is approximately level with the second
molar; at this point the labial sulcus has considerable depth but
this diminishes anteriorly until the sulcus is eliminated just in front
of the third premolar. The mobile length of the lips is therefore
about one third the length of the tooth row; the remainder is
closely tied down to the underlying bone and to the rhinarium.
It seems unnecessary to recognize both a buccinator and orbicularis

MASTICATION MUSCLES IN DIDELPHIS MARSUPIALIS 23

oris in Didelphis. A thick, well-defined muscle homologous with
the buccinator of other mammals is present and this fades out in
the anterior premolar region, leaving only traces of muscle in the
lip surrounding the anterior teeth.

Buccinator

The buccinator in Didelphis is a thick muscle, basically cres-
centic in shape with the “horns” pointing anteriorly and the
“body” lying across the angle of the mouth and forming the
cheek posteriorly (Figs. 5, 6 and 13). The attachments are to
soft tissue, to fascia and to bone. The inner, labial attachment is
anterior to the angle of the mouth, merging with the soft tissue
of the lip and gradually fading out anterior to the second premolar.
The outer border is attached to the maxilla just above the last
premolar and the first and second molars, as the muscle sweeps
round to its midpoint, where the attachment leaves bone (Fig.
4A). The fibers regain a bony attachment parallel to the upper
along the body of the lower jaw below the cheek teeth. This edge
can best be described as “rolled” (Fig. 13). The muscle is at its
thickest near the angle of the mouth where there is a somewhat
tendinous raphe. As it passes upward and forward or downward
and forward, the fibers sweep round and then turn under to reach
their attachment. At the angle of the mouth the muscle is covered
by the fascia overlying the anterior part of the superficial masseter
and its tendon.

Discussion

The function of the buccinator in man and in those mammals
in which this muscle has been examined is one of food control.
Contraction of the buccinator serves to assist the tongue in
repositioning the material on the occlusal surfaces of the cheek
teeth. It is worth noting that Didelphis frequently drops the lower
jaw through an arc of thirty degrees or more. When this occurs
the buccinator is under considerable tension and stands out within
the cheek. Indeed, the full depth of the labial sulcus becomes
clearly visible only in these circumstances as the cheek pulls away
from the teeth.

24 POSTILLA

CONCLUSIONS

The conclusions of this study, in addition to the basic descriptive
text, are as follows:

Previous descriptions of the muscles of mastication in Didelphis
have failed to appreciate the undifferentiated nature of the ad-
ductor musculature within the infratemporal fossa. This muscle
mass has been variously subdivided into separately named muscles.
In fact, there is no evidence for such subdivision, although for
descriptive purposes only the terms “internal”, “external” and
“posterior” adductors are convenient in reference to major parts
of this single muscle muscle mass which have distinctive fiber
orientations.

The anatomy of the superficial masseter in Didelphis is unlike
that of its homologue in the eutherian carnivores. In the latter
group this muscle usually inserts onto the small angular process
of the lower jaw and in some cases into a common raphe with
the internal pterygoid (Becht, 1954). The arrangement in
Didelphis differs due to the medial inflection of the angular process.
The nature of the superior attachment of the superficial masseter
also differs. In the carnivores this muscle takes origin from the
inferolateral surface of the zygomatic arch as a wide fibrous band
and is, therefore, a rectangular muscle with an upward and forward
inclination. In Didelphis the superficial masseter originates from
a narrow tendon attached to a boss on the maxilla just below and
anterior to the zygomatic process of that bone. The muscle then
fans out to become a powerful unipennate fleshy belly with a nearly
horizontal line of action. The superficial masseter is the only part
of the adductor mass to have achieved anatomical and, apparently,
functional separation.

We are cautious about the possible paleobiological significance
of the arrangement of adductor musculature in Didelphis. We are
aware, on the one hand, that Didelphis is one of the most general-
ized of living marsupials; its dentition is basically similar to that of
Late Cretaceous marsupials, although Clemens (1968) has demon-
strated certain distinct dental differences. On the other hand, there
is as yet no direct evidence that Didelphis retains the basic ad-
ductor pattern of Late Cretaceous marsupials. With reservations,
therefore, some speculative remarks may be made. The basic pat-
tern of mammalian jaw musculature was established in advanced

MASTICATION MUSCLES IN DIDELPHIS MARSUPIALIS 25

cynodonts (Crompton, 1963; Barghusen, 1968). At this phy-
logenetic stage, the adductor musculature had attained a position
and relative size comparable with the temporal and masseter of
mammals. Assuming that the adductor muscle pattern of Didelphis
retains the basic pattern of Late Cretaceous marsupials, it would
appear that an advanced degree of morphological differentiation
of the adductors was a comparatively late event in therian phy-
logeny. However, fiber groupings characterized by distinct orienta-
tion are present in Didelphis and this condition probably simulates
the first stage in the development of the differentiated jaw muscles
of eutherians.

ACKNOWLEDGMENTS

We appreciate the contributions of others to the preparation of
this paper. Our thanks are due in particular to Professors H. J. J.
Blackwood and A. W. Crompton for reading the manuscript and
for much helpful discussion; to Dr. W. Turnbull of the Field
Museum, Chicago, for the loan of dissection notes and for part
of the text of a forthcoming paper; to Messrs. R. Bauer, R. Morrill
and D. Allen for the patient trapping and subsequent care of our
colony of Didelphis; to Miss Margaret Newton and Miss Rosina
Miles for assistance in the preparation of the manuscript and lastly
to Miss Jennifer Middleton for Figures 1-7 and 11-14.

This work has been made possible by N.I.H. grant No. 1 RO1
DEO 02648-01 DEN.

APPENDIX I

THE ANATOMY OF THE DIDELPHIS SKULL AS RELATED
TO THE JAW MUSCULATURE

As can be seen in Figures 1, 2 and 3, the actual cranium of
Didelphis is small both absolutely, reflecting the limited cerebral
development of the opossum, and relatively when compared with
the snout. The extent to which the facial bones dominate the skull
is partly attributable to the long tooth row which, in the figured
specimen, approximates 69% of the total skull length. In order to
accommodate the molar series, the maxilla has an extensive poste-

26 POSTILLA

rior extension which completes the floor of the orbit (Figs. 1, 2).
The corresponding length of the mandibular tooth row coupled
with the posterolateral position of the jaw joint (Figs. 2, 3) result
in a relatively long lower jaw. With such a small cranium and a
large lower jaw, the available area for bony origin of the adductor
musculature is disproportionately small. However, the development
of nuchal and sagittal crests as well as the deep zygomatic arch
compensate for the limited surface area of the cranium.

The greater part of the adductor musculature in Didelphis takes
origin from the bony surfaces limiting the temporal fossa. In the
absence of a postorbital bar the fossa is delimited anteriorly by the
postorbital processes of the frontal and the jugal above (Fig. 2)
and by the posterior extension of the maxilla and the alveolus
of the third molar below (Figs. 1, 3). The fossae of both sides
share a common superior border, the sagittal crest. This is formed
by the frontals, the parietals and the fused postparietals and supra-
occipitals. The latter also contributes, with the squamosal, to the
nuchal crest which delimits the temporal fossa posteriorly. Strictly
speaking, the fossa has no inferior border but the origin of the
adductor musculature extends downward to include the thin
triangular pterygoid processes and the lower limit of the wing of
the alisphenoid. Posteriorly, the inferior border of the temporal
fossa is formed by the squamosal root of the zygomatic arch which
continues anteriorly to form the lateral wall of the fossa.

The zygomatic arch of Didelphis is a very deep and robust bar
of bone, formed by the zygomatic process of the squmosal, the
jugal and the zygomatic process of the maxilla. The latter makes
a very limited contribution to the outer, lateral surface of the arch
anteriorly but on its medial surface extends backward as far as the
postorbital process and forms the lateral wall of the orbit. The
zygomatic arch of Didelphis not only curves outward and back-
ward from its anterior root but also outward and downward. The
extreme lateral margin of the skull is formed by the inferior rather
than the superior border of the arch (Figs. 1, 2). The width of
the temporal fossa is greatest at the level of the postorbital con-
striction of the cranium and the pterygoid processes (Figs. 1,
3). The widening of the fossa is also more or less coincident
with the anterior border of the coronoid process of the lower jaw.
Posteriorly, the zygomatic arch changes orientation as it curves
medially toward the cranium. At the level of the squamoso-

MASTICATION MUSCLES IN DIDELPHIS MARSUPIALIS 27

alisphenoidal suture the lower border curves medially through a
right angle to become the anterior border of the squamosal root
of the zygomatic arch. The superior margin curves more gently
medially to merge with the body of the squamosal (Fig. 1) and to
continue toward the nuchal crest as a thick ridge of bone above
the external auditory meatus (Fig. 2). This “twisting” of the arch
brings the originally external surface into a downward-facing
position as the glenoid fossa. The internal surface forms an up-
ward and forward-facing bony floor to the posterior part of the
temporal fossa (Fig. 1).

The oval articular fossa is largely formed by the squamosal but
with a small contribution from the jugal near its anterolateral
margin. Its long axis is transverse to that of the skull. In its short
axis the fossa is shallowly concave. A robust postglenoid process
extends downward and slightly posteriorly (Fig. 2).

In its general form the mandible of Didelphis closely resembles
that of some eutherian carnivores. There are large coronoid and
angular processes; the latter is inflected medially, a marsupial
specialization. The lower border of the mandibular ramus widens
posteriorly, giving it an elongated triangular shape (Fig. 3) and
providing a large area for muscle attachment. Above its expanded
lower border the mandibular ramus is excavated on its lateral
surface by a well-developed masseteric fossa and on its inner
medial surface by a pterygoid fossa. The former extends from the
lower border of the lateral surface of the ramus to the apex of
the coronoid process and posteriorly to the condylar process. The
pterygoid fossa, much smaller, extends from the medial margin
of the inflected angle to the lingula. The lateral margin of the
lower border of the mandibular is smoothly curved from the level
of the second molar to below the middle of the masseteric fossa
(Figs. 2, 3). Posteriorly, this smoothly curved margin merges
with the inferior surface of the inflected angle. The masseteric
fossa is closely related anteriorly to the thickened border of the
coronoid process which arises inferolateral to the first molar
and extends upward for about two-thirds of the length of the
process to fade out at the junction of its anterior and superior
borders. The posterior border of the fossa which forms the sigmoid
notch with the short condylar process is very much thinner.

In lateral view (Fig. 2), the stout condylar process is con-
tinuous with the lower border of the mandible. The short condylar

28 POSTILLA

neck expands into the transversely orientated condyle which is
more sharply convex in its anteroposterior (short) axis than in
its transverse (long) axis. Much of the articular surface is flat.
The articular condyle is on a level slightly above the occlusal plane.

In the articulated skull the lower jaw bisects the temporal fossa
at an angle of approximately 15° to the long axis of the skull
(Fig. 1). The coronoid process, which in lateral view (Fig. 2)
projects above the upper border of the zygomatic arch, lies almost
equidistant from the arch and the outer wall of the braincase when
the mandible is in centric position.

APPENDIX II

THE ANATOMY AND INTERNAL ARCHITECTURE
OF THE ADDUCTOR COMPLEX

The adductor complex has four main areas of origin: medial,
lateral, superior and inferior. The first is the most extensive.
Anteriorly, the medial origin is limited by a slight ridge on the
frontal bone which passes posteroinferiorly to the fronto-alisphen-
oidal suture above the ethmoidal foramen. Passing above the optic-
orbital fissure and the anterior alar foramen, the ridge continues
(although less well-marked) posteriorly as the inferior margin
across the wing of the alisphenoid. The ridge terminates at the
anterior root of the zygomatic process of the squamosal. Like the
anterior and anteroinferior margins, the superior and posterior
limits of the medial origin are continous. The superior extends
from the postorbital process of the frontal as a slightly marked
ridge curving medially towards the midline (Figs. 1, 4C). It then
passes along the top of the sagittal crest to the junction of the
sagittal and nuchal crests. The posterior border corresponds with
the tip of the nuchal crest until its junction with the posterior root
of the zygomatic process. The margin then runs anteriorly along
the dorsal surface of the zygomatic process to the alisphenoid
where it joins the slight ridge marking the inferior border of the
area of attachment. The lateral wall of the braincase enclosed by
these margins is concave anteriorly and convex posteriorly
(Bigs:<1, 2).

MASTICATION MUSCLES IN DIDELPHIS MARSUPIALIS 29

The Internal Architecture of the Adductor Complex

THE INTERNAL ADDUCTOR. The internal adductor is of fairly simple
structure. As can be seen from Figures 8, 9 and 10, its fibers pass
laterally and more or less inferiorly to their insertion on the medial
surface of the coronoid process. However, the orientation of these
fibers in the parasagittal plane is not uniform. Those taking origin
from the anterior part of the medial wall of the fossa and from the
small fascial area above pass inferiorly, laterally and _ slightly
posteriorly. They insert either into a small tendinous area in front
of and continuous with the anterior border of the coronoid process
(Fig. 9B) or onto the anterior border of the process itself
(Figs. 8D, 9C, D). Fibers originating from the medial wall of
the fossa at the level of the postorbital constriction of the cranium
pass almost directly laterally and inferiorly (Fig. 8C left) to insert
on the entire medial surface of the coronoid process (Fig. 4B).
The most posterior fibers taking origin from the wall of the
cranium just anterior to the squamo-dentary joint pass laterally,
inferiorly and anteriorly to their insertion on the posterior part of
the medial surface of the coronoid process (Figs. 8B left, 10B).
The course of fibers originating from the medial wall of the fossa
above its maximum convexity is slightly different. In general, they
are all orientated anteriorly and pass more horizontally and
laterally than do the deeper and inferior fibers (Figs. 8B left, C).
They insert into either the apex of the coronoid process or into the
internal tendon. Anteriorly, the fibers originating from the dorsum
of the cranium just behind the postorbital process of the frontal
form the upper anterior part of the muscular postorbital wall and
have a complicated course. Instead of inserting into the medial
surface of the coronoid process near its anterior edge, they pass
over this edge and insert onto the lateral surface of the process.

THE EXTERNAL ADDUCTOR. The fibers of the external adductor
pass more or less directly inferiorly and medially to their insertion.
However, there is a variable degree of antero- or posteromedial
inclination depending upon the site of fiber origin. Anteriorly, for
example, fibers originating from the fascia near the upper border
of the zygomatic arch pass slightly posteriorly as well as medially
before inserting into the central part of the masseteric fossa
(Fig. 9B). As the fibers elongate towards the anterior and inferior

30 POSTILLA

parts of the muscle mass, their direction changes from the near
horizontal to the near vertical (Figs. 8, 9). The part of the
adductor originating from the medial surface of the zygomatic arch
has no significant change in fiber orientation; it inserts into the
inferior part of the masseteric fossa. The fibers passing to the ante-
rior of the coronoid process are almost vertical (Fig. 8D left).
There is, however, a more marked change in orientation of the
fibers which take origin from the inferior border of the zygomatic
arch. Just in front of the squamo-dentary joint, a band of fibers
passes inferomedially to link the inferior border of the zygomatic
arch and the concave posteroinferior area of the masseteric fossa
(Fig. 8B left, C right). This band is continued anteriorly as fibers
originating from the expanded lower border of the zygomatic arch
(Fig. 8D left). These gradually fade out as the lower border of
the mandible narrows anteriorly and curves inferiorly, thus increas-
ing the vertical distance between the arch and the lower border
of the masseteric fossa. In general, the outermost layers of fibers,
which originate from the masseteric fascia below the arch, parallel
the deeper group but are inclined slightly posteriorly (Fig. 10A).

THE POSTERIOR ADDUCTOR. The internal architecture of the poste-
rior adductor is basically simple, as can be seen from Figures 8,
9 and 10. Two small blocks of muscle are worth further comment.

The suprazygomatic slip is a thin band of fibers passing almost
horizcntally on the external surface of the adductor immediately
above the posterior root of the zygomatic arch. They insert into
the posterior border of the coronoid process immediately below
its apex. Removal of this slip exposes fibers of the posterior
adductor passing horizontally and in some cases even upwards to
insert into the internal tendon.

The inferior limit of the origin of the posterior adductor, the
“roof” of the squamo-dentary joint, provides attachment for a
thick band of fibers without internal tendons. Enclosed on three
sides by bone (Fig. 8A right), these fibers pass horizontally
forward to insert onto both the medial and lateral surfaces of the
posterior part of the coronoid process as well as its posterior
border below the recurved apex. This small block of muscle is
closely related to the external pterygoid which passes supero-
laterally to its insertion on the condylar neck immediately below.

MASTICATION MUSCLES IN DIDELPHIS MARSUPIALIS 31

LITERATURE CITED

Adams, L. A. 1919. A memoir on the phylogeny of the jaw muscles in
recent and fossil vertebrates. Ann. N. Y. Acad. Sci. 28: 51-166.

Allen, H. 1880. On the temporal and masseter muscles of mammals. Proc.
Acad. Nat. Sci. Philad. 1880: 385-396.

Barghusen, H. R. 1968. The lower jaw of cynodonts (Reptilia, Therapsida)
and the evolutionary origin of mammal-like adductor musculature.
Postilla 116: 1-49.

Becht, G. 1954. Comparative biologic-anatomical researches on mastica-
tion in some mammals. I and II. Proc. K. Ned. Akad. Wet., Series C,
56: 508-527.

Bennett, N. G. 1908. A contribution to the study of movements of the
mandible. Proc. R. Soc. Med. 1: 79-85.

Clemens, W. A. 1968. Origin and early evolution of marsupials. Evolution
22: 1-18.

Coues, E. 1872. The osteology and myology of Didelphys virginiana.
Mem. Boston Soc. Nat. Hist. 2: 41-154.

Crompton, A. W. 1963. On the lower jaw of Diarthrognathus and the
origin of the mammalian lower jaw. Proc. Zool. Soc. Lond. 140:
697-753.

Davis, D. D. 1964. The giant panda: a morphological study of evolutionary
mechanisms. Fieldiana, Zool. 3: 1-339.

Dobson, G. E. 1882. On the digastric muscle, its modifications and func-
tions. Trans. Linn. Soc. Lond., (Zool.), 2nd Ser., 2: 259-267.

du Chaine, J. 1914. Le digastrique (abaisseur de la mandible des mam-
miféres). J. Anat. Physiol., Paris, 50: 248-319, 393-417,

Edgeworth, F. H. 1935. The cranial muscles of vertebrates. Cambridge
University Press, Cambridge. 493 p.

Fiedler, W. 1952. Zur Gliederung der Kaumuskulatur bei den Saugetieren.
Verhandl. Anat. Ges. 50: 354-361.

Fox, R. C. 1964. The adductor muscles of the jaw in some primitive
reptiles. U. Kans. Publs. Mus. Nat. Hist. 15: 657-680.

Frick, H. 1957. Uber die Trigeminusmuskulatur und die tiefe Facial-
muskulatur von Orycteropus aethiopicus. Z. Anat. Entwgesch. 116:
202-217.

Hiiemae, K. M. 1966. The development, structure and function of the
mandibular joint in the rat. Ph. D. Thesis, unpubl., Univ. Lond.

Kawamura, Y. 1964. Recent concepts of the physiology of mastication,
p. 77-109. In P. H. Staple [ed.], Advances in Oral Biology. Vol. I.
Academic Press, New York.

Lubosch, W. 1938. Muskeln des Kopfes: Viscerale Muskulatur (Fort-
setzung). D. Saugetiere, p. 1065-1105. /n Bolk, Goppert, Kallius and
Lubosch [eds.], Handbuch der vergleichenden Anatomie der Wir-
beltiere 5. Urban and Schwarzenberg, Berlin and Vienna.

Miller, M. E., G. C. Christensen and H. E. Evans. 1964. Anatomy of
the dog. W. B. Saunders Co., Phil. 941 p.

Parsons, F. G. 1892. Some points on the myology of rodents. J. Anat.
Physiol., Lond., 26: x-xiii.

1896. Myology of rodents. Part II. Proc. Zool. Soc. Lond.
1896: 159-192.

1898. The muscles of mammals with special relation to
human myology. J. Anat. Physiol., Lond., 32: 428-450.

32 POSTILLA

1899. The joints of mammals compared with those of man.
J. Anat. Physiol., Lond., 34: 41-68.

Schumacher, G. H. and H. Rehmer. 1962. Uber einege Unterschiede am
Kauapparat bei Lagomorphen und Rodentia. Anat. Anz. 111: 103-122.

Scott, J. M. 1955. Growth changes in the glenoid fossa. Dent. Practnr.
Dent. Rec. 6: 117-120.

Sicher, H. 1944. Masticatory apparatus in the giant panda and the bears.
Field Mus. Nat. Hist., Zool. Ser., 29: 61-73.

Simpson, G. G. 1945. The principles of classification and a classification
of mammals. Bull. Am. Mus. Nat. Hist. 85: 1-350.

Toldt, C. 1904, 1905. Der Winkelfortsatz der Unterkiefer beim Menschen
und bei Sdaugetieren und die Beziehungen der Kaumuskulatur zu
demselben. Sber. Acad. Wiss. Wein., Abt. 2, 113: 43-108; Abt. 3,
114: 315-376.

Tullberg, T. 1899. Uber das System der Nagethiere: eine phylogenetische
Studie. Nova Acta R. Soc. Scient. Upsal., Ser. 3, 18: 1-514.

Turnbull, W. D. [in press]. The mammalian masticatory apparatus.
Fieldiana, Geol.

MASTICATION MUSCLES IN DIDELPHIS MARSUPIALIS 33

FIGURE SECTION
The following abbreviations refer to Figures 4, 8, 9 and 10.

MUSCLES

External adductor, EA; Internal adductor, IA; Posterior adductor,
PA; Superficial masseter, SM; Internal pterygoid, IP; External
pterygoid, EP; Digastric, posterior belly, Dpb; anterior belly, Dab;
Mylohyoid, Mh; Geniohyoid, Gh; Genioglossus, Gg; Hyoglossus,
Hh; Buccinator, B.

FASCIA AND TENDONS
Temporal fascia, Tf; Masseteric fascia, Mf; Adductor tendon, At;
Internal tendon, It (of either external adductor or internal ptery-
goid as shown); Tendon of superficial masseter, Smt.

Figures 8, 9 and 10

Serial coronal (Ca-p), horizontal (Ha-c), and sagittal (Sa-r)
sections of the heads of adult Didelphis to show the internal archi-
tecture of the masticatory musculature at various levels. The orien-
tation and labeling of each section is shown in the key diagram.

_ Gp Cc Cp Ca
The following symbols are used:

Be Bone
Thick fascia
Internal tendons
Fibers cut transversely
Fibers cut longitudinally

@

= Fibers cut obliquely, the “head” rep-
resents the cut surface, the “tail”
shows the direction and approximate
angle of the fiber.

34 POSTILLA

FIG. 1. Didelphis marsupialis: dorsal view of the articulated skull and
lower jaw. Young adult, actual size.

FIG. 2. Didelphis marsupialis: lateral view of articulated skull and lower
jaw. Actual size.

MASTICATION MUSCLES IN DIDELPHIS MARSUPIALIS 35

FIG. 3. Didelphis marsupialis: inferolateral view of articulated skull and
lower jaw to show the position of the squamo-dentary joint and the
inflected angle of the lower jaw. Actual size.

36 POSTILLA

FIG. 4. The bony attachments of the masticatory muscles in Didelphis:
A) lateral view of the skull and lower jaw; B) medial view of the lower
jaw; C) dorsal view of the articulated skull and jaw; D) inferolateral view
of the articulated skull and lower jaw.

MASTICATION MUSCLES IN DIDELPHIS MARSUPIALIS 37

Bey (i
Gh

FIG. 4. cont.

38 POSTILLA

External adductor

(Freed from fascial
attachment)

Internal adductor

tendon
yes Posterior adductor
A« Zygomatic musculature
y Se O ay, if . —ES Cut surface of Ext. adc
, ane ies 2 SSNS External adductor
——— Buccinator

ay) \ CWI
He S wiht
(ZY j fl" Deep surface

Yj . .
G N Superficial masseter

FIG. 5. Lateral view of a Didelphis head after removal of the skin and
dermal musculature to expose the temporal and masseteric fascia, the
underlying adductors and the superficial masseter.

Posterior adductor

External adductor

Superficial masseter

FIG. 6. Lateral view of a dissected head of Didelphis after reflection of the
external adductor, exposing the internal tendon continuous with the
coronoid process. Reflection of the superficial masseter shows the position
of the lower part of the external adductor.

MASTICATION MUSCLES IN DIDELPHIS MARSUPIALIS 39

TY oo _ Internal adductor
| —_—-
\ Internal adductor
Mt “= Wy tendon
SS ; ae A :

a OS iinnG. =~ =
; Spe nad wh SE =) yy
f “VN ebay =

Coronoid process
(zygomatic arch
removed)

External adductor
(reflected)

Superficial masseter

AF SADDLE

FIG. 7. Lateral view of the head of a dissected specimen of Didelphis
to show the relationships of the coronoid process, the internal tendon
and the adductors.

40 POSTILLA

FIG. 8. Coronal sections of a head of Didelphis. The posterior surface of
each section is figured. The left hand side of each section is in a plane
slightly anterior to the right hand side. For position of sections, see p. 33.

4l

MASTICATION MUSCLES IN DIDELPHIS MARSUPIALIS

% ye YS SS

NP)

SS

a

—-- a
=>

FIG. 8. cont.

42 POSTILLA

e
6° 6g
re b é

6

eer, 2
PESISEGE 7 ey
Serta CLES YO’ py

Us
WS
Cane b 3B

WY wr WY (LQ

\\ my Vip (ho ay {\

Cc

FIG. 9. Horizontal sections of a head of Didelphis viewed from _ below.
The upper half of each section is in a plane slightly ventral to the lower.
For position of sections, see p. 33.

MASTICATION MUSCLES IN DIDELPHIS MARSUPIALIS

43

FIG. 10. Sagittal sections of a head of Didelphis. Sections A-D show the
outer (lateral) surface of each section, section E the inner (medial) surface
of a section from the other side of the head. For position of sections,
ee) jo SiS

MASTICATION MUSCLES IN DIDELPHIS MARSUPIALIS 45

FIG. 10. cont.

46 POSTILLA

2)

a
3B 5 S
(e) —
~ 6 ep)
tay ex fe)
O Py
~ Sas oO
= ao, "©

=
x e
S iS
= 0
cc) wn
= © .e) 2 2
= dD) £
o. ~ 5
o oe eee
= = Ss. oe fe)
rot e fe) oe 8
e) re (oO) oS — =
wn Ct) = te} ec 2
®o _— z=) o
re} ro)
O £ =o Ors

FIG. 11. Ventral view of a head of Didelphis after removal of the supra-
hyoid musculature to show the relationships of the superficial masseter,
the internal pterygoid, and the mylohyoid.

47

Oesophagus

( hemisectioned )
Genioglossus
Hard palate

ae
fe}
oD
~
_
o
ous
a
=
Og
c
55
oro
e0
= 3
=O = oS
23 tae
= o> ~ wo
~ —0 on
ocr oD wn
—_- -—@ (= Qo
Ary Te x+_ SG 5 5
Se2 wa <2 WE
Do
(o} FS
ae 16
ay?
2 5
o
ats
Qe

a2

°

D

~

=

a) o

> _

= Qa

i a

Gaz fe}

<5 =
_

eats 2

eee c

FIG. 12. Ventral views of the head after removal of: a) the posterosuper-
ficial part of the internal pterygoid to show its relation to the inferior
dental nerve, and b) after removal of the greater part of the internal to
expose the external pterygoid.

48 POSTILLA

o

B32
ao. Seto
Su orc aS Te)
ae 2h =o ig a
te Ae (). = OT ~ te
S> SS 3-5 = re)
mn ao} ye ‘Ee
oe Meee) 9 Es o
O35 Ae, <e(a) SS (OSS

AN LAAT

wie ate 3
Shy IRL 4
CLES EDI 3

ss
ce) ®
> > = Ws
eee So ome
_ = ie} ie} a
ai =o c¥ S E>
: o ‘oO re)
2D a5 oo jo 2
o= = x 0 =) ~
a0 WE LOO ca) INS

FIG. 13. Ventral view of the head. after removal of the skin and superficial
fascia. to show the relationships of the suprahyoid muscles.

TA MippLeTON

MASTICATION MUSCLES IN DIDELPHIS MARSUPIALIS 49

5
_
® fe)
G

O
G =
Se re)
50} (eo)
=a) <6 se ae
Ors -< ee ra)
ORE oS oe >
— Oo oO a+ 2S
= ONO ” fe)
Ce roMOde 430 c
a5 OG) Fe fo) ©
=i, os & oo
= ag} —¢{e) (e)

SSSsasje

——=>

(6) o —

SS ee

= =

wn oS “s

oj AG

D 3S =

a § :

we € 5

) £ wv

Seo) eee ae

= oOo 5 no WS fe m)

@ Se ho cio Ee

ao <= re) > ec fe)
| — es (oy = fo)

: D

_ ie} me) qo) Wie ye

7) L ie) (2 foLc

ro S< > me SP cd)

a = ac = es rye (@)

FIG. 14. Ventral view of the head, after removal of parts of the digastric
and mylohyoid, to show the arrangement of the hyoid and tongue
musculature.

TAM

REVIEW

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