X.Jb^JI'J.

REGENERATION

Columtta ^ni&CTsitg Biological Series.

EDITED BY
HENRY FAIRFIELD OSBORN

AND

EDMUND B. WILSON.

1. FROM THE GREEKS TO DARWIN.

By Henry Fairfield Osborn, Sc.D. Princeton.

2. AMPHIOXUS AND THE ANCESTRY OF THE VERTEBRATES.

By Arthur Willey, B.Sc. London Univ.

3. FISHES, LIVING AND FOSSIL. An Introductory Study.

By Bashford Dean, Ph.D. Columbia.

4. THE CELL IN DEVELOPMENT AND INHERITANCE.

By Edmund B. Wilson, Ph.D. J.H.U.

5. THE FOUNDATIONS OF ZOOLOGY.

By William Keith Brooks, Ph.D. Harv., LL.D. Williams.

6. THE PROTOZOA.

By Gary N. Calkins, Ph.D. Columbia.

7. REGENERATION.

By Thomas Hunt Morgan, Ph.D.

COLUMBIA UNIVERSITY BIOLOGICAL SERLES. VIL

REGENERATION

BY

e^

THOMAS HUNT MORGAN, Ph.D.

PROFESSOR OF BIOLOGY, BRYN MAWR COLLEGE

THE MACMILLAN COMPANY

LONDON: MACMILLAN & CO., LTD.
I9OI

All rights reserved

Copyright, 1901,
By the MACMILLAN COMPANY.

Norivood Press

J. S Gushing & Co. — Berwick &' Smith

Norivood, Mass., U.S.A.

€o lis IHotijer

Digitized by the Internet Archive

in 2010 with funding from

Open Knowledge Commons and Harvard Medical School

http://www.archive.org/details/regenerationmorg

PREFACE

This volume is the outcome of a course of five lectures on
" Regeneration and Experimental Embryology," given in Columbia
University in January, 1900. The subjects dealt with in the lectures
are here more fully treated and are supplemented by the discussion
of a number of related topics. During the last few years the prob-
lems connected with the regeneration of organisms have interested
a large number of biologists, and much new work has been done in
this field ; especially in connection with the regenerative phenomena
of the Qgg and early embryo. The development of isolated cells or
blastomeres has, for instance, aroused widespread interest. It has
become clearer, as new discoveries have been made, that the latter
phenomena are only special cases of the general phenomena of
regeneration in organisms, so that the results have been treated
from this point of view in the present volume.

If it should appear that at times I have gone out of my way to
attack the hypothesis of preformed nuclear germs, and also the
theory of natural selection as applied to regeneration, I trust that
the importance of the questions involved may be an excuse for the
criticism.

If I may be pardoned a further word of personal import, I should
like to add that it has seemed to me that far more essential than each
special question with which the biologist has to deal is his attitude
toward the general subject of biology as a science. Never before in
the history of biology has this been more important than at the
present time, when we so often fail to realize which problems are
really scientific and which methods are legitimate for the solution
of these problems. The custom of indulging in exaggerated and

viii PRE FA CE

unverifiable speculation bids fair to dull our appreciation for hypoth-
eses whose chief value Hes in the possibility of their verification;
but those who have spent their time and their imagination in such
speculations cannot hope for long to hold their own against the
slow but certain advance of a scientific spirit of investigation of
organic phenomena. The historical questions with which so many
problems seem to be connected, and for which there is no rigorous
experimental test, are perhaps responsible for the loose way in which
many problems in biology are treated, where fancy too often supplies
the place of demonstration. If, then, I have tried to use my mate-
rial in such a way as to turn the evidence against some of the
uncritical hypotheses of biology, I trust that the book may have
a wider bearing than simply as a treatment of the problems of
regeneration.

I wish to acknowledge my many obligations to Professor H. F.
Osborn and to Professor E. B. Wilson for friendly criticism and
advice ; and in connection with the revision of the text I am greatly
indebted to Professor J. W. Warren, to Professor W. M. Wheeler,
to Professor G. H. Parker, and to Professor Leo Loeb.

Bryn Mawr College, Pennsylvania,
June II, igoi.

CONTENTS

CHAPTER I
General Introduction

PAGE

Historical Account of the Work on Regeneration of Trembley, Bonnet, and

Spallanzani ............ i

Some Further Examples of Regeneration ....... 6

Definition of Terms ........... 19

CHAPTER II

The External Factors of Regeneration in Animals

The Effect of Temperature 26

The Effect of Food 27

The Effect of Light 29

The Effect of Gravity 30

The Effect of Contact 33

The Effect of Chemical Changes in the Environment 35

General Conclusions . . . . . . . . . . '36

CHAPTER III

TkE Internal Factors of Regeneration in Animals

Polarity and Heteromorphosis 38

Lateral Regeneration 43

Regeneration from an Oblique Surface 44

The Influence of Internal Organs at the Cut-surface 52

The Influence of the Amount of New Material 54

The Influence of the Old Parts on the New 62

The Influence of the Nucleus on Regeneration . . . . , . -65

The Closing in of Cut-edges 69

X CONTENTS

CHAPTER IV
Regeneration in Plants

PAGE

Regeneration in Flowering Plants 71

Regeneration in Liverworts, Mosses, and Moulds 84

Hypothesis of Formative StuiTs 88

CHAPTER V

Regeneration and Liability to Injury

Examples of Supposed Connection between Regeneration and Liability to

Injury ............. 92

Regeneration in Different Parts of the Body ...... 97

Regeneration throughout the Animal Kingdom ...... 103

Regeneration and the Theory of Natural Selection 108

CHAPTER VI

Regeneration of Internal Organs. Hypertrophy. Atrophy

Regeneration of Liver, Eye, Kidney, Salivary Glands, Bones, Muscles, Nerves,

Brain, and Cord of Vertebrates . . . . . . . .111

Examples of Hypertrophy 115

Theories of Hypertrophy . . . . . . . . . .118

Atrophy 123

Incomplete Regeneration 125

CHAPTER VII

Physiological Regeneration

Supposed Relation between Physiological Regeneration and Restorative

Regeneration . . . . . . . . . . . .128

Regeneration and Growth . . . . . . . . ' . . 131

Double Structures 135

CHAPTER VIII

Self-division and Regeneration. Budding and Regeneration.
AuTOTOMY. Theories of Autotomy

Review of Groups in which Self-division occurs ...... 142

Division in Plane of Least Resistance . 144

CONTENTS XI

PAGE

Review of Groups in which Budding occurs. Relation of Budding to

Regeneration 149

Autotomy 150

Theories of Autotomy 155

CHAPTER IX
Grafting and Regeneration

Examples of Grafting in Hydra, Tubularia, Planarians, Earthworms, Tadpoles . 159

Grafting Pieces of Organs in Other Parts of the Body in Higher Animals . 178
Grafting of Parts of Embryos of the Frog . . . . . . .182

Union of Two Eggs to form One Embryo . . . . . . .188

CHAPTER X
The Origin of New Cells and Tissues

Origin of New Cells in Annelids ......... 190

Origin of the New Lens in the Eye of Salamanders ..... 203

The Part played by the "Germ-layers" in Regeneration .... 207

The Supposed Repetition of Phylogenetic and Ontogenetic Processes in

Regeneration 212

CHAPTER XI
Regeneration in Egg and Embryo

Introduction 216

Regeneration in Egg of Frog 217

Regeneration in Egg of Sea-urchin 228

Regeneration in Other Forms : Amphioxus, Ascidian, Ctenophore, Snail,

Jelly-fish, Fish 236

CHAPTER XII

Theories of Development

Theories of Isotropy and of Totipotence of Cells 242

Theory of Qualitative Division of Nucleus 243

Theory of Equivalency of Cells . . . . . . ' . . . 244

Theory of the Organized Structure of the Protoplasm 246

Theory of Cells as Units . 250

xii CONTENTS

PAGE

Further Analysis of Theories of Qualitative Nuclear Divisions and of the

Equivalency of Blastomeres . 252

Driesch's Analytical Theory, Criticism, and Later Theories of Driesch . 253

Conclusions 256

CHAPTER XIII

Theories of Regeneration

Pre-formation Theory 260

Cooiparison with Growth of Crystal 263

Completing Theory 264

Theory of Formative Stuffs 265

Conclusions ............. 269

Theory of Tensions controlling Growth 271

CHAPTER XIV
General Considerations and Conclusions

Organization 277

Machine Theory of Development and of Regeneration . . . . 283

Teleology . . . . . . . . . . . . . 283

"Action at a Distance" 284

Definition of Terms : Cause, Stimulus, Factor, Force, Formative Force,

Organization ............ 287

Regeneration as a Phenomenon of Adaptation 288

Literature . . . . 293

Index 31 1

REGENERATION

CHAPTER I

GENERAL INTRODUCTION

Although a few cases of regeneration were spoken of by Aris-
totle and by Pliny, the subject first attracted general attention
through the remarkable observations and experiments of the Abbe
Trernbley. His interest was drawn to certain fresh-water polyps,
hydras, that were new to him, and in order to find out if the organisms
were plants or animals he tried the effect of cutting them into pieces ;
for it was generally known that pieces of a plant made a new plant,
but if an animal were cut into pieces, the pieces died. Trembley found
that the polyp, if cut in two, produced two polyps. Logically, he
should have concluded that the new form was a plant ; but from
other observations, as to its method of feeding and of movement,
Trembley concluded that the polyp was an animal, and that the
property of developing a new organism from a part must belong to
animals as well as to plants. " I felt," he says, " strongly that nature
is too vast, and too little known, for us to decide without temerity
that this or that property is not found in one or another class of
organized bodies."

Trembley 's first experiments were made in 1740, and the remark-
able results were communicated by letter to several other naturalists.
It came about in this way that before Trembley's memoir had
appeared, in 1744, his results were generally known, and several
other observers had repeated his experiments, and extended them
to other forrris, and had even published an account of their own
experiments, recognizing Trembley, however, as the first discoverer.
Thus Reaumur described, in 1742, a number of other forms in which
regeneration takes place; and Bonnet, in 1745, also described some
experiments that he had made during the four preceding years.
Widespread interest was aroused by these results, and many different
kinds of animals were experimented with to test their power of
regeneration. Most important of these new discoveries were those
of Spallanzani, who pubHshed a short prehminary statement of his
results, in 1768, in his Prodromo.

B I

2 REGENERATION

Trembley found that when a hydra is cut in two, the time required
for the development of the new individuals is less during warm than
during cold weather. He also found that if a hydra is cut into three
or four parts, each part produces a new individual. If these new
hydras are fed until they grow to full size, and are then again cut
into pieces, each piece will produce a new polyp. The new animals
were kept in some cases for two years, and behaved in all respects
as do ordinary polyps.

Trembley also found that if the anterior, or head-end, with its
tentacles, is cut off, it also will make a new animal. If a hydra is
cut lengthwise into two parts, the edges roll in and meet, and in an
hour, or less, the characteristic form may be again assumed. New
arms may appear later on the new individual. If a hydra is split
lengthwise into four pieces, each piece will also produce a new polyp.

If the head-end only of a hydra is split in two, each half becomes
a new head, and a two-headed hydra results. If each of the new
heads is spHt again, a four-headed hydra is produced ; and if each
of the four heads is once more split in two, an eight-headed hydra is
formed. A hydra of this kind, in which seven heads had been pro-
duced in this way, is shown in Fig. i, A. Each head behaves as a
separate individual, and all remain united on the same stalk. If the
foot-end of a hydra is split, a form with two feet is produced.

One of the most ingenious and most famous experiments that
Trembley made consisted in turning a hydra inside out (Fig. i, B, i
and 2). The animal tends to turn itself back again, but by sticking a
fine bristle through the body, Trembley thought that the turning back
could be prevented, and that the inner surface of the hollow body
remained on the outside, and the outer surface of the body came to
line the new central cavity. Each layer then changed, he thought,
its original characteristics, and became like that of the other layer.
The details of these experiments will be described in a future chapter,
as well as more recent experiments that have put the results in quite
a different light.

Reaumur repeated Trembley's experiment of cutting a hydra into
pieces, and obtained the same results. He found also that certain
fresh-water worms, as well as the terrestrial earthworm, regenerated
when cut into pieces. At his instigation two other naturahsts^
examined the starfish and some marine polyps, and they concluded
that it was highly probable that these forms also could regenerate.
Reaumur pointed out that regeneration is more likely to occur in
fragile forms which are more exposed to injury.

Bonnet's experiments were made on several kinds of fresh-water

1 Guettard and Gerard de Villars. Bernard de Jussieu also, who demonstrated that star-
fish can regenerate.

GENERAL INTRODUCTION

worms, one of which, at least, seems to have been the annelid lum-
briculus. His first experiments (1741) showed that when the worm
is cut in two pieces, a new tail develops at the posterior end of the
anterior piece, and a new head at the anterior end of the posterior

B

Fig. I. — ^-j5. After Trembley. C-G'. After Bonnet. ^4. Seven-headed hydra made by splitting
head-ends lengthwise. B. Illustrating the method of turning hydra inside out by means of
a bristle ; i, foot being pushed through mouth ; 2, completion of process. C. Middle piece
of an earthworm (cut into three pieces) with new head and tail. D. Anterior part of an
earthworm regenerating a new " delicate " tail. E. Posterior third of a worm (lumbriculus)
that regenerated two heads. F. Middle piece of a worm (another species) cut into three
pieces. It made a tail at each end. F . Anterior, enlarged end (tail) of last. G. Small
piece of a worm. G' . Regeneration of head and tail of same.

piece. He found that if a worm is cut into three, four, eight, ten,
or even fourteen pieces, each piece produces a new worm ; a new
head appearing on the anterior end of each piece, and a new tail on
the posterior end (Fig. i, G, G'). The growth of the new head is
limited in all cases to the formation of a few segments, but the new

4 REGENERATION

tail continues to grow longer, new segments being intercalated just
in front of the end-piece that contains the anal opening. In summer
the regeneration of a new part takes place in two to three days ; in
winter in ten to twelve days, this difference not being due to the time
of year, but to the temperature. Bonnet found that if a newly
regenerated head is cut off, a new one regenerates, and if the second
one is removed, a third, new one develops, and in one case, this oc-
curred eight times : the ninth time only a bud-like outgrowth was
formed. In other cases a new head was produced a few more times,
but never more than twelve. He thought that the capacity of a part
to regenerate is in proportion to the number of times that the animal
is liable to be injured under natural conditions.

Bonnet found that short pieces from the anterior or posterior end
of the body failed to regenerate, and usually died in a few days.
Occasionally two new heads appeared at the anterior end of a piece
(Fig. I, E\ and sometimes two tails at the posterior end.

Another kind of fresh-water worm^ was found that gave a very
remarkable result. If it was cut in two pieces, the posterior piece
produced at its anterior end, not a new head, but a new tail. Thus
there is formed a worm with two tails turned in opposite directions,
as shown in Fig. i, F, F' .

Spallanzani made many experiments on a number of different
animals, but unfortunately the complete account of his work was
never published, and we have only the abstract given in his Prodromo
(1768). He made a large number of experiments with earthworms
of several kinds, and found that a worm cut in two pieces may pro-
duce two new worms ; or, at least, that the anterior piece produces a
new tail, which increases in length and may ultimately represent the
posterior part of the body ; the posterior piece, however, produces
only a short head at its anterior end, but never makes good the rest
of the part that was lost. A short piece of the anterior end fails to
regenerate ; but in one species of earthworm, that differs from all
the others in this respect, a short anterior piece or head can make a
new tail at its posterior end.^ Spallanzani also found that if much of
the anterior end is cut off, the development of a new head by the
posterior piece is delayed, and, in some species, does not take place
at all.

If a new head is cut off, another is regenerated, and this occurred,
in one case, five times. If, after a new head has developed, a por-
tion only is cut off, the part removed is replaced, and if a portion of
this new part is cut off it is also regenerated. If a worm is split

1 An annelid of unknown species.

2 This statement of Spallanzani's I interpreted incorrectly ('99), thinking that he obtained
a two-tailed form as had Bonnet.

GENERAL INTRODUCTION 5

longitudinally into two pieces, the pieces die. If only a part of the
worm is split longitudinally and one part removed, the latter will be
regenerated from the remaining part.^ Several contemporaries of
Spallanzani also made experiments on the earthworm.^

Spallanzani found that a tadpole can regenerate its tail ; and if a
part of the new tail is cut off, the remaining part will regenerate
as much as is lost. Older tadpoles regenerate more slowly than
younger ones. If a tadpole is not fed, it ceases to grow larger,
but it will still regenerate its tail if the tail is cut off.'*^ Salamanders
also regenerate a new tail, producing even new vertebrae, If a leg
is cut off, it is regenerated ; if all four legs are cut off, either at
the same time or in succession, they are renewed. If the leg is
cut off near the body, an imperfectly regenerated part is formed.
Regeneration of the legs was found to take place in all species of
salamanders that were known to Spallanzani, but best in young
stages. In full-grown salamanders, regeneration takes place more
promptly in smaller species than in larger ones. Curiously enough,
it was found that if the fingers or toes are cut off, they regenerate
very slowly. If the fingers of one side and the whole leg of the
opposite side are cut off at the same time, the leg may be regen-
erated as soon as are the fingers of the other side. A year is, how-
ever, often insufficient in some forms for a leg to become fully
formed. If an animal is kept without food for two months after
a leg has been cut off, the new leg will regenerate as rapidly as in
another salamander that has been fed during this time. If the
animal is kept longer without food, it will decrease in size, but
nevertheless the new leg continues to grow larger. Occasionally
more toes or fewer toes than the normal number are regenerated ;
but as a rule the fore leg renews its four toes, and the hind leg
its five toes.

In one experiment, all four legs and the tail were cut off six times
during the three summer months, and were regenerated. Spallan-
zani calculated that 647 new bones must have been made in the new
parts. The regeneration of the new limbs was as quickly carried out
the last time as the first. Spallanzani also found that the upper and
lower jaws of salamanders can regenerate.

If the tentacles of a snail or of a slug are cut off, they are renewed ;
and Spallanzani found that even if the entire head is cut off a new
one is regenerated. Also other parts of the snail, as the foot, or the

1 There is some doubt in regard to this statement of Spallanzani's. In a letter to Bonnet
he denies that this takes place in the earthworm.

2 Spallanzani refers to the work of Ginnani, Vandelli, Vallisneri.

3 He found that the legs of the tadpole of the frog, and of two species of toads, also have
the power of regeneration.

6 RE GENERA TION

collar, may be regenerated. The head of the slug, it was found,
regenerates with more difficulty than does that of the snail.

These justly celebrated experimentsof Trembley, Reaumur, Bonnet,
and Spalianzani furnished the basis of all later work. Many new facts,
it is true, have been discovered, and in many cases we have penetrated
further into the conditions that influence the regeneration, but many
of the important facts in regard to regeneration were made known by
the work of these four naturalists.

SOME FURTHER EXAMPLES OF REGENERATION

' So many different phenomena are included at the present time
under the term " regeneration," that it is necessary, in order to get a
general idea of the subject, to pass in review some typical examples
of the process.

The regeneration of different parts of the salamander shows some
characteristic methods of renewal of lost parts. If the foot is cut off
a new foot is regenerated; if more than the foot is cut off, as much is
renewed as was lost. For instance, if the cut is made through the
fore leg, as much of the fore leg as was removed, and also the foot,
are regenerated ; if the cut is made through the upper part of the
leg, the rest of that part of the leg and the fore leg and the foot are
regenerated. The new part is at first smaller than the part removed,
although it may contain all the elements characteristic of the leg. It
gradually increases in size until it has grown to the same size as the
leg on the other side of the body, and then its growth comes to an
end.

Other parts of the body of the salamander also have the power of
regeneration. If a part of the tail is cut off, as much is renewed as
has been removed ; if a part of the lower or upper jaw is cut off, the
missing part is regenerated ; if a part of the eye is removed, a new eye
is formed from the part that remains ; but if the whole eye is extir-
pated, or the whole limb, together with the shoulder girdle, is removed,
neither structure is regenerated.

In other vertebrates the power of regeneration is more limited.
A hzard can regenerate its tail, but not its hmbs. A dog can regen-
erate neither its limbs nor its tail.

It has been stated that the new limb of the salamander is at first
smaller than the one removed, but it may contain all the elements of
the original limb. We find this same phenomenon in other forms,
and since it is a point of some theoretical interest, a few other
examples may be given. If the tail of a fish that has a bilobed form
is cut off near the base, as indicated in Fig. 40, G, there appears over
the exposed edge a narrow band of new material. The new part

GENERAL INTRODUCTION

now begins to grow faster at two places than at intermediate points,
as shown in Fig. 40, H. The new tail, although very short, assumes,
as a result, the characteristic bilobed form. The point of special

Fig. 2. — A. Allolobophora fcetida. Normal worm. i?-i^ Anterior ends of worms, which, after the
removal of one, two, three, four, and five segments, have regenerated the same number.
G. Anterior third cut off. Only five head-segments regenerated. H. Worm cut in two in
middle. A head-end of five segments regenerated. /. Worm cut in two posterior to middle.
A heteromorphic tail regenerated at anterior end.

interest is that the new material that appears over the exposed edge
does not first grow out at an equal rate at all points until it reaches
the level of the original fork, and then continue to grow faster in two

REGENERATION

regions to form the lobes of the tail, but the two regions of most rapid
o-rowth are very soon estabUshed in the new tail. Subsequent growth
in all parts of the new tail enlarges it to the full size.

riL

Fig. 3. — A, B. Short head-ends o'iA.fcetida that did not regenerate at posterior surface. C, D,
E. Longer anterior pieces, that made new segments at their posterior ends. F. After Hazen.
A piece consisting of five (3 to 7) anterior segments grafted, in a reversed position, upon the
anterior end of another worm. A heteromorphic head of about two segments regenerated
at the free end, which is the posterior end of the piece.

In some cases of regeneration, in which the new part is at first
smaller than the part removed, the new part represents at first only
the distal portion of the body, and although the new part may grow
to the full size, the whole of the part removed may never come back.

GENERAL INTRODUCTION' 9

This is illustrated in the regeneration of the anterior end of the earth-
worm ; for example, in the red-banded earthworm, or brandling {Allo-
lobophora foetida)} If one segment of the anterior end is cut off, one
segment is very quickly regenerated (Fig. 2, B)\ if two segments are cut
off, two come back (Fig. 2, C) ; if three segments are cut off, as many
are regenerated (Fig. 2, Z?) ; if four are cut off, generally four come
back (Fig. 2, E)\ when five are cut off, four or five come back (Fig.
2, F^ ; but if six or more are cut off, only four or five are regenerated
(Fig. 2, G\ It is found in this case that a limit is soon reached beyond
which fewer segments are produced than have been removed. The
new segments form the anterior end or head that enlarges to the char-
acteristic size ; but the missing segments behind the new head are
never regenerated, and the worm remains shortened throughout the
rest of its life. If the reproductive region has been removed with
the anterior part, new reproductive organs are never formed and
the worm remains incapable of reproducing itself.

This same relation between the number of segments cut off
from the anterior end and the number that is regenerated seems to hold
good throughout the whole group of annelids, although the maximum
number that comes back may be different in different species. Thus
in lumbriculus six or seven or even eight new segments come back if
more than that number have been removed.

If we examine the method of regeneration from the posterior end
of a piece of an earthworm, we find that when several or many
posterior segments have been removed a new part comes back, com-
posed at first of a very few segments. The terminal segment
contains the new posterior opening of the digestive tract. New
segments are now formed just in front of the terminal segment, the
youngest being the one next to the end-segment. The process con-
tinues until the full complement of segments is made^ up (Fig. 3,
C, D, E). Comparing these results with those described above for
the anterior end, we find, in both cases, that only a few segments
are at first formed, but in the posterior regeneration new segments
are intercalated near the posterior end. This process of interca-
lation is the characteristic way in which many annelids add new seg-
ments to the posterior end, as they grow larger and longer.

Amongst the flatworms the fresh-water planarians show remark-
able powers of regeneration. If the anterior end is cut off at any
level, a new head is produced (Fig. 4, C). The new worm is at first
too short, i.e. the new head is too near the pharynx, but changes
take place in the region behind the new head that lead to the devel-
opment of new material in this part. The new head is, in conse-

^ These experiments on the earthworm are in the main taken from my own results ('95)
('97) ('99).

lO

RE GENERA TION

quence, carried farther and farther forward until the typical relations
of the parts have been formed, when the growth in the region behind
the head comes to an end (Fig. 4, C^). Similar changes take place
when the posterior end is cut off, as shown in Fig. 4, B, B^. The new
part contains the new pharynx that is proportionately too near the
head, but the pharynx is carried farther backwards by the formation
of new material in front of it, until it has reached its typical distance

Fig. 4. — A-E. Plana7-ia maailata. A. Normal worm. B, E^. Regeneration of anterior half.
C, Ci. Regeneration of posterior half. D. Cross-piece of worm. Z?i, ZJ^, Z53^ /)4. Regenera-
tion of same. E. Old head. iJi, E'^, E^. Regeneration of same. F. P. lugiibris. Old head
cut off just behind eyes. F'^. Regeneration of new head on posterior end of same.

from the head. In these planarians the results are somewhat com-
plicated, owing to the old part changing its form, especially if the
piece is not fed ; but the main facts are given above, and a more
complete account of the changes that occur will be given in another
place.

LATERAL REGENERATLON

Not only does regeneration take place in an antero-posterior direc^
tion, but in many animals also at the side. The regeneration of the
limb of the salamander is, of course, a case of lateral regeneration in

GENERAL INTRODUCTION II

relation to the animal as a whole, but in a longitudinal direction
in regard to the limb itself. Lateral regeneration of the limb would
take place if the limb was split lengthwise into two parts and one of
the parts removed. If the entire salamander were cut in two length-
wise, each half would most certainly die without regeneration, if for
no other reason than that the integrity of the median organs is
necessary for the life of the different parts. If, however, a planarian
is cut lengthwise into a right and left half, each piece will complete
itself laterally and make a new worm (Fig. 13^, A-D). Even a narrow
piece cut from the side will produce a new worm by regenerating
laterally, as shown in Fig. 19, a, b, c. In hydra, also, a half-longi-
tudinal piece produces a new animal, but in this case not by the
addition of new material at the side, but by the cut-edges meeting
to make a tube of smaller diameter. Subsequently the piece changes
its form into that characteristic of hydra.

REGENERATION OF TERMINAL PORTIONS OF THE BODY

In most of the preceding examples the behavior of the larger piece
of the two that result from the operation has been described ; but there
are some important facts in connection with the regeneration of the
smaller end-pieces. The leg, or the tail, that has been cut from the
salamander soon dies without regenerating. The life of the leg can
be maintained only when the part is supplied with certain substances
from the body of the animal. It does not follow, of course, that,
could the leg or the tail be kept alive, they would regenerate a
salamander. In fact, there is evidence to show, in the tail at least,
that, although it may regenerate a structure at its anterior end, the
structure is not a salamander, but something else. This has been
definitely shown in certain experiments with the tail of the tadpole.
It is possible to graft the tail of one tadpole in a reversed position,
i.e. with its anterior end free, on the tail of another tadpole (Fig. 54,
A-D), or even on other parts of the body. Regeneration takes place
from the free end, i.e. from the proximal end of the grafted tail.
The new structure resembles a tail, and not a tadpole. If it be
objected that the experiment is not conclusive because of the presence
of the old tail, or of the use of the newly developing part, the objec-
tion can be met by another experiment. If, as shown in Fig. 56, A,
a triangular piece is cut out of the base of the tail of a young tadpole,
the cut being made so deep that the nerve-cord and notochord are
cut in two, there develops from the proximal end of the tail a new
tail-like structure that is turned forward, or sometimes laterally. In
this case the objections to the former experiment do not apply, and
the same sort of a structure, namely, a tail, is produced.

12

REGENERATION

In the earthworm also we find some interesting facts connected
with the regeneration of the terminal pieces. If one, two, three,
four, or five segments are cut from the anterior end, they will die
without regenerating. Pieces that contain more segments, six to
ten, for example, may remain alive for a month or longer, but do not
regenerate (Fig. 3, A, B'). That this lack of power to regenerate at the
posterior end is not due to the smallness of the piece can be shown
by removing from a piece of five segments one or two of its anterior
segments. These will be promptly regenerated. Another experiment

Fig. 5. — Hydra viridis. A. Normal hydra. Lines indicate where piece was cut out. B, 1-4.
Changes in a piece of A, as seen from the side. C, 1-4. Same as seen from the end. D, E,
F. Later stages of same piece, drawn to same scale.

has shown, however, that if these small pieces can be kept alive for a
long time, and also supplied with nourishment, regeneration will take
place at the posterior end. If, for instance, a small piece of eight or
ten segments has its anterior three or four segments cut off, and is
grafted by its anterior end to the anterior end of another worm, as
shown in Fig. 3, F, the piece will begin, after several months, to re-
generate at its exposed posterior end, but in the one instance in which
this experiment has been successfully carried out, a new head, and
not a tail, appeared on the exposed free end. The result is not due
to the grafting, or to the anterior position of the posterior end, but to

GENERAL INTRODUCTION

13

some peculiarity in the piece itself. We find the converse of this
result in an experiment with the tail region of the earthworm, v/here
the outcome is more clearly seen to be connected with the nature of
the piece itself. If a piece less than half the length of the worm is
cut off from the posterior end, there is generally formed from its
anterior cut-surface, not a head, but another tail (Fig. 2, /). The
result is similar to that described by Bonnet for one of the fresh-water
annelids. A parallel case to that of the head of the earthworm is
found in one of the planarians. If the head of Planaria lugubj'is is
cut off just behind the eyes (Fig. 4, F\ there is produced, at the pos-
terior cut-edge of the head, a new head turned in the opposite direc-
tion, as shown in Fig. 4, F'^,

REGENERATION BY TRANSFORMATION OF THE ENTIRE PIECE

In the regeneration of some of the lower animals, the transforma-
tion of a piece into a new animal of smaller size is brought about by a
change in form of the piece itself, rather than through the production
of new material at the cut-ends. If a ring is cut from the body of
hydra, as shown in Fig. 5, A, the open ends of the ring are soon
closed by the contraction of the sides of the piece, and in the course
of a few hours the ring has become a hollow sphere; or, if the
piece is longer, a closed cylinder. After a day or two, the piece begins
to elongate, and four tentacles appear near
one end (Fig. 5, B, C, D). The piece con-
tinues to elongate until it forms a small
polyp, having the typical proportions of
length to breadth (Fig. 5, E, F). It has
changed into a new cylinder that is longer
than the piece cut off, but correspondingly
narrower. In this case there cannot be said
to be a replacement of the missing parts,
but rather, through the transformation of
the old piece,. the formation of a new whole.
In planarians also the formation of a new
worm from a piece involves a change in the
form of the old part, as well as the addition
of new material at the cut-end. If a cross-
piece is cut out, as shown in Fig. 4, D, new
material appears at the ends, but the old
piece also becomes narrower and longer B

(Fig. 4, n^-D^). If the old head is cut off, ^^^- £- f;. ^'-f, °1 ^^^^
it produces new material at its posterior end stnpe injured at two points

/-r^. 7^ 7-1 \ Til n (see circles in v4). 5. Regen-

(Pig. 4, F, h^\ and also becomes smaller eration of same piece.

14

RE GENERA TION

as the new part grows larger (Fig. 4, E'^, E^). In a land planarian,
Bipaliiim kewense, a piece is transformed into a new worm, as shown
in Fig. 6, A, B. In this case the old pigment stripes of the piece are
carried directly over into the new worm, the piece elongating during
the transformation.

A similar change takes place in pieces of unicellular animals, as
best shown by cutting off pieces of stentor. If Stentor ccenUeiis is

Fig. 7. — Stentor cceruleus. A. Normal, fully expanded individual. A^. Same contracted.
Line a-a indicates where it was cut in two. B, C. Pieces after division. i?i, B'^, B^. Re-
generation of three distal pieces {B) containing old peristome, fi, C^. Regeneration of two
proximal or foot pieces {C).

cut in two pieces, as indicated in Fig. 7, each piece makes a new
individual of half size, but of proportionate form. The old peristome
remains on the anterior piece, but becomes reduced in size as the piece
changes its shape, and although it may be at first too large for the
length of the new piece, it ultimately reaches a size about proportion-
ate to the rest of the animal. The posterior piece is at first too long

GENERAL INTRODUCTION

15

for the size of the new peristome that is formed, but the latter becomes
larger, until the characteristic form has been reached. The change
in form of the stentor may take place in a few hours, and the result

B

Fig. 8. — Aftt-r Gmber. Stentor cceruleus. A. Cut into three pieces. B. This row shows regen-
eration of anterior piece. C. This row shows regeneration of middle piece, D. I'his row
shows regeneration of posterior piece.

is brought about, not by the development of new protoplasm over the
cut-end, but by a change of the old protoplasm into the new form. A
similar experiment is shown in Fig. 8, in which a stentor was cut into
three pieces, each piece containing a part of the old nucleus.

REGENERATION IN PLANTS

In the higher plants the production of a new plant from a piece
takes place in a different way from that by which in animals a new
individual is formed. The piece does not complete itself at the cut-
ends, nor does it change its form into that of a new plant, but the
leaf-buds that are present on the piece begin to develop, especially
those near the "distal end of the piece, as shown in Fig. 32, A, and
roots appear near the basal end of the piece. The changes that take
place in the piece are different from those taking place in animals,
but as the principal difference is the development of the new part
near the end, rather than over the end, and as in some cases the

i6

REGENERATION

new part may even appear in new tissue that covers the end, and,
further, since the process seems to include many factors that appear
also in animals, we are justified, I think, in including this process
in plants under the general term regeneration.

Fig, 9. — After Vochting. A, A^, A"^. Pieces of thallus of Lunularia communis regenerating at
the apical end. B. Piece of thallus cut in two in the middle line. Z?i. Same split at side of
middle. C. An oblique piece extending to middle line. Ci, C'^. Oblique pieces not extend-
ing to middle line. D. Fruiting stalk stuck into sand, producing new thallus above sand.
D^. Same laid horizontally regenerating near base. E. Same with fruiting head cut off.
Regenerating at base. E^. Twisted piece regenerating at two points. F. Piece of ray of
head regenerating near base. F'^. Same with distal end of ray cut off. Also regenerating
at base.

In the lower plants, such as the mosses, the liverworts, the moulds,
and the unicellular forms, regeneration also takes place. Vochting
has shown that pieces from any part of the thallus of a liverwort ^
produce new plants. If a cross-piece is cut off, there appears a small

^ Lunularia vulgaris.

GENERAL INTRODUCTION

17

outgrowth from the middle of the anterior cut-edge, as shown in
Fig. 9, A, A^, that gradually enlarges to form a new thallus. It will
be seen from the figures that the whole anterior edge does not grow
forward, but a new thallus arises from a group of cells at, or near,
the anterior edge. These cells are the least-differentiated cells in
the piece, and have softer cell walls than have the other cells.

Fig. 10. — After Pringsheim. A. A piece of seta of sporophore of Hypnum ctipressiforme, sending
out protonema-threads. B. Longitudinal section of a piece of the seta of sporopliore of
Bryum ccespitosiim. C. Piece of same oi I/ypnu?n cupressl/orme. Moss-plant arising from new
protonema. B. Piece of same of Hypnum serpens with protonema and moss-plant arising
from it.

Pringsheim has shown that if a piece of the stalk of the sporan-
gium of certain mosses is cut off, it produces at its ends thread-like
outgrowths which are like the protonema-stage of the moss, and from
this protonema new moss-plants may arise (Fig. 10, A, B, C, D).

Braefeld has obtained a somewhat similar result in one of the
moulds, in which a piece of the sporangium stalk gives rise to a
mycelium from which new sporangia may be produced.

i8

RE GENERA TION

REGENERATION IN EMBRYOS AND EGGS

Regeneration takes place not only in adult organisms, but also in
embryos, and larvae of many animals. It is often stated that the
power of regeneration is more highly developed in embryos than in
adults, but the facts that can be advanced in support of this view-
are not numerous. One of the few cases of this sort known to us
is that of the leg of the frog, that does not regenerate, while the leg
of the tadpole is capable of regenerating.

Fig. II. — A. Blastula of Sea-urchin. Dotted lines indicate where pieces of wall were cut off. To
the right are shown stages in the development of these pieces. B. Two-cell stage of egg
of sea-urchin. One blastomere isolated. Its development shown in figures to right of B.
C. Fertilized but unsegmented egg. Dotted hne indicates where it was cut in two. Upper
row of figures to riglit shows development of nucleated piece ; lower row shows the fertiliza-
tion and development of non-nucleated piece.

The early stages in the development of the sea-urchin, or of the star-
fish, may be taken to illustrate the power of regeneration in embryos.
If the hollow blastula of the sea-urchin is cut into pieces (Fig. ii. A),
each piece, if not too small, may produce a new blastula. The

GENERAL INTRODUCTION 1 9

edges of the piece come together, and fuse in the same way in which
a piece of hydra closes. A new hollow sphere of small size is formed,
which then passes through the later stages of development as does the
whole normal blastula.

Still earher stages of the sea-urchin, or of the starfish, have the
power of producing embryos if they are cut into pieces. If the seg-
menting Q.^g is separated into a few parts, each part will continue to
develop. Even the first two blastomeres or cells will, if separated,
produce each a whole embryo (Fig. ii, B). The power of develop-
ment of a part does not even end here, for, if the undivided, fertilized
Q,gg is cut into pieces, the part that contains the nucleus will segment
and produce a whole embryo (Fig. \\, C, upper row). If the Qgg is
cut in two or more pieces before fertilization, and then each part is
fertilized, it has been found that not only the nucleated, but even the
non-nucleated fragments (if they are entered by a single spermato-
zoon) may produce embryos (Fig. ii, C, lower row).

It may be questioned whether the development of parts of the
embryo, or of the Qgg, into a whole organism can be included in the
category of regenerative processes. There are, it is true, certain dif-
ferences between these cases and those of adult forms, but as there
are many similarities in the two cases, and as the same factors appear
in both, we cannot refuse, I think, to consider all the results from a
common point of view.

PH YSIOL 0 GICAL RE GENERA TION

Finally, there are certain normal changes that occur in animals
and plants that are not the result of injury to the organism, and these
have many points in common with the processes of regeneration.
They are generally spoken of as processes of physiological regenera-
tion. The annual moulting of the feathers of birds, the periodic loss
and growth of the horns of stags, the breaking down of cells in dif-
ferent parts of the body after they have been active for a time, and
their replacement by new cells, the loss of the peristome in the proto-
zoon, stentor, and its renewal by a new peristome, are examples of
physiological regeneration. This group of phenomena must also be
included under the term "regeneration," since it is not sharply sepa-
rated from that including those cases of regeneration after injury, or
loss of a part, and both processes appear to involve the same factors.

DEFINITION OF TERMS

The older writers used such terms as " replacement of lost parts,"
"renewal of organs," and "regeneration" to designate processes
similar to those described in the preceding pages. The term regen-

20 RE- GENERA TION

eration has been for a long time in general use to include all such phe-
nomena as those referred to, but amongst recent writers there is some
diversity of opinion as to how much is to be included in the term, and
the question has arisen as to the advantage of applying new names
to the different kinds of regeneration. There can be little doubt of
the advantage, for the sake of greater clearness, of the use of different
terms to designate different phenomena, but I think that there is at
the same time the need of some general term to cover the whole field,
and the word regeneration, that is already in general use, seems to
fulfil this purpose better than any other.

Roux 1 points out that Trembley, and later Nussbaum, showed
that a piece of hydra regenerates without the formation of new mate-
rial. Roux adds that since during development the piece takes no
nourishment, the regeneration must be brought about by the rearrange-
ment of the cells present in the piece.^ The change may, or may
not, involve an increase in the number of the cells through a process
of division. In consequence of this method of development a re-dif-
ferentiation of the cells that have been already differentiated takes
place. This process of regeneration, Roux points out, is very similar
to the " post-generation " of the piece of the blastula of the sea-urchin
embryo, and he concludes that " regeneration may be brought about
entirely, or very largely, through the rearrangement and re-differen-
tiation of cells without any, or with very little, proliferation taking
place." In the adults of higher animals regeneration by prolifera-
tion preponderates, but rearrangement and re-differentiation of cells
occur in all processes of regeneration, even in higher vertebrates.
The two kinds of regeneration that Roux distinguishes are, he says,
essentially quantitative.^

1 Gesammelte Abhandlungen, No. 27, p. 836.

2 The fact that the piece does, or does not, take in food has no bearing on the question,
since many animals that do not feed while the regeneration is going on produce new cells to
form the new part.

^ These two kinds of regeneration are post-generation and regeneration proper. The
distinction that Roux attempts to make between these two processes is to a certain extent
artificial and rests at present on a very unsafe basis, at least in so far as the post-generation
of the frog's embryo is taken as a representative case of this process. Roux states that in
the process of regeneration the injured tissues produce each their like in the new part, while
in the process of post-generation of the frog's egg the new cell-material arises in part from
the nuclei and yolk-material of the injured half and in part through the accidental posi-
tion of the nuclear material of the uninjured half. In order more fully to understand this
distinction the original description of the process of post-generation given by Roux in his
account of the development of half embryos of the frog's egg must be referred to. In later
papers Roux pointed out that the missing half of the frog embryo, as well as of other forms,
may be post-generated without any new material appearing at the open side of the embryo.
It is unfortunate, I think, that the original term should have been extended to include these
other processes that do not partake of the nature of post-generation as at first defined, but
are more like the true process of regeneration as described by Roux.

GENERAL INTRODUCTION 21

Barfurth^has defined regeneration as " the replacement of an organ-
ized whole from a part of the same." If the part is given by nature,
there is a process of physiological regeneration ; if the part is the
result of an artificial injury, the process is one of pathological re-
generation. Barfurth includes in the latter category the production
of a new, entire individual from a piece, as in hydra ; regeneration
by proliferation, as in the earthworm; and also the development of
pieces of an Q.gg or of an embryo.

Barfurth's definition of regeneration is unsatisfactory, since an Q.g^
is itself a portion of an organism that makes a new whole, and this
sort of development is not, of course, as he himself points out, to be
included in the term regeneration. Nor does the use of the word
"replacement" save the definition, since in many cases the kind of
part that is lost is not replaced. The use of the word "pathological"
to distinguish ordinary regeneration from physiological regeneration
is, I think, also unfortunate, since it implies too much. There is noth-
ing necessarily pathological in the process, especially in such cases as
hydra, or as in the development of a piece of an Q^g where the piece
is transformed directly into a new organism. Furthermore, in those
cases in which (as in some annelids and planarians) a new head is
formed after or during the process of natural division, there is little
that suggests a pathological process ; and in this instance the regen-
eration takes place in the same way as after artificial section.

Driesch, in his Analytische TJieorie, states that Fraisse and Bar-
furth have established that during regeneration each organ produces
only its like. Driesch defines regeneration, therefore, as the re-awak-
ening of those factors that once more bring into play, by means of
division and growth, the elementary processes that had ceased to act
when the embryonic development was finished. This is regeneration
in the restricted sense, but Driesch also points out that this definition
must be enlarged, since, when a triton, for example, regenerates its
leg, not only does each tissue produce its like, but later a reconstruc-
tion and differentiation takes place, so that a leg and foot are formed,
and not simply a stump containing all of the typical tissues. Driesch
holds that regeneration should include only those cases in which a
proliferation of new tissue precedes the development of the new part,
and suggests that other terms be used for such cases as those of pieces
of hydra, pieces of the ^^^, etc., in which the change takes place in
the old part without proliferation of new tissue. It seems to me
unwise to narrow the scope of the word regeneration as Driesch pro-
poses, for it has neither historical usage in its favor, nor can we make
any fundamental distinction between cases in which proliferation
takes place and those in which it does not. As will be shown later,

^ Ergebnisse der Anatomic und Entwickelungsgeschichte. 1891-1900,

22 RE GENERA TION

the factors that are present in the two cases appear to be in large part
the same, and while it may be convenient to put into one class those
cases in which proHferation precedes the formation of the new organs,
and into another class those cases in which the change takes place
without proliferation, yet, since the distinction is one of subordinate
value, it is necessary to have one word to include both groups of
cases ; and no better word than regeneration has, I think, been as yet
suggested.

Driesch has made use of two other descriptive terms. The word
" reparation " is used to describe the development of the hydranth of
tubularia. The new hydranth is formed in this case out of the old
tissue at the end of the piece (Fig. 20, A). The change appears to be
the same as that which takes place in a piece of hydra, etc. The word
" reparation " does not seem to me to express very satisfactorily this
sort of change, or sharply separate it from those cases in which the
animal is repaired by adding what has been taken away ; but in this
latter sense Driesch does not use the term. I have not made use of
the word, in general, except as applied to Driesch's work.

Another term, " regulation," used by Roux, ^ and also by Driesch and
others, is used in a sort of physiological sense to express the readjust-
ments that take place, by means of which the typical form is
realized or maintained. By inference we may extend the use of the
word to include the changes that take place in the new material, that
is proliferated in forms that regenerate by this method. Driesch
uses this term, regulation, to include a much more general class of
phenomena than those included in the term regeneration, as for in-
stance, the regulation of metabolism and of adaptation, etc. One of
the subdivisions of the term regulation is called "restitution." This
word also is used where I should prefer to use the word regeneration as
a general term, and the word reorganization when reference is made
to the internal changes that lead to the production of a typical
form.

Both Roux and Driesch also speak of " self-regulation," by which is
meant, I suppose, that the changes taking place are due to readjust-
ments in the part itself, and are not induced by outside factors. The
expression " self-regulation " is not,. I think, a very happy one, since
all change is ultimately dependent upon a relation between inside and
outside conditions.

Hertwig^ defines regeneration as the power of replacement of a
part of the organism. He states that in all cases the beginning of
the process is the same, viz. the appearance of a small protuberance
composed of cells, that is the rudiment of the new part. It is evident

^ As used in connection with other terms, see his Ges. Abhandl., Vol. II, page 41.
2 Die Zelle und die Gewebe.

GENERAL INTRODUCTION 23

that Hertwig has taken into account only one side of the process.
Those cases in which a rearrangement or reorganization takes place
in the old part are not even considered.^ Goebel^ points out that in
plants the fully formed cells are, as a rule, incapable of further growth
after they have once served as a basis of an organ of the body, but
often some of the cells may remain in a latent condition, and grow
again, when the intercellular interactions are disturbed. This is the
case, he thinks, in regeneration. Goebel speaks of regeneration by
means of adventitious buds in those cases in which the buds had not
previously existed before the removal of the part. In those cases in
which the buds are in existence before the piece is removed, as in
the leaves of Asplenium, Begonia, etc., the development is not the
result of regeneration, Goebel thinks, but the buds represent a stage
in the development of the species. It may be pointed out, however,
that it is certainly a remarkable fact that often the conditions that
lead to the unfolding of an existing bud are the same as those that
lead to the development of a new bud.

The preceding account will suffice to illustrate some of the princi-
pal ideas that are held in regard to the process of regeneration.
Since many new facts have come to light in the last few years, it may
not be amiss to point out what terms will be used in the following
pages to include each kind of process.

The word " regeneration " has come to mean, in general usage, not
only the replacement of a lost part, but also the development of a
new, whole organism, or even a part of an organism, from a piece of
an adult, or of an embryo, or of an o.^^. We must include also those
cases in which the part replaced is less than the part removed, or even
different in kind.

At present there are known two general ways in which regenera-
tion may take place, although the two processes are not sharply
separated, and may even appear combined in the same form. In
order to distinguish broadly these two modes I propose to call those
cases of regeneration in which a proliferation of material precedes the
development of the new part, " epimorphosis." The other mode, in
which a part is transformed directly into a new organism, or part
of^ an organism without proliferation at the cut-surfaces, "morphal-
laxis."

In regard to the form of the new part, certain terms may be used
that will enable us to characterize briefly different classes. When the
new part is like that removed, or like a part of that removed, as when
a leg or a tail is regenerated in a newt, the process is one of "homo-

1 Hertwig's description of the method by which a piece of hydra makes a new one shows
that he did not understand the kind of change that takes place in this animal.

2 Organographie der Pflanzen, '98.

24

RE GENERA TION

morphosis." ^ Under this heading we may distinguish two cases, in one
of which the entire lost part is at once, or later, replaced — holomorpho-
sis ; in the other the new part is less than the part removed — mero-
morphosis. When the new part is different from the part removed the
process hasbeen called by Loeb "heteromorphosis," but there are at least
two different kinds of processes that are covered by this definition.
In one case the new part is not only different from the part removed,
but is also an organ that belongs to a different part of the body (or it

Fig. 12. — After Herbst. Diagram showing brain, eye, and " heteromorphic " antenna (in place
of eye of one side) of palasmon. The animal had lived in a dark aquarium for five months.

may be unhke any organ of the body). This we may call " neomor-
phosis." As an illustration of this process may be cited the develop-
ment of an antenna, when the eye of a crab or of a prawn is cut off
near the base (Fig. 12); and as an example of an organ different in
kind from any organ of the same animal, may be cited the case of
Atyo'ida potimiriim, in which the new leg is unlike any other leg on
the body. The name " heteromorphosis " can be retained for those
cases in which the new part is the mirror figure of the part from
which it arises, or more generally stated, where the new part has

1 This term is used by Driesch in his Analytische Theorie.

GENERAL INTRODUCTION 2$

its axes reversed as compared with the old part. As an example of
this may be cited the development of an aboral head on the pos-
terior end of a piece of the stem of Tubularia (Fig. 15, B), or the
development of a tail at the anterior end of a posterior piece of an
earthworm (Fig. 2).

The term " physiological regeneration " I shall use in the ordinary
sense to include such changes as the moulting and replacement of
the feathers of birds, the replacement of teeth, etc., — changes that
are a part of the life-cycle of the individual. In some cases it can
be shown that these processes are closely related to ordinary re-
generation, as when a feather pulled out is formed anew without
waiting for the next moulting period, and formed presumably out of
the same rudiment that would have made the new feather in the
ordinary moulting process.

It is sometimes convenient to contrast the process of physiological
regeneration with all other kinds. The use of the term " pathological
regeneration " for the latter seems to me, as has been said, unsatisfac-
tory. The two terms proposed by Delage,^ viz. " regular regeneration "
and " accidental regeneration," have certain advantages, although
there is nothing accidental, or at least occasional, in regard to the pro-
cess itself, as it is entirely regular, although it may only occur after
an accident to the animal. The term " regular regeneration " is, I
think, more satisfactory than " physiological regeneration," but the
latter has the advantage that it has come into current use. For what
is known as pathological or accidental regeneration, I propose the
term " restorative regeneration," and I shall continue to use the
term " physiological regeneration " as generally understood.

1 Delage, V. La Structure du Protoplasma, etc., '95.

CHAPTER II

THE EXTERNAL FACTORS OF REGENERATION IN ANIMALS

There is a constant interchange of material and of energy that
takes place between a plant or an animal and its surroundings, and
this interchange may be influenced by such physical conditions as
temperature, light, gravity, etc., or by such chemical conditions as
the composition of the atmosphere or of the water surrounding the
organism. We can study the process of regeneration either by keeping
the regenerating organism under the same conditions that it is subject
to in its natural environment, or else we can change the surrounding
physical or chemical conditions. In this way we can determine how
far the regeneration is affected by external changes, and how far it is
independent of them. If a change in the external conditions pro-
duces a definite change in the regeneration, then the new condition is
called an external factor of regeneration.

TEMPERATURE

That the rate at which regeneration takes place can be influenced
by temperature has been shown by Trembley, Spallanzani, Bonnet,
and by many more recent writers. In fact, so familiar is the process
to every one who has studied regeneration, that it is usually taken for
granted that such is the case.

In general it may be stated that the limits of temperature under
which normal growth may take place represent also the limits of
temperature for regeneration. Lillie and Knowlton ('97) have deter-
mined the limits of temperature within which regeneration takes
place in Planaria torva. The worm was cut in two transversely
through the pharynx, and the time required at different temperatures
to produce a new head on the posterior piece was recorded. The
lowest temperature at which regeneration was found to take place
was 3°C. Of six individuals kept at this temperature only one regen-
erated at all, and in this one the eyes and brain were still incomplete
after six months. The optimum temperature, or at least that at
which regeneration takes place most rapidly, was found to be 29. 7° C;
a new head developed in 4.6 days at this temperature. At 31.5° C.

26

EXTERNAL FACTORS OF REGENERATION IN ANIMALS 2'J

regeneration was slower, requiring 8.5 days to make a new head. At
32° C. incomplete regeneration sometimes took place, but death
occurred in about six days. At 33° C. regeneration was very slight,
and the animals died within three days. At 34° C, and above this
point, no regeneration took place, and death soon occurred.

In Hydra viridis, Peebles ('98) has found that regeneration is
quicker at 26°-27° C. than at 28°-30° C. At the former temperature
regeneration takes place in 48 hours. If kept at I2°C. pieces may
regenerate in 96 hours, but not all the pieces had regenerated in this
case until 168 hours.

INFLUENCE OF FOOD ON REGENERATION

While the growth of an animal or of a plant is, in most cases, and,
of course, within certain limits, directly connected with the amount
of food that is obtainable, nevertheless extensive regeneration may take
place in an animal, or part of an animal, entirely deprived of food. In
this case the material for the new part is derived from the excess of
material in the old part, and not only surplus
food material, but even the protoplasm itself
appears to be drawn upon to furnish material
to the new part. The relation between regen-
eration and the amount of food present in the
old part is well shown by experiments with
planarians. If a planarian is kept for several
months without food, it will decrease very
much in size. In fact, the volume of a
starved worm of Planaria higiibris compared
with that of a fully fed individual may be only
one-thirteenth of the latter (Fig. 13, A, B).
If a starved worm is cut in two pieces,
each piece will regenerate, although less
quickly than in a well-fed worm. The new ^

part will coritinue to increase in size at the fig. 13. — Drawn by n. m.

r -i. 1 J • L^ i_ • ^ J • Stevens. A. Large well-

expense of the old piece that is already in a fed individual of //awar.a
starved condition. On the other hand, an i^gubns. b. Same after

being kept without food

excess of food does not necessarily produce a for 4 mos. 13 days. Both

I,. ra.1 ^-r T>j„ drawn to same scale.

hastening of the regeneration, for, as Bardeen

('01) has shown, worms that have been for several days without food
may regenerate more quickly than worms that have been fed just
before they were cut into pieces.

The growth of the new part at the expense of the old tissues is a
phenomenon of the greatest importance, an explanation of which
will involve, I think, the most fundamental questions pertaining to

28

REGENERATION

growth. The results show that growth is connected with a structural
factor, and is not simply a physiological phenomenon, although no
doubt physiological factors are involved. But the physiological factors
that are here at work seem to be different from what is ordinarily
understood ; for the fact that a tissue that is slowly starving to death
should be reduced still further, and at a more rapid rate, in order to
supply material to a new part, is certainly a remarkable phenomenon.

Fig. I3i. — Planaria lugubrls. Dotted line indicates where the worm was cut in two lengthwise.
Upper three figures show how a half, that is being fed, regenerates. Lower three figures show
other half kept without food.

At present we are not in a position to offer any explanation that rests
on observation, or experiment, as to how the transfer of material takes
place, or as to how the new tissue manages to get hold of the mate-
rial from other parts. It is possible to protect the old part to a large
extent by keeping the regenerating piece well supplied with food. If
a well-fed planarian is cut in two along the middle line of the body
as indicated in Fig. 13^, A, there develops, in the course of five or six
days after the operation, new material along the cut-side of each

EXTERNAL FACTORS OF REGENERATION IN ANIMALS 29

piece, and a new pharynx appears at the border between the old and
the new parts. If one of the pieces is fed at intervals, it is found
that the new part grows more rapidly than does the new part in the
piece without food. The old tissue in both pieces has shortened
somewhat after the operation, and has also decreased somewhat in size
as the first new material developed along the cut-side, but in the
piece that is fed the old half begins to increase again until it reaches
its former size, and may even surpass the latter. A large full-sized
worm is produced from this piece, as shown in Fig. I3|, B, C, D. In
the starved piece the old part continues to grow small, due to the lack
of food and also to the increase in the new side. This increase takes
place very slowly, but ultimately a small symmetrical worm may be
produced, as shown in Fig. I3|-, E, F, G. It will be seen that the
starved piece needs to produce relatively less and less new material
in order to become symmetrical, because as the old material diminishes,
the pharynx comes to lie nearer to the middle line.

EFFECT OF LIGHT ON REGENERATION

Although few experiments have been made to test the effect of
light on regeneration, it is certain that in many cases light has no
effect on the process, neither as to the quality nor the quantity of the
result. In one form, a tubularian hydroid, EiLdendriunt racemosjLvi,
it has been shown by Loeb that the regeneration of the hydranth
takes place only when the animal is exposed to light. When a
colony of eudendrium is brought into the laboratory and placed in an
aquarium, the hydranths soon die ; but if the colony is kept in a lighted
aquarium, new hydranths are regenerated in a few days. If, on the
other hand, the colony is kept in the dark, new hydranths do not
appear; but if it is brought back again into the light the hydranths
appear. In one experiment one lot of pieces was kept in diffuse day-
light, and another lot in the dark. The former produced fifty new
hydranths in a few days; those in the dark had not made any
hydranths after seventeen days. They were then brought into the
light, and in a few days several hydranths had developed on each
piece.

Loeb also tried the effect of different colored hght on the regen-
eration of eudendrium. Dishes containing pieces of the hydroid were
put into a box that was covered by colored glass plates. Pieces sub-
jected to dark red and to dark blue Hght gave the following results.
The old hydranths, as is generally the case, were absorbed in the
course of three days. The first new hydranths appeared in the blue
light on the fourth day, and during the following days the hydranths
in this lot steadily increased. Eight days after the beginning of the

30 RE GENERA TION

experiment there were eighty hydranths under the blue glass, but not
one had developed in the red light. On the ninth day the red glass
was replaced by a dark blue one. Two days later hydranths began to
appear, and on the following day thirty-two hydranths had appeared,
and in a few days more as many as sixty had developed.^ Loeb con-
cluded that only in the more refrangible (blue) rays does the regen-
eration of the hydranth take place, while the less refrangible (red)
rays act as darkness does.^ This hydroid is the only animal yet
found that shows the effect of light on regeneration, and it is inter-
esting to find that it is one of the few animals known in which light
has an influence on the growth, if the heliotropism, or turning towards
the light, of the hydranth is looked upon as a phenomenon of growth.
There is another series of experiments made to test the effect of
light on regeneration, which gave, however, negative results. Herbst
observed that when the eye of certain Crustacea^ is cut off, some-
times an eye and sometimes an antenna is regenerated. A number
of individuals from which the eyes had been removed were kept in
the light, and others in the dark, in order to see if the presence or
absence of light is a factor in determining the kind of regeneration
that takes place. It was found that as many individuals regenerated
eyes in the dark as in the light. It was discovered later by Herbst
and myself, independently, that, when the end only of the eye-stalk is
cut off, an eye regenerates, but when the eye-stalk is cut off at the
base, an antenna regenerates. The difference in the result has there-
fore no connection with the presence or absence of light.

GRA VI TY

The only case known amongst animals, in which regeneration is
influenced by the action of gravity,^ is that of the hydroid Antemtu-
laria antennina. This hydroid lives attached to the bottom of the
sea several metres below the surface. The hydroid consists of a
single, vertical, central stem, or axis, with two or four series of lateral
branches along which the hydranths arise (Fig. 14, A). The stem is
attached by so-called stolons, or roots. In its normal growth at the
free end the hydroid has been shown by Loeb to exhibit marked
geotropic changes. If, for instance, the stem is bent over to one side
the new growth that takes place at the apex of the stem directs the
new part upwards in a vertical direction.

If pieces are cut from the stem of antennularia and suspended in

^ The dark red glass was fairly monochromatic; the dark blue let a trace of red light
through.

2 The same difference was found in this form in regard to heliotropism.

^ Palsemon and Sicyonia.

^ The regeneration of the lens of triton may also be affected by gravity.

EXTERNAL FACTORS OF REGENERATION IN ANIMALS

31

the water, regeneration takes place at the cut-ends. If a piece is
suspended with its apical end upwards (Fig. 14, B), a new stem devel-
ops at the upper cut-end, and new roots from the lower cut-end.
If a piece is suspended with its basal end upwards (Fig. 14, C), there
is formed at its upper (basal) end a new stem with its branches also
slanting upwards as shown in the figure. Roots appear at the

/

Fig. 14. — After Loeb. Normal stalk of Antennularia aniennlna. B. Piece regenerating in vertical,
normal position. C. Piece regenerating in inverted position. D. Piece regenerating in in-
clined, vertical position. E. Piece regenerating in inclined, inverted position. K Piece
regenerating in horizontal position.

lower (apical) end. Since gravity is the only force that acts in a
vertical direction under the conditions of the experiment, Loeb con-
cluded that it plays an important role in determining the kind of
regeneration that takes place. Its action is of such a nature that a
new stem develops from the upper cut-end, and roots from the lower
end, regardless of whether the upper end is the basal or the apical
end of the piece. Similar results are also obtained, according to

32 RE GENERA TION

Loeb, if the pieces are suspended obliquely. In a piece of this sort,
it is found that new stems arise along the upper surface of the old
stem, and roots from the lower surface as well as from the lower
cut-end (Fig. 14, D, E). If a piece of the stem is placed horizontally
on the bottom of an aquarium, the branches that come off from the
under surface of the stem begin to grow downwards at their ends,
and where they come in contact with a solid body they fasten them-
selves to it, thus showing that they are true roots (Fig. 14, F\ One
or more stems may arise from the upper side of the main stem.
These stems grow vertically upwards, and produce lateral branches.
Only in one case did a new stem, or stem-like structure, arise from
one of the vertical branches, as shown to the left in Fig. 14, F.

Loeb found it also possible to change the character of the growth
of the apex of the normal stem and to transform it into a root. A long
piece of the hydroid was cut off and suspended vertically with the
basal end upwards. From the upper end a new stem began to grow,
and then the entire piece was reversed, so that the new stem pointed
downwards. Under these circumstances the young stem did not
bend around and begin to grow upwards, as a yovmg plant might
have done, but it ceased to grow as a stem, and at its apex one or
more roots developed. Loeb concludes : " I cannot imagine by
what means the place of the formation of organs in antennularia
is determined in connection with the orientation of the animal except
by means of gravity."

The response of antennularia to the action of gravity is, I think,
conclusively demonstrated by Loeb's results, but that the phenomenon
may be complicated by other factors is shown, I think, by the follow-
ing experiments. Driesch found that if pieces of antennularia are
cut off and placed between horizontal plates, so that both ends are
free, roots are produced by the basal end.^ If the basal end with its
new roots is cut off, new roots may appear, but sometimes a thin
stem also. If the end is again cut off, a larger stem, and also one or
two roots, may appear, and if the operation is repeated again only
a stem is formed. The factor that brings about this change is not
shown by the experiment. The piece had been kept in a horizontal
position throughout the whole time. The apical end died in most
cases without producing roots, but it is not stated whether or not
roots appear on the stem between the plates of glass. If they
develop they may affect the result, as certain experiments that I have
made seem to show.

In my experiments, made at a different time of year from that at

1 Driesch does not give in his paper ('99) the position of the hydroids, or the method of
the experiment, but I can supply the details given above from a personal communication
from Driesch.

EXTERNAL FACTORS OF REGENERATION IN ANIMALS 33

which Loeb's experiments were made, pieces of the stem were sus-
pended vertically, — some with the apical end upwards, others with the
basal end upwards. In nearly all cases roots were formed by both
the upper and lower ends. In a few cases, in which the apical end
was upwards, a new stem developed at that end. Pieces suspended
in a horizontal position also produced roots at both ends. After
removing the ends with their new roots from the pieces suspended
vertically, I found that roots again appeared at both ends in nearly
every case. The difference between these results and those of Loeb
may be due to the time of the year at which the experiments were
made, or possibly to some other difference, but the results show that
the response to gravity is not always so constant as Loeb's results
indicate.

In a few cases in my experiments the basal end of the hydroid was
left attached to the stem on which it had grown, and the piece was
put into the same aquarium used for the preceding experiments. In
those pieces that lay on the bottom of the aquarium, with the stem
standing vertically, a new shoot, and not new roots, appeared on the
upper end. Other pieces were hung at the top of the water of the
aquarium with the stem turned downwards, and the basal, attached
end of the piece upwards. These pieces produced neither a stem nor
roots from the apical end. The results show that the presence of
roots at one end has an influence on the regeneration at the other
end. The same thing was shown in one case in which a short piece
sank to the bottom of the dish and, developing roots at its basal end,
became fixed : a stem grew out of the apical end.

A number of other experiments that I made, in which pieces of
antennularia were fixed to a rotating" wheel, gave negative results,
since neither roots nor stems appeared on the pieces. The rubbing
of the ends of the piece against the water as the wheel turned round,
or else the agitation of the water, prevented, most probably, the
regeneration from taking place.

How gravity acts on antennularia has not as yet been determined.
The only suggestion that we can offer at present is that it brings
about a rearrangement of the lighter and heavier parts of the tissues.
A rearrangement of this sort has been demonstrated when the &gg of
the frog is inverted, and in consequence certain changes are brought
about in the development that will be described in another chapter.

EFFECT OF CONTACT

The contact of a newly forming part with a solid body has been
shown by Loeb in a few cases, at least, to be a factor in regeneration.
If a piece is cut from the stem of the tubularian hydroid Tubiilaria

34

RE GENERA TION

mesembryanthemwn, and the piece held so that its basal end comes in
contact with a solid body, a root develops at that end. If a piece is
held in a similar position, but with its apical end in contact with
a solid body, a root does not develop from this end. Evidently the
development of a root in this form is also connected with an internal
factor ; but that there is in reality a reaction in this case, and not sim-
ply the development of a root at the basal end, is shown by the f ollow-

FlG. 15. — After Loeb. A. A piece of the stem of margelis placed in a dish. Roots come off
where stem touches dish, and polyps at other points. B. Piece of the stem of tubularia pro-
ducinsj a hydranth at each end. C. Cerianthus viembranaceus. Piece cut from side produc-
ing tentacles only on oral side of cut.

ing experiment : If a piece is cut from the stem and suspended so that
both ends are surrounded by water — it makes no difference whether
the piece is vertical or horizontal — a hydranth develops first on the
apical end, and then another on the basal end (Fig. 15, B^. When
the apical end of a piece is stuck in the sand, leaving the basal end
free, a hydranth develops on the latter, but not on the end in the sand.
In another hydroid, Margelis carolincnsis, studied by Loeb, the
effect of contact is more easily demonstrated. If a branch of margelis

EXTERNAL FACTORS OF REGENERATION IN ANIMALS 35

is put into a dish of water and is kept from all motion, the parts that
come in contact with the dish produce roots that attach themselves.
Even the apical end of the stem may grow out as a root, as shown in
Fig. 15, ^. Those parts of the branch that are not in contact with
any solid object give rise to new hydranths. Another hydroid, Pen-
naria tiarella, also shows, according to Loeb, the same response to
contact. In this connection it is interesting to find that a growing
hydranth of pennaria, if brought in contact with a solid body, turns
away from the region of contact and bends at right angles to the body
which it touches. We find, once more, that a factor having an influ-
ence on the growth of the animal has also a similar influence on the
regeneration.

Loeb has found that if pieces of the hydroid Campanularia are cut
off and placed in a dish filled with sea water, all the hydranths that
touch the bottom of the dish are absorbed and transformed into the
substance of the stem. The coenosarc may creep out of the stem
wherever it comes in contact with the glass, and produce stolons that
give rise to new polyps on their upper surfaces. Loeb shows that
growth takes place at the end of the stolon that pushes out of the
perisarc, and this growing region draws the rest of the coenosarc after
it. If a new hydranth appears along the old piece, the coenosarc is
drawn towards the hydranth.

EFFECT OF CHEMICAL CHANGES IN THE ENVIRONMENT

Temperature, light, gravity, and contact are the most familiar kinds
of external physical agencies that have a direct influence upon the
growth of organisms. Food, though coming from the outside, yet acts
only after it has entered the body. Organisms that live in water may
be affected by the quantity and the kinds of the salts contained in the
water, and also by the dissolved gases. The only experiments that
have been made to show the influence of this last class of agents on
animals are those made by Loeb. He placed pieces of the stem of
tubularia in sea water of different degrees of concentration. After
eight days the pieces, that had meanwhile produced hydranths, were
measured. It was found that the maximum growth in length takes
place, not in normal sea water, but in a much diluted solution. Loeb
interprets this result to mean that the cells of tubularia must have a
certain amount of turgidity in order to grow, and this is possible so
long as the concentration does not pass a certain limit. This limit is
reached by the addition of 1.6 grams of sodium chloride to each 100
c.c. of sea water. With a decrease in the concentration, the cells
become more turgid, the maximum point corresponding to the
maximum amount of growth. Below this point the solution is sup-

36 ■ REGENERATION

posed to act as a poison. The most important result of this experi-
ment is to show that the maximum growth does not take place in sea
water in which the animal is accustomed to live, but in a much more
dilute solution. Normal sea water contains about 3.8 per cent of
salts ; the maximum growth takes place in a solution containing only
2.2 per cent. Not only is the length of the stem greater in the latter
solution, but the thickness of the stem is also greater. The stem
is smaller in a solution containing more salt than that contained in
ordinary sea water.

There is another variant in these solutions which Loeb takes into
account. With the increase in concentration of the solution its power
of absorbing oxygen decreases, but the difference is too slight to
affect the main result.

Not only does the amount of salts in solution affect the osmotic
condition of the cells, but the salts also play a part in the metabolism
of the animal. As the result of a series of experiments, the details of
which may be here omitted, Loeb has shown that the regeneration of
tubularia takes place only when the salts of potassium and of magne-
sium are present. A very little of the potassium salt is necessary,
too much retards, and still more prevents regeneration.

There must be also a certain amount of oxygen dissolved in sea
water in order that regeneration may take place. If a piece of the
stem of tubularia is cut off and one end pushed into a small tube
that fits the stem closely, and if the tube is then stuck into the sand
at the bottom of an aquarium, a hydranth develops only at the free
end of the piece, and none at the end in the tube. The result
appears to be due to the lack of oxygen. If the piece is then taken
from the tube, a hydranth may appear at the end that has been in
the tube.

Another experiment shows the same result even more clearly. If
a piece of the stem is suspended freely in the water, so that its lower
end is almost in contact with the surface of the sand, but does not
quite touch it, no regeneration takes place at the lower end. This
result is interpreted by Loeb as due to the lack of oxygen in the
water near the surface of the sand.^

GENERAL CONSIDERATIONS

In connection with the action of external factors on regeneration it
is evident that in some cases they may not be in themselves necessary
for the growth of a new part, yet when growth takes place they may
determine what sort of a part is produced. For instance, if gravity

ijacobson has shown that the layer of water just above the sedimentary layer at the
bottom is poor in oxygen.

EXTERNAL FACTORS OF REGENERATION IN ANIMALS 37

determines the kind of regeneration in antennularia, it is possible that
if the regenerating piece were placed on a rotating wheel, the piece
might still produce a new stem at the apical end, and roots at the
lower end. In an experiment of this sort that I made, the pieces did
not, it is true, regenerate at all, but this was probably due not to the
change of position in regard to gravity, but to agitation of the water,
or to the rubbing of the cut-end against the water. It is also possible
that in this form the attachment of the piece at one end may be a
factor that may counterbalance the action of gravity. Other factors,
such as food, or temperature, or oxygen, appear not to determine the
kind of product that results, but only the rapidity with which the
change takes place. The salts in solution seem also to act on
the rate and extent of the new growth, but possibly other cases may
be found in which the kind of regeneration may also be affected by
the salts.

It is important to find that those animals whose growth and regen-
eration are influenced by such external factors as light, gravity, and
contact are attached animals that stand in a constant relation to these
physical agents. They form only a very small part of the entire
number of animals in which regeneration takes place. Animals
that constantly move about are not, as a rule, influenced during
their growth and regeneration by gravity and contact, and under
natural circumstances they are always changing their position in
regard to these agents. Temperature, and food, and substances in
solution act alike on fixed and free forms, and they are, it appears,
both influenced in the same way by these agents. The most signifi-
cant fact that has been discovered in connection with the influence of
external factors on regeneration is that the same factors that influ-
ence the normal growth of the organism also affect in the same way
the regeneration.

As yet an analysis of the external factors that influence growth has
not been made out as completely for animals as for plants, especially
in those cases in which the result is determined by several factors
at the same -time. An examination of the factors that influence
regeneration in plants will be made in a later chapter. First, how-
ever, the internal factors of regeneration in animals will be consid-
ered.

CHAPTER III

THE INTERNAL FACTORS OF REGENERATION IN ANIMALS

The comparatively few cases in animals in which regeneration has
been shown to be influenced by external factors have been given in
the preceding chapter. In all other cases that are known the factors
are internal. By this is meant that we cannot trace any direct
connection between the result and any of the known external agents
that have been shown in other cases to have an influence on regener-
ation. Certain external conditions must, of course, be present, such
as a supply of oxygen, a certain temperature, moisture in some cases,
etc., in order that the process may go on, but they are without
influence on the kind of regeneration, and are necessary for all parts
alike.

POLARITY AND HETEROMORPHOSIS

Trembley, Spallanzani, and Bonnet knew that, in general, at the
end of a piece of an animal from which a head has been cut off a
new head develops, and from the posterior cut-surface of a piece a
new posterior part is regenerated. Allman was the first to give the
name "polarity" to this phenomenon. ^

In several animals regeneration takes place more readily from one
end than from the other of the same cut, and this difference seems
to be connected with the kind of new part that is to be regenerated,
and not with the actual power of regeneration of the region itself.
For instance, if a short piece is cut from the anterior end of an earth-
worm, a new anterior end is quickly regenerated from the anterior
cut-surface of the posterior piece, but no regeneration takes place, or
only after a long time, from the posterior cut-surface of the anterior
piece. These relations are reversed if the posterior end of a worm
is cut off. There regenerates very quickly a new posterior end from
the posterior cut-surface of the anterior piece, but no regeneration
takes place, or only after a long time, from the anterior cut-surface of
the posterior piece. The new structures that develop after a long
time from the posterior surface of a short anterior piece, and from

1 "There is thus manifested in the formative force of the tubidaria-stem a well-marked
polarity, which is rendered very apparent if a segment be cut out from the centre of the
stem." Allman ('64).

38

INTERNAL FACTORS OF REGENERATION IN ANIMALS

39

the anterior surface of a short posterior piece, correspond to a differ-
ent part of the worm from that which would be expected to develop,
if the polarity of the piece is taken into account. Another reversed
head develops on the posterior cut-surface of the anterior piece, and

Fig. i6. — A. Head of Planar ia lugubris with line indicating level at which A^ was cut off.
^1. Head of last regenerating a new head at its posterior end. B. Piece oi P. maculata re-
generating head at each end. C. Posterior end of Allolobophora fcetida regenerating a new
tail at its anterior end. C^. Enlarged anterior end of last with new tail. O^. Tip of new tail.
D. Anterior end of one individual of A. fcetida, grafted to anterior end of another worm,
leaving posterior end of piece exposed. This has begun to regenerate. E. After Hazen.
Similar experiment in which a new head regenerated at posterior end of grafted piece.
F. Two longer pieces of A. fxtida united by anterior ends. One end was subsequently cut
off and a new tail regenerated. G. End of a developing piece of Tubularia mesembryanthe-
vium that had been cut off; it has regenerated, at its proximal end, another proboscis.

another tail on the anterior end of the posterior piece. The polarity
of the new part is in this case reversed, as compared with that of
the piece from which it arises. In the earthworm there is a marked
delay in the regeneration of these heteromorphic parts. Even in
tubularia in which heteromorphosis takes place, there is usually a

40 ' REGENERATION

delay of twenty-four hours in the formation of the reversed head.
In Planaria htgiibris, in which a reversed head develops, if a piece is
cut from the anterior end just behind the eyes, the delay in the for-
mation of the reversed head is very shght, if indeed there is any
delay at all.

In the earthworm and in the planarian the production of reversed
structures appears to be connected with the part of the body through
which the cut is made, and to be due to internal factors. The ques-
tion arises whether the presence of certain organs at the exposed
surface can account for the result. It is conceivable that if such
organs are present, and produce new cells that go into the new
part, the presence of such cells may be the factor that determines
what the new part will become ; and in consequence the polarity
of the part may be reversed. For example, the presence of the
cut-end of the oesophagus or of the pharynx at the posterior sur-
face of the anterior piece of the earthworm may determine that a
new pharynx develops at the cut-end, and this may in turn act on
the rest of the new tissues in such a way that a head rather than a
tail is formed. When a posterior piece is cut off, the presence of the
stomach-intestine at the cut-end may inliuence the new part, so that a
tail is produced. It can be shown, however, that a new head may
arise at the anterior end of a piece that contains only the stomach-
intestine, as sometimes occurs when the worm is cut in two anterior
to the middle ; and it is not improbable that a tail can be produced
from the posterior end of a piece that contains the old oesophagus,
and perhaps even the old pharynx. In the planarian I have espe-
cially examined this point, but I have not yet found that the result
can be referred to the cut-surface passing through any particular
organ, or to the absence of any organs at the cut-end.

If, instead of referring the result to any one organ, we assume that
the tissues near the cut-ends are specialized in such a way that they
can only produce their like, and that the sum total of tissues of this
sort making up the new part determines the result, we can only sug-
gest that this may be so, but we cannot show at present that it is so,
or that the result could be brought about in this way.

We might make an appeal to the hypothesis of formative stuffs,
and assume that there are certain substances present in the head, and
others in the tail, of such a sort that they determine the kind of dif-
ferentiation of the new part ; but this view meets also with serious
objections. In the first place, it gives only the appearance of an
explanation because it assumes both that such stuffs are present, and
that they can produce the kind of result that is to be explained.
Until such substances have been found and until it can be shown that
this kind of action is possible, the stuff-hypothesis adds nothing to

INTERNAL FACTORS OF REGENERATION IN ANIMALS

41

the facts themselves, and may withdraw attention from the real solu-
tion of the problem.

Bonnet, who first proposed the hypothesis of specific stuffs, went
further and assumed also that they move in definite directions in the
body, the head-stuff flowing forward and the tail-stuff flowing back-
ward. It was necessary to assume definite movements of the stuffs
in order to account for the development of the head at the anterior
end of a piece and of a tail at the posterior end. In cases of hetero-
morphosis of the sort described above, these stuffs, if they brought
about the results, would have to move in opposite directions from those
assumed in the hypothesis ; or else that part of the hypothesis that
postulates the movement of the substances must be dropped, and in its
place there must be substituted the idea of the excessive amount of
such substances in the ends accounting for the heteromorphosis. An
hypothesis that must be changed in this fundamental way to explain
both classes of facts cannot be given very serious consideration. Of
these possible ways in which it has been
attempted to account for the phenomenon
of heteromorphosis, the first one suggested
seems to me simpler and more probable, but
which organs are to be made responsible
for the result cannot at present be stated.
The fact that both Bardeen and I have ob-
tained heteromorphosis in planarians in
other regions than in the head indicates
at least that other factors than the presence
of head tissues or of head substances may
bring about the development, and if it can
be discovered what produces the result in
regions remote from the head we may be
in a position to explain the result in the
head region in the same way, although it may
be, of course, that the same result may be
brought aboijt by different factors, when the
internal conditions are somewhat different.

Another phenomenon connected with
the polarity of a piece is shown by Ceri- fig. 17. - After Voigt. Pianarian
anthus membranaceous. When a triangular ^i'h three oblique cuts at side.
piece is cut from the side of the body, a half
circle of tentacles appears around the lower
edge of the cut, as shown in Fig. 15, C.
The presence of a free distal edge on the
lower side of the opening is a sufficient
stimulus to call forth the development of tentacles.

Tlie most anterior cut (left
side), directed forward, pro-
duced a tail. The one on the
right side, directed backwards,
produced a head. The most
posterior cut (left side) made
a head with pharynx, and also
a tail-like outgrowth.

42

REGENERA TION

A somewhat similar result is obtained when an incision is made in
the side of the body of a planarian. A lateral head may grow out
from the anterior edge of the cut-surface, as shown in Fig. 1 7.

It has been shown by Loeb that if the incurrent siphon of the ascid-
ian Ciona intestinalis be partially cut off, new eye-specks develop
around the margin of the cut, as shown in Fig. \Z, A. I have repeated

Fig. 18. — A. After Loeb. Anterior end of Ciona intestinalis with oral-siphon partially cut off.
Eye-specks regenerate, both on oral and aboral edge. B. Same (after T. H. M.), showing
similar result on excurrent siphon.

this experiment and obtained the same result, and found, as had
Loeb also, that the same holds true for the excurrent siphon (Fig.
18, B\ In these cases the new eyes appear both on the anterior
and posterior edges of the cut. Most probably the result is con-
nected with an external stimulus, rather than with an internal one.
This may be true also for cerianthus, but probably not for the
planarian.

INTERNAL FACTORS OF REGENERATION IN ANIMALS 43

LATERAL REGENERATION

Since the most familiar cases of regeneration are those that take
place at the anterior and posterior ends, we not unnaturally come to
think of polarity as a phenomenon connected only with the long
axis of the animal ; but there are also many cases of lateral regenera-
tion in which a similar relation can be shown. In such a case as the
regeneration of the leg of a salamander, or of a crab, we find
instances of lateral regeneration, but since the development takes
place in the direction of the long axis of the leg, the polarity of the
leg may be thought of as substituted for that of the body. In other
animals, however, the regeneration is strictly lateral. I have found
that if the anterior end of an earthworm, or even of lumbriculus, is
split lengthwise in halves, and then one of the half-pieces is removed,
the missing half is replaced by the half left attached to the rest of
the worm. Trembley split a hydra lengthwise into two pieces, and
each piece bent inwards to make a new tubular body. Bickford,
Driesch, and I have obtained similar results with pieces of the stem
of tubularia.

In planarians which have a flat, broad body, lateral regeneration
takes place readily. If a worm is split in two along the middle line
of the body (Fig. 13^, A), each half regenerates the missing half.
This is brought about by the development of new tissue along the
cut-side, and the extension into the new part of outgrowths from the
digestive tract. Lateral regeneration also takes place if the worm
is split lengthwise into two unequal parts. In this case the larger
piece produces new material along the cut-side, and into this new
part the branches of the old digestive tract extend. The smaller
piece also produces new material along the cut-side, a new pharynx
appears along the line between the old and the new tissue, and a new
digestive tract is formed out of the remains of the old one (Fig.
19, a, b, c). New branches grow out of the fused part into the
new tissues at the side. The new worm that develops from a piece
that is less than half the width of the old worm is about as wide as
the piece that was cut off, for what is gained at the cut-side is lost
in the old part. The piece loses in length also during regeneration.
If the new worm is fed, it increases in size, gaining in breadth both
on the old side, as well as on the new side, and in time it becomes a
full-grown, symmetrical worm.

In the formation of the new part in these cases of lateral regenera-
tion it is not difficult to understand how some of the old organs, as
the digestive tract, grow out laterally into the new part ; but it is
more difficult to see how longitudinal organs, such as the nerve-cord
and genital ducts, are formed anew. Bardeen, who has examined the

44 REGENERATION

development of the new nerve-cord in lateral pieces, thinks that the
new nerve-cord grows backwards in the new part from the brain that
develops at the anterior end, either out of the old brain, if it, or any
part of it, is left, or out of the new brain that develops from the
anterior end of the lateral cord that is present in the piece. What
takes place in pieces cut so far to one side that none of the old cord
is present in the piece he did not make out ; but I can state that a

new brain develops even when none
of the lateral cord is present.

The development of a new head
in pieces cut to one side of the old
median line offers some facts of
interest. A piece may be cut from
the side of a planarian of such a
shape that it has no anterior sur-
FiG. 19. — Indicating how a piece is cut off ^3-^6 at all (Fig. 1 9, ^); yet a head

from side of Flanaria maculata. a, b, dcVClopS at the anterior end of the
c. Regeneration of last. d. Regenera- • 1 i i

tion of single liead at side. ^. Regenera- UCW material that appears at the

tion of two heads at side. ^-^^^ j^ ^^^^^^ ^^ ^^^^ ^^ ^^^ g-^^^

later it assumes an anterior position. In this case an axial structure
arises in a lateral position, unless we look upon the new head as
arising at the anterior end of the new part, rather than at the side
of the old, but there is no evidence in favor of such an interpretation,
since the head arises at the same time as does the rest of the new
material at the side. In a small piece all of the new material at the
side may be used to form the new head (Fig. 19, d). Sometimes
two heads develop (Fig. 19, e).

REGENERATION FROM AN OBLIQUE SURFACE

There are also certain important facts connected with the regen-
eration from an oblique surface. The first case of the sort was
described by Barfurth. He found that if the tail of a tadpole is cut
off obliquely, as shown in Fig. 20, B, the new tail that develops stands
at first at right angles to the obhque surface. The angle that the
new tail makes with the axis of the old tail will be in proportion to
the obliquity of the cut-surface. The notochord that occupies the
centre of the new tail begins at the end of the old notochord, and
extends to the tip of the new tail, dividing it in the same proportion-
ate parts as does the notochord of the normal tail. The other organs
occupy corresponding positions. As the new tail becomes larger it
slowly swings around into line with the old part. This phenomenon
of regeneration from an oblique surface has been found in a number
of other forms. It has been described by Hescheler, and by myself

INTERNAL FACTORS OF REGENERATION IN ANIMALS

45

in earthworms (Fig. 20, D), both for the anterior and posterior ends.
I have shown that it also takes place in the tail of a teleostian fish,
fundulus (Fig. 20, C), and have offered the following explanation of
the phenomenon. The new material that is first laid down is, to a
certain extent, indifferent as regards its axes. A symmetrical struc-

FlG. 20. — A, A^. After Driesch. A. Piece of stem of tubularia cut off obliquely, showing oblique
position of tentacles. A^. Same, later stage. B. After Barfurth. Tail of tadpole regenerat-
ing from oblique surface. C. Tail of fundulus regenerating from oblique surface. D. After
Hescheler. Anterior end of allolobophora regenerating from oblique surface. E. Piece of
planaria, cut off by two oblique cuts, regenerating new head and tail. F, F'^, F'^. Three
stages in the development of a new head (of a piece of bipalium) at anterior end of oblique
surface.

ture is then formed, with the old edge as a basis. The median
point of the cut-edge connected with the median point of the outer
surface of the new edge, gives the axis of symmetry of the new tail.
The other regions assume corresponding positions. In the tail of
the tadpole the position of the new notochord is determined by the

46

RE GENERA TION

cut-end of the old notochord and the median, outer point of the new
material, and since the new material is at first equally developed
along the cut-edge, or at least symmetrically developed, the new tail
must stand at right angles to the cut-edge. This explanation will
cover, I think, all cases of regeneration from an oblique surface. It
assumes a law of symmetry in the new material that is in accordance
with the observed position in which the new structure appears. The
hypothesis makes no pretence to explain why the new structures
sJioiUd assume a symmetrical position, but given that they do, the
observed result follows.

There are certain peculiarities connected with the regeneration
from an oblique surface in planarians that may be considered in this
connection. If the worm is cut in two by means of an oblique cut,
as shown by the oblique line in Fig. 21, B, the new head that appears

Fig. 21. — Planaria lugubris. Upper row. A. Part of head cut off obliquely; a-a^. Regenera-
tion of new head. Lower row. B. More of head cut off obliquely ; b-b'^. Regeneration of
same.

on the anterior cut-surface of the posterior piece appears at one side
and not in the middle of the oblique surface (Fig. 21, B, b). The new
head stands at right angles to the cut-surface. The anterior piece of
the worm produces a new tail at the side of the posterior cut-surface,
in the same way that the tail is formed in Fig. 20, E. The tail
also stands at right angles to the cut-surface. The new pharynx

INTERNAL FACTORS OF REGENERATION IN ANIMALS

47

that develops in a piece of this kind appears in the middle of the pos-
terior cut-surface, between the old and the new parts. It may extend
somewhat obliquely in the new part, and point toward the new tail.

If a piece is cut from the anterior part of a worm by two oblique
and parallel cuts, the new head appears at one side of the anterior
cut-surface, and the new tail at the other side of the posterior cut-
surface. The new pharynx appears in the new material of the pos-
terior part in the middle line. Thus the middle lines of the new
head and tail and pharynx lie in different positions, yet these parts are

Fig. 22. — Two upper rows Planar ia liigubris. Lower row Flanaria maadata. Upper row.
Tail-piece cut off obliquely in front of genital pore. Figures show mode of regeneration.
Middle row. Piece including old pharynx cut off by two cross-cuts, regenerating head and
tail. Lower row. Piece cut off as last, regenerating head and tail.

subsequently brought into the same line. This is done by the head ex-
tending more forward and becoming broader, the tail growing backward
and also becoming broader. The old piece becomes narrower at the
same time. These three changes going on simultaneously produce a
new symmetrical worm. In one form, Planaria liLgiibris, the symmetri-
cal form is reached largely by the forward growth and the enlargement
of the head, and the growth backward and the enlargement of the
tail (Fig. 22, B). In Planaria maailata the old part shifts, so that it
forms a new median line connecting the median line of the new head

48 REGENERATION

and new tail. This is best shown when the piece includes the old
pharynx (Fig. 22, C). The pharynx is also shifted, so that its anterior
end points towards the side at which the new head lies, and its pos-
terior end towards the new tail. The result is that a new symmetri-
cal worm is formed, as shown by the series of figures in Fig. 22, C.
In Planaina maculata the changes take place largely in the old part,
and the old material extends throughout the entire length of the new
worm. In Planaria lugiibris the change takes place largely in the
new parts (Fig. 22, B). The general method in the latter species by
which the symmetry is attained can be best shown by cutting the
worm in two by an oblique cut just in front of the genital pore (Fig.
22,^). The posterior piece produces a new head at the side, and a
new pharynx appears along the border between the new and the old
parts, as shown in these figures. Its posterior end touches the middle
line of the old part, and from this point it extends obliquely across
the new tissue towards the middle of the new head. As regenera-
tion goes on the new head is carried farther forward, it becomes
larger, and the main region of new growth is found to be, in the fig-
ure, to the left side of the new part. As a result of these changes the
new head turns forward, and comes to lie nearer the middle line of
the old part. The pharynx is also turned more forward, and finally,
as the new parts enlarge, the symmetrical form is produced. The
internal factors that are involved in the development of these oblique
pieces are very difficult to analyze. The position of the new head
and tail at one side of the cut-edge is the most difficult phenomenon
of all to explain. We may, I think, safely regard the first new mate-
rial that is proliferated along the cut-edge as totipotent, and our spe-
cial problem resolves itself into discovering what factor or factors
determine that the new head is to form at the most anterior end of
the new material, and the new tail at the most posterior end. If we
assume that the result is in some way connected with the influence
of the old part on the new, and that this influence is of such a sort
that the more anterior part of the old tissue determines that one side
of the head must be at the most anterior edge, we have at least a
formal explanation of the position of the head at the side. Given the
position of the new head fixed at one side, its breadth will be determined
by the maximum breadth possible for the formation of a new head.
This is also in part an assumption, but it has at least certain general
facts of observation in its favor. The oblique position of the new
head is the result of its symmetrical development in the new material
in the same way that the position of the tail of the fish or of the tad-
pole is the result of the symmetrical formation of the new tail on the
oblique surface. The subsequent changes, by means of which a sym-
metrical worm is developed, are the result of different rates of growth

INTERNAL FACTORS OF REGENERATION IN ANIMALS

49

in the different parts. In this connection the most important fact is
that the growth takes place most rapidly where it will bring about the
new form. This problem, which is one of the most fundamental in
connection with the phenomena of development and of regeneration,
will be more fully discussed in a later chapter.

A number of assumptions have been made in the above attempt to
give an analysis of the formation of a head at the side of an oblique
surface. That these assumptions are not entirely arbitrary, but have
a certain amount of evidence in their favor, can, I think, be shown.
The new material that first appears is supposed to be totipotent, in
the sense that any part of it may produce any part of the structure
that develops from this material. That this is probable is shown by
the following experiment. If a cross-piece is cut from a worm, and
then split lengthwise into halves, each half will produce a new head
at the anterior edge of the piece. This result shows, at least, that
from the tissue lying to the right or to the left of the middle line new
material may be formed from which a whole head may develop. The
new head does not stand at first with its middle axis in line with the
middle of the old piece, i.e. it does not stand squarely at the anterior
end of the half-piece, but more towards the inner side of the piece.
It may appear that the old part has sufficient influence on the new
part to shift the axis of the latter toward the old middle line, but
while some such influence may be present, it is probable that the posi-
tion of the head is in part the outcome of another factor, viz. the
presence at the inner side of the piece of an undeveloped new side,
with which the explanation of the less development of the inner side
of the head is also connected.

If a cross-piece is cut from a worm and kept until a small amount
of new tissue appears over the anterior and posterior cut-surfaces,
and if then the piece is split in two lengthwise, there will develop
from each piece a new head out of the new material over the anterior
surface. The result shows
that the new material is at
first totipotent, in the sense
that it may still produce
one or more heads accord-
ing to the conditions. It
is possible, of course, that
the formation of the new
head may have begun at the time of the experiment, but if it had,
the development had not gone so far that a new arrangement was
impossible. If, however, the piece is not cut lengthwise until just
before the formation of a head (Fig. 23, ^4), then each half-piece pro-
duces at first a half-head, that completes itself later at the cut-side.

Fig. 23. — Planar ia maculata

Cross-piece, allowed to

regenerate, then cut in two lengthwise, as indicated by
line. a-a^. Regeneration of left half.

e?^^•

-S^i

'y/r.

,fv

CO ^ ^ REGENERATION

CT-1I!I19 ;

Ano^'fer experiment shows even more satisfactorily that the

^/g p •;|T^'fcfepaf over an anterior cut-edge may produce one or more new heads

' according to the conditions, and that the result is not connected with

the region from which the new material is derived. If the anterior

end of a planarian is cut off and then an oblong piece is removed from

the middle of the worm, as shown in Fig. 24, A, it will be found, if

Fig. 24. — Planar ia lugubrls. A. Showing where a piece, 4, was removed from middle of a
worm, a, b. Regeneration of a single head, c, cK Regeneration of two heads. £>, £, F. Re-
generation of small piece, 4, that was cut out.

the side parts are kept from fusing together in the middle line, that a
new head develops at the anterior end of each part, as shown in Fig.
24, c, c^. If, on the other hand, the two sides come together and fuse
in the middle line, as shown in Fig. 24, a, b, the new material that
appears over their anterior ends becomes continuous and produces
a single head. In this case, although the middle part of the old
tissue has been removed, a single head develops that is normal in all
respects, and the eyes are not nearer together than when the middle
part is present, as when regeneration takes place from an anterior
cross-cut surface.

The assumption that the lateral position of the head on an oblique
surface is connected with the more anterior region of the old material
that is found at that side, can be made at least more intelligible by
the following experiment : If the head of a planarian is cut off
obliquely, as indicated in Fig. 21, B, so that one of the "ears" is left
at one side, the new head arises at the side in connection with the
part of the old head that lies at that side. The new head does not
extend over the entire cut-surface, which is longer of course than a
cross-cut would be, but lies at one side, as in the other cases just
described. In this case we can see that if the new head cannot, on
account of certain conditions, extend over the entire cut-surface, one
side of it may be determined by the presence of a part of the old head.

INTERNAL FACTORS OF REGENERATION IN ANIMALS 51

and this influence may be stronger than any other that might tend
to locate the new head in the original middle line. If we suppose
that similar conditions prevail in all cases when oblique surfaces are
present in these worms, we have a formal solution of the problem.
The argument cannot be convincing unless we can give a further
explanation of the nature of this influence that the old part has upon
the new.

In other cases, as in the regeneration from an oblique surface in
the tail of the tadpole and of a fish, we must assume that the factor
that determines the middle of the new part has a stronger influence
on the new material than has the most posterior part of the old
tissue.

The influence of an oblique cut-surface on the position of the
new parts is shown in a different way in the hydroid, tubularia.
The conditions are different in this case inasmuch as there is no
proliferation from the cut-end, but the old part produces the new
hydranth. Driesch found that if the stem of tubularia is cut in
two obliquely, the new tentacles, that develop as two rings around
the tube near its cut-end, stand obliquely on the stem,^ as shown in
Fig. 20, A. In most cases, both the distal and the proximal circles
of tentacles lie obliquely to the long axis of the stem, but there is
some variability in the result, and occasionally one or the other,
especially the proximal circle, may be squarely placed, although, as
a rule, the influence of the oblique cut-end can be seen. It can be
shown, I think, that the oblique position of the rings of tentacles in
tubularia is the outcome of factors different from those that are
found in the regeneration of the tail of the tadpole and of the head
and tail of the planarian. Driesch suggested that the distance of
the tentacle-rings from the cut-end is the result of some sort of
"regulation " that determines their position at a given distance from
the region at which the surrounding water acts on the exposed end.
Hence, if the exposed surface is an oblique one the rings will also
be formed in an oblique position. On the other hand, I have sug-
gested that we can imagine the regulation to result from other
factors. At the beginning of the development, and before the
tentacles appear, there is a withdrawal of tissue from the cut-end
that leaves the region from which the proboscis develops quite thin.
If this material withdraws at a uniform rate and to the same distance
at all points from the end of the piece, as observation shows to be
the case, and if, as appears also to be true, the outer end of the distal
ring of tentacles lies at the inner end of the proboscis region, then
it too will assume an oblique position if the cut-end is oblique. If
we imagine a similar series of regulations taking place throughout

1 The same holds good for the basal hydranth if it arises near an oblique end.

52

RE GENERA TION

A B

Fig. 25. — Piece of stem of Tubularia mesembry-
anthetnu?n split in two lengthwise. Forma-
tion of whole hydranth that turned away
from contact with old perisarc.

the piece, we can account for the
results. On this hypothesis the
action of the water on the free
end need not be a factor in the
result, but the oblique end is itself
sufficient to determine the series
of regulations, or mass-relations,
that lead to the laying down of
an oblique hydranth.

When the hydranth protrudes
from the stem it assumes an
oblique position, as shown in Fig.
20, A^. Driesch supposed the
oblique position of the hydranth
to be due to an oblique zone that
develops behind the hydranth, but
the result can best be explained,
as certain other experiments that
I have made seem to show, as
due to the negative thigmotropism
of the hydranth at the time it pro-
trudes from the old perisarc. It
turns away from the projecting
side of the oblique end of the
perisarc, as it does from any solid
body with which it comes in con-
tact. That this is the case is best
shown by splitting the stem length-
wise into halves. In this case,
although the two circles of ten-
tacles may be laid down squarely
(Fig. 25, A), the new hydranth
protrudes at right angles to the
old perisarc, as shown in Fig.
25, B.

THE INFLUENCE OF INTERNAL ORGANS AT THE CUT-SURFACE
ON THE NEW STRUCTURE

In a few cases it has been discovered that the presence of certain
organs at the exposed surface is necessary in order that regenera-
tion may take place. The following experiment that I have recently
carried out shows, for instance, the influence of the nerve-cord on
the regenerating part. A few of the anterior segments of the earth-

INTERNAL FACTORS OF REGENERATION IN ANIMALS

53

B

wzx

B

worm are cut off, as shown in the left-hand figure in Fig. 26, and
then a piece of the mid-ventral body wall of the worm is cut out,
a part of the ventral nerve-cord being removed with the piece. The
cut-edges meet along the mid-ventral line and fuse, closing the
wound. As a result of the operation there is left exposed, at
the anterior end of the worm, a cut-surface with all of the internal
organs present except the nervous system. The anterior end heals
over, but I have not observed the development of a new head at this
level, although the exposed end is in a region at which, under
ordinary circumstances, a new head readily regenerates. In several
cases a new head developed at the
point where the cut-end of the ner-
vous system is situated, i.e. at the
level B in the figure.

A variation of the same experi-
ment shows still more conclusively
the importance of the nervous sys-
tem for the result. A few anterior
segments are cut from the anterior
end as before. A cut is made, as
shown in the right-hand figure in
Fig. 26, to one side of the mid-ventral
line (indicated by the black line in
the figure at the level A). Then, at
the posterior end of this cut a piece
is removed from the mid-ventral
line as in the former experiment
(shown by the stippled area in the
figure). A portion of the ventral
nerve-cord is removed with the piece.
As a result of this operation, two
anterior ends of the nervous system
are left exposed (shown by the black
dots in the figure). At the anterior
end of the worm, i.e. at A, there is
one exposure, and at the posterior
end of the region from which the
piece was removed there is another.
Two heads develop in successful
cases, one at the anterior end of the anterior cut-surface, i.e. at A,
and the other at B.

The results show that in the absence of the cut-end of the nervous
system at an exposed surface a new head does not develop ; and con-
versely, the development of a new head takes place when the anterior

i^

_>

Fig. 26. — Left-hand figure X sho\^■s how,
alter cutting oft' the anterior end oiAllolo-
bophora fcEtida, a piece of the ventral
wall (including a part of the nerve-cord)
is cut out. Right-hand figure Y illus-
trates a more complicated operation, in
which the piece of the ventral wall that
is cut out is a little behind the anterior
end.

54 REGENERA TION

end of the nervous system is present at a cut-surface, even when such
a surface is not at the anterior end of the worm. We may perhaps be
able to extend this statement, and state that as many heads will
develop as there are exposed anterior ends of the nervous system.

In two other cases, at least, a somewhat similar conclusion may be
drawn, although it appears that in these cases other organs than the
nervous system may be the centres around which the new parts
develop. Tornier has shown that when the vertebrae of the tail of
the lizard are injured, the new material proliferated by the wounded
surfaces serve as centres ^ for the regeneration of new tails ; and
Barfurth has found that the notochord in the tail of the tadpole plays
a similar role in the formation of a new tail. These experiments will
be more fully described in connection with the formation of double
structures, but from what has been said it will be seen that the cases
are parallel to that of the earthworm.

Until more has been discovered in regard to the internal factors of
regeneration, it would be venturesome to make any general statement
based on these few cases, but there is opened here a wide field for
experimental work. By eliminating one by one the different organs
that are present in the old part, it may be possible to discover much
more in regard to the internal conditions that are necessary in order
that the process of regeneration may take place.

THE INFLUENCE OF THE AMOUNT OF NEW MATERIAL

There are certain results connected with the amount of new mate-
rial which is produced during regeneration, that should be considered
in connection with the question of internal factors. It has been
pointed out that when one segment only is removed from the ante-
rior end of the earthworm only one new one returns ; when two
are cut off two come back, and this holds good up to five segments.
Beyond this, no matter how many are removed, only five at most come
back. The latter result seems to be connected with the amount of
material that is formed over the cut-surface before differentiation
begins. When only one or two segments have been cut off, the new
material that is formed is soon suflEicient in amount for the production
of one or two new segments, but when three to five are cut off some-
what more material is formed before differentiation begins. When
more than five are cut off the new material is at best only sufficient
to produce five new ones, and in some cases even a smaller num-
ber is formed. This hypothesis assumes that there is a lower limit
of size for the formation of new segments below which a segment

^ Although it is by no means certain that the results may not be due in part, at least, to
injuries to the nervous system.

INTERNAL FACTORS OF REGENERATION IN ANIMALS 55

cannot develop. The interpretation is fully in accordance with what
we know to be the case for small pieces of hydra and of other forms
that, below a certain minimal size, do not regenerate. The question
as to how many segments are formed out of the new part is determined,
not only by the amount of new material, but also by the number of
segments to be replaced, at least up to five segments. Beyond this
limit we may think of the maximum possible number of segments
appearing in the new material. That a relation of some sort obtains
between the old and the new parts, that may have an influence
on the number of the new segments which are formed, is shown by the
fact that, when one, two, three, four, or five are cut off, just this
number comes back. A sort of completing principle exists as a
factor in the result, but when so much has been cut off that the old
part cannot complete itself in the new material that is formed, then
other factors must determine how many segments will be produced.

In planarians we find a similar phenomenon. If much of the
anterior end is cut off, only a head is formed at the anterior cut-
surface of the posterior piece, and the intermediate region is
absent. I interpret this in the same way as the similar case in the
earthworm. As soon as enough new material has been formed
for the anterior end to appear, it begins to develop, and since it can-
not develop below a certain minimal size, or rather, since the ten-
dency to produce a head approaching the maximum size is stronger
than the tendency to produce as much as possible of the missing
anterior end, all the new material goes into the new head. In the
planarian the possibility of subsequently replacing the missing region
behind the head exists, and the intermediate part is later pro-
duced, the head being carried farther forward. The same is true of
the new posterior end of the earthworm, in which a growing region
is established at a very early stage in front of the tip of the tail,
but no such growing region is present at the anterior end in the
earthworm. These differences appear to be connected with the
general phenomena of growth in these forms. In the planarian
interstitial growth can take place in any part of the body, hence the
possibility of producing a missing region is present in all parts of
the worm ; but in the earthworm we never find new segments inter-
calated at the anterior end during normal growth, nor does this
take place during regeneration. At the posterior end of the earth-
worm we find a region of growth in which new segments are pro-
duced, and we find the same thing is true in the regeneration of the
posterior end. In other words, the growing region in front of the
last segment is also regenerated.

It has been found in several forms that pieces below a certain size
do not regenerate. In those cases in which a small piece dies soon

$6 ' REGENERATION

after its removal from the rest of the body we have no direct means
of knowing whether or not the piece has potentially the power to
regenerate, but in some other cases, in which small pieces may be
kept alive for some time, they may not regenerate. Furthermore,
the regeneration of small pieces that are just above the minimal size
is often delayed and is sometimes imperfect. These small pieces
seem to meet with a greater difficulty in regenerating than do larger
pieces. Peebles has shown that pieces of hydra that measure less
than \ mm. in diameter (= about ^\-^ of the volume of hydra) do not
regenerate, although if very small pieces are taken from a develop-
ing bud they may regenerate, even when only \ mm. in diameter.
Very small pieces that are, however, just above the minimal size,
while they may assume a hydra-like form, produce only one or two
tentacles. The failure of the smallest pieces to regenerate is not
due to their dying, since they may live for a much longer time than
would suffice for larger pieces to regenerate. Isolated tentacles of
hydra do not produce new hydras, although they may remain alive
for some time. A single tentacle is larger than the minimal piece,
so that its failure to regenerate is probably connected with the differ-
entiation of the tentacle, rather than with its size. The lack of
power to regenerate in the smallest pieces of hydra cannot be con-
nected with the absence of any special organ,
since these pieces contain both ectoderm and
endoderm. In tubularia also, Driesch and
I have found that pieces below a certain size
do not regenerate (Fig. 27). There is likewise
in planarians a lower limit of regeneration,
even for pieces that contain all the ele-
ments which, being present in larger pieces,
make regeneration possible. Lillie has found
Q D that nucleated pieces of the protozoon stentor

Fig. 27.— Tubularia mesembry- fail to regenerate if they are below the mini-

anthenium. y^. Minimal-sized ■, • tt i . i • • • i • , o«

piece tiiat produced a hy- ^nal sizc. He placcs this minimal sizc at 80 |1.
drantii. B, c. Pieces below diameter, which he calculates as ^V of the

minimal size. D. Ring pro- ' i • i /

duced by closing of small volumc of the stciitor from which the piece
P'^'^^" has come. I have obtained a slightly smaller

piece that regenerated, and since it came from a larger stentor it repre-
sents about gij of the whole animal. The lack of the power of devel-
opment of these smallest pieces seems to be due to the absence of
sufficient material for the production of the typical form. We can
give no other explanation of the phenomenon at present, especially
since the pieces contain material that we know from other experiments
has the power of producing any part of the organism. The super-
ficial area of small pieces is relatively greater than that of larger pieces.

INTERNAL FACTORS OF REGENERATION IN ANIMALS 57

but there is no evidence that this relation can in any way influence
the result. Whether the difference in surface tension could prevent
the small piece from assuming the typical form and hold it, as it
were, in a spherical form is not known, but there is little probability
that this is the explanation of the phenomena.

The regeneration of small pieces of animals and of plants may
often fail to take place, because, as Vochting has pointed out, the
injury caused by the cutting may extend so far into the small piece
that its repair may be impossible. In other cases there may be an
insufficient reserve supply of food stuff, although, if a proportionate
form of any size could be produced, it is difficult to see how this could
be the case. There can be no doubt, however, that pieces taken from
parts of the body that are dependent on other parts for their food,
oxygen, etc., will die for lack of these things, and even if they can
live for some time their further development may not take place in the
absence of sufficient food to carry on the process. After these pos-
sibilities have been given due weight, there remain several cases in
which there can be little doubt that the failure of a small piece to
regenerate is owing to the lack of sufficient material to produce even
the smallest possible form for that sort of material, i.e. for the organ-
ization to be formed on so small a scale.

There are some facts in connection with the regeneration of small
pieces of tubularia that have an important bearing on this question of
organization size. If long pieces of the stem are cut off, the new
hydranth, that develops out of the old tissue at the end of the piece,
occupies, within certain limits, a region of definite length. If pieces
of the stem are cut off that are only twice the length of the hydranth-
forming region, the length of the latter will be reduced to half the
length that it has in longer pieces, and if still smaller pieces are cut
off, the hydranth-forming region may be reduced, as Driesch has
shown, to seventy per cent of the normal length. The hydranths
that develop from the smaller pieces have also a reduced number of
tentacles, as I have found. It was first shown by Bickford, and later
by Driesch, and by myself, that in many cases very short pieces of
the stem of tubularia produce only the distal parts of a Jiydranth.
This happens most often when the length of the piece is less than
the average normal length of the hydranth-forming area, but it may
also take place in pieces that are much longer than the minimal size
of the least hydranth-forming region. Driesch made the further dis-
covery, which I have confirmed, that pieces from the distal end of the
stem are more likely to produce these partial structures than are
pieces from the more proximal part. Some of these partial structures
are represented in Fig. 28, C-G. Sometimes the inner tube, or coeno-
sarc, which is composed of the two layers of the body, ectoderm and

58

HE GENERA TION

endoderm, draws away from the chitinous perisarc, as shown in Fig,
28, B. A hydranth with a short stalk is then produced. In other cases,
Fig. 28, C, almost all of the coenosarc is used up to form the hydranth,
and only a short, dome-shaped knob represents the stalk. In still other
cases there may be no stalk at all (Fig. 27, D\ but only the hydranth.
Forms like the last two are more often produced from pieces of the

Fig. 28. — Tubularia vusembryanthe7num. Products of regeneration of short pieces. A. Piece
that regenerated a hydranth in same way as do longer pieces, but with fewer tentacles.
B. Pieces whose stem drew away from wall of old perisarc (cylinder in figures). C. Hydranth
with almost no stallc. D. Hvdranth without stalk. E. Distal part of hydranth with one long
proximal tentacle. E^. Similar, but more reduced. -£2. Similar, with two tentacles at side.
F. Proboscis with reproductive organs. G. Proboscis without reproductive organs.

distal end of the stalk. From very small pieces, forms like those shown
in Figs. 28, E—E^, that represent only proboscides with a reduced
number of tentacles, are sometimes formed. Reproductive organs
may be present at the base of these pieces. A further reduction is
shown in Figs. 28, E, G, that are proboscides with only the distal circle
of tentacles ; in one of these, reproductive organs are present around
the base. Partial forms more reduced than these have not been found.

INTERNAL FACTORS OF REGENERATION IN ANIMALS 59

If we examine the factors that determine the production of the
partial structures, we find, in the first place, that the size of the piece
is of the greatest importance. The reduced forms appear most often
in pieces that are shorter than the average length of the hydranth-
forming area. A second factor is connected with the region of the
stem from which the piece is taken. Larger pieces from the distal
end produce partial structures, especially hydranths with very short
stalks (Fig. 28, C), or with none at all (Fig. 28, D). There are cer-
tain facts connected with this distal region, which lies just behind the
hydranth, that should be mentioned in this connection. It was first
discovered by Dalyell that a hydranth-head lives for only a limited time,
and that when it dies a new head is regenerated from the region behind
the old one. The stalk of the new hydranth continues to elongate for
some time after the new hydranth has been formed. Whether this
continuous growth in the distal end, or the normal formation of a new
hydranth by it from time to time, can in any way be connected with
the development of partial structures from this region cannot at
present be stated. The distal part of the stem contains more of the
red-pigment, that .gives color to the stem and to the hydranth, than
does any other part. Loeb first advanced the view that the red-
pigment in the stem acts as a formative substance in Sachs' sense,
and determines the production of a new hydranth by accumulating
near the cut-end of the piece. Driesch also assumes the red-pigment
to be a factor in the result, but supposes that it acts quantitatively^
rather than in determining the quality of the result. If this red-pig-
ment acted in the way supposed either by Loeb or by Driesch, it might
act as one of the factors in the production of these partial structures.
This red-pigment is contained in the form of reddish granules in the
cells of the endoderm. The granules are of various sizes, the largest
being easily seen even with low powers of the microscope. When a
piece of the stem is cut off, the ends close by the drawing in of the
cut-edges over the open-end. A circulation of the fluid contained in
the piece then begins. In the fluid, globules appear very soon that
contain red-pigment granules like those in the endoderm. The glob-
ules appear to be endodermal cells, or parts of cells, that are set free
in the central cavity. The circulation continues for about twenty-
four hours. At about this time one end of the stem becomes reddish,
owing to the presence in it of a larger number of red-pigment granules
than before. The ridges that are the rudiments of the tentacles appear
(Fig. 30, A\ and a new hydranth very rapidly develops. At the time
when the hydranth begins to appear the globules in the circulating
fluid disappear. They disappear at the time when the red-pigment
of the forming hydranth is rapidly increasing in quantity, and not
Unnaturally one might suppose that the pigment of the circulating

6o RE GENERA TION

fluid had been added to the wall where the hydranth is produced.
The globules disappear in the region of the new hydranth, but, I
think, it can be shown that they do not form any essential part of the
hydranth. They may be found stuck together in a ball that lies in the
digestive tract of the new hydranth, and when the hydranth is fully
formed the pigment is ejected, as Stevens has shown, through the
mouth.

The development of the new hydranth begins several hours be-
fore the red-pigment globules have disappeared from the circulation.
The walls in the region of the future hydranth begin to thicken,
and, later, pigment develops in the endoderm of this region. The
new pigment is formed in the new cells of the endoderm, and does
not come from the circulating globules, as shown by the development
of very short pieces of the stem. In these the amount of new pig-
ment that develops in the new hydranth may be far greater than that
in the whole original piece (Fig. 30, Z>), and in this case there can be
no question but that new pigment is made in the endodermal cells of
the hydranth. The formation of a hydranth, that usually takes place
after another twenty-four hours, from the basal end of a long piece,
shows that a hydranth may develop when there are no granules in
the circulating fluid. These basal hydranths may contain as much
pigment as do the distal ones.

Driesch suggested that the red-pigment in the circulating fluid
determines quantitatively by its presence how much of a hydranth
is formed, or the size of the hydranth in relation to the rest of
the piece. There seems to be no evidence in favor of this view
and much against it. Loeb has not stated specifically whether
he means that it is the pigment in the circulating fluid or that
in the walls which acts as a formative stuff ; the presumption is
that he meant the latter. An examination of the piece during regen-
eration gives no evidence in favor of the view that the pigment moves
into the region of the new hydranth. On the contrary, it remains
constant in amount at all points except where the new hydranth is
developing, and there is in this region unquestionably a large develop-
ment of new pigment.

The evidence for and against the idea that the red-pigment of
tubularia is a formative stuff, or even building material, has been
considered at some length, because it is the only case in which the
hypothetical formative stuff has been definitely located in a specific,
recognizable substance that can be followed during the process of
regeneration. It is well, I think, to give the question full considera-
tion, especially as the hypothesis often appears to give an easy solu-
tion of some of the problems of regeneration. In a later chapter the
subject will be more fully treated.

INTERNAL FACTORS OF REGENERATION IN ANIMALS

6i

Since the red-pigment hypothesis does not explain the phenomenon
of the formation of the partial structures in tubularia, we must look
for another explanation. As the matter stands at present we can only
assume that there is a predisposition of a very small piece to form a
larger partial structure than a smaller whole one. This problem of the
method of development of small pieces of the stem of tubularia is fur-
ther complicated by the development in many cases of double hy-
dranths, or double parts of hydranths, as shown in Fig. 29, A-E.

D

Fig. 29. — Tubularia mesembryanthemum. A. Short piece with hydranth at each end. B. Double
piece with one'circle of proximal tentacles. C. Double piece vvilh only two proximal tentacles,
D. Double proboscis with two sets of reproductive organs. E-E'^. Double proboscis.

The first form (Fig. 29, A) shows two hydranths turned in opposite
directions, that are united at their bases. Another form has only a
single circle of proximal tentacles between the two proboscides (Fig.
29, B-C\ In other forms there are only two proboscides, each with its
reproductive organs (Fig. 29, D\ and often there are simply two pro-
boscides united at the base (Fig. 29, E-FJ). It is the rule, even
in longer pieces, that a hydranth appears at each end of the piece, if
the piece is suspended or even lies on the bottom of the water ; but

62

REGENERA TION

in all these cases the basal hydranth develops about twenty-four hours
after the apical one. In the short pieces, however, the two ends
develop at the same time, although the development of all the short
pieces, whatever structures they may produce, whether single or
double, is delayed, and the hydranths may not appear until after the
long pieces have produced their basal hydranths. In these double

§ i i i

.^^

Fig. 30. — Tubularia mesembryanthemum. A. Short piece with reduced hydranth-region. B. Piece
from distal end of stalk producing a hydranth without a stalk (see Fig. 27, D). C. Piece pro-
ducing hydranth as outgrowth of end. C^. Later stage of last. D. Short piece producing
double proboscis (see Fig. 28, E).

structures both ends develop at the same time (Fig. 30, D). If we
suppose the influences that start the development of the piece begin
first at the distal end, the region affected will He so near to the
proximal end of the piece that the development at this end may be
hastened, and under these circumstances the region of new forma-
tion will be shared by the two hydranths. The factors that deter-
mine that a larger, partial structure is formed in preference to a
smaller whole one will no doubt be found to be the same in these
double structures and in the single ones.

THE INFLUENCE OF THE OLD PARTS ON THE NEW

One of the most striking and general facts connected with the phe-
nomenon of regeneration is that the new part that is built up on the
exposed surface is like the part removed. This suggests that an in-
fluence of some sort starts from the old part and changes the part
immediately in contact with it into a structure that completes the old
part in that region. We can imagine that the new part that has been
changed in this way may act on the new part just beyond it, and so
step by step the new part may be differentiated. It is not difficult to
show that the phenomenon is really more complicated than this, and
that other factors are also acting on the new part; but, nevertheless,
that the old part has some such influence is probable. Under certain
conditions, however, this influence may be counteracted by other fac-

INTERNAL FACTORS OF REGENERATION IN ANIMALS 63

tors, and something different from the part removed may be formed.
One example of this sort has already been discussed, namely, that in
which after the removal of much of the anterior end of the earthworm
or of a planarian, only the distal end comes back. Another case is
that in which something different from the part removed is regener-
ated. If the tip of the eye of the hermit-crab or of other crustaceans
is cut off a new eye is regenerated, but if the eye-stalk is cut off near
its base an antenna-Hke organ develops. Herbst has suggested that
the presence of the ganglion at thQ end of the stalk accounts for the
regeneration of a new eye, when only the tip of the stalk is cut off.
In the absence of the ganglion at the cut-edge the stalk does not pro-
duce an eye, but an antenna, as is shown when the eye-stalk is cut
off near the base. The factors that determine the development of an
antenna instead of an eye have not been discovered. Przibram has
shown that when the third maxilliped of portunas, carcinas, or of other
crustaceans is cut off near the base, the new appendage that develops
is different from the one removed, and resembles a leg in many ways,
but if the animal is kept until it has moulted several times the
appendage becomes more and more like the part removed. Another
remarkable case has also been described by Przibram for AlpJieits
platyrrhyncJms . In this decapod, the claws of the first pair of legs are
different from each other, one being much larger than the other and
having a different structure.^ If the larger claw is thrown off at its
breaking-joint, and the smaller one left intact, the latter at the next
moult (or sometimes after two moults) changes into the character-
istic larger claw and the newly regenerated claw is like the smaller
one. If the experiment is repeated on this same animal, i.e. if the
newly acquired large claw is removed, then at the next moult the
smaller claw becomes the larger one and the new claw becomes
the smaller one — the conditions now being the same once more as at
the beginning. If both claws of an animal are thrown off at the
same time, two new claws regenerate that are both of the same size,
and each is a small copy of the claw that was removed. As yet no
experiments have been made that show what factors regulate the
development of each kind of claw.

Returning again to the question of the regeneration of parts simi-
lar,to the ones removed, there are some interesting results that Peebles
has obtained in the colonial hydroids, podocoryne and hydractinia.
These colonies consist of three principal sorts of individuals : the
nutritive, the reproductive, and the protective zooids. Peebles has
found that if the stalks of these zooids are cut into pieces, each pro-
duces the same kind of zooid as was originally carried by that stalk.
Pieces of the stem of the nutritive zooid produce new nutritive zooids

1 In normal animals some have the right claw the larger and some the left.

64 RE GENERA TION

at the anterior end of the piece, and sometimes also at the basal end.
A similar statement may be made for each of the other kinds.
Another method of regeneration sometimes takes place, when, for
instance, a piece of the stalk of a nutritive individual is left undis-
turbed without being supplied with fresh water. It sends out root-
like stolons instead of producing a new zooid. The stolons appear
first at the ends of the piece, but may later also appear at several
points along the piece. They make a delicate network, and the origi-
nal piece may entirely disappear in the stolons. After several days
new feeding zooids grow out at right angles to the stolon network.
Pieces of the stalk of protective zooids may also produce stolons, but
they spread less slowly, and the formation of new individuals was not
observed. In one case a piece of a reproductive zooid made a short
stolon, and from it arose a new individual that seemed to be a nutri-
tive zooid. If the latter. result proves to be true, we see that a piece
may produce a new part that is of a different kind from that of which
the piece itself was once a part, but this is brought about by the forma-
tion of a stolon that is itself one of the characteristic structures by
means of which these colonial forms produce new nutritive zooids.
In this case there is a return of the piece to a simpler form, the stolon,
and, acting on this, the factors that produce nutritive zooids may bring
about new nutritive zooids. The influence of the old structure is lost
when the piece assumes a new character.

Another series of experiments gives an insight into an internal
factor of regeneration that may prove, I think, to be one of some
importance and help in interpreting certain phenomena. If the
head-end of a planarian is cut off, the posterior piece split along
the middle line, and one side cut off, just above the lower end of the
longitudinal cut, as shown in Fig. 31, A, it will be found that, if the
long and the short sides are kept from uniting along the middle
line, each half will produce a new head on its anterior surface (Fig.
31, C). If the two halves grow together, and the anterior surface of
the shorter piece becomes connected with the anterior surface of the
longer piece by means of the new tissue that develops along the
inner side of the latter (Fig. 30, B), then a head appears only
on the anterior half. The development of a head on the shorter
half is prevented by the establishment of a connection with the
new side. Sometimes an abortive attempt to produce a head is
made, but the posterior surface fails to produce anything more than
a pointed outgrowth. If we attempt to picture to ourselves how this
influence of the new- side on the posterior surface is brought
about, we can, I think, most easily conceive the influence to be due
to some kind of tension or pull of the new material which is of such a
sort that it restrains the development of a head at a more posterior

INTERNAL FACTORS OF REGENERATION IN ANIMALS

65

level. We can picture to ourselves the same kind of process taking
place in the regeneration of the tail of a fish from an oblique surface.
The maximum rate of growth is found over that part of the cut-sur-

FlG. 31. — Planaria lugubris. A. Showing how worm was operated upon. B. A single head
regenerated at anterior cross-cut. It was united by a Hne of new tissue along the side of
the long half-piece with the new tissue at the anterior end of the short half-piece. The two
half-pieces reunited along the middle line. C. Two heads regenerated, one from each half
cross-cut. The two half-pieces were kept apart along the middle line.

face that is nearer the base of the tail (Fig. 40). At all other points
the growth is retarded, or held in check, and it can be shown that
the suppression is connected with the formation of the typical form
of the tail in the new part. If we cannot actually demonstrate at
present that this is due to some sort of tension between the different
parts which regulates the growth, we find, nevertheless, that it is by
means of some such idea as this that we can form a clearer concep-
tion of how such a relation of the parts to each other is established.
In a later chapter this subject will be dealt with more fully.

THE INFLUENCE OF THE NUCLEUS ON REGENERATION

The influence of the nucleus on the process of regeneration has
been shown in a number of unicellular forms. It was first observed
by Brandt in 1877 that pieces of ActinospJicEriiiin eicJiJiornii that con-
tain a nucleus assume the characteristic form, but pieces without a
nucleus fail to do so. Schmitz ('79) found that when the wall
of the many-celled siphonocladus is broken, the protoplasm rounds
up into balls, some of which contain one or more nuclei, while

F

66 RE GENERA TION

others may be without nuclei. The nucleated pieces produce a new-
membrane, and later become typical organisms, but non-nucleated
pieces do not form a new membrane, and soon disintegrate. Nuss-
baum ('84, 'Z6) cut into pieces the ciliate infusoria, oxytricha and
gastrostyla. Those pieces that contained a nucleus quickly regener-
ated a new whole organism of smaller size, that had the power of
further reproduction, while the pieces that did not contain a part
of the nucleus showed no evidence of regeneration ; and, although
they continued to move about for as much as two days, they subse-
quently disintegrated. Gruber obtained the same result on another
ciliate infusorian, Stentor coBvuleus. He found that, although the
non-nucleated pieces close over the cut-surface, and move about for
some time, they eventually die. He further showed that a non-
nucleated piece containing a portion of a new peristome in process
of formation will continue to develop this new peristome, although a
new peristome is never produced by a non-nucleated piece under
other circumstances. He believes that if the new peristome has
begun to be formed under the influence of the old nucleus, it may
continue its development after the piece is severed from its connection
with the nucleus. A non-nucleated piece containing a part of the
old peristome does not produce a new peristome from the old piece.
Gruber observed that a non-nucleated piece of amoeba behaves differ-
ently from a nucleated piece, and dies after a time.

Klebs found that when certain algae are put into a solution that
does not seriously injure them, but causes the protoplasm to contract
into balls, some of these contain nuclei, others not. If, for instance,
threads of zygnema, or of spirogyra, are placed in a 16 per cent solu-
tion of sugar, the protoplasm of each cell breaks up into one or more
clumps, some with nuclei, others without. Both kinds may remain
alive for a time; some of the non-nucleated pieces may live for
even six weeks. The nucleated pieces surround themselves at once,
when returned to water, with a new cellulose wall, but the non-nucle-
ated pieces remain naked. The latter can, nevertheless, produce in
the sunlight new starch that is used up in the dark and is made anew
on the return to light. ^

Balbiani ('88) found that non-nucleated pieces of cytrostomum,
trachelus, and protodon failed to regenerate, and Verworn ('89 and
'92) obtained similar results on several other protozoa. Similar
facts have been made out by Hofer ('89), Haberlandt and Gerassi-
moff ('90). Palla ('90) found that in certain cases non-nucleated
pieces, especially those from cells in growing regions, can produce a
new cell wall; while more recently Townsend ('97) has shown in

1 In other plants, fumaria, for example, non-nucleated pieces do not seem to be able to
make new starch after using up that which they contain at first.

INTERNAL FACTORS OF REGENERATION IN ANIMALS 67

several forms that non-nucleated pieces do not produce a new cell
wall unless they are connected by protoplasmic threads with nu-
cleated pieces. The most delicate connection suffices to enable a
non-nucleated piece to make a cell wall, even when the nucleated
piece lies in one cell and the non-nucleated in another, the two being
connected by a thread of protoplasm that passes through the inter-
vening wall.

If we examine somewhat more in detail some of these cases, we
find that when a form like stylonychia is cut into three pieces, the two
end-pieces without a nucleus fail to regenerate, while the central
piece makes a new entire organism of smaller size. If stentor is cut
into three pieces, each piece containing one or more nodes of the
macronucleus, each produces a new stentor. If, however, a piece is
cut off so that it does not contain a part of the macronucleus, it
fails to regenerate. Verworn ('95) succeeded in removing the central
capsule with its contained nucleus from the large radiolarian, Thallasi-
colJa iiiicleata. The non-nucleated animal remained alive for some
time, but eventually died. The nucleated capsule developed a new
outer zone with processes like those in the normal animal. If the
nucleus is taken from the capsule, the capsule dies, but shows some
traces of the formation of an outer zone. If the protoplasm is re-
moved as far as possible from around the nucleus, the latter does not
regenerate new protoplasm, but dies after a time. Verworn con-
cludes that the protoplasm cannot carry on all its normal functions
without the nucleus, or the nucleus without the protoplasm.

These experiments sufficiently demonstrate that non-nucleated
pieces are unable to regenerate. If we attempt to examine further
into the meaning of the phenomenon, we find a few things that
appear to have a bearing on the result. The behavior of the non-
nucleated pieces shows that the metabolism of the cell has been
changed after the removal of the nucleus. In some cases the
protoplasm is not able to carry out the process of digestion of the
included food substances. This process may be due to some inter-
change that goes on between the nucleus and the protoplasm,
which is stopped by the removal of the nucleus, and, in consequence,
the metabolism of the cell is changed. The lack of regenerative
power may be due to this change in the metabolism. It cannot be
claimed, however, that the result is due to a lack of energy in the
pieces, for the incessant motion of the cilia in some kinds of pieces,
that goes on for several days, shows that a large store of energy is
present. Unfortunately, we do not know enough of the relation that
subsists between the nucleus and the protoplasm to be able to state to
what the lack of regenerative power is due.

Loeb ('99) has suggested that the lack of power of non-nucleated

68 REGENERATION

pieces may be due to a lack of oxidation. The nucleus contains
substances which, according to Spitzer, are favorable to the process
of oxidation. When the nucleus is removed, the oxidation is sup-
posed by Loeb to be too low to allow the process of regeneration to
take place. In support of this view, he points out that while non-
nucleated pieces of infusoria live for only two or three days, non-
nucleated pieces of plants containing chlorophyl may be kept alive
for five or six weeks. Non-nucleated pieces containing chlorophyl
can obtain a supply of oxygen, owing to the breaking down of carbon
dioxide in the chlorophyl-bodies, and the consequent setting free of
oxygen. It should be pointed out, on the other hand, as opposed to
Loeb's view, that non-nucleated pieces of amoeba have been kept
alive for fourteen days ; and that despite the better oxidation that
may take place in non-nucleated pieces of plants, regeneration does
not take place.

It has been found that non-nucleated pieces of the Q,g^ of the
sea-urchin do not segment or develop, and the result is the same
whether the pieces come from fertilized or unfertilized eggs. If,
however, a spermatozoon enters one of these pieces, the piece will
segment, and, as Boveri and later Wilson have shown, it will produce
an embryo.

Boveri also tried fertilizing a non-nucleated piece of the ^gg of
one species of sea-urchin with a spermatozoon of another species.
He found that the embryo that develops is of the type of the species
from which the spermatozoon has come, and he concluded that the
nucleus determines the character of the larva, and that the protoplasm
has no influence on the form. The evidence from which Boveri
drew his conclusion is not beyond question. It has been shown by
Seeliger ('95) and myself ('95) that if whole eggs of the species
SpJicerecJiinus gramtlaris, used by Boveri, are fertilized by the sper-
matozoa of the other species, EcJiiniis microtuberailatiis, there is
great variability in the form of the resulting larvae. Most of them are
intermediate in character between the types of larvae of the two
species, but a few of them are like the paternal type. Vernon ('99)
has more recently shown that the character of hybrids is dependent
upon the ripeness of the sexual products of the two parents. If,
for instance, the eggs (sphaerechinus) are at the minimum of maturity,
the hybrids are more like the male (strongylocentrotus).

It remains, therefore, still to be shown whether or not the proto-
plasm has any influence on the form of larva that comes from a non-
nucleated piece, fertilized by a spermatozoon of another species.
That the nucleus of the male does have an influence on the form of
the animal is abundantly shown by the inheritance of the peculiarities
of the father through the chromatin of the spermatozoon.

INTERNAL FACTORS OF REGENERATION IN ANIMALS 69

THE CLOSING IN OF CUT-EDGES

One of the most familiar changes that takes place when a cut-edge
is exposed involves the rapid covering over of the exposed tissues.
This takes place from the margin of the wound, and a layer of cells,
usually the ectoderm at first, covers the surface. The closing in is
brought about in many forms by the contraction of the muscles of
the outer wall of the body. This seems to be the case in the earth-
worm and in the planarian, as well as in other animals, such for in-
stance as the starfish, holothurian, etc. But in addition to this
purely muscular contraction another process takes place, that is less
conspicuous in forms in which the muscles bring about the first clos-
ing, but which is evident in forms in which the muscles are absent
or little developed. I am able to cite two striking cases that have
come under my own observation. When a piece is cut from the stem
of tubularia, the ends close in twenty minutes to half an hour. The
body wall, the coenosarc, composed of the two layers of ectoderm and
endoderm, withdraws a little from the cut-edge of the outer hard tube,
or perisarc, that covers the stem, and then begins to draw across the
open end. A perfectly smooth, clean edge is formed that advances
from all points to the centre, where the final closing takes place. The
closing is not due to an arching over of the coenosarc, but the thin
plate is formed standing nearly at right angles to the outer tube.
This plate is composed of two layers of cells, of which there are a
number of rows arranged concentrically between the centre and the
outer edge. In the absence of muscle-fibres in the stem, the result
cannot be due to a muscular contraction, and even if short fibres
existed the transportation of cells entirely across the open end would
speak against this interpretation.^ Since the closing over takes place
without any support, we cannot suppose the process to be due to
any sort of cytotropic effect. The closing takes place equally well
in diluted sea water and in stronger solutions. The method of
withdrawal of the cells, as best seen when longitudinal pieces are
studied, resembles very much the withdrawal or contraction of proto-
plasmic processes in the protozoa, and so far as one can judge from
resemblances of this sort, the two processes appear to be the same.

This closing in of the cut-surface, while a preliminary step in the
process of regeneration, cannot, I think, be regarded as a part of the
regeneration in a strict sense. That the two processes are not
dependent on the same internal factors is shown by the following
experiments : If a bunch of tubularia is kept in an aquarium, it will

^ I have found that the closing in takes place equally well when one per cent of KCl is
added to the sea water. This salt has, as Loeb has shown, an inhibiting effect on muscular
contractility, — not, however, on amoeboid movements.

70 REGENERATION

produce new heads two or three times and then cease, and if after the
last-formed heads have died, pieces of the stem are cut off, they close
as readily as do pieces from fresh hydroids. Moreover, at certain
times of year the species Tiibularia {Parypha) crocea lose their
heads, and only the stalks remain. Pieces of these stalks will not
regenerate new heads, at this time, although they close in as quickly
as do pieces at other times of the year when the heads are present
and when new ones regenerate.

Another equally good illustration of what seems to be the same
phenomenon is found in the closing in of wounded surfaces in the
young tadpole embryos. If embryos are taken from the jelly mem-
branes, or even after they have been set free, and cut in half, each
piece quickly covers over the wounded surface by means of the ecto-
dermal cells. A much more striking illustration of this closing over
in the young tadpole is obtained by cutting, with a pair of small scis-
sors, a large piece from the side. The area may be a fourth or more
of the entire side, and yet it may be closed over in an amazingly short
time. Half an hour or an hour often suffices to cover a large exposed
surface. In this case also the wound is covered not by individual
cells wandering over the exposed surface, but by a steady advance of
the smooth edge of the ectoderm toward a central point. The process
is so similar to that which takes place in tubularia that little doubt
can remain as to the two being due to the same factors. As there are
no muscle fibres present in the part of the frog's embryo from which
the piece is cut off, the result cannot be due to muscular contraction,
but appears to be a contractile phenomenon similar to that in tubularia.
Even the small piece that is cut from the side of the body shows the
same phenomenon. At first it suddenly bends outwards owing to some
physical difference between the inner and the outer parts of the
piece. Then the edges thicken, bend in, and begin their advance over
the inner tissues. The process is seldom completed, since there
appears to be a limit to which the ectoderm can be stretched as the
edges advance. A most striking phenomenon both in pieces of tubu-
laria and of the frog's embryo is the entire absence of dead material
at the wounded surface. No sooner is the operation performed than
the advance begins, and there is not a trace of dying cells or parts of
cells to be seen.

CHAPTER IV

REGENERATION IN PLANTS

The series of experiments that Vochting has carried out on the
regeneration of the higher plants are so much more complete than all
previous experiments, and his analysis of the problems concerning
the factors that influence regeneration is so much more exact than
any other attempts in this direction, that we may profitably confine
our attention largely to his results. Many of his experiments were
made with young twigs or shoots of the willow (salix), which, after
the removal of the leaves, were suspended in a glass jar containing
air saturated with water. Under these circumstances the pieces pro-
duced new shoots from the buds (leaf-buds) that are present near the
point at which the leaves were attached, and new roots, in part from
root-buds, that are also present on the stem.

If the piece is suspended in a vertical position with its apex
tipward (Fig. 32, A), small swellings appear after three or four days
near the lower, i.e. the basal, end of the piece. These break through
quickly and grow out as roots. If a leaf-bud is present near the
basal end of the piece, the first roots appear at the side of or under
this ; later others appear around the same region. The first roots
to appear under these conditions come from pre-formed root rudi-
ments, the others are, in part at least, new, adventitious roots. If
the lower end of the cut is made through the lower part of a long
internode, i.e. just above a bud, the roots appear as a rule only near
the cut-end, and few if any of the roots develop at the first bud above
this region. In many cases there is formed over the basal cut-surface,
in the region" of the cambium, a thickening, or callus, and not infre-
quently from this also one or more roots may develop. The direction
taken by the new roots is variable, being sometimes downward,
sometimes more or less nearly at right angles to the stem.

While these changes have been taking place at the base, the leaf-
buds at the apical end have begun to develop. One, two, three, four,
or even five of the higher buds begin to elongate, the number and
extent of development depending on the length of the piece. The
topmost or apical bud grows fastest, and the others grow in the order
of their position. In the region below the lowest bud that develops

71

72

REGENERATION

there may be one or more buds that do not grow ; but if the piece is
cut in two just above these buds, they will then grow out.

The results show that at the base of the piece the same factors
that bring about the development of the rudiments of preexisting
roots also cause the development of new roots, if the lower end is
in a region in which there are no rudiments of roots present. The

Fig. 32. — After Vochtin?. A. Piece of willow cut off in July, suspended in moist atmosphere with
apex upward. B. Older piece of willow (cut off in March) suspended in moist atmosphere
with apex downward. C. Piece of willow with a ring removed from middle. Apex upward.

D. Piece of root of Populus dilatata. Basal end upward. Shoots from basal callus.

E. Piece of root of same with two rings removed. New shoots develop from basal callus,
and from basal end of each ring.

influence that produces the new roots is confined to the basal part
of the piece. In the apical part of the piece there are no adventi-
tious structures produced, but a longer region is active, and several
pre-formed leaf-buds begin to elongate. The topmost shoot grows
faster than the others, showing that the influence that produces the
growth is stronger near the apical end than at points further removed.
If another piece of a willow stem be placed under the same condi-

REGENERATION IN PLANTS 73

tions, but suspended with the basal end uppermost, results that are
in many respects similar to the last are obtained. Roots appear
around the base of the piece, i.e. around the upper end, and the leaf-
buds that develop are those that stand nearest to the apical, at present
the lower, end of the piece.

These results seem to indicate that, in the main, the chief factors
that determine the growth of the new part are internal ones ; and
although internal factors do appear to be the dominating ones, since
roots appear in both cases at the base and shoots at the apex, yet it
would be wrong to conclude that gravity has no influence at all on th^
result. In fact, other experiments show that it does have an influence^

If an older branch (8-12 mm. in diameter) is cut off and hung up
with its base upward, the result is somewhat different from that with
younger branches. The roots appear along the entire length of the
piece, as shown in Fig. 32, B\ the largest are those near the base,
and they decrease in size toward the apex of the piece. It is also
noticeable that all the roots come from preexisting root-buds, and no
adventitious roots are formed, even at the base. The leaf-buds that
develop are those arising near the apex, as in the last experiments.
They bend upward as they grow longer. A comparison of the
results obtained from younger and older pieces may, at first, seem
to show that the difference in their development is due to the greater
amount of reserve food stuff in the older piece, and Vochting thinks
it probable that this influence may account for the strength, length,
and even for the number of roots that develop, but he believes that it
is improbable that their mode of origin and their location can be so
determined. Furthermore, the development of new roots around
the base of the younger piece can hardly be explained as due to the
absence of food stuff. The explaiiation of the production of a smaller
number of roots in a young piece is that its tissues are less highly
specialized, its buds less advanced, and the piece itself is in a lower
stage of development. Another explanation must be found for the
greater number of roots that develop in the older piece. This is due,
as Vochting tries to show, in part to the influence of gravity on the
piece.

Vochting's general conclusion is that "the force or forces that
determine th.t polar differeiices in the piece are most evident and most
energetic in very young twigs ; that this difference decreases with the
age of the twig whose leaf-buds and root-buds become further devel-
oped. It is clear that the new roots of young tzvigs could appear in
corresponding number and strength in exactly the same regions in
which they grow out from pre-f ormed buds of a year-old twig. Since
this does not occur, and since the roots appear only near the base of
young twigs, the explanation must be that the innate polar forces

74

RE GENERA TION

act more energetically in young twigs, and the buds that develop
in the older twigs must arise in antagonism to the action of this
force." The polar difference between apex and base is present,
nevertheless, as Vochting's experiments show, even in quite old
pieces.

A series of experiments was carried out with the internodes of several
plants in order to see if, in the absence of pre-formed buds, new buds

Fig. 33. — After Vochting. A. Internodal piece of Begonia discolor. Apex upward. B. Same
with apex downward. C. Internodal piece of Heterocentroii diversifolium. Apex upward.
D, E. Pieces of leaf of Heterocentron diversifolium. Apex downward. F. Same with apex
upward. D, E, F. Same planted in earth.

would develop. The experiments were undertaken in order to ascertain
whether the same polarity, exhibited by longer pieces, would be also
found in internodal pieces. In most plants pieces of this kind do not
produce new structures, but in Heterocentron diversifolium an internode
produces roots at its basal end without regard to the position of the
piece (Fig. 33, C). Leaves do not appear on these pieces. On the
other hand internodes of Begonia discolor give the opposite result, as

REGENERATION IN PLANTS 75

shown in Fig. 33, A, B. In this case leaf-buds appear at the apex of
the internodal piece (Fig. 33, A), even when the apical end is down-
ward (Fig. 33, B). From the bases of the new shoots roots may then
develop, as also shown in the figure (Fig. 33, B). Vochting con-
cludes that the same polarity that is a characteristic feature of longer
pieces is also present in internodal pieces.

It is not necessary to separate completely portions of the stem in
order to produce roots near one end and shoots near the other. If a
ring, including the cambium layer, is cut from the piece, as indicated
in Fig. 32, C, the part above and the part below act independently of
each other, and each behaves as a separate piece. In various other
ways the same result may be obtained, as by simply making an
incision in the stem at one side, or by partially splitting off parts of
the stem (Fig. 34, (7).

If instead of a piece of the stem, a piece of a root is removed,
the results are as follows. ^ It should be remembered that the
basal end of a root is the part nearer the stem, the apex is
the part nearer the apex of the root. If pieces of the root of the
poplar, Popubis dilatata, are suspended vertically (Fig. 32, D) in a
moist chamber, a covering of new cells, a callus, appears over the cut-
ends. From the basal callus numerous leaf-shoots may develop.
Pieces of large roots may produce over a hundred of these shoots
from a single basal callus. In some cases adventitious shoots
may also arise from the side of the" root near, the basal end.
Roots develop from the callus over the apical end ; less often from
the sides near the end. If a similar piece of root is suspended with
its apical end upward, the new shoots arise as before over the basal
end, that is now turned downwards.

The leaves of some plants, as has long been known, are able to
procluce new plants. The begonias are especially well suited for ex-
periments of this kind. A piece of the stalk of a leaf suspended in a
moist atmosphere produces roots near its base. In most cases the
opposite end of the stalk, z.^. the end nearest the leaf, putrefies and
slowly dies toward the base. Near the base there may arise, before
the breaking down of the piece has reached this point, leaf-buds that
arise just above the first-formed roots. When these new shoots have
reached a certain size they may produce their own roots at or near
the base. If, however, a portion of the leaf is left attached to the
leaf-stalk (Fig. 35, A\ new roots arise near the basal end of the stalk,
and later shoots grow out near the point of union of the leaf and its
stalk at the point where the veins of the leaf come off. These shoots
produce roots of their own near the base, and roots may also appear
on the part of the leaf-stalk near its union with the lamina. If a

1 Knight obtained similar results in 1809.

•jQ REGENERATION

part of the mid-vein, or of any large vein of the leaf, is cut out, leav-
ing a part of the lamina on each side (Fig. 35, B\ and the piece is
suspended vertically, roots appear on the basal end of the vein, and
in the same region one or more shoots arise.

Leaves of heterocentron with the stalk attached, if kept in diffuse
light, produce roots along the stalk, especially near the basal end,
but shoots do not appear, even after five months (Fig. 35, C).
] These experiments show that the leaves do not exhibit the same
polar relations that are shown by pieces of the stem and root.
Vochting points out that the results may be explained in either of
two ways. The stem and the root have in general an unlimited
growth with a vegetative point at the apex. The leaf has only a
limited growth. Its cells form permanent tissue, hence the leaf does
not produce a new plant from its outer part. The second possibility
is this : the phenomenon is connected with the symmetrical relations
that different structures possess. Stem and root are symmetrical in
two or more directions, the leaf on the other hand is a flat structure
with one plane of symmetry, and even symmetry in one plane may
be absent. If the leaf could produce shoots at its apex and roots at
its base, from the semilunar fibrovascular bundle of the leaf, then an
individual (the leaf) with its single plane of symmetry would produce
shoots and roots that are symmetrical in two planes. Such a result
would be so anomalous that one may well doubt the possibility of its
coming into existence.^

Later, Vochting attempted to see if the same relation found in the
leaf would hold for other organs that have a limited growth. He
found that such structures, as spines, for example, produce both
shoots and roots near the base, as do leaves.

These experiments of Vochting on the regeneration of pieces of
the higher plants show that a piece possesses an innate polarity, or
"force," as Vochting sometimes calls it (although he explicitly states
that he does not use the word " force " in its strict, physical sense).
It does not follow, of course, that external conditions may not also
influence the regeneration, but in those experiments in which the
pieces were freely suspended in a moist atmosphere, the external fac-
tors are as far as possible excluded, so that the effect of the innate
tendencies are most clearly seen. In another series of experiments the
influence of external conditions on the regeneration was especially

1 Vochting points out that a parallel case is found in certain conifers. In these there
arise from a vertical many-sided main stem whorls of side branches that are symmetrical in
one plane. These lateral branches, if cut off and planted, produce new roots and new
branches, but the latter are always side-branches, like the parts from which they arise. They
never produce a normal main axis. Nevertheless, although these branches cannot them-
selves produce a main shoot, a callus may be formed at the base of the piece, and from
this a new main stem may arise.

REGENERATION IN PLANTS J J

Studied. This analysis that Vochting has made of the problem of
regeneration is in the highest degree instructive, since it shows how-
several factors, — some internal, others external, — take a hand in the
result ; and it is only possible to unravel the problem by combining
different experiments carried out in such a manner that one by one
the different factors at work are separated.

If a piece of a young stem of Salix vimhialis is suspended ver-
tically in a moist atmosphere, with the lower end in water (for | of a
centimetre), and the piece kept in the dark, the result is, in the main,
the same as when similar pieces are suspended in moist air without
coming into contact with water. Roots arise near the base, and
shoots near the apex, without regard to which end is in the water.

If the same experiment is repeated in ordinary air, i.e. air not
saturated with water, the result is somewhat different. If the twig
is suspended vertically with its apex tcpzvard, roots soon appear on
the basal end that is in the water, but no roots develop above the
water. Small protuberances may appear above the water in the
places at which roots would develop if the piece were surrounded by
a moist atmosphere, but they do not break through the bark. If the
piece is then covered by a jar containing air saturated with moisture,
these protuberances may become roots. It is clear, therefore, that
the dryness of the air has prevented their development.

If a similar twig is suspended (in the air) with its apex doivmvard,
and the lower end in water, root protuberances appear, at first, only
around the base, i.e. at the upper end. Under the water, at the
apical end, small and weak roots may develop, or may even not
appear at all.

These results agree, in the main, with those in which the piece is
surrounded by moist air, and give evidence of an inner polarity that
is an important factor in the regeneration. The results show that in
a piece with the basal end in water and the rest of the piece in the
air the tendency to produce roots above the water is suppressed by
the dryness of the air. In an inverted piece, however, with the apex
in water, the innate tendency to produce roots at the basal end is
strong enough to overcome the effect of the dryness of the air to
suppress their development. The abundance of water absorbed
by the apex of the piece makes the development of the roots possible
under these conditions despite the dryness of the air.^

There is another factor connected with the submergence of the
end of the stem in water that can be shown by putting a longer part
of the end under the water. Neither roots, if it is a basal end, nor
leaf-buds, if it is an apical end, appear on the deeper parts of the
submerged end. This is due, in all probability, to the insufTficiency

^ A piece suspended in ordinary air dries up without producing any new structures.

y8 REGENERATION

of oxygen in the water, and as a result the buds are prevented from
developing.

It can be shown that light has also an influence on the regen-
eration of pieces, and that it has a stronger influence on some plants
than on others. In some plants roots develop only on that side of
the stem that is less illuminated. In Lepismiuni radicans, for in-
stance, adventitious roots are produced by the plant even in dry air.
Pieces of the stem can produce roots on either the upper or the
lower surface, according to which side is less illuminated. A
piece of the stem of this plant that had been kept in the dark pro-
duced two roots, one above and one below, — one, therefore, opposed
to the direction of the action of gravity, and the other in the direction
of that action. Even in pieces of the willow, suspended in a moist
atmosphere, roots develop better and over a greater length of the
stem on the less illuminated side.

Although the experiments with pieces of young willow-twigs may
seem to show that gravity is not a factor in regulating the develop-
ment of the new parts, the results show in reality only that internal
factors have a preponderating influence. By means of another series
of experiments it can be shown that gravity does have an influence on
the production of the new parts. It is evident that in order to test
the action of gravity, pieces must be placed in different positions in
relation to the vertical. It will be found, if this is done, that different
results are obtained according to the angle that the piece makes with
the vertical. If a piece is suspended in a moist atmosphere, with its
apical end iipzvard, the smaller the angle that the piece makes with
the vertical so much the more are the leaf-buds that develop confined
to the upper part of the piece, and so much the more do they develop
from all sides of the upper end ; conversely, the greater the angle
with the vertical, i.e. the more nearly horizontal the position of the
piece, so much the more are the leaf-buds that develop found along
the upper side of the apical end (as well as around the end). If the
piece is placed in a horizontal position, the leaf-buds develop not only
around the apex, but they develop along the entire length of the upper
surface, best, however, near the apical end.

If similar pieces are suspended in oblique positions, with the basal
<?;z^ ///'7y«r(^, different results are obtained. In the preceding experi-
ment the polarity of the piece and gravity act together, while in this
experiment their action is opposed. Although there is a great
amount of variability in the results, yet the action of gravity is found
to have less influence on the result than has the inner polarity, and
the influence of the latter is so much greater that the action of gravity
is hardly noticeable.

The roots do not show as markedly the influence of gravity as

REGENERATION IN PLANTS

79

do the leaf-buds, yet Vochting has found that the position in which
they appear varies with the position of the piece with respect to the
vertical.

In the preceding cases the rudiments of the leaf-buds and of the
roots were probably present in most cases, so that gravity only
awakens them into activity. In other forms, as, for instance, in

Fig. 34. — After Vochting. A. End of a piece of Heferocenfron diversifolium. Apex downward.
B. Piece of same bent and suspended "with concave-side upward." C. Piece of a stem of
Salix viviinalis. Apex upward. A piece of the side has been lifted up and two wedges
inserted.

heterocentron, it is possible to show that gravity may even determine
the production of new buds. If pieces of the end of a branch,
including the growing point, are suspended vertically, some with the
apical end upward, others v/ith the basal end upward (Fig. 34, A),
the former produce roots only around the base, but in the latter
roots appear frequently, not only at the base, but even extending
along the stem. They appear not only at the nodes, where pre-

8 O RE GENERA TION

formed rudiments may be present, but also in the internodes, where
there are no rudiments of roots.

Stems of heterocentron placed in a horizontal position produce a
circle of roots around the base, and later, in several cases, roots from
the under surface of the stem, both from the nodes and the inter-
nodes; but these roots are smaller than those at the base. Those
around the base are often longer on the lower side than on the
upper side.

Vochting has also studied the regeneration of pieces of roots of
the poplar and of the elm suspended horizontally in a moist chamber.
A callus develops from the cambium region of the basal end, and
from this a thick bunch of adventitious sprouts grows out. A weak
callus may develop on the apical ejid also, from which a few roots
develop. In other cases adventitious shoots are produced also from
the apical callus, especially from the upper edge of the callus.
The results are variable, but show that at times leaf-shoots may
develop from the apical end of the root. It is also singular to find
that, while pieces of the root produce new leaf-shoots very readily,
yet they often fail to produce new roots, or produce only a few that
arise from the apical callus or from the sides near that region. It is
difficult to show that gravity has any influence on the result.

Vochting recognizes another sort of influence that determines the
position of new organs on a piece. If a young, growing end of a
stem of Heterocentron diversifolium is suspended by two threads in
a horizontal position, the ends bend upward as a result of the nega-
tive geotropism of the piece. The new roots appear at the base of
the piece, and also on the co7tvex side of the bent part of the stem, as
shown in Fig. 34, B. The same result can be obtained by forcibly
bending a twig, and then tying the ends together, so that it remains
in its bent position. If a piece of this sort is suspended in a moist
atmosphere, with the bent inner concave side turned npivnrd, the
roots appear on the base and at the bend, especially on the 7inder
side, both from the nodes and internodes. If now in order to see if
gravity takes any part in the result the next piece is suspended with
the outer convex side of the bent part turned upward, it is found that
many of the pieces produce roots only at the base, but others pro-
duce roots also at the bent portion of the stem, but they are fewer
than in the last experiment. The roots arise for the most part on the
nnder side of the arch, and only a few arise from the upper part. It
is clear that gravity is also one of the factors in the result. Leaf-
buds arise in these pieces with the concave side turned npivar'd only
near the apex ; rarely one may develop on the lower part of the basal
end. In pieces with the concave side turned dozvnzvard the leaf-buds
arise for the most part at the apex, but sometimes they appear on the

REGENERATION IN PLANTS 8 1

Upper part of the basal arm. The results are due to two factors,
gravity and an inner "force" that is supposed to be the resultant of
a growth phenomenon taking place in the bent portion. Vochting
supposes that a process of growth takes place as a result of the bend-
ing ; " the plasma streams to this region, and a new development
takes place here more easily." Vochting adds that this view will not
explain the morphological character of the new organs, and that this
must be due to quite other causes. The results may, I venture to
suggest, find a simpler explanation as the result of the bending, dis-
turbing the tensions of the protoplasm, causing the two arms of the
piece to act as if they had been separated from each other. This
idea is more fully developed in a later chapter.

Sachs has criticised Vochting's general conclusion in regard to the
internal factors that determine the regeneration in a piece of the stem
of a plant. He gives very little weight to the innate polarity of the
piece, and attempts to explain the results as due to certain substances
in the stem of such a sort that, accumulating in any region, they
determine the kind of regeneration that takes place. Sachs also as-
sumes that gravity acts on these substances in such a way that
the root-forming substances flow downward and the shoot-forming
substances flow upward. In a piece of a stem, the two formative sub-
stances contained in it accumulate at the two ends, and determine
the kind of regeneration that takes place. It is evident that Sachs'
hypothesis fails to explain the method of regeneration of an inverted
piece suspended in a vertical position, since the roots appear at the
upper end and the shoots at the lower end. Sachs explains this as
the result of the previous action of gravity on the piece, while the piece
was a part of the tree and stood in a vertical direction. He supposes
the longer time that gravity has acted on the piece has determined its
basi-apical directions, so that this influence is shown in the inverted
piece, rather than the action of gravity on it in its new position.
This conception involves quite a different idea from the original one
of formative substances flowing in definite directions. Moreover,
Vochting has met this interpretation by using the twigs of the weep-
ing willow, that hang downward on the tree. If gravity has acted on
these drooping twigs in the way that Sachs supposes it can act, then
we should expect to find, if Sachs' view is correct, that roots would
develop at the apical end of a piece of the twig, and leaves at the
basal end, if the piece is hung vertically with its basal end {i.e. the
end originally nearer the trunk of the tree) upward. The regeneration
of these pieces shows, however, that they behave in the same way as do
pieces of twigs that have always stood vertically on the tree. There
can be, therefore, no doubt that the distinction between base and apex
is an expression of some innate quaHty of the plant itself. That an

82 ■ REGENERATION

external factor, gravity, is also a factor in the regeneration of the
pieces, is abundantly shown by the experiments of Vochting and
others, but that innate factors are also at work cannot be doubted.
We find evidence in many animals of a similar difference between the
two ends of a piece, and we speak of this difference between the ante-
rior and posterior ends of a piece as its polarity. What this polarity
may be we do not know, and it is even doubtful whether we should be
justified in speaking of it as a force in the sense that the difference in
the ends of a magnet is the result of a magnetic force. The kind
of polarity shown by animals and plants does not seem to correspond
to any of the so-called forces with which the physicist has to deal, but
a further discussion of this question will be deferred to a later chapter.

The preceding account of regeneration in some of the higher
plants has shown that their usual method of regeneration is by means
of latent buds that are present along the sides of the stem, or by
means of adventitious buds that develop anew along the sides of
the stem. In a few cases new buds may develop from the new tissue
of the callus that forms over the cut-ends, but in such cases the new
shoots, or the new roots, are much smaller in diameter than the end
from which they arise, and usually several or many new shoots de-
velop on the same callus. In these respects the regeneration of the
higher plants is different from that of the higher animals, for, in the
latter, the new part arises from the entire cut-surface. This differ-
ence is no doubt connected with differences in the normal method
of growth in plants and in animals, and an explanation of the growth
would, perhaps, also give an explanation of the mode of regeneration.
The normal method of growth in higher plants takes place largely by
the formation of lateral buds, as well as by terminal growth, and we
find that regeneration takes place in most cases from the same lateral
buds or from others of a similar kind that develop after the piece has
been separated.

It is sometimes stated that the higher plants do not regenerate at
the cut-ends, because they produce buds at the sides. The statement
implies that there is some sort of antagonism between the regenera-
tion of a bud at the end, and the development of buds at the side. It
may be true that the development of a latent bud at the side might
suppress the tendency to produce a bud at the end, if such a tendency
exists ; but if we remove the lateral, pre-formed buds, new ones
develop at the sides, and not at the end. That there need not be an
antagonism between the formation of a bud, or of buds, at the end,
and also at the sides, is shown in Vochting's experiments with the
roots of the poplar. In these, leaf-shoots and root-shoots developed
both from the callus over the cut-end, and at the side of the piece also.
It has further been shown that, although a piece of the internode does

REGENERATION IN PIANTS

83

not produce new leaf-buds at the sides, neither does it regenerate a
new apical bud at the end.

A most interesting fact connected with the regeneration of the
higher plants is, as has been pointed out, that even when a callus is
formed over the cut-end, and new growth takes place from this callus.

Fig. 35. — After Vochting. A. Leaf-stalk of Begonia rex with a portion of the lamina. Sus-
pended with base upward. B. Piece of lamina of leaf of same. C. Leaf of Heteroceiitron
diver sifoliu7n. D. Leaf-stalk of Begonia discolor.

there is produced, not a single terminal bud, but a number of separate
buds. The piece does not complete itself, but produces new buds,
that make new branches. The explanation of this mode of regenera-
tion in plants is not known. It appears to be connected with the
production, by means of buds, of all the new structures. Why this
should occur we do not know, and the only suggestion that offers

84 RE GENERA TION

itself is that the result may be in some way connected with the hard
cell walls in plants that make difficult the organization of large areas
into a new whole. As a result, the new development takes place in a
small group of similar cells, that are sufficiently near together to
organize themselves into a whole despite the interference met with in
the cell walls.

Vochting has also studied the regeneration of pieces of the liver-
wort, Liimtlaria vulgaris. The results have been already partly given
in the iirst chapter. If cross-pieces are taken from the thallus, each
produces a new bud at its anterior or apical end (Fig. 9, A, A^). The
new bud arises from the cut-surface, or very near it, from a group of
cells of the midrib that lies nearer the under side (Fig. 9, A'^). The
bud gives rise to a new thallus that springs from a narrow base at its
origin from the old piece. If a piece is cut longitudinally from the
thallus along the old midrib, the new bud arises at the anterior end
from the midrib (Fig. 9, B). It comes either from the anterior cut-
surface near the inner edge, or from the anterior end of the inner
edge, and in some cases two new buds arise, one at each of these
places. If the piece is removed from one side of the midrib it does
not regenerate as quickly as when a part of the midrib is present, but
when the new bud develops it arises from the anterior part of the
inner edge (Fig. g, B^). If the piece is cut far out at one side, it may
be a long time before the new bud arises. This difference in the rate
of development of these pieces is explained by Vochting as due to the
simpler character of the cells near the midrib.

If oblique pieces are cut off, with an anterior oblique cut-edge, as
shown in Fig. 9, C, C^, the new bud arises along the anterior surface. If
the piece includes a portion of the old midrib at its inner end, the new
bud arises from this (Fig. 9, C), but if the piece lies to one side of the
midrib, the new bud arises near the anterior end of the anterior
oblique surface (Fig. 9, C^, C^)

A number of experiments that were made in order to determine
what part gravity and light may take in the regeneration gave nearly
negative results. The regeneration appears to result largely from
internal factors.

If a piece of the thallus is divided parallel to its surface, the two
parts may each produce a new thallus, but this arises much more
readily from the lower piece. If a piece of the latter is cut into
small pieces no larger than half a cubic millimetre, and even much
smaller, each may produce a new thallus.

Vochting also studied the regeneration of parts having a limited
growth. If a gemmiferous capsule is cut off, then split into two or
four pieces, and these are placed on moist sand, it is found that new
buds arise alona: the basal cut-edgfe. In order to show that this is

REGENERATION IN PIANTS 85

not due to the new part arising on the basal end because there is no
other cut-surface, the apical part of some of the pieces was cut off.
These pieces, with two free ends, produced new buds only on their
basal ends.

The sexual organs of lunularia are borne on the top of erect
reproductive branches having a limited growth (Fig. 9, D), which
carry later the sporiferous branches. The branches have a stalk and
a terminal disk. If pieces of the stalk are cut off they do not pro-
duce any new parts for a long time, but ultimately each produces
from the basal cut-surface, or not far from the basal end, a new bud
(Fig. E^). If the disk is left attached to the piece, the result is the
same as before (Fig. D ^). If a twisted part of the stalk is used, new
buds may develop at the base and also near the twisted region, as
shown in Fig. 9, E ^. If pieces of the stalk are stuck into the sand,
some with the apical end, others with the basal end in the sand, the
former produce new buds at the upper basal end, the latter produce
buds on the stalk just above the surface of the sand. Pieces that
retain the old disk when stuck into the sand (Fig. 9, D) produce one or
more buds along the stalk above the sand, often some distance above
it. The part buried in the sand does not seem able to develop new-
buds, and as a result they are produced at the first region of the
basal part of the stalk, where the conditions make it possible for
buds to develop.

If the disk is cut entirely from the stalk and placed on moist
sand, it produces adventitious buds in the region at which the stalk
was removed. Buds are also produced at the bases of the rays that
go off from the disk. They arise from the under side of the rays
without regard to the position of the disk, /.^..whether it is turned
upward or downward. If the rays are cut off they produce new
buds at the base (Fig. 9, F~), and if the outer tip of the ray is also
cut off, the new bud still arises at the base, as shown in Fig. 9, F'^.
These results on pieces with limited growth agree in every respect
with those that have been obtained in flowering plants. Vochting
thinks that the .phenomenon is due in all cases to the limited growth
of the parts. Goebel rejects this interpretation, and thinks that the
results can be accounted for by the direction of the movement of
formative or, at least, of building material. In favor of this view,
he points out that in other liverworts the polarity is not shown in the
same degree as in lunularia (according to Schostakowitsch), and
also that in very old pieces of marchantia, as Vochting has shown,
the polarity disappears. In the latter case the attractive action at
the vegetative point, to which the building stuff is supposed to flow,
is less strong ; and in longer pieces the influence of the apical region
may not extend,, throughout the entire length of the thallus. In favor

86 REGENERATION

of this interpretation he points out that in young prothallia of os-
munda, adventitious shoots do not appear, but in older plants, that
have become longer, these shoots may appear at the base, because
this region is no longer influenced by the apex, and consequently it
is possible for building material to accumulate at the basal end.
It may be granted that Goebel's idea is possibly correct, viz. that the
apex, or the apical end of a piece, may have some influence in pre-
venting the development of shoots at the base, but it does not follow
that this influence can be accounted for on the ground of a with-
drawal of building stuff from the basal part. As I shall attempt to
show in a later chapter, this influence may be of a different nature.

It has been found by Pringsheim and others that pieces of the
stem of mosses may also produce new plants, and this holds even for
pieces of the stalk of the sporophore and of the wall of the spore
capsule (Fig. lo, A-D). In this case, however, there is not produced
a new moss plant directly from the end of the piece, but threads or
protonemata grow out, as shown in Fig. lo, A, B, and from these
new moss plants are formed in the same way as on the ordinary
protonema. The threads that arise from the piece grow out from
single cells in the middle part of the stem. These cells are less dif-
ferentiated and are richer in protoplasm than are the other cells in
the stem.

The prothallia of certain ferns are said by Goebel to regenerate if
cut in two ; at least this is true for the part that contains the vegeta-
tive point. In a piece without the growing point, the cells are very
little specialized, and the piece may remain alive ; yet it is incapable
of producing a new growing point. Comparing this result with the
power of regeneration possessed by lower animals, Goebel states ^ that
since in a plant new organs may arise without the typical form of the
plant being produced, "therefore, the completion of a leaf, for instance,
that has been injured, would be of no 7ise to the plant, while in ani-
mals that do not have a vegetative point, the loss of an organ is a
permanent disadvantage in case the organ removed cannot be regen-
erated." The "explanation" of the difference in the two cases is
supposed, apparently, by Goebel, to depend on the usefulness, or
non-usefulness, of the regenerative act !

Brefeld has described several cases of regeneration in moulds.
There is produced from the zygospore of Miicor miicedo a germinat-
ing tube that forms at its end a single sporangium. If the tube is
destroyed or injured, a second one is formed from the zygospore, and
if this is injured a third time, a new tube is produced. Each time
the sporangium is smaller than in the preceding case.

If the spore-bearing stalk of Copritius stercoraritis is cut off, the

■• Goebel, '98, page 37.

REGENERATION IN PI A NTS

S7

end grows out and produces a new sporangium. If pieces of the
stem are cut off and placed in a nourishing medium, they produce
from the ends a new myceHum, and from this new erect hyphae may
develop. In the former case, the cut-end regenerates the part
removed in somewhat the same way that an animal regenerates at the
cut-end ; in the latter, there is a return to the mycelium stage, as in

i^

,M!i'f''

<^"^_

<^ V

Fig. 36. — After Goebel. Achimenes Haageana. A leaf-cutting of a plant in flower. The new
plant, regenerating at base of leaf-stalk, proceeded at once to produce a flower.

the piece of the moss that produces a new protonema. If the my-
celium and the protonema are looked upon as an embryonic stage in
the formation of the sexual form, there is a return in these cases to an
embryonic form or mode of development.

One of the most remarkable and important discoveries in con-
nection with the regeneration of plants is that the new individuals that
develop from leaves cut off from certain plants differ according to

8 8 RE GENERA TION

the region of the old plant from which the leaf has been taken.
Sachs discovered in 1893 that when the leaves of the begonia are
taken from a plant in bloom, the adventitious buds that develop from
the leaves very quickly produce new flowers. If the leaves are taken
from a plant that has not yet produced flowers, the new plant that
develops from the leaf does not produce flowers until after a much
longer time. Goebel repeated the experiment with achimenes, and
found that the new plants that develop from leaves from the flower-
ing part of the stem (Fig. 36) produce flowers sooner than do the
plants that develop from leaves from the base of the same plant.
The former produce, as a rule, only one or two leaves and the flower
stalk ; the latter, a large number of leaves.

Sachs explains these results as due to a flower-forming stuff that
is supposed to be present in the leaves when the plant is about to
blossom. This material is supposed to act on the new plant that
develops from the leaves, and to bring it sooner to maturity. Goebel
points out that the result may also be explained by the fact that the
leaves in the flowering region may be poorer in food materials and,
in consequence, the adventitious buds that they produce are weaker,
and, as experience has shown in other cases, a weakening of the
tissues brings about more quickly the formation of flowers. Never-
theless, Goebel inclines to Sachs' hypothesis of specific or formative
stuffs, without, however, denying that there is also an inner polarity
or "disposition" that also appears in the phenomena of regeneration.
But Goebel seems to think that the phenomena of polarity "can
most easily be brought under a common point of view by means of
Sachs' assumption that there are different kinds of stuffs that go to
make the different organs. In the normal life of the plant shoot-
forming stuffs are carried to the vegetative points, while root-forming
materials go to the growing ends of the roots. In consequence,
when a piece is cut off and the flow of the formative stuffs is inter-
rupted, the root-forming stuff will accumulate at the base of the
piece and the shoot-forming stuffs at the apex. In the leaf the flow
of all formative substances is toward the base of the leaf, and it is
in this region that the new plants arise after the removal of the leaf."
A confirmation of this point of view, Goebel believes, is furnished by
the following cases. Some monocotyledonous plants seldom set seed
because the vegetative organs, the bulbs, tubers, etc., that reproduce
the plant, exert a stronger attraction upon the building stuff than
do the young seeds. ^ Lindenmuth has shown in some of these
forms that pieces of the stem produce, near the base, numerous
bulblets, because the building stuff moves toward the base. In
HyacijitJius orientalis, on the other hand, bulblets are produced at

1 Examples of this are found in Lilium cattdidum, Lachenalia luteola.

REGENERATION IN PLANTS 89

the apical part of a piece of the flowering plant. In this plant the
seeds ripen normally, presumably because of the migration of stuffs
toward the developing seeds. The results in all these cases are due,
Goebel thinks, to the direction of the flow of formative stuffs, and
cannot be explained as connected in any way with the limited
growth of the part.

These cases, cited by Goebel, are not in my opinion altogether to
the point ; and they fail also to establish convincingly the conclusion
that Goebel draws from them. It may be granted that starch is
stored up in certain parts of the plant, and if these parts are re-
moved the starch may be stored up in other parts, as Vochting
(^'^'J^ has shown ; but that the movement of this starch to the base
can account for the lack of development of the seeds in certain cases
seems to me improbable, or, at least, far from being established by
the cases cited. It may be granted that the presence of starch in a
region may act on the organs there present and determine their fate.
Vochting has shown in the potato that by removing the tubers the
axial buds, especially in the basal leaves, become tuber-like bodies,
but it should not be overlooked that the tubers themselves are formed
from underground stolons, that arise in the same way as do those
in the axils of the leaves. It would be erroneous, I think, to con-
clude from these cases of the effect of food stuffs on certain re-
gions that there are formative stuffs for all the organs of the plant,
and that these stuffs migrate in different directions and determine
the nature of the part. Even the migration of such substances in
definite directions in the tissue is itself in need of explanation, since
it has been made highly probable by Vochting's experiments that
this is not produced by agents outside of the plant. Furthermore,
Vochting has shown that the tendency of starch to accumulate in the
tubers and the formation of the tuber are separate phenomena.

This hypothesis of formative stuffs held by such able botanists
as Sachs and Goebel demands nevertheless serious consideration, if
for no other reason than that if it is true it offers quite a simple
explanation of many phenomena of growth and of regeneration. We
should, I think, distinguish between specific or formative stuffs and
building or food stuffs. By specific stuffs is meant a special kind of
substance which, being present in a part, determines the nature of the
part. Sachs supposes, for instance, that a specific substance is made
by the leaves of a plant which is transported to the vegetative, growing
region (which has so far produced only leaves), and changes its
growth so that flowers are produced. Goebel does not commit him-
self altogether to specific stuffs of this sort, but speaks also of
building stuffs. By building stuff we may understand food material
that is necessary for growth, and from which any part of the plant

90

REGENERATION

may be made. Its presence in larger or smaller quantities may
determine what a particular part shall become, but further than
this it exerts no specific action. This means that the presence of a
certain amount of food substance may determine what a given region
shall produce, but it is not supposed that there are different kinds of
food materials that correspond to each kind of structure. If there
were such, they would not differ from specific substances, unless we
wish to make subtle distinctions without any basis of fact to go upon.

Goebel points out that there is evidence to show that the greater
or less quantity of food substance contained in a plant often deter-
mines the nature of its growth, as for instance the production of
flowers when the food supply runs low and the production of foliage
when the food supply is abundant. This difference may explain
Sachs' experiment with begonia leaves ; and if so, there is no need
for supposing specific flower stuffs to be made in the plant.

There is another point of view which has been, I think, too much
neglected, viz. that the production of food stuffs is itself an expression
of changes taking place in the living tissues, and if the structure
is changed so that it no longer produces the same substances it
may then lead to the development of different kinds of organs. The
difference in the regeneration of an apical and a basal leaf of begonia
may be due to some difference in the structure of the protoplasm.
The greater or smaller amount of starch produced in these leaves may
be only a measure of, and not a factor in, the result.

In this same connection another question needs to be discussed.
It is assumed by several botanists that in a normal plant the latent
shoots or buds along the stem do not develop so long as the terminal
shoots are growing, because the latter use up all the food material
that is carried to that region. If the terminal bud is destroyed the
lateral shoots then burst forth, in consequence, it is assumed, of the
excess of food stuff that now comes to them. I do not believe that
the phenomena can be so easily explained. If a piece of a plant is
cut off, the leaves removed, and the piece suspended in a moist
chamber and kept /;/ the dark, the lateral buds at the apex will begin
to develop. If we assume that the piece cannot develop any new
food substance in the dark, then it contains just the same amount
as it did while a part of the plant, and yet that amount is ample for
the development of the lateral buds. Moreover, only the more apical
buds develop ; but if the piece is then cut in two, the apical buds of
the basal piece, that had remained undeveloped, will now develop.
How can this be explained by the amount of food substances in the
piece ? If it is assumed that in the normal plant the food substances
flow only to the growing points, and the buds are out of the main cur-
rent and fail in consequence to develop, it can be shown that this

REGENERATION IN PLANTS 9 1

idea also fails to explain certain results. Vochting has found, for
example, that if an incision is made below a bud and the piece con-
taining the bud be lifted up somewhat from the rest of the piece,
remaining attached only at its anterior end, the bud will begin to
develop. In this case the conditions preclude an accumulation of food
substances in the piece, and the bud is even farther removed than at
first from the main current, yet it begins to develop.

We shall find, I think, that the idea of food stuffs fails to explain
some of the simplest phenomena, and while it need not be denied
that under certain conditions the presence or accumulation of food
materials may produce certain definite results, yet such food stuffs
seem to play a very subordinate part as compared with certain other
internal or innate factors.

CHAPTER V
REGENERATION AND LIABILITY TO INJURY

There is a widespread belief amongst zoologists that a definite
relation exists between the liability of an animal to injury and its
power of regeneration. It is also supposed that those individual
parts of an animal that are more exposed to accidental injury, or to
the attacks of enemies, are the parts in which regeneration is best
developed, and conversely, that those parts of the body that are rarely
or never injured do not possess the power of regeneration.

Not only do we find this belief implied in many ways, but we find
this point of view definitely taken by several eminent writers, and in
some cases carried so far that the. process of regeneration itself is sup-
posed to be accounted for by the liability of the parts to injury. In
order that it may not appear that I have exaggerated the widespread
occurrence of this belief, a few examples may be cited.

Reaumur in 1742 pointed out that regeneration is especially char-
acteristic of those animals whose body is liable to be broken, or, as in
the earthworm, subject to the attacks of enemies. Bonnet (1745)
thought that such a connection exists as has just been stated, and
that the animals that possess the power of regeneration have been
endowed with germs set aside for this very purpose. He further
believed that there would be in each animal that regenerates as many
of these germs as the number of times that it is liable to be injured
during its natural life. Darwin in his book on Animals and Plants
under Domestication says : " In the case of those animals that may
be bisected, or chopped into pieces, and of which every fragment will
reproduce the whole, the power of regrowth must be diffused through-
out the whole body. Nevertheless, there seems to be much truth in
the view maintained by Professor Lessona^ that this capacity is gen-
erally a localized and special one serving to replace parts which are
eminently liable to be lost in each particular animal. The most strik-

1 Delage and Giard give Lessona ('69) the credit for first stating that the phenomenon
of regeneration is an adaptation to hahility to injury; but Reaumur first suggested this idea
in 1742, and Bonnet in 1745. Delage's interpretation, viz. that Lessona ascribed this to
a pr'evoyance de la nature, has been denied by Lessona's biographer, Camerano (Za Vita
di M. Lessona, Acad. R. d. Torino, 2, XLV, 1896), and by Giard (^Sur V antotomie Para-
sitaire^ etc., Compt. Kendus de Seances de la Societe de Biologic, May, 1897).

92

REGENERATION AND LIABILITY TO INJURY 93

ing case in favor of this view is that the terrestrial salamander, accord-
ing to Lessona, cannot reproduce lost parts, whilst another species
of the same genus, the aquatic salamander, has extraordinary powers
of regrowth, as we have just seen ; and this animal is eminently liable to
have its limbs, tail, eyes, and jaws bitten off by other tritons."

Lang, referring to the brittleness of the tails of lizards, points out
that this is a very useful character, since the bird of prey that has
struck at a lizard gets hold of only the last part of the animal to dis-
appear under cover ; the lizard escapes by breaking off its tail. The
brittleness of the tail is, therefore, an adaptive character that has
become fixed by long inheritance.

To this example may be added that of certain land snails in the
Phihppine Islands. The individuals of the genus helicarion live on
trees in damp forests, often in great droves. They are very active,
and creep with unusual swiftness over the stems and leaves of the
trees. Semper has recorded that all the species observed by him
have the remarkable power of breaking off the tail (foot) close behind
the shell, if the tail is roughly grasped. A convulsive movement is
made until the tail comes off, and the snail drops to the ground, where
it is concealed by the leaves. Semper adds that in this way the snails
often escaped from him and from his collectors, leaving nothing behind
but their tails. The tail is said to be the most obvious part of the
animal, and it is assumed that this is, therefore, the part that a rep-
tile or bird would first attack. ^ Lang states that in this case external
influences have produced an extraordinarily well-developed sensitive-
ness in the animal, so that it reacts to the external stimulus by volun-
tarily throwing off the tail. It would be, of course, of small advantage
to be able to throw off the tail unless the power of regenerating the
lost organ existed, or was acquired at the same time as the extreme
sensitiveness that brings about the reaction. Lang does not state,
however, explicitly that he believes the regenerative power to have
arisen through the exposure of the tail of the lizard and the tail of
the snail to injury, although he thinks that the mechanism by means
of which these parts are thrown off has been acquired in this way.
Several other writers have, however, used these same cases to illus-
trate the supposed principle of liability to injury and power of
regeneration.

Weismann in his book on TJie Germ Plasm has adopted the
principle of a connection between regeneration and liability to in-
jury and has carried it much farther than other writers. We can,
therefore, most profitably make a careful examination of Welsmann's

1 Whether, having once failed in this way to obtain the snail, the bird or lizard would
not learn to make a frontal attack is not stated. Or shall we assume that the tail is all that
is wanted?

94 REGENERATION

position. His general idea may be gathered from the following
quotation : ^ " The dissimilarity, moreover, as regards the power of
regeneration m various members of the same species, also indicates that
adaptation is an important factor in the process. In proteus, which in
other respects possesses so slight a capacity for regeneration, the gills
grow again rapidly when they have been cut off. In lizards again this
power is confined to the tail, and the limbs cannot become restored.
In these animals, however, the tail is obviously far more likely to
become mutilated than are the limbs, which, as a matter of fact, are
seldom lost, although individuals with stumps of legs are occasionally
met with. The physiological importance of the tail of a lizard con-
sists in the fact that it preserves the animal from total destruction, for
pursuers will generally aim at the long trailing tail, ^ and thus the
animal often escapes, as the tail breaks off when it is firmly seized.
It is, in fact, as Leydig was the first to point out, specially adapted for
breaking off, the bodies of the caudal vertebrae from the seventh
onward being provided with a special plane of fracture so that they
easily break into two transversely. Now if this capability of fracture
is provided for by a special arrangement and modification of the parts
of the tail, we shall not be making too daring an inference if we
regard the regenerative power of the tail as a special adaptation, pro-
duced by selection, of this particular part of tJie body, the freqnent loss
of which is in a certain measure provided for, and not as the outcome
of an unknown ' regenerative power ' possessed by the entire animal.
This arrangement would not have been provided if the part had been
of no, or of only slight, physiological importance, as is the case in
snakes and chelonians, although these animals are as highly organized
as lizards. The reason that the limbs of lizards are not replaced is, I
believe, due to the fact that these animals are seldom seized by the
leg, owing to their extremely rapid movements." Overlooking the
numerous cases of the regeneration of internal organs that have been
known for several years, and basing his conclusion on a small, uncon-
vincing experiment of his own on the lungs of a few salamanders,
Weismann concludes : " Hence there is no such thing as a general
power of regeneration ; in each kind of animal this power is graduated
according to the need of regeneration in the part under consideration ;
that is to say, the degree in which it is present is mainly in proportion
to the liability of the part to injury."

After arriving at this conclusion the following admission is a
decided anticlimax : " The question, however, arises as to whether
the capacity of each part for regeneration results from special process
of adaptation, or whether regeneration occurs as the mere outcome —

1 The Germ Plasm. Translation by W. Newton Parker, 1893, P^g^ 116.

■■^ There are no facts that show that this statement is not entirely imaginary. T. H. M.

REGENERATION AND LIABILITY TO INJURY 95

which is to some extent unforeseen — of the physical nature of an
animal. Some statements which have been made on this subject seem
hardly to admit of any but the latter explanation." After showing that
some newts confined in aquaria attacked each other, " and several
times one of them seized another by the lower jaw, and tugged and
bit at it so violently that it would have been torn off had I not separated
the animals^' '^ and after referring to the regeneration of the stork's
beak, Weismann concludes: "Such cases, the accuracy of which can
scarcely be doubted, indicate that the capacity for regeneration does not
depend only on the special adaptation of a particular organ, but that
a general power also exists which belongs to the whole organism, and
to a certain extent affects many and perhaps even all parts. By
virtue of this power, moreover, simple organs can be replaced when
they are not specially adapted for regeneration." The perplexity of
the reader, as a result of this temporary vacillation on Weismann's
part, is hardly set straight by the general conclusion that follows on
the same page : " We are, therefore, led to infer that the general
capacity of all parts for regeneration may have been acquired by
selection in the lower and simpler forms, and that it gradually
decreased in the course of phylogeny in correspondence with the
increase in complexity of organization ; but that it may, on the other
hand, be increased by special selective processes in each stage of its
degeneration, in the case of certain parts which are physiologically
important and are at the same time frequently exposed to loss."

There are certain statements of facts in the same chapter that are
incorrect, and the argument is so loose and vague that it is difficult
to tell just what is really meant. As a misstatement of fact I may
select the following case : It is stated that lumbriculus does not have
the power of regenerating laterally if cut in two, and it is argued that
a small animal of this form could rarely be injured at the side without
cutting the animal completely in two. As a matter of fact, lumbricu-
lus can regenerate laterally, and very perfectly, as any one can verify
if he takes the trouble to perform the experiment ; but, of course, if
the whole a^nimal is split in two lengthwise the pieces die, or if a very
long piece is split from one side the remaining piece usually disin-
tegrates. If, however, the anterior end is split in two for a short
distance, or if a piece is partially split in two, the half remaining in
contact with the rest of the piece completes itself laterally. The
same result follows also in the earthworm.

As an example of looseness of expression I may quote the follow-
ing from Weismann : " A useless or almost useless rudimentary part
may often be injured or torn off tvithoiit causing processes of selection
to occur zvhich would produce in it a capacity for regeneration. The
^ The italics are, of course, my own. T. H. M.

96 REGENERATION

tail of a lizard again, which is very liable to injury, becomes regen-
erated because, as we have seen, it is of great importance to the indi-
vidual and if lost its owner is placed at a disadvantage." And as an
example of vagueness, the following statement commends itself :
" Finally the complexity of the individual parts constitutes the third
factor which is concerned in regulating the regenerative power of the
part in question ; for the more complex the structure is, the longer
and the more energetically the process of selection must act in order
to provide the mechanism of regeneration, which consists in the
equipment of a large number of different kinds of cells with the sup-
plementary determinants which are accurately graduated and regu-
lated as regards their power of multipHcation."

Without attempting to disentangle the ideas that are involved in
these sentences, let us rather attempt to get a general conception of
Weismann's views. In a later paper (1900), in reply to certain criti-
cisms, he has stated his position somewhat more lucidly. In the
following statement I have tried to give the essential part of his
hypotheses : Weismann believes the process of regeneration to be
regulated by " natural selection " ; in fact, he states that it has arisen
through such a process in the lower animals — since they are more
subject to injury — and that it has been lost in the higher forms
except where, on account of injury, it has been retained in certain
parts. Thus when Weismann speaks of regeneration as being an
adaptation of the organism to its environment, we must understand
him to mean that this adaptation is the result of the action of natural
selection. We should be on our guard not to be misled by the state-
ment that because regeneration is useful to the animal, it has been
acquired by natural selection, since it is possible that regeneration
might be more or less useful without in any way involving the idea
that natural selection is the originator of this or of any other adapta-
tion. It will be seen, therefore, that in order to meet Weismann on
his own ground it will be necessary to have a clear understanding in
regard to the relation of regeneration to Darwin's principle of natural
selection. With Weismann's special hypothesis of the "mechanism,"
so-called, by which regeneration is made possible we have here noth-
ing to do, but may consider it on its own merits in another chapter.

In order to have before us the material for a discussion of the
possible influence of natural selection on regeneration, let us first
examine the facts that bear on the question of the liability of the
parts to injury and their power to regenerate, and in this connection
the questions concerning the renewal of parts that are thrown off by
the animals themselves in response to an external stimulus are worthy
of careful consideration. A comparison between the regeneration of
these parts with that of other parts of the same animal gives also

REGENERATION AND LIABILITY TO INJURY 97

important data. Furthermore, a comparison may be made between
different parts of the same animal, or between the same parts of
different animals living under similar or dissimilar conditions.

There are only a few cases known in which a systematic exami-
nation has been carried out of the power of regeneration of the dif-
ferent parts of the body of the same animal. Spallanzani's results
show that those salamanders that can regenerate their fore legs can
regenerate their hind legs also. Towle, who has examined in my
laboratory the regeneration of a number of American newts and sala-
manders, finds also that both the fore and hind legs regenerate in the
same forms. The tail and the external gills, in those newts with
gills, also regenerate. It has also been shown in triton that the eye
regenerates if a portion of the bulb is left. Broussonet first showed
(1786) that the fins of fish have the power to regenerate, although,
strangely enough, Fraisse and Weismann state that very Httle power
of regeneration is present in the fins of fish. I have found that the
fins of several kinds of fish regenerate, belonging to widely different
families.^ In Funduhis JieteroclitjLs I have found that the pectoral,
pelvic, caudal, anal, and dorsal fins have the power of regeneration.
In reptiles the feet do not regenerate, — at least no cases are known, —
but the tail of lizards has this power well developed. In birds neither
the wings nor the feet regenerate, but Fraisse has described the case
of a stork in which, the lower jaw being broken off, and the upper
being cut off at the same level, both regenerated. Bordage has
recorded the regeneration of the beak of the domesticated fighting
cocks (of the Malay breed) of Mauritius. In the mammals neither
the legs, nor the tail, nor the jaws regenerate, although several of
the internal organs, as described in the next chapter, have extensive
powers of regeneration.

The best opportunity to examine the regenerative power in simi-
lar organs of the same animal is found in forms like the Crustacea,
myriapods, and insects, in which external appendages are repeated in
each or many segments of the body. In decapod Crustacea, includ-
ing shrimps,, lobsters, crayfish, crabs, hermit-crabs, etc., regeneration
takes place in the walking legs of all the forms that have been exam-
ined, and this includes members of many genera and families. I have
made an examination of the regeneration of the appendages (Fig. 37)
of the hermit-crab. In this animal, which lives in an appropri-
ated snail's shell, only the anterior part of the body projects from the
shell. The part that protrudes is covered by a hard cuticle, while the
part of the body covered by the shell is quite soft. Three pairs of
legs are protruded from the shell. The first pair with large claws

^ Fundzdus heteroclitus, Stenopus chrysops, Decapteriis macrella, Menticirrhus macrella,
Carassiiis attraius, Phoxiiiiis fuiididoides, N'oturiis sp., and a few others.
H

98

REG EN ERA TION

are used for procuring food, and as organs of offence and defence ;
the second and third pairs are used for walking. The following two
pairs, that correspond to the last two pairs of walking legs of crabs
and crayfishes, are small, and are used by the animal in bracing it-
self against the shell. The first three pairs of legs have an arrange-

FlG. 37. — Appendages of Hermit-crab (^a/a^wrzw /o;?^/Vfl/7>«j). ^. Third walking leg. B. Next
to last thoracic leg. B"^. Last thoracic leg. C, C'l, C^. Three abdominal appendages of male.
D. Teison and sixth segment with last pair of abdominal appendages. E. Regeneration of
new leg from cut-end outside of " breaking-joint." F. Leg regenerating from cut made inside
of " breaking-joint." G. Leg regenerating from cut made very near the body.

ment at the base, the "breaking-joint," by means of which the leg is
thrown off, if injured. The last two pairs of thoracic legs cannot be
thrown off. The first three pairs of legs are often lost under natural
conditions. In an examination of 188 individuals I found that 21 (or
II per cent) had lost one or more legs. If one of the first three legs
is injured, except in the outer segment, it is thrown off at the break-

REGENERATION AND LIABILITY TO INJURY 99

ing-joint, and a new leg regenerates from the broken-off end of the
stump that is left. The new leg does not become full size, and is of
little use until the crab has moulted at least once. The leg breaks
off so close to the body, and the part inside of the breaking-joint is
so well protected by the bases of the other legs, that it is scarcely
possible that the leg could be torn off inside of the breaking-joint,
and, as a matter of observation, all crabs that are found regenerating
their legs under natural conditions do so from the breaking-joint.
If, however, by means of small scissors, the leg is cut off quite near
the body, a new leg regenerates from the cut-end, even when the leg
is cut off at its very base. The breaking-joint would thoroughly pro-
tect from injury the part of the leg that lies nearer to the body, and
yet from this inner part a new leg is regenerated. Moreover, the
new leg is perfect in every respect, even to the formation of a new
breaking-joint. In this case we have a demonstration that there need
be no connection between the liability of a part to injury and its
power of regeneration.

In still another way the same thing may be shown. If the crab
is anaesthetized, and a leg cut off outside of the breaking-joint, it is
not, at the time, thrown off — the nervous system, through whose
action the breaking off takes place, being temporarily thrown out
of order. After recovery, although the leg is thrown off in a large
number of cases, it is sometimes retained. In such cases it is found
that from the cut-end the missing part is regenerated. In this case
also we find that regeneration takes place from a part of the leg that
can never regenerate under natural circumstances.

The third and fourth legs of the hermit-crab cannot be thrown
off, but they have the power of regeneration at any level at which
they may be cut off. They are in a position where they can seldom
be injured, and I have never found them absent or injured in crabs
caught in their natural environment. The soft abdomen is protected
by the snail's shell. At the end of the abdomen the last pair of
abdominal appendages serve as anchors to hold the crab in the shell.
These appenjiages are large and very hard, and can seldom be in-
jured unless the abdomen itself is broken, and under these circum-
stances the crab dies. Yet if these appendages are cut off they
regenerate perfectly, and after a single moult cannot be distinguished
from normal ones.

The more anterior abdominal appendages are present only on one
side of the adult, although they are present on both sides of the larva,
and, to judge from a comparison with other Crustacea, these append-
ages have degenerated completely on one side, and have become
rudimentary in the male, even on the side on which they are present.
They too will regenerate if they are cut off. In the female these

lOO REGENERATION

appendages are used to carry the eggs, and are, therefore, of use.
They also have a similar power of regeneration. The maxillae and
maxillipeds of the hermit-crab have likewise the power of regenera-
tion, as have also the two pairs of antennae and the eyes.

In other decapod Crustacea also it has been shown that the power
of regeneration of the appendages is well developed. It has been
long known that the crayfish and the lobster can regenerate lost
parts. The first pair of legs, or chelae, in these forms has a breaking-
joint, at which the leg can be thrown off, yet in the crayfish I have
seen that if the leg is cut off inside of the breaking-joint it will regen-
erate. The four pairs of walking legs do not possess a breaking-joint,
but may be thrown off in some cases at a corresponding level. They
regenerate from this level, as well as nearer the body and farther be-
yond this region. Przibram has recently shown that, in a number of
Crustacea, regeneration of the appendages takes place, even when the
entire leg is extirpated as completely as possible.

Newport has shown that the myriapods can regenerate their legs,
and it is known that several forms have the power of breaking off
their legs in a definite region at the base if the legs are injured, and
I have observed in Cerniatia forceps that this takes place even when
the animal is thrown into a kiUing fluid. Newport ('44) has also
shown that when the legs of a caterpillar are cut off new ones regen-
erate during the pupa stage. It has been long known ^ that the legs
of mantis can regenerate, and Bordage, who has recently examined
the question more fully, has shown that a breaking-joint is present at
the base of the leg. The tarsus of the cockroach also regenerates,
producing only four, instead of the five, characteristic segments.^

A number of writers have recorded the regeneration of the legs of
spiders.^ Schultz, who has recently examined more thoroughly the
regeneration of the legs in some spiders, finds that the leg is renewed
if cut off at any level. He removed the leg most often at the meta-
tarsus, but also at the tibia, and generally between two joints. In
some cases the leg was cut off at the coxa, at which level it is gen-
erally found to be lost under natural conditions. Wagner observed
in tarantula that when the leg is removed at any other place than at
the coxa, the animal brings the wounded leg to its jaws, and bites it
off down to the coxa. In the Epcitid(E, that Schultz chiefly made use
of, this never happened. He observed, however, even in these forms,
that when the leg is cut off at the coxa it regenerates better than

^ See Newport and Scudder.

2 Brindley, '97.

8 Lepelletur, Nouveaii Bulletin de la Socicte philoinatique, 1813, Tome III, page 254 ;
Heineken, Zool. Journal, 1828, Vol. IV, page 284 (also for insects, ibid., page 294) ;
Miiller, Manual de Physiol., Tome I, page 30 ; Wagner, W., Btdl. Soc. Imp. Natural.^
Moscow, '87.

REGENERATION AND LIABILITY TO INJURY

lOI

when cut off at any other level. Schultz states that we see here an
excellent example of how regeneration is influenced by natural selec-
tion, since regeneration takes place best where the leg is most often
broken off. On the other hand, the author hastens to add that since
regeneration also takes place when the leg is cut off at any other

-laii w'

5 -A. ..,

-r- r-. ® -'^

: i

A

*>./

x-

T^

V

F

Fig. 38. — A-F. AfterKing. A. Starfish with four arms regenerating at different levels. 5. Three
arms regenerating from disk. C. Arm split in two producing two arms. D. Arm cut off
obliquely, regenerating at right angles to cut-surface. E. Startish split between two aims,
producing two new arms from split. F. An arm, with a small piece of disk attached, regen-
erating three new arms. G. After P. and F. Sarasin. Starfish {Linck'ia 7nidtifo7-mis) with
four new arms springing from end of one arm. Interpreted as a new starfish, but probably
only multiple arms (see C, above).

level, this shows that the power to regenerate is characteristic of all
parts of the organism, and is not merely a phenomenon of adaptation,
as Weismann believes. It seems highly improbable that a spider
could ever lose a leg in the middle of a segment, i.e. between two
joints, since the segments are hard and strong and the joints much

1 02 RE GENERA TION

weaker; but nevertheless the leg has the power to regenerate also
from the middle of the segment, if cut off in this region.

The formation of the new part takes place somewhat differently,
according to Schultz, when the leg is amputated between two seg-
ments than when cut off at the coxa. In the latter case, there is pro-
duced from the cut-end of the last segment a solid rod which, as it
grows longer, bends on itself several times. Joints appear in the
rod, beginning at the base. The leg is set free at the next moult.
If the leg is cut off nearer the distal end a smaller rod is formed,
that extends straight forward, or may be thrown into a series of folds.
It lies, however, inside of the last segment, since the surface exposed
by the cut is quickly covered over by a chitinous covering. The piece
is set free at the next moult.

Loeb has found that if the body of the pycnogonid, Phoxichili-
diiini maxillare, is cut in two there regenerates from the posterior
end of the anterior half a new body-like outgrowth.

Without attempting to describe the many cases in worms and
mollusks in which there is no obvious connection between the power
of the part to regenerate and its liability to injury, but where it is
more difficult to show that it may not exist, let us pass to an examina-
tion of the regeneration of the starfish. It has been known since the
time of Reaumur that starfish have the power of regenerating new
arms if the old ones are lost. It has been stated that in certain
starfishes an arm itself can produce a new starfish, — Haeckel {^7'^^,
P. and R. Sarasin ('88), von Martens ('84), and Sars ('75, — but this
has been denied by other observers. In several species of starfishes,
the separated arm does not regenerate ; but if a portion, even a small
piece, of the disk is left with the arm, a new disk and arms may
develop (Fig. 38, F^. When the arm of Asterias vulgaris is injured
it pinches off in many cases at its base, and a new arm grows out from
the short stump that remains. When these starfishes regenerate
new arms in their natural environment, the new arms almost always
arise from this . breaking region.^ Thus King found out of 1914
individuals of Asterias vulgaris collected at random, 206, or 10.7
per cent, had one or more new arms, and all these except one arose
from near the disk. In other species it appears that the outer por-
tions of the arm may be broken off without the rest of the arm being

^ The Sarasins have described several cases in Linckia multiformis in which an old arm
has one or more new arms arising from it. In one case (copied in our Fig. 38, tP), four rays
arise from the end of one arm, producing the appearance of a new starfish. In fact the
Sarasins interpret the result in this way, although they state that there is no madreporite on
the upper surface, and they did not determine whether a mouth is formed at the convergence
of the rays, because they did not wish to destroy so unique a specimen — even to find out
the meaning of it. There seems to me little probability that the new structure is a starfish,
but the old arm has been so injured that it has produceil a number of new arms.

REGENERATION AND LIABILITY TO INJURY 103

thrown off. King has found that in asterias, regeneration takes place
more rapidly from the base than at a more distal level. It may-
appear, at first thought, that the more rapid regeneration of the arm
at the place at which^ it is usually thrown off may be associated with
its more frequent loss at this region — in other words, that the more
rapid regeneration has been acquired by the region at which the arm
is generally broken off. This interpretation is, however, excluded by
the fact that, in general, the nearer to the base the arm is cut off, so
much the more rapid is its regeneration. In other words, the more
rapid regeneration of the arm at the base is only a part of a general
law that holds throughout the arm. If the proposition is reversed,
and it is claimed that the arm has acquired the property of breaking
off at the base, because it regenerates more rapidly at that level, the
following fact recorded by King is of importance, viz. that, although
the arm regenerates faster at the base, yet a new arm is not any
sooner produced in this way, since there is more to be produced and
the new arm from the base may never catch up to one growing less
rapidly from a more distal cut-surface, but having a nearer goal to
reach.

The results of our examination show that those forms that are
liable to have certain parts of their bodies injured are able to regener-
ate not only these parts, but at the same time other parts of the body
that are not subject to injury. The most remarkable instance of this
sort is found in those animals having breaking-joints. In these
forms, we find that regeneration takes place both proximal and distal
to this region. If the power of regeneration is connected with the
liability of a part to injury, this fact is inexplicable.

Turning now to the question as to whether regeneration takes
place in those species that are subject to injury more frequently or
better than in other species, we find that the data are not very com-
plete or satisfactory for such an examination. It is not easy to ascer-
tain to what extent different animals are exposed to injury. If we
pass in review the main groups of the animal kingdom, we can at
least glean sqme interesting facts in this connection.

In the protozoa nucleated pieces have been found to regenerate
in all forms that have been examined, including amoeba, difllugia,
thalassicolla, paramoecium, stentor, and a number of other ciliate
infusoria.

In the sponges it has been found by Oscar Schmidt that pieces
may produce new individuals, but how widely this occurs in the group
is not known. In the ccelenterates many forms are known to regen-
erate, and it is not improbable that in one way or another the process
occurs throughout the group. The hydroid forms, hydra, tubularia,
parypha, eudendrium, antennularia, hydractinia, podocoryne, etc.,

1 04 RE GENERA TIOIV

the jelly-fish, gonionemus, and certain members of the family Thau-
mantidcB, have been found to regenerate. Amongst the Scyphosoa,
metridium, cerianthus, and the scyphistoma of aurelia regenerate,
and the jelly-fishes belonging to this group have a limited amount of
regenerative power.

In the platodes we find that all the triclads, thus far examined,
including planaria, phagocata, dendrocoelum, and the land triclad,
bipalium, regenerate. It has been shown that the marine triclads
also regenerate, but less rapidly and extensively, while the marine
polyclads have very limited powers of regeneration. The regeneration
of the trematodes and cestodes has not, so far as I know, been studied,
neither have the nematodes been examined from this point of view.

Some of the nemerteans regenerate, others do not seem to have
this power. A small fresh-water form, tetrastemma, that I examined,
did not regenerate, although some of the pieces, that were filled with
eggs, remained alive for several months.

In the annelids we find a great many forms that regenerate —
many marine polychseta have this power ; all oligochaeta that have
been studied regenerate ; both land forms, like lumbricus, allolobo-
phora, etc., and fresh-water forms, like lumbriculus, nais, tubifex, etc.

In the Crustacea the appendages have the power to regenerate in
all the forms that have been examined.

Several kinds of myriapods, as well as a number of spiders, are
known to regenerate their legs. In the insects, however, only a few
forms are known to have this power, — caterpillars, mantis, and the
cockroach. The large majority of insects, in the imago state, do not
seem to be able to regenerate, although in a few cases regeneration
has been found to occur.^

In the mollusks, regeneration of the head takes place under certain
conditions. Spallanzani thought that if the entire head is cut off a
new one regenerates. This conclusion was denied by at least eleven
of his contemporaries, and confirmed by about ten others. It was
found later that the result depends in part on the time of year and in
part on the kind of snail. Carriere, who more recently examined the
question, found that even under the most favorable conditions regen-
eration does not take place if the circumoesophageal nerve-commissure
is completely removed with the head, but if a part remains, a new
head develops. It has been stated that a new foot regenerates in
helicarion, and I have found that the foot regenerates also in the fresh-
water snails, physa, limnasa, and planorbis. If the margin of the
shell of a lamellibranch or of a snail is broken off, it is renewed by
the mantle. The arms of some of the cephalopods are known to
regenerate, particularly the hectocotylized arm.

1 For a review of the literature see Brindley, '98.

REGENERATION AND LIABILITY TO INJURY

105

In all the main groups of echinoderms, with one possible excep-
tion, regeneration has been found to take place. Probably all star-
fishes and brittle-stars regenerate their arms, and even if cut in two
or more pieces, new starfishes develop. The crinoids regenerate lost
arms, and even parts of the disk ; also the visceral mass. The holo-
thurians have very remarkable powers of regeneration. In some
forms regeneration takes place if the animals are cut in two, or even
in more than two pieces. The remarkable phenomenon of eviscera-
tion that take place in certain holothurians, if they are roughly
handled, or kept under unfavorable conditions, are well known and
have been described by a number of writers. It has even been sug-
gested that the holothurian may save itself by offering up its viscera

Fig. 39. — A. A/nphiiima means with left fore and hind leg regenerating. B. Necturus maculatus
with right fore leg beginning to regenerate after eight months. C. Plethedon cinereus. A,
B, C. Drawn to same scale.

to its assailant ! Unfortunately for this view, it has been found that
the viscera are unpalatable, at least to sea-anemones and to fishes.
Ludwig and Minchin suggest that the throwing off of the Cuvierian
organs, which are attached to the cloaca, is a defensive act, and if car-
ried too far, according to the latter writer, the viscera may also be
lost. The holothurians have remarkable recuperative powers and
may regenerate new viscera in a very short time. The sea-urchins
form, perhaps, an exception in this group, since there are no records
of their regenerative power, but no doubt this is because they have
not been as fully investigated as have other forms.

In the vertebrates the lower forms, amphioxus, petromyzon, and
sharks, have not been studied in regard to their regenerative power.

1 06 RE GENERA TION

In the teleostean fishes the fins of a number of forms are known to
regenerate. It is probable that this takes place in most members of
the group.

In the amphibia we find a large number of forms that regenerate
their limbs and tail, and other parts of the body, but limitations appear
in certain forms. The rapid regeneration of the legs in the smaller
urodeles has been often described. In larger forms it takes place
more slowly, at least in large forms having large legs. In proteus
the regeneration may extend over a year and a half, and in necturus
it takes more than a year to make a new limb, at least in animals in
confinement. In the large form, amphiuma, that has extremely small
legs, regeneration takes place much more rapidly than in a form like
necturus having much larger legs (Fig. 39).

In amphiuma the feet are not used by the animal as organs of
locomotion, since they are too small and weak to support the heavy
body. They can be moved by the animal in the same way that the
feet are moved in other forms, and yet are useless for progression.
It is said by Schreiber that the regeneration of the legs of Triton
■martnoratus is relatively very slight as compared with that of other
forms. Fraisse also found in this form that an amputated leg did
not grow again, only a deformed stump being produced. The tail
also is said to regenerate to only a slight extent, but, so far as I know,
there is nothing peculiar in the life of this form that makes it less
liable to injury than other large urodeles.^ Weismann cites the case of
proteus, which is said also to regenerate less well than do other forms.
It lives in the caves of Carniola, where there are few other animals
that could attack or injure it, and to this immunity is ascribed its lack
of power of regeneration ; yet Goette states that he observed a regen-
erating leg in this form, but that the process was not complete after
a year and a half. In necturus also, which is not protected in any
way, regeneration is equally slow. Frogs are unable to regenerate
their limbs, although they are sometimes lost, but the larval tadpole
can regenerate at least its hind legs. In the Hzards the tail regen-
erates, but at present we do not know of any connection between
this condition and the liability of certain forms to injury. Turtles
and snakes do not regenerate their tails. I do not know of any
observations on crocodiles.

In birds, the legs and wings are not supposed to have the power
to regenerate,^ but in two forms ^ at least the beak has been found to

1 I do not know whether this animal was kept long enough to make it certain that the
legs do not regenerate.

2 A statement to the contrary quoted in Darwin's Animals and Plaiits under Domesti-
cation is doubted by Darwin himself.

* The stork and the fighting cocks.

REGENERATION AND LIABILITY TO INJURY lO/

possess remarkable powers of regeneration. There are a few very-
dubious observations in regard to the regeneration in man of super-
fluous digits that had been cut off.^

These examples might be added to by others in the groups cited,
and also by examples taken from the smaller groups of the animal
kingdom, but those given will suffice, I think, to show that the power
to regenerate is characteristic of entire groups rather than individual
species. When exceptions occur, we do not find them to be forms
that are obviously protected, but the lack of regeneration can rather
be accounted for by some peculiarity in the structure of the animal.
If this is borne in mind, as well as the fact that protected and unpro-
tected parts of the same animal regenerate equally well, there is
established, I think, a strong case in favor of the view that there is
no necessary connection between regeneration and liability to injury.
We may therefore leave this side of the question and turn our atten-
tion to another consideration.

It will be granted without argument that the power of replacement
of lost parts is of use to the animal that possesses it, especially if the
animal is liable to injury. Cases of usefulness of this sort are gener-
ally spoken of as adaptations. The most remarkable fact in connec-
tion with these adaptive responses is that they take place, in some
cases at least, in parts of the body where they can never, or at most
very rarely, have taken place before, and the regeneration is as per-
fect as when parts liable to injury regenerate. Another important
fact is that in some forms the regeneration is so slow that if the
competition amongst the animals was very keen those with missing
legs, or eyes, or tails, would certainly succumb ; yet, if protected, they
do not fail to regenerate. If, therefore, the animal can exist through
the long interval that must elapse before the lost part regenerates,
we cannot assume that the presence of the part is of vital importance
to the animal, and hence its power to regenerate could scarcely be
described as the result of a "battle for existence," and without this
principle "natural selection" is powerless to bring about its supposed
result.

It is extremely important to observe that some cases, at least, of
regeneration are not adaptive. This is shown in the case where a new
head regenerates at the posterior end of the old one in Plaiiaria
higubris, or where a tail develops at the anterior end of a posterior
piece of an earthworm, or when an antenna develops in place of an
eye in several Crustacea. If we admit that these results are due to
some inner laws of the organism, and have nothing to do with the rela-
tion of the organism to its surroundings, may we not apply the same
principle to other cases of regeneration in which the result is useful }

1 See Darwin, loc cit.

1 08 RE GENERA TION

So firm a hold has the Darwinian doctrine of utihty over the
thoughts of those who have been trained in this school, that whenever
it can be shown that a structure or a function is useful to an animal,
it is without further question set down as the result of the death
struggle for existence. A number of writers, being satisfied that the
process of regeneration is useful to the animal, have forthwith sup-
posed that, tJierefore, it must have been acquired by natural selection.
Weismann has been cited as an example, but he is by no means alone
in maintaining this attitude. It would be entirely out of place to
enter here into a discussion of the Darwinian theory, but it may be
well worth while to consider it in connection with the problem of
regeneration.

We might consider the problem in each species that we find
capable of regenerating ; or, if we find this too narrow a field for our
imagination, we might consider the process of regeneration to have
been " acquired by selection in the lower and simpler forms," and
trace its subsequent progress as it decreased in the course of phylog-
eny " in correspondence with the increase in complexity of organiza-
tion," or with the decrease of exposure to injury. At the risk of
adopting the narrower point of view I shall confine the discussion to
the possibility of regeneration being acquired, or even augmented,
through a process of natural selection in any particular species.

The opportunity to regenerate can only occur if a part is removed
by accident or otherwise. On the Darwinian theory we must suppose
that of all the individuals of each generation that are injured, in
exactly the same part of the body, only those have survived or have
left more offspring that have regenerated. In order that selection may
take place, it must be supposed that amongst these individuals injured
in exactly tJie same region, regeneration has been better in some forms
than in others, and that this difference is, or may be, decisive in the
competition of the forms with each other. The theory does not
inquire into the origin of this difference between individuals, but
rests on the assumption of individual differences in the power to
regenerate, and assumes that these differences can be heaped up by
the survival and inbreeding of the successful individuals; i.e. it is
assumed that, by this picking out or selection through competition in
each generation of the individuals that regenerate best, the process
will become more and more perfectly carried out in the descendants,
until at last each part has acquired XkxQ power of complete regeneration.

There are so many assumptions in this argument, and so many
possibilities that must be realized in order that the result shall follow,
that, even if the assumptions were correct, one might still remain
sceptical in regard to the possibiHties ever becoming realized. If we
examine somewhat more in detail the conditions necessary to bring

REGENERATION AND LIABILITY TO INJURY 109

about this supposed process, we shall find ample grounds for doubt,
and even, I think, for denial that the results could ever have been
brought about in this way.

In the first place, the assumption that the regeneration of an
organ can be accounted for as a result of the selection of those indi-
vidual variations that are somewhat more perfect, rests on the
ground that such variations occur, for the injury itself that acts as a
stimulus is not supposed to have any direct influence on the result,
i.e. for better or worse. All that natural selection pretends to do is
to build up the complete power of regeneration by selecting the most
successful results in the right direction. In the end this really goes
back to the assumption that the tissue in itself has power to regen-
erate more completely in some individuals than in others. It is just
this difference, if it could be shown to exist, that is the scientific
problem. But, even leaving this criticism to one side, since it is very
generally admitted, it will be clear that in many cases most of the
less complete stages of regeneration that are assumed to occur in the
phyletic series could be, in each case, of very little use to the indi-
vidual. It is only the completed organ that can be used ; hence the
very basis of the argument falls to the ground. The building up of
the complete regeneration by slowly acquired steps, that cannot be
decisive in the battle for existence, is not a process that can be
explained by the theory.

There is another consideration that is equally important. It is
assumed that those individuals that regenerate better than those that
do not, survive, or at least have more descendants ; but it should not
be overlooked that the individuals that are not injured (and they will
belong to both of the above classes) are in even a better position than
are those that have been injured and have only incompletely regen-
erated. The uninjured forms, even if they did not crowd out the
regenerating ones, which they should do on the hypothesis, would
still intercross with them, and in so doing bring back to the average
the ability of the organism to regenerate. Here we touch upon a
fatal objection to the theory of natural selection that Darwin himself
came to recognize in the later editions of the Origin of Species,
namely, that unless a considerable number of individuals in each gen-
eration show the same variation, the result will be lost by the swamping
effects of intercrossing. If this be granted, there is left very httle
for selection to do except to weed out a few unsuccessful competitors,
and if the same causes that gave origin to the new variation on a
large scale should continue to act, it will by itself bring about the
result, and it seems hardly necessary to call in another and question-
able hypothesis.

Finally, a further objection may be stated that in itself is fatal to

no REGENERATION

the theory. We find the process of regeneration taking place not
only at a few vulnerable points, but in a vast number of regions, and
in each case regenerating only the missing part. The leg of a sala-
mander can regenerate from every level at which it may be cut off.
The leg of a crab also regenerates at a large number of different
levels, and apparently this holds for all the different appendages. If
this result had been acquired through the action of natural selection,
what a vast process of selection must have taken place in each species !
Moreover, since the regeneration may be complete at each level and
in each appendage without regard to whether one region is more
liable to injury than is another, we find in the actual facts themselves
nothing to suggest or support such a point of view.

If, leaving the adult organism, we examine the facts in regard to
regeneration of the embryo, we find again insurmountable objections
to the view that the process of regeneration can have been produced
by natural selection. The development of whole embryos from each
of the first two or first four blastomeres can scarcely be accounted for
by a process of natural selection, and this is particularly evident in
those cases in which the two blastomeres can only be separated by a
difficult operation and by quite artificial means. If a whole embryo
can develop from an isolated blastomere, or from a part of an embryo
without the process having been acquired by natural selection, why
apply the latter interpretation to the completing of the adult organism "t

Several writers on the subject of regeneration in connection with
the process of autotomy (or the reflex throwing off of certain parts of
the body) have, it seems to me, needlessly mixed up the question of
the origin of this mechanism with the power of regeneration. If it
should prove true that in most cases the part is thrown off at the
region at which regeneration takes place to best advantage, it does
not follow at all that regeneration takes place here better than else-
where, because in this region a process of selection has most often
occurred. The phenomenon of regeneration in the arm of the star-
fish, that has been described on a previous page, shows how futile is
an argument of this sort. If, on the other hand, the autotomy is
supposed to have been acquired in that part of the body where regen-
eration takes place to best advantage, then our problem is not con-
cerned with the process of regeneration at all, but with the origin of
autotomy. If the attempt is made to explain this result also as the
outcome of the process of natural selection acting on individual vari-
ations, many of the criticisms advanced in the preceding pages
against the supposed action of this theory in the case of regeneration
can also readily be applied to the case of autotomy. In Chapter
VIII, in which the theories of autotomy are dealt with, this problem
will be more fully discussed.

CHAPTER VI

REGENERATION OF INTERNAL ORGANS. HYPERTROPHY.

ATROPHY

It is a more or less arbitrary distinction to speak of internal in
contrast to external organs, since the latter contain internal parts ; but
the distinction is, for our present purposes, a useful one, especially in
regard to the question of regeneration and liability to injury. In this
connection we shall find it particularly instructive to examine those
cases of regeneration of internal organs that cannot be injured, under
natural conditions, without the animal itself being destroyed. An
illustration of this may be given. The liver, or the kidney, or the
brain of a vertebrate can seldom be exposed to accidental injury with-
out the entire animal being destroyed, although, of course, diseases
of various kinds may injure these organs without destroying the ani-
mal, but cases of the latter kind are not common.

The experiments made by Ponfick ('90) on the regeneration of the
liver in dogs and in rabbits gave the most striking results. Ponfick
found after removal of a fourth, or of a half, or even, in a few success-
ful operations, of three-fourths of the liver, that, in the course of four
or five weeks, the volume of the remaining part increased, and in the
most extreme case, to three times that of the piece that had been
left in the body. The first changes were found to have begun as
early as thirty hours after the operation, when the liver cells had
begun to divide. The maximum number of dividing cells was found
about the seventh day, and then decreased from the twentieth to the
twenty-fifth day, but cells were found dividing even on the thirtieth
day. These dividing cells appeared everywhere throughout the liver,
and were no more abundant at the cut-edges than elsewhere. There
takes place, in consequence, an increase in the volume of the liver,
rather than a replacement of the part that is removed. The increase
takes place in the cells of the old part, the lobules swelling up to two,
three, or even four times their former size. No new liver lobules
seem to be formed. The old tubules of the liver also become larger,
owing to an increase in the number of their cells. Since the change
takes place in the old part, and is due to an increase in size of the

1 1 2 REGENERA TION

lobules, tubes, etc., the process is spoken of as one of hypertrophy
rather than of regeneration.

Kretz found a case in which the entire parenchyma of the liver
seemed to have been destroyed, presumably by a poison from some
micro-organism, and later a regeneration of the tissue had taken
place. If this conclusion is correct, it shows that sometimes an in-
ternal organ may meet with an injury that does not directly destroy
the rest of the body, and the animal may survive.

The regeneration of the salivary gland of the rabbit described by
Ribbert is another example of an internal organ that can seldom be
injured, and yet can be replaced after artificial removal. Weismann
('93) has recorded an experiment in which half of a lung of triton
was cut off. After fourteen months the lung had not been restored
in four individuals, and in one " it was doubtful whether a growth of
the lung had not taken place, but even in this case it had not recov-
ered its long, pointed form."

The regeneration of the eye in triton was first made known by
Bonnet. The right eye was partly cut out, and after two months it had
completely regenerated. Blumenbach, in 1784, removed the anterior
part of the bulb of the eye of " Lacerta lacustrisy Six months later
a smaller bulb was present. Phillipeaux ('80) found that if the eye
of an aquatic salamander was not entirely removed, a new eye regener-
ated ; but if the eye was completely extirpated a new eye did not
appear. Colucci, in 1885, described the regeneration of the lens of
the eye of triton from the edge of the optic cup. Wolff, later, inde-
pendently, discovered the same fact, and it has been more recently
confirmed by E. Miiller ('96), W. Kochs ('97), P. Rothig ('98), and
Alfred Fischel ('98). The most important part of this discovery is
that the new lens develops from the margin of the optic cup, and not
from the outer ectoderm, as it does in the embryo. This result will
be more fully discussed in a later chapter. It is highly probable in
this case that the regeneration stands in no connection whatsoever
with the liability of the eye to injury, for of the large number of
salamanders that have been examined, none has been found with
the eye mutilated. The position of the eye is such that it is well
protected from external injury, and the tough cornea covering its
outer surface would also further protect it from accidental injury.
When we recall the high degree of structural complexity of the eye,
its capacity to regenerate, if only a portion of the bulb is left, and its
power to replace the lens if this is removed are certainly very remark-
able facts. We find here, I think, an excellent refutation of the
incorrectness of the general assumption of a connection between
regeneration and liability to injury. Moreover, since there is no
evidence whatsoever to show that the eyes in these animals are ever

REGENERATION OF INTERNAL ORGANS II3

subject to diseases caused by bacteria, and much evidence to show that
they are not so injured, we are still further confirmed in our general
conclusion.

It has been known for a long time that even in man the lens of
the eye is sometimes regenerated after its removal. The regeneration
has been supposed to take place from the old capsule of the lens, or
possibly from a piece of the lens left after the operation ; but what-
ever its origin, the fact of its regeneration in man, and in other mam-
mals also, is a point of some interest in this connection.

Podwyssozki ('86) found that regeneration may take place in the
kidney of certain mammals, — best in the rat, more slowly in the rabbit.
The restoration of the lost part takes place first by replacement of
the epithelium. The old canals may then push out into the connec-
tive tissue that accumulates in the new part, but there is no new for-
mation of canals or of glomeruli. According to Podwyssozki the
regeneration of the kidney is less complete than that of any other
gland. Peipers has reinvestigated the subject, and his results agree
in the main with those just given. He finds in addition that new
canals may grow out from the old ones into the new part.

Podwyssozki and Ribbert ('97) have found that the salivary gland
has a remarkable power of regeneration. Ribbert removed a half
(or even more than this) of the salivary gland of the rabbit. In the
course of two or three weeks new material had developed over the
cut-surface. In one case at least five-sixths of the gland had been
taken out, and at the end of three weeks the gland had regenerated
to its full size. Microscopic examination showed that the greater
part of the gland was made up of new lobes, some of which were as
large as, others smaller than, the normal lobes. The new part con-
tained new tubes with terminal acini. These had arisen from the
tubes of the old part. The connective tissue of the new part also
came from that of the old. In this case a true process' of regenera-
tion takes place from the cut-surface ; in addition a certain amount of
enlargement, or hypertrophy, also takes place in the old part. Rib-
bert believes there is a connection between the process of hypertrophy
and of regeneration of such a kind that the more active the one, the
less active the other.

Regenerative changes are known to occur in other internal organs
besides these glandular ones. Broken bones are united, if brought in
contact, by a process that involves a certain amount of regeneration.
Although new bony tissue may be formed at the region of union, the
bones of mammals and of birds do not seem able to complete them-
selves, if a part is removed, except to a limited extent. While the
broken bones of the leg or of the arm have the power of reuniting if
held for some time in place, yet in nature this condition can seldom

114 2<E GENERA 7 'ION

be fulfilled, and the animal with a broken leg or wing will most prob-
ably be killed. Nevertheless, since the bones have this power at
whatever level they may be Jaroken (but only if they are kept together
artificially), the process can scarcely have been acquired through the
liability of the parts to injury. We find here another instance of a
useful process existing in animals, but one that could not have been
acquired by exposure of the part to injury. It is probable that this
same property is found in all the bones of the body, — in those that
may occasionally be injured, and in those that are not.

The muscles have also the power of regenerating, although few
experiments have been made except in those forms in which the
whole leg can regenerate, yet there are a few observations that show
that even in mammals, in which the leg or the arm cannot regenerate
as a whole, a certain amount of regeneration of the muscles them-
selves may take place.

It has been known for a long time that if a nerve is cut a new
nerve grows out from the cut-end, and may extend to the organs sup-
plied by that nerve. The process takes place more successfully if
the peripheral part is left near the cut-end from which the new nerve
grows. Whether this old part only serves to guide the new part to
its proper destination, or whether it may also contribute something to
the new nerve, as, for instance, cells for the new sheath, is not finally
settled. The general opinion in regard to the origin of the new nerve
fibres is that the central axis or fibril grows from the cut-end. That
this power could have been acquired for each nerve as a result of its
liability to injury is too improbable to discuss seriously.

The central nervous system of the higher vertebrates seems to
have very little power of regeneration, and although in some cases
a wounded surface may be covered over and a small amount of con-
nective tissue be formed, the development of new ganglion cells does
not seem to occur. In other animals, as the earthworm, planarian,
and even in the ascidian, as shown by Loeb, a new entire brain may
develop after the removal of the old brain, or of that part of the
body in which it is contained.

This examination of the power of regeneration of internal organs
in the vertebrates has shown that it is highly improbable that there
can be any connection between their power of regeneration and their
liability to injury. That the internal organs may be occasionally
injured by bacteria, or by poisons made in the body, may be admitted,
but that injuries from this source have been of sufficient frequency
to establish a connection, if such were indeed possible, between their
power of regeneration and their liability to injury from these causes
is too improbable a view to give rise to much doubt. These results
taken in conncctio'i with those discussed in the preceding chapter go

HYPER TR OPHY I i 5

far toward disproving the view that the power of regeneration has a
connection with the liability of a part to injury.

HYPERTROPHY

The hypertrophy, or unusual enlargement, of organs has long
attracted the attention of physiologists, and the extremely interesting
observations and experiments that have been made in this connection
have an important although an indirect bearing on the problem of
regeneration. Ribbert, as has been pointed out, holds that the
processes of hypertrophy and of regeneration stand in a sort of
inverse relation to each other, but it is doubtful, I think, if any such
general relation exists. Two kinds of hypertrophy are now generally
distinguished : functional hypertrophy, which takes place when a
part becomes enlarged through use ; and compensating hypertrophy,
which takes place when one organ being removed another enlarges.
The enlargement in the latter case may, of course, be brought about
by the increased use of the parts that enlarge, but as this is not
necessarily the case, the distinction between the two processes is a
useful one. The causes of compensating hypertrophy are by no
means simple, and several possibilities have been suggested to
account for the enlargement. The best ascertained facts in con-
nection with hypertrophy relate almost entirely to man and to a
few other mammals. ^

By hypertrophy is meant an increase of the substance of which
an organ is composed. Swelling due to the imbibition of water or
of blood-serum is not, in a technical sense, a process of hypertrophy.
Virchow distinguishes two kinds of hypertrophy: (i) Hypertrophy
in a narrower sense in which the enlargement is due to an increase
in the size of the cells of which an organ is composed. This en-
largement of the individual cells leads of course to an increase in
the size of the whole organ. (2) Hyperplasy due to an increase
in the number of cells of which an organ is composed, which also
causes an enlargement of the whole organ if the cells retain the
normal size. ' The division into functional and compensating hyper-
trophy given above is a physiological distinction, and both of these
processes might occur in Virchow's subdivisions.

Giants may be looked upon as hypertrophied individuals, since all
the organs of the body are larger than the normal. The enlargement
is, in this case, not due to external influences, but to some peculiarity

1 The more generally accepted results are given in Virchow's Celhdai' Pathology and
in Ziegler's Pathological Anatomy. An excellent review of the subject dovi'n to 1895
is given in a summary by Ludwig Aschoff in the Ergebnisse d. allgem. patholog. Morphol.
und Physiologie, 1895, "Regeneration und Hypertrophic," in which there are two hundred
and eighteen references to the literature.

1 1 6 RE GENERA TION

of the organism itself. Whether the size is due to more cells being
present, as seems probable, or to the cells being larger, or to both,
has not, so far as I know, been determined for man. In a mollusk,
CrepidiUa fornicata, in which large and small adult individuals occur,
it has been shown by Conklin ('98) that the difference is due entirely
to the larger number of cells in the larger individual. In this case
external conditions, in so far as they retard the maximum possible
growth of the individual, are responsible for the differences in size.
The distinction is, in this case, rather between large normal indi-
viduals and dwarfs, than between giants and normal or average
individuals.

The voluntary muscles of the body of man grow larger, and may
be said to hypertrophy, as a result of doing certain kinds of work.
The muscles of the hand and arm grow large through use, and
become smaller again if not used ; but the muscles of the fingers of a
musician do not hypertrophy, although the total amount of work done
may Ipe very large. It is only when muscular work is done against
great resistance that enlargement of the muscles takes place. The
factors that may bring about the enlargement will be discussed later.

The kidneys seem to give the most satisfactory evidence of com-
pensating hypertrophy. NothnageP states that it has been shown
in man, in the rabbit, and in the dog, that when one kidney has been
removed the other enlarges ; and that this takes place both for young
animals, in which the kidneys have not reached their full size, and in
adult animals, in which the remaining kidney becomes larger than
normal. In the adult the enlargement is due to hypertrophy, in
Virchow's sense, in the tubules and in the epithelium of the canals.
In the young animal there is, in addition, a hyperplastic growth that
leads to an increase in the number of glomeruli, etc.

Experiments have shown that the same amount of urea is excreted
by the animal after the removal of one kidney as before ; in fact, this
is true immediately after the operation, before any increase in the
size of the organ has taken place. This means that, under normal
conditions, the kidneys do not perform their maximum of work. It
is important to observe in this connection that the remaining kidney
gets more blood than it would get if the other were present. Noth-
nagel sums up the changes that take place in this way : First, the
removal of one kidney ; second, an increase in the flow of blood in
the remaining kidney ; third, an increase in the functional activity and
excretion of this kidney ; fourth, along with the increase in the flow
of blood, there is a necessary increase in the amount of food that is

1 Nothnagel gives a review of the subject down to 1886 in an article entitled "liber
Anpassung und Ausgleichung bei pathologischen Zustdnden. Zeitsch. f. klinische Medicin."
1886. Vols. X and XI.

HYPER TROPHY 1 1 7

brought to the kidney in the blood ; fifth, this food is taken up in
larger amount than before by the cells, which leads to an increase in
the growth of the cells, which produces hypertrophy. The increase
in size, looked at from this point of view, Nothnagel says, has nothing
mysterious about it. The enlargement seems to be an adaptation ; but
the enlargement does not take place because it is an adaptive process,
but because it cannot be helped under the conditions that arise. We
shall return again to Nothnagel's interpretation, when we come to
consider other views.

Experiments of the sort just described are most easily carried out
on the paired organs of the body, such as the salivary glands, the
tear glands, the mammae of the female, and the testes of the male.
In regard to the latter two organs the evidence, especially in the case
of the testes, is conflicting, but the recent experiments of Ribbert
seem to give definite results. Nothnagel had found that after the re-
moval of one testis there is no hypertrophy of the other. He pointed
out that this, result does not stand in contradiction to his hypothesis
in regard to the kidneys, for the loss of one testis does not lead to
a greater functional activity in the other. Each acts for itself alone.
The result shows further, he adds, that the process of hypertrophy
is not an adaptive one, but a physical or a physiological process.
Ribbert on the contrary thinks that even Nothnagel's statistics give
evidence of hypertrophy, and Ribbert's own experiments give un-
mistakable evidence of a considerable enlargement of the remaining
testis. In his experiments, young rabbits were used that were born
of the same mother and in the same litter. One of the testes was
removed from some of the individuals, and after some months the
remaining testis was taken out and its weight compared with that
of the control animal. In sixteen out of seventeen experiments there
was found to be a noticeable increase in the single testis as compared
with either testis of the control animal. The results show that in
some cases the single testis weighs almost as much as the two to-
gether of the control animal. It is important also to notice that
in this case th.e enlargement has taken place in an organ that has not
been active, as was the case with the kidney.

Ribbert has also shown that hypertrophy takes place in the
mammae of the rabbit after the removal of some of them. Five out of
the eight mammae were removed in three cases, and seven out of the
eight in two other cases from young rabbits about two months old.
Ribbert found that if the operator is not careful to remove completely
all the tissue of a mamma an active regenerative process takes place
from the part that remains. After five and a half months the single
remaining mamma of one animal measured six and one-half by three
and four-fifths centimetres, and the corresponding one in the control

T 1 8 RE GENERA TION

animal five and three-fourths by three and one-half centimetres. The
glandular tissue was also found less developed in the control animal.

In another experiment the rabbit experimented upon bore young
when it was six and a half months old. Soon after the birth of the
young and before the mamma had been used the animal was killed
and the single mamma that had been left was measured. It was
much enlarged and projected more than the normal mammae. It
measured nine by five centimetres. In a normal control animal ^ the
corresponding mamma measured seven by five centimetres. The
number of acini was in the proportion of sixteen in the animal oper-
ated upon to ten in the normal. The results show a distinct com-
pensating hypertrophy, due to a hyperplastic increase in the number
of elements of the gland.

A further example of compensating hypertrophy has been found
after the removal of the spleen, when the lymphatic glands of other
parts of the body become enlarged. There are also observations
which go to show that after the removal of some of the lymphatic
glands others undergo an enlargement.

Ziegler^ has given a critical review of the various opinions and
hypotheses that have been advanced to account for the process
of hypertrophy. According to Cohnheim^ hypertrophy in bones,
muscles, spleen, and glands is due to hyperaemia, i.e. increased blood
supply. He thinks that neither mechanical nor chemical stimuH can
cause directly new processes of growth. Recklinghausen* thinks
that hypertrophy is not due to any extent to an increase in the food
supply. Samuel^ explains hypertrophy as due to a removal of, or
to a decrease in, the resistance to growth and also to the influence
of the nerves. Klebs ^ thinks that three factors enter into the prob-
lem, {a) inherited peculiarities, ijj) overfeeding, (<;) a removal of the
controlling influences. Weigert believes that reparative processes
are due to the removal of influences that prevent growth, and not
to a direct stimulus. He thinks that a stimulus may start a func-
tional act, but can never start a nutritive or a formative one. Good
nourishment, for instance, may bring a tissue to a maximum develop-
ment that is predetermined by innate peculiarities, but " idioplastic
forces" are not thereby increased. Pekelharing '' thinks that hyper-
trophy is due to a disappearance of a resistance to growth, and also
to a stimulus causing proliferation.

We see from these various opinions how little is really known ;

1 Not, however, from the same Htter.

2 Inter nat. Beitrage zu wissensch. Medicin. Festschrift fiir R. Virchow, Vol. II, 1 89 1.
^ Vorlesungen ilber allegemeine Pathologie, Vol. I, 1882. * Handbuch.

^ Handbuch d. allgem. Pathologie, 1879. ^ Allgeineiiie Pathologie, Vol. II, 1889.

"^ Uber Endothelwucherungen in Arterien. Beitr. z. pathol. Anat., Vol. VIII, 1890.

HYPERTROPHY

119

how little has been determined as yet by experiment as to the causes
that bring about hypertrophy. Many of the views are more or less
plausible in the absence of direct, experimental evidence, but it
remains for the future to decide as to the correctness of all of them.
They are valuable as suggestions, in so far as they show the different
possibilities that must be taken into account.

Ziegler first advocated the view, in the first edition of his LeJirbitcJi,
that hypertrophy is due to a lessening of the resistance to growth.
He thinks that while hyperaemia and transudation may support the
new growth, they are never the only cause of the formation of new
tissue. While Virchow's view that any injury to the body or to an
organ excites prohferation finds support in the work of Strieker and
Grawitz, yet the view has been combated by Cohnheim and by Wei-
gert, and is no longer held by many pathologists. Ziegler points out
that as a result of his own work, and that of his students, traumatic
and chemical lesions are not followed at once by new growth of the
tissue, but by degeneration of the tissue, and by changes in the cir-
culation that- lead to exudations. The new growth begins, at the
earliest, eight hours after the operation, and generally only after
twenty-four hours. Also after mechanical, chemical, or thermal
injuries, a long interval elapses before phenomena of growth begin.
The injury itself does not appear to produce the growth, but brings
about those conditions that lead to cell-multiplication. Ziegler dis-
cusses what is meant by the idea of a lessening of the resistance to
growth. He himself does not mean by this that hypertrophy depends
on changes in the physical conditions, because it is known that living
phenomena are the outcome of chemical processes and it is, therefore,
a priori probable that the effect is brought about by chemical sub-
stances in the fluids of the tissues. These substances affect func-
tional actions, and may even bring about regenerative changes. This
action of chemical substances on the formative activity of the cell is
theoretically possible in either of two ways ; first, chemical substances
of definite concentration are set free, or, second, chemical substances
are present in the normal condition that prevent proliferation, but if
their influence should be counteracted by other substances the condi-
tions become favorable to growth. It is known in the case of certain
unicellular organisms, that derive their nourishment from the surround-
ing medium, that their increase in number may be retarded by the pres-
ence of certain chemical substances. It is also known that certain
organisms may themselves produce chemical substances that prevent
their own multiplication. It is, therefore, at least conceivable that after
a part has been injured a new substance may be produced that acts
upon and destroys in the organ itself the substances there present that
have prevented its further growth. The other interpretation is that

120 RE GENERA TION

in the breaking down of the tissue of the organ a substance is pro-
duced that excites the cells to proliferation.

Klebs suggested that the accumulation of the leucocytes at the
wounded surface may act as a stimulus to growth, and that the chro-
matin of their nuclei might be absorbed by the cells of the tissue, and
combining with the nuclei of these cells bring about the new growth.
But Ziegler points out that we now know that although the leucocytes
are dissolved and absorbed over the wounded surface, no process of
absorption, of the sort postulated by Klebs, takes place. Ziegler thinks
that Nothnagel is wrong in supposing that an increase in the blood
supply, bringing with it an increase in the nourishment, can account
for the hypertrophy of the kidney. On the contrary he believes
that the growth is the result of an increase in the function of the organ
due to the increase of the chemical substance, urea, that is brought to
the secreting cells. The muscles of the body also hypertrophy as a
result of their activity and not as a result of the additional blood supply.

In connection with these problems of hypertrophy it may be pointed
out that, under certain conditions, blood vessels may enlarge and
their walls become thickened. To cite a single example, Nothnagel
found that if the femoral artery of the rabbit is tied, the blood vessels,
that come off immediately above the ligature, and which have already,
through their subdivisions, connections in the muscles with other
branches of the same femoral artery (that come off below the liga-
ture), grow larger after a time. This he believes to be due, in
the first instance, to the increased speed of the blood in the ves-
sels, and thereby the bringing to these arteries of an increased food
supply. Other writers have given different interpretations. Ziegler
himself believes that several factors may be capable of bringing about
the result. He thinks it improbable that the increase in the food
supply can alone be the cause, and thinks it much more probable that
the increased work that the vessels must perform while carrying more
blood will account for the enlargement.

In connection with this discussion it may not be unprofitable to
recall that in the regeneration of the lower animals we find simpler
conditions in which proliferation of the cells takes place under cir-
cumstances where many of the factors suggested in the above discus-
sion are absent. In the first place we find that new growth may occur
without any increase in the nourishment that is brought to the organ.
Regeneration takes place in the entire absence of food, except so far
as it may be stored up in the tissues. Even in a planarian that is
starving and decreasing in size, proliferation of new cells will take
place if a part is removed. In many of the lower forms there may
be proportionately even a much greater proliferation than in the
regeneration and hypertrophy in the mammalian organs. It is true

H YPER TR OPHY 1 2 1

that proliferation may be more active if the tissues are well fed, but
this does not show that the presence of food is a factor in the pro-
liferation except so far as it keeps the proliferating cells in their best
condition for growth. It is possible in many animals, more espe-
cially in some of the lower forms, to force them to grow rapidly by
supplying them with a large amount of food, and conversely by de-
creasing the food to delay the growth. While this shows that the
rate of growth is, within certain limits, a function of the amount of
food, there may be also other factors that enter into the result, and
in all cases there is an upper limit beyond which it is not possible to
make the animal grow any larger.

That the presence of certain substances may bring about the
enlargement of a part must be admitted as probable. It has been
shown, for instance, that after the removal of certain lymphatic
glands other glands may become larger. This appears to be due to the
greater activity of the gland, brought about probably by the presence
of an increased amount of some specific substance. In this instance
the result can scarcely be due to a decrease in the physical resistance
to growth or to an increase in the blood flow, except so far as this
is brought about by the increased activity. It is, of course, possible,
even if it cannot be positively shown in the case of the lymphatic
glands, that a substance in the blood causes the hypertrophy in cer-
tain organs, while in others, as in the kidney, an increase in the blood
flow may be also a factor in its hypertrophy.

The view held by several pathologists, that hypertrophy and
regeneration may be caused by the removal of a physical resistance
to growth, cannot be looked upon as a very probable hypothesis.
The experiments in grafting of hydra and lumbriculus show that
regeneration may still take place when the physical resistance has
been reestablished by grafting two pieces together. These results,
which are more fully described in a later chapter, demonstrate that
the growth is due to other influences.

A comparison with the lower animals shows that proliferation
takes place when all but three of the factors considered in connection
with hyperttophy and regeneration in the higher forms have been
eliminated. These are, first, the action of substances that act either
directly or as counteracting some substance already present, as Zieg-
ler suggests ; second, an innate tendency in the organism to complete
itself; and, third, the use of the organ. It is impossible that the sec-
ond factor enters into the problem of hypertrophy. In those cases
in which regeneration takes place when a part of an organ is removed,
as in the case of the liver, for example, the result may possibly also
involve the second of the two factors, for the process is much like
that of morphallaxis in the lower animals.

122 REGENERATION

If it be granted that the growth in a hypertrophied organ is
brought about by some substance that increases the function of that
organ, can we suppose the phenomenon of regeneration to be due
to similar factors ? In other words, can we reduce both phenomena
to the same principle ? The case is complicated by two facts that
may be illustrated by concrete examples. If a piece is cut from the
middle of the body of lumbriculus new cells are produced at both
ends of the piece. If we suppose the proliferation is brought about
by the accumulation of certain substances in the piece, we must still
invoke other factors to account for the differentiation of the prolifer-
ated material, since a head forms at one end and a tail at the other.
All the hypothesis can do in itself is to account for a proliferation,
not for the differentiation, and, both in the case of hypertrophy and in
that of regeneration, it is the formation of new structures that we are
chiefly concerned with, rather than the simple act of growth or of
proliferation. If a piece of a hydra is cut off, the whole piece changes
into the typical hydra form. Here there is no extensive process of
proliferation, and the change is in the old part. It seems highly
improbable that the production of substances in the piece could account
for its change of form. These examples will suffice to show that in
the process of regeneration it is very improbable that the change is
brought about by special substances that may develop or be present
in the part. We must suppose that during regeneration the forma-
tion of the typical form is not the result of a stimulus originating in a
chemical substance acting upon the living material, but due to changes
brought about directly in the living part itself. We must conclude,
therefore, that despite the apparently close connection between the
phenomena of hypertrophy of uninjured organs and of regeneration,
they may often involve different factors.

If specific substances can bring about the hypertrophy of an organ,
it is still not clear at present whether they do so by directly causing
new growth, or whether their presence only stimulates the organ to
greater activity and the activity of the organ is the cause of its
growth. Since it must be supposed that in each organ a different
specific substance brings about its activity and the consequent hyper-
trophy, it seems more probable that the result is due to the activity
itself rather than to a stimulus from the substance. This view is fur-
ther supported by the fact that in the case of the muscles and of the
blood vessels the hypertrophy is directly connected with their use.
The greater use brings about a larger supply of blood, but the blood
is only different in amount and not in its quality. It must be con-
fessed that it is difficult to see how the use of a part could make its
growth increase, for by use the tissues break down ; and we are not
familiar with any other processes within the body that make for the

ATROPHY 123

building up of an organ in more than an inverse ratio to its breaking
down. We are, however, familiar with phenomena of building up
due to an increase in the food supply. It might appear from this to
be more in accordance with what we find, to assume that the hyper-
trophy is solely due to an increase in the food supply ; yet there are
other facts known that show that an organ does not increase in size
simply because it gets more blood, and that this occurs only when
the organs have a greater functional activity. It is a safer conclu-
sion, I think, at present to assume that both the activity of the
organ and the increase in its supply of food acting together are
factors in the result. On the other hand we are so much in the
dark concerning the functioning and growth of organs that we can do
little more, as the preceding pages shov/ only too clearly, than specu-
late in the vaguest sort of way as to what changes take place ; but
since the processes seem to be within reach of experimental methods
we can hope in the near future to learn more of . how the pro-
cesses of hypertrophy are brought about.

ATROPHY

It would not be profitable to enter into a general discussion of
the many cases of absorption, or of atrophy of parts of the organism,
but a few examples may be given that have a general bearing on the
topics discussed in this chapter. The more noticeable cases arise
through disuse of an organ, as shown, for example, in the decrease
in size of the muscles of man when they are not used. Since this
may take place in a single group of disused muscles, when no such
change occurs in other muscles of the same individual that are in
use, the most obvious explanation is that the decrease is due directly
to disuse. Since the blood that goes to all the parts is the same,
the diminution cannot be ascribed to any special substance in the
blood. The flow of blood into the disused muscle is less than when
the muscle is used, and it might be supposed that atrophy is directly
caused by the lessened nourishment that the muscle receives. There
is also the possibility that the decrease is brought about by the
accumulation of certain substances in the disused muscle itself, but
since, in general, the breaking down of the muscle is most active
when it is used, it seems improbable that the result can be due
directly to this cause, unless indeed it could be shown that the sub-
stances produced by a disused muscle are different from those in an
active muscle.

Lack of food, as is known, may cause organs to decrease, the fat
first disappearing, and then in succession in vertebrates, the blood,
the muscles, the glands, the bones, and the brain. Certain poisons

124 REGENERATION

may also affect definite organs and bring about a decrease in size,
as when the thymus and mammae decrease from iodine poisoning, and
certain extensor muscles after lead poisoning. Atrophy may also be
brought about by pressure on a part, as when the feet or waist are
compressed. In old age there may be a decrease in some of the
organs, as in the bones, the testes and ovary, and even in the heart.

Degenerative changes appear even in the young stages of some
animals, as when the tail of the tadpole is absorbed and the arms of
the pluteus of the sea-urchin are absorbed by the rest of the embryo.

Especially interesting are the cases of absorption that take place
when organs are transplanted to unusual situations in the body.
Zahn transplanted a foetal femur to the kidney, where it continued to
grow but was later absorbed. Fischer transplanted the leg of a bird's
embryo to the comb of a cock, where it continued at first to grow, but
after some months degenerated. The spleen, the kidney, and the
testis have been transplanted, but they degenerate, and, in general,
the larger the transplanted piece the more probable its degeneration.
Small pieces of the skin have been transplanted from one individual
to another, and it has been found that small pieces maintain them-
selves better than large pieces. Ribbert's recent experiments in
transplanting small pieces of different organs have been more success-
ful than earlier experiments in which larger pieces were used. The first
difficulty seems to be in establishing a blood supply to the new part,
in order to nourish it. If the piece is quite small, it can absorb the
substances, necessary to keep it alive, from the surrounding tissues,
until the new blood supply has developed.

In the lower animals grafting experiments have been more success-
ful, because the parts can remain alive for a longer time. It is
important to find, however, that even in these cases, a part grafted
upon an abnormal region of the body is usually absorbed. Rand
shows that if the tentacles of hydra become displaced, as sometimes
happens when a piece containing the old tentacles regenerates (Fig.
48, A-A^), the misplaced tentacles are absorbed ; and I can confirm this
result. In hydra, the hollow tentacles are in direct communication
with the central digestive tract, and a displaced tentacle seems to be
in as good a position as a normal one, as far as its nourishment is
concerned, yet it becomes absorbed.

Rand also found, in other experiments, that when the anterior end
of a hydra is grafted upon the wall of another hydra, the piece may
maintain itself if it is large ; but it is slowly shifted toward the base
of the hydra to which it is grafted, and then the two separate in this
region. If the graft is small, it may be entirely absorbed into the
wall of the animal to which it is attached.

Marshall found that if the head of a hydra is partially split in two.

ATROPHY 125

each half-head completes itself (as Trerabley had already shown). The
body then begins slowly to separate into two parts, beginning at the
angle between the two heads, until finally the two parts completely sep-
arate. King (1900) has repeated the experiment in a large number of
cases with the same result. It seemed that the division might be
brought about by the weight of the halves causing the gradual sepa-
ration of the body, but King has shown that this is not the case, for,
when a double form remained hanging with its head down, it still
divided into two parts (Fig. 47, A\ In this case, the weight of the two
heads would cause the parts to come together rather than to separate,
if gravity had any influence of the sort suggested. Marshall and
King have also shown that if the posterior end of a hydra is split in
two, the two parts do not continue to separate, but one of the two, if
the pieces have been split some distance forward, may become con-
stricted from the other, and, producing new tentacles at its apical
end, become a new individual.

I have carried out a series of experiments on planarians of a some-
what similar nature. If the posterior end is split in two, the separa-
tion extending into the anterior part of the worm (Fig. 44, C^,
each half completes itself, but the halves do not separate unless they
happen to tear themselves apart. If one of the pieces is cut off, not
too near the region of union with the other half, a new posterior end,
replacing that cut off, regenerates. If, however, the piece is cut off
quite near the region or union of the halves, the piece that is left
may be absorbed.

The absorption of misplaced parts in the lower animals cannot be
explained, I think, by any lack of nutrition, especially in the case of
the tentacles of hydra. The result may be due either to the displaced
part not receiving exactly those substances, perhaps food substances,
that it gets in its normal position, or it may be due to some formative
influence. At present we are not in a position to decide between
these alternatives, and, while the former view seems more tangible,
and the latter quite obscure, the latter may nevertheless be found
to contain the true explanation. If the view that I have adopted in
regard to the organization — namely, that it can be thought of as
acting through a system of tensions peculiar to each kind of proto-
plasm — is correct, it may be possible to account for the absorption of
misplaced parts by some such principle as this.

INCOMPLE TE RE GENERA TION

A somewhat unusual process of regeneration takes place when
the jelly-fish, Gonioneimi.s vertens, is cut into pieces. As first shown
by Hargitt, the cut-edges come together and fuse, and the pieces

126

RE GENERA TION

assume the form of a bell, but the missing parts are not replaced.^ I
have worked on the same form and obtained substantially the same
results. If the jelly-fish is cut in two, as indicated by the dotted line
in Fig. 39^, A and A\ each half closes in and assumes the form
shown in B, B. Each new jelly-fish has only the two original radial
canals that each half had when separated from the other. A faint
line along the region of fusion of the pieces seems to represent a
new radial canal, — it is not represented in the figures, — and each

t'lG. 35,.^. — A. AboAil view of Gonione mus verteas. A'^. Side view of same. Dotted line in each
indicates where jelly-fish was cut into halves. B, B. New individual from a half. As seen
from above and from the side. C, C^. New individuals from a \ piece. As seen from above
and from the side. D. New individual from a piece less than \. It contained a part of one
of the radial canals. A new proboscis with mouth regenerated in all pieces, but no new
canals or tentacles.

half-proboscis has completed itself. There are not formed any new
tentacles, except perhaps one, or a few more, where the cut-edges
meet. Thus there is actually very little regeneration, although the
typical jelly-fish form is assumed by the half-piece. If a jelly-fish
is cut into four pieces, each piece containing one of the radial
canals, the pieces also assume the bell-like form, as shown in
C, C . A new proboscis develops from the proximal end of the
old radial canal, and since this end is often carried to one side

1 Haeckel (1870) first showed, in another medusa, that pieces produce new medusa.

ATROPHY 127

during the closing in of the piece, the new proboscis lies not at the
top of the sub-umbrella space, but, as seen in the figure, quite to one
side. Pieces even smaller than these one-fourth jelly-fish will assume
the bell-hke form, especially if they contain a bit of the margin of the
old bell and a part of one of the radial canals, as shown in Fig. 39-2, D.
Although I have kept these partial medusae for several weeks, and
have fed them during this time, I have found that the missing organs
do not come back. That these pieces do undergo a certain amount of
regeneration is shown by the formation of a new proboscis, and, in
certain cases, a new radial canal. Even the tentacles may be par-
tially regenerated, as Hargitt has shown, — especially, as I have found,
if the margin of the bell is cut off very near the base of the line of
tentacles. Small knobs appear along the cut-edge, but the pieces die
before regeneration goes very far. If, however, the margin is cut
off in only one quadrant, new tentacles may be produced along the
cut-edge.

CHAPTER VII

PHYSIOLOGICAL REGENERATION. REGENERATION AND
GROWTH. DOUBLE STRUCTURES

During the normal life of an individual many of the tissues of the
body are being continuously renewed, or replaced at definite periods.
The replacement of a part may go on by a process of continuous
growth, such as takes place in the skin and nails of man, or the re-
placement may be abrupt, as when the feathers of a bird are moulted.
It is the latter kind of process that is generally spoken of as physio-
logical regeneration. In the same animal, however, certain organs
may be continually worn away, and as slowly replaced, and other
organs replaced only at regular intervals.

Bizozzero has made the following classification of the tissues of
man, on the basis of their power of physiological regeneration,
(i) Tissues made up of cells that multiply throughout life, as the
parenchyma cells of those glands that form secretions of a definite
morphological nature ; the tissues of the testes, marrow ; lymph
glands, ovaries ; the epithelium of certain tubular glands of the
digestive tract and of the uterus ; and the wax glands. (2) Tis-
sues that increase in the number of their cells till birth, and only
for a short time afterward, as the parenchyma of glands with fluid
secretions, the tissues of the liver, kidney, pancreas, thyroid, con-
nective tissue, and cartilage. (3) Tissues in which multiplication of
cells takes place only at an early embryonic stage, as striated muscles
and nerve tissues. In these there is no physiological regeneration.

There are many familiar cases of periodic loss of parts of the body.
The hair of some mammals, is shed in winter and in summer. Birds
renew their feathers, as a rule, once a year. Snakes shed their skin
from time to time. The antlers of deer are thrown off each year,
and new ones formed accompanied by an increase in size and branch-
ing of the antlers. In other cases similar changes may be associated
with certain stages in the life of the animal. The milk-teeth of the
mammals are lost at definite periods, and new teeth acquired.^ The
larval exoskeleton of insects is thrown off at intervals, and after

1 In rodents, however, the incisors continue to grow throughout the hfe of the animal.

128

PHYSIOLOGICAL REGENERATION 1 29

each moult the body increases in size ; but after the pupa stage is
passed and the imago formed, there is no further moulting. In the
Crustacea, on the other hand, the adult animals moult from time to
time, and the upper limit of size is less well defined than in the insects.
The larvae also pass through a series of moults.

An interesting case of physiological regeneration has been de-
scribed by Balbiani in a unicellular form, stentor. From time to time
a new peristome appears along the side, moves forward and replaces
the old peristome, that is absorbed as the new one comes into position.
In other infusoria the peristome may be absorbed before encystment,
and a new one appear when the animal emerges from the cyst.
Schuberg states that when division takes place in bursaria the new
peristome develops on the aboral piece in the same way as after
encystment ; and Gruber observed that, when an aboral piece of an
infusorian is cut off, a new peristome develops in the same way as
after normal division of the animal. These observations indicate that
the process of physiological regeneration may follow the same course
and probably involves the same factors as the process of restorative
regeneration.

Tubularia absorbs its old hydranth-heads if placed in an aquarium,
and regenerates new ones. It may even absorb the hydranth while
growing in an aquarium, as Dalyell has shown, and presumably, there-
fore, also under natural conditions. After each regeneration the new
stalk behind the head increases in length.

In plants, in which there is a continuous apical growth, new parts
are being always added at the end of the stem, and old parts are con-
tinually dying, as seen in palms. Most trees and shrubs in temperate
climates lose their leaves once a year and produce new ones in the
spring. Since the new leaves develop from the new shoots at the end
of the stem and branches, the old ones can, only in a general wa}'-, be
said to be renewed.

That a very close relation exists between the process of physio-
logical regeneration and restorative regeneration will be sufficiently
evident from the preceding illustrations. We do not gain any insight
into either of the processes, so far as I can see, by deriving the one
from the other, for the process of restorative regeneration may be, in
point of time, as old as that of physiological regeneration. This does
not mean, of course, that the same factors may not be present in both
cases. So similar are the two processes that several naturalists have
attempted to show how the process of restorative regeneration has
been derived from physiological regeneration. Barfurth, recognizing
the resemblance between the two processes, speaks of restorative
regeneration as a modification of physiological regeneration, and
Weismann also supports this point of view. He says : " Physiological

1 3 O RE GENERA TION

and pathological regeneration obviously depend on the same causes,
and often pass one into the other, so that no real line of demarca-
tion can be drawn between them. We nevertheless find that in
those animals in which the power of regeneration is extremely great
physiologically, it is very slight pathologically. This proves that a
slight power of pathological regeneration cannot possibly depend on
a general regenerative force present within the organism, but rather
that this power can be provided in those parts of the body which
require a continual, periodic regeneration ; in other words, the regen-
erative power of a part depends on adaptation." It is, I think,
erroneous to state "that in those animals in which the power of
regeneration is extremely great physiologically, it is very shght patho-
logically." All that we are justified in concluding from the evidence
is that in some cases in which physiological regeneration takes place,
as in the vertebrates, pathological (restorative) regeneration may not
be well developed ; but even in these forms restorative regeneration
is certainly present, and present especially in internal organs, as in
the salivary gland, in the liver, and in the eye, which are little exposed
to injury. How far physiological regeneration takes place in the
tissues of the lower animals we do not know at present, except in a
few cases, but far from supposing it to be absent, it may be as well
developed as in higher forms. Weismann's further conclusion, that
because in some animals physiological regeneration is very great and
restorative regeneration very slight, therefore the latter cannot " de-
pend on a general regenerative force within the organism," is, I
think, quite beside the mark. In this connection we should not fail
to notice a difference between these two regenerative processes that
several writers have also called attention to, viz. that the power of
cell-multiplication and the formation of new cells in each kind of
tissue does not carry with it the power of restorative or even of phy-
siological regeneration, in cases where several kinds of tissue make
up an organ. For instance, if the leg of the mammal is cut off, the
old cells may give rise to new ones, but the processes that would
bring about the formation of the new leg are not present, or, rather,
if present, cannot act. Thus, although the production of new cells
from each of the different parts of the leg of a mammal may take
place, yet the conditions are unfavorable to the subsequent formation
of a new leg out of the proliferated cells. We should not infer that
this power does not exist, but that under the conditions it cannot be
carried out. The assumption that physiological regeneration is the
forerunner of restorative regeneration, in the sense that historically
the former preceded the latter and furnished the basis for the devel-
opment of the latter, cannot be shown, I think to be even probable.
This way of looking at the two processes puts them, I believe, in a

REGENERATION AND GROWTH I3I

wrong relation to each other. We find both processes taking place
in the simplest forms as 'in the unicellular protozoa, and present
throughout the entire animal kingdom without any connection,
excepting so far as they both depend on the general processes of
growth characteristic of each organ and of each animal. This leads
us to consider the general question of regeneration in its relation to
the phenomena of growth.

REGENERATION AND GROWTH

It has been pointed out in several cases in which external factors
influence the growth of a plant, or of an animal, that the same factors
play a similar part in the regeneration. The action of gravity on the
growth of plants has been long known, and that it is a factor in the
regeneration of a piece of a plant has also been shown. The only
animal in which gravity has been definitely shown to be an important
factor during growth is antennularia, and it has been found that
gravity is also a factor in the regeneration of the same form. Not
only is this influence shown in the growth of the new part that has
developed, but the same influence seems to be one of the factors that
determines where the new growth takes place. This latter relation is
known in only a few cases, for instance in plants, according to
Vochting, and in antennularia, according to Loeb, so that, until
further evidence is forthcoming, it is best not to extend this general-
ization too far ; but it seems not impossible that it may be generally
true. How an external factor may determine the location of new
growth, as well as the subsequent development of the new part, we
do not know at present.

In regard to the internal factors that influence the growth and the
regeneration of new parts, we are almost completely in the dark. In
cases of hypertrophy of the kidney, etc., the evidence seems to show
that a specific substance, urea, that is normally taken from the blood
by this organ may, if present in more than average amounts, excite
the cells to greater activity and to growth, but whether the urea itself
does this directly, or only indirectly through the greater functional
activity of the cells, has not, as we have seen, been ascertained. That
growth is influenced by internal factors can be shown, at least in
certain cases, even although we cannot refer to the definite chemical
or physical factors in the process. Some experiments that I have
made on the tails of fish show very clearly the action of an internal
factor. If the tail of fundulus is cut off obliquely, as indicated by
the line 2-2 in Fig. 40, A, new material appears in a few days along the
outer cut-edge. It appears to be at first equal in amount along the
entire edge. As the material increases in width, it grows faster over

132

REGENERATION

that part of the edge that is nearer the base of the tail (Fig. 40, C^.
This growth continues to go on faster on the lower side, until the
rounded form of the tail is produced. If we make the oblique cut so
that the part nearer the base of the tail is on the upper side, the result
is the same in principle ; the upper part of the new material grows
faster than any other part. If we make two oblique cuts on the same

H I

Fig. 40. — A. Tail of Fundulus heteroclitus. Lines indicate levels at which B and Cwere cut off.
B. Regenerating from cross-cut. C. Regenerating from oblique cut. Z), E. Regenerating
from two oblique surfaces. G. Tail of stenopus. //, /. Tail of last cut off squarely and
obliquely.

tail, as shown in Fig. 40, D, or as in E, the new part grows
faster in each case on that part of the cut-edge that lies nearer the
base of the tail. These results may be supposed to be due to the better
nourishment of the new tissues nearer the base of the tail ; but it is
not difficult to show that the difference in the rate of growth over
different parts of the cut-edge is not due to this factor. If, for

REGENERATION AND GROWTH 1 33

example, we cut off the tail of one fish squarely near the outer end,
as shown in Fig. 40, /% i-i, and the tail of a second near the base of the
tail, as shown in Fig. 40, F, 2-2, and of a third by an oblique cut that
corresponds to a cut extending from the upper side of the cut-edge of
the tail of the first fish to the lower cut-edge of the tail of the second
fish, as shown in Fig. 40, F, we find that the rate of growth over the
first and second tails is about the same as that of the lower side
of the third tail. In other words, the maximum rate of growth that
is possible for the entire oblique edge is carried out only near the
lower edge, and the growth of the rest of the new material is held in
check. By means of another experiment a similar phenomenon can
be shown. If the bifurcated tail of a young scup {Stenopiis chrysops^
is cut off by a cross-cut (Fig. 40, G, i-i), it will be found that at first
the new material is produced at an equal rate along the entire cut-
edge; but it soon begins to grow faster at two points, one above and
the other below, so that the characteristic swallow-tail is formed at a
very early stage (Fig. 40, H) and before the new material has grown
out to the level of the notch of the old tail. If the tail of another
individual is cut off by an oblique cut (Fig. 40, G, 2-2), we find, as
shown in Fig. 40, /, that at two points the new tail grows faster, but
the lower lobe faster than the upper one.

These results show very clearly that in some way the development
of the typical form of the tail influences the rate of growth at different
points. The more rapid growth takes place in those regions at which
the lobes of the tail are developing. In other words, although the
physiological conditions would seem to admit of the maximum rate of
growth over the entire cut-edge, this only takes place in those parts
that give the new tail its characteristic form. The growth in other
regions is held in check. The same explanation applies to the more
rapid growth at that part of an oblique cut that is nearest the base
of the tail, for by this means the tail more nearly assumes its typical
form.

These results demonstrate some sort of a formative influence in
the new part. We can refer this factor at present only to some
structural feature that regulates the rate of growth. We find here
one of the fundamental phenomena behind which we cannot hope to
go at present, although it may not be beyond our reach to determine
in what way this influence is carried out in the different parts. This
topic will be more fully considered in a later chapter.

Another illustration may be given from certain experiments in
the regeneration of Planaria litgnbris. If the posterior end is cut
off just in front of the genital pore, as indicated in Fig. 41, new
material develops at the anterior cut-edge, and in a few days a new
head is formed out of this new material. A new pharynx appears

134

RE GENERA TION

in the new tissue immediately in front of the old part. It lies,
therefore, just behind the new head. The proportions of the new
worm are at this time very different from those of a typical worm,
since the head is much too near to the new pharynx and to the old
genital pore. New material is now produced in the region behind
the head and in front of the pharynx, so that the head is carried
further forward until the new worm has fully assumed the character-
istic proportions. As the new head is formed the old part loses its
material, so that it becomes flatter and narrower, and if the worm is
not fed the old part may lose also something of its former length.
If the worm is fed, however, as soon as the pharynx develops the
old part loses less and the new part grows forward more rapidly.

Fig. 41. — Posterior end of Planaria lugubris, cut off between pharyngeal and genital pores.
Figure to left shows the piece after removal. The four figures to the right show the regenera-
tion of the same piece, drawn to scale. As soon as the new pharynx had developed, the
worm was fed. The experiment extended from November 17 to January 8.

The most striking phenomenon in the growth of the new worm is
the formation of new material in the region behind the head. The
result of this growth is to carry the head forward and produce the
characteristic form of the animal. This change is all the more in-
teresting since the growth does not take place at a free end, but in
the middle of the new material. It is only by the formation of new
material in this region that the head is carried to its proportionate dis-
tance from the pharynx. It appears that in some way the growth is
regulated by influences that determine the form of the new organism.
Another experiment on the same animal gives also a somewhat
similar result. If a worm is cut in two obliquely (Fig. 21, B^ and
the regeneration of the posterior piece is followed, it is found that
the new material appears at first evenly along the entire cut-surface.

DOUBLE STRUCTURES 1 35

It then begins to grow faster on one side (Fig. 21, b\ and a head
appears in this region with its axis at right angles to the cut-edge.
As the head grows larger the growth is more rapid on one side, and
as a result the head is slowly turned forward (Fig. 21, b). This
more rapid growth on one side brings the new head finally into its
typical position with respect to the rest of the piece. The end result
of these changes is to produce a new worm having a typical form.
If the oblique cut is made behind the old pharynx, as in Fig. 22, A,
the new pharynx that appears in the new material along the cut-edge
lies obliquely at first, indicating that the new median line is very
early laid down in the new part, and connects the middle line of the
old part with the middle of the new head. As the region behind the
new head grows larger and broader the pharynx comes to lie more
and more in an antero-posterior direction, and finally, when the new
part is as broad as the old,^ the pharynx lies in the middle line of
a symmetrical worm.

These results show that the new growth may even take place
more rapidly on one side of the structural median line than on the
other, and on that side that must become longer in order to produce
the symmetrical form of the worm. Here also we find that a for-
mative influence of some sort is at work that regulates the different
regions of growth in such a way that a typical structure is produced.
The more rapid growth on one side is, however, in this case clearly
connected with the relatively smaller development of the organs on
that side, and perhaps this same principle may explain all other
cases. If so the phenomenon appears much less mysterious than
it does when the growth is referred to an unknown regulative factor.

DOUBLE STRUCTURES

A Structure that is single in the normal animal may become
double after regeneration, and in some cases the special conditions
that lead to the doubling have been determined. Trembley showed
that if the head of hydra is split lengthwise into two parts,
each part may. complete itself and a two-headed form is produced.
If the posterior end of a hydra is split, an animal with two feet is
made. It is true that the two-headed forms may subsequently sepa-
rate after several weeks into two individuals, and even the form
with two feet may lose one of them by constriction, as Marshall and
King have shown. Driesch has produced a tubularian hydroid with
two heads by splitting the stem partially into two pieces. Each head
is perfect in all respects, and although each has fewer tentacles than

1 If the young worm is fed the new part becomes almost as broad as the old piece, but
if the worm is not fed the old part decreases in breadth and the new part does not grow as
broad as in the former case.

136

REGENERA TION

the head that regenerates from an undivided stem, yet the number of
tentacles on each head is more than half the average number. This
is connected apparently with the fact that the circumference of each
half is greater than half the circumference of the original stem.
Planarians with double tails, produced by partial splitting, have been
described by Duges and by Faraday, and it has also been shown
that by partial splitting of the anterior end of the worm two heads
can be produced. Van Duyne, Randolph, and Bardeen and I have
obtained the same result. Each half completes itself on the cut-side
and produces a symmetrical anterior end. If one of the heads is cut
off, it will be again regenerated. If the heads are united very near to
the trunk, as in Fig. 42, A, they may never grow to the full size of the

B

Fig. 42. — Plattaria lugubris. A. Two heads produced after operation similar to that in Fig. 24.
Each head about half size. B. Worm split in half through level of pharynx. New half-worms
larger than half of normal worm.

original head, as I have found; but if the pieces have been split poste-
riorly, so that each head has a long anterior end, then each one may
become nearly as large as the original head (Fig. 42, B\ We see
in these cases the influence of the region of union on the growth of
the new part. If the new part is near the region of attachment, the
smaller size of the latter restrains the growth of the new head; but
if the region of union is farther distant, the head may grow more
nearly to its full size despite the influence of the region of union.
King has found in the starfish that if the arm is split lengthwise, each
half may complete itself laterally and a forked arm result. An addi-
tional entire arm may be formed by splitting the disk partially in two
between two arms. If the cut-edges do not reunite a new arm will
grow out from each cut-surface (Fig. 38, £"). In this case the de-

DOUBLE STRUCTURES 1 3/

velopment of the new arm cannot be accounted for on the assump-
tion that the typical form completes itself, since a sixth arm cannot
be supposed to be a typical structure in the starfish. The result must
depend on other factors, such as the presence of an open surface in a
region where the cells have the power of making new arms.

Barfurth has been able to produce a double tail in the tadpole by
the following method : A hot needle is thrust into one side of the
tail, so that the notochord and the nervous system are injured. The
tail is then cut off just posterior to the region injured by the needle.
A new tail grows out from the cut-end, and also in some cases an-
other tail grows out at the side .where the notochord was injured by
the needle. The injury to the notochord and the removal of tissue
immediately about it leads to a proliferation of cells, around which
other tissues are added and the new tail produced.

Lizards with double tails have often been described,^ and it now
appears that all these cases are due to injuries to the normal tail.
Tornier has succeeded, experimentally, in producing double and
even triple tails. If the end of the tail is broken off, and the tail
is then injured near the end, two tails may regenerate, one from
the broken end and one from the region of injury (Fig. 43). Under
natural conditions this might occur if the tail were partially bitten off
and the end of the tail lost at the same time. A regenerated tail may
produce another tail if it is wounded. A three-tailed lizard may be
made by cutting off the tail and then making two injuries proximal
to the broken end. Two of the new tails may be included in the
same outer covering if they arise near together, as shown in Fig.
43, B. Lizards with two or three tails may be produced in another
way. If the tail is cut off very obliquely, so that two or three verte-
brae are injured, there arises from each wounded vertebra a cartilagi-
nous tube that forms the axis of a new tail. Tornier thinks that
the regeneration is the result of overnourishment of the region where
the injury has been made, but this does not seem in itself a sufficient
explanation. Tornier has also been able to produce, experimentally,
double limbs in Triton cT-istatiis in the following way: The hmb is
cut off near the body, and, after the cut-end has formed new tissue,
a thread is tied over the end in such a way that it is divided into two
parts. As the new material begins to bulge outward it is separated into
halves by the constricting thread, and each part produces a separate
leg (Fig. 43, Z>). The soles of the two feet in the individual repre-
sented in Fig. 43, D, are turned toward each other. The femur is
bifid at its outer end, and to each end the lower part of one leg is
attached. The bones in this part are fused together at the knee, so
that only the foot portions can be separately moved.

^ See Fraisse for literature.

138

RE GENERA TION

The same method used to produce double tails in the lizard can
also be used to produce double legs. The femur is broken in the
vicinity of the hip-joint, and the soft parts are cut into over the break.
Then, or better somewhat later, the leg is amputated below the

Fig. 43. — After Tornier. A. Lacerta agilis. Produced by partly breaking off old tail. New tail
arises at place of breaking. Old tail also remains. B. Three-tailed form — two tails being
united in a common covering. Old tail had been cut off (it regenerated the lower branch
from cut-end) and two proximal vertebrse that had been injured. C. Additional limb of
Triton cristatus produced by wounding femur. D. Double foot of Triton cristatus produced
by tying thread over regenerating stump. E. Foot of Triton cristatus. Dotted lines indicat-
ing how foot was cut off. F. Regeneration of same. G. Another way of cutting off foot.
H. Result of last operation.

broken part. A new limb regenerates from the cut-end, and at the
same time another limb grows out from the broken femur (Fig. 43, C).
The same result is reached if the femur has a slit cut into it in the
region of the hip-joint, so that it is much injured. Later the leg is
cut off below the place of injury. A double leg is the result.

DOUBLE STRUCTURES 1 39

Feet with supernumerary digits can also be produced by artificial
wounds. If the first and second and then the fourth and fifth toes
are cut off, as indicated by the lines in Fig. 43, E, so that a part of
the tarsus and a part of the tibia and fibula are cut away (the
third finger being left attached to the remaining middle portion), more
toes grow out from the wounded surface than were removed, as shown
in Fig. 43, i^ A similar result may be obtained in another way. If
the first and second toes are cut off by an oblique cut (Fig. 43, G),
and then after the wound has healed the third, fourth, and fifth toes
are also cut off by another oblique cut (a part of the tarsus being
removed each time), more toes are regenerated than were cut off ^
(Fig. 43, H).

Tornier suggests that the double feet that are sometimes formed in
embryos — even in the mammalia — have resulted from a fold of the
amnion constricting the middle of the beginning of the young leg, in
the same way as is brought about artificially by tying a string over
the growing end of the regenerating leg of triton.

In many of these cases, in which the double structure is the result
of splitting the part in the middle line, the completion of the new
part is exactly the same as though the parts had been entirely sepa-
rated. The only special problem that we meet with in these instances
is that this doubling is possible while the piece remains a part of the
rest of the organism. This shows that there is a great deal of inde-
pendence in the different parts of the body in regard to their regen-
erative power, and that local conditions may often determine the
formation of double structures.

It has been shown during the last decade that double embryos may
be produced artificially by incomplete separation of the first two
blastomeres. Driesch, Loeb, and others have demonstrated that if the
first two cells of the Q,g% of the sea-urchin be incompletely separated,
each may produce a single embryo and the two remain sticking to-
gether. Wilson has shown in amphioxus that the same result occurs
if the first two cells are partially separated by shaking. Schultze has
shown in the frog that if at the two-cell stage the Q.gg is held in an
inverted position, i.e. with the white hemisphere turned upwards, each
blastomere gives rise to a whole embryo — the two embryos being
united, sometimes in one way, sometimes in another, as shown in Fig.
6'i^. In this case it appears that the results are due to a rotation of
the contents of each blastomere, so that like parts of the two blasto-
meres become separated. In the Q.%g of the sea-urchin, and of am-
phioxus, gravity does not have a similar action on the &gg, but the
results seem to be due to a mechanical separation of the blastomeres.
These cases of double structures, produced by the segmenting ^g^y

1 In the figure one double or forked toe is present.

I40

REGENERA TION

appear to belong to the same category as those described above for
adult forms — especially in those cases where pieces regenerate by
morphallaxis.

In connection with the production of double structures there
should be mentioned a peculiar method of formation of new heads,
first discovered by Van Duyne in a planarian. He found that if the

Fig. 44. ■ — A. Planaria higubris, cut in two as far forward as region between eyes, regenerating
half-heads. B. Same cut in two at one side of middle line. Smaller piece produced a new
head. C. Planaria viaculata, split in two. It produced two heads in angle. D. Another,
that produced a single head in angle.

animal is cut in two in the middle line, the halves being left united
only at the head-end, as shown in Fig. 44, D, C, there may appear one
or two new heads in the angle between the halves. I have repeated
this experiment with the same result, and have found that it may also
occur when only a piece is partially split from the side of the body,
as shown in Fig. 44, B. In Van Duyne's experiment the two new

DOUBLE STRUCTURES

141

heads do not appear unless the cut extends far forward, but if the
division extends into the region between the two eyes there may be
formed, as I have found, a single eye on each side that makes a pair
with the old eye of that side (Fig. 44, A). It is evident in this case
that each head has completed itself on the cut-side, the completion
including the eye and the side of the head also with its " ear-lobe."
The result, in this case, is the same as though the pieces had been
completely cut in two. If the cut does not extend quite so far for-
ward there are usually formed one or two heads near the angle, each
with a pair of eyes and a pair of ear-lobes (Fig. 44, C). Sometimes
a single head develops in the angle itself (Fig. 44, D), and it is diffi-
cult to tell whether it belongs to one or to the other side, or whether
it is common to both sides. Van Duyne spoke of the double and
single head of the latter kind which he obtained as heteromorphic
structures in Loeb's use of the term. According to this definition,
heteromorphosis is the replacement of an organ by one that is morpho-
logically and physiologically unlike the original one, but this statement
has been made to cover a number of different phenomena. The
examples of heteromorphosis that Loeb gives by way of illustration of
the phenomenon are : the production of a hydranth on the aboral end
of tubularia, and the formation of roots in place of a stem in anten-
nularia, etc. The formation of the heads in the angle in planarians
does not appear to me to belong in this category. It seems rather
that the phenomenon is of the same sort as the formation of a new
head at the side of a longitudinal piece, and if so the new heads in
the angle are, therefore, in their proper structural position for new
heads belonging to the posterior halves. Even if it should prove
true that a single head may develop exactly in the angle itself, and
belong to both sides, it can be interpreted by an extension of the same
principle.^ The position of this median head turned backward sug-
gests an obvious comparison with the production of the heteromor-
phic head in Planaria htgiibris, but a closer examination will show,
I think, that the two cases are different. The heteromorphic head
is produced only when the head is cut off close behind the eyes. If
cut off slightly behind this region, a posterior end is generally
formed. But in the worms split lengthwise the head in the angle
may be formed at a level much farther posteriorly than the eyes. If
the split extends into the head, then the eyes that develop are the sup-
plements of those of the old part. Our analysis leads, therefore, to
the conclusion that the heads, or parts of heads, in the split worms
are not heteromorphic structures but supplementary heads.

1 A parallel case is found when a piece partially split in two at the anterior end (Fig. 24)
produces one or two heads on each half, according to the extent of fusion of the new mate-
rial that goes to form the new head or heads.

CHAPTER VIII

SELF-DIVISION AND REGENERATION. BUDDING AND REGEN-
ERATION. AUTOTOMY. THEORY OF AUTOTOMY

Self-division, as a means of propagation, is of widespread occur-
rence in the animal kingdom. In some cases the animal simply
breaks into pieces and subsequently regeneration takes place in the
same way as when the animal is cut into pieces by artificial means.
In other cases the parts are gradually separated, and during this
time new parts are formed by a process resembling that of regenera-
tion after separation. A few zoologists have tried to show how the
process of regeneration before separation has been derived from
regeneration following self-division. It is our purpose to examine
here the evidence in favor of this hypothesis.

A study of the forms that propagate by means of self-division
shows that the process is present in many groups of the animal
kingdom. In the unicellular forms this method is universally present ;
and in the multicellular forms the division of the individual cells is
looked upon as a process similar to the method of propagation in the
protozoa. The sponges do not multiply by self-division. In the
coelenterates, on the other hand, we find this mode of propagation
present in most forms. Hydra appears rarely, if at all, to divide by
a cross-division, and, although one or two cases of longitudinal
division have been described, it is not improbable that they have
been started by the accidental splitting of the oral end. The hydro-
medusae, StoinobracJiiiim viirabile, Phialidiimi variabile, Gastroblasta
RaffcElei, are known to increase by division. ^ Several actinians and
many corals divide longitudinally, while the scyphistoma of the
scyphomedusas produce free-swimming ephyras by cross-divisions
of the fixed strobila stage. The ctenophors do not divide.

It is known that several fresh-water planarians propagate by
division, the tail-end breaking off in the region behind the old
pharynx. In one form,^ and possibly in others, regeneration may
begin before the separation takes place. Many of the rhabdocoe-
lous planarians increase by cross-division — the separation taking
place more nearly in the middle of the body. In these forms the

1 See Lang ('88). ^ See Zacharias ('86).

142

SELF-DIVISION AND REGENERATION 1 43

parts develop new organs more or less completely before they sepa-
rate. In the trematodes self-division does not take place. The
division of the body of the tapeworm into proglottids may represent
a process of self-division, but the proglottids do not regenerate after
separation.

The nemertians break up readily into pieces, if roughly treated
or if the conditions of life are unfavorable, but this can scarcely be
spoken of as a process of voluntary self-division. Regeneration
takes place in some species, but imperfectly or not at all in others.

In the group of annelids we find many cases of self-division,
especially in marine polychaetes and in fresh-water oligochastes. One
of the most interesting forms, belonging*to the first group, is the palolo
worm in which the swimming headless form, that is set free by divi-
sion, serves to distribute the sexual products. Subsequently it appears
that the piece dies without regenerating a new head. If we examine
more in detail some of the cases of self-division in annelids, we find
the following interesting facts. In nereis the posterior region of the
body undergoes great changes of structure, the new worm being
known under a different name, viz. heteronereis. In this part of
the worm, eggs (or sperm) are produced, but it does not separate
from the anterior end as a distinct individual. In the family of
scyllids the changes that take place in the posterior or sexual end of
the body are often accompanied by non-sexual modes of fission.
In some species the changes that take place are like those in
nereis, and no separation occurs ; in other species the sexual region
becomes separated from the anterior or non-sexual regions. In
scyllis a new head develops, after separation, on the sexual or pos-
terior piece. A new tail is also regenerated by the non-sexual or
anterior piece, and as many new segments are formed as are lost.
The new posterior region may again produce sexual cells, and again
separate. In autolytus a new head develops on the posterior piece
before it separates. A region of proliferation is also found at the
posterior end of the anterior part. In some species new individuals
develop in this zone of proliferation, and a chain of as many as six-
teen worms may be present before the one first formed drops off. A
still more complicated process is found in myriana. The region just
in front of the anus elongates, and gives rise to a large number of
segments. These form a new individual with the head at the ante-
rior end. Then another series of segments is proliferated at the
posterior end of the old, or anterior worm, and just in front of the
first-formed individual. This region also makes a new individual.
The process continuing, a chain of individuals is produced, with the
oldest individual at the posterior end and the youngest at the ante-
rior end of the series. Each individual grows larger, and produces

1 44 RE GENERA TION

more segments at its posterior end. Reproductive organs appear in
each individual, and when the germ-cells are mature the chain
breaks up.

None of the earthworms propagate by self-division, although occa-
sionally, under unfavorable conditions, pieces may pinch off at the
posterior end.^ Lumbriculus, on the other hand, propagates by self-
division, although it has been disputed whether the division takes
place without the intervention of an external injury or disturbance of
some sort, or whether the division may take place entirely from inter-
nal causes, that is, spontaneously. Von Wagner has shown that at
certain seasons lumbriculus breaks up much more readily than at
other times, which may only mean that it is more sensitive to stimuli
at one time than at another.

The pieces into which lumbriculus breaks up regenerate after
separation. In another form, Ctenodrilus monostylos, division takes
place first in the middle of the body behind a cross-septum. Each
half may again divide in the same way, and the same process may be
repeated again and again until some of the pieces are reduced to a
single segment. A new anterior and posterior end may then develop
on each piece. In Ctenodrilus pardalis each segment of the middle
region of the body constricts from the one in front and from the one
behind, and each produces a new head at its anterior end and an anal
opening at its posterior end. The worm then breaks up into a num-
ber of separate worms. In this series, self-division of the individual
is not associated with the development of sexual forms, but seems to
be a purely non-sexual method of reproduction. In the leeches self-
division does not occur, and no cases are known in the mollusks.

In the echinoderms several forms reproduce by voluntary self-di-
vision. In the brittle-stars some forms divide by the disk separating
into two parts, one having two and the other three of the old arms.
Each piece of the disk then regenerates the missing part of the disk
as well as the additional arms. In the starfishes the arms may be
thrown off if injured, and, while in certain forms the lost arm does
not regenerate a new disk, yet, according to several writers, it
may in other species regenerate a new animal. Dalyell observed a
process of self-division in a holothurian, each part producing a new
individual, and more recent observers have confirmed this discovery.

No cases of self-division are known in the groups of myriapods,
insects, crustaceans, spiders, polyzoans, brachiopods, enteropneusta,
or vertebrates.

Before discussing the general problems connected with the pre-
ceding cases, I should like to point out that it is certainly a striking
fact that in all, or nearly all, of these cases of self-division, the sepa-

1 See Hescheler ('97).

SELF-DIVISION AND REGENERATION 1 45

ration takes place in the shortest axis, without regard to the structure
of the animal. A law similar to that enunciated in connection with
the division of the cell seems to hold for the organism as a whole :
namely, division takes place, as a rule, in the shortest diameter of the
form. The protozoa are, in a sense, excluded, since being unicellular
forms they come under the rule for the division of the cell. In the
coelenterates we find the actinians and corals, that have short, cylin-
drical bodies, dividing from the oral to the aboral end, while the longer
scyphistoma divides transversely. The fiat, bell-shaped medusa, gas-
troblasta, divides in an oral-aboral plane. The flat-worms and an-
nelids divide transversely, and, therefore, in the plane of least resist-
ance. The most important illustrations of this principle are furnished
by the echinoderms. Those brittle-stars that divide through the disk
do so in the shortest direction, that is, from the oral to the aboral side,
whilst the holothurians that are long, cylindrical forms divide across
the body and, therefore, in a structural plane at right angles to that of
the brittle-stars. It may be claimed that in all these cases the plane
of division is that in which the animal is most likely to be broken
in two by external agents, but this is, I think, only a coincidence,
and the result is really due to internal conditions. The division is
brought about in most cases, and perhaps in all, by the contraction
of the muscles ; and the arrangement of the muscles in connection
with the form of the body is the real cause of the phenomenon.

Returning to the general question of the occurrence of the process
of division in the different groups, we find that in nearly all of them
in which self-division occurs it is found in a number of different
forms in the same group. The process seems to be characteristic
of whole groups rather than of species, and so far as evidence of this
sort has any value it points to the conclusion that the process is not
necessarily a special case of adaptation to the surroundings, because
the species that divide may live under very diverse conditions.

A further examination of the facts throws a certain amount of
light on the relation between the processes of self-division and of
regeneration. The following questions may serve to guide us in our
examination : . —

(i) Is regeneration found only in those groups in which self-divi-
sion takes place as a means of propagation ; or, conversely, does
self-division only occur in those groups that have the power of
regeneration .''

(ii) Is regeneration confined, in the groups that make use of self-
division as a means of propagation, to those regions of the body
where the self-division takes place .''

(iii) Is regeneration as extensive in the groups that do not propa-
gate by self -division as in those that do ?

146 RE GENERA TIOJV

(iv) Can we account, in any way, for the presence of self-division
in certain groups, and for its absence in others ?

(v) What relation exists between the forms that prepare for sub-
sequent self-division and those that do not ?

The first question is easily answered. Regeneration is also found
in nearly all the other groups that do not propagate by self-division,
— as, for instance, the mollusks, vertebrates, etc. The second half of
the question may also be answered. All the groups that propagate
by self-division have also the power of regeneration.^

In answer to the second question there is ample evidence showing
that regeneration is by no means confined to those regions of the
body in which the self-division occurs.

In answer to the third question, it may be stated that although,
in the groups that propagate by self-division, regeneration may be
present in nearly all parts of the body, the same phenomenon occurs
in other groups that do not propagate by division.

The fourth question offers many difficulties, and our answer will
depend largely upon what we mean by '^ accounting for'' the process
in certain groups. If the question is interpreted to ask, Why does
an animal divide .'' no answer can be given. If it is meant to ask, Can
we see how the process would be difficult, or even impossible, in cer-
tain groups and not in others 1 then an approximate answer may be
given, or at least an hypothesis formed. In the first place, the power
of regeneration must be present in the region at which the self-
division takes place in order that the result may lead to the formation
of new individuals, or else be acquired in that region along with the
acquirement of the means for division. A leech is not much more
complicated than a marine annelid, yet it has little or no power of
regeneration ; hence, perhaps, propagation by division could not be
acquired by the leeches until they had first acquired the power to
regenerate. In the second place, in certain forms a separation of the
body into two parts would lead to the death of one or of both parts,
owing to the dependence of the different regions upon each other.
In forms like the vertebrates, insects, Crustacea, etc., we can readily
see why this would be the case. Hence propagation by means of
self-division could not be acquired, since the division itself would
lead to the destruction of the organism. In the third place, the
structure of the body may be such that the process of self-division
would be mechanically impossible. A hard outer coat, like that
of the sea-urchin, combined with a weak development of the mus-

1 The proglottids of the cestodes seem to be an exception, but they are little more than
sacs filled with embryos at the time of their separation. How far regeneration may take
place in the scolex, or young proglottids, is not known, but it is not improbable that some of
the abnormal forms that have been described may be due to regeneration.

SELF-DIVISION AND REGENERATION 147

culature of the body, would effectively prevent the self-division of
the animal.

The fifth question has many sides. It involves us on the one
hand in a historical question of the origin of self-division, and on the
other hand in a discussion of the stimulus that brings about, not only
the division, but the changes that precede the division in those cases
in which the new part develops before division takes place.

Several zoologists have held that the process of self-division fol-
lowed by regeneration has been the starting-point for the process of
propagation preceded by regeneration. Von Kennel, for instance,
maintains that self-division in some of the annelids has arisen in this
way. He says : " We recognize everywhere in the animal kingdom the
power of organisms to replace lost parts, and we call this regenera-
tion. It may be developed in very different degrees in animals, and,
as a rule, only those parts of the body have the power of regenera-
tion that still possess the organs that are essential for independent
existence. The higher the organization of the animal, so much the
less is its power of regeneration, perhaps, because the division of
labor of the different organs has gone so far that extensive injuries
cannot be repaired. . . . There is no doubt that this power is adap-
tive, in a high degree, to preserve the species under unfavorable con-
ditions, so that they are much better off in the battle for existence
than are the animals that live under the same conditions but have
not the power of regeneration. . . . The power of regeneration that
gives the animal a better chance in the battle for existence and, there-
fore, makes more certain the continuance and the distribution of the
species will be, as is well known from numerous observations, in a
high degree inherited, indeed even increased so that its descendants
will possess that power in a higher degree than their forefathers ; and,
in consequence, a much smaller stimulus (motive) suffices, than at
first, to bring about the division of the parts." After showing, accord-
ing to the usual formula, that the process of regeneration is useful,
and, therefore, would come under the guidance of natural selection,
von Kennel proceeds to show how the result is connected with an
external stimulus ! He asks : " Can accidental injuries account for
the result (viz. for the division in lumbriculus, planarians, and star-
fish), since how few starfish are there with regenerating arms in com-
parison with the enormous number of uninjured individuals } Should
we not rather look for the external stimuli that have initiated the pro-
cess of self-division .? " " Animals that have developed the power of
regeneration by a long process of inheritance will have acquired along
with this the property of easier reaction to all external adverse condi-
tions. In a sense the sensitiveness for such stimuli is sharpened, and
the animal responds at once by breaking up. In the same way the

148 REGENERATION

ear of a good musician becomes more sensitive through practice. If
we think of the same stimulus as regularly recurring, and as always
answered in the same way, then we may look upon it as a normal
condition of the life of the animal and its response as also a normal
process in the animal. If, for instance, the breaking into pieces of
lumbriculus is a consequence of the approach of cold weather or of
other external conditions, then the organization of this animal must
react by breaking up in consequence of its adaptation to the condi-
tions acquired through heredity. The self -division becomes a normal
process under normally recurring conditions. If the organism has
been accustomed to respond through numerous generations, and,
therefore, its sensitiveness has become highly developed, it will be
seen that it may be influenced by the slightest change in the unfavor-
able conditions, and although, at first, the change may not be suffi-
ciently strong to cause the animal to divide, yet the introductory
changes leading to the division may be started, which will in turn
make the division, when it occurs, easier and the animal that pos-
sesses this responsiveness more likely to survive. This would be the
case if a slow process of constriction took place, so that, at the time
of separation, no wounds of any size are formed." "By a further
transfer of the phenomenon, a partial, or even a complete, regeneration
may set in before division takes place." "We find changes like this
in the series of forms, Liunbriaihis, Ctenodrihis monostylos, Cteiio-
drilus pardalis, Nais, Chcetogaster. It appears in a high degree
probable that the series has originated in the way described. Per-
haps zoologists will find after some thousands of years that lumbricu-
lus propagates as does nais at present." In this way von Kennel
tries to show how the process of regeneration, that takes place before
division, has been evolved from a simple process of breaking up in
response to unfavorable conditions. The imaginary process touches
on debatable ground, to say the least, at every turn, and until some of
the principles involved have been put on a safer basis, it would be
unprofitable to discuss the argument at any length.

We should never lose sight of the fact that the arranging of a series
like that beginning with lumbriculus and ending with chaetogaster is a
purely arbitrary process and does not rest on any historical knowledge
of how the different methods originated or how they stand related, and
no one really supposes, of course, that these forms have descended
from each other but at most that the more complicated processes may
have been at first like those shown in other forms. Even this involves
assumptions that are far from being established, and it seems folly
to pile up assumption on top of assumption in order to build what is
little more than a castle in the air.

REGENERATION AND BUDDING 1 49

REGENERATION AND BUDDING

In several groups of animals a process of budding takes place
that presents certain features not unlike those of self-division. It
is difficult, in fact, to draw a sharp hne between budding and self-
division, and although several writers have attempted to make a dis-
tinction between the two processes, it cannot be said that their
definitions have been entirely successful. It is possible to make a
distinction in certain cases that may be adopted as typical, but the
same differences may not suffice in other cases. For instance, the
development of a new individual at the side of the body of hydra is a
typical example of budding, while the breaking up of lumbriculus or of
a planarian into pieces that form new individuals is a typical example
of division. In a general way the difference in the two processes
involves the idea that a bud begins as a small part of the parent ani-
mal, and increases in size until it attains a typical form. It may
remain permanently connected with the parent, or be separated off.
By division we mean the breaking up of an organism into two or
more pieces that become new individuals, the sum-total of the
products of the division representing the original organism. Von
Kennel first sharply formulated this distinction, and it has been also
supported by von Wagner, who has attempted to make the distinc-
tion a hard and fast one ; ^ but as von Bock has pointed out, there
are forms like pyrosoma and salpa in which the non-sexual method
of propagation partakes of both peculiarities, and in Syllis ramosa the
individuals appear to bud from the sides, while in other annelids a
process of division takes place. Von Bock assumes, therefore, as
more probable, that budding and self-division are only different phe-
nomena of the same fundamental process. It might be better, I
think, to go even further in order to clear this statement from a pos-
sible historical implication, and state only that the two processes
involve some of the same factors.

Budding occurs in several groups of the animal kingdom. There
are numerous cases in the protozoa, such, for instance, as that in
noctiluca. • In the sponges buds are formed that go to build up a col-
ony in most instances. In the coelenterates cases of lateral budding are
found in nearly all the main groups, and in one and the same indi-
vidual, as in the scyphistoma of aurelia, in fact both budding and
division occur. In the polyzoa, in the ascidians, and in cephalodiscus
lateral budding takes place. In the rhabdocoel turbellarians, and in
some of the annelids, we find chains of new individuals produced by
a process that is often spoken of as budding. It is convenient, how-
ever, to distinguish these cases of axial budding from those of lateral

^ Except for the protozoa.

150 RE GENERA TION

budding; for, while they both involve an increase in the products
over that of the original animal, the axial relations in lateral buds are
established in a new plane, while in axial budding the main axis of
the new animal is a part of that of the old, and this difference may
involve different factors. The process of budding does not occur in
the insects, spiders, crustaceans, mollusks, ctenophores, brachiopods,
nematodes, vertebrates, or in several other smaller groups.

This examination shows that there are groups in which both pro-
cesses take place, viz, coelenterates, planarians, annehds ; and others
in which budding alone takes place, viz. ascidians, polyzoa, cephalo-
discus ; and one group at least in which division, but not budding,
takes place, the echinoderms. It is obvious that from the occurrence
of the process of budding in the animal kingdom we cannot infer
anything as to its relation to division or to regeneration.

It has been pointed out that in the flowering plants, in which the
growth takes place by means of buds, the power of terminal regen-
eration is very slightly developed, and its absence is sometimes ac-
counted for on the ground that the new growth takes place by means
of the development of lateral buds. If by this statement it is meant
that buds being present the suppression of regeneration in other
regions may occur, then there may be a certain amount of truth
in the statement. If, however, it is intended to mean that be-
cause a plant has acquired the power of reproducing new parts by
means of buds it has, therefore, lost the power to regenerate in other
ways (or has never developed the power to regenerate), then the
argument is, I think, fallacious ; for we find even in flowering plants
that the new buds sometimes arise from the new part, or callus,
that forms over the cut-end, and this process resembles a real regen-
erative process. We also find that hydroids that produce lateral
buds also regenerate freely from an exposed end. But we are at
present so much in the dark in regard to the causes that bring about
budding in organisms that a discussion of the possibilities would
hardly be profitable.

AUTO TOM Y

The process of autotomy differs only in degree from the process
of self-division. In autotomy the part thrown off does not produce
a new animal. The breaking off of the tail of the lizard at the base,
if the outer part is injured, is an example of a typical process of
autotomy. The throwing off of the crab's leg, if the leg is injured, is
also another typical case of autotomy. There is a definite breaking-
joint at the base of the crab's leg at which the separation always
takes place (Fig. 45, A i-i). The breaking-joint is in the middle of
the second segment from the base of the leg, where there is found,

AUTOTOMY

151

on the outside of the leg, a ring-like groove that marks the place of
rupture. A comparison of the legs of the crab with the walking
legs of the crayfish, or of the lobster, shows that the groove in the
crab's legs corresponds to a joint in the legs of the two other forms.
In the crayfish and lobster the walking legs generally break off at
this same level, although by no means as easily or with as much
certainty as in the crab. The first pair of legs of the crayfish and

Fig. 45. — A. After Andrews. Base of leg of crab to show breaking-joint, i-i. B. After Fre-
dericq. Diagram of leg of crab to show how autotomy takes place. C. After Andrews.
Longitudinal section of base of leg to show in-turned chitinous plate at breaking-joint.

lobster, carrying the large claws, have also a breaking-joint at the
base of the leg similar to that in the crab's leg, and these legs break
off in the living animal always at the breaking-joint.

Reaumur first recorded that if the leg of a crayfish or of a crab is
cut off outside of the breaking-joint it is always thrown off later at
the breaking-joint. Fredericq has made a careful examination of the
way in which the leg is thrown off in the crab, Carcijius mcznas.
He found that the breaking does not take place at the weakest part

152

REGENERATION

of the leg; for the leg of a dead crab will support a weight of 3| to
5 kilograms, which represents about one hundred times the weight of
the crab's body. When the weight is increased to a point at which the
leg breaks, it does so between the body and the first segment or
between the first and second segments. When it breaks off in this
way, the edges are ragged and are left in a lacerated condition ; but
when the leg is thrown off by the animal at the breaking-joint, there
is left a smooth surface covered over, except in the centre, by a
thin cuticle. Through the opening in the centre of this cuticle a
nerve and a blood vessel pass to the distal part of the leg. Very
little bleeding takes place when the leg is thrown off, but if the leg
is cut off or broken off at any other level the bleeding is much
greater. Fredericq studied the physiological side of the process and
found that it is the result of a reflex nervous act. He found that if
the brain of the animal is destroyed the leg may still be thrown off,
but if the ventral cord is destroyed the reflex action does not take
place. The reflex is brought about ordinarily by an injury to the
leg that starts a nerve impulse to the ventral nerve-cord, and from
this a returning impulse is sent to the muscles of the same leg,
causing the muscles in the region of the breaking-joint to contract
violently, and the result of their contraction is to break off the leg.
If the muscles are first injured, the leg cannot be thrown off. Andrews,
who has studied the structure of the breaking-joint in the spider-
crab, has found that there is a plane of separation extending inwards
from the groove on the surface. This plane is made by a narrow
space between two chitinous membranes that are continuous at their
outer ends with the general chitinous covering of the leg (Fig. 45, C\
When the leg breaks off, one-half of the double membrane is left
attached to the base of the leg and the other to the part that is lost.
This in-turned membrane seems to correspond to the in-turning of
the surface cuticle in the region of the joints. The arrangement of the
muscles at the breaking-joint is shown in Fig. 45, B. The upper
muscle is the extensor muscle of the leg, and through its contraction
the breaking off takes place. When it contracts the leg is brought
against the side of the body, which is supposed to offer the resistance
necessary to break off the leg. If the leg is held by an enemy,
this may offer sufficient resistance for the muscle to bring about the
breaking.

In many crabs the leg is not thrown off if simply held, but only
after an injury. Even the most distal segment may be cut off and
the leg remain attached, and sometimes it is not lost after the distal
end of the next to the last segment is cut off. If a crab is tethered
by one leg it will not throw off its leg in order to escape, unless, in
the crab's excitement, the leg is twisted or broken. How generally

AUTOTOMY 153

this holds for all crabs cannot be stated. Herrick says : " Uninten-
tional experiments in autotomy have often been made by tethering
a lobster or a crab by its large claws. The animal, of course, escapes,
leaving only its leg behind. When lobsters are drawn out of the water
by the claws, or when a claw is pinched by another lobster, or while
they are handled in packing, especially for the winter market, they
often ' cast a claw,' and the transportation of lobsters at this season
is said to be attended by considerable loss in consequence." The
large claws of the lobster are quite heavy, the base relatively small
at the breaking-joint, and it may be that simply the weight of the
claw, when out of the water, may strain the leg so that it breaks
off, — the leg being injured by its own weight. The lobster seems to
lose its claws quite often under natural conditions. Rathburn^ states
that " out of a hundred specimens collected for natural history pur-
poses in Narragansett Bay in 1880, fully 25 per cent had lost a claw
each, and a few both claws." Herrick ^ records that " in a total of
725 lobsters captured at Woods Holl in December and January,
1 893-1 894, fifty-four, or 7 per cent, had thrown off one or both
claws."

The autotomy of the arms of the starfish has been often ob-
served.^ The arms are thrown off very near the base in many forms.
If the animal is simply held by the arm it does not break off, but if
injured it constricts and falls off. The lost arm does not regenerate
a new starfish in most forms, but, as stated on page 102, there are
recorded some cases in which the arm seems to have this power.
King has found that out of a total of 1914 starfish (^i-Zm^j vulgaris^
there were 206, or 10.76 per cent, that had new arms, and all of
these, with one exception, arose from the base of the arm. The
growth of the new arm from the base takes place more rapidly, as
shown in Fig. 38, A, than when the arm is regenerated from a more
distal level; but in the latter case the arm, despite its slower growth,
may complete itself before another does that originates at the same
time from the base of the old arm. There is, therefore, in this
respect no pbvious advantage, so far as regeneration is concerned,
in throwing off the injured arm nearer to the disk.

In the brittle-stars (ophiurians) the arm breaks off with greater
ease and at any level. If the arm is simply held and squeezed, it
will, in some forms, break off just proximal to where it is held. If
the broken end is again held, another small piece breaks off, and in
this way the arm may be autotomized, piece by piece, to its very base.

^ The Fisheries and Fishing htdustries of the United States, Washington, 1887.
2 "The American Lobster," Bull. U. S. Fish Comm., 1895.

^ Reaumur in 1742 records the first observations. Spallanzani also described the pro-
cess, and many later writers have examined it.

154 ^^ GENERA TION

Regeneration may take place from any region, but, as yet, no obser-
vations have been made on the relative rate of growth of the new-
arm at different levels.

One of the most remarkable cases of autotomy is that in holothu-
rians, in which the Cuvierian organs, and even the entire viscera, may
be ejected when the animal is disturbed. A new digestive tract is
regenerated.^

It is known that several of the myriapods lose their legs at a defi-
nite region near the base, and that they have the power of throwing
off the leg in this region if it is injured. I have often observed that
the legs of Sattigera forceps are thrown off if they are held or injured,
and even when the animal is thrown into a killing fluid. Amongst the
insects the plasmids or walking-sticks also throw off their legs at a
definite joint, as described by Scudder, and more recently by Bor-
dage, and still later by Godelmann. New legs are regenerated
from the stump of the old leg, as has long been known.^ Other
insects do not have the power of throwing off their legs, and we have
only a few observations that show that the legs if lost can be regen-
erated. It is known in the cockroach that the tarsus can regenerate
if lost or if cut off, and that fewer segments are regenerated than are
present in the normal animal. Newport found that the true legs of a
caterpillar are regenerated during the pupa stage if they have been
previously cut off.

A further example of autotomy is found in the v/hite ants, which
break off their wings at the base after the nuptial flight. There
exists a definite and pre-formed breaking-plane in this region.
The true ants also lose their wings after the nuptial flight, but there
does not seem to be a definite plane of breaking, so that the process
can scarcely be called one of autotomy. These cases also differ from
the other cases of autotomy in that the lost parts are not renewed.

It has been observed^ that if the leg of tarantula is cut off at any
other place than at the coxa, the animal bites off the wounded leg with
its jaws down to the coxa. In other spiders this does not occur,
although Schultz has observed that when the legs are lost under nat-
ural conditions they are found broken off in most cases at the coxa.
Schultz has also found that the legs regenerate better from this
region than from any other. It would be rash, I think, to conclude
without further evidence that the habit of tarantula to bite off a
wounded leg down to the coxa has been acquired in connection with
the better regeneration of the leg at this place. It is possible that
the injury may excite the animal to bite off the leg as far as possible,
which might be to the coxal joint. It would certainly be very remark-

1 The phenomenon has been observed by Dalyell, Semper, Minchin, and others.

2 Miiller, Elet?tents of Physiology, 1837. ^ By Wagner ('87).

THEORIES OF A OTOTOMY 155

able if this spider had acquired the habit in connection with the better
regeneration of the leg at the base, since the leg can presumably also
regenerate at any level, as in the epeirids.

In this same connection I may record that in the hermit-crab I
have often observed that when a leg is cut off outside of the break-
ing-joint, if the leg is not thrown off at once, the claws of the first
legs catch hold of the stump and, pulling at the leg, offer sufficient
resistance for the leg to break off at the breaking-joint. I cannot
believe that this instinct has anything to do with the better regenera-
tion of the leg at the coxal joint, however attractive such an hypothesis
may appear.

THEORIES OF AUTOTOMY

A number of writers have pointed out that under certain condi-
tions it is an obvious advantage to the animal to be able to throw off
a portion of the body and thereby escape from an enemy. It has
been suggested that if a crab is seized by the leg, the animal may
save its life at times at the expense of its leg ; and since the crab has
the power of regenerating a new leg, it is the gainer in the long run
by the sacrifice. The holothurian, that ejects its viscera, has been
supposed to offer a sufficient reward to its hungry enemy, and escapes
paying the death penalty, at the expense of its digestive tract. Thus,
having shown that the process of autotomy is a useful one, it is
claimed that it must have been acquired through a process of natural
selection ! An equally common opinion is that autotomy is an adap-
tation for regeneration, since in certain cases, as in that of the crab's
leg, better conditions for subsequent regeneration occur at the break-
ing-joint than when the amputation takes place at any other region.
Since less bleeding takes place when the crab's leg is thrown off at
the breaking-joint, and since the wound closes more quickly when
the arm of the starfish is lost at the base, it is assumed that we have
in both cases an adaptation to meet accidents, and that the adaptation
has been acquired by natural selection.

A consideration of these questions involves us once more in a dis-
cussion of the theory of natural selection. An attempt has been made
in another place (pages 108-110) to show that we are not justified in
assuming that because a process is useful, therefore it must have been
acquired by means of natural selection. Even if it were granted that
the theory of natural selection is correct, it does not follow that all
useful processes have arisen under its guidance. We may, therefore,
leave the general question aside, and inquire whether the process of
autotomy could have arisen through natural selection (admitting that
there is such a process, for the sake of the present argument), or
whether autotomy must be due to something else.

156 RE GENERA TION

If we assume that the leg of some individual crayfishes or crabs,
for example, broke off, when injured, more easily at one place than at
another, and that regeneration took place as well, or even better, from
this region than from any other, and if we further assume that those
animals in which this happened would have had a better chance of
survival than their fellows, then it might seem to follow that in time
there would be more of this kind of animal that survived. But even
these assumptions are not enough, for we must also assume that this
particular variation was more likely to occur in the descendants of
those that had it best developed, and that amongst those forms that
survived, some had the same mechanism developed in a still higher
degree, and, the process of selection again taking place, a further
advance would be made in the direction of autotomy. This, I think,
is a fair, although brief, statement of the conventional argument as to
how the process of natural selection takes place. But let us look
further and see if the results could be really carried out in the way
imagined, shutting our eyes for the moment to the number of suppo-
sitions that it is necessary to make in order that the change may
occur. It will not be difficult, I believe, to show that even on these
assumptions the result could not be reached. In the first place, the
crabs that are not injured in each generation are left out of account,
and amongst these there will be some, it is true, that have the particu-
lar variation as well developed as the best amongst those that were
injured, and others that have the average condition, but there will be
still others that have the possibilities less highly developed, and the
two latter classes will be, on the hypothesis, more numerous than
those in the first class. The uninjured crabs will also have
an advantage, so far as breeding and resisting the attacks of their
enemies are concerned, as compared with those that have been injured,
and in consequence they, rather than the injured ones, will be more
likely to leave descendants. Even if some of those that have been
injured, and have thrown off the leg at the most advantageous
place, should interbreed with the uninjured crabs, still nothing, or
very little, can be gained, because, on Darwinian principles, inter-
crossing of this sort will soon bring back the extreme variations
to the average.

The process of natural selection could at best only bring about
the result provided all crabs in each generation lose one or more of
their legs, and amongst these only the ones survive that break off the
leg at the most advantageous place ; but no such wholesale injury
takes place, as direct observation has shown. At any one time only
a small percentage, about ten per cent, have regenerating legs, and
as the time required completely to regenerate a leg, even in the sum-
mer, is quite long, this percentage must give an approximate idea of

THEORIES OF AUTOTOMY 1 57

the extent of exposure to injury. It is strange that those who assert
off-hand that, because autotomy is a useful process, therefore it must
have been acquired by natural selection, have not taken the pains to
work out how this could have come about. Had they done so, I can-
not but believe they would have seen how great the difficulties are
that stand in the way.

A further difficulty is met when we find that each leg of the crab
has the same mechanism. If we reject as preposterous the idea that
natural selection has developed in each leg the same structure, then
we must suppose that a crab varies in the same direction in all its legs
at the same time; and if this is true it is obvious that the principle of
variation must be a far more important factor in the result than the
picking out of the most extreme variations. The same laws that
determine that one individual varies in a useful direction farther than
do other individuals may, after all, account for the entire series of
changes. If it be replied that natural selection does not take into
account the causes of the differences of individual variation, this is
to admit that it avowedly leaves out of account the very principles
that may in themselves, and without the aid of any such supposed
process as natural selection, bring about the result. The Lamarckian
principle of use and disuse does not give an explanation of autotomy,
since the region of the breaking-joint is not the weakest region of the
leg, or the place at which the leg would be most likely to be injured.

We cannot assume autotomy to be a fundamental character of liv-^
ing things, since it occurs only under special conditions, and in special
regions of the body. While it might be possible to trace the autot-
omy of the legs of the Crustacea, myriapods and insects, to a common
ancestral form, yet this is extremely improbable, because the process
takes place in only a relatively few forms in each group. The au-
totomy of the wings of white ant::, that takes place along a preexisting
breaking-line must certainly have been independently acquired in this
group. The breaking off of the end of the foot in the snail helica-
rion is also a special acquirement within the group of mollusca.

Bordage has suggested that the development of the breaking-joint
at the base of the leg of phasmids has been acquired in connection with
the process of moulting. He has observed that during this period the
leg cannot, in some cases, be successfully withdrawn through the
small basal region ; and hence, if it could not break off, the animal
would remain anchored to the old exoskeleton. It escapes at the
expense of losing its leg. The animal, having acquired the means of
breaking off its leg under these conditions, might also make use of the
same mechanism when the leg is held or injured, and thereby escape
its enemy. The fact that the crayfish has a breaking-joint only for
the large first pair of legs would seem to be in favor of this interpre-

158 RE GENERA TION

tation, but the crab has the same mechanism for the slender walking
legs, that one would suppose could be easily withdrawn from the old
covering. It should also be remembered that we do not know
whether the breaking-joint at the base of the leg of the crab and
of the crayfish would act at the time when the leg is being with-
drawn from the old exoskeleton, unless the leg were first injured
outside of the joint.

Our analysis leads to the conclusion that we can neither account
for the phenomenon of autotomy as due to internal causes alone in
the sense of its being a general property of protoplasm, nor to an
external cause, in the sense of a reaction to injury or loss from
accident. There would seem then only one possibility left, namely,
that it is a result of both together, or in other words, a process that
the animal has acquired in connection with the conditions under
which it lives, or in other words, an adaptive response of the organism
to its conditions of life.

We are not, however, able at present to push these questions
farther, for, however probable it may seem that animals and plants
may acquire characteristics useful to them in their special conditions
of life, and yet not of sufficient importance to be decisive in a life and
death struggle, still we cannot, at present, state how this could have
taken place in the course of evolution. For, however plausible it
may appear that the useful structure has been built up through an
interaction between the organism and its environment, we cannot
afford to leave out of sight another possibility, viz. that the struc-
ture or action may have appeared independently of the environ-
ment, but after it appeared the organism adopted a new environment
to which its new characters made it better suited. If the latter alter-
native is true, we should look in vain if we tried to find out how the
interaction of the environment brought about the adaptation. The
relation would not be a causal one, in a physical sense, but the out-
come of a different sort of a relation, viz. the restriction of the organ-
ism to the environment in which it can remain in existence and leave
descendants.

CHAPTER IX

GRAFTING AND REGENERATION

By uniting parts of the same or different animals, or of plants,
there is given an opportunity of studying a number of important
problems connected with the regeneration of the grafted parts.
Trembley's experiments in grafting pieces of hydra are amongst
the earliest recorded cases of uniting portions of different animals,
although in plants the process of grafting has been long known.^
Trembley found that if a hydra is cut in two, the pieces can be
reunited by their cut-surfaces, and a complete animal results. No
regeneration takes place where the union has been made. He also
succeeded in uniting the anterior half of one individual with the
posterior half of another individual, and again produced a single
individual. He failed to obtain a permanent union between different
species.

More recently, Wetzel has carried out a number of different
experiments in uniting pieces of hydra. He found that if two
hydras are cut in two, the two anterior pieces may be united by the
aboral cut-surfaces (Fig. 46, B), and the two posterior pieces may
also be united by their oral cut-surfaces (Fig. 46, A). The fusion
of these " Hke-ends " takes place as readily as when unlike ends are
brought in contact, as in Trembley's experiments. Subsequently,
however, regenerative changes take place. When, for instance, two
anterior pieces are united by their aboral ends, there develop after
two or three days one or two outgrowths, at or near the line of union,
that become new feet, and the two individuals may subsequently
separate. When two posterior pieces are united by their oral sur-
faces, a double circle of tentacles generally develops, one on each
side of the line of union. The pieces' then pinch apart and produce
two hydras.^ In another experiment the head and a part of the foot
were cut from a hydra, and the head was turned around and grafted
by its aboral surface upon the aboral surface of the middle piece.
Another animal was cut in two in the middle, and the posterior half
was grafted by its oral end to the oral end of the middle piece. In

^ For references to the literature on grafting in plants see Vochting ('84).
2 In one case they separated only after three months.

159

i6o

REGENERATION

this way a new, artificial individual was made, as shown in Fig. 46, C,
with the middle part of the body in a reverse direction as compared
with the orientation of the two end-pieces.^ The union of the three
pieces was so perfect that not even a swelling or a constriction indi-
cated the places of fusion. After six days a normal bud appeared at
the region of union of the posterior and middle pieces, that gave
rise to a new hydra, which separated after a few days. The com-

FlG. 46. — A. Two posterior pieces of liydra united by their oral ends. B. Two anterior pieces
of hydra united by their aboral ends. C. A " long hydra " made by uniting three pieces ; the
middle piece reversed. D. After Peebles. Two posterior pieces of brown hydra united by
oral ends, and one cut off near union. A new anterior end developed from the cut, aboral sur-
face, i^ After Peebles. Union of a nutritive and a protective polyps of hvdractinia. Subse-
quently former cut off at line, i-i. E. Union of two posterior pieces of hydra by oral ends.
Subsequently one piece cut off at line, 2-2. £i. New head regenerated in region of union,
and a foot from aboral cut-end. E'^, E^. Fusion of two parts with a single hydra.

pound animal was healthy and ate many daphnias. It was kept under
observation for twenty-four days, and appeared normal, giving off
several more buds.

In other experiments of this same sort a foot generally developed
where the two aboral surfaces came together, and the head-end sepa-
rated from the rest of the piece. In another case a mouth and tenta-
cles appeared at the place at which the oral ends had united.

^ This and other experiments were carried out by pushing the pieces on a bristle.

GRAFTING AND REGENERATION l6l

In a different kind of experiment, the anterior ends of two hydras
were cut off and united by their aboral surfaces ; then one of the
components was cut in two, just back of the circle of tentacles.
After five days two short, hook-like processes appeared at the cut,
oral end. They produced a foot, by means of which the animal
fixed itself. In this case it will be seen that a foot developed from
an oral end. The result might not in itself be considered sufficient to
show whether the development of a foot at the oral end of a piece is
due to the influence of the other component, or is simply a case of
heteromorphosis having no connection with the presence of the other
component. Since heteromorphosis has never been observed in iso-
lated pieces of hydra, the probability is that the result is in some way
connected with the presence of the other component. Peebles has
made a number of experiments, in which special attention was paid
to this point. Fifteen anterior pieces were united in pairs by their
aboral cut-surfaces, and then one component was cut in half, leaving
an exposed oral end. Out of this number five pieces formed a new
head at the cut-surface, and the pieces became attached by a foot,
that developed at the region of union. Two others did not regener-
ate at the cut-surface, but became fixed as before, and neither regen-
erated nor became fixed at the cut-end. Three became attached at
the cut, oral surface, but none of these developed a characteristic
foot. The result shows, nevertheless, that some influence was present
that inhibited the development of a mouth and tentacles at the oral
cut-end, since these always develop in isolated pieces. In another
series of experiments posterior ends were united by their oral sur-
faces, and then one of the two pieces was cut in two (Fig. 46, E\ A
new hypostome and tentacles developed at the region of union, and
a foot at the aboral cut-surface, as shown in Fig. 46, E^. An organ-
ism, with one mouth and a circle of tentacles, and two bodies and
two feet, resulted. The bodies soon began to fuse together (Fig. 46,
j5"^) into a single one, and when the fusion had extended to the region
of the feet, they also fused into a single structure (Fig. 46, E^), so
that a single hydra was produced.

In another experiment, twenty-two posterior ends were united in
the same way, and then one of the two components was cut in two.
In five cases a single head developed on the aboral end of the smaller
piece (Fig. 46, D^. It is evident in this case that the union of the two
pieces has been a factor in bringing about the development of an
aboral head. Another of the grafts produced an aboral head, and also
one in the region of union. The remaining sixteen grafts produced
new heads, if they developed at all, only in the region of union. Pee-
bles states that the regeneration of aboral heads takes place only when
one component is cut off near the region of union of the two pieces.

1 62 REGENERATION

In general, it may be stated in regard to these experiments in
hydra that when pieces are united in the same direction, that is, by
unHke surfaces, a single individual is formed and no regeneration
takes place where the union has been made, but when like surfaces
are brought together, although perfect union may result, a process of
regeneration takes place later, at or near the line of union. Even
the presence of cut-surfaces at one or both cut-ends of the united
components does not generally affect the result, although, in a few
cases, it may change it, in so far that heteromorphic regeneration may
take place from one piece. This sometimes leads to a suppression of
regeneration at the line of union. The experiments do not show,
perhaps, conclusively whether the heteromorphosis of the smaller
component is due to the polarity of the larger component effecting a
change in the smaller one, or whether the closing of the oral end of
the smaller component (by its union with the other) brings about the
result. All things considered, it seems to me that the larger compo-
nent has directly influenced the other.

King has found that if two posterior pieces of hydra are united
by the oral cut-surfaces, and then after they have fused both pieces
are cut off 7iear the line of fusion, there develops from the small
piece a single Jiydra, with a foot at one end and tentacles at the other.
If only one of the pieces is cut off near the line of fusion, a new
head develops from its oral surface, as Peebles had found. If two
anterior ends are united by their aboral cut-surfaces, and then later
both are cut off near the line of fusion, a single hydra develops from
the small, double piece. If one of the components is cut off near
the line of union, a foot develops from the oral cut-end. If in any
of the cases the cut is made some distance from the line of union,
then each cut-surface develops its typical structure. These experi-
ments leave no doubt as to the influence of the larger piece on the
smaller one. Especially interesting is the formation of one individual
from two short pieces united in opposite directions. In this case we
must suppose that one piece has the stronger influence on the combi-
nation (perhaps because it is a little larger), and determines the polari-
zation of the other piece.

King finds that when two posterior pieces are united by their oral
ends, regeneration of one or of two heads often takes place at the
line of union (Fig. 47, B, B^, B% as Wetzel had found. If a dark
green individual is united to a hght green one, it can be seen that in
many cases the new heads are formed by both components, as shown
in Fig. 47, B^. Later one of the posterior ends is absorbed, and
the halves may then separate (Fig. 47, B'^, B'^). If a number of
pieces are united, as indicated in Fig. 47, E, a number of heads may
be formed, and one or more of these may have a double origin. No

GRAFTING AND REGENERATION

163

evidences of separation of the pieces was observed in cases of this
sort.

In one experiment two posterior pieces were united by oblique
surfaces, as shown in Fig. 47, C, and one of the two was afterwards
cut across, as indicated by the cross-line. The subsequent re-
generation that took place is shown in Fig. 47, C^. A head, com-

FlG. 47. — After King. A. Hydra split in two, hanging vertically downwards. Later the halves
completely separated. B. Two posterior ends united by oral surfaces. B'^. Same; it regen-
erated two heads, each composed of parts of both pieces. IP'. Absorption of one piece lead-
ing to a later separation of halves. C. Two posterior ends united by oblique surfaces. Later
one piece partially cut off, as indicated by line. C^. Later still, two heads developed, one at
A^, the other at il/. D. Similar experiment in which only one head developed, at yl/. E. Five
pieces united as shown by arrows. Four heads regenerated, one being composed of parts of
two pieces.

posed of parts of both pieces, developed at the cut-surface M, and
another in the region N in Fig. 47, C, composed of material of one
component. In another case, shown in Fig. 47, D, a head devel-
oped only at the cut-edge, but it was made up of material from both
components.

A series of grafting experiments of another sort has been made

164

REGENERATION

by Rand. A part of one hydra is grafted upon the side of another
one in the following way. A groove is scratched in a film of soft
paraffine covering the bottom of a dish filled with water. Another
groove is made at right angles to the first one, and opening into it.
A hydra (the stock) is placed in the first groove, and a wound made
in its side with a knife. Another hydra is cut in two, and one piece
(the graft) placed in the other groove, and its cut-surface brought
into contact with the wound in the side of the first individual. If
the operation is successful the exposed surfaces of the two hydras

Fig. 48. — After Rand. A. Head of Hydra cut off. After eight dajs. A^. Same after thirteen
days. Three tentacles misplaced. A"^. Same after eighteen days. A^. Same after twenty-
one days. Misplaced tentacles absorbed. B. Anterior end of Hydra fusca, grafted upon
side of body of another individual. Half an hour after operation. /?l. Same after four days.
i?2. Same after thirty-eight days. B^. Same, foot-region after forty-nine days. j5*. Same
after separating. Fifty-second day.

quickly unite, and the combination may be taken out of the groove.
If the piece grafted on the stock included about the anterior half
of a hydra, a two-headed animal results, as shown in Fig. 48, B.
Although the graft has been united to the side of the stock, it soon
assumes an apparently terminal position (Fig. 48, B^). This is due
to the graft sharing with the anterior end of the stock the common
basal portion of the stock. A slow process of separation of the two
anterior ends now begins, brought about by a deepening of the angle
between the halves (Fig. 48, B"^). This leads ultimately to a com-

GRAFTING AND REGENERATION 1 65

plete separation of the two individuals (Fig. 48, B'^, B^). Each may
get a part of the original foot, or a new foot may arise on the graft
as the division approaches the base.

In other experiments only a small part of the foot-end was cut
from the animal that served as the graft. The long anterior piece
was grafted as before upon the side of the stock. After the two had
united, the graft was cut in two, leaving a part of the graft attached
to the stock. The part regenerated tentacles, and in tv/o cases sub-
sequently separated from the stock as in the first experiment. In a
third case the graft was absorbed by the stock as far as the circle
of new tentacles, but its subsequent fate was not determined. In a
fourth case the graft did not regenerate its tentacles, and was com-
pletely absorbed into the wall of the stock. The smaller the piece
that is grafted on the stock the greater the chance that it will be
absorbed, and furthermore short, broad rings are more likely to
be absorbed than long, tubular pieces of the same volume.^

Rand's results show in general that when hydras are grafted
together they regain the typical form in one of two ways, — either
by separation into two individuals, or by the absorption of the smaller
into the larger component. In the former case the result is brought
about in the same way as when the anterior end is partially split in
two and the halves subsequently separate. When the graft is ab-
sorbed it is not clear whether the absorbed piece disappears or, as
seems not improbable, forms a part of the wall of the stock.

It is important to notice the difference between lateral buds and
lateral grafts. The buds separate in the course of four or five days
by constricting at the base, but this never happens in lateral grafts.
Rand has also made some experiments with buds. He cut off the
outer oral end of a bud, and grafted it back upon the stock in a new
place. It did not separate from the stock as does a bud, but by
a slow process of division it was set free in the same way as are
lateral grafts. The proximal end of the bud, which was left at-
tached, developed tentacles at its free end, constricted at its base,
and was set free. The separation was, however, somewhat delayed.

In anothei: experiment a bud was split in two lengthwise, and the
cut was extended so that the body of the parent was separated into
two pieces. Twenty-four hours later it was found that each half-bud
had closed in, and was much larger than when first cut. The half-
bud, that was attached to the posterior end of the anterior piece, was
constricting at its base, and subsequently it separated at its point of

1 Rand found that when a posterior piece was grafted by its cut, oral end to the side
of another hydra that it was absorbed into the stock. In one case it moved down the whole
length of the body of the stock and finally disappeared by absorption into the foot of the
stock.

1 66

REGENERA TION

attachment. The other half of the bud, that had been left attached
to the anterior end of the posterior piece, had swung around, so that
its long axis corresponded to that of the posterior, parental piece.
At first a slight constriction indicated the line of union of the two,

B

D

Fig. 49. — After Peebles, yi. Grafting in Tubulaiiu viesenbryanthemum. A small piece of the
stock taken from the region near the base, and grafted in a reversed direction on the oral end
of a long piece. B. Same with distal tentacles in small piece, and proximal tentacles in large
piece (modified from Peebles). C. Same. Formation of hydranth (original). D. Like y^.
Both pieces produce hydranths. E. Protrusion of hydranths of last. F. Piece of oral end
cut off, turned around and grafted on oral end of long piece. A single hydranth produced.
Distal tentacle from both components. G. A short piece from distal (oral) end of long piece
cut off, and grafted by its pro.ximal end to proximal end of the same long piece.

but later this disappeared and a single hydra resulted. Whether
the difference in the fate of the two half-buds is connected with their
different polar relations to the parts of the parent, or is due to some
other difference in the absorbing power of the anterior and posterior
pieces, is not known.

GRAFTING AND REGENERATION 1 6/

Tubularia is not so well suited as hydra to show the influence
of grafting on the united parts, since pieces of tubularia produce
hydranths, both at the oral and aboral ends, although the latter
hydranths take longer to develop. Peebles has shown, nevertheless,
that grafting has an influence on the behavior of a piece. In order
to show that the polarity of a small piece could be affected by a
larger piece, the following experiment was carried out. After cutting
off the old hydranth from the end of a stem, a short piece was then
cut from the distal end of the same stem, turned around, and its oral
end brought in contact with the oral end of the original piece, as
indicated in Fig. 49, F. The two pieces, being held together for a
few minutes, stuck together and subsequently united perfectly.
From eighty-eight pieces united in this way the following results were
obtained. Thirty-six formed a single hydranth at the end at which
the grafting had been made. The distal row of tentacles appeared
in the smaller reversed component, the proximal row in the larger
piece (Fig. 49, B\ The new hydranth pushed out later through the
perisarc of the smaller piece (Fig. 49, C). In this experiment the
smaller component was shorter than the average length of the hy-
dranth-forming region. In two cases, in which the smaller component
was larger, both circles of tentacles appeared in this piece. In six of
the experiments the tips of the proximal tentacles arose from a part
of the wall of the smaller piece, hence these tentacles had a double
origin (Fig. 49, i^). In five of the unions the smaller as well as the
larger component produced a hydranth ; the two were stuck together
by their oral ends (Fig. 49, D, E). The remaining four unions gave
somewhat different results. In three of these the smaller piece pro-
duced only a part of a hydranth that remained sticking to the end of
the hydranth formed by the larger component. In the thirty-six
cases in which the minor component took part in the formation of
the single hydranth, the influence of the larger component was shown
not only in reversing the polarity of the smaller component, although
this might in part be accounted for by the closing of the oral end of
the smaller piece, but also in the time of development, since the
hydranth appeared sooner than does the aboral hydranth and at the
same time as does the oral hydranth.

In another series of experiments, a short piece was cut from the
basal end of a long piece (three to four centimetres) and brought
forward and grafted in a reversed position on the anterior end of
the same long piece (Fig. 49, A). Of five unions of this sort, one
produced a hydranth in each component, neither being reversed.
Another of the pieces produced a hydranth partly out of each com-
ponent (and at the same time another at the aboral end of the large
piece). The other two pieces produced a single hydranth, a part of

1 68 RE GENERA TION

which came from the minor component and appeared before the
aboral hydranth on the aboral end of the larger piece. This last
result shows that the small piece from the basal end has been affected
by the oral end in such a way that it develops more rapidly than it
would have done had it remained a part of the basal end.

In a third series of experiments a short piece (about a half of a
millimetre) was cut from the anterior end of a long piece (one and
five-tenths to two centimetres) and grafted in a reversed position on
the posterior end of the same long piece (Fig. 49, G). In four cases
a hydranth developed only at the oral end of the long piece and none
from the aboral end or from the short piece. Eight unions produced,
however, in the region of the graft, a hydranth formed partly by
each component. Later another hydranth developed at the oral end
of the larger piece. The latter results are not convincing, but they
may show that the small piece has hastened the development of the
hydranth at the aboral end.

Peebles has also made some experiments in grafting pieces of dif-
ferent members of the colonies of hydractinia and podocoryne. The
colony of the former is made up of three different kinds of individ-
uals : the nutritive, the reproductive, and the protective hydroids.
A series of prehminary experiments showed that if these individuals
are cut into a number of pieces each piece regenerates the same kind
of individual as that of which it had been a part. It was also
observed that if pieces of the nutritive individuals were allowed to
remain quietly on the bottom of the dish they sent out branching
stolons, which stuck to the bottom of the dish, and from these stolons
there arose later nutritive hydranths that stood at right angles to the
surface. When pieces of the same kind of individuals are grafted
together, the results are essentially the same as with tubularia. If
pieces of different kinds of individuals are united, the opportunity
is given of testing the possible influence of one kind on the other.
Peebles united a nutritive and a protective polyp by the cut, aboral
ends (Fig. 46, E), and after they had grown together one of the
polyps was cut off near the region of union, so that a small piece
of a nutritive polyp was left attached to a protective polyp. When
the piece of the nutritive polyp regenerated, it made a new nutritive
polyp. The influence of the protective polyp was not apparent. If
a nutritive and a reproductive polyp are united in the same way, and
the latter cut in two near the line of union, a new reproductive polyp
develops from the piece left attached to the nutritive polyp. Again
there is shown no influence of the one on the other kind of polyp.

Hargitt has also made a number of grafting experiments on other
hydroids. His most interesting results are those in which parts of
two medusae were united by holding their cut-surfaces together by

GRAFTING AND REGENERATION 1 69

means of bristles passing through the individuals. Hargitt also finds
that while in certain hydroids it is possible to bring about a union of
oral with oral end, or aboral with aboral, or oral with aboral end of
the same species/ yet a permanent union between different species
cannot be brought about. These results are in agreement with those of
a number of writers who have recorded the difficulty or impossibility
of uniting parts of different species of hydra. In a few instances it
has been possible to unite temporarily a piece of a brown hydra with
a piece of a green one, — as I have also seen accomplished, — yet the
pieces subsequently separate. Wetzel succeeded in obtaining better
results with two species of brown hydras, Hydra fi^sca and Hydra
grisea. In one experiment the head of Hydra grisea was grafted on
the body (from which the head had been cut off) of Hydra fiisca.
After five hours the pieces seemed to have united. Later a constric-
tion appeared at the place of union, and the head-piece produced
a foot near the line of union, and the posterior piece produced
a circle of tentacles at its anterior end. Eight days later, when the
animal was being killed, it fell apart into two pieces. It was observed
that during the period of union a stimulus to one piece was not car-
ried over to the other. Wetzel's results seem to show that pieces of
these two species of hydra unite at first, when brought together, as per-
fectly as do pieces of the same species, but the union never becomes
permanent, a constriction appearing later at the line of union, and the
pieces separating in this region. These results indicate, it seems to
me, that the factors that bring about the first union are different from
those that make the grafted pieces one organic whole. Other results
indicate that the union of oral to oral end, or aboral to aboral end,
while at first as perfect as between unlike surfaces, nevertheless is
less permanent than when unlike surfaces are united ; at least, sub-
sequent regeneration is more likely to occur in the former than in the
latter, and after this occurs the separation of the individuals often
takes place. It seems, moreover, not improbable that a more per-
manent union results when similar regions are united by unlike sur-
faces, than when the union is at different levels. If, for instance,
the anterior half of one hydra is united to the posterior half of
another individual, the union is generally permanent; but if one or
both of the pieces are longer than half the length, so that a " long
animal" results, new tentacles are more often formed at the oral
end of one component, and the parts subsequently separate. It
may be that, at present, the data are insufficient to establish this
general rule, and no doubt other modifying influences must be also
taken into account; but it is important that attention should be
drawn to this side of the subject.

1 Pieces from male and female colonies of the same species also unite.

I/O

HE GENERA TION

Grafting experiments in planarians have so far been carried out in
only the two cases which I have described. In one of these the ante-
rior ends of two short pieces of Bipalium kewense were united (Fig.

50, A). Neither piece produced a
head at the region of union. Later
the pieces were cut apart by an
obhque cut that passed across the
hne of union (Fig. 50, C\ so that
each piece retained at its most an-
terior end (at one side) a piece of

Fig. 51. — Two pieces of Bipalium kewense
united by posterior ends. Each regen-
erated a head at anterior end.

the other individual in a reversed
position. A head developed at the
anterior (and lateral) end of each
piece, in such a way that a part at
least of the small reversed piece
was contained in the new head
(Fig. 50, D). In the other case two
pieces of bipalium were united by
their posterior cut-surfaces. Each
piece produced a new head at its
free end, and the pieces greatly elongated, but remained sticking
together {Fig. 51).

A large number of experiments have been made by Joest in graft-
ing pieces of earthworms. The cut-surfaces were held in contact by
means of two or three threads passing through the body wall of each
piece and tied across, so that the pieces were drawn together and
held firmly in that position. Joest found that pieces of the same or
of different individuals could be united in various ways, and the
union become permanent. If the anterior end of one worm is united to
the posterior end of the same, or of another worm, a perfect union is

B D

Fig. 50. — A. Two pieces of Bipalium keivense
united by anterior ends. B, C. Later
stages of same. Line in C indicates how
pieces were cut apart. D. Two worms
produced by these pieces. All drawn to
scale.

GRAFTING AND REGENERATION

171

formed, and no subsequent regeneration takes place (Fig. 52, A).
Long worms can be made by uniting two pieces, each more than half
the length of a worm, or by uniting three pieces, as shown in Fig. 52, C.
Short worms can be formed by cutting a middle piece from a worm,
and uniting the anterior and posterior pieces (Fig. 53, D). Joest
found that when a short worm is made in this way, so that no repro-
ductive region is present, the new worm does not produce new repro-
ductive organs. It is conceivable that new reproductive organs might

Fig. 52. — After Joest. A. Union of two pieces oi Allolobophora terrestris in normal position.
Twenty-two months after operation. B. Union of two pieces Lumbricus rubellus. Pieces
turned i8o° with respect to each other. C. Union of three pieces oi A. terrestris to make a
"long worm." D. Union of two worms (by anterior ends) from each of which eight an-
terior segments had been removed. After three months. Regenerating two new heads.
E. A small piece oi Lumbricus rubellus grafted upon Allolobophora terrestris. Former re-
generated an.anterior end.

have been produced either in the old segments, or by the formation
of a new reproductive region between the two united pieces, but
neither process takes place. In the long worms two sets of repro-
ductive organs, etc., are present. This sort of union is, however,
less permanent, as the worms often pull apart.

Joest also united two posterior ends by their anterior surfaces.
In many cases no regeneration took place, and, in the absence of a
head, the combination is destined to die, although it may remain
alive, without food, for several months. When two very long pieces

1/2 RE GENERA TION

were united by their anterior ends, — only eight segments being
removed from each worm, — although perfect union took place at
first, later one or two new heads generally developed at the region of
union (Fig. 52, D). When only one head developed it did not seem
to belong to one of the components rather than to the other, and
originated in the new tissue that appeared between the two pieces.
These experiments, in which the anterior surfaces of two pieces are
united, show also that the new head arises between the two pieces
most often, if not exclusively, when the union is in the anterior ends
of the worms. This corresponds with what is now known in regard
to the development of new heads by isolated pieces, since there is less
tendency to produce a head the farther posteriorly the cut has been
made. At more posterior levels a tail and not a head is often regen-
erated, as has been stated, on the anterior cut-surface. This forma-
tion of a heteromorphic tail seems to have been suppressed in the
pieces united in this region, except in one case,^ in which it appears,
from Joest's account, that a tail probably regenerated, although Joest
speaks of it as a head.

It is more difficult to unite two anterior ends by their posterior
cut-surfaces, not because the surfaces refuse to unite, but because the
two pieces crawl away from each other and pull apart. In one case,
however, union of this sort was brought about.

In all the combinations that have been so far described, the
dorsal and ventral surfaces of both components were kept in the
same direction, so that the ventral nerve-cord of one piece came in
contact and fused with the nerve-cord in the other piece. Sometimes
it may happen that the components are not quite in the same position,
and the end of one nerve-cord may fail to abut against the other one.
In such cases Joest thinks that regeneration is more apt to take place
in the region of union, and he has carried out a series of experiments
in which the pieces were intentionally united, so that they are not in
corresponding positions. It is found that if one piece is turned so
that the nervous system lies 90 degrees, or even 180 degrees (Fig. 52,
B), from that of the other piece, the union takes place just as when
the pieces have the same orientation, except that the ends of the
nerve-cords do not unite. Subsequent regeneration from one or from
both components generally takes place in the region of union.

It is more difficult to unite pieces of different species of worms,
yet Joest has succeeded also in making combinations of this sort.
One union between the anterior end of LumbriciLS nibelliLS and the
posterior end of AllolobopJiora terresti'is was permanent, and the new
worm reacted as a single individual, and lived for eight months.
Each piece retained its specific characters, and showed no influence

^ See Joest's Fig. 14.

GRAFTING AND REGENERATION

173

of the other component. By means of a similar experiment we have
a way of finding out if one component can influence regeneration
taking place from the other piece. Although Joest made only a few
observations of this sort, the results show that no such influence is
manifested.

By means of grafting it is possible to keep ahve small pieces of a
worm that would otherwise perish. For instance, pieces of a worm

^C.^"^-""'

Fig. 53. — After Joest. A. Small piece of AUolobophora terrestris from posterior end grafted upon
anterior end of another individual. Oral end free. Four weeks after grafting eight new
segments formed. B, Same fourteen days later. A new part of thirty-seven segments had
appeared at end of former eight segments. C. A piece of the body wall of AUolobophora
terrestris grafted upon the cut-end (anterior) of Lumbricus rubellus. Two months later, as
shown in figure, a head had grown on major component. D. Anterior and posterior ends of
A. terrestris united to make a " short worm." E. A piece of body wall of A. cya7iea grafted
on side of body of Lumbricus rubellus. F. Piece of /.. rubellus grafted on side of body of
another individual to produce a double-tailed worm.

containing only three segments are not capable of independent exist-
ence, except for a short time, and even pieces of from four to eight
segments die in most cases. It is not possible to unite small pieces
of this size directly upon larger pieces, since they will die, ordi-
narily, as a result of the operation, but larger pieces can be united
and then after union has been effected, one of them may be cut off
near the place of union. The same result is sometimes brought

174

RE GENERA TION

about accidentally by the worms themselves pulling apart and leav-
ing a small piece of one component attached to the other. Joest
found that in several cases these small, attached pieces regenerated.
In one case, after two long pieces had pulled apart, a small piece, left
by one of the two, regenerated a single new segment with a mouth at
its end. In another case, after one of the components had been cut
off, leaving two segments attached, a new part of seven segments
regenerated.^ Especially interesting is the case in which two indi-
viduals {A. terrestris) had been united to form a long worm. The
anterior component extended to within two centimetres of the anus ;
the posterior piece had had the first four segments removed. Three
days later the anterior piece was cut off three segments in front of
the region of union. About a month later a small part of eight seg-
ments had regenerated from the cut-end (Fig. 53, A). Fifteen days
later another new part of thirty-seven segments developed at the end
of the first new part (Fig. 53, B\ Joest speaks of the first eight seg-
ments as a head, and the second simply as a regenerative product.
There can be little doubt, I think, that both parts represent a hetero-
morphic tail. The region from which the regeneration took place
would make this interpretation highly probable, and Joest's figures
also indicate that the structure is a tail. The result is very interest-
ing, if my interpretation is correct, as it shows that the major com-
ponent did not influence the kind of regeneration, although the
surface of regeneration was separated by only three tail-segments
from the anterior end of the major component.

In another experiment a long animal was made by uniting Ltun-
briacs inibe litis (whose posterior third had been cut off) and Allolo-
bophora terrestris (whose first six segments had been cut off). Four
days later the two components had torn apart, but a small piece of
the anterior worm remained attached to the anterior end of the pos-
terior component. The small piece consisted of the dorsal part of
two and a half segments without any ventral part, so that the anterior
end of the posterior component was partially exposed. The small
piece of lumbricus was much fighter in color, and this difference
made it easy to distinguish between the two. In less than a month
the small transplanted piece had replaced its missing ventral part, so
that the entire anterior surface of the larger component was covered
over. The small piece, in addition to regenerating its ventral part
of four segments, had also begun to make new segments. After a
month and a half six new segments were present (Fig. 52, E), with
a mouth at the anterior end.'-^ Even after ten months the color of

1 It is not certain whether this is a head or a tail.

2 Joest states that this new part is a head, as shown by the presence of food matter in the
digestive tract of the posterior piece.

GRAFTING AND REGENERATION ' 1/5

the small piece was strikingly different from that of the major com-
ponent. The new head had the typical red-brown color of L. nibellus,
that forms a strong contrast to the grayish blue color of A. terrestris}
The result shows that the color of the regenerated part has not been
influenced by that of the posterior component, and this is all the more
interesting, as Joest points out, because the small piece that was left
after the worms pulled apart was too small to have lived independently
for any length of time, and must have derived all its nourishment
from the larger piece.

In other experiments pieces of one species were cut from the side
of the body and grafted upon the cut-surface of the anterior end (or
elsewhere) of another species. In one of these experiments a piece
from the side of A. terrestris, that extended over five or six segments,
was sewed upon the anterior cut-surface of L. riibelhis (from which
the anterior five segments had been removed). In about a month new
tissue appeared on the ventral side between the two pieces, and a
little later a complete head developed, whose dorsal side was made up
of the small piece (Fig. 53, C^. The grafted piece was dark, and the
new, regenerated part light in color and continuous with the brown
color of L. rubelhts, from which the new part had arisen. It is
important to notice that the four segments of the graft are completed
by four segments of the new part. After three months the new part
had assumed the red-brown color of L. riibelhis. The color of the
grafted piece had not changed. We see in this case that even the
presence of a part of another worm in a regenerating region does not
have any influence, at least so far as color is concerned, on the new
part, even though its segments supplement some of those of the
new part. The new tissue seems to have come entirely from the
major component, and to have carried over the color characteristics
of the old part.

It has been shown that when two posterior pieces are united by
their anterior ends the combination must sooner or later die, since it
has no way of procuring food. The question arises : What will hap-
pen if one of the two components is cut in two near the place of
union .'' Will a head then develop on the exposed aboral surface,
because a head is needed to adapt the worm to its surroundings, or
possibly, if it occurred, because the major component exerts some
sort of influence on the short, attached piece, as happens in hydra
and in tubularia ? Both Joest and I carried out an experiment
of this sort, and found that a tail and not a head regenerated, as
shown in Fig. 16, F. The experiment is, however, insufficient to
answer the question, since the region in which the second cut was
made is a region from which only a tail (and not a head) arises, even

^ The prostomium was misshapen, so that its specific character could not be made out.

I ^6 RE GENERA TION

when the oral end of a piece is exposed. In order to avoid this diffi-
culty I carried out another experiment. Two worms had the first
five or six segments cut off and the exposed anterior ends of the
worms united, as shown in Fig. i6, D. Then one of the components
was cut off, leaving three or four segments attached to the anterior end
of the other component. Although regeneration began in one case, it
did not go far enough to show what sort of a structure had developed,
but Hazen, who took up the same experiment, succeeded in one case
in obtaining a definite result. At the exposed aboral end of the
small piece a head and not a tail developed (Fig. i6, K). At first
sight it may appear that the result shows the influence of the major
component on the small piece, causing it to produce a head and not a
tail at its aboral end, but I think that this conclusion would be
erroneous, because it seems much more probable that we have here a
case of heteromorphosis, similar to that in Planaria lugubris, and that
the result depends entirely on the action of the smaller component.
It is hardly possible to demonstrate that this is the correct interpre-
tation, since if a small piece of this size is isolated it dies before it
regenerates. The result is paralleled, however, by the regeneration
of a tail at the anterior surface of a posterior piece.

The process of grafting has long been practised with plants, but
the experiments were made more for practical purposes than to study
the theoretical problems involved. Vochting has, however, carried out
a large number of well-planned experiments. He finds that a stem
can be grafted upon a root, and a root upon a stem, a leaf upon
a stem or upon a root. Even an entire plant can be grafted upon
another. The results show, however, in general, that, whatever the
new position may be, the graft retains its morphological characters — •
a shoot remains a shoot, a root is always a root, and a leaf a leaf.
Vochting concludes that there is in the plant no principle or organi-
zation that conditions an unchangeable arrangement of the main
organs. " The inherited order of the parts, acquired apparently on
physiological grounds, may be altered by the experimentator ; it is
possible for him to change the position of the building blocks within a
wide range without endangering the life of the whole." "It is essen-
tial, however, for the success of the experiment that the grafted
parts, or tissues, retain their normal orientation. If this condition is
not fulfilled there may take place, it is true, a union of the parts, but
sooner or later disturbances set in." Vochting transplanted pieces in
abnormal positions, sometimes reversing the long axis of the grafted
piece, sometimes the radial axes, and sometimes both together. In
some cases this led to the formation of swellings that interfered with
the nourishment but carried with it no further consequences. In
other cases the changes went so far that the vital processes were inter-

GRAFTING AND REGENERATION lyy

fered with. At times an incomplete union took place between the
parts ; at others, even though the first union was perfect, death later
ensued.

On the other hand, when similar pieces were grafted with their
original orientation, a perfect union took place and the piece became
a part of the stock. The results establish, Vochting claims, that
every part and every portion of a part has a polar orientation in one
direction, and furthermore, in a body having a radially symmetrical
form, there is also a radial polarization; that is, the inner side of
each part is different from the outer side of the same surface, even
though no such difference is apparent to us. The properties of the
tissue-complex rest, in the last analysis, on that of the cells ; the
properties of the whole being only the sum total of the properties of
its elements, so that we may say that every living cell of the root
is polarized, not only longitudinally, but also radially ; each has a
different apical and root pole, a different anterior and posterior pole,
and also right and left polar relations. These results, deduced from
the experiments in grafting, lead Vochting to formulate the follow-
ing rule : " Like poles repel, unlike poles attract." This rule is the
same as the law of the magnet. In fact, Vochting states that the
root and the stem relations show a remarkable resemblance, despite
many differences, to a magnet. If the magnet is broken into pieces
it may be reunited by bringing unlike poles together, but not by unit-
ing hke poles ; the same statement holds for the root and the stem.

Exception may be taken, I beheve, to parts of Vochting's conclu-
sions, especially in the light of the recent experiments in grafting in
animals. It is by no means to be granted without further demonstra-
tion that the properties of the whole organism are only the sum-
total of the action of the individual cells. If, as seems to be the case,
the cells are organically united into a whole, the properties of this
whole may be very different from the sum of the properties of the
individual cells, just as the properties of sugar are entirely different
from the sum of the properties of carbon, hydrogen, and oxygen.

The statement that hke poles repel and unlike poles attract is, I
believe, a conclusion that goes beyond the evidence. The experi-
ments show that like poles do often unite in plants, and this has
been abundantly shown to be the case in the lower animals, and even
in forms as high as the earthworm and the tadpole. Even if when like
poles are united subsequent changes take place, that in some cases,
although apparently not in animals, lead to the death of the graft, it
by no means follows that this has anything to do with the attraction
or repulsion of the parts, but rather with some difficulty in obtaining
food, or with the transportation of substances through the plant. In
the lower animals we have seen that when like poles are united

1/8 JiE GENERA TION

there is sometimes a stronger tendency to produce new organs at or
near the place of union than when unhke poles are united, but it
would be going too far, I think, to state that this is due to repulsion
of the parts, especially in the sense in which the like poles of a
magnet repel each other. It seems to be due rather to the two parts
failing to unite into a whole organization, each retaining the same
structural basis that it had before grafting, but this is a very different
principle from that of an attraction and repulsion of the parts, and
the question of the union of the parts appears also to be a different
question from that of the organization of the parts themselves.

In the mammals, and in general in all forms in which there is a
dependence of the parts on each other, it is impossible to carry out
grafting-experiments on the same scale as those described in the pre-
ceding pages. The principal difficulties are to make the parts unite,
and to supply nourishment and oxygen to the graft. Owing to the
dependence of the parts of the body on each other for a constant sup-
ply of oxygen and food derived from the blood, as well as for the
removal of the waste products, the parts cannot remain alive, or even
in good condition, while new connections are being established. For
this reason, as well as for others, it would not be possible, for instance,
to graft the arm of a man upon another man. The tissue may have the
power of uniting even in this case, as is seen when the bone is broken
and subsequently reunited, but the difficulty would be in supplying the
grafted arm with nourishment, etc., during the long time required for
the union to take place. Smaller parts of the body may be success-
fully grafted, and there are several recorded cases in which parts of a
finger, or of the nose, are said to have been cut off and to have reunited
after being quickly put back in place. Pieces of human skin may be
grafted without great difficulty upon an exposed surface, and it has
been said that small pieces succeed better than larger ones, owing,
most probably, to their being able to absorb sufficient oxygen, etc., and
keep alive until new blood vessels have grown into the grafted piece.

There are a number of old and curious observations in regard ta
cases of grafting in higher animals. It was found by Hunter and by
Duhamel that the spur of a young cock could be grafted upon the
comb, when it continued to grow to its normal size. The comb, being
richly supplied with blood, furnished the nourishment for the growth
of the spur. Fischer transplanted the leg of an embryo bird to the
comb of a cock, or of a hen, where it grew at first, but after some
months degenerated. Zahn transplanted the foetal femur to the kid-
ney, where it grew for a time, but later degenerated. Bert transplanted
the tail of a white rat to the body of Miis decinnanns, where it continued
alive ; but he found that the tail of the field mouse, Mus sylvatictis,
did not grow so well on the rat, and the tail of a rat would not unite

GRAFTING AND REGENERATION 1 79

at all with the body of a dog or of a cat. Bert bent over the tip of
the tail of a rat, and grafted the distal end into the skin of the back
of the same animal. After the tip had established union with the
surrounding tissues, the tail was cut off at its base. The grafted tail
remained alive, but did not regenerate at its free end.

There are several cases described by pathologists in which the skin
of one mammal has been transplanted to another. The transplanta-
tion of the skin of the negro upon a white man has been brought
about, but the evidence as to what subsequently happened is contradic-
tory. It appears that while in many instances the transplanted skin
has remained alive for a time, yet later it was thrown off by new skin
growing under it and replacing it.

Leo Loeb has described a curious instance of grafting pieces of
skin of different colors in the guinea pig. If a piece of black skin
from the ear of a guinea pig is grafted upon the white ear of another
animal, it unites and continues to live, but if a piece of white skin is
grafted upon a black ear, it is slowly thrown off and replaced by
new black skin that has regenerated around the edge of the graft from
the tissue of the black ear.

In the literature of pathology there are many cases described in
which parts of the body of mammals, particularly internal organs,
have been grafted in unusual regions. The results have not
always been the same, for while in some cases it appears that the
operation has succeeded, in others the grafted part is subsequently
absorbed, and in still other cases the graft may be at first partly
absorbed and later begin to grow again. It appears that the estab-
lishment of an adequate blood supply is the most important element
of 'success. Ribbert, who has made an extensive and successful series
of experiments, has stated that the grafting takes place better when
small pieces of an organ are used, since these can draw immediately on
the surrounding regions for their oxygen, etc., while larger pieces are
found to break down in the interior, owing to the fact that this part is
too far removed from the supply of oxygen, food, etc. After the grafted
piece has established a blood supply of its own, it may continue to
grow. Ribbert transplanted small pieces of different tissues of the
rabbit and guinea pig in, and upon the surface of, the lymph glands
of the same or of another individual. The lymph gland was chosen
because small pieces of tissue can be afterwards easily detected. A
small piece of tissue about as large as a pin's head is cut off from
whatever tissue is to be grafted, and as quickly as possible placed in
a small cleft made in the lymph gland. After several days, weeks, or
months, the gland is removed and the graft examined by means of
serial sections.

Most of the experiments were made with " epithehal organs," and

l80 REGENERATION

according to Ribbert, if pieces of such organs are composed of
epithelium only, they cannot be successfully grafted. For instance,
the cells of the cornea can be readily separated from their under-
lying connective tissue, and can be kept alive in the lymph gland,
but the cells diminish in number, show retrogressive metamorphosis
in the direction of atrophy, and are finally absorbed. It seems that
epithelium by itself cannot extract nourishment from its surround-
ings. Nothing is easier, however, than to transplant epithelium,
if its connective tissue is present. The connective tissue furnishes
so good a basis for nourishment that the epithelium not only lives,
but may continue to proliferate. Ribbert finds that pieces of skin
roll in after their removal. Then a process of growth takes place
corresponding to that which follows a wound in the skin. The
surface is closed and a small cyst is formed with a central cavity.
The epithelium undergoes no changes during the first days or weeks.
It remains stratified and shows an active process of cornification and
desquamation. Similar results were obtained when pieces of the
conjunctiva were transplanted, either under the skin in the anterior
chamber of the eye, or in the lymph gland.

A small piece of the lining epithelium of the trachea with its
underlying cartilage was also placed in the lymph gland. The epi-
thelium grew, and covered over the wounded surface, forming over it
only a single layer of cells. The old many-layered epithelium also
became arranged in a single layer.

The wax glands, found in the inguinal folds of the rabbit, were
also transplanted. The gland is composed of closed, compressed
alveoli, surrounded by large, polygonal, clear cells. Small pieces of
a gland, transplanted upon the lymph gland, underwent character-
istic changes. The cells of the alveoli were changed into a stratified
epithelium ; and broken-down cells, and wax, were found in the interior
of the alveoli. The central alveoli underwent the greatest change,
while some of the peripheral alveoli that were in contact with the
lymph gland remained unchanged. It seems that the difference is due
to the better nourishment of the outer alveoli. After several months
the alveoli swell up and degenerate. Transplanted pieces of the
salivary glands also change, the alveoli producing a lining epithelium
like that of the transplanted wax gland. The same change was ob-
served in a piece of a salivary gland transplanted in the body cavity.

Small pieces of the liver were cut off and placed in the lymph
gland. They did not always grow as well as did the preceding
tissues, but often went to pieces. If they healed, the liver tissue
often remained unchanged for several weeks. After two or three
weeks connective tissue appeared between the peripheral liver cells,
separating the cells from each other. The cells grew smaller, their

GRAFTING AND REGENERATION l8l

protoplasm disappeared, and they at last disintegrated. Pieces of
the gall duct behaved differently. They sometimes showed active
growth, leading to the development of numerous branched canals.^

Pieces of the kidney, when transplanted, suffered a great change,
and were subsequently absorbed. Transplanted pieces of a testis
also changed. After six days, Sertoli's cells and the spermatozoa
disappeared. A kind of indifferent cell remained, characterized by
clear protoplasm and by a large nucleus. After seventeen days
further changes were observed, and later the pieces were com-
pletely absorbed. Pieces of the ovary rapidly disappeared, leaving
only a mass of interstitial connective tissue.

The connective tissue underwent, in all the transplanted pieces,
characteristic changes. The tissue became less dense, the protoplasm
and nucleus of each cell enlarged. The cells multiphed, but only
very slowly. These changes took place after one or two days. After
a month or two the cells became more compact, their processes more
numerous, and the nucleus small and long. Later degeneration set in.

Small pieces of bone from the caudal vertebrae were also trans-
planted, care being taken that each piece should contain some of the
periosteum and marrow. The bone tissue goes to pieces, but the
periosteum and marrow develop further. New bone is formed from
the cells of the marrow as well as from those of the periosteum.
Finally the entire piece, both its old and its new parts, is absorbed.
Pieces of muscles were also absorbed.

These experiments of Ribbert show that transplanted pieces of
tissue do not increase in size by growth, but undergo changes
which he describes as a return to an earlier condition of develop-
ment. The abnormal condition of their existence seems to be the
cause of this change. The transformation may be due to a change
of nourishment, or to a loss of nerve influence, or to lessened func-
tional activity.

These results have a direct bearing on the problem of regenera-
tion. They show that all kinds of tissue may continue to live, and
the cells multiply in different parts of the body, but there seems to
be nothing in these cases comparable to a regeneration of the entire
organ. In the new situation the cells often assume an entirely new
arrangement. After a period of activity, a process of degeneration
commences, and the piece atrophies. Ribbert thinks that the atrophy
is due to lack of nourishment, yet it is not clear how this could be
the case, since for the first few weeks after transplantation there is
an active growth, and in some cases, as in that of the bone, there is a
formation of new, characteristic tissue. It may be that the trans-

^ It is known that the process of regeneration of the liver takes place especially from
the gall ducts.

1 8 2 REGENERA TION

planted tissues can no longer manufacture the substances necessary
for their specific growth, and after the materials that have been
brought along with them have been used up, the growth of the piece
is stopped and its subsequent degeneration begins. It would be
interesting to see if pieces transplanted to the same kind of organ
as that to which they belong will become permanently incorporated
in their new position.

The grafting-experiments that have been described in the preced-
ing pages were carried out with pieces of adult organisms. Some-
what different conditions are present when parts of the developing
&^^ or embryo are united, inasmuch as a process has been started
in them that may go on independently, to a certain extent, of the union
of the pieces. Born has carried out a large number of experiments
in grafting parts of tadpoles of the same species, and also of differ-
ent species. The union is brought about at the time when the tad-
poles are about to leave the jelly membranes. The cut-surfaces are
brought in contact and the pieces pushed together and held in place
for an hour or two by means of .small silver blocks or pieces of wire.
The pieces readily stick together, and the union is a permanent one.
Before describing Born's results, it may be well to consider the power
of regeneration of young tadpoles. If the tail is cut off a new one is
regenerated by the tadpole, but all parts of the body do not have
this same power. Schaper found that if a part of the brain, or even
the entire brain, is removed, no regeneration takes place. I have
found that if the region where the heart is about to develop is cut
out from a young embryo, a new heart is not formed. ^ If a tadpole
is cut in two across the middle of the body, neither piece regenerates
the missing half. Byrnes has found, however, that if the region from
which the posterior limb develops is cut out a new limb regenerates.
In older tadpoles, Spallanzani found that if the hind limb is cut off
it will regenerate, and Barfurth has more recently confirmed this
result. The end of the tail that has been cut off from a young tad-
pole, before the tail has begun to differentiate, may continue alive for
several days. It grows larger and flatter, and the V-shaped meso-
blastic somites are formed. A slight regeneration even starts at its
anterior end, as first observed by Vulpian and later by Born. The
notochord and nerve-cord may send new tissue into the new part, and
even some of the muscle cells may extend into this part, but the piece
dies before regeneration goes any further. If, however, the tail is
grafted in a reverse direction on the body of another tadpole, the
regeneration may go further and produce a tail-like structure, as
Harrison discovered and as I have also seen.

1 In one case I observed rhythmic pulsations in a vessel on one side of the neck, in the
region above the pharynx.

GRAFTING AND REGENERATION 1 83

Born found that if the anterior half of one tadpole was united to the
posterior half of the same or of another tadpole a single individual was
formed which he kept alive in several cases until the time of metamor-
phosis. If the head of a tadpole is cut off and grafted upon the side
of the body of another tadpole, the head will remain alive and con-
tinue to develop in its new position, and, if well nourished by means
of the connecting blood vessels that develop, it may grow to be as
large as the head of the tadpole to which it is attached. Similarly, if
the tail of one tadpole is grafted upon the side of the body of another
tadpole, it also continues to develop, and at the time of metamorphosis,
when the normal tail is absorbed, the additional or misplaced tail also
shows signs of breaking down. Even the posterior half of one tad-
pole, if grafted to the ventral side of another, may continue to develop,
producing legs, etc.

Born succeeded in uniting tadpoles of different species in several
different ways. They were united by their heads or by their ventral
surfaces, or longer and shorter tadpoles made by using pieces longer
or shorter than a half. In all of these cases there is no regeneration,
at the place of union, and the internal organ, the digestive tract, ner-
vous system, and blood vessels unite when brought into contact-
When pieces are united end to end, like organs unite to like, the
nerve-cord with the nerve-cord, digestive tract with digestive tract,,
segmental duct with segmental duct, coelom with coelom, and although
less often, the notochords sometimes join together. The lack of
union of the ends of the notochord is explained by its frequent par-
tial displacement at the cut-end, for when the cut is made the noto-
chord, being tougher than the other structures, is often dragged out of
place in one or in both pieces, so that the ends do not meet when the
pieces are put together. When like organs are brought together the
substance of one unites directly with the substance of the other, and
if the organ "is a hollow one, as is the digestive tract or the nerve-cord,
their cavities also become continuous. There is also, Born states,
some evidence to show that if similar organs are not brought exactly
in contact their ends find each other and unite, and if they do not at
first meet s'quarely they may do so later. When the ends of unlike
organs are brought in contact, as, for instance, the nerve-cord and
notochord, they do not unite, but connective tissue develops between
them. The union of like parts, Born suggests, may be due to some
sort of cytotropism, the outcome of a mutual attraction between simi-
lar cells like that which Roux has observed between the isolated
cells of the segmented o.^^ of the frog. Born thinks that the first
rapid union of the pieces is due to the attraction of the ectoderm of
one component for that .of the other.

Born succeeded also in uniting pieces of the tadpoles of different

1 84

REGENERA TION

species, even when they belonged to different genera. It is found,
however, that some of these combinations can be more easily made
than others, but it is not clear whether the difference depends upon
differences in the sizes of the pieces, or the rate of growth of the ecto-

FlG. 54. — A. After Harrison. Union of two tadpoles by posterior ends. Two days after opera-
tion. The line to the left of plane of union indicates where the two were cut apart. B. Tail
of right-hand tadpole in A. Five days after cutting apart. C. Same. Nine days after cut-
ting apart. D. Same. Ninety-five days after cutting apart. E. After Born. Combination
of Rana esculenta (anterior) and Rana arvalis (posterior) . Thirteen days after the operation.

derm over the cut-surfaces, or to a deeper-lying lack of affinity between
the tissues. A combination of Rana escidenta (anterior) with Bombi-
nator ig7ieiis (posterior) was made. The combination lived for ten
days, and then showing pathological changes, it was killed. Another
combination is shown in Fig. 54, E, in which the anterior part of Rana

GRAFTING AND REGENERATION 1 85

esailenta was united to the posterior part of Rana arvalis} The blood
of the posterior component was driven through the vessels by the
action of the heart of the anterior component. The animal lived
for seventeen days.

In all these combinations between different species, each develop-
ing part retains its specific characters, and, although in several cases
one part received its nourishment from the other through the com-
mon circulation, yet no influence of one component on the other
could be observed.

Harrison has succeeded in keeping an individual made up of two
species, Rana virescens and Rana palnstris, for a much longer time, —
until, in fact, the transformation of a tadpole into a frog had taken
place. Each half retained the characteristic features of the species
to which it belongs.

The absence of regeneration after the union of the pieces may
be attributed, in several cases, to the absence of this power in the
region through which the cut has been made ; but in other experiments
this cannot be the explanation, since the power to regenerate can be
shown to exist in the part. This is the case in an experiment car-
ried out by Harrison and repeated later by myself. If the tips of
the tail of two tadpoles are cut off and interchanged (Fig. 55, A, B),
a perfect union takes place between the two parts, and a single tail
develops. Each of the cut-surfaces has the power to regenerate,
but the union of the parts has suppressed the regeneration. If,
however, like parts are not brought in contact, regeneration may take
place in the region of union (Fig. 55, D).

Both Harrison and I have made a number of experiments, in
which the end of the tail of a tadpole of one species was inter-
changed with a similar part of another species. It is found that as
the new tail grows larger the ectoderm of the grafted piece is car-
ried out to the tip of the new tail, as shown in Fig. 55, C, and does
not cover all the inner tissues that belong to the same piece, the
rest of the tail being covered by the ectoderm of the major com-
ponent. If the tip of the tail is now cut off, as indicated by the line
b-b in Fig. 55, C, there are left at the exposed edge two kinds of ecto-
derm, and from the cut-edge a new tail regenerates, covered in part
by each of the two kinds of ectoderm. I made this experiment in
order to see if the new ectoderm would show any influence of its
dual origin, especially along the line where the two kinds are in con-
tact, but no influence could be detected. In another series of experi-
ments the grafted tail was cut off, as shown in Fig. 55, A, or in Fig.
55, B, or in Fig. 55, C, a-a. In these cases there is left exposed, at
the cut-edge, the internal tissues of the two species. The new tail

1 The figure was drawn fifteen days after union.

1 86 REGENERATION

that regenerates is composed in part of material derived from one
species and in part from that of the other, but each tissue remains
true to its kind, and there is found no evidence of an influence of one
on the other (Fig. 55, E). These experiments show that even when
the two kinds of tissue regenerate side by side, and unite to form a
single morphological organ, there is no influence of a specific kind
of one tissue on the other.

B

Fjg. 55. — A. Rana sy/vafica- with grafted tail oi Rana palustris. Line a-a indicates where tail
was cut off. D. Ra7ia palustris with grafted tail of Rana sylvatica. Line a-a indicates where
tail was cut off. C. Older stage of a graft like B. Lines' indicating two possible operations.
D. Another individual with two tails, one composed of both components. E. Later stage of
last, when tail was cut off at level a-a.

Another series of experiments in grafting, similar to one of those
made by Joest and myself on the earthworm, has been made by Har-
rison on the tadpole. I have also later made similar experiments.
Two tadpoles are united by their posterior ends, as shown in Fig. 54, A,
and a day or two after union one of the tails is cut off near the line
of union. There is thus left attached to the end of the tail of one
tadpole a part of the tail of the other united in a reverse direction, so
that the exposed cut-end is the anterior end of the small piece.
There grows out from this cut-end a structure that resembles a tail
(Fig. 54, B, C, D). It contains a continuation of the notochord and
nerve-cord, that taper in a characteristic way to the end of the new
structure. The tail is flat and has a central band of muscle tissue, and

GRAFTING AND REGENERATION 1 8/

a dorsal and ventral fin. The muscles of the normal tail have a
characteristic V-shaped arrangement with the apex of the V's turned
forward, but unfortunately in the new tail the muscles are so
irregular that it is impossible to make out their arrangement
(Fig. 54, D). If the new part is in reality a tail, the V's ought
to stand in the same way as do those in the major component, and
opposed to the V's on the part from which the new material arises.
If the new structure is not a tail at all, but a new growth, or even a
suppressed trunk, then the V's should stand as in the small part itself.
It has not been possible as yet to obtain a decisive case. Harrison
obtained one case in which the arrangement of the muscles in the
new part seemed to be more as it should appear if the new part is
a heteromorphic tail (Fig. 54, D). Even if this could be shown to be
the case, it may be that under the conditions of the experiment the
arrangement of the muscles is determined by the use of the tail,
although this does not seem very probable. Harrison, after a careful
analysis of the question, left it undecided, but seemed more inchned
to the view that the result is due to the development of something
new rather than a heteromorphic growth. On the contrary I am
strongly inclined to believe that the latter is the true explanation. In
another way I have been able to bring about the development of the
same structure. A small triangular piece is cut from the upper part
of the tail, as indicated in Fig. 56, A, one point of the triangle passing
through the notochord, or even through the aorta. If the cut-surfaces
are kept apart for a few hours, until the exposed end has been covered
over by ectoderm, they may not unite afterward, and two exposed
surfaces are left, — one at the distal end of the base of the tail, and the
other at the proximal end of the outer part of the tail. The latter
surface corresponds to that in the grafting-experiment. Regenera-
tion may take place from the two surfaces ; both new parts seem to
be exactly alike, and both resemble a regenerated tail. The one from
the proximal surface of the outer part of the tail contains a notochord,
nerve-cord, connective tissue, pigment cells, and muscle tissue (Fig. 56,
B\ The arrangement of the muscle fibres is generally very irregular,
and the characteristic V-shaped arrangement cannot be detected.

In only a few cases have attempts been made to unite two eggs
or two very early embryos, although there are a few casual observa-
tions ^ in which such a fusion has been observed. The problems that
arise in connection with the union of two eggs are full of interest.
Each Q,gg has the power of producing an embryo of normal size. If
two eggs are united into one, will a single giant organism result, or
two organisms .'' If the former, we must suppose that a new organi-
zation is formed of double size. Whether an upper limit of organiza-

1 Metschnikoff ('86), Herbst ('92).

1 8 8 REG EN ERA TION

tion exists can only be determined by such an experiment. If two
fused organisms result from the fusion of two eggs, it would show
the structure of the Qg'g is of such a kind that two organizations can-
not readjust themselves into a single one of double size. Moreover, it
is important to discover whether any difference exists as to the stage
of development at which the union is brought about, for it is conceiv-
able that while a rearrangement is possible at one stage, it might
not be at another.

B

Fig. 56. — A. Tadpole to show where the V-shaped piece is cut from the tail. B. Later stage of
same with a new tail-like outgrowth from the anterior end of tail.

It has been shown that two blastulse of the sea-urchin can be
united to form a single embryo. I found ('95) that occasionally two
blastulae stick together and fuse, so that a single sphere of double
size is formed. As a rule two gastrulae and two more or less com-
plete embryos develop from each double blastula, but in a few cases
I found that a single embryo may be formed, that shows, however,
traces of its double origin. Driesch has more recently (1900) suc-
ceeded ^ in bringing about more readily a union of two segmenting

^ Eggs without membranes were placed in sea water without calcium, to which a few
drops of sodium hydroxide have been added.

GRAFTING AND REGENERATION 1 89

eggs or blastulse, and obtained perfect single individuals from two
fused blastulae. He finds that if the fusion takes place at an early-
stage the resulting embryo is less likely to show its double origin
than when older blastula stages are united. Zur Strassen has also
observed giant embryos of ascaris that arise by a fusion of two eggs.
Loeb has found that the eggs of chaetopterus, which can be made to
develop parthenogenetically in certain salt solutions, often stick to-
gether and produce giant embryos.

CHAPTER X

THE ORIGIN OF NEW CELLS AND TISSUES

There are many difficulties in the way of determining the origin
of the cells that make up the new part. The only means at present
at our command for studying their source is by serial sections of a
number of different stages taken at intervals from different animals.
Since there may be differences between the processes in different in-
dividuals, and since we can only piece together the information gained
from successive stages, much uncertainty exists in regard to the
changes that take place during regeneration, even in some of those
forms that have been examined over and over again. Were it possi-
ble actually to follow out the movements of the living cells in one and
the same animal, the problem would offer fewer difficulties, but this
cannot be done. It will be more profitable to consider first the bet-
ter-known and simpler processes, and afterward those that are less
well-known.

The regeneration of the head and tail of lumbriculus and of cer-
tain naids is a comparatively simple process, and has been studied by
several investigators, whose results agree, at least in regard to the most
essential features. Semper {'76) described the origin of the new
organs in the formation of new individuals by budding in nais. He
found that the new brain and nerve-cord develop from the ectoderm,
the new mesoderm also from ectoderm, and the new digestive tract from
the old one, except the pharynx, which arises by the fusion of two meso-
dermal " gill-slits." Biilow ('83) studied the regeneration of the tail of
lumbriculus. He found the ventral cord in the new part arising from a
paired ectodermal thickening, the mesoderm arising from a prolifera-
tion of cells. These cells are invaginated in the region between ecto-
derm and endoderm — the in-turning of the proctodaeum being looked
upon as an endodermal invagination.^ The more recent work of Ran-
dolph, Rievel, Michel, Hasse, Hepke, and von Wagner on the same or
related forms has served to point out certain errors in the earlier work
of Semper and Biilow, and has added some new and important facts,
especially in connection with the origin of the mesoderm in the new
part. "Without attempting to give a detailed account of these results,

^ The usual interpretation at present is to regard the proctodseal ingrowth as ectodermal.

190

THE ORIGIN OF NEW CELLS AND TLSSUES

191

I shall describe the principal changes that have been found to take
place. When the anterior end of lumbriculus or of tubifex is cut off,
the cut-surface very quickly closes, as a result of the contraction of
the body wall. According to some investigators, the circular muscles
are chiefly concerned in the closing, but according to others the lon-
gitudinal muscles bring about the result. The cut-end of the diges-

FlG. 57. — After Hasse. Regeneration of head of Tubifex rivulorum. A. Sagittal section of an-
terior end. Six days after cutting in two. B. Eleven days after cutting in two. C. Cross-
section through new part. Five days after operation. D. Fourteen days after operation.
E. Si.xteen days after operation.

five tract is pulled a little inward, and its end also closes (Fig. 57, A).
For a day or two no important changes can be observed to take
place, but new ectoderm soon appears over the cut-surface. This ecto-
derm arises in all cases from the old ectoderm, and as it increases in
amount the old ectoderm is pushed back from over the cut-end, leav-
ing a layer composed of a single row of cells over the end. Since
nuclei in process of division are rarely present before these initial

192 RE GENERA TION

processes begin, it is probable that the changes are due, in large part,
to an out-wandering of ectodermal cells, or, what amounts to the same
thing, to the leaving behind of cells as the old ectoderm withdraws from
the cut-end. In the new ectoderm over the end, an active process of
proliferation takes place (Fig. 57, B\ that leads to the production of a
large number of cells lying within the new part. The ectoderm has at
this time begun to bulge outward, so that the proliferated cells come
to lie within the dome-shaped beginning of the new head. There
appears to be some difference in the number and in the location of
the proliferations in different species. In general, the new cells arise
from the ventral and ventro-anterior region of the dome-shaped ecto-
dermal covering of the new part. Most of this new material gives
rise to the brain, commissures, and ventral nerve-cord (Fig. 57, C).
The cells giving rise to these structures in tubifex come from two ven-
tral regions of proliferation that extend along the sides and dorsally to
the anterior end in front of the digestive tract. Where the two masses
meet above and in front, the brain is formed.^ The cells that do not
take part in the formation of the nervous system give rise to the mus-
cles and connective tissue of the new head. These cells lie especially
at the outer sides of the proliferated mass. The origin of the new
muscles from ectoderm stands in sharp contrast to the current ideas
in regard to the origin of new tissues, and yet it is a point on which
the more recent investigators are entirely in accord. Michel, Hepke,
and von Wagner have arrived at the same conclusion after a careful
examination, and there seems to be no reason for refusing to accept
their results. The theoretical importance of this discovery will be
discussed later.

Soon after the proliferation from the ectoderm has begun, the
blind end of the digestive tract starts to push forward (Fig. 57, D).
The cells in the most anterior part of its wall begin to divide, and the
end grows in an anterior direction as a more or less solid rod. This
rod extends, in some species, as far forward as the ectoderm, meeting
the latter on the inner side of its antero-ventral surface. At this
point an in-turning of ectodermal cells, in the form of a blind pit,
develops, and later this pit, deepening to become a tube, forms the
mouth cavity. Its inner end is from the beginning in contact with
the anterior end of the digestive tract, or else it connects with the
latter soon after its formation. The two flatten against each other,
the cells draw away in the middle of the region of contact, and the
cavity of the new mouth becomes continuous with the cavity of the
old digestive tract. The mouth lies at first nearly terminal in posi-
tion (Fig. 57, E), but by the forward growth of the body wall over

^ In some species the two proliferating regions seem to be in contact above from the
beginning (Hepke, in Nais),

THE ORIGIN OF NEW CELLS AND TISSUES 1 93

and in front of the mouth to form the prostomium, the mouth comes
later to lie more on the ventral surface. The short tube produced by
the in-turned ectoderm forms only a short part of the digestive tract.
It leads from the mouth opening to the new pharynx, and forms,
therefore, only the buccal cavity. A similar ectodermal tube, the
stomodasum, which develops in the egg-embryo, becomes not only
the buccal chamber, but also the lining of the pharynx. The latter
is, therefore, considered an ectodermal structure in the embryo. On
the other hand, in the regenerated head the lining of the new
pharynx arises from the anterior part of the endodermal digestive
tract. We find, therefore, that the same organ, the pharynx, may
arise in the same animal from distinct "germ-layers." This result
also has an important bearing on our ideas concerning the value and
meaning of the so-called "germ-layers," and has helped to bring
about a revolution of current opinion as to the importance of these
layers.

The preceding account of the development of the head has shown
that while certain of the new organs and layers arise from the same
organs of the old part, yet this is not true for all of them. Thus
while the ectoderm gives rise to ectoderm, the new muscles do not
appear to come from the old ones, or even from other mesodermal
tissues, but from the ectoderm. The old digestive tract gives rise to
the greater part of the new one, but the new pharynx comes from
the old endoderm, and not from the in-turned ectoderm. The nervous
system does not arise from the old ventral cord, but from a proHfera-
tion of ectoderm. It has, thus, the same origin as the nervous sys-
tem of the embryo. The origin of the new blood vessels has not
been satisfactorily made out. The seta sacs arise from ectodermal
pits as in the embryo.

In regard to the origin of the new mesoderm, the evidence is still
insufficient, I think, to show that cells derived from the old muscles
or peritoneum take no part in the formation of the new muscles and
peritoneum; but that the greater part of the new muscles, etc., comes
from the proliferated cells can scarcely be doubted. This latter dis-
covery loses none of its significance, however, even if it should prove
true that the old muscles, etc., contribute something to the new part.
It is also not entirely disproven that the ventral nerve-cord does not
take a small share in the development of the new cord.

The regeneration of a new tail-end in these same forms appears
to take place in much the same way as the head. The cut-end
quickly closes ; later a layer of ectoderm appears over the posterior
surface, and the new part bulges out and becomes dome-shaped.
A paired, or in some species a single, region of proliferation develops
from the ectoderm, that gives rise to the new ventral nerve-cord.

194

HE GENERA TION

Lateral proliferations of ectoderm produce, according to some
writers, the material out of which the mesoderm of the new tail is
formed. Randolph, on the other hand, has described the new meso-
derm as arising from the old, especially from certain large peritoneal
cells that are found throughout the body. The cut-end of the diges-
tive tract closes, and later new cells develop at its posterior end. An
in-turning of ectoderm, in the form of a pit, fuses with the posterior end
of the die:estive tract and establishes communication with the outside.

Fig. 58. — After Hescheler.
B. After eleven days,
dividual).

Regeneration of anterior end of earthworm. A. After four days.
C. After tvi'enty-five days. D. After twenty-one days (younger in-

The regeneration of the anterior end of the earthworm has been
carefully worked out by Hescheler, and although on account of the
greater complexity of the process the results are not so decisive as
those just described, yet in many respects they are in agreement.
In Hescheler's experiments only four or five anterior segments were
cut off. The closing of the cut-end is somewhat different from that
in lumbriculus. A plug of cells soon forms over the end (Fig.

THE ORIGIN OF NEW CELLS AND TISSUES 1 95

58, A). The new cells appear to be lymph cells. Although this
mass of cells may be quite large, the cells do not seem to form
later any of the organs in the new head. The presence of these cells
makes it very difficult to work out the origin of the other cells that
appear later. Owing to the absence of this lymph plug in lum-
briculus and nais it is easier to follow in them the regenera-
tive processes. In the midst of these lymph cells spindle-like cells
soon appear whose origin is obscure, but Hescheler thinks it im-
probable that they are transformed lymph cells, although they are
completely intermixed with the latter. The spindle-cells arrange
themselves later in regular bands, that appear to be extensions of the
longitudinal muscles. A few days after the operation, the lymph
plug is covered over, beginning at the edge, by the ectoderm. The
new ectodermal cells arise from the old ectoderm, and seem to extend
over the lymph plug by a sort of migration process. Division of the
cells does not occur at this time. These covering cells are at first all
alike, the characteristic gland cells of the ectoderm being absent.
The digestive tract withdraws somewhat from the outer cut-surface,
and its end closes. The closed end abuts against the inner surface
of the lymph plug. The next changes are initiated by the appear-
ance of karyokinetic divisions in all the tissues of the new part, which
lead to a rapid growth and elongation. Dividing cells are found in
the new, as well as at the border of the old, ectoderm, where the
new and the old parts are continuous. At this stage there appears
in the lymph plug another kind of cell, that seems to arise, in part
at least, from the ectoderm by an in-wandering of new cells. Other
new cells may come from the edge of the old muscles, but it is
not clear whether they come from a transformation of muscle cells,
or from undifferentiated cells lying in the old muscles. In addition to
these sources of new cells, it appears not improbable that cells may
separate from the end of the digestive tract.

Nerve fibres push out from the end of the ventral nerve-cord into
the new part, and groups of cells, often in process of division, appear
in the old ganglia, even in those that lie a long distance from the anterior
end. It is not improbable, Hescheler thinks, that new cells, as well
as fibres, grow forward from the most anterior end of the nerve-cord
into the new part. A mass of nerve cells and fibres appears in front
of the old nerve-cord, and extends upwards and around the digestive
tract, to meet over the anterior end of the latter in another mass of
cells that have arisen from an early in-wandering of ectodermal cells.
It is not improbable that the masses around the digestive tract (the
commissures) and also the new ventral cord may also include cells
that have had the same origin.

A tubular invagination of ectoderm is formed at this time at the

196

RE GENERA TION

anterior end. It meets the anterior end of the digestive tract ; the
two fuse, and the communication of the digestive tract with the out-
side is established. The pharynx develops from the anterior part

of the digestive tract, which
after Hescheler's operation
may contain some of the origi-
nal ectodermal stomodaeum,
since only five of the anterior
segments were cut off, and
the embryonic stomodaeum
extends somewhat behind this
region. In another experi-
ment, carried out by Kroeber,
somewhat more of the anterior
end was removed, but the re-
sult was the same (Fig. 59), so
that it is clear that the new
pharynx may be formed from
the old endoderm.

Hescheler leaves several
points still unsettled, more
especially the origin of the

Fig. 59. —After Kroeber. Regeneration of anterior cells that give risC tO the nCW

end of Allolobophora fcetida, after removal of six ■■ , r,^ j. •*. • i ^

segments. The first stomodceal invaginadon mUSCUiatUrC, DUt It IS aimOSt

had been destroyed The new pharynx is devel- impossible tO make OUt their

opmg from the endoderm. ^

origin in this animal, owmg to
the presence of the lymph cells. Hescheler's discovery that the cells
of the lymph plug do not themselves, in all probability, contribute to
the new part, is an important result, and shows that these seemingly
undifferentiated cells do not possess the power of giving rise to the
different kinds of new tissues. The in-wandering of cells into this
solid plug from the ectoderm, and perhaps also from other sources,
and their subsequent union to produce the definitive organs, is also a
point of capital importance, especially as it puts us on our guard
against a too ready acceptation of the view that all cells in a mass
that have the same general and undifferentiated appearance have had
a similar origin, and in showing that apparently indifferent cells may
really carry with them into the new part those characters that deter-
mine their fate. Other cells, apparently equally undifferentiated,
and lying in the same position, may have quite different possibilities.
In the vertebrates, the regeneration of the tail and limbs of am-
phibia and of the tail of hzards has been studied by a number of
investigators. The regeneration of the tail of several urodeles
and of the larva of the frog was investigated more fully by Fraisse

THE ORIGIN OF NEW CEIIS AND TISSUES 1 97

('95) and by Barfurth ('91). If we examine first the results of
Fraisse's study of the tail of urodeles, which have bony vertebrse, we
find the following changes take place. The cut-surface is covered by
the skin bending over the exposed part, accompanied by a migration
of cells from the edge of the ectoderm. Only the unspecialized
cells leave the old ectoderm to wander out over the cut-surface ;
gland cells and sense cells are entirely absent from the new ectoderm.
These kinds of cells develop later out of the undifferentiated cells
over the new part. The development of new vertebras does not fol-
low the embryonic method of development. In the embryo the
endodermal notochord is first laid down, and around this and the
nerve-cord mesodermal cells accumulate to form the skeletal tissue.
Later the notochord is largely obliterated, as the vertebrae develop,
pieces of it being left along the vertebral column. In the regeneration
of the tail of the adult animal, the remnants of the old notochord
(even if exposed by the cut) do not take any part in the formation of
new tissue. In fact, there is no notochord formed at all. From
the injured vertebrae, or at least from their covering of skeletal tis-
sue, cells are proliferated, out of which a cartilaginous tube develops,
enclosing the new nerve-cord, which is growing out from the cut-
end of the old cord. In this tube centres of deposition of calcareous
material are formed, and the new vertebras are produced in this way.
The new nerve-cord develops from the cut-end of the old cord, and
more especially out of the cells of the lining epithelium of the canalis
centralis. The new muscles develop from cells that arise from the
old muscles.

In the tadpole of the frog the regeneration of the tail takes
place essentially in the way just described for the adult urodele,
except that, there being only a notochord in the tail, only a notochord
is regenerated. According to Fraisse, the new notochord develops
from cells that arise from the sheath of the old notochord, and not
from the vacuolated cells of the notochord itself. The notochord
cells are, he states, derived from the endoderm of the embryo,^ while
the sheath arises from the mesoderm ; hence the newly regenerated
notochord that arises from the sheath of the old one comes from a
different germ-layer. Exception may be taken to this statement,
because in the frog's embryo the notochord develops from tissue that
is at first perfectly continuous with the mesoderm, and, in fact, may
be called mesoderm ; also because it is probable, in the light of more
recent research, that both the notochord and its sheath have exactly
the same origin.

1 This seems to be true for urodeles, but whether it is true for the anurans is rather a
question of definition, as I have pointed out in my book on The Development of the Frog's

198 RE GENERA TION

It is known that the tail of Hzards breaks off generally at a definite
region near the base, and that the break does not occur between the
vertebrae, but in the middle of a vertebra- — in some species the seventh
caudal. The vertebras are thicker at their ends than in the middle,
and are lirmly held together by intervertebral cartilages. The cen-
tres of the caudal vertebrae are the weakest links in the chain, or at
least the place at which the vertebral column is most easily broken in
response to the contraction of the tail-muscles. ^ Fraisse and others
speak of this arrangement as an adaptation for breaking off the tail.

The new tail that regenerates does not contain a new series of
vertebrae, as does the new tail of the salamander, but, instead, a car-
tilaginous tube that is attached to the half of the broken seventh
caudal vertebra.

The regeneration of the new tissues of the tail of the lizard takes
place as follows : A scab forms over the cut-surface, composed in part
of clotted blood, in part of broken-down tissues from the injured cells.
In the course of a week the necrotic tissue falls off, and a smooth sur-
face of ectoderm is found covering the end of the tail. The new ecto-
derm appears to come from the old, but its method of development
has not been studied. The deeper layer of the skin of the lizard is
composed of mesodermal connective tissue, and in the new part this
layer arises from the connective tissue of the old part. The tissue
that forms the cartilaginous tube of the new tail develops from the
skeletal tissue of the broken vertebra. The remnants of the old noto-
chord, that are present in the vertebra, have nothing to do with the
new structure, nor does the new tube represent in any way a noto-
chord, but it appears to be a structure siii generis. In later stages,
osseous plates may be formed in the cartilage, but these are too
irregular to be compared to vertebrae. A tube grows out from the
cut-end of the nerve-cord, which in some forms, as Fraisse shows,
is only an extension of the lining epithelium of the nerve-cord. In
other forms it is possible that other cells of the old cord may also grow
backward, divide, and produce new cells. The fine thread that is
formed in this way does not send out any nerve fibres into the sur-
rounding parts. In Angiiis fragilis, however, a few ganglion cells are
present in the new cord. It is probable, Fraisse states, that while the
new tube is morphologically a nerve-cord, yet physiologically it is not
functional in any of the reptiles.

The new muscles come from the old ones. Fraisse thinks that the
new muscle fibres come from the so-called " spindle fibres " that split
off from the primitive muscle bundles. These fibres, Fraisse believes,
originate normally during the process of physiological regeneration of

^ The attachments of the muscles may be the cause of the break in the middle of the
vertebrae, rather than l:)etvveen two vertebrae.

THE ORIGIN OF NEW CELLS AND TISSUES 1 99

the muscles, and also after injury to the muscles. From these spindle
cells the new muscle fibres develop in the same way as the muscle
cells of the embryo.

Fraisse sums up the results of his studies of regeneration as fol-
lows : (i) Both in amphibians and reptiles, injured tissues can only
produce new tissues hke themselves. The leucocytes assume only
the function of nutrition and of devouring the broken-down parts of
tissues. They never become fixed tissues — neither connective tissue
nor any other sort. (2) All tissues are capable of regenerating them-
selves, either directly out of their differentiated elements, or out of a
rriatrix. As a matrix for the epidermis, there is the Malpighian layer
of the skin ; for the central nervous system, the epithelium of the
central canal of the nerve-cord ; and for the musculature, the spindle
fibres.

Fraisse also formulates the following general statements : {a) Re-
generation is neither a pure recapitulation of the ontogeny nor of
the phylogeny. The process is rather a hereditary one, with which
comphcated adaptations of the tissues are often involved that fol-
low the laws of correlated development, {b) We cannot explain the
phenomenon of regeneration, as the result of wounding the tissues,
or as the outcome of an increase in the food supply, or as due to the
removal of a resistance to growth. Far more important are the prin-
ciples covered by the former paragraph, (a).

Barfurth has studied in detail the regeneration of the tail in some
amphibia ; and his results, while not covering as much ground as do
those of Fraisse, yet give a more detailed account of the origin of the
new tissues. Barfurth's results on triton and siredon are not essen-
tially different from those of Fraisse. In the tadpole of the frog, Bar-
furth finds that the notochord regenerates from the sheath of the old
notochord. In the larval urodele, he finds that the new notochord
arises as in the tadpole, and not from the skeletal sheath, as Fraisse
maintains. In very young larvae of siredon the chordal cells them-
selves seem to give rise to the cells of the new notochord. In older
larvae, in which the skeletal tissue is developed around the notochord,
regeneration t&.kes place both from this tissue and also from the sheath
of the notochord. He concludes that in the regeneration of the new
notochord, and also of the skeleton, the origin of the cells depends
upon the developmental stage of the supporting tissues.

In regard to the regeneration of the muscles, Barfurth comes to
the following conclusions : In very young larvae of siredon, the de-
generative changes in the muscle cells are often very sHght. Regen-
eration takes place by growth from and the displacement of the old
muscles. During this time bud-like terminal and lateral formations
occur in the muscle fibres. These outgrowths contain nuclei and

200 REGENERATION

form sarcoblasts ; and these pass into the new part, where they make
the new muscle fibres in the same way as do the cells of the embryo.
In older larvae of the frog, and in mature animals in general, the
changes are more complicated. Two processes can be distinguished:
{a) degenerative and {Jf) regenerative, {a) Broken-down muscle
fibres that have been cut, and torn-off pieces of muscle fibres, are
found present. There follows an accumulation of leucocytes and of
giant cells. The nuclei in the degenerating muscle fibres atrophy,
and the substance of the fibres breaks down, {b) The muscle fibres
split lengthwise to form spindle fibres, and there is an increase in the
number of nuclei at the same time. Sarcoblast-like outgrowths of the
old muscle fibres are formed, which produce the sarcoblasts that
become new muscle fibres.

Barfurth agrees with Fraisse in two main points, viz. that all the
tissues of the tail have the power of regeneration, and that each tissue
produces only tissue like itself. The law which Kolhker attempted to
establish, viz. that the elements of the formed tissues have lost the
power of producing other kinds of tissue, — the law of the specification
of the tissue, — is supported by these results of Fraisse and of Bar-
furth, but is contradicted, as has been shown above, by the results on
the earthworm, and also as we shall see even in the amphibia, as for
instance in the regeneration of the lens of the eye.

Spallanzani ^ was the first to study the regeneration of the
limb in salamanders, and found that the skeleton in the new part is
like that in the normal limb. Bonnet, Philipeaux,^ as well as other
naturalists,^ also examined the regeneration of the limbs of salaman-
ders. Gotte ('79) has studied the embryonic development and the
regeneration of the limb of triton, especially in regard to the origin
of the new bones. He found that the skeleton develops in much the
same way in the embryonic hmb and in the regenerated limb, and the
process in the latter may be said to repeat that in the former. This
is especially true for the regeneration of the limb of a very young
larva, but the older the larva the more it departs from the embryonic
type of development. If the limb is cut off through the upper arm,
or through the thigh, new tissue develops over the cut-end. If the
larva is quite young, so that formation of the cartilages in the leg has
not gone very far, the new tissue differs very little from the old ; but
if the leg of an older larva is amputated, the difference between the
old and the new parts is more striking. If the bones of the leg have

1 Prodromo, 1768.

- Philipeaux, Compies rcndus de VAcad. des sciences de V Institiit de France, Annee
1866, 1867.

2 Todd {Quarterly Journal of Science, Literature, and Arts, Vol. XVI), Blumenbach,
Treviranus, Von Siebold.

THE ORIGIN OF NEW CEILS AND TISSUES 20I

become ossified, the transition from the old to the new part is at first
very sharp. The new tissue, that will make the new cartilages of the
new limb, develops as a cap over the cut-end of the old bone.
G5tte does not give an explicit statement in regard to the origin
of the new cartilage, but his account leads one to suppose that it
develops from the old cartilage or from some part of the bone.
This is, in fact, the case, as I have observed in preparations of the
regenerating leg of Pletliodon cinerens, in which the new cartilaginous
tissue comes from the periosteum of the old bone. Gotte shows
that two long rods of tissue are formed, that are separate for the
greater part of their length. They give rise to the two bones of the
lower leg, or forearm, as the case may be. The broken end of
the femur or humerus also completes itself by a short cartilaginous
cap, which is at first continuous with the two rods just described.
The ends of these two rods break up into a series of pieces that
form the tarsalia, or the carpalia, and the digits. Two digits are first
formed, and the others are added as outgrowths from the side of one
of the two rods. It is important to note that the new cartilages are
formed, in large part, out of a continuous substratum (or rather of
two) which separates into proportionate parts to produce the elements
of the new limb.

The regeneration of the muscles of the limb of an adult animal,
plethodon, has been recently worked out by Towle. The leg was
cut off in the middle of the forearm. Extensive changes take place
in all the muscles that extend across the level of the cut. The old
fibres in the lower end of the muscle, i.e. those near the cut-end,
disintegrate, and the number of nuclei greatly increases. The divi-
sion of the nuclei seems to be direct, each retaining some of the
old muscle substance about itself. From some of these cells the new
muscle tissue is formed in the new part. Higher up in the forearm
the muscle fibres break down to a smaller extent, and still higher up
some of the old fibres may remain intact. New muscle fibres are also
formed in the old muscle, especially in the region near the cut-end.

The process of regeneration has not been so fully worked out in
any other vertebrates as in those described in the preceding pages,
although the regeneration of single tissues or organs in the verte-
brates has been extensively investigated. In all such cases it is found
that like tissues give rise to like.

In the planarians it has been found that during regeneration the
ectoderm covers the exposed surface, and from it arises the new ecto-
derm ; the digestive tract appears to come in part from the old tract
and in part from the middle-layer cells ; the nervous system appears
also to develop out of the middle-layer cells that are found scattered
through the body. These cells seem to form a sort of reserve supply

202 REGENERATION

that gives rise to the digestive tract, nervous system, and middle-layef
cells in the new parts. From them also arise the new pharynx, and the
lining of the pharynx chambers, as well as some other structures. It
is impossible to say at present whether one and the same kind of cell
may give rise to all these structures, or whether different kinds of
cells are present in the middle layer, that cannot be distinguished
from each other by the methods at present at our command.

The changes taking place in the tissues of those animals that
regenerate by morphallaxis have been only quite recently carefully
investigated. Bickford stated that in tubularia the old differentiated
tissue changes over directly into the tissue of the new part, and
Driesch confirmed this statement. Stevens has studied by means of
serial sections the different changes that take place. Division of both
ectodermal and endodermal cells is found to occur, but especially the
ectodermal. Whether all the ectodermal cells divide, or only some of
them, is difficult or impossible to state, but whether this happens or
not, all the old region goes over into the new hydranth.

The changes that take place in hydra have been recently worked
out in my laboratory by Rowley, who finds that a certain amount of
division takes place in the old cells, especially in the ectoderm. The
division of the cells is not a very active process, and it seems not
improbable that many of the old cells go over without dividing into
the new part.

One of Trembley's most celebrated experiments was that in which
hydras were turned inside out (Fig. i, A, B), so that the ectoderm
came to Hne the inner cavity and the endoderm to cover the outer
wall. The tentacles were not everted but remained sticking out of
the mouth of the everted animal. Their openings, or arm-holes,
therefore, appear on the outer surface of the body. In order to
prevent the everted hydra from turning itself back again, as it tends
to do, Trembley pushed a small bristle crosswise through the wall of
the body. Finding the hydras still sticking on the bristles the next day,
he concluded that they had not returned to their former condition, but
that the outer layer (the endoderm) had changed its character so that
it became ectoderm, and the inner layer (the ectoderm) became
endoderm.^ The experiment seemed to show that the two layers
could change their specific character and be transformed into each
other according to their position in the animal. These remarkable
results were not challenged until 1887, when Nussbaum repeated the
experiment and showed that Trembley had overlooked an important
fact. It was found that even the bristle pushed through the body
does not prevent the hydra from regaining its original condition,
although it may delay the turning back. If the turning back can be

1 How the tentacles could have gotten into their normal position is not explained.

THE ORIGIN OF NEW CELLS AND TISSUES 203

prevented, the animal dies. Nussbaum showed how the turning back
takes place in an animal while it remains on the bristle. The everted
foot-end begins first to turn back, pushing into the central cavity.
When it comes to the bristle it passes to one side of it, and continuing
to turn back the foot passes out of the mouth, drawing the rest of the
body after it.^ The last act of the turning can take place only by
tearing away through one or both sides, and this is often done. The
bristle may still remain sticking to the body through one side, or even
remain through both sides if the body has, after tearing through,
healed up around the bristle. The process of turning back may take
place quite quickly, and had been overlooked by Trembley, who
trusted too confidently to the presence of the bristle sticking through
the animal.

The method by which the turning back of the layers takes place
was not, it appears, clearly described by Nussli^aum in his first paper,
for his account seems to imply, in certain passages, that the ectoderm
may slide over the endoderm during the process, rather than that
both layers always turn together. Ischikawa, who studied the problem
later, gave a clearer account of the method of turning back. Nuss-
baum has stated in a later paper that he had described essentially
the same process.

In conclusion, it can be definitely stated that a transformation of
ectoderm into endoderm cannot take place in hydra. Ischikawa also
tried removing the endoderm from a piece by spreading it out and
then killing the inner layer by weak acid appHed with a brush, but
pieces of this sort failed to regenerate a new endoderm.

Tower has recently stated that if a living hydra is put into a
strong light from an arc lamp of 52 volt 12 ampere capacity, that
is focussed on the animal (after passing through an alum cell), the
ectoderm cells fly off, but if the animal is kept, it subsequently pro-
duces a new ectoderm. Whether all the ectoderm is lost, or only the
larger neuro-muscular cells, was not made out.

One of the most unexpected discoveries of recent times in con-
nection with the problem of regeneration is the renewal of the
extirpated 'eye of triton and salamandra. Colucci first discovered
in 1891 that if the eye is partially removed a new eye develops from
the piece that remains and that the new lens develops from the margiji
of the b?tlb. Wolff, a few years later, not knowing of Colucci's
results, also found that after extirpation of the lens of triton, by
making an incision in the cornea, a new lens develops from the edge
of the old iris. Wolff pointed out the great theoretical importance
of this result. The experiment has been repeated and confirmed by

1 The foot sometimes pushes out through one of the sUts made by the bristle instead of
out of the mouth.

204

RE GENERA TION

a number of more recent workers, so that there remains no question
as to its accuracy.

After the removal of the old lens the wound in the cornea
quickly heals, and in the course of two or three weeks a thickening
appears at one point at the edge of the iris (Fig. 60, A). The cells
that produce this thickening are the ordinary deeply pigmented cells
of the iris, where the outer layer of cells of the iris becomes continu-

/ ^

Fig. 60. — After Wolff. Regeneration of lens of eye of Triton. A. Edge of iris with beginning
lens. B, C, D. Later stages of same. E. After Fischel. Whole eye with regenerating lens.

ous with the inner layer. The cells increase in number and produce
a spheroidal ball that hangs down into the space formerly occupied
by the lens (Fig. 60, E). The cells become clearer by absorbing
their pigment and arrange themselves concentrically as in the normal
lens. When fully formed the new lens separates from the iris and
occupies the normal position.

The most surprising fact in connection with the development of

THE ORIGIN OF NEW CELLS AND TISSUES 20 5

the new lens is that it arises from a part of the body from which the
lens of the eye never develops in the embryo of this form or of any
other vertebrate. In the embryo the lens develops from the ecto-
derm at the side of the head and only secondarily unites with the
optic cup, that has come from an evagination of the anterior wall of
the fore brain. In the regeneration of the adult lens, however, the
ectoderm covering the eye takes no part in the formation of the new
lens, — in fact, it is separated from the eye by the thick inner, meso-
dermal layer of the cornea. The lens develops, as has been stated,
from the already differentiated layers of the iris. It is a point of
further interest to notice that the cells that form the transparent lens
come from the iris cells that are in part at least filled with black pig-
ment. If this pigment remained in the cells the new lens, while it
might be structurally perfect, would be physiologically useless. The
pigment disappears, however, as the lens develops. In this case we
find a highly specialized organ, the lens, developing out of tissue
also specialized in another direction. It does not siraphfy the prob-
lem to point out that the lens and the iris are both parts of the eye,
since they have arisen from different parts of the body and have
only secondarily come into apposition with each other. Colucci was
contented to point out that both the embryonic lens and the regen-
erated one come from ectoderm and that the result can be brought
into harmony with the " germ layer " hypothesis.

Wolff has called attention to the fact that the new lens arises
from the upper edge of the iris, and that this is obviously the most
advantageous position in which it could develop from the iris, since
by its own weight it falls into place as it develops. If the lens had
developed from any other point of the margin, its position would be
less advantageous, as it might not be brought into its proper position.

Fischel, who has more recently studied the regeneration of the
lens in the larvae of Salamandra macjilata, finds that after the
removal of the lens the iris is thrown into wrinkles or folds and may
stick at first to the cut-edge of the cornea. After the cornea has
healed, the iris returns to its normal position. He finds that the
first changes are more or less alike around the entire rim of the iris
and involve a partial absorption of the pigment, a separation of the
inner and outer layers at the edge, and a swelling of the margin.
These changes go only a little way in those parts that do not pro-
duce a lens, but at the upper edge of the iris they go farther and
lead to the formation of a lens in that region. He finds also that a
new lens develops in animals kept in the dark as well as in those
kept in the light, and in the same way.

Fischel also tried the effect of removing a part of the upper edge
of the iris at the time when the lens was extirpated, in order to see

205 REGENERATION

if, in the absence of this part, the lens would develop from other
parts of the uninjured margin of the iris. He found that the new-
lens still comes from the upper edge of the iris from the part left
after the operation and not from the intact edge in other parts.
This seemed to show that an injury to the iris is in itself a stimulus
that starts the formation of a lens. This conclusion is made prob-
able by the results of other experiments in which the iris was stuck at
several points, when new lenses began to develop at several of these
regions of injury. In some cases Fischel found that two or more
lenses began to develop when the iris had not been intentionally
injured; but it is not improbable that some sort of injury may have
been effected when the lens was removed. Fischel, as has been said,
removed extensive portions of the upper part of the iris and found
that a new lens could be formed at the cut-edge, even in the region
of the pars ciliaris ; and, even after the removal of the entire upper
part of the iris, lens-like structures may appear in the inner or retinal
layer of the remaining region.

If instead of removing the lens it is displaced by pressing on the
cornea until the lens leaves its normal position and comes to lie in
the vitreous humor, a new lens develops from the edge of the iris, as
though the old lens had been entirely removed from the eye, but in
the experiments in which this was done the new lens was not well
developed. The result shows that it is not necessary that the old
lens be removed from the eye in order to induce the regeneration of
a new one, but only that the lens lose its normal position in the eye.

In regard to the stimulus that determines the development of the
lens, Fischel agrees with Wolff that gravity has a share in producing
the result. The absence of the old lens from its normal position,
as well as the wrinkling of the cornea, may also enter in as factors.
Fischel takes issue with Wolff as to the interpretation of the result
as an adaptation, and states that "the organism always responds to a
change of relation in only one way, whose direction is already deter-
mined by internal structural relations, without regard to whether
the result is adaptive or not. The response follows each stimulus in
a way determined by the limited possibilities of the cells. With
such a uniformity in the reaction, the idea of a fundamental adapt-
ability cannot be connected, since the reaction, that appears to us to
be adaptive in a series of complicated changes may be non-adaptive
in another series."

Whether Fischel has here really met Wolff's argument is, I think,
open to question. It does not alter the result to show that factors
already existing enter into the process, so long as the organism is so
constructed that just those factors are present that bring about a use-
ful response. That the response may be sometimes imperfect does

THE GERM-LAYERS IN REGENERATION 20/

not affect seriously the argument — in fact, it makes the case all the
more remarkable if these imperfect attempts are in the direction of
useful responses. Fischel sums up his conclusions as follows : " It is
not necessary, and it is irreconcilable with the facts, to describe the
formation of the lens in a teleological sense, and to bring this case
forward as a proof of the universal apphcation of a teleological
principle. As has been already stated, the facts in regard to this
case show much more clearly that the organism reacts to each
change always in a manner that corresponds to its limited possibili-
ties without regard to a teleological principle. A planarian, for in-
stance, responds to a stimulus and makes a new head, even when
it possesses one or more already ; a tubularian produces a hydranth
at its basal end, if this end is freely surrounded by water ; an actin-
ian forms a new mouth on the side of its body, etc. ; so also do the
cells of the pars ciliaris, and the pars iridica retincE differentiate into
lens fibres. Working blindly, without respect to the consequences
as far as they concern the whole, the one thing only is pro-
duced for which the conditions are present that bring about its
formation in the cells."

THE PART PLAYED BY THE " GERM-LAYERS" IN REGENERATION

Our examination of the origin of the tissues and organs in the
new parts has shown that in most cases the old tissues give rise to
the same kind of tissue in the new part ; or in some other cases,
as in the nervous system, the regenerating organs arise from the
same "layer" as that from which they develop in the embryo.
These facts have led many writers to state that the tissues and
organs in the regenerated part arise from the same germ-layers as
do the same parts in the embryo. It is supposed that ectoderm
gives rise to ectoderm, and to those structures that arise from the
ectoderm in the embryo, as, for instance, the nervous system, stomo-
daeum, etc. The endoderm is supposed to give rise to endoderm, and
to endodermal structures, and the mesoderm to mesoderm and its
derivates. So fixed has this opinion become that it is not uncom-
mon to find investigators proclaiming the triumphant success of their
results, because they have been able to trace the organs in the regen-
erated part to the same germ-layers that give rise to these organs in
the embryo. Before deciding as to the value of this point of view,
let us examine briefly the foundations of the so-called germ-layer
hypothesis.

The origin of this hypothesis goes back at least to 1759, when
C. F. Wolff maintained his thesis that the digestive tract of the chick
exists as a fiat, leaf-like structure that subsequently rolls up into

208 REGENERA TION

a tube. He thought it probable that other embryonic organs might
arise in the same way. His views made at the time no impres-
sion on his contemporaries, and lay buried until 1812, when Meckel
republished Wolff's work in a German translation. Pander, in 18 17,
distinguished two layers in the early embryo, a serous and a mucous,
and stated that later a third, vascular layer appears between the
other two. Von Baer published in 1829 his celebrated memoir on
the development of the chick, in which he made out two primary
layers in the germ, the animal and the vegetative layer, and held that
each of these separates into two to produce the four embryonic
layers. Remak, in 1851-1855, gave a more precise description of the
germ-layers, and stated that from the innermost layer, the epithelium
and glandular cells of the digestive tract arise (including the lining
of the glands that open into the digestive tract). From the outer-
most layer he showed that the integument and sense organs and the
nervous system develop, and from the two middle layers develop the
muscles, blood, excretory, and reproductive organs. By the term
" germ-layers " was meant at this time only that the embryo is formed
out of sheets.

Huxley in 1849 pointed out that a medusa is made up of two
layers, an outer and an inner, and called attention to their possible
equivalency to von Baer's serous and mucous layers. This idea of a
resemblance between the layers of an embryo and of an adult of
a lower form furnished the starting-point for the more modern for-
mulation of the germ-layer hypothesis. Kowalevsky's work on the
development of a number of- the lower animals showed that there is
present in many forms a two-layered stage, or gastrula, formed by
an in-turning of the wall of the hollow blastula. In this way two
germ-layers are established, an outer and an inner, that correspond
to the ectoderm and to the lining of the digestive tract, or endoderm.
While Kowalevsky's work did much toward laying the foundation of
the modern study of embryology, he himself indulged in very httle
of the sort of speculation that came into vogue a few years later.
Kowalevsky's discovery of the gastrula stage in the embryos of many
different groups has been fully confirmed and extended, but the elabo-
rate speculations that have been built up on this as a basis have
gone far beyond the evidence, and, for a time, drew the attention of
embryologists away from more important problems. Haeckel took a
more extreme position than most of his contemporaries, and assumed
that the gastrula stage that occurs in so many of the groups of meta-
zoa corresponds to an ancestral, two-layered adult animal, the gas-
trasa, from which all the higher forms have descended. The presence
of the gastrula in the development was interpreted as a " repetition "
of this ancestral adult stage. Thus the two primary layers are sup-

THE GERM-LAYERS IN REGENERATION 209

posed to have an historical meaning.^ Embryologists soon began a
search for a similar mode of interpreting the middle germ-layer, or
layers, which led, amongst other views, to the formulation of the
" gut-pouch hypothesis." From this point of view the body cavi-
ties, or coelomes, are supposed to have been originally sac-like out-
growths from the digestive tract of an ancestral adult animal. Later,
these coelome sacs are supposed to have been shut off from connec-
tion with the digestive tract — their cavities becoming the body cavi-
ties, and their walls giving rise to the mesodermal organs. The
formation of pouches from the walls of the archenteron of the embryo
in several groups of animals has been interpreted as a repetition of
the ancestral adult animal.

A comparison of the germ-layers in different forms very soon
led to an attempt to " homologize " the layers in different animals.
If the layers have had historically the same origin, or appear in the
same way in the embryos, or give rise to the same organs, they are
said to be homologous. In the absence of a knowledge of the first
two of these conditions it is generally considered sufficient, if it can
be shown that similar organs arise from a layer, to "homologize"
that layer in the two forms. The study of embryology soon became
a search for homologies. The results led to inextricable difficulties
and innumerable contradictions until, a reaction setting in, many
embryologists became sceptical in regard to the value of this entire
method of study.

The results of a detailed study of the process of cleavage in a
number of groups have helped, perhaps, to clear the way for a sounder
conception. It has been found that the cleavage of the Qg% in mem-
bers of the groups of annelids, mollusks, and turbellarians is ex-
tremely similar — so similar, in fact, that it seems hardly possible that
they could be due to chance, especially as the series of cleavages is
quite complicated. The discovery of these similarities led at once
to comparison, and comparison to the establishment once more of
homologies, and the homologies led again to contradictions, until at
present scarcely any two workers agree as to a criterion of homol-
ogy.^ Leaving this question aside, however, and fixing our attention
only on the similarity of the process of cleavage, we are justified, I
think, in looking for an explanation of the similarity in some sort of
an historical connection. We can eliminate, I think, without discus-
sion the possibility of this type of cleavage representing an ancestral

1 I have given elsewhere {^The International Monthly, March, 1901) a fuller treatment
of the gastraea theory from the historical point of view.

2 It may be pointed out that there may be really several kinds of homology, such as
homology due to similar origin of the blastomeres, or to their position, or to their fate, etc.
The confusion that has arisen may in part result from the attempt to make homologous
parts agree in all points.

P

2IO REGENERATION

adult animal. So far as the question of descent enters the problem,
we can infer with some degree of probability that the groups in ques-
tion may have come from a common group in which the tg^ divided
in much the same way as we find it dividing at the present time. As
a formal hypothesis this view meets with no serious difficulty, since a
chain of forms, or a continuous living substance, connects the present
animals with those living in the past ; and we may assume that the
same factors peculiar to the Q^g of the ancestors are still present in
the eggs of their descendants. This sort of explanation gives us no
causal knowledge of the way in which the ^gg divides, nor does it
preclude the possibility of new changes coming in that may entirely
alter the form of the cleavage. Moreover, since we are dealing with
a question of historical probability only, we cannot be certain that the
same type of cleavage may not have arisen quite independently in
each group.

The argument in favor of the gastrula stage also representing an
ancestral larval stage may be admitted as a remote possibility, but
on evidence even .far less satisfactory than that for the similarities of
cleavage being accounted for by a common descent. That this gas-
trula was ever an adult form we have no means of deciding, even as
a matter of probability, and even if this could be made plausible it by
no means follows that such an adult stage would become an embryonic
stage of later forms. Consequently that part of the germ-layer theory
that rests on such a supposed connection cannot be looked upon as
much more than a fiction.

But even granting that there is an historical, embryonic ^ connec-
tion, its small importance for the scientific problems connected with
embryonic development, and budding and regeneration has been
shown by a number of recent discoveries, and nowhere more clearly
than in the cases of the formation of new individuals by budding.
As an example may be cited the method of development of the
ascidian from the &^Z, and by means of buds. The work of Kowa-
levsky, Delia Valle, Seeliger, and Van Beneden on the budding pro-
cess of ascidians showed that there are some discrepancies between
the bud development and the embryonic development. The more
recent papers of Hjort, Oka, Pizon, Salensky, Lefevre, and others
have shown very clearly that the germ-layer theory is inapplicable to
the bud development in this group. The bud arises as a double-
walled tube, or rather a tube within a tube, with a space between.
The outer tube comes in all cases from the ectoderm of the animal ;
the inner tube has a different origin in different species. In perophora,
didemnum, and clavellina, the inner tube comes from endoderm ; in
botryllus it arises from the ectoderm of the larval peribranchial or

1 That is, one not depending on inheritance through adult forms.

THE GERM-LAYERS IN REGENERATION 21 r

atrial cavity. In all these forms the inner tube gives rise to the new
pharyngeal cavity of the bud, while this same cavity comes from the
endoderm of the archenteron of the embryo. In the bud embryo the
peribranchial space is also derived from the inner tube ; hence it is
endodermal in the first series, and ectodermal in botryllus. In the
Qg^ embryo it is ectodermal. In regard to the development of
the nervous system there is some difference of opinion. A number
of investigators have found that the new brain arises from the outer
part of the inner or branchial tube, which has in most cases an
endodermal origin. Seeliger and Lefevre believe the nervous sys-
tem to arise from mesodermal cells that lie between the two tubes.
It appears, nevertheless, that in several forms the brain really comes
from the inner tube, which also gives rise to the branchial sac. There-
fore, in those cases in which the inner tube is endodermal the brain
has the same origin, and in the case in which the inner tube is ecto-
dermal, the brain is ectodermal, but the pharyngeal sac has also an
ectodermal origin. There is obviously no definite relation between
the origin of these structures in the bud and in the Q.gg embryo.

A similar difficulty is met with in the Bryozoa in regard to the
development of the Q.gg embryo and the bud embryo.

Braem, who has made a critical examination of the germ-layer
theory,^ has found it impossible to give a morphological definition of
a germ-layer, and has adopted a physiological criterion. He thinks
that in whatever way a germ-layer arises, whether by folding, or by
delamination, etc., it exists independently of its method or place of
origin. A layer is not endodermal because it forms the inner wall
of a gastrula, but it is endodermal because it develops into the diges-
tive tract. The germ-layers of different forms are only similarly
placed, but whether they are homologous will depend on other
things. On this view the inner tube of the ascidian bud that gives
rise to both digestive tract and to the nervous system is simply an
indifferent layer until it gives rise to these structures. Its cells
may be looked upon as indifferent, as are those of the blastula.
Thus the difficulty of the morphologist is not solved, but the knot is
cut. For Braem the germ-layers are convenient terms, since he
rejects any historical significance that they may have, and it is just
this side of the question that the morphologist has attempted to work
out. While the evidence shows that the germ-layers cannot have
any such final attributes as embryologists have attempted to assign
to them, and that Braem has called attention to the real and impor-
tant problems connected with the study of development, yet it may
still be admitted without endangering the newer point of view, that
there may be also an historical question in connection with the germ-

1 Biologisches Centralblatt, XV, '95.

212 RE GENERA TION

layers, if not in the sense of a repetition of an ancestral adult gastraea,
yet in the sense that similarity in embryonic development may in
some cases find its historical explanation in a common descent.

If in the light of this discussion we turn to the phenomena of
regeneration, we again find evidence showing that the germ-layer
theory fails to apply in all cases. It has been pointed out that in
lumbriculus, and in the naids, the new mesoderm is derived from the
ectoderm, and does not come from the old mesodermal tissues. The
mesoderm of the embryo in annelids is derived from one, and later
from two, superficial cells of the blastula,^ that push in about the time
of gastrulation. They cannot, at this time, be referred to one layer
rather than to the other. It cannot be affirmed, therefore, that in
regeneration, the mesoderm arises from a different layer from that in
the embryo, but neither can this be denied. The most important
point in this connection is that the new mesoderm comes from the
ectoderm that is already differentiated, and not from the mesodermal
tissues. It is clear, however, that while the lining of the pharynx in
the embryo is ectodermal, it is endodermal in the regenerated part.

It is true that these cases are very exceptional, and that generally
the new organs come from similar organs in the old part, but one
established exception is sufficient to show that the traditional concep-
tion of the germ-layers may be of little value, and since the hypothe-
sis itself, out of which the idea in regard to regeneration from definite
germ-layers has been formed, has been proven to be insufficient in
other directions, the time is ripe to look for a more secure footing.
It need hardly be added that the idea of a supposed necessity for an
organ to arise from a definite germ-layer is so empty of all signifi-
cance that we may well rejoice to be able to set it aside as a naive
view that has had its day. Furthermore, a new series of problems
has arisen in connection with the experimental work to be described
in a later chapter. If, as seems probable, the question of the germ-
layers will be merged into the much broader question of the origin
of the specification of the tissues, we can in the future more profitably
direct our attention to the experimental evidence that bears on the
latter question.

THE SUPPOSED REPETITION OF PHYLOGENETIC AND ONTOGENETIC
PROCESSES IN REGENERATION

It has been claimed that at times ontogenetic, and even phylo-
genetic, processes are repeated during regeneration. Fraisse, for
instance, who advocates this point of view, thinks that it has been

^ A small amount of embryonic mesenchyme may come from some of the ectodermal
quartettes of the embryo and produce the branching muscles of the head, but not the char-
acteristic muscles of the trunk.

PHYLOGENETIC AND ONTOGENETIC PROCESSES 21 3

too much neglected, and calls attention to several instances of what
he believes to be cases in point. He thinks that Bulow is correct in
his comparison between the method of development of the new tissue
at the end of the tail in certain naids, and the method of gastrula-
tion and formation of the mesoderm in the embryo. Later results
have shown, however, that in several points Bulow's observations are
incorrect. The in-turning of ectoderm that Biilow compares with the
process of gastrulation is connected with the formation of the ecto-
dermal proctodaeum, and is not comparable with the development of
the endoderm in the embryo.

Gotte also, as we have seen, cites a case of resemblance between
the regeneration of the limbs of the salamander and their mode of
embryonic development. He finds the resemblances less marked as
the animal becomes older. The resemblance is, however, not very
close and of a rather general sort, and since the same structures
develop in both cases out of the same kind of substance, it is not sur-
prising that there should be some resemblances in the processes. This
evidence is counterbalanced by the mode of regeneration of the tail
in the adult of certain forms, and in the regeneration of the lens of
the eye from the iris.

Carriere finds that the eye of snails regenerates from the ectoderm
in much the same way as the young eye develops. Granted that the
eye is to come from the ectoderm in both cases, and that the same
structure develops, it is not to be wondered at that the two processes
have much in common.

The mistake, I think, is not in stating that the two processes are
sometimes similar, or even identical, but in stating the matter as
though the regenerative process repeats the embryonic method of
development. If the same conditions prevail, then the same factors
that bring about the embryonic development may be active in bring-
ing about the regenerative processes. In fact, we should expect
them to coincide oftener than appears to be the case, but this may
be due to the conditions being different in the young and in the
adult.

It has been claimed also that in some cases there is regenerated a
structure like that possessed by the ancestors of the animal. The
stock example of this process is Fritz Miiller's result on the regener-
ation of the claw of a shrimp, Atypoida protiniiriim} Fraisse and
Weismann and others have brought forward this case as demonstra-
tive. The animal is said to regenerate a claw different from any of
those in the typical form, and one that resembles the claw of another
related genus, Cm-odina. The value of evidence of this sort is not
above question. Przibram has shown in other Crustacea that when

1 Cosmos, Vol. VII, p. 388.

214 ^^ GENERA TION

a maxilliped is cut off a structure different in kind often regenerates,
but that after several months the typical structure returns. Do we find
here an ancestral organ that first appears, and then gives way to its
more modern representative ? If it resembled the maxilliped of any
other crustacean, the evidence would, no doubt, be accepted by those
who accept the evidence furnished by Miiller. What then shall we
say to the case, first discovered by Herbst, in which the eye of cer-
tain prawns being cut off, an antenna-like organ regenerates ? Since
these antennae are similar to those possessed by the same animal,
shall we assume that it once had antennae in place of eyes ?

Another comparison, that Fraisse has made, is worth quoting as
showing how far credulity may be carried. In the regeneration of the
tail of certain lizards pigment first appears in the ectoderm of the new
part and then sinks deeper into the layers. Fraisse found a lizard on
Capri in which the tail is pigmented throughout life, and although he
did not know whether or not the pigment is in the skin he suggests
that this lizard represents an ancestral condition, that is repeated by
the regenerating tails of other forms.

Boulenger ('88) pointed out that the scales over the regenerated
tail of several lizards have a different arrangement from that of the
normal tail, and furthermore, the new arrangement is sometimes like
that found in other species. He claims that this shows that such forms
are related, even where no evidence of their relation is forthcoming.
That the conditions in the new tail may be different from those in
the normal tail is shown by the absence of a vertebral column, etc. ;
therefore that the scales also should have a new arrangement is not
surprising, but the facts fail, I think, to show that there need be any
genetic relation between the forms in question. That the conditions
in the new tail might be like those in an ancestral form may be
admitted, but this is very different from assuming that the results
show a genetic relation actually to exist. The main point is that,
even if the results should be nearly identical, it may be entirely mis-
leading to infer that ancestral characters have reappeared.

In some cases an extra digit or toe may regenerate on the leg of
a salamander, and this too has been interpreted as a return to an
ancestral condition. But Tornier has shown, as has been stated,
that several additional digits, or even a whole extra hand, may
be produced by wounding the leg in certain ways, and these too
would have to be interpreted as ancestral, if the hypothesis is carried
out logically. It has been shown by King that one or more additional
arms may be produced in a starfish by splitting between the arms
already present, and if we accepted evidence of this sort as having
any value in interpreting lines of descent we should conclude ^ that

^ King pointed out the fallacy of this argument.

PHYLOGENETIC AND ONTOGENETIC PROCESSES 21 5

the ancestors of the starfish had six, seven, or more arms according
to the number that can be produced artificially, etc. Therefore, until
further evidence of a more convincing kind is forthcoming, we can
safely, I think, decline to accept the results, so far known, as having
any value in interpreting the relationships or the descent of the
animals.

CHAPTER XI

REGENERATION IN EGG AND EMBRYO

Not only do adult organisms have the power of regeneration, but
embryos and larval forms possess the same power, and even portions
of the segmenting, and also the unsegmented, egg may be able not
only to continue their development, but in many cases to produce
whole organisms. Haeckel observed in 1 869-1 870 that pieces of the
ciliated larvae of certain medusae, and even pieces of the segmented
egg, could produce whole organisms. The more recent experiments
of Pfliiger ('83) and of Roux ('83) on the frog's egg mark, however,
the beginning of a new epoch in embryological study. The expla-
nation of this is to be found, I think, not only in the introduction of
experimental methods, but also in the fact that Pfliiger and Roux
realized the important theoretical questions involved in their results.

Pfliiger's experiments were made by changing the conditions
under which the egg develops in order to determine what factors con-
trol the development. Since these experiments were made with whole
eggs, the problems of regeneration were not directly involved in his
results, although his conclusions are of great importance in connec-
tion with questions concerning the regeneration of the egg. A part
of Roux's work dealt directly with the development of a new organ-
ism from a piece of the egg or of the embryo. Roux's principal dis-
covery 1 ('88) was that a half -embryo develops from either of the first
two blastomeres of the frog's egg, if the other blastomere has been
injured or destroyed, but that subsequently the missing half of the
embryo is " post-generated." Roux was led to this experiment by his
discovery that the plane of the first cleavage of the egg corresponds
very often to the median plane of the body of the embryo.^ This
relation suggested that there might be some causal connection between
the two phenomena in the sense that the first cleavage plane divides
the material for the right side of the body from that of the left side.
In a descriptive sense this would be, of course, true if the two planes
do really correspond, and if there was no later shifting of material

1 Roux's earlier experiments in 1885, in which the unsegmented or segmented egg was
stuck and a part of its contents removed, the remaining part making a whole embryo, will
be considered in another connection.

2 This had been first discovered by Newport in 1851.

216

REGENERATION IN EGG AND EMBRYO

217

across the middle line, but whether the two phenomena are causally
connected, or are merely due to a coincidence, could only be determined
by further experiment. The observations themselves are not beyond
question, for the two planes do not always coincide, and may be even

Fig. 61. — After Roux. A Section of semi-blastula of frog's egg. i5. Half-embryo. C. Cross-
section of last (reversed right and left in B and C). D. Anterior half-embryo.

ninety degrees apart. These cases of divergence were thought by
Roux to be due to an unobserved shifting of the developing embryo,
but it is improbable that all cases can be accounted for in this way.

Roux carried out his experiment by plunging a hot needle into
one of the first two blastomeres, so that it is injured to such an extent

2 1 8 RE GENERA TION

that its development is prevented. The same needle, without heating
again, was used for one or two other eggs, for, if the needle had been
so hot in the first instance that both blastomeres had been injured by
the heat, this might not happen in the second or the third ^gg. It
was found that amongst the eggs that had been operated upon in this
way, some had been so much injured that neither blastomere developed,
others had been so little injured that both blastomeres developed, but
in the successful operations the uninjured blastomere developed, while
the injured one did not. In the last case the uninjured blastomere
divided, and produced a large number' of cells. A segmentation
cavity was present in the upper part of the hemisphere (Fig. 6i, A).
The injured half remained in contact with the other, completing the
sphere, but it did not segment. A half-embryo developed from the
uninjured half, as shown in Fig. 6i, B, C. This embryo has a half-
medullary fold along the side in contact with the injured half. At the
anterior end somewhat more than half a head is present, and at the
posterior end there is a half-blastopore. The cross-sections^ (Fig. 6i,
C\ through the embryo, show that beneath the half-medullary fold a
rod-like notochord is present, which is made up apparently of fewer
cells than the normal notochord, but it has, in cross-section, a round
and not a half form. At the side, the mesoderm is present, as in the
normal embryo, and it has produced the characteristic mesoblastic
somites. An archenteron is formed in the half-embryo, and, since it
is smaller than the normal, it may, perhaps, be called a half-archen-
teron. The embryo is, therefore, in most respects a half-structure.
The head is, however, nearly a whole head, but whether this is due
to a whole head developing out of material derived entirely from one
of the two blastomeres, or whether, as Roux supposes, a portion of
the material of the injured blastomere has been worked over, i.e.
"post-generated," remains, I think, an open question.

The results of this experiment seem to confirm Roux's conjecture
that the material of each of the first two blastomeres is of such a sort
that it gives rise to half the embryo, and, if so, there would be some
probability that there is a causal connection between the first cleavage
and the separating out of the parts of the embryo. In fact, Roux drew
this conclusion, and even attempted to show how such a qualitative
division is brought about. It should not be overlooked, however, that
this conclusion goes beyond the legitimate bounds of deduction from
the results, since the half-development takes place while the injured
half retains its connection with the developing half, the former still
remaining alive. On the other hand, the presence of the injured half
makes the experiment more suitable to demonstrate that each of the
first blastomeres gives rise, under normal circumstances, to half of the
^The cross-section C is reversed as compared with the half-embryo B.

KEGENERATION IN EGG AND EMBRYO 219

embryo. If one half had been removed, we can foresee that its
absence might lead to other comphcations that would affect the
result.

The most important outcome of this experiment is, I think, to show
that a half-structure may develop by itself, i.e. that there is a certain
amount of independent power of development in the parts of the egg.

Roux also tried to show that if, after the second cleavage has been
completed, the two blastomeres that lie on opposite sides of the first
cleavage plane are killed by a hot needle, the remaining two produce
either an anterior or a posterior half of an embryo. An embryo
derived from the two "anterior" blastomeres is represented in Fig.
61, D. The anterior half of the body is present. Posteriorly the
half-embryo abuts against the injured half. It is possible, I think,
that this embryo may represent the anterior half of a whole embryo
of half size that has been prevented from closing in posteriorly by the
mass of injured material of the undeveloped blastomere. Roux did
not determine positively whether the two "posterior" blastomeres
could give rise to posterior half-embryos ; one embryo in his opinion
appeared to bear out this interpretation. This part of Roux's work
is, it seems to me, not so satisfactory as the part dealing with the
first two blastomeres, and we may leave it, for the present, out of the
discussion, and consider only the result of the first experiment, in
which one of the first two blastomeres was injured. Since the prob-
lems involved in the two cases are essentially the same, nothing will
be lost by dealing with the first case alone.

The uninjured blastomere first gives rise to a half-embryo. After
this has been accomplished, other changes take place that " reorgan-
ize," according to Roux, the material of the injured half in such a way
that the missing half of the embryo is formed by a process that Roux
calls "post-generation." This process can be studied only by means
of sectioning the embryos, and since the eggs may be injured to a
varying extent, there must be some uncertainty in making out the
sequence of events. It is found that the yolk of the injured blasto-
mere is vacuolated in places, and that the protoplasm in the path of
the needle has been killed (Fig. 61, A). Irregular pieces of chromatin
are found in the protoplasm, which seem to come from an irregular
breaking up of the nucleus.

The changes that lead to the reorganization of the injured half
may take place at different times in different eggs. Roux describes
three kinds of reorganization phenomena. The first includes the
formation of new cells in the injured half. Nuclei, surrounded by
finely granular protoplasm, appear in the protoplasm of the injured
blastomere. These nuclei arise from two sources : in part from the
scattered chromatin of the injured blastomere itself, and in part from

220 ^ REGENERATION

nuclei, or from cells without walls that have emigrated from the
developing half. Around these nuclei, as centres, the protoplasm
(with its contained yolk) of the injured half breaks up into cells. This
cellulation of the yolk may take place in different eggs at different
times. In some cases it may not have appeared as late as the gas-
trula stage of the uninjured half; in others, it may take place at the
time when the uninjured half is segmenting. ^ The formation of the
cells in the injured half begins always near the developing half, and
extends thence into the injured parts. The new cells are of different
sizes, but are larger than those of the uninjured half.

The cellulation of the yolk takes place only in the least injured
parts of the protoplasm. Where the protoplasm and yolk have been
much injured, they are changed over by the second method of reor-
ganization. This part of the blastomere is either actually devoured
by wandering cells, or is slowly changed under the influence of the
neighboring cells, so that it becomes a part of these cells.

The surface of the injured half is covered over by ectoderm that
grows directly from the developing half (third method of reorganiza-
tion),— at least this happens where the protoplasm has been much
injured. In other parts of the injured half the new cells that have
appeared in this part, and that lie at the surface, become new
ectoderm.

Post-generation now begins in the reorganized and cellulated
half ; the cells become changed over into the different layers and
organs that make the new half-embryo. A few hours or a night is
sometimes sufficient to change a hemi-embryo into a whole embryo.
The new half-medullary fold develops from the new ectoderm to
supplement the half already present. The mesoblast appears over
the side. Its upper part seems to come from the uninjured meso-
derm that has grown over to the other side, but this is added to at the
free edge by cells that belong to the newly cellulated part. The new
differentiation is, in general, in a dorso-ventral direction. The lack-
ing half of the archenteron arises in connection with the half of the
archenteron already present in the hemi-embryo. The yolk cells
arrange themselves radially, and a split appears in the post-gen-
erated part, extending from the archenteron of the hemi-embryo.
The split opens, and the new half-archenteron appears. In general,
Roux states, the post-generation of the organs of the injured half
proceeds from the already differentiated germ-layers of the hemi-
embryo. The post-generation begins where the exposed surfaces of
the germ-layers of the hemi-embryo touch the newly cellulated regions
of the injured half.

^This difference is due, I suppose, to the amount of injury that the nucleus of the
injured half may have suffered.

REGENERATION IN EGG AND EMBRYO 221

It is most difficult to account for these post-generative changes,
since the new part has, according to Roux, a double and even a three-
fold origin. The pieces of the old nucleus, he admits, may take a part
in the formation of the new cells ; wandering cells migrate from the
yolk mass of the old half into the new, and the cells of the formed
germ-layers may be pushed over to the other side. Since a certain
share, and perhaps a large share, of the new cells comes from the
hemi-embryo, it is clear that, in addition to the power of self-differen-
tiation shown by the uninjured blastomere, we must also ascribe to it
certain regenerative powers, at least to the extent that each kind of
cell that comes from it can give rise in the injured half to cells hke
itself, and produce similar structures in the other half.

If then, as Roux supposes, the development of the Qg^ consists in
an orderly, qualitative series of changes that lead to the subsequent
differentiation, we must also suppose that the new parts are gifted
with latent powers by virtue of which they can re-create all parts of
the other half. Roux supposes, in fact, that each cell carries with it
a sort of reserve-plasm, that is dormant in ordinary development but
is awakened when any disturbance of the normal development takes
place. Objections have been made to this subsidiary hypothesis,
since the addition of this to the original assumption of a series of
qualitative changes involves such complications that the view can
hardly be considered a probable one. This objection is, I think, not
as strong as certain critics believe, since the facts of development
show beyond a doubt that although the Q,g^ has the power of pro-
gressive change it has also, as certain experiments show, the power
of reorganization, if the ordinary course of events is interrupted.
This admission by no means throws us back upon Roux's hypothesis,
for, as will be shown later, a different conception of the development
may better account for both phenomena.

Inasmuch as a good deal of discussion has taken place in regard
to the process of post-generation described by Roux, it should be
stated that Endres and Walter reexamined the process, and found, as
had Roux, that the reorganizing cells migrate from the uninjured to
the injured side, and around them the protoplasm of that side makes
new cells. They found that the injured half is directly overgrown
by the ectoderm from the developing half. When the material of the
injured blastomere is only incompletely reorganized, there is formed,
after post-generation, an embryo that has a protrusion of yolk in the
dorsal part of the body. When the injured material is completely
worked over, a perfectly formed embryo may result. The typical
half-embryos that Roux obtained were also obtained by Endres and
Walter. They deny that whole embryos develop from one of the
first two blastomeres, as Hertwig affirms.

222

REGENERA TION

Hertwig repeated Roux's experiment and obtained results entirely
"different from those of Roux. He injured one of the first two blasto-
meres of the frog's ^g^ with a hot needle, or by means of a galvanic
current. Hertwig states that after the operation the o.g'g turns so
that the uninjured part lies uppermost. This is owing, he thinks, to
the appearance of a blastula or of a gastrula cavity in the developing

V

Fig. 62. — After O. Hertwig. A. Section through a frog's egg (blastula stage) in which one blasto-
mere had been killed. B. Same. Gastrula stage. C. Later gastrula stage. Z?, E. Surface
view of embryos from one of first two blastomeres. F. Same as last (E). Dorsal view.
G. Ventral view of last. H. Dorsal view of another embryo, lying in a very eccentric position.
/. Later stage of embryo from one blastomere. Other injured blastomere nearly covered
over. J. Section through gastrula stage of embryo from one of first two blastomeres.
K. Cross-section of the embryo shown in F and G.

part. The segmentation cavity is found in many cases surrounded by
the cells of the segmenting half (Fig. 62, A), but at other times at the
border between the new and the old parts. In still other cases the
cavity may lie eccentrically, and in some cases the floor of the cavity
may be bounded by the yolk substance of the injured half. An em-
bryo appears on the upper, uninjured part, though it is not, according to
Hertwig, a half-embryo, but a whole embryo, or at least one approach-

REGENERATION IN EGG AND EMBRYO 223

ing that condition (Fig. 62, D, E, F, G, H). It is shorter than the
normal embryo, and its posterior end is incomplete. When these
embryos are cut into sections, it is found that the part that has
developed corresponds to the dorsal part of a normal embryo, but
the ventral part is continuous with the yolk substance of the injured
half (Fig. 62, B, C, J, K). Hertwig interprets these embryos as
forms in which the yolk portion of the developing half, together with
the whole of the injured blastomere, represents a yolk mass that has
not yet been enclosed by the margin of the developing part.

In nearly all the embryos that Hertwig has described, the medul-
lary folds appear eccentrically on the developing half (Fig. 62, D, F,
K), and in some cases they may lie so far to one side that they are
situated almost at the edge ; and the less development of one of the
folds makes the embryo appear almost like the hemi-embryos obtained
by Roux. In fact, one embryo seems to have been a true hemi-
embryo.

Hertwig attributes the eccentric position of the embryo to the
eccentric position of the blastopore of an earlier stage, but he does not
attempt to account for the eccentricity of the latter.

It is significant in this connection to find that Hertwig obtained
other embryos that show a condition of "spina bifida." In these
there is an exposure of yolk in the mid-dorsal line between the halves
of the medullary folds. Still other embryos in the same series of
experiments were only slightly injured, and developed nearly nor-
mally. In these cases, Hertwig thinks, the blastomere that was
stuck had been only slightly injured, and had partly developed. I
have also often observed in this experiment that the injured blasto-
mere may segment and add cells to the developing half, but in such
cases the development of the injured half may be less regular than is
that of the uninjured half. It seems to me not improbable that in sev-
eral of the embryos described by Hertwig both blastomeres have taken
part in the development. The main points of difference between
the results of Roux and of Hertwig cannot, however, be explained
in this way, and the explanation is to be found in another direction.

Hertwig emphasizes the view that the injured blastomere is not
dead, but exerts an influence upon the other half — an influence of
the same kind as that which the yolk of a meroblastic egg has on the
protoplasmic portion of the egg from which the embryo arises. He
ventured to prophesy that if the injured yolk mass could be entirely
removed, the uninjured blastomere would produce a normal embryo
without defect, and one Hke the normal embryo in every respect
except in size.^

1 The development of isolated blastomeres of the ctenophore egg shows that this need
not be the case.

224

A' E GENERA TION

Roux interprets Hertwig's results as due to the sudden partial
post-generation of a part of the injured half of the Q.gg. He thinks
that a half-embryo had first developed, and then to this there has been

Fig. 63. — A. After Wetzel. Section through an egg (blastula stage) reversed at two-celled stage.

B. After Schultze. Double embryo, from reversed two-celled stage, united ventrally.

C, C^. Two views of another double embryo (united dorsally). C'^. Cross-section through
last. D. After Wetzel. Double embryo united laterally. Z)i. Section throitgh same.

REGENERATION IN EGG AND EMBRYO 225

quickly added a part of the missing side. This reply fails, however,
to meet Hertwig's description of the method of development of the
embryos. Later w^ork, however, has put us in a position to give a
more satisfactory account of the differences between the results of
Roux and Hertwig. It seemed to me that the two kinds of embryos
might be due to the different positions of the eggs after the operation.
It had been shown by Schultze ('94) that if a normal o.^^ in the two-
celled stage is turned upside down and held in that position two
embryos develop from the egg (Fig. 6-^, B, C, D). These embryos
are united in various ways, and arise presumably one from each of
the first two blastomeres. These results have been confirmed by
Wetzel, who examined more fully into the early development of the
twin embryos. He showed with much probability that the proto-
plasm rotates in each blastomere, so that in many cases the lighter
part flows, or starts to flow, toward the upper hemisphere of the tgg.
In this way similar protoplasmic regions of the two blastomeres
may become separated, and under these circumstances each blasto-
mere gives rise to a whole embryo. A cross-section through one of
the segmentation stages of one of these eggs is shown in Fig. 63, A.
The smallest cells are found at the outer side of each half, and the
two segmentation cavities lie one in the upper region of each hemi-
sphere. Some of the different kinds of embryos that develop from
inverted eggs are shown in Fig. 6^), B, C, D. They are united in Fig.
63, B, by their ventral surfaces, and in Fig. 6^, C, C^, C^, by their
dorsal surfaces, and in Fig. 63, D, D \ at the sides. These differences
are probably accounted for by the different ways in which the proto-
plasm of the first two blastomeres rotated before the Q,gg divided.

A consideration of these results led me to carry out the following
experiment on eggs operated upon by Roux's method. After stick-
ing one of the first two blastomeres, some of the eggs were placed
so that the uninjured blastomere kept its normal position, i.e. with
the black hemisphere upward. Other eggs were turned, so that
more or less of the white hemisphere was upward. From the two
kinds of eggs two kinds of embryos were obtained. From those with
the black hemisphere upward the embryo was a half-embryo like that
described by Roux, while from the eggs with the white hemisphere
upward embryos developed that were in many respects whole embryos
of half size.i The explanation of this difference will be obvious from
what has been said. When the black hemisphere is uppermost the
contents of the uninjured blastomere remain as in the normal o^gg,
and a half-embryo results. When the white hemisphere is uppermost
the contents of the uninjured blastomere rotate, so that it generally
shifts its relation to the protoplasm in the other injured half, and a

1 In one case a half-embryo resulted.
Q

226 RE GENERA TION

whole embryo develops, as in Schultze's experiment. In one case I
obtained a half-embryo from an inverted ^gg. The result did not
appear to be due to a lack of rotation of the protoplasm, because the
medullary folds were white, showing that the protoplasm must have
changed its position. The result can possibly be explained as due
to the protoplasm rotating in each blastomere along the line between
the halves, so that it still retains the same relation as that of the
normal two-celled stage.

The whole embryos of half size are generally imperfect in certain
respects on account of their union with the other half. They resemble
in all important points the embryos described by Hertwig, and I see
no grounds for interpreting them as embryos of a meroblastic type,
but rather as whole embryos of half size, whose development pos-
teriorly and ventrally has been delayed or interfered with by the
presence of the other blastomere.

It has not been possible to separate the first two blastomeres of
the frog's &gg, for if one is removed the other collapses. In the sala-
mander, that has a mode of development similar to that of the irog}
it has been possible tp separate the first two blastomeres. Herlitzka,
who carried out this experiment, found that each blastomere gives rise
to a perfect, whole embryo of half size. We cannot doubt, I think,
that the same power of producing a whole embryo is also present in
each of the first two blastomeres of the frog's ^gg. When the two
remain in contact in their normal relation to each other, each produces
only a half ; when like regions of the two blastomeres are separated,
each produces a whole embryo. Thus we see that whatever the fac-
tors may be that determine the development of a single embryo from
the &gg, still each half, and perhaps each fourth also, has the power of
producing a whole embryo.

In later papers Roux has stated that he had also, even in his
earlier experiments, found other kinds of embryos than the half-em-
bryos that he described. Some of these were whole embryos that
had developed from the uninjured blastomere without the injured one
taking any part or only a very small share in their formation. He
found, he states, all stages between those embryos that had used up
all the yolk material of the injured side (though post-generated) and
those that had not used any part of it. The latter kind of embryo he
does not recognize as a whole embryo of half size in the sense that a
single blastomere has developed directly into a smaller whole embryo,
but he believes that there must have been formed at first a half-blas-
tula, half-gastrula, half-embryo, and that the last stage completed
itself laterally without using any material from the injured half.

^ The plane of the first cleavage has been shown in two urodeles to correspond, not to the
median longitudinal plane, but to a cross-plane of the embryo.

REGENERATION IN EGG AND EMBRYO 22/

That the uninjured blastomere may at first segment as a half is not
improbable, but that whole embryos are formed only by the formation
of new material at the side of a half-embryo is, I think, hardly possible,
since the results of Schultze, Wetzel, Hertwig, and myself show that
a whole embryo may develop directly out of the material of a single
blastomere.

Spemann (1900) has carried out some novel experiments on the
eggs of triton, and has shown how in another way double structures
may be produced. If a ligature is tied loosely around the Q.g^ at
the first cleavage exactly along the division plane between the first
two blastomeres, it will be found later that the long axis of the single
embryo Hes, in the great majority of cases, across the ligature, and
only in a small percentage of cases does the median plane correspond
with that of the ligature, and, therefore, with the first cleavage plane.

If one of the latter eggs is allowed to develop to the blastula
stage, and the ligature is then drawn tighter, so that the blastula
is completely constricted, an embryo develops from each half.

If one of the former eggs is allowed to develop to a stage when the
medullary plate is laid down, but is not yet sharply marked off, and
the ligature is then tightened, there will be formed (the plane of con-
striction being across the medullary plate) from the anterior part a
normal head with eyes, nasal pits, ears, and a piece of the notochord,
and from the posterior part there will be formed, at its anterior end,
another new head just behind the ligature. Ear-vesicles develop in-
this part at the typical distance from the anterior end. The brain
that develops has a typical cervical curvature, and eye evaginations
appear at the anterior end. The chorda, that extended at first to the
anterior end of this region, is partially absorbed.

If the ligature is drawn tighter at a later stage, when, for instance,
the medullary plate is plainly visible but is still wide open, a different
result is obtained. The posterior part no longer forms a new head at
its anterior end, but develops into those structures that it would form
normally. In some cases it was found that the region from which
the ear develops had been pinched in two, and in consequence a
small vesicle appears in front of the constriction and another behind it.

In those cases in which the ligature lies in the median plane of the
embryo, it is found that a double anterior end is produced. As the
embryo develops it tends to elongate, and in consequence the mate-
rial is pushed forward on each side of the ligature. A double head is
the result. The extent of the doubhng depends on the depth of the
constriction between the halves. In the most extreme cases two com-
plete heads are formed with an inner nasal pit, eye, and ear on each
head, as well as the normal outer ones. The results show that even
such complicated structures as the eyes and ears, etc., may arise

228

REGENERA TION

from parts of the body where they never appear under normal
conditions.

A series of experiments that have been made on the eggs of sea-
urchins has led to equally important results. The earliest experi-
ments are those of O. and R. Hertwig, who, in addition to studying
the effect of different drugs on the developing ^g^, found that
fragments of the eggs of sea-urchins, obtained by violently shak-
ing the eggs in a small vial, could give rise, if they contained a

Fig. 64. — Sea-urchin egg and embryo. A. Two-cell stage. B. Same, with blastoraeres separated.
G. Two half-sixteen-cell stages. C. Open half-blastula stages. D. One of last, later stage,
closed blastula of half size. H. Gastrula of half size. F. Whole pluteus of half size. H. A
hall-sixteen cell dividing in same way as a whole egg (eight cell) . /. Whole egg at sixteen-
cell stage.

nucleus, to small whole embryos. Boveri made the important discov-
ery in 1889 that if a non-nucleated piece of the Q.gg of the sea-urchin
is entered by a single spermatozoon, the piece develops into a whole
embryo of a size corresponding to that of the piece. Fiedler, in 1891,
separated the first two blastomeres by means of a knife, and found
that the isolated blastomere divides as a half, but he did not succeed
in obtaining embryos from the halves. Driesch has made many ex-
periments, beginning in 1891, with the eggs and embryos of the sea-
urchin. He separated the first two blastomeres ('91) by means of

REGENERATION IN EGG AND EMBRYO 229

Hertwig's method of shaking the eggs, and studied the development
of the isolated blastomeres. He found that the cleavage was strictly
that of a half, and not like that of a whole o.^^. The normal ^^^
divides into two, four, and eight equal parts. At the next division, four
of the cells divide very unequally, producing four very small cells,
the micromeres, at one pole. The four cells of the other hemisphere
divide equally (Fig. 64, /). The isolated blastomere divides at first
into two equal parts, then again into equal parts. At the next divi-
sion two of the cells produce micromeres and two divide equally (Fig.
64, G). This is exactly what happens at this division in each half, if
the blastomeres are not separated. In later stages a half-sphere is
formed that is equivalent to half of the normal sphere (Fig. 64, C).
The open side corresponds to the side at which the half would have
been united to the other half. Thus up to this point a half-cleavage
and a half-blastula have appeared.^

In later stages the open half-blastulae close in, producing a whole
sphere that becomes perfectly symmetrical (Fig. 64, D). A symmetri-
cal gastrula develops (Fig. 64, ^) by the invagination of a tube at one
pole, and a symmetrical embryo is formed (Fig. 64, F^ that resembles
the normal embryo except in point of size.

Driesch has also found that a number of twin embryos arise from
the shaken eggs. They arise from eggs whose blastomeres have been
disturbed or shifted, so that each produces a small whole embryo, the
two embryos being united to each other in various ways.

In a second paper, published in the following year, Driesch ex-
tended his experiments, and attempted to discover how far the " inde-
pendence " of the blastomeres extends ; i.e. he tried to find out if all
the blastomeres resulting from the cleavage are alike. When one
of the first four cells is separated^from its fellows by shaking, it
continues to divide, in most cases as a quarter, and produces later
a small spherical blastula. Many of these blastulae, although
apparently healthy, never develop further, although they may remain
alive for several days. In one experiment only eight out of twenty-
six reached the pluteus stage, with a typical digestive tract and
skeleton.

From these experiments Driesch drew the important conclusion
that the cleavage cells or blastomeres of the sea-urchin's &gg are
equivalent, in the sense that if they were interchanged a normal em-
bryo would still result. A somewhat similar view is expressed in the
dictum that the position of a blastomere in its relation to the others
determines what part it will produce, if its position is changed it
gives rise to another part, etc., — or, expressed more concisely, the

1 In some cases, especially in sphserechinus, even at the eight-celled stage, the blasto-
meres seem to shift their position, so that a whole sphere of half size is formed.

2 3 O RE GENERA TION

prospective value of a blastomere is a function of its position. ^
Driesch extended these experiments further in 1893. His aim was
to separate different groups of cells at the sixteen-cell stage in orde:^
to see whether the cells around the micromere pole (or "animal pole ")
if separated from those of the opposite (or "vegetative pole") could
produce a whole embryo, etc. Eggs whose membranes had been re-
moved by shaking immediately after fertilization were allowed to
develop normally to the sixteen-cell stage and were then shaken into
pieces. Amongst the groups of cells that were present those that con-
tained the micromeres were picked out. It was found that they give
rise to whole embryos. In order to obtain cells that belong to the
vegetative hemisphere, the blastomeres were shaken apart at the
eight-cell stage, and those groups of cells that in later divisions did
not produce micromeres were isolated. From these also whole em-
bryos develop. The results show that the cells of both hemispheres
are able to produce whole embryos, and that at the sixteen-cell stage
the different parts of the &^^ are still capable of producing all parts
of the embryo. It is important to observe that the results of the
experiment do not show that if the normal development goes on
undisturbed any part of the Q.gg may become any part of the em-
bryo, for it is highly probable that a definite region of the egg may
always produce a definite part of the embryo. The results do show,
however, that, even if this is true, any cell has the power of produc-
ing any or all parts of the embryo if the normal conditions are
changed.

In connection with these experiments Driesch discussed the fac-
tors that determine the axial relations of the embryo. If all the cells
have the power of producing all parts, what determines in the normal
development, and also in the development of a part of the whole, the
axial relations of the embryo.-* Driesch assumed that the Q,g^ has a
polar structure, and that the same polarity is found in all parts of the
protoplasm. Around this primary axis all the parts are alike or
isotropous.^ The origin of the mesenchyme and the position of the
archenteron, that develop at one pole, are determined by the polarity
of the protoplasm. The plane of bilateral symmetry may appear in
any one of all the possible radial planes around the primary axis.
The selection of a particular one is due to some accidental difference
in the structure of the protoplasm, or to some external factor. In
later papers Driesch modified this view, and assumed that along with
the primary polarity a bilateral structure also exists in the proto-
plasm.

1 Hertwig had a year before expressed a similar view in regard to the equivalency of the
blastomeres.

2 A view advanced Ijy Pfliiger.

REGENERATION IN EGG AND EMBRYO 23 I

Wilson ('93) Studied the development of isolated blastomeres of
amphioxus, and found that it agreed in all essential respects with
the mode of development of the blastomeres of the sea-urchin. The
isolated blastomeres of the two-cell and four-cell stages produce whole
embryos, but the blastomeres of the eight-cell stage develop only
as far as the blastula. The blastomeres segment, after separation,
in most cases not as a part, but as a whole t-^g would divide,
although the cleavage of the one-eighth blastomere only approaches
that of the. entire Q.^g, but is never identical with it. Incompletely
separated blastomeres give rise to twins, triplets, etc. Wilson agreed
with the Hertwig-Driesch conception of the value of the early blasto-
meres, and accepted the view that the fate of each is a function of
its position, and that at first they are qualitatively alike. During the
early cleavage he supposed that a change takes place that is slight
at the two-cell stage, greater at the four-cell stage, and in the eight-
cell stage the differentiation has gone so far that the blastomere can
no longer return to the condition of the ovum. ** The ontogeny
assumes more and more the character of a mosaic work as it goes
forward."

Loeb ('94) showed that if the eggs of the sea-urchin are placed in
sea water, diluted by distilled water, the Q.gg swells and bursts its
membrane, so that a part of its protoplasm protrudes. Into this pro-
trusion some of the first-formed nuclei pass, and from both the part
remaining in the ^%^ membrane, as well as from the protruding part,
an embryo is produced, the two embryos often sticking together. In
several cases two to eight separate groups of blastomeres are formed
from one Q.^g and develop into whole embryos. ^

The question of the number of cells which are produced by the one-
half and one-fourth embryos had not up to this time been determined.
Until this was known it could not be stated whether the smaller
embryos were miniature copies of the normal embryos in all respects,
or whether they assumed the typical form with fewer cells. I found
('95) that the blastula from one of the first two blastomeres contains
half the number of cells produced by the whole embryo, and that in
the later stages also it contains only about half the normal number.
The one-fourth blastomere produces only a fourth of the whole num-
ber of cells, and yet can develop with this number, in many cases,
into a whole embryo. The one-eighth blastomere produces one-
eighth the normal number of cells. In most cases I found that these
one-eighth blastomeres do not produce embryos, but occasionally
they produce a gastrula, and probably a young pluteus stage.

1 The evidence to show that more than four and certainly more than eight such groups
that come from a single egg can produce a pluteus is, I think, insufficient, and the result
improbable.

232

REGENERATION

The development of nucleated fragments of the ^gg was also
studied in order to find out if they too produce a smaller number of
cells than does the whole egg, and a number in proportion to their
size. The problem is different in this case, because the nucleus has
not divided before the piece is separated, and the results ought to
show whether there is a prescribed number of divisions for the ^g^
nucleus, or whether the number of times it divides is regulated by
the amount of the protoplasm. It was found that the number of
cells produced by each fragment is in proportion to the size of the
piece. This shows that the division of the nucleus is brought to an
end when the protoplasm has become subdivided to a certain point.

A further examination of the number of cells that are invaginated
in these smaller " partial " larvae to produce the archenteron seemed
to show that they often use relatively more than their proportionate
number. The normal blastula of SphcBrechimis grmmlaris contains
about five hundred cells and turns in fifty cells, or one-tenth the total
number. The one-half and one-fourth embryos, and some of the
small embryos from the egg fragments, seemed to invaginate more
than one tenth of their total number of cells.

Driesch (1900) reexamined this point, and found that the em-
bryos from isolated blastomeres may use the proportionate number
of cells. I have made a new study of the problem on a larger scale
and have found that my earher statement, as well as that of Driesch,
is substantially correct, and that the difference that we found is due
to the time at which the embryos gastrulate. Thus the one-half
embryos and even the one-fourth embryos, that gastrulate as soon as
(or only a little later than) the normal, whole embryos, turn into the
archenteron about one-half and one-fourth the number of cells
invaginated in the whole embryo; but those partial embryos that
gastrulate later (as most of them do) turn into the archenteron more
than a half or a fourth of the number of cells turned in at first
by the whole embryo. This difference between the early and the
retarded partial embryos is in large part due to a slow increase of
cells that takes place during the delay in development.

Driesch ('95) found that pieces of the blastula wall of the sea-
urchin, if large enough, can also produce a gastrula and embryo. I
found that the number of cells in these pieces does not increase
appreciably after they are cut off (if the operation has been carried
out at the end of the cleavage period), and that the new embryo is
organized out of the cells present at the time of removal of the piece
from the wall. There is, therefore, in this case no chance for "post-
generation " by means of new cells produced at the side, which Roux
has supposed to take place in the frog embryo.

The development of pieces of the blastula wall, if they are not too

REGENERATION IN EGG AND EMBRYO

233

small, also shows that the lack of power to develop, found in some
of the one-fourth and in many of the one-eighth blastulas, is not
the result of any special differentiation that they have undergone
during the cleavage period, but is due to their size.

A recent series of experiments by Driesch (1900) on the develop-
ment of isolated blastomeres of the sea-urchin's &^g has given more
exact data in regard to their limit of power to produce embryos, and
has shown the possibilities in these respects of different parts of the
^%^. By means of a method discovered by Herbst (1900) it is pos-
sible to obtain isolated blastomeres more readily than by the some-
what crude shaking process. If the eggs, after fertilization and after
the removal of the membrane by shaking, are placed in an artificial
sea water, from which all calcium salts have been left out, the eggs
divide normally, but the blastomeres are not held firmly together, and
readily fall apart if the Q.^g is disturbed. By means of a fine pipette
any desired blastomere or group of blastomeres can be picked out.
If these are returned to sea water they continue to develop.

Driesch found that the one-half and one-fourth blastomeres
develop into proportionate gastrulae and larvae ; that the one-eighth
blastomeres, both of the animal and the vegetative hemispheres, some-
times produce gastrulae, and even the beginning of the larval stage
with the rudiments of a skeleton. There are certain differences
between the one-eighth larvae that come from the animal hemisphere
and those from the vegetative half. More of the one-eighth
blastomeres from the animal part of the q^^ die than from the
opposite part, but of those that remain alive a larger percentage
reach the gastrula stage than in the case of those from the vege-
tative pole ; their protoplasm moreover is not so clear as is that of
the larvae from the other hemisphere. These "animal pole" blasto-
meres develop faster than those of the other sort. The gastrulae
from the one-eighth blastomeres of the vegetative hemisphere do
not die so often after separation, the protoplasm of the larvae is
clearer, and they often produce long-lived blastulae with long cilia.
The blastulae often develop into gastrulae without mesenchyme.
These results show that although whole larvas may be produced from
the one-eighth blastomeres of both hemispheres, yet there are certain
characteristics that may be referred with great probability to differences
that are present in the protoplasm of the two hemispheres of the o^Z?)-
The differences are not in all cases sufficient to interfere with the
production of all the characteristic structures of the embryo, yet
traces of the origin of the larvae can be found in their structure. It
is probable that the so-called animal (or micromere) pole corresponds
to that part of the Q^g from which the archenteron is produced.
Hence the one-eighth blastulae from this hemisphere gastrulate

234 REGENERATION

sooner and in proportiojiately larger numbers than do those from the
opposite hemisphere. The vegetative hemisphere would correspond
to that part of the Q^'g from which the wall of the normal gastrula is
derived, and this may account for the clearer protoplasm of these
embryos, their inability in many cases to gastrulate, their larger cilia,
and the absence of mesenchyme in some of them. Driesch finds
that the number of cells that go into the mesenchyme of the partial
larvae is in proportion to the total number, and that the number of
cells in the archenteron is probably also proportionate.^

The smallest blastomeres that produce gastrulas are the one-
sixteenth products. Out of a total of 139 cases only 31 produced true
gastrulae, 5 produced gastrulae with evaginated archenteron, and 103
remained blastulae with long cilia. The one-thirty-second blasto-
meres were not observed to gastrulate.

Driesch ('95) has also made a study of the potentialities of the
blastula and gastrula stages of sphaerechinus, echinus, and asterias.
If a blastula is cut in half before the mesenchyme cells are produced,
both pieces produce gastrulae and larvae. Since some of the pieces
probably come from the animal hemisphere, and others from the vege-
tative hemisphere, it follows that all parts of the blastula possess the
power of producing whole embryos, and in this respect the potentiali-
ties are the same as for the blastomeres. If the experiment is made
at a stage just before the archenteron has begun to develop (Fig. 65,
A\ the results may be different. A half that contains the region
from which the archenteron is about to develop will produce a gastrula
and a larva (Fig. 6^, A, lower row to right of ^). A half that contains
only the opposite regions of the egg (Fig. 65, A, upper row) may in
some cases gastrulate,'^ often abnormally, but as many as half of the
pieces do not gastrulate. They may remain alive for a week or more,
and even produce a typical ciliated ring with a mouth in the centre,
but do not form a new archenteron. These important results show
that after the formation of the mesenchyme and archenteron at one
pole, the other cells of the blastula wall are no longer able to carry
out a process that the same cells were able to carry out at a slightly
younger stage, but whether this loss of power is connected with the
previous formation of the archenteron, or due to some other change
which has by this time taken place in the cells, cannot be determined
from the experiment. It is also important to note that these small
ectodermal blastulae can still develop whole, typical, ectodermal
organs, the ciliated ring and the mouth, and that the former especially
has the characteristic structure of the whole normal ring.

1 Driesch's figures seem to show, nevertheless, that the archenterons are proportionately
too large.

2 These may be pieces that were cut obliquely, as Driesch suggests, so that they con-
tain a part of the archenteric region.

REGENERATION IN EGG AND EMBRYO

235

Similar phenomena have been made out by Driesch in the devel-
opment of the archenteron of the same forms. At the end of the nor-

FlG. 65. — A. Blastula of sea-urchin beginning to gastrulate. Cut in half as indicated by line.
Two rows of iigures to right show development of upper and lower halves. B. Later gastrula
cut in half. Two rows of figures to right show later development. C. End of gastrulation
process. Embryo cut in half. Two rows of figures to right show later stages of each half.
D. Formation of endodernial pouches from inner end of archenteron. Embryo cut in two.
Two rows of figures to right show later stages.

mal gastrula period of the starfish embryo, there is produced from the
inner part of the archenteron two outgrowths, or pouches, that later
constrict off to give rise to the coelom sac and water-vascular system.

236 RE GENERA TION

If the gastrula is cut in two in such a way that the inner end of the
archenteron, i.e. the part from which the pouches develop, is cut off
(Fig. 65, C\ it is found that the piece containing the posterior part
of the archenteron closes in, forms a new sphere, and from the present
inner end of the archenteron (that has also healed over) a pair of
pouches is produced (Fig. 65, C, lower row to right of C\ These
pouches have arisen, therefore, from a more posterior part of the
archenteron than that from which the pouches normally arise.

If the same experiment is made at a later stage, when the pouches
have been given off from the archenteron (Fig. 65, D, lower row to
right of D), no new pouches are formed. This means that after the
archenteron has once produced its pouches it loses throughout all its
parts the power to repeat the process, although these parts possessed
this power at an earlier stage. It is a very plausible view that the
result is directly connected with the formation of the normal pouches,
although it is of course possible that some other change has taken
place in the archenteron that prevents the formation of the pouches.

In order to give as nearly as possible a consecutive account of the
experiments on the eggs of the frog and of the sea-urchin, a number
of other discoveries have been passed over. Let us now examine
some of the results on other forms.

Chabry, as early as 1887, experimented with the eggs of an ascid-
ian. By means of an ingenious instrument he was able to prick and
kill individual blastomeres. The results of his experiments were not
described very clearly, and later writers have interpreted his results in
different ways.^ Chabry stated that he obtained half-embryos from
one of the first two blastomeres, but his figures show, especially in
the light of later work, that the embryos were whole embryos of half
size, although certain organs, as the papillae and the otolith, may be
lacking.

Driesch ('95) reexamined the development of isolated blastomeres
in one of the ascidians, Phalliisia mammalata, and found that the
cleavage of blastomeres, isolated by shaking, is neither like that of
the whole Qg%, nor is it like that of half the normal cleavage, although
it shows some characteristics of the latter. A symmetrical gastrula
is produced, and from this a typical whole larva of half size. These
larvae lack, however, one or more papillae, and the otolith rarely
develops. The absence of these organs Driesch ascribes to the
rough treatment that the q.^% has received, since embryos from whole
eggs may sometimes lack these organs if the development has taken
place under unfavorable conditions. The isolated one-fourth blasto-
mere may also produce a whole larva.

Crampton ('97) has also studied the development of the isolated

1 Driesch, Hertwig, Roux, Weismann, Barfurth. For review see Driesch ('95).

REGENERATION IN EGG AND EMBRYO 237

blastomeres of another ascidian, Molgiila manJiattensis. He has more
fully worked out the cleavage, and finds that the isolated blastomere
segments as a part, i.e. as it would have segmented had it remained
in connection with the rest of the o:^^. In general appearance
the half-cleavage seems to differ from the half of the complete
■cleavage, because rearrangements of the blastomeres occur, but
despite these shiftings the form of the division is always like that of
a part. A whole embryo develops, although there may be defects
in certain organs, which are due, he suggests, to the smaller amount
•of material available for the development of the larva.

Zoja showed in 1 894-1 895 in a number of jellyfish that the iso-
lated blastomeres produce whole larvae of smaller size.^ In one form,
liriope, the endoderm that forms the digestive tract is normally de-
laminated at the sixteen-cell stage, each cell of the blastula wall
dividing into an inner and an outer part. In the blastula from the
•one-half blastomere this delamination also takes place when sixteen
cells are present, and not at the preceding cleavage when only eight
cells are present. In this form, therefore, the whole number of cells
develops before the delamination takes place, and the one-half larva
is composed of the same number of cells as is the normal embryo at
this stage, but the cells are only half as large. In other species the
endoderm appears to begin to develop in the half-larvae when only
half the total number of cells is present.

The conditions in the o^gg of the bony fishes are very different
from those in the preceding forms. The protoplasm, from which the
embryo is produced, accumulates at one pole to make the blastodisc.
After the cleavage of this blastodisc, the blastoderm that has resulted
grows over the yolk sphere at the same time that the embryo is form-
ing along one meridian. I carried out some experiments, in 1895,
on the eggs of FiindiUiis heteroclitiis. If one of the first two
blastomeres of the Q.gg of fundulus is destroyed, the remaining one
produces a whole embryo. If three of the first four blastomeres are
removed, the remaining one may produce a whole embryo of small
size. The problem of development is, in the case of the fish, different
from the other cases described, inasmuch as the whole yolk sphere is
left attached to the remaining blastomere and is covered over by cells
derived from this blastomere. The smaller embryo that is formed
lies on a yolk of full size.^

Wilson's work on amphioxus has been already described in con-

^ Bunting ('94) also found that isolated blastomeres of hydractinia make whole em-
bryos.

2 If the yolk of the dividing egg is partially withdrawn without disturbing the blasto-
meres, the form of the cleavage may be altered, but a normal whole embryo develops over
the smaller yolk sphere.

^38

REGENERA TION

nection with the experiments on the sea-urchin's eggs. Later I ('96)
also obtained whole larvae from one-half and one-fourth blastomeres,
and I also found that the one-eighth blastomeres do not develop
beyond the blastula stage. The number of cells of which the one-
half larva is composed is half that of the normal larva, and the one-

FlG. 66. — Ctenophore-egg and embryo. A. Normal sixteen-cell stage. B. Half-sixteen-cell
stage. C. Later half-segmentation stage. D. Later half-embryo. E. Corresponding whole
embryo. F. Half-embryo seen from side. G. Same seen from apical end. In F and G,
four rows of paddles present, three endodermal sacs and ectodermal stomach.

fourth larva is made up of one-fourth of the total number of cells.
In all the preceding cases in which the blastomeres have been sepa-
rated, a whole embryo has developed, although the cleavage was
often like that of a part. In one form, however, it has been found
that a whole embryo does not develop. Chun ('92) first showed that
the isolated one-half blastomere of the ctenophore &^g produced a

REGENERATION IN EGG AND EMBRYO 239

half-larva. He also inferred from certain incomplete embryos caught
in the sea, that these incomplete larvae could subsequently regener-
ate the missing parts. Driesch and Morgan ('95) studied the devel-
opment of the isolated blastomeres of another ctenophore, Beroe ovata.
They found that the isolated one-half blastomere divides exactly as a
half of the whole ^^^ (Fig. 66, A, B, C). It remains more or less a
half-structure, even after the ectoderm has grown over the whole sur-
face (Fig. 66, D). The invagination of ectoderm, to form the so-called
stomach, that takes place at the lower pole of the whole embryo, is
formed at one side of the lower pole in the half -embryo (Fig. 66, F, G).
It pushes into the endodermal yolk mass, and lies not in the middle,
but somewhat to one side. In the normal embryo there are formed
four endodermal sacs or pouches in the central yolk mass that become
connected with the inner end of the ectodermal stomach, around
which they lie symmetrically. In the half-embryo two sacs are
formed, and in addition a smaller third sac, which always lies on the
side of the stomach that is nearest the outer wall (Fig. 66, F, G). The
embryo is, therefore, somewhat more than half the normal embryo in
regard to the number of its endodermal sacs.

There are present eight meridional rows of paddles in the normal
embryos of the ctenophore. They lie symmetrically on the sides,
converging towards an apical sense organ. In the one-half larva
there are always only four of these rows of paddles that are not
equally distributed over the surface, since on one side there is a wider
gap between two of the rows than elsewhere (Fig. 66, G). The
sense plate also lies somewhat eccentrically, i.e. more towards the
side corresponding to that at which the other blastomere lay.

If the one-fourth blastomeres are separated, each continues to seg-
ment as though still a part of the whole. A one-fourth embryo
develops that has an unsymmetrical stomach, with tcao endodermal
sacs. There are only two rows of paddles. The embryos are, there-
fore, in several respects one-fourth embryos, but the presence of two
endodermal sacs, instead of only one, shows that in this particular,
at least, the embryo is more than a fourth of the whole.

The part of the work of Driesch and Morgan, that has a special
bearing on the interpretation of the one-half and one-fourth develop-
ment of the isolated blastomeres, is that in which some experiments
are described which consisted in cutting off portions of the unseg-
mented Q.gg. If a fertiHzed but unsegmented Q.gg is cut in two by
means of a small pair of scissors, the part that contains the nucleus
may segment, and give rise to an embryo. The division is generally
like that of a part, and in such cases an incomplete embryo develops.
The embryo may have fewer rows of swim-plates than has the normal
embryo, and fewer endodermal sacs, and the stomach may be in an

240 REGENERATION

eccentric position. The embryos resemble in every respect the incom-
plete embryos from isolated blastomeres. It is important to note that
although the embryos from isolated blastomeres resemble those from
pieces of the segmented o,^^, in the former case the nucleus has
divided once, and each blastomere contains half of the original
nucleus, while in the latter case the entire segmentation nucleus is
present in the piece. These facts seem to show that in this q^^ the
incomplete development is directly connected with the protoplasm,
and not with the nucleus, — a view that is maintained by Driesch and
Morgan in connection with these experiments.

It was found in one or two instances that the nucleated pieces
divided in the same way that the whole Qg^ did, except that the blas-
tomeres are proportionately smaller. From pieces of this kind whole
embryos of small size developed. In this case we must suppose that
the protoplasm has succeeded in rearranging itself into a new whole
of smaller proportions.^

Crampton ('96) has shown in a mollusk, Ilyanassa obsoleta, that
when a blastomere is separated from the rest, the cleavage proceeds
as though the blastomere or its products were still present, and the
larva is defective in those organs that are normally derived from that
blastomere. These results are in line with those on the ctenophore
&gg. Fischel (1900) has also made some experiments on the seg-
mented Q.gg of the ctenophore, and has confirmed several of the results
obtained by Driesch and Morgan. In addition he has tried the effect
of disturbing the first-formed cells by pushing them over each other,
so that their relative positions are changed. He finds as a result
that the paddles, sense organ, etc., appear in unusual positions, and
the latter may be doubled. This shows that we must regard the
material or structural basis of the organs as present very early in
the different parts of the Qgg, and that the organs develop without
much regard to their relation to other organs.

Ziegler ('98) has also made some observations on the &%g of this
same ctenophore, that bear directly on some of the questions here
raised. His study of the cleavage shows that the micromeres arise
from the part of the &gg that is opposite the pole at which the
first cleavage furrow appears — the animal pole. Fischel's results
have shown that the paddles and the sense organs arise from these
micromeres, for, if the latter are displaced the former are also.

Ziegler performed the experiment of cutting off that part of an Q.gg
(which has just begun to divide) lying opposite the region in which
the first furrow has appeared. In this way there was removed
from the unsegmented ^gg the part from which the micromeres

1 We offered as a possible explanation in this case that the egg had been cut in two
symmetrically with reference to the eccentric nucleus.

REGENERATION IN EGG AND EMBRYO 241

develop. Ziegler found that the micromeres still arise, and that from
such pieces larvae develop that have eight rows of paddles and four
endodermal sacs. In one case two of the sacs were smaller than the
others ; in another case one of the four was very much smaller than the
rest. In another operation a large piece was cut from the egg, leaving
a small nucleated piece that divided into two blastomeres of unequal
size. An embryo developed from this small piece with four endoder-
mal sacs, and only four well-developed rows of paddles. The four
rows of paddles that were lacking were represented by two groups of
a few plates each.

Ziegler gives a different interpretation of these results from that
which Driesch and Morgan have offered. He interprets the last ex-
periment, in which after the operation the piece divided into two
unequal parts, and only four rows of paddles appeared, as meaning
that the development of these organs on the smaller part is sup-
pressed on account of the small size of the part. If the part had
been still smaller all trace of the missing paddles might disappear, as
he thinks was the case in certain experiments of Driesch and Morgan.
There can be, I think, little doubt that if a piece is small enough, the
result would follow as Ziegler supposes. It does not seem probable,
however, that the pieces were really below the lower limit in the
experiments of Driesch and Morgan, since the smaller blastomere
was in one case as large as the whole piece {i.e. as both blastomeres
taken together) in one of Ziegler's experiments.

Ziegler's results show very clearly that we are not obliged to
think of the substance of the micromeres as laid down in the proto-
plasm of the ^g^, and hence there is no ground for supposing the
substance of the paddles is necessarily present in the vegetative
hemisphere of the Q.gg. His results^ show that if the vegetative part
is cut off, miicromeres and paddles are still formed, although that
part of the ^gg substance from which they normally arise has been
removed. It should be pointed out, in this connection, that Driesch
and Morgan did not suppose that the bases of the micromeres, or of
the paddles, are actually laid down in a definite part of the proto-
plasm of the Qgg. They had also observed that in some cases whole
embryos arose after a part of the Qgg had been removed, and this
they attributed to the symmetrical position of the cut in relation
to the organization of the Q.gg. Ziegler's operations were made more
or less in this symmetrical plane, excepting the one that gave rise to
an incomplete embryo. Driesch and Morgan held that the formative
factors become localized in the protoplasm, rather than arise from
the nucleus, but pointed out that these observations do not lead to
His's conclusion of localized germ areas in the Qgg.

CHAPTER XII

THEORIES OF DEVELOPMENT

The experimental work that Pfliiger carried out in 1883 on the
effect of gravity on the cleavage of the frog's egg, and the con-
clusions that he drew from his experiments, mark the starting-
point for the modern study of experimental embryology.^ We can
trace the influence of Pfliiger's results through most of the more
recent work, and one of the conclusions reached by Pfliiger, namely,
that the material of the egg may be divided by the cleavage planes
in any way whatsoever without thereby altering the position of the
embryo on the egg, is, I think, one of the most important results that
has yet been reached in connection with the experimental work on
the egg. Pflijger's analysis of the factors that direct the develop-
ment has also an important bearing on the interpretation of the
development of a whole embryo from a part of an egg.

Pfliiger found that in whatever position the frog's egg is turned
before it begins to divide, the first two planes come in vertically, and
the third horizontally, and that later the smallest cells are always
formed in the upper hemisphere. He concluded, therefore, that
gravity has some sort of influence in determining the position of the
planes of cleavage. Pfliiger observed that the position of the median
plane of the body of embryos that have developed from eggs turned
into unusual positions does not, as a rule, correspond to the plane of
the first cleavage, but that the embryo generally lies on that meridian
of the egg that passes through the primary egg axis and the highest
point of the egg in its new position. Since any meridian may happen
to be placed uppermost, the embryo may, therefore, develop upon
any one of the primary meridians, and hence the material must be
isotropous around the primary axis. Furthermore, since the embryo
appears always below the middle of the egg, in whatever position
the egg may lie, we must conclude that in each meridian the material
is also isotropic.

It may be pointed out that while more recent work has substanti-
ated, on the whole, the latter conclusions^ of Pfliiger, just stated, still

1 These experiments have been quite fully described in my book on T/ie Developinent of
the Frog's Egg.

2 Not, however, the supposed action of gravity on the egg.

242

THEORIES OF DEVELOPMENT 243

the results of studies of regenerative phenomena of organisms show-
that the conclusions are not necessarily the only ones deducible from
the experiments; for, although it may be true that any possible primary
meridian of the egg may become the median plane of the body of the
embryo, it does not follow that there is no one organized plane always
present in the normal ^g^, i.e. the ^gg may not be entirely isotropic.
That this may be the case is shown in the regeneration of pieces
of adult animals in which a piece cut to one side of the old median
plane may develop a new plane of symmetry of its own. This possi-
bility must be also admitted for the Q.gg. If we substitute the term
" totipotence," meaning that any meridian of the Q.gg has the possi-
bihty of becoming the median plane of the embryo, in place of
Pfliiger's term " isotropy," we remove this element of possible error
from his statement.

Roux and Born have shown that the only action that gravity has
on the frog's ^gg is to bring about a rearrangement of the contents
of the Qgg, a phenomenon that Pfliiger had not observed. The lighter
part flows to the highest region of the Qgg, and the heaviest to the
bottom of the Q.gg, hence the change in the position of the cleavage
planes observed by Pfluger that begin in the upper, more protoplasmic
part of the &gg.

Another series of experiments, that we also owe, in the first place,
to Pfluger ('84), consist in compressing the Qg'g before and during
its cleavage. The position of several of the cleavage planes may be
altered, yet a normal embryo develops from the o^gg. The same
experiment has been repeated by Hertwig ('93), and by Born ('93),
on the frog's Q.gg, and by Driesch ('92), Ziegler ('94), myself ('93),
and others, on the Q,gg of the sea-urchin, with substantially the same
results. The value of the experiment lies not so much in showing
that the coincidence between the first cleavage planes and the orient-
ing planes of the body may be lost, as in showing that under these
circumstances the nuclei have a different distribution in the proto-
plasm from that which they hold in the normal Q.gg. Any theory of
development that depends on the qualitative distribution of nuclear
products during the cleavage period meets with great difficulties in
the light of these results, and in order to overcome them will be
obliged to add qualifications of such a kind as materially to alter
its simplicity. Roux's theory, for instance, comes into this category.
Roux ('83) suggested that since the comphcated karyokinetic division
of the nucleus is carried out in such a way as to insure a precise divi-
sion of the chromatin, and since the qualities of the male are transmitted
to the Qgg through the chromatin of the spermatozoon, it is probable
that the division of the chromatin is a qualitative process, by means
of which the elements are distributed to different parts of the Qgg.

244 REGENERATION

According to Roux, the first division of the frog's Q,gg divides the
material of the right half of the embryo from that of the left ; the
second division separates the material of the anterior half from that
of the posterior half. Roux limited, to a certain extent, his hypothesis
to these two divisions of the frog's tg^,, and stated further that it is
not improbable that during the later stages of development there may
take place an interaction of the parts on each other, and this inter-
action would be another factor in the development. Weismann has
adopted Roux's hypothesis, and has extended it to all organisms, and
to most of the divisions of the developing egg, at least to all those
divisions in which the qualities of the layers, tissues, organs, etc., are
separated. On this slight basis he has constructed his theory of
development and of regeneration It is important, therefore, to
examine critically the evidence furnished by experimental embryology
for or against this hypothesis of a qualitative division of the ^gg dur-
ing the cleavage period.

The development of a half embryo from one of the first two
blastomeres of the frog's Q.gg, in Roux's experiment, seemed to sup-
port Roux's hypothesis, but it was not long before it was seen that
the presence of the other blastomere vitiated the evidence to such
an extent as to render it worthless, so far as this hypothesis is
concerned. Then followed the experiments with the isolated blasto-
meres of the sea-urchin, amphioxus, jelly-fish, teleost, ascidian, triton,
etc., in which each blastomere, when completely separated, gives rise
to a whole embryo. From these experiments Driesch and Hertwig
drew the opposite conclusion, namely, that during the cleavage there
is a quantitative division of the &gg into blastomeres that are equiva-
lent, or at least totipotent. Roux attempted to meet the results of
these experiments in two ways. He pointed out that in several of
these cases the isolated blastomere divides as a half or as a fourth
of the &gg, and that in the sea-urchin this leads to the formation of an
open half-blastula. In the second place, Roux brought more to the
front his subsidiary hypothesis of the reserve germ plasm. He sup-
posed that along with the early qualitative division of the nucleus,
by means of which each part receives its particular chromatic sub-
stance, there is also a quantitative division of a sort of reserve germ
plasm contained in the nucleus. Each cell may receive also a part
of this material, and hence each cell may contain the potentialities
of the whole ^gg. This reserve plasm may be awakened by any
change that alters the normal development, as, for instance, when
the blastomeres are separated. It may take some time for this
reserve stuff to wake up, as shown by the half-development of the
sea-urchin's o-gg that goes on for some time after the separation
of the blastomeres. This hypothesis cannot be objected to on purely

THEORIES OF DEVELOPMENT 245

formal grounds, but we are not so much concerned with a purely
logical hypothesis as with a verifiable one.

It has been pointed out that the experiment of compressing the
&gg in different planes that leads to a new distribution of the nuclei
is a formidable obstacle to Roux's hypothesis. If the nuclear divi-
sions in the compressed Q.gg are of the same sort as in the normal
Q^^, we should expect to find as a result either a monstrous form
with all its parts misplaced, or, if the parts are mutually dependent,
nothing at all. Roux has attempted to meet this case by supposing
that the nucleus itself responds to the change in the protoplasm and
alters its divisions in such a way as to send to each part of the com-
pressed ^g^ the right sort of material for that part. This means
that the nucleus can so entirely change the sequence of its divisions
that instead, for instance, of sending to each pole of the first spindle
the material of the right and left sides of the body, as it does nor-
mally, it may divide under compression in such a way that the
material for the anterior half of the embryo is separated from that
of the posterior half. That a change involving such a vast number
of qualities could take place, as a result of the slight compression on
the Q,^^ that brings about a change in the position of the spindle,
seems highly improbable. It is, of course, not a disproof of the
hypothesis to show that it involves very great complications, for the
very assumption itself of a qualitative division of the nucleus, in
the Roux-Weismann sense, involves us in great complications.

A more damaging criticism of the hypothesis of a qualitative
division of the nucleus is found in an appeal to direct observation,
which shows that the chromatin divides always into exactly equal parts.'
In many cases we know, from the subsequent fate of the cells, that
two cells arising from the same cell play very different roles in the
subsequent development, yet the chromatin of the nucleus is always
divided equally.

The development of the isolated blastomeres of the ctenophore
^g^ may seem at first sight to give support to Roux's hypothesis, for
in this case the first two cells are completely separated, and yet give
rise to half-structures. Crampton's experiments on the eggs of
ilyanassa may also appear to be evidence in favor of this view.
In fact, however, they give no more support to the idea of a quahta-
tive division of the nucleus than they do to that of a qualitative divi-
sion in the protoplasm, and there are some further experiments on
the ctenophore egg which indicate that it is the latter rather than the
former sort of division that takes place. As stated in the preceding
chapter, Driesch and Morgan found that, if a part of the protoplasm
of the unsegmented Q.^g of the ctenophore is removed, an incomplete
embryo develops, although the whole of the segmentation nucleus is

246 RE GENERA TION

present. Ziegler's results show that, even after the removal of that
part of the egg from which the micromeres develop, the segmenta-
tion may still be like that of the whole o^gg, and this shows that the
Qgg has great powers of recuperation (at least in a symmetrical
plane), so far as its protoplasm is concerned. If, however, it is true
that when a part is cut off unsymmetrically the protoplasm cannot
reorganize itself, then the conclusion that Driesch and Morgan drew in
regard to the protoplasm will hold, provided, as seems to be the case,
the smaller blastomere of the first two is large enough to produce the
typical structures. The main point is this : If the protoplasm re-
adjusts itself after the operation, so that the piece divides as a whole,
a complete embryo develops ; if, however, the protoplasm does not
readjust itself, and the piece divides as a part, an incomplete em-
bryo is formed. Since in both cases the same nucleus is present,
and since the difference is obviously connected with a change in the
protoplasm, it seems much more probable that the phenomenon of
whole and half development is connected with the protoplasm and
not with the nucleus.

The hypothesis that Pfliiger, Hertwig, and Driesch have adopted,
namely, that the cleavage divides the Q.gg into potentially equal parts,
stands in sharp contrast to the Roux-Weismann conception of devel-
opment. There are two ideas in the former view which should be
kept, I think, clearly apart : the first is, that the blastomeres are
potentially equal (isotropous), because they are exactly alike ; the
second is, that despite the differences that may exist amongst them
they are still potentially able to do the same thing, i.e. they are toti-
potent. The former alternative is that adopted by Pfliiger, Hertwig,
and Driesch ; the latter view, to which Driesch seems more inclined
in his later writings, is the one that I should prefer.^ The first
four blastomeres of the sea-urchin's Q,gg appear to be exactly alike,
and we find that each can make a whole embryo. If we assume,
however, that despite their likeness and their totipotence they are
different in so far as there is present in the protoplasm a bilateral
structure, we are nearer, in my opinion, to the truth ; for, unless we
assume the bilateral structure to be determined later by some exter-
nal factor, of which there is no evidence, we must suppose that after
fertilization, at least, there must be a bilateral structure to the proto-
plasm, and this view is borne out in one sense by the subsequent
mode of cleavage of the blastomeres if they are separated. Whether
this bilaterality of the fertilized Q,gg leads to the bilaterality of the
cleavage is, however, a different question. In some cases this
appears to be the case, in others it is clearly not the case, and we
must suppose that some other condition determines the bilaterality

1 As stated in my article on " The Problem of Development," 1900.

THEORIES OF DEVELOPMENT 247

of the later stages than that which influences the cleavage. Many-
facts of experimental embryology and of regeneration show, more-
over, that a new bilateral structure may be readily assumed by
pieces that have lost their connection with the rest of the organism.

After the third division of the Q,^g of the sea-urchin, four of the
blastomeres are somewhat different, so far at least as the material of
which they are made up is concerned, from the other four ; yet any
one of the eight blastomeres, or groups of blastomeres, can produce
a whole embryo. The same statement can be made for much later
stages, since it has been found that fragments from any part of the
blastula wall can give rise to whole embryos, and we miay safely attrib-
ute this property to all the cells, although on account of the size of the
cells of later stages they cannot individually produce a whole embryo,
but each can produce any part of an embryo, which amounts to the
same thing. If we assume that all of these cells are exactly alike,
as Hertwig has done, we fail to see how the next stage in the devel-
opment could take place, unless some external factor could act in
such a way as to change the different parts of the Q.gg. We have,
however, no reason to suppose that all the cells are alike because
they are all potentially equal. Even pieces of an adult animal — of
hydra or of stentor, for example — can produce new whole organisms,
although we must suppose these pieces to be at first as unlike as are
the parts of the body from which they arise. Moreover, we do not
know of a single q^^ or embryo in which we cannot readily detect
differences in different parts of the protoplasm.

Can these gross differences, that we can see, in the materials of
the ^g'g explain the different development of the parts of the ^.gg ?
It can be shown, I think, that they do not necessarily determine the
result. If we cut in two a blastula, so that one piece contains only
the cells from the animal half and the other piece cells from the
vegetative half, each produces a whole embryo ; yet the one half
lacked just those parts which by hypothesis were supposed to
determine the gastrulation of the other half. If we suppose that
the materials or structures that are characteristic of the vegetative
half are gradually distributed from the vegetative to the animal pole
in decreasing amounts, then any piece of the &gg will contain more
of these things at one pole than at the other. If, then, it could be
shown that the gastrulation depends on the relative amounts of these
materials in the different parts of the blastula, the difficulty met with
in the former view disappears in part. I say in part, because the rela-
tive amount of materials that produces the results implies a connect-
ing substratum that is acted upon and determines the result. Even
if we suppose that this polar distribution of material could account
for the polar invagination, we should still be at a loss to account for

248 RE GENERA TION

the origin of the bilateral symmetry. In many eggs there is no evi-
dence of a bilateral distribution of the material, although in some few-
cases there may be, so far as the form is concerned, a plane of bilat-
eral symmetry. But even if it is supposed to be present in all eggs,
and to coincide with the first plane of cleavage (or with any other
cleavage plane), we still could not explain the bilateral symmetry of
the one-half and one-fourth whole embryos that come from the corre-
sponding isolated blastomeres. If a preexisting bilateral plane exists
in the Q.gg, it must be reestablished in some way in the isolated blasto-
mere and in pieces of the blastula wall. In the latter case this could
scarcely be brought about by a redistribution of the gross contents
of the piece, since the presence of cell walls would interfere with such
a process.

This analysis shows, I think, that the transformation of a piece
into a new whole really involves a change in the fundamental struc-
ture itself. There cannot be much doubt that both the polarity and
the bilaterality of the q^^, or of a piece of the Q.gg, belong fundament-
ally to the same class of phenomena, and we are forced to the sup-
position that they are inherent peculiarities of the living substance.
Driesch thought at one time that it is only necessary to suppose that
the protoplasm, and every part of it, possesses a primary polarity,
and that some inequality in the material might determine the plane
of bilaterality; but later he thought it necessary to assume also the
presence of a bilateral structure in the protoplasm, and in all parts of
it. This assumption of every part having a polar and a bilateral struc-
ture, and the polarity and bilaterality of the whole being the sum
total of those of all its parts, is, I think, insufficient to meet the situa-
tion. If, for example, the first plane of cleavage coincides with the
median plane of the body, the right blastomere has a structure that
leads to the formation of the right side of the body, and similarly
for the left blastomere. If the two blastomeres are separated,
and each gives rise to a whole embryo with a new plane of bilateral
symmetry, we must suppose that a new bilaterality has been
produced. It does not make the problem any simpler to assume, as
Driesch has done, that this is brought about by the elements re-
arranging themselves bilaterally on each side of a new plane that
passes through the middle of the isolated blastomere, for what we
need to have explained is what determines the new median plane.
It seems to me that the problem is not any simpler, if we assume the
polarity and bilateraHty to be the property of a large number of ele-
ments, as Driesch has done, than if we assume at once the polarity
and bilaterality as characteristic of the whole Qg'g. The difficulty of
understanding how a new bilaterality can be induced in a piece of the
whole is as great on the one assumption as on the other. Not only

THEORIES OF DEVELOPMENT 249

is it, I think, a much simpler idea to suppose the structure is some-
thing pertaining to the whole and is not the sum total of smaller
wholes, but the idea is more in accord with other phenomena.

We meet here, I think, with precisely the same problem that we
meet with in the regeneration of parts of adult animals. If a plana-
rian is cut in two lengthwise, along the middle line, each half produces
new tissue at the cut-side, out of which the missing half is formed.
In this case the old median plane remains, more or less, as the median
plane of the new worm, i.e. the structure of the new part is built
up on that of the old. Very much the same result follows when the
worm is cut longitudinally into two unequal parts. The larger piece
retains its old plane of symmetry and adds to the cut-edge a new part
that completes the symmetry. The smaller piece also builds up new
material along the cut-edge, and a new plane of symmetry is formed
between the old and the new parts. Here, also, a median plane
is established at the edge of the old material, but in this case the
material lay to one side of the old middle line, and this involves the
changing over to a large extent of the old material, so that it fits
in with the new structures of the new median plane.

In those forms in which the readjustment takes place entirely in
the old part, the change of conditions is more difficult to interpret. In
some, respects hydra gives us an intermediate condition, but since it
is a radially symmetrical instead of bilaterally symmetrical form, the
transformation is not so obvious. If a cylindrical piece is cut from
the body, and is then cut lengthwise into two half-cylinders, each closes
in and makes a cylinder of smaller diameter. A little new tissue
may appear along the fused edges, but the missing half is not re-
placed, and a new hydra with a body of half size is formed from the
piece. It is to all appearances a radially symmetrical form, and we
must think, in this case, of the new axis of symmetry as having shifted
to the middle of the piece. As yet no similar experiments have been
made on a bilateral animal that regenerates by morphallaxis, so that we
have nothing to appeal to for comparison with the bilateral Q.gg, but the
results, just described for the planarian and for hydra, indicate how a
change might take place in pieces of adult animals that would lead to
the formation in them of a new symmetrical structure. If we imag-
ine a case of this sort, and suppose that after separating a piece from
the side the cut-edge closed in and the piece assumed a symmetrical
form, it is conceivable that a new plane of bilateral symmetry might
soon appear in the middle of the piece owing to the symmetrical form
of the piece ; or the new plane of symmetry might slowly shift from
the cut-edge toward the middle of the piece, after reaching which the
balance or equilibrium would be attained. This statement, it must be
confessed, is little more than a supposition, and rests on the unproven

2 5 O RE GENERA TION

assumption that the internal symmetry may develop in response to a
symmetrical change in shape of the piece as a whole, which is partly
the outcome of purely physical factors. At present, however, I see
no other probable inference from the facts.

If we suppose a bilateral structure is present in the fertilized egg,
and that it corresponds to the lirst plane of cleavage, a change of the
sort that we have just sketched above may be supposed to take place
when the blastoraeres are separated. The stimulus is found in the
new spherical form assumed by the isolated blastomere, and we may
imagine the change to take place, in the way indicated, by virtue
of the old bilaterality that is present, the change beginning at the
side originally in contact with the other half.

There are several facts which seem to indicate that a change in the
axial relations of the ^%g is very easily brought about before any
definite organs have appeared. The fact that the point of entrance
of the spermatozoon in the Q.gg of the frog^ and of the sea-urchin ^
may determine the first plane of cleavage points to this conclusion.
The fact that, in the frog, and also in the triton, the median plane of
the embryo corresponds sometimes to the first, sometimes to the
second plane of cleavage, and sometimes to neither one, shows that
the bilaterality of the embryo-structure may or may not coincide with
the plane of cleavage. In the fish also there seems to be no corre-
spondence between the planes of cleavage and those of the embryo,
so that different factors may determine the two. We should not be
justified in concluding from this evidence that a bilateral structure is
absent, but rather that it is of such a sort as to be independent of
the cleavage, and that it can be also easily changed. It is prob-
able that the kind of organization that we must suppose to exist in the
&g^ is of a very simple sort, and capable of easy readjustment. There
is certainly no evidence in favor of the view that the organization of
the ^^^ need be anything like the organization of the embryo that
comes from the ^^g, although the organization of the Qgg may be
perfectly definite in its character. Until we know more of the nature
of this organization, it is useless to speculate further as to how it can
be altered.

Another question of much importance in connection with our
present topic is the part played by the individual cells in the
early development of the whole ^g^, or of any part of the Qg'g.
Hertwig ('93) thinks that the development is brought about by the
action of the individual cells on each other. Driesch, when he states
that the fate of a blastomere is a fimction of its position in the whole,
does not commit himself definitely one way or the other so far as the
cell as a unit is concerned. Whitman and others have urged the

1 According to Roux. ^ According to E. B. Wilson.

THEORIES OF DEVELOPMENT 25 I

insufficiency of the cell theory, and think that cell boundaries play
no important part in the development, but that the embryo develops
as a whole. This has seemed to me to be the more probable view in
the light of certain results of experimental embryology. Driesch, in
later papers, has also opposed Hertwig's idea, and Wilson in his book
on The Cell has also, to a certain extent, adopted this point of
view. The formation of a typical larva in the sea-urchin and in am-
phioxus out of one-half or one-fourth the whole number of cells
demonstrates, I think, the insufficiency of the cell-unit hypothesis.
The discovery of continuous protoplasmic connections between neigh-
boring cells, and the formation of new protoplasmic connections
between all regions, as found by Mrs. G. F. Andrews,^ gives us a
basis of fact on which to rest the hypothesis of the embryo being a
whole structure. This view meets with no great difficulty on the
grounds that the nuclei are distinct centres of metabolic activity, for
we know at present so little of what sort of action takes place between
the nucleus and the protoplasm that we cannot rest our argument on
any demonstrable relation.

The discovery that pieces below a certain minimum size are inca-
pable of producing a whole organism is of capital importance. It
has been pointed out that pieces of the Q'g^ of the sea-urchin less than
one-sixteenth of the whole do not produce even the gastrula stage.
In amphioxus the one-eighth blastomere seems to be near the lower
limit of development. It has also been found that there is a lower
limit for pieces of adult organisms below which they do not regen-
erate. This has been shown for hydra, tubularia, planarians, and
stentor, and is probably true for all forms. This result is especially
interesting in those cases in which the parts contain all the elements
necessary to produce a new organism, and come from parts of the body
that are totipotent in these respects. It seems certain that the
lack of power of development in these cases is due entirely to the
smallness of the piece. We can express the idea in another way by
stating that a certain volume is necessary in order that a piece may
produce the typical organization. This conclusion is important as
showing that the organization is something enormously large as com-
pared with the size of the chemical or physical molecules, and even
of the crystal molecule. The size of a piece that is at the lower
limit of organization is also very much larger than the smallest cells
of which the embryo is made up, and this relation is a point in favor
of the view that the organization is not simply the resultant of the
interaction of the cells, but is something much larger than these cells ;
and we may even go further, I think, and add that it dominates the
cells rather than is controlled by them.

1 1897.

2 52 RE GENERA TION

In the light of the questions discussed in the preceding pages, we
may now attempt to follow out in a more connected way some of the
modern views and hypotheses dealing with the problem of develop-
ment.

Hertwig, as we have seen, has opposed the Roux-Weismann
hypothesis, and has formulated a view of his own. According to
Hertwig, the cleavage divides the ^gg into equivalent parts, — an idea
very similar to that of Pfiuger. The cells he regards as units, and
the development as the result of the interaction of the cells, — a
process that in a way Roux had also assumed to take place between
the different parts of the later embryo. Thus, while Hertwig's hy-
pothesis contains little that is really new, it has selected portions from
several already existing hypotheses, and united them into a consistent
whole. It has been objected to Hertwig's view that the interaction
of equivalent cells could never account for the introduction of new-
processes in the development ; but if we grant that the cells are
never entirely equivalent, whatever their potence may be, this objection
can, I think, be met. Hertwig's chief service has been his destructive
criticism of the Roux-Weismann idea of qualitative nuclear division.

Hertwig maintains that each stage in the development is the cause
of the next stage, and states that a description of the series of stages
through which the embryo passes gives a causal knowledge of the
phenomena of development. He claims that beyond this descriptive
knowledge we cannot hope to penetrate. Both Roux and Driesch
have taken issue with Hertwig, and have pointed out that while each
stage in the development contains within itself the causes of the suc-
ceeding stage, yet we gain no idea as to these causes from a simple
description of two consecutive stages themselves. To state that the
fertilized Q^g is the cause of the cleavage gives us no idea of what
sort of a process the cleavage is, or how it arises, or what determines
the sequence of the divisions, etc. The blastula, for instance, con-
tains the factors that produce the gastrula ; but to state that, in a
physical sense, the blastula is the cause of the gastrula is an erroneous
interpretation of what is meant by causal knowledge. If Hertwig's
idea were correct, there would be as many causes in each embryo as
there are stages in its development, and as many causes in the whole
range of embryology as there are forms that develop multiplied by the
number of stages in each embryo. What we should seek to discover
is the particular cause that brings about each kind of process. If
we could discover the cause in one single case, it is highly probable
that it would be found to extend to a large number of other cases.

Driesch formulated an hypothesis of development in his Ana-
lytische Theorie, but has modified and changed it in several later
contributions. It is difficult to give in a few words the subtile analysis

THEORIES OF DEVELOPMENT 253

which Driesch has made of the phenomena of development. His ana-
lytical theory rests on the dictum that the prospective value of each
blastomere is a function of its position in the whole. By " function " is
meant " a relation of dependence of a general unknown kind." This
idea is connected with the following one, viz. that any blastomere
could be interchanged with any other one without altering the end-
result A few elementary processes are supposed to be "given" in
the structure, or in the composition of the Q,g^. Each elementary
process is the outcome of a cause, and each elementary process must
release the succeeding causes, — i.e. if the organization of the phase
A is present, one of the causes of the next phase B is also then present.
The first elementary process is the cleavage, that is initiated (" aus-
gelost ") by the fertilization. After a fixed number of divisions has
taken place, the cleavage process comes to an end. It has led to the
production of a number of cells having similar nuclei but having a
different plasma structure, and the result is the blastula stage. Or-
gans whose formation starts from the blastula stage arc called primary
organs ; the archenteron, the mesenchyme, the cihated band, and the
mouth of the sea-urchin embryo belong to this class. Secondary
organs are those that arise from the primary ones, as the coelom sacs,
for instance, in the sea-urchin embryo. The primary organs are
started by the setting free("Auslosung") of a new elementary process
in the blastula, and later the secondary organs are started by new ele-
mentary processes that arise in the gastrula, which cannot appear until
the gastrula stage itself is present as a starting-point. In other
words, the elementary processes that are "given" in the ^.g^ can
only come into action, or be set free after a certain stage has come
into existence. This means that we must think of each organ that
responds to a stimulus as having the possibility of receiving that stimu-
lus, and also of answering to it. Even in inorganic nature every reac-
tion must depend on a specific receptiveness and a specific answer.
Driesch supposes that the receptivity is in the protoplasm, and the
power to respond is in the nucleus of each cell. In this way he
attempts to meet the difficulty that the nucleus is, in every cell, the
bearer of the totality of all the " Anlagen" ; but inasmuch as it is sur-
rounded by a specific plasma, it is in a position to receive only cer-
tain stimuli, and can therefore only respond to certain causes.

In the specific nature of the cytoplasm of the cell lies the pro-
spective potence of every organ, and the possibilities of each cell are
hmited by its plasma ; the cell becomes more and more limited as
development proceeds. It may be said, therefore, that in the course
of development the cells become actually limited in their possibihties,
although they may still retain within themselves, in the nucleus, the
potentialities of the entire organism.

254 ^E GENERA TION

In the course of development each causal reaction brings about
not only chemically specific differences, and thereby makes possible the
introduction of new elementary processes, but the reaction also brings
about by this very means a lessening of the possibilities of the cell,
because each cell will now only respond to a more limited set of
causes. We may say that the elementary process is not only the
cause of the next change, but by virtue of its specific nature it is the
beginning stage of the future reactions. Development proceeds from
a few prearranged conditions, that are given in the structure of the
Q^Z, and these conditions, by reacting on each other, produce new
conditions, and these may in turn react on the first ones, etc. With
every effect there is at the same time a new cause, and the possibility
of a new specific action, i.e. the development of a specific receiving
station for stimuli. In this way there develops from the simple con-
ditions existing in the o.^^ the complicated form of the embryo.

In this brief summary of some of the essential features of Driesch's
hypothesis, I have omitted some parts that seem to me to go beyond
the legitimate field of a scientific hypothesis, — such, for instance, as the
causal harmony of the reactions ; and other parts have been omitted
because they are improbable in the light of more recent work. It
would not be difficult to show that many difficulties beset each stage
of the argument, or to show how slender a basis of fact there is to
support some of the hypotheses. In fact, Driesch himself has modi-
fied very greatly some of the views of his Analytische TJieorie in his
later writings. The merits of the analysis should not be overlooked,
however, since it is one of the first philosophical attempts to show how,
in the light of recent discoveries, the process of epigenetic develop-
ment may receive a causal interpretation. Even if the argument
should break down, the hypothesis will remain an interesting contribu-
tion, opening the way to newer points of view in regard to the process
of development. In later papers, especially in those dealing with the
localization of morphogenetic processes, Driesch attempts to show that
certain experimental results demonstrate that there is a vitalistic prin-
ciple at work in the development of the organism from the Qgg, as
well as in the process of regeneration. He bases his argument on the
results of the experiment in which the gastrula of the sea-urchin &g^
is cut in two, as described already on page 234. The archenteron has
not, at the time of the experiment, subdivided itself into its three char-
acteristic parts. The posterior piece, that contains the posterior part
of the archenteron (the anterior part having been removed with the
anterior piece), produces a new whole embryo of smaller size, in which
the archenteron is subdivided into three parts, that are in the same
proportion to each other and to the whole embryo as are the same
divisions of the normal archenteron. This proportionate formation of

THEORIES OF DEVELOPMENT 255

the parts of the archenteron on a smaller scale cannot, Driesch claims,
be accounted for on any known chemical or physical principle.
There must be, therefore, a different sort of principle involved, and
this Driesch calls the vitalistic principle.

It may be pointed out that this illustration that Driesch has se-
lected is only an example of all proportionate development, which
many observers have described as taking place in pieces of em-
bryos. It is only a striking case of what has been also known in
many cases of regeneration, of small pieces producing whole struc-
tures, and there is nothing new or startling in this demonstration of
a vitalistic principle. The fact may be stated in another way, viz.
that the proportionate development of an organ is, within certain
limits, self-determining, or is self-determined by its size. The vital-
istic principle that Driesch sees demonstrated in these results is
the now familiar process of a smaller piece producing the typical
structure on a smaller scale ; a phenomenon that a number of other
writers had already called attention to as one of the most remark-
able phenomena connected with the regeneration of pieces of an adult
organism, or of an Q.gg.

It is something of this same sort that the older zoologists must
have had in mind when they spoke of " formative forces " as peculiar
to living things. The use of the word "force" in this connection has
often been objected to, and not without justification ; since it seems to
imply that the action is of the sort for which the physicist uses the
word "force." The fundamental question turns upon whether the
development of a specific farm is the outcome of one or more
" forces," or whether it is a phenomenon belonging to an entirely
different category from anything known to the chemist and the
physicist. If we state that it is the property of each kind of living
substance to assume under certain conditions a more or less constant
specific form, we only restate the result without referring the process
to any better-known group of phenomena. If we attempt to go
beyond this, and speculate as to the principles involved, we have
very little to guide us. We can, however, state with some assurance
that at present'we cannot see how any known principles of chemistry
or of physics can explain the development of a definite form by the
organism or by a piece of the organism. Indeed, we may even go
farther and claim that it appears to be a phenomenon entirely beyond
the scope of legitimate explanation, just as are many physical and
chemical phenomena themselves, even those of the simplest sort.
To call this a vitahstic principle is, I think, misleading. We can do
nothing more than claim to have discovered something that is present
in living things which we cannot explain and perhaps cannot eiven
hope to explain by known physical laws.

256

RE GENERA TION

Wilson ('94) has also rejected Roux's hypothesis of qualitative
nuclear division, and adopts the view of the totipotence of the early
blastomeres. He has also advanced the view that there is during
development a progressive differentiation of the cells. In a later con-
tribution ('96), he accepts " the view of Hertwig and of Driesch that
the various degrees of partial development beginning with the echino-
derm &gg and culminating in the gasteropod may be due to varying
conditions of the egg cytoplasm in the different forms." Wilson
points out that the series of forms represented at one end by amphi-
oxus and at the other end by the ctenophore and the gasteropod may
be brought under a common point of view, "for it is certain that
development must be fundamentally of the same nature throughout
the series, and the differences must be of secondary moment."

If we reject, as several students of experimental embryology and
of regeneration have done, the Roux-Weismann idea of the existence
of pre-formed germs in the nucleus, and also the idea of Hertwig of
the equivalency of the first-formed blastomeres, and Driesch's vitalis-
tic principle, what position can we take in regard to the problem of
development ? We may at least attempt to formulate our present
position.

There must be assumed to exist in the tg^ an organization of
such a kind that it can be divided and subdivided during the cleavage
without thereby losing its primary character. The refusion of the
cells after each division by means of protoplasmic connections indi-
cates how this may be possible. The organization must be thought
to be of such a kind that the factors determining the cleavage may
be different from those that determine the median plane of the body.
This is demonstrated by Pfluger's experiment in which the position of
the cleavage planes is changed, but the embryo appears in relation to
the primary meridians. The first-formed blastomeres, that result
from the division of the 0.2,^, do not seem to be strictly equivalent,
but they appear to be in most cases, at least, totipotent. The char-
acteristics of each part of the protoplasm may be a factor in determin-
ing what sort of structure may come from that part of the egg, but
back of this Hes the fundamental character of the protoplasm itself,
that determines what each part, in its relation to the whole, can do.
The division of the nucleus appears to be in all cases an exact quan-
titative division, and there is some evidence to show that the early
nuclei are all equivalent, — or at least totipotent. The division of the
protoplasm is often into unlike parts, and the kind of cytoplasm con-
tained in a part may or may not limit the potencies of each part.

One of the most important facts in connection with the organiza-
tion is that a part, if separated from the rest, may become a new
whole, and this appears to be a fundamental peculiarity of living

THEORIES OF DEVELOPMENT 25/

things. Analogies can be found, perhaps, in inorganic phenomena,
as for instance a storm dividing into two or more parts and each
developing a new storm centre of its own, or when a suspended drop
is divided and each half becomes a new sphere ; but these comparisons
lack some of the essential features of the organic phenomenon.

A progressive change takes place as development proceeds, so that
a stage once passed through is not repeated if a part is separated from
the rest, as illustrated by Driesch's experiments with the blastula and
gastrula of the sea-urchin and starfish, and by the method of develop-
ment of pieces of the adult, that do not pass through the embryonic
stages. As the protoplasm changes new conditions may arise, either
because the protoplasm in its new form can be acted upon by those
internal or external conditions to which it did not respond at first, as
Driesch has supposed, or, as I think equally probable, because the
series of reactions that have begun with the first step in the develop-
ment work themselves out in the same way that a chemical reaction
once started may pass through a long series of stages depending upon
the nature of the substance. The difference between these views lies
in this, that the former supposes latent substances, or elementary
processes or forces, whatever they may be called, to be present in the
0,2^^ and to act when a medium that responds to them has come into
existence; the other idea supposes that the whole process is started with
the first change and once set going is of such a kind as to continue
to an end through a regular series of stages. Both views are suppo-
sitions, and, it may be, reduce themselves ultimately to the same thing.

On any theory of development, the nucleus cannot be left out of
account, since the evidence that we now possess shows that through
the nucleus even the most trivial peculiarity of one parent, and prob-
ably of both, may be transmitted. This has led a number of zoolo-
gists to look upon the nucleus as a body containing specific elements
corresponding to those of the individual from which the nucleus has
come, but inheritance through the nucleus is no more a demonstration
of the existence of pre-formed elements of the male than are the gen-
eral facts of embryology a demonstration of pre-formation. All we can
legitimately conclude is that the substance of the nucleus is of such a
sort that it acts on the cytoplasm in a definite way, and determines,
in part at least, its differentiation. There has been steadily accumu-
lating evidence to show that during development there is an inter-
change of material between the nucleus and the protoplasm, and it is
not going far afield to conclude that the character of both nucleus
and protoplasm is altered by the interchange in material. If this is
admitted it is no more remarkable that a hybrid is midway between
its parents than that a parthenogenetic q.%^ produces a form like that
of the individual from which it has come.

258 RE GENERA TION

Several writers, as we have seen, have adopted the view that the
nuclei are storehouses of the undifferentiated germ plasm, and retain
everywhere the sum total of the " Anlagen" of the Q.g^ nucleus. I do
not know of any evidence that demonstrates that the nucleus is less
modified in these regards than is the rest of the cell. On the con-
trary it seems to me that a fair case might be established in favor of
the view that the nucleus and the cytoplasm cannot be contrasted in
this way, and that a change in the cytoplasm may also involve a
change in the nucleus.

The phenomena of regeneration show over and over again that
differentiated cells may change into structures entirely different from
what they have been, as illustrated in the development of the lens
from the edge of the iris, and in the production of a new hydra, or
tubularian, from a piece of an old one. It is, I think, an arbitrary
assumption to suppose that this is brought about by a reserve stuff in
the nucleus, for the production of new eggs and spermatozoa in the
animal, from cells that have themselves passed through most of the
early embryonic changes and have been parts of embryonic organs,
shows that although the protoplasm may change throughout these
stages, it may still come back to the starting-point, and there is
nothing to show that this return is brought about by the nucleus. I
cannot but think that Driesch was prejudiced by current opinion,
when he adopted the view, as one of the foundations of his analytical
theory, that the nucleus contains all the " Anlagen " of the whole or-
ganism, and that the protoplasm alone undergoes a progressive change.

The central problem for embryology is the determination of what
is the cause or causes of differentiation. Our analysis leads us to
answer that it is the outcome of the organization ; but what is the
organization } This it must be admitted is a question that we cannot
answer. Looked at in this way the problem of development seems
an insoluble riddle ; but this may be because we have asked a ques-
tion that we have no right to expect to be answered. If the physicist
were asked what is gravity he could give no answer, but nevertheless
one of the greatest discoveries of physics is the law of gravitation.
If we could answer the question of what the organization is to which
we attribute the fundamental phenomenon of development, there
would perhaps be nothing further left to find out in the development
of animals. Fortunately there is a different and safer point of view.
There are other questions to which we can expect an answer. Be-
cause the physicist cannot tell what gravity is, he neither rejects the
term nor despairs of obtaining a knowledge of how it acts. If our
analysis of the problem of development leads us to the idea of an
organization existing in the egg, our next problem is to discover how
it acts during development. Most of the results described in several

THEORIES OF DEVELOPAIENT 259

of the preceding chapters have taught us something of how the
organization behaves. We have found that it can be affected by
external circumstances, even to such an extent that its polarity may
be reversed. We have seen that if an organized structure is broken
up into pieces, each piece may reorganize itself into a new-
whole. The most familiar, and at the same time the most difficult
thing to understand, is that the organization is of such a kind that it
has the property of passing through a definite series of stages leading
to a typical result, and having reached its goal of throwing off organ-
ized bodies, or germ cells, that begin once more at the starting-point
and pass through the same cycle. The action of the organism is
sometimes compared to that of a machine, but we do not know of any
machine that has the property of reproducing itself by means of
parts thrown off from itself.

These are some of the most characteristic phenomena exhibited
by the organization. In the final chapter some of the questions that
have been suggested in connection with the method of action of the
organization will be further discussed.

CHAPTER XIII

THEORIES OF REGENERATION

It is significant to find that the theory of pre-formation of the
embryo in the egg, that was so very widely held during the seventeenth
and eighteenth centuries, and during the first part of the nineteenth
century, was at once applied to the explanation of the regeneration of
animals when this process became known. Bonnet in 1745 attempted
to explain the newly discovered facts in regard to the regeneration of
animals by means of the pre-formation theory. Just as the e.gg was
supposed to enclose a pre-formed germ, so he imagined there lay con-
cealed latent germs in the adult animal. At first Bonnet thought that
these germs must be whole germs, like those contained in the germ
cells of the reproductive organs, and that only as much of any one
developed as was needed to replace the missing part. Later, how-
ever, he admitted that the germs might be incomplete germs, which
are so located in each region that they represent the parts of the
body beyond that region. The purpose of these germs is to replace
any accidental injuries to the animal. He pointed out that some
animals are more subject to injuries than others, and these animals
are he thought especially well supplied with germs. Since in some
animals the same part may be replaced several times. Bonnet assumed
that on each occasion a new germ is awakened. As many sets of
germs are present in these animals as the number of times the animal
is liable to be injured in the course of its natural life.

Bonnet found that in lumbriculus a new head and a new tail may
appear at almost any level, if the worm is cut in two, and, therefore,
he supposed, head germs and tail germs are present throughout the
worm. But why, if this is so, should a head germ always develop at
the anterior end, and a tail germ at the posterior end of a piece cut
from the body .'' Bonnet's keen mind saw that it was necessary to make
a further assumption. He supposed that the fluids of the body that
pass forward carry nourishing substances for the head. When the
worm is cut in two these substances are stopped at the anterior cut-
surface, and there accumulating act on the latent head germ, and
nourishing it, cause it to develop. Correspondingly the nourishing

260

THEORIES OF REGENERATION 26 1

substances for the tail flow backward, and accumulating at the pos-
terior cut-surface awaken a tail germ to activity.

The part of the body in which these nourishing substances are
supposed to be produced is not specifically stated, but in one passage
Bonnet says that the fluids that flow toward the head are there
used up in that organ, and we may infer that he held a similar view
for the posterior region. He offers no explanation of the cause of
the flow of these substances in a given direction, and in this respect
his hypothesis lacks support where it is most needed. In fact, it is
no more improbable that a head germ should always develop at the
anterior end and a tail germ at the posterior end, than that head-
forming substances should flow in one direction and tail-forming in
another. It is not that it is worth while to object to Bonnet's hypothe-
sis on the ground that it does not explain everything, but it is worth
while to point out that it gives only the, appearance of an explanation,
and that it begs the whole question by the assumption of particular
nourishing fluids flowing in definite directions. So far as the blood
is concerned, we know that the different parts of the body take from
it those substances or fluids that they make use of, not that special
fluids flow to particular regions. It is probable that Bonnet thought
of the blood rather than of any other subtler fluids passing through
the tissues; and, if so, there is nothing that we know in regard to the
behavior of the blood that lends support to Bonnet's idea.

Bonnet takes care to state that the pre-formed germs may not
appear to us like miniature copies of the part into which they develop,
but they are so constructed that, as they absorb nourishment and
become larger, they assume a characteristic form.

Weismann, who has also accepted the pre-formation hypothesis to
account for the development of the egg, has applied the same concep-
tion of pre-formation to the process of regeneration. He believes that
partial, latent germs are present in different parts of the body, and
that these germs are present especially in animals that are liable to
injury and in those parts of the body that are likely to meet with
accidents. In these essential respects, Weismann's idea is the same
as Bonnet's; but in regard to the location of the germs, and their man-
ner of awakening, and as to how the forms, liable to injury, have ac-
quired their power to regenerate, Weismann adopts more modern
standards. He believes that the germs are located in the nucleus.
Those that bring about the development of the egg are supposed to
be different from those that bring about regeneration, because the
method of regeneration is generally different from the method of
development of the egg.

Regeneration, on Weismann's view, is brought about by latent
cells containing pre-formed germs in the chromosomes of the nucleus.

262 REGENERATION

These germs are called the determinants. Since at each level in an
animal, or in a part of an animal, regeneration may occur and re-
place the missing part, it is assumed that the germs are correspond-
ingly different at each level, and represent all the parts that lie
distal to that region. Weismann does not suppose that there is a
single germ at each level that represents all the distal parts, but that
in each layer, or organ, or part there are many cells that contain
germs corresponding to the distal regions. The qualities of the
latent cells are sorted out by means of the qualitative divisions of the
chromatic material of the nucleus. Moreover, since the new part can
itself regenerate, the further assumption is made that during regen-
eration new subsidiary or latent cells are laid down at each level.
This is supposed to be brought about by a quantitative division of
each germ after it has reached its definitive position in the new part.

Weismann's general attitude toward the problem of regeneration
is summed up in the following statements : " It may, I believe, be
deduced with certainty from those phenomena of regeneration with
which we are acquainted, that tJie capacity for regeneration is not a
primary quality of the organism, but that it is a pJienomenon of adap-
tation.'' Again, " Hence there is no such thing as a general power
of regeneration ; in each kind of animal this power is graduated ac-
cording to the need of regeneration in the part under consideration."
" We are, therefore, led to infer that the general capacity of all parts
for regeneration may have been acquired by selection in the lower
and simpler forms, and that it has slowly decreased in the course of
phylogeny in correspondence with the increase in complexity of
organization, but that it may, on the other hand, be increased by
special selective processes in each stage of its degeneration in the
case of certain parts which are physiologically important and at the
same time frequently exposed to loss."

The evidence brought forward in the preceding pages leads, I
think, to precisely the opposite conclusions, and, in certain cases at
least, it has been shown that there can be no relation between the
power of regeneration and the extent of exposure of a part to injury
or to loss. It is unnecessary to enter here further into this question,
since it has been discussed already in Chapter V.

Weismann's statement that the power of regeneration has de-
creased " in correspondence with the increase in the complexity of the
part" cannot by any means be entirely accepted. If the complexity
of a part is of such a kind that the part cannot sustain itself indepen-
dently until regeneration has taken place, or if the exposed surface of
the wound is such that it cannot be closed over, or if the new part
cannot be properly nourished, or if the tissues have changed in such
a way that their cells can no longer multiply, then the statement is, to

THEORIES OF REGENERATION - 263

a certain extent, true. On the other hand, when we find that one of
the most complicated organs of the body, the eye, can regenerate in
the salamander, if only a piece of the optic cup is left attached to the
nerve, we may well doubt if there is any such direct and general con-
nection between regeneration and complexity as Weismann maintains.

Weismann's so-called " mechanism " of quahtative nuclear division
is the basis of his conception of pre-formation. We are, I think, at
present in a position to reject not only this conception, since it finds
no support either in observation or experiment, but also his view that
regeneration is brought about by latent cells ; for it has been shown
in a large number of cases that the new cells come directly from the
old, differentiated ones. In a previous chapter it has been pointed
out that Weismann's idea that regeneration has been acquired by a
process of natural selection, and is under the influence of this sup-
posed agent, is in direct contradiction to a number of known facts.
Under these circumstances we are warranted, I think, in concluding
that the entire Weismannian point of view is wrong.

The process of regeneration has been often compared to the pro-
cess by which a broken crystal completes itself. Herbert Spencer, in
particular, has elaborated this idea. In his book on the Pi-inciplcs of
Biology, he says : "What must we say of the ability an organism has
to recomplete itself when one of its parts is cut off t Is it of the same
order as the ability of an injured crystal to recomplete itself } In
either case new matter is so deposited as to restore the original out-
line. And if, in the case of a crystal, we say that the whole aggregate
exerts over its parts a force which constrains the newly integrated mole-
cules to take a certain definite form, we seem obhged, in the case of
the organism, to assume an analogous force." Spencer has called
attention to a superficial resemblance between the renewal of a part
of a crystal and the regeneration of an animal, and without further
inquiry into the profound differences between the processes, assumes
that " analogous forces " are at work. Now that we know something
more of both processes, we find so much that is totally different, that
there remains no basis for Spencer's conclusion, namely, that analo-
gous forces must be present. Furthermore, Spencer's statement that
the whole crystal aggregate exerts over its parts a force of some kind
is diametrically opposed to our idea as to the method of "growth " of
a crystal in a saturated solution. The new material is added always
at the surface of the crystal, and the growth of each point is self-de-
termining. There is no central force that controls the deposition of
new material in the different regions. Rauber's work on the so-called
regeneration of the crystal has given us a clearer conception of how
the process is brought about. He has shown that when a piece is
broken from a crystal, and the crystal suspended in a saturated solu-

2 64 R^ GENERA TION

tion of the same substance, it becomes larger by the deposition of
new material over all its surfaces. The addition of new material may
be more rapid over the cut-surface than elsewhere, but it must not be
supposed that the more rapid " growth " takes place in order to com-
plete the form of the crystal, for the growth over the cut-surface fol-
lows precisely the same laws that regulate the " growth " over all the
other surfaces, that is taking place at the same time. In this respect
we find an essential difference between the regeneration of a crystal
and that of an animal, since in the latter the growth takes place only
over the cut-surface ; and, in forms that regenerate by proliferation, at
the expense of the old material, so that the old material is correspond-
ingly diminished as the new part grows larger. Regeneration may
even take place in an animal deprived of all food, and also in one that
is starving to death and diminishing in size. In those forms that re-
generate by a change in shape of the entire piece into that character-
istic of the typical form, the process bears not even the remotest
resemblance to the process in the crystal. It is so obvious from
every point of view that the comparison is entirely a superficial one,
that it seems useless to point out further differences between the two
processes.

Pfliiger ('83) has given, in brief outline, an hypothesis to account
for the process of regeneration. He states that since there is always
replaced exactly what is lost, the new part cannot arise from a pre-
existing whole germ. If, for instance, the leg of a salamander is cut
off at any level, as much comes back as is removed. The assumption
of a leg germ is insufficient to account for the fact that only as much
comes back as is lost, and not always a whole leg. Pfliiger, there-
fore, offers another hypothesis. He assumes that food material is
taken up at the wounded surface and organized into the substance of
the new part. The new material is laid down at the surface of the
old material, and is then organized into the kind of tissue that lay
just beyond that region in the whole limb. Upon this first layer a
new layer is deposited that is organized into the next part of the limb,
and so on, until the whole missing part is replaced. Pfliiger does
not give any idea of how the new material is deposited at the cut-sur-
face, but from what we know of the histology of the process we must
suppose, if we should adopt Pfliiger's interpretation, that new cells
are produced by the old ones, and that these new cells form the suc-
cessive layers out of which the new limb is produced. Pfliiger speaks
of an arranging molecular force, which we can only suppose, in the
light of what has just been said, to act from cell to cell through the
continuous protoplasm. Pfliiger also pointed out that in certain cases
the organization can take place only in a certain direction, that is, in
some forms regeneration can take place from one side of a cut-sur-

THEORIES OF REGENERATION 265

face, but not from the other. He interprets this as due to a polariza-
tion of the protoplasm, one surface having peculiarities that are
absent in the other.

There are certain objections to Pfliiger's hypothesis that suggest
themselves. In the first place the new part does not, in many cases,
replace all that has been removed, and hence it is difficult to see
how the building up in the way Pfliiger supposes, could take place.
In these cases the new material forms only the distal end of the
part removed, and the relation of the old to the new part is of sec-
ondary importance. Again, in cases of heteromorphosis, as when a
tail develops on an anterior cut-surface of a piece of an earthworm,
the result must be due to quite different factors from those suggested
by Pfliiger. The results are, in fact, the reverse of what the hypoth-
esis demands. Furthermore, when the entire piece is transformed
into a whole new organism, there is very little in the process to sug-
gest a change like that postulated by Pfliiger. On the other hand
there cannot be much doubt that the old part may have some influ-
ence, and in certain cases a very important influence on the new part,
but whether this is a purely molecular influence is open to doubt. In
whatever way this influence may act, it is only one of a number of
factors that take a share in the result. The amount of new material,
that is formed before the organization of the new part begins, seems
to be also a factor; and the one that determines how much of the
missing part can be replaced, and this in turn seems to be connected
with the lowest organization size that can be produced. The distal
end of the new part forms always the distal end of the organ that is
to be produced. If enough new material has developed (before the
organization of the new part takes place) to produce all of the miss-
ing part, the latter is formed, but if the material is insufficient to pro-
duce the whole structure, then as much of the distal end as possible
is formed. In some cases, as in the planarians, the missing interme-
diate regions may subsequently develop behind the distal part that is
flrst produced.

Sachs has advocated a view which has many points of similarity
to that of Bonnet, although, in reality, it is not a theory of pre-forma-
tion at all, but one of pure epigenesis. His idea rests on the view
that the form of a plant, or of an animal, is the expression of the kind
of material of which it is composed. Any change in its material
leads to a corresponding change in the form of the new parts.
Sachs holds that the idea of many morphologists, that there is for
each organism a specific form that tends to express itself, and which
controls the development of the organism, is a metaphysical idea that
has no ground in science. For instance, Sachs thinks that the flower
buds of a plant develop, not because of some innate, mystical force

266 RE GENERA TION

that causes the plant to complete its typical form, but because some
substance is made in the leaves which, being carried into the growing
region, becomes there a part of the material of that region, and from
this new material a flower is formed. Simple and clear as this
hypothesis appears to be at first sight, it will be found on more care-
ful examination that it fails to account for some of the most charac-
teristic phenomena of development and of regeneration. It may be
granted at the outset that the presence of certain substances may
undoubtedly influence the kind of growth of a new part ; but, on the
other hand, one of the most characteristic things of the organism is
that it asserts its specific nature within quite a wide range of change,
and, on the whole, resists the influence of other kinds of substances
than those connected with its ordinary life. While Sachs looked no
farther than the material substratum, and supposed that any change
in this altered the form, there is, at present, sufficient evidence to
show that it is the structure of the material that determines the most
important changes that take place in it. This means, if we attempt
to divest the statement of its somewhat metaphysical appearance,
that the material of the organism is not simply a mixture of different
kinds of materials, but a special kind of substance that has a definite
structure of its own. This structure may, of course, be changed, but
only by the addition of materials that the structure can take up as a
part of itself. If the material does not become a part of the struc-
ture or organization, it is without effect on the form.^ My meaning
can, perhaps, best be illustrated by the method of regeneration of
the tail of the fish from an oblique cut-surface. The growth of the
new part is not determined by the kind or by the amount of the new
material that is brought to the growing part, for, if it were, the new
part would grow at an equal rate at every point ; but the growth of
the new part is regulated by the form of the tail of each particular
kind of fish. The structure of the new part controls the growth of
the material of the new part, and not the reverse. The only inter-
pretation that can be given to this result is, I believe, that the new
material assumes a definite structure, or what we may call an organi-
zation, and the subsequent changes are controlled by the kind of
structure that is present; and since this structure has, as a whole, a
definite form, we can state that the form controls the material,
although the substitution of the word "form" for that of "the structure
of the new material " may give the statement an unfortunate, meta-
physical appearance.

In order to explain the regeneration of a piece of a plant, Sachs
supposes that two substances are produced by the plant, — one a stem-
(or leaf-) forming substance and the other a root-forming substance.

^ Unless it produces a physical change in the structure.

THEORIES OF REGENERATION 26/

If either of these substances combines with the protoplasm of any part,
a stem or a root is produced from that part. When a piece of the
stem is cut from a plant, these two substances accumulate, one at the
distal end and the other at the proximal end of the piece, and their
presence in these regions determines that new shoots develop at or
near the apex, and new roots at the base. Sachs tried to show that
the direction of the flow of these two substances is determined by the
action of gravity, — the lighter substance flowing to the higher parts,
and the heavier to the lower parts. We find here reproduced Bonnet's
idea of specific substances flowing in definite directions ; but Sachs
goes farther, and gives an explanation of the cause of the different
directions taken by the two kinds of substances, viz. that it is due to
the action of gravity. Vochting has shown, as we have seen, after a
thorough examination of the method of development of pieces of plants,
that Sachs's hypothesis fails to account for the results ; and he shows
also that an internal factor, which he calls the polarization, has the
most important influence on the regeneration.

It is not difficult to show that there are many other cases to which
the stuff hypothesis does not apply. If, as Bonnet attempted to show,
the regeneration is due to different stuffs, there is no explanation to
account for the flow in animals of head-forming stuffs forward and
tail-forming stuffs backward. In animals that regenerate laterally as
well as anteriorly and posteriorly, we should be obliged to assume
side-forming stuffs as well as head-forming and tail-forming stuffs ;
and since the kind of structures that are produced at the side are
different at each level, we should be obliged to assume that there are
many kinds of lateral stuffs. If regeneration can take place in a
dorsal and in a ventral direction, as, for example, when the dorsal and
the anal fins of teleostean fishes regenerate, there must also be stuffs to
account for their development. When regeneration takes place from
an oblique surface, it must be supposed that two or more of these
kinds of stuff are brought into action. The regeneration of just as
much of the limb of the salamander as is cut off also offers difficulties for
Sachs's view. If we assume a leg-forming substance, it fails to account
for the difference in the result at each level. If we assume that
different substances come into play according to the amount of the leg
that has been cut off, the hypothesis becomes as complicated as the
facts that it pretends to explain.

A special case, to which the stuff hypothesis has been applied by
Loeb and by Driesch, is that of tubularia, although the latter writer
has used the hypothesis only to a limited extent as involving quanti-
tative rather than qualitative results. There is present in the hydranth
and stem of tubularia a red pigment in the form of granules in the
endodermal cells. There is more of the red pigment in the stem near

2 68 RE GENERA TION

the hydranth than elsewhere. If a piece of the stem is cut off, it
closes its cut-ends, and a circulation of fluid begins in the central cavity.
In this fluid globules now appear that contain the red-pigment granules.
The globules appear to be free endodermal cells, or parts of such, that
have been set free in the central cavity. In the course of twenty-four
hours the new hydranth begins to appear near one end of the stem,
and in this region of the stem a much larger number of granules ap-
pear. A little later all the red granules disappear from the circulation.

Driesch has supposed that the red granules of the circulation be-
come a part of the wall of the new hydranth. The disappearance of
the red granules at this time from the circulation would seem to give
color to this view. But, on the other hand, I have found evidence
showing that this interpretation is incorrect. In the first place, the
granules that disappear from the circulation can be found lying in a
ball within the digestive tract of the newly formed hydranth ; hence
their disappearance can be accounted for, and we find that they are
not, or at least in large part are not, absorbed into the forming hy-
dranth.^ In the second place, there is a great increase in the number
of endodermal cells in the region in which the hydranth is about to
appear, and the thickening that results takes place some time before
the granules begin to disappear from the circulation. The new gran-
ules appear in the new endodermal cells, and are presumably formed
by them. Again, the hydranth, that develops later at the distal end,
appears when there are no granules in the circulating fluid, and yet
the hydranth may contain as much red pigment as does the proximal
one. Lastly, the development of very short pieces shows that at the
time of the formation of the new hydranth there is an enormous in-
crease in the number of red granules in the piece, for there are many
more of them contained in the new hydranth than were present in the
entire piece at the time of its removal.

Loeb has not referred to the red granules in the circulating fluid,
but simply to the red pigment which is present in the walls of the
piece. This is supposed to move forward into the hydranth region,
and call forth the development of a new hydranth. A study of the
number of the granules in the stem gives no support to this idea,
and the method of formation of single and of double hydranths in
short pieces shows that the increase in the nvmiber of granules in
the hydranth-forming region is not due to migration, but to local
formation.

That specific substances may have an influence on the growth of
certain parts cannot be denied, but it appears that in general they
play a very secondary role as compared with other factors that

1 Stevens ('oi) has found that this ball of red pigment is ejected from the mouth of the
new hydranth.

THEORIES OF REGENERATION 269

determine the form of the organism or the development of a part.
Vochting's beautiful experiments i^'i6) on tuberous plants show that
the presence of an excessive amount of food substances in the plant,
brought about by the artificial removal of the natural storehouses for
such material, may act on certain parts, such as the axial buds, or on
the stem, and cause them to produce structures that they do not pro-
duce under ordinary circumstances. The axial buds become swollen
and produce tuber-like bodies above ground, especially if the parts
are enclosed so as to be in the dark, since the light retards the growth
of tubers of all sorts. But it should not be overlooked that these
buds and stems are structurally the same things as the tuberiferous
stolons that have been removed, and hence the excess of material is
stored up in them in the same way as it is under normal circumstances
in the underground stems or stolons. The reaction is one normal to
the plant, although it usually takes place in a different part.

The preceding hypotheses that have been advanced to account
for the phenomena of regeneration, draw attention to some of the
most fundamental problems of regeneration and, even in those cases
in which the hypotheses have not given a satisfactory solution of the
problems, some of them have served the good purpose, both of direct-
ing attention to important questions and of leading biologists to make
experiments to test the new points of view. We should not underrate
their value, even if they have sometimes failed to give a solution of
problems, for they have been useful if only in eliminating certain
possibilities, and this simplifies all future work. So long as an
hypothesis is of a sort that it is within the range of observational and
experimental test, it may be of service, even if it prove erroneous ;
for our advance through the tangled thread of phenomena is not only
assisted by advances in the right direction, but all possibilities must
be tested before we can be certain that we have discovered the whole
truth. The value of a scientific hypothesis depends, it seems to me,
first, on the possibility of testing it by direct observation, or by experi-
ment ; second, on whether it leads to advance ; and, lastly, on its
elimination of certain possibilities.

The experiments described in Chapters II, III, IV, have shown that
there are many resemblances between the phenomena of growth and
of regeneration. It has been pointed out that when it could be shown
that certain external agents have a determining influence upon growth,
these same agents have a similar effect upon regeneration. This
also holds apparently for internal factors, although it is much more
difficult to demonstrate that this is true. The presence of an abun-
dance of food material in the tissues hastens regeneration in the same
way that growth is more rapid in a well-fed organism. Food may,
however, be looked upon rather as an external factor than as an

2 JO RE GENERA TION

internal one. An excellent example of an internal factor is found in
the interrelations of the parts to each other. This is shown in the
development of a piece of a plant in which the apical buds develop
faster than the proximal ones, and it appears that, in some way, the
development of the latter are held in check by the development of
the apical ones. Another case is found in the development of the
bilobed tail of certain fish in which particular regions are held in
check, while others grow at the maximum rate.

It is a curious fact that while we can cite several kinds of external
influences that affect the development and the regeneration of organ-
isms, the only internal factors that have been discovered are the so-
called polarity and this interrelation of the parts. Perhaps there
should also be added the specific nature of certain parts, limiting
the possibilities of new growth in these parts, and the presence
of the nucleus as necessary for the growth and regeneration of the
organism.

If it be admitted that the same factors that affect the growth also
affect in the same way the regeneration, we have made a distinct
advance. It is, moreover, not difficult for us to understand how this
is possible. If we consider first those cases in which growth takes
place at one or more points at which the cells are undifferentiated,
and compare this condition with that in regenerating animals that
produce new tissue by proliferation, we can picture to ourselves
that the same factors would act on the undifferentiated tissue in the
same way in both cases. This does not explain what causes the
organism to produce the new cells that appear over an exposed sur-
face, and we must search for other factors to account for the out-
wandering of cells, and for the local multiplication of the cells at the
cut-end. We find a parallel to those cases in which the growth of
an organism takes place throughout the whole body, in those animals
in which the regeneration also takes place in the old part. This com-
parison should not, however, be pushed too far, since, in some forms,
as, for example, a salamander, the growth of the animal takes place
throughout the body, while regeneration takes place by the prolifera-
tion of new material. The difference in the regenerative process in
a salamander and in a form like hydra is not due so much to the
inability of the old cells of the salamander to increase in number as
compared with those of hydra, but rather, it appears, to a certain
rigidity or stiffness of the body of the salamander that prevents the
rearrangement of the parts ; and the recompletion of the form takes
place in the direction of least resistance, i.e. at the open or cut-end
of the body.

Regeneration by means of morphallaxis takes place only in those
forms in which the body is not made up of a series of separated

THEORIES OF REGENERATION 2/1

parts. This kind of regeneration occurs in those organisms in
which the normal growth consists only in the enlargement of a sys-
tem of organs already present. A piece of an animal of this sort
usually contains the elements of each kind of organ, and from these
the new parts are produced, both by proliferation at the cut-ends and
by the enlargement of the parts that are present in the piece. In
forms with separate segments we find, in some cases, resemblances
between normal growth and regeneration, as shown, for example,
in the earthworm. There is present in the young worm a region in
front of the last segment, or, rather, a part of this segment, from
which new segments are formed. In the regeneration of the posterior
end a knob of new tissue is formed, and out of this a few segments
develop, the last one having a growing region similar to that in the
young worm. The subsequent stages in the regeneration involve
the formation of new segments from the last one, as in the young
worm. There is no such growing zone at the anterior end of the
young worm, and none is formed in the regeneration of an anterior
end, so that only the segments that are first laid down in the new
part are present in the new anterior end.

An interesting comparison may be made between the phenome-
non of growth and that of contraction and expansion of the proto-
plasm. The bending of heliotropic organisms toward or away from
the light, and the similar bending of negatively stereotropic forms
away from contact with a solid body, are supposed to be phenomena,
of growth, and resemble in many ways the phenomenon of contrac-
tion. In a plant that bends toward the light, it is found that the
most obvious change involves the amount of water on the two sides
of the stem, and this is most probably connected with a fundamental
'structural change in the protoplasm, that is too subtile for further
analysis. In the regeneration of some forms it is found that they re-
spond in the same way to light. While it cannot be demonstrated
that these phenomena really depend on processes of contraction
and of expansion, the results are nevertheless suggestive from this
point of view. Furthermore, I think, one cannot study the regenera-
tion of such forms as planarians, hydras, stentors, etc., without being
struck by the apparent resemblance of the change in form that they
undergo to a process of expansion. The idea of the expansion of
a viscid body carries with it, of course, the idea of tension within the
parts, and the return to the former condition is brought about by a
release from the tension and a return to a more stable condition.
If by the intercalation of new material the extended condition is
fixed, a new state of equilibrium will be established.

It has been already pointed out that in a piece of a plant suspended
in a moist atmosphere, the apical buds are those that first develop.

2/2 RE GENERA TION

and also grow faster than, the others. The buds situated nearer the
base may not even begin to develop, although they are at first as
favorably situated, so far as external circumstances are concerned, as
the uppermost ones. The roots appear first over the basal end,
and those nearer the base grow faster than do those nearer the
apex. There cannot be much doubt that the suppression of the
basal buds and of the more apical roots is connected with the devel-
opment of the apical buds and of the basal roots. This can be
shown by cutting a piece in two, when some of the basal buds will
grow into shoots and the apically situated root-buds, that are
now on the base of one piece, will begin to grow. It seems to me
this relation can be at least more fully grasped, if we look upon it as
connected with some condition of tension in the living part. The
tension can be thought of as existing throughout the softer, more
plastic parts. As long as the apical bud is present at the end of a
stem or branch, or even near the apex, it exerts on the parts lying
proximal to it a pull, or tension, that holds the development of these
parts in check ; but if the apical bud is removed the tension is relaxed,
and the chance for another bud developing is given.

It may be asked, how can it be explained that only the more api-
cally situated buds of a piece develop, rather than the basal ones,
since with the removal of the piece from the plant the tension has
been removed also. The only answer that can be made, so far as I
can see, would be that from the apex of the plant to its base the ten-
sion is graded, being least at the apex and increasing as we pass to
the base. Those buds will first develop that are in the region of least
tension, and their development will hold in check the other buds by
increasing or reestablishing the tension on the lower parts of the
piece. A new system is then established, like that in the normal
plant.

There are certain experiments with hydra that can, perhaps, be
brought under the same point of view. When two long posterior
pieces are united by their anterior cut-surfaces, each piece regener-
ates a circle of tentacles near the region of union, and each may pro-
duce a new head ; or only one head, common to both pieces, develops
at the side. Each piece has retained its individuality, which may
be interpreted to mean that each piece has retained its original con-
dition of tension. If, however, after a union of this kind one piece is
cut off, as soon as the two have well united, near the place of union,
so that it is relatively small as compared with the other component,
it may produce a head at its exposed basal end, and neither heads
nor tentacles may develop at the place of union of the pieces.

It is probable, in this case, that the larger component has acted
on the smaller one, so that its polarity is changed and becomes like

THEORIES OF REGENERATION 273

that of the larger component. It is possible, I think, to interpret
this result in terms of our tension hypothesis. The condition of ten-
sion in the larger piece has overcome that of the smaller piece, so
that the latter comes to have the same orientation that the larger piece
has ; and the development of a head at the free end then takes place.
The development of this head holds in check the development of a head
at the anterior end of the larger piece in the region of union of the
pieces. When two pieces of hydra are united by unlike poles, i.e. so
that they have the same orientation, it is found that if the pieces are
not too long, a head develops at the free end and none in the region
of grafting. The result is similar to that in plants ; the development
of the head at the free end suppressing any tendency that may exist
to produce a new head by the posterior piece at the place of union.
If the pieces united in this way are very long, a head develops at the
apical end, and, in some cases, also near the line of union. This may
be due to the pieces being so different at the place of union, that
a head develops below this region before the unification of the two
pieces is brought about, or because the formation of the head at
the free end is relatively so far removed from the place of union of
the pieces, that it does not influence the development of a head in
this region.

These cases of grafting also illustrate another point of some
interest. They show that the development of a head at the anterior
end of a piece is not the result of the injury from the cutting or
due to the action of some external condition on the free end, for
the regeneration may take place when two anterior ends have been
perfectly united to each other. The result can only be explained as
the outcome of some internal factor such as polarity.

These examples have been chosen from hydra rather than from
tubularia, in which somewhat similar phenomena have been observed,
because in hydra the development of heteromorphic structures is of
rare occurrence, while in tubularia external influence often calls forth
a heteromorphic development. There cannot be much doubt, how-
ever, that in tubularia the same kind of internal factors are also at
work.

A more striking illustration of the possible influence of tension of
the parts is shown by an experiment with planarians. If the head
of a planarian is cut off and the posterior piece is split partially in
two along the middle line, as shown in Fig. 31, A, and then one of
the halves is cut off just anterior to the end of the longitudinal cut,
the result is as follows : A new head develops at the anterior end
of the long half (Fig. 31, B), but no head develops on the posterior
cut-surface, provided this part has reunited along the middle line
with the long half, and a line of new tissue connects the anterior

2/4 ^^ GENERA TION

cut-surface of the long half and the more posterior cut-surface of the
shorter half. At least this happens if the piece is not split too far
posteriorly, i.e. through the region of the pharynx. If this is done,
a new head may develop from the posterior cut-surface. In another
way the development of the more posterior head can be brought
about. If the shorter side-piece is kept from fusing with the longer
side-piece in the middle line, it will invariably produce a new head
(Fig. 31, Cy The lack of development of the posterior head, when
the two cross-cut surfaces are united by a connecting part of new
material, can, it seems to me, be best explained by the influence of
the developing anterior head, or of the new side on the posterior new
tissue, and this influence can, I think, be better appreciated if we
suppose some sort of tension to be the influence at work.

Another example may be cited that shows even more clearly that
the internal factor regulating the growth in the new part is probably
some sort of tension. I refer to the development of the tail of
fundulus from an oblique cut, or of the bilobed tail of stenopus from
a cross cut. The assumption of the typical form that leads to the
holding in check of the growth in certain regions, as compared with
others, can be best understood, I think, as due to some sort of ten-
sion established in the different parts, that regulates the growth in
those regions.

It is evident that whatever factor will serve to explain the preceding
cases must also be expected to apply to the development of the whole
embryo from parts of the Q.^g or blastula, if the position that I have
taken is correct, namely, that these phenomena belong to the same
general group. Does the tension hypothesis make clearer the devel-
opment of a whole embryo from a part of an o.^'g ? This means, can
we think of the readjustment that takes place as due to the establish-
ment of a characteristic equilibrium that expresses itself in the
tensions of the different regions .-' There is, so far as I can see, no
difficulty in supposing that the organization is at bottom a system of
this kind ; indeed, it seems to me that from this point of view we can
get a better appreciation of the organization and of the series of
changes that take place in it during development. The example that
Driesch has chosen as a typical one of vitalistic action, namely, the
proportionate development of a part of the archenteron of the half-
embryo, seems to me to be likewise a case to which we can apply the
tension view.

In these, as well as in all other cases, we must think of the ten-
sions as existing, not only in one direction, but in the three dimensions
of space, and of all combinations of these. The material in which
the tensions exist must be thought of as labile, so that a change in
one region involves a rearrangement in many cases of the entire sys-

THEORIES OF REGENERATION 2/5

tem. The new rearrangement appears to take place on the founda-
tions of the old system.

It may appear that this idea of a system of tensions is too vague,
that it fails to point out how the reorganization takes place, and that
it gives not much more than the facts do themselves. There is a
certain amount of truth in these objections which I fully appreciate,
but something further can be said on these points. The view is
vague in so far as we cannot picture to ourselves in a mechanical
way just how such a system could bring about the suppression of
growth in one region and allow the maximum amount in another
region. But this is asking too much, since the hypothesis can only
claim, at present, to furnish a means by which we can at least
imagine what sort of a process is involved, and cannot give the
details of the process itself. It can be shown experimentally that if
the phenomenon is one of tension certain results should follow that
are observed to take place, as when by keeping the shorter half of
the planarian from reuniting to the larger half, or by breaking the
union if it has been formed, a head develops also at the posterior
cross-cut. In the second place, although we cannot understand how
the rearrangement of the tensions in a piece takes place, yet from
a causal point of view we can see how a change in one region of a
labile system may produce, by means of a change of tension, a com-
plete rearrangement of the parts throughout. It can even be
claimed for the tension hypothesis that it at least becomes easier for
us to see how such a change could take place, because it represents
the organization as the expression of a system under tension, and
hence, if the material is sufficiently flexible, a readjustment will proba-
bly take place when the system is changed in any region. It enables
us to see how the organization of the egg may be divided by every cell
division, and yet after the reunion of the cells the original equilibrium
be established. We may perhaps claim, therefore, that in these re-
spects the hypothesis does give us something more than do the
facts ; and, inasmuch as it brings a large number of phenomena under
a common point of view, the idea may be worth further consideration.

In conclusion, I may add that the hypothesis is, I hope, also a legit-
imate one, in the sense that being within reach of an experimental proof
or disproof, it may serve at least as a working hypothesis. Per-
haps more fundamental than the idea that a system of tensions
exists throughout the organization is the conception that the organi-
zation is itself a system of interrelated parts, and not a homogeneous
substance or a mass composed of a large number of repeated parts,
or rather, despite the presence of smaller, repeated units, the organi-
zation is not the result of their interaction, but of their regular
arrangement as parts of a whole structure. If, then, this inter-

2 16 RE GENERA TIOiV

relation of the different parts of the structure can be looked upon as
the result of a system of tensions, we can at least form a better idea
as to how a piece of a whole can readjust itself into a new whole of
smaller size. And it is this possibility of rearrangement or regula-
tion that is one of the most characteristic properties of living things.

CHAPTER XIV
GENERAL CONSIDERATIONS AND CONCLUSIONS

In the preceding chapters certain matters had to be taken for
granted, since it was not possible, or desirable, at the time to discuss
more fully some of the terms that are in common use, or to analyze
more completely many of the phenomena. It was also not necessary
to give the general point of view under which the phenomena were
considered in their physical, chemical, or even causal connection.
Little harm has, I trust, been done by relegating such questions to
the final chapter. An attempt will now be made to give more explicit
statements in regard to the use and meaning of such terms as " organi-
zation," "polarity," "factors," "formative forces," " vitalistic " and
"mechanical principles," "adaptation," etc.

It will be found that the hypotheses that have been advanced to
account for the phenomena of development and of regeneration may
be roughly classified under two heads : first, those in which the organi-
zation is " explained " as the result of the collective action of smaller
units ; and second, those in which the organization is itself regarded
as a single unit that controls the parts. Let us examine these points
of view more in detail, in order to see what has been meant in each
case by "the organization."

A favorite method of biological speculation in the last forty years
has been to refer the properties of the organism to invisible units,
and to explain the action of the organism as the resultant of their
behavior. The hypothesis of atoms and of molecules, by means of
which the chemist accounts for his reactions, has proved so exceed-
ingly fruitful as a working hypothesis that it has had, I think, a
profound influence on the mind of many biologists, who have, con-
sciously or unconsciously, attempted to apply a similar conception
to the structure of living organisms. The discovery that all of the
higher organisms are made up of smaller units, the cells, and that
the lower organisms are single, isolated cells, comparable to those
that make up the higher forms, has also drawn attention to the idea
that the whole organism is the result of the action of its units. Fur-
thermore, within the cells themselves units of a lower order have also
been discovered, such, for instance, as the chromosomes, the chloro-

277

278 RE GENERA TION

phyl bodies, etc., that repeat on a smaller scale some of the
fundamental properties of the entire organism, as growth and divi-
sion. It has been assumed that still farther down in the structure
there are smaller units having the same properties, and the smallest
of these are the ultimate units. The organism is looked upon as the
result of the properties of these minute germs. The gemmules of
Darwin furnish an example of an hypothesis of this sort ; also the
intracellular pangens of De Vries, the plasomes of Wiesner, the bio-
phors of Weismann, the idiosomes of Hertwig, and the micellae of
Nageli are other examples of this way of interpreting the organization.
These elements are endowed by their inventors with certain properties,
and these are of such a sort that they give the appearance of an explana-
tion to organic phenomena. It is useless to object to these hypotheses
that they are purely ideal, or fictitious, and that those properties have
been assigned to the germs that will bring about the desired explana-
tion, and have not been shown to be the real properties of the germs
themselves. But apart from the arbitrariness of the process, it cannot
be claimed that a single one of these creations has been shown to be
true, or has even been accepted by zoologists as probable. A more
serious objection to this point of view is that the most fundamental
characteristics of the organism, those that concern growth, develop-
ment, regeneration, etc., seem to involve in many cases the organism
as a whole. So many examples of this have been given in the preceding
pages, that it is not necessary to go over the ground again. It has
been shown that a change in one part takes place in relation to all
other parts, and it is this interconnection of the parts that is one of the
chief peculiarities of the organism. In phenomena of this kind even
the cells seem to play a secondary part, and if so, we can, I think,
safely leave out of account the smaller units of which the protoplasm
is supposed to be built up and we can neglect them, if for no other
reason than this, that the argument that has called them into existence
starts out with the cell as the highest unit. If the cell can be thrown
out, most probably the units of which the cell itself is supposed to be
made up can be safely disregarded also.

It may be objected that only through a knowledge of the minute
structure of the organism can we hope to understand the behavior of
the whole ; but my point of view is not that there may not be a funda-
mental structure, but that this is not formed by a repetition of ele-
ments, which give to the whole its fundamental properties. It can be
shown, I think, with some probability that the forming organism is of
such a kind that we can better understand its action when we con-
sider it as a whole and not simply as the sum of a vast number of
smaller elements. To draw again a rough parallel; just as the
properties of sugar are peculiar to the molecule and cannot be ac-

GENERAL CONSIDERATIONS AND CONCLUSIONS 2/9

counted for as the sum total of the properties of the atoms of carbon,
hydrogen, and oxygen of which the molecule is made up, so the prop-
erties of the organism are connected with its whole organization and
are not simply those of its individual cells, or lower units.

The strongest evidence in favor of this view is found in the
behavior of small pieces of an Q.gg, or of a protozoon, or even of a
many-celled organism. A lower limit of organization is very soon
reached, below which the piece fails to produce the characteristic
form, although all the necessary elements are present in the piece to
produce the entire structure. The size of these pieces is enormously
large as compared with the size of the cell, or of the imaginary ele-
ments of Nageli, Weismann, Wiesner, etc. These results indicate
that the organization is a comparatively large structure.

A few writers have either ignored the presence of smaller units,
or have dealt with the organism from a purely chemical and physical
point of view. They attempt to account for the changes in the
organism as the outcome of known physical and chemical princi-
ples. It must, of course, be granted that in a sense the properties
of the organism are the result of the material basis of the organism ;
but in another sense this idea gives a false conception of the
phenomena of life, because, if we were simply to bring together those
substances that we suppose to be present in the organism we have no
reason to think that they would form an organism, or show the
characteristic reactions of living things. Even from a chemical point
of view we can see how this result could not be expected, for it is
well known that the order in which a compound is built up, i.e. the
way in which the atoms or molecules are introduced into the structure,
is an important factor in the making of the compound. When we re-
member the immense period of time during which the organisms living
at present have been forming, we can appreciate how futile it will be
to attempt to explain the behavior of the organism from the little we
know in regard to its chemical composition. Its chief properties
are the result of its peculiar structure, or the way in which its ele-
ments are grouped. This structure has resulted from the vast num-
ber of influences to which the organism has been subjected, and
while it may be granted that if we could artificially reproduce these
conditions an organism having all the properties that we associate
with living things would result, yet the problem appears to be so
vastly complicated that few workers would have the courage to
attempt to accomplish the feat of making artificially such a structure.
To prevent misunderstanding, it may be added that while from the
point of view here taken, we cannot hope to explain the behavior
of the organism as the resultant of the substances that we obtain
from it by chemical analysis (because the organism is not simply

2 80 RE GENERA TION

a mixture of these substances), yet we have no reason to suppose that
the organism is anything more than the expression of its physical and
chemical structure. The vital phenomena are different from the
non-vital phenomena only in so far as the structure of the organism
is different from the structure of any other group of substances.

Nageli has stated that each part acts as though it knezv what the
other parts are doing. His idea of the idioplasm involves a con-
ception of the organism as a whole and not simply the sum total
of a number of parts. Hertwig, who maintained at one time that
the development of the embryo is the resultant of the action of the
cells on each other, admits in his work on Die Zelle und die
Gewebe that while this is in part true, yet on the other hand the
whole also exerts an influence on its parts. Driesch, who hypotheti-
cally suggested at one time that the nuclei act as centres of con-
trol of the cell by means of enzymes, has later adopted a widely
different view. Whitman has made a strong argument to the effect
that the cell theory is too narrow a standpoint from which to
treat the organism, and on several occasions I have urged that the
organism is not the sum total of the action and interaction of its
cells, but has a structure of its own independent of that of the cells.

This discussion will suffice to show some of the opinions that have
been held as to the nature of the organization of the organism. Let
us next ask what properties we may ascribe to it.

It has been found that certain polar, or rather dimensional, rela-
tions are characteristic of the organization. The term "polarity" ex-
presses this in a limited way, but refers only to one line having
two directions, while we now know that the -dimensional properties
relate to the three dimensions of space, and for this idea we might
make use of the term heterotropy. Thus we find that a piece of
a bilateral animal regenerates a new anterior end from the part that
lay nearer the anterior end of the original animal, a new right side
from the part that was nearest the original right side, and a new
dorsal part from the region that lay near the original dorsal
part, etc.

The polarity of a part can be changed in certain forms, as in
tubularia, by exposing the posterior cut-end to the external factors
that bring about the formation of a hydranth, or, as in hydra, by
grafting in a reversed direction a smaller piece on a larger one. In
Planaria liigiibris and in the earthworm the polarity of the new
tissue may be reversed, as compared with that of the part from which
it develops, if the new part arises from certain regions of the body.
A curious instance of the effect of the polarity is shown by the regen-
eration from an oblique surface in planarians. The new head arises
from the more anterior part of the new material, rather than from the

GENERAL CONSIDERATIONS AND CONCLUSIONS 28 1

middle of the anterior oblique surface, and the new tail arises from
the more posterior part of the posterior obhque surface. As an analy-
sis of this result has been already attempted in an earlier chapter, it
will not be necessary to go further into this question here.

The development of a new part at right angles to an oblique sur-
face has also been described, and it has been pointed out that the
result appears to be due to the symmetrical development of the new
structure in the new part. This symmetry of the newly forming part
must be also counted as one of the properties of the organization.

Finally, the mode of regeneration of a new, bifurcated tail in the
teleost, stenopus, shows that the new part may very early become
moulded into the characteristic form, and that the growth of the
different parts is regulated by the structure assumed at an early
stage. The new part does not grow out at an equal rate until it
reaches the level of the notch of the old tail, and then continue to
grow at two points to produce the bilobed form of the tail ; but
the bilobed condition appears at the very beginning of the develop-
ment.

These illustrations give us nearly all the data that we possess at
present on which to build up a conception of the organization. That
we must fail in large part fully to grasp its meaning from these meagre
facts is self-evident. The main difficulty seems to lie in this, — that
when we attempt to think out what the organization is we almost un-
avoidably think of it as a structure having the properties of a machine,,
and working in the way in which we are accustomed to think of ma-
chines as working. The most careful analysis of the " machine
theory," as applied to the phenomena of development and of re-
generation, has been made by Driesch. It has been pointed out that
in his Analytische Theoj'ie Driesch asstrmed that development is due
to " given " properties in the Q.gg ; that each stage is initiated by some
substance contained in the Q,gg acting on the stage that has just been
completed. That is, each stage is the condition of the following.
The "rhythm" of development is accounted for in this way. The
changes are described as due to chemical processes (including also
ferment actions). The nucleus is supposed to contain all the different
kinds of ferments that act, when set free, as stimuli on the protoplasm ;
but since the ferments are always set free at the propitious moment,
Driesch was obliged to assume that the cytoplasm acts on the nucleus
in such a way as to make it produce the proper ferment for the next
stage. Thus the cytoplasm first influences the nucleus, the latter
sets free a specific ferment that starts a new chemical change in the
cytoplasm, and the changed cytoplasm may then react again on the nu-
cleus, and a different ferment be set free, etc. Each change is there-
fore not only an effect of what has gone before, but the cause of the

282 RE GENERA TION

next process.^ Driesch points out that it is necessary at this stage to
make a further assumption, because the cytoplasm must not only be
acted upon by the ferment, but it must itself be of such a sort that it
responds to the action. This leads to a great complication of the
phenomena; but the assumption does not depart, in the last analysis,
from the idea of the cell as a system in a mechanical sense. This
assumption of a receiving and an answering station for the stimuli
carries with it the further assumption of a many-sided " Jiarmonyy
Without a harmony at each step in the development there could be
no orderly ontogeny. The assumption of this harmony introduces a
new element into the series of hypotheses. The appearance of a causal
explanation was given in those parts of the argument preceding the
introduction of the assumption of a harmony, but with the admission
of this new element into the argument, the causal point of view is left.
Driesch says in this connection : " If we cannot gain a singleness of
view in the way that has been followed, we can reach this in another
way. Indeed, the way of doing so has been already implied in that
part of the theory dealing with the harmony of the phenomena. The
existence of this harmony is inferred, because, in the large majority of
cases, the ontogeny leads to a typical result. Therefore we must
assume that the conditions for the end result are given — the con-
ditions are the harmony itself." Put somewhat less obscurely, if more
crudely, we may express Driesch's idea by saying that the harmony
that stands for a hen is given in the hen's Q,gg.

Driesch adds : " Because a typical result always follows, therefore
every single step in the ontogeny must be judged, from an analytical
standpoint, from the point of view of the result itself. The result is
VciQ purpose of the ontogeny. It is as though we visited daily a wharf
where a ship is being built, — everything appears a chaos of single
pieces, and we can only understand what we see when we consider
what is to be made. Only from a teleological point of view can we
speak of a development, for this term expresses the very existence of
an object to be developed. The term is used fraudulently if it is
intended to mean that the development is the outcome of 'processes,'
using this term in the sense that a mountain or a delta develops from
physical processes." " We can only reach a satisfactory view of the
phenomena when we introduce the word 'purpose.' This means that
we must look upon the ontogeny as a process carried out in its order
and quality as though guided by an intelligence. We arrive at this
conclusion, because the individual whole is 'given,' as the clearly
recognized goal of the entire process of development."

^ The importance of this conception is, in my opinion, marred by the fiction of the ferment
action of the nucleus; but it should not be overlooked that, Driesch avowedly called this a
pure fiction.

GENERAL CONSIDERATIONS AND CONCLUSIONS 283

In a later attempt to analyze the problem of development, Driesch
examined it more fully from the point of view of the machine theory.
This contribution must be looked upon rather as a tour de force that is
intended to show how far this idea can be carried in its application
to development. Driesch explains that in his analytical theory he
assumed from what is " given " in the egg that the o.^g can be under-
stood causally, as a machine is understood, but what is "given " can
be understood only teleologically. He says : " What I defended was
not vitalism, but, so far as the phenomena of life are concerned,
exactly the current physico-chemical dogmatism ; but I did not fail to
see and to point out the consequences of this dogmatism, which every
one (except Lotze) has avoided, viz., that the adaptive basis in which
the living phenomena take place is ' given.' " Driesch defines his
view as f ormal-teleological, in contrast to vitalistic. The former may
also be called a machine theory of life in which the purpose is given,
not explained.

In later writings Driesch has thrown over some of his earlier con-
clusions and adopted a causal-vitalistic philosophy. The basis of this
new conception is found in the proportional development of parts of
an original whole, as has been explained in a preceding chapter.
This result belongs to a category of phenomena that is in principle
not machine-like, but of a specifically different kind. It is something
that cannot be explained by the agencies of the outer world, such as
light, gravity, salinity, temperature, etc. After examining other
hypotheses, Driesch returns to a view that he had previously re-
jected, viz. the conception of "position," by which is meant the influ-
ence of the location in the whole. This position has certain directions,
but nothing in addition that is typical. By the term " location in the
whole " is meant that the word "location" {Lage) shall refer not to ge-
ometric space, but to the organization of the object that has its own
directions. A deformation of the whole may change very little the
relative location of the parts.

In his earlier writings Driesch rejected this idea, because it did
not seem to satisfy our etiological need, and also because he thought
that he could reach his goal from the standpoint of initiating stimuli
{Anslosungen). Driesch now assumes that the stem of tubularia and
the archenteron of the starfish, for example, have a polar structure.
Bilateral forms, as the whole larva of the starfish, have a coordinated
system of two axes with unlike poles and one axis with like poles,
each of a given length or proportion. The ends of the axes are char-
acteristic points of the system. If, in such a system, a typical act of
differentiation appears, to which we can assign a cause, so far as the
location is concerned, a change will occur as follows : To take the
simplest case, that of a system with only one axis having unHke poles, as

2 84 R^ GENERA TION

the archenteron of the starfish, in which differentiation has not begun,
we can picture to ourselves the formation of the divisions of the archen-
teron in a causal way by supposing the end of the axis, or pole, to be
the location (^Sitz) of an initiative " action at a distance " {anslosende
Fernkraft). This locality, just because it is the end of a system,
is something special ; and it acts in such a way that wherever an effect
is produced, it is the cause of that effect. This very way of looking
at the problem postulates a sort of causal harmony. But how, it may
be asked, can a special point or pole of an axis bring about an action
in the system } This can be shown by means of a simple case, viz.
the dividing up of the archenteron of the starfish into its character-
istic parts. There are two effects produced, viz. the formation of the
two constrictions of the wall. We need not consider the fact that the
constrictions are formed, for this is established in the potence of the sys-
tem, and is awakened by the initiating cause, but the place at which
the constrictions are produced is that for which we should account.
We must think of this cause as "action at a distance," and indeed as
an " action at a distance " that works at a determinate, typical dis-
tance. This inherent measure of distance of the action is not one of
absolutely fixed size, for a gastrula made shorter by an operation also
subdivides into proportionate parts. The action starts from the poles
of the system, and acts, not at an absolute, but at a relative distance,
since it is dependent upon the length of the axis of the whole differ-
entiating system. " The localization of ontogenetic processes is a
problem stii generis. The phenomenon can always be expressed on
the scheme of cause and effect, if we assume the ' action at a dis-
tance' to start from fixed points of a differentiating system."

In regard to the criterion of vitalistic phenomena Driesch makes
the following statement : " On the current view we are inclined to
see, in the formative changes, actual causes at work that even initiate
those processes that we call stimuli ; we do so because we pretend at
present to know something of the special mechanism by which the
formative changes work. The effects come into play through a
causal union of simple processes of a physical-chemical sort that we
may call a chain of stimuli. From the new point of view, the initia-
tory stimulus is not an initiatory cause or the effect of a causally
united chemico-physical phenomenon. The stimulus is, from this
point of view, a true stimulus, but the effect is not a true effect of
its initiation, but is rather to be designated a responsive effect, for
there is no connecting chain of stimuli. It is in the place of the
latter that the vitalistic view appears. The only data of a machine
sort in the conception are the arrangements for the reception and
guidance of the stimulus, perhaps also the means for carrying out
the response effect ; for the machine data are only the prerequi-

GENERAL CONSIDERATIONS AND CONCLUSIONS 285

sites of the phenomena, but in themselves do not bring about the
result."

Driesch finds in this argument a demonstration of the vitalistic
doctrine, but vitalism, of course, of a very special kind. Without a
more elaborate presentation of his view it is not possible to give a
detailed criticism of his conclusions ; but a few of the more obvious
objections that may be brought against this view may be discussed.
The assumption of "action at a distance" does not, I think, in any
way help to make the phenomenon clearer. The formation of a
typical larva of normal proportions from a piece of an ^gg is just as
mysterious after the assumption of an "action at a distance" of a
proportionate sort as it was before. Driesch has introduced into the
argument to establish a vitalistic standpoint one of the most obscure
ideas of physical science. There is, so far as I can see, no necessity
for such an assumption, since there is present in every case a contin-
uous medium of protoplasm, which would seem to make this idea at
least superfluous. Moreover, the additional element that Driesch has
added to his conception of the process, namely, an action in propor-
tion to the size of the piece, is objectionable if for no other reason
than that it attributes to the unknown principle of " action at a dis-
tance " a quality that is the very thing that ought itself to be
explained. This assumption, it seems to me, begs the entire ques-
tion, and we can give no better explanation why it should belong to
the principle of " action at a distance " than to anything else. Far.
from having given a demonstration of vitalism, Driesch has, I think,
in his analysis simply set up an entirely imaginary principle, which,
taken in connection with other undemonstrable qualities, is called
vitalism.

If we cannot accept Driesch's demonstration of vitalism, from
what point of view can we deal with the phenomenon of the produc-
tion of a typical form from each kind of living material "i Can we
find a physico-chemical explanation of the phenomenon } Enough
has been said to show that this property is one of the fundamen-
tal characteristics of living things and is, in all probability, a phe-
nomenon which we certainly cannot at present hope to explain.
Yet the question raised by Driesch is, at bottom, not so much
whether we can give a physico-chemical explanation, but whether
the phenomenon belongs to an entirely different class of phenom-
ena from that considered by the physicist and by the chemist. Let
us examine the results and see if we are really forced to conclude
that there is no other physico-causal point of view possible.

In many cases in which a response to an external stimulus takes
place, we must assume a physico-causal connection between the
stimulus and the effect. The action of poisons, for instance, is an

286 KE GENERA TION

example of this kind, and,, in some cases, as in the formation of the
galls of plants, the stimulus of a foreign body may lead to the devel-
opment of a structure, the gall, of a definite form. The experiments
of Herbst on the effect of lithium salts in sea water on the develop-
ment of the sea-urchin embryo lead to a similar conclusion. The
changes in form that result from other external agents, such as light,
gravity, contact, etc., can be best understood from a physico-causal
point of view, and it seems improbable at least that their action
within the organ is transformed into a vitalistic causal action through
Driesch's principle of an " action at a distance." ^ The effect of inter-
nal factors on the change of form is, however, much more difficult
to deal with, since we know so little at present about these factors.
Here we find amongst other phenomena that of the proportionate
formation of a whole organ from a part of an old one, or of an egg.
We find it difficult, if not impossible, to attribute this directly to
external causes, yet, as I have tried to show, the first steps through
which this takes place can be referred to physico-causal principles.
These are the separation of the piece from the whole ; the change of
the unsymmetrical piece into a symmetrical one, brought about, in part
at least, by contractile phenomena in the piece, aided, no doubt, in some
cases by surface tension, etc. These changes give the basis for the
development of a new organization along the lines of structure that
are already present in the piece. We find here the beginning of a
physico-causal change, and, so far as I can see, we have no reason
to suppose that at one stage in the process this passes over into the
vitalistic-causal principle. It should, I think, be pointed out in this
connection that even in the physical sciences it would not be difficult
to establish a vitaHstic principle, or whatever else it might be called,
if we chose to take into account such properties of bodies as those
which the chemist calls the affinities of atoms and molecules, or the
symmetrical deposition of material on the surface of a crystal from a
supersaturated solution, etc. These phenomena are usually looked
upon as " given," that is, beyond the hope of possible examination.
Until these questions are more fully understood scientists are, I
think, justified in showing a certain amount of self-restraint in regard
to the solution of such problems. Du Bois-Reymond has summed
up this point of view in the dictum, " Ignorabimus," which is inter-
preted to mean, not only that we are ignorant at present on certain
questions, but that we know we must remain ignorant. The forma-
tive changes in the organism appear to belong to this category of ques-
tions. This confession of ignorance need not mean that we cannot
hope to discover the conditions under which the phenomena take place,
so that we can predict with certainty what the results will be, but

1 Not that Driesch supposes this would be the case.

GENERAL CONSIDERATIONS AND CONCLUSIONS 28/

the meaning of the change itself may remain forever obscure, at
least from our present conception of physico-chemical principles.
Shall we, therefore, call ourselves vitalists, because we find certain
phenomena that we cannot hope to explain as the result of physical
principles, or for which we must invent an unknown principle ? Or
can we succeed in demonstrating a different kind of principle in liv-
ing things ? If we could, we might be justified in calling ourselves by
the name of vitalists. But who has made such a discovery } Does
the well-known phenomenon of proportionate development give a
demonstration of the unknown principle.'' Would one be justified
in claiming a different principle that is not a physico-causal one,
because the nerve impulse is different from any known physical phe-
nomenon .'' The preceding pages have made clear, I hope, that, for
my own part, I see no grounds for accepting a vitalistic principle
that is not a physico-causal one, but perhaps a different one from
any known at present to the physicist or chemist.

In order to make clear in what way certain terms have been used
in the preceding chapters, it may not be out of place to indicate how
it is intended that they should be employed. The word "cause" has
been used in the sense in which the physicist uses the term. A "stim-
ulus" is the chain of effects of a cause acting on a living body. In cer-
tain cases the cause itself may be spoken of as the stimulus, but
only when its specific action on a living body is implied. A "factor"
is a more general term and is usually one or more of a number of
causes that produce a result. It may prove convenient to use this term
where a change in form is produced. Thus the size of a piece is one
of the factors that determines the result ; the part of the body from
which the piece is taken may also be a factor, or rather the kind of
material contained in the piece. These examples will suffice to show
that the word is used for an observed connection of a very general
sort, especially for those cases in which we have not analyzed the
factor into its components. The term is especially useful for cases
in which the change in form is the outcome of the innate properties
of the organization. The term may be used so that it need not preju-
dice the result, either in favor of a physico-causal or a vitahstic-
causal point of view. It may be convenient to use it as an indifferent
term in these respects. The word "force " I have attempted to avoid
as far as possible, except in such current expressions as " the force of
gravity," etc., for, apart from the loose way in which the word is used
even by physicists, we know so little about the forces in the organ-
ism that it is best, I think, to use the word as sparingly as possible,
and only where a known physical force can be shown to produce an
effect.

288 iiE GENERA TION

Much misunderstanding has arisen in connection with the term
" formative force." In the first place we naturally associate with this
term the meanings attached to it by writers of the seventeenth and
eighteenth centuries. They assumed a formative principle in living
things, that is an expression of a formative force. Roux, who has
more recently used the term, has attempted to avoid misunderstand-
ing by using the plural, — " the formative forces of the organism " ;
but even under these circumstances, differences of opinion have
arisen, as shown by the controversy between Roux ('97) and Hertwig
('94 and '97), on this point. A change in form carries with it a
change of position of the parts, and the latter involves the idea of
forces, but the nature of these forces is entirely obscure to us, at
least we cannot refer them to any better-known category of physical
or chemical forces. They may, perhaps, be most profitably com-
pared to the forces of chemical union, but whether they are very
numerous or can be reduced to a limited number of kinds of force,
we do not know. If it could be shown that the changes in the organ-
ism are due to molecular changes, then the formative forces might
appear to be only molecular forces, but we are not in position at
present to demonstrate that this is the case, however probable it
may appear.

Finally, the use of the term " organization " may be considered,
although from what has been said already it is clear that there must
be a certain amount of vagueness connected with our idea of what
the organization can be. The organization, from the point of view
that I have adopted, is a structure, or arrangement of the material
basis of the organism, and to it are to be referred all the fundamental
changes in form, and perhaps of function as well. We also use the
term as appHed to the completed structure, by which we mean that
the organism consists of typical parts having a characteristic arrange-
ment carrying out definite functions. When applied to the &^%,
or to a regenerating piece, the term refers to some more subtle struc-
ture that we are led to suppose to be present from the mode of be-
havior of the substance. As pointed out, we know this organization
at present from only a few attributes that we ascribe to it, and are not
in a position even to picture to ourselves the arrangement that we
suppose to exist.

REGENERATION AND ADAPTATION

One of the most difficult questions with which the biologist has
to deal is the meaning of the adaptation of organisms to their environ-
ment. Pfliiger, in an article entitled " The Teleological Mechanics of
Living Nature," has drawn attention to the teleological character, or
purposefulness, of certain processes in the living organism. " There

GENERAL CONSIDERATIONS AND CONCLUSIONS 289

has been found only one general point of view, which if not absolute,
yet is the rule, to account for the eternal transformations of energy in
the living body. Only those combinations of causes take place that
are as favorable as possible for the welfare of the animal. This holds
true even when entirely new conditions are artificially introduced
into the living organism. What is more remarkable than that, even
in the highly organized mammal, there should be a regeneration of
the bile duct after its removal, or that after a large piece of a nerve
has been extirpated by a severe operation it should be again renewed .''
. . . What is more surprising than that the organism should become
accustomed to the most diverse kinds of organic and inorganic poi-
sons.'' . . . And, finally, there are a number of facts that make good
the law that changes appear to be governed by no other principle
than the purpose of making certain the existence of the organism."

Pfliiger's teleological law of causality is that "the cause of every
need of a living being is at the same time the cause of the fulfilment
of the need." Pfliiger explains that the word "cause" is here intention-
ally chosen in order to bring out the necessary, lawful connection in
which the cause of each need stands in relation to the fulfilment of
that need. He adds that it would have been more correct, but less
pointed, to have said "motive" or "inducement" instead of "cause."

In order to illustrate what is meant by this law, the following
examples may be given. Food and water bring back the organism
to its normal condition. The absence of food in the body leads to
hunger, and this to the taking in of more food ; or, in other words, the
need of food leads to the search for food, or at least to the taking in
of food. The sexual desire, or the need to reproduce, brings about
the condition of the animal that leads to reproduction. A defect in
the valves of the heart leads to the enlargement of the right or the
left ventricle. The removal of one kidney leads to the hypertrophy
and increased function of the other. And although not explicitly
stated by Pfliiger in this place, we may add to this list the removal
of a part of an animal, that leads to the regeneration of that part.
Pfliiger further states that we are making no subtle distinction when
we point out that these phenomena, if looked at from the point of
view of purposeful acts, appear to have a teleological side. In reply
to this it may be stated, however, that in certain cases of regenera-
tion it can be shown that the result is entirely useless, or even injuri-
ous to the organism ; hence the teleological nature of the process is
entirely lost sight of, and we are the more ready to accept a simple
causal explanation of the phenomena. The best example of this
that I can give is the development of a tail at the anterior end of a
posterior piece of an earthworm. This process is not an occasional
one, but is constant. An example of an apparently useful result, so

290 REG EN ERA TION

far as the individual's well-being is concerned, but entirely useless from
the point of view of the continuance of the species, is found in the
development, in the earthworm, of a new head after the removal of
the anterior end, including the reproductive region. New reproductive
organs are not formed, and, although, in virtue of the regeneration of
a new head, the individual is capable of carrying on its existence, yet
the race of earthworms is not thereby benefited. The production of
two tails in lizards, or of two or more lenses in the eyes of newts, are
examples of the regeneration of superfluous structures.

If, however, it is claimed that in the large majority of cases the
process of regeneration is for the welfare of the individual, and for
the race also, this must be admitted, and it is this fact which has made
a deep impression on the minds of many biologists.

From the causal point of view, we may look upon the formative
changes as the necessary outcome of strictly causal principles, and
we may suppose that they take place without respect to the final
result. But the question before us is rather to explain, if possible,
why the changes that take place are in so many cases useful ones.
That they are not always useful must be admitted, that they sometimes
are must be granted, and it is the latter alternative that has attracted
special attention. Now it is undoubtedly the simplest solution to
claim that the scientist has nothing to do with the adaptiveness of the
response, that his whole problem lies in a study of the causal phe-
nomena involved in each process, but it is unquestionably true that
scientists have not been satisfied to confine their hypotheses to this
side of the question. The widespread interest in the theory of natu-
ral selection is, I think, due to the fact that it appears to offer an
explanation of the formation of adaptive processes — not that it
pretends to explain the origin of the adaptive structures or processes
themselves, but that it seems to account for the adaptiveness of the
fully formed product, i.e. the organism. For it will be seen that if
only those forms (variations) survive that are useful, and survive
either because the environment selects them (and exterminates the
others), or because new forms that arise find a new place in nature
where they can remain in existence, then the adaptiveness of the
form to its surroundings would seem to be accounted for. In this
case we can see how the causal processes that take place in the organ-
ism need have no causal connection with the environment, — except
in the sense that the environment has acted as a selective agent, and
appears, therefore, in the light of a teleological factor. But, as has
been said before, the question is not so much that organisms are
adapted, as that organisms respond adaptively to changes to which
they can never have been subjected before. It is for the latter fact
that a solution is to be sought. *

GENERAL CONSIDERATIONS AND CONCLUSIONS 29 1

In this whole question there is danger of extending our own expe-
rience as agents in the constructing of products useful to ourselves, to
the organic world, in attempting to account for the way in which the
useful characters of organisms have arisen. We see a ship being
built, and we know that when it is finished it will be useful. We
explain its building by its future usefulness, — that is, we explain the
process as the result of human teleology. But have we any right to
extend this principle to the organic world, and infer that processes are
there carried out because they will ultimately be useful to the individual
in which they take place .'' Unconsciously we have shifted our point of
view. The ship does not build itself, and the final result of the build-
ing is of no use to the ship. On the contrary, the organism does
build itself and the result is useful only to itself. Unless we suppose
that some external agent acting as we do ourselves directs the
formative processes in animals and plants, we are not justified in
extending our experience as directive agents to the construction of
the organic world; and if we are not justified in drawing such a con-
clusion, since the organism by no means always responds adaptively,
and in many cases very badly and incompletely, then, it seems to me,
we must look for another point of view.

In connection with his work on the regeneration of the eye of the
salamander, Gustav Wolff ('93) has made some sweeping statements
in regard to the phenomenon of adaptation. " Purposeful adaptation
is that which makes the organism an organism. It is this adaptation
that appears to us as the most characteristic property of all living
things. We can think of no organism without this characteristic."
In another place he states, "... we recognize that every explana-
tion that presupposes the living being, every post-vital explanation of
organic adaptation, presupposes in every case that which it attempts
to explain ; we recognize that the explanation of adaptation must co-
incide with the explanation of life itself." There is, perhaps, some
truth in this statement, but, on the other hand, Wolff has, I think,
shot somewhat over the mark. As Fischel (1900) has pointed out,
the response is sometimes not adaptive, as when two lenses develop
in the same eyfe in the salamander ; and, we may add, as when an an-
tenna develops in certain Crustacea in place of an eye, or as when a
tail develops instead of a head, or a head in place of a tail. In the
light of these facts, it is, I think, going too far to assert that the power
of living things to respond adaptively to changes in themselves or in
their environment is synonymous with life itself. All that we can
fairly claim is that in several cases living forms have been shown to
be able to complete themselves, and this may be interpreted as an adap-
tive response. It would carry us far beyond the scope of the present
volume to discuss the question of adaptation in general, and I think it

292 REGENERA TION

highly probable that it will prove true that there are many kinds of
adaptive responses that must be considered separately and each on its
own merits. Let us, therefore, confine our concluding remarks en-
tirely to regenerative changes which, after they have been completed,
are for the good of the organisms. Our preceding discussion has led
to the conclusion that the phenomena of regeneration are not pro-
cesses that have been built up by the accumulation of small advances
in a useful direction ; that they cannot be accounted for by the sur-
vival of those forms in which the changes take place better than in
their fellows, for it is often not a question of life and death whether
or not the process takes place, or even a question of leaving more de-
scendants. On the contrary, it seepis highly probable that the regen-
erative process is one of the fundamental attributes of living things,
and that we can find no explanation of it as the outcome of the selec-
tive agency of the environment. The phenomena of regeneration
appear to belong to the general category of growth-phenomena, and
as such are characteristic of organisms. Neither regeneration nor
growth can be explained, so far as I can see, as the result of the use-
fulness of these attributes to the bodies with which they are indisso-
lubly associated. The fact that the process of regeneration is useful
to the organism cannot be made to account for its existence in the
organism.

LITERATURE

Aldrovandus, Ulysses.

1642. Historia Monstrorum. MDCXLII. Cap. VIII.

1645. Patritii boloniensis de quadrupedibus digitalis oviparis. Lib. II. Boloniae,
MDCXXXXV.
AUman, J. A.

'64. Report of the present State of our Knowledge of the Reproductive System in the
Hydroida. Report of the 33d Meeting of the British Assoc, 1864.
Andrews, E. A.

'90. Autotomy in the Crab. The American Naturalist, XXIV, 1890.
'91. Report upon the Annelida Polychaeta of Beaufort, North Carolina. Proc. U. S.
National Museum, XV, p. 286, 1891.
Andrews, G. F.

'97. Some Spinning Activities of Protoplasm, etc. Jour. Morph., XII, 1897.
Apostolides, N. Christo.

'82. Anatomic et developpement des Ophiures. Arch. Zool. Experim., X, 1882.
Aristotle.

Historia de animalibus, Julio Caesare, Scaligero interprete, cum ejusdem Commentariis.
Tolosae, MDCXIX, Lib. II, Cap. XX.
Arnoult de Nobleville et Salerne.

1756. Suite de la matiere medicale de Geoffroy, t. 12, MDCCLVI.
Aschoff, L.

'95. Regeneration und Hypertrophic. Ergebnisse d. allg. Path. Morph. und Physiol.,
1895.
Balbiani, E. G.

'88. Recherches experimentales sur la merotomie des infusoires cilies. Recueil zool. de

la Suisse, V, 1888.
'91. Sur les regenerations successives du peristome, etc., chez les stentors, etc. Zool.

Anz., 1891.
'91. Nouvelles recherches experimentales sur la merotomie des infusoires cilies. Arch,
microgr., IV et V, 1891-93.
Bardeen, C. R.

'01. On the Physiology of the Planaria maculata, etc. Am. Jour. Physiol., V, 1901.
Barfurth, D.

'91-00. Regeneration. Ergebnisse Anat. und Entvvickl. Merkel und Bonnet, 1891-

1900.
'91. Versuche zur funktionellen Anpassung. — Zur Regeneration der Gevvebe. Arch.

f. Mikr. Anat., XXXVII, 1891.
'93. Experimentelle Untersuchungen iiber die Regeneration der Keimblatter bei den

Amphibien. Anat. Hefte, IX, 1893.
'94. Die Experimentelle Regeneration iiberschiissiger Gliedmassenteile bei den Amphi-
bien, Arch. f. Entw^.-mech., I, 1894.
'99. Sind die Extremitaten der Frosche regenerationsfahig ? Arch. f. Entvi'.-mech., IX,

1899.
'99. Die Experimentelle Herstellung der Cauda bifida bei Amphibienlarven. Arch. f.
Entwr.-mech., IX, 1899.

293

294 REGENERATION

Barrois, J.

'77. Memoire sur I'embryologie des nemertes. Ann. Sc. Nat. (6), tome VI, 1877.
Bateson, W.

'94. Materials for the Study of Variation, 1894.
Baudelot, E.

'69. De la regeneration de I'extremite cephalique chez le Lombric terrestre. Bull. Soc.
d. Sc. Nat., Strassbourg, II, 1869.
Benham, W. B.

'96. Fission in Nermertines. Q. J. Micr. Sc., XXXIX, 1896.
Bergh, R. S.

'96. tjber den Begriff der Heteromorphose. Arch. f. Entw.-mech., Ill, 1896.
Bert, P.

'60. Recherches Experimentales. Ann. d. Sc. Natur. (5 Ser.), V, i860.
Bickford, E. E.

'94, Notes on Regeneration and Heteromorphosis in Tubularian Hydroids. Journ.
Morph., IX, 1894.
Blumenbach.

1787. Specimen physiologiae comparatae inter animantia calidi et frigidi sanguinis; in
commentationes soc. reg. scient. Gottingensis, Vol. VIII. Gottingae, 1787.
Bock, M. von.

'97. Uber die Knospung von Chaetogaster diaphanus. Jena. Zeit. f. Naturw., XXXI,
1897.
Bonnet, C.

1745. Traite d'insectologie. Seconde partie. Observations sur quelques especes de vers
d'eau douce, qui coupes par morceux, deviennent autant d'animaux complets.
Paris, 1745.
Bordage, E.

'97. Phenomenes d'autotomie observes chez les Nymphes de Monandroptera inuncans
et de Raphiderus scabrosus. Compt. Rend, des seances de la Soc. de Biologie. Paris,

1897.
'97. Sur la regeneration tetramerique du tarse des Phasmides. Ibid., 1897.
'98. Sur les localisation des surfaces de regeneration chez les Phasmids. Ibid., 1898.
'98. Gas de regeneration du bee des oiseaux explique par la loi de Lessona. Ibid.,

1898.
'99. Regeneration des membres chez les Mantides, etc. Ibid., XXVIII, 1899.
'99. Sur le mode probable de formation de la soudure-femoro-trochanterique chez les

Arthropodes. Ibid., XXVIII, 1899.
'00. On the Absence of Regeneration in the Posterior Limbs of the Orthoptera Salta-

toria and its Probable Causes. Ann. and Mag. of Nat. Hist., 1900.
'00, Regeneration of the Tarsus and of the Two Anterior Parts of Limbs in the Orthop-
tera Saltatoria. Ibid., 1900.
Born, G.

'97. tjber Verwachsungsversuche mit Amphibienlarven. Arch. f. Entw.-mech., IV, 1897.
Boulenger, G. A.

'88. On the Scaling of the Reproduced Tail in Lizards. Proc. Zool. Soc, London, 1898.
Boveri, Th.

'89, Ein geschlechtlich erzeugter Organismus ohne miitterliche Eigenschaften. Sitz-

ungsber. Ges. Morph. Phys. Miinchen , V, 1889.
'95. Uber die Befruchtungs- und Entwickelungsfahigkeit kernloser Seeigeleier. Arch, f,

Entw.-mech., II, 1895.
'01. ijber die Polaritat des Seeigel-Eies. Verhand. d. Phys.-Med. Gesell. Wiirzburg

(N. F.), XXXIV, 1901.
Brand, F.

'96. Fortpflanzung und Regeneration von Lemanea fluviatilis. Berichte d. deutsch,

botan. Gesell., V, 1896.

LITERATURE 295

Brefeld, 0.

'77. Die Entwickelungsgeschichte der Basidiomyceten. Botan. Zeit., 1876.
'77. Botanische Untersuchungen. Schimmelpilze, III (page 69), 1877.
Brindley, H. H.

'97. On the Regeneration of Legs in the Blattidae. Proc. Zool. Soc, London, 1897.
'98. On certain Characters of Reproduced Appendages in Arthropoda, particularly in the
Blattidae. Ibid., 1898.
Broussonet, M.

1786. Observations sur la regeneration de quelques parties du corps des Poissons. Hist,
d. I'Acad. Roy. des Sciences, 1786.
Billow, C.

'82. ijber Theilungs- und Regenerations-vorgange bei Wiirmern. Arch. Naturg., XLIX,

1882.
^2)T,. Die Keimschichten des wachsenden Schwanzendes von Lumbriculus variegatus, etc.

Zeit. Wiss. Zool.; XXXIX, 1883.
'83. iJber anscheinend freiwillige und kiinstliche Theilung mit wechselnder Regenera-
tion bei Coelenteraten, Echinodermen, und Vermes. Biol. Centralbl., Ill, 1883-84.
Byrnes, Esther F.

'98. On the Regeneration of Limbs in Frogs after the Extirpation of Limb Rudiments.
Anat. Anz., XV, 1898.
Cadiat, 0.

'76. Du cristallin, anatomie et developpement, usage et regeneration. These d'agrega-
tion. Paris, 1876.
Cardanus, Hieronymus.

1580. Mediolanensis, medici, de subtilitate. Lugundi, MDLXXX.
Carnot, P.

'99. Les regenerations d'organs. Paris, 1899.
Carriere, J.

'80. Studien iiber die Regenerations-Erscheinungen bei den Wirbellosen. Wiirzburg,
1880.
Chabry, L.

'87. Contribution a I'embryologie normale et teratologique des ascidies simples. Journ.
Anat. et Phys., XXIII, 1887.
Chantran, S.

'73. Experiences sur la regeneration des yeux chez les ecrevisses. Compt. rend., LXXVI,

1873-
Chun, C.

'92. Die Dissogonie der Rippenquallen. Festschr. f. Leuckart, 1892.
Colucci, V. S.

'85. Studio sperimentale sulla rigenerazione degli arti e della coda nei Tritoni. Rende-

conto delle sessioni della R. Accad. d. Scienze dell' 1st. di Bologna, 1885.
'91. Sulla regenerazione parziale dell' occhio nei Tritoni. Memorie della R. Accad.
delle Scienze dell' 1st. di Bologna (Ser. V), I, 1891.
Conklin, E. G.

'98. Environmental and Sexual Dimorphism in Crepidula. Proc. Acad. Nat. Science,
Philadelphia, 1898.
Contijan.

'90. Sur I'autotomie chez la Sauterelle et le Lezard. Compt. rend., 1890.
Coutiere, H.

'98. Notes sur quelques cas de regeneration hypotypique chez Alpheus. Bull. Soc. Ent.,
France, 1898.
Crampton, H. E.

'96. Experimental Studies on Gasteropod Development. Arch. f. Entw.-mech., Ill,

1896.
'97. The Ascidian Half-Embryo, New York Acad, of Sc, X, 1897.

296 REGENERATION

Dalyell, J. G.

'14. Observations on Some Interesting Phenomena in Animal Physiology, exhibited

by Several Species of Planariae. Edinburgh, 1814.
'47. Rare and Remarkable Animals in Scotland. London, 1847-48.
'51. Powers of the Creator, 1 85 1.

Darwin, C.

'54. Monograph of the Cirrepedia, 1854.

'68. The Variation of Animals and Plants under Domestication, 1868.

Davenport, C. B.

'93. Studies in Morphogenesis. I. On the Development of the Cerata in Aeolis. Bull.

Mus. Comp. Zool., XXIV, 1893.
'94. Studies in Morphogenesis. Nr. 2. Regeneration in Obelia and its Bearing on

Differentiation in the Germ-plasma. Anat. Anz. 9, 1894.
'97. Experimental Morphology, I and II. Nevi^ York, 1897-99.

Dawydoff, C.

'01. Beitrage zur Kenntnis der Regenerations Erscheinungen bei den Ophiuren, Zeit.
Wiss. Zool., LXIX, 1901.
Delage, Y.

'95. La Structure de Protoplasma et les Theories sur L'Heredite, 1895.

'99. Etudes sur la Merogonie. Arch, de Zool. experim. et generale, 1899.

Dendy, A.

'56. On the Regeneration of the Visceral Mass in Antedon Rosaceus. Stud. Biol. Lab.,
Owens College, I, 1856.

Dewitz, H.

'94. tjber das Abwerfen der Scheeren des Flusskrebses. Biol. Centralb., V, 1894.

Driesch, H.

'90. Heliotropismus bei Hydroidpolypen. Zool. Jahrb. (Syst. Abt.), V, 1890.

'91. Die Stockbildung bei den Hydroidpolypen und ihre theoretische Bedeutung. Biol.

Cent., XI, 1891.
'91. Die mathematisch-mechanische Betrachtung morphologischer Probleme der Biolo-

gie. Jena, 189 1.
'9l-'93. Enlwickelungsmechanische Studien.
'91. I. Der Wert der beiden ersten Furchungszellen in der Echinodermenentwick-

elung. Zeit. f. wiss. Zool., LIII, 1891.
'91. II. ijber die Beziehungen des Lichtes zur ersten Etappe der tierischen Formbildung.

Ibid.
'92. III. Die Verminderung des Furchungsmaterials und ihre Folgen. Zeit. f. wiss.

Zool., LV, 1892.
'92. IV. Experimentelle Veranderungen des Typus der Furchung und ihre Folgen.

Ibid.
'92. V. Von der Furchung doppelbefurchteter Eier. Ibid.

'92. VI. Uber einige allgemeine Fragen der theoretischen Morphologie. Ibid.
'93. VII. Exogastrula und Anenteria. Mitt. zool. Stat. Neapel, II, 1893.
'93. VIII. Uber Variation der Micromerenbildung. Ibid.

'93. IX. Uber die Vertretbarkeit der " Anlagen " von Ektoderm und Entoderm. Ibid.
'93. X. Uber einige allgemeine entwicklungsmechanische Ergebnisse. Ibid.
'92. Kritische Erorterungen neuerer Beitrage zur theoretischen Morphologie. II. Zur

Heteromorphose der Ilydroidpolypen. Biol. Cent., XII, 1892.
'93. Zur Verlagerung der Blastomeren des Echinideneies. Anat. Anz., VIII, 1893.
'93. Zur Theorie der tierischen Formbildung. Biol. Cent., XIII, 1893.
'93. Die Biologic als selbstandige Grundwissenschaft. Leipzig, 1893.
'94. Analytische Theorie der organischen Entwickelung. Leipzig, 1894. (Also Arch.

f. Entw.-mech., IV, 1896.)
'95, Von der Entwickelung einzelner Ascidienblastomeren. Arch. f. Entw.-mech., I,

1895.

LITERA TURE 297

'95. Zur Analysis der Potenzen embryonaler Organzellen. Arch. f. Entvv.-mech., II,

1895.
'96. Die Maschinentheorie des Lebens. Biol. Cent., XVI, 1896.
'96. Uber den Anteil zufalliger individueller Verschiedenheiten an ontogenetischen

Versuchsresultaten. Arch. f. Entvv.-mech., Ill, 1896.
'96. Die taktische Reizbarkeit der Mesenchymzellen von Echinus microtuberculatus.

Arch. f. Entw.-mech., Ill, 1896.
'96. Betrachtungen iiber die Organisation des Eies und ihre Genese. Arch. f. Entw.-
mech., IV, 1896.
'96. Uber einige primare und sekundare Regulationen in der Entwickelung der Echino-

dermen. Arch. f. Entvv.-mech., IV, 1896.
'96. Zur Analyse der Reparationsbedingungen bei Tubularia. Vierteljahrsschr. Nat.

Ges., Ziirich, XVI, 1896.
'97. Uber den Wert des biologischen Experiments. Arch. f. Entvv.-mech., V, 1897.
'97. Neuere Beitrage zur exakten Morphologic in englischer Sprache, III (1896).

Arch. f. Entvv.-mech., V, 1897.
'97. Studien iiber das Regulationsvermogen der Organismen. I. Von den Regulationen

Wachstums- und Differenzierungsfahigkeiten der Tubularia. Arch. f. Entw.-mech.,

V, 1897.
'97. Von der Beendigung morphogener Elementarprozesse. Arch. f. Entw.-mech., V,

1897-

'98. Uber rein miitterliche Charactere an Bastardlarven von Echiniden. Arch. f. Entw.-
mech., VII, 1898.

'99. Von der Methode der Morphologie. Biol. Cent., XIX, 1899.

'99. Die Lokalisation morphogenetischer Vorgange. Ein Beweis vitalistischen Ge-
schehens. Arch. f. Entw.-mech., VIII, 1899.

'99. Studien iiber das Regulationsvermogen. II. Quantitative Regulationen bei der
Reparation der Tubularia. Arch. f. Entw.-mech., IX, 1899. ■^I-'-' Notizen iiber die
Auflosungund Wiederbildung des Skeletts von Echinidenlarven. Ibid.

'00. Die isolirten Blastomeren des Echinidenkeimes. Arch. f. Entw.-mech., X,
1900.

'00. Studien iiber das Regulationsvermogen der Organismen. IV. Die Verschmelzung
der Individualitat bei Echinidenkeimen. Arch. f. Entw.-mech., X, 1900.

'99. Resultate und Probleme der Entwickelungsphysiologie der Thiere. Ergebn. d.
Anat. u. Entw. (1898), 1899.

01. Studien iiber das Regulationsvermogen der Organismen. V. Erganzende Beob-
achtungen an Tubularia. Arch. f. Entw.-mech., XI, 1901.

Driesch, H. and Morgan, T. H.

'95. Zur Analysis der ersten Entwickelungsstadien des Ctenophoreneies. Arch. f. Entw.-
mech., II, 1895. (Also Driesch : Bemerkungen, etc., Zool. Anz., 1896.)

Duges, A.

'28. Recherches sur la circulation, la respiration et la reproduction des Annelides

abranches. Annales des Sci. nat. (5), XVI, 1828.
• '29. Memoire sur les especes indigenes du genre Lacerta. Annales des Sciences natu-

relles, XVI, 1829.

Dumeril, A.

'67. Experiences demontrant que la vie aquatique des Axolotle abranchies exterieurs
se continue apres I'ablation des louppes branchiales. Nouvelles Archives du Museum.
Ill, 1867.

Duyne, J. van.

'96. Uber Heteromorphose bei Planarien. Pfliiger's Arch., LXIV, 1896.

Ehlers, E.

'69. Die Neubildung des Kopfes und der vorderen Korpertheile bei polychaeten Anne-

liden. Erlangen, 1869.
'99. Palolo. Biol. Centralb., XIX, 1899.

298 REGENERA TION

Eimer, Th.

'73. tjber Kiinstliche Theilbarkeit von Aurelia aurita und Cyanea capillata. Verb,
d. phys.-med. Gesell. zu Wiirzburg (N. F.), VI (Dec), 1873.
Emery, C.

'97. Wer hat die Regeneration der Augenlinse aus dem Irisepithel zuerst erkannt und
dagestellt? Anat. Anz., XIII, 1897.
Endres, H.

'95. Anstichversuche an Eiern von Rana fusca. II. Theil. Arch, f, Entw.-mech., II,

1895-96.
'95. tjber Anstich- und Schniirversuche an Eier von Triton taeniatus. 73 Jahreb. d.
Schles. Ges. f. Vaterl. Kultur, 18 JuU, 1895.
Endres, H., and Walter, H. E.

'95. Anstichversuche an Eiern von Rana fusca. I. Theil. Arch. f. Entw.-mech., II,
1895.
Fiedler, K.

'91. Entwickelungsmechanische Studien an Echinodermeiern. Festschr. Nageli u.
KoUiker, Zurich, 1891.
Fischel, A.

'97. Experimentelle Untersuchungen am Ctenophorenei, 1-4. Arch. f. Entw.-mech., VI,

1897-98.
'98. ilber die Regeneration der Linse. Anat. Anz., XIV, 1898.
Flemming, W.

'80. ijber Epithelregeneration und sogen. freie Kernbildung. Arch. f. mikr. Anat.,
XVIII, 1880.
Flexner, S.

'98. The Regeneration of the Nervous System of Planaria torva and the Anatomy of the
Nervous System of Double-headed Forms. Jour. Morph., XIV, 1898.
Forest-Heald, F. de.

'98. A Study of Regeneration as exhibited by Mosses. Bot. Gaz., XXVI, 1898.
Fraisse, P.

'85. Die Regeneration von Geweben und Organen bei den Wirbelthieren, besonders
bei Amphibien und Reptilien. Kassel und Berlin, 1885.

Fredericq, L.

'83. Sur I'autotomie ou mutilation par voie reflexe comme moyen de defense chez les

animaux. Arch. d. Zool. experim. (Ser. i), 1883.
'87. L'autotomie chez les etoiles de mer. Revue Scientifique (Ser. 3), XIII, 1887.
'93. L'autotomie ou la mutilation dans le regne animal. Bull, de I'Acad. roy. de Bel-
gique (Ser. 3), XXVI, 1893.
Frenzel, J.

'91. IJber die Selbstverstiimmelung (Autotomie) der Thiere. Arch. f. d. Ges. Physiol.,
L, 1891.
Friedlander, B.

'95. tJber die Regeneration herausgeschnittener Theile des Central nerven-systems von

Regenwiirmern. Zeit. f. Wiss. Zool. LX, 1895.
'98. Uber den sogennanten Palolo-wurm. Biol. Cent., XVIII, 1898.
'99. Nochmals der Palolo, etc. Biol. Centralbl., XIX, 1899.
Fuhrmann, M.

'98. Sur les phenomenes de la regeneration chez les Invertebres. Arch. Sc. Nat., V,
1898.
Gachet, M. H.

'34. Memoire sur la reproduction de la queue des reptiles sauriens. Actes de la societe
linneenne de Bordeaux, Nr. 36, 25 Juillet, 1834.
Gayat, M. J.

'73. Experimentalstudien ilber Linsenregeneration. Klin. Monatsbl. fiir Augenheilk.,

1873-

LITERA TURE 299

Gesner, Conrad.

1686. Historiae animalium. Lib. II, MDCLXXXVI.
Giard, A.

'95. Polydactylie provoquee chez Pleurodeles Walthii Mich. Compt. Rend. Soc. Biol.,

II, 1895.
'96. Y a-t-il antagonisme entre la "Greffe " et la " Regeneration." Ibid., 1896.
'97. Sur les regenerations hypotypiques. Ibid.., IV, 1897.
'97. Sur I'autotomie parasitaire, etc. Ibid.., 1897.
Gliickselig, M, Ch.

'63. IJber das Leben der Eidechsen, Verhandl. d. zool.-bot. Vereins in Wien., XIII, 1863.
Godelmann, R.

'01. Beitrage zur Kenntniss von Bacillus Rosii Fabr. mit besonderer Beriichsichtigung
der bei ihm vorkommenden Autotomie und Regeneration einzelner Gliedmassen.
Arch. f. Entw.-mech., XII, 1901.
Goebel, K.

'98. Organographie der Pflanzen. I. Allgemeine Organographie, Jena, 1898.
Goette, A.

'69. ijber Entwickelung und Regeneration des Gliedmassenskeletts der Molche. Tu-
bingen, 1869.
Gonin, J.

'96. Etude sur la Regeneration du cristallin. Ziegler's Beitrage z. pathol. Anat., XIX,
1896.
Goodsir, H. D. S.

'44. A Short Account of the Mode of Reproduction of Lost Parts in the Crustacea.
Ann. and Mag. Nat. Hist., XIII, 1844.
Graber, V.

'67. Zur Entwickelungsgeschichte und Reproductionsfahigkeit der Orthopteren. Be-
richte d. kaiserl. Akad. d. wiss. Wien. LV, 1867.
Greef , R.

'67. tjber Actinosphaerium Eichhornii, etc. Arch. f. Mikr. Anat., Ill, 1867.
Griffini e Marchio.

'99. Sulla rigenerazione totale della retina nei tritoni. Riforma med., 1899.
'99. Sur la regeneration de la retine chez les tritons. Arch. ital. de Biolog., XII.
Gruber, A.

'84-'5. tJber Kiinstliche Theilung bei Infusorien, I. Biolog. Centralbl., IV, 1884-85.

'85-'6. Same, Part II. Ibid., V, 1885-86.

'86. Beitrage zur Kenntniss der Physiologie und Biologie der Protozoen. Ber. Nat. Ges.

Freiburg, I, 1886.
'87. Mikroskopische Vivisektion. Ber. d. Naturfor. Gesell. zu Freiburg, II, 1887.
Haeckel, E.

'68. Monographic der Moneren. Jena Zeit. f. Naturwiss., IV, 1868.
'69. Entwickelungsgeschichte der Siphonophoren (page 73), 1869.
'78. Die Kometenform der Seesterne und der Generationswechsel der Echinodermen.
Zeit. f. wiss, Zool., XXX, 1878.
Hargitt, C. W.

'97. Recent Experiments on Regeneration. Zool. Bull., I, 1897.
'99. Experimental Studies upon Hydromedusae. Biolog. Bull., I, 1899.
Harrison, R. G.

'98. The Growth and Regeneration of the Tail of the Frog Larva. Arch. f. Entw.-
mech., VII, 1898.
Hasse, H.

'98. tJber Regeneration bei Tubifex rivulorum. Zeit. wiss. Zool., LXV, 1898.
Hazen, A. P.

'99. The Regeneration of a Head instead of a Tail in an Earthworm. Anat. Anz.,
XVI, 1899.

300 REGENERATION

Heider, K.

'97. 1st die Keimblatterlehre erschiittert? Zool. Centralb., IV, 1897.
Heineken, C.

'28-29. Experiments and Observations on the Casting off and Reproduction of the Legs
in Crabs and Spiders. The Zool. Journal, IV, 1828-29.

Hepke, P.

'97. ijber histo- und organogenetische Vorgange bei den Regenerationsprozessen der

Naiden. Zeit. vviss. Zool., LXV, 1897.
Herbst, C.

'94. tjber die Bedeutung der Reizphysiologie fiir die kausale Auffassung von Vorgangen

in der tierischen Morphologie. Biol. Centralb., XIV und XV, 1894 u. 1895.
'95-'99. liber die Regeneration antennenahnlicher Organe an Stelle von Augen I.

Arch. f. Entw.-mech., II, 1895.
'96. II. Versuche an Sicyonia sculpta. Vierteljahrsschr. d. Naturf.-Ges., Zurich, 1896.
'99. Ill u. IV. Weitere Versuche, u. s. '^. Arch. f. Entw.-mech., IX, 1899.
'96. Experimentelle Untersuchungen iiber den Einfluss der veranderten chemischen

Zusammensetzung, etc. Arch. Entw.-mech., II, 1896.
'97. iJber die zur Entwickelung der Seeigellarven nothwendigen anorganischen Stoff,

I. Ibid., V, 1897.
Herculais, K. d'.

'75. Recherches zur I'organisation at la developpement des volucelles, 1875.

Herlitzka, A.

'96. Contributo alio studio della capacita evolutiva dei due primi blastomeri nell' uovo
di tritoni (triton cristatus). Arch. f. Entw.-mech., II, 1896.
Herrick, F. H.

'95. The American Lobster. Bull. U. S. Fish Commission, 1895.
Hertwig, 0.

'85. Das Problem der Befruchtung und der Isotropic des Eies. Jena Zeit., XVIII, 1885.
'85. Welchen Einfluss iibt die Schwerkraft auf die Teilungen der Zellen? Ibid., 1885.
'90. Experimentelle Studien am tierischen Ei vor, wahrend und nach der Befruchtung.

Ibid., XXIV, 1890.
'92. Urmund und Spina bifida. Arch. f. mikr. Anat. XXXIX, 1892.
'92. Altere und neuere Entwickelungstheorien. Rede. Berlin, 1892.
'93. iJber der Wert der ersten Furchungszellen fiir die Organbildung des Embryo.

Arch. f. mikr. Anat. XLII, 1893.
'94. Zeit- und Streitfragen der Biologic, I. Praformation oder Epigenesis? Jena, 1894.
'95. Beitrage zur experimentellen Morphologie und Entwickelungsgeschichte. I. Die

Entwickelung des Froscheies unter dem Einfluss schvviicherer und starkerer Kochsalz-

losungen. Arch. f. mikr. Anat., XLIV, 1895.
'96. Experimentelle Erzeugung tierischer Missbildung. Festschr. Gegenbaur., II, 1896.
'97. Zeit- und Streitfragen, II. Mechanik und Biologic, Jena, 1897.
'98. tJber den Einfluss der Temperature auf die Entwickelung von Rana fusca und

Rana esculenta. Arch. f. mikr. Anat., LI, 1898.
'98. Die Zelle und Die Gewebe. II. Allgemeine Anatomic und Physiologic der

Gewebe. Jena, 1898.
'98. Beitrage, etc., IV. Uber einige durch Centrifugalkraft in der Entwickelung des

Froscheies hervorgerufene Veranderungen. Arch. f. mikr. Anat., LIII, 1898.
Hescheler, K.

'96-98. iJber Regenerationvorgange bei Lumbriciden, I u. 11. Jena. Zeit., XXX, 1896,

und XXXI, 1898.
Hirota, S.

'95. Anatomical Notes on the "Comet" of Linkia Multifora. Zool. Mag. Tokyo,

Vn, 1895.
His, W.

'75. Unsere Korperform und das physiologische Problem ihrer Entstehung. Leipsig,

1875-

LITERATURE 3OI

Hofer, B.

'89. Experimentelle Untersuchungen iiber den Einfluss des Kerns auf das Proto-
plasma. Jena. Zeitsch. f. Naturf. (N. F.), XVII, 1889.
Horst, R.

'86. Zur Regenerationslitteratur. Zool. Anz., IX, 1886.

Hoy, P. R.

'71. The Development of Amblystoma lurida. The American Naturalist, 1871.
Hubrecht, A. A. W.

'87. Report on the Nemertines. Reports of the Challenger Expedition, 1887.
Ischikawa, C.

'90. Trembley's Umkehrungsversuche an Hydra nach neuen Versuchen erklart. Zeit.
f. wiss. Zool., XLIX, 1890.
Joest, E.

'95. Transplantationsversuche an Regenwiirmern, Sitz. ber. d. Gesell. z. Berf. d. ges.
Naturwiss. zu Marburg, 1895.

'97. Transplantationsversuche an Lumbriciden. Arch. f. Entw.-mech. V, 1897.

Johnstonus, Joannes.

1657. Historiae naturalis de quadrupedibus. Amstelodami, MDCLVII, t. I, lib. IV, c.
II, art. I u. art. II.

Kennel, J. von.

'82. ijber Teilung und Knospung der Tiere. Dorpat, 1882.

'82. Uber Ctenodrilus pardalis. Arb. a. d. zool. zoot. Inst. Wiirzburg, V, 1882.

'88. Biologische und Faunistische Notizen aus Trinidad. Arb. d. Zool. -Zoot. Inst.,

Wiirzburg, VI, 1888.
Kinberg, J. G. H.

'67. Om regeneration af hufvudet och de framre segmenterna hosen Annulat. Oefversigt

af. kongl, Vetenskaps Akadamiens Forhandlmgar, 1867.

King, H. D.

'98. Regeneration in Asterias vulgaris Arch. f. Entw.-mech., VII, 1898.
'00. Further Studies on Regeneration in Asterias vulgaris. Ibid., IX, 1900.
Klein, Edm. J.

'95~'97- Regeneration, Transplantation und Autotomie im Thierreich. Fauna Luxem-
burg, 5-7, 1895-97.
Knight, T. A.

'09. On the Origin and Formation of Roots. Phil. Trans., 1809.
Kny, L.

'89. Umkehrversuch mit Ampelopsis quinquefolia. Berichte d. deutsch. botan.
Gesellsch., VII, 1889.
Kochs, W.

'97. Versuche iiber Regeneration von Organen bei Amphibien. Arch. f. mikr. Anat.,
XLIX, 1897.
Korschelt, E.

'97. iJber das Regenerationsvermogen der Regenvviirmer. Sitzungsber. Ges. Naturw.,

Marburg, 1897.
'98, tjber Regenerations- und Transplantationsversuche bei Lumbriciden. Ber. Zool.
Ges., 1S98.
Kowalevski, A. F.

'72. tJber die Vermehrung der Seesterne durch Theilung und Knospung. Zeit. wiss.
Zool., XXII, 1872.
Kramer, A.

'47. tJber den Palolowurm, 1847.

'99. Palolo untersuchungen. Biol. Centralbl., XIX, 1899.

'99. Palolo untersuchungen in October und November, 1898. Ibid,

302 REGENERATION

Krauss, H,

'98. Selbstverstummelungeii bei den Heuschrecken. Prometheus, IX, 1898.

Kroeber, J.

'00. An Experimental Demonstration of the Regeneration of the Pharynx of Allolo-
bophora from Endoderm. Biol. Bulletin, II, 1900.

Lacepede, B. G. E. de.

1788. Histoire naturelle des quadr. ovip. et des serpientes. 1788.

Lang, A.

'88. ijber den Einfluss der festsitzenden Lebensweise auf die Thiere. Jena, 1888.
Lefevre, G.

'98. Regeneration in Cordylophora. Johns Hopkins University Circulars, Feb. 8, 1898,
Lessona, M.

'69. Sulla reproduzione della parte in multi animali. Atti della Soc. Ital., X, 1869.
Lillie, F. R.

'96. On the Smallest Parts of Stentor capable of Regeneration. Journ. Morph., XII,.
1896,
Lillie, F. R., and Knowlton, F. P.

'97. On the Effect of Temperature on the Development of Animals. Zool, Bulletin,.
I, 1897.
Lindemuth, H.

tjber Bildung von Bulben, etc. Ber. bot. Gesell., XIV.

Loeb, J.

'91. Untersuchungen zur physiologischen Morphologic der Tiere. I. Uber Heteromor-

phose. Wiirzburg, 1891.
'92. Untersuch., etc. II. Organbildung und Wachstum. Wiirzbuvg, 1892.
'92. Investigations in Physiological Morphology. III. Experiments on Cleavage. Journ,

Morph., Vn, 1892.
'94. On Some Facts and Principles of Physiological Morphology. Biol. Lect., Woods

Holl, in 1893, 1894.
'94. Uber eine einfache Methode, zwei oder mehr zusammengewachsene Embryonen aus

einem Ei hervorzubringen. Pfliiger's Arch., LV, 1894.
'94. iJber die Grenzen der Teilbarkeit der Eisubstanz. Pfliiger's Arch., LIX, 1894.
'95. Beitrage zur Entwickelungmechanik der aus einem Ei entstehenden Doppelbild-

ungen. Arch. f. Entw.-mech., I, 1895.
'95. Bemerkungen iiber Regeneration. Arch. f. Entw.-mech., II, 1895.
'96. IJber den Einfluss des Lichts auf Organbildung bei Tieren. Pfliiger's Arch., LXIII,.

1896.
'96. Hat das Centralnervensystem einen Einfluss auf die Vorgange der Larvenmeta-

morphose ? Arch. f. Entw.-mech., IV, 1896.
'97. Zur Theorie der physiologischen Licht- und Schwerkraftwirkungen. Pfliiger's Arch.,

LXVI, 1897.
'98. On Egg-Structure and the Heredity of Instincts. Monist., VIII, 1898.
'98. Assimilation and Heredity. Monist., VIII, 1898.
'99. Uber die angebliche gegenseitige Beeinflussung der Furchungzellen und die Entste-

hung der Blastula. Arch. f. Entw.-mech., VIII, 1899.
'99. Warum ist die Regeneration kernloser Protoplasmastiicke unmoglich oder erschwert?

Arch. f. Entw.-mech., VIII, 1899.
'00. On the Transformation and Regeneration of Organs. Am. Journ. of Physiol.,

IV, 1900.
Loeb, L.

'97. Uber Transplantation von Weisser Haut auf einen Defect in Schwarzer Haut und
umgekehrt am Ohr des Meerschweinchens. Arch. f. Entw.-mech., VI, 1897.
'98. Uber Regeneration des Epithels. Arch. f. Entw.-mech., VI, 1898.
'99. An Experiment-Study of Transformation of Epithelium to Connective Tissue.

Medicin, 1899.

LITERATURE 303

Mcintosh, W. C.

'70. Notes on the Development of Lost Parts in the Nemerteans. Journ. Linn. Soc., X,

1870.
'73-' 74. Marine British Annelids. 1873-74.

Magnus, Albertus.

1661. Ordinis praedicatorum de animalibus. Lib. XXVI, tome VL Lugundi, MDCLI.

Mall, F. P.

'96. Reversal of the Intestine. Johns Hopkins Hospital Reports, I, 1896.

Marenzeller, F. von.

'79. Die Aufzucht des Badeschwamms aus Theilstiicken. Verh. Zool.-bot. Ges. Wien.,
XXXVIII, 1879.
Martinotti, C.

'90. liber Hyperplasie und Regeneration der driisigen Elemente in Beziehung auf ihre
Functionsfahigkeit. Centralbl. f. allg. Pathol, I, 1890.
Martins, E. von.

'66. Uber ostasiatische Echinodermen. Archiv. f. Naturgesch., L, 1866.

'84. iJber das Wiedererzeugungsvermogen bei Seesternen. Sitz. d. Gesell. naturf.
Freunde zu Berlin, 1884.
Mayer, C.

'59. Reproductionsvermogen und Anatomie der Naiden. Ver. Nat. Vereins, Rheinlande
XVI, 1859.
Mazza, F.

'90. Sulla ringenerazione della pinna caudale in alcuni Pesci. Atti Soc. Ligust. Sc. N.,
I, 1890.
Michel, A.

'98. Recherches zur la regeneration chez les Annelides. Bull. Sc. France et Belg.,
XXXI, 1898.
Mingazzini, P.

'91. Sulla rigenerazione nei Tunicati. Boll. Soc. Napoli, V, 189 1.
Monti, R.

'00. Studi Sperimentali suUa Regenerazione nei Rebdoceli marini. Rendiconti d. R.
Inst. Lomb. Sc. e Lett., (Ser. II,) XXXIII, 1900.

'00. La ringenerazione nelle Planarie marine. Mem. R. Inst. Lomb. Sc. Lett. CI. Sc.
Mat. Nat., XIX, 1900.
Morgan, T. H.

'93. Experimental Studies on the Teleost Eggs. Anat. Anz., VIII, 1893.

'93. Experimental Studies on Echinoderm Eggs. Ibid., IX, 1893.

'95. A Study of Metamerism. Q. J. Micr. Sc, XXXVII, 1895.

'95. The Formation of the Fish Embryo. Jour. Morph., X, 1895.

'95. Half Embryos and Whole Embryos from one of the first two Blastomeres of the
Frog's Egg. Anat. Anz., X, 1895.

'95. A Study of a Variation in Cleavage. Arch. f. Entw.-mech., II, 1895.

'95. Studies of th.e " Partial " Larvae of Sphaerechinus. Ibid.,\\, 1895.

'95. The Fertilization of non-nucleated Fragments of Echinoderm-Eggs. Ibid., II, 1895.

'96. The Number of Cells in Larvae from Isolated Blastomeres of Amphioxus. Ibid., Ill,
1896.

'97. Regeneration in AUolobophora foetida. Ibid., V, 1897.

'97. The Development of the Frog's Egg. New York, 1897.

'98. Developmental Mechanics. Science, N. S., VII, 1898.

'98. Experimental Studies of the Regeneration of Planaria maculata. Arch. f. Entw.-
mech., VIII, 1898.

'98. Regeneration and Liability to Injury. Zool. Bulletin, I, 1898.

'99. Regeneration of Tissue composed of Parts of Two Species. Biol. Bulletin, I, 1899.

'99. Regeneration in the Hydromedusa, Gonionemus vertens. The American Natu-
ralist, XXXIII, 1899.

304 R^ GENERA TION

'99. A Confirmation of Spallanzani's Discovery of an Earthworm regenerating a Tail in

place of a Head. Anat. Anz., XV, 1899.
'99. Further Experiments on the Regeneration of Tissue composed of Parts of Two

Species. Biol. Bulletin, I, 1899.
'99. Some Problems of Regeneration. Biological Lectures, Woods Holl (1898), 1899.
'00. Further Experiments on the Regeneration of the Appendages of the Hermit-Crab.

Anat. Anz., XVII, 1900.
'00. Regeneration : Old and New Interpretations. Biological Lectures, Woods Holl

(1899), 1900.
'00. Regeneration in Bipalium. Arch. f. Entw.-mech., IX, 1900.
'00. Regeneration in Planarians. Ibid., X, 1900.
'00. Regeneration in Teleosts. Ibid., X, 1900.
'01. Regeneration in Tubularia. Ibid., XI, 1901.

'01. The Problem of Development. The International Monthly, 1901.
'01. The Factors that determine Regeneration in Antennularia. Biol. Bulletin, II, 1901,
'01. Regeneration of Proportionate Structures in Stentor. Biol. Bulletin, II, 1901.
'01. Regeneration in Planaria lugubris. Arch. f. Entw.-mech., XII, 1901.
Morgan, T. H., and Tsuda, Ume.

'93. The Orientation of the Frog's Egg. Q. J. Micr. Sc, XXXV, 1893.
Miiller, E.

'96. Uber die Regeneration der Augenlinse nach Extirpation derselben bei Tritonen.
Arch. f. mikr. Anat., XLVII, 1896.
Miiller, F.

'80. Haeckel's Biogenetische Grundgesetz bei der Neubildung verlorener Glieder.
Kosmos, VIII, 1880-81.
Miiller, E.

'95. Uber das Wiederwachsen (Regeneration) von Korperteilen. Jahresb. d. Ver. f.
vaterl. Naturk. in Wiirttemberg, LVI, 1895.
Miiller, H.

'64. Uber Regeneration der Wirbelsaule und des Riickenmarkes bei Tritonen und Ei-
dechsen. Frankfurt a. M., 1864.
Miiller, 0. F.

1771. Von Wiirmern des siissen und salzigen Wassers. 1771.
Kageli, C von.

'84. Mechanisch-physiologische Theorie der Abstammungslehre. 1884.
Newport, G.

'44. On the Reproduction of Lost Parts in Myriapoda and Insecta. Phil. Trans., 1844.
Nussbaum, M.

'84. Uber spontane und kiinstliche Zellteilung. Sitz. d. Niederrh. Ges., 1884.

'86. Uber die Teilbarkeit der lebendigen Materie. I. Die spontane und kiinstliche

Teilung der Infusorien. Arch. f. mikr. Anat., XXVI, 1886.
'87. Uber die Teilbarkeit, etc. II. Beitrage zur Naturgeschichte des Genus Hydra.

Arch. f. mikr. Anat., XXIX, 1887.
'91. Mechanik des Trembleyschen Umstiilpungsversuchs. Arch. f. mikr. Anat., XXXVI,

1891.
'94. Die mit der Entwickelung fortschreitende Differenzierung der Zellen. Sitz.-Ber.
Niederrh. Ges. Bonn, 1894.
Nussbaum, J., and Sidoriak, S.

'90. Beitrage zur Kenntnis der Regenerations vorgange nach Kiinstlichen Verletzungen
bei alteren Bachforellen embryonen (Salmo fario. L.). Arch. f. Entw.-mech., X, 1890.
Parke, H. H.

'00. Variation and Regulation of Abnormalities in Hydra. Arch. f. Entw.-mech., X, 1900,
Parker, G. H., and Burnett, F. L.

'00. The Reactions of Planarians with and without Eyes to Light. Am. Journ. Physiol.,
IV, 1900.

LITER A TURE 305

Parona, C.

'91. L'Autotomie e la regeneratione delle appendici dorsale nella Tethys lepornia.

Atti della R. Universita di Genova, VII, 1891. (Also Zool. Anz., XIV, 1891.)
Peebles, Florence.

'97. Experimental Studies on Hydra. Arch. f. Entw.-mech., V, 1897.

'98. The Effect of Temperature on the Regeneration of Hydra. Zool. Bull., II, 1898.

'00. Experiments in Regeneration and in Grafting of Hydrozoa. Arch. f. Entw.-mech.,

X, 1900,

Perrier, Ed.

'72. Recherches sur I'Anatomie et la Regeneration des Bras de la Comatula rosacea.

Arch. Zool. Experim., II, 1872.
'73. Sur I'Autotomie et la Regeneration des Bras de la Comatula. Arch. Zool. Experim.,

11, 1873.
Peters, A.

'89. Uber die Regeneration des Endothels der Cornea. Arch. f. Mikr. Anat,, XXXIII,

1889.

Petrone, A.

'84. Du processes regenerateur sur le poumon, sur la foie et sur le rein. Archiv. Ital.
d. Biol., V, 1884.

Pfeffer, W.

'97. Pflanzenphysiologie, 1897.
Pfliiger, E.

'77. Die teleologische Mechanik der lebendigen Natur. Pfluger's Arch., XV, 1877.
'83. Uber der Einfluss der Schwerkraft auf die Teilung der Zellen. Pfluger's Arch.,

XXXI, 1883.
'83. Uber den Einfluss der Schwerkraft auf die Teilung der Zellen und auf die Entwick-

elung des Embryos. Pfluger's Arch., XXXII, 1883.
'84. Uber die Einwirkung der Schwerkraft und anderer Bedingungen auf die Richtung-

der Zellteilung. Pfluger's Arch., XXXIV, 1884.

Phillipeaux, J. M.

'66-'67. Experience demontrant que les membres de la salamandre aquatique (Triton

cristatus) ne se regenerent, etc. Compt. Rend. d. I'Acad. de Science, 1866-67.
'67. Sur la regeneration des membres chez I'Axolotl (Siren pisciformis). Ibid., 1867.
'74. Note sur les resultats de I'extirpation complete d'un des membres anterieurs sur

I'Axolotl et sur la salamandre aquatique. Gaz. Med. de Paris, 1874.
'76. Experiences montrant que les mamelons extirpes sur des jeunes Cochons d'Inde ne

se regenerent point. Compt. Rend., 8 Fev., 1876.
'76. Les membres de la salamandre aquatique bien extirpes ne se regenerent point.

Compt. Rend., LXXXII, Nr. 20, 1876.
'79. Note sur la regeneration de I'humeure vitiee chez les animaux vivant, lapins,

cochons d'Inde. Gaz. Med. de Paris, 1879.
'79. Sur la retablissement de la vue chez les cochons d'Inde apres I'extraction des hu-

meurs vitree et cristalline. Gaz. Med. de Paris, 1879.
'80. Note sur la production de I'oeil chez la salamandre aquatique. Gaz. Med. de Paris,

1880.

Plana, G.

'94. Ricerche sulla polidactilia acquisita determinata sperimentale nei tritoni e sulla
coda supernumera nelle lucertole. Ric. Lab. di Anat. norm, di Roma, IV, 1894.

Pliny, Secundus.

77. Secundi historia mundi. Lib. XXXVII, Lib. XL

Ponfick, E.

'90. Uber Rekreation der Leber. Verhandl. des X Intern. Kongresseszu Berlin, II, 1890.

Porta, Jo. Baptista.

1650. Neapohtani magiae naturalis libri viginti. Rhotomagi MDCL. Lib. II.

X

3o6 - REGENERATION

Prantl, K.

' 74. Untersuch. iiber die Regeneration des Vegetations-punktes an Angiospermenwurzeln.
Arb. a. d. Bot. Instit. in Wiirzburg, IV, 1874.
Preyer, W. \

'86. ijber die Bewegungen der Seesterne. Mitth. Zool. Stat. NeapoL, VII, 1886-87.
Pringsheim, G.

'76. Uber Vegetative Sprossen der Moosfriichte. Monatsberichte d. k. Akad. d, Wiss.
zu Berlin, Juli, 1876.
Przibram, H.

'96. Regeneration bei den Crustaceen. Zool. Anz., XIX, 1896.
'99. Die Regeneration bei den Crustaceen. Arb. d. Zool. Inst, in Wien., II, 1899.
'00. Experimentelle Studien iiber Regeneration. Biol. Centralbl., XX, 1900.
Quatrefages, A.

'65. Histoire naturelle des Annelees. I (page 126), 1865.
Rand, H. W.

'99. Regeneration and Regulation in Hydra viridis. Arch. f. Entw.-mech., VIII, 1899.
'99. The Regulation of Graft-Abnormalities in Hydra. Arch. Entw.-mech. IX, 1899.
Randolph, Harriet.

'92. The Regeneration of the Tail in Lumbriculus. Jour. Morph., VII, 1892.
'97. Observations and Experiments on Regeneration in Planarians. Arch. f. Entvi^.^
mech., 5, 1897.
Rankin, D. R.

'57, On the Structure and Habits of the Slowworm (Anguis fragilis Linn.). Edin-
burgh New Philos. Jour. (N. S.), V, 1857.
Rauber, A.

'95. Die Regeneration der Krystalle, I. Leipzig, 1895. II> 1896.
Reaumur, R. A. de.

1712. Sur les diversees Reproductions. Mem. d. I'Acad., 1712.
1742. Memoires pour servir a I'histoire des Insectes. Tome VI, Preface, 1742.
Ribbert, H.

'94. Beitrage zur kompensatorischen Hypertrophic und zur Regeneration. Arch. f.

Entw.-mech. I, 1894.
'97. Uber Veranderungen transplantierter Gewebe. Arch. f. Entw.-mech. VI, 1897.
'97. iiber Riickbildung an Zellen und Geweben und iiber die Entstehung der Ge-

schwiilste. Bibl. med. Abt., C, 1897.
'98. iJber Veranderungen der abnorm. gekriimmten Schwanzwirbelsaule des Kanin-

chens. Arch. f. Entw.-mech., VI, 1898.
'98. iiber Transplantation von Ovarium, Hoden, und Mamma. Arch. f. Entw.-mech.,
VII, 1898.
Rievel, H.

'96. Die Regeneration des Vorderdarms und Enddarms bei einigen Anneliden. Zeit.
wiss. Zool., LXII, 1896.
Ritter, W. E., and Congdon, E. M.

'00. On the Inhibition by ArtiHcial Section of the Normal Fission Plane in Stenostoma.
Proc. California Acad. Science, II, 1900.
Rothig, P.

'98. Uber Linsenregeneration. Inaug.-Diss. Berlin, 1898.
Roux, W.

'83. Uber die Bedeutung der Kernteilungsfiguren. Leipzig, 1883.

'85. Beitrage zur Entwickelungsmechanik des Embryo. I. Zur Orientierung iiber einige

Probleme der embryonalen Entwickelung. Zeit. f. Biologic, XXI, 1885.
'84. II. iJber die Entwickelung des Froscheies bei Aufhebung der richtenden Wirkung

der Schvvere. Breslauer aerztl. zeitsch., 1884.
'85. III. Uber die Bestimmung der Hauptrichtungen des Froschembryo im Ei und
iiber die erste Teilung des Froscheies. Ibid., 1885.

LITERATURE 307

'87. IV. Die Bestimmung der Medianebene des Froschembryo durch die Kopulations-

richtung des Eikernes und des Spermakernes. Arch. f. mikr. Anat., XXIX, 1887.
'88, V. Uber die kiinstliche Hervorbringung halber Embryonen durch Zerstorung einer

der beiden ersten Furchungskugeln, etc. Virchow's Archiv, CXIV, 1888.
'91. VI. Uber die morphologische Polarization von Eiern und Embryonen durch den

elektrischen Strom. Sitz. Ber. Akad. Wiss. Wien., CI, 1891.
'90. Die Entwickelungsmechanik der Organismen, eine anatomische Wissenschaft der

Zukunft. Wien, 1890.
'92. Uber das entvvickelungsmechanische Vermogen jeder der beiden ersten Furchungs-

zellen des Eies. Verhandl. Anat. Gesell. Wien., 1892,
'93, Uber Mosaikarbeit und neuere Entwickelungshypothesen. Anat. Hefte, II, 1893.
'93. ijber die Spezifikation der Furchungszellen und iiber die bei der Postgeneration

und Regeneration anzunehmenden Vorgange. Biol. Centralbl., XIII, 1893.
'94. Uber den Cytotropismus der Furchungszellen des Grasfrosches. Arch. f. Entw.-

mech., I, 1894.
'95. Gesammelte Abhandlungen iiber Entwickelungsmechanik. Leipzig, 1895.
'95. Uber die verschiedene Entwickelung isolierter erster Blastomeren. Arch. f.

Entw.-mech., I, 1895.
'96. iiber die Selbstordnung (Cytotaxis) sich beriihrender Furchungszellen, etc. Ibid.,

III, 1896.

'96. iiber die Bedeutung " geringer " verschiedenheiten der relativen Grosse der

Furchungszellen fiir den Charakter des I'urchungsschemas. Ibid., IV, 1896.
'97. Fiir unser Programm und seine Verwirklichung. Ibid., V, 1897.
'96. Zu H. Driesch's " Analytischer Theorie der organischen Entwickelung." Ibid.,

IV, 1896.

'00. Berichtigungen zu O. Schultze's jiingstem Aufsatz uber die Bedeutung der
Schwerkraft, etc. Ibid., X, 1900.
Sachs, J.

'80. Stoff und Form der Pflanzenorgane. Arbeiten d. bot. Instituts Wiirzburg, II,

1880-82.
'93. Physiologische Notizen, I, Flora, 1893.
Sarasin, P. and F.

'88. Knospenbildung bei Linckia multiformis. Ergebn. Naturforschung auf Ceylon,
1884-85. I. Wiesbaden, 1888.
Sars, G. 0.

'75. Researches on the Structure and Affinity of the Genus Brisinga. Christiania, 1875.
Schaper, A.

'98. Experimentelle Studien an Amphibienlarven. I. Haben kiinstlich angelegte De-
fekte des Centralnervensystems oder die vollstandige Elimination desselben einen
nachweisbaren Einfluss auf die Entwickelung des Gesamtorganismus junger Frosch-
larven? Arch. f. Entw.-mech., VI, 1898.
Schiedt, R. R.

'92. Diffuse Pigmentation of the Epidermis of the Oyster due to prolonged exposure to
Light. Regeneration of Shell and loss of Adductor Muscle. Proc. Acad. Nat. Sci.
Phila., 1892.

Schimkewitsch, W.

'00. iiber einer Fall von Heterotopie der Haare. Verh. d. k. Naturforscher Gesell. in
St. Petersburg, XXX, 1900.

Schmidt, E. 0.

'75. Spongien. Jahresb. Comm. Untersuch. Deutschen Meere in Kiel, II und III,
Jahrg., 1875.

Schostakowitsch.

'94. iiber Regeneration, etc., bei Lebermoosen. Flora, Erganzungsband, 1894.
Schultz, E.

'98, iiber die Regeneration von Spinnenfiissen. Trav. Soc. Nat. Petersb., XXIX, 1898.

3 o8 RE GENERA TION

Schultze, E.

'99. Aus dem Gebiete der Regeneration. Zeit. f. wiss. Zool., LXVI, 1899.

Schultze, L. S.

'99. Die Regeneration des Ganglion von Ciona intestinalis, L. und iiber das Verhaltnis
der Regeneration und Knospung zur Keimblatterlehre. Jena Zeit. f. Naturwiss.,
XXXIII, 1899.
Schultze, 0.

'94. Die kiinstliche Erzeugung von Doppelbildungen bei Froschlarven mit Hiilfe ab-

normer Gravitationswirkung. Arch. f. Entw.-mech., I, 1894.
'99. Uber das erste Auftreten der bilateralen Symmetric im Verlauf der Entwickelung.

Archiv. f. Mikr. Anat., LV, 1899.
'99. tjber die Nothwendigkeit der freien Entwickelung des Embryo. Ibid., 1899.
Scudder, S.

'68-69. Proceedings Boston Society of Natural History (page 99), XII, 1868-69.
SemoD, R.

'89. Neubildung der Scherbe in der Mitte eines abgebrochenen Seesternarmes. Jena.
Zeit. f. Naturw., XXIII, 1889.
Semper, C.

'68. Reisen in Archipel der Philippinen, II, 1868.

'76. Die Verwandtschaftsbeziehungen der gegliederten Thiere. Arb. zool.-zoot. Inst.
WUrzburg, III, 1876.
Siebold.

'28. Observationes quaedam de Salamandris et Tritonis. Diss. Berolini, 1828.

Simroth, H.

'77. Anatomic und Schizogonic der Ophiactis virens. Zeit. f. wiss. Zool., XXVIII, 1877.

Spallanzani, L.

1782. Risultati di esperienze sopra la riproduzione della Testa nelle Lumache Terrestri.

Memoria di Matematica e Fisica della Societa italiana, tomo I, Verona, 1782.
'26. Prodromo di un' opera sopra Ic riproduzioni animali. Milano, 1826.

Spemann, H.

'00. Experimentellc Erzeugung zweikopfiger Embryoncn. Sitzber. d. Phys. Med.

Gesell. Wiirzburg, 1900.
'01. Entwickelungsphysiologische Studien am Triton-Ei. Archiv. f. Entw.-mech., XII,

1901.
Spengel, J. W.

'93. Monographic der Enteropneusten. Fauna und Flora des Golfes von Ncapel, 1893.

Stahl, E.

'76. Uber kiinstliche hervorgerufene Protoncmabildungen an dcm Sporogonium der
Laubmoose. Bot. Zeit., 1876.

Strasser, H.

'99. Regeneration und Entwickelung. Berner Rektoratsrede. Jena, 1899.

Studer, Th.

'77. Echinodermen aus dem antarktischen Meere. Monatsber. d. Berliner Akad., 1877.

Tittmann, H.

'95. Physiol. Untersuch. iiber Callusbildung an Stocklingen. Jahr. f. wiss. Botan.,
XXVIII, 1895.
Tizzoni, G.

'83. Experimentellc Studie iiber die particUe Regeneration und Neubildung von Lebcr-
gcwebe. BioL Centralb., Ill, 1883-84.

Tornier, G.

'96. ijber Hyperdaktylie, Regeneration und Vererbung mit Experimenten. Arch. f.

Entw.-mech., Ill, 1896.
'97. Uber experimentell crzeugtc dreischwanzige Eidechscn und Doppelgliedmasscn

von Molchcn. Zool. Anz., XX, 1897.

LITERA TURK 309

'97. tjber Operationsmethoden, welche sicher Hyperdaktylie erzeugen mit Bemerkungen
liber Hyperdaktylie und Hyperpedie. Zool. Anz., XX, 1897.
Tower, W. L.

'99. Loss of the Ectoderm of Hydra viridis in the Light of a Projection Microscope.
The American Naturahst (page 505), June, 1899.
Towle, E. W.

'91. On Muscle Regeneration in the Limbs of Plethedon. Biol. Bull., II, 1891.
Trembley, A.

'74. Memoires pour servir ^ I'histoire d'un genre de Polypes d'eau douce. Leide, 1774.
Tytler, R. C.

'65. Farbenwechsel, die Hautung und die Regeneration des Schwanzes bei den Ascala-
boten. Journ. of the Asiatic Soc. of Bengal, 1865.
Vernon, H. M.

'99. The Effect of Staleness of the Sexual Cells on the Development of Echinoids.

Proc. Roy. Soc, LXV, 1899.
'00. Cross-Fertihzation among Echinoids. Arch. f. Entw.-mech., IX, 1900.
Verworn, M.

'91. Die physiologische Bedeutung d. Zellkerns. Arch. f. d. ges. Physiol., LI, 1891.
'88. Biologische Protistenstudien. I. Zeit. f. wiss. Zool., XLVI, 1888.
'89. Psycho-physiologische Protistenstudien, 1889.

'89. Die Polare Erregung der Protisten durch den galvanischen Strom. Arch. f. d. ges.
Physiol,, XLVI, 1889.
Vochting, H.

'77. Uber die Teilbarkeit und die Wirkung innerer und ausserer Krafte auf die Organ-

bildung in Pflanzenteilen. Ptiiiger's Arch., XV, 1877.
'78. ijber Organbildung im Pflanzenreiche. Bonn, 1878 u. 1884.
'85. Uber die Regeneration der Marchantieen. Jahrb. f. wiss. Botanik, XVI, 1885.
'87. Uber die Bildung von Knollen. Bibliotheca Botanica, No. 4, Cassel, 1887.
'92. iJber Transplantation am Pflanzenkorper. Tiibingen, 1892.
Voigt, W.

'99. Kiinstlich hervorgerufene Neubildung von korpertheilen bei Strudelwiirmern,
Sitz. d. Niederrhein. Gesell. f. Natur- und Heilkunde zu Bonn, 1899.
De Vries, H.

'89. Intracellulare Pangenesis, 1889.
Vulpian, M. A.

'59. Notes sur les phenomenes de developpement qui se manifestent dans la queue de
tres jeunes embryons de grenouille. Compt. Rend., XLVIII, 1859.
Wagner, F. von.

'93. Einige Bemerkungen iiber das Verhaltnis von Ontogenie und Regeneration. Biol.

Centralbl., XIII, 1893.
'97. Zwei Worter zur Kenntniss der Regeneration des Vorderdarms bei Lumbriculus.

Zool. Anz., XX, 1897.
'00. Beitrage zur Kenntniss der Reparationsprozesse bei Lumbriculus variegatus. I.
Zool. Jahrb., XIII, 1900.
Wagner, W.

'87. La regeneration des organes perdus chez les araignees. Bull. Soc. Imp. Natural.,
Moscow, 1887.
Watson, J.

'91. On the Redevelopment of Lost Limbs in the Insecta. The Entomologist, XXIV,
1891.
Weismann, A.

'91. Essays on Heredity, Vol. I. Clarendon Press, Oxford, 1891.

'92. Das Keimplasma. Eine Theorie der Vererbung. Jena, 1892.

'94. The Germ-plasm. New York, 1894.

'96. iJber Germinal-Selektion. Eine Quelle bestimmt gerichteter Variation. Jena, 1896.

310 RE GENERA TION

'97. Regeneration: Facts and Interpretations. Natural Science, April, 1897.
'99. Thatsachen und Auslegurigen in Besug auf Regtneration. Anat. Anz., XV, 1899.
Wendelstadt, H.

'01. Dber Knochenregeneration, Arch. f. mikr. Anat., LVII, 1801.
Werner, F.

'92, Selbstverstiimmelung bei Heuschrecken Zool. Anz., XV, 1892.
'96. tjber die Schuppenbildung des regenerierten Schwanzes bei Eidechsen. Sitz-
ungsber. d. kais. Akad. in Wien, CV, 1896.
Wetzel, G.

'95. Transplantationsversuche mit Hydra. Arch. f. mikr. Anat., XLV, 1895.

'95. Uber die Bedeutung der cirkularen Furche in der Entwickelung der Schultzeschen

Doppelbildungen von Rana Fusca. Arch. f. mikr. Anat., XLVI, 1895.
'96. Beitrag zum Studium der kiinstlichcn Doppelmissbildungen von Rana Fusca.
Inaug. Dissert., 1896.
Whitman, C. 0.

'89. The Seat of Formative and Regenerative Energy. Jour. Morph., II, 1889.
'93. The Inadequacy of the Cell Theory of Development. Jour. Morph., VIII, 1893.
'95. Evolution and Epigenesis. Biolog. Lectures at Woods HoU in 1894, 1895.
Wiedersheim, R.

'77. ijber Neubildung von Kiemen bei Siren lacertina. Morph. Jahrb., Ill, 1887.
Wilson, C. B.

'97. Experiments on the Early Development of the Amphibian Embryo under the Influ-
ence of Ringer and Salt Solutions. Arch. f. Entw.-mech., V, 1897.
'00. The Habits and Early Development of Cerebratulus Lacteus. Q. J. Mic, Sc,
XLIII, 1900,
Wilson, E. B.

'92. The Cell-Lineage of Nereis. Jour. Morph., VI, 1892.

'93. Amphioxus and the Mosaic Theory of Development. Jour. Morph., VIII, 1893.

'95. On Cleavage and Mosaic Work. Appendix to Crampton. Arch. f. Entw.-mech.,

HI, 1895.
'96. The Cell in Development and Inheritance. New York and London, 1896.
'98. Considerations on Cell-Lineage and Ancestral Reminiscence. New York Acad.
Science, II, 1898.

Wolff, G.

'94. Bemerkungen zum Darwinismus mit einem experimentellen Beitrag zur Physiologic

der Entwickelung. Biok Centralbl., XIV, 1894.
'93. Entvvickelungphysiologische. Studien. I. Die Regeneration der Urodelenlinse.
Arch. f. Entw.-mech., I, 1893.
Zacharias, 0.

'86. iJber Fortpflanzung durch Spontanquertheilung, etc. Zeit. f. wiss. Zool., XLIII,
1886.
Ziegler, E.

'91. tjber die ursachen der pathologischen Gewebsneubildungen. International Bei-
trage zur wissenschaftliche Medizin. Festschrift fiir Virchow, II, 1891.
Ziegler, H. E.

'98. Experimentelle Studien iiber die Zellteilung, I. Die Zerschniirung der Seeigeleier.

Arch. f. Entw.-mech., VI, 1898.
'98. Experimentelle Studien, etc.. III. Die Furchungszellen von Beroe ovata. Arch,
f. Entw.-mech., VII, 1898.
Zoja, R.

'95. Sullo sviluppo dei blastomeri isolati delle uova di alcune meduse. Arch. f. Entw.-
mech., I u. II, 1895.

INDEX

Accidental Regeneration, 25.
Achimenes, 88.
Actinians, 142.

Actinosphasrium eichhornii, 65.
"Action at a distance," 283-287.
Adaptation, 94, 158, 277, 288-292.
Allman, 38.

Allolobophora terrestris, 172, 174, 175.
Alpheus platyrrhynchus, 63.
Amoeba, 103.
Amphibia, 106.

Amphioxus, 105, 139, 231,237.
Amphiuma, 106.

Analytische Theorie of Driesch, 253-254.
Andrews, E. A., 152.
Andrews, Mrs. G. F. 251.
Anguis fragilis, 198.
Annelids, 104, 143.

Antennularia antennina, 30-33, 103, 131.
Ants, 154.
Aristotle, i.
Aschoff, 115.
Ascidian, 114, 149.
Ascidian egg, 236,
Asplenium, 23.
Asterias vulgaris, 102, 103.
Atrophy, ill, 123-125.
Atyoida potimirum, 24, 213.
Aurelia, 104.
Autolytus, 143.

Autotomy, no, 142, 1 50-155; theories of,
155-158.

Baer, von, 208.

Balbiani, 66, 129.

Bardeen, 41, 136.

Barfurth, 21, 45, 54, 129, 137, 197, 199,

200.
Begonia, 23; B. discolor, 74.
Beneden, Van, 210.
Beroe ovata, 239.
Bert, 178.

Bickford, E., 57, 202.
Biophors, 278.

Bipalium, 13, 14, 104; grafting, 170.

Birds, 97, 106.

Bizozzero, 128.

Blastomeres, 19, no.

Blastulae, fusion of, 188.

Blood vessels, 120, 122-123.

Blumenbach, 112.

Bock, von, 149.

Bombinator igneus, 184.

Bones, 113, 124, 181.

Bonnet, i; experiments with worms, 2, 26,

38, 41, 92, n2, 200, 260, 261, 267.
Bordage, 97, 100, 157.
Born, 182-183, 243.
Boulenger, 214.
Boveri, 68, 228.
Braefeld, 17, 80.
Braem, 211.
Brandt, 65.

Breaking-joint, 150-152.
Brindley, 100, 104.
Brittle-stars, 105, 144, 145.
Broussonet, 97.
Bryozoa, 211.
Budding, 142, 149-150.
Billow, 190, 213.
Bunting, 237.
Byrnes, 182.

Callus, 82, 83.

Camerano, 92.

Campanularia, 35.

Carniola, 106.

Carodina, 213.

Carriere, 104, 213.

Cat, 179.

Caterpillar, 100, 104, 154.

Cause, 287, 290.

Cells, origin of, 190-215.

Cephalodiscus, 149.

Cerianthus membranaceous, 41, 104.

Cermatia forceps, 100.

Cestodes, 103, 146.

Chabry, 236.

312

INDEX

Chsetogaster, 146.

Chsetopterus, 189.

Chun, 238.

Ciona intestinalis, 42.

Closing wound, 69.

Cockroach, 100, 104.

Coelenterates, 145, 149.

Cohnheim, 118, 119.

Colucci, 112, 203.

Conifers, 76 (footnote).

Conklin, 116.

Connective tissue, 180, 181.

Contact, 33, 37.

Coprinus stercorarius, 86, 87.

Corals, 142.

Crab, 43, 151, 152, 158.

Crampton, 236, 240, 245.

Crayfish, 100, 151, 157.

Crepidula fornicata, 116.

Crinoids, 105.

Crystal, regeneration of, 263-264.

Ctenodrilus monostylos, 144, 148.

Ctenodrilus pardalis, 144, 148.

Ctenophore-egg, 238-241.

Ctenophores, 142.

Cuvierian organs, 105.

Cytotropism, 69, 281.

Daly ell, 129, 144.

Darwinism, 108.

Darwin's pangenesis, 278.

Delage, 25, 92.

Dendroccelum, 104.

Difflugia, 103.

Double structures, 128, 135-14I.

Driesch, definition of regeneration, 21, 22;
reparation, 22; regulation, 22; restitu-
tion, 22; self-regulation, 22; antennu-
laria, 32; 43, 57, 59, 60, 135, 139, 188,
202, 228-236, 243, 246, 248, 250, 251,
252-255, 257, 267, 268, 274, 280, 281-
287,

Driesch and Morgan, 239-241, 245.

Du Bois-Reymond, 286.

Duges, 136.

Duhamel, 178.

Duyne, van, 136, 140, 141.

Dwarfs, 116.

Earthworm (Allolobophora foetida), 9, 12,
38-39, 40, 53, 144, 170, 194, 271, 280,
290.

Echinoderms, 105, 144.

Echinus microtuberculatus, 68.

Egg, 18, 19, 139, 188, 216.

Embryo, 18, no, 216; grafting in, 182-
189; union of, 188; tension hypothesis,
274.

Endres, 221.

Epeiridie, 100.

Epimorphosis, 23.

Epithelium, 180.

Eudendrium racemosum, 29, 30, 103.

External factors, 26.

Eye, 203; Crustacea, 30; lens, 203-205.

Factors, 277,

Faraday, 136.

Fiedler, 228.

Fischel, 112, 205-207, 240, 291, 292.

Fischer, 124, 178.

Fish, 6, 97, 131-133, 274, 281; lens, 290.

Fish's eggs, 237.

Flatworms, see Planarians.

Food, influence of, 27, 37, 120, 122, 123.

Force, 76, 287.

Formative forces, 255, 277, 288.

Formative stuffs, 40, 88, 89, 90, 91.

Fraisse, 21, 97, 196, 197, 198, 199, 200, 214.

Fredericq, 151, 152.

Frogs, 106.

Frogs' egg, 216.

Fundulus eggs, 237.

Fundulus heteroclitus, 45, 97, 274.

Gastroblasta Raffaelei, 142, 145.

Gerassimoff, 66.

Germ-layers, 207-212.

Giants, 115.

Giard, 92.

Godelmann, 154.

Goebel, 22, 85, 86, 88, 89, 90.

Goette, 106, 200, 201, 213.

Gonionemus, 104, 125.

Grafting, 159-189.

Gravity, influence of, 30-33, 37.

Grawitz, 1 19.

Growth, 128, 131-135, 269-271, 278, 292.

Gruber, 66.

Guinea pig, 179.

Haberlandt, 66.
Haeckel, 102, 208, 216.
Half-embryos of frog, 216-226.
Hargitt, 125, 127, 168, 169.
Harmony, 282.
Harrison, 186, 187.
Heart, 124.
Heineken, 100.
Helicarion, 93.

INDEX

313

Heliotropism, 271.

Hepke, 190, 192,

Herbst, 30, 214, 286.

Hermit-crab, 63, 97-99; autotomy, 155

Herrick, 153.

Hertwig, O., 22, 23, 222-227, 243, 246, 251,

252, 256, 278, 280, 288.
Hertwig, R., 228.
Hescheler, 44, 194, 196.
Heterocentron dive rsi folium, 74, 80.
Heteromorphosis, 24, 38-42.
Heteronereis, 143.
Heterotropy, 280.
His, 241.
Hjort, 210.
Hofer, 66.
Holomorphosis, 24.
Holothurians, 105, 145, 154.
Homology, 209.
Homomorphosis, 23.
Hunter, 178.
Huxley, 208.

Hyacinthus orientalis, 88.
Hydra, i, 2, 11, 56, 103,121,122,124,142,

149; grafting, 159-166, 203, 270, 272.
Hydra grisea, 169.
Hydra fusca, 169.
Hydractinia, 103, 168.
Hyperplasy, 115.
Hypertrophy, iii, 1 15-123.

Idiosomes, 278.
Ilyanassa obsoleta, 240.
Internal factors, 38, etc., 52-54.
Internal organs, 52-54, III.
Iris, 204-207.
Ischikawa, 203.

Jelly-fish's eggs, 237.
Joest, 170-175, 186.

Kennel, von, 147, 148, 149.

Kidney, 113, 116, 124, 180.

King, 102, 103, 125, 135, 139, 153, 162, 214.

Klebs, 66, 118, 120.

Knight, 75.

Knovsdton, 27.

Kochs, W., ^112.

Kowalevsky, 208, 2 ID.

Kretz, 112.

Kroeber, 196.

Lamarckianism, 157.

Lang, 92, 93.

Lateral Regeneration, 9, 10, 28, 29, 43.

Leeches, 146.

Lefevre, 2io, 211.

Lepelletur, 100.

Lepismium radicans, 78.

Lessona, 92, 93.

Liability to injury, 92-1 10; view of Reaumur,

92; of Bonnet, 92; of Darwin, 92; of

Lang, 93; of Semper, 93; of Weismann,

93-96.
Light, influence of, 29, 30, 37.
Lillie, 26, 56.
Limnsea, 104.
Linckia multiformis, 102.
Lithium salts, 286.
Liver, iii, 180.
Liverworts, 16.
Lizard, 6, 94, 106; double tail, 137-139; 198,

214, 290.
Lobster, 153.
Loeb, J., 24, 29, 30, 31, 33, 34, 35, 42, 59,

67, 68, 102, 114, 131, 139, 141, 189, 231,
267, 268.

Loeb, Leo, 179.

Ludwig, 105.

Lumbricus rubellus, 172, 174, 175.

Lumbriculus, 43, 104, 144, 149, 190, 191.

Lung, 112.

Lunularia vulgaris, 84, 85.

Lymphatic glands, 121 ; grafting upon, 179.

Machine theory, 281.

Mammals, 97, 11 7-1 18; grafting, 178.

Man, 107; grafting, 178, 179.

Mantis, lOO, 104.

Margelis carolinensis, 34.

Marshall, 124-125.

Martens, von, I02.

Mauritius, fighting cocks, 97, 106.

Mechanism, 277.

Meckel, 208.

Mesoderm, 193, 194.

Metridium, 104.

Michel, 190, 192.

Minchin, 105.

Minimal size, 55-57.

Molgula manhattensis, 237.

Mollusks, 104.

Morgan, 9, 30, 32, t,z> 43.44, 57-62, 64, 65,

68, 126, 131, 175, 185, 186, 187, 225, 231,
232, 237, 238, 243, 246, 247, 248, 249,
268.

Morphallaxis, 13, 270-271,
Mosses, 16, 17.
Moulds, 16.
Mouse, 178.

314,

INDEX

Mucor mucedo, 86.

Muller, E., 112.

Miiller, Fritz, 100, 213.

Mus decumanus, 178,

Mus sylvaticus, 178.

Muscles, 114, 116, 120, 128, 181.

Myriapods, 100, 104; autotomy, 154.

Nageli, 278, 280.

Nais, 104, 146.

Natural selection, 96, 108-1 10, 155-157, 262,

290, 292.
Necturus, 106.
Nematodes, 104.
Nemerteans, 104, 143.
Nereis, 143.
Nerves, 114.
Nervous system, 114.
Newport, 100, 154.
Nothnagel, 116, 117, 120.
Nucleus, influence of, 66, 67, 258, 281.
Nussbaum, 20, 66, 202, 203.

Oblique surface, 44-52, 281.

Oka, 210.

Old part, influence of, 62-65.

Oligochceta, 143.

Ontogeny, 212-215, 282.

Organization, 251, 275, 277, 278, 279, 288.

" Origin of Species," 109.

Ovary, 124.

Oxygen, influence of, 36, 77-78.

Palla, 66.

Palolo, 143.

Paramoecium, 103.

Parypha, see Tubularia.

Pathological Regeneration, 21.

Peebles, F., hydra, 27, 56, 63, loi, 167, 168.

Peipers, 113.

Pekelharing, 1 18.

Pennaria tiarella, 35.

Petromyzon, 105.

Pfliiger, 216, 242-243, 246, 252, 256, 264, 265,

288.
Phagocata, 104.
Phailusia mammalata, 236.
Phasmids, 154.
Phialidium variabile, 142.
Phillipeaux, 112, 200.
Phoxichilidium maxillare, I02.
Phylogeny, 212-215.
Physa, 104.

Physiological Regeneration, 19, 25, 128-131.
Pizon, 210.

Planaria lugubris, see Planarian.

Planaria maculata, see Planarian.

Planaria torva, 26.

Planarian, 9, 11, 13, 27, 28, 29, 40, 41, 43,
44-51, 64-65, 104, 107, 129, 133-135,
136, 141, 142, 201, 207, 273, 280.

Planorbis, 104.

Plants, 15, 70-91.

Plasomes, 278.

Platodes, 104.

Plethedon cinereus, 201.

Pliny, I.

Podocoryne, 103, 168.

Podwyssozki, 113.

Poisons, 123.

Polarity, 38-40, 43, 177, 277, 280.

Polychaeta, 143.

Polyclads, 104.

Polyzoa, 149.

Ponfick, III.

Populus dilatata, 75, 76, 80.

Post-generation, 20; criticism of, 20 (foot-
note); 216, 219-221.

Pringsheim, 17, 86.

Proglottids, 146.

Proteus, 106.

Protozoa, 103, 145.

Przibram, 63, 100, 213.

Purpose, 282, 283.

Qualitative division of nucleus, 263.

Rabbit, 112, 113, I17, I18, 179.

Rana esculenta, 184.

Rana palustris, 185.

Rana virescens, 185.

Rand, 124, 164.

Randolph, 136, 190, 194.

Rat, 113, 179.

Rathburn, 153.

Rauber, 263-264.

Reaumur, i ; experiments with worm and
with hydra, 2; 92, 15 1.

Recklinghausen, 118.

Regeneration, definition of, 19-25; incom-
plete, 125.

Regular Regeneration, 25.

Regulation, 22.

Remak, 208.

Reparation, 22.

Restitution, 22.

Restorative Regeneration, 25.

Rhabdocnelous, Planarians, 142, 149.

Ribbert, 112, 1 15, 1 17, 179-181.

Rievel, 190.

INDEX

315

Roots, 80.
Rothig, 112.

Roux, definition of Regeneration, 20,22, 183,
216-226, 243, 250, 252, 256, 288.

Sachs, 81, 88, 89; theory of Regeneration,
265-267.

Salamander, 5, 6, il, 43, 200, 213, 214, 270.

Salamandra maculata, 205.

Salensky, 210.

Salivary gland, 112, 113, 180.

Salix viminalis, 77,

Samuel, 118.

Sarasin, 102.

Sars, 102.

Schaper, 182.

Schmidt, O., 103.

Schmitz, 65.

Schostokowitsch, 85.

Schreiber, 106.

Schuberg, 129.

Schultz, 100, loi, 102, 154.

Schultze, 139, 225-227.

Scudder, 100, 154.

Scutigera forceps, 154.

Scyphistoma, 104, 142, 149.

Scyphozoa, 104.

Sea-urchin, 18, 19, 105.

Sea-urchin's egg, 228.

Seeliger, 68, 2io.

Self-division, 142.

Self-regulation, 22.

Semper, 93, 190,

Sertoli's cells, 181.

Sharks, 105.

Siredon, 199.

Skin, 178, 179, 180.

Snail, 213.

Snakes, 106.

Spallanzani, Prodromo, I, 4; experiments
with earthworms, 4; tadpole, 5; salaman-
ders, 5 ; snail, 5, 26, 38, 104, 153, 182, 200.

Spemann, 227.

Spencer, Herbert," 263.

Sphserechinus granularis, 68.

Spiders, 100, 104.

Spina bifida, 6.

Spleen, 124.

Sponges, 103, 142, 143, 149.

Spur of cock, 178.

Starfish, 18, 19, 102, 103, 105, iio, 144, 153,
214, 284.

Stenopus chrysops, 133, 274, 281.

Stentor, 14, 15, 56, 66, 67, 103, 129.

Stimulus, 283, 284, 285.

Stomobranchium mirabile, 142.

Stork, 97.

Strassen, zur, 189.

Strieker, 119.

Stuffs, 265-269.

Syllids, 143.

Syllis ramosa, 149. "

Tadpole, II, 45; closing of wound, 70; 106,

137, 182-186, 197, 199-200.
Tail, 197.
Tapeworm, 143.
Tarantula, 1 00, 154.
Teleology, 282, 288-292.
Teleost's egg, 237.
Temperature, 26-27, 37.
Tension, 272-278; in egg, 274.
Testes, 117, 124, 181.
Tetrastemma, 104.
Thallasicolla nucleata, 67.
Theories of Regeneration, 260.
Tornier, 54, 137, 139, 214,
Tower, 203.
Towle, 97, 201.
Townsend, 66.
Trachea, 180.
Transplantation, 179.
Trematodes, 104.
Trembley, i ; experiments with hydra, 2, 20,

26, 38>43. 159, 202.
Triclads, 104.
Triton cristatus, 137.
Triton eye, 112; lens, 112.
Triton marmoratus, 106.
Tubifex, 104, 191.
Tubularia, 25, 33, 34, 52, 56-62, 69, 70,

103, 129, 167-168, 267, 273.
Turtles, 106.

Urodeles, 106, 197.

Valle, della, 210.

Vernon, 68.

Vertebrae, 181.

Verworn, 66, 67.

Virchow, 115.

Vitalism, 277, 284, 285.

Vochting, 16, 57, 71-91, 131, 176, 269.

Vries, de, 278.

Vulpian, 182.

"Wagner, von, 144, 149, 190, 192.
Wagner, W., lOO.
Walter, 221.
Wax glands, 180.

3i6

INDEX

Weigert, Ii8, 119.

Weisman, 93-96, 97, loi, 106, 108, 112,

129-130, 245, 252, 256, 261-263, 278.
Wetzel, 159, 169, 227.
White ants, 154.
Whitmann, 280.

Whole embryos, of reduced size, 222.
Wiesner, 278.
Willow, 71-82.

Wilson, E. B., 68, 139, 231, 237, 250, 251,

256.
Wolff, C. F., 207, 208.
Wolff, G., 112, 203, 205, 206, 291, 292.

Zahn, 124, 178.

Ziegler, 115, 1 18, 119, I2I, 240-241, 243,

246.
Zoja, 237.