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THE DEVELOPMENT OF THE CHICK - AN INTRODUCTION TO EMBRYOLOGY  
{{Review - Lillie’s Development of the Chicken collapsetable}}
 
{| class="wikitable mw-collapsible mw-collapsed"
! Review - Lillie’s Development of the Chicken - an Introduction to Embryology 3rd Edn. (1952)  
|-
| Lillie’s Development of the Chicken Introduction to Embryology. 3rd Edition, revised by Howarp L. Hamilton. (Pp. 574; 283 figs.; 14 plates; $8.50.) New York: H. Holt & Co. 1952.
 
The writing of the present edition was begun in 1945 at the request of Dr Frank R. Lillie himself with Dr B. H. Willier acting as advisory editor. It was Dr Lillie’s hope that he might live to see the new edition in print but this was not to be. The general outline of previous editions has been preserved. Part 1, which consists of six chapters, is devoted to an account of the early embryology up to and including the 3rd day. The account of the development of the embryo is given on a general basis and in addition a detailed account is given of specially selected stages.
 
Part 2 of the book consists of nine chapters and is an account of the development of the embryo from the 4th day to hatching; the various systems and external form are described as separate entities. A few chapters, such as the one dealing with the external form of the embryo and the embryonic membranes, and the one describing the body cavities, mesenteries and septum transversum, have remained relatively unchanged. Chapter 4, ‘From laying to the formation of the first somite’, chapter 8; ‘The nervous system’, and chapter 13, ‘The urogenital system’, are more or less completely rewritten. A new chapter, the fifteenth, describing the development of the integument, has been added. The other chapters have been extensively revised.
 
The new accounts are based on recent literature, but the author has tried to follow Dr Lillie’s example of going to the chick itself to check questionable points. To this end some original work is included in the text, but it is to be regretted that the author has not indicated more clearly which parts of the text result from this original work. The only clear indications consist of an opinion on the processes concerned with the formation of endoderm (p. 101) and two footnotes, one dealing with the coelomic cavity (p. 149) and one with the tail bud (p. 176). A further footnote refers to a communication from Rawles on the patency of the ductus arteriosus in the newly-hatched chick (p. 462).
 
This book is very well written and its format is attractive. The book reaches a happy compromise which makes it a most readable introduction to embryology while yet remaining an invaluable reference work for the research worker.
 
There is little to criticize in this work which has evidently been prepared with great care, but future editions might be improved by a rearrangement of the bibliography. The references should be listed at the end of the chapter they concern and not in an appendix of 32 pages at the end of the book. Also the magnification of drawings and photographs of early embryos should be given. Figs. 153 and 155 would be improved by being photographs rather than drawings of sagittal sections through an embryo. In fig. 222 the drawings are too small and too faint.
 
Apart from these minor faults the present work is a credit to the author and had Dr Lillie lived he would have been proud to have his name associated with it. It will continue to perpetuate Dr Lillie’s influence on the development of embryology.
 
[[Embryology History - William Hamilton|W. J. Hamilton]]
 
{{chicken}}
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==THE DEVELOPMENT OF THE CHICK - AN INTRODUCTION TO EMBRYOLOGY==
BY  
BY  


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==Part I The Early Development To The End Of The Third Day==
==Part I The Early Development To The End Of The Third Day==


==CHAPTER IX  ORGANS OF SPECIAL SENSE==
==Appendix==


I. The Eye


The development of the eye up to the stage of 36 somites has
===General Literature===
been already described. We shall now consider the subsequent
changes in the following order: (1) optic cup, (2) vitreous body,
(3) lens, (4) anterior chamber, cornea, iris, etc., (5) choroid and
sclerotic, (6) the conjunctival sac and eyelids, (7) the choroid fissure and the optic nerve.


1. The optic cup at the stage of 36 somites is composed of
V. Baer, C. E., L'eber Entwickelurigsgeschichte der Tiere. Beobachtung
two layers, an inner, thicker layer, known as the retinal layer,
and an outer, thinner layer, known as the pigment layer; these
are continuous with one another at the pupil and choroid fissure.  
The inner and outer layers come into contact first in the region
of the fundus, and the cavity of the original optic vesicle is gradually obliterated. The choroid fissure is in the ventral face of
the optic cup; it is very narrow at this time, and opens distally
into the pupil; centrally it ends at the junction of optic stalk
and cup, not being continued on the stalk as it is in mammals (Fig.
157).  


The walls of the optic cup may be divided into a lenticular
und Reflexion. Konigsbcrg, 1828 u. 1837.  
zone {pars lenticularis or pars cceca) and a retinal zone; the former
includes the zone adjacent to the pupil, not sharply demarcated
at first from the remainder or retinal zone, but later bounded distinctly by the ora serrata. The retinal zone alone becomes the
sensitive portion of the eye; the lenticular zone develops into the
epithelium of the iris and ciliary processes.  


In the lenticular zone the inner and outer layers become actually fused, but in the retinal zone they may always be separated;
id., 2. Teil — Herausgegeben von Stieda. Konigsberg, 1888.
indeed, in most preparations they are separated by an actual
Duval, Mathias, Atlas d'embryologie. (With 40 plates.) Paris, 1889.
space produced by unequal shrinkage.  
Foster, M., and Balfour, F. M., The Elements of Embryology. Second Edition revised. London, 1883.
Gadow, Hans, Die Vogel, Bronn's Klassen und Ordniingen des Thier-Reichs, Bd. VI, Abth. 4, 1898.
Handbuch der vergleichenden und experimentellen Entwickelimgslehre der Wirbeltiere. Edited by Dr. Oskar Hertwig and written by numerous  collaborators. Jena, 1901-1907.  


The differentiation of the lenticular from the retinal zone
begins about the seventh day, when a marked difference in thick
271


Hls, W., LTntersuchungen fiber die erste Anlage des Wirbeltierleibes. Die  erste Entwickelung des Hiihnchens im Ei. Leipzig, 1868.
Keibel, F., and Abraham, K., Normaltafeln zur Entwickelungsgeschichte  des Huhnes (Gallus domesticus). Jena, 1900.




272
V. KoLLiKER, A., Entwickelungsgeschichte des Menschen und der hoheren


Thiere. Zweite Aufl. Leipzig, 1879.
Marshall, A. M., Vertebrate Embryology. A Text-book for Students and


Practitioners. (Ch. IV, The Development of the Chick.) New York


THE DEVELOPMENT OF THE CHICK
and London, 1893.
MiNOT, C. S., Laboratory Text-book of Embryology. Philadelphia, 1903.
Pander, Beitrage zur Entwickelungsgeschichte des Hiihnchens im Ei. Wiirz
burg, 1817.
Prevost et Dumas, Memoire sur le developpement du poulet dans I'oeuf.


Ann. Sc. Nat., Vol. XII, 1827.
Preyer, W., Specielle Physiologic des Embryo. Leipzig, 1885.
Remak, R., Untersuchungen iiber die Entwickelung der Wirbelthiere. Berlin, 1855.


===Literature — Chapter I===


ness appears. The transition from the thinner lenticular to the  
Bartelmez, George W., 1912, The Bilaterality of the Pigeon's Egg. A
thicker retinal zone soon becomes rather sudden in the region of  
Study in Egg Organization from the First Growth Period of the Oocyte
the future ora serrata. About the eighth or ninth day a further
to the Beginning of Cleavage. Journ. of Morph. Vol. 23., pp. 269-328.  
differentiation arises within the lenticular zone, marking off the
regions of the iris and ciliary processes (Fig. 159). The region


CoSTE, M., Histoire generale et particuliere du developpement des corps
organises, T. I. (Formation of Egg in Oviduct, see Chap. VI). Paris,
1847-1849.


D 'Hollander, F., Recherches sur I'oogenese et sur la structure et la signification du noyau vitellin de Balbiani chez les oiseaux. Archiv. d'anat.
micr., T. VII, 1905.


Gegenbaur, C, Ueber den Bau und die Entwickelung der Wirbeltiereier
mit partieller Dottertheilung. Archiv. Anat. u. Phys., 1861.


ep ^es p r


Glaser, Otto, 1913, On the Origin of Double-yolked Eggs. Biol. Bull.,


Vol. 24, pp. 175-186.
HoLL, M., Ueber die Reifung der Eizelle des Huhnes. Sitzungsber. Akad
Wiss. Wien, math.-nat. KL, Bd. XCIX, Abth. Ill, 1890.


157 ■ 158
V. Nathusius, W., Zur Bildung der Eihiillen. Zool. Anz. Bd. XIX, 1896.


Fig. 157. — Section through the eye of a chick embryo at the
Die Entwickelung von Schale und Schalenhaut des Hiihnereies im


beginning; of the fourth day of incubation. (After Froriep.)
Ovidukt. Zeitschr. wiss. Zool., Bd. LV, 1893.  


ch. Fis. I., Lip of the choroid fissure. Di., Lateral wall of the
Parker, G. H., Double Hen's Eggs. American Naturalist, Vol. XL. 1906.  
diencephalon. V, \", Distal and proximal walls of the lens, st.,
Optic stalk.  


Fig. 158. — Section of the distal portion of the eye of a chick,
Pearl, Raymond and Curtis, M. R, 1912, Studies on the Physiology of  


second half of the fifth day of incubation. (After Froriep.)
Reproduction in the Domestic Fowl. V. Data Regarding the Physiology


c. ep. int., Internal epithelium of the cornea. Corn, pr., Cornea
of the Oviduct. Journ. of Exp. Zoology. Vol. 12, pp. 99-132.  
propria. Ect., Ectoderm, ep.. Epidermis. ir.,Iris. mes.. Mesoderm, p., Pigment layer of the optic cup. r., Retinal layer of
Riddle, Oscar, 1911, On the Formation, Significance and Chemistry of the White and Yellow Yolk of Ova. Journ. of Morph., Vol. 22, pp. 455-490.  
the optic cup.  


of the iris is a narrow zone bounding the pupil in which the two
SoNNENBRODT, 1908, Die Wachstunsperiode der Oocyte des Huhns. Arch.
la3'ers of the optic cup become blended so that pigment from
the outer layer invades the inner layer; the epithelia are decidedly


f. mikr. Anat. w. Entw. Bd. 72, pp. 415-480.
Waldeyer, W., Die Geschlechtszellen. Handbuch der vergl. und exper.


Entwickelungslehre der \Yirbeltiere. Bd. I, T. 1, 1901.


ORGANS OF SPECIAL SENSE
===Literature — Chapter II===


Andrews, E. A., Some Intercellular Connections in an Egg of a Fowl. The
Johns Hopkins University Circular. Notes from the Biological Laboratory, March, 1907.


Barfurth, D., Versuche iiber die parthenogenetische Furchung des Hiihnereies. Arch. Entw.-mech., Bd. 2, 1895.


273
Blount, Mary, The Early Development of the Pigeon's Egg with Especial
Reference to the Supernumerary Sperm-nuclei, the Periblast and the
Germ-wall. Biol. Bull., Vol. XIII, 1907.


Duval, M., De la formation du l^lastoderm dans Foeuf d'oiseau. Ann. Sc.
Nat. Zool., Ser. 6, T. XVIII, 1884.


Gasser, E., Der Parablast und der Keimwall der Vogelkeimscheibe. Sitzungsber. der Ges. zur Beford. d. ges. Naturwiss. zu Marburg, 1883.
Eierstocksei und Eileiterei des Vogels. Ibid, 1884.


u.e. /.  
Gotte, a., Beitrage zur Entwickelungsgeschichte der Wirbeltiere, II. Die
Bildung der Keimblatter und des Blutes im Hiihnerei. Archiv. mikr.
Anat., Bd. X, 1874.  


Harper, E. H., The Fertilization and Early Development of the Pigeon's
Egg. Am. Jour. Anat., Vol. Ill, 1904.


KiONKA, H., Die Furchung des Hiihnereies. Anat. Hefte, Bd. Ill, 1894.


C/2.  
Lau, H., Die parthenogenetische Furchung des Hiihnereies. Inaug. Dissert.
Jurjew — Dorpat., 1894.  


cj7.  
Oellacher, J., Untersuchungen iiber die Furchung und Blatterl)ildung im
Hiihnerei. Studien iiber experimentelle Pathologic von Strieker, Bd


I, 1869.
Oellacher, J., Die Veranderungen des unbefruchteten Keimes des Huhnereies
im Eileiter und bei Bebriitungsversuchen. Zeitschr. wiss. Zool., Bd.
XXII, 1872.




irjs
Patterson, J. Thomas, Gastrulation in the Pigeon's Egg; a ^Morphological


and Experimental Study. The Journ. of Morph., Vol. 29, pp. 65-123,


ant. (•/?.  
1909.  
Corri.  
Patterson, J. Thomas, Studies on the Early Dev^elopment of the Hen's


Egg. 1. History of the Early Cleavage and of the Accessory Cleavage.


The Journ. of Morph., Vol. 21, pp. 101-134, 1910.
Rauber, a., Ueber die Stellung des Hiihnchens im Entwicklungsplan.


ITj^
Leipzig, 1876.
Sobotta, J., Die Reifung und Befruchtung des Wirbeltiereies. Ergeb.


Anat. u. Entwickelungsgesch., Bd. V, 1895.


===Literature — Chapter III===


Edwards, C. L., The Physiological Zero and the Index of Development for


^ — op.n .  
the Egg of the Domestic Fowl, Gallus Domesticus. Am. Journ. Physiol.,


Vol. VI, 1902.
Eycleshymer, a. C, Some Observations and Experiments on the Natural


and Artificial Incubation of the Egg of the Common Fowl. Biol. Bull.,


■olf.  
Vol. XII, 1907.
Fere, Cm., Note sur I'influence de la temperature sur I'incubation de I'oeuf


de poule. Journ. de I'anatomie et de la physiologic, Paris, T. XXX,


1894.


/i .m
===Literature — Chapter IV and V===




Assheton, R., An Experimental Examination into the Growth of the Blastoderm of the Chick. Proc. Roy. Soc, London, Vol. LX, 1896.


Fig. 159. — Frontal section of the eye of an eight day chick. Shrinking in
Balfour, F. M. The Development and Growth of the Layers of the Blastoderm. Quar. Jour. Micr. Sc, Vol. XIII, 1873.  
the process of preparation has caused a separation between the retinal and  
pigment layers,
ant. ch., Anterior chamber of the eye. ch., Choroid coat, cil., Ciliary
processes. Corn., Cornea. 1. e. 1., Lower eyelid, n. m., Nictitating membrane, olf., Olfactory sac. op. n., Optic nerve, o. s., Ora serrata. p.,
Pigment layer of the optic cup. post, ch., Posterior chamber of the eye.
ret.. Retina, scl., Sclerotic coat. scl. C, Sclerotic cartilage, u. e. 1., Upper
eyelid.  


thinner than in the ciliary region. The mesenchyme overlying
On the Disappearance of the Primitive Groove in the Embryo Chick.  
the iris early becomes condensed to form the stroma of the iris;
lUd.  
the epithelia form the uvea of the developed iris (Fig. 159).  
The muscles of the iris (sphincter pupillse) are stated by


Balfour, F. M., and Deighton, A Renewed Study of the Germinal Layers
of the Chick. Quar. Jour. Micr. Sc, Vol. XXII, 1882.


DissE, J., Die Entwickelung des mittleren Keimblattes im Hiihnerei. Arch,
mikr. Anat., Bd. XV, 1878.


274
DuRSY, Emil, Der Primitivstreif des Hiihnchens. Lahr, 1866.


Duval, Mathias, Etudes sur la hgne primitive de rembr3'on du poulet.
Ann. Sc. Nat. Zool., Ser. 6, T. VII, 1S7S.


De la formation du blastoderm dans I'oiuf d'oiseau. Ann. Sc. Nat.
Zool., Ser. 6, T. XVIII. Paris, 1884.


THE DEVELOPMENT OF THE CHICK
Evans, Herbert M. On the Development of the Aorta), Cardinal and
UmbiUcal Veins and other Blood-vessels of Vertebrate Embryos from
Capillaries. Anatomical Record., Vol. 3, pp. 498-518, 1909.


Fol, H., Recherches sur le developpement des protovertcbres chez I'embryon
du poulet. Arch. sc. phys. et nat. Geneve, T. II, 1884.


Gasser, Lieber den Primitivstreifen bei Vogelembryonen. Sitz.-Ber. d. Gcs.
z. Beforcl. d. ges. Naturw. z. Marburg, 1877.


Nussbaum, Szily, and Lewis to arise from epithelial buds of the
Der Primitivestreif bei Vogelembryonen (Huhn w. Gans). Schriften
pupillary margin and the adjacent portion of the pigment layer
d. Ges. z. Beford. d. ges. Naturw. z. Marburg, Bd. XI, Suppl. Heft 1,  
of the iris. The marginal buds (Fig. 160) begin to form during
1879.  
the seventh day, the more peripheral ones somewhat later; the
former are less numerous and larger than the latter. The
observations are well supported, and appear to leave no doubt
that the specificity of the ectoderm cells of the iris is not fixed.  
According to Lewis the wandering pigmented cells of the anterior portion, at least, of the choroid also arise from the pigment
layer of the optic cup.  


The ciliary processes begin to form from the ciliary region
of the lenticular zone on the eighth day (Fig. 159) ; the epithelium


^M" Sph.  
Gasser, Beitrage zur Kenntnis der Vogelkeimscheibe. Arch. Anat. u
Sfih. ^-"


Entw., 1882.


Der Parablast unci der Keimwall der Vogelkeimscheibe. Sitz.-Ber.


ES.  
d. Ges. z. Beford. d. ges. Naturw. z. Marburg, 1883.
GoETTE, A., Beitrage zur Entwickelungsgeschichte der Wirbeltiere. II.  


Die Bildung der Keimblatter und des Blutes im Hiihnerei. Arch. mikr.


Anat., Bd. X, 1874.
Hertwig, O., Die Lehre von den Keimblattern. Handbuch der vergl. und


3pM
exper. Entwickehuigslehre der Wirbeltiere. Vol. I. Jena, 1903.
His, W., Der Keimwall des Htihnereies und die Entstehung der para
blastischen Zellen. Arch. Anat. und Entw., Bd. I, 1876.


Neue Untersuchung liber die Bildung des Hiihnerembryo. Arch.


Anat. und Entw., 1877.


Lecithoblast und Angioblast der "Wirbelthiere. Histogenetische


Studien. Abh. der math.-phys. Klasse der Konigl. Sachs. Ges. der


B.  
Wissenschaften, Bd. XXVI. Leipzig, 1900.  


Die Bildung der Somatopleura und der Gefasse beim Hiihnchen.


Anat. Anz., Bd. XXI, 1902.
Hubbard, M. E., Some Experiments on the Order of Succession of the


Fig. 160. — Two sections of the pupillary margin of the eye of a chick of 13
Somites of the Chick. Am. Nat., Vol. 42, pp. 466-471, 1908.  
days' incubation. A., X 260. B., 130. (After Lewis.)
Janosik, J., Beitrag zur Kenntnis des Keimwulstes bei Vogeln. Sitz-Ber
c. P., Ciliary process. E. B., Epithelial bud. P., Margin of pupil, p. 1.,  
Akad. Wiss. Wien, math.-phys. KL, Bd. LXXXIV, 1882.  
Pigment layer of Iris. r. 1., Retinal layer of iris. Sph., Bud for the formation of the sphincter muscle of the iris, derived from the margin. Sph.',  
Roller, C, Beitrage zur Kenntnis des Hiihnerkeimes im Beginne der Be
Sph.", Submarginal buds of the sphincter.  
briitung. Sitzungsber. Wien. Akad. Wiss., math.-nat. KL, 1879.
Untersuchungen liber die Blatterbildung im Hlihnerkeim. Arch.  


becomes thrown into folds projecting towards the posterior chamber, the cavity of the folds being filled by the mesenchyme of the
mikr. Anat., Bd. XX, 1881.
developing choroid coat. The muscles of the ciliary body develop from the mesenchyme of the processes, which acquire a  
V. Kolliker, a., Zur Entwickelung der Keimblatter im Hiihnerei. Verb.  
connection with the lens through a special differentiation of the
vitreous body, the zonula ciliaris (zonula Zinnii).  


In the retinal portion of the optic cup the inner la3^er forms
phys.-med. Ges. Wlirzburg, Bd. VIII, 1875.
the entire retina proper from the internal limiting membrane
KopscH,FR.,Ueber die Bedeutung des Primitivstreifens beim Hiihnerembryo,
to the rods and cones inclusive. The outer layer forms the pig


und liber die ihm homologen Theile bei den Embryonen der niederen


ORGANS OF SPECIAL SENSE 275
Wirbeltiere. Intern. Monatschr. f. Anat. u. Phys., Bd. XIX, 1902.
MiTROPHANOW, P. J., Teratogene Studien. II. Experimentellen Beo
bachtungen liber die erste Anlage der Primitivrinne der Vogel. Arch.


ment layer of the retina. About the middle of the fourth day
Entw.-mech., Bd. VI, 1898.  
pigment begins to develop in the outer layer and extends throughout it, even to the distal portion of the optic-stalk at first (Ucke,  
'91). The histogenesis of the retina of the chick has been described by Weysse (1906).  


2. The Vitreous Humor (Corpus Vitreum). Until comparatively recently embryologists have adhered to the view stated
Beobachtungen liber die erste Entwickelung der Vogel. Anat.  
by Schoeler (1848) and Kolliker (1861) that the vitreous body
arises from mesenchymal cells that enter the e3^eball through
the choroid fissure. The fact that the embryonic vitreous humor
of birds is almost entirely devoid of cells was a serious difficulty.
The cells are in fact so scanty as to be absent in many entire
sections. Moreover, in character they resemble embryonic
blood-cells and not mesenchyme, and disappear entirely by the
eighth day. It seems impossible that they should play any
important part in the origin of the massive vitreous body. Researches of the last few years have demonstrated that the vitreous
body is primarily of ectodermal origin, its fibers arising as processes
of cells of the inner layer of the optic cup and the matrix as
secretion. According to some the cells of the lens are responsible
wholly (Lenhossek) or in part (S/ili) for the fibers; this view,
however, has been strongly combatted (Kolliker and Rabl) and
requires further evidence to substantiate it.  


Both retinal and csecal parts of the cup take part in the formation of the fibers of the vitreous body; the retinal part is at first
Hefte, Bd. XII, 1899.
the most important, and the primary vitreous body is almost
Now^\cK, K., Neue Untersuchungen liber die Bildung der beiden primiiren
entirely retinal in its origin. But after the caecal part is differentiated the activity of the retinal part becomes less, and the
greater part of the fillers of the vitreous body appears to be
formed from cells of the csecal part, that send out branching
and anastomosing processes into the posterior chamber. There
is no sharp boundary between the fibers that form the vitreous
body and those that form the zonula; and the fibers of the latter
may be regarded as homologous to those of the former. The
matrix of the embryonic vitreous body may be regarded as a
secretion of the walls of the optic cup. Later, the secretion
appears to be confined to the ciliary processes. It is possible
that the mesenchyme plays some part in the formation of the
vitreous body after the formation of the pecten begins; but there
is no evidence that it does so at first.


Keimblatter und die Entstehung des Primitivstreifen beim Hiihnerembryo. Inaug. Diss. Berlin, 1902.
Patterson, J. Thos., The Order of Appearance of the Anterior Somites in


the Chick. Biol. Bull., Vol. XIII, 1907.
Patterson, J. T. An experimental Study on the Development of the Vascular


276 THE DEVELOPMENT OF THE CHICK
Area of the Chick Blastoderm. Biol. Bull. XVI, pp. 83-90, 1909.
Peebles, Florence. Some Experiments on the Primitive Streak of the


3. The Lens. The account of the development of the lens is
Chick. Arch. Entw.-mech., Bd. VII, 1898.
mainly after Rabl. The wall of the lens-sac is everywhere a single-layered epithelium, though the nuclei are at different levels in


the cells.
A Prehminary Note on the Position of the Primitive Streak and its


Shortly after the lens-sac has become separated from the ectoderm the proximal wall (that next the cavity of the optic cup)
Relation to the Embryo of the Chick. Biol. Bull., Vol. IV, 1903.  
begins to thicken by elongation of the constituent epithelial cells
(Figs. 157 and 158). During the fourth day the elongation of the
cells increases greatly as the first step in the formation of the lens
fibers, while those of the distal wall remain practically unchanged,
being destined to form the epithelium of the lens. Between the
cells of the proximal and distal walls are found ceUs of an intermediate character, bounding the equator of the lens (Fig. 158).  


During the fifth day the elongation of the cells of the proximal
waU proceeds apace; those in the center of the wall are most
elongated and there is a gradual decrease towards the equator
of the lens. In this way the face of the proximal wall gradually
approaches the distal wall and meets it on the fifth day, thus
obliterating the central part of the lens ca\ity, though the peripheral part remains open for a considerably longer time (Fig. 158).
The nuclei of the lens fibers occupy approximately their center,
and thus form a fairly broad curved band, concave towards the
optic cup. At the same time the lens is increasing very rapidly


in size.


During the sixth, seventh, and eighth days the same processes
Peebles, Florence, The Location of the Chick Embryo upon the Blastoderm. Journ. Exp. Zool., Vol. I, 1904.  
continue and the elongation of the lens fibers makes itself felt
Platt, J. B., Studies on the Primitive Axial Segmentation of the Chick.  
on the inner face of the lens which becomes convex. The form
and arrangement of the parts is shown in Figure 159. The fibers
already present are destined to form only the core of the adult
lens; and a new process begins at this time, leading to the formation of fibers that wrap themselves around this core in a meridional direction and form many concentric layers (666 according
to Rabl). These new concentric fibers proceed from cells situated
between the core fibers and the lens epithelium, that is, around
the equator of the lens. There is a very rapid multiplication of
cells here; those next the core transform into fibers arranged
meridionally on the surface of the core; others develop over these
and thus the original fibers come to be surrounded by more and
more concentric layers. At first these are disposed rather irregularly, but soon the arrangement becomes extraordinarily regular.  


Bull. Mus. Comp. Zool. Harv., Vol. 17, 1889.
Rabl, C, Theorie des Mesoderms. Morph. Jahrb., Bde. XV und XIX,


1889 and 1892.
Rauber, a., Primitivstreifen und Neurula der Wirbelthiere, in normaler


ORGANS OF SPECIAL SENSE
und pathologischer Beziehung. Leipzig, 1877.


Ueber die embryonale Anlage des Hiihnchens. Centralb. d. med.


Wiss., Bd. XII, 1875.


277
Ueber die erste Entwickelung der Vogel und die Bedeutung der Primi
tivrinne. Sitz.-ber. d. naturf. Ges. zu Leipzig, 1876.
Rex, Hugo, Ueber das Mesoderm des Vorderkopfes der Ente. Archiv. mikr. Anat., Bd. L., 1897.




RiiCKERT, J., Entwickelung der extra-embryonalen Gefasse der Vogel. Hand
buch der vergl. w. exp. Entw.-lehre der Wirbelthiere, Bd. I, T. 1,


This process is kept up not only
1906.  
during embryonic life, but during the entire growth of the
fowl; thus the thickness of the
superimposed lamellae is only
0.60 mm. at hatching, but is
2.345 mm. in the adult (Rabl).  


In the fowl the lens includes
Ueber die Abstammung der bluthaltigen Gefassanlagen beim Huhn,  
three concentric layers of fibers:
(1) the central mass or core
formed by the proximal wall of
the original lens-sac; this has
the same diameter (0.80 mm.)
as the entire fiber mass at eight
days. Nuclei are entirely absent. (2) An intermediate layer
of meridional rows of fibers
rather irregularly arranged,  
which shade gradually into the
fibers of the core and into those
of (3) the radial lamellae, which
form the greater part of the
substance of the adult lens.
The meridional rows and the
radial lamellae proceed from the
cells of the intermediate zone
of the original lens-sac. Fig.
161 shows a sector of an equatorial section through the lens
of a chick. The three zones
are well marked; the extraordinary regularity of the superimposed layers of the radial
lamellae is well shown.


The lens epithelium of birds
und uber die Entstehung des Randsinus beim Huhn und bei Torpedo.  
and reptiles also produces a
peculiar structure which may be
called the equatorial ring (Ringwulst, Rabl).  


It will be seen in the figures
Sitzungsber. der Bay. Akad. Wiss., 1903.
ScHAUiNSLAND, H., Bcitrage zur Biologie und Entwickelung der Hatteria


nebst Bemerkungen uber die Entwickelung der Sauropsiden. Anat.


Anz. XV, 1899.
ViALLETOX, Developpement des aortes chez I'embryon de poulet. Journ.


de I'^nat. T. XXVIII, 1892. See also Anat. Anz., Bd. VII, 1892.
ViRCHOW, H., Der Dottersack des Huhns. Internat. Beitrage zur wiss.


Med., Bd. I, 1891.
Waldeyer, W., Bemerkungen uber die Keimblatter und den Primitivstreifen


bei der Entwickelung des Huhnerembryo. Zeitschr. rationeller Medicin,


1869.
Whitman, C. O., A Rare Form of the Blastoderm of the Chick and its Bearing


^
on the Question of the Formation of the Vertebrate Embryo. Quar.


Journ. Micr. Sc, Vol. XXIII, 1883.
WiLLL\MS, Leonard W. The Somites of the Chick. Am. Journ. of Anat.,


Vol. 11, pp. 5.5-100, 1910.


f&^ #'
Literature to Chapter VI included in following chapters.


===Literature — Chapter VII===




Fig. 161. — Equatorial section through
CHARBONNEiy-SALLE ct Phisalix, De I'evolution postembryonnaire du
the lens of a chick embryo of eight
days. The main mass of the entire
lens is represented by irregularly
arranged central fibers. Towards
the surface (above) the fibers are
arranged in rows and are quite
regularly six sided. (After Rabl.)


sac vitellin chez les oiseaux. C. R. Acad. Sc, Paris, 1886.
Dareste, C, Sur I'absence totale de I'amnios dans les embryons de poule.


C. R. Acad. Sc, Paris, T. LXXXVIII, 1879.
Duval, M., Etudes histologiques et morphologiques sur les annexes des


278 THE DEVELOPMENT OF THE CHICK
embryons d'oiseau. Journ. de I'anat, et de la phys., T. XX, 1884.
Etude sur I'origine de Tallantoide chez le poulet. Rev. sc. nat.,


that the epithelium is originally thinnest distally and thickens
Paris, 1877.  
towards the equator. This condition increases up to the eighth
day, at which time the thickening increases more a short distance
from the equator, so that there is a broad ring-shaped thickening
of the anterior epithelium separated by a narrow thinner zone
from the cells of the equatorial zone (cf. Fig. 159). This ring
increases in thickness during the greater part of the period of
incubation, and its cells become fibers arranged in a radial direction. The meaning of this curious structure is somewhat obscure,
but from the fact that it shows on its surface the impression of
the ciliary processes, Rabl w^as of the opinion that it served in
accommodation of the eye as an intermediary between the ciliary
processes and the true lens-fibers.  


4. Anterior Chamber and Cornea, etc. When the optic vesicle
is first formed it is in immediate contact with the ectoderm.
After its invagination the lips of the optic cup withdraw a short
distance from the surface. At the same time the lens invaginates and is cut off from the ectoderm, but rem.ains in contact
with it during the third day. There is thus a ring-shaped space
between the lens and optic cup on the one hand and the ectoderm
on the other, which is the beginning of the anterior chamber of
the eye (cf. Fig. 96 C). With the formation of the cornea the
lens withdraws somewhat from the surface and the space spreads
over the whole external surface of the lens; at first it is very
narrow, but increases in size by the formation of the iris and
the bulging of the cornea.


The cornea itself develops from two sources: (1) the external
Duval, M., Sur ime organe placentoide chez rembryon des oiseaux. C. R.  
epithelium is derived from the ectoderm overlying the anterior
chamber, (2) the cornea propria and the internal epithelium
lining the anterior chamber develop from the surrounding mesenchyme but in somewhat different ways.  


The cornea propria appears on the fourth day as a delicate structureless membrane beneath the corneal epithelium.  
Acad. Sc, Paris, 1884.  
During the fifth day it increases to about the thickness of
Fromann, C, Ueber die Struktur der Dotterhaut des Huhnes. Sitz.-ber.  
the overlying ectoderm (Fig. 158). About this time mesenchyme cells from the margin of the optic cup begin to migrate
between the cornea propria and lens, and soon form a single
complete layer of cells on the inner face of the cornea propria;
this layer becomes the inner epithelium of the cornea (Fig. 158).  
The cornea propria is still devoid of cells, but on the sixth and


Jen. Ges. Medizin u. Naturw., 1879.
FuLLEBORN, F., Beitrage zur Entwickelung der Allantois der Vogel. Diss.,


Berlin, 1894.
Gasser, E., Beitrage zur Entwickelungsgeschichte der Allantois, der Miiller
schen Gange iind des Afters. Frankfurt a. M., 1874.
GoTTE, A., Beitrage zur Entwickelungsgeschichte des Darmkanals im Hiihn
chen. Tubingen, 1867.
HiROTA, S., On the Sero-amniotic Connection and the Foetal Membranes in


ORGANS OF SPECIAL SENSE 279
the Chick. Journ. Coll. Sc. Imp. Univ. Japan, Vol. VI, Part IV, 1^94.
LiLLiE, Frank R., Experimental Studies on the Development of the Organs


seventh days the mesenchyme surroimding the eyeball begins
in the Embryo of the Fowl (Gallus domesticus): 1. Experiments on the  
to penetrate it from all sides in the form of a compact wedge,
which, advancing in the substance of the cornea propria, soon
meets in the center. These cells form the so-called corpuscles
of the cornea. They appear arranged in strata from a very
early period.


The anterior chamber is bounded by the cornea externally;
Amnion and the Production of Anamniote Embryos of the Chick. Biol.  
its margins, which are at first coincident with the lips of the optic
cup, soon extend peripherally over the iris (Fig. 159). The inner
epithelium ceases at the margin of the cavity or is continuous
with the cells of the sclerotic; it does not appear, in an eight-day
chick at any rate, to be reflected over the iris, but the epithelium
of this structure next the anterior chamber appears to be simply
a special differentiation of its own superficial cells. The anterior
chamber is closed centrally by the lens, but communicates more
or less for a considerable period around its margin with the posterior chamber. This is at least the appearance in good sections;
it seems probable, though, that in life there is contact between
the optic cup and lens.  


The stroma of the iris proceeds from that portion of the
Bull., Vol. V, 1903. 2. The Development of Defective Embryos and
mesenchyme left in association with the pars iridis retinae after
the peripheral extension of the anterior chamber. It becomes
very vascular at an early stage. The canal of Schlemm arises
as a series of vacuoles just peripheral to the margin of the anterior chamber about the eighth day. These soon run together
to form a ring, which is separated from the anterior chamber
by the ligamentum pectinatum iridis.


5. The choroid and sclerotic coats are differentiations of the
the Power of Regeneration. Biol. Bull., Vol. VII, 1904.
mesenchyme surrounding the optic cup. But little is known
Mertens, H., Beitrage zur Kenntniss der Fotushiillen im Vogelei. Meckels
concerning the details of their development in the chick. A
figure of Kessler's shows chromatophores developed in the choroid
coat at twelve days; I find a very few already formed at eight
days. Cartilage begins to appear in the sclerotic at eight days,  
the forerunner of the sclerotic ossicles (Fig. 159).  


6. The Eyelids and Conjunctival Sac. The integument over
Archiv, 1830.  
the embrvonic eveball remains unmodified until about the
Mitrophanow, p. J., Note sur la structure et la formation de I'enveloppe
seventh day. At this time a circular fold of the integument
forms around the eyeball with the pupil as its center. At the
same time a semi-lunar fold develops within the first on the side
of the eyeball next the beak. (See Figs. 122-124.) From the


du jaune de I'ceuf de la poule. Bibliogr. Anat., Paris, 1898.
PopoFF, Demetrius, Die Dottersackgefasse des Huhnes. Wiesbaden, 1894.
Pott, R., and Preyer, W., Ueber denGaswechsel und die chemischen Verander
ungen des Hiihnereies wahrend der Bebriitung. Archiv. ges. Phys., 1882.
Preyer, W., Specielle Physiologic des Embryo. Leipzig, 1885.
Ravn, E., Ueber die mesodermfreie Stelle in der Keimscheibe des Huhner
embryo. Arch. Anat. u. Entw., 1886.


Ueber den Allantoisstiel des Hiihnerembryo. Verh. Anat. Ges., 1898.
ScHAUiNSLAND, H., Die Entwickelung der Eihaute der Reptilien und der


280 THE DEVELOPMENT OF THE CHICK
Vogel. Handbuch der vergl. und exp. Entw.-lehre der Wirbeltiere. Bd.


first fold the upper and lower eyelids are developed, and from the
I, T. 2, 1902.  
second the third eyelid or nictitating membrane. The area bounded
by the outer ring-shaped fold becomes the conjunctival sac.  


From their place of origin the free edges of these folds then
Beitrage zur Entwickelungsgeschichte der Wirbeltiere. II. Beitrage zur
grow towards the center, and thus a cavity, the conjunctival
sac, is formed between the folds and the integument over the eyeball (conjunctiva sclerse). The outer fold grows more rapidly
above and below than at the sides and the opening narrows,
becoming, therefore, gradually elhptical and finally somewhat
spindle-shaped. Thus the upper and lower eyelids are established.
The semi-lunar fold of the embryonic nictitating membrane also
grows towards the pupil, most rapidly in its center. The conjunctival sac also expands peripherally, especially at the inner
angle of the eye, and thus accommodates itself to the increasing
size of the eyeball (Fig. 159).  


The Harderian gland is visible on the eighth day as a solid
Entwickelungsgeschichte der Eihaute der Sauropsiden. Bibliotheca
ingrowth of ectodermal cells of the conjunctival sac at the innermost angle of the nictitating membrane.  


Feather germs develop on the outer surface of both upper
Zoologica, 1903.
and lower lids especially at their edges. The ectoderm covering
Schenk, S. L., Beitrage zur Lehre vom Amnion. Archiv. mikr. Anat., Bd.  
the inner faces of the upper and lower lids, both faces of the nictitating membrane and the remainder of the conjunctival sac
becomes modified into a moist mucous membrane. Over the
cornea the ectoderm is especially modified as already noted.  


Papillce Conjunctiva Sclerce. On the seventh day of incubation
VII, 1871.  
papillae begin to appear on the surface of the conjunctiva sclerse
and soon form a ring surrounding the iris at some distance peripheral to its margin (Figs. 122, 123 and 124). The number of these
papillae appears to be quite constantly fourteen. They are at first
fully exposed owing to the undeveloped condition of the eyelids,
but the latter overgrow them about the eleventh or twelfth days.
Degeneration of the papillae begins about this time, and on the
thirteenth day they have entirely disappeared. In section they
are found to be thickenings of the ectoderm, produced by multiplication of the cells. They may rise above the surface; but more
frequently project inwards towards the connective tissue. There
is apparently no accompanying hypertrophy of the latter. Thus
they differ quite essentially from feather germs with which it
seems natural to compare them; and their significance is entirely
problematical (see Xussbaum).  


Ueber die Aufnahme des Nahrungsdotters wahrend des Embryonal
lebens. Sitz.-ber. Akad. Wiss. Wien, math.-nat. Kl., 1897.
Shore, T. W., and Pickering, J. W., The Proamnion and Amnion in the


Chick. Journ. of Anat. and Phys., Vol. XXIV, 1889.
Soboleff, Die Verletzung des Amnions wahrend der Bebriitung. Mittheil,


ORGANS OF SPECIAL SENSE 281
embryolog. Inst., Wien, 1883.
Strahl, H., Eihaute und Placenta der Sauropsiden. Ergeb. Anat. u. Entw.
gesch., Bd. I, 1891.
Stuart, T. P. A., A Mode of Demonstrating the Developing Membranes in


7. Choroid Fissure, Pecten, and Optic Nerve. The pecten of
the Chick. Journ. Anat. and Phys., London, Vol. XXV, 1899.  
the hen's eye is a pigmented vascular plate inserted in the depression occupying the center of the elongated blind spot, or entrance
ViRCHOW, H., Beobachtungen am Hiihnerei; iiber das dritte Keimblatt
of the optic nerve, which extends meridionally from the fundus
nearly to the ora serrata. The pecten projects a considerable
distance into the posterior chamber and its free edge is much
longer than its base, being consequently folded like a fan; hence
the name. The optic nerve runs along the base of the pecten,  
its fibers passing off on either side into the retina; thus it continually diminishes in size until it disappears. The pecten is
consequently separated from the choroid coat by the optic nerve.
It is supposed to function as a nutrient organ for the layers of
the retina, by means of lymph channels that pass off from its
base into the retina. There is no arteria centralis retinae in the


bird's eye.  
im Bereiche des Dottersackes. Virchow's Arch., Bd. LXII, 1874.  


These structures develop in connection with the choroid
fissure as follows: On the fourth day the choroid fissure has become a very narrow slit, and by the middle of the day its edges
are in apposition in the pars cceca of the bulbus. Proximally,
however, the meeting of the lips of the fissure is prevented by the
mesoblast, in which the basal blood-vessel runs along the entire
length of the open portion of the fissure. During the fourth
day this blood-vessel enters the posterior chamber Avith its enveloping mesenchyme along the entire length of the open portion
of the choroid fissure, and forms a low mesenchymal ridge connected by a narrow neck of mesenchyme in the fissure with the
mesenchyme outside. During the fifth day the ridge becomes
higher and keel-shaped, and a thickening appears along part of
its free edge above the blood-vessel. During this day also fusion
of the lips of the choroid fissure has taken place in the pars caeca.
At the same time an important change begins in the proximal
portion of the choroid fissure that leads to the formation of the
pecten proper. This is an involution of the lips of the optic cup
bounding the choroid fissure on each side of the mesodermal
keel, and their continuous ingrowth until they meet over the
keel and fuse above it in a mass in which the outer and inner
layers of the retina are indistinguishably fused. Thus the proximal portion of the mesodermal keel is enclosed in a kind of tunnel
composed of the involuted edges of the optic cup. The formation of this tunnel progresses gradually from the fundus towards


ViRCHOW, H., Ueber das Epithel des Dottersackes im Hiihnerei. Diss., Berlin.
1875.


Der Dottersack des Huhnes. Internat. Beitrage zur wissenschaft.
Medizin, Bd. I, 1891.


282
Das Dotterorgan der Wirbeltiere. Zeitschr. wiss. Zool., Bd. LIII,
Suppl., 1892.


Das Dotterorgan der Wirbelthiere. Arch. mikr. Anat., Bd. XL, 1892.
Dottersyncytium, Keimhautrand und Beziehungen zur Koncrescenzlehre. Ergeb. Anat. u. Entw., Bd. VI, 1897.


Ueber Entwickelungsvorgange, welche sich in den letzten Bruttagen
am Hiihnerei abspielen. Anat. Anz., Bd. IV, BerHn, 1889.
VuLPiAX, La physiologie de I'amnios et de I'allantoide chez les oiseaux.


THE DEVELOPMENT OF THE CHICK
Mem. soc. biol., Paris, 1858.
Weldox, W. F. R., Prof, de Vries on the Origin of Species. (Includes experiments on amnion.) Biometrica, Vol. I, 1902.


===Literature — Chapter VIII===


Beard, J., Morphological Studies, II. The Development of the Peripheral


the ora serrata by the same process of involution, until on the
Nervous System of Vertebrates. Pt. I. Elasmobranchs and Aves.  
eighth day the mesodermal keel is completely covered up.  


Fig. 162 gives a diagrammatic view of the condition of the
Quar. Journ. Micr. Sc, Vol. XXIX, 1888.  
pecten in the middle of the seventh day of incubation. Figs.  
Beraneck, E., Etudes sur les replis medullaires du poulet. Recueil Zool.  
163 and 164 show sections through this at the points a, h, c, d, e,
indicated in the figure. The formation of the tunnel will be
readily understood by study of the figures. It will be seen that
the major portion of the embryonic pecten is of ectodermal origin,  
and that the mesoderm forms a relatively inconspicuous part
of it. Later, on the same day, it becomes increasingly difficult


Suisse, Vol. IV, 1887.
Bethe, Albrecht, Allgemeine Anatomic und Physiologie des Nervensys
tems. Leipzig, 1903.
Brandis, F., Untersuchungen iiber das Gehirn der Vogel. Arch. mikr.


Anat., Bd. XLI, 1893; Bd. XLIII, 1894; Bd. XLIV, 1895.
Burrows, Montrose T., The Growth of Tissues of the Chick Embryo


CAfi^^
Outside the Animal Body, with Special Reference to the Nervous System.


Journ. Exp. Zoology, Vol. 10, pp. 63-83, 1911.
Cajal, S. R. y., Sur I'origine et les ramifications des fibres nerveuses de la


P.  
moelle embryonnaire. Anat. Anz., Bd. V, 1890.  


A quelle epoque aparaissent les expansions des cellules nerveuses de


la moelle epiniere du poulet. Anat. Anz., Bd. V, 1890.
Froriep, a., Ueber Anlagen von Sinnesorganen am Facialis, Glossopha
ryngeus und Vagus, iiber die genetische Stellung des Vagus zum Hypo
glossus, und iiber die Herkunft der Zungenmuskulatur. Arch. Anat.


u. Entw., 1885.
Carpenter, Frederick Walton, The Development of the Oculomotor Nerve,


the Ciliary Ganglion, and the Abducent Nerve in the Chick. Bull.


Mus. Comp. Zool. Harv. Vol. XLVIII, 1906.
DissE, J., Die erste Entwickelung des Riechnerven. Anat. Hefte, Abth. I,


i PB.  
Bd. IX, 1897.
GoLoviNE, E., Sur le developpement du systeme ganglionnaire chez le poulet.  


Anat. Anz., Bd. V, 1890.
GoRONOwiTscH, N., Die axiale und die laterale (A. Goette) Kopfmetamerie


der Vogeleml^ryonen. Anat. Anz., Bd. VII, 1892.


H^
L'ntersuchungen iiber die Entwickelung der Sogenannten " Ganglien
leisten " im Kopfe der Vogelembryonen. Morph. Jahrb., Bd. XX, 1893.






Heinrich, Georg, Untersuchungen iiber die Anlage des Grosshirns beim
Hiihnchen. Sitz.-ber. d. Ges. f. Morph. u. Phys. in Munchen, Bd. XII,


Fig. 162. — Diagrammatic reconstruction of the pecten of the  
1897.  
eye of a chick embryo of 1\ days' incubation. (After Bernd.)
Hill, Charles, Developmental History of the Primary Segments of the  


Ch. fis. 1., Lip of the choroid fissure. Ch. fiss., Choroid fissure. Mes., Mesoblast. Mes. b., Boundary of the mesoblast
Vertebrate Head. Zool. Jahrbucher, Abth. Anat. Bd. XIII, 1900.  
within the choroid fissure. Mes. K., Thickening of the mesoblastic keel. op. C, Optic cup. O. St., Optic stalk. P., Pecten. P. B., Base of the pecten.  
His, W., Die Neuroblasten und deren Entstehung im embryonalen Mark.  


The arrow indicates the direction of growth of the ectodermal tunnel.  
Abh. math.-physik. Klasse, Konigl. Sachs. Ges. Wiss., Bd. XV, 1889.
Histogenese und Zusammenhang der Nervenelemente. Arch. Anat.
u. Entw., Suppl., 1890.
Ueber das frontale Ende des Gehirnrohres. Arch. Anat. u. Entw., 1893.
Ueber das frontale Ende und iiber die natiirliche Eintheilung des
Gehirnrohres. Verh. anat. Ges., Bd. VII, 1893.
His, W. (Jr.)» Ueber die Entwickelung des Bauchsympathicus beim Hiihnchen und Menschen. Arch. Anat. u. Entw., Suppl., 1897.
V. KoLLiKER, Ueber die erste Entwickelung der Nervi olfactorii. Sitz.-ber.  


The lines a, b, c, d, e show the planes of the sections reproduced in Fig. 163 (a, b, c, e) and in Fig. 164 (d).  
phys. med. Ges. zu Wiirzburg, 1890.
V. KuPFFER, K., Die Morphogenie des Centralnervensystems. Handbuch der


to distinguish ectodermal and mesodermal portions of the pecten,  
vergl. und exp. Entwickelungslehre der Wirbeltiere, Kap. VIII, IP, 1905.
and thereafter it is quite impossible to say which parts of it are
Lewis, M. R. and Lewis, W. H., The Cultivation of Tissues from Chick
of ectodermal and which are of mesodermal origin. During the
eighth and ninth days the pecten increases greatly in height,  
and becomes relatively very much narrower.  


The folds of the pecten now begin to develop and, b}^ the
Embroyos in Solutions of NaCl, CaCl2, KCl and NaHCOg. Anatomical
seventeenth day their number is 17-18, the same as in the adult.
The pigment does not begin to appear until about the twelfth day.
The details of the development of the blood-vessels are not known.  


Record, Vol. 5, pp. 277-293. See also Anat. Rec, Vol. 6, nos. 1 and 5, 1911.
Marshall, A. M., The Development of the Cranial Nerves in the Chick.


Quar. Journ. Micr. Sc, Vol. XVIII, 1878.


ORGANS OF SPECIAL SENSE
The Segmental Value of the Cranial Nerves. Journ. Anat. and Physiol.,


Vol. XVI, 1882.
v. MiHALCOVics, v., Entwickelungsgeschichte des Gehirns. Leipzig, 1877.
Onodi, a. D., Ueber die Entwickelung des sympathischen Nervensy stems.


Arch. mikr. Anat., Bd. XXVI, 1886.
Rabl, C, Ueber die IMetamerie des Wirbelthierkopfes. Verh. anat. Ges.,


283
VI, 1892.
RuBASCHKiN, W., Ueber die Beziehungen des Nervus trigeminus zur Riech
schleimhaut. Anat. Anz., Bd. XXII, 1903.
Weber, A., Contribution a Tetude de la metamerism du cerveau anterieur


chez quelques oiseaux. Arch, d'anat. microsc, Paris, T. Ill, 1900.
Van Wijhe, J. W., L^eber Somiten und Nerven im Kopfe von Vogel- und


Reptilien-embryonen. Zool. Anz. Bd. IX, 1886.


The Optic Nerve. Owing to the relations established by the
Ueber die Kopfsegmente und das Geruchsorgan der Wirbelthiere
choroid fissure, the floor of the optic stalk is continuous from the
first with the inner layer of the retina (Fig. 96 B), and it furnishes
the path along which the optic nerve grows. The axones of the
optic nerve originate, for the most part, from the retinal neuroblasts, composing the layer next to the cavity of the optic cup,
and their growth is thus centripetal. They are first formed in
the fundus part of the retina, and grow in the direction of the


Zool. Anz., Bd. IX, 1886.


===Literature — Chapter IX===


Organs of Special Sense


Mes ft
A. The Eye


Addario, C, Sulla struttura del vitreo embryonale e de' neonati, sulla matrice del vitreo e suU' origine della zonula. Ann. OttalmoL, Anno 30,
1901-1902.




AddariOjC, Ueber die Matrix desGlaskorpers im menschlichen und thierischen


Auge. Vorlauf. Mitth. Anat. Anz., Bd. XXI, 19(32.
Agababow, Untersuchiingen iiber die Natur der Zonula ciliaris. Arch.


mikr. Anat., Bd. L, 1897.
Angelucci, a., Ueber Entwiekelung und Bau des vorderen Uvealtractus der


Fig. 163. — Outlines of sections in the planes a, b, c, e, of
Vertebraten. Arch. mikr. Anat., Bd. XIX, 1881.
Arnold, J., Beitrage zur Entwickekmgsgeschichte des Auges. Heidelberg,  


Fig. 163. (After Bernd.)
1874.  
AssHETON, R., On the Development of the Optic Nerve of Vertebrates, and


bl. v., Blood vessel, i. 1., Inner or retinal layer of the
the Choroidal Fissure of Embryonic Life. Quar. Journ. Micr. Sc, Vol.  
optic cup. o. 1., Outer or pigment layer of the optic cup.  
P. inv., Angle of invagination of the pecten. Other abbreviations as before. (Fig. 162.)


XXXIV, 1892.
Bernd, Adolph Hugo, Die Entwiekelung des Pecten im Auge des Hiihn
chens aus den Blattern der Augenblase. Bonn, 1905.
Cajal, S. R. y., Sur la morphologie et les connexions des elements de la retine


des oiseaux. Anat. Anz. Bd. IV, 1889.


optic stalk between the internal limiting membrane and the neuroblast layer (ganglion cell layer), thus forming a superficial layer
Sur la fine structure du lobe optique des oiseaux et sur I'origine reelle
of axones; their formation begins on the fourth day, and there is
a period about the end of this day when axones are found in the
distal part of the optic stalk, next to the bulbus oculi, but not
in the proximal part, next to the brain. This observation affords
conclusive proof of the retinal origin of the fibers of the optic


des nerfs optiques. Int. Monatschr. Anat. u. Phys., Bd. VIII, 1891.
Cirincione, G., Ueber die Entwiekelung der Capsula perilenticularis. Arch.


Anat. u. Entw., Suppl. Bd., Jahrg. 1897.


284
Zur Entwiekelung des Wirbeltierauges. Ueber die Entwiekelung


des Capsula perilenticularis. Leipzig, 1898.


Ueber die Genese des Glaskorpers bei Wirbelthieren. Verh. Anat.


THE DEVELOPMENT OF THE CHICK
Ges., 17. Versamml. in Heidelberg, 1903.
Collin, R., Recherches sur le developpement du muscle sphincter de I'iris


chez les oiseaux. Bibliog. Anat., T. XII, fasc. V. Paris, 1903.
Froriep, a., Ueber die Entwiekelung des Sehnerven. Anat. Anz., Bd. VI,


1891.


nerve; moreover, at an early stage of their differentiation it is
Die Entwiekelung des Auges der Wirbeltiere. Handb. der vergl. u.  
possible to trace their connection with retinal neuroblasts.  


The first fibers of the optic nerve are formed, as already
exp. Entw.-l. der Wirbeltiere, Bd. II, 1905.
stated, from the fundus part of the retina; the fibers, therefore,  
HuscHKE, E., Lieber die erste Entwiekelung des Auges und die damit zusam
pass directly to the floor of the optic stalk; but on the fifth day
menhangende Cyklopie. Meckel's Arch., 1832.
the formation of fibers begins from more distal portions of the
Kessler, L., Untersuchungen liber die Entwiekelung des Auges, angestellt
retina and these do not grow towards the insertion of the optic
stalk, l3ut towards the choroid fissure; arrived there, they bend
centrally and run in a bundle on each side along the floor of the
bulbus oculi to the optic stalk, where they join with the fibers first
formed. The later formed fibers pass to still more distal portions


am Hiihnchen und Tauben. Dissertation. Dorpat, 1871.


Die Entwiekelung des Auges der Wirbelthiere. Leipzig, 1877.
V. Kolliker, a., LTeber die Entwiekelung und Bedeutung des Glaskorpers.


Verh. anat. Ges., 17. Vers. Heidelberg, 1903.


■ Mes/I
Die Entwiekelung und Bedeutung des Glaskorpers. Zeitschr. wiss.


Zool., Bd. LXXVII, 1904.
V. Lenhossek, M., Die Entwiekelung des Glaskorpers. Leipzig, 1903.
Lewis, W. H., Wandering Pigmented Cells Arising from the Epithelium of


the Optic Cup, with Observations on the Origin of the M. Sphincter


P.,  
Pupillffi in the Chick. Am. Journ. Anat., Vol. II, 1903.
LocY, W. A., Contribution to the Structure and Development of the Vertebrate Head. Journ. Morph., Vol. XI. Boston, 1895.


Accessory Optic Vesicles in the Chick Embryo. Anat. Anz., Bd. XIV,


1897.
NussBAUM, M., Zur Riickbildung embryonaler Anlagen. (Corneal papillae


of chick embryos.) Archiv. mikr. Anat., Bd. LVII, 1901.






NussBAUM, M., Die Pars ciliaris retinae des Vogelauges. Arch. mikr. Anat., Bd.


LVII, 1901.


Die Entwiekelung der Binnenmuskeln des Aiiges der Wirbeltiere.


Arch. mikr. Anat., Bd. LVIII, 1901.
Rabl, C, Ziir Frage nach der Entwickehmg des Glaskorpers. Anat. Anz.,


t-«*''f;
Bd. XXII, 1903.


Ueber den Ban und die Entwickehmg der Linse. II. Reptihen imd


Vogel. Zeitschr. wiss. Zool., Bd. LXV, 1899.
Robinson, A., On the Formation and Structure of the Optic Nerve, and its


«^:Mfe^2^
Relation to the Optic Stalk. Journ. Anat. and Phys. London, 1896.
SziLi, A.V. Beitrag zur Kenntniss der Anatomic und Entwickelungsgeschichte


der hinteren Irisschichten, etc. Arch. Opthalm., Bd. LIII, 1902.


Zur Anatomic und Entwickelungsgeschichte der hinteren Irisschichten, etc. Anat. Anz., Bd. XX, 1901.


Zur Glaskorperfrage. Anat. Anz. Bd. XXIV, 1904.
ToRNATOLA, Origiuc et nature du corps vitre. Rev. gener. d 'opthalm. Annee


14, 1897.
UcKE, A., Epithelreste am Opticus und auf der Retina. Arch. mikr. Anat.,


Bd. XXXVIII, 1891.


Zur Entw^ickelung des Pigmentepithels der Retina. Diss, aus Dorpat.


Fig. 164. — Section in the plane of d of Fig. 162, to
Petersburg, 1 89 1 .  
show the histological structure. (After Bernd.)
ViRCHOW, H., Facher, Zapfen, Leiste, Polster, Gefasse im Glaskorperraum
Abbreviations as before.  


von Wirbelthieren, sowie damit in Verbindung stehenden Fragen. Er
gebn. Anat. u. Entw., Bd. X. Berlin, 1900.
Weysse, a. W., and Burgess, W. S., Histogenesis of the Retina. Am.


Naturalist, Vol. XL, 1906.


of the choroid fissure, and, as the pecten forms in the manner
already described, the fibers of the optic nerve all unite beneath
it on their way to the original optic stalk. Thus, the optic nerve
obtains an insertion coincident in length with the base of the
pecten, and its fibers, radiating off into the retina on each side
of the pecten, separate the latter completely from the choroid
coat of the eyeball.


The optic stalk is at first a tubular communication between
the optic vesicle and the fore-brain, and its walls are an epithelial
layer of the same thickness throughout. The fibers of the optic


B. The Nose


Born, G., Die Nasenhohlen und der Thranennasengang der amnioten Wir
belthiere II. Morph. Jahrb., Bd. V, 1879; Bd. VIII, 1883.
CoHN, Franz, Zur Entwickelungsgeschichte des Geruchsorgans des Hiihn
chens. Arch. mikr. Anat., Bd. LXI, 1903.
Dieulafe, Leon, Les fosses nasales des vertebres (morphologic et embry
ologie). Journ. de I'anat. et de la phys., T. 40 and 41, 1904 and 1905.


ORGANS OF SPECIAL SENSE 285
(Translated by Hanau W. Loeb: Ann. of Otol., Rhin. and Laryng., Mar.,


nerve grow into its ventral wall exclusively, between its epithelial
June and Sept., 1900.)
cells, which gradually become disarranged and irregular. Thus
Disse, J., Die erste Entwiekelung des Riechnerven. Anat. Hefte, Bd. IX,  
the ventral wall becomes increasingly thick and the lumen excentric. By the sixth day the lumen appears in cross-section as a
narrow lenticular space with an epithelial roof, above the large
optic nerve. Soon after, the lumen disappears entirely; no trace
of its former existence is to be found on the eighth day.


II. The Development of the Olfactory Organ  
1897.  
Ganin, M., Einige Thatsachen zur Frage iiber das Jacobsohn'sche Organ der


The origin of the olfactory pit, external and internal nares, and
Vogel. Arb. d. naturf. Ges. Charkoff, 1890 (russisch). Abstr. Zool.  
olfactory nerve, has already been considered (pp. 169, 215, and 263).  
Before the formation of the internal and external nares, not only
has the entire olfactory epithelium become invaginated, but, owing
to the elevation of internal and external nasal processes, the pit
has become so deepened that the margin of the olfactory epithelium proper now lies a considerable distance within the cavity.
That part of the nasal cavity thus lined with indifferent epithelium
is known as the olfactory vestibule. After the fusion of the
internal nasal process with the external nasal and maxillary
processes, the cavity deepens still more.  


The choanse lie at first just within the oral cavity, but the
Anz., 1890.
palatine processes of the maxillary process, growing inwards
V. KoLLiKER, A., Ueber die Entwickehmg der Geruchsorgane beim Menschen
across the primitive oral cavity (pp. 298, 299), unite on the sixth
or seventh day at their anterior ends with the internal nasal
processes, and thus cut off an upper division of the primitive
oral cavity at its anterior end from the remainder; in this way
the internal openings of the nasal cavities into the oral cavity
are carried back of the primitive choanae; they are henceforward
known as the secondary choanse. Further growth of the palatine
processes brings them nearly together in the middle line along
the remainder of their length, about the eleventh day; but fusion
does not take place, the birds possessing a split palate. Thus
the superior division of the primitive oral cavity is added to the
respiratory part of the nasal passages.


The nasal cavity is further elaborated between the fourth
und Hiihnchen. Wiirzburger med. Zeitschr., Bd. I, 1860.
and eighth days by ingrowths from the lateral wall (turljinals)
V. MiHALKOvics, v., Nasenhohle und Jacobson'sche Organ. Anat. Hefte,
and by the formation of the supraorbital sinus as an evagination
that grows outwards above the orbit. Three turbinals are formed
in the nasal cavities, viz., the superior, middle, and inferior turbinals. These arise as folds of the lateral wall projecting into


I. Abth., Bd. XI, 1898.
Peter, Karl, Entwickehmg des Geruchsorgans und Jakobson'sche Organs


in der Reihe der Wirbeltiere. Bildung der ausseren Nase und des


286 THE DEVELOPMENT OF THE CHICK


the lumen, the superior and middle from the olfactory division
Gaumens. Handbuch der vergl, und experiment. Entwickelimgslehre
proper, and the inferior from the vestibulum; on the middle
turbinal, however, the sensory epithelium gradually flattens out
to the indifferent type. The middle turbinal appears first in
the ventral part of the olfactory division, about the beginning
of the fifth day, and the superior somewhat later, immediately
above the former, the two being separated by a deep groove
(Fig. 165). The vestibular turbinal arises still later, and is well
formed on the eighth day.  


Fig. 166 shows a reconstruction of the nasal cavity, seen from
der Wirbeltiere. IP, 1902.  
the lateral side, of an embryo of about seven days. It is a reconstruction of the epithelium, and thus practically a mold of the
Preobraschensky, L., Beitrage zur Lehre liber die Entwiekelung des Ge
cavity; therefore projections into the cavity appear as depressions
ruchsorganes des Huhnes. Mitth. embryol. Inst. Wien, 1892.
in the model, and the grooves and outgrowths of the external
PuTELLi, F., Ueber das Verhalten der Zellen der Riechschleimhaut bei
wall as projections. The superior turbinal has an oval shape with
the long axis in an apical direction; it is bounded by a fairly deep
depression, the elevated margin of the model, from the lower end
of which the supra-orbital sinus (S. s'o.) passes off ventrally and
externally. The deep depression immediately below the superior
turbinal lodges the median turbinal. A fairly long passage leads
off from its neighborhood to the choanse and a shorter one, the
vestibulum, to the external nares. The depression in the wall of
the vestibulum is caused by the vestibular or inferior turbinal.
The palatine and maxillary sinuses are not yet formed.  


The external nares are closed during the greater part of the
Hiihnerembryonen friiher Stadien. Mitth. embr. Inst. Wien, 1889.  
period of incubation by apposition of their walls. The form
and dimensions of the nasal cavities change greatly during incubation, owing to shifting in the original positions of the turbinals,
outgrowth of the facial region, and development of sinuses. The
details are not very well investigated, and an examination of
them would lead too far.  


There has been a good deal of discussion as to the existence
C. The Ear
of an organ of Jacobson in the nose of birds; it has usually been
assumed that it is entirely absent even in the embryo. Others
have identified the ducts of nasal glands as a modification of this
organ. Recently, however, Cohn has described a slight evagination in the median wall of the primary olfactory pit, that
agrees precisely in its form and relationship with the first rudiment of the organ of Jacobson in reptiles. Although it persists
only from the stage of about 5.3 mm. to about the stage of


Hasse, C, Beitrage zur Entwiekelung der Gewebe der hautigen Vogel
schnecke. Zeitschr. wiss. Zool., Bd. XVII, 1867.
HuscHKE, Ueber die erste Bildungsgeschichte des Auges und Ohres beim


bebriiteten Hiihnchen. Isis von Oken, 1831.
Kastschenko, N., Das Schlundspaltengebiet des Hiihnchens. Arch. Anat.


ORGANS OF SPECIAL SENSE
u. Entw., 1887.
Keibel, Ueber die erste Bildung des Labyrinthanhanges. Anat. Anz., Bd.


XVI, 1899.
Krause, R., Die Entwickekmg des Aquaeductus Vestibuh, s. Ductus endo
lymphaticus. Anat. Anz., Bd. XIX, 1901.


Die Entwickekmgsgeschichte des hautigen Bogenganges. Arch. mikr.


287
Anat., Bd. XXXV, 1890.
MoLDENHAUER, W., Die Entwickcking des mittleren und des ausseren Ohres.


Morph. Jahrb., Bd. Ill, 1877.
PoLi, C, Sviluppo della vesicula auditiva; studio morphologico. Genoa,


1896.


5.9 mm. head-length, he identifies it positively as a rudimentary
Zur Entwickekmg der Gehorblase bei den WirbeUieren. Arch. mikr.  
organ of Jacobson.  


The septal gland arises on the eighth day from the inner
Anat., Bd. XLVIII, 1897.
wall of the vestibulum, opposite the base of the vestibular tur
Retzius, G., Das Gehororgan der Wirbelthiere. II. Theil, Reptihen Vogel,  


Sanger. Stockhokn. 1881-1884.
RoTHiG, p., und Brugsch, Theodor, Die Entwickekmg des Labyrintkes


beim Huhn. Archiv. mikr. Anat., Bd. LIX, 1902.
RtJDiNGER, Zur Entwickekmg des hautigen Bogenganges des inneren Ohres.


FiG. 165. — Transverse section of the olfactory organ of a
Sitzungsber. Akad. Miinchen, 1888.  
chick embryo, of 7.5 mm. head length. (After Cohn.)
f., Line of fusion, e. n., External nasal process, i. n.,
Internal nasal process. T. 1, T. 2, Intermediate and superior turbinals.
 
binal, as a solid cord of cells. This grows backwards in the nasal
septum and passes to the outer side and branches, subsequentlyj
acquiring a lumen.
 
 
 
288
 
 
 
THE DEVELOPMENT OF THE CHICK
 
 
 
III. The Developmext of the Ear
 
The ear develops from two entirely different primary sources,
viz., the otocyst,and the first visceral or hyomandibular cleft : The
former furnishes the epithelium of the membranous lab^-rinth; the
entodermal pouch of the latter becomes the tympano-eustachian
cavity; and part of the external furrow forms the external auditory meatus; the tissue between the internal pouch and the external furrow develops into the tympanum. The mesenchyme in
the neighborhood of each of these primordia becomes modified,
 
 
 
 
 
 
 
S.3h.
 
 
^..x*""^
 
 
 
 
T.2
 
 
r.].
 
 
^ ^
 
 
 
 
W^4^m
 
 
 
 
/^
 
 
^
 
 
flM
 
 
 
 
r^
 
 
 
 
y
 
 
ch.
 
 
^^Hi
 
 
R
 
 
M
 
 
,/^
 
 
 
 
 
 
\^^^^ ■III MHiOF* '
 
 
 
 
W^P
 
i
 
 
 
 
\
 
 
T3.
 
 
 
i- • \'
 
\
 
 
 
 
1
 
 
^mF
 
 
 
 
 
 
 
 
...^
 
 
^\
 
 
^WPCTf^^iifif •h'liT'iit'vif
 
 
 
elN.
 
 
^H'
 
^
 
 
 
 
/
 
 
 
Fig. 166. — Reconstruction of the nasal cavity of a chick
 
embryo of about 7 days; lateral view. (After Cohn.)
 
Ch., Choanal, e. N., External nares. S. s'o., Supraorbital sinus. T. 1, T. 2, T. 3, Intermediate, superior and inferior (vestibular) turbinals.
 
(1) to form the bony labyrinth, perilymph, and other mesenchymal
parts of the internal ear, and (2) to form the auditory ossicles of
the middle ear. Thus the ear furnishes a striking example of the
combination of originally diverse components in the formation
of a single organ. The course of evolution of this complex senseorgan is thus illustrated in the embryonic development; in the
Selachia the hyomandibular cleft is a communication between
pharynx and exterior, like the branchial clefts, and still preserves
to a certain extent the respiratory function. The embryonic
history furnishes a summary of the way in which it was gradually
 
 
 
ORGANS OF SPECIAL SENSE
 
 
 
289
 
 
 
 
drawn into the service of the otocyst in the course of evohition.
 
Development of the Otocyst and Associated Parts. In
Chapter VI we took up the formation of the otocyst and the
origin of the endolymphatic duct. The Letter is at first an apical
outgrowth from the otocyst, but its attachment soon becomes
shifted to the median side of the otocyst, owing to the expansion
of the dorsal external wall of the
latter (Fig. 167). Three divisions
of the otocyst may now be distinguished: (a) ductus endolymphaticus
or recessus labyrinthi; (6) pars superior labyrinthi; (c) pars inferior
labvrinthi. The boundarv between
the two latter is rather indistinctly
indicated at this stage by a shallow
groove on the median face of the
otocyst. The development of these
parts may now be followed separately.
 
(a) The Development of the Ductus
Endolymphaticus. It was noted in
Chapter VI that the ductus endolymphaticus is united to the epidermis
by a strand of cells that preserves a
lumen up to the stage of 104 hours
at least (Fig. 98). Shortly after, this
connection is entirely lost.
 
The opening of the endolymphatic duct into the otocyst
appears to be shifted more and more ventrally along the median
surface, with the progress of differentiation of the other parts
of the otocyst, until it lies in the region of communication of
the utriculus, sacculus and lagena (Figs. 168 and 171). This is
brought about by the various foldings and expansions of the
wall of the otocyst described in b and c. In the meantime the
endolymphatic duct has increased in length with the growth of
the surrounding parts, and on the sixth day the distal half begins
to expand to form the saccus endolymphaticus, lying between
the utriculus and the hind-brain. The elongation of the entire
endolymphatic duct and the enlargement of the saccus continue
during the seventh day, and on the eighth day the saccus overtops
 
 
 
Fig. 167. — Model of the otocyst
of a chick embryo shortly before its separation from the
ectoderm. (After Krause.)
 
D. e., Endolymphatic duct.
Ect., Ectoderm, p. v., Pocket
for formation of vertical semicircular canals. X indicates the
strand of cells uniting the endolymphatic duct to the ectoderm.
 
 
 
290
 
 
 
THE DEVELOPMENT OF THE CHICK
 
 
 
the hind-brain and bends in above it towards the middle line (Fig.
168). The right and left sacci are, however, still separated by
a considerable space. The walls of the saccus already form a
large number of low folds, presumably glandular, the first begin
 
 
 
FiG. 168. — Transverse section through the head of a chick embryo of eight
 
days in the region of the ear (photograph).
 
C. a., Anterior semicircular canal. C. h., Horizontal semicircular canal.
Caps, and., Auditory capsule. Cav. Tymp., Tympanic cavity. Col., Columella. Duct end., Endolymphatic duct. ex. au. M., External auditory
meatus. Fis. Tub., Tubal fissure. Lag., Lagena. M. C, Meckel's cartilage.
Myel., Myelencephalon. N'ch., Notochord. p'l.. Perilymph. Sac, Sacculus. Sac. end.. Endolymphatic sac. Tub. Eust., Eustachian tube. Tymp.,
Tympanum. L^tr., Utriculus. X., Sac derived from the inner extremity
of the tympanic cavity.
 
 
 
nings of which were visible on the sixth day. The form of the
saccus and ductus endolymphaticus at a somewhat later stage
is shown in the reconstruction (Fig. 173).
 
 
 
ORGANS OF SPECIAL SENSE
 
 
 
291
 
 
 
 
It is interesting to note that the epidermic attachment to the endolymphatic duct is about at the junction of the saccus endolymphaticus
and ductus endolymphaticus s.s. If this may bear a phylogenetic interpretation, it would seem that the saccus should be regarded as an addition to the primitive ductus of Selachii, which opens on the surface.
 
(b) Development of the Pars Superior Lahyrintki; Origin of the
Se7nicircular Canals. We have already seen that the shifting
of the ductus endolymphaticus to the median surface of the
otocyst is brought about by a vertical extension of the superior
lateral wall of the otocyst, w'hich forms a shallow pocket opening
widely into the otocyst (Fig. 167). Slightly
later a second pocket is formed by a horizontally extended evagination of the lateral w^all
of the pars superior directed towards the
epidermis. These two pockets, known as the
vertical and horizontal pockets, are the forerunners of the semicircular canals : the vertical
of both anterior and posterior, and the horizontal of the horizontal semicircular canal.
The horizontal pocket forms at about the middle of the external surface on the fifth day;
immediately above it is a roughly triangular,
pear-shaped depression in the wall of the otocyst, bounded by the vertical pocket on the
other tw^o sides. Thus the vertical pocket consists of two divisions, anterior and posterior,
meeting at the apex of the otocyst (Fig. 169) «
 
The pockets gradually deepen; and the
semicircular canals arise from them by the fusion of the walls of the central part of each
pocket, thus occluding the lumen except at
the periphery (Fig. 170). The fused areas
subsequently break through. The peripheries
thus form semicircular tubes communicating at each end with
the remainder of the superior portion of the otocyst, or ntriculus,
as it may now be called. Three semicircular canals are thus
formed, one from each division of the original vertical pocket
and one from the horizontal pocket. The upper ends of the anterior and posterior semicircular canals, formed from the anterior
and posterior divisions of the vertical pocket, open together into
 
 
 
Fig. 169. — Model of
the auditory labyrinth (otocyst) of
a chick embryo of
undetermined age ;
view from behind.
(After Rothig and
Brugsch.)
 
C. 1., Pocket for
the formation of the
lateral (horizontal)
semicircular canal.
 
C. v., pocket for formation of vertical
semicircular canals.
 
D. C, PrimonHum
of ductus cochlearis
and lagena. D. e.,
endolymphatic duct.
 
 
 
292
 
 
 
THE DEVELOPMENT OF THE CHICK
 
 
 
 
the apex of the utricukis; and the horizontal canal formed from
the external pocket extends between the separated lower ends
of the other two.
 
We must now proceed to a more detailed examination. In
 
point of time the anterior (sagittal)
semicircular canal is the first to be
formed (Fig. 171) ; the external (horizontal or lateral) canal comes next,
and considerably later the posterior
(frontal). Thus the anterior canal
is at first the largest, the external
next, and the posterior the smallest.
These differences are, however,
largely compensated in the course
of the embryonic development. The
ampullae appear as dilations in the
pockets even before the canals are
Pig. 170. — Model of the auditory formed, and are conspicuous dilalabyrinth of a chick embryo of 6 tions by the time that the central
days and 17 hours; external view, parts of the pockets have broken
(After Rothig and Brugsch.) throuo'h (Fig. 172).
 
C. a., Pocket for formation of „. ^^^ ^^„ , ,, _^^u^+^
 
anterior semicircular canal. C.I., FlgS. 1/0-1/3 show the pocketS
 
Pocket for formation of lateral ^Tid canals at six days seventeen
semicircular canal. C. p., Pocket , , _+^^„ u^tt,.^
 
for formation of posteriir semicir- hours, seven days seventeen houis,
 
cular canal. D. c, Ductus coch- eight days seventeen hours, and
 
learis. D. e., Endolymphatic duct. . ^ , ■> ,^ j
La., LagenL eleven days seventeen hours. It
 
will be seen that, whereas the anterior and lateral canals are formed from the start in planes at
right angles to one another, viz., the sagittal and horizontal, the
posterior canal is not at first in the third or transverse plane, but
gradually assumes it.
 
The form of the utriculus is gradually assumed during the
formation of the semicircular canals; it becomes drawn out into
a roughly triradiate form, so that it consists of a central cavity
and three sinuses, viz., the median sinus which receives the end
of the anterior and posterior semicircular canals, the posterior
sinus situated above the ampulla of the external semicircular
canal, and the anterior sinus in the region of the ampullae of the
horizontal and sagittal semicircular canals (cf. Fig. 173). A short
distance in front of the posterior sinus on the median face of
 
 
 
ORGANS OF SPECIAL SENSE
 
 
 
293
 
 
 
the utriculus occur the openings of the ductus endolymphaticus,
sacculus, and ductus cochlearis; the two latter derived from the
pars inferior of the otocyst, to the development of which we
now turn.
 
(c) Development of the Pars Inferior Lahyrinthi; Lagena,
Ductus Cochlearis, and Sacculus. During the changes described
in the pars superior labyrinthi, the pars inferior has developed
into the ductus cochlearis and lagena on the one hand, and the
sacculus on the other. Throughout the series of the vertebrates
 
 
 
 
Fig. 171. — Model of the auditory labyrinth of the left side of a chick
of 7 days and 17 hours. A. Median view. B. External view.
(After Rothig and Brugsch.)
A. a., Ampulla of the anterior semicircular canal. A. p., Ampulla
 
of the posterior semicircular canal. C. a., Anterior semicircular
 
canal. C. 1., Pocket for formation of the lateral semicircular canal.
 
C. p., Pocket for formation of the posterior semicircular canal. Sa.,
 
Sacculus. Other abbreviations as before.
 
the structure of the pars superior is very uniform; the pars inferior,
on the other hand, has a characteristic structure in each class
and exhibits in general a progressive evolution. The condition
in the chick is characteristic on the whole for the class of birds.
At six days the lower division of the otocyst has grown out
ventralward into a deep pouch which is curved posteriorly and
towards the middle line (Fig. 170); the terminal portion is the
nicUment of the lagena, and the intermediate portion of the ductus
 
 
 
294
 
 
 
THE DEVELOPMENT OF THE CHICK
 
 
 
cochlearis; the tip of the lagena in its growth ventralward has
reached the horizontal level of the notochord. The sacculus is
barely indicated yet, but is clearly seen on the seventh day as
a slight protuberance on the median surface of the uppermost
part of the pars inferior; it lies in front of the lower end of the
endolymphatic duct at a slightly lower level and is separated by
two depressions above and below, from the anterior ampulla
and the ductus cochlearis respectively. The furrows above the
sacculus and below the ampulla of the frontal semicircular canal
mark the boundary between the pars superior and inferior.
 
 
 
 
 
S
 
 
C.d.
 
 
^
 
 
WAd.
 
 
 
 
a
 
 
V
 
 
^""^^^w
 
 
^^^ "\ U
 
 
p
 
 
 
^./.
 
 
5....^
 
 
D.e.
 
 
i
 
 
,^H
 
 
D.c.
 
 
 
 
 
Fig. 172. — Model of the auditory labyrinth of the
 
right side of a chick embryo of 8 days and 17
 
hours ; external view. (After Rothig and Brugsch.)
 
A. a., Ampulla of the anterior semicircular canal.
A. 1., Ampulla of the lateral semicircular canal. A.
p., Ampulla of the posterior semicircular canal. C.
a., Anterior semicircular canah C. 1., Lateral semicircular canal. C. p., Posterior semicircular canal.
Sa. e., Endolymphatic sac. U., Utriculus. Other
abbreviations as before.
 
 
 
A day later (Fig. 172), these furrows have cut in deeper and
have become continuous on the median surface; the lagena has
enlarged distally, and the sacculus is a hemispherical protuberance. The tip of the lagena lies beneath the hind-brain (Fig.
 
 
 
ORGANS OF SPECIAL SENSE
 
 
 
295
 
 
 
168). The condition shown in Fig. 173, at eleven days seventeen hours is substantially the same as in the adult.
 
(d) Development of the Auditory Nerve and Sensory Areas of the
Labyrinth. During the changes in the form of the labyrinth
described in the preceding section, the lining epithelium has
become thin and flattened except in eight restricted areas: viz.,
the three cristce acusticce, one in each of the ampullae of the semicircular canals, the macula utriculi, the macula sacculi, the 'papilla
 
 
 
 
Fig. 173. — Model of the auditory labyrinth of
the right side of a chick embryo of 11 days
and 17 hours; external view. (After Rothig
and Brugsch.) Abbreviations as before.
 
lagenoe, the papilla hasilaris and the macula neglecta. Each of
these contains sensory cells ending in fine sensory hairs projecting into the endolymph, or fluid of the labyrinth, and receives a
branch of the auditory nerve proceeding from the acustic ganglia.
Returning to an early stage to follow the development of sensory areas and nerves, we note first that the acustic ganglion from
w^hich the auditory nerve arises takes its origin from the acustico
 
 
296 THE DEVELOPMENT OF THE CHICK
 
facialis ganglion which lies in front of and below the center
of the auditory pit. During the closure of the latter, the acustic
ganglion becomes fused with part of the wall of the otocyst in
such a way that it becomes impossible to tell in ordinary sections where the epithelial cells leave off and the ganglionic cells
begin. This fused area may be called the auditory neuro-epithelium. At the 36 somite stage the neuro-epithelium is confined
to the lower (ventral) fourth of the otocyst, covering the entire
tip, the anterior face, and a small portion of the median face
(cf. Fig 98). The neuro-epithelium is the source of all the sensory areas, which arise from it by growth and subdivision. The
branching of the auditory nerve follows the subdivision of the
neuro-epithelium.
 
The exact manner in which the changes take place has not
been made a subject of special investigation in the chick, so far
as the author knows. However, it can be said in general that
there is first a partial division of the neuro-epithelium into a
pars superior and a pars inferior, and that the former divides
into the cristse acusticse (sensory areas of the three ampullae)
and the macula utriculi, while the latter furnishes the macula
sacculi, papilla basilaris and papilla lagense.
 
The sensory cells differentiate from the epithelium of the
labyrinth, and the nerve fibers from the bipolar neuroblasts of
the acustic ganglion, the peripheral process growing into the
epithelium and branching between the sensory cells, while the
central process grows into the brain.
 
(e) Bony Labyrinth, Perihjmph, etc. The loose mesenchyme
that entirely surrounds the otocyst, differentiates in the course
of development into the membrana propria and perilymphatic
tissue of the membranous labyrinth, the perilymph and the bony
labyrinth in the following manner; on the sixth day a single layer
of mesenchyme cells in contact with the cells of the otocyst are
arranged with their long axes parallel to the wall, and show
already in places a slight fibrous differentiation. These gradually
form the membrana propria, which appears on the eighth day
as an extremely thin adherent layer with protruding nuclei at
intervals. The mesenchyme external to this delicate layer is
already differentiated on the sixth day into a perilymphatic
and a procartilaginous zone; in the former the mesenchyme is
of loose consistency, and in the latter zone it has become dense
 
 
 
ORGANS OF SPECIAL SEXSE 297
 
as a precursor to chondrification. The distinction between the
perilymphatic and cartilaginous zones is most distinct (on the
sixth day) on the median surface of the ductus cochlearis and
lagena. The differentiation proceeds rapidly, however, and on
the eighth day the entire membranous labyrinth is surrounded
by a mass of embryonic cartilage, the foundation of the bony
labyrinth, excepting around the endolymphatic duct (Fig. 168).
Between the bony and membranous labyrinths is a thick layer
of perih'mphatic tissue composed of very loose-meshed mesenchyme, which in the course of the subsequent development
breaks down to form the perilymphatic space. Portions of the
perilymphatic tissue, however, remain attached to the membranous labyrinth and form a support for its blood-vessels and
nerves.
 
The Development of the Tubo-tympanic Cavity, External
Auditory Meatus and Tympanum. These structures develop
directly or indirectly from the first or hyomandibular visceral
cleft and the adjacent wall of the pharynx. In a preceding
chapter the early development of this cleft was described; we
saw that the pharyngeal pouch forms two connections with the
ectoderm, a dorsal one corresponding to a pit-like depression of
the ectoderm, and a ventral one corresponding to an ectodermal
furrow. The latter connection is soon lost, the ectodermal furrow slowly disappears, and the ventral portion of the pouch
flattens out. In the dorsal connection, however, an opening is
formed which closes on the fourth day, and the dorsal division
of the pouch then frees itself from the ectoderm and expands
dorsally and posteriorly until it lies between the otocyst and the
ectoderm, still preserving its connection with the pharynx (Fig.
102).
 
(a) The Tuho-tympanic Space. The dorsal portion of the
first visceral pouch forms the lateral part of the tubo-tympanic
space, but the greater portion of the latter is derived from the
lateral wall of the pharynx itself, immediately adjacent to the
entrance into the first visceral pouch; the region concerned
extends from near the anterior edge of the second visceral pouch
forwards, and ends a short distance in front of the first pouch.
The original transverse diameter of the pharynx in this region
increases in the course of development, and a frontal partition
grows across the pharynx forming a dorsal median chamber into
 
 
 
298
 
 
 
THE DEVELOPMENT OF THE CHICK
 
 
 
which the two tubo-tympanic cavities open. The median chamber communicates by a longitudinal slit (tubal fissure) in the
 
roof of the pharynx with the
oral cavity (Figs. 168 and
175).
 
The frontal partition in
question is a posterior prolongation of the palatine
processes of the maxillary
arch, and forms as follows:
If the head of a four-day
chick be halved by a sagittal plane, and the interior
of the pharynx and mouth
cavity be then viewed by
reflected light, an elongated
lobe will be seen on the median surface of the mandibular arch and maxillary
process (Fig. 174 A). This
lobe begins far forward on
the median surface of the
maxillary process and may
be followed posteriorly over
the median surface of the
mandibular arch to the first
visceral pouch, where it
ends with a free rounded
extremity. The lobe itself
is called by Moldenhauer
the colliculus palato-phar
 
 
O.PhT
 
 
 
 
GoDjJ.p.
 
 
 
Fig. 174. — A. Head of a chick embryo of
4 days, halved by median section and
viewed from the cut surface. (After
Moldenhauer.)
 
B. Internal view of the pharynx of a
pigeon embryo, corresponding in development to a chick of 10 days. (After Moldenhauer.)
 
Col. 1., Colliculus lingualis. Col. p. p.,
Colliculus palato-pharyngeus. Cr. i., Crus
inferior. Cr. s., Crus superius. Hyp.,
Hypophysis. Mx., Maxilla. N'ch., Notochord. O. Ph. T., Ostium tubse pharyngae. S. P., Seessell's pocket. 2, 3, 4,
Second, third, and fourth visceral arches.
 
 
 
yngeus; it is bounded above
and below by depressions,
viz., the sulcus tubo-tympanicus dorsally and the
sulcus lingualis ventrally,
both of which end behind
 
 
 
in the first visceral pouch;
anteriorly the ventral furrow disappears at the margin of the
mouth, and the dorsal furrow near SeessePs pocket. The maxil
 
 
ORGANS OF SPECIAL SENSE 299
 
lary portion of the colliculus palato-pharyngeus corresponds to
the palatine processes of mammals; the mandibular portion is
peculiar to Saiiropsida.
 
If the interior of the pharynx and oral cavity of a ten-day
chick be examined (Fig. 174 B), it will be found that the colliculus has undergone important changes. Its maxillary or anterior division divides in two limbs, crura superior and inferior^
diverging anteriorly and separated by a depression which continues the nasal cavity backward; its free posterior end extends
farther backwards than before, and is more elevated. The
bounding sulci are both deeper than before. The sulcus tubotympanicus, with which we are specially concerned, now extends
on to the median surface of the hyoid arch. Subsequently, the
crura superiores of the opposite side meet in the middle line and
fuse together; in a similar fashion the posterior ends of the colliculi fuse; thus the sulci tubo-tympanici open into a dorsal
chamber common to both, which communicates with the ventral
division of the pharynx by a slit remaining between the two
fused areas. The crura inferiores also approach one another
in the middle line but do not fuse, thus leaving the typical split
palate of birds in front of the fused lower ends of the crura superiores. In this way the typical adult condition of the bird's
palate is established.
 
From this description it will be seen that only the most lateral
portion of the tubo-tympanic cavity is directly derived from
the first visceral pouch. In later stages it is quite impossible
to say exactly what part, but it is quite certain that it lies within
the tympanic part of the cavity. About the end of the fifth
or the beginning of the sixth day the tubo-tympanic canal begins
to enlarge distally to form the tympanic cavity proper (cf. Fig.
168); the auditory ossicles (see chapter on skull) are beginning
to form just above its dorsal extremity, and as the tympanic
cavity enlarges it expands around them, displacing the mesenchyme, and finally meets above the auditory ossicles, so that
these appear to lie within it, though as a matter of fact the relation is analogous to that of the entodermal alimentary tube to
the body-cavity. The process of inclusion of the auditory ossicles
is not, however, concluded until about the twelfth day. The
blind end of the tympanic cavity attains a level dorsal to the
external auditory meatus. (See below.)
 
 
 
300 THE DEVELOPMENT OF THE CHICK
 
During the seventh and eighth days the enlarging cartilaginous
labyrinth presses down on the Eustachian tube and hinders its further
enlargement. On the eighth day the tube is a wide but narrow slit
which appears crescentic in a sagittal section of the head (Fig. 150).
 
Some rather obscure details about the formation of the tubo-tympanic canal are mentioned here as suggestions for further work on the
subject. On the sixth day almost the entire roof is composed of flattened cells similar to the roof of the pharynx; the floor, however, is lined
with a columnar epithelium which extends out to and surrounds the
distal extremity; it seems probable that this terminal chamber lined
on all sides by columnar epithelium represents the first visceral pouch
proper. On the eighth day the cavity of this distal chamber is completely constricted off from the main tympanic cavity, though it is still
connected with the latter by a solid rod of cells, which gives unequivocal
evidence of its origin. I do not know what becomes of this separated
cavity later. (See Fig. 168 X.)
 
(5) The External Auditory Meatus and the Tympanum. We
have already seen that on the ectodermal side there are originally
two depressions corresponding to the first visceral pouch, viz.,
a dorsal round one in which a temporary perforation is formed,
and an elongated ventral furrow. Between these is a bridge of
tissue within which the external auditory meatus arises as a new
depression, first clearly visible on the sixth day, when it is surrounded by four slight elevations, tw^o on the mandibular and
t'wo on the hyoid arch. The meatus gradually becomes deeper
and tubular, mainly owdng, I think, to the elevation of the surrounding tissue, the bottom of the meatus, or tympanic plate,
being held in position by the forming stapes. The meatus is
directed in a general median direction Avith a slight slant dorsally
and posteriorly, and the tympanic plate is placed obliquely, not
opposite the lateral extremity of the tympanic cavity, but ventrally to this (cf. Fig. 168).
 
Even on the sixth day the position of the head of the stapes
may be recognized by the density of the mesenchyme internal to
the bottom of the meatus. During the seventh and eighth days
the stapes becomes sharply differentiated, and the internal face
of the tympanum is established in proportion as the tympanic
cavity expands around the cartilage (cf. Fig. 168). Thus the
tympanum is faced by ectoderm externally, by entoderm internally, and includes an intermediate mass of mesenchyme, which
differentiates by degrees into the proper tympanic substances.
 
 
 
==CHAPTER X  THE ALIMENTARY TRACT AND ITS APPENDAGES==
 
The origin of the alimentary canal and of its various main
divisions and appendages has been considered in preceding chapters. The subsequent history will now be taken up in the following order:
 
1. The mouth and oral cavity.
 
2. The pharynx and its derivatives.
 
3. The oesophagus, stomach and intestine.
 
4. The liver and pancreas.
 
5. The respiratory tract.
 
The history of the yolk-sac and allantois was considered with the
embryonic membranes (Chap. VH); the detailed history of the
mesenteries will be taken up in connection with the body cavities
(Chap. XI).
 
I. Mouth and Oral Cavity
 
The oral cavity may be defined embryologically as that part
of the alimentary canal formed on the outer side of the oral plate.
Anatomically, however, such a definition is unsatisfactory both
because it is impossible to determine the exact location of the
oral plate in late stages, and also because of the difference in
extent of the ectodermal component in roof and floor of the
mouth; the definitive mouth cavity includes part of the floor of
the embryonic pharynx. It is, however, of interest to determine
as nearly as possible the limits of the ectodermal component
of the oral cavity. In the roof this is not difficult because the
hypophysis, which arises just in front of the oral plate, retains
its connection with the mouth cavity until definitive landmarks
are formed. The median sagittal section of an eight-day chick
(Fig. 148) shows that this point is situated almost immediately
opposite to the glottis, that is, between the palatine and tubal
fissures in the roof (cf. Fig. 175). In the floor the extent of
the ectodermal component is much less. If the tongue is entirely
 
301
 
 
 
302
 
 
 
THE DEVELOPMENT OF THE CHICK
 
 
 
a pharyngeal structure (in the embryological sense) the limit
of the ectoderm would lie near the angle between the tongue
and the floor of the mouth. In the side walls the boundary must
be near the lines uniting the dorsal and ventral points as thus
determined.
 
 
 
V,
 
 
 
^ .
 
 
 
To/7^//e
 
 
 
H1.V.H
 
 
 
.»v
 
 
 
 
 
 
\
 
 
'■ i
 
 
1
 
 
\
 
 
/'
 
 
-' - .
 
 
 
w
 
 
 
S
 
 
 
 
-Trdc/fed.
 
 
 
Cor77.//r
 
 
 
Fig. 175. — Floor and roof of the mouth of the hen. The jaw muscles were
cut through on one side, the lower jaw disarticulated and the entire floor
drawn back.
Corn. H., Cornu of the hyoid. Fis. pal., Palatine fissure. Fis. Tub.,
 
Tubal fissure. Mu., cut surface of jaw muscles.
 
We have already considered the formation of the boundaries
of the mouth (Chap. VI and Chap. VII), and of the palate (Chap.
IX, page 299). These data need not be repeated, so we have
left to consider only the development of the beak, egg-tooth,
tongue, and oral glands.
 
Beak and Egg-tooth. The beak is a horny structure formed
by cornification of the epidermal cells around the margins of
 
 
 
ALIMENTARY TRACT AND ITS APPENDAGES
 
 
 
303
 
 
 
l£.T
 
 
 
the mouth: the egg-tooth is a mammiform hard structure with
pointed nipple (Figs. 176 and 177) situated on the dorsum of the
upper jaw near its tip (cf. Fig. 150).
Its function is to aid in breaking
the shell-membrane and the shell itself at the time of hatching; shortly
afterwards it is lost. It is, therefore, an organ concerned with a single critical event in the life of the
individual; nevertheless fully developed like the instinct of its use,
needed only for the same critical
event. Though its structure is different from that of the beak, it develops in connection with the latter,
and the two will, therefore, be con
 
 
 
■s^
 
 
Fig. 176. — Outline of the upper jaw of a chick embryo
of 18 days' incubation. (After
Gardiner.)
 
E. T., Egg tooth. L. gr., Lip
groove.
 
 
 
sidered together.
 
The formation of the egg-tooth begins on the sixth day from
an area situated in the middle line near the tip of the upper jaw,
distinguishable in the living embryo by its opacity, which contrasts with the translucency of
the surrounding parts; in profile view, the area is seen to be
slightly elevated. In sections
the appearance is found to be
due to an accumulation of
rounded ectodermal cells lying
between a superficial layer of
periderm of several layers of
cells, and the subjacent mucous
layer of the epidermis (Fig.
177). Without losing their
rounded shapes this mass of
cells gradually assumes the
form of the egg-tooth by the
fourteenth day. The overlying
layer of periderm is lost during
the act of hatching. During their differentiation the cells of the
egg-tooth secrete an intercellular substance of horny consistency
in which intercellular protoplasmic connections are found. The
 
 
 
 
Fig. 177. — Transverse section through
 
the upper jaw of a chick embryo of
 
11 days. (After Gardiner.)
 
E. T., Egg tooth. H. Horn. L. gr.,
Lip groove. Pd., Periderm. T. R.,
Tooth ridge.
 
 
 
304 THE DEVELOPMENT OF THE CHICK
 
protoplasm of the cell-bodies themselves becomes densely packed
with granules, apparently also of a horny nature, and the boundaries of the cells and outlines of the nuclei become indistinct.
 
Reptiles with a horny egg-shell are provided with a true dentinal
tooth on the premaxilla, which has the same function as the egg-tooth
of birds and of those reptiles that have a calcareous shell (crocodiles,
turtles, and Trachydosaurus). The latter is, however, as we have
seen, a horny structure, and therefore not a tooth morphologically.
Rose therefore proposes the term '' Eischwiele" for the horny toothlike structure, to distinguish it sharply from the real egg-tooth.
 
The formation of the upper beak begins in the neighborhood
of the egg-tooth and spreads towards the tip and the angle of
the mouth. Similarly, in the lower jaw the differentiation begins
near the tip. It is a true process of cornification, that takes
place beneath the periderm and involves many layers of cells.
It is therefore preceded by a rapid multiplication of cells of the
mucous layer of the epidermis. Soon after the appearance of
the horn a groove appears a little distance above and parallel to
the margin of the upper beak, extending from the anterior end a
short distance backwards (Fig. 176). In sections, this appears
as an invagination of the epidermis; a similar but shallower
invagination appears on the lower beak. In the upper beak the
lips of the invagination fuse together and thus close the groove;
in the lower beak the groove flattens out and disappears. These
grooves correspond in many respects to the grooves that form
the lips of other vertebrates, and they may be interpreted as a
phylogenic reminiscence of lip-formation.
 
Teeth. All existing species of birds are toothless, but some
of the most ancient fossil birds possessed well-developed teeth;
it is natural, therefore, to expect that rudiments of teeth might
be found in the embryos of some existing birds. In the early
part of the nineteenth century some observers interpreted papillae
on the margin of the jaws of certain young birds as rudimentary teeth; these were, however, shown to be horny formations,
and therefore not even remotely related to teeth. Gardiner was
one of the first to call attention to a thickening of the ectoderm forming a ridge projecting slightly into the mesenchyme,
just inside the margin of the jaw of chick embryos about six
days old (Fig. 177). The ridge disappears shortly after cornification sets in. Gardiner discussed the possibility of this represent
 
 
ALIMENTARY TRACT AND ITS APPENDAGES 305
 
ing a stage in tooth formation, and rejected the interpretation.
Rose, however, has found the same ridge still better developed
in embryos of the tern and ostrich, and identifies it very positively with the tooth-ridge or first step in the formation of the
enamel organ of other vertebrates. It seems probable that this
is the case, and that in this ridge we have the very last stage
of the disappearance of teeth.
 
The Tongue. The tongue develops from two primordia in
the floor of the embryonic pharynx, one situated in front of, and
the other behind the thyroid diverticulum. The former, or
tuberculum impar, becomes manifest on the fourth day as a
slight rounded swelling situated between the lower ends of the
first and second visceral arches. The swelling is bounded behind
by a groove that has the ductus thyreoglossus for its center, and
in front by a shallow groove, that represents the frenulum, on
the posterior margin of the mandibular arches. The second
primordium, or jjars copularis, arises just behind the thyroid
and includes the lower ends of the second visceral arches, a small
part of the lower ends of the third, and the region between these
arches. According to Kallius the tuberculum impar forms only
the center of the fore part of the tongue, and the lateral parts
arise from two folds that form right and left of it (lateral tonguefolds). The tuberculum impar thus expanded and the pars copularis constitute two very distinct components in the development
of the tongue.
 
Soon after the closure of the thyroid duct the two tongue
components become confluent, but the zone of junction remains
visible for a long time as a groove (cf. Fig. 148). Moreover
the epithelium of the forward component soon becomes thickened and stratified, while in the pars copularis the epithelium
remains thin and simple for a long time. With the elongation of
the jaws the tip of the tongue grows forward above the frenulum
(Fig. 148) and the shape of the entire organ conforms itself to
the shape of the mouth cavity.
 
Figure 175 shows the tongue of the adult fowl. The anterior
half is pointed and horny and is bounded from the posterior half
by a double crescent whose posterior convexity is beset with horny
spines. It seems probable that the anterior portion is derived
from the precopular part, though this has not been demonstrated
by continuous observation. Cornification of the precopular part
 
 
 
306 THE DEVELOPMEXT OF THE CHICK
 
sets in about the eighth day, and the early thickening of the
epitheUum of this part already referred to is undoubtedly the
first stage in the process.
 
The development of the musculature of the tongue has not
been followed. The development of the skeletal parts is considered under the head of the skeleton.
 
Oral Glands. The following oral glands occur in the hen:
1, lingual glands; 2, mandibular glands; 3, glands opening at
the angle of the mouth; 4, palatine glands in the neighborhood
of the choanse. The only account of their development known
to me is the brief one of Reichel. All the glands begin as solid
ingrowths of the mucosa, which may branch more or less, and
secondarily acquire a lumen. Their development begins relatively
late. The mandibular glands appear first on the eighth day as
a series of solid ingrow^ths of the mucosa extending on both sides
of the base of the tongue forward to near the mandibular symphysis. They are still mostly solid on the eleventh clay, and
very slightly branched, if at all. The lingual glands arise beneath
the lateral margin of the tongue and grow up on each side of the
lingual cartilage towards the upper surface where they branch
out. They begin to form on the eleventh day. No glands form
on the upper surface of the tongue. The glands of the angle of
the mouth appear on the eleventh day, in situ, as slight epithelial
ingrowths. Their further history has not been followed. Anterior and posterior palatine glands can be distinguished; the
first in front of the choanse, the latter at the sides of and behind
the choanse. They begin to appear after the eleventh day.
 
II. Derivatives of the Embryonic Pharynx
 
The pharynx, which is such an extensive and important region
of the early embryo owing to the development of the visceral
arches and clefts, becomes relatively much reduced in the process
of development, though of course it becomes much larger absolutely. In the adult it is a somewhat ill-defined cavity from
which the oesophagus leads away posteriorly, and which is confluent with the mouth anteriorly. The tubal fissure opens in
its roof and the glottis in its floor. During the course of development, however, certain more or less persistent structures form
from its walls, or from the epithelium of the pouches. Although
these are relatively inconspicuovis organs in the adult, they are of
 
 
 
ALIMENTARY TRACT AXD ITS APPENDAGES 307
 
considerable morphological importance, being of very ancient
origin and common to the whole series of vertebrates. They are
the thyroid body or gland, the thymus, the postbranchial or
suprapericardial bodies, and certain epithelial vestiges.
 
Fate of the Visceral Clefts. The times of opening and closing
of the visceral clefts have been already given (pp. 176 and 177).
The later history of the first visceral pouch has been described
(p. 297). The second, third, and fourth pouches retain their
connections with the corresponding ectodermal grooves for a
long time during the thickening of the visceral arches. The consequence is, that not only the pouches, but also the ectodermal
furrows, are drawn out into long epithelial tubes, and the original
closing plate is thus deeply invaginated. In the case of the
second cleft the tube ruptures and begins to degenerate on the
sixth day, leaving no remnants. In the case of the third and
fourth clefts the ectodermal components become solid on the
sixth day, and form strands (funiculi prcecervicales) connecting
the entodermal pouches with the sinus cervicalis. These strands
are subsequently broken through and disappear. Parts of the
entodermal pouches, however, persist in the thymus, suprapericardial bodies and other epithelial remains. (See below.)
 
Thyroid. The thyroid sac (median thyroid of authors) loses
all connection with the pharyngeal epithelium on the fourth day,
and on the seventh day it becomes divided in two massive lobes
placed bilaterally (see Fig. 178). These then migrate backwards
on each side of the trachea towards the hinder end of the derivatives of the third visceral pouch (Verdun) and become lodged
in the junction of the subclavian and common carotid arteries,
where they are found in the adult just internal to the jugular vein.
 
The so-called lateral rudiments of the thyroid, or postbranchial
bodies, are histologically entirely different from the thyroid proper.
They are described below.
 
Visceral Pouches. The second visceral pouch leaves no
derivatives in the adult; during the fourth day, however, a considerable thickening of the epithelium appears on its dorsal and
posterior aspect, near its opening into the pharynx; though this
disappears very soon, it may be considered to represent the
thymus II of Selachia and Anura.
 
The third visceral pouch loses its connection with the pharynx
by atrophy of its internal portion between the seventh and eighth
 
 
 
308
 
 
 
THE DEVELOPMENT OF THE CHICK
 
 
 
days, and its intermediate portion persists as an epithelial pocket
on the ventral face of the jugular vein (Fig. 178). This pocket
soon divides into dorsal and ventral moities of which the former
develops into the chief part of the thymus (thymus III) and the
latter into the so-called epithelial vestige III. (See below.)
 
The fourth visceral pouch likewise separates from the pharynx
on the seventh day, and furnishes from its dorsal portion the
thymus IV, and from its ventral portion epithelial vestige IV.
(See below.)
 
 
 
 
Fig. 178. — The derivatives of the embryonic pharynx of the chick. (After
Verdun from Maurer.)
 
A. Of 7 days' incubation.
 
B. Of 8 days' incubation.
 
Ep. 3, Ep. 4, Epithelial bodies derived from the third and fourth visceral
pouches. J., Jugular vein, p'br (V)., Postbranchial bodies derived from
the fifth visceral pouch. Ph., Pharynx. Th. 3, Th. 4, Parts of the thymus
derived from the third and fourth visceral pouches respectively. T'r., Thyroid. Ill, IV, third and fourth visceral clefts.
 
The fifth pouch (postbranchial body) likewise becomes isolated on the seventh day as a closed vesicle; its differentiation is
considered below.
 
The Thymus. According to the above, the thymus of the
chick has a double origin on each side; the main portion (thymus
III) is derived from the dorsal wall of the intermediate part of
the third visceral pouch. This soon elongates to form an epithelial cord extending along the jugular vein; a smaller portion
(thymus IV) of the thymus is derived from a corresponding part
of the fourth visceral pouch, and fuses with thymus III (Fig. 178).
 
 
 
ALIMENTARY TRACT AND ITS APPENDAGES 309
 
In the young chick the thymus forms a voluminous tract of lobulated aspect, extending the entire length of the neck; later it
atrophies and in old subjects one finds only traces of it. (Verdun.)
 
Epithelial vestiges are formed from the ventral wall of the
intermediate portions of the third and fourth visceral pouches;
these come to lie together at the hinder end of the thymus in the
base of the neck. They are found in the adult near the lower
pole of the thyroid (Fig. 178).
 
The postbranchial bodies have been called lateral rudiments
of the thyroid; in their differentiation, however, they do not form
thyroid tissue, but two main kinds of epithelial tissues similar
to the tissues of the thymus and epithelial vestiges respectively.
They are to be regarded, therefore, as a fifth pair of visceral
pouches, for which there are other reasons, as we have seen before.
The constituent elements, however, do not separate as in the case
of the third and fourth visceral pouches, but form a rather illdefined mass situated a short distance behind the thyroid (Fig.
178).
 
The epithelial derivatives of the embryonic pharynx in the
chick are, therefore; 1. thyroid; 2. thymus (from III, IV);
3. epithelial vestiges (from III, IV); 4. postbranchial bodies,
including thymus V and epithelial vestiges V. The thyroid
develops in essentially the same manner in all vertebrates. In
the case of the thymus it may be said in general that more visceral
pouches are concerned in the lower than in the higher vertebrates.
 
III. The GEsophagus, Stomach and Intestine
 
During the third and fourth days a very pronounced lateral
curvature of the alimentary canal develops, the convexity being
turned to the left and the concavity therefore to the right. The
part involved extends from the posterior portion of the oesophagus to the end of the duodenum. As the duodenum is at first
very short, the stomach is the part principally affected at the
start. The depth of the mesogastrium (dorsal mesentery of
the stomach) is considerably increased by the displacement ; in the
region of the greatest curvature it descends directly in the middle
line, then bends sharply to the left and is attached to the dorsal
wall of the stomach; the accessory mesentery arises at the bend.
(See Chap. XL) The stomach does not rotate on its long axis so
as to carry the attachment of the mesogastrium to the extreme
 
 
 
310
 
 
 
THE DEVELOPMENT OF THE CHICK
 
 
 
left, as in mammals; in the chick the lateral bending of the
stomach appears to be uncomplicated by any such rotation. The
curvature leaves a large space within it to the right containing
the meatus venosus and liver, in short, the entire median mass
of the septum transversum.
 
The main divisions of the intestine are marked out by their
position, size-relations and structure before the closure of the
yolk-stalk; thus on the third day the oesophagus appears as a
constricted portion immediately behind the pharynx, and the
stomach as a spindle-shaped enlargement behind the oesophagus;
the duodenum is indicated at the same time by the hepatic and
 
 
 
 
Fig. 179. — Viscera of a chick embryo of 6
 
days, seen from the right side. (After
 
Duval.)
 
All., Allantois. Au. r., Right auricle.
B.a., Bulbus arteriosus, c. pr., Csecal processes. D. L., Loop of the duodenum. Giz.,
Gizzard. Lg. r., Right lung. Li., Liver.
R., Rectum, t. R., Tubal ridge. V., Ventricle. W. B., Wolffian body. Y. St., Yolk
stalk. X., Duodcno-jejunal flexure.
 
 
 
pancreatic outgrowths. The form of the intestine on the sixth
day is illustrated in Figure 179. Behind the stomach, the intestine forms two loops descending ventrally. The first or duodenal
loop is relatively slightly developed at this time, and forms an
open curve just beneath the right lobe of the liver. Its ascending limb rises to a high dorsal position just behind the liver, and
 
 
 
ALIMEXTARY TRACT AND ITS APPENDAGES
 
 
 
311
 
 
 
bends sharph^ to enter the descending limb of the second loop.
This bend or duodeno-jejunal flexure (X, Fig. 179) is a relatively
fixed point in the growth of the intestine, and marks the boundary between the duodenum and succeeding parts of the small
intestine. The second loop descends deep into the umbilical
cord, and the yolk-stalk is attached to its lowermost portion.
A bilateral swelling at the upper end of its ascending limb is the
primordium of the caecal processes, and marks the anterior end of
the large intestine, which passes in a slight curve to the cloaca.
In the subsequent growth of the intestine the fixed point
referred to above at the hinder end of the duodenum is held in its
place, and the duodenal loop in front of it simply becomes longer
 
 
 
 
Fig. 180. — Viscera of a chick embryo of 17 days'
 
incubation from the right side. (After Duval.)
 
Am., Attachment of amnion to umbilical stalk.
Li. r., 1., Right and left lobes of the liver. Pc, Pancreas. U. St., UmbiHcal stalk. Other abbreviations
same as Fig. 179.
 
without forming secondary convolutions; the pancreas comes to
lie in this loop. The second loop, on the other hand, forms
numerous secondary convolutions (Fig. 180) which lie at first in
the umbilical cord, but which are gradually retracted (seventeenth to eighteenth day) into the abdominal cavity.
 
The two intestinal caeca begin to grow out as finger-shaped
processes from the swelling already referred to, about the seventh
day, and rapidly attain considerable length. The large intestine
elongates only about in proportion to the growth of the entire
embryo.
 
Having thus noted the general gross anatomy of the embry
 
 
312
 
 
 
THE DEVELOPMENT OF THE CHICK
 
 
 
onic intestine, we may next note a few details concerning some
of its divisions. The history of the mesenteries is considered in
Chapter XI).
 
(Esophagus. Owing to the rapid elongation of the neck the
oesophagus quickly becomes a long tube. On the sixth day its
lumen becomes very narrow, and on the seventh day completely
occluded immediately behind the glottis, owing to proliferation
of the lining cells. On the eighth day the occluded portion
 
 
 
\
 
 
 
 
 
 
 
 
 
 
 
 
 
■^
 
 
 
 
 
 
-y
 
 
 
•-'^?':
 
 
 
Fig. 181. — Photograph of a transverse section through the oesophagus and trachea of an 8-day chick.
Cop. H., Copula of the hyoid. (Es., (Esophagus. Tr., Trachea.
Ven. jug., Jugular vein.
 
 
 
extends only a short distance behind the glottis: it is compressed dorso- vent rally and extended laterally throughout the
occluded region (Fig. 181). On the eleventh day it is open again
along its entire length. The crop arises as a spindle-shaped dilatation of the fx^sophagus at the base of the neck; on the eighth
day it is about double the diameter of the parts immediately
 
 
 
ALIMENTARY TRACT AND ITS APPENDAGES 313
 
in front of and behind it (Fig. 150). No detailed account of its
development exists.
 
Stomach. It is well known that the stomach of birds exhibits
two successive divisions, the pro vent riculus and the gizzard,
the former of which has a digestive function and is richl}^ provided with glands, while the latter has a purely mechanical function, being provided with thick muscular walls, within which is
the compressed cavity lined on each side by tendinous plates.
 
On the third day of incubation, the divisions of the stomach
are not recognizable, either by the form of the entire organ or by
the structure of the walls. On the fifth day, however, the first
indications of the formation of the compound glands of the
pro vent riculus may be seen in the cardiac end; the posterior or
pyloric end occupies the extreme left of the gastric curve and
forms the rudiment of a blind pouch projecting posteriorly, that
develops into the gizzard. On the sixth and seventh days this
pouch expands farther in the same direction (cf. Fig. 179), and a
constriction forms between the anterior portion of the stomach,
or pro vent riculus, and the gizzard, as thus marked out. The
gizzard grows out farther, to the left and posteriorly, at the same
time undergoing a dorso-ventral flattening, owing to the formation of the large muscle-masses. According to this account,
therefore, the. greater curvature of the gizzard would represent
the original left side of the portion of the embryonic stomach
from which it is derived, and the original right side would be
represented by the lesser curvature.
 
The large compound glands of the proventriculus are indicated on the fifth or sixth days as slight depressions of the entoderm towards the mesenchyme; on the seventh day these become
converted into saccular glands with narrow necks (Fig. 182).
Each sacculus becomes multilobed about the twelfth or thirteenth
days, and each lobulus includes a small number of culs-de-sac,
lined with a simple epithelium. The last subsequently become
tul)ular, and the original sacculus then represents the common
duct of a large compound gland. (See Cazin.)
 
The simple, tubular glands of the gizzard begin to form about
the thirteenth or fourteenth day, and the lining of the gizzard
is simply the hardened secretion of these glands; it is thus essentially different from cuticular and corneous structures of the surface of the body. According to Cazin, the glands of the gizzard
 
 
 
314
 
 
 
THE DEVELOPMENT OF THE CHICK
 
 
 
are formed as folds and culs-de-sac excavated in the thickness of
the original epithelial wall, by elevations of the subjacent connective tissue. It should be noted finallv, that from the eie:hth
day on, the surface of the mucosa, both in the proventriculus and
in the gizzard, is covered with a thick layer of secretion; subsequently replaced in the gizzard by the corneous lining.
 
 
 
 
Fig. 182. — Photograph of a transverse section of an 8-day chick through
the region of the proventriculus and tip of the heart.
A. coel., Coeliac artery. A. o. m., Omphalomesenteric artery. Cav. om.,
Cavum omenti. Cav. pc, Pericardial cavity. Coel., Coelome. Gon., Gonad.
Lig. g-h., Gastro-hepatic ligament. M. D., Miillerian duct. Mtn., Metanephros. p'c, Membranous pericardium. Pr'v., Proventriculus. S'r., Suprarenal. V. c. i., Vena cava inferior. Ven., Ventricle of heart. V. h. 1., Left
hepatic vem. V. s'c, Subcardinal vein. V. umb., Umbihcal vein.
 
Large Intestine, Cloaca, and Anus. The cloaca of the adult
is a large chamber opening to the exterior by the anus; it consists
of three divisions: the proctodseum or terminal chamber is capable
of being clo.sed by the sphincter muscle, the bursa Fabricii opens
into its dorsal wall, and it is separated by a strong circular fold
 
 
 
ALIMENTARY TRACT AND ITS APPENDAGES
 
 
 
315
 
 
 
from the intermediate section of the cloaca or iirodaeum; this is
a relatively short division of the cloaca which receives the renal
and reproductive ducts in its dorsal wall by two pairs of openings;
it is bounded from the larger anterior division, coprodseum, by
a rather low circular fold; the coprodaeum passes gradually, without a sharp line of division, into the rectum.
 
The early embryological history of these parts has been considered in the preceding chapters. The condition on the fourth
day is shown in the accompanying figure (Fig. 183) representing a
 
 
 
mMMMmmNhh
 
 
 
 
Fig. 183. — Median sagittal section of the hind end of a chick embryo
 
on the fourth day of incubation. (After Gasser from Maurer.)
 
All., Allantois. Am., Tail fold of amnion, cl. M., Cloacal membrane. CI., Cloaca. N'ch., Notochord. n. T., Neural tube. R., Rectum. Y. S ., Wall of yolk-sac.
 
 
 
sagittal section of the hind end of the embryo. The cloaca is the
large terminal cavity of the intestine, closed from the exterior
by the cloacal membrane, in which the entoderm of the floor of
the cloaca is fused to the superficial ectoderm at the base of the
tail. The line of fusion is a long, narrow median strip, extending
from just below the neck of the allantois to the hinder end of the
cloaca. Leading out from the cloaca ventrally, in front of the
 
 
 
316
 
 
 
THE DEVELOPMENT OF THE CHICK
 
 
 
cloacal membrane, is the neck of the allantois, and dorsal to this,
the large intestine. Though not shown in the figure, it may be
noted that the Wolffian ducts open into the cloaca behind and
dorsal to the opening of the rectum.
 
The appearance of the cloaca in a longitudinal section does
not, however, give an adequate idea of its form. The anterior
portion of the cloaca which receives the rectum, stalk of the
allantois and Wolffian ducts is expanded considerably in the
lateral plane, and thus possesses a large cavity. The posterior
 
 
 
 
 
 
■ -T,»T7i
 
 
 
 
 
 
 
 
 
ffecl.
 
 
 
 
 
 
 
 
 
 
 
 
i«^,|A
 
 
 
-'I
 
 
 
 
 
 
 
 
 
^
 
 
 
 
 
■,'f'
 
 
 
d/?./:
 
 
 
 
 
 
 
 
*'-y.
 
 
 
;^S^Ii
 
 
 
 
 
 
-^Z
 
 
Fig. 184. — Frontal section through the region of the
 
cloaca of a 5Way chick embryo.
 
an. F., Anal fold. B. F., Bursa Fabricii. CI., Cloaca.
Coel., Coelome. Rect., Rectum. W. D., Wolffian duct.
X., Posterior angle of the body-cavity; the epithelium
is invaginated and folded so as to simulate a glandular
structure.
 
 
 
portion, on the other hand, is greatly compressed laterally and
the cavity is extremely narrow. During the fifth day the walls
of this part of the cloaca become actually fused together, and
its cavity obliterated, or rendered virtual only (Fig. 184). Thus
the anterior part of the cloaca is prolonged backwards by a
 
 
 
ALIMENTARY TRACT AXD ITS APPENDAGES 317
 
median plate which is continuous ventrally with the cloacal membrane.
 
This plate was interpreted by all the earlier observers (up to Wenckebach) as the hypertrophied cloacal membrane. It is, however, not
difficult to demonstrate in good series of sections, that this is not the
case; the cloacal membrane forms only a small part of this plate, and
its ectodermal component is thin.
 
During the fifth and sixth days, vacuoles appear in the posterior and dorsal part of the fused portion of the cloaca, and
these soon run together in the uppermost part, but remain as a
chain of vacuoles ventrally (Fig. 184). The vacuolated portion
is the primordium of the bursa Fabricii and its duct. Its cavity,
which is extremely narrow and ill-defined at this time, may be
regarded as a re-establishment of the cavity of the posterior
division of the embryonic cloaca; its communication with the
anterior portion of the cloacal cavity is soon closed.
 
At this stage the lining epithelium of the rectum is much
thickened, and the lumen has therefore become narrow (Fig. 184).
 
During the seventh day the conditions change very rapidly
and on the eighth day the relations are as shown in Figure 185.
The anterior portion of the original cloaca, or urodseum, has
become compressed in an antero-posterior direction; the allantois
leads off from it anteriorly and ventrally, and the rectum with
its cavity now obliterated is attached to its anterior face; the dorsal extension, above the rectum (see Fig. 185), is related to the
urinogenital ducts. The bursa Fabricii has now a well-defined
cavity that no longer communicates with the urodseum. The
tissues surrounding the cloacal membrane have grown out to
form a large perianal papilla, and the cloacal membrane is
therefore invaginated; its direction also is so altered that the
invaginated cavity or proctodseum now lies behind it; the bursa
Fabricii is on the point of opening into the highest point of the
proctodseum. Vacuolization of the tissue between the cloacal
membrane and the urodasum indicates its subsequent disappearance.
 
At eleven days (Fig. 186) the general arrangement is essentially the same, but there are important differences in detail.
The bursa Fabricii has now become a long-stalked sac, opening
into the proctodseum at the level of the urodseal membrane.
The latter is still quite a thick plate, but the vacuoles in it fore
 
 
318
 
 
 
THE DEVELOPMENT OF THE CHICK
 
 
 
shadow its final rupture. The lower end of the large intestine
is perfectly solid, and higher up, somewhat vacuolated. (The
solid stage begins on the seventh day.) The urinogenital ducts
open into the urodseum above the solid end of the large intestine.
It will be seen, therefore, that the urodseum is transformed into
a passageway between the urinogenital ducts and the allantois,
being closed anteriorly by the solid large intestine and posteriorly
by the urodseal (cloacal) membrane.
 
 
 
 
Fig. 185. — Photograph of the region of the cloaca in a median sagittal
 
section of an 8-day chick.
 
All., Allantois. An., Anus. B. F., Bursa Fabricii. caud. A., Caudal
artery. Int., Intestine. N'ch., Notochord. p. P., Perianal papilla. Rect.,
Rectum. Ur'd., Urodseum.
 
 
 
During the twelfth and thirteenth days, the vacuoles in the
upper part of the large intestine flow together and re-establish
the cavity, but the lower end still remains closed by a solid plug
of cells; immediately anterior to the latter the large intestine is
dilated, and this apparently corresponds to the coprodaeum of
 
 
 
ALIMENTARY TRACT AXD ITS APPENDAGES
 
 
 
319
 
 
 
the adult cloaca. Even on the seventeenth day the large intestine appears to be still closed at its lower end, and the urodseal
membrane still persists as a plug of vacuolated cells. (Gasser.)
Both plugs must, however, disappear soon after.
 
It would thus appear that the urodgeum only of the adult
cloaca corresponds to the embryonic cloaca; the proctodjeum is
certainly derived from an ectodermal pit, and it is probable that
 
 
 
 
Fig. 186. — Chick embryo of 11 days, sagittal section
 
through the region of the cloaca. Reconstructed from
 
several sections. (After Minot.)
 
All'., Ascending limb of the allantois. AH"., Descending limb of the allantois. An., Anal invagination. An.pl.,
Urodeal membrane. Art., Umbihcal artery. B. F.,
Bursa Fabricii. b. f., Duct of the bursa. Clo., Cloaca.
Ec, Ectoderm. Ent., Entoderm of the rectum. Ly.,
Nodules of crowded cells, probably primordia of lymphoid structures in the wall of the large intestine. W. D.,
Wolffian duct.
 
the coprodseum represents the enlarged lower extremity of the
embryonic large intestine. The bursa Fabricii is an entodermal
structure derived from the posterior portion of the embryonic
cloaca.
 
 
 
IV. The Development of the Liver axd Paxcreas
 
The Liver. The anterior and posterior liver diverticula, described in Chapter VI, constitute the rudiments from which the
 
 
 
320
 
 
 
THE DEVELOPMENT OF THE CHICK
 
 
 
substance of the liver is derived. A third diverticulum is distinguished by Brouha as the right posterior diverticulum; this is
an early outgrowth of the posterior diverticulum. Hepatic cylinders arise from both primary diverticula at an early stage, and
these, branching and anastomosing, soon form a basket-work of
liver tissue around the intermediate portion of the meatus venosus.
The anterior diverticulum alone extends forward to the anterior
 
 
 
 
'M.
 
 
 
Fig. 187. — Reconstruction of gizzard, duodenum,
 
and hepato-pancreatic ducts of a chick embryo
 
^ of 124 hours. (After Brouha.)
 
D. ch., Ductus choledochus. D. cy., Ductus cysticus. D. h. cy., Ductus hepato-cysticus. D. h. d.,
Dorsal or hepato-enteric duct. Du., Duodenum.
G. bl., Gall bladder. Giz., Gizzard. Pa. d., Dorsal pancreas. Pa. v. d.. Right ventral pancreas.
Pa. V. s., Left ventral pancreas.
 
 
 
end of the meatus, and it even encroaches on the sinus venosus, as
we have already seen; in the posterior part of the meatus venosus,
on the other hand, the liver tissue is derived entirely from the
posterior diverticulum. The mesenchyme in the interstices of
the hepatic framework is replaced almost immediately by blood
 
 
ALIMENTARY TRACT AND ITS APPENDAGES 321
 
vessels that empty into the meatus, and thus appear as branches
of the latter.
 
The gall-bladder is a very early formation, arising from the
hindermost portion of the posterior hepatic diverticulum, as a
distinct bud about the stage of 68 hours (Fig. 103), and forming
a pyriform appendage at 84 hours. It may reasonably be regarded as derived from the most posterior portion of the primitive hepatic gutter, an interpretation that agrees with the
condition found in more primitive vertebrates.
 
At the stage of 68 hours (cf. Fig. 103B), the anterior and
posterior diverticula proceed from a common depression of the
ventral wall of the duodenum, the ductus choledochus. By
means of an antero-posterior constriction, the latter becomes
much more clearly defined as development proceeds (Fig. 187);
there arise from it also the right and left ventral primordia of
the pancreas (see below), so that it receives at this stage four
main ducts, viz.: the right and left ventral pancreatic diverticula
and the cephalic and caudal hepatic diverticula. On the sixth
day these four ducts obtain independent openings into the duodenum and the common bile duct thus ceases to exist. The
relations thus established are practically the same as in the
adult.
 
As the caudal hepatic diverticulum grows out it carries the
attachment of the gall-bladder with it, so that the latter is then
attached to the caudal diverticulum, which is thus divided in
two parts, a distal or ductus hepato-cysticus, and a proximal or
ductus cystico-entericus. That portion of the liver arising from
the cephalic diverticulum is thus without any connection with
the gall-bladder. There seem, however, to be anastomoses
between the ductus hepato-cysticus and the original cephalic
duct (ductus hepato-entericus) in the adult, lying in the commissure of the liver; the embryological origin of these appears,
however, to be unknown. In the course of the development,
the openings of the two original ducts into the duodenum come
to lie side by side instead of one behind the other, and the original
cephalic duct (ductus hepato-entericus) appears to be derived
mainly from the left lobe, and the ductus cystico-entericus mainly
from the right lobe of the liver. The actual distribution is, however, by no means so simple; the mode of development of the
lobes of the liver (see below) would explain a preponderant dis
 
 
322 THE DEVELOPMENT OF THE CHICK
 
tribution of the cephalic duct to the left, and the caudal duct to
the right lobe.
 
The liver is primarily an unpaired median organ. Its division
into right and left lobes is therefore secondary and has no fundamental embryological significance. The factors that determine
its definitive external form are the following: (a) the relative
power of growth of its various parts; (6) limitation of its extension to the septum transversum and its connections; (c) the limitations of space in the coelome.
 
Bearing these principles in mind, the growth of the liver
may be described as follows: three primary divisions succeeding one another in a cranio-caudal direction, may be distinguished
at an early stage, viz., an antero-dorsal division, abutting on the
postero-dorsal part of the sinus venosus, formed by the anterior
end of the cephalic hepatic diverticulum; an intermediate division,
surrounding the meatus venosus in which both cephalic and
caudal hepatic diverticula are concerned; and a postero- ventral
division, beneath the posterior end of the meatus venosus and the
right omphalomesenteric vein, formed exclusively by the caudal
diverticulum.
 
The growth of the liver causes expansion of the median mass
of the septum transversum in all directions, excepting anteriorly,
and the substance of the liver extends more or less into all the
connections of the latter, viz., the lateral mesocardia, the lateral
closing plates associated with the umbilical veins, the primary
ventral ligament, the mesentery of the vena cava, the gastrohepatic ligament, and that part of the hepatic portal vein formed
by the right omphalomesenteric vein.
 
At the stage of 96 hours the anterior division spreads
out in the lateral mesocardia behind the Cuvierian ducts nearly
to the lateral body-wall on each side. The intermediate division,
on the other hand, lies largely on the right side of the middle
line, owing to the displacement of the stomach to the left and the
meatus venosus to the right. A small lobe is, however, pushing
itself to the left beneath the gastro-hepatic ligament. The posterior division lies entirely on the right ventral side of the hinder
end of the meatus venosus and right omphalomesenteric vein,
as far back as the dorsal anastomosis. There are, of course,
no sharp lines of demarcation between the divisions, so that in
general it may be said that the liver substance tends more and
 
 
 
ALIMENTARY TRACT AND ITS APPENDAGES 323
 
more to the right side of the body from its fairly symmetrical
anterior end backwards.
 
The lines of development of the liver are thus marked out.
On the sixth day the anterior division is larger on the left than
on the right side, owing no doubt to the incorporation of the sinus
venosus into the right auricle, thus leaving more room for the
liver on the left side. Passing backwards in a series of sections
to the region of the center of the meatus venosus, we find the liver
larger on the right than on the left side, being centered around
the meatus, but a small lobe extends over to the left side A^entral
to the stomach. The posterior division, again, is confined to
the right side and ends in a free right lobe projecting caudally to
the region of the umbilicus. The division of the liver into right
and left lobes thus takes place on each side of its primary median
ligaments, dorsal or gastrohepatic, and primary ventral; expansion being inhibited in the median line by the stomach above and
heart below, it takes place on both sides, but particularly on the
right side where there is more space.
 
The reader is referred to Chapter XI for description of the
origin of the ligaments of the liver and the relations of the liver
to the pericardium and other structures; also to Chapter XII for
description of its blood-vessels.
 
The histogenesis of the liver should be finally referred to.
This organ is remarkable in possessing no mesenchyme in the
embryonic stages (Minot, 1900); but from the start the hepatic
cylinders are directly clothed with the endothelium of the bloodvessels, so that only the thickness of the endothelial wall separates
the hepatic cells from the blood in the sinusoids. The hepatic
cylinders have been described as arising in the form of solid buds
from the primary diverticula; the buds first formed branch
repeatedly, forming solid buds of the second, third, etc., orders,
and wherever buds come in contact they unite, forming thus a
network of solid cylinders of hepatic cells. The solid stage does
not, however, last very long, for on the fifth day it can be seen
that many of them have developed a small central lumen by displacement of the cells. Thus there gradually arises a network
of thick-walled tubes instead of solid cylinders, and the whole
system opens into the primary diverticula from which it arose.
 
The Pancreas. The pancreas arises as three distinct entodermal
diverticula, the origin of which has been already described, and
 
 
 
324
 
 
 
THE DEVELOPMENT OF THE CHICK
 
 
 
has correspondingly in the adult three separate ducts oj^ening
into the duodenum. (Two pancreatic ducts is the rule in Gallus,
according to Gadow in Bronn's Thierreich.) Of the three pancreatic diverticula, the dorsal one arises first (about 72 hours)
then the right ventral slightly earlier than the left ventral
(about 96 hours). The two latter arise from the common
 
 
 
cav./^.
 
 
 
■Pe.d.
 
 
 
Coel.
 
 
 
 
Goel.
 
 
 
^Jie/>.2d
 
 
 
D-Jiej) 2.
 
 
 
V.o.m.s.
 
 
 
Fig. 188. — Transverse section through the duodenum and hepatopancreatic ducts of a chick embryo of 5 days. (After Choronschitzky.)
Ao., Aorta, cav. F., Caval fold. Coel., Coelome. D. hep. 2, 2 a,
2 b, Posterior hepatic diverticulvun and branches of same. Du., Duodenum. Li., Substance of Hver. M'st., Dorsal mesentery. Pa. d.,
Dorsal pancreas. Pa. v. d.. Right ventral pancreas. Pa. v. s., Left
ventral pancreas. Spl., Spleen. V. c. p., Postcardinal vein. V. H.,
Vena lienalis. V. o. m. d.. Right omphalomesenteric vein. V. o. m. s.,
Left omphalomesenteric vein.
 
hepatic diverticulum near its jimction with the duodenum (Fig.
188). The differentiation of the three parts is essentially similar,
and proceeds naturally in the order of their origin. Solid buds
arise from the ends of the diverticula, and these branch repeatedly
in the surrounding mesenchyme, but do not anastomose; the
 
 
 
ALIMENTARY TRACT AND ITS APPENDAGES 325
 
final terminations of the buds form the secreting and the intermediate portions the various intercalated and excretory ducts
that form a branching system opening into the main ducts.
 
The successive stages in the development of the pancreas
may be stated thus (following Brouha): At 124 hours the two
ventral pancreatic ducts pass anteriorly and a little to the left,
crossing the cephalic hepatic duct which lies between them.
They are continued into ramified pancreatic tubes which already
form two considera])le glandular masses. The right ventral
pancreas is united by a very narrow bridge to the dorsal pancreas,
and the latter is moulded on the left wall of the portal vein,
while its excretory duct has shifted on the left side of the duodenum nearer the ductus choledochus. At 154 hours the duct of
the dorsal pancreas is still nearer to the others, and the three pancreatic ducts enter a single glandular mass, the dorsal portion of
which, derived from the primitive dorsal pancreas, is moulded on
the left wall of the portal vein, and is continued into a smaller ventral portion formed by the fusion of the two ventral pancreases..
 
Subsequently, the pancreatic lobes fill up the duodenal loop
(Figs. 179 and 180), and elongate with this so as to extend from
one end of it to the other in the adult; the three ducts open
near the termination of the duodenum (end of distal limb)
beside the two bile ducts.
 
V. The Respiratory Tract
 
The origin of the laryngotracheal groove and the paired
primordia of the lungs w^as described in Chapter VI. At the stage
of 36 somites the laryngotracheal groove includes the ventral
division of the post branchial portion of the pharynx, which is
much contracted laterally so as to convert its cavity into a deep
and narrow groove. This communicates posteriorly with right
and left finger-shaped entodermal diverticula (the entodermal
lung-primordia) extending into the base of the massive pearshaped mesodermal lung-primordia attached to the lateral walls
of the oesophagus. The mesodermal lung-primordia are continuous with the accessory mesenteries, as described in Chapter XI;
and by them attached to the septum transversum.
 
Bronchi. Lungs and Air-sacs. The primitive entodermal
tubes form the primary bronchi, in which two divisions may be
distinguished on each side, viz: a part leading from the end of
 
 
 
326 THE DEVELOPMENT OF THE CHICK
 
the trachea to the hilum of the lung (extra-puhiionary bronchus),
and its continuation within the lung, extending its entire length
(mesobronchus) . All the air passages of the lung, and the airsacs, arise from the mesobronchi by processes of budding and
branching, enlargement of buds to form air-sacs, and by various
secondary anastomoses of branches. The mesobronchi are surrounded from the first by a thick mass of mesenchyme, covered
of course towards the body cavity by a layer of mesot helium.
In the early development the mesenchyme of the lung-primordia
grows so rapidly as to provide adequate space for the branching of the mesobronchi entirely within the mesenchymal
tissue.
 
Although the development of the lungs of the chick was
studied by several earlier investigators, our principal reliance in
this subject rests on the beautiful and complete study by Locy
and his students.
 
We may note the general topographical development as
follows: The expansion of the lungs takes place into the pleural
cavities; they therefore raise themselves from their surfaces of
attachment, oesophagus and pleuroperitoneal membrane, and
project in all directions, but especially dorsally and anteriorly
(Fig. 189). We may thus distinguish free and attached surfaces;
the latter is nearly a plane surface and on the whole ventral in
position, and the free arched surfaces are dorsal. However, it
should be remembered that the pleuroperitoneal membrane
which forms the attached surface, lies at first in a sagittal plane,
and only secondarily becomes frontal. In successive stages, the
attached surface of the lung (pleuroperitoneal membrane)
rotates from a sagittal to an approximately frontal plane (Chap.
XI). An anterior lung lobe grows out in front and dorsal to the
mesobronchus, beginning at six days, and the extra-pulmonary
bronchus thus acquires a ventral insertion into the lung.
 
Stages in the development may be described as follows:
At 96 hours, the bronchi arise from the end of the trachea, ventral to the oesophagus and pass back on either side of the latter,
describing near their centers a rather sharp curve that brings
the dorsal ends to a higher level than the oesophagus. A very
slight dilatation at the extreme end of the mesobronchus is usually
interpreted as the beginning of the abdominal air-sac.
 
 
 
ALIMENTARY TRACT AND ITS APPENDAGES
 
 
 
327
 
 
 
At six days the mesobronchus within the hmg describes a
course nearly parallel to the oesophagus as far as the middle of
the lung; in this part of its course it lies near the median surface and ascends very slightly. About the middle of the lung
it makes a sharp bend, and passes toward the lateral and dorsal
surface of the lung; here it enters a considerable thin-walled
dilatation from which it is continued straight backwards by means
 
 
 
-. ' m\J^!^
 
 
 
^^^'A/
 
 
 
 
■Nes-b.dX ^^;;^
 
 
 
Y.ca.
 
 
 
F-'\^'it
 
 
 
M'
 
 
 
vf
 
 
P6
 
 
 
 
 
 
Fig. 189. — Photograph of transverse section through the lungs of an 8-day
chick embryo.
A. A. d., Right aortic (systemic) arch. D. art. d., s., Right and left ductus
arteriosi. Ent'b.l., Branches of first entobronchus. M. ph pc, Pleuropericardial membrane. Mes'b. d., s., Right and left mesobronchia. (Es.,
(Esophagus. Pc, Pericardial cavity, pi. Cav., Pleural cavity. Rec. p. e. s.,
Left pneumato-enteric recess. V. c. a., Anterior vense cavse.
 
of a second curve, and ends in the same slight thick-walled dilatation that we noted on the fourth day. There are thus three very
distinct divisions of the mesobronchus which we may name the
anterior, the middle, and the posterior.
 
Four evaginations arise on the sixth day from the mesial
 
 
 
328 THE DEVELOPMENT OF THE CHICK
 
wall of the anterior division of the mesobronchus, which is otherwise unbranched. These represent the entobronchi; they arise
in antero-posterior order, and the first is therefore the largest.
The part of the mesobronchus from which they arise will form
the vestibulum of the adult lung.
 
Later on the same day the ectobronchi, six in number, begin
to arise from the dorsal surface of the dilated portion of the
middle division of the mesobronchus. Other independent outgrowths of the same division of the mesobronchus are the
so-called laterobronchi and dorsobronchi (Locy). These four
groups of out-growths may be classed as secondary bronchi (Fig.
191).
 
On the ninth day (Fig. 191) the first entobronchus has formed
a number of branches in the anterior lobe of the lung, and two of
its terminal twigs, one in the antero-dorsal, the other in the anteroventral tip of the lung, are slightly dilated and project as primordia
of the cervical and interclavicular air-sacs respectively. The
second entobronchus is also subdivided several times; its terminal
branches extending to the dorsal surface of the lung. The third
entobronchus bends ventrally, and from its base a narrow canal
extends into the pleuroperitoneal membrane, where it expands
into the anterior thoracic air-sac, which is much the largest of
the air-sacs at this time.
 
Between the eighth and eleventh days, numerous tertiary
bronchi (parabronchi) arise from the secondary bronchi (Fig.
190). These are considerably smaller than the tubes from which
they arise, and are extremely numerous, radiating from all parts
of the secondary bronchi towards the free surfaces and interior
of the lungs. They are embedded in the mesenchyme of the lung,
which is already marked out into areas hexagonal in cross-section,
with the parabronchi in the centers, by the developing pulmonary
blood-vessels.
 
From the twelfth to the eighteenth days parabronchi of different origin meet and fuse in a most extensive fashion, thus forming an intercommunicating net-work of tubes throughout the
lung. Air-capillaries finally arise from the parabronchi in the
centers of the hexagonal areas and form an anastomotic net-work
arising from and surrounding the parabronchi. This completes
the system of tubes arising from the secondary bronchi; but
 
 
 
ALIMENTARY TRACT AND ITS APPENDAGES
 
 
 
329
 
 
 
another system, that of the recurrent bronchi, develops from the
air-sacs which we now go on to consider.
 
 
 
 
Ft.C.
 
 
 
Li Pt.C.
 
 
 
Fig. 190. — Transverse section through the lungs of a chick embryo of 11
 
a. til. A. S., Anterior thoracic air-sac. Ao., Aorta. Aur. d., s., Right and
left auricles. B. d., s., Right and left ducts of Botallus. F., Feather germs.
Li., Liver. P. C, Pericardial cavity, p. p. M., Pleuroperitoneal membrane.
P V , Pulmonary vein. Par'b., Parabronchi. PI. C, Pleural cavity. Pt. C,
Peritoneal cavity. R., Rib. Sc, Scapula. V. d., s., Right and left ventricles.
 
The expanding hmgs nearly fill the pleural cavities on the
eleventh day. Subsequently, the pleural cavity is obliterated
by fusion of the free surfaces of the lungs with the wall of the
pleural cavities. Thus it happens that the dorsal surfaces of the
 
 
 
330
 
 
 
THE DEVELOPMENT OF THE CHICK
 
 
 
lungs of the adult ''have no peritoneal covering," although this
is denied by other authors.
 
The air-sacs are terminal expansions of entobronchi or of the
mesobronchus (Fig. 191). From all of them with the exception
of the cervical sac there grow bronchial tubes which connect with
parabronchi secondarily within the lung proper. Owing to their
method of origin, and also to the fact that the current of air through
them in the functional lung is from the air-sacs, these tubes are
known as recurrent bronchi. The lungs of birds thus differ from
 
 
 
Cerir.S.
-Br.
 
 
 
.I-CLt.TnoC
-Mes.moi
^Bixt. l~Ent.2
-EntA.
 
 
 
 
BcU4--^
 
 
 
Dors.
 
 
 
---i.at.3--'
— HccBr.-
 
 
 
-Abd,S.
 
 
 
Fig. 191. — The air passages of the limg of the chick early on the ninth day
of incubation. A Lateral view; B. Mesial view. (After Locy and Larsell.)
Abd. S., Abdominal Air-sac. Ant. Th. S., Anterior thoracic air-sac. Br.,
Bronchi. Cerv. S., Cervical air-sac. Dors., Dorsibronchi. Ect. 1, Ect. 2,
etc., First to fourth Ectobronchi. Ent. 1, Ent. 2, etc., First to fourth Entobronchi. Lat. 3, Third laterobronchus. Lat. moi.; Mes. moi.. Lateral and
mesial moieties of the interclavicular air-sac. Rec. Br., Recurrent bronchi.
 
those of other vertebrates in having no terminal alveoli, containing residual air; there is instead a system of communicating tubes
through which the air flows.
 
The abdominal air-sacs do not undergo any considerable
expansion until after the eighth day (cf. Fig. 191). Then they
push through the hinder end of the pleuroperitoneal membrane,
now fused with the lateral body- wall, and penetrate the latter
just beneath the peritoneum. About the tenth day they begin
to expand into the abdominal cavity just behind the liver, thus
evaginating the peritoneum. The left sac is somewhat larger
 
 
 
ALIMENTARY TRACT AND ITS \PPENDAGES 331
 
than the right. The expansion goes on lapidly and by the
thirteenth to the fifteenth day they have reached the hinder end
of the body cavity, and have akeady expanded into it so far as
to form fusions with the mesentery. Recurrent bronchi begin
to develop from their base about the ninth day.
 
The cervical sacs appear early from an anterior branch of the first
entobronchus (Fig. 191). They form no recurrent bronchi (Locy).
 
The interclavicular sac, which is single in the adult, arises
from two sacs on each side, a lateral moiety from the first entobronchus, and a mesial moiety from the third. These four parts
fuse to form the single sac of the adult (Locy). These sacs form
recurrent entobranchi.
 
The anterior thoracic sac forms about the seventh day as a
dilatation of the ventral wall of the third entobronchus projecting into the pleuroperitoneal membrane near its median
edge; it thus lies just lateral to the pneumato-enteric recesses.
From this position it expands laterally and posteriorly in the
pleuroperitoneal membrane and thus gradually splits it in two
layers (Fig. 190, 11 days).
 
The posterior thoracic air-sac arises from the third laterobronchus somewhat later than the others, and grows at first
through the hinder portion of the pleuroperitoneal membrane to
enter the lateral body wall. In its subsequent expansion, it splits
the posterior portion of the pleuroperitoneal membrane, as the
anterior thoracic air-sac does the anterior portion of the same
membrane. Anterior and posterior thoracic air-sacs then come
into contact, forming a septum. Both form recurrent bronchi.
 
The lower layer of the pleuroperitoneal membrane, split off
from the upper layer by expansion of anterior and posterior
thoracic air-sacs, constitutes the oblique septmn. The most
posterior portion of the oblique septum, however, is derived from
the peritoneum of the lateral body wall by expansion of the posterior thoracic air-sacs behind the pleuroperitoneal membrane.
 
Like the abdominal air-sacs, ''the remainder expand rapidly,
particularly from the fourteenth day on, among the thoracic
viscera, and fuse intimately with these and the walls of the body
cavity in a few days, the coelomatic fluid being in the meantime
absorbed. The interclavicular air-sac grows out to form the
subscapular air-sac and at the time of hatching has approached
close to the humerus." (Selenka.)
 
 
 
332 THE DEVELOPMENT OF THE CHICK
 
The Laryngotracheal Groove.. The embryonic primordium
of the larynx and trachea communicates at first along its entire
length with the postbranchial division of the pharynx (72 hours).
At 96 hours the hinder portion of the groove is already converted
into a tube lying beneath the anterior end of the oesophagus; this
is the beginning of the trachea; the anterior part of the original
groove represents the larynx, and its opening into the pharynx
the glottis. It is not clear whether the trachea arises as an outgrowth of the hinder end of the laryngotracheal groove, or from
the hinder portion of the groove itself, by constriction from the
pharynx. At 96 hours the lumen of the lower end of the trachea
and adjoining portion of the two bronchi is obliterated by thickening of the walls; this is, however, a very transitory condition.
 
The growth of the trachea in length is extremely rapid, keeping pace, of course, with the elongation of the neck. At six days
the trachea is a long epithelial tube with thick wahs branching into the two bronchi at its lower end. At its cephahc
end the lumen opens into a considerable cavity, representing
the larnyx; the glottis appears to be closed by a plug of
epithelial cells continuous with the sohd wall of the oesophagus.
At eight days the lumen of both larynx and glottis is completely
closed by the thickened epithehum; at eleven days the cavity
of the lower end of the larynx is re-established, and the cell
mass at the upper end is converted into a mesh-work by vacuoUzation; the lips of the glottis still show a complete epithelial
fusion. Thus it is apparent that the cavity of the larynx is estabhshed by the formation of vacuoles within the soUd cell-mass,
and by their expansion and fusion. I cannot say how soon the
glottis becomes open.
 
The development of the laryngotracheal apparatus, including
the cartilages and muscles, has not been specially investigated in
the chick. In general, it can be said that the parts external to the
epithehum arise from the mesenchyme, which begins to condense
around the epithelial tube on the fifth day. On the eighth day
the glottis forms a decided projection into the pharynx. Distinct
cartilaginous rings in the trachea are not visible on the eighth day,
but are well formed on the eleventh day. As regards the syrinx
it has been established by Wunderhch for Fringilla domestica that
the tympanic cartilage arises from the lower tracheal rings. The
origin of the musculature of the syrinx is not known.
 
 
 
==CHAPTER XI  THE BODY-CAVITIES, MESENTERIES AND SEPTUM TRANSVERSUM==
 
The development of these parts is one of the most difficult
subjects in embryologA^ involving, as it does, complex relations
between the viscera, vascular system, and primitive body-cavity,
on which the definitive relations of the bodv-cavities and mesenteries depend.
 
The pericardial and pleuro peritoneal cavities are completely
separated in all vertebrates excepting Amphioxus, cyclostomes
and some Selachii and ganoids, in which narrow apertures exist
between the two. The pleural and peritoneal divisions of the
coelome of the trunk communicate widely in amphibia; among
reptiles completely closed pleural cavities are found apparently
only in Crococlilia; in birds and mammals they are completely
closed.
 
As we have seen, in the early embryo of the chick there is
free communication between all parts of the body-cavity. We
have to consider, therefore, (1) the separation of the pericardial
and pleuro peritoneal cavities, (2) the separation of pleural and
peritoneal cavities, and (3) development of the mesenteries.
 
I. The Separation of the Pericardial and Pleuroperi
TONEAL Cavities
 
The pericardial cavity proceeds from the cephalic division of
the primitive coelome (parietal cavity of His). We may review
its primitive relations as follows (stage of 10 somites; see Chap.
V) : it contains the heart which divides it into right and left
parts so long as the dorsal and ventral mesocardia persist; these,
however, disappear very early. Laterally, the parietal cavity
communicates with the extra-embryonic body-cavity (Figs. 53
and 54) ; posteriorly it is bounded by the wall of the anterior
intestinal portal (Fig. 67), on which the heart is seated like a
 
333
 
 
 
334 THE DEVELOPMENT OF THE CHICK
 
rider in his saddle, the body of the rider being represented by
the heart, and his legs by the omphalomesenteric veins. On
each side of this posterior wall the parietal cavity communicates
with the coelome of the trunk. The floor of the parietal cavity
comprises two parts meeting at the head-fold, the anterior part
being composed of somatopleure, and the posterior part of
splanchnopleure; the former is part of the definitive pericardial
wall, the latter, known as the precardial plate, is provisional
 
(Fig! 67).
 
The lateral mesocardia also take part in boundmg the parietal
cavity. It will be remembered that these arise as a fusion on
each side between the somatopleure and the primitive omphalomesenteric veins, and that the ducts of Cuvier develop in them.
As the blastoderm is spread out flat at the time that they form,
they constitute at first a lateral boundary to the posterior part
of the parietal cavity; but as the embryo becomes separated from
the blastoderm they assume a frontal position between the sinus
venosus and body-wall, tne original median face becoming dorsal
and the lateral face ventral. Thus they come to form a dorsal
wall for the posterior part of the parietal cavity (Fig. 119). The
communication of the parietal cavity with the ccelome of the
trunk is thus divided into two, known respectively as the dorsal
parietal recess and the ventral parietal recess. The former is
a passageway above the lateral mesocardia, communicating in
front with the parietal (pericardial) cavity and behind with the
trunk cavity; the latter is a communication on each side of the
wall of the anterior intestinal portal ventral to the lateral mesocardia.
 
The completion of the posterior wall of the pericardium is
brought about by the formation and development of the septum
transversum.
 
Septum Transversum. The septum transversum arises from
three originally distinct parts, viz., (1) a median mass, (2) the
lateral mesocardia, and (3) lateral closing folds arising from
the body-wall between the uml:)ilicus and the lateral mesocardia.
 
1. The median mass proceeds from the ventral mesentery
of the fore-gut. The location of the heart and liver in the ventral
mesentery divides it in three parts, viz., (a) a superior part,
comprising the mesocardium and dorsal ligament of the liver
(gastrohepatic ligament), uniting the floor of the fore-gut and
 
 
 
THE BODY-CAVITIES
 
 
 
335
 
 
 
the heart and Uver, (h) a median portion comprising the sinus
venosus, ductus venosus and Hver, and (c) an inferior portion.
Tlie superior part persists in the region of the sinus venosus and
liver, and the inferior part only as the primary ventral ligament
of the liver.
 
The median mass of the septum transversum thus includes
the sinus venosus, liver, and dorsal and ventral ligaments of the
liver.
 
At sixty hours the median mass includes chiefly the sinus
and ductus venosus and their mesenteries. At eighty hours
(Fig. 192) a constriction begins to appear between sinus and
 
 
 
 
Fig. 192. — Reconstruction of the septum transversum and
associated mesenteries of a chick embryo of 80 hours. (After
Ravn.)
Ao., Aorta. Int., Intestine. Liv., Liver. PI. m'g., Plica
 
 
 
mesogastrica.
 
 
 
S.V., Sinus venosus.
 
 
 
ductus venosus, and the walls of the latter are expanded by the
formation of liver tissue, so that the cylindrical form characteristic of sixty hours is lost, and the lateral walls of the ductus
venosus bulge considerably. The continued growth of the liver
causes a rapid lateral expansion of this portion of the septum
transversum (Fig. 193 A).
 
The primary ventral ligament of the liver is included within
the wall of the anterior intestinal portal up to al)out eighty hours.
But, as the volk-sac shifts farther back, this ligament appears
as a separate membrane (inferior part of the primary ventral
 
 
 
336
 
 
 
THE DEVELOPMENT OF THE CHICK
 
 
 
 
Fig. 193. — Reconstruction of the septum transversum and
associated mesenteries of a chick embryo of 5 to 6 days. (After
 
Ravn.)
 
A. Entire.
 
B. After removal of the liver and sinus venosus.
 
A., Aorta, ac. M., Accessory mesentery. cav. F., Caval
fold. coel. F., Coeliac fold. Her., Hiatus communis recessum. Int., Intestine. Lg., Lung. Liv., Liver, m. p., Pleuropericardial membrane, pvl., Primary ventral ligament of the
hver. Sv., Sinus venosus.
 
mesentery), uniting the ventral and posterior face of the liver
 
to the body-wall just in front of the umbilicus (Fig. 193 A, pvl.).
 
For the purposes of these figures the body-wall is cut away.
 
Nevertheless, it can be seen that the pericardial cavity commiuii
 
 
THE BODY-CAVITIES 337
 
cates with the peritoneal cavity around the median mass of the
septum transversum beneath the kiteral mesocardia.
 
2. The lateral mesocardia constitute the second component
of the septum transversum. At the stage of sixty hours they
are nearly round in section. At eighty-six hours the substance
posterior to the duct of Cuvier begins to thicken (Fig. 192) so
that the section is no longer round but elongated towards the
umbilicus. They still extend almost transversely to the lateral
body-wall. However, the retreat of the heart backwards soon
changes their direction (Fig. 193 A) so as to form a long oblique
partition between the pericardium and the dorsal parietal recess,
the direction of the ducts of Cuvier being changed at the same
time. The lateral mesocardia are directly continuous with the
anterior portion of the median mass of the septum transversum.
 
3. The lateral closing folds arise as ridges of the lateral bodywall extending obliquely from the primary ventral ligament of
the liver upwards and forwards to the lateral mesocardia. They
arise along the course of the umbilical veins which open at first
into the ducts of Cuvier. As the lateral closing folds develop
first at their anterior ends, they appear as direct backward
prolongations of the lateral mesocardia. They fuse with the
lateral ventral surface of the liver (median mass of the septum
transversum), and when they are completed back to the primary
ventral ligament of the liver, they completely close the ventral
communication of the pericardium with the peritoneal cavity.
They mark out a triangular area on the cephalic face of the liver
with postero-ventral apex and antero-dorsal base, which forms
the median portion of the posterior wall of the pericardium (cf.
Fig. 193 A). At six days the ventral communication of the
pericardium is reduced to a very small opening, and at eight days
it is entirely closed.
 
Closure of the Dorsal Opening of the Pericardium. As already
noted the pericardial cavity communicates with the peritoneal
cavity above the lateral mesocardia by way of the dorsal
parietal recesses, which are destined to form a large part of the
pleural cavities. We have, therefore, to consider next the closure
of the aperture between the pleural and pericardial cavities.
We have already seen that the heart shifts backwards very rapidly
between the third and sixth days, and this draws out the lateral
mesocardia in an oblique plane directed from dorsal anterior to
 
 
 
338 THE DEVELOPMENT OF THE CHICK
 
ventral posterior (Fig. 193); the ducts of Ciivier thus become
oblique also, and the lateral mesocardia become converted into
an oblique septum between the posterior parts of the incipient
pleural cavities and the pericardial cavity (pleuro-pericardial
membrane). In front of the sinus venosus, however, the pleural
and pericardial cavities communicate with one another between
the ducts of Cuvier, which form a projection from the lateral
body-wall, and the bronchi which project laterally beneath the
oesophagus. These apertures are gradually closed by fusion of
the walls of the bronchi with the projecting duct of Cuvier, beginning in front and extending back to the sinus venosus. Thus the
incipient pleural cavities come to end blindly in front, though
they still communicate widely behind with the peritoneal cavity.
The membrane thus established between pleural and pericardial
cavities is know^n as the pleuro-pericardial membrane.
 
Establishment of Independent Pericardial Walls. With the
formation of the ventral body-wall the precardial plate (a portion
of the splanchnopleure, which at first forms part of the floor of
the pericardial cavity) is gradually replaced by the ventral bodywall. The pericardial cavity is thus bounded ventrally and
laterally by the body-wall and posteriorly by the median mass
of the septum transversum. It has no independent walls at
first. The definitive pericardium is, however, a membranous
sac, and this is formed by two main processes: in the first place
the membrane of the anterior face of the liver (median mass of
the septum transversum) which forms the posterior boundary
of the pericardium becomes much thickened, and gradually
splits off from the liver (cf. Figs. 148 and 150), the peritoneal
cavity extending pari passu between the liver and the membrana
pericardiaco-peritoneale thus formed. The suspensory ligament
of the liver, however, remains in the middle line, and the membrane is also directly continuous w^ith the liver dorsally around
the roots of the great veins. Thus a membranous wall is established for the posterior part of the pericardium. In the second
place the peritoneal cavity extends secondarily into the bodywall bounding the pericardium ventrally and laterally, and thus
splits a membranous pericardial sac oE from the body-wall. In
this process the liver appears to play an active role. At least
its anterior lobes occupy the peritoneal spaces thus established
(Fig. 194). In the mammals, on the other hand, it is the ex
 
 
THE BODY-CAVITIES
 
 
 
339
 
 
 
tension of the pleural cavities ventrally that splits the membranous pericardium from the body-wall.
 
Derivatives of the Septum Transversum. From the preceding
account it will be seen that the following are derivatives of the
septum transversum: (1) The posterior part of the pericardial
membrane. (2) The pleuro-pericardial membrane. (3) The liver
with its vessels and gastro-hepatic and primary ventral ligaments.
 
 
 
 
Fig. 194. — Photot;raph of a transverse section of an 8-day chick.
 
abd. A. S., Abdominal air-sac. A. coel., Coeliac artery. Ao., Aorta.
A. o. m., Omphalomesenteric artery. Aiir. d., Right auricle. Cav. pc,
Pericardial cavity. M. D., Miillerian duct. M. pc, Membranous pericardium. Msn., Mesonephros. Pr'v., Proventriculus. S., Septum ventriculorum. V. c. i., Vena cava inferior. V. h. d., Right hepatic vein. V. d.,
Right ventricle. V. s., Left ventricle.
 
(4) A small part of the heart (the sinus venosus). As regards
the last, it should be noted that the anterior portion of the original
septum transversum is gradually constricted from the major
posterior portion and becomes established as the sinus venosus;
 
 
 
340 THE DEVELOPMENT OF THE CHICK
 
this subsequently becomes incorporated in the right auricle of
the heart. (See Chap. XII).
 
II. Separation of Pleural and Peritoneal Cavities; Origin
OF THE Septum Pleuro-peritoneale
 
The pleuro-peritoneal septum arises from the so-called accessory mesenteries, the origin of which must now be described.
At first the septum transversum has only a median dorsal mesentery, viz., the superior part of the primary ventral mesentery
that unites the septum transversum to the floor of the fore-gut,
and so by way of the dorsal mesentery of the latter to the dorsal
body-wall. Subsequently, however, there arises a pair of mesenteries extending from the lateral wall of the cesophagus to the
septum transversum. These are the accessory mesenteries, and
they arise as follows: about the sixtieth hour they appear as
mesenchymatous outgrowths, forming elongated lobes, projecting
from the side walls of the oesophagus opposite the hind end of
the lung rudiments. The right and left lobes are practically
the same size at first and they bend over ventrally and soon fuse
with the median mass of the septum transversum, represented
at this time by the sinus and meatus venosus (cf. Figs. 118-120,
Chap. VI). Thus are produced a pair of bays of the peritoneal
cavity ending blindly in front, bounded laterally by the accessory
mesenteries, and in the median direction by the intestine and
its mesenteries. These are the pneumato-enteric recesses.
 
These bays have received different names from the various authors:
thus His named only the right one as recessus superior sacci omenti;
the left one being practically absent in mammals; Stoss called both recessus pleuro-peritoneales ; :\Iall called them gastric diverticula; Hochstetter, recessus pulmo-hepatici ; Maurer, bursa hepatico-enterica ; Ravn,
recessus superior for the right one and recessus sinister for the left. We
may call them the pneumato-enteric recesses (recessus pneumato-enterici) ,
following Broman.
 
At seventy-two hours the entodermal lung-sacs extend to
the base of the accessory mesenteries, ending at the anterior
end of the pneumato-enteric recesses. On the left side at this
time the recess is fully formed back to near the anterior end of
the cephalic hepatic diverticulum, on the right side considerably
farther back; that is, the accessory mesentery is already longer
on the right than on the left side, and the mesenchymatous lobe
 
 
 
THE BODY-CAVITIES 341
 
from which it arises (pUca mesogastrica, Broman) can be traced
back, shifting its attachment to the dorsal mesentery, as far as
the anterior intestinal portal and a little farther (Fig. 192, cf.
also Fig. 120).
 
At ninety-six hours the entodermal lung-sacs extend far into
the accessory mesenteries, and thus lie laterally to the pneumatoenteric recesses. On the left side the accessory mesentery ceases
opposite the tip of the lung, but on the right side it is continued
back by the mesentery of the vena cava as far as the middle of
the stomach, and in this region its ventral attachment is to the
superior lateral angle of the liver.
 
The growth of the lung-sacs into the accessory mesenteries
divides the latter into three parts, viz., a superior portion uniting
the lung to the dorsal mesentery, a median portion enclosing the
lung, and an inferior portion uniting the lung-sacs to the median
mass of the septum trans versum. Now, as the liver expands
laterally the ventral attachment of the accessory mesentery is
carried out towards the lateral body-wall, inasmuch as its attachment is to the lateral superior face of the liver (cf. Fig. 231, Chap.
XIII). Thus the accessory mesenteries are gradually shifted
from their original almost sagittal plane to a plane that is approximately frontal. The developing lungs project dorsally from the
accessory mesenteries, which may now be called the pleuroperitoneal membranes, into the pleural cavities (Fig. 189); and
the latter communicate with the peritoneal cavity onl}^ laterally
to the liver. These communications are then soon closed by a
fusion betw^een the lateral edges of the pleuro-peritoneal membrane and the lateral body-wall; this fusion is not completely
established on the eighth day, but it is on the eleventh day.
 
In reptiles and mammals the so-called mesonephric mesentery plays
an important part in the closure of the pleural cavities. It arises from
the apex of the mesonephros at its cephalic end, and fuses with the septum
transversum. It thus forms a partition between the hinder portion
of the pleural cavity and the cranio-lateral recesses of the peritoneal
cavity. Subsequently, in mammals, its posterior free border fuses with
the caudal bounding folds of the pleural cavity that arise as forwardly
directed projections from the accessory mesentery on the right side
and the wall of the stomach on the left. Hochstetter states that such
a mesonephric fold is found in the chick but that it does not appear to
play any essential part in the formation of the septum pleuro-peritoneale.
 
 
 
342 THE DEVELOPMENT OF THE CHICK
 
I find it in the chick as a very minute vestige at the cranial end of the
mesonephros associated with the funnel of the Miillerian duct. It aids
in the final closure of the pleural cavity by bridging over the narrowchink between the lateral angle of the pleuro-peritoneal membrane and
the lateral body-wall. (See Bertelli, 1898.)
 
The oblique septum of birds arises as a layer split off from
the septum pleuro-peritoneale (pulmonary aponeurosis or pulmonary diaphragm of adult anatomy) by the expansion of the
anterior and posterior thoracic air-sacs within it. This mode
of formation is clearly seen, particularly on the right side, in a
series of transverse sections of a chick embryo of eleven days
(Fig. 190). Thus the cavity between the oblique septum and the
pulmonary diaphragm (cavum sub-pulmonale of Huxley) is not
a portion of the bodv-cavitv and bears no relation to it. The
ingrowth of muscles into the pulmonary diaphragm can be
observed in the same series of sections. It begins on the tenth
day according to Bertelli.
 
HI. The Mesenteries
 
The dorsal mesentery is originally a vertical membrane
formed by reduplication of the peritoneum from the mid-dorsal
line of the body-cavity to the intestine; mesenchyme is contained
from the outset between its peritoneal layers, and serves as the
pathway for the development of the nerves and blood-vessels
of the intestine. In the course of development, its lower edge
elongates with the growth of the intestine, and is thrown into
folds, or twisted and turned with the various folds and turnings
of the intestine. Detailed studies of its later development in the
chick have not been published, but the principal events in its
history are as follows: For convenience of description the dorsal
mesentery may be divided into three portions corresponding to
the main divisions of the alimentary tract, viz., an anterior
division belonging to the stomach and duodenum, sometimes
known as the mesogastrium; an intestinal division belonging to
the second loop of the embryonic intestine that descends into
the umbilicus; and a posterior division belonging to the large
intestine and rectum. Inasmuch as the duodeno-jejunal flexure
(Figs. 179 and 180, X) retains from an early stage a short
mesenterial attachment, there is quite a sharp boundary in the
chick between the first and second divisions of the dorsal
 
 
 
THE BODY-CAVITIES 343
 
mesentery. The mesogastriiim becomes modified b}- the displacement of the stomach, the outgrowth of the duodenal loop,
the formation of the omentum, and by the development of the
pancreas and spleen in it. (See below.)
 
The second division of the mesentery is related to the longest
division of the intestine, but as this arises from a relatively very
small part of the embryonic intestine, its dorsal attachment is
short and the roots of the mesenteric arteries are grouped
together. The third division is relatively long and not very
deep; at its base it approaches near to the mesogastrium, to
which it is attached by the root of the intermediate division.
 
The Origin of the Omentum (mainly after Broman). In a
preceding section we saw that the accessory mesentery is continued back on the right side (at the stage of seventy-two hours)
by a fold of the dorsal mesentery of the stomach known as the
plica mesogastrica (Fig. 120). The stomach is already displaced
somewhat to the left, hence the dorsal mesentery is bent also,
and the plica mesogastrica arises from the angle of the bend
(Fig. 120). The ventral mesentery of the stomach, including
the meatus venosus and liver, remains in the middle line. Thus
the bodv-cavitv on the right of the stomach is divided into two
main divisions, viz., the general peritoneal cavity lateral to the
plica mesogastrica and liver, and another cavity between the
plica mesogastrica and liver on the one hand, and the stomach
on the other; the latter cavity has two divisions, a dorsal one
between the plica mesogastrica and upper half of the stomach
(recessus mesenterico-entericus) and a ventral one between the
liver (meatus venosus) and stomach (recessus hepatico-entericus),
which are continued anteriorly into the pneumato-enteric recesses.
Subsequently, they Ijecome entirely shut off from the peritoneal
cavity, but at present (stage of Fig. 120) they communicate
with it by a long fissure bounded by the accessory mesentery in
front, by the plica mesogastrica above, and the meatus venosus
below; this opening may be called the hiatus communis recessum;
it corresponds to the foramen of Winslow of mammals (cf. Fig.
193 A).
 
As development proceeds, a progressive fusion of the right
dorsal border of the liver with the plica mesogastrica takes place
in a cranio-caudal direction, thus lessening the extent of the^
hiatus.
 
 
 
344 THE DEVEL0P:\IEXT OF THE CHICK
 
At about ninety-six hours, the pUca mesogastrica divides to
form two longitudinal folds, in the lateral one of which the vena
cava inferior develops (cf. Fig. 193 B) ; it is hence known as the
caval fold; the more median division is the coeliac fold including
the coeliac arter}^ Between them is a subdivision of the recesses
known as the cavo-coeliac recess, which corresponds to the atrium
burs£e omentalis of mammals. The fusion of the right lateral
border of the liver continues along the course of the caval fold,
and the vena cava inferior is soon completely enveloped in liver
tissue. Behind the point where the vena cava inferior enters
the liver, the latter fuses with the ventral edge of the right mesonephros, thus progressively diminishing the opening of the collective recesses into the peritoneal cavity. At about the one hundred and sixtieth hour, the fusion reaches the portal vein, and the
recesses are thus completely shut off from the peritoneal cavity.
Thus a lesser peritoneal cavity is completely separated on the
right side of the body from the main cavity; and from the former
both lesser and greater omental spaces develop on the right and
left sides respectively of the coeliac fold. (Bursa omenti minoris
and bursa omenti majoris of the bursa omentalis dextra.)
 
The communication of the lesser and greater omental spaces
in front of the coeliac fold is closed by fusion of the latter with
the right side of the proventriculus at about the one hundred
and sixtieth hour, though it remains open throughout life in some
birds. The two omental spaces are also elongated in a posterior
direction by the caudal prolongation of the right lobe of the liver
and of the gizzard respectively (Fig. 195). The lateral wall of
the omentum minus is attached to the lateral dorsal border of
the right lobe of the liver as already described, and it is therefore
carried back by the elongation of this lobe; but as the vena cava
inferior is inserted about the middle of this wall and cannot be
drawn back, it results that there is a deep median indentation
of the lateral wall of the omentum minus, at the bottom of which
lies the vena cava inferior.
 
The condition of both right and left omental spaces at 154
hours is shown in Figures 195 and 196. Subsequently, about the
eleventh day, the mesogastrium behind the spleen becomes perforated, and the greater omental space thus opens secondarily
into the left side of the body-cavity. A true omental fold exists
only for a short time in the development of the chick, and is
 
 
 
THE BODY-CAVITIES
 
 
 
345
 
 
 
soon taken up by the caudal elongation of the stomach. Obliteration of the cavity of the omentum by fusion of its walls takes
place at its caudal end. (Broman.)
 
Spaces corresponding to the omental cavities are also formed
on the left side of the body, but they are of much less extent.
(See Fig. 196.) The communication of these spaces with the
greater peritoneal cavity is not, however, shut ofT as on the right
side. However, a secondary and later fusion of the left lobe
of the liver with the lateral body-wall, and of the gizzard with
 
 
 
 
-rBr
 
 
 
Doniin
 
 
 
Her-
 
 
 
Du
 
 
 
-Giz
 
 
 
-Bomd/'
 
 
 
Fig. 195. — Recon.struction of the omental space of a chick embryo of 154
 
hours from the right side. (After Broman.)
 
Bomaj., Bursa omenti majoris. Bomin., Bursa omenti minoris. Du.,
Duodenum. Giz., Gizzard. Her., Hiatus communis recessum. oe., (Esophagus, rBr., Right bronchus. Rpedx., Right pneumato-enteric recess.
 
 
 
the ventral body-wall does isolate a portion of the peritoneal
cavity from the remainder on the left side. Into this the pneumato- and hepato-enteric cavities of the left side open; however,
it is obvious that this space is not analogous to the omental
spaces on the right.
 
Origin of the Spleen. The spleen arises as a proliferation from
the peritoneum clothing the left side of the dorsal mesentery
just above the extremity of the dorsal pancreas. This proliferation forms the angle of a cranio-caudal fold of the dorsal mesentery which is caused by the displacement of stomach and intestine
 
 
 
346
 
 
 
THE DEVELOPMENT OF THE CHICK
 
 
 
to the left side of the body-cavity (Fig. 188), and which is
exaggerated by the rapid growth of the dorsal pancreas (Choronschitzky). The spleen is thus genetically related to the wall of
the great omentum, and lies outside the cavity of the latter.
The cells of the spleen are proliferated from a peritoneal thickening, which may be compared in this respect to the germinal
epithelium. It is recognizable at ninety-six hours, and the mass
formed by its proliferation grows rapidly, forming a very considerable projection into the left side of the body-cavity above
the stomach, at six days (cf. Fig. 197).
 
 
 
Rpesi)i
 
 
 
 
Du-^^_
 
 
 
R/ie>-iii
 
 
 
— Bomaj
 
 
 
Fig. 196. — The same model from the left side. (After Broman.)
Hrpesin., Hiatus recessus pneumato-entericus sinister. 1. Br.,
Left bronchus. Pr'v., Proventriculus. Rhesin., Recessus hepatoentericus sinister. Rpesin., Right pneumato-enteric recess. Other
abbreviations as in Fig. 195.
 
According to Choronschitzky, the peritoneal cells invade the
neighboring mesenchyme, and, spreading through it, form an illdefined denser area, the fundamental tissue of which is therefore
mesenchymal. The meshes of the latter are in immediate continuity with the vena lienalis, but the vascular endothelium is
 
 
 
THE BODY-CAVITIES
 
 
 
347
 
 
 
not continued into these meshes. Thus free embryonic cells
of the primordium of the spleen enter the venous circulation
directly, and become transformed into blood-corpuscles.
 
On account of the intimate relation between the pancreas and spleen
in early embryonic stages, certain authors (see esp. Woit) have asserted
a genetic connection, deriving the spleen from the pancreas. There
is, however, no good evidence that the relation is other than that of
propinquity.
 
 
 
' Gon.
 
 
 
A.o.fn.
 
 
 
 
Fig. 197. — Photograph of transverse section through a chick embryo of
8 days.
A. o. m., Omphalomesenteric artery. Du., Duodenum. Giz., Gizzard.
Gon., Gonad. II., Ihum. M. D., Miillerian duct. Pc, Pancreas. V. umb.,
Umbilical vein.
 
It should also be noted that the absence of rotation of the
chick's stomach (as contrasted with mammals) and the lesser
development of the great omentum appear to be the causes of
the more primitive position of the spleen in birds as contrasted
with mammals.
 
 
 
==CHAPTER XII THE LATER DEVELOPMENT OF THE VASCULAR SYSTEM==
 
 
 
 
I. The Heart. (For an account of the earlier development,
 
see Chapters V and VI.)
 
At the stage of seventy-two hours (Fig. 198), the ventricle
consists of a posterior transverse portion and two short parallel
limbs; the right limb is continuous with the bulbus arteriosus
 
from which it may be distinguished by
a slight constriction, and the left limb
with the atrium. The constriction between the latter is the auricular canal.
Between the two limbs in the interior
of the ventricle is a short bulbo-auricular septum separating the openings of
bulbus and atrium into the ventricle. A
slight groove, the interventricular sulcus,
that extends backwards and to the right
from the bulbo-auricular angle, marks
the line of formation of the future interventricular septum (Fig. 199).
 
The Development of the External
Form of the Heart. We have seen that
in the process of development the heart
shifts backwards into the thorax. The ventricle undergoes the
greatest displacement, owing to its relative freedom of movement, and thus comes to lie successively to the right of, and then
behind the atrium. A gradual rotation of the ventricular division
on its antero-posterior axis accompanies its posterior displacement;
and this takes place in such a way that the bulbus is transferred
to the mid-ventral line, where it lies between the auricles (Figs.
 
199 and 200).
 
The auricles arise as lateral expansions of the atrium, the
 
348
 
 
 
Fig. 198. — Ventral view of
the heart of a chick embryo of 2.1 mm. head
length. (After Greil from
Hochstetter.)
 
Atr., Atrium. B. co.,
Bulbus cordis, b. V., The
constriction between bulbus
and ventricle. C. au. v., Auriculo-ventricular canal. V.,
Ventricle.
 
 
 
LATER DEVELOPMENT OF VASCULAR SYSTEM
 
 
 
349
 
 
 
left one first at an early stage and the right one later. The left
auricle is thus larger than the right for a considerable period of
time in the early development. When the right auricle grows
out it passes above the bulbus, which is already in process of
rotation, and the two auricles then expand ventrally on each
side of the bulbus. The apex of the ventricle belongs primarily
to the left side and this remains obvious as long as the external
interventricular groove exists. In the adult the apex of the
heart belongs to the left ventricle.
 
 
 
 
Fig. 199. — Ventral view of the heart of a
 
chick embryo of 5 mm. head-length.
 
(After Masius.)
 
Atr. d., s., Right and left auricles.
B. Co. Bulbus cordis. V. Ventricle.
 
 
 
The varying positions occupied by the chambers of the heart in relation to the body axes constitute a serious difficulty in describing the
development. For instance, the auricular canal is at first in front of
the atrium (before any bending of the heart takes place). As the ventricular loop turns backward and beneath the atrium, the auricular
canal is ventral to the atrium ; and finally, as the ventricles assume their
definitive position behind the auricles, the derivatives of the auricular
canal (auriculo-ventricular openings) come to lie behind the atrium. In
other words, the atrium rotates around a transverse axis through nearly
180 degrees in such a way that its original anterior end becomes succes
 
 
350
 
 
 
THE DEVELOPMENT OF THE CHICK
 
 
 
sively ventral and posterior. The definitive ventral surface of the heart
is a cranial rather than a ventral surface during the critical period of
development described below, up to eight days (cf. Figs. 148 and 150).
In other words, the apex of the heart is directed ventrally rather than
posteriorly, though it has a posterior inclination. For simplicity of description, however, it seems better to use the definitive orientation in the
following account; that is, to regard the apex of the heart as posterior
instead of ventral, and the bulbus face of the heart as ventral instead
of cranial, in position.
 
 
 
 
Fig. 200. — Ventral view of the heart of a
chick embryo of 7.5 mm. head-length. (After
 
Masius.)
 
Atr. d., s., Right and left auricles. B. Co.,
Bulbus cordis. V., Ventricle.
 
 
 
Division of the Cavities of the Heart. The embryonic
heart is primarily a single continuous tube; during development
a complex series of changes brings about its complete division
into right and left sides, corresponding to the pulmonary and
systemic circulations. Partitions or septa arise independently
in each primary division of the cardiac tube, excepting the sinus
venosus, and subsequently these unite in such a way as to make
two independent circulatory systems. During this time the
 
 
 
LATER DEVELOPMENT OF VASCULAR SYSTE:\r 351
 
appropriate valves are formed. We have thus to describe the
origin of three primary septa, viz., the interauricular septum,
the interventricular septum, and the septum of the truncus and
bulbus arteriosus. These do not, however, themselves unite
directly, but are joined together by the intermediation of a fourth,
large, cushion-like septum formed in the auricular canal, i.e., in
the opening between the primitive atrium and ventricle.
 
In general it may be said that the development of the three
primary septa takes place from the periphery towards the center,
i.e., towards the cushion-septum of the auricular canal, and that
it is practically synchronous in all three, though there is a slight
precedence of the interauricular septum. During the same time
the cushion-septum of the auricular canal is formed. We may
then consider first the origin of these septa separately, and second
their union.
 
(o) The Septum Trunci et Bulbi Arteriosi (Septum AorticoPulmonale). This septum divides the truncus and bulbus arteriosus into two arteries, the aorta and pulmonary artery. Three
divisions may be distinguished, viz., a part in the truncus arteriosus, a part in the distal division of the bulbus extending to
the place of formation of the semilunar valves, and a part in the
proximal portion of the bulbus, which subsequently becomes
incorporated in the ventricles. In mode of formation these are
more or less independent, though they unite to form a continuous
septum.
 
The septum of the truncus arteriosus arises on the fifth day
as a complete partition extending from the cephalic border of
the two pulmonary arches into the upper portion of the bulbus
arteriosus; the blood current flowing through the bulbus that
passes behind this partition enters the pulmonary arches exclusively, that passing in front enters the two remaining pairs of aortic
arches. During the latter half of the fifth day and on the sixth
day the septum of the truncus is continued into the proximal portion of the bulbus and divides it in two stems. Here, however,
it co-operates with three longitudinal ridges of the endocardium
of the bulbus, one of which is in the direct line of prolongation of the septum of the truncus, which therefore is continued
along this one and between the other two as far as the place of
formation of the semilunar valves (Fig. 201). The entire septum
thus formed has a slightly spiral course, of such a nature that
 
 
 
352
 
 
 
THE DEVELOPMENT OF THE CHICK
 
 
 
 
 
,
 
 
. AS. So p.
 
 
/
 
 
/^
 
 
(^S)
 
 
1
 
 
w
 
 
A.Sao.p.
 
 
 
Fig. 201. — A. Section through the
truneus arteriosus of an embryo of 5
mm. head-length.
B. Section through the distal portion of the bulbus arteriosus of the
same embryo. (After Greil.)
 
A., Aorta. P., PulmonaHs. A. S. ao
 
 
 
the pulmonalis, which lies dorsal to the aorta distally, is gradually
transposed to its left side. The third division of the aorticpulmonary septum arises near the opening of the bulbus into
the ventricle in the form of two ridges of the endocardium on
the right and left sides respectively of the bulbus, the pulmonary
 
division lying ventral and the
aortic division dorsal to the
incipient partition. A third
slight endocardial ridge of the
proximal part of the bulbus is
described (Hochstetter, Greil)
at this stage, but it soon disappears. The proximal bulbus
ridges may be seen on the fifth
day; on the sixth day they are
well formed; on the seventh day
they have united to form a partition w^hich becomes continup., Plane of the septum aortico-pulmo- qus with the partition in the
 
nale. 1, 2, and 3, Ridges prolonging DOrtion of the bulbus.
 
the septum aortico-pulmonale. ^tlStai poition oi ine u.uuus.
 
■ Thus the separation of the aortic and pulmonary trunk is completed down to the ventricle.
 
The semilunar valves arise by excavation of three endocardial thickenings in each trunk formed at the caudal end of the
distal division of the bulbus (Hochstetter, Greil). The origin
of these thickenings is as follows. Both the aortic and pulmonary
trunks receive one each of the original endocardial ridges of the
distal portion of the bulbus owing to the course of the aorticpulmonary septum. Each also receives half of the ridge along
which the septum of the truneus is prolonged. A third ridge
arises subsequently in each between these two. A cavity then
arises in each ridge and opens distally into the aorta and pulmonary artery respectively, thus forming pockets open in front.
These valves are fully formed at eight days.
 
The aortic-pulmonary septum becomes thick early in its
history and the muscular layers of the vascular trunks, which
at first form a common sheath for both, gradually constrict into
the septum, and separate when the constriction brings them
together, so that each vessel obtains an independent muscular
wall. Subsequently, a constriction extends from the outer layer
 
 
 
LATER DEVELOPMENT OF VASCULAR SYSTEM 353
 
of the truncus and bulbus along the entire length of the septum,
and thus completely separates the aorta and pulmonary arteries
from each other. On the eighth day each vessel has independent
muscular walls, and the external constriction has made some
progress.
 
(6) The Interventricular Septum. As noted before, the interventricular sulcus that extends from the bulbo-auricular angle
towards the apex of the heart marks the line of development of
the interventricular septum. The right division of the primitive
ventricle is therefore continuous with the bulbus and the left
with the atrium. However, the partition, bulbo-auricular septum, which at first separates the primitive right and left limbs
of the ventricle, undergoes rapid reduction and becomes a mere
ridge by the stage of ninety-six hours. Thus the opening of the
bulbus and the auricular canal lie side by side, separated only
by this slight ridge. The rotation of the ventricle brings the
bulbus from the right side into the mid-ventral line so that the
opening of the bulbus comes to lie ventral to the auricular canal
on its right side (cf. Figs. 199 and 200).
 
In the interior of the heart the development of the interventricular septum is associated with the formation of the trabeculse or ramified and anastomosing processes of the myocardium
that convert the peripheral part of the ventricular cavity into a
spongy mass at an early stage. Along the line of the interventricular sulcus these trabeculse extend farther into the cavity
than elsewhere, and become united together at their apices by a
slight thickening of the endocardium, which clothes them all,
thus originating the interventricular septum (Fig. 202). This
process begins at the apex of the ventricle, and extends towards
the base, the fleshy septum becoming gradually higher and thicker
and better organized. It thus has a concave free border, directed
towards the bulbo-auricular ridge and continued along both the
ventral and dorsal surfaces of the ventricle. The septum develops
more rapidly along the dorsal than the ventral wall and on the fifth
day reaches the neighborhood of the auricular canal on this side,
and unites with the right side of the fused endocardial cushions
which have in the meantime developed in the latter. (See below.)
Thus the interventricular foramen, or communication between
the ventricles, is gradually reduced in extent and limited to the
ventral anterior portion of the septum. It is never completely
 
 
 
354
 
 
 
THE DEVELOPMENT OF THE CHICK
 
 
 
closed, but, as we shall see later, the interventricular foramen
is iitilized in connecting up the aorta with the left ventricle.
 
It will be seen that if the original direction of this septum,
as indicated by the interventricular groove on the surface, were
preserved (Fig. 199), the interventricular septum would fuse
with the bulbo-auricular ridge and the right ventricle would then
be continuous with the bulbus only, and the left ventricle with
the atrium, and circulation of the blood would be impossible.
The avoidance of this condition is due to the rotation of the bulbus by which it is brought beneath the auricular canal, and by
widening of the auricular canal to the right. Thus the inter
 
 
 
FiG. 202. — Frontal section of the heart of a chick
embryo of 9 mm. head-length. (After Hochstetter.)
E. C, Median endothelial cushion. 1. E. C, Lateral endothelial cushion. S. Atr., Septum atriorum.
S. v., Septum ventriculorum.
 
 
 
ventricular septum meets the right side of the cushion-septum
and divides the auricular canal, though the opening of the bulbus
remains on its right.
 
(c) The inter auricular septum forms at the same time as the
septum between the ventricles, as a thin myocardial partition
arising from the vault of the atrium between the openings of the
sinus venosus and pulmonary vein; it extends rapidly with concave free border towards the auricular canal, and soon fuses
 
 
 
LATER DEVELOPMENT OF VASCULAR SYSTEM
 
 
 
355
 
 
 
completely along its entire free border with the endothelial
cushions of the latter. It would thus establish a complete partition between the two auricles were it not for the fact that
secondary perforations arise in it before its free edge meets the
endothelial cushions (Fig. 203). These have the same ph^^siological significance as the foramen ovale in the mammalian
heart, and persist through the
period of incubation, closing
soon after hatching.
 
(d) TheCushion-septum (Septum of the Auricular Canal).
This septum completes the entire system by uniting together
the three septa already considered. It forms as two cushionlike thickenings of the endothelium in the floor and roof respectively of the auricular canal
(cf. Figs. 202, 203 and 204).
These cushions rapidly thicken
so as to restrict the center of
the atrioventricular aperture,
and finally, fusing together, divide the latter into two vertically-elongated apertures, right
and left respectively. The time
of formation of this large endocardial cushion dividing the auricular canal is coincident with
the formation of the other septa.
 
(e) Completion of the Septa.
 
 
 
 
Fig. 203. — Reconstruction of the
 
heart of a chick embryo of 5.7 mm.
 
head-length, seen from right side.
 
Part of the wall of the right auricle
 
is cut away. (After Masius.)
 
B. Co., Bulbus cordis. D. C. Duct
of Cuvier. E. C. d., v., Dorsal and
ventral endothelial cushions. O.S.v.,
Opening of the sinus venosus into the
right auricle. 0. 1,0. 2, Primary and
secondary ostia or inter-auricular connections.
 
Thus bv the end of the fifth
 
 
 
or the beginning of the sixth day of incubation, the heart is
prepared for the rapid completion of a double circulation. The
embryonic circulation is never completely double, however, for
the reason that the embryonic respiratory organ (allantois)
belongs to the aortic system, and full pulmonary circulation does
not begin until after hatching. However, between the sixth
and eighth days the right and left chambers of the heart become
completely separated, except that the interauricular foramina
 
 
 
356
 
 
 
THE DEVELOPMENT OF THE CHICK
 
 
 
remain until hatching, and serve as a passageway of blood from
the right side to the left side.
 
The completion of the cardiac septa takes place in such a
way that the aorta becomes connected with the left ventricle,
the pulmonary artery remaining in connection with the right.
To understand how this occurs it is necessary to remember that,
although the bulbus arteriosus is primitively connected with the
right side of the ventricle, the revolution of the latter has transferred the bulbus to the middle line where it lies to the right of
 
 
 
 
Fig. 204. — Reconstruction of the heart of a
chick embryo of 5.7 mm. head-length. Ventral face removed; interior of the dorsal
half. (After Masius.)
Atr. d., s., Right and left auricles. D. C.
d., s., Right and left ducts of Cuvier. E. C,
Endothelial cushion, i. A. S., Interauricular septum. M. V., Opening of the meatus
venosus into the sinus. S. V., Sinus venosus.
V. d., s., Right and left ventricles.
 
the interventricular septum, and ventral to the right division of
the auricular canal. The bulbo-auricular ridge thus forms the
floor of this side of the auricular canal. The interventricular
septum is attached to the right side of the cushion-septum and
its foramen and the aperture of the bulbus lie side by side. It
will also be remembered that the proximal portion of the bulbus
is divided by a partition formed by right and left endocardial
 
 
 
LATER DEVELOPMENT OF VASCULAR SYSTEM 357
 
ridges, and that the aortic division of the bulbus hes above the
pulmonary division, that is, next the bulbo-aiiriciilar ridge.
The left bulbus ridge is thus continuous with the interventricular
septum immediately beneath the foramen of the latter, and the
right bulbus ridge lies on the opposite side.
 
The bulbus septum now becomes complete by fusion of the
right and left sides. The blood from the left ventricle is then
forced in each systole through the interventricular foramen and
along a groove in the right side of the cushion-septum into the
aortic trunk. This groove, how^ever, is open to the right ventricle also above the septum of the bulbus; but it is soon bridged
over by an extension of the cushion-septum along the bulboauricular ridge as far as the right side of the septum of the bulbus;
in this way the space existing between the interventricular septum and the opening of the aorta is converted into a tube, and
thus the aorta is prolonged through the cushion-septum, and
by way of the interventricular foramen into the left ventricle.
 
Fate of the Bulbus. The distal portion of the bulbus is converted into the proximal parts of the aorta and pulmonary artery.
The part proximal to the semilunar valves is gradually incorporated into the ventricles, owing to extension of the ventricular
cavities into its wall, and subsequent disappearance of the inner
wall of the undermined part.
 
The Sinus Venosus. (For earlier development see Chap. VI;
relation to septum trans versum. Chap. XI.)
 
In the course of development, the sinus venosus gradually
separates from the septum trans versum, though always connected
with the latter by the vena cava inferior. In early stages (up to
about 24 somites) it is placed quite symmetrically behind the
atrium, and extends transversely to the entrance of the ducts of
Cuvier on each side. The sinu-auricular aperture is approximately
in the median line at first, so that the right and left divisions of
the sinus are nearly symmetrical. The condition of approximate
bilateral symmetry of the sinus is, however, rapidly changed
by shifting of the sinu-auricalar aperture to the right side with
the outgrowth of the right auricle (24-36 somites); thus the left
horn of the sinus becomes elongated; moreover, the main expansion of the sinus takes place in the region of the sinu-auricular
aperture, and thus the left horn appears relatively narrow in diameter. The interauricular septum forms to the left of the sinu
 
 
358 THE DEVELOPMENT OF THE CHICK
 
auricular aperture (Fig. 204). At the stage of ninety-six hours the
o-eneral form of the sinus is that of a horseshoe situated between
the atrium and the septum trans versum; the ends of the horseshoe, or horns of the sinus venosus, are continued into the ducts
of Cuvier. The sinu-auricular aperture Ues on the right, and
here the cavity of the sinus is largest; the right horn of the sinus
is relatively short and the left horn forms a transverse piece on
the anterior face of the septum transversum, which gradually
curves dorsally and enters the left duct of Cuvier.
 
The right and left boundaries of the sinu-auricular aperture
project into the cavity of the right auricle as folds that meet
below the aperture and diverge dorsally (Fig. 204), thus forming
sinu-auricular valves; a special development of the muscular
trabecule running along the roof of the right auricle from the
angle of these valves corresponds to the septum spurium of mammalia. The sinus septum arises as a fold of the roof of the sinus
between the entrance of the left horn and the vena cava inferior;
it grows across the sinus into the sinu-auricular aperture and
thus divides the latter (cf. Fig. 231). Subsequently, the sinus
becomes incorporated in the right auricle, and the systemic
veins thus obtain independent openings into the latter (see account
of development of the venous system). The sinu-auricular
valves disappear during this process.
 
II. The Arterial System
 
The Aortic Arches. In the Amniota six aortic arches are
formed connecting the truncus arteriosus with the roots of the
dorsal aorta. The first four lie in the corresponding visceral
arches; the fifth and sixth are situated behind the fourth visceral
pouch; the fifth is a very small and transitory vessel, the existence of which was not suspected until comparatively recently
(v. Bemmelen, Boas), and the sixth or pulmonary arch was previously interpreted as the fifth. The discovery of the fifth arch
has brought the Amniota into agreement with the Amphibia
as regards the number and significance of the various aortic arches.
 
The fate of the aortic arches in the chick is as follows (see
Figs. 205, 206) : the first and second arches disappear as already
described (Chap. VI), and the anterior prolongation of the dorsal
aort2e in front of the third arch constitutes the internal carotid;
the ventral ends of the first and second arches form the external
 
 
 
LATER DEVELOPMENT OF VASCULAR SYSTEM
 
 
 
359
 
 
 
 
carotid. The third arch on each side persists as the proximal
portion of the internal carotids; and the dorsal aorta ruptures
on each side between the dorsal ends of the third and fourth
arches. The fourth arch and the root of the dorsal aorta disappear on the left side, but remain on the
right as the permanent arch of the aorta.
The fifth arch disappears on both sides;
the sixth arch persists throughout the
period of incubation and forms an important arterial channel of the systemic
circulation until hatching. Then the
dorsal portion (duct of Botallus or ductus arteriosus) becomes occluded, and
the remainder of the sixth arch becomes
the proximal portion of the pulmonary
arteries.
 
The details of these changes are as
follows: On the third and fourth days of
incubation the first and second aortic
arches disappear (Fig. 102). The lower
ends of these arches then appear as a
branch from the base of the third arch
on each side, extending into the mandible and forming the external carotid artery. The dorsal aorta in front of the
third arch constitutes the beginning of
the internal carotid. During the fourth
day the sixth pair of aortic arches is
formed behind the fourth cleft, and the
origin of the pulmonary arteries is transferred to them (Fig. 102). The fifth pair
of aortic arches is also formed during the fourth day (Fig. 206.)
It is a slender vessel passing from near the base to near the
summit of the sixth arch. As it has been entirely overlooked
by most investigators, it is certain that it is of very brief duration,
and it may even be entirely absent in some embryos. Apparently
it has no physiological importance, and it can be interpreted only
as a phylogenic rudiment.
 
Thus at the beginning of the fifth day the entire series of
aortic arches has been formed, and the first, second, and fifth
 
 
 
Fig. 205. — Diagram of
 
the aortic arches of birds
 
and their fate. (After
 
Boas.)
 
Car. com., Common carotid. Car. ext., External
carotid. Car. int., Internal
carotid. D. a., Ductus arteriosus. L., Left. p. A.,
Pulmonary artery. P.,
Right.
 
1, 2, 3, 4, 5, and 6, First,
second, third, fourth, fifth,
and sixth aortic arches.
 
 
 
360 THE DEVELOPMENT OF THE CHICK
 
have entirely disappeared. The surviving arches are the third
or carotid arch, the fourth or aortic arch, and the sixth or pulmonar}^ arch. Up to this time the development is symmetrical
 
on both sides of the body.
 
During the fifth and sixth
 
days the two sides become
 
asymmetrical, the fourth arch
 
becoming reduced on the left
 
side of the body and enlarged
 
on the right. Fig. 207 shows
 
the condition on the two sides
 
Fig. 206. — Camera sketch of the aortic of the body on the sixth day.
 
arches of the left side of a chick em- Jf the fourth arch of the two
 
bryo U days old. From an injected ^-^^^ ^^ compared it will be
 
specimen. (After Locy.) ,i . ,i ^ r.
 
Au 1 • +• • T?- one seen that the leit one is re
Abbreviations as m h ig. 205.
 
duced to a very narrow rudiment which has lost its connection with the bulbus arteriosus,
while on the right side it is well developed. Another important
change illustrated in the same figure is the reduction of the dorsal
aorta between the upper ends of the carotid and aortic arches to
a narrow connection. Two factors co-operate in the diminution
 
 
 
 
 
 
Fig. 207. — Reconstruction of the aortic arches of a 6-day
chick embryo from a series of sagittal sections.
 
A. Left side.
 
B. Right side.
 
Car. com., Common carotid. Car. ext., External carotid.
Car. int., Internal carotid. D. a., Ductus arteriosus.
3, 4, and 6, Third, fourth, and sixth aortic arches.
 
and gradual disappearance of this part of the primitive dorsal
aorta, viz., the elongation of the neck and the reduction of the
blood current. It will be seen that relatively little circulation
is possible in this section, because the current up the carotid
 
 
 
LATER DEVEL0P:\IEXT OF VASCULAR SYSTEM 361
 
arch turns forward and that up the aortic arch turns backward,
hence there is an intermediate region of stagnation, and here
the obUteration occurs.
 
On the eighth day the changes indicated on the sixth day
are completed. The left aortic arch has entirely disappeared,
and the connection between the upper ends of the carotid and
aortic arches is entirely lost on both sides (Fig. 208), though lines
of apparently degenerating cells can be seen between the two.
On the other hand, the upper end of the pulmonary arch (duct
of Botallus) is as strongly developed on both sides as the
right aortic arch itself. The pulmonary artery proper is relatively very minute (Fig. 208), and it can transmit only a small
 
 
 
<^M
 
 
 
 
 
A B.
 
Fig. 208. — Reconstruction of the aortic arches of an 8-day embryo from
a series of sagittal sections.
 
A. Left side.
 
B. Right side. . -si
A. o. m., Omphalomesenteric artery. Ao. A., Aortic (systemic) arch.
 
Car., Carotid. D. a., Ductus arteriosus, d. Ao., Dorsal aorta, p. A., Pulmonary artery. S'cl., Subclavian artery. V., Valves of the puhnonary
a,rtery.
 
quantity of blood; the principal function of the pulmonary arch
is obviously in connection with the systemic circulation. In
other words, both sides of the heart pump blood into the aorta
during embryonic life; after hatching, the duct of Botallus becomes occluded as already noted, and the pulmonary circulation
is then fully established.
 
The Carotid Arch. With the retreat of the heart into the
thorax, the internal and external carotids become drawn out into
long vessels extending through the neck region. The internal
carotids then become approximated beneath the vertebral centra.
The stem of the external carotid forms an anastomosis with the
internal carotid in the mandibular region, and then disappears,
 
 
 
362
 
 
 
THE DEVELOPMENT OF THE CHICK
 
 
 
Car. cow
 
 
 
s.cl.s
 
 
 
so that its branches appear secondarily as branches of the internal carotid. The common carotid (car. communis) of adult
anatomy is derived entirely from the proximal part of the internal carotid.
 
The Subclavian Artery. The primary subclavian artery
arises on the fourth day from the fifteenth (eighteenth of entire
 
series) segmental artery of
the body-wall when the
wing-bud forms, and gradually increases in importance with the growth of the
wdng. During the fifth day
a small artery that arises
from the base of the carotid
arch grows backwards and
unites with the primary subclavian at the root of the
wing. Thus the subclavian
artery obtains two roots, a
primary one from the dorsal
aorta and a secondary one
from the carotid arch (Fig.
209). As the latter grov/s
in importance the primary
root dwindles and finally
disappears (about the ninth
day). Apparently the Crocodilia and Chelonia agree
with the birds in this respect, while the other vertebrates retain the primary
root.
 
The Aortic System includes the aortic arch and
the primitive dorsal aorta
 
 
 
 
Fig. 209. — Dissection of the heart and
aortic arches of a chick embryo in the
latter part of the sixth day of incubation. (After Sabin.)
 
All., Auricle. Car. com., Common carotid. S'cl. d., s., primary and secondary
subclavian artery.
 
3, 4, 6, Third (carotid), fourth (systemic), and sixth (puhnonary) arches.
 
 
 
with its branches (Fig. 216).
 
The segmental arteries belong to the primitive dorsal aorta;
originally there is a pair in each intersomitic septum, but their
fate has not been thoroughly worked out in the chick. At six
days the cervical segmental arteries are united on each side by
 
 
 
LATER DEVELOPMENT OF VASCULAR SYSTEM 363
 
a longitudinal anastomosis communicating with the internal
carotid in front.
 
The two omphalomesenteric arteries are originally independent
(Chap. Y), but as the dorsal mesentery forms, they fuse in a
common stem extending to the umbilicus. The anterior mesenteric artery arises from this. The coeliac and posterior mesenteric arteries arise independently from the dorsal aorta (Fig. 216).
 
Mesonephric arteries arise from the ventro-lateral face of the
dorsal aorta and originally supply the glomeruli; they are very
numerous at ninety-six hours, but become much reduced in
number as the renal portal circulation develops; some of them
persist as the definitive renal and genital arteries.
 
The umbilical arteries arise from the same pair of segmental
arteries that furnishes the primitive artery of the leg. Thus
on the fourth day the umbilical arteries appear as branches of
the sciatic arteries; but later the umbilical arteries become much
larger than the sciatic (Fig. 216). The right umbilical artery is,
from the first, smaller than the left. On the eighth day its intermediate portion in the region of the neck of the allantois is much
constricted, and it gradually disappears. The caudal artery is
the narrow posterior extremity of the dorsal aorta behind the
umbilical arteries.
 
I do not find a stage in the chick when the umbilical arteries unite
directly with the dorsal aorta by way of the intestine and dorsal mesentery, though no doubt indirect connections exist at an early stage. In
mammals (Hochstetter) the primitive umbilical artery has such a
splanchnic course, but a secondary connection in the somatopleure soon
replaces the primary splanchnic path.
 
III. The Venous System. (See Chapter VI for origin of the
 
first venous trunks)
 
We shall take up the development of the venous system in
the following order: (a) the system of the anterior venae cavse
(venae cavse superiores) ; (5) the omphalomesenteric and umbilical veins and the hepatic portal system; (c) the system of the
inferior vena cava.
 
The anterior venae cavae are formed on each side b}' the
union of the jugular, vertebral, and subclavian veins. The jugular
is derived from the anterior cardinal veins, which extend down
the neck in close proximity to the vagus nerves. The embryonic
 
 
 
364 THE DEVELOPMENT OF THE CHICK
 
history of its branches is not known in detail (see Chap. VI and
Fig. 162 for the first branches). The history of the vertebral
veins, which open into the jugular veins near the base of the
neck, formed by union of anterior and posterior branches, is
likewise unknown. Presumably they are formed in part by
anastomoses between segmental veins. The subclavian vein
arises primitively as a branch of the posterior cardinal vein;
it receives the blood from the wing and walls of the thorax. The
part of the posterior cardinal behind the entrance of the subclavian vein disappears on the sixth day, and its most proximal
part represents then the anterior continuation of the subclavian
vein (Fig. 216). The part of the superior vena cava proximal
to the union of jugular and subclavian veins is derived from the
duct of Cuvier, and on the left side also from the left horn of
 
the sinus venosus.
 
The primitive omphalomesenteric veins unite behind the
sinus venosus to form the meatus venosus, around which the
substance of the liver develops as described in Chapters VI and
X; the union extends back to the space between the anterior
and posterior liver diverticula, where the omphalomesenteric
veins diverge and pass out to the yolk-sac along the margins
of the anterior intestinal portal (Fig. 210 A). In the latter part
of the third day (34-36 somites) an anastomosis forms between
the right and left omphalomesenteric veins above the intestine
just behind the dorsal pancreas, and thus establishes a venous
ring around the intestine, the upper portion of which is formee*.
by the anastomosis, the lower portion by the meatus venosus,
and the sides by the right and left omphalomesenteric veins
respectively (Fig. 210 B). Even during the formation of this
first venous ring it can be seen that its left side is becoming narrower than the right side, and in less than a day it disappears
completely (Fig. 210 C). Thus the blood brought in by the
left omphalomesenteric vein now passes through the dorsal
anastomosis to the right omphalomesenteric vein, and the latter
alone connects with the meatus venosus.
 
While this is taking place (seventy-two to ninety-six hours)
the intestine has elongated, the anterior intestinal portal has
shifted backwards, and a second anastomosis is formed between
the two omphalomesenteric veins ventral to the intestine and
immediately in front of the intestinal portal (Fig. 210 D). Thus
 
 
 
LATER DEVELOPMENT OF VASCULAR SYSTEM
 
 
 
365
 
 
 
a second venous ring is established around the ahmentary canal,
the lower portion of which is formed by the second anastomosis,
 
 
 
M^
 
 
 
//it.
 
 
 
' ■ \ Af.y.
 
 
 
 
 
 
A
 
 
 
Kr./ [ ^,
 
 
 
Ko/nX'
 
 
X ^'i/.s.
 
 
 
D.C. -- '
 
 
 
 
m.
 
 
 
n)
 
 
 
 
 
 
 
jy.
 
 
 
 
 
 
^ D
 
 
 
/r/-/
 
 
 
 
 
 
y.o..7?
 
 
 
 
 
 
 
/^:c.r.
 
 
 
Y.
 
 
 
Fig. 210. — Diagrams illustrating the development of the hepatic
portal circulation. (After Hochstetter.)
 
A. About the fifty-eighth hour.
 
B. About the sixty-fifth hour; first venous ring formed around
the intestine.
 
C. About the seventy-fifth hour; the left limb of the first venous ring has disappeared.
 
D. About the eightieth hour; the second venous ring is established.
 
E. About the one hundredth hour; the right limb of the second
venous ring has disappeared.
 
F. Hepatic circulation about the one hundred and thirtieth
hour, immediately before the disappearance of the intermediate
portion of the meatus venosus.
 
a. i. p., Anterior intestinal portal. D. C, Duct of Cuvier. int.,
Intestine. M. V., Meatus venosus. (Es., OEsophagus. Pc, Pancreas. St., Stomach. S. v.. Sinus venosus. V. c. i., Vena cava
inferior. V. h.. Hepatic veins. V. o. m.. Omphalomesenteric vein.
V. r. 1, First venous ring. v. r. 2, Second venous ring. V. u. d.,
Right umbilical vein. V. u. s., Left umbilical vein.
 
 
 
366 THE DEVELOPMENT OF THE CHICK
 
the upper portion by the first anastomosis, and the sides by the
right and left omphalomesenteric veins respectively. This ring
is^lso soon destroyed, this time by the narrowing and disappearance of its right side (Fig. 210 E).
 
Thus at about 100 hours the condition is as follows (Fig. 210
E) : the two omphalomesenteric veins unite to form a single trunk
in front of the anterior intestinal portal and ventral to the intestine (second anastomosis), the single trunk then turns to the left
(left side of second ring), passes forward and above the intestine
to the right side (first or dorsal anastomosis), and then farther
forward on the right side of the intestine (right side of first venous
ring) to enter the liver, where it becomes continuous with the
 
meatus venosus.
 
The Hepatic Portal Circulation becomes established in the
following manner: The meatus venosus is primarily a direct
passageway through the liver to the sinus venosus (Fig. 210 C);
but, as the liver trabecule increase, more and more of the blood
entering the meatus venosus is diverted into the vascular channels or sinusoids that occupy the spaces between the trabeculse.
By degrees these secondary channels through the liver substance
form two sets of vessels, an afferent one, branching out from
the caudal portion of the meatus venosus, in which the blood
is flowing into the hepatic sinusoids, and an efferent set branching from the cephalic portion of the meatus venosus in which
the blood is flowing from the hepatic sinusoids into the meatus
(210 D and E). By degrees the circulation through the liver
substance gains in importance, and liver trabeculse grow across
the intermediate portion of the meatus venosus (six to seven
days cf. Fig. 216), thus gradually occluding it as a direct path
through the liver (Fig. 210 F).
 
In this way there arises a set of afferent veins of the liver,
branches of the omphalomesenteric or hepatic portal vein, and
a set of efferent vessels which unite into right and left hepatic
veins opening into the cephalic portion of the original meatus
venosus. These veins begin to be differentiated after the one
hundredth hour of incubation, and the disappearance of the
intermediate portion of the meatus venosus as a direct route
through the liver is completed on the seventh day.
 
The original hepatic portal circulation is thus supplied mainly
with blood from the yolk-sac. But on the fifth day the mesen
 
 
LATER DEVELOPMEXT OF VASCULAR SYSTEM ' 367
 
teric vein begins to form as a small vessel situated in the dorsal
mesentery and opening into the omphalomesenteric vein behind
the dorsal pancreas. This vein increases in importance as the
development of the viscera proceeds, and becomes the definitive
hepatic portal vein; it receives branches from the stomach, intestine, pancreas, and spleen. The development of these branches
proceeds "pari passu with the development of the organs from
which they arise, and does not require detailed description. It
should be noted, however, that part of the veins from the gizzard and proventriculus form an independent vena porta sinistra
which enters the left lobe of the liver.
 
A distinct subintestinal vein extends forward from the root of the
tail at the stage of ninety-six hours to the posterior intestinal portal,
where it opens into the branch of the left omphalomesenteric vein,
that extends forward from the posterior end of the sinus terminalis.
This vein appears to take up blood from the allantois at an early stage.
However, it disappears at about the time when the umbilical vein becomes the functional vein of the allantois. Originally it appears to
open into s\Tnmetrical right and left branches of the omphalomesenteric vein that encircles the splanchnic umbilicus. The right branch
is, however, much reduced at ninety-six hours (cf. Hochstetter, 1888).
 
The Umbilical Veins. The umbilical veins appear as vessels
of the lateral body-wall opening into the ducts of Cuvier (Fig.
210 C; cf. Fig. 117); at first they show anastomoses with the
latter, which, however, soon disappear. They are subsequently
prolonged backwards in the somatopleure along the lateral closing
folds of the septum transversum (Chap. XI). Up to the end of
the third day of incubation they have no direct connection with
the blood-vessels of the allantois, and function only as veins of the
body-wall.
 
However, they obtain connection with the efferent vessels
of the allantois during the fourth day, apparently by widening
of parts of an intervening vascular network, and then the allantoic l)lood streams through them to the heart. The right umbilical vein disappears on the fourth day, and the left one alone
persists.
 
In the meantime the central ends of the umbilical veins have
acquired new connections. (Middle of third day. Fig. 210 D.)
This takes place through the formation of anastomoses, especially
on the left side, between the umbilical vein and the hepatic
 
 
 
368 THE DEVELOPMENT OF THE CHICK
 
vessels. (On the right side similar connections appear, according
to Brouha, but as the entire right umbilical vein soon degenerates
thev need not be considered farther.) The blood of the left umbilical vein thus divides and part flows into the duct of Cuvier by
way of the original termination, and part flows through the liver
into the meatus venosus. The original connection is then lost
and all of the blood of the umbilical vein flows through the liver
into the meatus venosus. Although the intrahepatic part is
at first composed of several channels, yet the blood of the umbilical vein flows fairly directly into the meatus venosus, and
thus takes no part in the hepatic portal circulation. On the
eighth day the entrance of the umbilical vein into the cephalic
part of the meatus venosus is still broken into several channels
by liver trabeculae (Fig. 182) ; these, however, soon disappear,
and the vein then empties directly into the meatus venosus, which
has in the meantime become the terminal part of the inferior
vena cava. As the ventral body-wall closes, the umbilical vein
comes to lie in the mid-ventral line, and in its course forward it
passes from the body-wall in between the right and left lobes
of the liver. The stem of the umbilical vein persists in the adult,
as a vein of the ventral body-wall opening into the left hepatic
vein.
 
The System of the Inferior Vena Cava (Post-cava). The
post-cava appears as a branch of the cephalic portion cf the meatus
venosus, and in its definitive condition the latter becomes its
cephalic segment; thus the hepatic and umbilical veins appear
secondarily as branches of the post-cava. The portion of the
post-cava behind the liver arises from parts of the postcardinal
and subcardinal veins, and receives all the blood of the posterior
portion of the body and viscera, that does not flow through the
hepatic portal system. The history of the development of this
vein, therefore, involves an account of (1) the origin of its proximal portion within the liver, and (2) of the transformation of the
postcardinals and subcardinals.
 
The proximal portion of the post-cava arises in part from
certain of the hepatic sinusoids in the dorsal part of the liver
on the right side at about the stage of ninety hours, and in part
from a series of venous islands found at the same time in the
caval fold of the plica mesogastrica (Figs. 211 and 212. See
Chap. XI). As the caval fold fuses Avith the right dorsal lobe of
 
 
 
LATER DEVELOPMENT OF VASCULAR SYSTEM
 
 
 
369
 
 
 
the liver, the venous islands flow together and establish a venous
trunk extending along and within the right dorsal lobe of the
liver, and opening anteriorly into the meatus venosus. At first
the connection with the meatus venosus lies near the sinus venosus, but in later stages is some cUstance behind the latter. Behind
the liver the dorsal attachment of the caval fold is to the ventral
surface of the right mesonephros, and at this place the vena cava
enters the mesonephros and connects with the subcardinal veins
(cf. Fig. 182).
 
The latter vessels arise as a series of venous islands on the
median surface of the mesonephros and lateral to the aorta on
each side. Such disconnected primordia are first evident at
 
 
 
l>.c.s.
V.u.s
 
 
 
^M--OCd.
 
 
 
V.u.d
 
 
 
 
U [[User:Z8600021|Mark Hill]] ([[User talk:Z8600021|talk]])'V.c.h
 
Fig. 21L — A drawing of a wax reconstruction of
 
the veins in the region of the liver of a sparrow
 
embryo. Outline of the liver represented by
 
broken lines. Dorsal view. (After Miller.)
 
D. C. d., s., Right and left ducts of Cuyier.
 
D. v., Ductus (meatus) venosus. S. V., Sinus
 
venosus. V.c. i., Vena cava inferior. V. u. d.,s.,
 
Right and left umbilical veins.
 
about the seventieth hour, and soon they run together to form
a longitudinal vessel on each side, which has temporary direct
connections with the postcardinals (Fig. 212), replaced afterwards (fifth day) by a renal portal circulation through the substance of the mesonephros. As the subcardinal veins enlarge,
they approach one another just behind the omphalomesenteric
artery beneath the aorta and fuse together (sixth day. Fig. 213).
In the meantime, the post-cava has become continuous with the
anterior end of the right subcardinal (Fig. 213).
 
The venous circulation is then as follows: The blood from
 
 
 
370
 
 
 
THE DEVELOPMENT OF THE CHICK
 
 
 
Ucp.d.
 
 
 
A-o.m.
 
 
 
 
Vsc.d.
 
 
 
LATER DEVELOPMENT OF VASCULAR SYSTEM 371
 
 
 
C. V.sc.d.
 
 
 
V3C.S.
 
 
 
V.c.i.
 
 
 
A.OM
 
 
 
V.c.fi.d.
 
 
 
Vscd.
 
 
 
 
Fig. 213. — Reconstruction of the venous system of
a chick of 5 days. Ventral view. (After Miller.)
a., Mesonephric veins. Ao., Aorta. A. sc. s., Left
sciatic vein. Other abbreviations as before.
 
the right and left postcardinal veins passes through the vascular network of the mesonephros, and empties into the subcardinal veins, from which it flows into the vena cava inferior,
and so through the meatus venosus to the heart. Prior to the
sixth day, however, the greater portion of the blood in tlie pos
 
 
FiG. 212. — Reconstruction of the venous system of a chick of 90 hours,
ventral view. (After Miller.)
A. o. m., Omphalomesenteric artery, a. sc. s.. Left sciatic artery. A.
u. s., Left umbilical artery, b., Vessels enclosed within ventral side of mesonephros. V. c. p. d., s., Ri^ht and left posterior cardinal veins. V. c. i.,
Vena cava inferior. V. sc. d., s., Right and left subcardinal veins.
 
 
 
372 THE DEVELOPMENT OF THE CHICK
 
terior cardinals passes forward to the ducts of Cuvier without
entering the mesonephric circulation. On the fifth and sixth
days the cephalic ends of the postcardinals gradually dwindle
and disappear (cf. Fig. 216); thus all of the blood entering the
postcardinals must pass through the mesonephros to the subcardinals, which thus become efferent vessels of the mesonephros;
and a complete renal-portal circulation is established.
 
This form of circulation continues during the period of functional activity of the mesonephroi, and as the latter gradually
atrophy, the portions of the subcardinals posterior to the anastomosis gradually disappear. A direct connection between the
post- and subcardinals is then established on each side, by way
of the great renal veins, which have in the meantime formed in
connection with the development of the kidney (Fig. 214).
 
The crural and ischiadic veins have, in the meantime, developed
in connection with the formation of the hind limbs, as branches
of the postcardinals. Thus the hinder portion of the latter becomes transformed into the common iliac veins, and at the hinder
end the postcardinals form an anastomosis (Fig. 214).
 
IV. The Embryonic Circulation
 
On the fourth day the blood is driven into the roots of the
dorsal aorta through three pairs of aortic arches, viz., the third
or carotid, the fourth or aortic, and the sixth or pulmonary. The
fifth pair of aortic arches is also functional for a time during this
day, but soon disappears. The blood passing ap the third or
carotid arch is directed forward through the internal and external
carotid arteries to the head; that passing up the fourth and
sixth arches turns backwards to enter the dorsal aorta, so that
there is an intermediate area of stagnation in the roots of the
dorsal aorta between the carotid and aortic arches; though this
is more or less problematical, the arrangement of the vessels renders such a condition very probable. A very small proportion of
the blood enters the rudimentary pulmonary arteries from the
sixth arch. The blood in the dorsal aorta passes backwards and
enters (1) the segmental arteries, (2) the omphalomesenteric
arteries, (3) the (rudimentary) umbilical arteries, and behind
the latter passes into the narrow continuation of the dorsal aortse,
still separate in this region, known as the caudal arteries.
 
The blood is returned to the heart through the sinus venosus
 
 
 
LATER DEVELOPMENT OF VASCULAR SYSTEM 373
 
 
 
 
Fig. 214. — Reconstruction of the venous system of a sparrow embryo,
corresponding to a chick of about 14 days. (After Miller.)
V. c.i. H., Intra-hepatic part of the vena cava inferior. V
Part of the vena cava inferior derived from the subcardinal vein.
Genital veins. V. i. e. d., s., Riorht and left vena iliaca externa
 
 
 
d., s.
 
 
 
c. i. SC,
 
V. V. g.,
 
V. i. i.,
 
Right and left vena intervertebralis lum
 
 
Vena iliaca interna. V. i. 1.
 
balls. V. r. m. d., s., Right and left great renal veins.
 
almost exclusively, the pulmonary veins being very rudimentary
at this stage. The veins entering the sinus venosus are the ducts
of Cuvier, and the meatus venosus. The former are made up
on each side by (1) the anterior cardinal vein, returning blood
from the head, (2) the posterior cardinal vein returning blood
from the veins of the Wolffian bodv, and the intersomitic veins,
(3) the umbilical veins returning blood mainly from the body
 
 
374
 
 
 
THE DEVELOPMENT OF THE CHICK
 
 
 
wall, inasmuch as direct connection with the veins of the allantois
is not yet established. The meatus venosus receives the omphalomesenteric veins, and the blood of the allantois by way of the
subintestinal vein (the latter arrangement of very brief duration).
Thus at this time all of the blood is mixed together in the
 
sinus venosus, viz., that re
 
 
A m^ CA.Q.rn.)
Ao.
I-!- Vsrs.
 
 
 
-- Vils.
 
 
 
 
ceived through the ducts of
Cuvier, presumal)ly venous,
and that received through
the meatus venosus, presumably arterial, owing to its
circulation in the superficial
vascular network of the yolksac. Apparently there is no
arrangement for separation
or discrimination in the redistribution of the blood.
But on the other hand it
should be noted that most
of the blood comes from the
yolk-sac, owing to the slight
 
 
 
Vu.d.
Fig. 215. — Region of the bifurcation of
the post-cava in the adult fowl. Ven
tral view (After Miller) development of the vessels
 
A.m. s. (A. o.m.), Omphalomesenteric , , , . .1 • x
artery. A. i. s., Left internal iliac artery, ot the embryo at this time;
V. c. i., Vena cava inferior. ^ V. i. c. d.,
Right common iliac vein. V. i. e. d., Right
external iliac vein. V. i. i. d., Right internal iliac vein. V. i. 1. s., Left vena mtervertebralis lumbalis. V. sr. s., Left
suprarenal vein. Vv. g., Genital veins.
Vv. r.m., Great renal veins.
 
 
 
and that the blood of the
embryo itself cannot be
highly venous owing to the
shortness of the circuit and
the delicate nature of the
embryonic tissues, which, no doubt, permit direct access of oxygen.
On the sixth day the embryonic circulation enters on a second
phase, owing to the changes in the structure of the heart and
arrangement of the vessels described in detail in the preceding
part of this chapter.
 
On the eighth day the circulation is as follows: The right
and left ventricles are completely separate, and the former
pumps the blood into the pulmonary trunk, the latter into the
aortic trunk. The carotid arteries arise from the base of the
aortic arch and convey the blood to the head, and also, by way
of the sul:»clavians, to the walls of the thorax and to the wing.
The left aortic arch has disappeared, and the right arch is con
 
 
LATER DE\ ELOPMEXT OF VASCULAR SYSTEM 375
 
tinuous with the dorsal aorta. The pulmonary trunk divides into
right and left arches from which the small pulmonary artery is
given off on each side, and the arch is continued without perceptible diminution in size as the ductus Botalli (ductus arteriosus) to the dorsal aorta. Thus the greater quantity of blood
pumped by botli sides of the heart passes into the dorsal aorta
by way of the right aortic arch, and the right and left ductus
Botalli; but part of the blood from the left ventricle passes into
the carotids. The main branches of the dorsal aorta are (1)
coeliac, distributed to stomach and liver mainh% (2) omphalomesenteric to the 3'Olk-sac and mesentery, (3) right and left
umbilical arteries (of which the left is much more important, the
right soon disappearing), to the allantois and leg, (4) segmental
arteries to the body-wall, (5) the caudal arteries.
 
The anterior venae cavae (former ducts of Cuvier) return the
blood from the head, wing, and walls of the thorax to the right
auricle; but owing to the formation of the sinus septum, the left
vena cava opens directly into the right auricle to the left of the
sinus valves, and the right one, also independently, to the right of
the sinus valves. The proximal portion of the vena cava
inferior is the original meatus venosus, and it receives the
right and left hepatic veins, the last of w^hich receives all the
blood from the allantois through the umbilical vein (original
left).
 
There is also an hepatic portal and a renal portal circulation.
The hepatic portal system is supplied with blood mainly from
the yolk-sac, but also from the veins of the alimentary canal by
the mesenteric vein; the latter is a relatively unimportant vessel
at eight da3^s, but groW'S in importance and becomes the entire
hepatic portal vein after absorption of the yolk-sac. The hepatic
portal vein branches wdthin the liver into a system of capillaries
which reunite to form the right and left hepatic veins. Thus
all the absorbed nutrient material passes through the capillaries
of the liver, where certain constituents are no doubt acted on
in some important, but little understood, way.
 
The renal portal circulation persists through the period of
functional activity of the mesonephros. The afferent vein is
the posterior cardinal which is supplied by the segmental veins
and the veins of the leg and tail. The blood flows through the
capillaries of the mesonephros into the subcardinal veins, and
 
 
 
376 THE DEVELOPMENT OF THE CHICK
 
hence to the vena cava inferior. With the degeneration of the
mesonephros, the subcardinals disappear in large part and the
postcardinals then empty directly into the vena cava inferior
by way of the renal veins, which have formed in the meantime.
The embryonic renal portal system of birds is similar in all essential respects to the permanent system of amphibia and constitutes a striking example of recapitulation. The left auricle of
the heart receives the small pulmonary veins.
 
Thus practically all of the blood is returned to the right auricle
of the heart; a considerable part of it is diverted into the left
auricle through the foramina in the septum atriorum, and thus
the blood reaches both ventricles. Complete systems of valves
prevent its regurgitation in any direction.
 
It is an interesting question to what extent the different kinds
of blood received by the right auricle remain separate and receive
special distribution through the body. The blood poured in by
the anterior venae cavse is purely venous, and it seems probable
from the arrangement of the sinus valves that it passes into the
ventricle of the same side, and so into the pulmonary arch and
through the ductus Botalli into the dorsal aorta, and thus in part
at least to the allantois where it is oxygenated. The blood coming
in through the posterior vena cava is purified and rich in nutrition,
for part of it comes from the allantois, where it has been oxygenated, and part has passed through the renal portal circulation,
where, no doubt, it has been purified of nitrogenous excretory
matter, and the remainder is mostly from the yolk-sac and hence
laden with nutrition. This blood appears to be diverted through
the foramen of the septum atriorum into the left auricle, and
thence to the left ventricle, and so out into the carotids and
aortic arch. It would seem, therefore, to be reasonably certain
that the carotids receive the purest and most nutritious blood,
for the blood in the dorsal aorta is mixed with the blood from
the right ventricle. There can be no reasonable doubt that the
heart is a more effective organ for separate and effective distribution of the various kinds of blood received by it than this account
would indicate. But further investigation is necessary to determine in what ways and to what extent this takes place.
 
At the time of hatching the following changes take place:
the umbilical arteries and vein are obliterated in the allantois,
owing to drying up of the latter; their stems remaining as relatively
 
 
 
 
Fig. 216. — Diagram of the relations of the main splanchnic blood vessels
 
on the sixth day of incubation.
 
A. c, CoeHac artery. Adv., Vena advehens. All., Allantois. A. m.. Mesenteric artery. Ao., Aorta. A. o. m., Omphalomesenteric artery. A. p.,
Pulmonary artery. A. sc. Sciatic artery. A. u. d.. Right umbilical artery.
A. u. s., Left umbilical artery. A. V., Vitelline arteries. Car. int., Internal
carotid. Car. ext.. External carotid. CI., Cloaca. D. a., Ductus arteriosus.
D. v., Ductus (meatus) venosus. Int., Intestine. J. e., External jugular
vein. J. i.. Internal jugular vein. Li., Liver. Scl., Subclavian artery. V.
c. a.. Anterior vena cava. V. c. i.. Inferior Vena cava. V. c. p.. Posterior
cardinal vein. V. m., Mesenteric vein. V. o. m., Omphalomesenteric vein.
Vp., Pulmonary vein. V. s'c, Subcardinal vein. V. s'cl., Subclavian vein.
V. u. (s.). Umbilical vein (left). V. V., Vitelline vein. W. B., Wolffian
body. Y. S., Yolk-sac. Y. St., Yolk-stalk.
 
 
 
LATER DEVELOPMENT OF VASCULAR SYSTEM 377
 
insignificant vessels. The veins of the yolk-sac likewise disappear. The ductus arteriosus (Botalli) is obliterated on both
sides, and becomes a solid cord uniting the pulmonary arteries
and arch of the aorta. Thus the blood from the right ventricle
is driven into the lungs, and the pulmonary artery enlarges.
The foramina in the septum atriorum gradually close, and so a
complete double circulation is established. The right auricle
receives all the systemic (venous blood), which is then driven
through the lungs by way of the pulmonary artery, and returned
in an oxygenated condition through the pulmonary veins to
the left auricle; thence to the left ventricle and out through the
aorta into the systemic circulation again.
 
 
 
CHAPTER XIII
 
THE URINOGENITAL SYSTEM
 
The history of the pronephros and the origin of the mesonephros have been ah'eady described (Chap. VI). We have now
to consider (1) the later history of the mesonephros, (2) the
development of the metanephros or permanent kidney, (3) the
development of the reproductive organs and their ducts, and
(4) the development of the suprarenals. All these organs form
an embryological unit, by virtue of their mode of origin and their
interrelations. Thus we find that the intermediate cell-mass is
significant for the development of all: its growth causes the formation of the Wolffian body, on the median face of which the gonads
arise. The secreting tubules and renal corpuscles of the permanent kidney are also derivatives of the intermediate cell-mass.
The Wolffian duct is derived from the same source, and by change
of function becomes the vas deferens, after functioning for a while
as the excretory duct of the mesonephros. Certain parts of the
mesonephros also enter into the construction of the testis. And
the Miillerian duct, which forms the oviduct of the female, is
derived from the epithelium covering the Wolffian body.
 
I. The Later History of the Mesonephros
In Chapter VI we traced the origin of the nephrogenous
tissue, and the differentiation of the first mesonephric tubules
within it. We saw that in each of the segments concerned a
number of balls of cells arises by condensation within the nephrogenous tissue, and that these become converted into vesicles.
We saw also that each vesicle sends out a tubular sprout from
its lateral side to the Wolffian duct, with which it unites; and
that its median face becomes converted into a renal corpuscle.
These processes take place sucessively in antero-posterior order
within the somites concerned, so that a series of stages in the
development of the tubules may be studied in the same embryo.
Moreover, all the tubules of a given somite do not develop simul
.378
 
 
 
THE URIXOGEXITAL SYSTEM
 
 
 
379
 
 
 
taneously: primary tubules are formed in each somite from the
most ventral portion of the nephrogenous tissue; then secondar}tubules later from an intermediate portion, and tertiary tubules
later yet from the dorsal portion.
 
Fig. 217 represents a transverse section through the middle
 
 
 
 
^»f^^5^° v'"'it>f ^i:^j#^^'
 
 
 
 
 
 
 
 
 
 
 
 
 
Fig. 217. — Transverse section through the middle of the
 
Wolffian body of a chick embryo of 96 hours.
 
Ao., Aorta. Coel., Coelome. Col. T., Collecting tubule.
Glom., Glomerulus, germ. Ep., Germinal epithelium. M's't.,
Mesentery, n. t., Nephrogenous tissue. T. 1,2, 3, Primary,
secondary, and tertiary mesonephric tubules. V. c. p., Posterior cardinal vein. W. D., Wolffian duct.
 
of the Wolffian body at the stage of ninety-six hours, showing a
primary, secondary, and tertiary tubule. The primary tubule
is typically differentiated; the secondary has formed the secreting
tubule and the rudiment of the renal corpuscle, but the tubule
does not yet open into the Wolffian duct, though it is connected
with it; the tertiary tubule is still in the vesicular stage. Some
undifferentiated nephrogenous tissue remains above the rudiment of the tertiary tubule, which makes it possible that quarternarv tubules mav be formed later.
 
Referring still to the same figure, it will be noted that the
Wolffian duct itself has formed a considerable evagination dorsomedially (collecting tubule), with which both secondary and
tertiary tubules are associated as well as the undifferentiated
nephrogenous tissue. Similar evaginations are formed along
the entire length of the functional portion of the mesonephros.
 
 
 
380
 
 
 
THE DEVELOPxAIEXT OF THE CHICK
 
 
 
0(,
 
 
 
ov
 
 
 
o
 
 
 
Q>(
 
 
 
o
 
 
 
OO,
 
 
 
o
 
 
 
o
 
 
 
o
 
 
 
o r
 
 
 
o
 
 
 
xoz
 
 
 
X22
 
 
-2ZIC
 
 
 
22YII
 
 
 
Fig. 114. A.
 
 
 
Figs. 218 and 219 illustrate the form of these evaginations in
duck embr3^os of 40 and 50 somites respectively, as they appear
in reconstructions of the posterior portion of the mesonephros.
 
It will be seen that they gradually
form sacs opening into the Wolffian
duct. Subsequently, by elongating,
these sacs form collecting tubules
that gather up the secretions of the
mesonephric tubules proper and conduct them to the Wolffian duct.
These conducting tubules are stated
to branch more or less; it is also
said that they are more highly developed in the duck than in the chick.
Felix proposes to call them mesonephric ureters.
 
In the case of the secondary and
tertiary tubules, three parts may be
distinguished : parts one and two (derived from the nephrogenous tissue)
I;. o\C ^rc the renal corpuscle and secreting
 
tubule respectively; the third part is
the collecting tubule derived by
evagination from the Wolffian duct.
In the case of the primary tubules,
a conducting part appears to be
formed secondarily, though in what
way is not clear.
 
The formation of new tubules
ceases on the fifth day, all the nephrogenous tissue being then used
up. Up to the eighth day at least
the tubules grow rapidly in length
and become more differentiated. The
result is a relatively enormous protrusion into the bodv-cavity on each
side of the dorsal mesentery. Degeneration of the tubules sets in
about the tenth or eleventh days,
and the tissue is gradually absorbed;
 
 
 
2Mir
 
 
 
 
 
 
'XSKT
 
 
 
THE URIXOGEXITAL SYSTEM
 
 
 
381
 
 
 
this process extends over the whole of the latter period of incubation, and is completed at hatching. Parts, however, remain
in the male in connection with the testis; non-functional remnants
 
 
 
O ^ °o o
O
 
O.'l
 
 
 
 
' ."fi.T •-.
 
 
 
yxxiii
 
 
 
n.T.
 
 
 
Fig. 219. — Profile reconstruction of part of the
 
mesonephros and diverticulum of the ureter of
 
a duck embryo of 50 somites. (After Schreiner.)
 
CI., Cloaca. Int., Intestine. Mn. T., Meso
nephric tubules, n. T., Nephrogenous tissue.
 
Ur Ureter W. D.. Wolffian duct.
 
XXXII, XXXIII, XXXIV, Somites of the
same number.
 
may also be detected in the female (p. 401). It is difficult to
state the exact period of beginning and cessation of function of
the mesonephric tubules. Judging from the histological appear
 
 
PiG 918 — Profile reconstruction of part of the Wolffian duct and primordia
of mesonephric tubules (represented by circles) of a duck embryo of 45
somites. (After Schreiner.)
YXTV XXV etc., position of the correspondmg somites. Lines 114 A,
 
114 B 114 C ^represent the positions of the sections shown in these figures.
 
 
 
382
 
 
 
THE DEVELOPMENT OF THE CHICK
 
 
 
ances, however, it is probable that secretion begins in the tubules
on the fifth day and increases in amount up to the eleventh day
at least, when signs of degeneration become numerous. Presumably the functional activity diminishes from this stage on, being
replaced by the secretion of the permanent kidney.
 
 
 
SrC:^
 
 
 
Gq/?.-%
 
 
 
 
 
 
 
Fig. 220. — Transverse section through the mesonephros
 
and neighboring parts of a 6-day chick, in the region of
 
the spleen.
 
Ao., Aorta, bl. V., Blood vessels (sinusoids). Caps., Capsule of renal corpuscle. Coel., Coelome. col. T., Collecting
tubule. D., Dorsal. Giz., Gizzard. Glom., Glomerulus.
Gon., Gonad. L., Left. Spl., Spleen. Sr. C, Cortical substance of the suprarenal, s. t., Secreting tubule. T. R.,
Tubal rid^e. V., Ventral. V. c. p., Posterior cardinal vein
V. s'c. 1., Left subcardinal vein. W. D., Wolffian duct.
 
Figs. 220 and 221 represent sections through the mesonephros
on the sixth and eighth days respectively (see also Fig. 222,
eleven days). The renal corpuscles show the typical capsule
and glomerulus, and relation to the secreting tubules. The latter
are considerably convoluted on the sixth day, much more so on
the eighth day. The conducting tubules can usually be distinguished by their smaller caliber and thinner walls. The Wolffian
 
 
 
THE URIXOGEXITAL SYSTEM
 
 
 
383
 
 
 
duct is situated near the dorso-lateral edge of the mesonephros,
and the opening of a collecting tubule into it is shown in Figure
220. The renal corpuscles are situated next the median face of
the Wolffian body. The space between the tubules is occupied
 
 
 
';7.f.o.z.
 
 
 
Mh'tr
 
 
 
 
-3.?V
iVJ).
 
 
 
apmm
 
 
 
 
Gon.l
 
 
 
Fig. 221. — Transverse section through the metanephros, mesonephros,
gonads and neighboring parts of an 8-day chick,
bl. v., Blood vessels (sinusoids). B. W., Body-wall. col. T. M't'n.,
Collecting tubules of the metanephros. M. D., Miillerian duct. M's't., Mesentery, n. t. i. z., Inner zone of nephrogenous tissue (metanephric). n. t. o.
z., Outer zone of the nephrogenous tissue. Symp. Gn., Sympathetic o^anghon of the twenty-first spinal ganglion. V. C, Centrum of vertebra. Other
abbreviations as before.
 
almost entirely by a wide vascular network of sinusoidal character; that is, the endothelial walls of the vessels are moulded
directly on the basement membrane of the tubules without any
intervening connective tissue. The circulation is described in the
chapter on the vascular system.
 
 
 
384 THE DEVELOPMENT OF THE CHICK
 
II. The Development of the Metaxephros or Permanent
 
Kidney
 
The metanephros or permanent kidney supplants the mesonephros in the course of development. It is derived from two
distinct embryonic primordial (1) the nephrogenous tissue of
the two or three posterior somites of the trunk (31 or 32 to 33),
which furnish the material out of which the renal corjxiscles
and secreting tubules develop; and (2) a diverticulum of the
posterior portion of the Wolffian duct (Fig. 219), which develops
by branching into the collecting tubules and definitive ureter.
The development of the kidney takes place in a mass of mesenchyme, known as the outer zone of the metanephrogenous tissue,
that furnishes the capsule and connective tissue elements of
the definitive kidney, in which also the vascular supply is developed
(Figs. 221 and 222). The cortical tubules of the kidney are
thus derived mainly from the nephrogenous tissue, and the medullary tubules and ureter from the metanephric diverticulum.
 
Thus the definitive kidney is analogous in mode of development to the mesonephros, and is best interpreted as its serial
homologue. This point of view may be regarded as definitely
established by the work of Schreiner, to which the reader is referred for a full account of the history of the subject.
 
The metanephric diverticulum, or primordium of the ureter
and collecting tubules, arises about the end of the fourth da}^ as
a rather broad diverticulum of the Wolffian duct at the convexity
of its terminal bend to the cloaca (Fig. 219). It grows out
dorsally, forming a little sac, which, however, soon begins to grow
forward median to the posterior cardinal vein and dorsal to the
mesonephros (Fig. 224); by the end of the fifth day its anterior
end has reached the level of the csecal appendages of the intestine, and on the eighth day its anterior end has reached its definitive position at the level of the vena cava inferior, near to the
anterior end of the mesonephros (twenty-first definitive somite or
twenty-fifth of the entire series; cf. Fig. 150).
 
It should be noted that the metanephric diverticulum is similar
in its mode of origin to the so-called mesonephric ureters. It
may in fact be regarded as the posterior member of this series,
but it is separated from those that form the collecting tubules of
the mesonephros by at least two somites in which no diverticula
 
 
 
THE URINOGEXITAL SYSTEM
 
 
 
385
 
 
 
of the mesonephros are formed (Fig. 219). During its growth
forward a series of small diverticula arise from its wall and extend
dorsally (Fig. 223); these branch secondarily in a generally dichot
 
 
,'-''^i,< ■•'>"!■'■-■<- ■■■■---■: .
 
 
 
 
 
 
Af^Y.
 
 
 
^y^
 
 
 
 
Fig. 222. -Transverse section through the metanephros, mesonephros
gonads and neighboring structures of an 11-day male chick,
a. A. S., Abdominal air-.sac. Ao., Aorta B W Rndv wall r^^i n
 
duct. Mst., .Mesentery. M't'n., Metanephros. Sp., Spine of neural areh
 
W D^'woMandScrotr' '\t """.'^' "*'. J e.^., Vna ca"™ Meri*:
vv . u., \^ oiman duct. Other abbreviations as before.
 
 
 
386
 
 
 
THE DEVELOPMENT OF THE CHICK
 
 
 
 
Fig. 223. — Profile reconstruction of the Wolffian
duct and primordium of the metanephros of a
chick embryo of 6 days and 8 hours. (After
Schreiner.)
 
XXV to XXXIH, twentv-fifth to thirty-third
somites. Al. N., Neck of allantois. CI., Cloaca.
Int., Intestine. M's'n., Mesonephros. n. T.,
Nephroojenous tissue of the metanephros included
within the dotted lines. W. D., Wolffian duct.
Ur., Ureter.
 
 
 
THE URIXOGEXITAL SYSTEM 387
 
omoiis manner, and it is from them that the collecting tubules
of the kidney arise; the posterior unbranched portion of the metanephric diverticulum represents the definitive ureter.
 
The following data concerning these branches should be noted:
 
(1) the first ones are formed from the posterior portion of the
metanephric diverticulum, and the process progresses in an
anterior direction. This is the reverse direction of the usual order
of embryonic differentiation, but the reason for the order is the
same, viz., that differentiation begins in the first formed parts.
 
(2) A posterior, smaller group of collecting tubules is separated
at first by an unbranched portion of the ureter from an anterior
larger group (Fig. 223). The unbranched region corresponds to
the position of the umbilical arteries which cross here. (3) During
the fifth and sixth days the terminal portion of the Wolffian
duct common to both mesonephros and metanephros is gradually
drawn into the cloaca, and thus the ureter obtains an opening
into the cloaca independent of the Wolffian duct and posterior
to it (Fig. 223).
 
The Nephrogenous Tissue of the Metanephros. The nephrogenous tissue of the thirty-first, thirty-second, and thirty-third
somites is at first continuous with the mesonephros (Figs. 218
and 219), but on the fourth and fifth da3^s that portion situated
immediately behind the mesonephros degenerates, thus leading
to a complete separation of the most posterior portion situated
in the neighborhood of the metanephric diverticulum. This constitutes the metanephrogenous tissue proper (inner zone). It is
important to understand thoroughly its relations to the metanephric diverticulum. This is indicated in Fig. 219, which represents a graphic reconstruction of these parts in a duck embryo
of 50 somites. It will be seen that the metanephrogenous tissue
covers nearly the entire metanephric diverticulum; a transverse
section (Fig. 224) shows that it lies on its median side. The
outer dotted line (Fig. 219) gives the contour of a dense portion
of mesenchyme related to the diverticulum and nephrogenous
tissue proper. In section this forms a rather ill-defined area
shading into the nephrogenous tissue on the one hand and into
the surrounding mesenchyme on the other.
 
Fig. 224 shows the relations of the three constituent elements
of the kidney at the end of the fifth day, as seen in a transverse
section. The metanephric diverticulum lies on the median side
 
 
 
388
 
 
 
THE DEVELOPMENT OF THE CHICK
 
 
 
of the cardinal vein, and is in contact, on its median face, with
the proper nephrogenous tissue (inner zone); the latter shades
into the outer zone, the cells of which are arranged concentrically
with reference to the other parts. The relations subsequently
established may be summarized in a few Avords; the inner zone
of tissue grows and branches pari passu with the growth and
branching of the metanephric diverticulum, so that the termination of every collecting tubule is accompanied by a portion of
 
 
 
 
Fig. 224. — Transverse section through the
 
ureter and metanephrogenous tissue of a
 
5-day chick.
 
A. umb., Umbilical artery. Coel., Coelome.
 
M's't., Mesentery, n. t. i. z., Inner zone of the
 
nephrogenous tissue, n. t. o. z., Outer zone of
 
the nephrogenous tissue. Ur., Ureter. V. c.p.,
 
Posterior cardinal vein. W. D., Wolffian duct.
 
the inner zone, which is, however, always distinct from it. This
conclusion is established by the fact that from the start the two
elements, collecting tubules and inner zone, are distinct and
may be traced continuously through every stage. The outer
zone differentiates in advance of the two more essential constituents at all stages, and thus forms a rather thick investment
 
for them.
 
The formation of the secreting tubules from the inner zone
 
 
 
THE URIXOGEXITAL SYSTEM
 
 
 
389
 
 
 
 
Fig. 225. — Sections of the embryonic metanephros of the chick
to show developing tubules. (After Schreiner.)
 
A. Nephric vesicle or primordium of secreting tubule (ur. t )
and collecting tubule (col. T.); 9 days and 4 hours.
 
B. Elongation of nephric vesicle; same embryo.
 
C. Indication of renal corpuscle at the distal end of the
forming tubule.
 
D. The secreting tubule appears S-shaped.
 
E. Secreting tubule well formed; 9 davs and 21 hours.
 
F. Secreting tubule opening into collecting tubule; 11 days.
 
 
 
390 THE DEVELOPMENT OF THE CHICK
 
of the metanephrogenous tissue takes place in essentially the
same manner as the formation of the mesonephric tubules. The
first stages may be found in seven and eight-day chicks in the
portion of the kidney behind the umbilical arteries. The inner
zone tissue begins to arrange itself in the form of minute balls
of cells in immediate contact with the secreting tubules; a small
lumen then arises within the ball, transforming it into a thickwalled epithelial vesicle with radially arranged cells. The vesicle
then elongates away from the collecting tubule and gradually
takes on an S-shape. The distal end of the S becomes converted into a renal corpuscle as illustrated in Figure 225
and the proximal end fuses with the wall of the collecting tubule;
an opening is then formed between the two.
 
On the eleventh day of incubation, secreting tubules are thus
formed throughout the entire length of the kidney; but the histological structure does not yet give the effect of an actively secreting gland, although degeneration of the mesonephros has already
begun. The full development of the nephric tubules in the
chick has not been studied.
 
At all stages in its develojDment the kidney substance is
separated from the mesonephros by a distinct layer of undifferentiated mesenchyme, which is, however, at certain times extremely thin. But there is no evidence that at any time elements
of the mesonephros, e.g., undifferentiated nephrogenous tissue,
extend up into the metanephric primordium which so closely
overlies it (cf. Figs. 221 and 222).
 
The kidney is entirely retroperitoneal in its formation, and
its primary capsule is established by differentiation of the periphery of the outer zone. This may be seen in process at eleven
days (Fig. 222) : the primary capsule is definitely estal^lished on
its median and lateral sides; but is defective dorsally and at the
angle next the aorta. With the subsequent degeneration of the
mesonephros, and projection of the kidney into the coelome,
its ventral surface acquires a secondary peritoneal capsule.
 
III. The Organs of Reproduction
 
The gonads are laid down on the median surface, and the
ducts on the lateral surface of the Wolffian body, which thus
becomes converted into a urinogenital ridge. The composition
of the urinogenital ridge is at first the same in all embryos, whether
 
 
 
THE URIXOGENITAL SYSTEM 391
 
destined to become male or female. It has three divisions:
(1) the anterior or sexual division, containing the gonad, involves
about the anterior half of the Wolffian body; (2) a non-sexual
region of the Wolffian body occurs behind the gonad, and
(3) behind the Wolffian body itself the urinogenital ridge contains only the Wolffian and Mullerian ducts. A transverse section through the anterior division shows the following relations
(Fig. 221): on the mecUan surface the gonad, on the lateral surface near the dorsal angle of the body-cavity the Wolffian and
Mullerian ducts, the latter external and dorsal to the former:
between the gonad and ducts lie the tubules of the Wolffian
body destined to degenerate for the most part.
 
There is an incUfferent stage of the reproductive system
during which the sex of the embryo cannot be determined, either
bv the structure of the gonad or the degree or mode of development of the ducts. In those embryos that become males the
gonad develops into a testis, the Wolffian duct becomes the vas
deferens, the tubules of the anterior part of the Wolffian body
become the epididymis, those of the non-sexual part degenerate,
leaving a rudiment known as the paradidymis, and the Mullerian
duct becomes rudimentary or disappears. In embryos that become females, the gonad develops into an ovary; the Wolffian duct
disappears or becomes rudimentary, the Mullerian duct develops
into the oviduct on the left side and disappears on the right side,
and the tubules of the Wolffian body degenerate, excepting that
functionless homologues of the epididymis and paradidymis persist, known as the epoophoron and paroophoron respectively.
 
It is not correct to state, as is sometimes done, that the
embryo is primitively hermaphrodite, for, though the ducts characteristic of both sexes develop equally in all embryos, the primitive gonad is, typically, only indifferent. Nevertheless, if the
gonad be physiologically as well as morphologically indifferent
in its primitive condition, the possibility of an hermaphrodite
development is given. The primitive embryonic conditions
appear to furnish a basis for any degree of development of the
organs of both sexes.
 
Development of Ovary and Testis. Indifferent Period. The
reproductive cells of ovary and testis alike arise from a strip
of peritoneal epithelium, known as the germinal epithelium,
which is differentiated on the fourth day by its greater thickness
 
 
 
392 THE DEVELOPMENT OF THE CHICK
 
from the adjacent peritoneum (Fig. 217). The germinal epithelium lies between the base of the mesentery and the mesonephros
at first, but as the latter grows and projects into the body-cavity
the germinal epithelium is drawn on to its median surface. It is
difficult to determine its antero-posterior extent in early stages;
it begins near the point of origin of the omphalomesenteric arteries,
and its posterior termination is indefinite, but it certainly extends
over seven or eight somites.
 
Two kinds of cells are found in the germinal epithelium, viz.,
the ordinary peritoneal cells and the primordial germ-cells. The
latter are typically round, and several times as large as the
peritoneal cells (Figs. 226 and 227); the cytoplasm is clear
but contains persistent yolk granules and a large attraction
sphere, and the nucleus contains one or two nucleoli; they
are sharply distinguishable from the peritoneal cells, and they
may be traced through a continuous series of later developmental stages into the ova and spermatozoa. The origin of
these primordial germ-cells is therefore a matter of considerable
interest.
 
Two views have been held: (1) that they are derived from
the peritoneal cells, and (2) that they have an independent history
antecedent to the differentiation of a germinal epithelium, representing in fact undifferentiated embryonic cells that reach the
germinal epithelium by migration from their original source.
The former view was due to Waldeyer, and was supported by
observations of cells intermediate in structure between the primordial germ-cells and cells of the peritoneum (e.g. by Semon).
These observations have, however, been shown to be erroneous.
The second view has been demonstrated for a considerable number
of vertebrates; and quite recently Swift has shown that the
primordial germ-cells of the chick arise from the germ-wall at the
anterior margin of the pellucid area in a late stage of the primitive
streak; that they later enter the blood stream and are carried
into the embryo; some, which reach various inappropriate positions, degenerate; but others leaving the blood near the base of
the mesentery reach the germinal epithelium by migration. The
independent and early origin of germ-cells has an obvious
bearing on the theory of the continuity of the germ-plasm of
Weismann.
 
 
 
THE URINOGENITAL SYSTEM
 
 
 
393
 
 
 
Two other epithelial constituents enter into the composition of
the indifferent gonad, viz.: the rete tissue or cords of the urinogenital union, and the sexual cords. These lie between the germinal epithelium and the glomeruli of the Wolffian body. Between
these elements is a sparse mesenchyme continuous with the surrounding mesenchyme, constituting the stroma of the gonad.
 
 
 
.*,^
 
 
 
V
 
 
 
ty.b
 
 
 
 
 
 
 
 
 
• V^
 
 
 
^V^.-_
 
 
 
 
 
 
 
;*
 
 
 
m
 
 
 
w -*■•« ' * '
 
 
 
'A~s t.
 
 
 
Fig. 226. — Cross-section through the genital primordium of Limosa segocephala. (After Hoffmann, from Fehx and Biihler.)
 
The stage is similar to that of a chick embryo of 4| days.
 
Germ., Germinal epithelium. Mst., Mesentery. S. C., Rete cords.
v., Posterior cardinal vein. W. D., Wolffian duct.
 
 
 
Some primordial germ-cells occur in the stroma, though most are
in the germinal epithelium.
 
The rete cords appear within the gonad on the fifth day;
they are solid cords of epithelial cells that fill up the interior
 
 
 
394 THE DEVELOPMENT OF THE CHICK
 
of the gonad and cause it to protrude from the surface of the
Wolffian body (Fig. 226); the cords extend from the germinal
epithelium towards the hilum of the gonad (represented at this
time by the broad surface opposed to the Wolffian body), and
into the Wolffian body where they enter into close connection
with the renal corpuscles. In the Wolffian body and intermediate
zone they are very irregular in their course and connected by
numerous anastomoses, corresponding to the rete region of the
future testis. Strands of these cells pass dorsally, and, according
to some authors, form the cortical cords of the suprarenal capsules
(Fig. 226).
 
The following views of the origin of the rete cords in birds
have been held: (1) That they arise as outgrowths of the capsules
of renal corpuscles (Hoffmann, Semon) and the neck of the
Wolffian tubules also (Semon); (2) that they are ingrowths of
the germinal epithelium (Janosik); (3) that they differentiate
from the stroma (Prenant, Firket). The subject is a somewhat
difficult and complicated one, but the view that the rete cords
arise as outgrowths of the capsules of renal corpuscles brings the
birds into line, in this respect, with the reptiles and amphibia.
Hoffmann's observation that the rete cords lie at first on the
lateral side of the blood-vessels intervening between the germinal
epithelium and the Wolffian body, and that the cells of the cords
are directly continuous with those of the capsules, should be
conclusive.
 
The sexual cords arise as proliferations of the germinal epithelium which appear as buds projecting into the stroma (Fig.
227). They are definitely limited in time of origin between the
middle of the fifth and sixth days of incubation (Swift). They
carry with them numerous primordial germ-cells from the germinal
epithelium. About the end of the sixth day all free themselves
from the germinal epithelium, and a layer of stroma begins to
separate them sharply from the latter. They are destined to
form the seminiferous tubules in the male, and the so-called
medullary cords in the female.
 
Sexual Differentiation. The period of morphological indifference of the gonad is relatively long and the actual sexual differentiation appears slowly. It manifests itself (1) in differences in
the behavior of the germinal epithelium; (2) of the sexual cords;
 
 
 
THE URINOGENITAL SYSTEM
 
 
 
395
 
 
 
(3) larger size of the left ovary and ultimate disappearance of the
right one; (4) behavior of the stroma, particularly the albuginea.
The sex of the embryo can first be definitely determined about
the 156th hour, by the relative sizes of the two gonads, by the behavior of the germinal epithelium and by the presence of a larger
 
 
 
K,'-^
 
 
 
 
 
 
germ. ep.
 
 
 
pro.
 
 
 
m.
 
 
 
y^''^/.
 
 
 
 
 
 
4
 
 
 
 
 
coelom
 
 
 
 
 
.fSf
 
 
 
 
 
 
 
 
 
 
 
 
Fig. 227. — Portion of a transverse section through an
ovary of a 6^ day chick embryo (after Swift), germ,
ep., germinal epitheHum. m. c, sexual cord. pr. o.,
primordial germ-cells.
 
number of primordial germ-cells in the germinal epithelium of
 
the female. (Swift.)
 
As already stated, the sexual cords form the seminiferous
tubules of the testis; they are made up of two kinds of cells, viz.:
the primordial germ-cells and the ordinary peritoneal cells derived
from the germinal epithelium. After the seventh day they constitute most of the bulk of the testis, and the rete cords are pressed
towards the hilum by the sexual cords which radiate in that direc
 
 
396
 
 
 
THE DEVELOPIMENT OF THE CHICK
 
 
 
tion. The sexual cords now begin to branch and anastomose,
and soon form a reticulmn with mesenchyme in the meshes. About
the thirteenth day the primordial germ-cells, which have been
inactive, begin to divide, and a rapid increase in numbers ensues.
 
 
 
Intc. sir.
 
 
 
 
> -*=
 
 
 
 
 
 
m^f
 
 
 
 
 
 
'^:y/:
 
 
 
•%
 
 
 
vSJ*;*
 
 
 
?^:
 
 
 
.?*'
 
 
 
?,i'
 
 
 
 
 
 
Fig. 228. — Portion of a transverse section through the right testis of a
20 day chick embryo. The section shows a seminiferous cord in which a
lumen is beginning to develop. Note the position and polarization of the
spermatogonia (after Swift).
Int. c, interstitial cells. L., beginning of lumen. M. C, Mitochondrial
granules within a spermatogonium, p. c, supporting cells, derivatives of
peritoneal cells of the sexual cords, s. c, seminiferous cord, sp., spermatogonia, str., stroma.
 
The sexual cords are solid up to about the twentieth day of incubation; a lumen then begins to appear and they become transformed into tubules (Fig. 228). The primordial germ-cells form
the spermatogonia, and the peritoneal cells form the supporting
cells of the seminiferous tubules (Swift).
 
After the sixth day the germinal epithelium of the testis
rapidly retrogresses and becomes reduced to a thin peritoneal
 
 
 
THE URIXOGENITAL SYSTEM 397
 
endothelium. The stroma of the primitive testis remains scanty
up to the eleventh day. It then increases rapidly between the
sexual cords and also forms a layer between germinal epithelium
and seminiferous tubules, which becomes the albuginea. Interstitial cells appear in the stroma of the testis about the thirteenth
day and increase so rapidly as to form an immense amount by the
twentieth day (Swift).
 
As the testis increases in size it projects more from the surface of the Wolffian body, and folds arise above and below it
as well as in front and behind, that progressively narrow the
surface of apposition, which in this way becomes gradually
reduced to form the hilum of the testis, through which the rete
cords pass to the neighboring renal corpuscles (cf. Figs. 221 and
 
222).
 
As the testis is attached to the anterior portion of the Wolffian
body, the latter may be divided in two portions, an anterior
sexual and a posterior non-sexual portion. In the latter part of
the period of incubation the non-sexual portion undergoes absorption while the anterior portion becomes converted into the
 
epididymis.
 
The irregularly anastomosing rete cords in the region of the
hilum are united to the neighboring renal corpuscles by the original
strands and these form the vasa efferentia. In order to complete
the urinogenital union it is necessary that the rete cords unite
with the seminiferous tubules. The exact manner in which this
takes place has not been worked out for the chick; but there is
no doubt that this union does take place so that the seminiferous
tubules connect by way of the rete with the mesonephric tubules
and thus with the Wolffian duct.
 
As regards the formation of the epididymis: the renal corpuscles
of the Wolffian tubules concerned diminish in size, the glomerulus disappears and the cells of the capsule become cylindrical.
These changes progress from the lateral side of the Wolffian
body towards the testis; that is to say, the more lateral corpuscles
are first affected. A rudiment of the non-sexual part of the
Wolffian body persists in the . mesorchium of the male, between
testis and kidney. It is known as the paradidymis.
 
The development of the ovary in the chick has been studied
in recent years by Firket and by Swift.
 
The right ovary never undergoes much development after
 
 
 
398
 
 
 
THE DEVELOPMENT OF THE CHICK
 
 
 
the indifferent stage; it is destined to retrogress, and finally it
disappears.
 
In the indifferent gonad the sexual cords are formed in the
same way whether the organ is to become ovary or testis; but,
whereas in the case of the testis these cords are destined to form
the functional seminiferous tubules, in the case of the ovary they
form only the cords of the medulla. The cortex of the ovary
which includes the functional follicles develops from a second
 
 
 
 
Fig. 229. — Cross-section of the ovary of a young embryo of Numenius
arcuatus. (After Hoffmann.)
bl. v., Blood-vessel, germ. Ep., Germinal epithelium, r., rete ovarii.
s. c, Sexual cord.
 
proHferation of the germinal epithelium. The sexual cords cease
to grow, and become converted into tubes with a wide lumen,
and low epithehum; shortly after hatching they entirely disappear.
 
The characteristic feature of the development of the ovary is
a second period of intensive growth of the germinal epithelium
accompanied by a rapid increase of the primordial germ-cells
contained in it. This goes on very rapidly during the eighth to
the eleventh days of incubation. The inner surface of the germinal epithelium, or ovigerous layer of the ovary, begins to form
 
 
 
THE URIXOGEXITAL SYSTEM
 
 
 
399
 
 
 
low irregular projections into the stroma, or the latter begins to
penetrate the ovigerous layer at irregular distances so as to
produce elevations. This condition is well illustrated in Fig.
229.
 
In the course of development the ovigerous layer continually
increases in thickness, and the projections into the stroma form
veritable cords of ovigerous tissue, which correspond to the
 
 
 
i^s^^iS:
 
 
 
^^
 
 
 
 
 
 
 
 
Fig. 230. — Cross-section of the ovary of a fledgling of Numenius arcuatus 3-4 days old. The germinal epithelium is below. (After
Hoffmann.)
s. c, Sexual cords.
 
cords of Pfltiger in the mammalian ovary. The cords carry
the primitive ova with them. The surface of the ovary also
begins to become lobulated by the extension of the stroma trabeculae. Successive stages in the growth and differentiation of
the primitive ova occur from the surface towards the inner ends
of the ovigerous strands. Fig. 230 represents a section through
 
 
 
400 THE DEVELOPIMENT OF THE CHICK
 
the ovary of a fledgling of Numenius arcuatus three or four days
old. The germinal epithelium covers the surface and is continuous with the ovigerous strands projecting far into the stroma.
The strands are broken up in the stroma into nests of cells;
next the germinal epithelium are found characteristic primitive ova, but in deeper situations the primitive ova are larger
and each is accompanied by a group of epithelial cells, which are
distinctly differentiated as granulosa cells of young follicles in
the deepest. Thus the young follicles arise by separation of
nests of cells from the ovigerous strands within the stroma;
each nest includes a young ovocyte and a group of epithelial
cells which arrange themselves in a single layer of cuboidal cells
around the ovocyte. On each side of the free border of the ovary
the embryonic state persists, and it is not known whether this
condition is maintained permanently, as in some reptiles, or
not.
 
The atrophy of the Wolffian body is much more complete in
the female than in the male; no part of it remains in a functional
condition, but the part corresponding to the epididymis of the
male remains as a rudiment, known as the epoophoron. It has
almost the same structure in young females as in young males,
but the rete cords uniting it with the ovary do not become tubular.
A rudiment of the non-sexual part of the Wolffian body is also
found in the hen between ovary and Iddney in the lateral part of
the mesovarium; it has been named the paroophoron.
 
Development of the Genital Ducts. The Wolffian Duct. The
origin and connections of the Wolffian ducts have been already
sufficiently described. In the male they are connected with the
seminiferous tubules by way of the epididymis, vasa efferentia,
and rete, and function as vasa deferentia exclusively, after degeneration of the mesonephros. Subsequently they become
somewhat convoluted, acquire muscular walls and a slight terminal dilatation. The details of these changes are not described
in the literature. In the female the Wolffian duct degenerates;
at what time is not stated in the literature, but presumably along
with the Wolffian body.
 
The Mullerian Duct. The Miillerian duct, or oviduct, is laid
down symmetrically on both sides in both male and female embryos; subsequently both right and left ]\Iiillerian ducts degenerate in the male; in the female the right duct degenerates, the
 
 
 
THE URIXOGEXITAL SYSTEM 401
 
left only remaining as the functional oviduct. We have now to
consider, therefore, (1) the origin of the ducts during the indifferent stage, and (2) their subsequent history in the male
and in the female.
 
The origin of the IMlillerian duct is preceded by the formation
of a strip of thickened peritoneum on the lateral and superior
face of the Wolffian body extending all the way to the cloaca
(cf. Fig. 220). This strip, which may be called the tubal ridge,
appears first at the anterior end of the Wolffian body on the
fourth da}", and rapidly differentiates backwards; it lies immediately external to the Wolffian duct. The anterior part of the
Miillerian duct arises as a groove-like invagination of the tubal
ridge at the cephalic end of the Wolffian body immediately
behind the external glomeruli of the pronephros. The hps of
this groove then approach and fuse on the fifth day, so as to form
a tube which soon separates from the ridge. This process, however, takes place in such a way as to leave the anterior end of
the tube open and this constitutes the coelomic aperture of the
oviduct, or ostium tuh(£ abdominale. Moreover, the closure of
the groove does not take place uniformly, and one or two openings into the Miillerian duct usually occur near the ostium on
the fifth clay. Typically, however, these soon close up, though
persistence of one of them may lead, as a rather rare abnormality,
to the occurrence of two ostia in the adult. There is no ground
for the view (see Balfour and Sedgwick) that the two or three
openings into the anterior end of the Miillerian duct correspond
to nephrostomes of the pronephros; they are situated too far
posteriorly and laterally to bear such an interpretation.
 
The anterior part of the Miillerian duct is thus formed by
folding from the epithelium of the tubal ridge; it constitutes a
short epithelial tube situated between the Wolffian duct and the
tubal ridge, ending blindly behind. The part thus formed is relatively short; the major portion is formed by elongation of the
anterior part, which slowly grows backwards between the Wolffian
duct and the tubal ridge, reaching the cloaca on the seventh day.
The growing point is solid and appears to act like a wedge separating the Wolffian duct and the tubal ridge, being thus closely
pressed against both, but apparently without receiving cells from
either. Balfour's view, that it grows by splitting off from the
Wolffian duct or at the expense of cells contributed by the latter,
 
 
 
402 THE DEVELOPAiEXT OF THE CHICK
 
has not been supported by subsequent investigators. A short
distance in front of the growing point the Mullerian duct receives
a kuiien, and mesenchyme presses in from above and below,
and forms a tunic of concentrically arranged cells around it
 
(Fig. 221).
 
The ]Mullerian duct thus begins to project above the surface
of the Wolffian body, and, as it does so, the thickened epithelium
of the tubal ridge becomes flat and similar to the adjacent peritoneum; whether it is used up in the formation of the mesenchymatous tunic of the epithelial Mullerian duct is not known.
Up to this time the development is similar in both sexes and on
both sides of the body.
 
In the male development of these ducts ceases on the eighth
day; retrogression begins immediately and is completed, or at
any rate far advanced, on the eleventh day. In this process the
epithelial wall disappears first, and its place is taken by cells
of mesenchymatous appearance, though it is not known that
transformation of one kind into the other takes place. Retrogression begins posteriorly and proceeds in the direction of the
head; the ostium is the last to disappear. The mesenchymatous
tunic shares in the process, so that the ridge is no longer found
(see Fig. 222). In the male the IMullerian ducts never open into
 
the cloaca.
 
In the female the development of the right Mullerian duct
ceases after the eighth day, and it soon begins to degenerate. Its
lumen disappears and it becomes relatively shorter, so that its
anterior end appears to slip back along the Wolffian body. On
the fifteenth day slight traces remain along its former course and
a small cavity in the region of the cloaca. It never obtains an
opening into the cloaca (Gasser).
 
With the degeneration of the anterior end of the Wolffian
body the ostium tubse abdominale comes to be attached by a
Ugament to the body-wall (Fig. 231); farther back the ligamentous attachment is to the Wolffian body.
 
The fimbriae begin to develop on the eighth day on both
sides in both sexes. It is only in the left oviduct of the female, however, that development proceeds farther, and differentiation into ostium, glandular part, and shell gland takes
place. This appears distinctly about the twelfth day. The
lower end expands to form the primordium of the shell
 
 
THE URIXOGEXITAL SYSTEM
 
 
 
403
 
 
 
gland at this time, but does not open into the cloaca. Indeed,
the opening is not established until after the hen is six months
old (Gasser.)
 
 
 
Aom
 
 
 
M'cj2
 
 
 
pl.C.r
 
 
 
/iec.p/j.e/iii'
 
 
 
o.r.a
 
 
 
 
 
 
 
Vcd.l.
 
 
 
Aar.v.c
 
 
 
Fig. 231. — Photograph of a cross-section of an embryo of 8 clays through the
 
ostia tubae abdominaha.
 
a. A. S., Xeck of abdominal air-sac. O. T. a., Ostium tubae abdominale.
M's't.ac, Accessory mesentery, pi. C. r., 1., Right and left pleural cavities.
Rec. pn. ent. r., Right pneumato-enteric recess. V. c. a. 1., Left anterior
vena cava. R., rib. Other abbreviations as before.
 
 
 
IV. The Suprarenal Capsules
 
The suprarenals of the hen are situated medial to the anterior
lobe of the kidney, in the neighborhood of the gonad and vena
cava inferior. They have a length of about 8-10 mm. The
substance consists of two kinds of cords of cells, known respectively as cortical and medullary cords, irregularly intermingled:
the so-called cortical cords make up the bulk of the substance,
and the medullary cords occur in the meshes of the cortical cords.
 
 
 
404 THE DEVELOPMENT OF THE CHICK
 
The terminology does not, therefore, describe well the topographical arrangement of the components; it was derived from
the condition found in many mammals, the cortical cords of the
birds corresponding to the cortical substance, and the medullary
cords to the medullary substance of mammals. The medullary
cords are often called phseochrome or chromaffin tissue on account
of the specific reaction of the constituent cells to chromic acid,
and their supposed genetic relation to tissue of similar composition
and reaction found in the carotid glands and other organs associated with the sympathetic system.
 
The embryonic history has been the subject of numerous
investigations, and has proved a particularly difficult topic, if
we are to judge from the variety of views propounded. Thus
for instance it has been maintained at various times: (1) that
cortical and medullary cords have a common origin from the
mesenchyme; (2) that they have a common origin from the
peritoneal epithehum; (3) that the origin of the cortical and
medullary cords is absolutely distinct, the former being derived
from the sexual cords by way of the capsules of the renal corpuscles and the latter from the sympathetic ganglia; (4) that
their origin is distinct, but that the cortical cords are derived
from ingrowths of the peritoneum, and the medullary cords from
sympathetic ganglia. The first view may be said now to be
definitely abandoned, and no one has definitely advocated a
common epithehal origin since Janosik (1883). Thus it may
be regarded as well estabUshed that the two components have
diverse origins, and it seems to the writer that the fourth view
above is the best supported. (See Poll and Soulie.) The comparative embryological investigations strongly support this
view.
 
Origin of the Cortical Cords. According to Soulie, the
cortical cords arise as proliferations of a special suprarenal zone
of the peritoneum adjacent to the anterior and dorsal part of
the germinal epithehum. This zone is distinguishable early on
the fourth day, and begins about half a millimeter behind the
glomeruH of the pronephros, extending about a millimeter in a
caudal direction. Proliferations of the peritoneal epithelium are
formed in this zone, and soon become detached as groups of
epithelial cells lying in the mesenchyme between the anterior
end of the Wolffian body and the aorta. Such proliferation con
 
 
THE URINOGEXITAL SYSTEM 405
 
tinues up to about the one hundredth hour or a httle later, and
a second stage in the development of the cortical cords then
begins: The cords grow rapidly and fill the space on the mediodorsal aspect of the AVolffian body, and then come secondarily
into relation with the renal corpuscles of the latter and the sexual
cords.
 
According to Semon and Hoffmann the relation thus established is a primary one, that is to say, that the cortical cords
arise from the same outgrowths of the capsules of the renal corpuscles that furnish the sexual cords. Rabl agrees essentially
with Soulie, and it seems probable that Semon and Hoffmann
have overlooked the first stages in the origin of the cortical cords
of the suprarenal corpuscles.
 
During the fifth, sixth, and seventh days there is a very
rapid increase of the cortical cords accompanied by a definite
circumscription of the organ from the surrounding mesenchyme;
however, no capsule is formed yet. The topography of the organ
on the eighth day is shown in Figs. 150 and 182. Whereas during
the fourth, fifth, and sixth days the arrangement of the cortical
cells is in masses rather than in cords, on the eighth day the
cords are well developed, in form cylindrical with radiating cells,
but no central lumen. The organ has become vascular, and the
vessels have the form of sinusoids, i.e., they are moulded on the
surface of the cords with no intervening mesenchyme.
 
Origin of the Medullary Cords. The medullary cords take
their origin unquestionably from cells of the sympathetic nervous system. During the growth of the latter towards the mesentery, groups of sympathetic cells are early established on or near
the dorso-median surface of the cortical cords (Fig. 226). The
ingrowth of the sympathetic medullary cords does not, however,
begin until about the eighth day. At this time there is a large
sympathetic ganglionic mass on the dorso-median surface of the
anterior end of the suprarenal, and strands of cells characterized
sharply by their large vesicular nuclei and granular contents
can be traced from the ganglion into the superficial part of the
suprarenal. These cells are precisely like the specific cells of
the ganglion, perhaps a little smaller, and without axones. On
the eleventh day these strands have penetrated through a full
third of the thickness of the suprarenal, and are still sharply
characterized, on the one hand by their resemblance to the
 
 
 
406 THE DEVELOPMENT OF THE CHICK
 
sympathetic ganglion cells, and on the other by their clear
differentiation from the cells of the cortical cords. These
occupy the relations characteristic of the differentiated medullary cords, and there can be httle doubt that they develop into
them.
 
 
 
CHAPTER XIV
THE SKELETON
 
I. General
 
From an embryological point of view, tlie bones of the body,
their associated cartilages, the ligaments that unite them together
in various ways, and the joints should be considered together,
as they have a common origin from certain aggregations of
mesenchyme. The main source of the latter is the series of
sclerotomes, but most of the bones of the skull are derived from
the unsegmented cephalic mesenchyme.
 
Most of the bones of the body pass through three stages in
their embryonic development: (1) a membranous or prechondral
stage, (2) a cartilaginous stage, (3) the stage of ossification.
Such bones are known as cartilage bones, for the reason that
they are preformed in cartilage. Many (see p. 433 for list) of
the bones of the skull, the clavicles and the uncinate processes of
the ribs do not pass through the stage of cartilage, but ossification takes place directly in the membrane; these are known as
membrane or covering bones. The ontogenetic stages of bone
formation parallel the phylogenetic stages, membrane preceding
cartilage, and the latter preceding bone in the taxonomic series.
Thus, in Amphioxus, the skeleton (excluding the notochord)
is membranous; in the lamprey eel it is partly membranous and
partly cartilaginous; in the selachia it is mainly cartilaginous; in
higher forms bone replaces cartilage to a greater or less degree.
The comparative study of membrane bones indicates that they
were primitively of dermal origin, and only secondarily grafted
on to the underlying cartilage to strengthen it. Thus the cartilage bones belong to an older category than the membrane
bones.
 
The so-called membranous or prechondral stage of the skeleton
is characterized simply by condensation of the mesenchyme.
Such condensations arise at various times and places described
 
407
 
 
 
408 THE DEVELOPMENT OF THE CHICK
 
beyond, and they often represent the primordia of several future
bony elements. In such an area the cells are more closely aggregated, the intercellular spaces are therefore smaller, and the
area stains more deeply than the surrounding mesenchyme.
There are, of course, stages of condensation in each case, from
the first vague and undefined areas shading off into the indifferent
mesenchyme, up to the time of cartilage or bone formation,
when the area is usually well defined. In most of the bones,
however, the process is not uniform in all parts; the growing
extremities may be in a membranous condition while cartilage
formation is found in intermediate locations and ossification has
begun in the original center of formation; so that all three stages
may be found in the primordium of a single bone {e.g., scapula).
Usually, however, the entire element is converted into cartilage
before ossification begins.
 
The formation of cartilage (chondrification) is brought about
by the secretion of a homogeneous matrix of a quite special character, which accumulates in the intercellular spaces, and thus
gradually separates the cells; and the latter become enclosed in
separate cavities of the matrix; when they multiply, new deposits
of matrix form between the daughter cells and separate them.
As the original membranous primordium becomes converted into
cartilage, the superficial cells flatten over the surface of the
cartilage and form a membrane, the perichondrium, which becomes the periosteum when ossification takes place.
 
The process of ossification in the long bones involves the following stages in the chick:
 
(1) Formation of Perichondral Bone. The perichondrium
deposits a layer of bone on the surface of the cartilage near its
center, thus forming a bony ring, which gradually lengthens into
a hollow cylinder by extending towards the ends of the cartilage.
This stage is well illustrated in Fig. 231 A and in the long bones
of Fig. 242; the bones of the wing and leg furnish particularly
good examples; the perichondral bone is naturally thickest in
the center of the shaft and thins towards the extremity of the
 
cartilages.
 
(2) Absorption of Cartilage. The matrix softens in the
center of the shaft and becomes mucous, thus liberating the
cartilage cells and transforming the cartilage into the fundamental tissue of the bone marrow. This begins about the tenth
 
 
 
THE SKELETON
 
 
 
409
 
 
 
day in the femur of the chick. The process extends towards the
ends, and faster at the periphery of the cartilage {i.e., next to
the perichondral bone) than in the center. In this way there
remain two terminal, cone-shaped cartilages, and the ends of the
cones project into the marrow cavity (Fig. 231 A).
 
(3) Calcification of Cartilage. Salts of lime are deposited in
the matrix of the cartilage at
 
the ends of the marrow cavity;
such cartilage is then removed
by osteoclasts, large multinucleated cells, of vascular endothelial origin, according to
Brachet (seventeenth or eighteenth day of incubation).
 
(4) Endochondral Ossification. Osteoblasts within the
marrow cavity deposit bone on
the surface of the rays of calcified cartilage that remain
between the places eaten out
by osteoclasts, and on the
irmer surface of the perichondral bone.
 
These processes gradually
extend towards the ends of
the bone, and there is never
any independent epiphysial
center of ossification in long
bones of birds, as there is in
mammals. The ends of the
bones remain cartilaginous
and provide for growth in length. Growth in diameter of the
bones takes place from the periosteum, and is accompanied by
enlargement of the marrow cavity, owing to simultaneous absorption of the bone from within. It is thus obvious that all of
the endochondral bone is removed from the shaft in course of
time; some remains in the spongy ends.
 
The details of the process of ossification will not be described
here, and it only remains to emphasize a few points. At a stage
shortly after the beginning of absorption of the cartilage in the
 
 
 
 
Fig. 231 A. — Longitudinal section of
the femur of a chick of 196 hours' incubation; semi-diagrammatic. (After
Brachet.)
 
art. Cart., Articular cartilage. C. C,
Calcified cartilage, end. B., Endochondral bone. M., Marrow cavity. P'ch.,
Perichondrium. P'os., Periosteum,
p'os. B., Periosteal bone. Z. Gr., Zone
of growth. Z. Pr., Zone of proliferation.
Z. R., Zone of resorption.
 
 
 
410 THE DEVELOPMENT OF THE CHICK
 
center of the shaft, the perichondral bone is invaded by capillary
vessels and connective tissue that break through into the cavity
formed by absorption; it is supposed by many that osteoblasts
from the periosteum penetrate at the same time. The marrow
of birds is derived, according to the best accounts, from the
original cartilage cells, which form the fundamental substance,
together with the intrusive blood-vessels and mesenchyme. The
endochondral osteoblasts are believed by some to be of endochondral origin (i.e., derived from cartilage cells), by others of
periosteal origin. For birds, the former view seems to be the
best supported.
 
In birds, calcification does not precede absorption of the
cartilage, as it does in mammals, until the greater part of the
marrow cavity is formed. The cones of cartilage, referred to
above, that are continuous with the articular cartilages, are
absorbed about ten days after hatching.
 
On the whole, perichondral ossification plays a more extensive
role in birds than in mammals. The endochondral bone formation begins relatively much later and is less extensive. The
bodies of the vertebrae, which ossify almost exclusively in an
endochondral fashion, form the main exception to this rule.
 
Ossification in membrane proceeds from bony spicules deposited between the cells in the formative center of any given
membrane bone. It spreads out from the center, the bony
spicules forming a network of extreme delicacy and beauty.
After a certain stage, the membrane bounding the surface becomes
a periosteum which deposits bone in dense layers. Thus a membrane bone consists of superficial layers of dense bone, enclosing
a spongy plate that represents the primitive bone before the
establishment of the periosteum.
 
The formation of bones proceeds from definite centers in all
three stages of their formation; thus we have centers of membrane formation, centers of chondrification and centers of ossification. Membranous centers expand by peripheral growth,
cartilage centers expand by the extension of cartilage formation
in the membrane from the original center of chondrification, and
bony centers expand in the original cartilage or membrane.
Several centers of chondrification may arise in a single primitive
membranous center; for instance, in the membranous stage, the
skeleton of the fore-limb and pectoral girdle is absolutely con
 
 
THE SKELETON 411
 
tinuoiis; cartilage centers then arise separately in different parts
for each of the bones: similarly for the hind-limbs and pelvic
girdle, etc. Separate centers of ossification may likewise appear
in a continuous embryonic cartilage, as for instance, in the base
of the skull or in the cartilaginous coraco-scapula, or ischioilium. Such centers may become separate bones or they may
subsequently fuse together. In the latter case, they may represent bones that were phylogenetically perfectly distinct elements,
as for instance, the prootic, epiotic, and opisthotic centers in
the cartilaginous otic capsule; or they may be of purely functional significance, as for instance, the separate ossifications in
the sternum of birds, or the epiphysial and diaphysial ossifications of the long bones of mammals. It is usually possible on
the basis of comparative anatomy to distinguish these two categories of ossification centers.
 
Phylogenetic reduction of the skeleton is also usually indicated in some manner in the embryonic history. Where elements
have completely disappeared in the ph3dogenic history, as for
instance, the missing digits of birds, they often appear as membrane formations in the embrvo, which then fade out without
reaching the stage of cartilage; if the latter stage is reached the
element usually fuses with some other and is therefore not really
missing, e.g., elements of the carpus and tarsus of birds (though
not all). But the ontogenetic reduction may go so far that
the missing elements are never distinguishable at any stage of
the embryonic history; thus, though the missing digits of birds
are indicated in the membranous stage, their component phalanges
are not indicated at all.
 
II. The Vertebral Column
 
The primordia of the vertebral column are the notochord
and sclerotomes. The former is the primitive axial support of
the body, both ontogenetically and phylogenetically. In both
components, notochord and sclerotomes, we may recognize a
cephalic and trunk portion. The notochord, as we have seen,
extends far into the head, and the sclerotomes of the first four
somites contribute to the formation of the occipital portion of
the skull. The cephalic parts are dealt with in the development
of the skull. The history of the notochord and sclerotomes will
be considered together, but we may note in advance that the
 
 
 
412 THE DEVELOPMENT OF THE CHICK
 
notochord is destined to be completely replaced by the bodies of
the vertebrae, derived from the sclerotomes.
 
The Sclerotomes and Vertebral Segmentation. The vertebral
segmentation does not agree with the primitive divisions of the
somites, but alternates with it; or in other words, the centers
of the vertebrae do not coincide with the centers of the original
somites, but with the intersomitic septa in which the segmental
arteries run. Thus each myotome extends over half of two
vertebral segments, and the spinal ganglia and nerves tend to
alternate with the vertebrae. It therefore happens that each myotome exerts traction on two vertebrae, obviously an advantageous
arrangement, and the spinal nerves lie opposite the intervertebral
foramina.
 
This arrangement is brought about by the development of
each vertebra from the caudal half of one sclerotome and the
cephalic half of the sclerotome immediately behind; parts of
two somites enter into the composition of each vertebra, as is
very obvious at an early stage: Fig. 232 represents a section
through the base of the tail of a chick embryo of ninety-six hours;
it is approximately frontal, but is inclined ventro-dorsally from
behind forwards. The original somites are indicated by the
myotomes and the segmental arteries. In the region of the
notochord one can plainly distinguish three parts to each
sclerotome, viz., (1) a narrow, median, or perichordal part
abutting on the notochord, in which no cUvisions occur either
within or between somites; (2) a caudal lateral cUvision distinguished by the denser aggregation of the cells from (3) the cephalic
division. Between the caudal and cephalic cUvisions of the sclerotome is a fissure (intervertebral fissure) which marks the boundary
of the future vertebrae. Each vertebra in fact arises from the
caudal component of one sclerotome and the cephalic component
of the sclerotome immediately behind. Between adjacent sclerotomes is the intersomitic septum containing the segmental artery.
If one follows these conditions back into successively earlier stages,
one finds that the intervertebral fissure arises from the primitive
somitic cavity, and that the distinction between caudal and
cephalic divisions of the sclerotome is marked continuously from a
very early stage by the presence of the intervertebral fissure and
the greater density of the caudal division, i.e., the cephalic component of each definitive vertebra.
 
 
 
THE SKELETOX
 
 
 
413
 
 
 
 
 
 
TT — ^5 — a « "o-w
 
 
 
 
 
 
'1 •^^•^-'o.ool
 
 
 
 
^/7 — ^ ^ifflii'
 
 
 
^
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
.«"»
 
 
 
 
 
 
, < r. ■,■
 
 
 
 
 
 
 
 
 
 
CdUd^C/ "^dl "■'5-S:^;
 
 
 
/y7/i:/^
 
 
 
 
 
 
 
7^^?l?
 
 
 
'»2g.' «>5.<' '• ^- .
 
 
 
 
 
 
 
.. °SS-,.
 
 
 
 
 
 
 
 
 
1 vs^-i.^-"^'":^^^-^^
 
 
 
 
 
5 'D
 
 
 
o v.
 
 
4^
 
 
 
■^s
 
 
 
 
 
 
y;7/j. /--^ XtCf"^ -fi-.sV^ -o. o " :
 
 
 
 
 
 
 
 
 
■'-r-,'fc'-V' •'»'£'';'■■'/<' '?<^ Co"© ^ -^ .li-a - - S.Jo
 
 
 
^ 6
 
 
 
 
 
~ ^ Ask ' S»Jo - , ^»
 
 
 
TK^r^
 
 
 
. .0^:^
 
 
 
 
 
 
 
^ «. . ', >^.-".,^e
 
 
 
«,,?rV.?:
 
 
 
^!.
 
 
 
"-J
 
 
 
Fig. 232.— Frontal section through the base of the tail of a chick
embryo of 96 hours. The anterior end of the section (above
in the figure) is at a higher plane than the posterior end.
caud. Scl., Caudal division of the sclerotome, ceph Scl Cephalic division of the sclerotome. Derm., Dermatome. Ep., Epidermis. Gn., Ganglion, int's. F., Intersomitic fissure int'v F
Intervertebral fissure. My., Mvotome. N'ch., Notochord Nt'
Neural tube, per'ch. Sh., Perichordal sheath, s. A., Segmental
artery.
 
 
 
414 THE DEVELOPMENT OF THE CHICK
 
Now, if one follows these components as they appear at successively higher levels in such a frontal section as Fig. 232, one
finds that the perichordal layer disappears in the region of the
neural tube, and that the spinal ganglia appear in the cephalic
division of the sclerotome, and almost completely replace it.
Thus the caudal division of the sclerotome is more extensive, as
well as denser, than the cephalic division.
 
In transverse sections one finds that the sclerotomic mesenchyme spreads towards the middle line and tends to fill all the
interspaces between the notochord and neural tube, on the one
hand, and the myotomes on the other. But there is no time at
which the sclerotome tissue of successive somites forms a continuous unsegmented mass in which the vertebral segmentation
appears secondarily, as maintained by Froriep, except in the thin
perichordal layer; on the contrary, successive sclerotomes and
vertebral components may be continuously distinguished, except
in the perichordal layer; and the fusion of caudal and cephalic
sclerotome halves to form single vertebrae may be continuously
followed. Thus, although the segmentation of the vertebrae is
with reference to the myotomes and ganglia, it is dependent
upon separation of original sclerotome halves, and not secondarily
produced in a continuous mass.
 
Summarizing the conditions at ninety-six hours, we may say
that the vertebrae are represented by a continuous perichordal
layer of rather loose mesenchvme and two mesenchvmatous
arches in each segment, that ascend from the perichordal layer
to the sides of the neural tube; in each segment the upper part
of the cephalic sclerotomic arch is occupied almost completely
by the spinal ganglion, but the caudal arch ascends higher, though
not to the dorsal edge of the neural tube. The cranial and caudal
arches of any segment represent halves of contiguous, not of the
same, definitive vertebra.
 
Membranous Stage of the Vertebrae. In the following or
membranous stage, the definitive segmentation of the vertebrae
is established, and the principal parts are laid down in the
membrane. These processes are essentially the same in all the
vertebrae, and the order of development is in the usual anteroposterior direction. As regards the establishment of the vertebral segments: Figs. 233 and 234 represent frontal sections
through the same vertebral primordia at different levels from
 
 
 
THE SKELETON
 
 
 
415
 
 
 
the thoracic region of a five-day chick. The notochord is
slightly constricted intervertebrally, and the position of the
intersegmental artery, of the myotomes and nerves, shows that
each vertebral segment is made up of two components representing succeeding sclerotomes. In the region of the neural
arches (Fig. 234) the line of union of cranial and caudal vertebral
components is indicated by a slight external indentation at the
place of union, and by the arrangement of the nuclei on each
side of the plane of union.
 
 
 
Cduc/.Sc/
ceph.Sc'.
 
//
 
 
• » ." '5',*' 'Ir "-V^ ^i*^-^-* -'.
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
:^^V:. .
 
 
 
 
 
 
 
 
 
Mj/-"^^^
 
 
 
ceph Sci.- ''^
 
 
 
^ \ . o c
 
 
y^i-
 
 
.y.y^;{^^> -jt^.> " /^^.^
 
 
 
 
 
 
 
 
 
 
Fig. 233. — Frontal section through the notochord and pri
mordia of two vertebrae of a 5-day chick; thoracic region.
 
Note intervertebral constrictions of the notochord. The
 
anterior end of the section is above.
 
N., Spinal nerve. Symp., Part of sympathetic cord. v. C,
Region of pleurocentrum, in which the formation of cartilage
 
 
 
has hegun.
 
 
 
Other abbreviations as in Fig. 232.
 
 
 
The parts of the vertebrae formed in the membranous stage
are as follows: (1) The vertebral body is formed by tissue of
both vertebral components that grows around the perichordal
sheath; (2) a membranous process (neural arch) extends from
the vertebral body dorsally at the sides of the neural canal; but
the right and left arches do not yet unite dorsally; (3) a lateral
or costal process extends out laterally and caudally (Fig. 233)
from the vertebral body between the successive myotomes.
 
The union of the right and left cephalic vertebral components
 
 
 
416
 
 
 
THE DEVELOPMENT OF THE CHICK
 
 
 
(caudal sclerotome halves) beneath the notochorcl is known as
the subnotochordal bar (Froriep). It forms earlier than the
remainder of the body of the vertebra and during the membranous
stage is thicker, thus forming a ventral projection at the cephalic
end of the vertebral body that is very conspicuous (Fig. 235).
 
 
 
caud-Se/.
 
 
 
 
 
 
 
 
 
 
 
 
 
caud Se/
 
s.A
cep/?.'5c/
 
 
 
 
 
 
 
cac/f^ ^C/
 
 
 
 
 
 
 
 
jtfy:
 
 
 
 
 
 
 
 
 
i A^.V
 
 
 
to ei\--^^ i-
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
»",-^*
•c,-^
 
 
 
>p.
 
 
 
 
 
 
S-li
 
 
 
Fig. 234. — Frontal section including the same vertebral primordia as Fig. 233, at a higher level through the neural arches,
a. C, Anterior commissure of the spinal cord. v. R., Ventral root of spinal nerve. Other abbreviations as before (Fig;.
232).
 
 
 
It chondrifies separately from the vertebral body and earlier.
Except in the case of the first vertebra it fuses subsequently
with the remainder of the vertebral body, and disappears as
 
 
 
THE SKELETOX
 
 
 
417
 
 
 
a separate component. Schauinsland has interpreted it as the
homologue of the haemal arches of reptilia {e.g., Sphenodon).
 
The membrane represents not only the future bony parts
but the ligaments and periosteum as well. Hence we find that
the successive membranous vertebrae are not separate structures
but are united by membrane, i.e., condensed mesenchyme, and
are distinguishable from the future ligaments at first only by
greater condensation. In the stage of Fig. 233, chondrification
has already begun in the vertebral body, hence there is a sharp
 
 
 
/v'a
 
 
 
Fig. 235. — Median sagittal section of the cervical region at
 
the end of the sixth day of incubation. (After Froriep.) x 40.
 
b. C, Basis cranii. iV. L. 1, 2, 3, First, second, and third
intervertebral ligaments, s. n. b. 1, 2, 3, 4, First, second, third,
and fourth subnotochordal bars (hypocentra). v. C. 3, 4,
Pleurocentra of third and fourth vertebrae.
 
 
 
distinction in this region l^etween the vertebral bod}^ and intervertebral discs. The centers of chondrification, however, grade
into the membranous costal processes and neural arches.
 
The vertebral segmentation has now become predominant as
contrasted with the primitive somitic.
 
The development of the vertebrae during the fifth day comprises: (1) Fusion of successive caudal and cephalic divisions of
 
 
 
418 THE DEVELOPMENT OF THE CHICK
 
the sclerotomes to form the definitive vertebrae; (2) union of the
cephaUc vertebral components beneath the notochord to form the
subnotochordal bar; (3) origin of the membranous vertebral
bodies and of the neural arch and costal processes.
 
Chondrification, or development of cartilage, sets in from the
following centers in each vertebra: (1) the cephalic neural arches
and subnotochordal bar, forming a horseshoe-shaped cartilage
at the cephalic end of each vertebra; (2) and (3) right and left
centers in the body of each vertebra behind the subnotochordal
bar, which soon fuse around the notochord; (the subnotochordal
bar probably corresponds to the hypocentrum, and the lateral
centers (2 and 3) to the pleurocentra of palaeontologists) ; (4) and
(5) centers in each costal process (Figs. 235 and 236). These
centers are at first separated by membrane, l)ut except in the
case of the costal processes, which form the ribs, the cartilage
centers flow together. The neural arches end in membrane
which gradually extends dcrsally around the upper part of the
neural tube, finally uniting above with the corresponding arches
of the other side to form the memhrana reuniens. The chondrification follows the extension of the membrane. During this
time the transverse processes of the neural arch and the zygopophyses are likewise formed as extensions of the membrane.
 
The distinction that some authors make between a primary
vertebral l^ody formed ]:)y chondrification within the perichordal
sheath, and a secondary vertebral body formed by the basal
ends of the arches surrounding the primary, is not a clear one
in the case of the chick.
 
On the seventh and eighth days the process of chondrification extends into all parts of the vertebra; the entire vertebra
is, in fact, laid down in cartilage on the eighth da}', although the
neural spine is somewhat membranous. Fig. 237 shows the
right side of four trunk vertebrae of an eight-day chick, prepared
according to the methylene b,lue method of Van Wijhe. The
 
 
 
Fig. 236. — Frontal section of the vertebral column and neighboring structures of a 6-day chick. Upper thoracic region. Note separate centers
of chondrification of the neural arch, centrum, and costal processes. Anterior end of section above.
B. n. A., Base of neural arch. br. N. 1, 2, 3, First, second, and third
brachial nerves. Cp. R., Capitulum of rib. iv. D., Intervertebral disc.
Mu., Muscles. N. A., Neural arch. T. R., Tuberculum of rib. V. C, Centrum of vertebra. Other abbreviations as before.
 
 
 
THE SKELETON
 
 
 
419
 
 
 
 
--jV.D.
 
 
 
420
 
 
 
THE DEVELOPMENT OF THE CHICK
 
 
 
notochord runs continuously through the centra of the four
vertebrae shown. It is constricted intra vertebrally and expanded
intervertebrally, so that the vertebral bodies are amphicoelous.
The intervertebral discs are not shown. A pre- and postzygapophysis is formed on each arch. It is by no means certain that the
parts separated by the clear streak shown in the figure extending
through centra and arches correspond to the sclerotomal components of the primitive vertebrae, though this was the interpretation of Schauinsland as shown in the figure; further
study seems necessary to determine the exact relations of the
primitive sclerotomal components to the parts of the definitive
vertebra. The successive vertebrae have persistent membranous
 
 
 
 
Fig. 237. — The right side of four bisected vertebrse of the trunk
 
of an 8-day chick. (After Schauinsland.)
 
caud. V. A., Caudal division of vertebral arch. ceph. v. A.,
Cephalic division of vertebral arch. N'ch., Xotochord.
 
connections in the regions of the neural spines, zygapophyses
and centra. These are shown in Figs. 238 and 239 (cf. also
Fig. 150) ; they are continuous with the perichondrium and all
are derived from unchondrified parts of the original membranous vertebrae.
 
Atlas and Axis (epistropheus). The first and second vertebrae agree with the others in the membranous stage. But, when
chondrification sets in, the hypochordal bar of the first vertebra does
not fuse with the body, but remains separate and forms its floor
(Figs. 238 and 239). The body of the first vertebra chondrifies
separately and is attached by membrane to the anterior end of
the body of the second vertebra, representing in fact the odontoid process of the latter. It has later a separate center of ossification, but fuses subsequently wdth the body of the second
vertebra, forming the odondoid process (Fig. 240).
 
 
 
THE SKELETON
 
 
 
421
 
 
 
Formation of Vertebral Articulations. In the course of development the intervertebral discs differentiate into a peripheral intervertebral ligament and a central suspensory ligament which at first
contains remains of the notochord. There is a synovial cavity
between the intervertebral and suspensory ligaments. This differentiation takes place by a process of loosening and resorption
 
 
 
 
Fig. 238. — Median sagittal section of the basis
 
cranii and first three vertebral centra of an
 
8-day chick.
 
B. C, Basi-cranial cartilage, iv. D. 1, 2, 3, 4,
 
First, second, third, and fourth intervertebral
 
discs. N. T., Floor of neural tube. s. n. b. 1, 2,
 
First and second subnotochordal bars. V. C.
 
1, 2, 3, First, second, and third pleurocentra.
 
of cells just external to the perichordal sheath (Fig. 241). The intervertebral ligament takes the form of paired, fibrous menisci, or, in
other words, the intervertebral ligaments are incomplete around
the bodies of the vertebrae dorsally and ventrally (Schwarck).
Ossification is well advanced in the clavicles, long bones,
 
 
 
422
 
 
 
THE DEVELOPMENT OF THE CHICK
 
 
 
and membrane bones of the skull before it begins in the vertebrae.
It takes place in antero-posterior order, so that a series of stages
may be followed in a single embryo (cf. Fig. 242). There are
three main centers for each vertebra, viz., one in the body and
one in each neural arch. The ossification of the centrum is almost
 
 
 
 
 
 
—Medobl
 
 
 
H'9^1112
 
 
 
.f
 
 
 
'." " ">• '•'ti't-'
 
 
 
 
 
 
 
 
oC-l.o
 
 
 
 
 
 
 
-^mk
 
 
 
 
 
 
 
 
 
T/ltl
rceiMS.
 
 
 
, i: f 'j'f' , ., f , n yc
 
 
 
 
 
 
■yj
 
 
 
.-^,4^V^J^/?^.^^
 
 
 
UJ:
 
 
 
 
 
 
5p.G/i2-Fi
 
 
 
 
^■>'i
 
 
 
'RVd.
 
 
 
-+,-'
 
 
 
'-■'oi-.S'"'- (,.'■>•,'■ I ■
 
 
 
5i/mp.Cn
 
 
 
-r/^V4
 
 
 
 
 
 
PiQ 239. — Lateral sagittal section of the same vertebrse (as in Fig.
 
238).
At 1, 2, Floor and roof of atlas. B. C, Basis cranii. Cerv. n. 1, 2,
First and second cervical nerves. Med. Obi., Medulla oblongata.
R. V. 2, 3, 4, Ribs of the second, third, and fourth vertebrse. V . A.
2, 3, Arches of the second and third vertebrse.
XII 2, Second root of hypoglossus.
 
entirely endochondral, though traces of perichondral ossification
may be found on the ventral and dorsal surfaces of each centrum
before the endochondral ossification sets in. The perichondral
centers soon cease activity. The endochondral centers arise
just outside the perichordal sheath near the center of each vertebra on each side of the middle line, but soon fuse around the
 
 
 
THE SKELETON
 
 
 
423
 
 
 
notochord, and rapidly spread in all directions, but particularly
towards the surface, leaving cartilaginous ends (Fig. 241). The
notochord is gradually reduced and exhibits two constrictions
 
 
 
 
Fig. 240. — The first cervical vertebrae of a young
 
embryo of Haliplana fuliginosa. (After Schauins
land.)
 
s.n.b. 1,2, First and second subnotochordal bars.
R. 3, 4, 5, 6, Ribs of the third, fourth, fifth, and sixth
cervical vertebrae.
 
 
 
and three enlargements within each centrum. The main enlargement occupies the center and the two smaller swellings the
cartilaginous ends, the constriction occurring at the junction of
the ossified areas and cartilaginous ends (Fig. 241).
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
J
 
 
 
Fig. 241. — Section through the body of a cervical vertebra of a chick embryo of about 12
days. (After Schwarck.)
 
1, Endochondral ossification. 2, Articular
cartilages. 3, Notochord. 4, Loosening of cells
of the intervertebral disc, forming a synovial
cavity. 5, Periosteum. 6, Ligamentum suspensorium surrounding the notochord.
 
 
 
424 THE DEVELOPMENT OF THE CHICK
 
The centers of ossification in the neural arches arise from
tlie perichondrium a short distance above the body of the vertebra, and form bony rings about the cartilaginous arch. They
gradually extend into all the processes of the neural arch. Thus
the neural arches are separated from the vertebral centra by a
disc of cartilage which is, however, finally ossified, fusing the
arches and centra. At what time this occurs, and at what
time endochondral ossification begins in the arches, is not
known exactly for the chick.
 
The vertebral column of birds is characterized by an extensive
secondary process of coalescence of vertebrae. Thus the two
original sacral vertebra? coalesce with a considerable number of
vertebrae, both in front and behind, to form an extensive basis
of support for the long iliac bones. The definitive sacrum may
be divided into an intermediate primary portion composed of
two vertebrge, an anterior lumbar portion, and a posterior caudal
portion. The development of these fusions has not been, apparently, worked out in detail for the chick. The bony centers are
all separate on the sixteenth day of incubation (cf. Fig. 249).
Similarly, the terminal caudal vertebrae fuse to form the so-called
pygostyle, which furnishes a basis of support for the tail feathers.
 
III. Development of the Ribs and Sternal Apparatus
In the membranous stage of the vertebral column, all of the
trunk vertebra? possess membranous costal processes the subsequent history of which is different in different regions. In the
cervical region these remain relatively short, and subsequently
acquire independent centers of chondrification and ossification.
The last two cervical ribs, however, acquire considerable length.
In the region of the thorax, the membranous costal processes
grow ventralward between the successive myotomes and finally
unite in the formation of the sternum (q.v.). In the lumbar and
sacral regions the membranous costal processes remain short.
The primary costal process is an outgrowth of the membranous
centrum, corresponding in position to the capitulum of the
definitive ril). The tuberculum arises from the primary costal
process while the latter is still in the membranous condition and
grows dorsal ward to unite with the neural arch in the region of
the transverse process. (See Fig. 236.)
 
The centers of chondrification and ossification of the typical
 
 
 
THE SKELETON 425
 
ribs (cervical and thoracic) arise a short distance lateral to the
vertebral centers, with which they are connected only by the
intervening membrane, which forms the vertebro-costal ligaments. Chondrification then proceeds distally.
 
The cervical ribs chondrify from a single center. The thoracic
ribs have two centers of chondrification; a proximal one, corresponding to the vertebral division of the rib. and a distal one
corresponding to the sternal division. The lumbar and sacral
membranous costal processes do not chondrify separately from
the vertebral bodies; if they persist at all, therefore, they appear
as processes of the vertebrae, and are not considered further.
 
In the fowl the atlas does not bear ribs, and in the embryo the primary
costal processes of this vertebra do not chondrify. The second to the
fourteenth vertebrae bear short ribs, with capitulum and tuberculum
bounding the vertebrarterial canal. The fourteenth is the shortest of
the cervical series. The fifteenth and sixteenth vertebrae bear relatively
long ribs, but, as these do not reach the sternum, they are classed as
cervical. The entire embryonic history, however, puts them in the
same class as the following sternal ribs; on an embryological basis they
should be classed as incomplete thoracic ribs. They possess no sternal
division, but the posterior one has an uncinate process like the true thoracal ribs. The following five pairs of ribs (vertebrae 17-21) possess
vertebral and sternal portions, but the last one fails to reach the sternal
rib in front of it.
 
The vertebral and sternal portions of the true thoracal ribs
meet at about a right angle in a membranous joint. This bend
is indicated in the membranous stage of the ribs.
 
The membranous ribs growing downwards and backwards
in the wall of the thorax make a sudden bend forward, and their
distal extremities fuse (seven and eight days) in a common membranous expansion (primordium of the sternum), which, however,
is separated from the corresponding expansion of the opposite
side bv a considerable area of the body-wall.
 
The vertebral and sternal portions of the ribs ossify separately;
the ossification of the ribs is exclusively perichondral up to at
least the sixteenth day (cf. Fig. 242).
 
The uncinate processes were not formed in any of the embryos
studied. Apparently they arise as separate membranous ossifications after hatching.
 
The sternum takes its origin from a pair of membranous expan
 
 
426
 
 
 
THE DEVELOPMENT OF THE CHICK
 
 
 
sions formed by the fusion of the distal ends of the first four
true thoracal ribs; the fifth pair of thoracal ribs does not take
part in the formation of the sternum. The sternum thus arises
as two distinct halves, which lie at first in the wall of the thorax
at the posterior end of the pericardial cavity (eight days). The
greatest extension of the sternal primordia is do rso- ventral, the
 
 
 
 
Fig. 242. — Photograph of the skeleton of a 13-day
chick embryo. Prepared by the potash method.
(Preparation and photograph by Roy L. Moodie.)
1, Premaxilla. 2, NasaL 3, lachrymaL 4, Parasphenoid. 5, Frontal. 6, Squamosal. 7, Parietal.
8, Exoccipital. 9, Cervical rib. 10, Coracoid. 11,
Scapula. 12, Humerus. 13, Ilium. 14, Ischium. 15,
Pubis. 16, Metatarsus. 17, Tibiofibula. 18, Palatine. 19, Jugal. 20, Maxilla. 21, Clavicle.
 
ventral extremities corresponding to the anterior end of the definitive sternum, which is formed by concrescence of the lateral halves
in the middle line beginning at the anterior end. The concrescence
 
 
 
THE SKELETON 427
 
then proceeds posteriorly, as the dorsal ends of the priraordia
rotate backwards and downwards towards the middle line.
 
Although there are two lateral centers of chondrification,
these soon fuse. The carina arises as a median projection very
soon after concrescence in any region, and progresses backwards,
rapidly following the concrescence. There is, therefore, no stage
in which the entire sternum of the chick is ratite, though this
condition exists immediately after concrescence in any region.
The various outgrowths of the sternum (episternal process, anterolateral and abdominal processes), arise as processes of the membranous sternum and do not appear to have independent centers
of chondrification.
 
The sternum ossifies from five centers, viz., a median anterior
center and paired centers in the antero-lateral and abdominal
processes. The last appear about the seventeenth day of incubation. On the nineteenth day a point of ossification appears
at the base of the anterior end of the keel. At hatching centers
also appear in the antero-lateral processes. The centers gradually
extend, but do not completely fuse together until about the third
month. The posterior end of the median division of the sternum
remains cartilaginous for a much longer period. In the duck
and many other birds there are only two lateral centers of ossification; the existence of five centers in the chick is, therefore,
probably not a primitive condition.
 
IV. Development of the Skull
 
The skull arises in adaptation to the component organs of
the head, viz., the brain, the sense organs (nose, eye, and ear)
and cephalic visceral organs (oral cavity and pharynx); it thus
consists primarily of a case for the brain, capsules for the sense
organs, and skeletal bars developed in connection with the margins of the mouth and the visceral arches. In the chick,
the primordia of the auditory and olfactory capsules are continuous ab initio with the primordial cranium; the protecting coat
of the eye (sclera) never forms part of the skull. Therefore, we
may consider the development of the skull in two sections, first
the dorsal division associated with brain and sense organs (neurocranium), and second, the visceral division or splanchnocranium.
Although the investment of the eyes forms no part of the skull,
yet the eyes exert an immense effect on the form of the skull.
 
 
 
428 THE DEVELOPMENT OF THE CHICK
 
Development of the Cartilaginous or Primordial Cranium.
 
(1) The Neurocranium. The neurocranium is derived from the
mesenchyme of the head, the origin of which has been described
previously. The mesenchyme gradually increases in amount and
forms a complete investment for the internal organs of the head.
It is not all destined, however, to take part in the formation of
the skeleton, for the most external portion forms the derma and
subdermal tissue; and, internal to the skeletogenous layer, the
membranes of the brain and of the auditory labyrinth, etc., are
formed from the same mesenchyme.
 
The notochord extends forward in the head to the hypophysis
(Figs. 67, 88, etc.), and furnishes a basis for division of the
neurocranium into chordal and prechordal regions. Within the
chordal division again, we may distinguish pre-otic, otic, and
post-otic regions according as they are placed in front of, around,
or behind the auditory sac. The part of the postotic region
behind the vagus nerve is the only part of the neurocranium
that is primarily segmental in origin. The sclerotomes of the
first four somites (Figs. 63 and 117) form this part of the skull;
and at least three neural arches, homodynamous with the vertebral arches, are formed in an early stage, but fuse together while
still membranous, leaving only the two pairs of foramina of the
twelfth cranial nerve as evidence of the former segmentation. It
is also stated that membranous costal processes are found in
connection with these arches, but they soon disappear without
 
chondrifying.
 
The primordial neurocranium is performed in cartilage and
corresponds morphologically to the cranium of cartilaginous
fishes. However, it never forms a complete investment of the
brain; except in the region of the tectum synoticum it is wide
open dorsally and laterally. It is subsequently replaced by
bone to a very great extent, and is completed and reinforced
by numerous membrane bones.
 
The neurocranium takes its origin from two quite distinct
primordia situated below the brain, viz., the parachordals and
the trabecular. The former develop on each side of and around
the notochord, being situated, therefore, behind the cranial
flexure and beneath the mid- and hind-brain; the trabeculae are
prechordal in position, being situated beneath the twixt-brain
and cerebral hemispheres, and extending forward through the
 
 
 
THE SKELETON 429
 
interorbital region to the olfactory sacs. It is obvious, therefore,
that the parachordals and trabeculse must form with relation to
one another the angle defined by the cranial flexure.
 
The parachordals appear in fishes as paired structures on
either side of the notochord, uniting secondarily around the
latter; but in the chick the perichordal portion is formed at the
same time as the thicker lateral portions, so that the parachordals
exist in the form of an unpaired basilar plate from the first. The
trabeculae are at first paired (in the earliest membranous condition), but soon fuse in front, while the posterior ends form a pair
of curved limbs (fenestra hypophyseos) that surrounds the infundibulum and hypophysis, and joins the basilar plate behind the
latter. At the same time that the parachordals and trabeculae
are formed by condensations of mesenchyme, the latter condenses also around the auditory sacs and olfactory pits in direct
continuity with the parachordals and trabeculae respectively; so
that the auditory and olfactory capsules are in direct continuity
with the base of the neurocranium from the beginning.
 
Chondrification begins in the primordial cranium about the
sixth day; it appears first near the middle line on each side, and
extends out laterally. Somewhat distinct centers corresponding
to the occipital sclerotomes may be found in some birds, but
they soon run together, and the entire neurocranium forms a
continuous mass of cartilage (sixth, seventh, and eighth days).
 
During this process the trabecular region increases greatly in
length simultaneouslv with the outgrowth of the facial region,
and the angle defined by the cranial flexure becomes thus apparently reduced. The posterior border of the fenestra hypophyseos
marks the boundary between the basilar plate and trabecular
region.
 
In the region of the basilar plate the following changes take
place: (1) in the post-otic or occipital region a dorso-lateral
extension (Fig. 244) fuses with the hinder portion of the otic
capsule, thus defining an opening that leads from the region of
the cavity of the middle ear into the cranial cavity (fissure metotica). This expansion is pierced by the foramina of the ninth
tenth and eleventh nerves. (2) The otic region becomes greatly
expanded by the enlargement of the membranous labyrinth. The
cochlear process grows ventrally and towards the middle line and
thus invades the original parachordal region (Fig. 168). The
 
 
 
430 THE DEVELOPMENT OF THE CHICK
 
posterior region of the otic capsule expands dorsally above the
hind-brain, and forms a bridge of cartilage extending from one
capsule to the other, known as the tectum synoticum (Fig. 244,
33). (3) The preotic region expands laterally and dorsally in
the form of a wide plate (alisphenoidal plate) which is expanded
transversely, and thus possesses an anterior face bounding the
orbit posteriorly and a posterior face forming part of the anterior
wall of the cranial cavity. This plate arises first between the
ophthalmic and maxillo-mandibular branches of the trigeminus,
and subsequently sends a process over the latter that fuses with
the anterior face of the otic capsule, thus establishing the foramen
prooticum.
 
For an account of numerous lesser changes, the student is referred
to Gaupp (1905), and the special literature (especially Parker, 1869).
The various foramina for the fifth to the twelfth cranial nerves are
defined during the process of chondrification ; the majority of these are
shown in the figures.
 
The trabecular region may be divided into interorbital and
ethmoidal (nasal) regions. The basis of the skeleton in this
region is formed by the trabecule alread}^ described. The median
plate formed by fusion of the trabeculse extends from the pituitary
space (fenestra hypophyseos) to the tip of the head; a high median
keel-like plate develops in the interorbital and internasal regions
 
Fig. 243. — Skull of an embryo of 65 mm. length; right side. Membrane
bones in yellow. Cartilage in blue. (Drawn from the model of W. Tonkoff ;
made by Ziegler.)
 
Fig. 244. — View of the base of the same model.
 
24.3-244. — 1, Squamosum. 2, Parietale. 3, Capsula auditiva. 4, Capsula auditiva (cochlear part). 5, Fissura metotica. 6, Epibranchial cartilage.
7, Sphenolateral plate. 8, Foramen prooticum. 9, Columella. 10. Otic process of quadratum. 11, Basitemporal (postero-lateral part of the parasphenoid).
12, Articular end of Meckel's cartilage. 13, Angulare. 14, Supra-angulare. 15,
Dentale. 16, Skeleton of tongue. 17, Pterygoid. 18, Palatine. 19, Rostrum
of parasphenoid. 20, Quadrato-jugal. 21, Jugal (zygomaticum). 22, Vomer.
23, Maxilla. 24, Premaxilla. 25, Anterior turbinal. 26, Posterior turbinal.
27, Nasale. 28, Prefrontal (lachrymale). 29, Antorbital plate. 30, Interorbital foramen. 31, Interorbital septum. 32,Frontale. 33, Tectum synoticum.
34, Foramen magnum. 35, Prenasal cartilage. 36, Orbital process of quadrate. 37, Articular process of Quadrate. 38. Fenestra basicranialis posterior.
39, Chorda. IX, Foramen glossopharyngei. X, Foramen vagi. XII, Foramina hypoglossei.
 
Fig. 245. — Visceral skeleton of the same model.
 
1, Dentale. 2, Operculare. 3, Angulare. 4, Supra-angulare. 5. Meckel's
cartilage. 6, Entoglossum (cerato-hyal). 7, Copula (1). 8, Pharyngobranchial (1). 9, Epibranchial. 10, Copula (2),
 
 
 
3?
 
 
 
30
 
 
 
3^y
 
 
 
 
f/g 243
 
 
 
 
 
f/"g t45
 
 
 
T,^
 
 
a4^
 
 
 
THE SKELETON 431
 
and fuses with the trabeculse, forming the septum interorbitale
and septum nasi (Fig. 243). The free posterior border of this
plate hes in front of the optic nerves; an interorbital aperture
arises in tlie plate secondarily (Fig. 243).
 
In the ethmoidal region the septum nasi arises as an anterior
continuation of the interorbital plate; and the trabecular plate
is continued forward as a prenasal cartilage in front of the olfactory sacs. Curved, or more or less rolled, plates of cartilage
develop in the axis of the superior, middle, and inferior turbinals
(see olfactory organ), and these are continuous with the lateral
wall of the olfactory capsules, which in its turn arises from the
dorsal border of the septum nasi (Figs. 243 and 244).
 
(2) The Origin of the Visceral Chondrocranium (Cartilaginous
Splanchnocranium) . The visceral portion of the cartilaginous
skull arises primarily in connection with the arches that bound
the cephalic portion of the alimentary tract, viz., oral cavity
and pharynx. In the chick, cartilaginous bars are formed in
the mandibular arch, hyoid arch, and third visceral arch. In
fishes, the posterior visceral arches also have an axial skeleton,
but hi the chick the mesenchyme of these arches does not develop
to the stage of cartilage formation. The elements of these arches
are primarily quite distinct. The upper ends of the mandibular
and hyoid skeletal arches are attached to the skull; and the lower
ends of the three arches concerned meet in the middle line. Two
medial elements or copulse are formed in the floor of the throat,
one behind the angle of the hyoid arch, and one behind the
third visceral arch (Fig. 245).
 
Mandibular Arch. Two skeletal elements arise in the mandibular arch on each side, a proximal one (the palato-quadrate) and a distal one (Meckel's cartilage). The former is
relatively compressed, and the latter an elongated element (Fig.
243, 10). The palato-quadrate lies external to the antero-vertral part of the auchtory capsule, and soon develops a triradiate
form. The processes are: the processus oticus, which applies
itself to the auditory capsule, the processus articidaris, which
furnishes the articulation for the lower jaw, and the processus
orhitalis, Avhich is directed anteromedially towards the orbit.
A small nodule of cartilage of unknown significance lies above
the junction of the processus oticus and otic labyrinth. Meckel's
cartilage is the primary skeleton of the lower jaw, corresponding
 
 
 
432 THE DEVELOPMENT OF THE CHICK
 
to the definitive lower jaw of selachians. It consists of two
rods of cartilage in the rami of the mandibular arch, which articulate proximally with the processus articularis of the palatoquadrate cartilage,, and meet distally at the symphysis of the
lower jaw. The form of the articulation of the lower jaw is early
defined in the cartilage (seven to eight days).
 
Hyoid Arch. The skeletal elements of the hyoid arch consist of
proximal and distal pieces (with reference to the neurocranium)
which have no connection at any time. The former are destined to
form the columella, and the latter parts of the hyoid apparatus.
The columella apparently includes two elements (in Tinnunculus
according to Suschkin, quoted from Gaupp) : a dorsal element,
interpreted as hyomandibular, in contact with the wall of the
otic capsule, and a small element (stylohyal) beneath the former.
The two elements fuse to form the columella, the upper end of
which is shown in Fig. 168. The stapedial plate (operculum of
the columella) is stated to arise in Tinnunculus from the wall
of the otic capsule, being cut out by circular cartilage resorption
and fused to the columella.
 
The distal elements of the hyoid arch consist of (1) a pair
of ceratohyals, which subsequently fuse in the middle line to
form the entoglossal cartilage, the proximal ends remaining free as
the lesser cornua of the hyoid, and (2) a median unpaired piece
(copula I or basihyal) behind the united ceratohyals (Fig. 245).
 
First Branchial Arch. The skeletal elements of the third visceral
(first branchial) arch are much more extensive than those of the
hyoid arch. They are laid down as paired cerato- and epi-branchial
cartilages on each side, and an unpaired copula II (basibranchial I)
in the floor of the pharynx, in the angle of the other elements
(Fig. 245). The cerato- and epibranchials increase greatly in
length, and form the long curved elements (greater cornua) of the
hyoid, which attain an extraordinary development in many birds.
 
Ossification of the Skull. The bones of the skull are of two
kinds as to origin: (1) those that arise in the primordial cranium,
and thus replace cartilage (cartilage bones or replacement bones),
and (2) those that arise by direct ossification of membrane (membrane or covering bones).
 
The cartilage bones of the bird's skull are: (a) in the occipital
region; the basioccipital, two exoccipitals, and the supraoccipitals; {h) in the otic region: prootic, epiotic, and opisthotic;
 
 
 
THE SKELETON 433
 
(c) in the orbital region: the basisphenoid, the orbitosphenoids,
the ahsphenoids and ossifications of the interorbital septum; (d) in
the ethmoidal region the bony ethmoidal skeleton; (e) the palatoquadrate cartilage furnishes the quadrate bone; (/) a proximal
ossification, the articulare, arises in Meckel's cartilage and fuses
later with membrane bones; (g) the upper part of the hyoid arch
furnishes the columella, and the ceratohyals the os entoglossum;
(h) the cerato- and epibranchials ossify independently, as also
do the two copulse. (See Figs. 243, 244 and 245.)
 
The membrane bones of the skull are: (a) in the region of the
cranium proper: parietals, frontals, squamosals; (6) in the facial
region: lachrymals, nasals, premaxillae, maxillae, jugals, quadrato-jugals, pterygoids, palatines, parasphenoid, and vomer; (c)
surrounding Meckel's' cartilage and forming the lower jaw: angulare, supra-angulare, operculare, and dentale. (See Figs. 243, 244
and 245.)
 
The embryonic bird's skull is characterized by a wealth of
distinct bones that is absolutely reptilian; but in the course of
development these fuse together so completely that it is only in
the facial and visceral regions that the sutures can be distinguished
readily.
 
In order of development the membrane bones precede the
cartilage bones, though the latter are phylogenetically the older.
Thus, about the end of the ninth day, the following bones are
present in the form of delicate reticulated bars and plates: all
four bones of the mandible, the faint outline of the premaxillae,
the central part of the maxillae, the jugal and quadratojugal, the
nasals, the palatines and pterygoids. The base of the squamosal
is also indicated by a small triangular plate ending superiorly in
branching trabeculae, delicate as frost-work. A faint band of
perichondral bone is beginning to appear around the otic process
of the quadrate, the first of the cartilage bones to show any
trace of ossification. These ossifications appear practically
simultaneously as shown by the examination of the earlier stages.
 
On the twelfth day these areas have expanded considerably,
and the frontals and prefrontals (lachrymals) are formed; the
rostrum of the parasphenoid is also laid down, and the exoccipitals appear in the cartilage at the sides of the foramen magnum.
The parietals appear behind the squamosal (Fig. 242) about the
thirteenth day; the basioccipitals soon after. The supraoc
 
 
434 THE DEVELOPMENT OF THE CHICK
 
cipital appears as a pair of ossifications in the tectum synoticum
on each side of the dorsal middle line, subsequently fusing
together.
 
A detailed history of the mode of ossification of all the various
bones of the skull would be out of place in this book. The figures
illustrate some points not described in the text. The reader is
referred to W. K. Parker (1869) and to Gaupp (1905).
 
V. Appendicular Skeleton
 
The appendicular skeleton includes the skeleton of the limbs
and of the girdles that unite the limbs to the axial skeleton. The
fore and hind-limbs, being essentially homonymous structures,
exhibit many resemblances in their development.
 
The Fore-limb. The pectoral girdle and skeleton of the
wing develop from the mesenchyme that occupies the axis and
base of the w^ng-bud, as it exists on the fourth day of incubation. It is probably of sclerotomic origin, but it is not known
exactly how many somites are concerned in the chick, nor which
ones. After the wing has gained considerable length (fifth day)
it can be seen from the innervation that three somites are principally involved in the wing proper, viz., the fourteenth, fifteenth,
and sixteenth of the trunk. But it is probable that the mesenchyme of the base of the wing-bud, from which the pectoral
girdle is formed, is derived from a larger number of somites.
 
It is important, then, to note first of all that the scapula,
coracoid, clavicle, humerus, and distal skeletal elements of the
wing are represented on the fourth day by a single condensation
of mesenchyme, which corresponds essentially to the glenoid
region of the definitive skeleton. From this common mass a
projection grows out distally in the axis of the wing-bud, and
three projections proximally in different directions in the bodywall. These projections are (1) the primordium of the wingskeleton, (2) of the scapula, (3) of the coracoid, (4) of the
clavicle.
 
The Pectoral Girdle. The elements of the pectoral girdle are
thus outgrowths of a common mass of mesenchyme. The scapula
process grows backward dorsal to the ribs; the coracoid process
grows ventralward and slightly posterior towards the primordium
of the sternum, thus forming an angle slightly less than a right
angle with the scapular process; and the clavicular process grows
 
 
 
THE SKELETON 435
 
out in front of the coracoid process ventrally and towards the
middle hne. ThevSe processes are quite well developed on the
fifth day, and increase considerably in length on the sixth day,
when the hind end of the scapula nearly reaches the anterior end
of the ilium, and the lower end of the coracoid is very close to
the sternum. The elements are still continuous in the glenoid
region.
 
About the end of the sixth day independent centers of chondrification appear in the scapula and coracoid respectively near
their imion; these spread distally and fuse centrally, so that
on the seventh day the coraco-scapula is a single bent cartilaginous element. In the angle of the bend, however (the future
coraco-scapular joint), the cartilage is in a less advanced condition than in the bodies of the two elements. The clavicular
process, on the other hand, never shows any trace of cartilage
formation, either in early or more advanced stages, but ossifies
directly from the membrane. It separates from the other elements of the pectoral girdle, though not completel}', on the eighth
dav.
 
The scapula and coracoid ossify in a perichondral fashion,
beginning on the twelfth da}^, from independent centers, which
approach but never fuse, leaving a permanent cartilaginous
connection (Fig. 242). The clavicle, on the other hand, is a
purely membrane bone; bony deposit begins in the axis of the
membranous rods on the eighth or ninth days, soon forming
fretted rods that approach in the mid-ventral line by enlarged
ends, which fuse directly without the intervention of any median
element about the twelfth to thirteenth day, thus forming the
furcula or wish-bone (Fig. 246).
 
The nature of the clavicle in birds has been the subject of a sharp
difference of opinion. On the one hand, it has been maintained that it
is double in its origin, consisting of a cartilaginous axis (procoracoid)
on which a true membrane bone is secondarily grafted (Gegenbaur, Fiirbringer, Parker, and others) ; on the other hand, all cartilaginous preformation in its origin has been denied by Rathke, Goette, and Kulczycki. After
careful examination of series of sections in all critical stages, and of
preparations made by the potash method, I feel certain that in the chick
at least there is no cartilaginous preformation. It is still possible (indeed probable on the basis of comparative anatomy) that the theory
of its double origin is correct phylogenetically; but it is certain that the
 
 
 
436
 
 
 
THE DEVELOPMENT OF THE CHICK
 
 
 
procoracoid component does not develop beyond the membranous stage
in the chick. It is interesting that the clavicle is the first center of ossification in the body, though perichondral ossification of some of the
long bones begins almost as soon.
 
The Wing-bones. The primordium of the wing-bones is
found in the axial mesenchyme of the wing-bud, which is originally continuous with the primordium of the pectoral girdle, and
shows no trace of the future elements of the skeleton. The
differentiation of the elements accompanies in general the external
differentiation of the wing illustrated in Figs. 121 to 124, Chapter
VII. The humerus, radius, and ulna arise by membranous differentiation in the mesenchyme in substantially their definitive
relations; they pass through a complete cartilaginous stage and
 
 
 
 
Fig. 246. — Photograph of the pectoral
girdle of a chick embryo of 274 hours;
prepared by the potash method. (Preparation and photograph by Roy L.
Moodie.)
 
1, Coracoid. 2, Clavicle. 3, Scapula.
4, Humerus.
 
 
 
then ossify in a perichondral fashion (see Fig. 242). In the
carpus, metacarpus, and phalanges, more elements are formed
in the membrane and cartilage than persist in the adult. Elimination as well as fusion takes place. These parts will therefore
require separate description.
 
As birds have descended from pentadactyl ancestors with
subsequent reduction of carpus, metacarpus, and phalanges, it
is naturally of considerable interest to learn how much of the
ancestral history is preserved in the embryology. The hand is
represented in the embryo of six days by the spatulate extremity
of the fore-limb, which includes the elements of carpus, metacarpus, and phalanges. From this expansion five digital rays
grow out simultaneously, the first and fifth being relatively
 
 
 
THE SKELETOX
 
 
 
437
 
 
 
small; the second, third, and fourth represent the persistent digits.
In each ray is a membranous skeletal element, which, however,
soon disappears in the first and fifth. Thus there are distinct
indications of a i^entadactyl stage in the development of the
bird's wing.
 
In the definitive skeleton there are but two carpal bones,
viz., a radiale at the extremity of the radius, and an ulnare at
the extremity of the ulna. In the embryo there is evidence of
seven transitory pieces in the carpus arranged in two rows, proximal and distal (Fig. 247). In the proximal row only two car
 
 
M.c.J
 
M c. 2
 
 
 
^A*"?^
 
 
 
jPcA
 
 
 
 
-U
 
 
 
M'c.-?^
 
 
 
Cp.^ Cp3 ^•^■
 
 
 
P'c/).
 
 
 
Fig. 247. — Skeleton of the wing of a chick embryo of 8 days. (After W.
 
K. Parker.)
 
Cp. 2, 3, and 4, Second, third, and fourth carpalia. C. U., Centraloiilnare. H., Humerus. I. R., Intermedio-radiale. M'c. 2, 3, 4, Second,
third, and fourth metacarpalia. P'ch., Perichondral bone R., Radius.
U., Ulna.
 
tilages appear, viz., the radiale and ulnare; but in earlier stages
each appears to be derived from two centers: the radiale from a
radiale s.s. and an intermedium, the ulnare from an ulnare s.s.
and a centrale. Evidence of such double origin of each is found
also in the cartilaginous condition {v. Parker, 1888). Four
elements in all enter into the composition of this proximal row.
In the distal row there are three distinct elements corresponding
to the three persistent digits, and representing, therefore, carpalia
II, III, and IV. These subsequently fuse with one another,
and with the heads of the metacarpals to produce the carpometacarpus.
 
On the seventh day the metacarpus is represented Ijy three
cartilages corresponding to the three persistent digits, viz., II,
 
 
 
438 THE DEVELOPMENT OF THE CHICK
 
III, IV. Metacarpal II is only about one third the length of III.
Metacarpal IV is much more slender than III, and is bowed out
in the middle, meeting III at both ends. The elements are at
first distinct, but II and III fuse at their proximal ends in the
process of ossification. Cartilaginous rudiments of metacarpals
I and V have also been found by Parker, Rosenberg, and Leighton.
As to the phalanges, Parker finds two cartilages in II, three
in III, and two in IV on the seventh day; but already on the
eighth day the distal phalanges of III and I^' have fused with
the next proximal one.
 
As regards the homology of the digits of the wing, the author has
adopted the views of Owen, Mehnert, Norsa, and Leighton, that they
represent numbers II, III, and IV, which seem to be better supported
by the embryological evidence than the view of ^Meckel, Gegenbauer,
Parker, and others, that they represent I, II, and HI.
 
The Skeleton of the Hind-limb. The skeleton of the hindlimb and pelvic girdle develops from a continuous mass of mesenchyme situated at the base of the leg-bud. The original center
of the mass represents the acetabular region; it grows out in four
processes: (1) a lateral projection in the axis of the leg-bud, the
primordium of the leg-skeleton proper, (2) a dorsal process, the
primordium of the ilium; and two diverging ventral processes,
one in front of the acetabulum (3) the pubis, and one behind
(4) the ischium. In the membranous condition the elements are
continuous. The definitive elements develop either as separate
cartilao-e centers in the common mass (usually), or as separate
centers of ossification in a common cartilaginous mass (ilium
 
and ischium).
 
The Pelvic Girdle. The primitive relations of the elements of
the pelvic girdle in Larus ridibundus is shown in Fig. 248, which
represents a section in the sagittal plane of the body, and thus
does not necessarily show the full extent of any of the cartilaginous elements, but only their general relations. The head of the
femur is seen in the acetabulum, the broad plate of the ilium
above and the pubis and ischium as cartilaginous rods of almost
equal width below, the pubis in front and the ischiimi behind
the acetabuhmi. In this stage the pehdc girdle, in this and
many other species of birds, consists of three separate elements
on each side in essentially reptilian relations.
 
 
 
THE SKELETOX
 
 
 
439
 
 
 
In the chick at a corresponding age the ihum is much more
extensive, and the ischium is united with it by cartilage- the
pubis, however, has only a membranous connection with the
ilium (contra Johnson). In the course of development the distal
ends of the ischium and pubis rotate backwards until the two
elements come to lie substantially parallel to the ilium (Figs.
242 and 249). The displacement of the ischium and pubis may
 
 
 
//.
 
 
 
u^
 
 
 
'^lx'~^^'~^i''
 
 
/s.n.
 
 
 
Is.
 
 
 
Cr.N.
 
 
 
oi.JV.
 
 
 
Fig. 248. — Sagittal section of the right half of the body
of Lams ridibundus, to show the composition of the pelvic girdle; x 35. Length of the leg-bud of the embryo,
0.4 mm. (After Mehnert.)
F., Femur, cr. N., Crural nerve. II., Ihum. I. s., Ischium. Is. N., Ischial nerve, ob. N., Obturator nerve.
P., Pubis.
 
be associated wdth the upright gait of birds; it is fully established
on the eighth day in the chick. The mode of ossification, which
is perichondral, is shown in Fig. 249.
 
Later, the ilium obtains a very extensive pre- and postacetabular union with the vertebrae. I have fomid no evidence
in a complete series of preparations (potash) of attachment by
ribs arising as indei^endent ossifications. The ischium also fuses
 
 
 
440
 
 
 
THE DEVELOPMENT OF THE CHICK
 
 
 
with the ventral posterior border of the iUum, and the pubis,
 
except at its anterior and posterior ends, with the free border
 
of the ischium.
 
The spina iliaca, a pre-acetabular, bony process of the ihum,
 
requires special mention inasmuch as it has been interpreted (by Marsh) as the
true pubis of birds, and the
element ordinarily named
the pubis as homologous to
the post-pubis of some reptiles. There is no evidence
for this in the development.
The spina iliaca develops as
a cartilaginous outgrowth of
the ilium and ossifies from
the latter, not from an independent center (Mehnert).
 
The Leg-skeleton. The
skeleton of the leg develops
from the axial mesenchyme,
which is at first continuous
with the primordium of the
pelvic girdle. In the process
of chondrification it segments into a larger number
of elements than found in
the adult, some of which are
suppressed and others fuse
together. The digits grow
out from the palate-like expansion of the primitive
limb in the same fashion as
in the wing. In general the
 
separate elements arise in the proximo-distal order (Figs. 242 and
 
249)..
 
The femur requires no special description; ossification begins
 
on the ninth day.
 
The primordium of the fibula is from the first more slender
than that of the tibia, though relatively far larger than the adult
 
 
 
 
Fig. 249. — Photograph of the skeleton
 
of the leg of a chick embryo of 15 days'
 
incubation. Prepared by the potash
 
method. (Preparation and photograph
 
by Roy L. Moodie.)
 
1, Tibia. 2, Fibula. 3, Patella. 4,
Femur. 5, Ilium. 6, Pleurocentra of
sacral vertebrae. 7, Ischium. 8, Pubis.
9, Tarsal ossification. 10, Second, third,
and fourth metatarsals. 11, First metatarsal. I, II, III, IV, First, second, third,
and fourth digits.
 
 
 
THE SKELETON
 
 
 
441
 
 
 
fibula. The fibular cartilage extends the entire length of the crus,
but ossification is confined largely to its proximal end; on the
fourteenth day its lower half is represented by a thread-like filament of bone. '
 
No separate tarsal elements are found in the adult; but in the
embryo there are at least three cartilages,
viz., a fibulare, tibiale and a large distal
element opposite the three main metatarsals. In the course of development, the
two proximal elements fuse with one
another, and with the distal end of the
tibia. The distal element fuses with
the three main metatarsals, first with the
second, then with the fourth, and lastly
with the third (Johnson).
 
Five digits are formed in the membranous stage of the skeleton. In the
case of the fifth chgit, only a small nodule
of cartilage (fifth metatarsal) develops and
soon disappears. The second, third, and
fourth are the chief digits; the first is
relatively small. ^Metatarsals 2, 3, and 4
are long and ossify separately in a perichondral fashion. They become applied
near their middle and fuse with one
another and with the distal tarsal element
to form the tarso-metatarsus of the adult
(Fig. 250). The first metatarsal is short,
lying on the preaxial side of the distal end
of the others (Fig. 249); it ossifies after
the first phalanx. The number of phalanges is 2, 3, 4, and 5 in the first, second, third, and fourth digits
respectively (Fig. 249).
 
The patella is clearly seen in potash preparations of thirteen-day
chicks. At the same time there is a distinct, though iiiiiuite, separate
center of ossification in the tarsal region (Fig. 249).
 
 
 
 
Fig. 250. — Photograph
of the skeleton of the
foot of a chick embryo
of 15 days' incubation.
(Preparation and photograph by Roy L.
Moodie)
 
1, 2, 3, 4, First, second,
third, and fourth digits.
M 2, M 3, M 4, Second,
third, and fourth metatarsals.
 
 
 
APPENDIX
 
 
 
GENERAL LITERATURE
 
V. Baer, C. E., L'eber Entwickelurigsgeschichte der Tiere. Beobachtung
 
und Reflexion. Konigsbcrg, 1828 u. 1837.
 
id., 2. Teil — Herausgegeben von Stieda. Konigsberg, 1888.
Duval, Mathias, Atlas d'embryologie. (With 40 plates.) Paris, 1889.
Foster, M., and Balfour, F. M., The Elements of Embryology. Second
 
Edition revised. London, 1883.
Gadow, Hans, Die Vogel, Bronn's Klassen und Ordniingen des Thier-Reichs,
 
Bd. VI, Abth. 4, 1898.
Handbuch der vergleichenden und experimentellen Entwickelimgslehre der
 
Wirbeltiere. Edited by Dr. Oskar Hertwig and written by numerous
 
collaborators. Jena, 1901-1907.
Hls, W., LTntersuchungen fiber die erste Anlage des Wirbeltierleibes. Die
 
erste Entwickelung des Hiihnchens im Ei. Leipzig, 1868.
Keibel, F., and Abraham, K., Normaltafeln zur Entwickelungsgeschichte
 
des Huhnes (Gallus domesticus). Jena, 1900.
V. KoLLiKER, A., Entwickelungsgeschichte des Menschen und der hoheren
 
Thiere. Zweite Aufl. Leipzig, 1879.
Marshall, A. M., Vertebrate Embryology. A Text-book for Students and
 
Practitioners. (Ch. IV, The Development of the Chick.) New York
 
and London, 1893.
MiNOT, C. S., Laboratory Text-book of Embryology. Philadelphia, 1903.
Pander, Beitrage zur Entwickelungsgeschichte des Hiihnchens im Ei. Wiirz
burg, 1817.
Prevost et Dumas, Memoire sur le developpement du poulet dans I'oeuf.
 
Ann. Sc. Nat., Vol. XII, 1827.
Preyer, W., Specielle Physiologic des Embryo. Leipzig, 1885.
Remak, R., Untersuchungen iiber die Entwickelung der Wirbelthiere. Berlin, 1855.
 
LITERATURE — CHAPTER I
 
Bartelmez, George W., 1912, The Bilaterality of the Pigeon's Egg. A
Study in Egg Organization from the First Growth Period of the Oocyte
to the Beginning of Cleavage. Journ. of Morph. Vol. 23., pp. 269-328.
 
CoSTE, M., Histoire generale et particuliere du developpement des corps
organises, T. I. (Formation of Egg in Oviduct, see Chap. VI). Paris,
1847-1849.
 
D 'Hollander, F., Recherches sur I'oogenese et sur la structure et la signification du noyau vitellin de Balbiani chez les oiseaux. Archiv. d'anat.
micr., T. VII, 1905.
 
Gegenbaur, C, Ueber den Bau und die Entwickelung der Wirbeltiereier
mit partieller Dottertheilung. Archiv. Anat. u. Phys., 1861.
 
443
 
 
 
444 APPENDIX
 
Glaser, Otto, 1913, On the Origin of Double-yolked Eggs. Biol. Bull.,
 
Vol. 24, pp. 175-186.
HoLL, M., Ueber die Reifung der Eizelle des Huhnes. Sitzungsber. Akad
Wiss. Wien, math.-nat. KL, Bd. XCIX, Abth. Ill, 1890.
 
V. Nathusius, W., Zur Bildung der Eihiillen. Zool. Anz. Bd. XIX, 1896.
 
Die Entwickelung von Schale und Schalenhaut des Hiihnereies im
 
Ovidukt. Zeitschr. wiss. Zool., Bd. LV, 1893.
 
Parker, G. H., Double Hen's Eggs. American Naturalist, Vol. XL. 1906.
 
Pearl, Raymond and Curtis, M. R, 1912, Studies on the Physiology of
 
Reproduction in the Domestic Fowl. V. Data Regarding the Physiology
 
of the Oviduct. Journ. of Exp. Zoology. Vol. 12, pp. 99-132.
Riddle, Oscar, 1911, On the Formation, Significance and Chemistry of
 
the White and Yellow Yolk of Ova. Journ. of Morph., Vol. 22, pp.
 
455-490.
SoNNENBRODT, 1908, Die Wachstunsperiode der Oocyte des Huhns. Arch.
 
f. mikr. Anat. w. Entw. Bd. 72, pp. 415-480.
Waldeyer, W., Die Geschlechtszellen. Handbuch der vergl. und exper.
 
Entwickelungslehre der \Yirbeltiere. Bd. I, T. 1, 1901.
 
LITERATURE — CHAPTER II
 
Andrews, E. A., Some Intercellular Connections in an Egg of a Fowl. The
Johns Hopkins University Circular. Notes from the Biological Laboratory, March, 1907.
 
Barfurth, D., Versuche iiber die parthenogenetische Furchung des Hiihnereies. Arch. Entw.-mech., Bd. 2, 1895.
 
Blount, Mary, The Early Development of the Pigeon's Egg with Especial
Reference to the Supernumerary Sperm-nuclei, the Periblast and the
Germ-wall. Biol. Bull., Vol. XIII, 1907.
 
Duval, M., De la formation du l^lastoderm dans Foeuf d'oiseau. Ann. Sc.
Nat. Zool., Ser. 6, T. XVIII, 1884.
 
Gasser, E., Der Parablast und der Keimwall der Vogelkeimscheibe. Sitzungsber. der Ges. zur Beford. d. ges. Naturwiss. zu Marburg, 1883.
Eierstocksei und Eileiterei des Vogels. Ibid, 1884.
 
Gotte, a., Beitrage zur Entwickelungsgeschichte der Wirbeltiere, II. Die
Bildung der Keimblatter und des Blutes im Hiihnerei. Archiv. mikr.
Anat., Bd. X, 1874.
 
Harper, E. H., The Fertilization and Early Development of the Pigeon's
Egg. Am. Jour. Anat., Vol. Ill, 1904.
 
KiONKA, H., Die Furchung des Hiihnereies. Anat. Hefte, Bd. Ill, 1894.
 
Lau, H., Die parthenogenetische Furchung des Hiihnereies. Inaug. Dissert.
Jurjew — Dorpat., 1894.
 
Oellacher, J., Untersuchungen iiber die Furchung und Blatterl)ildung im
Hiihnerei. Studien iiber experimentelle Pathologic von Strieker, Bd
 
I, 1869.
Oellacher, J., Die Veranderungen des unbefruchteten Keimes des Huhnereies
im Eileiter und bei Bebriitungsversuchen. Zeitschr. wiss. Zool., Bd.
XXII, 1872.
 
 
 
APPENDIX 445
 
Patterson, J. Thomas, Gastrulation in the Pigeon's Egg; a ^Morphological
 
and Experimental Study. The Journ. of Morph., Vol. 29, pp. 65-123,
 
1909.
Patterson, J. Thomas, Studies on the Early Dev^elopment of the Hen's
 
Egg. 1. History of the Early Cleavage and of the Accessory Cleavage.
 
The Journ. of Morph., Vol. 21, pp. 101-134, 1910.
Rauber, a., Ueber die Stellung des Hiihnchens im Entwicklungsplan.
 
Leipzig, 1876.
Sobotta, J., Die Reifung und Befruchtung des Wirbeltiereies. Ergeb.
 
Anat. u. Entwickelungsgesch., Bd. V, 1895.
 
LITERATURE — CHAPTER III
 
Edwards, C. L., The Physiological Zero and the Index of Development for
 
the Egg of the Domestic Fowl, Gallus Domesticus. Am. Journ. Physiol.,
 
Vol. VI, 1902.
Eycleshymer, a. C, Some Observations and Experiments on the Natural
 
and Artificial Incubation of the Egg of the Common Fowl. Biol. Bull.,
 
Vol. XII, 1907.
Fere, Cm., Note sur I'influence de la temperature sur I'incubation de I'oeuf
 
de poule. Journ. de I'anatomie et de la physiologic, Paris, T. XXX,
 
1894.
 
LITERATURE — CHAPTERS IV AND V
 
Assheton, R., An Experimental Examination into the Growth of the Blastoderm of the Chick. Proc. Roy. Soc, London, Vol. LX, 1896.
 
Balfour, F. M. The Development and Growth of the Layers of the Blastoderm. Quar. Jour. Micr. Sc, Vol. XIII, 1873.
 
On the Disappearance of the Primitive Groove in the Embryo Chick.
lUd.
 
Balfour, F. M., and Deighton, A Renewed Study of the Germinal Layers
of the Chick. Quar. Jour. Micr. Sc, Vol. XXII, 1882.
 
DissE, J., Die Entwickelung des mittleren Keimblattes im Hiihnerei. Arch,
mikr. Anat., Bd. XV, 1878.
 
DuRSY, Emil, Der Primitivstreif des Hiihnchens. Lahr, 1866.
 
Duval, Mathias, Etudes sur la hgne primitive de rembr3'on du poulet.
Ann. Sc. Nat. Zool., Ser. 6, T. VII, 1S7S.
 
De la formation du blastoderm dans I'oiuf d'oiseau. Ann. Sc. Nat.
Zool., Ser. 6, T. XVIII. Paris, 1884.
 
Evans, Herbert M. On the Development of the Aorta), Cardinal and
UmbiUcal Veins and other Blood-vessels of Vertebrate Embryos from
Capillaries. Anatomical Record., Vol. 3, pp. 498-518, 1909.
 
Fol, H., Recherches sur le developpement des protovertcbres chez I'embryon
du poulet. Arch. sc. phys. et nat. Geneve, T. II, 1884.
 
Gasser, Lieber den Primitivstreifen bei Vogelembryonen. Sitz.-Ber. d. Gcs.
z. Beforcl. d. ges. Naturw. z. Marburg, 1877.
 
Der Primitivestreif bei Vogelembryonen (Huhn w. Gans). Schriften
d. Ges. z. Beford. d. ges. Naturw. z. Marburg, Bd. XI, Suppl. Heft 1,
1879.
 
 
 
446 APPENDIX
 
Gasser, Beitrage zur Kenntnis der Vogelkeimscheibe. Arch. Anat. u
 
Entw., 1882.
 
Der Parablast unci der Keimwall der Vogelkeimscheibe. Sitz.-Ber.
 
d. Ges. z. Beford. d. ges. Naturw. z. Marburg, 1883.
GoETTE, A., Beitrage zur Entwickelungsgeschichte der Wirbeltiere. II.
 
Die Bildung der Keimblatter und des Blutes im Hiihnerei. Arch. mikr.
 
Anat., Bd. X, 1874.
Hertwig, O., Die Lehre von den Keimblattern. Handbuch der vergl. und
 
exper. Entwickehuigslehre der Wirbeltiere. Vol. I. Jena, 1903.
His, W., Der Keimwall des Htihnereies und die Entstehung der para
blastischen Zellen. Arch. Anat. und Entw., Bd. I, 1876.
 
Neue Untersuchung liber die Bildung des Hiihnerembryo. Arch.
 
Anat. und Entw., 1877.
 
Lecithoblast und Angioblast der "Wirbelthiere. Histogenetische
 
Studien. Abh. der math.-phys. Klasse der Konigl. Sachs. Ges. der
 
Wissenschaften, Bd. XXVI. Leipzig, 1900.
 
Die Bildung der Somatopleura und der Gefasse beim Hiihnchen.
 
Anat. Anz., Bd. XXI, 1902.
Hubbard, M. E., Some Experiments on the Order of Succession of the
 
Somites of the Chick. Am. Nat., Vol. 42, pp. 466-471, 1908.
Janosik, J., Beitrag zur Kenntnis des Keimwulstes bei Vogeln. Sitz-Ber
Akad. Wiss. Wien, math.-phys. KL, Bd. LXXXIV, 1882.
Roller, C, Beitrage zur Kenntnis des Hiihnerkeimes im Beginne der Be
briitung. Sitzungsber. Wien. Akad. Wiss., math.-nat. KL, 1879.
Untersuchungen liber die Blatterbildung im Hlihnerkeim. Arch.
 
mikr. Anat., Bd. XX, 1881.
V. Kolliker, a., Zur Entwickelung der Keimblatter im Hiihnerei. Verb.
 
phys.-med. Ges. Wlirzburg, Bd. VIII, 1875.
KopscH,FR.,Ueber die Bedeutung des Primitivstreifens beim Hiihnerembryo,
 
und liber die ihm homologen Theile bei den Embryonen der niederen
 
Wirbeltiere. Intern. Monatschr. f. Anat. u. Phys., Bd. XIX, 1902.
MiTROPHANOW, P. J., Teratogene Studien. II. Experimentellen Beo
bachtungen liber die erste Anlage der Primitivrinne der Vogel. Arch.
 
Entw.-mech., Bd. VI, 1898.
 
Beobachtungen liber die erste Entwickelung der Vogel. Anat.
 
Hefte, Bd. XII, 1899.
Now^\cK, K., Neue Untersuchungen liber die Bildung der beiden primiiren
 
Keimblatter und die Entstehung des Primitivstreifen beim Hiihnerembryo. Inaug. Diss. Berlin, 1902.
Patterson, J. Thos., The Order of Appearance of the Anterior Somites in
 
the Chick. Biol. Bull., Vol. XIII, 1907.
Patterson, J. T. An experimental Study on the Development of the Vascular
 
Area of the Chick Blastoderm. Biol. Bull. XVI, pp. 83-90, 1909.
Peebles, Florence. Some Experiments on the Primitive Streak of the
 
Chick. Arch. Entw.-mech., Bd. VII, 1898.
 
A Prehminary Note on the Position of the Primitive Streak and its
 
Relation to the Embryo of the Chick. Biol. Bull., Vol. IV, 1903.
 
 
 
APPENDIX 447
 
Peebles, Florence, The Location of the Chick Embryo upon the Blastoderm. Journ. Exp. Zool., Vol. I, 1904.
Platt, J. B., Studies on the Primitive Axial Segmentation of the Chick.
 
Bull. Mus. Comp. Zool. Harv., Vol. 17, 1889.
Rabl, C, Theorie des Mesoderms. Morph. Jahrb., Bde. XV und XIX,
 
1889 and 1892.
Rauber, a., Primitivstreifen und Neurula der Wirbelthiere, in normaler
 
und pathologischer Beziehung. Leipzig, 1877.
 
Ueber die embryonale Anlage des Hiihnchens. Centralb. d. med.
 
Wiss., Bd. XII, 1875.
 
Ueber die erste Entwickelung der Vogel und die Bedeutung der Primi
tivrinne. Sitz.-ber. d. naturf. Ges. zu Leipzig, 1876.
Rex, Hugo, Ueber das Mesoderm des Vorderkopfes der Ente. Archiv.
 
■ mikr. Anat., Bd. L., 1897.
RiiCKERT, J., Entwickelung der extra-embryonalen Gefasse der Vogel. Hand
buch der vergl. w. exp. Entw.-lehre der Wirbelthiere, Bd. I, T. 1,
 
1906.
 
Ueber die Abstammung der bluthaltigen Gefassanlagen beim Huhn,
 
und uber die Entstehung des Randsinus beim Huhn und bei Torpedo.
 
Sitzungsber. der Bay. Akad. Wiss., 1903.
ScHAUiNSLAND, H., Bcitrage zur Biologie und Entwickelung der Hatteria
 
nebst Bemerkungen uber die Entwickelung der Sauropsiden. Anat.
 
Anz. XV, 1899.
ViALLETOX, Developpement des aortes chez I'embryon de poulet. Journ.
 
de I'^nat. T. XXVIII, 1892. See also Anat. Anz., Bd. VII, 1892.
ViRCHOW, H., Der Dottersack des Huhns. Internat. Beitrage zur wiss.
 
Med., Bd. I, 1891.
Waldeyer, W., Bemerkungen uber die Keimblatter und den Primitivstreifen
 
bei der Entwickelung des Huhnerembryo. Zeitschr. rationeller Medicin,
 
1869.
Whitman, C. O., A Rare Form of the Blastoderm of the Chick and its Bearing
 
on the Question of the Formation of the Vertebrate Embryo. Quar.
 
Journ. Micr. Sc, Vol. XXIII, 1883.
WiLLL\MS, Leonard W. The Somites of the Chick. Am. Journ. of Anat.,
 
Vol. 11, pp. 5.5-100, 1910.
 
Literature to Chapter VI included in following chapters.
 
LITERATURE — CHAPTER VII
 
CHARBONNEiy-SALLE ct Phisalix, De I'evolution postembryonnaire du
 
sac vitellin chez les oiseaux. C. R. Acad. Sc, Paris, 1886.
Dareste, C, Sur I'absence totale de I'amnios dans les embryons de poule.
 
C. R. Acad. Sc, Paris, T. LXXXVIII, 1879.
Duval, M., Etudes histologiques et morphologiques sur les annexes des
 
embryons d'oiseau. Journ. de I'anat, et de la phys., T. XX, 1884.
Etude sur I'origine de Tallantoide chez le poulet. Rev. sc. nat.,
 
Paris, 1877.
 
 
 
448 APPENDIX
 
Duval, M., Sur ime organe placentoide chez rembryon des oiseaux. C. R.
 
Acad. Sc, Paris, 1884.
Fromann, C, Ueber die Struktur der Dotterhaut des Huhnes. Sitz.-ber.
 
Jen. Ges. Medizin u. Naturw., 1879.
FuLLEBORN, F., Beitrage zur Entwickelung der Allantois der Vogel. Diss.,
 
Berlin, 1894.
Gasser, E., Beitrage zur Entwickelungsgeschichte der Allantois, der Miiller
schen Gange iind des Afters. Frankfurt a. M., 1874.
GoTTE, A., Beitrage zur Entwickelungsgeschichte des Darmkanals im Hiihn
chen. Tubingen, 1867.
HiROTA, S., On the Sero-amniotic Connection and the Foetal Membranes in
 
the Chick. Journ. Coll. Sc. Imp. Univ. Japan, Vol. VI, Part IV, 1^94.
LiLLiE, Frank R., Experimental Studies on the Development of the Organs
 
in the Embryo of the Fowl (Gallus domesticus): 1. Experiments on the
 
Amnion and the Production of Anamniote Embryos of the Chick. Biol.
 
Bull., Vol. V, 1903. 2. The Development of Defective Embryos and
 
the Power of Regeneration. Biol. Bull., Vol. VII, 1904.
Mertens, H., Beitrage zur Kenntniss der Fotushiillen im Vogelei. Meckels
 
Archiv, 1830.
Mitrophanow, p. J., Note sur la structure et la formation de I'enveloppe
 
du jaune de I'ceuf de la poule. Bibliogr. Anat., Paris, 1898.
PopoFF, Demetrius, Die Dottersackgefasse des Huhnes. Wiesbaden, 1894.
Pott, R., and Preyer, W., Ueber denGaswechsel und die chemischen Verander
ungen des Hiihnereies wahrend der Bebriitung. Archiv. ges. Phys., 1882.
Preyer, W., Specielle Physiologic des Embryo. Leipzig, 1885.
Ravn, E., Ueber die mesodermfreie Stelle in der Keimscheibe des Huhner
embryo. Arch. Anat. u. Entw., 1886.
 
Ueber den Allantoisstiel des Hiihnerembryo. Verh. Anat. Ges., 1898.
ScHAUiNSLAND, H., Die Entwickelung der Eihaute der Reptilien und der
 
Vogel. Handbuch der vergl. und exp. Entw.-lehre der Wirbeltiere. Bd.
 
I, T. 2, 1902.
 
Beitrage zur Entwickelungsgeschichte der Wirbeltiere. II. Beitrage zur
 
Entwickelungsgeschichte der Eihaute der Sauropsiden. Bibliotheca
 
Zoologica, 1903.
Schenk, S. L., Beitrage zur Lehre vom Amnion. Archiv. mikr. Anat., Bd.
 
VII, 1871.
 
Ueber die Aufnahme des Nahrungsdotters wahrend des Embryonal
lebens. Sitz.-ber. Akad. Wiss. Wien, math.-nat. Kl., 1897.
Shore, T. W., and Pickering, J. W., The Proamnion and Amnion in the
 
Chick. Journ. of Anat. and Phys., Vol. XXIV, 1889.
Soboleff, Die Verletzung des Amnions wahrend der Bebriitung. Mittheil,
 
embryolog. Inst., Wien, 1883.
Strahl, H., Eihaute und Placenta der Sauropsiden. Ergeb. Anat. u. Entw.
gesch., Bd. I, 1891.
Stuart, T. P. A., A Mode of Demonstrating the Developing Membranes in
 
the Chick. Journ. Anat. and Phys., London, Vol. XXV, 1899.
ViRCHOW, H., Beobachtungen am Hiihnerei; iiber das dritte Keimblatt
 
im Bereiche des Dottersackes. Virchow's Arch., Bd. LXII, 1874.
 
 
 
APPENDIX 449
 
ViRCHOW, H., Ueber das Epithel des Dottersackes im Hiihnerei. Diss., Berlin.
1875.
 
Der Dottersack des Huhnes. Internat. Beitrage zur wissenschaft.
Medizin, Bd. I, 1891.
 
Das Dotterorgan der Wirbeltiere. Zeitschr. wiss. Zool., Bd. LIII,
Suppl., 1892.
 
Das Dotterorgan der Wirbelthiere. Arch. mikr. Anat., Bd. XL, 1892.
Dottersyncytium, Keimhautrand und Beziehungen zur Koncrescenzlehre. Ergeb. Anat. u. Entw., Bd. VI, 1897.
 
Ueber Entwickelungsvorgange, welche sich in den letzten Bruttagen
am Hiihnerei abspielen. Anat. Anz., Bd. IV, BerHn, 1889.
VuLPiAX, La physiologie de I'amnios et de I'allantoide chez les oiseaux.
 
Mem. soc. biol., Paris, 1858.
Weldox, W. F. R., Prof, de Vries on the Origin of Species. (Includes experiments on amnion.) Biometrica, Vol. I, 1902.
 
LITERATURE — CHAPTER VIII
 
Beard, J., Morphological Studies, II. The Development of the Peripheral
 
Nervous System of Vertebrates. Pt. I. Elasmobranchs and Aves.
 
Quar. Journ. Micr. Sc, Vol. XXIX, 1888.
Beraneck, E., Etudes sur les replis medullaires du poulet. Recueil Zool.
 
Suisse, Vol. IV, 1887.
Bethe, Albrecht, Allgemeine Anatomic und Physiologie des Nervensys
tems. Leipzig, 1903.
Brandis, F., Untersuchungen iiber das Gehirn der Vogel. Arch. mikr.
 
Anat., Bd. XLI, 1893; Bd. XLIII, 1894; Bd. XLIV, 1895.
Burrows, Montrose T., The Growth of Tissues of the Chick Embryo
 
Outside the Animal Body, with Special Reference to the Nervous System.
 
Journ. Exp. Zoology, Vol. 10, pp. 63-83, 1911.
Cajal, S. R. y., Sur I'origine et les ramifications des fibres nerveuses de la
 
moelle embryonnaire. Anat. Anz., Bd. V, 1890.
 
A quelle epoque aparaissent les expansions des cellules nerveuses de
 
la moelle epiniere du poulet. Anat. Anz., Bd. V, 1890.
Froriep, a., Ueber Anlagen von Sinnesorganen am Facialis, Glossopha
ryngeus und Vagus, iiber die genetische Stellung des Vagus zum Hypo
glossus, und iiber die Herkunft der Zungenmuskulatur. Arch. Anat.
 
u. Entw., 1885.
Carpenter, Frederick Walton, The Development of the Oculomotor Nerve,
 
the Ciliary Ganglion, and the Abducent Nerve in the Chick. Bull.
 
Mus. Comp. Zool. Harv. Vol. XLVIII, 1906.
DissE, J., Die erste Entwickelung des Riechnerven. Anat. Hefte, Abth. I,
 
Bd. IX, 1897.
GoLoviNE, E., Sur le developpement du systeme ganglionnaire chez le poulet.
 
Anat. Anz., Bd. V, 1890.
GoRONOwiTscH, N., Die axiale und die laterale (A. Goette) Kopfmetamerie
 
der Vogeleml^ryonen. Anat. Anz., Bd. VII, 1892.
 
L'ntersuchungen iiber die Entwickelung der Sogenannten " Ganglien
leisten " im Kopfe der Vogelembryonen. Morph. Jahrb., Bd. XX, 1893.
 
 
 
450 APPENDIX
 
Heinrich, Georg, Untersuchungen iiber die Anlage des Grosshirns beim
Hiihnchen. Sitz.-ber. d. Ges. f. Morph. u. Phys. in Munchen, Bd. XII,
 
1897.
Hill, Charles, Developmental History of the Primary Segments of the
 
Vertebrate Head. Zool. Jahrbucher, Abth. Anat. Bd. XIII, 1900.
His, W., Die Neuroblasten und deren Entstehung im embryonalen Mark.
 
Abh. math.-physik. Klasse, Konigl. Sachs. Ges. Wiss., Bd. XV, 1889.
Histogenese und Zusammenhang der Nervenelemente. Arch. Anat.
u. Entw., Suppl., 1890.
Ueber das frontale Ende des Gehirnrohres. Arch. Anat. u. Entw., 1893.
Ueber das frontale Ende und iiber die natiirliche Eintheilung des
Gehirnrohres. Verh. anat. Ges., Bd. VII, 1893.
His, W. (Jr.)» Ueber die Entwickelung des Bauchsympathicus beim Hiihnchen und Menschen. Arch. Anat. u. Entw., Suppl., 1897.
V. KoLLiKER, Ueber die erste Entwickelung der Nervi olfactorii. Sitz.-ber.
 
phys. med. Ges. zu Wiirzburg, 1890.
V. KuPFFER, K., Die Morphogenie des Centralnervensystems. Handbuch der
 
vergl. und exp. Entwickelungslehre der Wirbeltiere, Kap. VIII, IP, 1905.
Lewis, M. R. and Lewis, W. H., The Cultivation of Tissues from Chick
 
Embroyos in Solutions of NaCl, CaCl2, KCl and NaHCOg. Anatomical
 
Record, Vol. 5, pp. 277-293. See also Anat. Rec, Vol. 6, nos. 1 and 5, 1911.
Marshall, A. M., The Development of the Cranial Nerves in the Chick.
 
Quar. Journ. Micr. Sc, Vol. XVIII, 1878.
 
The Segmental Value of the Cranial Nerves. Journ. Anat. and Physiol.,
 
Vol. XVI, 1882.
v. MiHALCOVics, v., Entwickelungsgeschichte des Gehirns. Leipzig, 1877.
Onodi, a. D., Ueber die Entwickelung des sympathischen Nervensy stems.
 
Arch. mikr. Anat., Bd. XXVI, 1886.
Rabl, C, Ueber die IMetamerie des Wirbelthierkopfes. Verh. anat. Ges.,
 
VI, 1892.
RuBASCHKiN, W., Ueber die Beziehungen des Nervus trigeminus zur Riech
schleimhaut. Anat. Anz., Bd. XXII, 1903.
Weber, A., Contribution a Tetude de la metamerism du cerveau anterieur
 
chez quelques oiseaux. Arch, d'anat. microsc, Paris, T. Ill, 1900.
Van Wijhe, J. W., L^eber Somiten und Nerven im Kopfe von Vogel- und
 
Reptilien-embryonen. Zool. Anz. Bd. IX, 1886.
 
Ueber die Kopfsegmente und das Geruchsorgan der Wirbelthiere
 
Zool. Anz., Bd. IX, 1886.
 
LITERATURE — CHAPTER IX
Organs of Special Sense
 
A. The Eye
 
Addario, C, Sulla struttura del vitreo embryonale e de' neonati, sulla matrice del vitreo e suU' origine della zonula. Ann. OttalmoL, Anno 30,
1901-1902.
 
 
 
APPENDIX 451
 
AddariOjC, Ueber die Matrix desGlaskorpers im menschlichen und thierischen
 
Auge. Vorlauf. Mitth. Anat. Anz., Bd. XXI, 19(32.
Agababow, Untersuchiingen iiber die Natur der Zonula ciliaris. Arch.
 
mikr. Anat., Bd. L, 1897.
Angelucci, a., Ueber Entwiekelung und Bau des vorderen Uvealtractus der
 
Vertebraten. Arch. mikr. Anat., Bd. XIX, 1881.
Arnold, J., Beitrage zur Entwickekmgsgeschichte des Auges. Heidelberg,
 
1874.
AssHETON, R., On the Development of the Optic Nerve of Vertebrates, and
 
the Choroidal Fissure of Embryonic Life. Quar. Journ. Micr. Sc, Vol.
 
XXXIV, 1892.
Bernd, Adolph Hugo, Die Entwiekelung des Pecten im Auge des Hiihn
chens aus den Blattern der Augenblase. Bonn, 1905.
Cajal, S. R. y., Sur la morphologie et les connexions des elements de la retine
 
des oiseaux. Anat. Anz. Bd. IV, 1889.
 
Sur la fine structure du lobe optique des oiseaux et sur I'origine reelle
 
des nerfs optiques. Int. Monatschr. Anat. u. Phys., Bd. VIII, 1891.
Cirincione, G., Ueber die Entwiekelung der Capsula perilenticularis. Arch.
 
Anat. u. Entw., Suppl. Bd., Jahrg. 1897.
 
Zur Entwiekelung des Wirbeltierauges. Ueber die Entwiekelung
 
des Capsula perilenticularis. Leipzig, 1898.
 
Ueber die Genese des Glaskorpers bei Wirbelthieren. Verh. Anat.
 
Ges., 17. Versamml. in Heidelberg, 1903.
Collin, R., Recherches sur le developpement du muscle sphincter de I'iris
 
chez les oiseaux. Bibliog. Anat., T. XII, fasc. V. Paris, 1903.
Froriep, a., Ueber die Entwiekelung des Sehnerven. Anat. Anz., Bd. VI,
 
1891.
 
Die Entwiekelung des Auges der Wirbeltiere. Handb. der vergl. u.
 
exp. Entw.-l. der Wirbeltiere, Bd. II, 1905.
HuscHKE, E., Lieber die erste Entwiekelung des Auges und die damit zusam
menhangende Cyklopie. Meckel's Arch., 1832.
Kessler, L., Untersuchungen liber die Entwiekelung des Auges, angestellt
 
am Hiihnchen und Tauben. Dissertation. Dorpat, 1871.
 
Die Entwiekelung des Auges der Wirbelthiere. Leipzig, 1877.
V. Kolliker, a., LTeber die Entwiekelung und Bedeutung des Glaskorpers.
 
Verh. anat. Ges., 17. Vers. Heidelberg, 1903.
 
Die Entwiekelung und Bedeutung des Glaskorpers. Zeitschr. wiss.
 
Zool., Bd. LXXVII, 1904.
V. Lenhossek, M., Die Entwiekelung des Glaskorpers. Leipzig, 1903.
Lewis, W. H., Wandering Pigmented Cells Arising from the Epithelium of
 
the Optic Cup, with Observations on the Origin of the M. Sphincter
 
Pupillffi in the Chick. Am. Journ. Anat., Vol. II, 1903.
LocY, W. A., Contribution to the Structure and Development of the Vertebrate Head. Journ. Morph., Vol. XI. Boston, 1895.
 
Accessory Optic Vesicles in the Chick Embryo. Anat. Anz., Bd. XIV,
 
1897.
NussBAUM, M., Zur Riickbildung embryonaler Anlagen. (Corneal papillae
 
of chick embryos.) Archiv. mikr. Anat., Bd. LVII, 1901.
 
 
 
452 APPENDIX
 
NussBAUM, M., Die Pars ciliaris retinae des Vogelauges. Arch. mikr. Anat., Bd.
 
LVII, 1901.
 
Die Entwiekelung der Binnenmuskeln des Aiiges der Wirbeltiere.
 
Arch. mikr. Anat., Bd. LVIII, 1901.
Rabl, C, Ziir Frage nach der Entwickehmg des Glaskorpers. Anat. Anz.,
 
Bd. XXII, 1903.
 
Ueber den Ban und die Entwickehmg der Linse. II. Reptihen imd
 
Vogel. Zeitschr. wiss. Zool., Bd. LXV, 1899.
Robinson, A., On the Formation and Structure of the Optic Nerve, and its
 
Relation to the Optic Stalk. Journ. Anat. and Phys. London, 1896.
SziLi, A.V. Beitrag zur Kenntniss der Anatomic und Entwickelungsgeschichte
 
der hinteren Irisschichten, etc. Arch. Opthalm., Bd. LIII, 1902.
 
Zur Anatomic und Entwickelungsgeschichte der hinteren Irisschichten, etc. Anat. Anz., Bd. XX, 1901.
 
Zur Glaskorperfrage. Anat. Anz. Bd. XXIV, 1904.
ToRNATOLA, Origiuc et nature du corps vitre. Rev. gener. d 'opthalm. Annee
 
14, 1897.
UcKE, A., Epithelreste am Opticus und auf der Retina. Arch. mikr. Anat.,
 
Bd. XXXVIII, 1891.
 
Zur Entw^ickelung des Pigmentepithels der Retina. Diss, aus Dorpat.
 
Petersburg, 1 89 1 .
ViRCHOW, H., Facher, Zapfen, Leiste, Polster, Gefasse im Glaskorperraum
 
von Wirbelthieren, sowie damit in Verbindung stehenden Fragen. Er
gebn. Anat. u. Entw., Bd. X. Berlin, 1900.
Weysse, a. W., and Burgess, W. S., Histogenesis of the Retina. Am.
 
Naturalist, Vol. XL, 1906.
 
 
 
B. The Nose
 
Born, G., Die Nasenhohlen und der Thranennasengang der amnioten Wir
belthiere II. Morph. Jahrb., Bd. V, 1879; Bd. VIII, 1883.
CoHN, Franz, Zur Entwickelungsgeschichte des Geruchsorgans des Hiihn
chens. Arch. mikr. Anat., Bd. LXI, 1903.
Dieulafe, Leon, Les fosses nasales des vertebres (morphologic et embry
ologie). Journ. de I'anat. et de la phys., T. 40 and 41, 1904 and 1905.
 
(Translated by Hanau W. Loeb: Ann. of Otol., Rhin. and Laryng., Mar.,
 
June and Sept., 1900.)
Disse, J., Die erste Entwiekelung des Riechnerven. Anat. Hefte, Bd. IX,
 
1897.
Ganin, M., Einige Thatsachen zur Frage iiber das Jacobsohn'sche Organ der
 
Vogel. Arb. d. naturf. Ges. Charkoff, 1890 (russisch). Abstr. Zool.
 
Anz., 1890.
V. KoLLiKER, A., Ueber die Entwickehmg der Geruchsorgane beim Menschen
 
und Hiihnchen. Wiirzburger med. Zeitschr., Bd. I, 1860.
V. MiHALKOvics, v., Nasenhohle und Jacobson'sche Organ. Anat. Hefte,
 
I. Abth., Bd. XI, 1898.
Peter, Karl, Entwickehmg des Geruchsorgans und Jakobson'sche Organs
 
in der Reihe der Wirbeltiere. Bildung der ausseren Nase und des
 
 
 
APPENDIX 453
 
Gaumens. Handbuch der vergl, und experiment. Entwickelimgslehre
 
der Wirbeltiere. IP, 1902.
Preobraschensky, L., Beitrage zur Lehre liber die Entwiekelung des Ge
ruchsorganes des Huhnes. Mitth. embryol. Inst. Wien, 1892.
PuTELLi, F., Ueber das Verhalten der Zellen der Riechschleimhaut bei
 
Hiihnerembryonen friiher Stadien. Mitth. embr. Inst. Wien, 1889.
 
C. The Ear
 
Hasse, C, Beitrage zur Entwiekelung der Gewebe der hautigen Vogel
schnecke. Zeitschr. wiss. Zool., Bd. XVII, 1867.
HuscHKE, Ueber die erste Bildungsgeschichte des Auges und Ohres beim
 
bebriiteten Hiihnchen. Isis von Oken, 1831.
Kastschenko, N., Das Schlundspaltengebiet des Hiihnchens. Arch. Anat.  


u. Entw., 1887.
===Literature — Chapter X===
Keibel, Ueber die erste Bildung des Labyrinthanhanges. Anat. Anz., Bd.


XVI, 1899.
Krause, R., Die Entwickekmg des Aquaeductus Vestibuh, s. Ductus endo
lymphaticus. Anat. Anz., Bd. XIX, 1901.
Die Entwickekmgsgeschichte des hautigen Bogenganges. Arch. mikr.
Anat., Bd. XXXV, 1890.
MoLDENHAUER, W., Die Entwickcking des mittleren und des ausseren Ohres.
Morph. Jahrb., Bd. Ill, 1877.
PoLi, C, Sviluppo della vesicula auditiva; studio morphologico. Genoa,
1896.
Zur Entwickekmg der Gehorblase bei den WirbeUieren. Arch. mikr.
Anat., Bd. XLVIII, 1897.
Retzius, G., Das Gehororgan der Wirbelthiere. II. Theil, Reptihen Vogel,
Sanger. Stockhokn. 1881-1884.
RoTHiG, p., und Brugsch, Theodor, Die Entwickekmg des Labyrintkes
beim Huhn. Archiv. mikr. Anat., Bd. LIX, 1902.
RtJDiNGER, Zur Entwickekmg des hautigen Bogenganges des inneren Ohres.
Sitzungsber. Akad. Miinchen, 1888.
LITERATURE — CHAPTER X
The Alimentary Tract and Its Appendages  
The Alimentary Tract and Its Appendages  


Line 9,731: Line 816:
embrologiche. Monit. zook Itak, Anno 1, 1890.  
embrologiche. Monit. zook Itak, Anno 1, 1890.  


454 APPENDIX


GoppERT, E., Die Bedeutimg der Zunge ftir den secundaren Gaumen und den  
GoppERT, E., Die Bedeutimg der Zunge ftir den secundaren Gaumen und den  

Latest revision as of 10:57, 22 November 2020

Review - Lillie’s Development of the Chicken - an Introduction to Embryology 3rd Edn. (1952)  
Lillie’s Development of the Chicken Introduction to Embryology. 3rd Edition, revised by Howarp L. Hamilton. (Pp. 574; 283 figs.; 14 plates; $8.50.) New York: H. Holt & Co. 1952.


The writing of the present edition was begun in 1945 at the request of Dr Frank R. Lillie himself with Dr B. H. Willier acting as advisory editor. It was Dr Lillie’s hope that he might live to see the new edition in print but this was not to be. The general outline of previous editions has been preserved. Part 1, which consists of six chapters, is devoted to an account of the early embryology up to and including the 3rd day. The account of the development of the embryo is given on a general basis and in addition a detailed account is given of specially selected stages.


Part 2 of the book consists of nine chapters and is an account of the development of the embryo from the 4th day to hatching; the various systems and external form are described as separate entities. A few chapters, such as the one dealing with the external form of the embryo and the embryonic membranes, and the one describing the body cavities, mesenteries and septum transversum, have remained relatively unchanged. Chapter 4, ‘From laying to the formation of the first somite’, chapter 8; ‘The nervous system’, and chapter 13, ‘The urogenital system’, are more or less completely rewritten. A new chapter, the fifteenth, describing the development of the integument, has been added. The other chapters have been extensively revised.


The new accounts are based on recent literature, but the author has tried to follow Dr Lillie’s example of going to the chick itself to check questionable points. To this end some original work is included in the text, but it is to be regretted that the author has not indicated more clearly which parts of the text result from this original work. The only clear indications consist of an opinion on the processes concerned with the formation of endoderm (p. 101) and two footnotes, one dealing with the coelomic cavity (p. 149) and one with the tail bud (p. 176). A further footnote refers to a communication from Rawles on the patency of the ductus arteriosus in the newly-hatched chick (p. 462).


This book is very well written and its format is attractive. The book reaches a happy compromise which makes it a most readable introduction to embryology while yet remaining an invaluable reference work for the research worker.


There is little to criticize in this work which has evidently been prepared with great care, but future editions might be improved by a rearrangement of the bibliography. The references should be listed at the end of the chapter they concern and not in an appendix of 32 pages at the end of the book. Also the magnification of drawings and photographs of early embryos should be given. Figs. 153 and 155 would be improved by being photographs rather than drawings of sagittal sections through an embryo. In fig. 222 the drawings are too small and too faint.


Apart from these minor faults the present work is a credit to the author and had Dr Lillie lived he would have been proud to have his name associated with it. It will continue to perpetuate Dr Lillie’s influence on the development of embryology.

W. J. Hamilton

chicken

Review - Lillie’s Development of the Chicken - an Introduction to Embryology 3rd Edn. (1952)  
Lillie’s Development of the Chicken Introduction to Embryology. 3rd Edition, revised by Howarp L. Hamilton. (Pp. 574; 283 figs.; 14 plates; $8.50.) New York: H. Holt & Co. 1952.

The writing of the present edition was begun in 1945 at the request of Dr Frank R. Lillie himself with Dr B. H. Willier acting as advisory editor. It was Dr Lillie’s hope that he might live to see the new edition in print but this was not to be. The general outline of previous editions has been preserved. Part 1, which consists of six chapters, is devoted to an account of the early embryology up to and including the 3rd day. The account of the development of the embryo is given on a general basis and in addition a detailed account is given of specially selected stages.

Part 2 of the book consists of nine chapters and is an account of the development of the embryo from the 4th day to hatching; the various systems and external form are described as separate entities. A few chapters, such as the one dealing with the external form of the embryo and the embryonic membranes, and the one describing the body cavities, mesenteries and septum transversum, have remained relatively unchanged. Chapter 4, ‘From laying to the formation of the first somite’, chapter 8; ‘The nervous system’, and chapter 13, ‘The urogenital system’, are more or less completely rewritten. A new chapter, the fifteenth, describing the development of the integument, has been added. The other chapters have been extensively revised.

The new accounts are based on recent literature, but the author has tried to follow Dr Lillie’s example of going to the chick itself to check questionable points. To this end some original work is included in the text, but it is to be regretted that the author has not indicated more clearly which parts of the text result from this original work. The only clear indications consist of an opinion on the processes concerned with the formation of endoderm (p. 101) and two footnotes, one dealing with the coelomic cavity (p. 149) and one with the tail bud (p. 176). A further footnote refers to a communication from Rawles on the patency of the ductus arteriosus in the newly-hatched chick (p. 462).

This book is very well written and its format is attractive. The book reaches a happy compromise which makes it a most readable introduction to embryology while yet remaining an invaluable reference work for the research worker.

There is little to criticize in this work which has evidently been prepared with great care, but future editions might be improved by a rearrangement of the bibliography. The references should be listed at the end of the chapter they concern and not in an appendix of 32 pages at the end of the book. Also the magnification of drawings and photographs of early embryos should be given. Figs. 153 and 155 would be improved by being photographs rather than drawings of sagittal sections through an embryo. In fig. 222 the drawings are too small and too faint.

Apart from these minor faults the present work is a credit to the author and had Dr Lillie lived he would have been proud to have his name associated with it. It will continue to perpetuate Dr Lillie’s influence on the development of embryology.

W. J. Hamilton

chicken

THE DEVELOPMENT OF THE CHICK - AN INTRODUCTION TO EMBRYOLOGY

BY

FRANK R. LILLIE

PROFESSOR IN THE UNIVERSITY OP CHICAGO

SECOND EDITION, REVISED

NEW YORK HENRY HOLT AND COMPANY

1919

Copyright, 1908, 1919,

BY

HENRY HOLT AND COMPANY


Part I The Early Development To The End Of The Third Day

Appendix

General Literature

V. Baer, C. E., L'eber Entwickelurigsgeschichte der Tiere. Beobachtung

und Reflexion. Konigsbcrg, 1828 u. 1837.

id., 2. Teil — Herausgegeben von Stieda. Konigsberg, 1888. Duval, Mathias, Atlas d'embryologie. (With 40 plates.) Paris, 1889. Foster, M., and Balfour, F. M., The Elements of Embryology. Second Edition revised. London, 1883. Gadow, Hans, Die Vogel, Bronn's Klassen und Ordniingen des Thier-Reichs, Bd. VI, Abth. 4, 1898. Handbuch der vergleichenden und experimentellen Entwickelimgslehre der Wirbeltiere. Edited by Dr. Oskar Hertwig and written by numerous collaborators. Jena, 1901-1907.


Hls, W., LTntersuchungen fiber die erste Anlage des Wirbeltierleibes. Die erste Entwickelung des Hiihnchens im Ei. Leipzig, 1868. Keibel, F., and Abraham, K., Normaltafeln zur Entwickelungsgeschichte des Huhnes (Gallus domesticus). Jena, 1900.


V. KoLLiKER, A., Entwickelungsgeschichte des Menschen und der hoheren

Thiere. Zweite Aufl. Leipzig, 1879. Marshall, A. M., Vertebrate Embryology. A Text-book for Students and

Practitioners. (Ch. IV, The Development of the Chick.) New York

and London, 1893. MiNOT, C. S., Laboratory Text-book of Embryology. Philadelphia, 1903. Pander, Beitrage zur Entwickelungsgeschichte des Hiihnchens im Ei. Wiirz burg, 1817. Prevost et Dumas, Memoire sur le developpement du poulet dans I'oeuf.

Ann. Sc. Nat., Vol. XII, 1827. Preyer, W., Specielle Physiologic des Embryo. Leipzig, 1885. Remak, R., Untersuchungen iiber die Entwickelung der Wirbelthiere. Berlin, 1855.

Literature — Chapter I

Bartelmez, George W., 1912, The Bilaterality of the Pigeon's Egg. A Study in Egg Organization from the First Growth Period of the Oocyte to the Beginning of Cleavage. Journ. of Morph. Vol. 23., pp. 269-328.

CoSTE, M., Histoire generale et particuliere du developpement des corps organises, T. I. (Formation of Egg in Oviduct, see Chap. VI). Paris, 1847-1849.

D 'Hollander, F., Recherches sur I'oogenese et sur la structure et la signification du noyau vitellin de Balbiani chez les oiseaux. Archiv. d'anat. micr., T. VII, 1905.

Gegenbaur, C, Ueber den Bau und die Entwickelung der Wirbeltiereier mit partieller Dottertheilung. Archiv. Anat. u. Phys., 1861.


Glaser, Otto, 1913, On the Origin of Double-yolked Eggs. Biol. Bull.,

Vol. 24, pp. 175-186. HoLL, M., Ueber die Reifung der Eizelle des Huhnes. Sitzungsber. Akad Wiss. Wien, math.-nat. KL, Bd. XCIX, Abth. Ill, 1890.

V. Nathusius, W., Zur Bildung der Eihiillen. Zool. Anz. Bd. XIX, 1896.

Die Entwickelung von Schale und Schalenhaut des Hiihnereies im

Ovidukt. Zeitschr. wiss. Zool., Bd. LV, 1893.

Parker, G. H., Double Hen's Eggs. American Naturalist, Vol. XL. 1906.

Pearl, Raymond and Curtis, M. R, 1912, Studies on the Physiology of

Reproduction in the Domestic Fowl. V. Data Regarding the Physiology

of the Oviduct. Journ. of Exp. Zoology. Vol. 12, pp. 99-132. Riddle, Oscar, 1911, On the Formation, Significance and Chemistry of the White and Yellow Yolk of Ova. Journ. of Morph., Vol. 22, pp. 455-490.

SoNNENBRODT, 1908, Die Wachstunsperiode der Oocyte des Huhns. Arch.

f. mikr. Anat. w. Entw. Bd. 72, pp. 415-480. Waldeyer, W., Die Geschlechtszellen. Handbuch der vergl. und exper.

Entwickelungslehre der \Yirbeltiere. Bd. I, T. 1, 1901.

Literature — Chapter II

Andrews, E. A., Some Intercellular Connections in an Egg of a Fowl. The Johns Hopkins University Circular. Notes from the Biological Laboratory, March, 1907.

Barfurth, D., Versuche iiber die parthenogenetische Furchung des Hiihnereies. Arch. Entw.-mech., Bd. 2, 1895.

Blount, Mary, The Early Development of the Pigeon's Egg with Especial Reference to the Supernumerary Sperm-nuclei, the Periblast and the Germ-wall. Biol. Bull., Vol. XIII, 1907.

Duval, M., De la formation du l^lastoderm dans Foeuf d'oiseau. Ann. Sc. Nat. Zool., Ser. 6, T. XVIII, 1884.

Gasser, E., Der Parablast und der Keimwall der Vogelkeimscheibe. Sitzungsber. der Ges. zur Beford. d. ges. Naturwiss. zu Marburg, 1883. Eierstocksei und Eileiterei des Vogels. Ibid, 1884.

Gotte, a., Beitrage zur Entwickelungsgeschichte der Wirbeltiere, II. Die Bildung der Keimblatter und des Blutes im Hiihnerei. Archiv. mikr. Anat., Bd. X, 1874.

Harper, E. H., The Fertilization and Early Development of the Pigeon's Egg. Am. Jour. Anat., Vol. Ill, 1904.

KiONKA, H., Die Furchung des Hiihnereies. Anat. Hefte, Bd. Ill, 1894.

Lau, H., Die parthenogenetische Furchung des Hiihnereies. Inaug. Dissert. Jurjew — Dorpat., 1894.

Oellacher, J., Untersuchungen iiber die Furchung und Blatterl)ildung im Hiihnerei. Studien iiber experimentelle Pathologic von Strieker, Bd

I, 1869. Oellacher, J., Die Veranderungen des unbefruchteten Keimes des Huhnereies im Eileiter und bei Bebriitungsversuchen. Zeitschr. wiss. Zool., Bd. XXII, 1872.


Patterson, J. Thomas, Gastrulation in the Pigeon's Egg; a ^Morphological

and Experimental Study. The Journ. of Morph., Vol. 29, pp. 65-123,

1909. Patterson, J. Thomas, Studies on the Early Dev^elopment of the Hen's

Egg. 1. History of the Early Cleavage and of the Accessory Cleavage.

The Journ. of Morph., Vol. 21, pp. 101-134, 1910. Rauber, a., Ueber die Stellung des Hiihnchens im Entwicklungsplan.

Leipzig, 1876. Sobotta, J., Die Reifung und Befruchtung des Wirbeltiereies. Ergeb.

Anat. u. Entwickelungsgesch., Bd. V, 1895.

Literature — Chapter III

Edwards, C. L., The Physiological Zero and the Index of Development for

the Egg of the Domestic Fowl, Gallus Domesticus. Am. Journ. Physiol.,

Vol. VI, 1902. Eycleshymer, a. C, Some Observations and Experiments on the Natural

and Artificial Incubation of the Egg of the Common Fowl. Biol. Bull.,

Vol. XII, 1907. Fere, Cm., Note sur I'influence de la temperature sur I'incubation de I'oeuf

de poule. Journ. de I'anatomie et de la physiologic, Paris, T. XXX,

1894.

Literature — Chapter IV and V

Assheton, R., An Experimental Examination into the Growth of the Blastoderm of the Chick. Proc. Roy. Soc, London, Vol. LX, 1896.

Balfour, F. M. The Development and Growth of the Layers of the Blastoderm. Quar. Jour. Micr. Sc, Vol. XIII, 1873.

On the Disappearance of the Primitive Groove in the Embryo Chick. lUd.

Balfour, F. M., and Deighton, A Renewed Study of the Germinal Layers of the Chick. Quar. Jour. Micr. Sc, Vol. XXII, 1882.

DissE, J., Die Entwickelung des mittleren Keimblattes im Hiihnerei. Arch, mikr. Anat., Bd. XV, 1878.

DuRSY, Emil, Der Primitivstreif des Hiihnchens. Lahr, 1866.

Duval, Mathias, Etudes sur la hgne primitive de rembr3'on du poulet. Ann. Sc. Nat. Zool., Ser. 6, T. VII, 1S7S.

De la formation du blastoderm dans I'oiuf d'oiseau. Ann. Sc. Nat. Zool., Ser. 6, T. XVIII. Paris, 1884.

Evans, Herbert M. On the Development of the Aorta), Cardinal and UmbiUcal Veins and other Blood-vessels of Vertebrate Embryos from Capillaries. Anatomical Record., Vol. 3, pp. 498-518, 1909.

Fol, H., Recherches sur le developpement des protovertcbres chez I'embryon du poulet. Arch. sc. phys. et nat. Geneve, T. II, 1884.

Gasser, Lieber den Primitivstreifen bei Vogelembryonen. Sitz.-Ber. d. Gcs. z. Beforcl. d. ges. Naturw. z. Marburg, 1877.

Der Primitivestreif bei Vogelembryonen (Huhn w. Gans). Schriften d. Ges. z. Beford. d. ges. Naturw. z. Marburg, Bd. XI, Suppl. Heft 1, 1879.


Gasser, Beitrage zur Kenntnis der Vogelkeimscheibe. Arch. Anat. u

Entw., 1882.

Der Parablast unci der Keimwall der Vogelkeimscheibe. Sitz.-Ber.

d. Ges. z. Beford. d. ges. Naturw. z. Marburg, 1883. GoETTE, A., Beitrage zur Entwickelungsgeschichte der Wirbeltiere. II.

Die Bildung der Keimblatter und des Blutes im Hiihnerei. Arch. mikr.

Anat., Bd. X, 1874. Hertwig, O., Die Lehre von den Keimblattern. Handbuch der vergl. und

exper. Entwickehuigslehre der Wirbeltiere. Vol. I. Jena, 1903. His, W., Der Keimwall des Htihnereies und die Entstehung der para blastischen Zellen. Arch. Anat. und Entw., Bd. I, 1876.

Neue Untersuchung liber die Bildung des Hiihnerembryo. Arch.

Anat. und Entw., 1877.

Lecithoblast und Angioblast der "Wirbelthiere. Histogenetische

Studien. Abh. der math.-phys. Klasse der Konigl. Sachs. Ges. der

Wissenschaften, Bd. XXVI. Leipzig, 1900.

Die Bildung der Somatopleura und der Gefasse beim Hiihnchen.

Anat. Anz., Bd. XXI, 1902. Hubbard, M. E., Some Experiments on the Order of Succession of the

Somites of the Chick. Am. Nat., Vol. 42, pp. 466-471, 1908. Janosik, J., Beitrag zur Kenntnis des Keimwulstes bei Vogeln. Sitz-Ber Akad. Wiss. Wien, math.-phys. KL, Bd. LXXXIV, 1882. Roller, C, Beitrage zur Kenntnis des Hiihnerkeimes im Beginne der Be briitung. Sitzungsber. Wien. Akad. Wiss., math.-nat. KL, 1879. Untersuchungen liber die Blatterbildung im Hlihnerkeim. Arch.

mikr. Anat., Bd. XX, 1881. V. Kolliker, a., Zur Entwickelung der Keimblatter im Hiihnerei. Verb.

phys.-med. Ges. Wlirzburg, Bd. VIII, 1875. KopscH,FR.,Ueber die Bedeutung des Primitivstreifens beim Hiihnerembryo,

und liber die ihm homologen Theile bei den Embryonen der niederen

Wirbeltiere. Intern. Monatschr. f. Anat. u. Phys., Bd. XIX, 1902. MiTROPHANOW, P. J., Teratogene Studien. II. Experimentellen Beo bachtungen liber die erste Anlage der Primitivrinne der Vogel. Arch.

Entw.-mech., Bd. VI, 1898.

Beobachtungen liber die erste Entwickelung der Vogel. Anat.

Hefte, Bd. XII, 1899. Now^\cK, K., Neue Untersuchungen liber die Bildung der beiden primiiren

Keimblatter und die Entstehung des Primitivstreifen beim Hiihnerembryo. Inaug. Diss. Berlin, 1902. Patterson, J. Thos., The Order of Appearance of the Anterior Somites in

the Chick. Biol. Bull., Vol. XIII, 1907. Patterson, J. T. An experimental Study on the Development of the Vascular

Area of the Chick Blastoderm. Biol. Bull. XVI, pp. 83-90, 1909. Peebles, Florence. Some Experiments on the Primitive Streak of the

Chick. Arch. Entw.-mech., Bd. VII, 1898.

A Prehminary Note on the Position of the Primitive Streak and its

Relation to the Embryo of the Chick. Biol. Bull., Vol. IV, 1903.


Peebles, Florence, The Location of the Chick Embryo upon the Blastoderm. Journ. Exp. Zool., Vol. I, 1904. Platt, J. B., Studies on the Primitive Axial Segmentation of the Chick.

Bull. Mus. Comp. Zool. Harv., Vol. 17, 1889. Rabl, C, Theorie des Mesoderms. Morph. Jahrb., Bde. XV und XIX,

1889 and 1892. Rauber, a., Primitivstreifen und Neurula der Wirbelthiere, in normaler

und pathologischer Beziehung. Leipzig, 1877.

Ueber die embryonale Anlage des Hiihnchens. Centralb. d. med.

Wiss., Bd. XII, 1875.

Ueber die erste Entwickelung der Vogel und die Bedeutung der Primi tivrinne. Sitz.-ber. d. naturf. Ges. zu Leipzig, 1876. Rex, Hugo, Ueber das Mesoderm des Vorderkopfes der Ente. Archiv. mikr. Anat., Bd. L., 1897.


RiiCKERT, J., Entwickelung der extra-embryonalen Gefasse der Vogel. Hand buch der vergl. w. exp. Entw.-lehre der Wirbelthiere, Bd. I, T. 1,

1906.

Ueber die Abstammung der bluthaltigen Gefassanlagen beim Huhn,

und uber die Entstehung des Randsinus beim Huhn und bei Torpedo.

Sitzungsber. der Bay. Akad. Wiss., 1903. ScHAUiNSLAND, H., Bcitrage zur Biologie und Entwickelung der Hatteria

nebst Bemerkungen uber die Entwickelung der Sauropsiden. Anat.

Anz. XV, 1899. ViALLETOX, Developpement des aortes chez I'embryon de poulet. Journ.

de I'^nat. T. XXVIII, 1892. See also Anat. Anz., Bd. VII, 1892. ViRCHOW, H., Der Dottersack des Huhns. Internat. Beitrage zur wiss.

Med., Bd. I, 1891. Waldeyer, W., Bemerkungen uber die Keimblatter und den Primitivstreifen

bei der Entwickelung des Huhnerembryo. Zeitschr. rationeller Medicin,

1869. Whitman, C. O., A Rare Form of the Blastoderm of the Chick and its Bearing

on the Question of the Formation of the Vertebrate Embryo. Quar.

Journ. Micr. Sc, Vol. XXIII, 1883. WiLLL\MS, Leonard W. The Somites of the Chick. Am. Journ. of Anat.,

Vol. 11, pp. 5.5-100, 1910.

Literature to Chapter VI included in following chapters.

Literature — Chapter VII

CHARBONNEiy-SALLE ct Phisalix, De I'evolution postembryonnaire du

sac vitellin chez les oiseaux. C. R. Acad. Sc, Paris, 1886. Dareste, C, Sur I'absence totale de I'amnios dans les embryons de poule.

C. R. Acad. Sc, Paris, T. LXXXVIII, 1879. Duval, M., Etudes histologiques et morphologiques sur les annexes des

embryons d'oiseau. Journ. de I'anat, et de la phys., T. XX, 1884. Etude sur I'origine de Tallantoide chez le poulet. Rev. sc. nat.,

Paris, 1877.


Duval, M., Sur ime organe placentoide chez rembryon des oiseaux. C. R.

Acad. Sc, Paris, 1884. Fromann, C, Ueber die Struktur der Dotterhaut des Huhnes. Sitz.-ber.

Jen. Ges. Medizin u. Naturw., 1879. FuLLEBORN, F., Beitrage zur Entwickelung der Allantois der Vogel. Diss.,

Berlin, 1894. Gasser, E., Beitrage zur Entwickelungsgeschichte der Allantois, der Miiller schen Gange iind des Afters. Frankfurt a. M., 1874. GoTTE, A., Beitrage zur Entwickelungsgeschichte des Darmkanals im Hiihn chen. Tubingen, 1867. HiROTA, S., On the Sero-amniotic Connection and the Foetal Membranes in

the Chick. Journ. Coll. Sc. Imp. Univ. Japan, Vol. VI, Part IV, 1^94. LiLLiE, Frank R., Experimental Studies on the Development of the Organs

in the Embryo of the Fowl (Gallus domesticus): 1. Experiments on the

Amnion and the Production of Anamniote Embryos of the Chick. Biol.

Bull., Vol. V, 1903. 2. The Development of Defective Embryos and

the Power of Regeneration. Biol. Bull., Vol. VII, 1904. Mertens, H., Beitrage zur Kenntniss der Fotushiillen im Vogelei. Meckels

Archiv, 1830. Mitrophanow, p. J., Note sur la structure et la formation de I'enveloppe

du jaune de I'ceuf de la poule. Bibliogr. Anat., Paris, 1898. PopoFF, Demetrius, Die Dottersackgefasse des Huhnes. Wiesbaden, 1894. Pott, R., and Preyer, W., Ueber denGaswechsel und die chemischen Verander ungen des Hiihnereies wahrend der Bebriitung. Archiv. ges. Phys., 1882. Preyer, W., Specielle Physiologic des Embryo. Leipzig, 1885. Ravn, E., Ueber die mesodermfreie Stelle in der Keimscheibe des Huhner embryo. Arch. Anat. u. Entw., 1886.

Ueber den Allantoisstiel des Hiihnerembryo. Verh. Anat. Ges., 1898. ScHAUiNSLAND, H., Die Entwickelung der Eihaute der Reptilien und der

Vogel. Handbuch der vergl. und exp. Entw.-lehre der Wirbeltiere. Bd.

I, T. 2, 1902.

Beitrage zur Entwickelungsgeschichte der Wirbeltiere. II. Beitrage zur

Entwickelungsgeschichte der Eihaute der Sauropsiden. Bibliotheca

Zoologica, 1903. Schenk, S. L., Beitrage zur Lehre vom Amnion. Archiv. mikr. Anat., Bd.

VII, 1871.

Ueber die Aufnahme des Nahrungsdotters wahrend des Embryonal lebens. Sitz.-ber. Akad. Wiss. Wien, math.-nat. Kl., 1897. Shore, T. W., and Pickering, J. W., The Proamnion and Amnion in the

Chick. Journ. of Anat. and Phys., Vol. XXIV, 1889. Soboleff, Die Verletzung des Amnions wahrend der Bebriitung. Mittheil,

embryolog. Inst., Wien, 1883. Strahl, H., Eihaute und Placenta der Sauropsiden. Ergeb. Anat. u. Entw. gesch., Bd. I, 1891. Stuart, T. P. A., A Mode of Demonstrating the Developing Membranes in

the Chick. Journ. Anat. and Phys., London, Vol. XXV, 1899. ViRCHOW, H., Beobachtungen am Hiihnerei; iiber das dritte Keimblatt

im Bereiche des Dottersackes. Virchow's Arch., Bd. LXII, 1874.


ViRCHOW, H., Ueber das Epithel des Dottersackes im Hiihnerei. Diss., Berlin. 1875.

Der Dottersack des Huhnes. Internat. Beitrage zur wissenschaft. Medizin, Bd. I, 1891.

Das Dotterorgan der Wirbeltiere. Zeitschr. wiss. Zool., Bd. LIII, Suppl., 1892.

Das Dotterorgan der Wirbelthiere. Arch. mikr. Anat., Bd. XL, 1892. Dottersyncytium, Keimhautrand und Beziehungen zur Koncrescenzlehre. Ergeb. Anat. u. Entw., Bd. VI, 1897.

Ueber Entwickelungsvorgange, welche sich in den letzten Bruttagen am Hiihnerei abspielen. Anat. Anz., Bd. IV, BerHn, 1889. VuLPiAX, La physiologie de I'amnios et de I'allantoide chez les oiseaux.

Mem. soc. biol., Paris, 1858. Weldox, W. F. R., Prof, de Vries on the Origin of Species. (Includes experiments on amnion.) Biometrica, Vol. I, 1902.

Literature — Chapter VIII

Beard, J., Morphological Studies, II. The Development of the Peripheral

Nervous System of Vertebrates. Pt. I. Elasmobranchs and Aves.

Quar. Journ. Micr. Sc, Vol. XXIX, 1888. Beraneck, E., Etudes sur les replis medullaires du poulet. Recueil Zool.

Suisse, Vol. IV, 1887. Bethe, Albrecht, Allgemeine Anatomic und Physiologie des Nervensys tems. Leipzig, 1903. Brandis, F., Untersuchungen iiber das Gehirn der Vogel. Arch. mikr.

Anat., Bd. XLI, 1893; Bd. XLIII, 1894; Bd. XLIV, 1895. Burrows, Montrose T., The Growth of Tissues of the Chick Embryo

Outside the Animal Body, with Special Reference to the Nervous System.

Journ. Exp. Zoology, Vol. 10, pp. 63-83, 1911. Cajal, S. R. y., Sur I'origine et les ramifications des fibres nerveuses de la

moelle embryonnaire. Anat. Anz., Bd. V, 1890.

A quelle epoque aparaissent les expansions des cellules nerveuses de

la moelle epiniere du poulet. Anat. Anz., Bd. V, 1890. Froriep, a., Ueber Anlagen von Sinnesorganen am Facialis, Glossopha ryngeus und Vagus, iiber die genetische Stellung des Vagus zum Hypo glossus, und iiber die Herkunft der Zungenmuskulatur. Arch. Anat.

u. Entw., 1885. Carpenter, Frederick Walton, The Development of the Oculomotor Nerve,

the Ciliary Ganglion, and the Abducent Nerve in the Chick. Bull.

Mus. Comp. Zool. Harv. Vol. XLVIII, 1906. DissE, J., Die erste Entwickelung des Riechnerven. Anat. Hefte, Abth. I,

Bd. IX, 1897. GoLoviNE, E., Sur le developpement du systeme ganglionnaire chez le poulet.

Anat. Anz., Bd. V, 1890. GoRONOwiTscH, N., Die axiale und die laterale (A. Goette) Kopfmetamerie

der Vogeleml^ryonen. Anat. Anz., Bd. VII, 1892.

L'ntersuchungen iiber die Entwickelung der Sogenannten " Ganglien leisten " im Kopfe der Vogelembryonen. Morph. Jahrb., Bd. XX, 1893.


Heinrich, Georg, Untersuchungen iiber die Anlage des Grosshirns beim Hiihnchen. Sitz.-ber. d. Ges. f. Morph. u. Phys. in Munchen, Bd. XII,

1897. Hill, Charles, Developmental History of the Primary Segments of the

Vertebrate Head. Zool. Jahrbucher, Abth. Anat. Bd. XIII, 1900. His, W., Die Neuroblasten und deren Entstehung im embryonalen Mark.

Abh. math.-physik. Klasse, Konigl. Sachs. Ges. Wiss., Bd. XV, 1889. Histogenese und Zusammenhang der Nervenelemente. Arch. Anat. u. Entw., Suppl., 1890. Ueber das frontale Ende des Gehirnrohres. Arch. Anat. u. Entw., 1893. Ueber das frontale Ende und iiber die natiirliche Eintheilung des Gehirnrohres. Verh. anat. Ges., Bd. VII, 1893. His, W. (Jr.)» Ueber die Entwickelung des Bauchsympathicus beim Hiihnchen und Menschen. Arch. Anat. u. Entw., Suppl., 1897. V. KoLLiKER, Ueber die erste Entwickelung der Nervi olfactorii. Sitz.-ber.

phys. med. Ges. zu Wiirzburg, 1890. V. KuPFFER, K., Die Morphogenie des Centralnervensystems. Handbuch der

vergl. und exp. Entwickelungslehre der Wirbeltiere, Kap. VIII, IP, 1905. Lewis, M. R. and Lewis, W. H., The Cultivation of Tissues from Chick

Embroyos in Solutions of NaCl, CaCl2, KCl and NaHCOg. Anatomical

Record, Vol. 5, pp. 277-293. See also Anat. Rec, Vol. 6, nos. 1 and 5, 1911. Marshall, A. M., The Development of the Cranial Nerves in the Chick.

Quar. Journ. Micr. Sc, Vol. XVIII, 1878.

The Segmental Value of the Cranial Nerves. Journ. Anat. and Physiol.,

Vol. XVI, 1882. v. MiHALCOVics, v., Entwickelungsgeschichte des Gehirns. Leipzig, 1877. Onodi, a. D., Ueber die Entwickelung des sympathischen Nervensy stems.

Arch. mikr. Anat., Bd. XXVI, 1886. Rabl, C, Ueber die IMetamerie des Wirbelthierkopfes. Verh. anat. Ges.,

VI, 1892. RuBASCHKiN, W., Ueber die Beziehungen des Nervus trigeminus zur Riech schleimhaut. Anat. Anz., Bd. XXII, 1903. Weber, A., Contribution a Tetude de la metamerism du cerveau anterieur

chez quelques oiseaux. Arch, d'anat. microsc, Paris, T. Ill, 1900. Van Wijhe, J. W., L^eber Somiten und Nerven im Kopfe von Vogel- und

Reptilien-embryonen. Zool. Anz. Bd. IX, 1886.

Ueber die Kopfsegmente und das Geruchsorgan der Wirbelthiere

Zool. Anz., Bd. IX, 1886.

Literature — Chapter IX

Organs of Special Sense

A. The Eye

Addario, C, Sulla struttura del vitreo embryonale e de' neonati, sulla matrice del vitreo e suU' origine della zonula. Ann. OttalmoL, Anno 30, 1901-1902.


AddariOjC, Ueber die Matrix desGlaskorpers im menschlichen und thierischen

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mikr. Anat., Bd. L, 1897. Angelucci, a., Ueber Entwiekelung und Bau des vorderen Uvealtractus der

Vertebraten. Arch. mikr. Anat., Bd. XIX, 1881. Arnold, J., Beitrage zur Entwickekmgsgeschichte des Auges. Heidelberg,

1874. AssHETON, R., On the Development of the Optic Nerve of Vertebrates, and

the Choroidal Fissure of Embryonic Life. Quar. Journ. Micr. Sc, Vol.

XXXIV, 1892. Bernd, Adolph Hugo, Die Entwiekelung des Pecten im Auge des Hiihn chens aus den Blattern der Augenblase. Bonn, 1905. Cajal, S. R. y., Sur la morphologie et les connexions des elements de la retine

des oiseaux. Anat. Anz. Bd. IV, 1889.

Sur la fine structure du lobe optique des oiseaux et sur I'origine reelle

des nerfs optiques. Int. Monatschr. Anat. u. Phys., Bd. VIII, 1891. Cirincione, G., Ueber die Entwiekelung der Capsula perilenticularis. Arch.

Anat. u. Entw., Suppl. Bd., Jahrg. 1897.

Zur Entwiekelung des Wirbeltierauges. Ueber die Entwiekelung

des Capsula perilenticularis. Leipzig, 1898.

Ueber die Genese des Glaskorpers bei Wirbelthieren. Verh. Anat.

Ges., 17. Versamml. in Heidelberg, 1903. Collin, R., Recherches sur le developpement du muscle sphincter de I'iris

chez les oiseaux. Bibliog. Anat., T. XII, fasc. V. Paris, 1903. Froriep, a., Ueber die Entwiekelung des Sehnerven. Anat. Anz., Bd. VI,

1891.

Die Entwiekelung des Auges der Wirbeltiere. Handb. der vergl. u.

exp. Entw.-l. der Wirbeltiere, Bd. II, 1905. HuscHKE, E., Lieber die erste Entwiekelung des Auges und die damit zusam menhangende Cyklopie. Meckel's Arch., 1832. Kessler, L., Untersuchungen liber die Entwiekelung des Auges, angestellt

am Hiihnchen und Tauben. Dissertation. Dorpat, 1871.

Die Entwiekelung des Auges der Wirbelthiere. Leipzig, 1877. V. Kolliker, a., LTeber die Entwiekelung und Bedeutung des Glaskorpers.

Verh. anat. Ges., 17. Vers. Heidelberg, 1903.

Die Entwiekelung und Bedeutung des Glaskorpers. Zeitschr. wiss.

Zool., Bd. LXXVII, 1904. V. Lenhossek, M., Die Entwiekelung des Glaskorpers. Leipzig, 1903. Lewis, W. H., Wandering Pigmented Cells Arising from the Epithelium of

the Optic Cup, with Observations on the Origin of the M. Sphincter

Pupillffi in the Chick. Am. Journ. Anat., Vol. II, 1903. LocY, W. A., Contribution to the Structure and Development of the Vertebrate Head. Journ. Morph., Vol. XI. Boston, 1895.

Accessory Optic Vesicles in the Chick Embryo. Anat. Anz., Bd. XIV,

1897. NussBAUM, M., Zur Riickbildung embryonaler Anlagen. (Corneal papillae

of chick embryos.) Archiv. mikr. Anat., Bd. LVII, 1901.


NussBAUM, M., Die Pars ciliaris retinae des Vogelauges. Arch. mikr. Anat., Bd.

LVII, 1901.

Die Entwiekelung der Binnenmuskeln des Aiiges der Wirbeltiere.

Arch. mikr. Anat., Bd. LVIII, 1901. Rabl, C, Ziir Frage nach der Entwickehmg des Glaskorpers. Anat. Anz.,

Bd. XXII, 1903.

Ueber den Ban und die Entwickehmg der Linse. II. Reptihen imd

Vogel. Zeitschr. wiss. Zool., Bd. LXV, 1899. Robinson, A., On the Formation and Structure of the Optic Nerve, and its

Relation to the Optic Stalk. Journ. Anat. and Phys. London, 1896. SziLi, A.V. Beitrag zur Kenntniss der Anatomic und Entwickelungsgeschichte

der hinteren Irisschichten, etc. Arch. Opthalm., Bd. LIII, 1902.

Zur Anatomic und Entwickelungsgeschichte der hinteren Irisschichten, etc. Anat. Anz., Bd. XX, 1901.

Zur Glaskorperfrage. Anat. Anz. Bd. XXIV, 1904. ToRNATOLA, Origiuc et nature du corps vitre. Rev. gener. d 'opthalm. Annee

14, 1897. UcKE, A., Epithelreste am Opticus und auf der Retina. Arch. mikr. Anat.,

Bd. XXXVIII, 1891.

Zur Entw^ickelung des Pigmentepithels der Retina. Diss, aus Dorpat.

Petersburg, 1 89 1 . ViRCHOW, H., Facher, Zapfen, Leiste, Polster, Gefasse im Glaskorperraum

von Wirbelthieren, sowie damit in Verbindung stehenden Fragen. Er gebn. Anat. u. Entw., Bd. X. Berlin, 1900. Weysse, a. W., and Burgess, W. S., Histogenesis of the Retina. Am.

Naturalist, Vol. XL, 1906.


B. The Nose

Born, G., Die Nasenhohlen und der Thranennasengang der amnioten Wir belthiere II. Morph. Jahrb., Bd. V, 1879; Bd. VIII, 1883. CoHN, Franz, Zur Entwickelungsgeschichte des Geruchsorgans des Hiihn chens. Arch. mikr. Anat., Bd. LXI, 1903. Dieulafe, Leon, Les fosses nasales des vertebres (morphologic et embry ologie). Journ. de I'anat. et de la phys., T. 40 and 41, 1904 and 1905.

(Translated by Hanau W. Loeb: Ann. of Otol., Rhin. and Laryng., Mar.,

June and Sept., 1900.) Disse, J., Die erste Entwiekelung des Riechnerven. Anat. Hefte, Bd. IX,

1897. Ganin, M., Einige Thatsachen zur Frage iiber das Jacobsohn'sche Organ der

Vogel. Arb. d. naturf. Ges. Charkoff, 1890 (russisch). Abstr. Zool.

Anz., 1890. V. KoLLiKER, A., Ueber die Entwickehmg der Geruchsorgane beim Menschen

und Hiihnchen. Wiirzburger med. Zeitschr., Bd. I, 1860. V. MiHALKOvics, v., Nasenhohle und Jacobson'sche Organ. Anat. Hefte,

I. Abth., Bd. XI, 1898. Peter, Karl, Entwickehmg des Geruchsorgans und Jakobson'sche Organs

in der Reihe der Wirbeltiere. Bildung der ausseren Nase und des


Gaumens. Handbuch der vergl, und experiment. Entwickelimgslehre

der Wirbeltiere. IP, 1902. Preobraschensky, L., Beitrage zur Lehre liber die Entwiekelung des Ge ruchsorganes des Huhnes. Mitth. embryol. Inst. Wien, 1892. PuTELLi, F., Ueber das Verhalten der Zellen der Riechschleimhaut bei

Hiihnerembryonen friiher Stadien. Mitth. embr. Inst. Wien, 1889.

C. The Ear

Hasse, C, Beitrage zur Entwiekelung der Gewebe der hautigen Vogel schnecke. Zeitschr. wiss. Zool., Bd. XVII, 1867. HuscHKE, Ueber die erste Bildungsgeschichte des Auges und Ohres beim

bebriiteten Hiihnchen. Isis von Oken, 1831. Kastschenko, N., Das Schlundspaltengebiet des Hiihnchens. Arch. Anat.

u. Entw., 1887. Keibel, Ueber die erste Bildung des Labyrinthanhanges. Anat. Anz., Bd.

XVI, 1899. Krause, R., Die Entwickekmg des Aquaeductus Vestibuh, s. Ductus endo lymphaticus. Anat. Anz., Bd. XIX, 1901.

Die Entwickekmgsgeschichte des hautigen Bogenganges. Arch. mikr.

Anat., Bd. XXXV, 1890. MoLDENHAUER, W., Die Entwickcking des mittleren und des ausseren Ohres.

Morph. Jahrb., Bd. Ill, 1877. PoLi, C, Sviluppo della vesicula auditiva; studio morphologico. Genoa,

1896.

Zur Entwickekmg der Gehorblase bei den WirbeUieren. Arch. mikr.

Anat., Bd. XLVIII, 1897. Retzius, G., Das Gehororgan der Wirbelthiere. II. Theil, Reptihen Vogel,

Sanger. Stockhokn. 1881-1884. RoTHiG, p., und Brugsch, Theodor, Die Entwickekmg des Labyrintkes

beim Huhn. Archiv. mikr. Anat., Bd. LIX, 1902. RtJDiNGER, Zur Entwickekmg des hautigen Bogenganges des inneren Ohres.

Sitzungsber. Akad. Miinchen, 1888.

Literature — Chapter X

The Alimentary Tract and Its Appendages

A. The Oral Cavity and Organs

Fraisse, p., Ueber Zahne bei Vogeln. Vortrag, geh. in der phys.-med.

Ges. Wiirzburg, 1880. Gardiner, E. G., Beitrage zur Kenntniss des Epitrichiums und der Bikkmg

des Vogelscknabels. Inaug. Dissert. Leipzig, 1884. Arch. mikr. Anat., Bd. XXIV, 1884. Gauff, E., Anat. L^ntersuchungen iiber die Nervenversorgung der Mund und Nasenhohledrusen der Wirbekiere. Morph. Jahrb., Bd. XIV, 1888. GiACOMiNi, E., Sulle glanduH sakvari degk uccelk. Richerche anatomico embrologiche. Monit. zook Itak, Anno 1, 1890.


GoppERT, E., Die Bedeutimg der Zunge ftir den secundaren Gaumen und den

Ductus naso-pharyngeus. Beobachtungen an Reptilien und Vogeln.

Morph. Jahrb., Bd. XXXI, 1903. Kallius, E., Die mediane Thyreoideaanlage und ihre Beziehung zum Tuber culum impar. Verb. anat. Ges., 17. Vers., 1903.

Beitrage zur Entwickelung der Zunge. Verb. anat. Ges., 15. Vers.

Bonn, 1901. Manno, Andrea, Sopra il niodo onde si perfora e scompare le membrana

faringea negli embrioni di polio. Richerche Lab. Anat. Roma, Vol.

IX, 1902. Oppel, a., Lehrbuch der vergleichenden mikroskopischen Anat. der Wir beltiere. Jena, 1900. Reichel, p., Beitrag zur Morphologie der ^Mundhohlendriisen der Wirbel thiere. Morph. Jahrb., Bd. VIII, 1883. Rose, C., Ueber die Zahnleiste und die Eischwiele der Sauropsiden. Anat.

Anz., Bd. VII, 1892. Sluiter, C. p., Ueber den Eizahn und die Eischwiele einiger Reptilien.

Morph. Jahrb., Bd. XX, 1893. Yarrell, W., On the Small Horny Appendage to the Upper Mandible in

Very Young Chickens. Zool. Journal, 1826.

B. Derivatives of the Emhryonic Pharynx

van Bemmelen, J. F., Die Visceraltaschen und Aortenbogen bei Reptilien

und Vogeln. Zool. Anz., 1886. His, W., Ueber den Sinus praecervicalis und die Thymusanlage. Arch.

Anat. u. Entw., 1886.

Schlundspalten und Thymusanlage. Arch. Anat. u. Entw., 1889. Der Tractus Thyreoglossus und seine Beziehung zum Zungenbein.

Arch. Anat. u. Entw., 1891. Kastschenko, N., Das Schlundspaltengebiet des Hiihnchens. Arch. Anat.

und Entw., 1887. LiESSNER, E., Ein Beitrag zur Kenntniss der Kiemenspalten und ihrer An lagen bei amnioten Wirbelthieren. Morph. Jahrb., Bd. XIII, 1888. Mall, F. P., Entwickelung der Branchialbogen und Spalten des Hiihnchens.

Arch. Anat. und Entw., 1887. DE Meuron, p., Recherches sur le developpement du thymus et de la glande

thyreoide. Dissertation, Geneve, 1886. MiJLLER, W., Ueber die Entwickelung der Schilddriise. Jen. Zeitschr., Bd.

VI, 1871. Seessel, a., Zur Entwickelungsgeschichte des Vorderdarms. Arch. Anat.

und Entw., 1877. Verdun, M. P., Sur les derives branchiaux du poulet. Comptes rendus

Soc. Biol., Tom. V. Paris, 1898.

Derives branchiaux chez les vertebres superieurs. Toulouse, 1898.


APPENDIX 455

C. (Esophagus, Stomach, Intestine

BoRNHAUPT, Th., Uritersuchiingen fiber die Entwickelung des Urogenital systems beim Huhnchen. Inaug. Diss. Riga, 1867. Cattaneo, G., Intorno a un recente lavoro sullo stomaco degli iiccelli. Pavia,

1888.

Istologia e sviluppo del apparato gastrico degli uceelli. Atti della

Soc. Ital. di Sc. Nat., Vol. XXVII, Anno 1884. Milano, 1885. Cazin, M., Recherches anatomiques, histologiques et embryologiques sur

I'appareil gastrique des oiseaux. Ann. Sc. Xat. Zool. 7 ser., Tom. IV,

1888.

Sur le developpement embryonnaire de Testomac des oiseaux. Bull.

de la societe philomathique de Paris. 7 ser., Tom. XI, Paris, 1887. Developpement de la couehe cornee du gesier du poulet et des glandes

qui la seeretent. Comptes rendus, T. CI, 1885. Cloetta, M., Beit rage zur mikroskopischen Anatomic des Vogeldarmes.

Archiv. mikr. Anat., Bd. XLI, 1893. Fleischmaxx, Albert, Morphologische studien uber Kloake und Phallus der

Amnioten. III. Die Vogel, von Dr. Carl Pomayer. Morph. Jahrb.,

Bel. XXX, 1902. Gasser, E., Beitrage zur Entwiekelungsgeschichte der Allantois, Miiller schen Gauge und des Afters. Frankfurt a. M., 1893.

Die Entstehung der Kloakenoffnung bei Hiihnerembryonen. Arch.

Anat. u. Entw., 1880. Maurer, F., Die Entwickelung des Darmsystems. Handb. d. vergl. u.

exp. Entw.-lehre der Wirbeltiere. 11^, 1902. v. MiHALCovics, v., Untersuchungen liber die Entwickelung des Harn- und

Geschlechtsapparates der Amnioten. Internat. Monatschr. Anat. u.

Phys., Bd. II, 1885-1886. MiNOT, C. S., On the Solid Stage of the Large Intestine in the Chick. Journ.

Bos. Soc. Med. Sc, Vol. IV, 1900. Pomayer, Carl. See Fleischmann. Retterer, E., Contributions a I'etude du cloaque et de la bourse de Fabricius

chez des oiseaux. Journ. de I'anat. et de la phys. 21 An. Paris, 1885. Seyfert, Beitrage zur mikroskopischen Anatomic und zur Entwiekelungsgeschichte der blinden Anhange des Darmcanals bei Kaninchen, Taube

unci Sperling. Inaug. Diss. Leipzig, 1887. ScHW^\RZ, D., Untersuchungen des Schwanzendes bei den Embryonen der

Wirbeltiere. Zeitschr. wiss. Zool., Bd. XL VIII, 1889. Stieda, L. LudwiG, L^eber den Bau und die Entwickelung der Bursa Fabricii.

Zeitschr. wiss. Zool., Bd. XXXIV, 1880. Swenander, G., Beitrage zur Kenntniss des Kropfes der Vogel. Zool. Anz.,

Bd. XXIT, 1899. Weber, A., Quelques faits concernant le developpement de Tintestin moyen,

et de ses glandes annexes chez les oiseaux. C. R. Soc. Biol., T. LIV. Paris,

1902. Wenckebach, K. F., De Ontwikkeling en de bouw der Bursa Fabricii. Inaug. Dissert. Leiden, 1888.


456 APPENDIX

D. Liver and Pancreas

Bracket, A., Die Entwickelung unci Histogenese der Leber und des Pancreas.

Ergebnisse d. Anat. u. Entw.-gesch., 1896. Brouha, M., Recherches sur le developpement du foie, du pancreas, de la

cloison mesenterique et des cavites hepato-enteriques chez les oiseaux.

Journ. de Tanat. et phys., T. XXXIV. Paris, 1898.

Sur les premieres phases du foie et sur revolution des pancreas ven traux chez les oiseaux. Anat. Anz., Bd. XIV, 1898. Choronschitzky, B., Die Entstehung der Milz, Leber, Gallenblase, Bauch speicheldriise und des Pfortadersystems bei den verschiedenen Abthei lungen der Wirbelthiere. Anat. Hefte, Bd. XIII, 1900. Felix, W., Zur Leber und Pancreasentwickelung. Arch. Anat. u. Entw., 1892. Frobeen, F., Zur Entwickelung der Vogelleber. Anat. Hefte, 1892. GoTTE, Alex., Beitrage zur Entwickelungsgeschichte des Darmcanals im

Huhnchen. Tubingen, 1867. Hammar, G. a., Ueber Duplicitat ventraler Pancreasanlage. Anat. Anz.,

Bd. XIII, 1897.

Ueber einige Hauptztige der ersten embryonalen Leberentwickelung.

Anat. Anz., Bd. XIII, 1897.

Einige Plattenmodelle zur Beleuchtung der fruheren embryonalen

Leberentwickelung. Arch. Anat. u. Entw., 1893. MiNOT, C. S., On a Hitherto Unrecognized Form of Blood-Circulation without

Capillaries in the Organs of Vertebrata. Proc. Boston Soc. of Nat.

Hist., Vol. XXIX, 1900. ScHREiNER, K. E., Beitrage zur Histologic und Embryologie des Vorder darms der Vogel. Zeitschr. wiss. ZooL, Bd. LXVIII, 1900. Shore, T. W., The Origin of the Liver, Journ. of Anat. and Phys., Vol. XXV,

1890-91. Saint-Remy, Sur le developpement du pancreas chez les oiseaux. Rev.

biol. du Nord de la France. Annee V, 1893.

E. The Respiratory Tract

Bar, M., Beitrage zur Kenntniss der Anatomic und Physiologic der Athemwerkzeuge bei den Vogeln. Zeitschr. wiss. Zool., Bd. LXI, 1896.

Bertelli, D., Sviluppo de sacchi aeriferi del polio. Divisione della cavita celomatica degli uccelli. Atti della Societa Toscana di scienze natural! residente in Pisa. Memorie, Vol. XVII, 1899.

Blumsteix-Judina, Beila, Die Pneumatisation des Markes der Vogelknochen. Anat. Hefte, Abth. I, Bd. XXIX (Heft 87), 1905.

Camp ANA, Recherches d 'anatomic de physiologic, et d 'organogenic pour la determination des lois de la genese et de revolution des especes animals. I. Memoire. Physiologic de la respiration chez les oiseaux. Anatomic de I'appareil pneumatique puhnonnaire, des faux diaphragmes, des seremus et de I'intestin chez le poulet. Paris, Masson, 1875.

Goeppert, E., Die Entwickelung der luftfiihrenden Anhange des Vorderdarms. Handbuch d. vergl. u. exp. Entw.-lehre der Wirbeltiere, Bd. II, T. 1, 1902.


APPENDIX 457

LocY, W. A. and Larsell, O., The Embryology of the Bird's Lung, Based on Observations of the Domestic Fowl. Am. Journ. of Anat., Vol. 19, pp. 447-504, and Vol. 20, pp. 1-44, 1916.

Rathke, M. H., Ueber die Entwickelung der Atemwerkzeuge bei den Vogeln und Saugetieren. Nov. Act. Acad. Caes. Leop. Car., T. XIV. Bonn, 1828.

Selenka, E., Beitrage zur Entwickelungsgeschichte der Luftsiicke des Huhnes. Zeitschr. wiss. Zool., Bd. XVI, 1866.

Strasser, H., Die Luftsacke der Vogel. Morph. Jahrb., Bd. Ill, 1877.

Weber, A., et Buvignier, A., Les premieres phases du developpement du poumon chez les embryons de poulet. Comptes rendus hebd. des seances de la societe de Biologie, Vol. LV. Paris, 1903.

WuNDERLiCH, L., Beitrage zur vergleichenden Anatomie und Entwickelungsgeschichte des unteren Kehlkopfes der Vogel. Nova Acta Acad. Caes. Leop. Carol. Germanicae, Bd. XL VIII, 1884.


LITERATURE — CHAPTER XI

Beddard, F. E., On the Oblique Septa ("Diaphragm" of Owen) in the Passerines and some other Birds. Proc. Zool. Soc. London, 1896.

Bertelli, D., Sullo sviluppo del diaframma dorsale nel Polio. Nota preventiva. Monit. Zool. Ital., Anno IX, 1898.

Contributo alia morfologia ed alio sviluppo del diaframma ornitico. Ibid., 1898.

Bracket, A., Die Entwickelung der grossen Korperhohlen imd ihre Trennung von einander, etc. Ergebnisse d. Anat. u. Entw.-gesch., Bd. VII, 1897.

Broman, Ivar, Die Entwickelungsgeschichte der Bursa omentalis und ahnlicher Recessbildungen bei den Wirbeltieren. Wiesbaden, 1904.

B-ROUHA, M. See Chap. X.

Butler, G. W., On the Subdivision of the Body Cavity in Lizards, Crocodiles and Birds. Proc. Zool. Soc. London, 1889.

Choronschitzky, B. See Chap. X.

Dareste, C, Sur la formation du mesentere et de la gouttiere intestinale dans Tembryon de la poule. Comptes rendus, T. CXII, 1891.

HocHSTETTER, F., Die Entwickelung des Blutgefasssystems. Handbuch der vergl. und exp. Entw.-lehre der Wirbeltiere. IIP, 1903.

Janosik, J., Le pancreas et la rate. Bibliographic Anat. Annee 3. Paris, 1895.

LocKWOOD, C. B., The Early Development of the Pericardium, Diaphragm and Great Veins. Phil. Trans. Roy. Soc, London, Vol. CLXXIX, 1889.

Mall, F. P., Development of the Lesser Peritoneal Cavity in Birds and Mammals. Journ. Morph., Vol. V, 1891.

Maurer, F., Die Entwickehmg des Darmsystems. Handbuch d. vergl. u. exp. Entw.-lehre d. Wirbeltiere, Vol. II, 1906.

Peremeschko, LTeber die Entwickelung der Milz. Sitzungsber. d. Akad. d. Wiss. in Wien, math., naturwiss. Klasse, Bd. LVI, Abth. 2, 1867.

Ravn, E., Die Bildung des Septum transversum beim Hiihnerembryo. Arch. Anat. u. Entw., 1896. See also Anat. Anz., Bd. XV, 1899.


458 APPENDIX

Reichert, Entwickelungsleben im Wirbeltierreich. Berlin, 1840. Remak, Untersuchungen liber die Entwickelung des Wirbeltierreichs, p. 60,

1850-1855. UsKOW, W., Ueber die Entwickelung des Zwerchfells, des Pericardium und

des Coeloms. Arch. mikr. Anat., Bd. XXII, 1883. WoiT, O., Zur Entwickelung der Milz. Anat. Hefte, Bd. IX, 1897.

LITERATURE — CHAPTER XII

V. Baer, K. E., Ueber die Kiemen und Kiemengefasse im den Embryonen

der Wirbeltiere. Meckel's Archiv., 1827. VAN Bemmelen, J., Die Visceraltaschen und Aortenbogen bei Reptilien und

Vogeln. Zool. Anz., 1886. Boas, J. E. V., Ueber die Aortenbogen der Wirbeltiere. Morph. Jahrb.,

Bd. XIII, 1887. Brouha. See Chap. X. HocHSTETTER, F., Die Entw^ickelung des Blutgefasssystems (des Herzens

nebst Herzbeutel und Zwerchfell, der Blut- und Lymphgefasse, der

Lymphdriisen und der Milz in der Reihe der Wirbeltiere). Handbuch

der vergl. und exp. Entwickelungslehre der Wirbeltiere. IIP, 1903. Beitrage zur Entwickelungsgeschichte des Venensystems der Amnioten.

I. Hiihnchen. Morph. Jahrb., Bd. XIII, 1888.

Ueber den Ursprung der Arteria Subclavia der Vogel. Morph. Jahrb,

Bd. XVI, 1890.

Entwickelung des Venensystems der Wirbeltiere. Ergeb. der Anat.

u. Entw., Bd. Ill, 1893. HuscHKE, E., Ueber die Kiemenbogen und Kiemengefasse beim bebriiteten

Hiihnchen. Isis, Bd. XX, 1827. Langer, a., Zur Entwickelungsgeschichte des Bulbus cordis bei Vogeln und

Saugetieren. Morph. Jahrb., Bd. XXII, 1894. LiNDES, G., Ein Beitrag zur Entwickelungsgeschichte des Herzens. Dissertation. Dorpat, 1865. LocY, W. A., The Fifth and Sixth Aortic Arches in Chick Embryos with

Comments on the Condition of the Same Vessels in other Vertebrates.

Anat. Anz., Bd. XXIX, 1906. Mackay, J. Y., The Development of the Branchial Arterial Arches in Birds,

with Special Reference to the Origin of the Subclavians and Carotids.

Phil. Trans. Roy. Soc, London, Vol. CLXXIX, 1889. Masius, J., Quelques notes sur le developpement du coeur chez le poulet.

Arch. Biol., T. IX, 1889. Miller, W. S., The Development of the Postcaval Veins in Birds. Am.

Journ. Anat., Vol. II, 1903. PopoFF, D., Die Dottersackgefasse des Huhnes. Wiesbaden, 1894. Rathke, H., Bemerkungen iiber die Entstehung der bei manchen Vogeln

und den Krokodilen vorkommenden unpaaren gemeinschaftlichen Carotis.

Arch. Anat. u. Phys., 1858. Rose, C, Beitrage zur vergleichenden Anatomie des Herzens der Wirbeltiere. Morph. Jahrb., Bd. XVI, 1890.


APPENDIX 459

Rose, C, Beitrage zur Entwickelungsgeschichte des Herzens. Inaug. Dissert.

Heidelberg, 1888. ToNGE, Morris, On the Development of the Semilunar Valves of the Aorta

and Pulmonary Artery of the Chick. Phil. Trans. Roy. Soc, London,

Vol. CLIX, 1869. Twining, Granville H., The Embryonic History of the Carotid Arteries

in the Chick. Anat. Anz., Bd. XXIX, 1906. ViALLETON, L., Developpement des aortes posterieures chez I'embryon de

poulet. C. R. Soc. Biol., T. III. Paris, 1891.

Developpement des aortes chez Tembryon de poulet. Journ. de

Tanat. et phys., T. XXVIII, 1892. ZucKERKANDL, E., Zur Anat. und Entwickelungsgeschichte der Arterien des

Unterschenkels und des Fusses. Anat. Hefte, Bd. V, 1895.

Zur Anatomie und Entwickelungsgeschichte der Arterien des Vor derarmes. Anat. Hefte, Bd. IV, 1894.

LITERATURE — CHAPTER XIII

Abraham, K., Beitrage zur Entwickelungsgeschichte des Wellensittichs.

Anat. Hefte, Bd. XVII, 1901. Balfour, F. M., On the Origin and History of the Urogenital Organs of

Vertebrates. Journ. of Anat. and Physiol., Vol. X, 1876. Balfour and Sedgwick, On the Existence of a Rudimentary Head Kidney

in the Embryo Chick. Proc. R. Soc, London, Vol. XXVII, 1878. On the Existence of a Head Kidney in the Embryo Chick and on

Certain Points in the Development of the Miillerian Duct. Quar. Journ.

Micr. Sc, Vol. XIX, 1879. BoRNHAUPT, Th., Zur Entwickelung des Urogenitalsystems beim Huhnchen.

Inaug. Diss. Dorpat, 1867. Brandt, A., Ueber den Zusammenhang der Glandula suprarenalis mit dem

parovarium resp. der Epididymis bei Hiihnern. Biolog. Centralbl.,

Bd. IX, 1889.

Anatomisches und allgemeines liber die sog. Hahnenfedrigkeit und

liber anderweitige Geschlechtsanomalien der Vogel. Zeitschr. wiss. Zool.,

Bd. XL VIII, 1889. Felix, W., Zur Entwickelungsgeschichte der Vorniere des Huhnchens Anat. Anz., Bd. V, 1890. Felix und Buhler, Die Entwickelung der Ham- und Geschlechtsorgane.

]. Abschnitt — Die Entwickelung des Harnapparates, von Prof. Felix.

Handbuch der vergl. u. exper. Entw.-lehre der Wirbeltiere, HIS 1904. FiRKET, Jean, Recherches sur I'organogenese des glands sexuelles chez les

oiseaux. Arch, de Biol. Tome 29, pp. 201-351. PI. 5, 1914. FuRBRiNGER, M., Zur vcrgleichendeu Anatomie und Entwickelungsgeschichte

der Excretionsorgane der Vertebraten. Morph. Jahrb., Bd. IV, 1878. Fusari, R., Contribution a I'etude du developpement des capsules surre nales et du sympathetique chez le poulet et chez les mamniiferes. Archives. Hal. de biologic, T. XVI, 1892.


460 APPEXDIX

Gasser, E., Beitrage zur Entwickelungsgeschichte der Allantois, der Muller schen Gange imd des Afters. Frankfurt a. M., 1874.

Die Entstehung des Wolff'schen Ganges beim Huhn. Sitz.-ber.

Naturf. Ges., Marburg, Jahrg. 1875.

Beobachtungen uber die Entstehung des Wolff'schen Ganges bei

Embryonen von Hiihnern und Gansen. Arch. mikr. Anat.. Bd. XIV, 1877. Gasser, E., und Siemmerling, Beitrage zur Entwickekmg des Urogenitalsys tems bei den Huhnerembryonen. Sitz.-ber. Naturf. Ges., Marburg, 1879. Gerhardt, U., Zur Entwickelung der bleibenden Niere. Arch. mikr. Anat.,

Bd. LVII, 1901. HocHSTETTER, F., Zur Morphologie der Vena cava inferior. Anat. Anz., Bd. Ill,

1888. Hoffmann, C. K., Etude sur le developpement de I'appareil urogenital des

oiseaux. Verhandelingen der Koninklyke Akademie van Wetenschap pen. Amsterdam, Tweede Sectie, Vol. I, 1892. Janosik, J., Bemerkungen iiber die Entwickelung der Nebennieren. Archiv.

mikr. Anat., Bd. XXII, 1883.

Histologisch-embryologische Untersuchungen iiber das Urogenital system. Sitzungsber. Akad. Wiss. Wien, math.-nat. Kl., Bd. XCI,

3. Abth., 1885. KosE, W., Ueber die Carotisdriise und das "Chromaffine Gewebe" der Vogel.

Anat. Anz., Bd. XXV, 1904. KowALEvsKY, R., Die Bildung der Urogenitalanlage bei Huhnerembryonen.

Stud. Lab. Warsaw Univ., II, 1875. KuPFFER, C, Untersuchungen iiber die Entwickelung des Harn- und Ge schlechtssystems. Arch. mikr. Anat., Bd. I, 1865; and ibid. Bd. II, 1866. V. MiHALCOVics, v., Untersuchungen iiber die Entwickelung des Harn und Geschlechtsapparates der Amnioten. Intern. Monatschr. Anat.

und Phys., Bd. II, 1885-1886. Miner viNi, R., Des capsules surrenales: Developpement, structure, fonc

tions. Journ. de Tanat. et de la phys, An. XL. Paris, 1904. NussBAUM, M., Zur Differenzierung des Geschlechtes im Thierreich. Arch.

mikr. Anat., Bd. XVIII, 1880.

Zur Entwickelung des Geschlechts beim Huhn. Verh. anat. Ges., Bd

XV, 1901.

Zur Riickbildung embryonaler Anlagen. Arch. mikr. Anat., Bd

LVII, 1901.

Zur Entwickelung des Urogenitalsystems beim Huhn. C. R. Ass.

d. An. Sess., 5. Liege, 1903. Poll, H., Die Entwickelung der Nebennierensysteme. Handbuch der

vergl. und exper. Entwickelungslehre der Wirbeltiere. III^ 1906. Prenant, a., Remarques a propos de la constitution de la glande genitale

indifferente et de I'histogenese du tube seminifere. C. R. Soc. biol.,

Ser. 9, T. II, 1890. Rabl, H., Die Entwickelung und Struktur der Nebennieren bei den Vogeln.

Arch. mikr. Anat., Bd. XXXVIII, 1891. Renson, G., Recherches sur le rein cephalique et le corps de Wolff chez les

oiseaux et les mammiferes. Arch. mikr. Anat., Bd. XXII, 1883.


APPENDIX 461

RucKERT, J., Entwickelung der Excretionsorgane. Ergebnisse der Anat.

u. Entw.-gesch., Bd. I, 1892. ScHREixER, K. E., Ueber die Entwickelung der Amniotenniere. Zeitschr.

wiss. Zool., Bd. LXXI, 1902. Sedgwick, A., Deve opment of the Kidney in its Relation to the Wolffian Body in the Chick. Quart. Journ. IMicr. Sc, Vol. XX, 1880.

On the Early Development of the Anterior Part of the Wolffian Duct and Body in the Chick, together with Some Remarks on the Excretory System of Vertebrata. Quart. Journ. Micr. Sc, Vol. XXI, 1881. Semon, Richard, Die indifferente Anlage der Keimdriisen beim Htihnchen und ihre Differenzierung zum Hoden. Jen. Zeitschr. Naturwiss., Bd. XXI, 1887. SouLiE, E. H., Recherches sur le developpement des capsules surrenales chez les vertebres superieurs. Journ. de I'anat. et phys., Paris, An. XXXIX, 1903. Swift, Charles H., Origin and Early History of the Primordial GermCells in the Chick. American Journal of Anat., Vol. 15, pp. 483516, 1914.

Origin of the Definitive Sex-Cells in the Female Chick and their Relation to the Primordial Germ-Cells. ib. Vol. 18, pp. 441-470, 1915.

Origin of the Sex-Cords and Definitive Spermatogonia in the Male Chick, ib. Vol.20, pp. 375-410, 1916. Waldeyer, W., Eierstock und Ei. Ein Beitrag zur Anatomie und Ent wickelungsgeschichte der Sexualorgane. Leipzig, 1870. Weldon, On the Suprarenal Bodies of Vertebrates. Quar. Journ. Micr. Sc, Vol. XXV, 1884.

LITERATURE — CHAPTER XIV

Agassiz, L., On the Structure of the Foot in the Embryo of Birds. Proc

Boston Soc Nat. Hist., 1848. Bizzozero, G., Neue Untersuchungen iiber den Bau des Knochenmarks der

Vogeln. Arch. mikr. Anat., Bd. XXXV, 1890. See also Arch. Ital. de

Biol., T. XIV, 1891. Blu.mstein-Judixa, Beila, Die Pneumatisation des Markes der Vogelkno chen. Anat. Hefte, Abth. I, Bd. XXIX, 1905. Bracket, A., Etude sur la resorption de cartilage et le developpement des

OS longs chez les oiseaux. Internat. Monatschr. Anat. und Phys., Bd.

X, 1893. Braun, M., Entwickelung des Wellenpapageis. Arb. Zool. Zoot. Inst. Wiirz burg, Bd. V, 1881. Brulle et HuGUENY, Developpement des os des oiseaux. Ann. Sc. Nat.,

Ser. Ill, Zool. T. IV,1845. BuNGE, A., Untersuchungen zur Entwickelungsgeschichte des Beckengiirtels

der Amphibien, Reptilien und Vogel. Inaug. Diss. Dorpat. 1880. CuviER, Extrait d'un memoire sur les progres de I'ossification dans le sternum

des oiseaux. Ann. des Sc Nat., Ser. I, Vol. XXV, 1832. V. Ebner, v., Ueber die Beziehungen der Wirbel zu den LTrwirbel. Sitzungsber.

d. k. Akad. d. Wiss. Wien, math.-naturwiss. Kl., Bd. CI, 3. Abth.. 1892.


462 APPENDIX

Urwirbel und Neugliederiing der Wirbelsaule. Sitzungsber. d. k.

Akad. d. Wiss. Wien, Bd. XCVII, 3. Abth. Wien, 1889, Jahrg., 1888. Froriep, a., Zur Entwickelungsgeschichte der Wirbelsaule, insbesondere

des Atlas und Epistropheus und der Occipitalregion. I. Beobachtungen

an Hiihnerembryonen. Arch. Anat. u. Entw., 1883. Gaupp, E., Die Entwickelung des Kopfskelettes. Handbuch der vergl. u.

exper. Entw.-lehre der Wirbeltiere, Bd. 3, 1905.

Die Entwickelung der Wirbelsaule. Zool. Centralbl., Jahrg. Ill, 1896. Die Metamerie des Schadels. Ergeb. der Anat. u. Entw., 1897. Gegenbaur, C, Untersuchungen zur vergl. Anat. der Wirbelsaule bei

Amphibien und Reptilien. Leipzig, 1864.

Beitrage zur Kenntniss des Beckens der Vogel. Eine vergleichende

anatomische Untersuchung. Jen. Zeitschr. Med. u. Naturw., Bd. VI, 1871. Die Metamerie des Kopfes und die Wirbeltheorie des Kopfskelettes,

im Lichte der neueren Untersuchungen betrachtet und gepriift. Morph.

Jahrb., Bd. XIII, 1888. GoETTE, A., Die Wirbelsaule und ihre Anhange. Arch. mikr. Anat., Bd.

XV, 1878. Hepburn, D., The Development of Diarthrodial Joints in Birds and Mammals. Proc. R. Soc. Edinb., Vol. XVI, 1889. Also in Journ. of Anat.

and Phys., 1889. Jager, G., Das Wirbelkorpergelenk der Vogel. Sitzungsber. Akad. Wien,

Bd. XXXIII, 1858. Johnson, Alice, On the Development of the Pelvic Girdle and Skeleton

of the Hind Limb in the Chick. Quar. Journ. Micr. Sc, Vol. XXIII,

1883. KuLCZYCKi, W., Zur Entwickelungsgeschichte des Schultergiirtels bei den

Vogeln mit besonderer Berucksichtigung des Schliisselbeines (Gallus,

Columba, Anas). Anat. Anz., Bd. XIX, 1901. Leighton, V. L., The Development of the Wing of Sterna Wilsonii. Am.

Nat., Vol. XXVIII, 1894. LuHDER, W., Zur Bildung des Brustbeins und Schultergiirtels der Vogel.

Journ. Ornith., 1871. Mannich, H., Beitrage zur Entwickelung der Wirbelsaule von Eudyptes

chrysocome. Inaug. Diss. Jena, 1902. Mehnert, Ernst, LTntersuchungen liber die Entwickelung des Os Pelvis

der Vogel. Morph. Jahrb., Bd. XIII, 1887.

Kainogenesis als Ausdruck differenter phylogenetischer Energieen.

Morph. Arb., Bd. VII, 1897. Morse, E. S., On the Identity of the Ascending Process of the Astragalus

in Birds w'ith the Intermedium. Anniversary Mem. Boston Soc. Nat.

Hist., 1880. Norsa, E., Alcune richerche sulla morphologia dei membri anteriori degli

uccelli. Richerche fatte nel Laborat Anatomico di Roma e alti labora tori biologici, Vol. IV, fasc. I. Abstract in French in Arch. Ital. biol.,

T. XXII, 1894. Parker, W. K., On the Structure and Development of the Skull of the Common Fowl (Gallus domesticus). Phil. Trans., Vol. CLIX, 1869.


APPEXDIX 463

Parker, W. K., On the Structure and Development of the Birds' Skull.

Trans. Linn. Soc, 1876.

On the Structure and Development of the Wing of the Common Fowl.

Phil. Trans., 1888. Remak, R., Untersuchungen liber die Entwickelung der Wirbeltiere. Berlin,

1850-1855. Rosenberg, A., Ueber die Entwickelung des Extremitiitenskelets bei einigen

durch die Reduction ihrer Gliedmaassen charakteristischen Wirbeltiere.

Zeitschr. wiss. ZooL, Bd. XXIII, 1873. ScHAUiNSLAND, H., Die Entwickelung der Wirbelsaule nebst Rippen und

Brustbein. Handbuch der vergl. und exper. Entw.-lehre der Wirbeltiere, Bd. Ill, T. 2, 1905. Schenk, F., Studien liber die Entwickelung des knochernen Unterkiefers

der Vogel. Sitzungsber. Akad. Wien, XXXIV Jahrg., 1897. Schultze, O., Ueber Eml^ryonale und bleibende Segmentirung. Verh.

Anat. Ges., Bd. X. Berlin, 1896. Stricht, O. van der, Recherches sur les cartilages articulaires des oiseaux.

Arch, de biol., T. X, 1890. SuscHKiN, P., Zur Anatomic und Entwickelungsgeschichte des Schadels der

Raub vogel. Anat. Anz., Bd. XI, 1896.

Zur Morphologic des Vogelskeletts. (1) Schadel von Tinnunculus.

Nouv. Mem. Soc. Imp. des X'atur. de Moscow, T. X\T, 1899. ScHWARCK, W., Beitrage zur Entwickelungsgeschichte der Wirbelsaule bei

den Vogeln. Anat. Studien (Herausgeg. v. Hasse), Bd. I, 1873. WiEDERSHEiM, R., Ucbcr die Entwickelung des Schulter- und Beckenglirtels.

Anat. Anz., Bd. IV, 1889, and V, 1890. WiJHE, J. W. VAN, Ueber Somiten und Nerven im Kopfe von Vogel- und

Reptilienembryonen. Zool. Anz., Jahrg. IX, 1886.


INDEX


Abducens nerve, 267

Abducens nucleus, 262, 263

Abnormal eggs, 2.5

Accessory cleavage of pigeon's egg, 38, 43, 44

Accessory mesenteries, 340, 341

Acustico-facial ganglion complex, 159 160, 262, 268

Air-sacs, 326, 330, 331

Albumen, 18

Albumen-sac, 217, 224

Albuginea of testis, 397

Alecithal ova (see isolecithal)

Allantois, blood-supply of, 222; general, 217; inner wall of, 220; neck of, 143, 144, 316; origin of, 143, 144; outer wall of, 220; rate of growth, 221; structure of inner wall, 223; structure of outer wall, 223

Amnion, effect of rotation of embryo on, 140, 141, 142; functions of, 231; head fold of, 137, 139; later history of, 231; mechanism of formation, 139, 140; muscle fibers of, 231; origin of, 135; secondary folds of, 142

Amnio-cardiac vesicles, 92, 116

AmpuUse of semicircular canals, 291

Anal plate, 143, 182

See also cloacal membrane

Angioblast, 88

Anterior chamber of eye, 278

Anterior commissure of spinal cord, origin of, 244

Anterior intestinal portal, 95 (Fig. 49), 121, 132

Anterior mesenteric artery, 363

Aortic arches, 198, 199, 203, 358362 ; transformations of, 359-361

Appendicular skeleton, 434

Aqueduct of Sylvius, 251.

Archenteron, 55

Area opaca, 39, 50, 61, 86; pellucida, 39, 50, 61; vasculosa, 61, 86; vitellina, 61, 62, 86

Arterial system, 121, 126, 198, 199, 203, 204, 228, 358-363

Atlas, development of, 420

Atrium bursse omentalis, 344


Auditory nerve, 295; ossicles, 299, 432; pit, 168

Auricular canal, 354

Auriculo- ventricular canal, 348; division of, 355

Axis, development of, 420

Axones, origin of, 235

Basilar plate, 429

Beak, 302, 304

Biogenesis, fundamental law of, 4

Blastoderm, 17; diameter of unin cubated, 61; expansion of, 50, 53,

61 Blastopore, 55, 82 Blood-cells, origin of, 118 Blood-islands, origin of, 86, 89 Blood-vessels, origin of, 118 Body-cavity, 115, 205-210, 333 Bony labyrinth, 296 Brain, primary divisions of, 108;

early development of, 147, 156;

later development of, 244-252 Branchial arch, first, skeleton of, 432 Bronchi, 325, 326 Bulbus arteriosus, 198, 201, 202, 348;

fate of, 357 Bursa Fabricii, 314, 317, 319 Bursa omenti ma j oris, 344 Bursa omenti minoris, 344

Canal of Schlemm, 279

Cardinal veins, anterior, 200, 204,

205, 363; posterior, 200, 204, 205,

368 Carina of sternum, 427 Carotid arch, 361 Carotid, common, 362; external 359,

361 ; internal, 359-361 Carpus, 436, 437 Cartilage, absorption of, 408; bones,

definition, 407; calcification of,

409 Caval fold, 344 Cavo-coeliac recess, 344 Cavum sub-pulmonale, 342 Cell-chain hypothesis, 255 Cell theory, \

Central and marginal cells, 41, 42 Central canal of spinal cord, 242


465


466


INDEX


Cerebellum, 155, 251

Cephalic mesoblastic somites, 108, 269, 428

Cerebral flexures, 149, 245

Cerebral ganjilia, 157-162, 262

Cerebral hemispheres, origin of, 151; (see telencephalon)

Cervical flexure, 133, 245

Chalazee, 18

Chemical composition of parts of hen's egg, 20, 21

Chiasma opticus, 154, 249

Choanal, 215, 285

Chondrification, 408

Chorion, 135, 217, 218, 220

Choroid coat of eye. 279; fissure, 166, 281 ; plexus, 248

Chromaffin tissue, 404

Chronology, 64

Cilary processes, 272, 274

Circulation of blood, 121, 122, 197200, 372-376

Circulation of blood, changes at hatching, 376; completion of double, 355

Classification of stages, 64-67

Clavicle, 434, 435

Cleavage of ovum (hen), 39-43

Cleavage of ovum (pigeon), 43-47

Cloaca, 314-319; (see hind-gut)

Cloacal membrane, 315, 318; (see also anal plate)

Coeliac artery, 363

Coelome (see body-cavity)

Coenogenetic aspects of development, 6

Collaterals, origin of, 238

Collecting tubules of mesonephros, 379, 380

CoUiculus palato-pharyngeus, 398

Commissura anterior, 252; inferior, 252 ; posterior, 252 ; trochlearis, 252

Concrescence, theory of, 82, 84

Cones of growth, 235

Conjunctival sac, 279

Coprodseum, 315, 318, 319

Coracoid, 434, 435

Cornea, 278

Corpus striatum, 247

Corpus vitreum, 275

Cortical cords of suprarenal capsules, 405

Cranial flexure, 133, 245; nerves, 261

Cristse acusticse, 295

Crop, 312

Crural veins^ 372

Cushion septum, 355

Cuticle of sheU, 17

Cutis plate, 185, 188


Delimitation of embryo from blastoderm, 91

Dendrites, origin of, 236

Determinants, 7

Diencephalon, early development of, 152; later development of, 249

Dorsal aorta, origin of, 121

Dorsal longitudinal fissure and septum of spinal cord, 243, 244

Dorsal mesentery, 172, 342

Duct of Botallus, 359, 361, 376

Ducts of Cuvier, 200, 204, 207, 361

Ductus arteriosus (see duct of Botalus) ; choledochus (common bileduct), 181, 321; cochlearis, 293; cystico-entericus, 321 ; endolymphaticus, 169, 289; hepato-cysticus, 321; hepato-entericus, 321; venosus (see meatus venosus)

Duodenum, 310, 311

Ear, later development of, 288

Ectamnion, 138

Ectoderm and entoderm, origin of, 52

Ectoderm of oral cavity, limits of, 301

Egg, formation of, 22, 24, 25

Egg-tooth, 302, 303

Embryonic circulation, on the fou.rth day, 372-374; on the sixth day, 374; on the eighth day, 374-376

Embryonic membranes, diagrams of, 219, 220; general, 216; origin of, 135; summary of later historj^, 145

Endocardium, origin of, 119

Endolymphatic duct (see ductus endolymphaticus)

Endolymphatic sac (see saccus endolymphaticus)

Entobronch;, 327, 328

Entoderm, origin of, 52

Ependyma, origin of, 239

Epididymis, 391, 398

Epiphysis, 153, 249

Epiphyses (of long bones), 409

Epistropheus, development of, 420

Epithalamus, 251

Epithelial ceUs of neural tube, 233, 234

Epithelial vestiges of visceral pouches 309

Epoophoion, 401

Equatorial ring of lens, 277-278

Excentricity of cleavage, 41, 47

Excretory system, origin of, 190

External auditory meatus, 297, 300

External form of the embryo, 211

Eye, early development of, 164; later development of, 271

Eyelids, 279-280


INDEX


467


Facial region, development of the,

214, 215, 216 Facialis nerve, 268 Facialis nucleus, 262, 263 Femur, 440 Fertilization, 35 Fibula, 440

First segmentation nucleus, 36 Fissura metotica, 429 Foetal development, 11 Fold of the omentum, 344, 345 Follicles of ovary, 22, 26, 27, 28, 30,

400 Follicular cells, origin of, 27, 400 Foramen, interventricular, 353, 354;

of Monro, 247; of Winslow, 343;

ovale, 355 Foramina, interauricular, 355 Fore-brain, origin of, 108 Fore-gut, 91, 9'3, 172 Formative stuffs, 15 Funiculi prajcervicales, 307

Gall-bladder, 321

Ganglia, cranial and spinal, 156; cranial, 157, 158, 159, 262; spinal, later development of, 254, 257

Ganglion, ciliare, 266; geniculatum, 268; jugulare, 268; olfactorium nervi trigemini, 264; nodosum, 161, 268 ; ~ petrosum, 161, 268; of Remak, 257

Gastric diverticula of body-cavity, 340

Gastrulation, 53, 84

Genetic restriction, law of, 8

Genital ducts, development of, 401

Germ-cells, general characters of, 9-12; comparison of, 12-14

Germ-wall, 47, 48, 69, 90, 128, 129

Germinal cells of neural tube, 233, 234

Germinal disc, 11, 12, 35, 37, 39

Germinal epithelium, 391, 392, 399

Germinal vesicle, 27, 28

Gizzard, 313, 314

Glomeruli of pronephros, 192

Glossopharyngeus, ganglion complex of, 161, 262, 268; nerve, 268; nucleus, 262, 263

Glottis, 332

Gray matter of spinal cord, development of, 240; origin of, 239

Haemal arch of vertebrae, 416, 417

Harderian gland, 280

Hatching, 232

Head, development of, 213

Head-fold, origin of, 91

Head process, 73, 80


Heart, changes of position of, 348, 349; development on second and third days, 200-203; divisions of cavities of, 350 ; ganglia and nerves of, 259; later development of, 348; origin of, 119

Hensen's knot, 73

Hepatic veins, 366

Hepatic portal circulation, 366, 375

Hermaphroditism of embryo, 391

Heterotaxia, 133

Hiatus communis recessum, 343

Hind-brain, origin of, 108

Hind-gut, 143, 172

Hind-limbs, origin of skeleton, 438

Hoffmann's nucleus, 240

Holoblastic ova, 11, 12

Humerus, 436

Hyoid arch, 175: skeleton of, 432

Hyomandibular cleft, 174, 297

Hypoglossus nerve, 269

Hypophysis, 154, 249

Hypothalamus, 251

Ilium, 438, 439

Incubation, normal temperature for, 65, 66

Indifferent stage of sexual organs, 391

Infundibulum (of brain), 154, 249

Infundibulum (of oviduct). See ostium tubae abdominale

Interganglionic commissures, 156

Intermediate cell-mass, 114, 190

Interventricular sulcus, 348, 353

Intervertebral fissure, 412

Intestine, general development of, 310. 311

Iris, 272 : muscles of, 273, 274

Ischiadic veins, 372

Ischium, 438, 439

Isolecithal ova, 11

Isthmus, of brain, 155; of oviduct, 22

Jacobson, organ of, 286 Jugular vein, 363

Kidney, capsule of, 390; permanent, 384-389; secreting tubules of, 390

Lagena, 293

Lamina terminalis, 105, 152, 247, 248

Larva, 11

Laryngotracheal groove, 178, 331,

332 Ijarynx, 332 Latebra, 1 9

Lateral plate of mesoblast, 115 Lateral tongue folds, 305 Lens, 166, 276-278


468


INDEX


Lenticular zone of optic cup, 271

Lesser peritoneal cavity, 344

Ligamentum pectinatuni iridis, 279

Limiting sulci, 130

Lingual glands, 30G

Lip-grooves, 304

Liver, histogenesis of, 323; later development of, 319-323; origin and early development of, 179, 180, 181 ; origin of lobes of, 322 ; primarv ventral ligament of, 335

Lungs,^ 178, 326

Macula utriculi, sacculi, etc., 295

Malpighian corpuscles (mesonephric) origin of, 195

Mammillae of shell, 17

Mandibular aortic arch, 121, 122, 203, 204

Mandibular arch, skeleton of, 431

Mandibular glands, 306

Mantle layer of spinal cord, origin of, 239

Margin of overgrowth, 52, 57

Marginal notch, 60, 84, 85

Marginal velum, 235

Marrow of bone, origin of, 410

Maturation of ovum, 32

Meatus venosus, 199, 364, 366, 368

Medullary cords of suprarenal capsules, 405, 406

Medullary neuroblasts of brain, 262

Medullary plate, 95; position of anterior end of, in neural tube, 102, 103

Megaspheres, 59

Membrana reuniens, 418

Membrane bones, definition of, 407

]\Iembranes of ovum, 10

Membranous labyrinth, 289

Meroblastic ova, 11

Mesencephalon, 108, 155, 251

Mesenchyme, definition of, 116

Mesenteric artery, 363

Mesenteric vein, 366, 367

Mesenteries, 333

Mesentery, dorsal, 172, 342; of the vena cava inferior, 341

Mesoblast, gastral, 110; of the head, origin of, 116, 117; history of between 1 and 12 somites, 109; lateral plate of, 110, 115; of opaque area, origin of, 86, 88; origin of, 74, 78; paraxial, 110; prostomial, 110; somatic layer of, 115; splanchnic layer of, 115

Mesobronchus, 326, 327

Mesocardia lateralia, 200, 207, 334, 337

Mesocardium, origin of, 120


Mesogastrium, 309, 342, 343 Mesonephric arteries, 363 Mesonephric mesentery, 341 Mesonephric tubules, formation of,

195 Mesonephric ureters, 380 Mesonephros, later history of, 378;

origin and early history of, 194 197; see ^^'olffian body Mesothalamus, 251 Mesothelium, definition of, 116 Metacarpus, 436, 437, 438 Metamorphosis, 11 Metanephros, 384-389 Metatarsals, 441 Metathalamus, 251 Metencephalon, 155, 251 Mid-brain (see Mesencephalon) Mid-gut, 172, 181, 310 Mouth, 301 Miillerian ducts, 391; degeneration

in male, 402, 403; origin of, 401,

402, 403 Muscles of iris, 274 Muscle plate, 185, 186 Myelencephalon, 155, 252 Myocardium, origin of, 119 Myotome, 188

Nares, 286

Nephrogenous tissue, 195, 378; of

metanephros, 384, 387 Nephrotome, 114, 190 Neural crest, 156 Neural folds, 97, 99 Neural groove, 97 Neural tube, 95, 105 Neurenteric canal, 73, 82 Neuroblasts, 233-239; classes of, in

spinal cord, 244 Neurocranium, 427, 428 Neuroglia cells, origin of, 239, 240 Neuromeres, 108, 148, 152, 155 Neurone theory, 236, 255, 256 Neuropore, 101, 105 Notochord, later development of,

411 ff; oriirin of, 80; in the region

of the skull, 428

Oblicjue septum, 331, 342 Oculo-motor nerve, 265; nucleus,

262, 263 Odontoid process, origin of, 420 (Esophagus, 179, 310, 312 Olfactory lobe; 247 Olfactory nerve, 263 Olfactory pits, 169, 285 Olfactory A'estibule, 285 Omentum, development of, 343 Omphalocephaly, 120


INDEX


469


Omphalomesenteric arteries, 199,363; veins, 364-366

Ootid, 14

Opaque area, see area opaca

Optic cup, 165, 271 ; lobes, 251 ; nerve, 2S3, 284, 285; stalk, 149, 164, 284, 285; vesicles, accessory, 164

Optic vesicles, primary, 108, 164; secondary, 166

Ora serrata, 272

Oral cavity, 215, 216, 301

Oral glands, 306

Oral plate, 95, 173

Orientation of embryo on yolk, 25, 63

Ossification, 408-411; endochondral, 409; perichondral, 408

Ostium tubse abdominale, 23 ; development of, 402, 403; relation to pronephros, 402

Otocyst, 168; later development of, 289; method of closure, 168

Ovary, 22, 398-401; degeneration of right, 398

Oviducal membranes of ovum, 10

Oviduct, 22; later development of, 403

Ovocyte, 13, 26, 27

Ovogenesis, 12, 26

Ovogonia, 12, 26

Ovum, 2. 10; bilateral symmetry of, 15; follicular membrane of, 10; organization of, 14; polarity of, 14

Palate, 285, 299

Palatine glands, 306

Palingenetic aspects of development,

6 Pancreas, 181, 323-325, 347 Pander's nucleus, 19 Papilla; conjunctivie sclerse, 280 Parabronchi, 328 Parachordals, 428, 429 Paradidvmis, 391, 398 Paraphysis, 248 Parencephalon, 108, 153, 249 Parietal cavity, 92, 116, 207, 208,

333, 334 Paroophoron, 401 Pars copularis (of tongue), 305 Pars inferior iabyrinthi, 289,. 293 Pars superior lal)yrinthi, 2S9, 291 Parthenogenetic cleavage, 35 Patella, 441 Pecten, 281, 282 Pectoral girdle, 434-436 Pellucid area (see area pellucida) Pelvic girdle, 438-440 Periaxial cords, 158, 159, 161 Pericardiaco-peritoneal membrane,

338


Pericardial and pleuroperitoneal cavities, separation of, 333

Pericardium, closure of dorsal opening of, 337; formation of membranous, 338; see parietal cavity.

Periblast, 38, 43, 47; marginal and central 48; nuclei, origin of, 47, 48

Perichondrium, 408

Periderm, 304

Perilymph, 296, 297

Periosteum, 409

Peripheral nervous system, development of, 252

Pfliiger, cords of, 399

Phseochrome tissue, 404

Phalanges, 436, 438; of foot, 441; of wing, 438

Pharynx, derivatives of, 306; early development of, 93-95, 173; postbranchial portion of, 178

Phvlogenetic reduction of skeleton, 411

Physiological zero of development, 65

Physiology of development, 6

Pineal bodv, 153, 249

Placodes, 160, 161

Pleural and peritoneal cavities, separation of, 340

Pleural grooves, 208, 209

Pleuro-pericardial membrane, 338

Pleuroperitoneal membrane, 326; septum, 340, 341

Plica encephali ventralis, 149, 245

Plica mesogastrica, 341, 344, 368

Pneumato-enteric recesses, 209, 340

Pneumatogastric nerve, 268

Polar bodies, 13, 34

Polyspermy, 35, 36, 37

Pons, 252

Pontine flexure, 149, 245

Postanal gut, 182

Postbranchial bodies, 307, 309

Posterior intestinal portal, 132

Postotic neural crest, 160, 161

Precardial plate, 334, 338

Preformation, 6

Pre-oral gut, 174

Pre-oral visceral furrows, 174, 175

Preotic neural crest, 158

Primitive groove, 72

Primitive intestine, 55

Primitive knot, 73

Primitive mouth, 55, 82

Primitive ova, 26, 392, 399

Primitive pit, 73

Primitive plate, 73

Primitive streak, 69; interpretation of, 82; origin of, 74; relation to embryo, 85

Primordia, embryonic, 8


470


INDEX


Primordial cranium, development of,

428 Primordial follicle, 27 Proamnion, 86, 138 Procoracoid, 435 Proctoda^um, 170, 314, 319 Pronephros, 190-193 Pronucleus male and female, 34, 36 Prosencephalon, 108, 149 Proventriculus, 313 Pubis, 438, 439 Pulmo-enteric recesses (see pneu mato-) Pulmonary arteries, 359 Pupil of eye, 166, 272

Radius, 436

Ramus communicans, 254, 257, 259

Recapitulation theory, 3; diagram of, 5

Recessus hepatico-entericus, 343 ; recessus mesenterico-eutericus, 343; recessus opticus, 153; recessus pleuro-peritoneales, 340; recessus pulmo-hepatici, 340; recessus superior sacci omenti, 340

Rectum, 317

Renal corpuscles, 378, 383

Renal portal circulation, 369, 372, 375

Renal veins, 372

Reproduction, development of organs of, 390-403 ^

Respiratory tract, 178, 325

Rete testis, 398

Retina, 274, 275

Retinal zone of optic cup, 271

Rhombencephalon, 108, 155

Ribs, development of, 424, 425

s (abbreviation for somites), 67

Sacrum, 424

Sacculus, 293, 294

Saccus endolymphaticus, 169, 289, 290

Saccus infundibuli, 249

Scapula, 434, 435

Sclerotic coat of eye, 279

Sclerotomes, and vertebral segmentation, 412; components of, 412; occipital, 428; origin of, 185, 186

Seessell's pocket, 174

Segmental arteries, 122, 199, 362

Segmentation cavity, 43, 47, 53 (see also subgerminal cavity)

Semeniferous tubules, 398

Semicircular canals, 291

Semi-lunar valves, 352

Sensory areas of auditory labyrinth, origin of, 296


Septa of heart, completion of, 355,

356, 357 Septal gland of nose, 287 Septum aortico-pulmonale, 351, 352; of auricular canal, 355 ; bulboauricular, 353; cushion, 351, 355; interauricular, 351, 354; interventricular, 351, 353, 354; of sinus venosus, 358

Septum transversum, 208, 209, 334; derivatives of, 339; lateral closing folds of, 334, 337 ; median mass of, 335

Septum trunci et bulbi arteriosi, 351

Sero-amniotic connection, 138, 143, 217

Sexual cords, 393, 394; of ovary, 398; of testis, 395

Sexual differentiation, 394, 395

Sheath cells, 255

Shell, structure of, 17

Shell membrane, 18

Sickle (of Roller), 71

Sinu-auricular aperture, 357, 358

Sinu-auricular valves, 358

Sinus terminalis 86 (see also vena terminalis)

Sinus venosub, 197, 200, 201, 357; horns of, 358; relation to septum transversum, 339

Skeleton, general statement concerning origin, 407

Skull, chondrification of, 429-432; development of, 427; ossification of, 432, 433, 434

Somatopleure, 62, 115

Somite, first, position in embryo. 111

Somites, of the head, 114; mesoblastic, origin of, 110, 111; mesoblastic, metameric value of, 184; primary structure of, 114

Spermatid, 13

Spermatocyte, 13

Spermatogenesis, 12

Spermatogonia, 13

Spermatozoa, period of life Avithin oviduct, 35

Spermatozoon, 9

Spina iliaca, 440

Spinal accessory nerve, 269

Spinal cord, development of, 239

Spinal nerves, components of, 254; development of, 252, 255; bomatic components of, 254; splanchnic components of, 256

Splanchnocranium, 427

Splanchnopleure, 62, 115

Spleen, 345-347

Spongy layer of shell, 17

Stapes, 300


INDEX


471


Sternum, development of, 425-427

Stigma of follicle, 25

Stomach, 179, 313

Stomodaeum, 170, 173

Stroma of gonads, 393 ; of testis, 397

Subcardinal veins, 368, 369

Subclavian artery, 362

Subclavian veins, 363, 364

Subgerminal cavity, 53, 61, 69

Subintestinal vein, 367

Subnotochordal bar, 416, 418

Sulcus lingualis, 298

Sulcus tubo-tympanicus, 298

Supraorbital sinus of olfactory cavity, 285

Suprarenal capsules, 403-406

Sutura cerebralis anterior, 103-105; neurochordalis seu ventralis, 105; terminalis anterior, 105

Sympathetic nervous system, 256261; relation to suprarenals, 406

Sympathetic trunks, primary, 257; secondary, 258

Synencephalon, 108, 153, 249

Syrinx, 332

Tables of development, 68

Tail-fold, 131

Tarsuh, 441

Tectum lobi optici, 251

Teeth, 304

Tela choroidea, 152

Telencephalon and diencephalon,

origin of, 150 Telencephalon, later development of,

245-249; medium, 151, 245 Telolecithal, 11 Ten somite embryo, description of,

122 Testis, 395-398 Tetrads, 33

Thalami optici, 154, 251 Thymus, 308 Thyroid, 178, 307 Tongue, 305 Torus transversus, 248 Trabeculee, of skull, 428, 429; of

ventricles, 353 Trachea, 331, 332 Trigeminal ganglion complex, 160,

267 Trigeminus nerve, 267 ; nucleus (motor), 262, 263 Trochlearis nerve, 266; nucleus, 262,

263 Truncus arteriosus, 198 Tubal fissure, 298, 301 Tubal ridge, 401

Tuberculum impar (of tongue), 305 Tuberculum posterius, 249


Tubo-tympanic cavity, 297-300

Tubules of mesonephros, degeneration of, 380-382; formation of, 195-196; primary, secondary, tertiary, 379, 380

Turbinals, 285, 286, 431

Turning of embryo, 133

Tympanum, 297, 300

Ulna, 436

Umbilical arteries, 363; veins, 367,

368 Umbilicus, 144; of yolk-sac, 216 UnincuVjated blastoderm, structure

of, 69 Ureter, origin of, 384 Urinogenital ridge, 390, 391; system,

later development of, 378, etc. Uroda}um, 314, 319 Uterus, 22 Utriculus, 291, 292 Uvea, 273

Vagina, 22

Vagus, ganglion complex of, 161; nerve, 268; nucleus, 262, 263

Variability, embryonic, 64

Vas deferens, 401

Vasa efferentia, 398

Vascular system, anatomy of, on fourth day, 197-200; origin of, 117

Venous system, 127, 199, 204, 205, 228, 363-372

Velum transversum, 150, 248

Vena cava, anterior, 363, 364; inferior, 368-372

Vena porta sinistra, 367

Vena terminalis, 228; see also sinus terminalis

Ventral aorta, 121

Ventral longitudinal fissure of spinal cord, 243

Ventral mesentery, 131, 182, 343

Vertebrae, articulations of, 421; coalescence of, 424; costal processes of, 418; hypocentrum of, 418; intervertebral ligaments of, 421; ossification of, 421-424; pleurocentrum of, 418; stage of chondrification of, 418; suspensory ligaments of, 421 ;

Vertebral column, 411; condition on fourth day, 414; condition on fifth day, 415, 417; condition on seventh and eighth days, 418, 420; membranous stage of, 414 Vertebral segmentation, origin of,

412 ff Visceral arches, 175; clefts, 174, 307; furrows, 174; pouches, 174;


472


INDEX


/


pouches, early development of, 175178; pouches, fate of, 307, 308

Vitelline membrane, 10, 30, 31

Vitreous humor, 275


ongm


White matter of spinal cord,

of, 239, 241 Wing, origin of skeleton of, 434, 436 Wolffian body (see mesonephros) ; atrophy, 380, 382, 401; sexual and non-sexual portions, 396; at ninetv-six hours, 379; on the sixth^day, 382; on the eighth day, 382, 383 ; on the eleventh day, 385


Wolffian duct, 191, 193, 194, 391, 401

Yolk, 17, 19; formation of, 29 Yolk-sac, 143, 225-231; entoderm

of, 50; blood-vessels of, 227-230;

septa of, 225-227; ultimate fate

of, 230, 231 Yolk-spheres, 19, 20 Yolk-stalk, 132, 225

Zona radiata, 10, 30, 31 Zone of junction, 52, 57 Zones of the blastoderm, 127-129

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