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XXIV. Researches on the Structure, Physiology, and Development of Antedon (Coma- 
tula, Lamk.) rosaceus.—Part I. By WiuuiaM B. Carpenter, MD., PRS, 


Received June 15,—Read June 15, 1865. 


Page 

Nem intmodueionirerepreti stereo «/cls\2)s ic) oie elelere: sisi ef steel tele) lel-t siaiele «i ofe se ofeishe)altfoatelate 671 
ee AastoricallSmmmary \./) aie cic -feleleie acl ofethd) alele e\siale eles alee seis oieldasicisineisic 673 
TIT. External Characters, and Habits: Synonymy...............2++ ss ee ee eees 692 
IV. Structure of the Skeleton, with its Ligaments and Muscles ................ 702 
V. Development of the Skeleton... 1... 0... cc cece ener ee eter cette tenes 726 


I.—INTRODUCTION. 


Tuar the only secure basis of Zoological Science is afforded by a thorough elucidation 
of the structure and life-history of typical forms representing particular subdivisions of 
the Animal Kingdom, will not, I anticipate, be disputed by any Naturalist of the present 
day. And every one who is even slightly acquainted with the history of that Science 
must be well aware that the standard Monographs which have been devoted to this 
object have exerted a more permanent influence on its progress, than have any of those 
comprehensive Systems which have been set up from time to time, and, after lasting for 
a while, have been overthrown to make way for others scarcely more durable. For any 
System of Classification is liable to be invalidated by new discovery; and the utmost 
which can be claimed for it is, that it accurately represents the state of knowledge at 
the time of its promulgation. But every Monograph which contains a faithful descrip- 
tion of the structure and life-history of any type whatever, however far it may be from 
absolute completeness, presents a body of facts which subsequent research may add to 
but cannot set aside; and may come to acquire, even at a long subsequent period, a 
value not anticipated by its author. 

I cannot suppose, therefore, that any apology is needed for my offering to the Royal 
Society a detailed account of perhaps the most interesting of our British Echinoderms ; 
of which the structure, notwithstanding the attention given to it by various eminent 
Anatomists, has been hitherto but very imperfectly made out; whilst of its life-history 
still less is known. ‘That I have solved every problem which its study has presented, is 
far more than I can affirm; but I venture to think that what I now bring forward will 
stand the test of future scrutiny; and that the results I have attained will prove of im- 
portance, not merely in leading to a better understanding of the important group of 
which Antedon is a representative, but also in helping to the solution of certain funda- 
mental questions in General Physiology. 

MDCCCLXVI. 47% 


i agg ga. 


672 DR. W. B. CARPENTER ON THE STRUCTURE, PHYSIOLOGY, AND 


The peculiar interest of Antfedon as a “typical form” arises from its being the only 
representative now left in British seas of that wonderful Order CrixoipEa, which, under 
various modifications, has maintained its place in our Fauna from the Silurian epoch to 
the latest Tertiary period. It is true that in some important particulars, Antedon is a 
less characteristic representative of the Crinoidea than is the existing Pentacrinus 
of the West Indian seas; and a complete Monograph of the structure and life-history 
of that organism would be one of the most valuable contributions which Paleo-zoolo- 
gical science could receive. But for such a Monograph there is unfortunately no rea- 
sonable ground of hope. ‘The rarity with which specimens of this Pentacrinus have 
occurred, and the imperfection of the state in which they have been preserved, have 
hitherto prevented any save a very unsatisfactory account of its structure from being 
given; although the best of these specimens fell under the examination of an Anatomist 
and Physiologist no less able than Professor Jonann Mutter. And even supposing that 
a fortunate chance should throw a perfect and well-preserved specimen in the way of 
some equally accomplished Naturalist, he could do no more than give a minute descrip- 
tion of its organization ;—a knowledge of its life-history being likely to remain unattain- 
able, on account both of the rarity of the species and of the great depths at which alone 
it is found. 

Moreover, although in its adult state dntedon seems to depart widely from the typical 
Crinoids, in having neither root nor stem, and in possessing a power of free locomotion 
of which they are altogether destitute, yet this departure involves what is really (ina 
physiological point of view) the least essential part of the Crinoidal fabric ;—a part, 
moreover, which exists in that earlier stage of this animal’s life, wherein it is in this as 
in all other particulars a true Crinoid; and which is afterwards replaced, so far as its 
function is concerned, by a prehensile apparatus that is subservient to the very same 
purpose. For, as I shall show hereafter, the mature Antedon habitually clings by its 
dorsal cirrhi to a fixed attachment, so as to resemble its Pentacrinoid larva in its ordinary 
habit; using its power of free locomotion only when persistence in its position would 
be no longer conformable to its requirements. 

It has been, therefore, because every addition to our knowledge of Antedon contributes 
to the elucidation of the structure, physiology, and life-history of the CrinoipEA gene- 
rally, that I have thought it worth while for some years past to devote a considerable 
portion of such brief periods of leisure as I have been able to command, to the careful 
study of the species (4. rosaceus) which presents itself abundantly on various parts of 
our northern, western, and southern shores. When I commenced this study, I enter- 
tained the hope of being able to trace out the whole history of its development, from the 
very commencement of its existence asa free-swimming larva. But I soon found that 
the earlier stages of this process take place during a part of the year in which my official 
duties do not allow of my visiting the coast; and learning that Professor WyvILLE 
THomson was able and willing to undertake this part of the inquiry, I gladly arranged 
with him that he should work out the developmental history of Antedon as far as the 


DEVELOPMENT OF ANTEDON (COMATULA, LAMK.) ROSACEUS. 673 


early Crinoidal stage, from which I should myself be prepared to take it up; and thus 
his Memoir on the Embryology of Antedon rosaceus, which has already appeared in the 
Philosophical Transactions (1865), will serve as the complement of my own. 

Before proceeding, however, to detail the results of my researches, I think it right to 
give a somewhat particular account of what has been already done by those who have 
made a special study of Anfedon; and also to mark out the principal stages in the pro- 
gress of our general knowledge, both of the true character of the Crinoipra as consti- 
tuting one of the primary Ordinal subdivisions of the Class EcuinoprrMarta, and of the 
relationship of the typical Crinoids to Antedon. It will appear in this Historical Sum- 
mary (p. 682) why I have thought it right, in concurrence with the views of Dr. J. F. 
Gray', Professor WYvILLE THomson’, and the Rev. AurreD M. Norman’, to revert to 
the generic name Antedon given to this type by FREMINVILLE, in preference to using 
either the designation Comatula conferred upon it by i.AmARcK, under which it is much 
more generally known, or that of Alecto given to it by Leacu, which is used by the 
Scandinavian Naturalists. 


IL—HISTORICAL SUMMARY. 


The earliest account of Antedon which I have been able to find, occurs in the ‘ Phy- 
tobasanus’* of Fasrus CotumNA; an author who deserves to be commemorated for the 
excellence of his descriptions of various plants and animals, and for the fidelity and 
beauty of his delineations, which were engraved on copper and printed on the same 
page with the letter press. The figure he gives* of his dexadacvaxtwoed¢ is so charac- 
teristic as to enable me almost certainly to identify it with the species which forms the 
subject of the present memoir; indeed I do not think it has been since surpassed by any 
figure not drawn from the animal in its natural position during life. I quote the words 
in which this author commences his description, as indicating the remarkable abundance 
of the specimens that fell under his notice, and the strong impression made upon him by 
their beauty :—‘‘ Nova et perelegans est hujus Stelle forma, ab aliis omnibus differens 
nec adhuc descripta, nostro litori frequens, ita ut nec ulla retrahantur retia, quin ipsis 
implicata, et simul cum piscibus in foro etiam non inveniatur.” He gives a very accurate 
description of its jointed arms and of its dorsal cirrhi; but he fancied that the latter 
were used to grasp food and to draw it into the mouth, which he erroneously supposed 
to be at the central point from which they radiate. Of the soft visceral mass occupying 
the ventral cavity of the cup, and having the mouth in its centre, he says, ‘ex adversa 
parte corpus conspicitur rotundum, leve, molle, cujus interiora propter tenuitatem con- 

1 British Museum Catalogue of British Radiata, p. 28. 

> Op. cit. 

> « On the Genera and Species of British Echinodermata,” in Annals of Natural History, 3rd ser. vol. xy. 
p: 99 (Feb. 1865). 

* @vroBdcavos, sive Plantarum aliquot Historia. Meapoli, 1592. 


* See p. 12 of the Appendix to the Phytobasanus, entitled “ Piscium aliquot Plantarumque novarum Historia.” 
422 


674 DR. W. B. CARPENTER ON THE STRUCTURE, PHYSIOLOGY, AND 


siderare nequivi; ipsum vero et facillimé disjungitur a stella.” Its colour he originally 
speaks of as subrubens; but in a later treatise’ (Observationes, Cap. II. p. 5) he describes 
it as crocewm; and he further remarks,—‘ reperiuntur frequenter vario colore distincte 
veluti maculose ; partes quidem cirrorum lutescentes, aliz albicantes, alize rubentes, alice 
pullo colore,”—a variety which has continually fallen under my own observation. And 
he further notes the remarkable fact that if these animals are placed whilst yet alive in 
fresh water, they impart their colour to it in a very short time. 

The figure and description of Fasrus CotumNa were adopted, without the addition of 
any further particulars, by ALDROvVANDUS in his great work ‘De Animalibus Insectis’ 
(Bononie, 1602); and from this it seems to have passed into other systematic treatises 
of the 17th Century. 

At the end of that century, however, there occurs a very remarkable notice of this 
type, on the part of a naturalist who deserves more honour than he has gained; namely 
Epwarp Luuuyp*, who succeeded Dr. Pitot as Head Keeper of the Ashmolean 
Museum. 

In order rightly to appreciate its value, we must look back to the history of the ideas 
which had prevailed up to that time in regard to the fossil CrrnoipEa. 

The earliest author who systematically treated of Crinoidal remains was the celebrated 
AgricoLa’; although from the manner in which he speaks of them it is evident that 
they had long attracted the attention of Naturalists, and that the names T’rochites, Entro- 
chus, and Encrinus had found their way into general use,—the first being applied to the 
separated joints of cylindrical stems, the second to fragments of similar stems composed 
of several joints, and the third to the summits, especially to that of Encrinus liliiformis, 
the species most commonly known. Of the real relationship of the three kinds of bodies 
thus distinguished, he does not seem to have had any idea. AGRicoxa further gave the 
distinctive designation Pentacrinus to crinoidal summits which had lost their digitations, 
and which showed five principal radiations ; whilst he conferred that of Astroites or Asteria 
upon fragments of pentagonal stems, of which each separate joint presents some resem- 


1 Minus cognitarum rariorumque nostro ccelo orientium stirpium édpacs, ... item de Aquatilibus aliisque 
nonnullis Animalibus libellus. Rome, 1616. 

2 Linvyp was born in Carmarthenshire in the year 1670; was a student of Jesus College, Oxford; travelled 
for scientific purposes throughout England, Scotland, Ireland, and Brittany ; and died at the early age of thirty- 
nine. His merits were thoroughly appreciated by the late Professor E. Fornrs, who, in dedicating to him the 
genus Zuidia, thus eulogizes him :—‘ He was a man of great knowledge and great talent. His studies were 
extended over large tracts of science and literature, and he enlightened both with his researches and his writings. 
He united a comprehensive and philosophical mind with an observing eye, and the energy to execute. Amid 
the multiplicity of his studies there was no confusion. He wrote on insccts, plants, fossils, antiquities, and 
languages; on all much and well. His principal works were ‘Lithophylacii Britannici Ichnographia,’ and 
‘ Archeeologia Britannica.’ Ray praised him. Strange to say, his name is omitted in many of our cyclopzdias, 
which deyote whole pages to men of less repute.” (British Starfishes, p. 136.) 

3 See especially Book V. of the Supplement “ De Natura Fossilium” to his great work ‘De Re Metallica,’ 


first published about 1530, and many times subsequently reprinted. 


DEVELOPMENT OF ANTEDON (COMATULA, LAMK.) ROSACEUS. 675 


blance to a Starfish. The descriptions of AGRICOLA were repeated by ConraD GESNER', who 
gave a figure of a portion of the stem of Pentacrinus briareus under the name of Asteria, 
and of a portion of the stem of Encrinus liliiformis under that of Entrochus; like his 
predecessor, moreover, approximating the Crinoids to the “lapides judici” (fossil spines. 
of Echini) and to Belemnites. No advance seems to have been made in the knowledge 
of the Crivoipra until 1669, when Lacumunp? for the first time figured a complete 
specimen of Encrinus liliiformis under the name Pentagonos, and showed that the 
Entrochi and Trochites were really parts of the same organism. Better figures of the 
summits of some paleozoic CriNoipDEA were soon afterwards given by Martin Lister in 
his “ Description of certain stones figured like plants, and by some observing men 
esteemed to be plants petrified”*: but having unfortunately adopted the erroneous 
notion that the Crinoids were the fossil remains of Plants which had lived at a great 
depth in the sea, he was led to regard the body of the Crinoid as the base of the stem, 
and its arms as ramifications of the roots. Two years afterwards Lister published 
figures of some stems of Pentacrinus*, which also he regarded as representing marine 
plants. And not long subsequently he was followed by Braumonr’, who described and 
figured some additional types of paleeozoic Crinoidea under the name of “ rock-plants 
- growing in the lead mines of Mendip Hills.” 

It was under the influence of such misconceptions on the part of the best-informed 
Naturalists of the time,—as well as of the doctrine still prevalent among the less instructed, 
that fossils are nothing else than “curiously figured stones” deriving their peculiar 
shapes from some ‘“ plastic virtue latent in the earth,’—that the researches of Lunvyp 
upon the fossil Crinoipea were commenced ; and it is therefore very much to his credit 
that he should have made such an important step in advance, as not only to refer these 
remains to the same group with the Sea-stars, but also to fix upon that particular 
Sea-star which we now know under the name Antedon, as the type to which they are 
most nearly allied. As this fact has been entirely ignored by the recent historians of 
this department of Paleontology, MM. pe Koyinck and Le Hon® (to whose labours I 


? De Rerum Fossilium, lapidum et gemmarum maxime, figuris et similitudinibus liber. Tiguri, 1565. 


* Oryctographia Hildesheimeusis, pages 58, 59. * Philosophical Transactions, No. 100 (1678). 

4 «A letter containing his observations of the Astroites or Star-Stones,” in Philosophical Transactions, 
No. 112 (1675). 

° Philosophical Transactions, No. 129 (1682), and No. 150 (1683). 

® Recherches sur les Crinoides du Terrain Carbonifére de la Belgique. Bruvelles, 1854.—The following 
is all the mention made by these authors of the researches of Linuyp. “A la fin du XVII" siecle parut 
Vouyrage de Lwyp, qui, par les nombreuses figures qu’il contient et les changements que son auteur fit subir 4 
la nomenclature de son époque, semble avoir produit une assez vive impression dans le monde savant au mo- 
ment de sa publication. L’auteur y a employé divers noms pour désigner les différens fragmens de Crinoides 
qwil a figurés, ou qui ont fait partie de sa collection. C'est ainsi qu’il donne les noms génériques de Porpites, 
d’Entrochus, de Volvola, et d Asteria \ des fragmens de tiges de divers espéces de Crinoides; qu il désigne 
sous celui de Stellaria, de Volvola, de Modiolus, et d’Astropodiwm un certain nombre de sommets et de frag- 
ments de sommets de ces animaux. Ce dernier nom suflit pour faire comprendre que Lwyn, 4 l’exemple de 


Lister et de Bravxonz, a confondu ces sommets avec leurs racines” (p. 30). 


676 DR. W. B. CARPENTER ON THE STRUCTURE, PHYSIOLOGY, AND 


am indebted for several references to the authors named in this summary), I think it 
right to cite the evidence of it in some detail. . 

The ‘Lithophylacii Britannici Ichnographia’ of Epwarp Lunvyp' (1699) is a work 
which, the more it is examined, leaves a stronger and yet stronger impression of the 
industry and sagacity of its author. ‘To elucidate the nature of Fossils by the compa- 
rison of their forms with those of existing Animals and Plants,—familiar as the principle 
now seems to us,—had not been systematically attempted (so far as I am aware) by any 
previous Naturalist ; and no one who may bestow a little attention on the contents of 
the ‘Lithophylacium’ can fail to perceive that it is something much more valuable than 
a mere collector’s catalogue, and deals with questions far more important than those of 
nomenclature. Lunvyp’s sixth class, that of Crustacea punctulata, includes all the 
fossil remains which we should now refer to the Class EcurNopERMATA; and in the 
general observations at the head of this division he expressly says,—‘‘ unde ad hanc 
classem retulimus omnes lapides ejusmodi materia conflatos; sive ii ad Echinos spectent, 

. sive ad Stellas marinas, ut Astrorrhiza, Astropodium, Asteria, Entrochus, Volvola, 
Appendicula, &c.” (these being the names which he assigned to various Crinoidal 
fragments). Further, in the supplemental Episto/e contamed in the same volume, we 
find an express discussion on the relations of the Enevinus of Lacumunp, the Entrochus 
of AgericoLa, and the Asteria of Piot, to existing forms of Sea-stars, as well as of the 
separated parts just named to each other; and it is quite obvious that he was perfectly 
satisfied that these fossils were neither minerals nor plants, but stony ossicles of Sea-stars. 
He not only put forth this conviction with yet greater earnestness in a subsequent 
Memoir’, which seems to have escaped the notice of the historians just cited, but even 
distinguished Antedon as the particular Sea-star to which the CrINoiDEA are most nearly 
related. His statements on this point are so remarkable as to deserve being quoted in 


1 The dedication of this work to Marrry Lisrer is in the following terms, alike honourable to both parties : 
—“Erudito imprimis viro D. Marrro Lister, Doctori Medico scriptis et praxi claro, Societatis Regie Socio 
illustrissimo ; Musei Oxoniensis, post ipsum cujus nomen preefert nobilissimum Ashmolum, fautori primario ; 
Bibliothece ibidem physic et antiquaric fundatori munifico; fossilium Britannia insule indagatori primo et 
feelici; preceptori suo indulgentissimo et Meceenati «ternum colendo; hane qualemcunque Lithophylacii Bri- 
tannici Ichnographiam, officii et gratitudinis ergo, humillime offert ac dedicat Epvarpus Lvrpres.”—Of the 
esteem in which the labours of Luuvyp were held by his contemporaries, a very interesting record is contained 
in the following notification :— 

Hujus Libri centwn et viginti tantiim Exemplaria impressa sunt, impensis infrascriptorum 


Itiusrriss. Yrrorum, 


D. Baronis Sommers, summi Anglix Cancellarii. D. T. Robinson. 

D. Comitis de Dorset, &e. D. H. Sloan. 

D. C. Montague, Cancellarii Scacearii. D. Fi. Aston. 

D. Isaaci Newton. D. Geoffray, Parisiensis. 
D. M. Lister. 


2 ¢Prelectio de Stellis Marinis Oceani Britannici, nec non de Asteriarum, Entrochorum, et Encrinorum Origine,’ 
published at Oxford in 1703, and incorporated as an Appendix in the great work of Lrxcxivs, ‘De Stellis 
Marinis’ (1733), and also in an edition of the ‘ Lithophylacium’ published in 1760. 


DEVELOPMENT OF ANTEDON (COMATULA, LAMK.) ROSACEUS. 677 
his own words. After describing nine specimens of different kinds of recent Starfish, 
he proceeds (§ xvii.) as follows:—* Inter has decem, tum ob clegantiam, tum quod 
maxime rara sit, primas tenet, quae decimo loco exhibetur, decempeda Cornubiensium ; 
seu Stella rubra loricata, claviculato modiolo; quinis radiis constans, pennatis ab exortu 
bifidis. In Cornubia juxta Pensans cum antecedente reperimus, sed longinquo maris 
refluxu. A Stella decem radiorum CoLuMN«&, si diversa sit, parvitate preesertim dis- 
tinguenda est. CoLUMNA enim sure Stelle pedalem tribuit longitudinem, cum nostra 
sex aut septem uncias non exsuperet.” With this Decempeda Cornubiensium, the Stella 
Acxacvnnog rosacea of Linck, our own Antedon rosaceus, Lunvuyp afterwards (§ xxx.) 
compares a fossil ‘‘e fodinis Glocestrensibus,” and specifies the following as the points 
of similarity :— Videmus enim (1), modiolum esse utrique ; (2) modiolo appendentes 
claviculas aut capreolos; (3) quinos radios, a primo exortu bifidos; (4) articulorum 
cujuslibet radii commissuram loricatam; (5) denique, radiis ab inferiori parte articu- 
latim adnascentes aristas. Hisce visis, Stellan decempedam lapideam, aut fossilem, 
hune lapidem pronunciare, nemo, opinor, dubitabit. () xxxt.) Fatemur nihilominus, 
quoad modiolorum figuram, multum interesse discriminis, cim lapidea Stella quasi 
ansellam habeat stellatam, ubi altera scutulum; et hanc majoris esse molis marina. 
Verum he note aliam tantum speciem inferunt, genus non tollunt. Concesso itaque, 
hunc lapidem decempedam esse; comperimus tandem Asteriam nonnullam nihil aliud 
fore, quam decempedz modiolum ; quod ex hoc ipso specimine manifestum est. Dixi 
nonnullam, quoniam varie dantur Asteria, earumque aliquot Stellarum, quas coriaceas 
diximus, vertebras exprimere alias docuimus, et ex No. 19, ubi Asteriv parvee cum 
Asterisci ossiculis denudatis conferuntur, propemodum constare arbitror.” In the same 
method of careful and intelligent comparison he proceeds in subsequent sections to show 
that the Encrinus of Lacumunnws is similarly related to his Decempeda; and although 
he seems to have been far from comprehending the true character of the stems of the 
Crinoidea (no recent pedunculate type of the group having been known to him), yet I 
think that no one who peruses the passages I have quoted can refuse him the credit of 
having—not as a mere guess, but on the sound basis of anatomical correspondence— 
distinctly predicated the ‘ntimate relationship between our recent Anfedon and the fossil 
Crinoipra; a relationship that was subsequently overlooked by Zoologists of the highest 
eminence, and has only within a comparatively recent period come to be generally 
admitted. 

The credit of having explicitly pointed out that the Crrvoipna, far from belonging to 
the Vegetable kingdom, are true Animals, closely approximating in structure to the 
existing types known as “ Sea-stars,” is assigned by MM. Koniycx and Le Hon, as also 
by MM. BianviLLe and Dusarpin, to Rosinvs'. Not only, however, was his treatise on 
the subject posterior by sixteen years to that of Lunuyp, but his conclusion was much 
less exact; his approximation of the Crinoidea having been not to the genus 

1 «Tentaminis de lithozois ac lithophytis olim marinis, jam vero subterrancis, prodromus, sive de stellis 


marinis quondam, nune fossilibus disquisitio.” Mamburgh, 1719. 


678 DR. W. B. CARPENTER ON THE STRUCTURE, PHYSIOLOGY, AND 


Antedon but to the genus Euryale. Hence it is obvious that in regard alike to Lunuyn’s 
priority in time, and to the greater accuracy of his conclusion, we are justified in 
claiming for our own countryman the merit of having been the first to take up this 
important position. 

Returning now to the history of Antedon, we find it characteristically described as a 
peculiar type of “Sea-stars” in the remarkable work of Linckius'; who seems to have 
been the first to attempt to bring together the large number of forms of this group 
acquired by the industry of collectors, and to endeayour to systematize them. Although 
his principles of classification were far from sound, and conducted him to an arrangement 
which was in many respects erroneous, yet they led him to erect Antedon (of which six 
species regarded by him as distinct are described under three generic names) into a group 
distinct not only from the Asteriade, but also from the Ophiuride, with which they have 
been associated by many later systematists. To this group (termed by him a Class, but 
rather in reality a Family) he assigned the name Crinite sive Comate Stelle, on account 
of the hairy appearance given to the arms by the “ capillary fibres” with which they are 
fringed ; thus distinctly foreshadowing the name Comatula conterred upon this generic 
type by Lamarck. The first of his genera he named Aexéxvnuoc, to dicate its possession 
of ten radiating caude crinite ; and he ranges under it three species, (1) the Crocea 
Zaffarana Neapolitanorum, or sexa8asvaxrwoedye of Fapius Conumna, (2) the Rosacea 
or Decempeda Cornubiensium of Lunvyp, and (3) the Barbata or jimbriata of BARRELIER. 
Of the first he quotes CoLumya’s description without copying his figure ; of the second 
he gives a figure, which though imperfect, is sufficient for its identification, and speaks 
of it as distinguishable from the preceding only by its inferiority of size, Conumna’s Sea- 
star being often a foot in diameter, whilst the diameter of Lunuyp’s does not surpass 
6 or 7 inches; of the third also he gives a figure, which shows it to be only another 
variety of the preceding, at the same time quoting the description given by BARRELIER*, 
who partook of the misapprehension of CoLumNa respecting the use of the dorsal cirrhi, 


1 Jomannts Henrrer Lixcxm Lipsiensis ‘ De Stellis Marinis liber singularis. Tabularum /Enearum Figuras 
exemplis nativis apprime similes et Autoris Observationes disposuit et illustravit Crristranvs Gaprren Fiscuer 
Regiomontanus.’ Lipsiw, 1733.—This work deserves special notice on many accounts. Its author, a Phar- 
macopolist at Leipzig, was a Foreign Member of the Royal Society, to the President and Fellows of which it is 
dedicated. The large number of types which are described and admirably figured testify to the industry and 
zeal of its author as a Collector, who seems to have spared neither pains nor expense in procuring specimens 
from every quarter of the world; and it is peculiarly interesting to find that a main purpose of the formation 
of this collection was to throw light on the exact nature of those Fossil remains, whose general resemblance to 
the Sea-stars was clearly enough recognizable, but whose precise affinities could not be predicated with certainty 
from anything then known. “In terris per omnem naturalis historia memoriam nihil repertum simile; in 
mari analogiam pre se ferebant viventia aliqua, sub latiore stellarum marinarum genere, ramorum insectorum 
charactere differentia. Sed nulla hujus generis reperiebatur species, cui quantitas et articulorum configuratio 
congruebant. Qurende stelle nove erant, ut instituta cum petrefactis ruderibus collatione, et genus et primeya 
forma elucerent.” (Preface.)—The binomial nomenclature, moreover, is employed more systematically by 
Lruvcxivs, than by any other pre-Linnean author with whom I am acquainted. 

> Barretrenr, Jacozt, ‘ Plante per Galliam, Hispaniam, et Italiam observate.’ Paris, 1714. 


DEVELOPMENT OF ANTEDON (COMATULA, LAMK.) ROSACEUS. 679 


these being likened in function to the proboscis of the Elephant or the upper lip of the 
Horse. His second genus, named Tproxaexaxvnpoc, is based on a specimen described by 
Periver’ as haying thirteen arms; this specimen, however, he suspects to have been 
imperfect. To his third genus he gave the designation Caput Meduse, which had been 
previously applied to the type since known as Hwryale; apparently thinking that it 
might be much more appropriately conferred on Sea-stars having very numerous (sixty 
or more) straight capillated arms, than on those with ramifying and twining but naked 
arms, to which he gave the name Astrophyton. Of the Caput Meduse he described and 
figured two species, brunneum and cinereum, both from the Museum of Seba; these do 
not seem to differ, however, in anything but size and colour. 

It is not a little remarkable that notwithstanding the correct approximation of the 
CrinoipEaA by Linvuyp to the nearest type of the Echinoderm group then known, and 
the prominence given to his views by their incorporation in the important systematic 
treatise of Liycxius, they should have been almost entirely without influence on the 
opinions of the most eminent Naturalists of the 18th Century. For, to pass by the 
notion of one that the stems of Encrinites are parts of the vertebral column of certain 
Fishes, and the idea of another that they are the products of the siphon of Orthoceratites, 
we find ELuis* (in 1753) suggesting that his Umdellularia Encrinus (the Pennatula Encrinus 
of Patias®) is the analogue of the Encrinus liliiformis, a figure of which he places by 
the side of that of his “‘ cluster-polype ” for the sake of comparison. He seems, however, 
to have had his doubts of the reality of this resemblance rather strengthened than 
removed by further inquiry; for in his ‘Essay on Corallines’ published two years 
afterwards, we find him, whilst repeating his previous figures, thus expressing himself :— 
“ At K is a figure of the Encrinos or Lilium Lapideum; which, whether it may not be 
the petrified Exwvie of this Animal, is submitted to the consideration of the curious in 
Fossils; for they have not yet been able. I apprehend, to fix upon anything more pro- 
bable. ‘The difference that appears to me, upon consulting Rosinus, a German author, 
who has published a treatise at Hamburgh particularly on this curious fossil, is that 
the Encrinos has rather been a species of Starfish, with a jointed stem or tail; and the 
rays of the star, instead of having Tentacula, or claws, at the end of each, like our 
Polype, are furnished with ranges of jointed fibres, along the inside of each ray like a 
brush ; of which the same author has given a curious plate, with a particular description 
of this extraordinary fossil.” (Op. cit. p. 99.) The notion of the relationship of Enerinus 
to Umbellularia and its Zoophytic allies, thus suggested by ELLis, was explicitly adopted 
by Mytius* in a treatise which he published at the same period on the same subject; 


‘ PeriverI, Jacosr, ‘Gazophylacium Nature et Artis;’ Zondini, 1711:—also ‘Aquatilium Animalium 
Amboinensium, Icones et nomina;’ Zondini, 1713. 

? Philosophical Transactions, vol. xlyiii. part 1, p. 305. 

* Elenchus Zoophytorum. Hage Comitum: p. 365. 

* Beschreibung einer neuen Gronlandischen Thierpflanze, pp. 16,17. Hannover, 1753, and London, 1754. 


¥ 


MDCCCLXYVI. oA 


680 DR. W. B. CARPENTER ON THE STRUCTURE, PHYSIOLOGY, AND 


and it seems to have been generally accepted, notwithstanding Exis’s own hesitation, 
since we shall find it to have been the source of the extraordinary misconception in 
regard to the nature of the Crrxoipra adopted by one of the most eminent Zoologists of 
the commencement of the 19th Century, especially distinguished by his knowledge of 
Invertebrate Animals. 

The discovery of a recent specimen of a pedunculated Crinoid, which was announced 
by Gurrrarp! in 1755, did not (as might have been expected) supply the correction of 
this error; for although he noticed the strong resemblance between this so-called 
Palmier marin and some of the Starfishes described by Linck, yet being unable to 
discover a central mouth, he seems to have concluded that this resemblance was falla- 
cious, and to have believed that nourishment was imbibed by the animal through the 
numerous minute pores which he affirmed to exist at the extremities of the tentacles 
and pinnules,—thus likening it to the Zoophytic type, although he refrained from 
ranking it definitely with that group. In his comparison of it with the fossil CrivoiDEA 
he made an extraordinary blunder, which was the reverse of that of Lister ; for whilst 
the latter mistook their summits for radiating and subdividing roots, GuETTARD imagined 
that the more or less regularly ramifying roots of Apiocrini were in reality their summits. 
Another specimen of the recent Pentacrinus very shortly afterwards (1761) came under 
the notice of Enis’, whose description of it is entitled ‘‘ An account of an Encrinus or 
Starfish, with a jointed stem, taken on the coast of Barbadoes, which explains to what 
kind of animal these fossils belong, called Starstones, Asteria, and Astropodea, which 
have been found in many parts of this kingdom.” The specimen examined by him was 
so imperfect that he did not recognize the place of the mouth; nor did he in any way 
more distinctly indicate than in the title just quoted the relationship of this organism 
to the Starfishes. Not having the base of the stem, he felt himself unable to affirm 
whether it moved freely through the sea, or was attached to the bottom like Corals and 
Sponges; and it is only by inference that it can be concluded that he was led by the 
study of this specimen to abandon his previous notion of the relationship of the Cri- 
NoipEA to “ cluster polypes.” 

It was unfortunate for science that Loyy.xus, instead of adopting the more advanced 
views of some of his predecessors as to the true relations of the Crinoipza, was so misled 
by the jointed structure of their stems as to rank them among Zoophytes in the genus 
Tsis; whilst he threw back Antedon among the other Starfish, ranking them all together 
in his genus Asterias*. And this arrangement was left unaltered in the twelfth edition 
of his ‘Systema Nature’ published in 1766, notwithstanding the appearance of the 

1 Mémoires de I’Académie des Sciences de Paris, 1755, p. 260. 

2 Philosophical Transactions, vol. lii. part 1, p. 357. 
3 In the tenth edition of the ‘Systema Nature,’ Holmiw, 1758, which is the first in which species are 
characterized, we find Comatula named Asterias radiata, and thus strangely described: —* radius duplicatis, 


superioribus pinnatis, inferioribus filiformibus.” It was long before the difference between the true rays and 
the filiform cirrhi came to be understood. 


‘DEVELOPMENT OF ANTEDON (COMATULA, LAMK.) ROSACEUS. 681 


memoirs of Guerrarp and Exits on the recent Pentacrinus; nor was it corrected in the 
edition of the same work subsequently published (1788-1793) by Guetiy.—By Buv- 
MENBACH', however, the CrivoipEA were correctly placed, in proximity with the recent 
Pentacrinus of Gurrrarp, in his division Vermes Crustacea, with which in his later 
editions he associates the name EcHINODERMATA* as a synonym; but he does not in any 
way recognize Antedon as a distinct type having a special relation to the Crinoids. 

Our Antedon rosaceus was described and figured by PENNANT in his ‘British Zoology’, 
under the Linnean names Asterias bifida and Asterias decacnemos ; and though no new 
light was thrown by him either on the peculiarities of its structure or on its affinities, 
yet it is deserving of notice that he specially alludes to the ventral as well as the dorsal 
surface being furnished with short simple rays, which are well represented in his figure. 
These “ventral rays,” as Lamarck afterwards pointed out, are in reality the basal pinnules 
of the arms, which are much longer than the rest, and (as I shall show hereafter) 
differ from them very remarkably in structure; but the manner in which they arch oyer 
the ventral surface of the central disk is such as to suggest to a superficial observer an 
analogy to the “short simple rays” or rather “cirrhi” of the dorsal surface.—The 
Antedon rosaceus was again described under the name of Asterias pectinata by ApAMs*, 
another British zoologist of the latter part of the last century; and his notice of it, 
though very slight, has this remarkable merit,—that it mentions the existence of two 
orifices to the digestive cavity. “'The body,” he says, “is covered on the upper side by 
five vnequal valves.” [By this expression he seems to indicate the division of the ventral 
surface of the disk into five sectors by the radial furrows converging from the bases of 
the arms.] ‘It is remarkable of this species that it is furnished with ¢wo apertures, 
one at the confluence of the valves, the other in the largest valve ; their position with 
respect to the centre is variable; the last may readily escape observation, except when 
the animal chooses to elevate it above the plane of the valve.” This observation seems 
to have been completely overlooked by those who subsequently described Antedon ; its 
possession of distinct oral and anal orifices having been announced as a new discovery 
by MeckKeEt in 1823. 

The Class EcHinopeRMATA was adopted by Cuvier in his first systematic arrangement 
of the Animal Kingdom’; but this neither contains any recognition of the peculiarities 
of Antedon, nor makes any mention whatever of the CrinoipEa. Of the ignorance which 
still prevailed in regard to the real nature of the last-named group, we have a remarkable 

* Handbuch der Naturgeschichte. Gttingen, 1780. 

* The term Ecutyopermara seems first to have been introduced by Kier in his ‘ Naturalis Dispositio Echino- 
dermatum’ published at Dantzig in 1734; but it was limited by him to the Zchini and their allies, now con- 
stituting the family Hchinida. Not having been able to obtain a sight of the original edition of the ‘ Handbuch 
der Naturgeschichte’ of Bromwensacu, I am unable to ascertain whether the term was applied by him to include 
the Asteriada and Holothurida before it was so applied by Brucikre in the ‘ Encyclopédie Méthodique ’ in 1792. 

8 Edition of 1776-77, vol. iv. pp. 65, 66, tab, xxxiii, fig. 71. 

« Linnean Transactions, vol. y. p. 10. 


5 Tableau Elémentaire de ’'Histoire Naturelle des Animaux, _ Paris, 1797. 
5A2 


682 DR. W. B. CARPENTER ON THE STRUCTURE, PHYSIOLOGY, AND 


illustration in the fact that Lamarck, in the first edition of his ‘Systeme des Animaux 
sans Vertcbres’ (1801), ranged them, as Linnzvus had done, among his ‘* Polypes a 
rayons coralligénes,” by the side of Gorgonia, Umbellularia, and Pennatula; apparently 
under the influence of the original suggestion of Exiis, and of the erroneous surmise of 
GvETTARD, who, however, nowhere goes so far as to affirm that the branching arms of 
his “ Palmier marin” actually bear Polypes. It is not a little surprising that, with the 
very specimen of the recent Pentacrinus Caput-Meduse described by Guerrarp under 
his eyes in the Museum at the Jardin des Plantes, Lamarck should have failed to recog- 
nize its close relationship to Antedon, a type which, as we shall presently see, specially 
attracted his attention. 

The first among post-Linnean zoologists who recognized the claim of this form of 
Sea-star to a distinct generic rank, on account of that difference from all others in its 
plan of structure which had been recognized by Lunuyp and Linck, seems to have been 
M. Friminvinte!, who in 1811 thus clearly defined the genus, to which he gave the 
designation Antedon :—“ Animal libre, 4 corps discoide, calcaire en dessus, gélatineux 
en dessous, environné de deux rangées de rayons articulés, pierreux, percés dans leur 
largeur d’un trou central; ceux du rang supérieur plus courts, simples, et d’égale 
grosseur dans toute leur longueur; ceux du rang inférieur plus longs, allant en dimi- 
nuant de la base & la pointe, et garnis dans toute leur longueur d’appendices alternes 
également articulés; bouche inférieure et centrale ;”—referring for his illustration to 
the figure in the ‘ Encyclopédie Méthodique’ (pl. exxiy. fig. 6), which obviously repre- 
sents the Stella decacnemos rosacea of Lixcx. Shortly afterwards (1814), and apparently 
in ignorance of FREMINVILLE’S definition, Dr. Leacn characterized this type under the 
generic name Alecto®. Both these designations, therefore, have a preferential claim to 
that of Comatula, which was not applied to the genus by Lamarck until the publication 
of the second edition of his ‘ Animaux sans Vertébres’ in 1816. This claim was recog- 
nized in regard to Alecto by Cuvier, who gave this name the preference to Comatula ; 
and also at one time by Professor Jou. MtLuer, who substituted Alecto for Comatula in 
many of his communications to the Berlin Academy; though he afterwards abandoned 
it in favour of Comatula (in ignorance, as it would seem, of the characterization of the 
genus by FREiMINVILLE), the name Alecto having been in the mean time assigned to a 
genus of Potyzoa established by Lamovroux, and having come to be generally received 
as its designation. Professor MULLeEr’s adoption of the name Alecto seems to have led 
to its employment by Scandinavian Naturalists, who have continued to use it, notwith- 
standing its abandonment by Professor Jou. MULter. It is clear, however, that if we 
are to put aside LAMARCK’s name on the ground of priority, we must go back, not to 
Alecto, but to Antedon ; and as FREMINViLLE’s definition of the genus is at least as correct 
as that of Lamarck, it would be contrary to the rules of Zoological Nomenclature, as 
now understood and acted ‘on, to pass it by. Notwithstanding the appropriateness of 

1 Nouveau Bulletin des Sciences, Socicté Philomathique, tom. ii. p. 349. 
? Zoological Miscellanics, vol. ii. p. 62. 


DEVELOPMENT OF ANTEDON (COMATULA, LAMK.) ROSACEUS. 6835 


LAMARCK’s name, therefore, and the general acceptance it has met with, I feel constrained 
to follow the example of Dr. J. E. Gray, Mr. Norman, and Professor Wyvitte Tuomson, 
in reverting to the previous designation given by FREMINVILLE. 

Although Lamarck clearly differentiated Comatula as a generic type from Asterias, 
Ophiura, and Euryale, he was very far from apprehending its most essential peculiarities ; 
and his description of it is strangely incorrect as regards one of its most prominent 
features, since he not only overlooked the true mouth, but described the anal funnel as 
the mouth, and placed it in the centre of the disk, which is contrary to the fact. “Au 
centre du disque inférieur ou ventral des Comatules, la bouche, membraneuse, tubuleuse 
ou en forme de sac, fait une saillie plus ou moins considérable suivant les espéces. Ce 
caractere singulier, qu’on ne rencontre jamais dans les Euryales ni dans les Ophiures, 
semble rapprocher les Comatules de certaines Médusaires.” (Op. cit. tom. ii. p. 532. 
This mistake is the more remarkable, as he expresses surprise at not finding the mouth 
(where it actually is) at the point of convergence of the furrows which pass from the rays 
along the ventral surface of the disk :—‘ Ce sillon, néanmoins, ne s'‘approche point de la 
bouche, et ne vient point s’y réunir, comme cela a lieu pour la gouttiére des rayons dans 
les Astéries.” He states, on the authority of Peron, that the Comatule habitually cling 
to Fuci or Zoophytes by their dorsal cirrhi, and spread out their rays in search of 
prey; and he goes on to affirm that they lay hold of this with their “grands rayons 
pinnés,” and bring it to the mouth with their ‘‘rayons simples inférieurs.’ What he 
means by the last-named organs, I do not feel able to determine with certainty, since 
the ‘“‘rayons simples” of his generic definition are “ dorsaux” not “ inférieurs ;” and I 
am inclined to suppose that he attributes this function to the pinnules springing from 
the basal joints of the arms, which, as he correctly remarks, are “ allongées et abaissces 
sous le yentre.” I feel confident, from observation of the habits of the living animal, 
that these pinnules are no more employed in the prehension of food than are the prin- 
cipal arms; and I am inclined (as will hereafter appear, § 15) to regard that peculiarity of 
their character and disposition, which Lamarck was the first to notice, as connected with 
the sensorial protection of the oral orifice. 

In this edition we still find Lamarck ranking the CrixoipEa among Polypes; though 
he separates them, together with Pennatula, Umbellularia, &c., into a distinct group, 
that of Polypi natantes. He speaks without hesitation of their ramified arms as bearing 
polypes arranged in rows (!), and remarks that they are especially distinguished from 
Pennatule and other genera of the order of floating Polypes by the articulated structure 
of the stem and branches. ‘Les Encrines,” he says (op. cit. p. 484), “se rapprochent 
de l Ombellulaire par leur ombelle terminale et polypifére ; mais leur tige et leur rameaux 
articulés, enfin la disposition des Polypes qui forment des rangées sur les rameaux de 
Yombelle, les en distinguent fortement.” It is singular that so eminent a Naturalist 
could haye committed himself to a misstatement of fact so extraordinary as that just cited. 

The publication of Lamarck’s work was very soon followed by that of the first edition 
(1817) of the ‘Régne Animal’ of Cuyrer, in which the Crrvoipea are included (after 


684 DR. W. B. CARPENTER ON THE STRUCTURE, PHYSIOLOGY, AND 


the example of BLUMENBACH) in the class EcninopERMATA; being placed at the end of 
the family Asteriada, in immediate sequence to Gorgonocephala (Euryale) and Alecto 
(Antedon). And this position they have retained in all subsequent systems of classifica- 
tion ; the only difference of opinion having been as to the intimacy of the relationship 
between the Crinoidea and other stellate forms of Echinodermata. 

The year 1821 constitutes an important epoch in this history; being that of the pub- 
lication by J. $. Miter, a German naturalist residing at Bristol, of the ‘ Natural History 
of the Crinoidea’ ; 


a work which laid the foundation of the scientific study which the 
group has since received on the part of various distinguished zoologists. Bringing together 
all the forms already known, and adding to these a large number first examined by himself, 
the author sought, in a careful comparison of their structural characters, a valid basis 
for their systematic arrangement; and the principles he developed have been followed 
(with some modifications in detail) by all who have since applied themselves to the 
same line of study, whilst the genera he created have been universally accepted as well- 
marked natural groups. The most faulty part of his system was the nomenclature he 
conferred on the seyeral pieces of which the cup and arms are composed ; this being 
drawn from the osseous skeleton of Vertebrata, to which the framework of the Crinoidea 
has no kind of analogy. At the conclusion of his description of the CrivoipEA, MILLER 
enters upon the consideration of their precise relationship to the several types included 
by Lamarck in his family Sted/erida; and after a careful comparison of their characters 
with those of the genera Asterias, Ophiura, and Euryale, he comes to the conclusion 
that with neither of these have the Crinoipna any close affinity. He then proceeds to 
the like comparison with Comatula, the results of which, he says (p. 127), “were even 
more favourable than the first appearances had given me reason to hope, presenting, 
indeed, a conformity of structure almost perfect in every essential part (except the 
column which is wanting, or at least reduced to a single plate), and exhibiting an 
animal which would be defined with sufficient precision as a Pentacrinus destitute of 
the column.” ‘The species of Comatula investigated by MILLER, though designated by 
him C. jimbriata, is closely allied to, if not identical with, the rosacea of Linck; the 
specimens of it which he examined were from Milford Haven. His description is gene- 
rally accurate as far as it goes, but it includes little else than the skeleton. He makes 
no mention of the true oral orifice, except to state that he could not detect in his dried 
specimens the pentagonal mouth figured by PENNANT; and it is obvious that, like 
Lamarck, he was misled by the prominence of the anal funnel into supposing it to be 
the mouth. To Minter, then, is distinctly due the credit of having first maintained, 
since LLHUYD, upon the basis of an exact comparative appreciation of the characters 
furnished by the skeleton, that among all the recent STELLERIDA, the only type which 
bears any close correspondence to the CriyoipEa is Antedon (Comatula); and that its 
relationship to the Crinoids is so intimate as to require its being included with them in 
the same family. He did not, however, propose to remove this family from the Order 
Stellerida, being ignorant of those peculiarities in its digestive and reproductive appa- 


DEVELOPMENT OF ANTEDON (COMATULA, LAMK.) ROSACEUS. 685 


ratus which are now generally admitted to entitle the Crivoipea to rank as a group of 
ordinal value. 

The first approach to a knowledge of these peculiarities was made by Mrckeu', who 
pointed out that the alimentary canal is provided with two orifices: the mouth, which 
is nearly central, but inconspicuons ; and the anus, which is prominent but eccentric. 
In ignorance, apparently, of what had been previously advanced by Mucxen, Dr. J. E. 
Gray’ in 1826 drew attention to the existence of a double orifice to the alimentary 
canal, and to the importance of this character in classification. And in the same year 
amore complete elucidation of this part of the structure of Comatula was effected by 
HEvsINGER®. 

In 1827 the remarkable discovery was announced by Mr. J. V. Tuompson‘ (by whom 
it had been made four years previously) of a true pedunculate Crinoid, to which he 
gaye the name Pentacrinus Europeus, living in the Cove of Cork. His examination of 
its structure enabled him to affirm its intimate resemblance, on the one hand to Coma- 
tula, and on the other to the ordinary Crinoids; and it is interesting to observe that he 
had been led, by noticing its possession of a double orifice to its alimentary canal, to 
the recognition of the like conformation in Comatula—a discovery which was thus made 
independently and nearly contemporaneously by Professor Mrckrn, Dr. J. E. Gray, and 
Mr. J. V. Tuompson. He does not limit himself to the description of that which he 
considers the perfect form of this organism; but gives an account, which though slight 
is very characteristic, of the principal phases of its development, commencing with that 
in which “the animal resembles a little club, fixed by an expanded basis, and giving 
exit at its apex to a few pellucid tentacula, no other part of the solid fabric being 
obseryable but an indistinct appearance of the perisome;” and he sagaciously adds, 
“From these observations connected with the growth of this animal, and by which it 
appears to present itself at various stages of its progress under considerable diversity of 
form, naturalists may learn to avoid the unnecessary multiplication of the genera and 
species of the Crinoidea by giving undue weight and consideration to characters ori- 
ginating in the progressive evolution of individual species, and which are consequently 
of a transitory and delusive nature.” 

One of the most important contributions hitherto made to our knowledge of the ana- 
tomical structure of Antedon, was the memoir of Hrvsinaer, ‘ Anatomische Untersuchung 
der Comatula mediterranea, published in 1829°. This is, for the most part, extremely 
exact in its details, so far as these extend; being chiefly deficient in regard to points 

” « Ueber die Oeffnungen des Speisekanals bei den Comatulen,” in Mxcxet’s ‘ Archiy fiir Physiol.,’ Bd. VII. 
(1823) p. 470. 

2 « Notice on the digestive organs of the genus Comatwa, and on the Crinoidea of Mrrer,” in ‘Annals of 
Philosophy,’ N. 8., vol. xii, (1826) p. 392. 

* « Bemerkungen tiber den Verdauungskanal der Comatulen,” in Mucxet’s ¢ Archiy fiir Physiol.’ (1826), p. 317. 

* Memoir on the Pentacrinus Europeus: a recent species discovered in the Coye of Cork, July 1, 1823. 
With two plates. By Jouy V. Tuomrson, F.L.S. Cork, 1827. 

* Hevsrncer’s ‘ Zeitschrift fiir organ. Physiol.’, Bd. III. p. 366. 


686 DR. W. B. CARPENTER ON THE STRUCTURE, PHYSIOLOGY, AND 


which the use of the microscope alone can determine: and among the excellent figures 
by which it is illustrated, are admirable sectional views of the structure of the visceral 
disk, which much surpass those subsequently given by Professor Jou. Miter. I shall 
have frequent occasion to refer to HevusinGrr’s memoir, when I come to describe the 
digestive apparatus of Antedon. 

In 1834 M. pe Buarnvinte published his ‘Manuel d’Actinologie,’ in which the rela- 
tions of the Crinoipra to the other members of the Order SreLLERIDA are carefully 
examined and set forth. He divides that Order into three Families, Asteridea, Astero- 
phydea, and Asterencrinidea; and of the latter he says (p. 248), “C'est a lintéressante 
découverte faite par M. Tuompson d’une trés-petite espéce d’Encrine vivante, sur les cétes 
dIrlande, et 4 son Mémoire a ce sujet, que nous devons la possibilité d’établir et de 
caractériser cette famille d'une maniere convenable, en nous appuyant aussi sur le travail 
ex professo de M. Miuuer sur les Encrinites fossiles.”. Further on he says of Mr. 
THompson’s discovery (p. 256), that he ‘‘a détruit toute espéce de doute sur la place des 
Encrines vivantes ou fossiles, et a démontré clairement la justesse de la manicre de voir 
de Rosrnus, adoptée par GurTTarD, ELLs, Parkinson, et M. Cuvier, contre celle de 
Linnf, suivie par M. pe Lamarck. Une Encrine mest pour ainsi dire quune Comatule 
renyersée, en supposant méme que cette position ne soit pas également naturelle a 
celle-ci, ce que je suis fortement porté a penser, et qui, au lieu de se cramponner a laide 
des rayons accessoires, est fixée par le prolongement de la partie centro-dorsale.” He 
divides his family Asterencrinidea into two groups, the free and the fixed; the only 
representative of the first being Comatula, whilst in the second he includes all MILuer’s 
genera of Crinoids, with the addition of the genus Phytocrinus, which he created for the 
reception of Mr. J. V. Tuompson’s Pentacrinus Europwus, regarding it (and with reason) 
as not properly referable to the genus Pentacrinus. He enters at length into the struc- 
ture of Comatula, the skeleton of which he describes correctly enough, whilst in regard 
to its soft parts he falls into some remarkable errors. Thus he states that the furrow 
which runs along the axis and the lateral pinnules of each arm is provided with “ cirrhes 
yentousaires,’ which serve to enable the animal to seize its prey; the fact being that 
these tentacula are not in any degree prehensile, and have no concern whatever in the 
acquisition of food. Again, whilst correctly describing the mouth, he states that the 
stomach has no second orifice, but terminates posteriorly in a blunt point; and that 
which Lamarck regarded as the mouth, and which English authors had rightly taken 
for an anus, he affirms to have no connexion with the alimentary canal, but to be a pro- 
longation from the “ general cavity of the body,” adding the suggestion that it may be 
the respiratory outlet, or may be subservient to the function of locomotion, or may be 
the termination of the oviducal canal. On this point he confesses himself unable to 
speak confidently, not having succeeded in discovering ovaries in the only individual 
which he dissected; but he surmises that in changing its place the animal may make 


use of its “vessie abdominale,” contracting it upon the water with which it had been 


previously filled, after the manner of Cuttle-fish. He rightly stated that Comatule 


DEVELOPMENT OF ANTEDON (COMATULA, LAMK.) ROSACEUS. 687 


attach themselves to fixed objects by means of their “ accessory rays” (or dorsal cirrhi), 
and that they extend their principal rays in every direction; but in asserting that this 
is “pour atteindre et pour attirer la proie vers Vorifice buccal,” he simply hazards a 
supposition for which there is not any foundation in fact, the arms not being used 
for the purpose of grasping food or of conveying it to the mouth. It is obvious that 
M. pe BLAINyILLE was entirely unacquainted with the excellent description of the 
alimentary canal previously given by Hrusincer; and that he stated as facts what were 
only his own conjectures. 

Not many years after Mr. THompson’s publication of his Pentacrinus Europwus, he 
ascertained that it is nothing else than the young of the Comatula, to which he had pre- 
viously noticed its close resemblance. This discovery he communicated to the Royal 
Society ina ‘* Memoir on the Star-Fish of the genus Comatula, demonstrative of the 
Pentacrinus Euvropeus being the young of our Indigenous Species”', which was read on 
the 18th of June 1835, but was not published in the Philosophical Transactions. The 
evidence which he adduces on this point is drawn from the resemblance between the 
most advanced specimens of Pentacrinus and the youngest Comatulw, which is so close 
as to leave no reasonable doubt of the development of the former into the latter. 
Mr. THompson also describes in this Memoir the development of the ova in conceptacles 
formed by the thickening of the membranous expansion inside each of the first fifteen 
or twenty pairs of pinne. The ova, he says, ‘‘ make their exit through a round hole on 
the fascial side of each conceptaculum, still, however, adhering together in a roundish 
cluster of about a hundred each ;” and he adds ‘* by what means these oya are dispersed, 
or how they become attached to the stems and branches of corallines, remain to be dis- 
covered.” He surmised that the parent must be gifted with the power of placing them 
in appropriate situations; and that from “the dispersed and attached ova” the young 
Pentacrini at once shoot up,—a supposition which was extremely natural at the period 
he wrote, not the least suspicion that the first product of the embryonic development 
of the EcninopERMATA generally is an active free-swimming pro-embryo, having at that 
time been hazarded by any Naturalist. 

In the same year (1835) some important observations on Comatula were published by 
M. Dusarpin*, who had watched the animal in a living state at Toulon. Like Mr. 
THompson, he noticed the development of the ova in the swollen pinnules, and their 
escape through apertures which form in the integument. He also stated correctly that 
these animals habitually live attached to Sea-weeds, Zoophytes, &c.; only swimming 
occasionally for the purpose of changing their place of attachment. And he recognized 
the fact that the arms are not prehensile, and that the food is obtained through an 
agency altogether distinct from that of which other Star-fish avail themselves; but of 
that agency he gave an entirely erroneous account (which he subsequently withdrew), 
being ignorant of what microscopic examination has since revealed as to the ciliary 


1 Edinburgh New Philosophical Journal, vol. xx. (1835-36), p. 295, 


? LInstitut, No. 119 (1835), p. 268. 


MDCCCLXYVI. 5B 


688 DR. W. B. CARPENTER ON THE STRUCTURE, PHYSIOLOGY, AND 


action by which the ingestion of food is really accomplished. An examination of the 
residual matters ejected through the anal orifice enabled him to determine that these 
were spicules of Sponges, Bacillariz, and remains of other microscopic organisms. 

In the same year also there appeared the “ Prodréme d’une Monographie des Radi- 
aires ou Echinodermes” of Professor AGassiz ; which left the position of Comatula among 
the Crinoidea, and of the Crinoidea as a family of the STeLLERIDA, very much the same 
as in BLAINVILLE’s arrangement. 

We next come to the memoir of Professor Jou. Mttipr, “ Uber den Bau des Penta- 
crinus Caput-Meduse,” communicated to the Berlin Academy’ on the 30th April, 1840, 
and the 15th May, 1841; which constitutes the most important contribution that has 
been made up to this time, not only to the anatomy of the Crinoipra generally, but to 
that of Antedon in particular; the structure of that type having been carefully investi- 
gated by Professor MiLuer, with the view of throwing light on that of the parts of his 
specimen of Pentacrinus which were unfortunately deficient, as well as for the sake of 
determining the precise relations of these two genera. I shall have such constant occa- 
sion in the subsequent portions of the present communication to refer to the labours of 
my distinguished predecessor, that I shall here only express my high appreciation of 
their value, and my regret that he did not himself live to supply that completion and 
extension of them, for which he is understood to haye collected materials during a visit 
he made to the coast of Norway, shortly before his death, for the purpose of studying 
Antedon in its living state. His investigation of the skeletons of Pentacrinus and of 
Antedon, and of the relations of their different parts as indicated by their muscular 
connexions, was conducted in a thoroughly philosophical spirit; and afforded the basis 
for a more satisfactory determination of the homologous parts in the fossil CrrnoipEa 
than had been possible on the comparatively empirical method of J. S. Minter. The 
nomenclature which he introduced has completely superseded that of his predecessor ; 
and, with some modifications, it will probably remain as the standard by which all 
descriptions of CrinoipEA will be drawn. In subsequent communications to the Berlin 
Academy, which are all embodied in his Memoir “ Uber die Gattung Comatula und 
ihre Arten”*, he laid down the principles on which he considered that the systematic 
arrangement of the numerous species now known might best be founded; and he gave 
descriptions of these species, based on the characters thus indicated, and for the most part 
drawn from personal examination of the specimens contained in the principal European 
museums. 

It was by Professor Epwarp Forpes that the title of the CrinoipEa to rank asa 
distinct Order of Echinodermata seems to have been first perceived; and in his ‘ History 
of British Star-fishes, and other Animals of the Class Echinodermata,’ published in 1841, 
he constituted such an Order under the title of Prynterapa, which he conferred upon it 
in conformity with his fundamental idea of classifying Echinodermata, like Arachnoder- 


* Abhandlungen der Kénigl. Akademie der Wissenschaften zu Berlin, 1841. 
* Abhandlungen der Kénigl. Akademie der Wissenschaften zu Berlin, 1847. 


DEVELOPMENT OF ANTEDON (COMATULA, LAMK.) ROSACEUS. 689 


mata, according to “the modifications of their organs and modes of progression.” He 
does not enter into any explicit justification of the claims either of the Crinoipra or of 
the Opnivripa to the ordinal rank here first assigned to them; but contents himself 
with remarking that “as an explanation of the true nature and relation of the Echino- 
dermatous tribes, I prefer it to any arrangement at present used, and have accordingly 
followed it throughout this work.” ‘There can now be no doubt that Professor Forses 
was completely justified in separating the Crinoipea from the SreLLERIDA with which 
they had been previously associated; since they differ entirely from the Asterida and 
the Ophiurida in the conformation both of their digestive and of their generative appa- 
ratus; whilst their resemblance to those groups is only suchas springs from the general 
disposition of the parts of their skeletons, the fundamental homologies of which are 
altogether diverse. And in accordance with his views, a rank corresponding to that of 
Ecuinipa and AsTertADA has been assigned to the CrinoipEa by the general consent of 
subsequent systematists; as D’Orspieny’, Van DER Horven’, Picrer’, Bronn‘, DE 
Kontnek and Le Hon’, and Dusarpin®. 

The account which Professor Epwarp Forses gave of Comatula rosacea appears to 
have been written without any knowledge of the previous anatomical investigations of 
HEUSINGER, and was issued before those of Professor MiLLuErR had been communicated 
to the Berlin Academy. It is for the most part confined to the external characters of 
the animal, which are in general correctly described, though not with the minuteness 
which could only be attained by a more elaborate microscopic investigation than Pro- 
fessor Forbes seems to have bestowed upon the details of its structure. He rightly 
apprehended the relative characters of the mouth and anus; and with respect to the 
latter he remarks, ‘“‘This curious vent has been mistaken by many authors for the 
mouth, and has greatly puzzled others; and M. pr BLAINVILLE suggested that it might 
be connected with the functions of respiration or generation: but any one who examines 
the Comatula alive, or dissects a specimen well preserved, will not doubt it is a true 
vent.” He made, however, a most extraordinary mistake in regard to the ovaries; for 
notwithstanding the very explicit statement of Mr. J. V.THompson (which he quotes) 
as to the liberation of the ova from conceptacles formed by the swelling of the pinne, 
he affirms that only spermatozoa are formed in these conceptacles, and that the real 
ovaries are certain ‘round brown dots, placed in regular rows and at regular distances 
along the margins of the canals, on the body, the arms, and the pinne.’”’ What is the 
true nature of these spots, is a question which will be considered hereafter; it may be 
positively affirmed, however, that they are not the ovaries, since the production of the 


1 Cours Elémentaire de Paléontologie et de Géologie Stratigraphiques. Paris, 1849. 
2 Handbook of Zoology, translated by Professor Cuarx. London, 1856. 
2 Traité de Paléontologie, 2®™e Ed. Paris, 1857. 
4 Die Klassen und Ordnungen des Thier-Reichs. Zweiter Band. Leipzig und Heidelberg, 1860. 
* Recherches sur les Crinoides du Terrain Carbonifére de la Belgique. Bruxelles, 1854. 
* Histoire Naturelle des Zoophytes Echinodermes. Paris, 1862. 
5 B2 


690 DR. W. B. CARPENTER ON THE STRUCTURE, PHYSIOLOGY, AND 


ova in the swollen portions of the pinne has been seen not merely by Mr. J. V. THompsoy, 
but by M. Dusarpry, Professor Mitier, Dr. Buscu, Professor Wyvitte 'THomson, and 
myself. The fact is that these animals are unisexual; and that while ova are produced 
in the conceptacles of some individuals, spermatozoa are deyeloped within others, and 
are set free in the same mode. 

The statement of Mr. J. V.THompson as to the identity of his Pentacrinus with the 
young of Comatula, on which doubts had been cast by M. Dusarpr’, was satisfactorily 
confirmed by Professor Forbes. ‘* When dredging in Dublin Bay,” he says (Introduction, 
p- xii), “in August 1840, with my friends Mr. R. Barn and W.'THompson, we found 
numbers of the Phytocrinus or Polype-state of the Feather-star, more advanced than 
they had ever been seen before, so advanced that we saw the creature drop from its stem - 
and swim about a true Comatula; nor could we find any difference between it and the 
perfect animal, when examining it under the microscope.” He did not, however, add 
anything to the account previously given by Mr. J. V. THompson of the successive stages 
of development of this Pentacrinoid larva ; and his description of the structure of its 
calcareous stem is very far from being accurate, as I shall have occasion to show here- 
after. 

The remarkable discoveries of Professor MULLER and other observers in regard to the 
larval or pro-embryonic forms of Ecuinipa, ASTERIADA, and OpHiuriDA, naturally led to 
the suspicion that some corresponding form of free-swimming pro-embryo must be the 
first product of the egg of Antedon; and that this probably gives origin to the Pentacri- 
noid larva by a process somewhat similar to that by which the young Echinus originates 
from its “ pluteus,” or the Asterias from its “ bipinnaria.” ‘To the solution of this pro- 
blem Dr. Wiin. Buscu’, a pupil of Professor MULLER, applied himself in 1849; and he 
was fortunate enough to discover such a free-swimming pseudembryo, somewhat Annelidan 
in its form; though he did not succeed in tracing it beyond its earliest stages, or in 
showing how the Pentacrinoid larva originates from it. It is probably through not 
haying done so, that his interpretation of his observations was in many points incorrect ; 
as has been shown by the more recent and complete researches of Professor WYVILLE 
‘YHomson*, who has worked out this part of the developmental history of dnatedon with 
a completeness that leaves scarcely anything to desire, and who (in accordance with my 
request) has not only traced the metamorphosis of the free-swimming pseudembryo into 
the pedunculate Crinoid, but has carried on the description of the latter to the stage at 
which my own observations best enable me to take it up. 

In 1856 an account was published by Professor Sars of the Pentacrinoid stage of 
Antedon Sarsii; but as the principal points of interest in this communication haye 
already been noticed in Professor Wyvitte THomson’s Memoir (p. 516), I need not 


1 T’Tustitut, No. 119 (1835). 

2 « Ueber die Larve der Comatula,” in Miiler’s Archiv, 1849, p. 400; and in Beobachtungen tiber Anatomie 
und Entwickelung einiger wirbellosen Seethiere. Berlin, 1851. 

3 « Qn the Embryogeny of Antedon rosaceus,” in Philosophical Transactions for 1865, p. 513, 


DEVELOPMENT OF ANTEDON (COMATULA, LAMK.) ROSACEUS. 691 


here repeat them. As he justly remarks, it would appear from Professor Sars’s descrip- 
tion that the pedunculate condition is much more prolonged in dA. Sarsii than in 
A. rosaceus; the animal being only distinguishable by the persistence of its stem from 
an adult Antedon. 

Early in 1863 Professor ALLMAN communicated to the Royal Society of Edinburgh! 
a Memoir “On a Prebrachial stage in the development of Comatula,” based on the 
obseryation of a single specimen which he had obtained on the coast of South Devon; 
and he was the first to publish the very interesting fact that the plates first formed in 
the Pentacrinoid larva are the circlet of Jasa/s and the circlet of orals superimposed 
on them, the former constituting the calyx, and the latter forming its pyramidal roof; 
the only vestige of the radials, which are afterwards to constitute the essential part of 
the skeleton, being a set of five minute plates intercalated between the upper angles of 
the basals. This disposition he compares with that of the plates in certain fossil 
Crinoipra, which in his opinion permanently represent a condition that is transitory 
in our Pentacrinoid larva. His account of the tentacular apparatus, however, bears 
evidence of the insufficient opportunities for observation afforded him by the possession 
of a single specimen; and I feel bound to state that having myself verified Professor 
Wyvitte THomson’s descriptions,—which are based on frequently-repeated observations 
made upon an ample supply of specimens, and these not merely in the phase of develop- 
ment which fell under Professor ALLMAN’s notice, but in all the preceding and subsequent 
stages,—I am quite satisfied of their correctness on all those points in which they differ 
from the descriptions of Professor ALLMAN. 


The foregoing constitute, I believe, all the contributions hitherto made to our 
acquaintance with the structure and physiology of Antedon ; and it only remains for me to 
notice two recent works, one on the Crinoipxa, the other on the KcnropERMATA generally, 
in which its relations to the Crinoids and to other Echinoderms are discussed with all 
the advantage of more advanced knowledge. 

The first of these is the memoir of MM. L. pE Koninck and H. Le Hon, entitled 
“Recherches sur Jes Crinoides du Terrain Carbonifére de la Belgique”*, which is much 
more comprehensive than its title would indicate, since it contains an elaborate History 
of the progress of knowledge as to the Crinoipna generally (to which I have already 
had occasion to refer, p. 675), and a philosophical investigation of their Zoological 
relations, and of the principles on which the classification of the group should be 
founded. Their inquiries have led them to a modification of the nomenclature of 
Professor MiLuer, which will, 1 believe, be found practically convenient, and which, 
therefore, I shall follow in my own description. The only addition to our knowledge 
of the recent Crinoidea which this memoir contains, is furnished by a previously 
unpublished communication from M. Ducnassaine to M. MICHELIN, accompanying a 

1 Transactions of the Royal Society of Edinburgh, vol. xxiii. p. 241. 
? Mémoires de Académie. Royale de Belgique. Bruxelles, 1854. 


692 DR. W. B. CARPENTER ON THE STRUCTURE, PHYSIOLOGY, AND 


specimen of Pentacrinus Caput-Medusw transmitted by him from Guadaloupe. “La 
bouche de I’Encrine se trouve circonscrite par cinq levres. Elle ne se voit que 
lorsqu’on a soulevé ces cing lévres. On yoit alors que c'est un petit trou rond d’enyiron 
deux lignes de diamétre. Les levres ne sont libres, et ne peuvent étre souleyées que de 
trois lignes environ. Dans le reste, elles sont adhérentes par les cing sillons qui partent 
des commissures et se prolongent jusqu’a la circonférence du disque. La mastication 
ne sopcre pas par la bouche, mais bien par les lévres, qui sont armées a cet effet d'une 
rangée de petites épines assez fortes. Quant a la nourriture, j’ai trouvé des débris de 
petits crustacés.” This statement is important, since the imperfection of the specimen 
of Pentacrinus described by Professor MULLER prevented him from giving any account 
of the parts about the mouth; but the correspondence of the peripheral part of the disk 
with that of Comatula led him to infer that the central portions are constructed on the 
same plan,—the validity of which inference is confirmed by the description just cited. 
It further appears from the reference made by our authors to the sketches of 
M. Ducnassaine, that the mouth of Pentacrinus Caput-Meduse is surrounded by Oral 
plates, similar in form to those which exist in the Pentacrinoid larva of Antedon, 
though no trace of them is to be found in the adult. I do not, however, regard the 
evidence as yet sufficient to establish this conclusion.—In regard to the fossil CRinoiDEa, 
MM. be Koninck and Le Hon made an important step in advance of their predecessors 
in strongly drawing attention to the single, double, or multiple anal plate, as a peculiar 
feature in the skeleton, introducing a bilateral symmetry in what would otherwise be 
regularly radial. ‘Their determination of the nature of this plate is fully borne out 
by its position in the Pentacrinoid larva of Antedon, although, like the oral plates, it 
is wanting in the adult. 

Of the recent systematic treatise by MM. Dusarpin and Hups on the EcHiNoDERMATA 
generally’, it is only needful to say that whilst it furnishes a convenient réswmé of pre- 
vious researches upon the Order CrinoipEa and upon the genus Comatula (which, as 
in D’Orsieny’s arrangement, is taken as the type of a distinct Family, Comatulide), it 
adds nothing to our knowledge of them. In their systematic arrangement and descrip- 
tion of the species of Comatula, these authors‘for the most part follow Professor MULLER. 


IIT.—EXTERNAL CHARACTERS, AND HABITS:—SYNONYMY. 


1. In common with other members of the Family ComatuLipa, our Antedon may be 
described generally as composed of a central disk, from which radiate ten slender arms, 
fringed with pinnules along their entire length (Plate XXXI.). The disk contains 
the whole of the proper Digestive apparatus, which forms a lenticular mass lying in the 
hollow of a shallow calcareous basin or Calya, and entirely exposed on its oral surface, 

* Histoire Naturelle des Zoophytes Echinodermes, comprenant la description des Crinoides, des Ophiurides, 


des Astérides, des Echinides, et des Holothurides. Par M. F. Dusanrpry et M. H. Hues. (Suites 4 Buffon.) Paris, 


1862, 


DEVELOPMENT OF ANTEDON (COMATULA, LAMK.) ROSACEUS. 693 


which is covered only by the membranous Perisome. ‘The centre of the visceral disk is 
occupied by the Mouth (Plate XXXII. fig. 3, m), which is small and slightly prolonged 
into five angles; and is surrounded by five somewhat elevated valvular folds, beneath 
the free edge of each of which is to be seen a row of minute tentacula. From the 
mouth there radiate five furrows channelled out in the perisome, and having elevated 
borders scolloped so as to form a series of minute valvules, from beneath each of which 
issues a cluster of three tentacles; these furrows soon bifurcate, and thus ten furrows are 
formed, of which one is continued on to the ventral surface of each of the arms in the 
extension of the perisome which clothes it. In the space between two of these furrows 
we see the large projecting vent or Anus (a), the shape of which differs much according 
as it is full or empty; sometimes its aperture is so completely closed as to be scarcely 
discernible, though the tube below is widely distended; whilst in other states we find 
the aperture patent, its edges everted and crenate, and the tube leading to it quite shrunk 
and flaccid.—On looking at the dorsal or aboral face of the central disk, which in the 
living state is ordinarily the inferior, we find it in great part concealed by an assemblage 
of jointed and uncinate Cirrhi, radiating from a central tubercle to which they are arti- 
culated (Plate XXXII. fig. 4), and extending even beyond the margin of the disk: the 
number of these ordinarily ranges in a full-grown specimen between twenty and thirty- 
two; and each of them normally consists of about sixteen segments. When these have 
been removed, we find the under surface of the calyx to be composed, as shown in 
Plate XXXII. fig. 1, of a single convex Centro-dorsal plate (c), having a somewhat 
pentagonal margin, within which are two or more rows of sockets for the articulation 
of the cirrhi, whilst the central space, which bears no cirrhi, is somewhat flattened. 
Along the five sides of this pentagon we see five pieces (7”) having their proximal 
and distal margins nearly parallel, but their surfaces convex; these are the Second 
Radials, the First being entirely concealed by the Centro-dorsal. And to the distal 
margins of the second radials are attached five pieces (7°) of nearly triangular form ; 
their basal margins rather exceeding in length the distal margins of the second radials 
to which they are applied ; whilst each of their inclined sides bears the first segment (67") 
of an Arm: these triangular pieces are the Zhird or Axillary Radials. ‘The spaces 
between the diverging Radials, and between the basal segments of the Arms as far as 
the fourth, are filled up by the membranous Perisome, which thus completes the floor 
of the calyx. Sometimes, however, we find minute plates imbedded in the substance 
of the perisome, at the angles between the second radials () 9). 

2. Each Arm is composed of a long series of calcareous segments, of which the dorsal 
surface is exposed like the dorsal surface of the calyx, whilst the ventral surface is 
clothed with an extension of the ventral perisome, carrying with it an extension of the 
radial furrows and their tentacular apparatus. With certain exceptions, hereafter to be 
noticed, every segment of the arms bears a jointed Pinnule, which repeats on a smaller 
scale the same structural features; and the furrows which pass from the disk to the 
arms, send branches also from the arms to the pinnules, which are continued to their 


694 DR W. .B. CARPENTER ON THE STRUCTURE, PHYSIOLOGY, AND 


extremities. Along the borders of these furrows there extend from the inner margins 
of the valvular folds which fringe them, groups of delicate tubular tentacula; each group 
consists of three, of which one is peculiarly extensile-—The pinnules are borne on the 
opposite sides of the successive segments of the arms, so that they present an alternate 
arrangement. Those belonging to the basal segments of the arms (Plate XXXII. fig. 5) 
assist In supporting the visceral mass, and during life they are observed to arch over 
the disk (Plate XX XI. A) instead of projecting laterally like the rest; they are, more- 
over, peculiar in being about twice as long as those which succeed them, and in being 
entirely destitute of the tentacular apparatus. ‘The succeeding pinnules, at the season 
of reproduction, become turgid in consequence of the development of the ovaries or testes 
in their substance, as already described by Professor WyviLLE THomson. 

3. When the visceral mass has been removed from the calyx, which is very easily 
accomplished by tearing away the perisome that closes round its margin, we find the 
floor of the basin (Plate XXXII. fig. 2) nearly smooth, but depressed in the centre, 
where there is a passage through the calcareous pentagon formed by the union of 
the First Radials, which passage is occupied by a soft pedicle. This pedicle we shall 
hereafter find to establish a connexion between the visceral mass and certain structures 
contained in the cavity of the centro-dorsal plate; and it is to be regarded as the residue 
of the original Crinoidal axis. At a little distance from the central passage we see five 
pairs of Muscles arranged pentagonally; these pass between the first and the second 
Radials. On the distal side of each of these we see two pairs of muscles, diverging from 
each other; these pass between the third Radials and the first Brachials,—the_ second 
and third Radials being connected by ligamentous union only (see § 37 and Plate 
XXXIV. fig. 2). 

4. The Colour of our Antedon varies greatly. Commonly it is that which its trivial 
name rosaceus implies; but the crimson frequently deepens to a rich damask hue, espe- 
cially during the breeding-season ; whilst it very frequently gives place to white on 
portions of the disk and arms, so that the animal has a beautifully variegated aspect. 
Sometimes, again, the predominant hue is a rich orange, and this may be variegated with 
white or crimson, or with a bright sulphur-yellow. This last is often the first colour 
assumed by the Pentacrinoid larvee, when not far from the termination of their pedun- 
culate stage. 

5. The Size of our Antedon also varies within a wide range. Its usual diameter from 
tip to tip of its extended arms may be from 4 to 5 inches, but specimens exceeding this 
limit are by no means uncommon; and I have occasionally met with specimens as much 
as 9 inches in diameter. As I am certain that these last were identical in structure 
with the ordinary type, I cannot regard an excess of size as affording adequate ground 
per se for specific differentiation. 


DEVELOPMENT OF ANTEDON (COMATULA, LAMK.) ROSACEUS. 695 


SYNONYMY. 


6. Referring to the memoir of the Rev. A. M. Norman “ On the Genera and Species 
of British Echinodermata”’ for definitions of the Order Crivorpra, the Family ANTE- 
DONIDH, the Genus Antedon, and the Species rosaceus, I have now to state my views on 
its synonymy. As to this I am not able to speak with the positiveness 1 could desire, 
since my investigations, though prosecuted over a considerable Geographical range, have 
not yet satisfied me as to the limits of variation in this type. In this, as in many similar 
cases, points of difference which seem extremely well marked when the most divergent 
examples from remote localities are compared, are found, when a sufficiently large 
number of examples from intermediate localities are examined, to present gradational 
modifications which go far to destroy their value as specific characters. And this will 
be found especially the case with those characters which rest on degree of development. 
Thus I can attach little value to the flattening of the Centro-dorsal plate (} 22) in one 
type, and its uniform convexity in another,—or to the nakedness of the flattened portion 
in the former, whilst the whole surface is covered with dorsal cirrhiin the latter ;—-when 
I find that in the early stage of both, the centro-dorsal plate is uniformly convex and 
entirely covered with dorsal cirrhi, so that young specimens of the two could not be dif- 
ferentiated. Nor can I adopt as characters of specific difference such variations in the 
number of Dorsal Cirrhi, the number of their joints, the proportion of the length of these 
joints to their breadth, and the form of their terminal claw, as I occasionally meet with 
among the cirrhi of specimens from the same locality resembling each other in all other 
respects; the shedding and renewal of these cirrhi continuing, in my opinion, through 


1 The following are given by Mr. Norman (Annals of Natural History, 3rd Series, vol. xv. p. 102) on the 
authority of Professor Wyvitte THomson, as the diagnostic characters of Antedon rosaceus :—* Perisom of the 
disk naked, or with scattered tubercles containing groups of radiating calcareous spicules. Centro-dorsal plate 
convex, flattened at the apex, its sides covered with dorsal cirrhi; but the central flattened portion, of greater 
or less extent, naked. Cirrhi 14-18-jointed; the joints short, the longest but little longer than broad. Ter- 
minal claw sharp and curved ; penultimate joint with a short pointed opposing tubercle, which is not developed 
into a claw. Proximal pairs of pinnules at least twice as long as those succeeding. Ovaries short and rounded. 
Usually, when mature, without any trace of interradial plates; frequently, however, with groups usually of 
three perisomatic interradial plates in the spaces between the radial axillaries. Colour crimson, scarlet, or 
mottled. Average size 43 inches from tip to tip of arms.”—Of <Antedon Milleri the following are given as 
characters :—‘ Perisom of the disk with scattered warts, supported by groups of diverging spicules. Centro- 
dorsal plate uniformly conyex, and entirely covered with dorsal cirrhi. Cirrhi 15-18-jointed ; the longest of 
the joints about once and a half as long as broad. Terminal claw curved andacute; penultimate joints without 
a trace of an opposing process. ‘Proximal pinnules greatly longer than those succeeding them. Ovaries long 
and narrow, extending over more than half the length of the pinnules. Groups of interradial plates occupying 
the spaces between the radial axillaries. Of a rich brown or reddish-tawny colour. Average size 11 inches 
from tip to tip of the arms.”—None of these characters appear to me sufficient for the differentiation of the two 
species to which they are respectively assigned, save the form of the ovaries, which (as Professor WYVILLE 
Tomson assures me) constitutes a strongly marked feature in each, and is not liable to gradational variations 
like Size, Colour, the form and relative abundance. of the Perisomatic plates, or to variations connected with 


grade of development like others alluded to above. 
MDCCCLXVI. 5c 


696 DR. W. B. CARPENTER ON THE STRUCTURE, PHYSIOLOGY, AND 


the whole life of the animal; and the several cirrhi of the same individual often pre- 
senting very marked differences in size and proportions (}§ 26-30). Even a character 
which in the first instance appeared so definite as the presence of interradial plates in one 
type (as in the Comatula fimbriata of J.S. Miter), and their entire absence in another 
(the Comatula rosacea of Femina and Epwarp Forbes, the Antedon decameros of Gray, 
the A. resaceus of NorMay, WyYvILLE Tuomson, and myself), has proved unreliable, as 
I shall hereafter fully explain (§ 39). And thus I am led to suspect that the range 
of variation in this type is very wide, and that the more extended the comparison of 
specimens from different localities and from different depths, the more reason there will 
appear for assigning only a varietal rank to several types which are at present-accounted 
different species. 

7. As there can be no reasonable doubt that the type which forms the subject of this 
memoir is the one described by Linck’ under the name Stella decacnemos rosacea, 
“ propter corporis fabricam rose similem,” and as the treatise of Linck is the foundation 
of all our scientific knowledge of the group of Sea-stars, his specific name has a prefer- 
ential claim to our acceptance, which has been already recognized by FLEmine’, 
BLAINVILLE’, and Epwarp Forses‘. With Epwarp Forses I am disposed to consider 
the Stella decacnemos barbata of Lixck (the fimbriata of Barrewier, whose figure and 
description he cites) as specifically identical with his rosacea, although FLEMING, 
Lamarck, and BLAINVILLE rank it as distinct; while Dusarpin* (upon what grounds I 
cannot discover) ranks it with the Actinometra pectinata of Jou. Miuter. It is im- 
possible to say with certainty whether the Decacnemos crocea zaffarana Neapolitanorum 
of Linck, the dexadacvaxtwoedne of FaBius CoLumna, is anything else than a larger form 
of the same, the description given of it not being sufficiently minute to enable its specific 
characters to be positively determined; and it may not improbably be the dntedon 
Milleri of Norman and Wyvitite Tuomson. With Professor Epwarp Forses, also, I 
consider both the <Asterias bifida and the Asterias decacnemos of Pennant’, and the 
Asterias pectinata of ADAMs’ to belong to the same specific type, since their descriptions 
and figures do not accord with the characters of either of the other British Comatule: 
by Lamarck, however, the Asterias decacnemos of Punnant and the Asterias pectinata of 
Apams are identified with the Decacnemos barbata of Linck, which he cites as Comatula 
barbata. Our Antedon rosaceus is undoubtedly the Alecto Europea of Luacu*; and 
there cannot, I think, be any question of its identity with the Comatula Mediterranea 
of Lamarck’. Under one or other of these two names this type is referred to in the 
principal Continental Monographs in which it is specially mentioned; the first being 
used by Professor Jon. Mijnier in his memoir “ Ueber den Bau des Pentacrinus Caput- 


1 De Stellis Marinis, p. 55, tab. xxxvui. fig, 66. ° British Animals, p. 490. 

> Manuel d’Actinologie, p. 248. 4 History of British Starfishes, p. 5. 

5 Histoire Naturelle des Zoophytes Echinodermes, p. 210. 6 British Zoology, vol. iv. pp. 65, 66. 

7 Linnean Transactions, vol. v. p. 10. 8 Zoological Miscellanies, vol. ii. 1814, p. 62. 
9 


Animaux sans Vertébres, 2nd Ed., tom. iii. p. 210. 


DEVELOPMENT OF ANTEDON (COMATULA, LAMK.) ROSACEUS. 697 


Meduse”'; whilst the second is adopted by Mecken’*, Heustvarr’, Sars‘, Dusarpin®, 
and Professor Jon. MULLER in his memoir “ Ueber die Gattung Comatula und ihre 
Arten”®. Professor WyviLte THomson regards the Comatula fimbriata of J. S. MriER’, 
which is described under the name C. Milleri by Prof. Jou. Miuer, as probably iden- 
tical with the Antedon Milleri of which I have already cited his definition (§ 6, note); 
Munter’s figure and description of it, however, seem to me scarcely sufficient to remove 
the doubt suggested by its locality () 39) whether it is anything else than the variety of 
A. rosaceus which is characterized by the presence of interradial plates. I am disposed 
to identify our Antedon rosaceus with the Comatula adeone of Dretue Cutase®. But 
it must not be confounded either with the Comatula jimbriata or with the C. adeone 
of Lamarck, Jon. Mtnuer, and Dusarpry, or with the C. rosea of Jon. MULLER and 
Dusarpin, which are distinct types. It is probably identical with the Alecto petasus of 
Von Dien? and Koren. 
8. The synonymy of our Antedon rosaceus, therefore, I consider to be as follows :— 


Stella decacnemos rosacea, LINCK. 

’ Stella decacnemos barbata, LrNcx. 

Asterias bifida, PENNANT. 

Asterias decacnemos, PENNANT. 

Asterias pectinata, ADAMS. 

Alecto Europea, Lmacu, followed by Jon. MUtuer. 

Comatula Mediterranea, Lamarck, followed by MeckeL, Hrvstncer, Sars, Dusarpiy, 
and Jon. MULLER. 

? Comatula barbata, Lamanck, followed by Fiemine. 

t Comatula fimbriata, J. S. Mrier. 
Comatula rosacea, FLEMING, BLAINVILLE, and EpwARrD ForBESs. 
Comatula decacnemos, J. V. Tompson. 

?Comatula adeone, DELLE CHIAIE. 

? Comatula Milleri, Jou. MULLER. 

Alecto petasus, VoX Dien and Koren. 

Antedon decameros, GRAY. 

The young pedunculate form of Antedon rosaceus, moreover, received from its disco- 
verer, Mr. J. V. Toompson, the designation Pentacrinus Europeus, and from BLAINVILLE 
that of Phytocrinus Europeus; whilst FLemine proposed for it the designation Hibernula. 

1 Aphandl. der Kénigl. Akad. der Wissenschaften zu Berlin, 1843, p. 177. 

* Archiy fiir Physiologie, 1823, p. 470. 

3 Mecxer’s Archiv, 1826, p. 317; and Hevstnecer’s Zeitschrift fiir organ. Physiol., Bd. III. p. 366. 
4 Beskrivelser og Jagttagelser, &c. Bergen, 1835. 

* LInstitut, 1835, p. 268; and Hist. Nat. des Echinodermes, Paris, 1862. 

® Abhandl. der Konigl. Akad. der Wissenschaften zu Berlin, 1847. 

7 Natural History of Crinoidea, Bristol, 1821, p. 132. 

8 Animali senza Vertebre del regno di Napoli. 

9 « Ofversigt af Skandinaviens Echinodermer,” in Kénigl. Vetensk. Akad. Handl. Stockholm, 1844. 


5c2 


698 DR. W. B. CARPENTER ON THE STRUCTURE, PHYSIOLOGY, AND 


Hapsits. 


9. The usual habitat of Antedon rosaceus appears to be water of from ten to twenty 
fathoms’ depth ; though it is found sometimes in shallower, and sometimes in deeper water. 
My experience agrees with that of Professor E. Forszs, that the largest specimens are 
obtained from deep water. The animals are generally brought up by the dredge either 
actually clinging to Sea-weeds (usually Laminaria) or to Zoophytes or Polyzoa, or in 
such association with them as suggests the idea that their detachment has been effected 
in the act of dredging. For reasons I shall presently give, I cannot by any means assent 
to the statement of Mr. J. V. Tompson’, that ‘‘ this curious Star-fish is an animal not 
only free, but leading the most vagrant life of any of the tribe with which it has been 
hitherto associated by naturalists—at one time crawling about amongst submarine 
plants, at others floating to and fro, adhering to thin fragments by means of its dorsal - 
claspers, or even swimming about after the manner of the Medusx.” It is quite true 
that, as stated by Mr. J. V. Tuompson, and confirmed by Professor Epwarp Fores, an 
Antedon placed freely in water will swim with considerable activity, moving back foremost 
by advancing five arms at a time, and then the alternate five; in fact I do not know any 
animal of which the movements are more graceful than those of the “ feather-star” (as 
Professor Epwarp Forbes appropriately called it). But I am quite satisfied from repeated 
observations that these movements are not habitual to the animal, and are to be regarded 
only in the light of a restless search after a new attachment, being kept up no longer 
than is requisite for obtaining this. If an Antedon be placed in a large basin of sea- 
water, having smooth sides and not containing any object of which its dorsal cirrhi can 
lay hold, the swimming action may continue (with occasional intermissions) for several 
hours. But if a rough angular stone, a Sea-weed, a Zoophyte, a cluster of Serpule, or 
anything to which its dorsal cirrhi can attach themselves (Plate XX X1.) be placed in the 
basin, the Antedon settles itself upon this, and if the attachment proves suitable, the 
creature seldom changes it. I have kept a number of Antedons, without any other 
animals, in the same Vivarium for several weeks together; and I have observed that the 
places of individuals which I could distinguish by some peculiarity of colour, were scarcely 
at all altered during the whole period,—the amount of change, in fact, being little more 
than would have been exhibited by an equal number of Actinie. One fine specimen I 
particularly noted as having firmly attached itself by the grasp of its dorsal cirrhi to the 
tube of a Serpula; and this it did not let go during the whole time of its captivity. 

10. Thus, as regards the ordinary fixedness of its position, the condition of the adult 
Antedon only differs from that of its Pentacrinoid larva in this; that whereas the latter 
necessarily remains fixed to the spot to which the base of its pedicle was originally 
attached, the former can quit its hold when its attachment is no longer suitable to its 
requirements, and can move from place to place in search of another. How intimate, 
moreover, is the functional relation between the dorsal cirrhi of the adult Antedon, and 
the stem of its Pentacrinoid larva, further appears from the fact that the cirrhi only 

1 Edinb. New Philos. Journal, yol. xx. (1835-36) p. 296. 


DEVELOPMENT OF ANTEDON (COMATULA, LAMK.) ROSACEUS. 699 


make their appearance in the latter part of the Pentacrinoid stage (as will be seen by a 
comparison of figs. A,B, ¢,D, E in Plate XXXIX. fig. 1), in preparation for that detach- 
ment of the “summit” from the stem, which thenceforth changes the condition of the 
animal from the fixed to the free. Notwithstanding that change, the life of the adult 
Antedon is habitually passed (I feel justified in asserting) so nearly in the same degree 
of fixedness as that of its Pentacrinoid larva, that it may almost equally be regarded as 
representing the life of the typical Crinoipea. If the creature ever quits its attach- 
ment, save on account of the unsuitableness of its position, it is probably during the 
period of sexual activity, at which it seems more frequently errant than at any other 
stage of its life except the earliest. 

11. In regard to the ordinary condition of the Arms, there is much the same variety 
as is seen among Actiniew with respect to the expansion of their tentacles. Sometimes 
the arms and their pinne are stretched out quite straight to their full length, and almost 
entirely in the same plane, so as to present an appearance of rigidity; whilst sometimes, 
still remaining fully extended, they are more or less closed together, so as to give to their 
whole expanse the shape of a funnel more or less deep, with the central disk at its 
bottom. More commonly, however, some of the arms curve either obliquely or towards 
the ventral surface; and this ventral curvature may be so great that the arm forms a 
spiral which reminds the observer of the unfolding frond of a Fern. Occasionally all 
the arms are seen to be thus coiled, so that the diameter of the animal is reduced to 
not more than one-third of that which it has when the arms are fully extended. In no 
instance have I ever seen the arms more than slightly curved in the dorsal direction; a 
peculiarity which will be readily accounted for when we examine the structure of their 
skeleton in detail. 

12. Whatever may be the purpose of the habitual expansion of the Arms, I feel quite 
justified in asserting that it is not (as stated by several Authors whom I have cited in my 
historical summary) the prehension of food. Ihave continually watched the results of 
the contact of small animals (as Annelids, or Entomostracan and other small Crustacea) 
with the arms; and have never yet seen the smallest attempt on the part of the animal 
to seize them as prey. Moreover, the tubular tentacula with which the arms are so 
abundantly furnished have not in the smallest degree that adhesive power which is 
possessed by the “feet” of the Ecuinipa and Astertapa; so that they are quite inca- 
pable of assisting in the act of prehension, which must be accomplished, if at all, either 
by the coiling-up of a single arm, or by the folding-together of all the arms. Now I 
have never seen such coiling-up of an arm as could bring an object that might be 
included in it into the near neighbourhood of the mouth; nor have I seen the contact 
of small animals with a single arm produce any movement of other arms towards the 
spot, such as takes place in the prehensile apparatus of other animals. Moreover, any 
object that could be grasped either by the coiling of one arm, or by the consentaneous 
closure of all the arms together upon it, must be far too large to be received into the 
mouth, which is of small size, and is not distensible like that of the AsTERIADA, 


700 DR. W. B. CARPENTER ON THE STRUCTURE, PHYSIOLOGY, AND 


15. A special function was assigned by Lamarck to what he terms the “rayons 
simples inférieures,” which, as he correctly states, are nothing else than the basal 
pinnules of the principal arms, “qui sont allongées et abaissées en dessous.” He says 
that these “rayons simples” serve to bring to the mouth the prey which has been 
captured by the “grands rayons pinnés.” ‘This assertion I cannot but consider to be 
purely hypothetical. It will be shown in the Second Part of this Memoir that there 
are such peculiarities of structure and disposition on the part of these basal pmmules— 
which are much longer than the rest, and habitually arch over the central disk (Plate 
XXXI. a)—as indicate a speciality of function; but I feel confident that the function 
assigned by LAMARCK cannot be the true one. For not only have I failed to perceive, 
after long continued observation and repeated experiments, any such movements of these 
pinne as would indicate a prehensile action, but I have found reason to suspect their 
function to be that of sensorially protecting the soft parts which occupy the ventral 
surface of the disk, and of preventing unsuitably large particles from being drawn in by 
the oral current. For if the ordinary pinnules of any arm be irritated by the contact of 
a rod, such irritation merely produces a languid wavy motion of the arm thus acted-on, 
which may extend itself to others if the irritation be repeated or prolonged. But if 
the rod be made to irritate the long dasal pinnules, all the arms (if the animal be in 
full vigour) immediately close together, with an energy and consentaneousness that are 
seen in no other movement. 

14. It was affirmed by M. Dusarpiy (l'Institut, No. 119, p. 268) that the arms are 
used for the acquisition of food in a manner altogether dissimilar to ordinary prehension ; 
for recognizing the fact that the alimentary particles must be of small size, he sup- 
posed that any such, falling on the ambulacral (?) furrows of the arms or pinne, are 
transmitted downwards along those furrows to the mouth wherein they all terminate, by 
the mechanical action of the digitate papille which fringe their borders. This doctrine 
he appears to have subsequently abandoned ; since in his last account of this type (Hist. 
Nat. des Echinodermes, p. 194) he affirms that the transmission of alimentary particles 
along the ambulacral (?) furrows is the result of the action of cilia with which their 
surface is clothed. Although I have not myself succeeded in distinguishing cilia on the 
surface which forms the floor of these furrows, yet I have distinctly seen such a rapid 
passage of minute particles along their groove, as I could not account for in any other 
mode, and am therefore disposed to believe in their existence. Such a powerful 
indraught, moreover, must be produced about the region of the mouth, by the action of 
the large cilia which (as I shall hereafter describe) fringe various parts of the internal 
wall of the alimentary canal, as would materially aid in the transmission of minute 
particles along those portions of the ambulacral (?) furrows which immediately lead 
towards it; and it is, I feel satisfied, by the conjoint agency of these two moving powers 
that the alimentation of Antedon is ordinarily effected. In the very numerous speci- 
mens from Arran the contents of whose digestive cavity I have examined, I have never 
found any other than microscopic organisms; and the abundance of the horny rays of 


‘DEVELOPMENT OF ANTEDON (COMATULA, LAMK.) ROSACEUS. TOL 


Peridinium tripos (Eur.) has made it evident that in this locality that Infusorium was 
one of the principal articles of its food. But in Antedons from other localities, I have 
found a more miscellaneous assemblage of alimentary particles; the most common 
recognizable forms being the horny casings of Enromosrraca or of the larve of higher 
Crustacea. It is not a little curious that in the specimens of Antedon which, through 
the kindness of Mr. C. Strwant, I have received from Plymouth Sound, the alimentary 
canal is frequently almost choked up by the body of a Suctorial Crustacean with its 
egg-masses. As this is far too large and powerful an animal to have been drawn into 
the mouth by the ciliary current as an article of food, and as its body rarely shows any 
indication of having been acted on by the digestive power of the Antedon, I am disposed 
to think that it has been introduced either as an egg or as a larva, and has undergone 
its development parasitically where it is found. 

15. There is one point in the habits of Antedon which must be regarded as of 
considerable importance in the determination of the office of that vast aggregate of 
tubular tentacula which is borne by the pinnated arms; namely, its close dependence, for 
the maintenance of its life, upon pure well-aérated water. The contrast in this respect 
between Antedon and members of the Order OpniuRIDA inhabiting the very same locali- 
ties and brought up from the same depths, is extremely striking. For the “sand-stars” and 
‘‘brittle-stars” are among the most hardy of the Echinoderms, maintaining their acti- 
vity in the Vivarium under circumstances fatal to the life of most others of its ordinary 
inhabitants; and I have seen them moving about for half an hour in dilute glycerine, 
immersion in which soon kills ordinary Starfishes. On the other hand, Antedons are 
among the first to die, when kept with other animals in a Vivarium; and although I 
was at first inclined to attribute this to the circumstance of their habitually living under 
a much greater pressure of water than the littoral animals with which they are asso- 
ciated in such artificial collections, yet I soon came to be satisfied that the real expla- 
nation was to be found in their inability to sustain any deficiency in the purity of the 
medium they inhabit. For by placing them by themselves, in small numbers, in an 
adequate supply of water, and by frequently renewing this, I have succeeded in keeping 
the same specimens for several weeks together; and the deficiency of vigour which they 
showed at the end of that time,—manifested in a general flaccidity of the arms, and in 
a disposition to the casting-off of portions of them,—appeared quite explicable by the 
insufficiency of their food-supply, made evident by the progressive shrinking of the visceral 
mass, the ventral surface of which came at last to be concave instead of protuberant. 
Moreover it happened on several occasions that if a dozen specimens of Antedon were 
thrown at night into a large basin of water, and were left without any means of attach- 
ment, they were all found dead in the morning, conglomerated at the bottom of the 
basin, clinging to each other with their dorsal cirrhi, and having their arms intertwined 
in such a manner as to suggest the idea that they had died of the Asphyxia produced 
by overcrowding, after exhausting themselves in efforts to find a suitable attachment. 
Whilst if, in a basin of the same size and containing the same quantity of water, there 


702 DR. W. B. CARPENTER ON THE STRUCTURE, PHYSIOLOGY, AND 


were placed, with a like assemblage of specimens, a sufficient number of rough stones 
to afford them all a basis of attachment, they would be all found in the morning in a 
state of full expansion, with every appearance of health and vigour. Hence I feel 
justified in concluding that in these animals the Respiratory function can only be 
effectually performed in a pure well-aérated medium, and that the free exposure of the 
arms to that medium is no less required. I may add, further, that the intermixture of 
a small proportion either of fresh-water or of glycerine with the sea-water in which 
Antedons are immersed, is very speedily fatal to them.—It will be shown in the Second 
Part of this Memoir that, besides the so-called “‘ambulacral” canal with its tentacular 
extensions, each Arm and each Pinnule contains an afferent and an efferent canal, in 
which the nutritive fluid is exposed to the aérating influence of the surrounding medium. 
And that this Branchial function is shared by the Tentacular apparatus also, would 
appear alike from the negation already given to its supposed prehensile activity, and 
from its own structure and relations, as will be fully shown hereafter. Such a double 
provision for the function of Respiration has been shown by M. DE QuATREFAGES to be 
very common among the ANNELIDA. 

16. From the foregoing observations and the reasonings based upon them, we seem 
justified in regarding the following as probable conclusions :— 

1. That Antedon, so far from being an active free-swimming animal, has the same 
fixed habit in its mature attached as in its earlier unattached condition; so that in 
regard to its general manner of life, it is not less entitled in the later than in the earlier 
stage of its existence, to rank as a type of the Crinoids generally. 

2. That neither the Arms and their ordinary Pinnules, nor those elongated basal Pin- 
nules which arch over the central disk, have any prehensile action, or any direct con- 
cern in obtaining supplies of food. 

3. That the ordinary Pinnules are specially related to the function of respiration, in 
virtue alike of their proper Branchial canals, and of the ambulacral canals and the 
tubular tentacula with which they are furnished. 

4, That the elongated basal Pinnules, in which the tubular tentacula are wanting, 
are rather related to the function of sensorial protection than to that of prehension. 


IV.—STRUCTURE OF THE SKELETON. 


1. Of the Skeleton generally, with its Ligaments and Muscles. 


17. The component pieces of which the Skeleton of Antedon is made up, alike in its 
adult condition and in every previous phase of its existence, present a remarkable 
accordance with each other in elementary structure; consisting throughout of that 
calcareous reticulation'—formed by the calcification of an animal basis that seems 


1 This reticulation appears to have been first noticed by Professor J. Mtzrer in 1841 (Uber den Bau des Pen- 
tacrinus) as constituting the skeleton of the recent Pentacrinus of the Antilles. It was more fully described by 
Professor VALENTIN in 1842 (Anatomie du genre Echinus) as presenting itself in the shell and spines of that 


DEVELOPMENT OF ANTEDON (COMATULA, LAMK.) ROSACEUS, 703 


nothing else than non-differentiated sarcode—which I have shown (/oc. cit.) to be the 
essential constituent of the skeleton in every type of the Class Ecurmnopermata, The 
character of this reticulation is best seen either in very thin sections of any portion of 
the skeleton (Plate XXXY.), or in that curiously-inflected cribriform lamina (Plate 
XXXIII. figs. 9-11) which I have termed the “ rosette” () 35). This is the only part 
of the skeleton of the adult Antedon in which the reticulation lies all in one plane; 
but, as Professor Wyvitte THomson has already shown, even its most solid portions, 
such as the First Radials, make their first appearance in the same form of cribriform 
lamelle (Plate XLI. fig. 1); and whilst these lamelle increase in superficial dimensions 
by the extension of the reticulation from their margins, they are augmented in thickness 
also by an extension of the reticulation from their inner surfaces into the animal 
basis in which they are imbedded.—When a portion of the skeleton, either from a fresh 
or from a spirit-specimen, is subjected to the action of dilute nitric or hydrochloric acid, 
by which the calcareous network is dissolved away, a continuous film of pellucid sarcodic 
substance is left, presenting no other trace of structure than in being studded at regular 
intervals with minute granular spots (Plate XLIII. fig. 1). The precise accordance of 
these spots, both in size and distance, with the meshes of the reticulation, leaves little 
room for doubt that whilst the pellucid sarcodic substance is the basis of the calcified 
network itself, the granular glomeruli occupy its interspaces. From the behaviour 
of this basis-substance with reagents, it seems to correspond closely with the plasma 
of the higher animals and with the sarcode of the lower; the pellucid substance being 
apparently albuminoid in its nature, whilst the granular spots are partly composed of 
oil-molecules. 

18. The pieces of the skeleton are held together by Ligaments, which consist of 
minute well-defined fibres bearing a strong resemblance in aspect to those of the Yellow 
Elastic substance, but not (like them) capable of resisting the action of strong acetic 
acid. ‘The diameter of these fibres (Plate XLIII. figs. 3, 34) does not exceed ~s}o5 of 
an inch; they usually run straight and parallel, but sometimes cross each other obliquely. 
Their attachment to the pieces of the skeleton which they connect is peculiarly firm; and 
this firmness is found to depend, when we examine portions of the skeleton that have been 
subjected to decalcification, on the passage of the fibres into the basis-substance of the 
skeleton itself (§ 27); much as the fibres of ligaments attached to bones are continuous 
with their fibroid basis, or as the fibres of tendons attached to cartilages pass into their 
intercellular substance. From the position and action of the ligaments connecting the 
pieces of the skeleton of Antedon, I think it is clear that some of them are simply 7nter- 
articular, having for their function to tie these pieces together, but allowing a certain 


genus. And haying myself independently discovered it, I was at the same period engaged in tracing it through 
all the leading types of the class Ecurvopgrara, fossil as well as recent ; the results of which inquiries were 
made known in the Annals of Natural History, vol. xii. (1843) p. 377; and more fully in the Reports of the 
British Association for the year 1847. 


MDCCCLXVI. 5D 


704 DR. W. B. CARPENTER ON THE STRUCTURE, PHYSIOLOGY, AND 


freedom of movement between them; whilst others are decidedly elastic, their action 
being to antagonize muscles, as in many other well-known cases among Vertebrate and 
Invertebrate animals. Where a firm union is required, without power of movement 
between one segment and another,—as we shall find to be the case in regard to the 
pieces which form the basis of the calyx,—there is no ligamentous connexion, but simply 
an adhesion of expanded surfaces, closely fitted to each other, and held together by the 
continuity of their sarcodic basis-substance. 

19. The segments of the Arms and of their lateral pinne, and to a certain extent 
those of the Rays which bear them, are made to move one upon another by a highly- 
developed Muscular apparatus. This consists of fibres (Plate XLIII. fig. 4) which 
resemble those of the ordinary muscles of Terebratulw’ in their general appearance 
and their want of mutual cohesion. They are cylindrical, or somewhat flattened, and 
show no trace whatever of transverse striation (Plate XLIII. fig. 4, a). Their diameter 
is about zs)o0 Of an inch; and I have not been able to resolve them into more minute 
elements. Interspersed among them are numerous spheroidal corpuscles ranging in 
diameter from about zodo0 to goloo Of an inch: similar corpuscles of hemispherical or 
elongated form are frequently to be seen adhering to the edges of the fibres by their 
flattened faces (a, 6); and sometimes elongated corpuscles are observable, over which the 


border of the fibre seems continuous (¢). What is the Histological import of these cor- 
puscles, does not seem very clear. I do not find that either they or the fibres are spe- 
cially affected by the ordinary reagents. The fibres expand a little at their terminations 
(fig. 4, z), so as to come into closer union than elsewhere ; and these expanded terminations 
are simply applied to the surfaces of the calcareous segments to which they are attached, 
not passing into their substance ; so that the muscular bundles are easily torn away en 
masse, leaving no such roughness behind as when a ligamentous connexion is similarly 
treated. From the entire absence of anything like Sarcolemma or Connective tissue, the 
fibres are very easily isolated from each other; and there is no difficulty in tracing the same 
individual fibres from one point of attachment to the other through the whole length of 
the muscular bundle, which is sometimes as much as 345 of an inch. The entire absence 
of any other component in the substance of these Muscles is a point of no little interest. 
After careful and repeated examination of them, I feel justified in stating that they show 
no trace either of Blood-vessels or Nerves; yet the evidence already given (§§ 9, 15) 
from observation of the habits of the living Antedon, shows that in energy and rapidity 
of muscular action it surpasses every other known animal of its class. When we come 
to study the Nutritive apparatus, we shall find that although no Blood-vessels pass into 
the substance of the Muscular bundles, their swrface forms the floor of a canal filled 
with nutritive fluid, for the aération of which there is a special provision in the wide 
expansion of the Arms. The mode in which Nervous influence is conveyed to them is 
a problem of greater difficulty. It will be shown in the Second Part of this Memoir, 


* See Mr. Hancocx’s Memoir “ On the Anatomy of the Brachiopoda,” in Philosophical Transactions for 1858, 
p. 804. 


DEVELOPMENT OF ANTEDON (COMATULA, LAMK.) ROSACEUS. 705 


that the cord which traverses the length of the Arms between the canal just mentioned 
and another canal that overlies it, and which was regarded by Professor MULLER as a 
nerye, really belongs to the Reproductive apparatus. But it will also be shown that a 
regular system of branching fibres proceeding from the solid cord (described by Professor 
MULLER as a vessel) that traverses the axial canal of each calcareous segment of the Rays 

nd Arms (§§ 54, 45) is traceable on the extremities of the muscular bundles; and reasons 
will be given for regarding these fibres as probably having the function of Nerves, though 
not exhibiting their characteristic structure. 


2. Of the Component Pieces of the Skeleton. 


20. In accordance with the nomenclature now generally adopted in describing the 
CrivomeEa, I shall distinguish the pieces of the skeleton as belonging (1) to the Stem, 
(2) to the Calyx, and (3) to the Arms. 

21. Stem.—As the body of Antedon, although attached by a stalk during the Crinoidal 
stage of its existence, becomes free by separation from this as it approaches maturity, its 
skeleton might not be expected to include any representative of the Crinoidal stem. 
Such a representative, however, unquestionably exists in the central protuberant plate, 
to the convex surface of which the Dorsal Cirrhi are attached, whilst its ventral surface 
gives support to the First Radials. The real nature of this plate was discerned by the 
acute Naturalist to whom we owe our first scientific acquaintance with the Crinoid type ; 
the following description being given of it by Mr. J. S. Minuer (Crinoidea, p. 129) :— 
“* At the base of the subglobose body of the Comatulw exists a pentagonal unperforated 
plate, slightly convex externally, and concave on the inside. Jt ts analogous in situation 
to the first columnar joint of the Crinoidea; but as it is not required to transmit the 
passage to the alimentary canal (no prolongation of the column existing in this animal), 
it is without central perforation”’. The true homology of this central plate was also dis- 


1 The above description must be taken in connexion with that of the “ Pelvis” in the succeeding paragraph. 
“On the margin of the pentagonal plate rests an annular plate resembling the rim of a basin, and forming with 
the former a basin-like cavity, which appears to occupy the place of the pelvis of the Pentacrinite. At the 
upper edge this’ pelvis-like plate is pentagonal, having between each of the angles a horseshoe-like impression 
for the insertion of the first costal joint. Externally numerous auxiliary side arms [the ‘dorsal cirrhi’ of 
Lamarcx and most succeeding authors] proceed from the pelvis-like plate, which, when they are broken off or 
removed, show the exterior surface of the plate marked with concaye impressions (the points of their insertion), 
each surrounded by a hexagonal rim more or less perfect, according as their situation is near the central or the 
marginal circumference of the plate.” It would hence appear that Mriter was led by his idea of the homo- 
logies of the centro-dorsal plate to regard it as composed of two pieces, one forming the bottom of the basin, 
the other its sides and rim. This, however, is certainly not the case; since not only does the most careful ex- 
amination of the plate in its mature form show no trace whatever of such separation, but its unity is clearly 
shown by the history of its development.—The latter part of the above-cited description of the “ pentagonal 
plate” is based on the idea that the canal which passes down the centre of the Crinoidal stem lodges a con- 
tinuation of the Digestive cavity. This has been shown by Professor J. Mirurr to be quite untrue as regards 
the recent Pentacrinus Caput-Meduse ; and I shall hereafter show that nothing of the kind obtains in the 
Pentacrinoid stage of Comatula. At a time when so little was known of the Anatomy of the Echinoderm type, 


dD 2 


706 DR. W. B. CARPENTER ON THE STRUCTURE, PHYSIOLOGY, AND 


cerned by Professor J. MULLER, who was led by his comparison of the component pieces of 
the calyx of Comatula with those of the calyx of Pentacrinus Caput-Meduse@ to perceive 
that the ‘‘ centro-dorsal” or “ knopf” of the former is the representative of the highest 
joint of the stem of the latter; the annulus formed by the adhesion of the First Radials 
resting in each case upon its upper surface. The correctness of this view is placed 
beyond all doubt by the study of the development of this “ centro-dorsal plate :” for, as 
I shall show in more detail hereafter (Sect. V.), this plate first presents itself in a form 
which nowise differentiates it from the other joints of the cylindrical stem; but begins 
to take on an extraordinary increase in a peripheral direction at the time when the 
dorsal cirrhi first sprout forth, and thenceforward remains in closer connexion with the 
Calyx than with the rest of the Stem, from which it separates itself so soon as the dorsal 
cirrhi are sufficiently developed to serve for the attachment of the animal. 

22. The Centro-dorsal plate’ has the form of a shallow basin, with thick walls, and 
lip turned inwards instead of outwards (Plate XX XIII. figs. 4, 5,6). Its outer margin, 
without departing much from the circular form, approaches the pentagonal sufficiently 
to justify the designation given to it by J. S. MILLER; and the margin of its inverted 
rim, forming the boundary of the opening into its cavity, is also slightly pentagonal. 
The diameter of this plate, in a full-grown Antedon, is about *16 inch; and its whole 
depth ‘07 inch, of which about half is the depth of its cavity, and the other half the 
thickness of its bottom. ‘The thickness of the peripheral portion of its wall, how- 
ever, to which alone the dorsal cirrhi are attached, is about twice that of the deepest 
part of the basin; as is shown in the vertical section represented in Plate XXXYV. 
fig. 2. The central portion of the convex dorsal surface, by which the centro-dorsal 
plate was originally articulated to the joint of the stem next beneath, is nearly flat, and 
shows no peculiarity. But the entire peripheral portion is marked out into distinct 
sockets for the articulation of the dorsal cirrhi. These sockets are more or less circular 
depressions, separated by intervening ridges; and from the bottom of each depression 
there rises a tubercular elevation having a minute perforation in its centre. About 
forty sockets may usually be counted in a full-grown specimen, disposed for the most 
part in two rows, one alternating with the other (Plate XX XIII. fig. 5). Of these 
sockets, however, there are usually some to which no cirrhi are attached; these, which 
are generally the nearest to the centre of the disk, are distinguished by the partial 
filling-up of their cavity, so that the intervening ridges and the central tubercles become 
less conspicuous, and by the absence of perforations in the latter. ‘The meaning of this 
difference will become obvious, when we follow out the development of the Centro-dorsal 
plate and its appendages (§§ 75, 86-88), and mark the transference of the prehensile 


Mittrr’s hypothesis was not so untenable as we haye since come to regard it; but the unhesitating tone in 
which the penetration of the stem by the Alimentary Canal is spoken of throughout Muixrer’s Treatise, should 
furnish a warning against any such assumption, 

1 The “ centro-dorsal piece ” of many authors is compounded of the true centro-dorsal plate and of the penta- 
gonal base or cirelet of first radials which closely adhere to it and to each other ($$ 23, 31). 


DEVELOPMENT OF ANTEDON (COMATULA, LAMK.) ROSACEUS, 707 


apparatus from the central to the peripheral portion of its convex surface, which is 
effected by the successional development of new cirrhi at the growing margin, whilst 
those which were originally implanted around the surface of articulation with the next 
joint of the stem appear to be cast off. 

23. The upper or ventral surface of the Centro-dorsal plate (Plate XX XIII. fig. 6) 
which is formed principally by the thick wall of the basin, but partly also by its inturned 
lip, is nearly flat; being slightly elevated between the angles of its external and its 
internal pentagons, and somewhat depressed in the intervening spaces. The elevations 
correspond with the lines of junction of the First Radials that rest upon it; and the 
depressions with the convexities of their dorsal surfaces (fig. 2). Its adhesion to the 
under side of the annulus formed by the First Radials is so close, that the line of 
junction is not readily distinguishable in a vertical section of the ‘ centro-dorsal piece ” 
compounded of both (Plate XXXV. fig. 1, @, a) ; and it is generally more easy to break 
away the centro-dorsal plate piecemeal, than to detach it as a whole from the annulus 
of first radials,—unless the composite piece has been boiled in a solution of caustic 
alkali, which dissolves the organic substance whereby they are cemented together, 
Round the margins of the internal pentagon, we commonly find five shallow depressions 
(Plate XX XIII. fig. 6, @, @) which correspond with the extremities of the elongated 
spout-like processes of the ‘‘rosette” (9 35); these, however, are seldom as strongly 
marked as in the figure, and are sometimes wanting altogether. 

24, The internal surface of the wall that bounds the cavity of the basin is marked by 
minute punctations (Plate XX XIII. fig. 6), which are the internal orifices of canals that 
proceed from the interior cavity of the Centro-dorsal plate to the centres of the tubercles 
in the sockets on its convex or dorsal surface. The course of these canals, whose diameter 
averages =o Of an inch, is shown in sections of the basin taken either perpendicular 
or parallel to its upper flattened surface (Plate XXXYV. figs. 1,4, 0,0). In such sections, 
when sufficiently magnified, it is also to be observed that the calcareous network which 
forms the basis of each socket is more solid than that of the general substance of the 
plate; its meshes being closer, and arranged with a regularity not observed elsewhere 
(fig. 4,¢,¢). This is conformable to what is seen in the test and spines of Echinus; the 
articular tubercles of the former and the basal cups of the latter being composed of a 
peculiarly close calcareous reticulation’. When this centro-dorsal plate is decalcified, 
the animal basis is found particularly firm at these spots, each socket having a membranous 
disk of its own, which is traversed by very fine ligamentous fibres having a radiating 
arrangement ; and by the convergence of these fibres is formed the interarticular liga 
ment which binds the first joint of the dorsal cirrhus to its articular socket. 

25. Dorsal Cirrhi.—The dorsal surface of the calyx of Antedon is ordinarily in great 
degree concealed by the cluster of Dorsal Cirrhi, which radiate from the convex surface 
of the centro-dorsal plate (Plate XXXII. fig. 4), and which extend, when straightened 


1 See Professor VaLentin’s Monograph ‘ Anatomie du genre Achinus, pp. 20, 31, figs. 16, 17, 36, 38.—My 


own preparations of these structures fully bear out Professor Varenvin’s descriptions, 


708 DR. W. B. CARPENTER ON THE STRUCTURE, PHYSIOLOGY, AND 


out or nearly so, considerably beyond the margin of the disk. These appendages, for 
which it seems to me that the designation given by Lamarck and adopted by Dusarpin is 
the most appropriate, were termed by J. S. MILLER “ auxiliary side arms,” by BLAINVILLE 
* yayons auxiliaires,” by Professor J. MULLER “ ranken,” and by Professor EDwaRD FoRBES 
“ filaments, jointed appendages, or simple arms.”’ Any name which indicates a resem- 
blance between these cirrhi and the Rays or Arms belonging to the calyx, is most inap- 
propriate ; since the two sets of organs have no other point of resemblance than that 
which consists in the articulated structure of their skeleton, whilst they differ in toto 
as regards both their homological relations and their functional uses. The designations 
respectively applied to them by J. S. Minter and by BuiainviLin were so far correct, as 
indicating their homology with those appendages of the stem in Pentacrinus which 
these authors distinguished by the same terms; and it is expressly stated by the former 
that “ these arms, the formation of their joints, and their hook-like termination, resemble 
in every particular those of Pentacrinus Caput-Meduse, only that they are much shorter, 
and formed of a less number of joints.” That the “dorsal cirrhi” of Antedon have no 
other function than that of mechanically fixing the animal, appears alike from the 
extreme simplicity of their structure (which presents not the smallest trace of the com- 
plex apparatus that is extended throughout the whole of the true brachial appendages), 
and from observation of the animal in its living condition, as I have already shown in 
the description of its habits ($$ 9, 10). 

26. The number of the Dorsal Cirrhi in Antedon rosaceus is by no means constant, nor 
is their size uniform. It is by no means uncommon to find, even on the largest speci- 
mens, one, two, three, and sometimes more of these organs in a very rudimental condi- 
tion; such being usually interposed between the larger ones at the extreme circum- 
ference of the Centro-dorsal plate. In order to ascertain the range of variation in this 
character (to which some systematists attach considerable importance in the discrimina- 
tion of species), I have carefully removed and laid upon separate tablets the entire clus- 
ters of cirrhi possessed by twelve Arran specimens, which, although differing in size, 
all presented every appearance of maturity; and I find the respective numbers of these 
organs to be as follows :— 


I. 21, of which 3 were rudimental. VII. 27, of which 3 were rudimental. 
WG Be e 4 “4 WAUUE 24) - 2 9 
iT. 25, 4 3 eS IX. 29, . 0 x 
TV.25, a 7 | xX. 7305 +4 2 é 

V. 2b, Bs 3 DG as ; 4 “ 
WA Ate 3 - AI: 32; = it 0 


Thus it appears that Professor Epwanp ForBEs was not far wrong in stating the number 
of these organs to be from twenty to thirty’. I cannot, however, by any means agree 


1 History of British Starfishes, p. 7. The number of cirrhi in Comatula Mediterranea is stated by Lamarck 
at 30, by Professor Jon. Mitrer at 30-40, and by Dusarpry at 20-26.—I have lately had the opportunity, 
through the kindness of Mr. J. Gwxx Jrrrreys, of examining a yariety of Antedon rosaceus from the coast of 


DEVELOPMENT OF ANTEDON (COMATULA, LAMK.) ROSACEUS. 709 


with him in the following statement (op. ctt., p. 7): ‘‘These filaments are not all alike ; 
there are two kinds of them. ‘The larger have fourteen joints, and a small thick, blunt, 
curved claw, which is smaller than the joints, and has a horny lustre: the smaller fila- 
ments have eighteen rough joints, and an almost straight claw, which is larger than the 
joints preceding it.” Tshall presently show that the first-named form is that of the fully 
developed cirrhus, whilst the latter (save as to the number of joints) is that of the same 
organ in an earlier stage of its development; and that occasionally (though rarely) the 
rudimental form is retained with an increase in the number of joints beyond the average. 
In each of eleven out of the twelve specimens, in which I have examined the cirrhi with 
great care, I have found the predominant number of segments, excluding the one which 
bears the claw, to be 15; but in at least one-third of the cirrhi in each of these speci- 
mens (excluding those which retained their rudimental characters) the number of 
segments is below that standard, ranging from 14 to 10, and in a few instances to 9. 
In the single exceptional specimen, the predominant number of segments was 16, and 
one cirrhus had 17 (besides the claw); and this number I have never found exceeded, 
though the whole number of cirrhi whose joints I have counted exceeds 300. In two 
cirrhi retaining the rudimental form, I have counted 17 segments besides the claw; 
but I have never found this number exceeded’. 

27. The typical form of the Dorsal Cirrhi is represented in Plate XXXII. fig. 5, a; 
in which we notice (1) that the cirrhus is curved along a great part of its length in the 
same direction as its terminal claw, the distinction being thus marked between its 
convex or oral and its concave or aboral border; (2) that the basal segments are short, 
their diameter considerably exceeding their length, and are cylindrical, or nearly so; 
(3) that there is a progressive increase both in the length and in the diameter of the 
segments as far as the 11th joint, this increase being at first so much more rapid in 
length than in diameter that the 5th, 6th, 7th, and 8th segments are considerably longer 
than they are broad, approaching the proportion of 5: 2°, with some degree of lateral 
compression ; (4) that beyond the 11th joint the length of the segments again dimi- 
nishes, their diameter remaining nearly the same; (5) that the last segment has attached 
to it by simple suture a strong, sharp claw, and is itself prolonged at the base of this, 
on its aboral margin, into a short pointed opposing process*. Between the segments is 


Ross-shire, one specimen of which possesses 42 dorsal cirrhi of which 7 are rudimental, and another 46 of which 
8 are rudimental. 

1 The number of joints in the cirrhi of Comatula Mediterranea is stated by Professor J. Mitier to be 18-20, 
and by Dvsarpry to be about 20. 

2 Tam particular in the statement of these proportions, because they have been employed on insufficient 
grounds (as I believe) by Professor Wyvirte Tuomson as a character of specific distinction between A. rosaceus 
and A. Milleri. 

3 This process, as I shall presently show, is almost always wanting in cirrhi which have not attained their full 
development; and as it is not unfrequently absent in such as show no other characters of immaturity, I 
cannot agree with Professor Wrvittz Tuomson (Joc. cit.) in regarding the possession of this opposing process as 


a valid specific character of A. rosaceus. 


710 DR. W. B. CARPENTER ON THE STRUCTURE, PHYSIOLOGY, AND 


interposed a ligamentous (not muscular) substance; this is seen in the basal joints to 
be as thick on the oral side as it is on the aboral; but as we advance towards the middle 
of the cirrhus, the thickness of the interarticular substance is seen to be much greater on 
the aboral side, the form of the segments being so modified as to admit of considerable 
flexure in that direction, whereby the prehensile power of the claw is much increased. 
When a cirrhus is subjected to decalcification, it is found that this interarticular sub- 
stance corresponds with the general sarcodic basis of the skeleton in every particular, 
save in the great abundance and regular distribution of its fibrous component. The 
fibres can be distinctly traced passing straight and direct between the articular surfaces 
(Plate XLIII. fig. 5), not terminating there, however, as do the muscular fibres (§ yy 
but becoming incorporated with the basis-substance of the calcified segments. And it 
seems clear from the history of the development of these organs, that the basis-sub- 
stance of the calcified segments and the interarticular substance which connects them, 
are originally similar ; but that whilst the former is altered by the deposit of its calca- 
reous reticulation, the latter is changed by the augmentation of its fibrous component. 
The connexion of the basal segment with the socket of the centro-dorsal plate to which 
it is articulated, is effected by precisely the same kind of ligamentous substance (§ 24). 

28. When the segments are separated by boiling in a solution of potass, and their 
opposed faces are examined (Plate XX XITI. fig. 8), it is seen that each is perforated by 
an axial canal of about one-fifth of its diameter, around which is a projecting articular 
surface; and that on the oral and aboral sides of this projection there are two depres- 
sions for the lodgment of the interarticular hgament. In the basal segments (a), the 
canal with its surrounding projection is central, and the oral and aboral depressions are 
of equal size, or nearly so; but in the terminal segments (4) the canal and articular sur- 
face are nearer the oral side, and the ligamental depression is both larger and deeper on 
the aboral. This difference is still better seen in longitudinal sections of these two por- 
tions of the cirrhus respectively (Plate XX XY. figs. 2,3); in which also we observe that 
the terminal claw is attached to the last segment at a, a, by a plane surface admitting of 
no movement, the two being held together by continuity of their animal basis-substance. 
When a thin portion of such a section is examined with a sufficient magnifying power, 
the calcareous reticulation is seen, as in other cases (§ 24), to be much closer at the 
articular surfaces than it is elsewhere; and in the portion of the last segment which is 
prolonged into the opposing process (fig. 3), the reticulation is covered with a layer of 
homogeneous shell-substance like that which forms the solid pillars in the spines of the 
Ecninipa. Of this substance nearly the whole solid shell of the terminal claw is com- 
posed, its interior, however, being occupied by a large cavity which is continuous with 
the axial canal (c, c) of the cirrhus, and the inner layer of its wall having the characteristic 
reticular structure. 

29, The Axial Canal which thus runs from the base to the apex of each Cirrhus, is 
continuous at its base with the canal which passes from the concavity of the Centro- 
dorsal plate to the summit of each articular tubercle (} 24). It was supposed by Professor 


DEVELOPMENT OF ANTEDON (COMATULA, LAMK.) ROSACEUS. 711 


J. Miuuer, who first noticed its presence, to be occupied by a nutrient vessel, proceeding 
from an organ contained in the basin-shaped cavity of the Centro-dorsal plate, which he 
designated as a heart, and from which he asserted that similar but much larger vessels 
pass off into the Radial plates, and thence by bifurcation into the Arms. I am perfectly 
satisfied, however, that these axial canals are occupied by cords of unconsolidated sarcodic 
substance; and that the central organ from which they proceed is developed out of the 
original Crinoidal Axis. How far these cords are subservient to the nutrition of the 
organ, or to the maintenance of its vitality, is a question that will be fully considered 
when the structure and function of the central organ to which they are related come 
under review, in the Second Part of this Memoir. 

30. Having thus described the structure of the typical Cirrhus and of its component 
pieces, I have to speak of the cirrhi whose condition departs more or less widely from 
that type. In almost every specimen of Antedon we find cirrhi which do not present all 
the characters of maturity; and there are very commonly some whose condition is quite 
rudimental, corresponding to that which will be described in detail when the develop- 
ment of the several pieces of the skeleton is being traced out (966). Such a one, repre- 
sented at )(Plate XXXII. fig. 5), is seen to consist of eight minute cylindrical segments, 
of which the basal is the largest, and of which the terminal is rounded off without any 
appearance of a claw. At cis shown a more adyanced stage of the same rudimental 
form; the segments having increased in length and diameter, but without showing any 
other change. At d we have a cirrhus which still presents the same rudimental form of 
the segments, but these have increased in number to fen, and the last segment carries 
a small claw; and the same condition is still presented at e, though the number of seg- 
ments has increased to twelve. At f, however, we not only see an increase in the size 
and number of the segments, of which there are sixteen besides the terminal claw, but 
there is an incipient bevelling-off of the opposed faces of the segments on their aboral 
side, which indicates an advance in development towards the mature type; and the 
basal segments are equalled in diameter by those which follow. It is comparatively 
rare, however, to find the rudimental form still exhibited by cirrhi which have attained 
dimensions so considerable; the shaping-out of the segments often taking place when 
they are still of very small size, and the terminal claw presenting its characteristic form 
almost from the first.. This course of development is seen in the series marked 
q, h, 7, k, l, m;—in which it is to be observed that the basal segments are even from 
the first of no larger diameter than the rest; that the mature proportions between the 
length and breadth of the segments are shown at a very early period (); that the bevel- 
ling-off of the opposed faces on the aboral side takes place (¢) when both in number and 
dimensions the segments are very immature; and that in a cirrhus (/) whose length and 
diameter do not exceed one-eighth of the normal standard shown at @, all the characters of 
maturity are presented by the individual segments, even to the development of the oppo- 
sing process on the penultimate segment. Hence between this and the typical mature 
cirrhus, the only difference consists in the number and size of the segments. At” is seen 

MDCCCLXVI. 5 E 


712 DR. W. B. CARPENTER ON THE STRUCTURE, PHYSIOLOGY, AND 


a cirrhus which consists of the typical number of segments, and which presents the 
general characters of maturity except as regards the form of the claw, but has not 
attained above three-fifths of the full length; this may obviously have been produced 
either by a more advanced development of the large rudimental form represented at f, 
or by the process of simple increase in the small mature form shown at m.—The augmen- 
tation in the number of segments I believe to be effected by the interposition of new 
segments at the base, this being the part at which they are of the smallest dimensions 
and have most the appearance of immaturity. ‘The augmentation in size is produced by 
addition to every part of the surface of the segment, this being imbedded (so to speak) 
in the animal basis-substance, into which the calcareous reticulation extends itself from 
the part previously solidified. It is to the large size of the meshes of that reticulation in 
the rudimental segments, that the roughness of their surface is due: as they approach 
maturity, the reticulation formed on the exterior of the old becomes closer, so as to 
give greater compactness of texture and smoothness of surface; and this is especially the 
case, as already mentioned, with that which forms the articular faces. 

31. Pentagonal Base of the Calyz.—When the Centro-dorsal plate has been detached 
from the rest of the Calyx (which is readily effected by boiling for a short time ina 
dilute solution of caustic potass), we find the basis of the latter to consist of a penta- 
gonal disk, formed by the close mutual adhesion of the five First Radials. The com- 
position of this disk is obvious enough when we look at the smooth dorsal surface 
(Plate XXXII. fig. 2) which was adherent to the margin and inverted lip of the centro- 
dorsal basin; the quinary division being clearly marked out by five radiating sutures. 
But on its ventral aspect (fig. 3) the sutures are less distinguishable, owing to the 
peculiar inequality of the surface. ‘The inner portion of the pentagonal base forms a 
sort of funnel, that slopes inwards to the central space; and the walls of this funnel 
present an alternation of radiating ridges and furrows, of each of which there are ten. 
Five of the furrows correspond with the divisions between the component pieces; and 
of the ridges which bound them, one belongs to each of the two adjacent Radials. Of 
the other five furrows, ene passes along the middle of each of the five Radials; and both 
the ridges which bound it belong to the same piece. The outer portion of the ventral 
face of the pentagonal base consists of five surfaces inclining outwards, and marked by 
peculiar ridges and fossze which will be better described when the separate pieces of this 
disk come under view (§ 33). Turning again to the dorsal aspect, we find the central 
vacuity of the pentagonal disk to be occupied by a single plate of extremely delicate con- 
formation and peculiarly inflected shape (Plate XX XIII. figs. 2,9); which I do not find 
to have been noticed by any of those who have previously described Antedon, and which, 
for the sake of facility of reference, I shall term the Rosette. I shall hereafter show, 
however, that it is really a composite structure, formed by the coalescence of outgrowths 
from the five Basal plates which constituted the primitive foundation of the calyx (§ 59), 
the original plates having been themselves almost entirely removed by absorption (§ 90). 
Its peripheral portion is so closely applied to the internal faces of the Radials of 


DEVELOPMENT OF ANTEDON (COMATULA, LAMK.) ROSACEUS. 713 


which this pentagonal base is composed, as to seem in absolute continuity with them 
(Plate XXXYV. fig. 1, f); whilst its central part also is frequently connected with it 
by delicate processes, which sometimes sprout forth irregularly from the inner margins 
of the component pieces of the pentagonal disk, but sometimes form a more regular 
ingrowth, which considerably contracts the central space on the ventral aspect of the 
disk (Plate XXXITI. figs. 1, 3), and becomes continuous with an annular projection 
from the ventral face of the rosette. 

32. The Pentagonal Base may be readily separated, after continuous boiling in the 
potass-solution, into its component First Radials, their mutual adhesion, and their 
adhesion to the centro-dorsal plate, being due to the interposition of a thin layer of sar- 
codic substance, continuous with that which occupies the meshwork of their own calca- 
reous reticulation. ‘The extreme fragility of the delicate processes whereby they are 
severally connected with the “rosette,” occasions their detachment from it when they are 
separated from one another. In the adult condition of 4. rosaceus, the “ rosette” itself is 
not resolved into distinct pieces by any amount of boiling; although in its immature 
stage it is readily separable into five component plates (§ 90).—The pieces of which the 
Pentagonal Base is made up will now be described in detail. 

33. First Radials—KEach of these pieces has a well-marked triangular form, the 
apical portion of the triangle, however, being deficient (Plate XXXVI. fig. 1, c, D). 
We may distinguish its ventral and its dorsal faces (c, D), the former looking towards 
the concavity of the calyx, whilst the latter is in contact with the centro-dorsal plate ; 
its internal face (B) bordering the central space of the pentagonal disk; its two Jateral 
surfaces (B, 7, 7) by which it adheres to its fellows; and its external face (A), by 
which it is articulated with the Second Radial. The ventral face (c) is divided by two 
curved ridges (d, d), bending towards each other along the median line, and there sepa- 
rated by a furrow, into a central and a peripheral portion, the former sloping inwards, 
so as to contribute to the formation of the central funnel; whilst the latter slopes 
outwards, so as in fact to become part of the external face of the plate. The dorsal 
face (D) is slightly convex, but is free from irregularity, except that there is a deep 
notch (/) in the centre of its inner margin. The two lateral faces (B, 7, 7) are perfectly 
flat; and their only feature is a large aperture (g, g) which each presents towards its 
internal margin. ‘The internal face (8), which is comparatively small and irregular, shows 
near its dorsal margin a pair of large apertures (e, e), the edges of which are raised 
so as to leave a distinct furrow (/) between them; this furrow, which has shown itself as 
a notch in the inner margin of the dorsal face (p, /) is continued onwards towards the 
ventral margin, but is more or less interrupted by the irregular processes which extend 
themselves to meet the rosette (§ 31), and which not unfrequently complete these furrows 
into canals (Plate XX XIII. fig. 1)—The external face is divided by a strong transverse 
ridge (A, @, a) into an upper and a lower portion; and the upper is again divided by a 
less elevated transverse ridge, and by median continuations of the ridges already noticed 
on the upper surface, into two pairs of fossie, b, 6, and c,c. Of these the upper pair 

DE2 


714 DR. W. B. CARPENTER ON THE STRUCTURE, PHYSIOLOGY, AND 


are the deeper; and they afford a surface of considerable extent for the attachment of 
the two great flexor muscles of the Ray, which fill up the whole space between the upper 
transverse ridge and the convex margins of the vertical plates, having an attachment also 
to the prolongations d, d of those plates, which stand forth as ridges bounding the median 
furrow. The shallower fosse (0, 6) give attachment to énterarticular ligaments, of which 
the special function seems to be to hold together the plates; since I have always found, 
in pulling them asunder, that the greatest resistance is offered at this part of their 
articulation. ‘The median furrow leads down to the large oval opening (e) of the radial 
canal, which partly interrupts the great transverse ridge. Below this ridge is a fossa 
(f) extending across the whole breadth of this surface, but especially deep in its median 
portion, for the lodgment of the elastic ligament which antagonizes by its extensile 
action the action of the flexor muscles.—The general disposition of the five pairs of 
flexor muscles passing between the First and the Second Radials, is shown in Plate 
XXXIV. fig. 2, m', m'. 

34. On removing the dorsal surface of the Pentagonal Base by the careful application 
of an acid (Plate XXXIII. fig. 1), or by making a section parallel to its dorsal surface, 
and in the plane of the openings which we have noticed in the internal, external, and 
lateral surfaces of each First Radial (Plate XXXIV. fig. 1, 4, B), we find that these all 
belong to one system of Canals extending radially from the central space, and also 
forming an annulus around it. The two apertures on the internal face of each First 
Radial (§ 33) lead to two canals which converge towards each other, and which very 
quickly meet, so as to form a single canal (a, @) which passes directly towards the 
external margin; whilst each of the converging canals gives off a large lateral branch 
(6, 6), which meets a corresponding branch in the adjacent radial; and thus the five 
great Radial Canals are intimately connected at their origin by an arrangement that 
reminds the Anatomist of the “ Circle of Willis” at the base of the Brain. 

35. Rosette—The peculiarly-shaped circular plate which occupies the central vacuity 
in the Pentagonal Base (Plate XX XIII. figs. 2, 9), and which is shown detached in 
figs. 10, 11, may be described as consisting of a disk perforated in the centre, with ten 
rays proceeding from it, five of these rays (a, a) being triangular in form and nearly 
flat; whilst each of the other five (4, >) that alternate with these has parallel margins 
inflected on its ventral aspect in such a manner as to form a groove, whilst the ray curves 
to its dorsal aspect in such a manner as to bring this groove to the periphery of the 
rosette, and then terminates abruptly as if truncated. Around the central perforation 
we sometimes find on the ventral surface an irregular raised collar, obviously corre- 
sponding to the central passage of the annulus of the pentagonal base; but more com- 
monly this is replaced by a number of vertical processes irregularly disposed (fig. 11). 
Its diameter, in a full-grown specimen, is about ‘045 inch. When we look at this 
“rosette” in situ (Plate XXXIII. fig. 9), we find that the five triangular rays are 
directed to the sutures between the five Radials (a, a), their apices joining the con- 
tiguous pairs of these, just between their two adjacent apertures leading to the radial 


DEVELOPMENT OF ANTEDON (COMATULA, LAMK.) ROSACEUS. 715 


canals; whilst each of the five spout-like rays joins the intermediate portion of one of the 
Radials, the inflected margins of the former being applied to the borders of the vertical 
furrow of the latter, in such a manner that the two grooves are united into a complete 
canal (0, 6). Notwithstanding the apparent continuity between the calcareous reticula- 
tion of the Rosette and that of the Pentagonal Base at the extremity of each ray of the 
former, I am disposed to think the continuity not real, since, after boiling in a solution 
of potass, the rosette separates itself from the Radials without any positive fracture 
at these points. A real continuity, however, would seem to exist between the central 
prolongations of the first Radials () 33) and the discoidal portion of the rosette, these 
prolongations attaching themselves to it either separately, or after coalescing with each 
other either to a slight extent or so completely as to form the collar just described, 
and the junction being so complete that its separation can only be effected by fracture. 

36. ‘This ‘‘ Rosette,” when viewed only with reference to its own structure and its con- 
nexions with the surrounding base of the Calyx, is one of the most beautiful objects 
with which Iam acquainted. But the interest attaching to it will be found greatly 
heightened, when the extraordinary process by which it is developed from the original 
Basals of the Pentacrinoid larva shall have been explained (§§ 89, 90); still more, when 
its relations to the soft parts lodged in the Centro-dorsal cavity and its Radial Canals 
shall have been displayed in the Second Part of this Memoir. 

37. Second Radials.—Proceeding now to the other components of the Calyx, we find 
the Second Radial (Plate XXXVI. fig. 2) to be a somewhat discoidal plate of elliptic 
figure, having two nearly parallel faces, one internal or central, articulating with the 
First radial, the other eaternal or distal, articulating with the Third radial. The 
internal face (a) is divided transversely (like the external face of the first radial) by a 
prominent ridge (a, a) that also passes round the large oval opening of the radial canal, 
and is then continued on either side of the median line to the upper margin of the plate, 
the two approximated ridges having a furrow between them. ‘The large depressed 
spaces bounded by these ridges on either side, are again marked out by secondary ridges 
into two pairs of fossee corresponding with those on the external face of the first radial 
(§ 33). Of these the upper pair (c, c) are the deeper, and are for the most part bounded 
by a pair of thin lamelle extended upwards from the proper margin of the plate, as is 
obvious when we examine it from the distal side (B, d, d). These lamelle give attach- 
ment to the distal ends of the flexor muscles; while in the shallower fosse (a, 4, 6) are 
lodged the tnterarticular ligameuts. Beneath the great transverse ridge is a broad fossa 
(f) that is particularly deep just beneath the opening of the radial canal (e); this gives 
attachment to the edastic ligament, the tension of which antagonizes the flexor action of 
the muscles. The external or distal face (B) is divided by a vertical ridge (a, a) that 
passes round the opening of the radial canal, into a pair of lateral fossie (, 6), which 
give attachment to the interarticular ligaments that connect the second with the third 
radial, no muscular bands being here interposed. 

38. Third Radials—The Third Radial, when looked-at from above or from below 


716 DR. W. B. CARPENTER ON THE STRUCTURE, PHYSIOLOGY, AND 


(Plate XXXVI. fig. 5, o, D), has a well-marked triangular form, presenting three articular 
faces; of these the central or internal looks towards the external face of the Second radial, 
whilst the face that looks obliquely outwards on either side serves as the base of an Arm. 
The internal face (fig. 8, 4) corresponds very closely to that with which it is articulated, 
being divided, like it, by a vertical ridge, that also passes round the opening of the radial 
canal, into two lateral fossee. When we look at this articular margin of the Third Radials 
from the dorsal side (p), we observe that its two lateral portions slope away in some degree 
from the median prominence ; and this is also seen when we look at the articulation in 
section (Plate XXXIV. fig. 1) or on its ventral aspect (fig. 2). Hence, when the opposed 
ridges of the Second and Third Radials are in contact with each other, the third radial 
would seem to have some power of /ateral movement upon the second. As no muscles, 
however, pass between the second and third Radials, which are connected by ligaments 
only, such movement, if it really exists, can only be attributed to the general contractility 
of the soft parts by which these plates are invested. From the upper margin of the 
internal face (A) we see projecting a pair of lamelle (d, d) which do not form part of the 
surface of articulation with the second Radial, but which enter into the two oblique 
surfaces of articulation with the first Brachials. Each of these last faces (B) is formed 
upon the plan just now described as presenting itself in the opposed articular surfaces 
of the first and second Radials, having the transverse ridge (a, a), the fosse for the 
interarticular ligaments (4, 0), the fossa for the elastic ligament (7, f), and the muscular 
fosse (c, ¢) with their thin vertical lamella, the lamella (d’) that rises from the distal 
angle being common to both the oblique faces. The dorsal surface of this plate (D) 
presents no marked peculiarity; but on the ventral (c) a considerable inequality is occa- 
sioned by the projection of the three vertical lamella. The radial canal, as we should 
expect, here divaricates, one branch passing on to either arm (Plate XXXIV. fig. 1, ¢). 
39. No trace of Interradial plates shows itself in the variety of Antedon rosaceus with 
which I am most familiar,—that, namely, which occurs in the estuary of the Clyde, in 
Strangford Lough, and in Kirkwall Bay. But in specimens from Ilfracombe and from 
Plymouth Sound of what, from their likeness in all other respects, I cannot but regard 
as belonging to the same specific type, I find certain small plates in the angles between 
the Second and Third Radials, which are obviously those referred to by Mr. J. S. MILLER 
in his Comatula jimbriata from Milford Haven as “intercostal plates or joints”’. 
Although Mriier figures only one such plate in each angle (which may be readily 
understood from his having only employed a low magnifying power in examining it), 
yet I find that, generally speaking, it is resolvable by the Microscope into a cluster of 
three or four small plates (Plate X XXIII. fig. 7,8), though it is not unfrequently found 
to consist of an aggregation of several minute bodies (fig. 7, A) scarcely larger individually 
than the fragments of calcareous reticulation often occurring in the ventral perisome 
(Part II.). Moreover I learn from Professor WYVILLE THOMSON that in a specimen recently 
dredged off Shetland by Mr. Baren, these plates were present in three of the angles, but 


1 Natural History of the Crinoidea, Frontispiece, fig. 2, G. 


DEVELOPMENT OF ANTEDON (COMATULA, LAMK.) ROSACEUS. 737 


were wanting in the other two. Hence I cannot but agree with him' in regarding them 
as non-essential parts of the skeleton, belonging to its pertsomatic and not to its radial 
system () 84). 

40. Arms.—Each of the ten Arms formed by the bifurcation of the Rays, is composed 
of a long succession of segments, gradually diminishing in diameter from its base to its 
termination. The nwmber of these segments appears to me to have no definite limit; 
for in every case in which the arm has presented the aspect of completeness, I have 
found its termination exhibiting the same indications of continued growth as are mani- 
fested by it when obviously immature (967). It is remarkable that although the forms 
and proportions of the segments vary widely in different parts of the Arm,—their length 
being four or five times their diameter near its extremity (Plate XX XVIII. fig. 4), 
less than twice their diameter about its middle (Plate XX XVII, fig. 1), and less than half 
their diameter near its base (Plate XXXVII. fig. 3),—this diversity almost entirely 
results from the progressive increase in diameter which shows itself in the segments as 
we pass from the extremity towards the base; the absolute length of the segments being 
nearly the same throughout. The average length of each segment is rather less than 
‘03 inch; and thus in an arm of which the total length is 4 inches, we have about 
140 segments. The general plan of their conformation is everywhere the same, each 
segment being fundamentally a cylindrical rod, perforated by an Axial Canal; and the 
departures from this form have reference chiefly to the attachment of the muscles and 
ligaments at the articular surfaces (Plate XX XVIII. figs. 2, 4). But the diversity in 
the proportions of the segments in the different parts of the Arms gives a great variety 
to their general aspect ; and it will hence be desirable to describe separately the Basal, 
the Middle, and the Terminal portions of the Arms. 

41. Basal Portion —The diameter of the Arms near their base in a full-grown speci- 
men is about ‘07 inch; and this is maintained with little diminution for nearly a quarter 
of their length. When we look at them from the dorsal side (Plate XX XVII. fig. 3), 
we see that the inner margin (that is, the one which looks towards the other arm of the 
same Ray) of their 7st segments is so much shorter than their outer that, whilst the two 
articular facets of the Third Radial incline towards each other at an angle of about 80°, 
that angle is widened-out between the distal articular faces of the two first Brachials that 
rest upon it to about 130°; and that by a similar difference in the length of the inner 
and outer margins of the second Brachials, their distal articular faces are brought nearly 
into the same plane. Generally speaking, a like inequality shows itself between the 
inner and the outer margins of the succeeding segments, but in an alternating manner ; 
so that their dorsal faces have the form of a succession of triangles, the apices of which 
point alternately to one side and the other, their vertical angles being 
about 40°. But there are many departures from the regularity of this 
arrangement; the most frequent being that which is produced by the 
close union of two segments having flattened articular surfaces whose plane is directly 


1“ On the Embryogeny of Antedon rosaceus,” Philosophical Transactions, 1865, p. 540, 


718 DR. W. B. CARPENTER ON THE STRUCTURE, PHYSIOLOGY, AND 


transverse to the axis of the arms, forming what is called a syzygy (sg),—a peculiarity 
which will be presently more fully described () 50). Excepting where syzygies occur, 
each segment after the first bears an articulated pinnule on its wider margin; and thus 
the pinnules spring alternately from each margin of the arm, the total of the two series 
equalling in number that of the segments, the pair forming each syzygy being counted 
as one. The articular facets for the basal segments of the pinnules, which are seen 
when the Arms are viewed on their lateral or their ventral aspects (Plate XXXVII. 
fig. 4, p, p), each consist of a shallow socket divided by a transverse ridge, which is per- 
forated by a minute aperture. In this basal portion of the arms, the articular facet of 
the pimnule encroaches on the distal articular surface of each segment; but in the 
Middle and Terminal portions of the Arms, we shall find that in consequence of the 
change of relative dimensions of the segments, the pinnules are articulated to their 
lateral faces. 

42. Even on the dorsal aspect of the Arms (Plate XX XVII. fig. 3), we notice that 
the margins of the successive segments do not come into close approximation except at 
the syzygies (sg, sg); and the spaces between them are occupied by an elastic ligamentous 
substance, which antagonizes the flexor muscles. ‘These muscles (Plate XX XVIII. fig. 
10) occupy the large spaces which are seen on the ventral aspect of the Arms, when the 
superficial soft parts have been cleared away (Plate XX XVII. fig. 4), to lie between 
the apposed faces of the segments ; each segment being thinned away towards its upper 
or ventral margin into a vertical plate, from the middle of which projects on either side 
a sort of keel that forms a buttress and divides each of the deep fosse left between the 
successive plates into two lateral halves. Where a syzygy occurs (sg, sg), the vertical 
plates of the two segments that form it come into close contact, and the keel projects 
only from one face of each, the two apposed segments thus taking the place of the single 
segment elsewhere. ‘This peculiar contrast between the dorsal and the ventral aspects of 
the Arms is still better brought into view by a vertical section taken a little on one side 
of the axis of the arm, so as not to pass through the projecting keels that divide the 
muscular fosse, and only partially to lay open the axial canal (Plate XXXVIIL fig. 11). 
This shows that the successive segments really come into contact with each other only 
by the great transverse ridges which cross their articular surfaces (Plate XXXVI. 
figs. 4—8, a, a), and embrace the opening of the axial canal; and that the space between 
these ridges and the dorsal surface, which is occupied by the elastic ligament, is much 
larger than it appears externally to be. Of the large space between the axial canal and 
the ventral margin, the part nearest the canal is occupied by the interarticular liga- 
ments which are lodged in the shallow fossz' that are seen on each articular surface just 
above the transverse ridge; whilst the much longer spaces intervening between the 
vertical plates are entirely filled by muscular substance (m, 7), the fibres passing directly 
from each plate to the next in front and behind, except in the case of a syzygy. 


‘ These are termed “articular facets” by Professor Mittrr; but I feel satisfied that they cannot come into 
ccntact with those of the succeeding segment, and that they have the character above assigned to them. 


DEVELOPMENT OF ANTEDON (COMATULA, LAMK.) ROSACEUS. 719 


Between the canal and the dorsal margin are shown the large elastic ligaments, /, J. 
—In Plate XLHI. fig. 6 is shown a similar section of a decalcified Arm, passing 
vertically along the median plane through the axial cord (a, a); so as to bring into view 
the muscles (m, m) lodged in the spaces intervening between the vertical lamella (s', s') 
of the successive segments, the interarticular ligaments (7, 7’) above the axial canal, and 
the great elastic ligaments (/’, ) below it, lodged in the deep fossee of the bodies of the 
segments (s, s).—In fig. 7 is shown a longitudinal section of a decalcified Arm passing 
horizontally through the axial cord (a, a); which exhibits the oblique disposition of the 
elastic ligaments (/’, /’), occasioned by the alternating obliquity of the segments; and also 
shows the interposition of the sarcodic radiations at the syzygies (sg, sq). 

43. When the articular surfaces of the Brachial segments are brought into view by 
separating these segments from each other, we find them for the most part characterized 
by the same features as those which are presented by the opposed surfaces of the First 
and Second Radials ($§ 33, 37). With certain exceptions to be presently noticed, each 
is divided by a transverse ridge (which usually crosses it more or less obliquely) embracing 
the opening of the axial canal; and whilst the single deep fossa below this ridge 
gives lodgment to the elastic ligament by which the arm is extended, the pair of shal- 
lower fossee above it serve for the attachment of the interarticular ligaments; whilst 
above these, again, are the pair of deep fossw, formed by the recession of the vertically 
projecting lamelle, in which the flexor muscles are lodged. From the peculiar shape of 
the brachial segments (§ 41), the articular surfaces generally incline to one side or the 
other, instead of looking directly forwards or backwards along the axis of the arm. 

44, It obviously results from the general conformation of the segments, the peculiar 
disposition of their articular surfaces, and the arrangement of the muscles and ligaments, 
that provision is made for very free flexion of the Arm towards the ventral aspect by the 
contraction of its muscles; and this flexion can take place to such an extent that the arm 
may in a moment coil itself into a spiral resembling that of a watch-spring. When the 
muscular tension is relaxed, the elasticity of the ligament on the dorsal side of each 
segment straightens the arm, and may even flex it in some degree in the opposite 
direction ; such dorsal flexion, however, never takes place to any considerable extent. 
The arms also possess a slight power of lateral flexion, in virtue, as it would seem, of an 
inequality of action in the two flexor muscles of each articulation; but this flexion is ~ 
very limited in amount. 

45, The Axial canal by which each segment is perforated, carries on through the whole 
length of the Arms the axial canal which divaricates in the Third Radial () 38); and 
it also gives off branches which in like manner enter the bases of the Pinnules, and 
proceed through their successive segments to their extremities. This canal is occupied 
by a solid cord of sarcodic substance, which I shall hereafter show to be really, like the 
similar cords that fill the canals of the dorsal cirrhi (§ 29), a branch of the original 
Crinoidal axis. 

46. The peculiarities presented by individual segments of the Arms are most conspi- 
MDCCCLXVI. 5 F 


720 DR. W. B. CARPENTER ON THE STRUCTURE, PHYSIOLOGY, AND 


cuous in the first five, every one of which may be readily distinguished from any other 
and it will be desirable, therefore, to describe each of these separately. 

47. First Brachial—lt has been already shown (§ 41) that the inequality between the 
lengths of the inner and the outer margins of this segment (Plate XXXVI. fig. 4, c, D) 
is so considerable as to compensate in great degree for the extreme obliquity of the 
distal face of the Third Radial, to which it is articulated; and is such as even to 
occasion a curtailment of the imner half of each articular surface (fig. 4, a, c). The 
proximal articular surface (A) presents on its outer side no special peculiarity ; but on 
its inner side we notice at the inner extremity of the fossa for the interarticular ligament 
a peculiar rounded pit (g), which might be supposed to be the socket for the articulation 
of apinnule. This, however, is not the case; for no pinnule is borne by this segment, and 
the articular sockets of the pinnules are always found on the longer sides of the Brachial 
segments. The muscular fosse are carried so far back by the recession of the vertical 
lamellz which bound them, as to form the greater part of the ventral face of the segment 
(fig. c, ¢, c). The distal face (B) is formed on the plan of that of the Second Radial 
(§ 37); being simply divided by a vertical ridge (a, a) into two lateral fosse (6, 6), in 
which are lodged interarticular ligaments, but no muscles. 

48. Second Brachial.—This segment presents a certain degree of resemblance to the 
preceding in general form, and, like it, has its outer margin so much longer than its inner 
as to produce a considerable obliquity between its articular surfaces (Plate XXXVI. 
fig. 5, c, D). But it is here the proaimal face (A) articulating with the First Brachial, 
which is divided (like that of the Third Radial, } 38) by a vertical ridge into two lateral 
fossee ; whilst the distal (B), which articulates with the Third Brachial, bears a general 
resemblance to the proximal face of the First, but is at once distinguished by the exca- 
vation of its outer and upper portion (trenching on the outer muscular fossa) into the 
articular surface for the first pinnule (/, figs. B, E). But for this difference, the Second 
Brachial might be easily mistaken for the First Brachial of the other arm of the same 
ray. 

49. Third Brachial—The general form of this segment (Plate XXXVI. fig. 6) is 
more discoidal than that of either of the preceding; but it still has a decided obliquity 
(figs. c, D) between its proximal and its distal articular surfaces, which is, however, in 
’ the contrary direction to that of the First and Second Brachials (Plate XX XVII. fig. 3). 
The proximal face (A) presents the usual arrangement of fosse for the lodgment of 
muscles and ligaments; the surfaces for the attachment of muscles being here chiefly 
provided by the two rounded lamelle which project from the upper or ventral margin 
of the segment (d, d, figs. 4,B). The distal face (B) shows a peculiarity of conformation 
which we have not yet encountered ; for it is unmarked by any prominent ridges or fosse, 
being in fact almost flat, except that it presents a series of slightly elevated ridges with 
alternating furrows, which radiate from the opening of the central canal towards the 
dorsal margin. The union of this face with the opposite face of the Fourth Brachial 
(sg, figs. ©, D, E) constitutes what was designated by Professor J. MULLER a syzygy. 


DEVELOPMENT OF ANTEDON (COMATULA, LAMK.) ROSACEUS. 721 


50. Fourth Brachial—This segment (Plate XXXVI. fig. 7) has the same general 
form with the preceding, and the obliquity of its two faces (c, p) is in the same direction, 
the longer being again the internal. While the dista/ face of this segment (8) conforms 
to the ordinary type, and is distinguished from the proximal face of the Fourth segment 
(with which it might otherwise be confounded) by possessing an articular socket for the 
pinnule (p, figs. B, ©, E), its proximal face (4) shows the same ridge and furrow arrange- 
ment as the distal face of the Third— When we examine the Third and Fourth segments 
in their natural apposition (fig. 6, c, D, E), we see that the two sets of ridges are applied 
to each other (sq), leaving between them flattened passages that are formed by the cor- 
respondence of the furrows. The adhesion between these apposed surfaces is so close, 
that it can only be dissolved (like that of the First Radials to each other and to the 
Centro-dorsal plate, §§ 31, 32) by boiling in a solution of caustic alkali. No ligamentous 
substance is interposed between them; but an examination of decalcified specimens shows 
that the canals are occupied by radial extensions of the ordinary sarcodic basis-substance 
(Plate XLIII. fig. 2). The peculiar arrangement of these suggests that, like the “ medul- 
lary rays” of an Exogenous Stem, they may serve to establish a communication between 
the “medullary axis” of this basis-substance which occupies the central canal, and the 
“cortical envelope” by which the surface of the segment is invested. When we come to 
study the development of the Brachial segments (§ 67), we shall find that the syzygies 
do not originate (as has been supposed by some) in an imperfect subdivision of segments, 
—no subdivision, perfect or imperfect, ever taking place; but that they are formed by 
a partial coalescence of segments originally quite distinct. For in the early stage of the 
existence of this animal as a detached Antedon, there is still so little specialization in 
the rod-like segments of the arms, that they are all nearly similar in form, have no 
proper articular surfaces, and are held together by nothing else than an imperfectly 
fibrous sarcodic substance. And whilst the majority of these gradually come to possess 
true articulations, and to be separated by the intervention of muscles and ligaments, a 
certain small proportion become more intimately united on a simpler plan, which admits 
of no motion between them. These syzygies are repeated at more or less frequent 
intervals along the greater part of the length of the arms; and as they are normally 
pretty constant in position in the several Arms of each individual, and in the several 
individuals of one species, whilst usually diverse in those of different species, it has been 
proposed by Professor J. MULLER to use them as characters of specific definition. To 
this it has been objected by DuJarpin’ that the syzygies are really variable in their 
number and in their mode of distribution on the several arms, especially when there has 
been a reparation after injury, so that on the same individual there may intervene from 
four to nine ordinary articulations between the corresponding syzygies. Whilst fully 
admitting the existence of irregularities thus originating, which are for the most part 
easily recognized, 1 am disposed to believe with Mtuuer that there is a normal type 
which is constant—as regards the basal portions of the arms at least—for each species, 

' Histoire Naturelle des Zoophytes Echinodermes, p. 193. 
oF2 


722 DR. W. B. CARPENTER ON THE STRUCTURE, PHYSIOLOGY, AND 


and which may thus afford valid specific characters. In Antedon rosaceus, and what I 
believe to be its varietal forms (§§ 6,7), the second syzygy (Plate XXXVIL. fig. 3) 
occurs at the junction of the 9th and 10th segments, and the third at the junction of 
the 14th and 15th. 

51. Fifth Brachial—We now come to that which may be regarded as the ordinary 
form of the segments constituting the basal portion of the Arm, and which is repeated 
with great uniformity except where a syzygy intervenes,—the peculiar mode of articu- 
lation existing between the First and the Second segments not presenting itself else- 
where. Each articular face (Plate XXXVI. fig. 8, 4, B) presents the same disposition 
of transverse ridges and ligamentous and muscular fossie (a, a, 0, 0, c, ¢); and the same 
vertical lamelle for the attachment of the muscles (d, d, figs. A, B, C) are common to both. 
The articular base of the pinnule is situated at the upper and outer margin of the 
distal articular surface (fig. B, p); and in this and the succeeding segments (in which its 
position is alternately on the inner and on the outer side) its presence always enables us 
at once to distinguish the distal from the proximal face of the segment. These faces are 
also distinguishable by the much greater inclination presented by the proximal face, the 
distal face being nearly vertical; this character, which repeats itself along the entire 
series of segments, is best seen on looking at the arm from above (Plate XXXVII. 
fig. 4) or in section (Plate XX XVIII. fig. 11). 

92. Middle Portion.—As we pass from the basal portion of the Arms in the direction 
of their termination, we find in the first instance no other change in the conformation of 
the segments than is brought about by a considerable diminution of their diameter 
without a corresponding diminution in their length (Plate XXXVII. fig. 1). Thus 
in the segment of which the proximal and distal faces and the longer side bearing the 
pinnule are represented in Plate XX XVIII. fig. 5, a, B, c!, we recognize the same arrange- 
ment of the great transverse ridge, the deep fossa for the elastic ligament between this 
ridge and the dorsal margin, the pair of shallower fosse for the interarticular ligaments 
on the ventral side of the ridge, and the larger and deeper muscular fossi chiefly formed 
by the vertical plates rising up on the ventral margin, with the articular socket for the 
pinnule encroaching on the muscular fossa of the longer side, that have been described 
in the last paragraph. But whilst the transverse and vertical diameters of this segment 
are scarcely more than half those of the Fifth Brachial, the length of the longer side is 
rather greater than less, so as quite to equal the transverse diameter. With this change 
of proportions there is an increased obliquity of the articular surfaces, alike in the trans- 
verse and in the vertical direction; and thus the spaces between the lamelle for the 
attachment of the muscles that pass from segment to segment remain undiminished in 
length (Plate XXXVII. fig. 2), although those lamelle are brought; by the reduction in 
the diameters of the segments, so much nearer to the axial canal of the arm. The arti- 
cular sockets of the pinnules are now quite removed from the articular surfaces of the 
segments; and when two segments are united by syzygy (fig. 1, sy, sq), their conjoint 


* These figures haye been inverted by the Artist, so that the dorsal margin is uppermost. 


DEVELOPMENT OF ANTEDON (COMATULA, LAMK.) ROSACEUS. 123 


length is but little greater than that of an ordinary single segment.—The same general 
proportions are maintained through a considerable part of the length of the Arm, the 
tendency being, however, to a further reduction in the diameter of the segments, without 
a corresponding reduction of their length; so that notwithstanding the increased obli- 
quity of the articular surfaces, the muscular fosse of the proximal and distal faces of 
each segment, instead of being separated merely by the thin vertical lamellae which 
form the floors of both, lie as it were along its ventral surface, and yet do not come 
into close approximation. 

53. Terminal Portion.—Passing onwards to the termination of the Arms, we find a 
progressive diminution in the diameter of the segments, without a corresponding reduc- 
tion in their length; so that their proportions now differ widely from those of the basal 
segments (Plate XX XVIII. fig. 4). We still observe, however, an alternating obliquity 
in the disposition of their articular surfaces as seen from the dorsal side; a sort of notch 
being left, first on one side and then on the other, which is occupied by the elastic 
ligament. On separating the articular surfaces, we no longer find them presenting the 
characteristic ligamental and muscular fosse ; but there are nearly plane surfaces above 
and beneath the central aperture, to which the ligaments are attached, whilst the muscles 
lie in elongated fossie excavated in the ventral face of the segments (¢, ¢, fig. 2, A,B). The 
articular sockets for the pinne (p, p) show themselves on the lateral surfaces of the seg- 
ments at about the middle of their length, and are quite removed from the muscular fosse. 
—Of the normal mode of termination of the Arms, I am unable—after an exami- 
nation of some hundreds of specimens—to speak with certainty; for I have never met 
with a specimen of this animal possessing in other respects the characters of maturity, 
which presented such a gradational diminution in the dimensions of the terminal seg- 
ments as might be fairly expected from the general plan of its structure. In a large 
proportion of cases the Arms end so abruptly as evidently to show that their terminal 
segments have been broken off. And when they do present such a termination as is 
shown in Plate XX XVIII. fig. 4, this has all the characters of immaturity (§ 67); and 
must be regarded as marking, not the completion of the growth of the Arm, but either 
the continuance of its normal extension, or the reproduction of the portion which has 
been lost. 

54. Pinne.—The pinnules with which the Arms are fringed (Plates XX XVII. figs. 
1, 2, 3, XX XVIII. figs. 4, 10, 11) are composed of articulated segments nearly cylin- 
drical in form, and gradually tapering from their base to their extremity, which bears a 
peculiar segment furnished with five or six minute hooks (Plate XX XVIII. fig. 3). 
The size and length of the pinnules vary considerably in different parts of the Arm, 
those near the base being not only longer, but also stouter in proportion to their length. 
The first pair of pinnules, which are attached to the Second Brachial segments, are 
much longer than those which succeed, often in fact attaining double their length; and 
these, as already mentioned, are nearly always seen in the living state bending over the 
yentral disk (Plate XX XI. fig. 4). The first segment, which is articulated to the Brachial 


724 DR. W. B. CARPENTER ON THE STRUCTURE, PHYSIOLOGY, AND 


segment that bears it by ligaments only, is much shorter than that which follows it 
(Plate XXXVII. fig. 5); and the length of the succeeding segments presents a consi- 
derable uniformity, until we approach the termination of the pinnule, where we often 
find a set of segments much shorter than the rest (Plate XX XVIII. fig. 3), suggesting 
the idea that these are the last formed. The number of segments in the pinnules is 
found by no means constant, when we compare either different pinnules of the same 
Arm, or corresponding pinnules in different individuals. Thus the jist, which from 
their peculiar relation to the mouth I distinguish as the oral pimnules, very commonly 
have about thirty-five segments; but I have not unfrequently counted as many as forty, 
and in one instance forty-five. And while the ordinary pinnules of the dasal part of 
the Arm have usually about twenty segments, the number not unfrequently rises to 
twenty-five. In the middle part of the Arm (Plate XX XVII. fig. 1) the number of 
segments in the pinnules may average eighteen; and in its terminal portion we find 
this rapidly diminishing from sixteen to half that number (Plate XX XVIII. fig. 4). 
The general conformation of the individual segments closely corresponds with that of 
the segments of the dorsal cirrhi (§ 28). They are nearly cylindrical, but somewhat 
compressed on their ventral aspect; and each of them (at least in the pinnules of 
the basal and middle parts of the Arms of well-developed specimens) has the dorsal 
margin of its distal end fringed by a set of short oblique spines (Plate XX XVII. fig, 3). 
The articular faces of the segments are formed on nearly the same plan with those of 
the segments of the dorsal cirrhi(§ 28), the opening of the central canal by which every 
segment is traversed, being surrounded by a slightly elevated ring, sometimes extended 
into a transverse ridge, and a depression being left by the bevelling-away of the surface 
in both directions, that serves for the lodgment of interarticular ligaments. But besides 
these depressions, there is in each of the basal segments, at least of well-developed 
pinnules, a small but deep notch in the ventral margin of each articular surface, but 
deeper in the distal; and this lodges a minute muscle (Plate XX XVIII. fig. 10), by the 
action of which the pinnules can be so flexed that those of the two sides of the Arm 
are brought towards each other, and also towards the line of its axis,—the converse 
movement of extension being effected (as in the Arms) by the elastic ligaments, when 
the muscles are relaxed. 


REPARATIONS. 


55. It is well known to Naturalists that a remarkable degree of reparative power is 
exhibited by EcuinoperMara generally; and our Antedon, so far from constituting an ex- 
ception, affords abundant exemplifications of its operation. For when we have the oppor- 
tunity of examining a large number of specimens brought up together by the dredge, we 
are sure to meet with several which have obviously sustained losses either of entire Arms 
or of portions of Arms, and in which the lost parts are being reproduced on a smaller 
scale. We so often find that the fracture has taken place at a syzygy (Plate XX XVIII. 
fig. 6) that the question suggests itself whether there is any special reparative power at 


DEVELOPMENT OF ANTEDON (COMATULA, LAMK.) ROSACEUS. 725 


this joint,—analogous to that which in the Decapod Crustacea is well known to exist in 
the basal extremity of the first phalanx. I am inclined to the belief, however, that the 
comparative frequency of fracture at the syzygies depends rather on the greater brittle- 
ness of the Arm at these points; the syzygal segments being held together only by 
sarcodic substance, instead of (as elsewhere) by ligaments and muscles. Certain it is 
that the reproductive power, instead of being limited (as in the Crab and Lobster) to 
one particular articulation, may be exerted at any point in the Arm, or even in the Ray. 
Thus we see in fig. 9 that a Ray has been torn off at the junction of the First and 
Second Radials; since not only the pair of Arms, but the Second and Third Radials 
which bear them are so much smaller than the rest, as to be obviously products of the 
reparative process. It is worthy of remark that the syzygies of these reproduced arms 
occur at the regular intervals. Another case of the same kind, in which the new Ray and 
Arms have attained a more advanced development, is shown in Plate XX XVIII. fig. 8, a. 
In other specimens in my possession, the reparation has commenced from the bifurcation 
of the Arms, from the articulation between the first and second Brachials, and from the 
articulation between the second and third; and here, again, it is interesting to remark 
that the first syzygy always occurs between the third and fourth segments, although there 
is often some irregularity (on the side of excess) in the interval between the first and the 
succeeding syzygies.—It is much more common, however, for only the terminal portion 
of an Arm to have been lost; and the new growth by which it is being replaced often 
affords a peculiarly good illustration of the mode in which the development of fresh 
segments is accomplished (§ 67). 

56. It is curious that in some cases the act of reparation should be attended with 
Monstrosity ; and this may be on the side either of excess or of defect. Of the former 
we have an example in Plate XX XVIII. fig. 8, B; where we see that a fracture having 
taken place at the articulation between the first and second Brachial segments, the new 
Second Brachial, instead of conforming to the ordinary type, resembles the Third or 
Axillary Radial, and gives support to two Arms, which have already attained a consider- 
able development. A case of the latter is shown in the specimen represented in Plate 
XXXVIII. fig. 7, where the normal bifurcation of the Ray has not taken place, the 
Third or Axillary Radial being deficient, whilst the Second (which has about twice its 
normal length) bears a single Arm of full size, with its syzygies regularly repeated. 
Whether this monstrosity had its origin in fracture, however, may be doubted; and the 
like doubt may be entertained in regard to another case of ‘monstrosity by excess,” 
which has presented itself to me in an oral Pinnule; a bifurcation like that of the Ray 
into a pair of Arms presenting itself at the second segment, so that two full-sized pinnules 
take the place of the ordinary single pinnule. 


726 DR. W. B. CARPENTER ON THE STRUCTURE, PHYSIOLOGY, AND 


V.—DEVELOPMENT OF THE SKELETON. 
1. General History of the Pentacrinoid Larva. 


57. The study of the development of the pieces of which the Skeleton of Antedon is 
made up, will be best pursued in the first instance by following the general history of the 
development of its Pentacrinoid Larva, from the epoch at which Professor WYvILLE 
THomson’s account of it ceases, to the termination of its attached condition ; since it will 
be in this mode that I can best make apparent the relation of the remarkable changes 
which the skeleton undergoes during this period, to the progressive evolution of the 
other parts of the fabric. 

58. The nature of the objects to which the Pentacrinoid Larve attach themselves, 
varies with the locality. In Lamlash Bay, Arran, where my own studies of Antedon have 
been for the most part carried on, I have never found them affixed to anything else than 
the fronds of Laminarie (to which the adult Antedon habitually clings), or to PoLyzoa 
or Spirorbes attached to these. But at Ilfracombe, where Laminariw are much less 
abundant, but where the Polyzoon Salicornaria grows in great luxuriance in the habitat 
of Antedon, the Pentacrinoid larve are found adherent to its stony Polyzoary. Mr. J. V. 
TuHompson found them in the Bay of Cork “attached to the various species of Sertu- 
laria and Flustracea which occur in the deeper parts of the harbour of Cove, viz. in from 
eight to ten fathoms.” Mr. Witt1Am THompson (of Belfast) found them attached to 
Delesseria sanguinea. Hence I think it can scarcely be doubted that the Pentacrinoids 
will attach themselves indifferently to any Fuci, Polyparies, or Polyzoaries, which 
may abound in the habitats of the parent Antedon. Though generally scattered over 
the surfaces of these, so as not to be in any near proximity to each other, yet sometimes 
we meet with a group of several Pentacrinoids very close together, so as to present in one 
view all the stages in development represented in Plate XX XIX. Ihave one specimen 
in my possession, indeed, in which more than seventy Pentacrinoids, all nearly in the 
same stage of development, are attached to the surface of a patch of Membranipora that 
was encrusting a frond of Laminaria; and in another, which I owe to the kindness of 
Professor WyvILLE THOMSON, thirty-five Pentacrinoids, in that earlier stage which was 
first described by Professor ALLMAN, are so closely clustered together that the discoidal 
bases of their stems have come into mutual contact, and have acquired a polygonal 
form. ‘These, he informs me, were bred in his Vivarium; and the circumstances of 
their aggregation were not a little curious. A pseudembryo, when losing its power of 
locomotion, was frequently seen floating in such a manner that its incipient discoidal base 
spread itself out (often in a stellate form) on the surface of the water, whilst the stem 
and body of the rudimental Pentacrinoid hung downwards from this; and it sometimes 
happened that by the approximation of a number of individuals in the same condition, 
the stellate extensions of the disks became mutually adherent. Similar clusters were 
found by Professor Wyvi1LLE THomson attached to the inner surface of a dead valve of 
Modiola modiolus. 


DEVELOPMENT OF ANTEDON (COMATULA, LAMK.) ROSACEUS. 127 


59. Referring to the admirable Memoir of Professor Wyvitte Tuomson' for full 
details of the early development of the Pentacrinoid Larva from the free pseudembryo, 
I shall briefly recall the principal features which it presents when it has fully assumed 
the Crinoidal type.-—The animal consists in the first instance of stem and calya alone, 
not even rudiments of arms being distinguishable. The stem is composed of from 8 to 
10 cylindrical segments, the lowest of which is articulated to a discoidal plate which 
forms its base of attachment; whilst the highest expands to serve as the foundation 
whereon the plates of the calyx are built up. The calyx completely encloses the visceral 
mass, its oral valves, when drawn together, meeting over the mouth; whilst, when these 
open out, it has the form of an inverted bell*. Its lower or aboral portion is composed 
of five dasal plates, which form by their approximation a five-sided pyramid with its 
truncated apex pointing downwards; whilst its oral part is composed of five oral 
plates, the approximation of which forms a similar pyramid with its truncated apex 
pointing upwards, though they are usually erected as separate valves, to allow the oral 
apparatus to be projected from within them. ‘These two pyramids are the parts of the 
skeleton of the calyx which first make their appearance; and the one is so superposed 
on the other that the plates of the oral are opposite to those of the dasal pyramid. 
At a somewhat later period the first radials make their appearance in the spaces left by 
the contiguous angles of the basal and oral plates, so as to alternate with these in posi- 
tion. Between two of the radials, and on the same level with them, an unsymmetrical 
plate early shows itself, the subsequent relation of which to the vent proves it to be an 
anal plate. From the summits of the first radials, the second radials are next seen to 
bud forth between the bases of the orals; and as the circle formed by these last does 
not increase in diameter, whilst the ring of first radials on which it rests has become 
larger, the orals are relatively carried inwards, whilst the second radials project somewhat 
outwards.—In the latest stage described by Professor WyviLLe THomson, the third or 
axillary radials have begun to show themselves at the distal extremities of the second ; 
and rudiments of a pair of jirst brachials are distinguishable at the distal extremities 
of the third radials*. 

60. The several portions of the skeleton are imbedded in a nearly homogeneous sar- 
codic substance, which externally forms a perisomatic investment, and internally consti- 
tutes a lining to the calyx. The Digestive Cavity seems in the first instance to be simply 
excavated in the body-substance; but as the radial plates are developed, giving an 
expansion to the equatorial portion of the cup, the wall of the Stomach becomes sepa- 
rated from the lining of the calyx by a distinct perivisceral cavity filled with fluid, in 
which the stomach seems to hang attached to the body-wall here and there by sarcodic 
bands and threads. Simultaneously with the appearance of the anal plate, a slender digi- 
tate process rises from one side of the stomach and curves towards that plate ; this con- 
stitutes the rudiment of the Intestine, but it has not as yet any outlet, and I believe it 
to be in this stage destitute even of an internal canal, being an extension of the wall of 
' Philosophical Transactions, 1865, p.513. ? Ibid. Plate XXVL., figs. 1,2,  * Jbid. Plate XXYVII. fig. 1. 

MDCCCLXVI. 5@ 


x 


728 DR. W. B. CARPENTER ON THE STRUCTURE, PHYSIOLOGY, AND 


the stomach but not of its cavity—The mouth of the bell, when the oral valves are 
expanded, is entirely occupied by the oral apparatus. The mouth itself is a wide orifice, 
allowing the interior of the stomach to be plainly seen when looked into from above ; 
and this is surrounded by a prominent ring from which arise the oral tentacles'. This 
ring is spoken of by Professor WyviLte THoMSoN as a proper “vessel;” but, as I 
shall show hereafter, although it doubtless represents the vascular ring which surrounds 
the mouth of Echinoderms generally, it is really an extension of the perivisceral cavity, 
partly separated from the rest. .The oral tentacles are of two kinds, extensile and 
non-extensile. Of the former there are in the first instance only five, presenting 
themselves at the intervals between the oral valves; whilst of the latter there are ten, 
a pair lying within each of those valves. Coincidently with the development of the 
Radials, however, the first-formed extensile tentacles are carried outwards on diyer- 
ticula from the oral ring, which thus originate the tentacular canals of the arms; whilst 
five additional pairs of extensile tentacles are developed between the five pairs of non- 
extensile, raising the whole number to twenty-five, of which the five first-formed are a 
little external to the rest. With the development of the second and third Radial plates 
that of the canal-system of the rays proceeds. The five “azygous” extensile tentacles 
are gradually carried outwards, by the prolongation of their respective diverticula, to the 
point of bifurcation of the Ray into Arms; and from these diverticula, which now con- 
stitute the tentacular canals of the rays, there arises on either side a series of delicate 
crescentic leaves, each of them haying in connexion with it one extensile and two non- 
extensile tentacles} an arrangement which afterwards comes to be repeated along the 
arms when they are developed at the bifurcation of the rays, and subsequently along the 
pinnules which fringe the arms of the adult. Beneath the tentacular canal a tubular 
extension of the perivisceral space passes along the ventral surface of each ray; and 
although this appears to form but a single canal, I shall hereafter show that it is 
very early divided by a horizontal partition extended from the membranous bands 
that suspend the digestive cavity in the perivisceral space; and that whilst the canal 
above the partition communicates with the portion of the perivisceral space which lies 
immediately round the mouth, the canal deneath the partition is extended from the 
portion of the perivisceral space which occupies the hollow of the calyx. The former I 
shall term the subtentacular, and the latter the celiac canal; their relations will be 
found very remarkable.—The general aspect of the young Pentacrinoid, as seen with its 
tentacular apparatus retracted in a spirit-specimen, is shown in Plate XXXIX. fig. 1, a, 
" for the sake of comparison with the later stages. 

61. For some little time after the appearance of the arms, the relations of the skeleton 
of the calyx to the visceral mass it includes undergo but little change (Plate XXXIX. 
fig. 1, 8); the chief difference consisting in the more compact condition it now comes 
to present, in consequence of the advanced development of its component pieces. The 
five basals (Plate XLI. fig. 1, 6, 2) now possess a regularly trapezoidal form; the 

3 Philosophiéal Transactions, 1865, Plate XXVI. fig. 3. 2 Thid. Plate XXYVII. fig. 3. 


Se DEVELOPMENT OF ANTEDON (COMATULA, LAMK.) ROSACEUS. 729 


lower part of each being an acute-angled triangle with its apex pointing downwards, and 
its upper part an obtuse-angled triangle with its apex directed upwards. The sides of 
the lower triangle are bordered by a somewhat thickened edge of solid transparent cal- 
careous substance, the presence of which marks that the plate has received its full increase 
in that direction. 'The adjacent borders of these plates, however, do not come into 
absolute contact, a thin lamina of sarcode being interposed between them; and there is 
also a passage left at the truncated apex of the inverted pyramid formed by their 
junction, through which the axial sarcodic cord of the stem is continued into the calyx. 
The upper margins of the basal plates have no distinct border, and seem to be still in 
process of growth. The first radials (r', 7') now form (with the anal, a, intercalated 
between two of them) a nearly complete circle, resting on the basals, and separating 
them entirely from the orals. Their shape is somewhat quadrangular; two of their 
angles pointing vertically upwards and downwards, and the other two laterally towards 
each other. Their lower angles are received between the upper angles of the basals; 
whilst on their upper, which are somewhat truncated, the narrow second radials (7°, 7°) 
are superimposed. Considerable spaces still exist between the adjacent radial plates, 
except where the anal plate is intercalated in the series; and these are filled only by 
sarcodic substance. ‘The central portion of these first radials is thickened by the endo- 
genous extension of the calcareous reticulation ; and this extends towards its upper 
angle, so as to form a kind of articular surface for the support of the second radials ; 
but it does not extend over the lateral or alar expansions of these plates, which still 
retain their original condition of cribriform films. The second radials (7°, 1°) differ 
completely from the first in shape, being rather rods than plates; but they are deeply 
grooved on their oral aspect, that which is subsequently to become a central canal being 
not yet closed in. The calcareous reticulation of their outer or aboral surface is cribri- 
form; but the ingrowth from which they derive their solidity is produced, as Professor 
WrvitLe Tomson has shown (p. 541), by the development of fasciculated tissue analo- 
gous to that of which the stem-joints are composed. ‘The same general description 
applies also to the third or avillary radials (7°, 7°), which, like the preceding, are nearly 
cylindrical at their proximal extremities, but expand towards their distal ends, so that 
each presents two articular surfaces, on which are imposed the pair of first brachials.— 
The oral plates (0, 0), which alternate with the second radials, though somewhat internal 
to them, now present somewhat of a triangular form, their apices pointing upwards; 
their basal angles, however, are cut off (as it were) by the encroachment of the first 
radials. At no part of their contour have these plates any definite margin like that 
which borders the two lower sides of the basal plates; but the calcareous reticulation 
of which they are composed is continued into the layer of condensed sarcode with which 
they are invested. Although the form of these plates is generally triangular, yet their 
surface is not that of either a plane or a spherical triangle, but presents a remarkable 
unevenness. Near the apex of each there is a deep depression externally, and a corre- 
sponding projection internally; and the effect of this projection seems to be that, when 
5G 2 


730 DR. W. B. CARPENTER ON THE STRUCTURE, PHYSIOLOGY, AND 


the apices of these plates incline to one another, so as to form a five-sided pyrem ‘dal 
cover to the calyx (Plate XXXIX. fig. 2), the plates will close together not merely 
at their apices and lateral margins, but also at the upper part of their internal surfaces. 
There is also a broad depression near the base of each plate, so that its lower margin is 
somewhat everted. The anal plate (a), which is intercalated between two of the first 
radials, has a tolerably regular circular shape ; but it consists of only a single cribriform 
film, and has no definite border. 

62. Concurrently with the adyance in the development of the Calyx, the Stem under- 
goes an increase both in the number and in the length of its component segments ; and 
while it also increases to some extent in its diameter, its solidity is still more augmented 
by the endogenous growth of its calcareous skeleton. ‘The cribriform plate on which it 
rests augments both in diameter and in thickness, absorbing into itself (as it were) nearly 
the whole of the organic substance of the basal disk. Its typical form may be considered 
as circular; but its margin is usually more or less deeply divided into lobes (Plate XX XIX, 
fig. 1). Its diameter is usually about ‘015 inch. In its centre is a deep depression that 
lodges the end of the lowest joint of the stem.—lIt will be remembered that the deve- 
lopment of each of the original segments of the Stem was shown by Professor WYVILLE 
THomson to commence by the solidification of a ring, which occupies what will afterwards 
become the middle of its length; and that from each of the two surfaces of this ring a 
hollow cylinder of calcareous trellis-work gradually extends itself. The length of each 
of these original joints is augmented by new calcareous deposit at its extremities, which 
finally become compactly rounded off and well defined, so that the apposed surfaces of 
two segments are clearly marked out from each other, instead of having their irregu- 
larities commingled, as in the earlier period of their formation. The diameter of each 
segment increases by new calcareous deposit on its cylindrical surface, bringing up its 
whole length to the size of the first-formed median ring, and finally giving to its 
extremities a slight excess beyond this. At the same time the solidity of each segment 
is increased by an inward extension of the calcareous trellis-work, which progressively 
fills up what was at first a hollow cylinder. This internal solidification, however, 
goes on more slowly than the completion of the external form and dimensions of the 
segments; for these may present their mature aspect, or nearly so, whilst possessing so 
little substance that their shape is altered, by the drying up of the soft sarcode-axis 
of their interior, to that represented in Plate XLI. fig. 4. 

63. While the original segments, which are stated by Professor WYVILLE THOMSON to 
be eight in number, are thus advancing towards completion, new segments are being 
developed in the interval between the highest of these and the base of the calyx, 
None of my specimens in the stage now described present fewer than twelve segments ; 
so that four at least must have been thus interpolated, That the upper end of the 
Stem is the part at which the new segments originate, is very plainly indicated by several 
considerations. It is there that, during the period in which the stem is continuing to 
increase, we always find the most rudimentary segments; and we may trace, as we 


DEVELOPMENT OF ANTEDON (COMATULA, LAMK.) ROSACEUS, 731 


descend the stem, a gradual passage from such as consist of little else than the primor- 
dial ring, to those which have attained their complete cylindrical form and their full 
dimensions. Moreover it is obviously there that the nutritive activity will be the 
greatest; the sarcode-substance intervening between the base of the calyx and the sum- 
mit of the stem being in most direct relation with that of the interior of the calyx 
(through the imperfect closure of its basal plates, § 61), and consequently with the 
visceral apparatus, And there is no other part of the stem in which there is the least 
appearance of any multiplication of segments, either by the subdivision of those already 
formed, or by the interpolation of new ones ;—the suggestion of Professor ALLMAN, that 
the transverse ridges running round the centres of the segments may be the indication 
of such a division, being negatived by the facts already stated as to its real character. 
That this ridge, which is prominent in the segments of the upper and middle part of the 
stem, so far disappears in those of the lower as to be represented only by a single line, 
is due to the circumstance that the lower segments are those of which the skeleton is 
first completed.—By the time that the opening-out of the Calyx commences in the man- 
ner to be presently described, the number of segments in the stem has usually risen to 
15 or 16; those of the inferior third of the stem are pretty nearly solidified throughout, 
only a small passage still existing through their interior; but those of the middle and 
upper thirds of the stem are still so far from having attained their completion, that 
their calcareous cylinders when broken across are found to be mere shells. The highest 
plate, on which the base of the calyx rests, is now distinguished from those below it by 
its somewhat larger diameter; but it does not as yet present any approach to the pecu- 
lar shape which it afterwards comes to possess.—The entire stem remains clothed with 
a thin layer of sarcodic substance; and its cavity is occupied by a cylinder of the same, 
which forms a continuous axis throughout its entire length, and passes up at its summit 
into the calyx. I have not been able to see any traces, at this early stage, of that fibrous 
structure which may be distinguished about the ends of the segments at a subsequent 
time. 

64. A very important change now takes place in the relations of the several parts of 
the Calyx and its contents, which gives to the body of the more advanced Pentacrinoid a 
much closer resemblance to that of the adult Antedon. For instead of being completely 
included within a calcareous casing, which not only supports it below, but can close over 
it aboye, the visceral apparatus which occupies the cavity of the calyx is henceforth to 
be merely supported by its skeleton; its upper surface losing all protection except such 
as is afforded by the infolding of the arms, and being extended into a disk of which the 
mouth only occupies the centre. This change is essentially connected with the increased 
development of the intestinal tube, which now forms a nearly complete circle around the 
stomach, and comes to possess a second or anal orifice. When we examine the compo- 
sition of the calyx (Plate XX XIX. fig. 1, c, and fig. 3), we find that the original dasals 
have undergone little if any increase, but that the first radials (r', 7’) are now much 
larger, and spread out so as to extend the base of the cup, instead of merely forming 


732 DR. W. B. CARPENTER ON THE STRUCTURE, PHYSIOLOGY, AND 


its sides. This spreading-out results from the increase in their own breadth, without a 
corresponding increase in the diameter of the circle on which they rest; so that they are 
forced to extend themselves obliquely instead of vertically. ‘The single anal plate 
(fig. 3, a), originally interposed between two of the first radials (7", 7'), being attached 
not so much to the neighbouring plates as to the visceral mass, begins to be lifted out 
(as it were) from between them with the development of the anal funnel, as is seen in 
Plate XL. fig. 2; and the space left by it is partly filled up by the lateral extension of 
the two radials between which it was previously interposed, but which do not yet come 
into mutual contact. The second and third radials (7, r?, and 7°, 7°) also increase in all 
their dimensions, but particularly in breadth; and they thus assist in supporting the 
visceral mass, which, at the conclusion of this stage, extends itself as far as the bifur- 
cation of the arms. The most remarkable change in the condition of the calcareous 
skeleton in this stage, however, consists in the altered relative position of the five 
oral plates (Plate XL. fig. 1, 0,0). This circlet, like that of the basal plates, does 
not partake of the enlargement so remarkably seen in the radials; its diameter being 
neither increased by the growth of its component plates, nor augmented by their sepa- 
ration from one another. It continues to embrace the circle of oral tentacles, the dia- 
meter of which comes to bear a smaller and yet smaller proportion to that of the ventral 
surface of the disk, as the size of the latter is augmented by the development of the 
intestinal tube around the gastric cavity; and thus it comes to pass that the circlet of 
oral plates detaches itself from the summits of the first radials on which it was previ- 
ously superimposed, and is relatively carried inwards by the great enlargement of the 
circle formed by the latter,—the space between the two series being now filled in only 
by the membranous perisome, which is traversed by the five radial canals that pass out 
from the oral ring between the oral valves to the bifurcation of the arms, as shown in 
Plate XL. fig. 1. 

65. In the earlier part of this stage, a continued increase takes place in the number 
of segments of the Stem, by the development of new rings at its summit; whilst the 
previously-formed segments of its middle and upper portions become progressively elon- 
gated and solidified, as those of the lower portion haye previously been. At or about 
the period, however, at which the change already described is taking place in the rela- 
tions of the oral and anal plates of the Calyx, the production of new calcareous segments 
in the stem appears to cease; and a remarkable change begins to show itself in the one 
on which the calyx rests. Instead of increasing in length, its original annular disk 
augments in diameter, becoming convex on its lower surface, and concave on its upper ; 
and it extends itself over the bottom of the calyx, in such a manner as to receive into 
its concavity the apices of the basal plates. This change commences whilst the calca- 
reous segments next below are still rudimentary; so that although no further imcrease 
in the number of segments takes place subsequently, yet some increase in its length will 
still be effected by the completion of the last-formed segments, previously immature. 
The total number of segments in the fully-developed Pentacrinoid stem is subject to a 


DEVELOPMENT OF ANTEDON (COMATULA, LAMK.) ROSACEUS. 733 


good deal of variation. I have counted as many as 24, and as few as 16; the average 
may be considered about 20. 

66. Soon after the highest segment of the Stem begins to enlarge, we notice on that 
portion of its under surface which extends itself beyond the segment whereon it rests, 
one or more minute tubercles, which are the origins of the dorsal cirrhi. Each of these 
tubercles is formed by a projection of the sarcodic substance of the perisome, within 
which are observable one or more minute annular disks of calcareous reticulation. The 
projection of the tubercle gradually increases, and the number of disks (which are the 
rudimental segments of the dorsal cirrhi) is multiplied; so that each incipient cirrhus 
presents the form of a short cylinder marked by transverse annulations (Plate XL. figs. 
1,2, cir). The length of this cylinder is progressively augmented by the formation of new 
disks, and by an increase in the thickness of the earlier ones; and the terminal segment 
* soon presents an indication of the peculiar character it is ultimately to assume. Hence 
it is obvious that the new segments cannot be added at the extremity of the tentacle; 
and since, during the whole progress of its growth, we always find that the basal segment 
is the shortest, it seems most probable that the increase in the number of segments is 
effected by the interpolation of new segments at the point at which the cirrhus springs 
from the plate which bears it,—a conclusion which is conformable to what has been 
already stated (§ 29) of the relation of the cirrhi to the peculiar modification of the 
central axis contained within the centro-dorsal basin.—As each cirrhus elongates itself, 
its extremity, which was at first bluntly rounded, becomes pointed, the terminal segment 
developing itself into a conical form, though still covered with the same thick inyest- 
ment of condensed sarcode as extends over the entire length of the rudimentary cirrhus. 
—tThe exactness with which radial symmetry is maintained throughout the formation of 
the skeleton of this organism (save in the case of the Anal plate, which has special refer- 
ence to the visceral mass), would lead us to anticipate that the first five cirrhi would be 
put forth together, radiating from the central tubercle, and developing themselves at 
corresponding rates. This, however, is not the case, for they are developed succession- 
ally, the first of them usually exhibiting numerous segments with a conical termination 
by the time that the fifth makes its appearance (Plate XX XIX. fig. 1,pD). The cirrhi of 
the first whorl alternate in position with the rays, so that one of them is opposite to the 
anal plate; and this I generally (though not always) find to be the latest in its develop- 
ment, the most advanced being the one which corresponds in position to the commence- 
ment of the intestine. 

67. The development of the Arms continues to take place on the plan already described 
in detail by Professor WyviLLE THomson. Each of them is terminated by a ‘“‘ growing 
point” of condensed sarcode, in which new segments successionally originate (Plate 
XXXVIII. fig. 1), a cribriform calcareous film being first formed on the dorsal face, and 
an ingrowth of fasciculated calcareous tissue then taking place in such a manner as in the 
first instance to leave a deep groove on the ventral face, which is afterwards converted 
into a canal by the closing-over of its margins; so that the transverse section which at first 


734 DR. W. B. CARPENTER ON THE STRUCTURE, PHYSIOLOGY, AND 


resembles a horseshoe finally comes to be aring. I feel quite satisfied that there is no 
interpolation of new segments (as some haye supposed) either at the base or at any part 
of the length of the arms, their longitudinal growth being effected in part by the addi- 
tion of new segments to their extremities, and in part by the augmentation in the length 
of each individual segment. ‘hus the average length of the basal segments of the arms 
in this stage of Pentacrinoid life is about ‘007 inch, and their diameter about -003 inch ; 
whilst in the adult Antedon their length averages about 03 inch, and their diameter 
about ‘07. As the skeleton of the arms increases in length, their vascular apparatus 
is prolonged, and new groups of tentacles are developed from its extensions, each of 
these consisting, as before, of a leaf-like expansion with three tentacles proceeding from 
its base, of which one is much more extensile than the other two. The sarcodic sub- 
stance which unites the pieces of the skeleton now begins to show a delicate fibrous 
texture at their adjacent extremities; but no separate fibres are as yet to be distin- 
guished. 

68. The changes which we observe during the later stages of Pentacrinoid life 
(Plate XXXIX. fig. 1, p, H) form in every respect a continuation of those already 
described. The Calyx is still more opened out by the increased lateral as well as 
longitudinal development of the first radials; but the diameter of the visceral disk 
augments in even larger proportion, so that it extends nearly as far as the bifurcation 
‘of the arms. The oral circlet is thus separated by a much wider interval from the 
periphery of the disk; and in this outer ring the anal funnel (Plate XL. fig. 2, v) is now 
a very conspicuous object, the anal plate (a) which it bears on its outer side being alto- 
gether lifted out from between the two first radials which it originally separated. Before 
the body of the Pentacrinoid drops off its stem, an incipient absorption of the oral 
plates is discernible; this absorption commencing along the margins of the apical por- 
tion, so that these plates lose their triangular form and become somewhat spear-shaped. 
The second and third radials exhibit an increase in all their dimensions, without much 
departure from their original form. 

69. The Arms continue to increase in length, both by the addition of new segments, 
and by the growth of those previously formed; and it is when they have attained the 
length of about °08 inch, and consist of about twelve segments, that we see the first 
indication of the development of pinnw. This shows itself, not (as might have been 
expected) at the base or oldest part of the arm, but at its growing extremity, which now 
presents a bifurcation (Plate XL. fig. 1), the two rami being in the first instance almost 
equal, and each tumefied at its extremity by an accumulation of sarcode-substance. One 
of these rami, however, grows faster than the other, and soon takes a line continuous 
with that of the axis of the arm, from which the other diverges at an acute angle; so 
that the former comes to be the proper extension of the Arm, whilst the latter soon 
takes on the characters of a Pinnule. Ere long, however, the growing point of the arm 
again subdivides; two branches are formed, as previously; and whilst one of these 
becomes a continuation of the arm, the other is soon to be distinguished as a pinnule 


DEVELOPMENT OF ANTEDON (COMATULA, LAMK.) ROSACEUS. 739 


given off from it on the side opposite to that of the first-formed pinnule. Thus the 
formation of the first pair of pinnules takes place in such a manner that the extremity 
of the arm presents an appearance in the first instance of difurcation, and then of trifur- 
cation. ‘The new segments henceforth added to the extremities of the arms are all pin- 
nated; the pinnules (whose skeleton consists, in this stage, of six or eight simple cylindrical 
segments) being developed alternately from one side and the other, and being furnished 
with extensions of the tentaculiferous apparatus of the arms. Owing to the thickness 
and opacity of the cumulus of condensed sarcode in which they originate, I am not able 
to speak with positiveness as to the mode of formation of their calcareous skeleton ; but 
I believe it to take place rather after the manner of the joints of the stem and dorsal 
cirrhi than after that of the segments of the rays and arms,—that is, to commence with 
a complete ring which extends itself longitudinally into a hollow cylinder, rather than 
by a cribriform plate which wraps itself (so to speak) around the extension of the sar- 
codic axis () 67). It is remarkable that the basal portions of the arms, which had been 
developed previously to the first appearance of the terminal pinnules, remain destitute 
of these appendages to the end of the Pentacrinoid stage; except in the case of the 
second segment, from which, on each arm, an ora/ pinnule (§ 54) is developed.—The 
connexion of the segments of the arms by distinct fibrous tissue is now clearly discernible ; 
but this tissue corresponds rather with the /igamentous than with the muscular tissue of 
the adult Antedon. 

70. The Stem, in this later stage of Pentacrinoid life, shows no increase in the number 
of its segments; but those last formed near its summit are developed to almost the same 
length as the rest; and all the segments are somewhat augmented in diameter towards 
their extremities, so as to present somewhat of the dice-box form. The original annulus, 
which is still distinguishable in the middle of their length, so far from constituting a 
projection, now lies in a hollow. The axial cavity, if not quite obliterated by the filling 
up of the segments, is very much contracted; on this point it is difficult to arrive at a 
positive determination. The connexion of the segments by a distinct fibrous tissue, 
resembling that of the arms, and not merely passing from one articular extremity to the 
other but also embracing the contiguous extremities which it connects, now becomes 
obvious.—The most important change which the stem presents at this period consists in 
the enlargement of its highest basin-shaped segment, from which the dorsal cirrhi are 
developed, and in the further development and multiplication of the cirrhi themselves. 
This segment, which now presents the aspect in miniature of the centro-dorsal plate of 
the adult Antedon, augments not only in absolute but in relative diameter, extending 
itself over the dorsal or outer surface of the basal plates, which, at the time of the detach- 
ment of the body from the stem, are almost entirely concealed by it. he first-formed 
whorl of cirrhi now shows itself ready for prehensile action, its terminal claws being 
hooked, the calcareous segments being bevelled off on their dorsal aspect so as to allow 
of the downward flexure of the cirrhi, and a considerable amount of contractile fibrous 
structure being developed between and around the extremities of the segments. A second 

MDCCCLXVI. 5H 


736 DR. W. B. CARPENTER ON THE STRUCTURE, PHYSIOLOGY, AND 


whorl of cirrhi is now developed after the same manner as the first, between the latter 
(with which it alternates in position) and the base of the calyx (Plate XLII. fig. 3); and 
a third whorl generally makes its appearance before the detachment of the Pentacrinoid, 
so that the young Antedon possesses ten cirrhi in different stages of advanced deyvelop- 
ment, and from one to five still rudimentary. 

71. The total length of the full-grown Pentacrinoid, from the base of the Stem to the 
extremities of the Arms when these are folded together, may be about ‘7 inch, that 
of the stem alone being about ‘25 inch; when, on the other hand, the arms are fully 
expanded radially, the diameter of their circle may be about ‘5 inch. At this period 
the body and arms usually possess a decided colour, which is sometimes sulphur-yellow, 
sometimes light crimson, sometimes an intermixture of both hues; this is usually more 
pronounced in the arms than in the body, and is entirely due to the development of pig- 
mentary matter in the minute pyriform vesicles scattered through the sarcodic layer 
which still forms, as in the earliest phase of embryonic life’, the general envelope of 
the body and its appendages. 

72. The precise stage of development at which the body of the animal becomes 
detached from the stem, varies, like that at which a ripening fruit drops off its stalk, 
according to circumstances. I have met with specimens still attached to their stems, 
which were larger and more highly coloured than others which were found free; and I 
have repeatedly noticed that when kept in captivity they fall off quite spontaneously at 
an earlier period than that at which they detach themselves under ordinary circumstances. 
But the detachment does not seem to take place normally, until the dorsal cirrhi are 
sufficiently developed to enable them to take the place of the stem functionally by giving 
the animal the means of attaching itself to fixed objects. 

73. Habits—Concerning the habits of the Pentacrinoid I have little to add to what 
has been already noticed by Mr. J. V. Toompson®. ‘The animal,” he says, ‘‘ possesses 
the power of bending or inclining the stem freely in every direction; and what is more 
remarkable, of twisting it up into a short spiral, and that, with a considerable degree of 
vivacity,—a kind of movement that has not been noticed except in the Vorticelle.” He 
speaks of the arms as “ at one time spreading outwards like the petals of a flower, at 
another, rolled inwards like an expanding bud;” and continues,—* From their structure 
and movements it can hardly be doubted that they serve to seize upon and conyey to the 
mouth whatever has been destined for its food, and which probably consists in every 
minute animal its powers enable it to overcome.” Now, whilst I am quite at one with 
this excellent observer as to the facts which he records, I differ from him in regard to 
their interpretation; for I have seen nothing to make me believe that in the Pentacri- 
noid, any more than in the adult Antedon, are the arms ever employed for prehension ; 
whilst the existence of large vibratile cilia on the walls of the digestive cavity, as seen by 
Professor WyviLLE THomson in the early Pentacrinoid, and by myself in the more 


1 See Professor Wyvirte Tromson’s Memoir, Philosophical Transactions, 1865, pp. 522, 535. 
* Memoir on the Pentacrinus Europeus, p. 7. 


DEVELOPMENT OF ANTEDON (COMATULA, LAMK.) ROSACEUS. 737) 


advanced, as well as in the adult Antedon, sufficiently accounts for the ingestion of ali- 
mentary particles, without attributing to the arms any prehensile action. Neither the 
oral nor the brachial tentacles are ciliated’; but I have frequently noticed a rapid move- 
ment of particles along the radial furrows and their brachial extensions, which intervene 
between the parallel rows of leaflets and tentacles developed on either side of the 
tentacular canals, such as indicates the action of cilia along the floor of those furrows. 
And as this movement always takes place from the extremities of the arms towards the 
mouth, I feel little doubt that it serves the purpose of bringing within reach of the 
ingestive current maintained by the gastric and intestinal cilia such alimentary corpus- 
cles as settle down upon the expanded arms and pinnules. 


2. Development of the Component Pieces of the Skeleton, from the commencement 
of the free or unattached stage. 


74. Having thus traced the history of the Pentacrinoid Larva to the stage at which 
it assumes its adult condition as a free Antedon, I skall describe in some detail the 
several pieces of which its skeleton is then composed ; and shall then trace the further 
development of each to its final completion. 

75. Beginning from the base, we have first to speak of the Centro-dorsal plate, or 
rather basin ; which, as was rightly stated by Professor J. Minn, is really the highest 
joint of the Pentacrinoid stem; whilst, as pointed out by Professor WyvILLE THomson?, 
“it represents a coalesced series of the nodal stem-joints in the stalked Crinoids.” 
Of this sagacious determination I shall hereafter (Part II.) adduce a most curious and 
unexpected confirmation. The centro-dorsal plate (Plate XLI. fig 2, ¢) at the stage 
now treated of, has the form of a basin with its lip énverted instead of everted; its 
diameter is about ‘05 inch, and its height about :012 inch. Its basal surface is some- 
what depressed in the centre; and here we may for a time distinguish a minute five- 
rayed perforation (fig. 6, ¢), which previously formed the communication between the 
cavity of the basin and the central canal that is still left in the upper segments (at- 
least) of the stem. ‘This perforation, however, is very soon closed up by an extension of 
the calcareous network, so that no trace of it remains visible either externally or inter- 
nally. Around the stellate aperture is seen a circular series of five sockets for the arti- 
culation of the dorsal cirrhi, each of them having a pore in its centre, which is usually 
at the summit of a minute elevation. This pore gives passage to a sarcodic thread which 
proceeds from the sarcodic axis contained within the cavity of the basin, and runs along 
the central canal of the cirrhus to its termination. A second series of sockets, alternating 
in position with the first, is seen nearer the upper margin of the basin. This margin, 


1 Mr. J. V. Tompson speaks of the brachial tentacula as “furnished with capitate cilia, alternately placed 
along their sides ;*’ but it is clear that he referred to the tubular processes of the tentacles which have been 
described by Professor Wrvirie Tuomson (p. 526), and that, writing in 1827, he did not employ the term cilia 
in the technical sense to which it is now limited, but merely meant distinct hair-like filaments. 

? Philosophical Transactions, 1865, p. 536. 
oH 2 


738 DR. W. B. CARPENTER ON THE STRUCTURE, PHYSIOLOGY, AND 


when viewed from above, is somewhat pentagonal; but the opening left by the inversion 
of the lip is nearly circular. Looking down into its cavity, we may distinguish what 
was once the central canal (now blocked up), and the pores leading to the articulations 
of the cirrhi. 

76. The circlet, or rather pentagon, of Basal plates (Plate XLI. figs. 5, 6, 6, 4), which 
is for the most part concealed externally by the centro-dorsal basin, is found, when exposed 
by the removal of the latter, to differ very little either in size or aspect from the circlet 
first completed in the Pentacrinoid (§ 59). The form of each plate (Plate XLI. fig. 
2, B) is an irregular trapezoid, with its lower angle truncated; and it still retains the 
solid pellucid margin which originally charaeterized it. But it has undergone a remark- 
able thickening by an endogenous extension of its calcareous network; and this has 
taken place in such a manner as to leave its substance channelled out by a canal which 
commences at its lower truncated angle, and almost immediately bifurcates, the two 
branches diverging in such a manner as to pass towards the two First Radials which 
severally abut on the sides of the upper triangle of each basal (Plate XLII. figs. 6, 7). 
This canal gives passage to a large sarcodic cord that proceeds from the wall of a 
remarkable quinquelocular organ contained within the centro-dorsal basin, which I 
shall hereafter describe under the name of the “ centro-dorsal vesicle,” and which I 
shall show to be an expansion of the original Crinoidal axis, hollowed out into a mul- 
tiple ventricular cavity. ach of the five primary cords (which originally lay on the 
internal surface of the basals forming the floor of the calyx) subdivides into two branches 
within the basal whose canal it enters; and thus each of the First Radials receives two 
branches supplied to it through the two basals whereon it rests. 

77. The form of the First Radials (Plate XLL. fig. 2, r', fig. 5, 7', and XLIL. figs. 5, 6, 
7,7’) is now that of a trapezium having its upper and lower sides nearly straight and 
parallel, whilst its lateral margins incline towards each other from above downwards. 
Externally they still present their original cribriform structure; and this is particularly 
obvious near the upper angles, where the first-formed perforated plate has not been thick- 
ened by internal addition. But whilst the external surface is convex, being arched from 
side to side, the internal is nearly plane, the concavity of the cribriform plate being filled 
up by an ingrowth of its calcareous reticulation, which still retains for the most part its 
original type. ‘This ingrowth, however, takes place in such a manner as to leave two 
deep channels, which commence from the lower angles of the plate, and converge so as 
to meet in its centre, so as to form one large canal, which becomes completely covered in 
and passes to the upper margin of the plate, where it opens between the articular surfaces. 
These converging channels, when the plates are in situ, are continuous with the diverging 
canals of the two Basals whereon each Radial abuts; in such a manner that the primitive 
canal that enters each basal communicates by its bifurcation with the converging canals 
of two different radials; while the single canal of each radial is fed (so to speak) by the 
primitive canal of two different basals. At each of the lower angles of the radial, more- 
over, the wide embouchure of the converging channel is in proximity with that of its 


DEVELOPMENT OF ANTEDON (COMATULA, LAMK.) ROSACEUS. 739 


adjacent radial (Plate XLI. fig. 5); and a continuity is thus established between the 
several parts of this canal-system, not only radially but peripherally. At the some- 
what later period represented in Plate XLII. figs. 6, 7, the channels are completely 
covered in, so as to be converted into canals; and cach embouchure is divided by a small 
calcareous islet into two passages, one of them opening opposite the canal of the basal, 
and the other opposite the corresponding canal of the adjacent radial. In this manner 
are formed the canals already described in the first radials of the adult Antedon (§ 54). 
The upper margin of the first radial now shows on either side of its centre an elevated 
articular surface (Plate X LI. fig. 2, r', a, a), the calcareous reticulation of which is much 
closer than that of the rest of the plate; and each of these gives attachment along its 
dorsal border to a distinctly fibrous ligament connecting it with the corresponding arti- 
cular surface of the Second Radials; whilst from the ridges which form its ventral 
border there are now seen to pass towards the opposite face of the second radials a set 
of larger and more defined parallel fibres, which, from their similarity to those occupying 
the like position in the adult, we know to be muscular. 

78. The Second Radials (Plate XLI. fig. 2, n*) now begin to show a modification of 
their original nearly cylindrical form ; being somewhat widened out at their lower end, 
so as to form two articular surfaces (a, a), which are not, however, directly opposite to 
those of the first radials, but slope away from them; so that whilst in close proximity 
with them on the dorsal face, where they are connected by ligament, they are separated 
by a considerable interval on the ventral side where muscle intervenes,—an arrangement 
which gives to the muscular fibres the length required for their efficient contraction. 
The upper end (/) of the second radial, however, is simply rounded off, presenting no 
proper articular surface ; and it is connected with the base of the Third Radial by liga- 
ment only. Although the dorsal surface of the second radial is everywhere convex, its 
ventral face still shows a deep groove along its median line; this, however, is separated 
by a distinct layer of calcareous network from the axial canal beneath it, which opens 
at its lower end between the articular surfaces, and at its upper in the centre of the 
rounded termination. 

79. The Third or Axillary Radials (Plate XLI. fig. 2, R*) also show but a slight 
departure from the original simple type; their lower portion being incompletely cylin- 
drical, whilst the upper is somewhat expanded laterally to form a pair of articular 
surfaces, which look obliquely towards either side, and are separated by a projecting 
median ridge. The lower extremity is rounded off, so as to resemble the upper end of 
the Second Radial, and shows, like it, the orifice of the axial canal in its centre; whilst 
each of the articular surfaces at its upper end shows a similar perforation, which is the 
orifice of one of the two branches into which the axial canal bifurcates in the interior 
of the segment, for the supply of the two Arms borne by it. ‘The dorsal face of this 
segment is everywhere irregularly convex ; but the ventral face has a deep depression in 
its centre, the bottom of which almost reaches the axial canal. 

80. The segments which form the skeleton of the Arms (Plate XLII. fig. 5) at this 


740 DR. W. B. CARPENTER ON THE STRUCTURE, PHYSIOLOGY, AND 


period, depart even less than the preceding from the simple type of conformation which 
they present at their first development (§ 67), being still obviously composed of the 
original cribriform plate, which constitutes their convex dorsal surface, with an ingrowth 
of fasciculated tissue that closes over the axial canal, and gives to the ventral aspect a 
flattened surface with a median groove. ‘This ingrowth is most abundant towards the 
extremities, where also the meshes of the reticulation are smaller, so that these parts 
have a more solid character than the rest. We now begin to see that alternate inclination 
to one side and the other, which is so marked a feature in the articular extremities of 
the segments of the adult ; and we also notice that whilst these extremities are in close 
contact with one another on the dorsal aspect (B), except where a small depression exists 
in each for the attachment of the articular ligament, the articular surfaces of the ventral 
face (A) slope away from each other so as to leave a considerable space for the lodgment 
of the two muscular bundles, which are now conspicuously interposed between each 
pair of segments in the basal part of the arms, with certain exceptions. These excep- 
tions correspond with those which present themselves in the adult (§) 47-50); though the 
peculiarities of conformation which mark them are as yet but little pronounced. ‘Thus 
the adjacent extremities of the first and second brachial segments present nearly the 
same aspect on their ventral as on their dorsal face, no bevelling-off being seen on the 
articular surfaces of either; and they are connected by ligament only, no muscular fibres 
being here distinguishable. Again, the adjacent articular surfaces of the third and 
fourth segments come into yet closer contact, not even a connecting ligament being 
interposed, and the line of their junction being transverse instead of oblique ; this pre- 
figures the peculiar syzygal union which shows itself between these and other pairs of 
segments in the adult () 50)—Towards the extremities of the Arms, we find the seg- 
ments even more cylindrical (Plate XLI. fig. 4, 4, B), except where lateral processes are 
given off for the articulation of the pmnules; and their terminal faces are simply apposed 
to each other transversely, without either the alternate obliquity or the bevelled articular 
surfaces of the basal segments. And at the growing points of the Arms precisely the 
same rudimental condition of the segments presents itself (Plate XX XVIII. fig. 1), 
as that which has been already described (§ 67) as showing itself at an earlier period 
in their basal segments. Thus we may trace in one and the same Arm several successive 
stages of development of the pieces of its skeleton; the most advanced segments (those 
nearest the base of the arms) showing adumbrations of their adult peculiarities, although 
not yet departing in any considerable degree from their simple primitive type. 

81. Besides the regular skeleton of the Arms, we commonly find their perisome of 
condensed sarcode to contain irregular branching spicules (Plate XLII. fig. 5, A,B), forming 
a sort of incomplete reticulation for the support of the elevated folds which constitute 
the margins of the ventral furrows. These are obviously the rudiments of the dermal 
plates which have been shown by Professor J. MULrr’ to form a complete armour to 
the ventral perisome and its prolongations along the ventral surface of the arms in Pen- 


1 Uber den Bau des Pentacrinus Caput-Meduse, p. 48. 


DEVELOPMENT OF ANTEDON (COMATULA, LAMK.) ROSACEUS. 741 


tacrinus Caput-Meduse. It is curious that this perisomatic skeleton of the Arms, like 
the Oral plates (§) 82, 94), subsequently undergoes complete absorption, so that no 
trace of it is discoverable in the adult Antedon. 

82. The only portions of the skeleton of the young Antedon now remaining to be 
described are the Oral and the Anal plates; and respecting these there is but little to 
be said. The only change which the five Ora/s have undergone consists in a further 
advance of the process of absorption, the commencement of which has been already 
noticed (§ 68). This process goes on with considerable rapidity during the period at 
which the pedunculate Pentacrinoid is being transmuted into the free Antedon ; and as 
the epoch of its detachment from the stem is not always precisely the same (9 72), so 
the amount that has been removed by absorption at that epoch varies in different speci- 
meus. In some we find the upper half or even two-thirds of each oral plate to have 
entirely disappeared; whilst in others the marginal portions only of the upper part of 
the plate have been removed, leaving a sort of central tongue projecting upwards from 
the basal portion. The single Anai plate (Plate XLI. fig. 2, a) still retains the elliptical 
form which characterized it from the time when it was lifted out from the circlet of radials 
() 64); and it seems to have undergone but little change in any of its dimensions, either 
by addition or absorption. It is still a simple cribriform film, of which the lower portion 
shows a closer texture and a more uniform margin than the upper; and it is not con- 
nected with any other portion of the skeleton, save by the general perisomatic substance. 

83. The entire skeleton of the Calyx—putting aside the centro-dorsal piece as really 
belonging to the stem—may be described, according to the formula of MM. pg Koninck 
and Lr Hon (op. cit.), as consisting of the following pieces :— 


Basalsre ttn et eee O 
eadtalse ye ONO 
first, 1 (Anal). 
second, 5 (Orals). 
Brachats 2 S| EO: 


Interradials { 


84. Professor WyvILLE THomson, however, regards the skeleton as composed of two 
systems of plates, the radial, and the perisomatic; which he states to be “ thoroughly 
distinct in their structure and mode of growth”’. The Radial system consists of the 
joints of the stem, the centro-dorsal plate, the radial plates, and the segments of the 
arms and pinnules. ‘The Perisomatic system includes the basal and oral plates, the 
anal plate, the interradial plates sometimes seen between the second radials (§ 59), 
and any other plates or spicules that may be developed in the perisome of the disk or 
arms (§§ 39, 81). Whilst partly agreeing with him on this point, I find myself unable 
to accept his distinction to its full extent, since its basis is not in harmony with my own 
observations. .“ The joints or plates of the radial system,” he says, “may be at once 
distinguished by their being chiefly made up of the peculiar fasciculated (or radial) tissue 


1 Philosophical Transactions, 1865, p. 540. 


742 DR. W. B. CARPENTER ON THE STRUCTURE, PHYSIOLOGY, AND 


of parallel rods which I have already described, and by their being perforated for the 
lodgment of a sarcodic axis.” ‘The extended researches which I formerly made on the 
calcareous skeleton of EcninopERMATA generally ', would lead me to attach but little im- 
portance to the form of the reticulation as a differential character, since this often varies 
greatly in the several portions of a single plate; and Professor Wyvittr THomson is 
forced by his reliance upon it to regard the superficial cribriform portions of the radial 
plates and even of the arm-joints as belonging to the perisomatic system,—a supposition 
which seems to me inconsistent with the fact that the ingrowth of the calcareous reti- 
culation in the First Radials, by which the axial canal is at first formed as a groove and 
is afterwards covered in (9 77), takes place on the cribriform, not on the fasciculated 
type. In fact there is no distinction in texture between the endogenous additions by 
which the first radials and the basals are respectively thickened; so that we cannot 
place them in separate categories on this score. But further, we have seen that in the 
stage now described, the Basals as well as the Radials are perforated to give passage to 
the radiating extensions of the sarcodic axis of the stem, which only reach the radials 
through the basals; so that this ground of distinction also fails to separate them.—I am 
myself disposed, however, to regard the perforation or non-perforation by the radiating 
extensions of the Crinoidal axis as quite sufficient in itself to differentiate the entire 
skeleton into two series of plates, which, with Professor Wryv1LLe Tomson, I should 
term the radial and the pertsomatic; but I should rank the Basal plates with the 
former, instead of with the latter. 

85. Ishall now describe the changes which each of the component pieces of the skeleton 
undergoes in its progress towards the type which it presents in the fully-developed An- 
tedon. 

86. Centro-dorsal piece.—Through the whole period of growth, the increase of this 
segment takes place at a greater rate than that of any other part of the skeleton; so 
that it soon comes to pass beyond the circlet of Basals, and to abut on the proximal 
edge of the First Radials; and instead of stopping here, it continues to increase in dia- 
meter, until it conceals the whole inferior surface of the first radials, and sometimes 
even encroaches somewhat on the Second (Plate XXXII. fig. 1). When we examine 
into the conditions of this increase, we find them to bear a remarkable resemblance to 
those which prevail in the growth of the skeleton of Vertebrated animals. For when 
we bear in mind the form of the basin, with its cavity and inverted rim (§ 22), and 
witness its augmentation in size from its original diameter of -005 inch to its final 
diameter of *16 inch, with a corresponding augmentation of its cavity, it becomes 
obvious that there must be not merely a progressive deposit of new material on the 
external surface, but also a continual removal of old material from the internal surface, 
analogous in every respect to that by which the cavity of a cylindrical bone is enlarged 
by absorption from within, at the same time as the diameter of its shaft is augmented 
by the deposit of new layers of bone on its exterior. 


‘ Reports of the British Association for 1847, p. 117 et seq. 


DEVELOPMENT OF ANTEDON (COMATULA, LAMK.) ROSACEUS. 743 


87. With this general augmentation in size, there is an increase both in the number of 
sockets for the articulation of the Dorsal Cirrhi, and in the size of the individual sockets ; 
and there is also a marked change in their disposition. I have not been able to satisfy 
myself that after the development of the first two whorls, each consisting of five cirrhi, 
any similar regularity is observable in their subsequent multiplication; but since, as I 
shall more fully explain hereafter, the real origin of each cirrhus is in a peduncle of 
sarcodic substance put forth from the central axis in the cavity of the centro-dorsal basin, 
and since the arrangement of the whole aggregate of such peduncles is distinctly verti- 
cillate, the want of a definite plan in the grouping of the cirrhi on the external surface 
of that plate seems attributable to their very close apposition. The new cirrhi always 
make their appearance between those previously formed and the base of the calyx, so 
that their sockets are close to the margin of the basin; and this is the position in which, 
as already stated (§ 26), we find those rudimental cirrhi that often present themselves 
even in the adult Antedon. The increase of the cirrhi in diameter is by no means 
proportional to the increase in the diameter of the centro-dorsal plate ; so that not only is 
space made on its surface for the augmentation in the number of their sockets from 10 
to between 30 and 40, but a vacancy gradually comes to be left in the central part 
of the exterior of the basin, which extends with its growth, and finally comes to bear a 
considerable proportion to its diameter (§ 22). This vacancy cannot be accounted 
for solely by the widening-out of the innermost circle of sockets by the general growth 
of the basin in the manner already described; and I feel no doubt that it is prin- 
cipally due to a progressive exuviation of the first-formed cirrhi from within out- 
wards, concurrently with the development of new ones near the margin; those cirrhi 
which surrounded the summit of the stem being first shed, and their sockets being 
filled up by new deposit; and the space thus formed being gradually widened by 
the progressive exuviation of the cirrhi that bound it, and the filling-up of their sockets. 
For in comparing a series of centro-dorsal plates in different stages of development, I 
find distinct traces of such an obliteration of the original sockets; and when we come 
to study the connexions of the sarcodic axes of the cirrhi with that central Crinoidal axis, 
of which the portion not left behind in the Stem is included within the Centro-dorsal 
plate, we shall find additional evidence to the same effect—Thus it appears that the 
total number of dorsal cirrhi developed during the life of any individual Antedon, con- 
siderably exceeds that which we meet with at any one epoch. How many of the earlier 
cirrhi are exuviated before the latest are put forth, I cannot state with certainty; but I 
should think that the number cannot average less than from 15 to 20, thus raising the 
total to at least 50. 

88. Before leaving the Centro-dorsal basin, there is a further point of much interest 
to be noticed in regard to its growth; namely, the perforation of its wall for the passage 
of the new twigs which are given off from the central axis from time to time, and 
which, when they emerge on its external surface, become the sarcodic axes of the cirrhi. 
It scarcely seems probable that such perforations should be left as vacuities in the 

MDCCCLXVI. 51 


744 DR. W. B. CARPENTER ON THE STRUCTURE, PHYSIOLOGY, AND 


exogenous additions made to the calcareous reticulation, whilst the radiating sarcodic 
twigs for whose passage they are destined are prevented from gaining access to them by 
the imperforateness of the inner wall. And looking to the numerous examples which 
we have in the development of Antedon, not only of the entire absorption of some parts 
of the skeleton, but of the complete remodelling of others,—as shown in the growth of 
this very plate, and still more remarkably in the formation of the “rosette” from the 
original “basals” (§§ 89, 90)—I cannot but regard it as more probable that these 
cirrhal twigs, as they are successively put forth in the cavity of the basin and impinge 
upon its inner wall, have the power of forcing (as to speak) a passage for themselves, 
by inducing an absorbent action in that part of its substance that lies in their course 
towards the external surface. 

89. Basal Plates—The mode in which the “rosette” (§ 35) is formed by the remo- 
delling and subsequent coalescence of the five Basals, and in which the sarcodic exten- 
sions of the central axis which are transmitted through the Radial plates to the Arms and 
pinnules, come to lie on the dorsal or external face of the “rosette,” whilst they origi- 
nally lay along the ventral or internal face of the basals, is certainly the most curious 
feature in the developmental history of the skeleton of Antedon.—It has been already 
shown () 76) that the cribriform plate of which each basal at first entirely consisted, is 
so much thickened by endogenous growth during the later stages of Pentacrinoid life, 
that the radial sarcodic cords come to be entirely invested by calcareous reticulation ; 
and the floor of the ventral cavity shows no inequality as we pass from the central por- 
tion formed by the basals to the peripheral formed by the radials (Plate XLI. fig. 5). 
Very soon after the detachment of the young Antedon, however, a remarkable change 
begins to show itself in the basal pentagon, which is now entirely concealed externally 
by the extension of the centro-dorsal basin over its dorsal surface; for the cribriform 
film of which each basal plate was originally composed, and which still forms its ex- 
ternal layer, now undergoes absorption, especially where it covers in the radial prolon- 
gation of the axis, so that the central space left by the incomplete meeting of the valves 
of the basal pentagon, is extended on its external aspect into five broad rays (Plate XLII. 
fig. 7,6), though on its internal or ventral aspect, where it is bounded by the last-formed 
portion of the endogenous reticulation, it shows no corresponding increase (Plate XLII. 
figs. 2, 6, 0). 

90. This removal of the older and outer part of each basal plate by absorption, and the 
consolidation of the newer and inner by additional calcareous deposit, go on at a rapid 
rate; so that in specimens whose size and general development show but little advance 
upon the earliest Antedon type, we find the basals already modelled into such a form 
that their coalescence will produce a somewhat unshapely “rosette.” In Plate XLI. 
fig. 8, a, is shown the dorsal aspect of one of the basal plates in which the removal of 
tlie external layer has been carried so much further, that what is now left of it consti- 
tutes only a kind of thickened margin along those sides of the plate which are received 
between the First Radials; and by an extension of the same process along the median 


DEVELOPMENT OF ANTEDON (COMATULA, LAMK.) ROSACEUS. 745 


line of each plate, until the external layer has been completely removed from its salient 
angle (fig. 5, 4), the two lateral portions of that layer are separated from each other; 
and remain only as a pair of curved processes extending themselves from the inner 
layer in such a manner as to give to the plate when viewed from its ventral side some- 
what the aspect of a saddle (fig. 3, c, d). When the five Basals thus altered are in 
their normal apposition, the curved process on either side each plate comes into contact 
with the corresponding process of its next neighbour; and the junction of the two 
forms a sort of ray curving towards the dorsal aspect. As each plate thus contributes 
the half of two of these curved rays, five such rays are formed between the five salient 
processes which are put forth by the internal or ventral layer, on the median lines of 
the five plates, and are received into the retreating angles formed by the junction of the 
First Radials. Very soon an actual continuity is established in the calcareous reticula- 
tion along the lines of junction, and the “ rosette” is completed, as shown in Plate XLII. 
fig. 1, although the peculiarity of its shape becomes much more strongly pronounced 
with the subsequent increase of its size (Plate XX XIII. figs. 9-11).—Thus we see that 
the “ Rosette” is essentially formed at the expense of the secondary or yentral layer 
of the original Basals, the ends of the curved rays being the sole residue of their primary 
or dorsal layer; and since, by the remoyal of the median portion of that layer in each 
plate, the radial cords are left bare on their dorsal aspect, they now pass from the cen- 
tral axis into the canals of the First Radials on the outside of the calcareous skeleton 
which occupies the central part of the base of the Calyx, instead of reaching these by 
passing (as they did in the first instance) along its internal face, or (as at a later period) 
through the middle of its substance. 

91. First Radials—In the passage of these plates from their rudimental to their 
mature condition, the principal alteration that we notice, besides an immense increase in 
size, consists in a change in the proportions of their principal dimensions, their thickness 
and solidity increasing much more rapidly than their superficial extension. ‘This increase 
takes place in such a manner that the lateral portions of the plate are brought to the 
same thickness with the median, the dorsal and ventral surfaces becoming nearly parallel ; 
and the lateral faces come to be flattened against each other, and to adhere so closely 
that by the apposition of the five plates a solid annulus is formed, The diameter of the 
central space of this annulus, which is occupied by the * rosette,” does not increase 
during growth in nearly the same degree as that of its periphery, the size of each plate 
(it would seem) being more augmented by addition to its external face than to its lateral 
faces; so that the ratio of its breadth at its inner and its outer margins, instead of being 
(as at the conclusion of Pentacrinoid life) about 2:3, comes to be only 1: 3, the shape 
of its dorsal face being thus changed from a trapezoid 
to a triangle with its apex truncated. Concurrently with 
these changes, we find that the various ridges and fosse {. 
on the external and ventral faces of the plate (§ 35, Plate 
XXXVI. fig. 1, a,c), for the attachment of the muscles and 

512 


746 DR. W. B. CARPENTER ON THE STRUCTURE, PHYSIOLOGY, AND 


ligaments by which it is articulated to the Second Radial, are gradually developed into 
the form they present in the adult; and that the characteristic ridges and furrows of its 
internal face (B), with the prolongations that connect it with the ventral face of the rosette, 
make their appearance. All these features are marked out when the size of the plate is 
still minute as compared with that which it ultimately attains; and a little consideration 
will show that they cannot be maintained through each subsequent stage of growth, 
without a process of modelling analogous to that already described in the growth of the 
centro-dorsal and basal plates,—the first-formed portions of the calcareous skeleton being 
remoyed by absorption, whilst new deposits are being laid down elsewhere. If any further 
evidence of this be needed, it will be found in the enlargement of the Canals which are 
occupied by the radial prolongations of the central sarcodic axis, the diameter of these 
canals in the adult being at least equal to the whole breadth of the plate in the young. 

92. Second Radials.—The alteration which the form of the Second Radials undergoes 
in their progress to maturity, is even greater than that of the First; for whilst they 
increase but little in the direction of their original length—+. e. in the space between 
their proximal and their distal faces,—they undergo a great augmentation both in 
breadth and in depth (Plate XXXVI. fig. 2), their proximal face attaining an equality 
in both dimensions with the distal face of the first radial to which it is articulated, and 
its distal face coming to present a similarly expanded surface to the proximal face of the 
third vadial, in the place of the mere convexity in which the then cylindroid segment 
terminated at an early period (§ 78). This change in the proportion of the several 
dimensions of these plates begins to show itself very soon after the termination of Pen- 
tacrinoid life, as is seen on comparing 7", 2” in Plate XLI. fig. 6, and Plate XLII. fig. 7; 
and, as in the preceding instance, there takes place concurrently with their increase of 
size a gradual development of the prominences that give attachment to muscles and 
ligaments, with a deepening of the cavities that lie between them, as well as a pro- 
gressive enlargement of the central canal. 

93. Third Radials—The change of form which the Third Radials undergo concur 
rently with their great increase in size, is scarcely less considerable than that of the 
Second; and the same tendency is manifested to lateral and vertical augmentation 
rather than to increase in radial length. The proximal face of the plate, which is ap- 
posed to the distal face of the second radial, rapidly increases both in width and depth ; 
and comes like it to present an expanded surface, the ventral and dorsal margins of 
which form the bases of triangles formed by the ventral and dorsal faces respectively 
(Plate XXXVI. fig. 3,c,p). The entire sides of these triangles now form the margins of 
those lateral surfaces for the articulation of the first Brachials, which in the earlier period 
were merely a pair of facets somewhat inclined to each other on the distal extremity of 
the segment (Plate XLII. fig. 3,7*). And these lateral articular faces, as they increase in 
proportional dimensions, come also to present prominences and fosse similar to those that 
are characteristic of the distal faces of the First Radials, which they nearly equal in size 
as well as resemble in appearance. The central canal, with the branches into which it 


DEVELOPMENT OF ANTEDON (COMATULA, LAMK.) ROSACEUS. TAT 


bifurcates, is progressively enlarged by the internal absorption of its wall, as in the pre- 
ceding cases. 

94. Oral Plates—The removal of these first-formed plates by absorption, which we 
have seen to commence before the termination of Pentacrinoid life, is completed very 
soon after the young Antedon has entered upon its free stage of existence. The absorp- 
tive process continues to take place from above downwards; and the last traces of these 
plates that can be distinguished, are seen as glistening fragments of calcareous network 
at the bases of five membranous valves which still fold over the tentacles forming the 
oral ring, in specimens which have attained a diameter of about an inch and a half. 
These soon disappear entirely. 

95. Anal Plate—This plate is still distinguishable in specimens that show no vestiges 
of the Orals; but it has undergone no increase in superficial dimensions, and is so far 
from being augmented in thickness that it seems rather to have been thinned by inci- 
. pient absorption over its whole surface, preparatory to its complete disappearance a short 
time after. I do not find that either the upper part of this plate disappears before the 
lower (as we have seen to be the case with the Orals), or the lower before the upper ; 
and as I have found no vestiges of it, though I have carefully sought for them, in young 
Antedons of about 2 inches in diameter, I conclude that the entire plate is removed at 
once by a continuance of absorption over its whole surface. 

96. Arms.—lIt does not seem requisite to follow in any detail the development of the 
segments of the Arms; since the changes in conformation through which the first 
formed Brachial segments pass in their progress to maturity, are precisely analogous to 
those which have been already described in the Radials; and the successive production 
of new segments at the extremities of the arms takes place after exactly the same fashion 
as in the Pentacrinoid stage. The general tendency is to an increase in the diameter of 
the segments, which is relatively much greater than the increase in their radial length 
(§ 40); and with this there is an extension of their apposed articular faces, which gra- 
dually come to present the ridges and fossee characteristic of the adult type, whilst at 
the syzygies these faces are brought into closer mutual approximation. The central 
canal by which each segment is traversed, undergoes a corresponding enlargement. The 
development of the Pinne from the basal portions of the arms, which for the most part 
remain destitute of them for some time after the first appearance of these lateral ap- 
pendages (§ 69), takes place by the time that the Orals disappear; but these interme- 
diate pinne are long in attaining the dimensions of those nearer the terminations of the 
arms. The increase of the Pinne in length, like that of the Arms themselves, partly 
depends upon an increase in the number of their segments, and partly on an augmen- 
tation in the length of each individual segment. How ‘and where the new segments 
are added, I cannot certainly say; but it may be safely assumed that they are not deve- 
loped at the terminations of the pinnules, since their peculiar terminal hook is formed 
when as yet the segments are few in number. And as the basal segment has a peculiar 
conformation for its articulation with the brachial from which the pinnule proceeds 


748 DR. W. B. CARPENTER ON THE STRUCTURE, PHYSIOLOGY, AND 


(§ 54), I cannot think it likely that it is displaced from time to time by the interposi- 
tion of a new segment between itself and the brachial. The most probable place for 
such interposition seems to be either between the basal and the second segment, or be- 
tween the penultimate segment and the terminal claw-bearing segment. Since no such 
traces of incompleteness present themselves in the segments which follow the basal as 
would justify the former supposition, we seem compelled to adopt the latter; and it is 
not a little curious that the increase in the number of segments in the Stem, the Dorsal 
Cirrhi, the Arms, and the Pinnules should thus take place in different modes,—the new 
segments making their appearance in the Stem immediately beneath its highest segment 
(§ 63), in each Dorsal Cirrhus at its base (} 66), in each Arm at its termination (§ 67), 
and in each Pinnule at the base of its terminal segment. 


EXPLANATION OF THE PLATES. 


PLATE XXXI. 


Side view of Antedon rosaceus attached by its dorsal cirrhi to a stone; drawn from a 
living specimen in a Vivartum.—Magnified 35 diameters. 

A, Disk and basal portion of the Arms of the same, as seen from above; showing the 
manner in which the basal pinnules arch over the ventral surface of the disk.—Magni- 
fied 34 diameters. 


PLATE XXXII. 


Fig. 1. Dorsal aspect of the Calyx of Antedon rosaceus, as seen after the removal of the 

dorsal cirrhi:—c, Centro-dorsal plate, entirely concealing the First Radials ; 
7, r°?, Second Radials; 7°, 7°, Third or Axillary Radials; 07’, ge First 
Brachials—Magnified § diameters. 

Fig. 2. Ventral aspect of the Calyx, as seen after the removal of the visceral mass. 
Around the central depression is seen a circlet of five pairs of Muscles, passing 
between the First and Second Radials; and outside these is a circlet of ten 
pairs, passing between the Third Radials and the First Brachials (see Plate 
XXXIV. fig. 2)—Magnified 8 diameters. 

Fig. 5. Ventral surface of the Visceral Disk, showing the mouth, m, in the centre, with 
five channels radiating from it, which form by their bifurcation the ten 
channels that pass along the Arms and give off branches to the Pinnules, the 
first and second of which on each arm assist in supporting the visceral mass ; 
at a is shown the Anus seated on a proboscis-like funnel that rises between 
two of the Radial channels.—Magnified 8 diameters. 

Fig. 4. Dorsal Cirrhi as seen radiating from the Centro-dorsal plate, ¢c, to which they are 
articulated.—Magnified 15 diameters. 


DEVELOPMENT OF ANTEDON (COMATULA, LAMK.) ROSACEUS. 749 


Fig. 5. Dorsal Cirrhi in various stages of growth and development :—a, typical mature 
cirrhus ; 6, c, d, ¢, f, successive stages of incomplete type; g, h, %, h, 1, suc- 
cessive stages of complete type; m,”, cirrhi presenting most of the characters 
of maturity, but having less than the normal number of segments, and deficient 
in the opposing process.—Magnified 45 diameters. 


PLATE XXXIII. 


Fig. 1. Pentagonal Base of the Calyx of Antedon vosaceus, formed by the coalescence of 
the five First Radials, its dorsal surface (shown in fig. 2) having been removed, 
so as to lay open the radiating Axial Canals, a, a, and their communicating 
branches, J, 6; around the central space is an irregular calcareous network, 
formed by the inosculation of processes sent off from the internal faces of the 
First Radials.—Magnified 25 diameters. 

Fig. 2. Pentagonal Base of the Calyx, formed by the coalescence of the five First Radials, 
with the Rosette in situ, as seen from its dorsal aspect, the Centro-dorsal plate 
having been removed.—Magnified 25 diameters. 

Fig. 3. Pentagonal Base of the Calyx, formed by the coalescence of the First Radials, 
as seen from its ventral aspect:—the central aperture for the passage of a 
prolongation of the Crinoidal Axis is surrounded by irregular processes from 
the inner margins of the First Radials, which connect themselves with the 
central portion of the Rosette; the oblique sides of the pentagon form the 
surfaces of articulation for the Second Radials.—Magnified 25 diameters. 

Fig. 4. Centro-dorsal plate, seen from its dorsal side after the removal of the cirrhi; 
showing its flattened central portion surrounded by between two and three 
circlets of articular sockets—Magnified 15 diameters. 

Fig. 5. Lateral view of the same, showing the alternating arrangement of the sockets. 
—Magnified 15 diameters. 

Fig. 6. Centro-dorsal plate, seen from its ventral side after its detachment from the 
Pentagonal Base, showing its basin-like cavity, the bottom of which is per- 
forated by minute apertures for the passage of the axial cords of the cirrhi; 
on the inturned lip of the basin are five shallow depressions, @, @, corresponding 
to the spout-like processes of the Rosette——Magnified 15 diameters. 

Fig. 7. Portions of Base of Calyx at origin of Rays, in the variety showing Interradial 
Plates :—c, Centro-dorsal; 7°, 7°, Second Radials; 7*, 7°, Third Radials: at A 
these interradials are numerous, minute, and dissociated, and are obviously 
perisomatic in their character; at B they are fewer, larger, and more com- 
pactly arranged.—Magnified 30 diameters. 

Fig. 8. Segments of Dorsal Cirrhi; @, basal, 4, from middle of length; showing the 
central passage surrounded by a prominent annulus, with depressions on either 
side for the attachment of ligaments.—Magnified 70 diameters. . 


750 DR. W. B. CARPENTER ON THE STRUCTURE, PHYSIOLOGY, AND 


Fig. 9. Central portion of fig. 2 more enlarged, showing the Rosette in sitw:—a, a, lines 
of junction of the First Radials; 0, 4, apertures formed by the coalescence of 
the spout-like processes of the Rosette with the inner margins of the First 
Radials.—Magnified 70 diameters. 

Fig. 10. Rosette separated and seen on its dorsal aspect, showing its five flattened trian- 
gular processes, a, a, and its five intermediate spout-like processes, 6, 0.— 
Magnified 100 diameters. 

Fig. 11. Rosette seen from the ventral side, showing around its central orifice irregular 
projections which coalesce with the processes given-off from the inner margins 
of the First Radials; a, a, triangular processes; 4, 6, spout-like processes.— 
Magnified 100 diameters. 


PLATE XXXIV. 
The following References are common to both Figures :— 
r, 7, First Radials. 
7°, 7°, Second Radials. 
r, 7°, Third or Axillary Radials. 
ér', by, First Brachials. 
br, br?, Second Brachials. 
br’, br’, Third Brachials. 
p, p, Pinnules. 

Fig. 1. Horizontal section of Calyx and basal portions of Arms of Antedon rosaceus, 
flattened out; showing the axial canals, a, a, of the Rays which communicate 
by circular branches at 0, 0 (as in Plate XXXIIT. fig. 1), and bifurcate at ¢, ¢, 
to pass into the Arms.—Magnified 18 diameters. 

Fig. 2. Interior of the Calyx with basal portions of Arms, of a young Antedon, to show 
the disposition of the Muscles :—m', m', five pairs of muscles passing between 
the First and Second Radials; m, m?, ten pairs of muscles passing between 
the Third or Axillary Radials and the First Brachials; m*, m*, ten pairs of 
muscles passing between the Second and the Third Brachials.—Magnified 50 
diameters. 

PLATE XXXYV. 

ig. 1, Vertical Section of the Centro-dorsal Piece; consisting of the Centro-dorsal 
plate which forms the dome of the cavity, and which is anchylosed at the 
lines a, a, a, to the First Radials; 0, 6, canals leading to the articular sockets 
of the cirrhi; c, basal segment of a cirrhus; d, d, axial canals of First Radials ; 
é, é, portions of Second Radials; 7, Rosette.-—Magnified 70 diameters. 

Fig, 2. Longitudinal Section of three of the basal segments of a Dorsal Cirrhus, showing 

the central articular processes, and the ligaments interposed between their 
peripheral surfaces.—Magnified 70 diameters. 


eal 
de 


DEVELOPMENT OF ANTEDON (COMATULA, LAMK.) ROSACEUS. 751 


Fig. 3. Longitudinal section of the terminal portion of a Dorsal Cirrhus; showing the 
claw articulated by the plane surface cut through at a, a, to the penultimate 
segment, and the movable articulation 4, 6, in which the fossie for the lodg- 
ment of the ligament are much larger and deeper on the aboral side; at ¢, ¢ 
is shown the central canal, which is continued into the cavity of the claw.— 
Magnified 70 diameters. 

Fig. 4. Section of Centro-dorsal plate taken in a plane parallel to its flattened surface ; 
showing at J, 0 the canals leading to the articular sockets.—Magnified 
70 diameters. 


PLATE XXXVI. 

In this Plate are shown the First, Second, and Third Radials, and the First, Second, 
Third, Fourth, and Fifth Brachials, of Antedon rosaceus; their different aspects being 
designated (except in fig. 1) as follows :— 

A, internal or proximal face. 
B, external or distal face. 


c, ventral or superior face. 
D, dorsal or inferior face. 
E, lateral face. 


The following References are common to the entire series :— 
a, a, Articular Ridges. 
b, b, Fosse for Interarticular Ligaments. 
c, ¢, Muscular Fosse. 
d,d, Vertical Lamelle. 

e, Axial Canal. 

f.f; Fossa for Elastic Ligament. 

p, Articular Socket of Pinnule. 

sg, Syzygy. 
The magnifying power for all the Figures is 15 diameters. 

Fig. 1. First Radial: on its internal aspect (B) are shown the apertures, ¢, é, of the two 
passages by which the Axial Canal originates, and the apertures, g, g, of the 
circular passage by which the axial canal of each Ray communicates with the 
canal of the Ray on either side; /, furrow between the prominent margins of 
the apertures ¢, ¢; 7,7, smooth inclined faces, closely adherent to those of 
the First Radials on either side: A, external face. 


Fig. Z. Second Radial. 

Fig. 3. Third or Axillary Radial; d’, vertical ridge dividing the two articular faces. 
Fig. 4, First Brachial. 

Fig. 5. Second Brachial. 

Fig. 6. Third Brachial, united in c, p, and E with the Fourth. 

Fig. 7. Fourth Brachial. 


Fig. 8. Fifth Brachial. 
MDCCCLXVI. 5 K 


=I 


DR. W. B. CARPENTER ON THE STRUCTURE, PHYSIOLOGY, AND 


PLATE XXXVII. 


. Portion of Skeleton of Arm of Antedon rosaceus about the middle of its length, 


seen from its dorsal aspect; the segments of the Arms and Pinne remaining 
united by their ligaments; sq, sy, syzygies.—Magnified 15 diameters. 


. A similar portion somewhat nearer the base, seen from its ventral aspect, 


showing the Muscular fossz and the situation of the articulations of the Pin- 
nules.—Magnified 10 diameters. 


. Basal portion of the skeleton of the Arms with their Pinnules, seen from their 


dorsal aspect :—7*, Third Radial; 1-16, Brachial segments; sg, syzygies.— 
Magnified 10 diameters. 

A similar portion of the Skeleton of the Arms with the Pinnules removed, seen 
from their ventral aspect; showing the Interarticular Ligaments, the deep 
Muscular fosse lying between the vertical ridges, the syzygies, sg, and the 
articular sockets of the Pinnules, p, p—Magnified 15 diameters. 


PLATE XXXVIII. 


. Terminal portion of growing Arm; from a preparation in which the soft parts 


have been made transparent by soda, and the calcareous reticulation is shown 
by black-ground illumination.—Magnified 120 diameters. 


. Portions of Arm near its termination, showing the nearly cylindrical form of its 


segments:—c, c, Muscular Fosse; p, p, Articular sockets of Pinnules; 
sg, syzygies.—Magnified 15 diameters. 


. Terminal portion of Pinnule, showing the hooks at its extremity, and the series 


of short segments below the last two.—Magnified 70 diameters. 


. Terminal portion of Skeleton of Arm, with its Pinnules, seen from its dorsal 


aspect.—Magnified 15 diameters. 


. Segment of Arm from about the middle of its length; a, distal face; B, proximal 


face; c, side view.—Magnified 15 diameters. 

[N.B. Figures 4 and B have been drawn in an inverted position with refer- 
ence to those in Plate XXXVI.; the wpper margin being here the dorsal, and 
the dower the ventral]. 


. Portion of an Arm that has been broken at the first syzygy, with new arm 


sprouting from this.—Magnified 10 diameters. 


. Single Arm growing from the Second Radial, 7°, the Third Radial being alto- 


gether deficient. ‘The segments of this arm have their normal size and pro- 
portions; and the syzygies occur at their regular intervals.—Magnified 
10 diameters. 


. Calyx and basal portion of Arms of a specimen which seems at A to have lost 


one of its Rays at the junction of the First and Second Radials, a wew Ray 
and Arms having been produced on a smaller scale; whilst at B the Second 


DEVELOPMENT OF ANTEDON (COMATULA, LAMK.) ROSACEUS. 753 


Brachial of one of the Arms acts as an axillary segment, bearing two small 
Arms.—Magnified 3} diameters. 

Fig. 9. Calyx and Basal portion of Arms of a specimen which seems, like the last, to 
have lost one of its Rays at the junction of the First and Second Radials, 
the Ray and Arms having been reproduced on a smaller scale-—Magnified 
54 diameters. 

Fig. 10. Basal portion of Arms with the soft parts removed from their ventral surface, 
so as to show the disposition of the Muscles; 7°, Third Radial, with its pair 
of Muscles on either side connecting it with J" the First Brachial; between 
this and the Second Brachial, 47’, there is only ligamentous union; the next 
pair of muscles connects the Second with the Third Brachial, 7°; between 
the Third and the Fourth Brachial there is a syzygy, sg; and beyond this 
the muscles connect every segment with that which succeeds it, except where 
asyzygy intervenes. The small muscles connecting the segments of the Pin- 
nules are also shown.—Magnified 15 diameters. 


a 
Q 


ig. 11. Vertical Longitudinal Section of an Arm taken near its base, to show the 
arrangement of its Muscles, m, m, and its Ligaments, /, 7, and the imterruption 
of these at the syzygy, s7— Magnified 15 diameters. (See also Plate XLII. 
fig. 6.) 


PLATE XXXIX. 


= 
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ig. 1. Group of Pentacrinoid larvee of Antedon rosaccus in different stages :—A, showing 
the Basals, J, }, the circlet of First Radials, 7’, 7’, already complete, the rudi- 
mentary Second and Third Radials supported by this, and the circlet of Orals, 
0, 0, alternating with these and resting on the First Radials; B, showing the 
incipient development of the Arms from the extremities of the Third Radials, 
the relative positions of the other parts being but little changed, and the Dorsal 
Cirrhi not having yet made their appearance (see Plate XLI. fig. 1 for a repre- 
sentation of the skeleton in this stage on a larger scale); c, showing the 
further development of the Arms, the incipient opening-out of the Calyx 
occasioned by the increased development of the First Radials, and the first 
appearance of the Dorsal Cirrhi; p, showing the first appearance of Pinnules 
at the extremities of the Arms, the further opening-out of the Calyx (bringing 
the vent into view), and the formation of the first whorl of Dorsal Cirrhi 
(see Plate XL.); E, showing the Pentacrinoid ready to assume its free condi- 
tion, two rows of Dorsal Cirrhi being now completed, the Arms being con- 
siderably elongated by the addition of new segments, and several pairs of 
Pinnules being formed at their extremities —Magnified 15 diameters. 

Fig. 2. Skeleton of early Pentacrinoid larva, from a dried specimen, showing the mode in 

which the Calyx can be (in that stage) completely closed in by the folding 

together of the Orals, 0, 0 —Magnified 70 diameters. 

dk 2 


g. 
Fig.l; 
Fig. 2. 
Fig. 1. 
Fig. 2. 
Fig. 3 
Fig. 4. 


DR. W. B. CARPENTER ON THE STRUCTURE, PHYSIOLOGY, AND 


Skeleton of the Pentacrinoid larva represented in Fig. 1, c, showing two rudi- 


mentary segments of the Stem, the incipient development of the Dorsal Cirrhi, 
the Basals, 4, 6, the First, Second, and Third Radials, r'y7', 7°,7°, 73,75, and 
the Anal, a, now being lifted up from between the First Radials—Magnified 
50 diameters. 


PLATE XL. 


More enlarged view of a Pentacrinoid larva of Antedon rosaccus, in a stage 


nearly corresponding with that shown in Plate XX XIX. fig. 1, D, the nearest 
Ray having been remoyed so as to bring into view the Oral apparatus :— 
ed, Centro-dorsal plate, bearing two cirrhi, cir, cir, one rudimentary, another 
in an advanced stage of development; 7',r', 7°,7°, 7°,7°, First, Second, and 
Third Radials; 0, 0, Orals, now completely separated from the Radials by 
the intervention of the membranous Perisome.—Magnified 60 diameters. 


Calyx of the same specimen seen from the other side, showing the Centro-dorsal 


plate, ed, bearing two cirrhi, cir, cir, one rudimentary, the other still retaining 
its rudimentary form, the First, Second, and Third Radials, 7,71, 7°,7°, 7°,7°, 
and the Anal, @, now lifted out from between the First Radials by the deve- 
lopment of the prominent Vent, v, to which it is attached.—Magnified 60 
diameters. 


PLATE XLI. 


Skeleton of Pentacrinoid at the time of the first development of the Arms, and 


before the first appearance of the dorsal cirrhi:—d, b, Basals; 7°, 7", First 
Radials; a, Anal; 7*, 7°, Second Radials; 0, 0, Orals; 7°, 7°, Third Radials.— 
Magnified 100 diameters. 


Separated portions of the skeleton of the Calyx of a Pentacrinoid at the epoch 


of its detachment from the stem :—s, external and internal (dorsal and ventral) 
faces of Basals; rR’, external and internal faces of First Radials; r®, external 
and internal faces of Second Radials; R*, external and internal faces of Third 
Radials; a, Anal; c, ventral aspect of Centro-dorsal basin.—Magnified 100 
diameters. 


. Basals in process of conversion into Rosette :—a, dorsal aspect, showing partial 


absorption of first-formed lamella; 4, another specimen turned a little to one 
side, showing the more complete absorption of the original lamella; 
ec, d, ventral and dorsal aspects of a basal which has been nearly modelled by 
absorption and outgrowth into the form requisite to constitute the; Rosette 
(Plate XXXIIT. figs. 10, 11) by union with its fellows.—Magnitied 100 
diameters. 


Portion of the dried Stem of a young Pentacrinoid; showing the prominent 


annulus in the middle of each segment.—Magnified 70 diameters. 


DEVELOPMENT OF ANTEDON (COMATULA, LAMK.) ROSACEUS. (i) 


Fig. 5. Skeleton of the Calyx of a Pentacrinoid nearly ripe for detachment, as seen from 
its internal or ventral aspect, the centro-dorsal plate having been remoyed; 
b, b, Basals; 7’, 2", First Radials.—Magnified 50 diameters. 

Fig. 6. The same, as seen from its external or dorsal aspect :—c, central pore for the 
passage of the sarcodic axis through the Centro-dorsal plate; }, 6, Basals ; 
”, 7, First Radials; 7°, 7°, Second Radials; 7°, 7*, Third or Axillary Radials ; 
br, br’, Brachials; @, Anal.—Magnified 50 diameters. 


PLATE XLII. 


. 1. Incipient Rosette (see Plate XX XIII. figs. 10, 11) formed by the coalescence 
of the five altered Basals, in a young Antedon.—Magnified 120 diameters. 


er 
ae 
bo 


. Skeleton of Base of Calyx of young Anfedon, seen from its internal or ventral 
side; showing the five basals (4) altered by endogenous growth, in preparation 
for the formation of the Rosette.—Magnified 100 diameters. 

Fig. 38. Calyx of young Antedon just detached, seen from its dorsal side, showing five 

Cirrhi of the mature type and five of the rudimentary type, the Radial and 
Brachial plates, and the extension of the visceral disk as far as the Third 
Radial.— Magnified 25 diameters. 

Fig. 4. Skeleton of the terminai portion of the Arms of a mature Pentacrinoid :—a, ven- 
tral aspect; B, dorsal aspect—Magnified 100 diameters. 

Fig. 5. Skeleton of the basal portions of the Arms of a mature Pentacrinoid :—a, ventral 
aspect; B, dorsal aspect.—Magnified 100 diameters. 

Fig. 6. Skeleton of base of Calyx of young Antedon, seen from its ventral aspect ; 
showing the five Basals grouped around 4, and traversed by canals for the 
radiating cords of the sarcodic axis, of which a trunk enters each basal from 
the central space, and then subdivides into two branches, that pass into the 
two Radials between which the salient angle of the basal projects ; thus each 
First Radial receives cords from two basals, and these are lodged in two Canals 
which coalesce into one towards its distal border, each of them having first 
become connected by a lateral branch with the like canal in its contiguous 
First Radial.—Magnified 70 diameters. 

Fig. 7. The same viewed from its dorsal aspect, the Centro-dorsal plate haying been 

removed ; showing that the central space around 4 on the under side has been 

enlarged by the absorption of part of the original Basals, though it is still con- 
tracted, nearer the cavity of the Calyx, by the secondary endogenous growth: 
the system of Axial Canals is displayed as in the preceding figure—Magnified 

70 diameters. 


Fig. 


DR. W. B. CARPENTER ON ANTEDON (COMATULA, LAMK.) ROSACEUS. 


PLATE XLIII. 


Portion of the Sarcodic Basis of the Skeleton of Antedon rosaceus, showing the 
granular glomeruli which occupy the interspaces of the calcareous reticula- 
tion.— Magnified 120 diameters. 

Transverse section of a decalcified Arm at a syzygy, showing the radiating exten- 
sions of sarcodic substance which occupy the grooves of the apposed calcareous 
segments.— Magnified 30 diameters. 

Ligamentous substance uniting the dorsal portions of the Brachial segments, 
magnified 70 diameters; 3a, portion of the same magnified 250 diameters. 


- Muscular fibres, magnified 250 diameters, showing at @ their enlarged termina- 


tions; A, separated fibres enlarged 870 diameters, showing nuclear (?) cor- 
puscles, a, 0, ¢. 


. Vertical section of the decalcified skeleton of the basal portion of an Arm of 


Antedon rosaceus, showing the disposition of the Muscles and Ligaments :— 
8, 8, 8, bodies of the segments perforated by the Axial Canal, @, a, and con- 
nected by the Interarticular Ligaments, /', /', and the Elastic Ligaments, /’, P; 
s', s', vertical lamellz, the spaces between which are occupied by the Muscles 
m, m.—Magnified 55 diameters. 


. Horizontal section of the decalcified skeleton of the basal portion of an Arm, 


passing through the Axial Canal a, a, and showing the alternating obliquity 
of the articulations, as shown in the disposition of the ligaments /*, ?; at 
8g, Sg, are shown in’ transverse section the radiating extensions of sarcodic 
substance interposed between the syzygies, shown in fig. 2.—Magnified 35 


diameters. 


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