394 COMPARATIVE ANATOMY chap. 



definitely arranged, may occur. It is very probable that many of the 

 different forms of pedicellarise, within certain divisions, have developed 

 independently out of spines. 



1. The pedicellarise in the Ophiuroidea. — In Trlchastcr clegans, from about the 

 thirty-sixth tentacle pore of an arm onwards, the two tentacle papillfe are replaced 

 on the adoral side of each poi-e by two hooks movably articulated on a stem. This 

 stem also is articulated with a ventral lateral process of the corresponding brachial 

 vertebral ossicle. The skeleton of this apparatus consists of three pieces, belonging 

 to the stem and to the tAvo diverging hooks. The hooks do not move against one 

 another, the planes of their movement being nearly parallel. On one side a flexor, 

 and on the other an extensor muscle connects each hook with the stem. In 

 Astrophyton also, similar pedicellarise are found, and in OphiotJirix fragilis the end 

 of the arpa is beset with movable hooks provided with ilexor and extensor muscles. 

 Similar hooks ocou', further, on the lateral shields of the arms in certain species of 

 Gorgonocephalus. 



2. The pedicellarise of the Asteroidea (Fig. .342). — In some groups, e.g. tlie 

 Aslerinidai, Solasteridce, and Pleraslerkhc, the pedicellarife are altogether wanting : 

 in the Astropectiiiidce they are only ver}- rarely found. 



In the simplest cases, groups of small spines may function as pedicellarise. The 

 spines of such a group are movably connected with the body, and may be arranged 

 either in two opposite rows of four to five spines each, these rows approximating or 

 diverging ; or else at definite points of the body three or four spines stand close 

 together, forming, wlien they incline towards one another, a three- or four-sided 

 pyramid. Two spines even may form a group. For instance, on the dorsal surface 

 of Asterina gibbosa, spines are found sometimes isolated, sometimes united in larger 

 or smaller groups. Among these groups there are couples connected at the base by 

 a transverse muscle, and such spines can niove towards one another more energetic- 

 ally than those of the other groups (Fig. 342, A to F). 



In the above cases, we have to a great extent to do with commencing or rudi- 

 mentary pedicellari.'e, and Ave recognise, in the larger and smaller groups of spines, 

 the material out of which pedicellari.-ie with two, three, or four forceps may be 

 developed. {Of. also what has been remarked on p. 392 on the spines of the Echinoidea 

 as organs for the seizing and conveying of prey to the mouth, and p. 390 on the 

 smaller spines of the Cidaroida. ) 



The true pedicellarise of the Asteroidea usually have two blades or valves, less 

 frequently three. Stalked and sessile pedicellarise may be distinguished. 



a. Sessile pedicellarise (Fig. 342, G). — The two blades rise 

 directly from the integument. Each consists of a calcareous piece 

 determining its shape, which may be long or short, broad or 

 narrow, pointed or blunt, flat or spoon-like. The two skeletal pieces 

 are directly articulated with a skeletal plate of the integument. In 

 Gymnasteria carinifera, for example, numerous double-bladed pedi- 

 cellarise rise at the edge of the ambulacral furrow. The two blades 

 are connected at their bases in a manner illustrated in the figure, by a 

 transverse muscle, the adductor muscle. Further, each blade at its 

 outer side (i.e. at the side turned away from the axis of the pedicel- 

 laria) is also connected with the subjacent calcareous plate of the 

 integument by an opening muscle (abductor). The bases of the 



