REPORT ON THE CIRRIPEDIA. 31 



After the four canals have run independently of one another for about 1^ mm.; 

 the first duct unites with one of the two ducts into which the second canal has divided, 

 whereas the other half of the second duct terminates by uniting -ndth the third. In the 

 lowest sections of the peduncle of Scalpellum mdgare which I have been able to 

 investigate, two ducts only are present. They run close to one another, and are 

 placed within the wide canal which in the peduncle represents the ccelom. Cf course 

 higher up in the peduncle they were situated in this canal also ; but at the place where 

 they commence with a blind extremity, as a rule, they are not within this cavity. All 

 the canals have very ii-regularly folded walls, and are filled up with a solid mass of a 

 granular structure. Probably this is the cement after it has been aifected by alcohol and 

 reagents. At many places, part of the chitinous (?) and irregularly folded wall is stained 

 also by the aluminium carminate. 



The way in which the cement is poured out into the canals has not been observed by 

 me. Everywhere round the canals a dense layer of connective tissue with numerous nuclei 

 is observed, and at the places where the wall of the duets is open, a spongy mass of this 

 tissue penetrates within the opening. Most probably the connective tissue is charged with 

 the duty of conducting the' cement till it comes within the canals. The communication 

 of the microscopic canals, at the end of which the glands are placed, with the cement- 

 ducts — or with the connective tissue surroundina; these ducts — has not been observed. I 

 think it impossible to observe this without the aid of very rich and fresh material. 



The cement-glands of Scalpellum regium (Wyv. Thoms.), Hoek, are not numerous, 

 but they are relatively large. They are placed in two groups in the superior part of the 

 peduncle to the right and to the left side (PL V. fig. 8). As a rule, each gland is composed 

 of three or four glandular cells (PL V. fig. 11). I measured a gland which appeared to me 

 to be unicellular, and its greatest diameter was 0"5 mm. ; another composed of thi-ee ceUs 

 had a length of 07 mm. The nuclei in the glands of this species have a very characteristic 

 fibrillar structure ; it is, of course, possible that the reagents have caused this. The ducts 

 going ofi" from the cells are narrow (their diameter being 0'016 to 0'02 mm.) ; the nuclei of 

 the cells forming their walls are very distinct. The walls of these ducts are not quite smooth : 

 globular vesicles adhere to them as small excrescences, and so give the duct, especially 

 when studied in transverse section, a very curious aspect (PI. VI. fig. 3). The ducts 

 unite together so as to form groups of nearly parallel ducts, but often many of them 

 retain their independence. Often two groups of ducts reunite, to become isolated again 

 after a short time. About the middle of the peduncle I counted more than twenty 

 groups of these ducts ; some were composed of three or four single ducts, others of more 

 (PL V. fig. 10). In the centre of each gi-oup of ducts often a much wider duct is visible : 

 especially wide is a duct which runs at the rostral side of the ^peduncle close to the 

 innermost layer of muscular fibres (PL V. fig. 10 ; PL VI. fig. 3). 



This wide duct may be seen to continue as far as the uppermost part of the peduncle. 



