54 Gen. Sub. 
I. GENERAL SUBJECTS. 
(247).—Excretion in molluscs, ancl comparison with that in other groups; 
CutcNOT (142).—Phagocytosis and excretion in annelids ; Schneider (697). 
—Phosphorescence and protoplasmic continuity; WatasIs (815).—Animal 
locomotion; Muybridge (563).—Relation of motion in animals to the 
electrical phenomena which are associated with it; Burdox-Saxderson 
( 98).—Physiology of locomotion ; Le Hello (442).—Nervous physiology 
of locomotion in dogfish; Bethe (62).—Nervous physiology of locomotion; 
Caselli (112).—Nervous functions; Langley (426). 
Galvanotaxis of Infusorians; Birnkoff (65).—Influence of constant 
galvanic current on lower animals; Carlgren (106).—Rheotropic re¬ 
actions in animals; Dewitz (172).—Reactions to stimuli in unicellular 
organisms,— Paramecium, etc.; Jennings (375, 376, 377).— Poikilo- 
thermal Vertebrates; Krehl & Svetbeer (415). — Galvanotropism of 
ciliated Infusorians; Mouton (559).—Specific gravity of Infusorians in 
relation to the problem of Geotaxis ; Platt (618).—Influence of Rontgen 
rays on Protozoa; Schaudinn (688).—Geotropism in Paramecium ; Sos- 
nowski (735).—Anemotropism and other tropisms in insects; Wheeler 
(829). 
Shell-making in Molluscs; Steinmann (744). 
Clamps and valves and similar mechanical arrangements in the animal 
kingdom; Thilo( 756).—Moulting and encystation in Nematodes; Matjpas 
( 509).—A diastatic ferment in the hen’s egg; Muller (560).—Utility of 
phosphorescence in deep-sea fixed Ccelentera—to attract the small Crus¬ 
taceans etc., which form the food; Nutting (581).—Do reactions of lower 
animals to injury indicate pain-sensations? Norman (575).—Osmotic 
properties of cells, their probable causes, and their functional importance; 
Overton (589).—Relation between internal temperature and respiratory 
movements in hibernating animals ; Pembrey & Pitts (600).—The marine 
milieu and the serum; Quinton (631).—Normal presence of minimal 
quantities of arsenic (in combination with nucleus) in the thyroid of man, 
pig, dog, sheep, etc. Also in thymus and brain, but not in liver or other 
organs; Gautier (270).—Fermentation ; Green (288).—Animal ferment 
decomposing oxygenated water; Abelous (1).—Soluble reducing ferment 
in the animal organism ; in extract of horse’s kidney a ferment w r as found 
which reduced nitrates, etc.; Abelous & Gerard (2).—Co-existence of 
oxidising and reducing diastatic ferments in animal organs,—horse’s 
kidney; Abelous & Gerard (3, 4).—Reducing power of urine; Holier 
( 324).—Cellular immunity of red blood corpuscles of hedgehog, etc., 
against the globulicidal ictliyotoxin of eel-serum ; Camus & Gley (104). 
—Duration of life; Beeton & Pearson (54).—Temperature of insects; 
Bachmetjew (32).—Palolo phenomenon and other cases of the influence 
of cosmic factors on physiological phenomena; Friedlander (250).— 
Chemical continuity of living substance; Hormann (357, 358).—Action of 
salts on Infusorians; Balbiani (34).—Production of heat by cold-blooded 
animals; Dubois (184). 
c. Pigmentation and Colour. 
Chlorophyll in liver of Invertebrates; Dastre & Floresco (154).— 
Melanotic pigment; Ehrmann (199).—Pigment of Arenicola ; Fauvel 
( 220).—Pigment forming in butterflies’ wings ; Friedmann (251).—Origin 
of pigment and coloration in leeches; Graf (286).—Pigments of Aplysia ; 
MacMunn (493).—Pigmentation and mobility of pigment granules in 
Tunicates; Pizon (616).—Affinities of the enterochromes; Newbigin 
( 570 ). — Colours and pigments of butterflies; Newbigin (571).—Dark 
pigment in Molluscs ; Steinmann (744). 
Coloration of British birds and their eggs; Fox (246).—Coloration in 
Turbellaria ; von Graff (287).—Development of coloration in Amphibians; 
