34 Fortes‐Silva, R., Martínez, F.J., Villarroel, M., and Sánchez‐Vázquez, F.J. (2010). Daily feeding patterns and self‐selection of dietary oil in Nile tilapia. Aquaculture Research 42: 157–160.
35 Fortes‐Silva, R., Martínez, F., and Sánchez‐Vázquez, F. (2011). Macronutrient selection in Nile tilapia fed gelatin capsules and challenged with protein dilution/restriction. Physiology and Behavior 102: 356–360.
36 German, D.P. and Bittong, R.A. (2009). Digestive enzyme activities and gastrointestinal fermentation in wood‐eating catfish. Journal of Comparative Physiology B 179: 1025–1042.
37 German, D.P., Nagle, B.C., Villeda, J.M. et al. (2010). Evolution of herbivory in a carnivorous clade of minnows (Teleostei: Cyprinidae): effects on gut size and digestive physiology. Physiological and Biochemical Zoology 83: 1–18.
38 Goodwin, T.W. (1986). Metabolism, nutrition, and function of carotenoids. Annual Review of Nutrition 6: 273–297.
39 Govoni, J.J., Boehlert, G.W., and Watanabe, Y. (1986). The physiology of digestion in fish larvae. Environmental Biology of Fishes 16: 59–77.
40 Griffin, M.E., Wilson, K.A., White, M.R., and Brown, P.B. (1994). Dietary choline requirement of juvenile hybrid striped bass. Journal of Nutrition 124: 1685–1689.
41 Gruger, E.H., Nelson, R.W., and Stansby, M.E. (1964). Fatty acid composition of oils from 21 species of marine fish, freshwater fish, and shellfish. Journal of the American Oil Chemists Society 41: 662–667.
42 Halver, J.E. (2002). The vitamins. In: Fish Nutrition, 3e (eds. J.E. Halver and R.W. Hardy), 62–143. San Diego, CA: Academic Press.
43 Halver, J., Smith, R.R., Tolbert, B.M., and Baker, E.M. (1975). Utilization of ascorbic acid in fish. Annals of the New York Academy of Sciences 258: 81–102.
44 Hamre, K. (2011). Metabolism, interactions, requirements and functions of vitamin E in fish. Aquaculture Nutrition 17: 98–115.
45 Hamre, K., Srivastava, A., Rønnestad, I. et al. (2008). Several micronutrients in the rotifer Brachionus plicatilis may be limiting for growth, survival and normal development of cod larvae. Aquaculture Nutrition 14: 51–60.
46 Hamre, K., Yúfera, M., Rønnestad, I. et al. (2013). Fish larval nutrition and feed formulation: knowledge gaps and bottlenecks for advances in larval rearing. Reviews in Aquaculture 5: S26–S58.
47 Hamre, K., Sissener, N.H., Lock, E.J. et al. (2016). Antioxidant nutrition in Atlantic salmon (Salmo salar) parr and post‐smolt, fed diets with high inclusion of plant ingredients and graded levels of micronutrients and selected amino acids. PeerJ 4: e2688.
48 Hemre, G.I., Mommsen, T.P., and Krogdahl, Å. (2002). Carbohydrates in fish nutrition: effects on growth, glucose metabolism and hepatic enzymes. Aquaculture Nutrition 8: 175–194.
49 Henry, B., Maslanka, M., and Slifka, K.A. (2010). Quality control aspects of feeding wild mammals in captivity. In: Wild Mammals in Captivity: Principles and Techniques for Zoo Management (eds. D.G. Kleiman, K.V. Thompson and C.K. Baer), 104–117. Chicago, IL: University of Chicago Press.
50 Hixson, S.M. (2014). Fish nutrition and current issues in aquaculture: the balance in providing safe and nutritious seafood, in an environmentally sustainable manner. Journal of Aquaculture Research and Development 5: 234.
51 Honeyfield, D.C., Hinterkopf, J.P., and Brown, S.B. (2002). Isolation of thiaminase‐positive bacteria from alewife. Transactions of the American Fisheries Society 131: 171–175.
52 Hoopes, L.A. (2017). Elasmobranch mineral and vitamin requirements. In: The Elasmobranch Husbandry Manual II: Recent Advances in the Care of Sharks, Rays and their Relatives (eds. M. Smith, D. Warmolts, D. Thoney, et al.), 135–146. Columbus: Ohio Biological Survey.
53 Horn, M.H. (1989). Biology of marine herbivorous fish. Oceanography and Marine Biology: An Annual Review 27: 167–271.
54 Horn, M.H., Gawlicka, A.K., German, D.P. et al. (2006). Structure and function of the stomachless digestive system in three related species of New World silverside fish (Atherinopsidae) representing herbivory, omnivory, and carnivory. Marine Biology 149: 1237–1245.
55 Hoseinifar, S.H., Zoheiri, F., and Caipang, C.M. (2016). Dietary sodium propionate improved performance, mucosal and humoral immune responses in Caspian white fish (Rutilus frisii kutum) fry. Fish & Shellfish Immunology 55: 523–528.
56 Hua, K. and Bureau, D.P. (2009). A mathematical model to explain variations in estimates of starch digestibility and predict digestible starch content of salmonid fish feeds. Aquaculture 294: 282–287.
57 Hua, K. and Bureau, D. (2010). Quantification of differences in digestibility of phosphorus among cyprinids, cichlids, and salmonids through a mathematical modelling approach. Aquaculture 308: 152–158.
58 Hussey, N.E., Cocks, D.T., Dudley, S.F.J. et al. (2009). The condition conundrum: application of multiple condition indices to the dusky shark Carcharhinus obscurus. Marine Ecology Progress Series 380: 199–212.
59 Janse, M. (2003). Considerations on the diet composition and feeding rate of demersal sharks in 15 European public aquaria. Zoo Biology 22: 203–226.
60 Janse, M., Firchau, B., and Mohan, P.J. (2004). Elasmobranch nutrition, food handling, and feeding techniques. In: The Elasmobranch Husbandry Manual: Captive Care of Sharks, Rays, and their Relatives (eds. M. Smith, D. Warmolts, D. Thoney and R. Hueter), 183–200. Columbus: Ohio Biological Survey.
61 Jaroszewska, M. and Dabrowski, K. (2011). Utilization of yolk: transition from endogenous to exogenous nutrition in fish. In: Larval Fish Nutrition (ed. G.J. Holt), 183–218. Oxford: Wiley.
62 Jobling, M. (2016). Fish nutrition research: past, present and future. Aquaculture International 24: 767–786.
63 Jobling, M. and Wandsvik, A. (1983). An investigation of factors controlling food intake in Arctic charr, Salvelinus alpinus L. Journal of Fish Biology 23: 397–404.
64 Johnsen, P.B. and Adams, M.A. (1986). Chemical feeding stimulants for the herbivorous fish, Tilapia zillii. Comparative Biochemistry and Physiology Part A 83: 109–112.
65 Kaitaranta, J.K. and Ackman, R.G. (1981). Total lipids and lipid classes of fish roe. Comparative Biochemistry and Physiology Part B: Comparative Biochemistry 69: 725–729.
66 Kamerman, T.Y., Davis, L., and Capobianco, J. (2017). Development of a body condition scoring tool for the spotted eagle ray, Aetobatus narinari. In: The Elasmobranch Husbandry Manual II: Recent Advances in the Care of Sharks, Rays and their Relatives (eds. M. Smith, D. Warmolts, D. Thoney, et al.), 147–152. Columbus: Ohio Biological Survey.
67 Kaushik, S., Georga, I., and Koumoundouros, G. (2011). Growth and body composition of zebrafish (Danio rerio) larvae fed a compound feed from first feeding onward: toward implications on nutrient requirements. Zebrafish 8: 87–95.
68 Khosravi, S., Jang, J.‐W., Rahimnejad, S. et al. (2015). Choline essentiality and its requirement in diets for juvenile parrot fish (Oplegnathus fasciatus). Asian‐Australasian Journal of Animal Sciences 28: 647–653.
69 Kiron, V. (2012). Fish immune system and its nutritional modulation for preventative health care. Animal Feed Science and Technology 173: 111–133.
70 Kizer, A. (2005). Percutaneous gastrostomy tube placement in a green moray eel. Exotic DVM 7: 31–35.
71 Knights, B. (1983). Food particle‐size preferences and feeding behaviour in warmwater aquaculture of European eel, Anguilla anguilla (L.). Aquaculture 30: 173–190.
72 Kohler, N.E., Casey, C.G., and Turner, P.A. (1995). Length‐weight relationships for 13 species of sharks from the western North Atlantic. Fishery Bulletin 93: 412–418.
73 Kolkovski, S., Czesny, S., Yackey, C. et al. (2000). The effect of vitamins C and E in (n‐3) highly unsaturated fatty acids‐enriched Artemia nauplii on growth, survival,