[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.4217/OPR.2014.36.2.199

Selection of Copepods as Live Food for Marine Fish Larvae Based on Their Size, Fecundity, and Nutritional Value

Yang, Sung Jin (Department of Marine Bio-materials and Aquaculture, College of Fisheries Sciences Pukyong National University)
Hur, Sung Bum (Department of Marine Bio-materials and Aquaculture, College of Fisheries Sciences Pukyong National University)

Publication Information

Ocean and Polar Research / v.36, no.2, 2014 , pp. 199-208 More about this Journal

Abstract

Copepods are a major food source for marine fish larvae in nature. Many studies on copepods culture have been conducted to develop a new live food for the seedling production of marine fish larvae. But fish farmers still depend on rotifer and Artemia nauplii. This study was carried out to find suitable copepods as live food for the larvae in hatchery. Eight species of copepods (1 calanoid, 2 cyclpoid, 5 harpacticoid) that were fed Isochrysis galbana were examined in terms of the size of nauplii, fecundity, amino acids, and fatty acids contents. These species were divided into small (nauplii length 46-86 ${\mu}m$ ) and large (nauplii length 120-188 ${\mu}m$ ) size group. Nitokra spinipes in the small group and Tigriopus japonicus in the large group showed the highest fecundity with 151.1 and 139.6 nauplii production per gravid female, respectively. With regard to nutrients, essential amino acids were the highest with 21.2% in cyclopoid Paracyclopina nana in the small group and n-3 HUFA were the highest in calanoid Pseudodiaptomus inopinus (8.5 ${\mu}g/mg$ ) in the large group and P. nana (8.8 ${\mu}g/mg$ ). In terms of the size, fecundity, and nutritional value of copepods examined in this study, N. spinipes and P. nana seem to be suitable copepod species to develop as a new live food for small mouth fish larvae.

Keywords

copepods; fecundity; live food; nauplii size; nutrient;

Citations & Related Records

Times Cited By KSCI : 4 (Citation Analysis)

Reference
Cited By KSCI

1	McEvoy LA, Naess T, Bell JG, Lie O (1998) Lipid and fatty acid composition of normal and malpigmented Atlantic hailbut (Hippoglossus hippoglossus) fed enriched Artemia: a comparison with fry fed wild copepods. Aquaculture 163:237-250 DOI
2	Lipman EE (2001) Production of the copepod Apocyclops panamensis under hatchery conditions. MSc. Thesis, Auburn University, 68 p
3	McEvoy LA, Navarro JC, Hontoria F, Amat F, Sargent JR (1996) Two novel Artemia enrichment diets containing polar lipid. Aquaculture 144:339-352 DOI ScienceOn
4	Morrison WR, Smith LM (1964) Preparation of fatty acid methyl esters and dimethylacetals from lipids with boron fluoride-methanol. J Lipid Res 5:600-608
5	Nanton DA, Castell JD (1998) The effect of dietary fatty acids on the fatty acid composition of the harpacticoid copepod, Tisbe sp., for use as a live food for marine fish larvae. Aquaculture 163:251-261 DOI
6	Naess T, Germian-Henry M, Naas KE (1995) First feeding of Atlantic halibut (Hippoglossus hippoglossus) using different combinations of Artemia and wild plankton. Aquaculture 130:235-250 DOI
7	Olivotto I, Capriotti F, Buttino I, Avella AM, Vitiello V, Maradonna F, Carnevali O (2008) The use of harpacticoid copepods as live prey for Amphiprion clarkii larviculture: Effects on larval survival and growth. Aquaculture 274: 347-352 DOI
8	Park HG (1997) Mass production of resting eggs of Korean rotifer, Brachionus plicatilis. Ph.D. Thesis, Pukyong National University, 115 p
9	Phelps RP, Sumiarsa GS, Lipman EE, Ian HP, Moss KK, Davis AD (2005) Intensive and extensive production techniques to provide copepod nauplii for feeding larval red snapper Lutjanus campechanus. In: Lee CS, O'bryen PJ, Marcus NH (eds) Copepods in aquaculture. Blackwell, Oxford, pp 151-168
10	Duncan DB (1995) Multiple-range and multiple F tests. Biometrics 11:1-42
11	Cutts CJ (2002) Culture of harpacticoid copepods: Potential as live feed for rearing marine fish. Adv Mar Biol 44:295-316
12	Drillet G, Joergensen NOG, Sorensen TF, Ramloev H, Hansen BW (2006) Biochemical and technical observations supporting the use of copepods as live feed organisms in marine larviculture. Aquac Res 37:756-772 DOI
13	Doi M, Ohno A, Taki Y, Singhagraiwan T, Kohno H (1997) Nauplii of the calanoid copepod, Arcartia sinjiensis as an initial food organism for larval red snapper Lutjanus argentimaculatus. Suisan Zoshoku 45:31-40
14	Evjemo JO, Reitan KI, Olsen Y (2003) Copepods as live food organisms in the larval rearing of hailbut larvae (Hippoglossus hippoglossus L.) with special emphasis on the nutritional value. Aquaculture 227:191-210 DOI ScienceOn
15	Fleeger JW (2005) The potential to mass-culture harpacticoid copepods for use as food for larval fish. In: Lee CS, O'Bryen PJ, Marcus NH (eds) Copepods in aquaculture. Blackwell, Iowa, pp 11-24
16	Fraser AJ, Sargent JR, Gamble JC (1989) Lipid class and fatty acid composition of Calanus finmarchicus (Gunnerus), Pseudocalanus sp. and Temora longicornis Muller from a nutrient-enriched seawater enclosure. J Exp Mar Biol Ecolol 130:81-92 DOI
17	Aragao C, Conceicao LEC, Fyhn HJ, Dinis MT (2004) Estimated amino acid requirements during early ontogeny in fish with different life styles: Gilthead seabream (Sparus aurata) and Senegalese sole (Solea senegalensis). Aquaculture 242:589-605 DOI
18	Guillard RL, Ryther JH (1962) Studies of marine planktonic diatoms. I. Cyclotella nana Hustedt and Detonula confervacea (Cleve). Can J Microbiol 8:229-239 DOI ScienceOn
19	Holt GJ (2003) Research on culturing the early life stages of marine ornamental species. In: Cato JC, Brown CL (eds) Marine ornamental species-Collection, culture and conservation. Iowa State Press, Iowa, pp 251-254
20	Lee KW (2004) Mass culture and food value of the cyclopoid copepod Paracyclopina nana Smirnov. Ph.D. Thesis, Kangnung National University, 125 p
21	Berg L (1997) Commercial feasibility of semi-intensive larviculture of atlantic halibut (Hippoglossus hippoglossus L.). Aquaculture 155:333-340 DOI
22	Budge SM (1999) Fatty acid biomarkers in a cold water marine environment. Ph.D. Dissertation, Memorial University of Newfoundland, 197 p
23	Cabrera T, Hur SB (2005) Effect of nutritional requirements and feeding regimes at first feeding on the survival of the larval olive flounder Paralichthys olivaceus. J Fish Sci Technol 8(4):228-234
24	Castell JD, Bell JG, Tocher DR, Sargent JR (1994) Effects of purified diets containing different combinations of arachidonic and docosahexaenoic acid on survival, growth and fatty acid composition of juvenile turbot (Scophthalmus maximus). Aquaculture 128:315-333 DOI
25	Yang SJ, Hur SB (2012) Selection of Isochrysis and Pavlova species for mass culture in high temperature season. Korean J Fish Aquat Sci 45(4):343-350 과학기술학회마을 DOI ScienceOn
26	Toledo JD, Golez MS, Doi M, Ohno A (1999) Use of copepod nauplii during early feeding stage of grouper epinephalus coioides. Fish Sci 65:390-397 DOI
27	Watanabe T (1982) Lipid nutriton in fish. Comp Biochem Physiol 73:3-15
28	Wright PA, Fyhn HJ (2001) Ontogeny of nitrogen metabolism and excretion. In: Wright PA, Anderson PM (eds) Nitrogen excretion. Academic Press, London, pp 149-200
29	Yoo JH, Hur SB (2002) Evaluation of ciliate Euplotes sp. as a live food for marine fish larvae. Korean J Fish Aquat Sci 35(5):542-544 과학기술학회마을 DOI ScienceOn
30	Yun JY, Hur SB (2011) Influence of temperature and salinity on the growth and size of the rotifer Brachionus plicatilis and B. rotundiformis. Korean J Fish Aquat Sci 44(6): 658-664 과학기술학회마을 DOI ScienceOn
31	Rhodes A (2003) Methods for high density batch culture of Nitokra lacustris, a marine harpacticoid copepod. In: Browman H, Berit Skiftesvik A (eds) 26th Annual Larval Fish Conference. IMR, Bergen, pp 449-465
32	Ronnestad I, Thorsen A, Finn RN (1999) Fish larval nutrition: a review of recent advances in the roles of amino acids. Aquaculture 177:201-1216 DOI ScienceOn
33	Pinto CSC, Souza-Santos LP, Santos PTP (2001) Development and population dynamics of Tisbe biminiensis (Copepoda: Harpacticoida) reared on different diets. Aquaculture 198:253-267 DOI ScienceOn
34	Rainuzzo JR, Reitan KI, Jorgensen L (1992) Comparative study on the fatty acid and lipid composition of four marine fish larvae. Comp Biochem Physiol 103:21-26
35	Rajkumar W, Kumaraguru KP (2006) Suitability of the copepod, Acartia clausi as a live feed for seabass larvae (Lates calcarifer Bloch): compared to traditional livefood organisms with emphasis on the nutritional value. Aquaculture 261:649-658 DOI ScienceOn
36	Sargent JR, Henderson RJ (1986) Lipids. In: Corner EDS, O'Hara SCM (eds) The biological chemistry of marine copepods. Oxford University Press, New York, pp 59-108
37	Sargent JR, McEvoy LA, Bell JG (1997) Requirements, presentation and sources of polyunsaturated fatty acids in marine fish larval feeds. Aquaculture 155:117-127 DOI
38	Schipp GP, Bosmans JMP, Marshall AJ (1999) A method for hatchery culture of tropical calanoid copepoda, Acartia spp. Aquaculture 174:81-88 DOI ScienceOn
39	Stottrup JG (2003) Production and nutritional value of copepods. In: Stottrup JG, McEvoy LA (eds) Live feeds in marine aquaculture. Blackwell, Oxford, pp 145-205
40	Stottrup JG, McEvoy LA (2003) Live feeds in marine Aquaculture. Aqua Res 35:213-214
41	Lee KW, Park HG, Lee SM, Kang HK (2006) Effects of diets on the growth of the brachkish water cyclopoid Paracyclopina nana Smirnov. Aquaculture 256:346-353 DOI
42	Sargent JR, McEvoy LA, Estevez A, Bell JG, Bell MV, Henderson RJ, Tocher DR (1999) Lipid nutrition of marine fish during early development: current status and future directions. Aquaculture 179:217-229 DOI ScienceOn