Sturgeon caviar and cardiovascular diseases, Caspian Sea wild and farmed beluga, Huso huso caviar and their lipid quality indices

Document Type : Research Paper

Authors

1 Department of Fisheries, Qaemshahr Branch, Islamic Azad University, Qaemshahr, Iran

2 Department of Food Science and Technology, Sari Agricultural Sciences and Natural Resources University, Sari, Iran

Abstract

The objective was to investigate the detailed information about proximate, fatty acid compositions and lipid quality indices in the caviar of wild and farmed beluga, Huso huso from Iran. The fatty acid composition varied with origin of caviars, although did no differ in proximate compositions. The most notable difference (P<0.05) was the higher concentration of linoleic acid (C18:2n-6) in farmed beluga caviar (8.32%) than in wild ones (0.37%). The amounts of docosahexaenoic acid (C22:6n-3) in wild and farmed caviars (23.88% and 23.75% respectively) were not different (P>0.05). There were significantly differences between samples in the amount of eicosapentaenoic (C20:5n-3), arachidonic (C20:4n-6) and docosapentaenoic (C22:5n-3) acids (P<0.05). The total ω-3 in wild and farmed caviars were 38.42% and 30.42% (P>0.05). Total ω-6 was higher in farmed samples (P<0.05). The ratio of ω-3/ω-6 was higher in wild (2.90) than in farmed (1.75) samples (P<0.05). It was also true for, AI content (0.29 and 0.28) and TI (0.18 and 0.21) and also PI content (1.73 and  1.46) respectively, however the differences were not significant (P>0.05). The present study indicated that, fatty acids profile in beluga caviars can be used as an index to determine fish origin and diet. Also farmed beluga caviar has good balanced with lipid quality indices to decrease the potential risk of coronary heart diseases and like wild ones could be considered as a good food sources.

Keywords


Abbas, EM & Hrachya, GH 2015, Fatty acid composition of caviar and liver from cultured great sturgeon, Huso huso. Journal of International Food Research, 22: 1083-1086.
Abedian Kenari, A, Regenstein, JM, Hosseini, SV, Rezaei, M, Tahergorabi, R, Nazari, RM, Mogaddasi, M & Kaboli, SA 2009, Amino acid and fatty acid composition of cultured beluga, Huso huso of different ages. Journal of Aquatic Food Product Technology, 18: 245-265.
Ackman, RG 1967, Characteristics of the fatty acid composition and biochemistry of some fresh-water fish oils and lipids in comparison with marine oils and lipids. Journal of Comparative Biochemistry and Physiology,  22: 907-922.
Ackman, RG 1989, Nutritional composition of fats in seafoods. Journal of Progress in Food & Nutrition Science,  13: 161-289.
Ackman, RG & Eaton, CA 1966, Some commercial Atlantic Herring oils; Fatty acid composition. Journal of the Fisheries Research Board of Canada, 23: 991-1006.
Alasalvar, C, Taylor, KDA, Zubcov, E, Shahidi, F & Alexis, M 2002, Differentiation of cultured and wild sea bass, Dicentrarchus labrax: total lipid content, fatty acid and trace mineral composition. Journal of Food Chemistry, 79: 145-150.
AOAC 2005, Official Methods of Analysis (18th ed), Association of Official Analytical Chemists. Gaithersburg, Maryland 20877-2417, USA.
Arts, MT, Ackman, RG & Holub, BJ 2001, Essential fatty acids in aquatic ecosystems: a crucial link between diet and human health and evolution. Canadian Journal of Fisheries and Aquatic Sciences, 58: 122-137.
Ashton, HJ, Farkvam, DO & March, BE 1993, Fatty acid composition of lipids in the eggs and alevins from wild and cultured Chinook Salmon, Oncorhynchus tshawytscha. Canadian Journal of Fisheries and Aquatic Sciences, 50: 648-655.
Bekhit, AE-DA, Morton, JD, Dawson, CO, Zhao, JH & Lee, HYY 2009, Impact of maturity on the physicochemical and biochemical properties of chinook salmon roe. Journal of Food Chemistry, 117: 318-325.
Bledsoe, GE, Bledsoe, CD & Rasco, B 2003, Caviars and fish roe products. Journal of Critical Reviews in Food Science and Nutrition, 43: 317-356.
Bobe, G, Zimmerman, S, Hammond, EG, Freeman, A, Lindberg, GL & Beitz, DC 2004, Texture of butters made from milks differing in indices of atherogenicity. Journal of Animal Industry Report, 650: 1.
Bowman, W & Rand, M 1980, Drugs used to relieve pain, Textbook of pharmacology, 2nd ed. Oxford: Blackwell.
Breslow, JL 2006, n−3 Fatty acids and cardiovascular disease. The American Journal of Clinical Nutrition, 83:1477S-1482S.
Calder, PC 2006, n−3 Polyunsaturated fatty acids, inflammation, and inflammatory diseases. The American Journal of Clinical Nutrition, 83: 1505S-1519S.
Caprino, F, Moretti, VM, Bellagamba, F, Turchini, GM, Busetto, ML, Giani, I, Paleari, MA & Pazzaglia, M 2008, Fatty acid composition and volatile compounds of caviar from farmed white sturgeon, Acipenser transmontanus. Journal of Analytica Chimica Acta, 617: 139-147.
Chen, IC, Chapman, FA, Wei, Cl, Portier, KM & O'Keefe, SF 1995, Differentiation of cultured and wild sturgeon, Acipenser oxyrinchus desotoi based on fatty acid composition, Journal of Food Science, 60: 631-635.
Connor, WE 1997, The beneficial effects of omega-3 fatty acids: cardiovascular disease and neurodevelopment. Journal of Current Opinion in Lipidology, 8: 1-3.
Czesny, S, Dabrowski, K, Christensen, JE, Van Eenennaam, J & Doroshov, S 2000, Discrimination of wild and domestic origin of sturgeon ova based on lipids and fatty acid analysis. Journal of Aquaculture, 189: 145-153.
DePeters, EJ, Puschner, B, Taylor, SJ & Rodzen, JA 2013, Can fatty acid and mineral compositions of sturgeon eggs distinguish between farm-raised versus wild white, Acipenser transmontanus sturgeon origins in California? Preliminary report. Journal of Forensic Science International, 229: 128-132.
Falahatkar, B & Najafi, M 2019, Modifying the physiological responses to handling stress in beluga sturgeon, Huso huso (L., 1758); Interactive effects of feeding time and dietary fat. Journal of Applied Ichthyology, 35: 307-312.
Farooqui, AA, Rosenberger, TA & Horrocks, LA 1997, Arachidonic acid, neurotrauma, and neurodegenerative diseases, in S Yehuda & DI Mostofsky (eds). Handbook of Essential Fatty Acid Biology: Biochemistry, Physiology, and Behavioral Neurobiology, Humana Press, New York, 277-295.
Fenton, WS, Hibbeln, J & Knable, M 2000, Essential fatty acids, lipid membrane abnormalities, and the diagnosis and treatment of schizophrenia. Journal of Biological Psychiatry, 47: 8-21.
Folch, J, Lees, M & Stanley, GS 1957, A simple method for the isolation and purification of total lipides from animal tissues. Journal of biological chemistry, 226: 497-509.
Fowler, KP, Karahadian, C, Greenberg, NJ & Harrell, RM 1994, Composition and quality of aquacultured hybrid Striped Bass fillets as affected by dietary fatty acids. Journal of Food Science, 59: 70-75.
Gallagher, ML, Paramore, L, Alves, D & Rulifson, RA 1998, Comparison of phospholipid and fatty acid composition of wild and cultured striped bass eggs. Journal of Fish Biology, 52: 1218-1228.
Gessner, J, Wirth, M, Kirschbaum, F, Krüger, A & Patriche, N 2002, Caviar composition in wild and cultured sturgeons – impact of food sources on fatty acid composition and contaminant load. Journal of Applied Ichthyology, 18: 665-672.
Gessner, J, Würtz, S, Kirschbaum, F & Wirth, M 2008, Biochemical composition of caviar as a tool to discriminate between aquaculture and wild origin. Journal of Applied Ichthyology, 24: 52-56.
Gibson, RA 1983, Australian fish—An excellent source of both arachidonic acid and ω-3 polyunsaturated fatty acids. Journal of Lipids, 18: 743-752.
Gong, Y, Huang, Y, Gao, L, Lu, J, Hu, Y, Xia, L & Huang, H 2013, Nutritional composition of caviar from three commercially farmed sturgeon species in China. Journal of Food and Nutriton Research, 1: 108-112.
Hedayatifard, M & Hassani Moghadam, E 2016, Effect of cold-smoking on the production of polycyclic aromatic hydrocarbons (PAHs), qualityIndexes, microbal community and omega-3 fatty acid profile of common carp, Cyprinus carpio. Journal of Fisheries Science and Technology, 5: 73-93.
Hedayatifard, M & Moeeni, S 2004, Quantitative and qualitative identification of the fatty acids in Persian sturgeon tissue, Acipenser persicus and effect of long term freezing on them. Journal of Agricultural Science (University of Tabriz), 14: 123–132.
Huynh, MD & Kitts, DD 2009, Evaluating nutritional quality of pacific fish species from fatty acid signatures. Journal of Food Chemistry, 114: 912-918.
Jeong, BY, Ohshima, T, Koizumi, C & Kanou, Y 1990, Lipid deterioration and its inhibition of Japanese Oyster, Crassostrea gigas during frozen storage. Journal of Nippon Suisan Gakkaishi, 56: 2083-2091.
Jorjani, S, Khanipour, AA & Ghelichi, A 2016, Chemical composition and fatty acid profile of common kilka, Clupeonella cultriventris caspia. Caspian Journal of Environmental Sciences, 12: 119-128.
Kalogeropoulos, N, Andrikopoulos, NK & Hassapidou, M 2004, Dietary evaluation of Mediterranean fish and molluscs pan-fried in virgin olive oil. Journal of the Science of Food and Agriculture, 84: 1750-1758.
Kaya, Y, Erdem, ME & Turan, H 2014, Monthly differentiation in meat yield, chemical and amino acid composition of wild and cultured brown trout, Salmo trutta forma fario (L., 1758). Turkish Journal of Fisheries and Aquatic Sciences, 14: 479-486.
Larsen, R, Eilertsen, K-E & Elvevoll, EO 2011, Health benefits of marine foods and ingredients. Journal of Biotechnology Advances, 29: 508-518.
Li, W, wei, QW & Shen, L 2014, Biochemical comparison between eggs from female Chinese sturgeon, Acipenser sinensis (Gray, 1835) reconditioned in freshwater and eggs from wild females: evaluation of female reconditioning as a conservation culture technique. Journal of Applied Ichthyology, 30: 1237-1242.
Marques, A, Teixeira, B, Barrento, S, Anacleto, P, Carvalho, ML & Nunes, ML 2010, Chemical composition of Atlantic spider crab Maja brachydactyla: Human health implications. Journal of Food Composition and Analysis, 23: 230-237.
Mol, S & Turan, S 2008, Comparison of proximate, fatty acid and amino acid compositions of various types of fish roes. International Journal of Food Properties, 11: 669-677.
Nazemroaya, S, Sahari, MA & Rezaei, M 2009, Effect of frozen storage on fatty acid composition and changes in lipid content of Scomberomorus commersoni and Carcharhinus dussumieri. Journal of Applied Ichthyology, 25: 91-95.
Nurhan, U 2007, Change in proximate, amino acid and fatty acid contents in muscle tissue of rainbow trout, Oncorhynchus mykiss after cooking. International Journal of Food Science & Technology, 42: 1087-1093.
Ovissipour, M & Rasco, B 2011, Fatty acid and amino acid profiles of domestic and wild beluga, Huso huso roe and impact on fertilization ratio. Journal of Aquaculture Research and Development, 2: 10.4172.
Özogul, Y, Özogul, F & Alagoz, S 2007, Fatty acid profiles and fat contents of commercially important seawater and freshwater fish species of Turkey: A comparative study. Journal of Food Chemistry, 103: 217-223.
Pajand, ZO, Soltani, M, Bahmani, M & Kamali, A 2017, The role of polychaete Nereis diversicolor in bioremediation of wastewater and its growth performance and fatty acid composition in an integrated culture system with Huso huso (Linnaeus, 1758). Journal of Aquaculture Research, 48: 5271-5279.
Park, KS, Kang, KH, Bae, EY, Baek, KA, Shin, MH, Kim, DU, Kang, HK, Kim, KJ, Choi, YJ & Im, JS 2015, General and biochemical composition of caviar from Sturgeon, Acipenser ruthenus farmed in Korea. Journal of International Food Research, 22: 777-781.
Potter, NN & Hotchkiss, JH 1995, Food sciences. 5th edition edn, Food Science Text Series, Springer US, New York, USA.
Rehbein, H 1985, Caviare: proximate composition, amino acid content and identification of fish species. Journal of Zeitschrift für Lebensmittel-Untersuchung und Forschung, 180: 457-462.
Rueda, FM, López, JA, Martínez, FJ, Zamora, S, Divanach, P & Kentouri, M 1997, Fatty acids in muscle of wild and farmed red porgy, Pagrus pagrus. Journal of Aquaculture Nutrition, 3: 161-165.
Saffar Shargh, A, Zakipour Rahimabadi, E, Alizadeh, E & Gheybi, F 2017, Amino acid and fatty acid profiles of materials recovered from Prussian carp, Carassius gibelio (Bloch, 1782), using acidic and basic solubilization/precipitation technique, Caspian Journal of Environmental Sciences, 15: 285-294.
Saliu, F, Leoni, B & Della Pergola, R 2017, Lipid classes and fatty acids composition of the roe of wild Silurus glanis from subalpine freshwater. Journal of Food Chemistry, 232: 163-168.
Sathivel, S, Prinyawiwatkul, W, Grimm, CC, King, JM & Lloyd, S 2002, FA composition of crude oil recovered from catfish viscera. Journal of the American Oil Chemists' Society, 79: 989-992.
Şengör, GF, Özden, Ö, Erkan, N, Tüter, M & Aksoy, HA 2003, Fatty acid compositions of flathead grey mullet, Mugil cephalus (L., 1758) fillet, raw and beeswaxed caviar oils. Turkish Journal of Fisheries and Aquatic Sciences, 3: 93-96.
Silversand, C, Norberg, B & Haux, C 1996, Fatty-acid composition of ovulated eggs from wild and cultured turbot, Scophthalmus maximus in relation to yolk and oil globule lipids. Journal of Marine Biology, 125: 269-278.
Steffens, W 1997, Effects of variation in essential fatty acids in fish feeds on nutritive value of freshwater fish for humans. Journal of Aquaculture, 151: 97-119.
Sternin, V & Doré, I 1993, Caviar - the resource book, Cultura (Cultura Enterprises), Moscow.
Taheri, S, Motallebi, A, Fazlara, A, Aghababyan, A & Aftabsavar, Y 2012, Changes of fatty acid profiles in fillets of Cobia, Rachycentron canadum during frozen storage. Iranian Journal of Fisheries Sciences, 11: 204-213.
Tamaru, CS, Ako, H & Lee, C-S 1992, Fatty acid and amino acid profiles of spawned eggs of striped mullet, Mugil cephalus (L., 1758). Journal of Aquaculture, 105: 83-94.
Trubo, R & Carroll, M 1997, Cholesterol cures. Rodale Press, Pensylvania, USA.
Turan, H, Sönmez, G & Kaya, Y 2007, Fatty acid profile and proximate composition of the thornback ray, Raja clavata (L., 1758) from the Sinop coast in the Black Sea. Journal of Fisheries Sciences, 1: 97-103.
Ulbricht, TLV & Southgate, DAT 1991, Coronary heart disease: seven dietary factors. Journal of The Lancet, 338: 985-992.
Vaccaro, AM, Buffa, G, Messina, CM, Santulli, A & Mazzola, A 2005, Fatty acid composition of a cultured sturgeon hybrid,  Acipenser naccarii × A. baerii. Journal of Food Chemistry. 93: 627-631.
Valfré, F, Caprino, F & Turchini, G 2003, The health benefit of seafood. Journal of Veterinary research communications, 27: 507-512.
Ward, OP & Singh, A 2005, Omega-3/6 fatty acids: Alternative sources of production. Journal of Process Biochemistry, 40: 3627-3652.
Wirth, M, Kirschbaum, F, Gessner, J, Krüger, A, Patriche, N & Billard, R 2000, Chemical and biochemical composition of caviar from different sturgeon species and origins. Journal of Food / Nahrung, 44: 233-237.
Wirth, M, Kirschbaum, F, Gessner, J, Williot, P, Patriche, N & Billard, R 2002, Fatty acid composition in sturgeon caviar from different species: Comparing wild and farmed origins. Journal of International Review of Hydrobiology, 87: 629-636.
Zakipour Rahimabadi, E, Faralizadeh, S & Khanipour, AA 2017, Fatty acid composition of fresh and smoked Black and Caspian Sea sprat, Clupeonella cultriventris (Nordmann, 1840) treated with different salt composition. Caspian Journal of Environmental Sciences, 14: 117-124.