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Change of Hematological Characteristic and Heavy Metal Concentration on Rockfish (Sebastes schlegeli) Rearing in the Copper Alloy Mesh  

Yang, Sung-Jin (Aquaculture Management Division, Aquaculture Research Institute, NFRDI)
Jun, Je-Cheon (Aquaculture Management Division, Aquaculture Research Institute, NFRDI)
Park, Jung-Jun (Aquaculture Management Division, Aquaculture Research Institute, NFRDI)
Myeong, Jeong-In (Aquaculture Management Division, Aquaculture Research Institute, NFRDI)
Shin, Yun-Kyung (Aquaculture Management Division, Aquaculture Research Institute, NFRDI)
Publication Information
Korean Journal of Ichthyology / v.26, no.3, 2014 , pp. 159-170 More about this Journal
Abstract
The effect of substances discharged from copper alloy mesh on the survival rate, growth, and health status of Sebastes schlegeli was investigated. Survival rate of experimental group was 10% higher than control group. There was no significant difference in weight gain and SGR between control group and experiment group (P<0.05). Glucose concentration was lower in the experimental group than that in the control group. GOT and GPT contents did not show significant difference during experiment except for the early three months of experiment (P<0.05). Ammonia concentration had not significantly changed in the experimental group, but it had increased until four months of experiment and then decreased afterwards in the control group. TCHO had decreased in the experiment group compared with that of control group. Copper and zinc contents had increased as compared with those in the initial stage of experiment with no significant difference between experiment group and control group (P<0.05). Histological analysis for the liver revealed that liver tissues were not particularly different from those in control group. There were no significant differences in survival rate, growth, and hematological characteristic between control group and experiment group (P<0.05). Though copper and zinc were accumulated as compared with those during the initial stage of experiment, the levels were lower than permissible levels for copper and zinc. As a result, copper alloy mesh would not adversely affect on the survival rate, growth, and health status of fishes.
Keywords
Copper alloy mesh; growth; health status; hematological characteristic; Sebastes schlegeli; survival rate;
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1 Friberg, L. and J. Vostal. 1972. Mercury in the environment. In: Friberg, L. and J. Vostal (eds.), An epidemiological and toxicological appraisal. CRS Press, Cleveland, pp. 29-90.
2 Furness, R.W. and P.S. Rainbow. 1990. Heavy metals in the marine environment. CRC press, Florida.
3 Gamperl, A.K., M.M. Vigayan and R.G. Boutilier. 1994. Experimental control of stress hormone levels in fishes: techniques and applications. Rev. Fish Biol. Fish., 4: 215-255.   DOI
4 Handy, R.D., D.W. Sims, A. Giles, H.A. Cambell and M.M. Musonda. 1999. Metabolic trade-off between locomotion and detoxification for maintence of blood chemistry and growth parameters by rainbow trout (Oncorhynchus mykiss) during chronic dietary exposure to copper. Aquat. Toxicol., 47: 23-41.   DOI
5 Hawbaker, J.A., V.C. Speer, V.W. Hays and D.V. Catron. 1961. Effect of copper sulfate and other chemotherapeutics in growing swine rations. J. A. Sci., 20: 163-167.
6 Hodson, P.V., M. McWhirter, K. Ralph, B. Gray, D. Thivierge, J.H. Carey, G. Van-Der-Kraak, D.M. Whittle and M.C. Levesque. 1992. Effects of bleached kraft mill effluent on fish in the St. Maurice River, Quebec. Environ. Toxcicol. Chem., 11: 1635-1651.   DOI
7 Hogstrand, C. and C.M. Wood. 1996. The physiology and toxicology of zinc in fish. In: Taylor, E.W. (ed.), Toxicology of Aquatic Pollution: Physiological, Cellular and Molecular Approaches. Cambridge University Press, Cambridge, pp. 61-84.
8 Huguenin, J.E. and F.J. Ansuini. 1975. The advantages and limitations of using copper materials in marine aquaculture. Proceedings of the OCEAN 75 Conference, Marine Technology Society, San Diego, CA, USA, pp. 444-453. I
9 to, Y. and T. Murata. 1990. Changes in glucose, protein contents and enzyme activities of serum in carp administered orally with PCB. Bull. Jap. Soc. Sci. Fish., 46: 465-468.
10 James, R., K. Sampath and P. Selvamani. 2000. Effect of ion-exchanging agent zeolite on removal of copper in water and improvement of growth in Oreochromis mossambicus (Peters). Asian Fish. Sci., 13: 317-325.
11 Roesijadi, G., W.E. Robinson. 1994. Metal regulation in aquatic animals: mechanisms of uptake, accumulation and release. In: Malins, D.C. and G.K. Ostrander (eds.), Aquatic toxicology. Boca Raton: Lewis Publishers, pp. 387-420.
12 Shaw, B.J., G. Al-Bairuty and R.D. Handy. 2012. Effects of waterborne copper nanoparticles and copper sulphate on rainbow trout, (Oncorhynchus mykiss): Physiology and accumulation. Aquat. Toxicol., 116-117: 90-101.   DOI
13 Shich, M.S. 1978. Changes of blood enzymes in brook trout induced by infection with Aeromonas salmonicida. J. Fish Biol., 11: 13-18.
14 SINTEF report. 2005. Application of brass net cages in Norwegian aquaculture-environmental analysis, Project number 840145.
15 Smith, A.C. and F. Ramos. 1980. Automated chemical analysis in fish health assessment. J. Fish Biol., 17: 445-450.   DOI
16 Solberg, C.B., L. Sæthre and K. Julshamn. 2002. The effect of copper-treated net pens on farmed salmon (Salmo salar) and other marine organisms and sediments. Mar. Pollut. Bull., 45: 126-132.   DOI
17 Sorensen, E.M. 1991. Metal Poisoning in Fish. CRC Press, Inc., Boca Raton. pp. 374.
18 Spear, P.A. 1981. Zinc in the Aquatic Environment: Chemistry, Distribution, and Toxicology. National Research Council of Canada, NRCC Associate Committee on Scientific Criteria for Environmental Quality, Environmental Secretariat, Ottawa.
19 Takeda, Y., A. Ichihara, H. Tanioka and H. Inoue. 1964. The Biochemistry of animal cells: I. The effect of corticosteroids on leakage of enzymes from dispersed rat liver cells. J. Biol. Chem., 239: 3590-3596.
20 Thomas, P. and L. Robertson. 1991. Plasma cortisol and glucose stress responses of red drum (Sciaenops ocellatus) to handling and shallow water stressors and anesthesia with MS-222, quinaldine sulfate and metomidate. Aquaculture, 96: 69-86.   DOI   ScienceOn
21 Torres, P., L. Tort and R. Flos. 1987. Acute toxicity of copper to Mediterranean dogfish. Comp. Biochem. Physiol., 86: 169-171.   DOI
22 James, R., K. Sampath, S. Jothilakshmi, I. Vasudhevan and R. Thangarathinam. 2008. Effects of copper toxicity on growth, reproduction and metal accumulation in chosen ornamental fishes. Ecohydrol. Hydrobiol., 8: 89-97.   DOI
23 Jos, Á., S. Pichardo, A.I. Prieto, G. Repetto, C.M. Vázquez, I. Moreno and A.M. Camean. 2005. Toxic cyanobacterial cells containing microcystins induce oxidative stress in exposed tilapia fish (Oreochromis sp.) under laboratory conditions. Aquat. Toxicol., 72: 261-271.   DOI
24 Kirk, R.S. and J.W. Lewis. 1993. An evaluation of pollutant induced changes in the gills of rainbow trout using scanning electron microscopy. Environ. Technol., 14: 577-585.   DOI
25 Kirchgessner, M. and F.J. Schwarz. 1986. Mineral content (major and trace element) of carp (Cyprinus carpio L.) fed with different protein and energy supplies. Aquaculture, 54: 3-9.   DOI
26 Kraemer, L.D., P.G. Campbell and L. Hare. 2005. Dynamics of Cd, Cu and Zn accumulation in organs and sub-cellular fractions in field transplanted juvenile yellow perch (Perca flavescens). Environ. Pollut., 138: 324-337.   DOI
27 Langlois, B.E., G.L Cromwell and V.W. Hays. 1978. Influence of type of antibiotic and length of antibiotic feeding period on performance and persistence of antibiotic resistant enteric bacteria in growing-finishing swine. J. Ani. Sci., 46: 1383-1396.
28 Lewis, A.G. and A. Metaxas. 1991. Concentrations of total dissolved copper in and near a copper-treated salmon net pen. Aquaculture, 99: 269-276.   DOI
29 Lorentzen, M., A. Maage and K. Julshamn. 1998. Supplementing copper to a fish meal based diet fed to Atlantic salmon parr affects liver copper and selenium concentrations. Aquaculture Nutrition, 4: 67-77.   DOI   ScienceOn
30 MAFF. 1995. Monitoring and Surveillance of Non-radioactive Contaminants in the Aquatic Environment and Activities Regulating the Disposal of Wastes at Sea, Directorate of Fisheries Research, Lowestoft, Aquatic Environment Monitoring Report No.44.
31 Van Raaij, M.T.M., G.E.E.J.M. Van den Thillart, G.J. Vianen, D.S.S. Pit, P.H.M. Balm and A.B. Steffens. 1996. Substrate mobilization and hormonal changes in rainbow trout (Oncorhynchus mykiss L.) and common carp (Cyprinus carpio L.) during deep hypoxia and subsequent recovery. J. Comp. Physiol., 166: 443-452.   DOI
32 Tsukrov, I., A. Drach, J. DeCew, M.R. Swift and B. Celikkol. 2011. Characterization of geometry and normal drag coefficients of copper nets. Ocean Engineering, 38: 1979-1988.   DOI
33 Turkmen, M., A. Türkmen and Y. Tepe. 2008. Metal contaminations in five fish species from Black, Marmara, Aegean and Mediterranean Seas. Turkey, J. Chilean Chem. Soc., 53: 1435-1439.
34 Vallee, B.L. and K.H. Falchuk. 1993. The biochemical basis of zinc physiology. Physiological Reviews, 73: 79-118.
35 Watanabe, T., V. Kiron and S. Satoh. 1997. Trace minerals in fish nutrition. Aquaculture, 151: 185-207.   DOI   ScienceOn
36 Ytreberg, E., J. Karlsson and B. Eklund. 2010. Comparison of toxicity and release rates of Cu and Zn from antifouling paints leached in natural and artificial brackish seawater. Sci. Total Environ., 408: 2459-2466.   DOI
37 Buckley, J.T., M. Roch, J.A. McCarter, C.A. Rendell and A.T. Matheson. 1982. Chronic exposure of coho salmon to sublethal concentrations of copper, and on copper tolerance. Comp. Biochem. Physiol. C., 72: 15-19.   DOI   ScienceOn
38 Andres, S., F. Ribeyre, J.N. Tourencq and A. Boudou. 2000. Interspecific comparison of cadmium and zinc contamination in the organs of four fish species along a polymetallic pollution gradient (Lot River, France). Sci. Tot. Environ., 248: 11-25.   DOI
39 Arellano, J.M., V. Storch and C. Sarasquete. 1999. Histological changes and copper accumulation in liver and gills of the Senegal sole, Solea senegalensis. Ecotoxicol. Environ. Saf., 44: 62-72.   DOI   ScienceOn
40 Bradley, R.W. and J.B. Sprague. 1985. The influence of pH, water hardness, and alkalinity on the acute lethality of zine to rainbow trout (Salmo gairdneri). Can. J. Fish. Aquat. Sci., 42: 731-736.   DOI
41 Bury, N.R., P.A. Walker and C.N. Glover. 2002. Nutritive metal uptake in teleost fish (Review). J. Exp. Biol., 206: 11-23.
42 Canli, M. and G. Atli. 2003. The relationships between heavy metal (Cd, Cr, Cu, Fe, Pb, Zn) levels and the size of six Mediterranean fish species. Environ. Pollut., 121: 129-136.   DOI   ScienceOn
43 Collvin, L. 1985. The effect of copper on growth, food consumption and food conversion of perch Perca fluviatilis L. offered maximal food rations. Aquat. Toxicol., 6: 105-113.   DOI   ScienceOn
44 Chapman, G.A. 1999. An acute TRV for Rainbow trout and Bull trout. Report prepared for the Montana Natural Resources Damage Program, Helena, MT, USA.
45 Cinier, C.C., M. Petit-Ramel, R. Faure, D. Garin and Y. Bouvet. 1999. Kinetics of cadmium accumulation and elimination in carp Cyprinus carpio tissues. Comp. Biochem. Physiol., 122: 345-352.
46 Collvin, L. 1984. Uptake of copper in gills and liver of perch, Perca fluviatilis. Ecol. Bull. (Stockholm), 36: 57-61.
47 Cotou, E., M. Henry, C. Zeri, G. Rigos, A. Torreblanca and V.A. Catsiki. 2012. Short-term exposure of the European sea bass Dicentrarchus labrax to copper-based antifouling treated nets: Copper bioavailability and biomarkers responses. Chemosphere, 89: 1091-1097.   DOI
48 Cousins, R.J. 1985. Absorption, transport, and hepatic metabolism of copper and zinc: special reference to metallothionein and ceruloplasmin. Physiol. Rew., 65: 238-309.
49 Dean, R.J., T.M. Shimmield and K.D. Black. 2007. Copper, zinc and cadmium in marine cage fish farm sediments: An extensive survey. Environ. Pollut., 145: 84-95.   DOI
50 Drummond, R.A., W.A. Spoor and G.F. Olson. 1973. Some shortterm indicators of sublethal effects of copper on brook trout, Salvelinus fontinalis. J. Fish Res. Board Can., 30: 698-701.   DOI
51 Efird, K.D. and D.B. Anderson. 1975. Sea Water Corrosion of 90-10 and 70-30 Cu-Ni: 14 Year Exposures. Materials Performance, 14: 37-40.
52 FAO/WHO. 2010. Joint FAO/WHO Expert Committee on Food Additives, Summary report of the seventy-third meeting of JECFA in the WHO Technical Report Series, Geneva, Switzerland, 12-13.
53 Filho, W. 1996. Fish antioxidant defenses. A comparative approach. Braz. J. Med. Bio. Res., 29: 1735-1742.
54 Oliva, M., M.C. Garrido, D. Sales Márquez and M.L. Gonzalez de Canales. 2009. Sublethal and lethal toxicity in juvenile Senegal sole (Solea senegalensis) exposed to copper: A preliminary toxicity range-finding test. Exp. Toxicol. Pathol., 61: 113-121.   DOI
55 McCarter, J.A. and M. Roch. 1984. Chronic exposure of coho salmon to sub-lethal concentrations of copper. III. Kinetics of metabolism of metallothionein. Comp. Biochem. Physiol., 77: 83-87.
56 Miles, R.D., S.F. O'eefe and P.R. Henry. 1988. The effect of dietary supplementation with copper sulfate or tribasic copper chloride on broiler performance, relative copper bioavaulability, and dietary prooxidant activity. Poultry Science, 77: 416-425.
57 O'ell, B.L. 1976. Biochemistry of copper. Symposium on trace elements. The Medical clinics of North America, 60: 697-703.
58 Olsson, P.E. 1996. Metallothioneins in fish: induction and use in environmental monitoring. In: Taylor, E.W. (ed.), Toxicology of Aquatic Pollution. Cambridge University Press, Cambridge, UK, pp. 187-204.
59 Ortiz, J.B., M.L. González de Canales and C. Sarasquete. 1999. Quantification and histopathological alterations produced by sublethal concentrations of copper in fundulus heteroclitus. Ciencias Marinas, 25: 119-143.
60 Paul, J.D. and I.M. Davies. 1986. Effects of copper- and tin-based anti-fouling compounds on the growth of scallops (Pecten maximus) and oysters (Crassostrea gigas). Aquaculture, 54: 191-203.   DOI
61 Peterson, L.K., J.M.D. Auria, B.A. McKeown, K. Moore and M. Shum. 1991. Copper levels in the muscle and liver tissues of farmed Chinook salmon, Oncorhynchus tshawytscha. Aquaculture, 9: 105-115.
62 Powell, C. and H. Stillman. 2009. Corrosion Behavior of Copper Alloys used in Marine Aquaculture. International Copper Association (ICA), http://www.copper.org/applications/cuni/pdf/marine_aquaculture.pdf(Retrieved October 15. 2010).
63 Rau, M.A., J. Whitaker, J.H. Freedman and R.T.D. Giulio. 2004. Differential susceptibility of fish and rat liver cells to oxidative stress and cytotoxicity upon exposure to prooxidants. Comp. Biochem. Physiol., 137: 335-342.