Determination of enrofloxacin residue in the muscle and liver of cultured rainbow trout in Chaharmahal-va-Bakhtiary province by ELISA
Subject Areas :
Food Science and Technology
فیروز Fadaeifard
1
1 - Assistant Professor of Aquatic animal Health and disease Departement, Faculty of Veterinary Medicine, Shahrekord Branch, Islamic Azad University, Shahrkord, Iran.
Received: 2012-05-23
Accepted : 2012-11-18
Published : 2012-05-21
Keywords:
Rainbow trout,
Elisa,
Enrofloxacin,
Chaharmahal-va-Bakhtiary,
Abstract :
Enrofloxacin is one of the broad-spectrum antibiotics in veterinary medicine which in recent years its application has grown considerably for the control of infectious diseases in farmed fish. Alpha
The aim of this study was to quantify enrofloxacin residue in muscle and liver of rainbow trout cultured in Chaharmahal-va-Bakhtiary province using ELISA method. For this, the samples were obtained from the farms located in Ardal and Koohrang areas during the spring and summer of 2011. Three farms were chosen from each area and 15 samples were taken from three weight categories including < 50, 50-150 and > 150 g (5 samples from each category). Results revealed that maximum (58.33) and minimum (23.33) percentage of enrofloxacin residue was determined in <50 g and >150 g categories, respectively. In Koohrang region, the quantity of enrofloxacin residues in muscle and liver samples was 13.84 ± 11.50 and 19.95 ± 18.06, respectively. Meanwhile in Ardal, the quantity of the residue was estimated at 12.83 ± 11.62 and 11.22 ± 11.09, respectively. Considering the sampling time, among spring samples the quantity of the residues in muscle and liver was estimated at 14.27 ± 13 and 22.06 ± 21.69, respectively. The quantity of enrofloxacin among the summer samples was 12.40 ± 10.29 and 8.86 ± 7.31, respectively. Moreover, mean value of enrofloxacin residue in the muscle and liver of Koohrang was higher than Ardal region. It was concluded that enrofloxacin residue was lower than the maximum acceptance limit determined by the European Union.
References:
Balizs, G. and Hewitt, A. (2003). Determination of veterinary drug residues by liquid chromatography and tandem mass spectrometry. Analytica Chimica Acta, 492: 105-131.
Bjorklund, H.V. and Bylund, G. (1990). Temperature-related absorption and excretion of oxytetracycline in rainbow trout (Salmo gairdneri R). Aquaculture, 84(3-4): 363-372.
Commission of the European Communities (2003). Commission Decision 2003/181/EC of 13 March 2003 Amending Decision 2002/657/EC as regards the setting of minimum required performance limits (MRPLs) for certain residues in food of animal origin.
Di Corcia, A. and Nazzari, M. (2002). Liquid chromatographic-mass spectrometric methods for analyzing antibiotic and antibacterial agents in animal food products. Journal of Chromatography A, 974(1-2): 53-89.
Ding, S., Shen, J., Zhang, S., Jiang, H. and Sun, Z. (2005). Determination of chloramphenicol residue in fish and shrimp tissues by gas chromatography with a microcell electron capture detector. The Journal of AOAC International, 88(1): 57-60.
Dulopnt, H.L. (1989). Quinolone antibacterial agents in the management of bacterial enteric infections. In: Wolfson, J.S., Hooper, D.C. (Editors), Quinolone Antibacterial Agents. American Society for Microbiology, Washington, DC, pp. 5-34.
European Commission (2008). Council Regulation 2377/90/EC, Off. J.Eur.Union, L224-www.emea.eu.int
FAO (2008). State of World Fisheries and Aquaculture (SOFIA), Food and Agricultural Organization of the United Nations, Rome.
Hernández Serrano, P. (2005). Responsible use of antibiotics in aquaculture. FAO, Rome.
Horie, M. and Takegami, H. (2006). Legal restriction on veterinary drug residues and analysis of residual veterinary drug in food by LC/MS (Japanese, English Abstract). Journal of the Mass Spectrometry Society of Japan, 54:91-96.
Huet, A., Charlier, C., Tittlemier, S.A., Singh, G., Benrejeb, S. and Delahaut, P. (2006). Simultaneous determination of (Xuoro) quinolone antibiotics in kidney, marine products, eggs, and muscle by enzyme-linked immunosorbent assay (ELISA). Journal of Agriculture and Food Chemistry, 54: 2822-2827.
Juan-Garca, A., Font, G. and Pic, Y. (2006). Electrophoresis, 27: 2240-2249.
Julie, B.W., Graham, B., Mary, C.C., Bebak-Williams, J., Bullock, G. and Carson, M.C. (2002). Oxytetracycline residues in a freshwater recirculating system. Aquaculture, 205(3-4): 221-230.
Lucchetti, D., Fabrizi, L., Guandalini, E., Podestà, E., Marvasi, L., Zaghini, A. and Coni, E. (2004). Long Depletion Time of Enrofloxacin in Rainbow Trout (Oncorhynchus mykiss). Antimicrobial Agents and Chemotherapy, 48(10): 3912-3917.
Lucchetti, D., Fabrizi, L., Esposito, A., Guandalini, E., Pasquale, M. and Coni, E. (2005). Simple confirmatory method for the determination of erythromycin residues in trout: a fast liquid-liquid extraction followed by liquid chromatography-tandem mass. Spectrometry. Journal of Agriculture and Food Chemistry, 53: 9689-9694.
Niessen, W.M.A. (1998). Analysis of antibiotics by liquid chromatography-mass spectrometry (Review). Journal of Chromatography A, 812: 53-76.
O'Grady, P., Moloney, M. and Smith, P.R. (1988). Bath administration of the quinolone antibiotic flumequine to brown trout (Salmo trutta) and Atlantic salmon (Salmon salar). Disease of Aquatic Organisms, 4: 27-33.
Olutosin, R.I. and James, O.P. (2004). Simple rapid determination of enrofloxacin and ciprofloxacin in bovine milk and plasma by high-performance liquid chromatography with fluorescence detection. Journal of Pharmaceutical and Biomedical Analalysis, 35: 43-153.
Samanidou, V., Evaggelia, F. and Evaggelopoulou, N. (2007). Analytical strategies to determine antibiotic residues in fish. Journal of Separation Science, 30: 2549-2569.
Sapkota, A., Sapkota, A.R., Kucharski, M., Burke, J., McKenzie,S., Walker,P. and Lawrence, R. (2008). Aquaculture practices and potential human health risks: Current knowledge and future priorities. Environment International, 34(8): 1215-1226.
Soltani, M. (2010). Study of the residuals of some antibiotics in farmed rainbow trout in Chaharmahal va Bakhtiary province, project, No: 2439. Fishery organization of Chaharmahal va Bakhtiary province.
Tittlemier, S.A., Van De Riet, I.J., Burns, G., Potter, R., Murphy, C., Rourke, W., Pearce, H.M. and Dufresne, G. (2007). Analysis of veterinary drug residues in fish and shrimp composites collected during the Canadian Total Diet Study, 1993-2004. Food Additives and Contaminants, 24(1): 14-20.
Ueno, R., Sangrungruang, K. and Miyakawa, M. (1999). A simplified method for the determination of several fish drugs in edible fish and shrimp by high-performance liquid chromatography. Food Research International, 32(9): 629-633.
Yolanda Pico, A.G.F. (2006). Determination of quinolone residues in chicken and fish by capillary electrophoresis mass spectrometry. Electrophoresis, 27: 2240-2249.