Characterization of Depuration Process of Mytilus galloprovincialis in Presence of Chloramine-T and Super-Oxidized Water

Seafood poisoning due to mussels contaminated with pathogens is an important health issue all over the world. Increasing attention and efforts are made to improve the last product quality of mussels and to save consumers from food poisoning. In this study, the depuration process of black mussels (Mytilus galloprovincialis) which have a high consumption rate and located in coastal waters of Turkey was tried to improve using Chloramine-T and superoxide disinfectants. For this purpose, mussels contaminated with Escherichia coli were subjected to depuration for 6 hours in the presence of 20 mg / L of two disinfectants. In the study, It was determined that E. coli numbers in the mussels of disinfectant groups with an initial bacterial load of 4.4 Log cfu / g, decreased to 3.70 and 3.86 Log cfu / g, respectively and the depuration was faster than the control group (4.05 Log cfu / g). As a result, it has been concluded that the use of food-suitable disinfectants in deposition waters can be used for faster and more effective purification. However, considering the possibility of chemicals leaving residues in mussels, detailed studies should be carried out.

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Achiwa N, Katayose M, Abe K. 2003. Efficacy of electrolyzed acidic water for disinfection and quality maintenance of fresh-cut cabbage. Food Preserv. Sci., 29: 341-346.

Altinok I. 2004. Toxicity and therapeutic effects of chloramine-T for treating Flavobacterium columnare infection of goldfish. Aquaculture. 239: 47-56.

Al-Haq MI, Seo Y, Oshita S, Kawagoe Y. 2001. Fungicidal effectiveness of electrolyzed oxidizing water on postharvest brown rot of peach. HortScience, 36, 1310–1314.

Booth NH, McDonald LE. 1988. Veterinary pharmacology and therapeutics, 6th edition. Iowa State University Press, Ames. Bowker JD, Carty D. 2011. Chloramine-T Margin of Safety Estimates for Fry, Fingerling, and Juvenile Rainbow Trout. N Am J Aquac., 73: 259-269.

CLSI. 2006. Performance standards for antimicrobial disk susceptibility tests. Approved standard. 9th Edition Document M2-A9. Clinical and Laboratory Standards Institute, Wayne, PA.

Çolakolu FA, Çardak M, Çolakoglu S, Künili IE. 2014. Depuration Times of Donax trunculus and Tapes decussatus. Braz J. Microbiol., 45:1017-1022.

Devienne KF, Raddi MSG. 2002. Screening for Antimicrobial Activity of Natural Products Using a Microplate Photometer. Braz J. Microbiol., 33: 166-168.

European Commission 1991. Council Directive 91/492 of 15 July 1991 laying down the health conditions for the production and the placing on the market of live bivalve molluscs. Official Journal of the European Communities 268:1-14.

Fabrizio KA, Sharma RR, Demirci A, Cutter CN. 2002. Comparison of electrolyzed oxidizing water with various antimicrobial interventions to reduce Salmonella species on poultry. Poultry Science, 81, 1598–1605.

Fujiwara K, Doi R, Iimoto M, Fujii T. 2000. Fundamental studies on crop disease control by spraying electrolyzed anode-side water. Environ. Control Biol., 38: 263-271.

Kim C, Hung YC, Brackett RE, Frank JF. 2001. Inactivation of Listeria monocytogenes biofilms by electrolyzed oxidizing water. J Food Process and Preserv., 25: 91–100.

Kim C, Hung YC, Brackett RE, Lin CS. 2003. Efficacy of electrolyzed oxidizing water in inactivating Salmonella on alfalfa seeds and sprouts. J Food Protect., 66: 208–214.

Liao L, Chen WM, Xiao XM. 2007. The generation and inactivation mechanism of oxidation–reduction potential of electrolyzed oxidizing water. J Food Eng., 1326-1332.

Park H, Hung Y, Brackett R. 2002a. Antimicrobial effect of electrolyzed water for inactivating Campylobacter jejuni during poultry washing. Food Microbiol., 72: 77-83.

Park H, Hung Y, Kim C. 2002b. Effectiveness of electrolyzed water as a sanitizer for treating different surfaces. J. Food Prot., 65: 1276-1280.

Powell MD, Clark, GA. 2003. In vitro survival and the effect of water chemistry and oxidative chemical treatments on isolated gill amoebae from AGD-affected Atlantic salmon. Aquaculture. 220:135–144.

Roosenburg WH, Rhoderick JC, Block RM, Kennedy VS, Gull SR, Vreenegoor SM, Rosenkranz A. Collette C. 1980. Effects of Chlorine-Produced Oxidants on Survival of Larvae of the Oyster Crassostrea virginica. Mar. Ecol. Prog. Ser., 3: 93-96.

Shiba A, Tsukasaki H, Kanaishi A, Shiba K, Chida T, Okamura N. 2000. Electrolyzed strong acidic water as a new harmless disinfectant agent and its application to dentistry. J. Showa Univ. Dent. Soc., 20:173-179.

Subagja J, Slembrouck J, Hung LT, Legendre M. 1999. Larval rearing of an Asian catfish Pangasius hypophthalmus (Siluroidei, Pangasiidae): Analysis of precocious mortality and proposition of appropriate treatments. Aquat. Living Resour., 12:37-44.

Salvesen I, Vadstein O. 1995. Surface disinfection of eggs from marine fish: evaluation of four chemicals. Aquaculture International., 3: 155-171.

Takahashi Y, Takeshita A, Endo M, Sasaki M. 2002. Cleaning effectiveness of electrolyzed water depending on the nursing procedure and degree of hand contamination. Biocontrol Sci., 7: 173-179.

Venkitanarayanan KS, Ezeike GOI, Hung YC, Doyle MP. 1999. Inactivation of Escherichia coli O157:H7 and Listeria monocytogenes on plastic kitchen cutting boards by electrolyzed oxidizing water. J Food Protect., 62, 857–860.

Yoshida K, Min J, Park J, Isobe S, Suzuki T. 2003. Disinfecting rice seeds using acidic electrolyzed water. Nogyo Shisetsu, 33: 247-253.