Sanitary-hygienic evaluation of meat processing enterprises productions and their sanation

A.P. Paliy, K.O. Rodionova, M.V. Braginec, A.P. Paliy, L.I. Nalivayko


The results in the determination microbiocinosis level of the objects of veterinary supervision at meat processing enterprises are presented. It was experimentally established that in 3 hours of the slaughter workshop working process, the total number of microorganisms is higher more than 5 times of the established standard, and by the end of the working shift the amount of MAFAnM on the floor and walls is (1.6 ± 0.23)×106 and (8.2 ± 1.1)×105 CFU/cm2, respectively, which is significantly more of the regulated indicators. It is determined, that the most contaminated in the production process is the table to wash stomach, the gutter to move off stomach, the table to disassemble intestinal kit and the gutter to move off intestinal kits. The gained results indicate the necessity for thorough and timely sanitization of contaminated surfaces. It has been established that the daily use of «Anti-Jermi SR S 25» detergent (2.0 % – 30 minutes) provides the high level of sanitation in the meat industry enterprises. The disinfectant «Germicidan FF Plus» ensures the complete destruction of sanitary-indicative microorganisms at veterinary supervision sites of meat-processing plants when applied at 0.5 % concentration with an exposure of 60 minutes. The obtained results broaden the spectrum of highly active antimicrobial agents, which are promising to use in the processing and food industries.


microbial contamination;MAFAnM;disinfection;disinfectant preparation;concentration;exposure

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Argakov, P.V., Ermakovich, M.M., Argakov, V.N. (2004). Evaluation of resistance of microorganisms to disinfectants. Journal of the Achievement of Science and Technology of the AIC, 11, 40-42. (In Russian)

Broda, D.M., Bell, R.G., Boerema, J.A., Musgrave, D.R. (2002). The abattoir source of culturable psychrophilic Clostridium spp. causing «blown pack» spoilage of vacuum-packed chilled venison. J. of Applied Microbiology, 93, 817-824. doi: 10.1046/j.1365-2672.2002.01757.x

Dimko, R.O., Puwkova, A.G., Solomon, V.V. (2015). Nomenclature and active substances of veterinary disinfectants registered in Ukraine. Scientific Bulletin of NUBiP of Ukraine, 221, 191-195. (In Ukrainian)

Gill, C.O. (1995). Current and emerging approaches to assuring the hygienic condition of red meat. Canadian J. Animal Sci., 75, 1-13. doi: 10.4141/cjas95-001

Hinton, A., Cason, J.A., Ingram, K.D. (2002). Enumeration and identification of yeasts associated with commercial poultry processing and spoilage of refrigerated broiler carcasses. J. of Food Protection, 65, 993-998. doi: 10.4315/0362-028X-65.6.993

Iacubchak, О.М. (2010). Veterinary disinfection (instructions and guidelines). Kyiv: "Bioprom Company". (In Ukrainian)

Isonhood, J.H., Drake, M. (2002). Aeromonas species in foods. J. of Food Protection, 65, 575-582. PMID: 11899061

Jeon, H.C., Kim, J.E., Son, J.W., Chae, H.S., Jin, K.S., Oh,

J.H., Shin, B.W., Lee, J.H. (2011). Evaluation of the microbial contamination status and sanitation practice level in butcher's shops in Seoul. Korean J. Vet. Serv., 34, 409-416. doi: 10.7853/kjvs.2011.34.4.409

Kipin, Е.N. (2011). Testing of new disinfectants in a meat processing plant. Veterinary Medicine, 3, 43-45. (In Russian)

Kirby, R.M., Bartram, J., Carr, R. (2003). Water in food production and processing: quantity and quality concerns. Food Control, 14, 283-299. doi: 10.1016/S0956-7135(02)00090-7

Kvatirka, O. (2010). Prevent mold plaque. Meat technology of the world, 12, 68-72. (In Ukrainian)

Lammerding, A.M., Fazil, A. (2000). Hazard identification and exposure assessment for microbial food safety risk assessment. Int. J. Food Microbiol., 58(3), 147-157. PMID: 10939265

Megenska, N.A. (2014). General principles of microbiological control of safety and quality of food and feed in accordance with European and international requirements. Veterinary biotechnology, 4, 34-38. (In Ukrainian)

Paliy, A.P., Paliy, A.P., Naumenko, O.A. (2015). Innovative technologies and technical systems in dairy cattle breeding: scientific and educational manual. Kharkiv: City Press. (In Ukrainian)

Paliy, A.P., Rodionova, K.O., Braginec, M.V. (2017). Patent № 118874 UA, МPK А61L 2/16; C11D 1/00. Method of foam washing of objects of veterinary supervision / applicant and patentee Lugansc NAU. - № u 2017 03123; pend. 03.04.17; publ. 28.08.17, Bul. № 16, p. 3. (In Ukrainian)

Paliy, A.P., Rodionova, K.O., Braginec, M.V. (2017). Patent № 119095 UA, МPK А61L 2/16; C11D 1/00. Method of damp disinfection of animal husbandry / applicant and patentee Lugansc NAU. - № u 2017 03124; pend. 03.04.17; publ. 11.09.17, Bul. № 17, p. 3. (In Ukrainian)

Paliy, A.P., Rodionova, K.O., Paliy, A.P. (2017). Contamination of animals and poultry meat and means of its reduction. Food Science and Technology, 11(4), 64-71. doi:

Paliy, A.P., Rodionova, K.O., Paliy, A.P. (2017). Disinfectants in the system of antiepizootic measures. Proceedings of the Velikie Luki state. agricultural Academy, 2, 24-33. (In Russian)

Paliy, A.P., Stegniy, B.T., Muzyka, D.V., Gerilovych, A.P., Korneykov, O.M. (2016). The study of the properties of the novel virucidal disinfectant. Agricultural Science and Practice. 3(3), 41-47. doi: 10.15407/agrisp3.03.041

Rodionova, K.O., Paliy, A.P. (2016). The effectiveness of application ultraviolet radiation for the sanitation of production premises of meat processing enterprises. Journal for Veterinary Medicine, Biotechnology and Biosafety, 2(4), 20-24.

Rodionova, K.O., Paliy, A.P. (2017). Analysis of quality and safety indicators poultry meat during primary processing. Journal for Veterinary Medicine, Biotechnology and Biosafety, 3(2), 5-9.

Rutala, W.A., Weber, D.J. (2013). Disinfectants used for environmental disinfection and new room decontamination technology. Am J. Infect Control, 41, 36-41. doi: 10.1016/j.ajic.2012.11.006

Salvat, G., Colin, P. (1995). Cleaning and disinfection practice in the meat industries of Europe. Rev Sci. Tech., 14(2), 313-341. PMID: 7579634

Syne, S.M., Ramsubhag, A., Adesiyun, A.A. (2013). Microbiological hazard analysis of ready-to-eat meats processed at a food plant in Trinidad, West Indies. Infect. Ecol. Epidemiol, 3. doi: 10.3402/iee.v3i0.20450

Vasilev, V.A. (2003). The tactics of choosing disinfectants and antiseptics in hospitals. Medical Reviewer, 11, 24. (In Russian)

Weber, D.J., Rutala, W.A., Sickbert-Bennett, E. (2007). Outbreaks associated with contaminated antiseptics and disinfectants. Antimicrob. Agents Chemother, 51, 4217-4224. doi: 10.1128/aac.00138-07

Wilhelm, B., Rajic, A., Greig, J.D., Waddell, L., Harris, J. (2011). The effect of hazard analysis critical control point programs on microbial contamination of carcasses in abattoirs: a systematic review of published data. Food borne Pathog Dis., 8, 949-960. doi: 10.1089/fpd.2010.0809

Zavgorodnii, A.I., Paliy, A.P., Kalashnik, M.V. (2012). The effectiveness of disinfection depending on the quality of mechanical cleaning. Veterinary Medicine of Ukraine, 5, 8-10. (In Ukrainian)


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