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Microbial challenges of poultry meat production

Published online by Cambridge University Press:  21 September 2007

N.M. BOLDER
N.M. BOLDER*
Affiliation:
Animal Sciences Group, Wageningen UR, Division Infectious Diseases, PO Box 65, 8200 AB Lelystad, The Netherlands
*
E-mail: nico.bolder@wur.nl
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Abstract

Food safety and shelf-life are both important microbial concerns in relation to broiler meat production. Focus is mainly placed on the absence or control of potentially pathogenic microbes such as Salmonella and Campylobacter but, from commercial point of view, other spoilage bacteria also play a role. Regarding food safety, the primary target should be the production of pathogen-free live animals, thereby allowing slaughter plants to keep the processing line free of those micro-organisms. Pathogen-free feed is fundamental in obtaining such conditions, as is the Good Hygienic Practice in farming, including grand parent stock (GPS), parent stock (PS) and hatcheries.

Interventions in the slaughter plant cannot always completely remove pathogens. However there are some measures of control available, including separation of flocks, carcass decontamination and implementing a balanced and operational HACCP system.

Shelf-life is closely linked to food safety during processing. The developments towards in-line processing, including chilling, portioning and deboning, allows optimal control. It minimizes processing time and product to product contact, and thus increases shelf-life and limits cross contamination. Refrigeration conditions are very important and an interruption of the refrigeration chain can accelerate microbial growth. Modified atmosphere packaging (MAP) may contribute in controlling the undesired growth of spoilage organisms, and can play a role in food safety as well.

The consumer needs to be educated in how to deal with food of animal origin that cannot be produced in an entirely sterile environment, in order to ensure shelf-life and correct preparation and use.

Keywords

poultry meat qualityfood safetySalmonellaCampylobacter
Type
Review Article
Information
World's Poultry Science Journal , Volume 63 , Issue 3 , September 2007 , pp. 401 - 411
Copyright
Copyright © World's Poultry Science Association 2007

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References

ALLEN, V.M., CORRY, J.E.L., BURTON, C.H., WHYTE, R.T. and MEAD, G.C. (2000) Hygiene aspects of modern poultry chilling. International Journal of Food Microbiology 58: 3948.Google Scholar
BERRANG, M.E., NOTHCUTT, J.K. and DICKENS, J.A. (2004) The contribution of air borne contamination to Campylobacter counts on defeathered broiler carcasses. Journal of Applied Poultry Research 13: 14.CrossRefGoogle Scholar
BOLDER, N.M. (1998) The Microbiology of the slaughter and processing of poultry. In: The microbiology of meat and poultry, , Davies and , Board eds., Blackie Academic & Professional, London. Pp 158173.Google Scholar
BOLDER, N.M. (2003) Het decontamineren van pluimveekarkassen; Vlees niet geheel vrij van Salmonella en Campylobacter. Vleesindustrie, juni: 1617 (Dutch).Google Scholar
BOLDER, N.M. (2006a) Chemical carcass decontamination to control Salmonella and Campylobacter in poultry meat, Proceeding European Poultry Congress, Verona, September 2006.Google Scholar
BOLDER, N.M. (2006b) Salmonella control in broiler farming. Proceedings of the European Poultry Congress, Verona, September 2006.Google Scholar
BOYSEN, L., KNØCHEL, S. and ROSENQUIST, H. (2007) Survival of Campylobacter jejuni in different gas mixtures. FEMS Microbiological Letters 266: 152157.CrossRefGoogle ScholarPubMed
BROWN, D.J., MADSEN, M., OLSEN, J.E. and BISGAARD, M. (1995) Automated catching machines transport crates and crate washing facilities as risk factors associated with the incidence of Salmonella enterica in broiler production. XIIth European Symposium on the Quality of Poultry Meat, ed Briz, Cepero, Zaragoza, Spain p 103104.Google Scholar
BYRD, J.A., ANDERSON, R.C., CALLAWAY, T.R., MOORE, R.W., KNAPE, K.D., KUBENA, L.F., ZIPRIN, R.L. and NISBET, D.J. (2003) Effect of experimental chlorate administration in the drinking water on Salmonella Typhimurium contamination of broilers. Poultry Science 82: 14031406.CrossRefGoogle ScholarPubMed
CASON, J.A., HINTON, A. and INGRAM, K.D. (2000) Coliform, Escherichia coli and salmonellae concentrations in a multiple-tank counter flow poultry scalder. Journal of Food Protection 63: 11841188.CrossRefGoogle Scholar
CHURCH, I.J. and PARSONS, A.L. (1995) Modified atmosphere packaging technology: a review. Journal Science of Food and Agriculture 67: 143152.CrossRefGoogle Scholar
CORRY, J.E.L., ALLEN, V.M., HUDSON, W.R., BRESLIN, M.F. and DAVIES, R.H. (2002) Sources of salmonella on broiler carcasses during transportation and processing: modes of contamination and methods of control. Journal of Applied Microbiology 92: 424432.CrossRefGoogle ScholarPubMed
DAVIES, R.H. and WRAY, C. (1997) Distribution of Salmonella contamination in ten animal feedmills. Veterinary Microbiology 51: 159169.Google Scholar
FLUCKEY, W.M., SANCHEZ, M.X., McKEE, S.R., SMITH, D., PENDLETON, E. and BRASHEARS, M.M. (2003) Establishment of a microbiological profile for an air-chilling poultry operation in the United States. Journal of Food Protection 66: 272279.CrossRefGoogle ScholarPubMed
GILL, C.O., MCGINNIS, J.C., BARBUT, S., YOUNG, D., LEE, N. and RAHN, K. (2004) Microbiological conditions of moisture-enhanced chicken breasts prepared at a poultry packing plant. Journal of Food Protection 67: 26752681.CrossRefGoogle Scholar
GREGORY, N.G. (1996) Welfare and hygiene during pre-slaughter handling. Meat Science 43: S35S46.CrossRefGoogle Scholar
HÄGGBLOM, P. (2006) Salmonella control in the feed sector. Salmonella Workshop – control in poultry from feed to farm. 13–17 March 2006, Uppsala, Sweden.Google Scholar
HANSON, I., EDEROTH, M., ANDERSSON, L., VÄGSHOLM, I. and OLSON ENGVALL, E. (2005) Transmission of Campylobacter spp. To chickens during transport to slaughter. Journal of Applied Microbiology 99: 11491157.CrossRefGoogle Scholar
HEEMSKERK, W.J.C. (2005) Improving processing hygiene by mechanical removal of faeces before scalding. XVIIth Eur. Symp. on the Quality of Poultry meat and XIth European Symposium on the Quality of Eggs and Egg Products, Doorwerth, The Netherlands, 23–26 May 2005, p 37).Google Scholar
HINTON, A. Jr., CASON, J.A. and INGRAM, K.D. 2004. Tracking spoilage bacteria in commercial poultry processing and refrigerated storage of poultry carcasses. International Journal of Food Microbiology 91:155165.CrossRefGoogle ScholarPubMed
HINTON, M. (2000) Microbial control in the meat industry. Flair Flow Europe Technical manual 379A/2000. Ed. Gormley, R.Google Scholar
HUMPHREY, T.J.LANNING, D.G. and LEEPER, D. (1984) The influence of scald water pH on the death rates of Salmonella typhimurium and other bacteria attached to chicken skin. Journal of Applied Bacteriology 57: 355359.CrossRefGoogle ScholarPubMed
JACOBS REITSMA, W.F., BOLDER, N.M. and MULDER, R.W.A.W. (1998) The influence of pre-slaughter stresses on the incidence and extent of human pathogens in poultry Cost: Pathogenic micro-organisms in poultry and eggs; 23–25 October 1996, Rome (I) in: Prevention of contamination of poultry meat, eggs and egg products. eds. Franchini, A., Mulder, R.W.A.W., European Communities 1998, Luxembourg, p 36.Google Scholar
KIM, J-W., SLAVIK, M.F., GRIFFIS, C.L. and WALKER, J.T. (1993) Attachment of Salmonella typhimurium to skins of chicken scalded at various temperatures. Journal of Food Protection 56: 661671.CrossRefGoogle ScholarPubMed
LOUGHNEY, C. (2004) How to clean for best results in the food processing industry. Meat Processing Global May/June: 1017.Google Scholar
MEAD, G.C., ALLEN, V.M., BURTON, G.H. and CORRY, J.E.L. (2000) Microbial cross contamination during air chilling of poultry. British Poultry Science 41: 158162.CrossRefGoogle ScholarPubMed
MULDER, R.W.A.W. and SCHLUND, J. (1999) Safety of poultry meat: from farm to table. report of the Int. Consultative Group on Food Irradiation (ICGFI) established under the aegis of FAO, IAEA and WHO.Google Scholar
MULDER, R.W.A.W. and DORRESTEYN, L.W.J. (1977) Hygiene beim Brühen von Schlachtgeflügel. Fleischwirtschaft 57; 22202222.Google Scholar
NAUTA, M., EVERS, E., HAVELAAR, A., BOLDER, N., VAN DER WAL, F.J., RIJSMAN, V., VAN HORNE, P., VAN WAGENBERG, C. and BERGEVOET, R. (2007) Risicobeheersing van Campylobacter in de pluimveevleesketen; Een modelmatige en economische analyse van kanalisatie van een hoog besmettingsniveau van Campylobacter in de mest. Report Thema Risicobeheersing Vleesproductieketens, BO-08–004. (Dutch).Google Scholar
NICHOLSON, F.A., GROVES, S.J. and CHAMBERS, B.J. (2005) Pathogen survival during livestock manure storage and following land application. Bioresource Technology 96(2): 135143.CrossRefGoogle ScholarPubMed
NYCHAS, G.-JE. and TASSOU, C.C. (1996) Growth/survival of Salmonella enteritidis on fresh poultry and fish stored under vacuum or modified atmosphere. Letters in Applied Microbiology 23: 115119.CrossRefGoogle ScholarPubMed
ROUGOOR, C., VAN DER WEIJDEN, W. and BOL, P. (2003) Voedselveiligheid tot (w)elke prijs? Essay and report of a conference. Stuurgroep Technology Assessment. Ministry of Agriculture, Nature Management and Food Quality. (Dutch).Google Scholar
RUSSELL, S. (2002) Intervention strategies for reducing salmonella prevalence. Watt Poultry USA October 2002: 2844.Google Scholar
RUSSELL, S. (2003) Intervention strategies for reducing salmonella prevalence on ready to cook chicken. Part one Processing. Poultry International June 2003: 2128.Google Scholar
SKOV, M.N., CARSTENSEN, B., TORNOE, N. and MADSEN, M. (1999) Evaluation of sampling methods for the detection of Salmonella in broiler flocks. Journal of Applied Microbiology 86: 695700.CrossRefGoogle ScholarPubMed
SLADER, J., DOMINGUE, G., JØRGESON, F., McALPINE, K., OWEN, R.J., BOLTON, F.J. and HUMPHREY, T.J. (2002) Impact of transport crate reuse and of catching and processing on Campylobacter and Salmonella contamination of broiler chickens. Applied and Environmental Microbiology 68: 713719.CrossRefGoogle ScholarPubMed
SMITH, D.P., CASON, J.A. and BERRANG, M.E. (2005) Effect of fecal contamination and cross contamination on numbers of coliform, Escherichia coli Campylobacter and Salmonella on immersion-chilled broiler carcasses. Journal of Food Protection 68: 13401345.CrossRefGoogle ScholarPubMed
WARRISS, P.D., WILKINS, J.L.BROWN, S.N.PHILLIPS, A.J. and ALLEN, V. (2004) Defaecation and weight of the gastro intestinal tract contents after feed and water withdrawal in broilers. British Poultry Science 45: 6166.CrossRefGoogle Scholar
YNTEMA, Y.J. (2005) TrusQ, Feed safety program. XVIIth Eur. Symp. on the Quality of Poultry meat and XIth Eur. Symp. on the Quality of Eggs and Egg Products, Doorwerth, The Netherlands, 2326 May 2005, p178).Google Scholar
ZUIDHOF, M.J., McGOVERN, R.H., SCHNEIDER, B.L., FEDDES, J.J.R., ROBINSON, F.E. and KORVER, D.R. (2004) Effects of feed withdrawal time on the incidence of fecal spillage and contamination of broiler carcasses at processing. Journal of Applied Poultry Research 13: 171177.Google Scholar