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The use of gamma radiation for the elimination of Salmonella from frozen meat

Published online by Cambridge University Press:  15 May 2009

F. J. Ley
Affiliation:
Wantage Research Laboratory (AERE), Wantage, Berks.
T. S. Kennedy
Affiliation:
Wantage Research Laboratory (AERE), Wantage, Berks.
K. Kawashima
Affiliation:
Wantage Research Laboratory (AERE), Wantage, Berks.
Diane Roberts
Affiliation:
Food Hygiene Laboratory, Central Public Health Laboratory, Colindale Avenue, London, N. W. 9
Betty C. Hobbs
Affiliation:
Food Hygiene Laboratory, Central Public Health Laboratory, Colindale Avenue, London, N. W. 9
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Summary

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The use of a gamma radiation process for the elimination of Salmonella from frozen meat is considered with particular reference to the treatment of boned-out horsemeat and kangaroo meat imported into the UK and intended for use as pet meat.

Examination of dose/survival curves produced for several serotypes of Salmonella in frozen meat shows that a radiation dose of 0·6 Mrad. will reduce a population by at least a factor of 105. The influence on the radiation resistance of salmonellas of such factors as preirradiation growth in the meat and temperature during irradiation have been examined and considered. It is also demonstrated with both preinoculated and naturally contaminated meat that postirradiation storage in the frozen state does not lead to the revival of irradiated salmonellas.

The properties of Salmonella survivors deliberately produced in meat using conditions of irradiation designed to simulate a commercial process are studied after six recycling treatments through the process. There were no important changes in characteristics normally used for identification of Salmonella but radiation resistance was lowered. Survivors grown in situ in meat after irradiation showed an abnormally long lag phase, and removal of competitive microflora in meat by the radiation treatment can influence the growth of salmonellas.

Type
Research Article
Copyright
Copyright © Cambridge University Press 1970

References

REFERENCES

Alper, T., Gillies, N. E. & Elkind, M. M. (1960). The sigmoid survival curve in radio-biology. Nature, London 186, 1062.CrossRefGoogle Scholar
Anderson, K., Crowder, E. F. & Woodruff, P. (1964). The isolation of salmonellae from kangaroo meat sold as pet food. Medical Journal of Australia ii, 668.CrossRefGoogle Scholar
Beasley, J., Hopkins, G. B., Mcnab, D. J. N., Richards, A. G. & King, G. J. G. (1967). Pet meat as a potential source of human salmonellosis. Lancet i, 560.CrossRefGoogle Scholar
Bridges, B. A. (1964). Microbiological aspects of radiation sterilisation. Progress in Industrial Microbiology 5, 285.Google Scholar
Coleby, B., Ingram, M., Shepherd, H. J., Thornley, M. J. & Wilson, G. M. (1961). Treatment of meats with ionizing radiation, vii. Effect of low temperatures during irradiation. Journal of the Science of Food and Agriculture 12, 483.CrossRefGoogle Scholar
Dyer, J. K., Anderson, A. W. & Dutiyabodhi, P. (1966). Radiation survival of food pathogens in complex media. Applied Microbiology 14, 92.CrossRefGoogle ScholarPubMed
Erdman, I.E., Thatcher, F. S. & Macqueen, K. F. (1961 a). Studies on the irradiation of micro-organisms in relation to food preservation. II. Irradiation resistant mutants. Canadian Journal of Microbiology 7, 207.CrossRefGoogle Scholar
Erdman, I. E., Thatcher, F. S. & Macqueen, K. F. (1961 b). Studies on the irradiation of micro-organisms in relation to food preservation. I. The comparative sensitivities of specific bacteria of public health significance. Canadian Journal of Microbiology 7, 199.CrossRefGoogle Scholar
Galbraith, N. S., Taylor, C. E. D., Cavanagh, P., Hagan, J. C. & Paton, J. L. (1962). Pet foods and garden fertilizers as sources of human salmonellosis. Lancet i, 372.CrossRefGoogle Scholar
Grecz, N. (1965). Biophysical aspects of Clostridia. Journal of Applied Bacteriology 28, 17.CrossRefGoogle Scholar
Harlan, J. W. & Kauffman, F. L. (1965). Effect of irradiation temperature and processing conditions on organoleptic properties of beef and chemical yields in model systems. Radiation Preservation of Foods. Advances in Chemistry Series 65, American Chemical Society, Washington, D.C. 1967.Google Scholar
Hickman, J. R., Law, A. W. & Ley, F. J. (1969). Studies on the wholesomeness of irradiated meat. Harwell Rep. no. A.E.R.E.—R-6028 (unclassified).Google Scholar
Hills, P. R. & Smith, A. H. (1967). An evaluation of several gas-chromatographic and colorimetric methods for the detection of irradiated horsemeat. A.E.R.E. Rep. no. R-5461, H.M.S.O.Google Scholar
Hobbs, B. C. (1965). Contamination of meat supplies. Monthly Bulletin of the Ministry of Health and the Public Health Laboratory Service 24, 123.Google ScholarPubMed
Hynes, M. (1942). The isolation of intestinal pathogens by selective media. Journal of Pathology and Bacteriology 54, 193.CrossRefGoogle Scholar
Idziak, E. S. & Incze, K. (1968). Radiation treatment of foods. I. Radurization of fresh eviscerated poultry. Applied Microbiology 16, 1061.CrossRefGoogle ScholarPubMed
Leifson, E. (1936). New selenite enrichment media for the isolation of typhoid and paratyphoid (Salmonella) Bacilli. American Journal of Hygiene 24, 423.Google Scholar
Ley, F. J. (1962). The use of ionizing radiation for the treatment of raw meat. Sanatarian, London 71, 185.Google Scholar
Ley, F. J. (1966). Application of radiation for the control of salmonellae in various foods. Food Irradiation. Proceedings of FAO/IAEA meeting, Karlsruhe 1966. IAEA Pub. no. 127, H.M.S.O.Google Scholar
Ley, F. J., Freeman, B. M. & Hobbs, B. C. (1963). The use of gamma radiation for the elimination of salmonellae from various foods. Journal of Hygiene 61, 515.Google ScholarPubMed
Ley, F. J. & Rogers, F. (1968). Processing with ionizing radiations. Biochemical and Biological Engineering Science, vol. 2, chap. 17 (Ed. by Blakeborough, N.). Academic Press.Google Scholar
Licciardello, J. J., Nickerson, J. T. R. & Goldblith, S. A. (1968). Elimination of salmonella in poultry. Proceedings of an FAO/IAEA Panel on elimination of harmful organisms from food and feed by irradiation. IAEA Pub. no. STI⊃PUB/200. H.M.S.O.Google Scholar
Licciardello, J. J., Nickerson, J. T. R., Goldblith, S. A., Shannon, C. A. & Bishop, W. W. (1969). Development of radiation resistance in Salmonella cultures. Applied Microbiology 18, 24.CrossRefGoogle ScholarPubMed
Mccrady, M. H. (1918). Tables for rapid interpretation of fermentation tube results. Canadian Public Health Journal 9, 201.Google Scholar
Matches, J. R. & Liston, J. (1968). Growth of salmonellae on irradiated and non-irradiated seafoods. Journal of Food Science 33, 406.CrossRefGoogle Scholar
Matsuyama, A., Thornley, M. J. & Ingram, M. (1964 a). The effect of freezing on the radiation sensitivity of vegetative bacteria. Journal of Applied Bacteriology 27, 110.CrossRefGoogle Scholar
Matsuyama, A., Thornley, M. J. & Ingram, M. (1964 b). The effect of freezing on the radiation sensitivity of bacterial spores. Journal of Applied Bacteriology 27, 125.CrossRefGoogle Scholar
Miles, A. A. & Misra, S. S. (1938). The estimation of the bactericidal power of blood. Journal of Hygiene 38, 732.Google Scholar
Mossel, D. A. A., Van Schothorst, M. & Kampelmacher, E. H. (1968). Prospects for the salmonella radicidation of some foods and feeds with particular reference to the estimation of the dose required. Proceedings of an FAO/IAEA Panel on elimination of harmful organisms from food and feed by irradiation. IAEA Pub. STI/PUB/200. H.M.S.O.Google Scholar
North, W. R. (1961). Lactose pre-enrichment method for isolation of salmonellae from dried egg albumin. Applied Microbiology 9, 188–95.CrossRefGoogle Scholar
Report (1964). Ministry of Health Report of working party on irradiation of food. H.M.S.O.Google Scholar
Rolfe, V. (1946). A note on the preparation of tetrathionate broth. Monthly Bulletin of the Ministry of Health and the Emergency Public Health Laboratory Service 5. 158.Google ScholarPubMed
Stapleton, G. E. (1955). Variations in the sensitivity of E. coli to ionizing relations during the growth cycle. Journal of Bacteriology 70, 357.CrossRefGoogle Scholar
Statutory Instruments (1967). The Food (Control of Irradiation) Regulations 1967. H.M.S.O.Google Scholar
Statutory Instruments (1969). The Meat (Sterilization) Regulations 1969. H.M.S.O.Google Scholar
Van Schothorst, M. & Kampelmacher, E. H. (1967). Salmonella in meat imported from South American countries. Journal of Hygiene 65, 321.CrossRefGoogle ScholarPubMed
Vernon, E. (1969). Food poisoning and Salmonella infections in England and Wales, 1967. Public Health, London 83, 205.CrossRefGoogle ScholarPubMed
Witkin, E. M. (1969). Ultraviolet-induced mutation and DNA repair. Annual Review of Microbiology 23, 487.CrossRefGoogle ScholarPubMed