Hostname: page-component-cd9895bd7-mkpzs Total loading time: 0 Render date: 2024-12-22T20:41:48.808Z Has data issue: false hasContentIssue false
  • English
  • Français

A multi-valved milking machine cluster to control intramammary infection in dairy cows

Published online by Cambridge University Press:  01 June 2009

Tony K. Griffin ,
Robert J. Grindal  and
A. John Bramley
Robert J. Grindal
Affiliation:
AFRC Institute, for Animal Disease. Research, Compton Laboratory, Compton, Neiubury RG16 0NN, UK
A. John Bramley
Affiliation:
AFRC Institute, for Animal Disease. Research, Compton Laboratory, Compton, Neiubury RG16 0NN, UK
Get access Rights & Permissions [Opens in a new window]

Summary

A milking machine claw incorporating valves to prevent movement of milk between teats during milking, and its contribution to the prevention of udder infection under experimental and field conditions, is described. Under experimental conditions a suspension of Streptococcus agalactiae and Str. dysgalactiae was introduced into the milking cluster during milking; 11 of 40 quarters became infected using a conventional claw piece whereas none of 40 quarters milked with the multivalve claw developed intramammary infection. In a 12-month experiment in ten commercial herds, each split into two equal susceptibility groups, the multi-valved cluster reduced the incidence of new infection with coliforms and Str. uberis by 17% (P < 0·1). The incidence of all new infections and new clinical cases was 14 and 25% lower compared to conventional clusters but these reductions were not significant.

Type
Original articles
Information
Journal of Dairy Research , Volume 55 , Issue 2 , May 1988 , pp. 155 - 169
Copyright
Copyright © Proprietors of Journal of Dairy Research 1988

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

REFERENCES

Bramley, A. J. & Neave, F. K. 1975 Studies on the control of coliform mastitis in dairy cows. British Veterinary Journal 131 160169CrossRefGoogle ScholarPubMed
British Standards Institution 1968 Methods of microbiological examination for dairy purposes. London: BSI (BS No. 4285)Google Scholar
Cousins, C. L., Thiel, C. C., Westgarth, D. R. & Higgs, T. M. 1973 Further short-term studies of the influence of the milking machine on the rate of new mastitis infections. Journal of Dairy Research 40 289292CrossRefGoogle ScholarPubMed
Cullen, G. A. 1966 The ecology of Streptococcus uberis. British Veterinary Journal 122 333339CrossRefGoogle Scholar
Dodd, F. H., Neave, F. K., Kingwill, R. G., Thiel, C. C. & Westgarth, D. R. 1966 The importance of hygiene in the control of udder diseases. 17th International Dairy Congress, Munich A 383390Google Scholar
Griffin, T. K., Bramley, A. J. & Dodd, F. H. 1980 a Milking machine modifications in the control of bovine mastitis. Proceedings of the International Workshop on Machine Milking and Mastitis pp. 1929 (Ed. O'shea, J.) Moorepark, Fermoy: An Foras TalüntaisGoogle Scholar
Griffin, T. K., Dodd, F. H., Neave, F. K., Westgarth, D. R., Kingwill, R. G. & Wilson, C. D. 1977 A method of diagnosing intramammary infection in dairy cows for large experiments. Journal of Dairy Research 44 2545CrossRefGoogle ScholarPubMed
Griffin, T. K., Grindal, R. J., Williams, R. L., Neave, F. K. & Westgarth, D. R. 1982 Effect of the method of removal of the milking machine cluster on new udder infection. Journal of Dairy Research 49 361367CrossRefGoogle ScholarPubMed
Griffin, T. K., Mein, G. A., Westgarth, D. R., Neave, F. K., Thompson, W. H. & Maguire, P. D. 1980 b Effect of deflector shields fitted in the milking machine teatcup liner on bovine udder disease. Journal of Dairy Research 47 19CrossRefGoogle ScholarPubMed
Griffin, T. K., Williams, R. L., Grindal, R. J., Neave, F. K. & Westgarth, D. R. 1983 Use of deflector shields to reduce intramammary infection by preventing impacts on the teat ends of cows during machine milking. Journal of Dairy Research 50 397404CrossRefGoogle ScholarPubMed
Hamann, J. & Tolle, A. 1978 Infection trials with conventional and non-conventional milking units. Proceedings, Annual Meeting, National Mastitis Council 17 269274Google Scholar
Hamann, J., Tolle, A. & Whittlestone, W. G. 1980 The vector function of two types of milking machines: experimental and field studies. Proceedings of International Workshop on Machine Milking and Mastitis 3044 (Ed. O'shea, J.) Moorepark, Fermoy: An Foras TalúntaisGoogle Scholar
International Dairy Federation 1979 Somatic cells in milk: their significance and recommended methods for counting. International Dairy Federation Bulletin (Document 114)Google Scholar
Jasper, D. E. & Whittlestone, W. G. 1976 Movement of infection between milk tubes, teat cups, and teats with a jacketed airflow cushion in a single chamber teat cup. Journal of Dairy Science 59 20772085CrossRefGoogle Scholar
Leonard, R. D., Whittlestone, W. G. & Brookbanks, E. O. 1970 The milking machine and mastitis. New Zealand Journal of Agriculture 120(6) 67Google Scholar
Magee, C. 1980 A comparison of three milking units in terms of milking performance and influence on organisms transport. Thesis, Cornell University, Ithaca, NY 14853, USAGoogle Scholar
Neave, F. K., Dodd, F. H., Kingwill, R. G. & Westgarth, D. R. 1969 Control of mastitis in the dairy herd by hygiene and management. Journal of Dairy Science 52 696707CrossRefGoogle ScholarPubMed
Needs, E. C., Anderson, M. & Morant, S. V. 1986 Interaction of factors which influence the extent of lipolysis during milking and storage of raw milk. Journal of Dairy Research 53 203210CrossRefGoogle Scholar
O'Callaghan, E., O'Shea, J., Meaney, W. J. & Crowley, C. 1976 Effect of milking machine vacuum fluctuations and liner slip on bovine mastitis infectivity. Irish Journal of Agricultural Research 15 401418Google Scholar
O'Shea, J., O'Callaghan, E., Meaney, W. J. & Crowley, C. 1976 Effect of combinations of large and small irregular and cyclic vacuum fluctuations in the milking machine on the rate of new infection in dairy cows. Irish Journal of Agricultural Research 15 377399Google Scholar
Sheldrake, R. F. & Hoare, R. J. T. 1980 Effect of a disinfectant udder wash and a post-milking teat dip on the bacterial population of the teat end and on the rate of new intramammary infection. Journal of Dairy Research 47 253258CrossRefGoogle Scholar
Thiel, C. C., Cousins, C. L., Westgarth, D. R. & Neave, F. K. 1973 The influence of some physical characteristics of the milking machine on the rate of new mastitis infections. Journal of Dairy Research 40 117129CrossRefGoogle ScholarPubMed
Thompson, P. D. & Schultze, W. D. 1975 Transfer of mastitis pathogens across the milking machine claw. Journal of Dairy Science 58 752Google Scholar
Whittlestone, W. G., Jasper, D. E., Kevey, W. A. & Duganzich, D. M. 1980 Some effects of milking without pulsation with a jacketed airflow cushion in a single chambered teatcup (PME). Milchwissenschaft 35 343346Google Scholar
Whittlestone, W. G., Twomey, A. & Crawley, W. E. 1972 The milking machine as a vector for mastitis infections. I. The inter unit transmission of microorganisms. Milchwissenschaft 27 618620Google Scholar
Wilesmith, J. W., Francis, P. G. & Wilson, C. D. 1986 Incidence of clinical mastitis in a cohort of British dairy herds. Veterinary Record 118 199204CrossRefGoogle Scholar