Hostname: page-component-586b7cd67f-dlnhk Total loading time: 0 Render date: 2024-11-26T13:21:30.240Z Has data issue: false hasContentIssue false
  • English
  • Français

Influence of processing temperature and seasonal change in diet on lipase activity and lipolysis during the mechanical separation of bovine milk

Published online by Cambridge University Press:  01 June 2009

Eric C. Needs ,
Malcolm Anderson ,
Stuart J. Payne  and
Elizabeth A. Ridout
Eric C. Needs
Affiliation:
*National Institute for Research in Dairying (University of Reading), Shinfield, Reading RG2 9 AT, UK
Malcolm Anderson
Affiliation:
*National Institute for Research in Dairying (University of Reading), Shinfield, Reading RG2 9 AT, UK
Stuart J. Payne
Affiliation:
*National Institute for Research in Dairying (University of Reading), Shinfield, Reading RG2 9 AT, UK
Elizabeth A. Ridout
Affiliation:
*National Institute for Research in Dairying (University of Reading), Shinfield, Reading RG2 9 AT, UK
Get access Rights & Permissions [Opens in a new window]

Summary

The effect of separating conditions on lipase activity and free fatty acid levels in preheated milk, cream and skim milk was measured on nine occasions during a 12-week period covering the seasonal change from winter feeding to summertime grazing. This change consisted of four periods each representing a different type of forage intake, namely: silage, kale, daytime grazing and 24 h grazing. Milk was separated at 30, 40, 50 and 60°C with preheating times of 10, 25 and 55 s. Results were expressed both as absolute values and in terms of changes relative to the original unheated milk. Lipase activity and free fatty acid concentration were significantly reduced as separation temperature increased but were not influenced by holding time. The loss of activity in cream was progressive so that at 60°C only 40% of the original activity remained. Up to 50°C little change occurred in preheated milk or skim milk activity, while at 60°C 83 and 76% respectively of the original activity remained. The amount of activity calculated to be associated with the fat fraction of the cream also decreased with temperature. Activity varied significantly with date; maximum values were observed during the first 3 weeks of summertime grazing. Relative activity values indicated that the susceptibility of milk lipase to heat inactivation also varied with date. Lipolysis was also significantly affected by date. Cream free fatty acid levels were lower during the period of daytime grazing and were significantly higher than those in preheated milk. The correlation between lipase activity and free fatty acid levels was generally poor, accounting for between 0 and 34% of the variance. Possible reasons for the effect of separating temperature on lipolysis in cream are discussed.

Type
Original Articles
Information
Journal of Dairy Research , Volume 52 , Issue 2 , May 1985 , pp. 255 - 266
Copyright
Copyright © Proprietors of Journal of Dairy Research 1985

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

Anderson, M. 1982 a Factors affecting the distribution of lipoprotein lipase activity between serum and casein micelles in bovine milk. Journal of Dairy Research 49 5159CrossRefGoogle ScholarPubMed
Anderson, M. 1982 b Stability of lipoprotein lipase activity in bovine milk. Journal of Dairy Research 49 231237CrossRefGoogle Scholar
Anderson, M., Needs, E. C. & Price, J. D. 1984 Lipolysis during the production of double cream. Journal of the Society of Dairy Technology 37 1922CrossRefGoogle Scholar
Astrup, H. N., Vik-Mo, L., Skr∅vseth, O. & Ekern, A. 1980 Milk lipolysis when feeding saturated fatty acids to the cow. Milchwissenschaft 35 14Google Scholar
British Standards Institution 1969 British Standard No. 696, Part II, p. 7 London: British Standards InstitutionGoogle Scholar
Deeth, H. C. & Fitz-Gerald, C. H. 1977 Some factors involved in milk lipase activation by agitation. Journal of Dairy Research 44 569583CrossRefGoogle Scholar
Deeth, H. C. & Fitz-Gerald, C. H. 1978 Effects of mechanical agitation of raw milk on the milk-fat globule in relation to the level of induced lipolysis. Journal of Dairy Research 45 373380.CrossRefGoogle Scholar
Deeth, H. C. & Fitz-Gerald, C. H. 1983 Lipolytic enzymes and hydrolytic rancidity in milk and milk products. In Developments in Dairy Chemistry-2 Lipids pp. 195239 (Ed. Fox, P. F.). London: Applied Science Publishers.CrossRefGoogle Scholar
Flemming, M. G. 1979 Lipolysis in bovine milk as affected by mechanical and temperature activation. Irish Journal of Food Science and Technology 3 111129Google Scholar
Frankel, E. N. & Tarassuk, N. P. 1959 Inhibition of lipase and lipolysis in milk. Journal of Dairy Science 42 409419CrossRefGoogle Scholar
Gholson, J. H., Scmexnailder, R. H. & Rusoff, L. L. 1966 Influence of a poor-quality low-energy ration on lipolytic activity in milk. Journal of Dairy Science 49 11361139.CrossRefGoogle ScholarPubMed
Hemmingway, E. B., Smith, G. H., Rook, J. A. F. & O'Flanagan, N. C. 1970 Lipase taint. Journal of the Society of Dairy Technology 23 4448.CrossRefGoogle Scholar
Koops, J. & Klomp, H. 1977 Rapid colorimetric determination of free fatty acids (lipolysis) in milk by the copper soap method. Netherlands Milk anil Dairy Journal 31 5674Google Scholar
Murphy, J. J., Connolly, J. F. & Headon, D. R. 1979 A study of factors associated with free fatty acid development in milk. Irish Journal of Food Science and Technology 3 131149Google Scholar
Nilsson-Ehle, P. & Schotz, M. C. 1976 A stable, radioactive substrate emulsion for assay of lipoprotein lipase. Journal of Lipid Research 17 536541.CrossRefGoogle ScholarPubMed
Olivecrona, T. 1980 Biochemical aspects of lipolysis in bovine milk. International Dairy Federation Bulletin Document no. 118 1925.Google Scholar
Salih, A. M. A. & Anderson, M. 1979 Effect of diet and stage of lactation on bovine milk lipolysis. Journal of Dairy Research 46 623631.CrossRefGoogle Scholar
Stobbs, T. H., Deeth, H. C. & Fitz-Gerald, C. H. 1973 Effect of energy intake on spontaneous lipolysis in milk from cows in late lactation. Australian Journal of Dairy Technology 28 170172Google Scholar
Tarassuk, N. P. & Frankel, E. N. 1957 The specificity of milk lipase. IV. Portion of the lipase system in milk. Journal of Dairy Science 40 418430CrossRefGoogle Scholar
Walstra, P. 1983 Physical chemistry of milk fat globules. In Developments in Dairy C, hemistry-2 Lipids pp. 119158 (Ed. Fox, P. F.). London; Applied Science Publishers.CrossRefGoogle Scholar
Walstra, P. & Van Beresteyn, E. C. H. 1975 Crystallization of milk fat in the emulsified state. Netherlands Milk and Dairy Journal 29 3565.Google Scholar
Wang, L. & Randolph, H. E. 1978 Activation of. 1. Distribution of lipase activity in temperature activated milk. Journal of Dairy Science 61 874880CrossRefGoogle Scholar