Hostname: page-component-586b7cd67f-2brh9 Total loading time: 0 Render date: 2024-11-26T10:32:32.369Z Has data issue: false hasContentIssue false
  • English
  • Français

Heat-induced association-dissociation of casein micelles preceding coagulation

Published online by Cambridge University Press:  01 June 2009

Kais S. Mohammad  and
Patrick F. Fox
Kais S. Mohammad
Affiliation:
Department of Dairy and Food Chemistry, University College, Cork, Irish Republic,
Patrick F. Fox
Affiliation:
Department of Dairy and Food Chemistry, University College, Cork, Irish Republic,
Get access Rights & Permissions [Opens in a new window]

Summary

Heating milk at 140 °C caused an initial increase in the percentage of total casein sedimented at 10000 g for 1 h and in the relative viscosity, but as heating continued both parameters decreased before increasing again just before the onset of visible coagulation. This suggests that heating milk at high temperatures caused an initial aggregation of casein micelles with a concomitant increase in particle size and weight, followed by dissociation of these aggregates with reaggregation just before coagulation. Chromatography of heated milk on controlled pore glass confirmed the above suggestion. Calcium appeared to play a major role in the initial association of casein micelles which was also influenced by the initial pH and total solids concentration but whey protein had no effect.

Type
Original Articles
Information
Journal of Dairy Research , Volume 54 , Issue 3 , August 1987 , pp. 377 - 387
Copyright
Copyright © Proprietors of Journal of Dairy Research 1987

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

Aoki, T., Suzuki, H. & Imamura, T. 1974 Formation of soluble casein in whey protein-free milk heated at high temperature. Milchwissenschaft 29 589594Google Scholar
Carroll, R. J., Thompson, M. P. & Melnychyn, P. 1971 Gelation of concentrated skim milk: electron microscopic study. Journal of Dairy Science. 54 12451252CrossRefGoogle Scholar
Creamer, L. K., Berry, G. P. & Matheson, A. R. 1978 The effect of pH on protein aggregation in heated skim milk. New Zealand Journal of Dairy Science and Technology 13 915Google Scholar
Davies, D. T. & White, J. C. D. 1966 The stability of milk protein to heat. 1. Subjective measurement of heat stability of milk. Journal of Dairy Research 33 6781Google Scholar
Davies, F. L., Shankak, P. A., Brooker, B. E. & Hobbs, D. G. 1978 A heat-induced change in the ultra-structure of milk and its effect on gel formation in yoghurt. Journal of Dairy Research 45 5358CrossRefGoogle Scholar
Donnelly, W. J., McNeill, G. P., Buchheim, W. & McGann, T. C. A. 1984 A comprehensive study of the relationship between size and protein composition in natural bovine casein micelles. Biochimica et Biophysica Acta 789 136143CrossRefGoogle ScholarPubMed
Fox, K. K., Harper, M. K., Holsinger, V. H. & Pallansch, M. J. 1967 Effect of high-heat treatment on stability of calcium caseinate aggregates in milk. Journal of Dairy Science 50 443450Google Scholar
Fox, P. F. 1981 Heat stability of milk: significance of heat-induced acid formation in coagulation. Irish Journal of Food Science and Technology 5 111Google Scholar
Fox, P. F. 1982 Heat-induced coagulation of milk. In Developments in Dairy Chemistry–l. Proteins, pp. 189228 (Ed. Fox, P. F.). London: Applied Science PublishersGoogle Scholar
Fox, P. F. & Hoynes, M. C. T. 1975 Heat stability of milk: influence of colloidal calcium phosphate and β-lactoglobulin. Journal of Dairy Research 42 427435CrossRefGoogle Scholar
Fox, P. F. & Morrissey, P. A. 1977 Reviews of the progress of Dairy Science: the heat stability of milk. Journal of Dairy Research 44 627646Google Scholar
W., Horwitz (ED.) 1970 Official Methods of Analysis of the AOAC, 11th edn p. 858. Washington, DC: Association of Official Analytical ChemistsGoogle Scholar
Jenness, R. & Koops, J. 1962 Preparation and properties of a salt solution which simulates milk ultrafiltrate. Netherlands Milk and Dairy Journal 16 153164Google Scholar
Kudo, S. 1980 The heat stability of milk: formation of soluble proteins and protein-depleted micelles at elevated temperatures. New Zealand Journal of Dairy Science and Technology 15 255263Google Scholar
McGann, T. C. A., Kearney, R. D. & Donnelly, W. J. 1979 Developments in column chromatography for the separation and characterization of casein micelles. Journal of Dairy Research 46 307311Google Scholar
Mohammad, K. S. 1982 Influence of organic salts and acids on the stability of milk protein to heat, ethanol and rennet. M.Sc. Thesis, National University of IrelandGoogle Scholar
Pyne, G. T. & McGann, T. C. A. 1960 The colloidal phosphate of milk. II. Influence of citrate. Journal of Dairy Research 27 917Google Scholar
Pyne, G. T. & McHenry, K. A. 1955 The heat coagulation of milk. Journal of Dairy Research 22 6068CrossRefGoogle Scholar
Sawyer, W. H. 1969 Complex between β-laetoglobulin and κ-casein. A review. Journal of Dairy Science 52 13471355Google Scholar
Singh, H. & Fox, P. F. 1985 a Heat stability of milk: the mechanism of stabilization by formaldehyde. Journal of Dairy Research 52 6576Google Scholar
Singh, H. & Fox, P. F. 1985 b Heat stability of milk: pH -dependent dissociation of micellar κ-casein on heating milk at ultra high temperatures. Journal of Dairy Research 52 529538Google Scholar
Singh, H. & Fox, P. F. 1986 Heat stability of milk: further studies on the pH-dependent dissociation of micellar κ-casein. Journal of Dairy Research 53 237248CrossRefGoogle Scholar
Wilson, H. K. 1971 Large protein particle changes in ultra high-temperature sterilized concentrated skim milk. Journal of Dairy Science 54 11221128CrossRefGoogle Scholar