Hostname: page-component-78c5997874-4rdpn Total loading time: 0 Render date: 2024-11-20T03:38:21.577Z Has data issue: false hasContentIssue false
  • English
  • Français

Effects of added salts on the heat stability of recombined concentrated milk

Published online by Cambridge University Press:  01 June 2009

Mary-Ann Augustin  and
Phillip T. Clarke
Mary-Ann Augustin
Affiliation:
CSIRO Division of Food Processing, Dairy Research Laboratory, Highett, Victoria 3190, Australia
Phillip T. Clarke
Affiliation:
CSIRO Division of Food Processing, Dairy Research Laboratory, Highett, Victoria 3190, Australia
Get access Rights & Permissions [Opens in a new window]

Summary

Changes in heat stability and Ca2+ activity of recombined concentrated milk (18% solids non-fat:8% fat) induced by the additions of 0·011–0·217 mol phosphate/kg skim milk solids (SMS), 0·022–0·217 mol citrate/kg SMS, 0·011–0·022 mol Ca/kg SMS and 0·016–0·067 mol EDTA/kg SMS were evaluated. Heat stability was assessed using an objective method which involved determination of viscosity after heating under controlled conditions. Low levels of added phosphate and citrate generally effected an acid shift of the viscosity–pH profile, while higher levels caused a broadening of the profile. Addition of CaCl2 at a level of 0·011 mol/kg SMS resulted in a narrowing of the viscosity–pH curve; additions of higher levels resulted in a non-heat stable recombined milk concentrate. EDTA also caused a narrowing of the viscosity–pH curve. The results highlight the importance of pH control for effective stabilization of recombined milk concentrates by additions of phosphate and citrate.

Type
Original Articles
Information
Journal of Dairy Research , Volume 57 , Issue 2 , May 1990 , pp. 213 - 226
Copyright
Copyright © Proprietors of Journal of Dairy Research 1990

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

Allen, R. J. L. 1940 The estimation of phosphorus. Biochemical Journal 34 858865CrossRefGoogle ScholarPubMed
Chaplin, L. C. 1984 Studies on micellar calcium phosphate: composition and apparent solubility product in milk over a wide pH range. Journal of Dairy Research 51, 251257CrossRefGoogle Scholar
Clarke, P. T. & Kieseker, F. G. 1986 A pilot scale preheating system for the treatment of milk and whey. CSIRO Food Research Quarterly 46 86–8Google Scholar
Dalgleish, D. G. 1987 Caseins and casein micelles at interfaces. In Proteins at Interfaces (ACS Symposium Series), No. 343 pp. 665676 (Eds Brash, J. L. and Horbett, T. A.). Washington D.C.: American Chemical SocietyGoogle Scholar
Dalgleish, D. G. & Law, A. J. R. 1988 pH-Induced dissociation of bovine casein micelles. I. Analysis of liberated caseins. Journal of Dairy Research 55 529538CrossRefGoogle Scholar
Davies, D. T. & White, J. C. D. 1960 The stability of milk protein to heat. I. Subjective measurement of heat stability of milk. Journal of Dairy Research 33 6781CrossRefGoogle Scholar
Fox, P. F. 1981 Heat stability of milk: significance of heat-induced acid formation in coagulation. Irish Journal of Food Science and Technology 5 111.Google Scholar
Fox, P. F. 1982 Heat-induced coagulation of milk. In Developments in Dairy Chemistry-I. Proteins pp. 189228 (Ed. Fox, P. F.). London: Applied ScienceGoogle 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 627646CrossRefGoogle Scholar
Geerts, J. P., Bekhof, J. J. & Scherjon, J. W. 1983 Determination of calcium ion activities in milk with an ion-selective electrode. A linear relationship between the logarithm of time and the recovery of the calcium ion activity after beat treatment. Netherlands Milk, and Dairy Journal 37 197211Google Scholar
Griffin, A. T., Hickey, M. W., Bailey, L. F. & Feagan, J. T. 1976 The significance of preheat and pH adjustment in the manufacture of recombined evaporated milk. Australian Journal of Dairy Technology 31 134137Google Scholar
Griffin, M. C. A., Lyster, R. L. J. & Price, J. C. 1988 The disaggregation of calcium-depleted casein micelles. European Journal of Biochemistry 174 339343CrossRefGoogle ScholarPubMed
Hardy, E. E., Muir, D. D., Sweetsur, A. W. M. & West, I. G. 1984 Changes of calcium phosphate partition and heat stability during manufacture of sterilized concentrated milk. Journal of Dairy Science 67 16661673CrossRefGoogle Scholar
Holt, C. & Dalgleish, D. G. 1986 Electrophoretic and hydrodynamic properties of bovine casein micelles interpreted in terms of particles with an outer hairy layer. Journal of Colloid and Interface Science 114 513524CrossRefGoogle Scholar
Holt, C., Davies, D. T. & Law, A. J. R. 1986 Effects of colloidal calcium phosphate content and free calcium ion concentration in the milk serum on the dissociation of bovine casein micelles. Journal of Dairy Research 53 557572CrossRefGoogle Scholar
Holt, C., Muir, D. D. & Sweetsur, A. W. M. 1978 Seasonal changes in the heat stability of milk from creamery silos in south-west Scotland. Journal of Dairy Research 45 183190CrossRefGoogle Scholar
Holt, C. & West, D. W. 1977 The salt composition of milk and formation of bovine casein micelles. Hannah Research institute Report pp. 5761Google Scholar
Kieseker, F. G. & Aitken, B. 1988 An objective method for determination of heat stability of milk powders. Australian Journal of Dairy Technology 43 2631Google Scholar
Kieseker, F. G., Clarke, P. T. & Aitken, B. 1984 A comparison of recombination and reconstitution processes for the preparation of dairy products. Australian Journal of Dairy Technology 39 145153Google Scholar
Lin, S. H. C., Leong, S. L., Dewan, R. K., Bloomfield, V. A. & More, C. V. 1972 Effect of calcium ion on the structure of native bovine casein micelles. Biochemistry 11 18181821CrossRefGoogle ScholarPubMed
Marier, J. R. & Boulet, M. 1958 Direct determination of citric acid in milk with an improved pyridine–acetic anhydride method. Journal of Dairy Science 41 16831692CrossRefGoogle Scholar
Newstead, D. F. 1977 Effect of protein and salt concentrations on the heat stability of evaporated milk. New Zealand Journal of Dairy Science and Technology 12 171175Google Scholar
Newstead, D. F., Sanderson, W. B. & Baucke, A. G. 1975 The effects of heat treatment and pH on the heat stability of recombined evaporated milk. New Zealand Journal of Dairy Science and Technology 10 113118Google Scholar
Nieuwenhuijse, J. A., Timmermans, W. & Walstra, P. 1988 Calcium and phosphate partitions during the manufacture of sterilized concentrated milk and their relations to the heat stability. Netherlands Milk and Dairy Journal 42 387421Google Scholar
Pyne, G. T. 1958 The heat coagulation of milk. II. Variations in sensitivity of casein to calcium ions. Journal of Dairy Research 25 467474CrossRefGoogle Scholar
Rose, D. 1961 a Variations in the heat stability and composition of milk from individual cows during lactation. Journal of Dairy Science 44 430441CrossRefGoogle Scholar
Rose, D. 1961 b Factors affecting the pH-sensitivity of the heat stability of milk from individual cows. Journal of Dairy Science 44 14051413CrossRefGoogle Scholar
Rose, D. 1962 Factors affecting the heat stability of milk. Journal of Dairy Science 45 13051311CrossRefGoogle Scholar
Rowland, S. J. 1938 The determination of the nitrogen distribution in milk. Journal of Dairy Research 9 4246CrossRefGoogle Scholar
Schmidt, D. G., Koops, J. & Westerbeek, D. 1977 Properties of artificial casein micelles. 1. Preparation, size distribution and composition. Netherlands Milk and Dairy Journal 31 328341Google Scholar
Sweetsur, A. W. M. & Muir, D. D. 1980 The use of permitted additives and heat-treatment to optimize the heat-stability of skim milk and concentrated skim milk. Journal of the Society of Dairy Technology 33 101105CrossRefGoogle Scholar
Sweetsur, A. W. M. & Muir, D. D. 1982 Natural variation in heat stability of concentrated milk before and after homogenization. Journal of the Society of Dairy Technology 35 120126CrossRefGoogle Scholar
Van Hooydonk, A. C. M., Hagedoorn, H. G. & Boerrigter, I. J. 1986 pH-induced physico-chemical changes of casein micelles in milk and their effect on renneting. 1. Effect of acidification on physico-chemical properties. Netherlands Milk and Dairy Journal 40 281296Google Scholar
White, J. C. D. & Davies, D. T. 1963 The determination of citric acid in milk and milk sera. Journal of Dairy Research 30 171189CrossRefGoogle Scholar