Hostname: page-component-cd9895bd7-8ctnn Total loading time: 0 Render date: 2024-12-19T02:59:50.827Z Has data issue: false hasContentIssue false

Mineral partitioning in milk and milk permeates at high temperature

Published online by Cambridge University Press:  13 September 2011

Divina D Kaombe
Affiliation:
Department of Chemical and Mining Engineering, University of Dar Es Salaam, P. O. Box 35131, Dar es Salaam, Tanzania
Yanhong Du
Affiliation:
No 2, Unit 2, Building No 7, Yard No 66, North Qing Shan Road, Dawukou District, Shizuishan, Ningxia, China753000
Michael J Lewis*
Affiliation:
Department of Food and Nutritional Sciences, The University of Reading, Whiteknights, Reading RG6 6AP, UK
*
*For correspondence; e-mail: [email protected]

Abstract

The soluble phase of milk was separated at 20 and 80°C using ultrafiltration. The resulting permeates were then subjected to further ultrafiltration and dialysis at close to these two temperatures. It was found that pH, Ca2+ and soluble Ca decreased as the separation temperature increased both in original UF permeates and in dialysates obtained from these permeates, but P decreased only slightly. The major reason for these changes was due to the precipitation of calcium phosphate/citrate complexes onto the casein micelle with concomitant release of H+. The pH of both permeates and dialysates from milk at 20°C were slightly higher than for milk. When UF permeates collected at 20 and 80°C, were each dialysed at both these temperatures, the dialysate collected at 80°C showed much less temperature dependence for pH and ionic calcium compared with that collected at 20°C. This is in contrast to milk, which shows considerable temperature dependence for pH and ionic calcium. Further experiments revealed that the pH and Ca2+ concentration of permeates showed high temperature dependence above the temperature at which they were separated, but a much lower temperature dependence below that temperature. These findings suggest that dialysis and UF of milk at high temperature provide the best means yet for estimating the pH and ionic calcium of milk at that temperature.

Type
Research Article
Copyright
Copyright © Proprietors of Journal of Dairy Research 2011

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

Association of Official Analytical Chemists 2005 AOAC 991.25. Determination of total calcium. Maryland, USA: GarthersbergGoogle Scholar
Augustin, MA & Clarke, PT 1991 Heat stability of recombined concentrated milk: changes in calcium activity and pH on sterilization. Journal of Dairy Research 58 6774CrossRefGoogle Scholar
Chandrapala, J, McKinnon, I, Augustin, M-A & Udabage, P 2010 The influence of milk composition on pH and calcium activity measured in situ during heat treatment of reconstituted skim milk. Journal of Dairy Research 77 257264CrossRefGoogle ScholarPubMed
Davies, DT & White, JCD 1959 Determination of heat-induced changes in the protein stability and chemical composition of milk. In 15th International Dairy Congress, London, pp 16771684, Vol. IIIGoogle Scholar
Farrell, HM & Kumosinski, TF 1988 Modelling of calcium-induced solubility profiles of casein for biotechnology: influence of primary structure and post-translational modification. Journal of Industrial Microbiology 3 6171CrossRefGoogle Scholar
Fox, PF & Morrissey, PA 1977 Reviews of the progress of Dairy Science: the heat stability of milk. Journal of Dairy Research 44 627646CrossRefGoogle Scholar
Fox, PF & McSweeney, PLH 1998 Dairy Chemistry and Biochemistry. London: Blackie Academic and ProfessionalGoogle Scholar
Geerts, JP, Bekhof, JJ & Scherjon, JW 1983 Determination of calcium ion activities in milk with an ion selective electrode. Netherlands Milk and Dairy Journal 37 197211Google Scholar
Hilgeman, M & Jenness, R 1951 Observations on the effect of heat treatment upon the dissolved calcium and phosphorous in skim milk. Journal of Dairy Science 34 483484Google Scholar
IDF 1990 Milk determination of total phosphorous content. Spectrometric method. IDF standard 42B. Belgium. Square Vergote 41. International Dairy FederationGoogle Scholar
Jenness, R & Patton, S 1959 Principles of Dairy Chemistry. New York: WileyGoogle Scholar
Kannan, A & Jenness, R 1961 Relation of milk serum proteins and milk salts to the effects of heat treatment on rennet clotting. Journal of Dairy Science 44 808822CrossRefGoogle Scholar
Lin, M-J, Lewis, MJ & Grandison, AS 2006 Measurement of ionic calcium in milk. International Journal of Dairy Technology 59 192199CrossRefGoogle Scholar
Ma, Y & Barbano, D 2003 Milk pH as a function of CO2 concentration, temperature, and pressure in a heat exchanger. Journal of Dairy Science 86 38223830CrossRefGoogle Scholar
Nieuwenhuijse, J, 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
On-Nom, N, Grandison, AS & Lewis, MJ 2010 Measurement of ionic calcium, pH and soluble divalent cations in milk at high temperature. Journal of Dairy Science 93 515523CrossRefGoogle ScholarPubMed
Pouliot, Y, Boulet, M & Paquin, P 1989a Observations on the heat-induced salt balance changes in milk I. Effect of heating time between 4 and 90°C. Journal of Dairy Research 56 185192CrossRefGoogle Scholar
Pouliot, Y, Boulet, M & Paquin, P 1989b An experimental technique for the study of milk salt balance. Journal of Dairy Science 72 3640CrossRefGoogle Scholar
Pouliot, Y, Boulet, M & Paquin, P 1989c Observations on the heat induced salt balance changes in milk. Journal of Dairy Research 56 193199CrossRefGoogle Scholar
Pyne, GT 1953 Some new factors in heat coagulation of milk. Proceedings of 13th International Dairy Congress, The Hague, pp 10321034. Vol. IIIGoogle Scholar
Pyne, GT 1958 The heat coagulation of milk. II. Variations in sensitivity of casein to calcium ions. Journal of Dairy Research 25 467CrossRefGoogle Scholar
Rose, D & Tessier, H 1958 Calcium ion concentration in milk. Journal of Dairy Science 41 351353Google Scholar
Rose, D & Tessier, H 1959 Composition of ultrafiltrates from milk heated at 80 to 230 F in relation to heat stability. Journal of Dairy Science 42 969980CrossRefGoogle Scholar
Schmidt, DG & Poll, JK 1989 Properties of artificial casein micelles. 4. Influence of dephosphorylation and phosphorylation of the casein. Netherlands Milk and Dairy Journal 43 5362Google Scholar
Smeets, WTGM 1955 The determination of the concentration of calcium ions in milk ultrafiltrate. Netherlands Milk and Dairy Journal 9 249260Google Scholar
Tsioulpas, A, Koliandris, A., Grandison, AS & Lewis, MJ 2010 Effects of stabiliser addition and in-container sterilisation on selected properties of milk related to casein micelle stability. Food Chemistry 122 10271034CrossRefGoogle Scholar
Walstra, P & Jenness, R 1984 Dairy Chemistry and Physics. New York: John Wiley and SonsGoogle Scholar