Free Access
Issue
Dairy Sci. Technol.
Volume 89, Number 3-4, May-August 2009
1st IDF/INRA International Symposium on Minerals and Dairy Products
Page(s) 335 - 348
DOI https://doi.org/10.1051/dst/2009014
Published online 14 May 2009
References of  Dairy Sci. Technol. 89 (2009) 335–348
  1. Anema S.G., Effect of milk concentration on heat-induced, pH-dependent dissociation of casein from micelles in reconstituted skim milk at temperatures between 20 and 120 $^{\circ}$C, J. Agric. Food Chem. 46 (1998) 2299–2305 [CrossRef].
  2. Anema S.G., Klostermeyer H., Heatinduced, pH-dependent dissociation of casein micelles on heating reconstituted skim milk at temperatures below 100 $^{\circ}$C, J. Agric. Food Chem. 45 (1997) 1108–1115 [CrossRef].
  3. Anema S.G., Lee S.K., Lowe E.K., Klostermeyer H., Rheological properties of acid gels prepared from heated pH-adjusted skim milk, J. Agric. Food Chem. 52 (2004) 337–343 [CrossRef] [PubMed].
  4. Anema S.G., Li Y., Further studies on the heat-induced, pH dependent dissociation of casein from the micelles in reconstituted skim milk, Lebensm-Wiss. Technol. 33 (2000) 335–343 [CrossRef].
  5. Aoki T., Kako Y., Relation between micelle size and formation of soluble casein on heating concentrated milk, J. Dairy Res. 50 (1983) 207–213 [CrossRef].
  6. Auty M.A.E., O'Kennedy B.T., Allan-Wojtas P., Mulvihill D.M., The application of microscopy and rheology to study the effect of milk salt concentration on the structure of acidified micellar casein systems, Food Hydrocoll. 19 (2005) 101–109 [CrossRef].
  7. Dalgleish D.G., Measurement of electrophoretic mobilities and zeta-potentials of particles from milk using laser Doppler electrophoresis, J. Dairy Res. 51 (1984) 425–438 [CrossRef].
  8. Dalgleish D.G., Law A.J.R., pH-Induced dissociation of bovine casein micelles. I. Analysis of liberated caseins, J. Dairy Res. 55 (1988) 529–538 [CrossRef].
  9. Dalgleish D.G., Law A.J.R., pH-Induced dissociation of bovine casein micelles. II. Mineral solubilization and its relation to casein release, J. Dairy Res. 56 (1989) 727–735 [CrossRef].
  10. del Angel C.R., Dalgleish D.G., Structures and some properties of soluble protein complexes formed by the heating of reconstituted skim milk powder, Food Res. Int. 39 (2005) 472–479 [CrossRef].
  11. Famelart M.H., Le Graët Y., Raulot K., Casein micelle dispersion into water, NaCl and CaCl2: physicochemical characteristics of micelles and rennet coagulation, Int. Dairy J. 9 (1999) 293–297 [CrossRef].
  12. Famelart M.H., Lepesant F., Gaucheron F., Le Graët Y., Schuck P., pH-Induced physicochemical modifications of native phosphocaseinate suspensions: influence of aqueous phase, Lait 76 (1996) 445–460 [CrossRef].
  13. Fox P.F., Hearn C.M., Heat stability of milk: influence of dilution and dialysis against water, J. Dairy Res. 45 (1978) 149–157 [CrossRef].
  14. Gaucher I., PiotM.,Beaucher E.,Gaucheron F., Physico-chemical characterization of phosphate-added skim milk, Int. Dairy J. 17 (2007) 1375–1383 [CrossRef].
  15. Gaucheron F., Le Graët Y., Schuck P., Équilibres minéraux et conditions physicochimiques, in: Gaucheron F. (Ed.), Minéraux et produits laitiers, Tec & Doc, Paris, France, 2004, pp. 219–280.
  16. Griffin M.C.A., Lyster R.L.J., Price J.C., The disaggregation of calcium-depleted casein micelles, Eur. J. Biochem. 174 (1988) 339–343 [CrossRef] [PubMed].
  17. Guyomarc'h F., Gueguiner C., Law A.J.R., Horne D.S., Dalgleish D.G., Role of the soluble and micelle-bound heat-induced protein aggregates on network formation in acid skim milk gels, J. Agric. Food Chem. 51 (2003) 7743–7750 [CrossRef] [PubMed].
  18. Heertje I., Visser J., Smits P., Structure formation in acid milk gels, Food Microstruct. 4 (1985) 267–277.
  19. Holt C., Inorganic constituents of milk. III. The colloidal calcium phosphate of cow's milk, J. Dairy Res. 49 (1982) 29–38 [CrossRef] [PubMed].
  20. Holt C., Biophysique des sels et de la micelle de caséine, in: Gaucheron F. (Ed.), Minéraux et produits laitiers, Tec & Doc, Paris, France, 2004, pp. 113–149.
  21. Holt C., Davies D.T., Law A.J.R., Effects of colloidal calcium phosphate content and free calcium ion concentration in the milk serum on the dissociation of bovine casein micelles, J. Dairy Res. 53 (1986) 557–572 [CrossRef].
  22. International Dairy Federation, Cheese and processed cheese – Determination of total phosphorus content (Photometric method), Standard 33C (1987) 1–3.
  23. Laligant A., Famelart M.-H., Brulé G., Piot M., Paquet D., Fermentation by lactic bacteria at two temperatures of pre-heated reconstituted milk. I – Behaviour of proteins and minerals, Lait 83 (2003) 181–192 [CrossRef].
  24. Le Graët Y., Brulé G., Les équilibres minéraux du lait : influence du pH et de la force ionique, Lait 73 (1993) 51–60 [CrossRef].
  25. Lee W.J., Lucey J.A., Rheological properties, whey separation, and microstructure in set-style yogurt: effects of heating temperature and incubation temperature, J. Text. Stud. 34 (2004) 515–536 [CrossRef].
  26. Lin S.H.C., Leong S.L., Dewan R.K., Bloomfield V.A., Morr C.V., Effect of calcium ion on the structure of native bovine casein micelles, Biochemistry 11 (1972) 1818–1821 [CrossRef] [PubMed].
  27. Lucey J.A., Dick C., Singh H., Munro P.A., Dissociation of colloidal calcium phosphate-depleted casein particles as influenced by pH and concentration of calcium and phosphate, Milchwissenschaft 52 (1997) 603–606.
  28. Lucey J.A., Tamehana M., Singh H., Munro P.A., Effect of interactions between denatured whey proteins and casein micelles on the formation and rheological properties of acid skim milk gels, J. Dairy Res. 65 (1998) 555–567 [CrossRef].
  29. Mekmene O., Le Graët Y., Gaucheron F., A model for predicting salt equilibria in milk and mineral-enriched milks, Food Chem. 116 (2009) 233–239 [CrossRef].
  30. Odagiri S., Nickerson T.A., Complexing of calcium by hexametaphosphate, oxalate, citrate, and ethylenediamine-tetraacetate in milk. II. Dialysis of milk containing complexing agents, J. Dairy Sci. 48 (1965) 19–22 [PubMed].
  31. Ono T., Dan H.T., Odagiri S., Dissociation of bovine casein micelles by dialysis, Agric. Biol. Chem. 42 (1978) 1063–1064.
  32. Ono T., Furuyama T., Odagiri S., Dissociation of large and small bovine casein micelles by dialysis, Agric. Biol. Chem. 45 (1981) 511–512.
  33. Ozcan-Yilsay T., Lee W.J., Horne D., Lucey J.A., Effect of trisodium citrate on rheological and physical properties and microstructure of yogurt, J. Dairy Sci. 90 (2007) 1644–1652 [CrossRef] [PubMed].
  34. Pitkowski A., Nicolai T., Durand D., Scattering and turbidity study of the dissociation of casein by calcium chelation, Biomacromolecules 9 (2008) 369–375 [CrossRef] [PubMed].
  35. Premlal Ranjith H.M., Lewis M.J., Maw D., Production of calcium-reduced milks using an ion-exchange resin, J. Dairy Res. 66 (1999) 139–144 [CrossRef] [PubMed].
  36. Schuck P., Piot M., Méjean S., Fauquant J., Brulé G., Maubois J.-L., Déshydratation des laits enrichis en caséine micellaire par microfiltration; comparaison des propriétés des poudres obtenues avec celles d'une poudre de lait ultra-propre, Lait 74 (1994) 47–63.
  37. Singh H., Fox P.F., Heat stability of milk: influence of colloidal and soluble salts and protein modification on the pH-dependent dissociation of micellar $\kappa $-casein, J. Dairy Res. 54 (1987) 523–534 [CrossRef].
  38. Singh H., Fox P.F., Heat stability of milk: role of $\beta $-lactoglobulin in the pH-dependent dissociation of micellar $\kappa $-casein, J. Dairy Res. 54 (1987) 509–521 [CrossRef].
  39. Udabage P., McKinnon I.R., Augustin M.A., Mineral and casein equilibria in milk: effects of added salts and calcium-chelating agents, J. Dairy Res. 67 (2000) 361–370 [CrossRef] [PubMed].
  40. Udabage P., McKinnon I.R., Augustin M.A., Effects of mineral salts and calcium chelating agents on the gelation of renneted skim milk, J. Dairy Sci. 84 (2001) 1569–1575 [PubMed].
  41. Walstra P., Jenness R., Salts, in: Walstra P., Jenness R. (Eds.), Dairy Chemistry and Physics, John Wiley and sons, New York, 1984, pp. 42–57.
  42. Ward B.R., Goddard S.J., Augustin M.A., McKinnon I.R., EDTA-induced dissociation of casein micelles and its effect on foaming properties of milk, J. Dairy Res. 64 (1997) 495–504 [CrossRef].

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