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Effect of chelators on functionality of milk protein concentrates obtained by ultrafiltration at a constant pH and temperature

Published online by Cambridge University Press:  20 September 2017

Lata Ramchandran ,
XiaoXia Luo  and
Todor Vasiljevic
Lata Ramchandran
Affiliation:
Advanced Food Systems Research Unit, College of Health and Biomedicine, PO Box 14428, Victoria University, Werribee Campus, Melbourne, VIC 8001, Australia
XiaoXia Luo
Affiliation:
Advanced Food Systems Research Unit, College of Health and Biomedicine, PO Box 14428, Victoria University, Werribee Campus, Melbourne, VIC 8001, Australia
Todor Vasiljevic*
Affiliation:
Advanced Food Systems Research Unit, College of Health and Biomedicine, PO Box 14428, Victoria University, Werribee Campus, Melbourne, VIC 8001, Australia
*
*For correspondence; e-mail: [email protected]
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Abstract

Modulating conditions during ultrafiltration of skim milk appears to be a feasible strategy to obtain milk protein concentrates (MPC) with tailored functionalities. Adjustment of pH and process temperature attenuated properties of casein micelle resulting in enhanced emulsification capacity. Additional pre-treatment options such as addition of calcium chelators can further impact on the functionality of MPC by modifying the calcium distribution and casein micelle integrity. The objective of the project was to establish effects of pre-treating skim milk with calcium chelators (EDTA or citrate) in concentrations between 10 to 30 mm prior to UF on the physical properties of the feed, corresponding retentates and dried MPC, including particle size, zeta potential and calcium distribution in skim milk and the corresponding retentates, as well as the physical functionalities such as solubility, heat stability and emulsifying properties. Addition of calcium chelators (EDTA or citrate), at levels 20–30 mm concentrations reduced casein micelle size as well as total, soluble and ionic calcium contents that resulted in MPC with enhanced solubility and heat stability. The emulsion capacity was, however, improved only with EDTA at 10 mm concentration. The enhanced functionality is attributed to the reduced particle size resulting from the removal of calcium from the retentate that could modify micellar casein to an extent sufficient to cause such improvements.

Keywords

MPCchelatorsultrafiltrationcalciumfunctionality
Type
Research Article
Information
Journal of Dairy Research , Volume 84 , Issue 4 , November 2017 , pp. 471 - 478
Copyright
Copyright © Hannah Research Foundation 2017 

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References

Anema, SG, Pinder, DN, Hunter, RJ & Hemar, Y 2006 Effects of storage temperature on the solubility of milk protein concentrate (MPC85). Food Hydrocolloids 20 386393 Google Scholar
Augustin, MA & Clarke, PT 1990 Effect of added salts on the heat stability of recombined concentrated milk. Journal of Dairy Research 57 213226 CrossRefGoogle Scholar
Dalgleish, DG & Law, AJR 1988 pH-induced dissociation of bovine casein micelles. I. Analysis of liberated caseins. Journal of Dairy Research 55 529538 Google Scholar
de Kort, E, Minor, M, Snoeren, T, Hooijdonk, T & van der Linden, E 2009 Calcium binding capacity of organic and inorganic ortho- and polyphosphates. Dairy Science and Technology 89 283299 Google Scholar
de Kort, E, Minor, M, Snoeren, T, Hooijdonk, T & van der Linden, E 2011 Effect of calcium chelators on physical changes in casein micelles in concentrated micellar casein solutions. International Dairy Journal 21 907913 CrossRefGoogle Scholar
de Kort, E, Minor, M, Snoeren, T, Hooijdonk, T & van der Linden, E 2012 Effect of calcium chelators on heat coagulation and heat induced changes of concentrated micellar casein solutions: the role of calcium-ion activity and micellar integrity. International Dairy Journal 26 112119 CrossRefGoogle Scholar
Dickinson, E & Golding, M 1997 Depletion flocculation of emulsions containing unadsorbed sodium caseinate. Food Hydrocolloids 11 1318 Google Scholar
Dimitreli, G & Thomareis, AS 2009 Instrumental textural and viscoelastic properties of processed cheese as affected by emulsifying salts and in relation to its apparent viscosity. International Journal of Food Properties 12 261275 Google Scholar
El-Bakry, M, Duggan, E, O'Riordan, ED & O'Sullivan, M 2011 Casein hydration and fat emulsification during manufacture of imitation cheese, and effects of emulsifying salts reduction. Journal of Food Engineering 103 179187 CrossRefGoogle Scholar
Farrell, HM Jr, Brown, EM & Malin, EL 2013 Higher order structures of the caseins: a paradox? In Advanced Dairy Chemistry: Volume 1A: Proteins: Basic Aspects, 4th edition, pp. 161184 (Eds McSweeney, PLH & Fox, PF). Boston: Springer US.Google Scholar
Gaucheron, F 2005 The minerals of milk. Reproduction Nutrition Development 45 473483 Google Scholar
Griffin, MCA, Lyster, RLJ & Price, JC 1988 The disaggregation of calcium depleted casein micelles. European Journal of Biochemistry 174 339343 Google Scholar
Harwalkar, VR 1982 Age gelation of sterilised milks. In Developments in Dairy Chemistry – 1 Proteins, pp. 229269 (Ed. Fox, PF) London, UK: Elsevier Applied Science Publishers Google Scholar
Havea, P 2006 Protein interaction in milk protein concentrate powders. International Dairy Journal 16 415422 Google Scholar
Holt, C 1985 The milk salts: their secretion, concentrations and physical chemistry. In Development in Dairy Chemistry-3: Lactose and Minor Constituents, pp. 143181 (Ed. Fox, PF). London, UK: Elsevier Applied Science Publishers Google Scholar
Holt, C 1992 Structure and stability of bovine casein micelles. In Advances in Protein Chemistry, pp. 63151 (Ed. Fox, PF). London, UK: Elsevier Applied Science Publishers Google Scholar
Huppertz, T, Gazi, I, Luyten, H, Nieuwenhuijse, H, Alting, A & Schokker, E 2017 Hydration of casein micelles and caseinates: implications for casein micelle structure. International Dairy Journal, In pressGoogle Scholar
Kaliappan, S & Lucey, JA 2011 Influence of mixtures of calcium−chelating salt on the physicochemical properties of casein micelles. Journal of Dairy Science 94 42554263 CrossRefGoogle Scholar
Keowmaneechai, E & McClements, DJ 2002 Influence of EDTA and citrate on physicochemical properties of whey protein−stability oil-in water emulsions containing CaCl2 . Journal of Agricultural and Food Chemistry 50 71457153 Google Scholar
Kim, J & Kramer, TA 2006 Improved orthokinetic coagulation model for fractal colloids: aggregation and breakup. Chemical Engineering Science 61 4553 Google Scholar
Luo, X, Ramchandran, L & Vasiljevic, T 2015 Lower ultrafiltration temperature improves membrane performance and emulsifying properties of milk protein concentrates. Dairy Science & Technology 95 1531 Google Scholar
Luo, X, Vasiljevic, T & Ramchandran, L 2016 Effect of adjusted pH prior to ultrafiltration of skim milk on membrane performance and physical functionality of milk protein concentrate. Journal of Dairy Science 99 10831094 Google Scholar
McIntyre, I, O'Sullivan, M & O'Riordan, D 2016 Effects of calcium chelators on calcium distribution and protein solubility in rennet casein dispersions. Food Chemistry 197 233239 Google Scholar
McMahon, DJ & Oommen, BS 2008 Supramolecular structure of the casein micelle. Journal of Dairy Science 91 17091721 Google Scholar
McMahon, DJ, Du, H, McManus, WR & Larsen, KM 2009 Microstructural changes in casein supramolecules during acidification of skim milk. Journal of Dairy Science 92 58545867 Google Scholar
Mekmene, O, Le Graet, Y & Gaucheron, F 2009 A model for predicting salt equilibria in milk and mineral-enriched milks. Food Chemistry 116 233239 Google Scholar
Mimouni, A, Deeth, HC, Whittaker, AK, Gidley, MJ & Bhandari, BR 2010 Rehydration of high-protein-containing dairy powder: slow- and fast-dissolving components and storage effects. Dairy Science & Technology 90 335344 Google Scholar
Mizuno, R & Lucey, JA 2005 Effects of emulsifying salts on the turbidity and calcium-phosphateprotein interactions in casein micelles. Journal of Dairy Science 88 30703078 Google Scholar
Odagiri, S & Nickerson, TA 1964 Complexing of calcium by hexametaphosphate, oxalate, citrate, and EDTA in milk. I. Effects of complexing agents of turbidity and rennet coagulation. Journal of Dairy Science 47 13061309 CrossRefGoogle Scholar
Panouille, M, Nicolai, T & Durand, D 2004 Heat induced aggregation and gelation of casein submicelles. International Dairy Journal 14 297303 CrossRefGoogle Scholar
Pitkowski, A, Nicolai, T & Durand, D 2008 Scattering and turbidity study of the dissociation of casein by calcium chelation. Biomacromolecules 9 369375 Google Scholar
Sikand, V, Tong, PS, Vink, S & Roy, S 2016 Physicochemical properties of skim milk powders prepared with the addition of mineral chelators. Journal of Dairy Science 99 41464153 CrossRefGoogle ScholarPubMed
Singh, H, Creamer, LK & Newstead, DF 1995 Heat stability of concentrated milk. In Heat-Induced Changes in Milk, pp. 256278 (Ed. Fox, PF). Brussels, Belgium: International Dairy Federation Google Scholar
Sweetsur, AWM & Muir, DD 1980 The use of permitted additives and heat treatment to optimize the heat stability of skim milk and concentrated skim milk. Journal of Dairy Technology 33 101105 Google Scholar
Udabage, P, Mckinnon, IR & Augustin, MA 2000 Mineral and casein equilibria in milk: effect of added salts and calcium-chelating agents. Journal of Dairy Research 67 361370 Google Scholar
Udabage, P, Mckinnon, IR & Augustin, MA 2001 Effect of mineral salts and calcium chelating agents on the gelation of renneted skim milk. Journal of Dairy Science 84 15691574 Google Scholar
Udabage, P, McKinnon, IR & Augustin, MA 2003 The use of sedimentation field flow fractionation and photon correlation spectroscopy in the characterization of casein micelles. Journal of Dairy Research 70 453459 Google Scholar
Upreti, P, Buhlmann, P & Metzger, LE 2006 Influence of calcium and phosphorus, lactose and salt-to moisture ratio on cheddar cheese quality: pH buffering properties of cheese. Journal of Dairy Science 89 938950 Google Scholar
Walstra, P 2003 Physical Chemistry of Foods. New York: Marcel Dekker Google Scholar
Ye, A 2011 Functional properties of milk protein concentrates: emulsifying properties, adsorption and stability of emulsions. International of Dairy Journal 21 1420 Google Scholar