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Lactose behaviour in the presence of lactic acid and calcium

Published online by Cambridge University Press:  07 September 2016

Rangani Wijayasinghe
Affiliation:
Advanced Food Systems Research Unit, College of Health and Biomedicine, Victoria University, Werribee, VIC 3030, Australia
Todor Vasiljevic
Affiliation:
Advanced Food Systems Research Unit, College of Health and Biomedicine, Victoria University, Werribee, VIC 3030, Australia
Jayani Chandrapala*
Affiliation:
Advanced Food Systems Research Unit, College of Health and Biomedicine, Victoria University, Werribee, VIC 3030, Australia
*
*For correspondence; e-mail: Janage.Chandrapala@vu.edu.au

Abstract

Physical properties of lactose appeared influenced by presence of lactic acid in the system. Some other components such as Ca may further attenuate lactose behaviour and impact its phase transition. A model-based study was thus implemented with varying concentrations of Ca (0·12, 0·072 or 0·035% w/w) and lactic acid (0·05, 0·2, 0·4 or 1% w/w) in establishing the effects of these two main acid whey constituents on lactose phase behaviour. Concentrated solutions (50% w/w) containing lactose, lactic acid and Ca were analysed for thermal behaviour and structural changes by Differential Scanning Colorimetry (DSC) and Fourier Transform Infrared Spectroscopy (FTIR), respectively. Presence of 1% (w/w) lactic acid and 0·12% (w/w) Ca in lactose solution significantly increased the evaporation enthalpy of water, delayed and increased the energy required for lactose crystallisation as compared to pure lactose. FTIR analysis indicated a strong hydration layer surrounding lactose molecules, restricting water mobility and/or inducing structural changes of lactose, hindering its crystallisation. The formation of calcium lactate, which restricts the diffusion of lactose molecules, is also partly responsible. It appears that Ca removal from acid whey may be a necessary step in improving the processability of acid whey.

Type
Research Article
Copyright
Copyright © Proprietors of Journal of Dairy Research 2016 

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References

Bhargava, A & Jelen, P 1996 Lactose solubility and crystal growth as affected by mineral impurities. Journal of Food Science 61 180184 CrossRefGoogle Scholar
Chandrapala, J, Duke, MC, Gray, SR, Zisu, B, Weeks, M, Palmer, M & Vasiljevic, T 2015a Properties of acid whey as a function of pH and temperature. Journal of Dairy Science 98 43524363 Google Scholar
Chandrapala, J, Duke, MC, Gray, SR, Weeks, M, Palmer, M & Vasiljevic, T 2015b Nanofiltration and nanodiafiltration of acid whey as a function of pH and temperature. Separation and Purification Technology 160 1827 Google Scholar
Charley, P & Saltman, P 1963 Chelation of calcium by lactose: its role in transport mechanisms. Science 139 12051206 CrossRefGoogle ScholarPubMed
Chiou, D, Langrish, TAG & Braham, R 2008 The effect of temperature on the crystallinity of lactose powders produced by spray drying. Journal of Food Engineering 86 288293 Google Scholar
Cook, WJ & Bugg, CE 1973 Calcium interactions with d-glucans: crystal structure of α, α-trehalose-calcium bromide monohydrate. Carbohydrate Research 31 265275 Google Scholar
de Wit, JN 2001 Lecturer's Handbook on Whey and Whey Products. Belgium: Publisher: European Whey Products Association Google Scholar
Ganzle, M, Haase, G & Jelen, P 2008 Lactose crystallization: hydrolysis and value added derivatives. International Dairy Journal 18 685694 Google Scholar
Gernigon, G, Baillon, F, Espitalier, F, Le Floch-Fouere, C, Schuck, P & Jeantet, R 2013 Effects of the addition of various minerals, proteins and salts of organic acids on the principal steps of α-lactose monohydrate crystallisation. International Dairy Journal 30 8895 CrossRefGoogle Scholar
Gosta, B 1995 Dairy Processing Handbook. Lund: Tetra Pak Processing Systems Google Scholar
Herrington, BL 1934a Some physico-chemical properties of lactose: I. The spontaneous crystallization of supersaturated solutions of lactose. Journal of Dairy Science 17 501518 Google Scholar
Herrington, BL 1934b Some physico–chemical properties of lactose: VI. The solubility of lactose in salt solutions; the isolation of a compound of lactose and calcium chloride. Journal of Dairy Science 17 805814 Google Scholar
Jelen, P & Coulter, ST 1973 Effects of certain salts and other whey substances on the growth of lactose crystals. Journal of Food Science 38 11861189 Google Scholar
Kirk, JH, Dann, SE & Blatchford, CG 2007 Lactose: a definitive guide to polymorph determination. International Journal of Pharmaceutics 334 103114 CrossRefGoogle ScholarPubMed
Lu, Y, Deng, G, Miao, F & Li, Z 2003 Sugar complexation with calcium ion. Crystal structure and FT-IR study of a hydrated calcium chloride complex of D-ribose. Journal of Inorganic Biochemistry 96 487492 Google Scholar
Maltini, E, Anese, M & Shtylla, I 1967 State diagram of some organic acid-water systems of interested in food. Cryo-Letters 18 263 Google Scholar
Mimouni, A, Schuck, P & Bouhallab, S 2005 Kinetics of lactose crystallization and crystal size as monitored by refractometry and laser light scattering: effect of proteins. Le Lait 85 253260 Google Scholar
Mimouni, A, Bouhallab, S, Famelart, MH, Naegele, D & Schuck, P 2007 The formation of calcium lactate crystals is responsible for concentrated acid whey thickening. Journal of Dairy Science 90 5765 CrossRefGoogle ScholarPubMed
Mullin, JW 1979 Crystal growth in pure and impure systems. In Industrial Crystallization, pp. 93103 (Eds Jancic, SJ & de Jong, EJ). New York: North-Holland Publishing Co. Google Scholar
Nguyen, M, Reynolds, N & Vigneswaran, S 2003 By-product recovery from cottage cheese production by nanofiltration. Journal of Cleaner Production 11 803807 Google Scholar
Omar, AE & Roos, YH 2007 Glass transition and crystallization behaviour of freeze-dried lactose–salt mixtures. LWT-Food Science and Technology 40 536543 Google Scholar
Panesar, PS, Kennedy, JF, Gandhi, DN & Bunko, K 2007 Bio-utilisation of whey for lactic acid production. Food Chemistry 105 114 CrossRefGoogle Scholar
Reid, SD & Fennema, RO 2008 Water and ice. In Fennema's Food Chemistry, 4th edition, pp. 1783 (Eds Damodaran, S, Parkin, LK & Fennema, RO). USA: Taylor & Francis group, LLC Google Scholar
Roos, Y & Karel, M 1990 Differential scanning calorimetry study of phase transitions affecting the quality of dehydrated raw materials. Biotechnology Progress 6 159163 Google Scholar
Sedlarik, V, Sáha, N, Kuritka, I, Emri, I & Sáha, P 2006 Modification of poly (vinyl alcohol) with lactose and calcium lactate: potential filler from dairy industry. Plastics, Rubber and Composites 35 355359 Google Scholar
Sharp, KA, Madam, B, Manas, E & Vanderkooi, JM 2001 Water structure changes induced by hydrophobic and polar solutes revealed by simulations and infrared spectroscopy. Journal of Chemical Physics 114 17911796 Google Scholar
Shrestha, AK, Adhikari, BP, Howes, TE & Bhandari, BR 2006 Effect of lactic acid on spray drying behaviour of acid-whey and study of their glass transition temperature. Journal of Food Science and Technology Nepal 2 5762 Google Scholar
Solis-Oba, M, Teniza-Garcia, O, Rojas-Lopez, M, Delgado-Macuil, R, Diaz-Reyes, J & Ruiz, R 2011 Application of infrared spectroscopy to the monitoring of lactose and protein from whey after ultra and nano filtration process. Journal of the Mexican Chemical Society 55 190193 Google Scholar
Vasiljevic, T & Jelen, P 1999 Temperature effect on behaviour of minerals during ultrafiltration of skim milk and acid whey. Milchwissenschaft Milk Science Intenational 54 243246 Google Scholar
Von Hippel, PH & Schleich, T 1969 The effects of neutral salts on the structure and conformational stability of macromolecules in solution. Structure and Stability of Biological Macromolecules 2 417574 Google Scholar
Wijayasinghe, R, Vasiljevic, T & Chandrapala, J 2015 Water-Lactose behaviour as a function of concentration and presence of lactic acid in lactose model systems. Journal of Dairy Science 98 85058514 Google Scholar
Yazdanpanah, N & Langrish, TAG 2011 Crystallization and drying of milk powder in a multiple-stage fluidized bed dryer. International Journal of Drying Technology 29 10461057 Google Scholar