Hostname: page-component-78c5997874-fbnjt Total loading time: 0 Render date: 2024-11-10T13:01:57.521Z Has data issue: false hasContentIssue false
  • English
  • Français

The influence of alkaline earth metal equilibria on the rheological, melting and textural properties of Cheddar cheese

Published online by Cambridge University Press:  15 October 2013

Darren R Cooke  and
Paul LH McSweeney
Darren R Cooke
Affiliation:
School of Food and Nutritional Sciences, University College Cork, Cork, Ireland
Paul LH McSweeney*
Affiliation:
School of Food and Nutritional Sciences, University College Cork, Cork, Ireland
*
*For correspondence; e-mail: p.mcsweeney@ucc.ie
Get access Rights & Permissions [Opens in a new window]

Abstract

The total calcium content of cheese, along with changes in the equilibrium between soluble and casein (CN)-bound calcium during ripening can have a major impact on its rheological, functional and textural properties; however, little is known about the effect of other alkaline earth metals. NaCl was partially substituted with MgCl2 or SrCl2 (8·7 and 11·4 g/kg curd, respectively) at the salting stage of cheesemaking to study their effects on cheese. Three cheeses were produced: Mg supplemented (+Mg), Sr supplemented (+Sr) and a control Cheddar cheese. Ca, Mg and Sr contents of cheese and expressible serum obtained therefrom were determined by atomic absorption spectroscopy. Addition of Mg2+ or Sr2+ had no effect on % moisture, protein, fat and extent of proteolysis. A proportion of the added Mg2+ and Sr2+ became CN-bound. The level of CN-bound Mg was higher in the +Mg cheese than the control throughout ripening. The level of CN-bound Ca and Mg decreased during ripening in all cheeses, as did % CN-bound Sr in the +Sr cheese. The presence of Sr2+ increased % CN-bound Ca and Mg at a number of ripening times. Adding Mg2+ had no effect on % CN-bound Ca. The +Sr cheese exhibited a higher G′ at 70 °C and a lower LTmax than the control and +Mg cheeses throughout ripening. The +Sr cheese had significantly lower meltability compared with the control and +Mg cheeses after 2 months of ripening. Hardness values of the +Sr cheese were higher at week 2 than the +Mg and control cheeses. Addition of Mg2+ did not influence the physical properties of cheese. Supplementing cheese with Sr appeared to have effects analogous to those previously reported for increasing Ca content. Sr2+ may form and/or modify nanocluster crosslinks causing an increase in the strength of the para-casein matrix.

Keywords

Calcium equilibriumcolloidal calcium phosphateCheddar cheeserheology
Type
Research Article
Information
Journal of Dairy Research , Volume 80 , Issue 4 , November 2013 , pp. 418 - 428
Copyright
Copyright © Proprietors of Journal of Dairy Research 2013 

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

Altan, A, Turhan, M & Gunasekaran, S 2005 Short communication: comparison of covered and uncovered schreiber test for cheese meltability evaluation. Journal of Dairy Science 88 857861Google Scholar
Bourne, MC 1978 Texture profile analysis. Food Technology 32 6266, 72Google Scholar
Brickley, CA, Lucey, JA & McSweeney, PLH 2009 Effect of the addition of trisodium citrate and calcium chloride during salting on the rheological and textural properties of Cheddar-style cheese during ripening. International Journal of Dairy Technology 62 527534Google Scholar
Creamer, LK & Olson, NF 1982 Rheological evaluation of maturing Cheddar cheese. Journal of Food Science 47 631636, 646Google Scholar
Cross, KJ, Huq, NL, Palamara, JE, Perich, JW & Reynolds, EC 2005 Physicochemical characterization of casein phosphopeptide-amorphous calcium phosphate nanocomplexes. Journal of Biological Chemistry 280 1536215369CrossRefGoogle ScholarPubMed
Dickson, IR & Perkins, DJ 1971 Studies on interactions between purified bovine caseins and alkaline-earth-metal ions. Biochemical Journal 124 235240Google Scholar
Fox, PF 1963 Potentiometric determination of salt in cheese. Journal of Dairy Science 46 744745Google Scholar
Gaucheron, F 2005 The minerals of milk. Reproduction Nutrition Development 45 473483Google Scholar
Gaucheron, F, Le Graet, Y, Boyaval, E & Piot, M 1997 Binding of cations to casein molecules: importance of physicochemical conditions. Milchwissenschaft 52 322327Google Scholar
Hassan, A, Johnson, ME & Lucey, JA 2004 Changes in the proportions of soluble and insoluble calcium during the ripening of Cheddar cheese. Journal of Dairy Science 87 854862Google Scholar
Holt, C 2004 An equilibrium thermodynamic model of the sequestration of calcium phosphate by casein micelles and its application to the calculation of the partition of salts in milk. European Biophysics Journal with Biophysics Letters 33 421434Google Scholar
Horne, DS 1998 Casein interactions: casting light on the black boxes, the structure in dairy products. International Dairy Journal 8 171177Google Scholar
IDF 1982 Cheese and Processed Cheese. Determination of the Total Solids Content. Brussels, Belgium: International Dairy Federation. Standard No. 4aGoogle Scholar
IDF 1986 Determination of the Nitrogen Content (Kjeldahl method) and Calculation of Crude Protein Content. Brussels, Belgium: International Dairy Federation. Standard No. 28aGoogle Scholar
IDF 2007 Milk and Milk Products – Determination of Calcium, Sodium, Potassium and Magnesium Contents – Atomic Absorption Spectrometric Method. Brussels, Belgium: International Dairy Federation. Standard No. 119Google Scholar
IIRS 1955 Determination of the Percentage of Fat in Cheese. Dublin, Ireland: Institute for Industrial Research and Standards. Irish Standard No. 69Google Scholar
Lee, MR, Johnson, ME & Lucey, JA 2005 Impact of modifications in acid development on the insoluble calcium content and rheological properties of Cheddar cheese. Journal of Dairy Science 88 37983809Google Scholar
Lee, MR, Johnson, ME, Govindasamy-Lucey, S, Jaeggi, JJ & Lucey, JA 2010 Insoluble calcium content and rheological properties of Colby cheese during ripening. Journal of Dairy Science 93 18441853Google Scholar
Lucey, JA & Fox, PF 1993 Importance of calcium and phosphate in cheese manufacture – a review. Journal of Dairy Science 76 17141724Google Scholar
Lucey, JA & Horne, DS 2009 Milk salts: technological significance. In Advanced Dairy Chemistry, Vol 3, pp. 351389 (Eds McSweeney, PLH & Fox, PF). New York: SpringerGoogle Scholar
Lucey, JA, Johnson, ME & Horne, DS 2003 Invited review: perspectives on the basis of the rheology and texture properties of cheese. Journal of Dairy Science 86 27252743Google Scholar
Lucey, JA, Mishra, R, Hassan, A & Johnson, ME 2005 Rheological and calcium equilibrium changes during the ripening of Cheddar cheese. International Dairy Journal 15 645653Google Scholar
Morris, HA, Holt, C, Brooker, BE, Banks, JM & Manson, W 1988 Inorganic constituents of cheese – analysis of juice from a one-month-old Cheddar cheese and the use of light and electron-microscopy to characterize the crystalline phases. Journal of Dairy Research 55 255268Google Scholar
O'Mahony, JA, Lucey, JA & McSweeney, PLH 2005 Chymosin-mediated proteolysis, calcium solubilization, and texture development during the ripening of Cheddar cheese. Journal of Dairy Science 88 31013114Google Scholar
O'Mahony, JA, McSweeney, PLH & Lucey, JA 2006 A model system for studying the effects of colloidal calcium phosphate concentration on the rheological properties of Cheddar cheese. Journal of Dairy Science 89 892904Google Scholar
Pastorino, AJ, Ricks, NP, Hansen, CL & McMahon, DJ 2003 Effect of calcium and water injection on structure-function relationships of cheese. Journal of Dairy Science 86 105113Google Scholar
Philippe, M, Gaucheron, F, Le Graet, Y, Michel, F & Garem, A 2003 Physicochemical characterization of calcium-supplemented skim milk. Lait 83 4559CrossRefGoogle Scholar
Philippe, M, Le Graet, Y & Gaucheron, F 2005 The effects of different cations on the physicochemical characteristics of casein micelles. Food Chemistry 90 673683Google Scholar
Rosskopfova, O, Galambos, M & Rajec, P 2011 Distribution of strontium in milk component. Journal of Radioanalytical and Nuclear Chemistry 290 601606Google Scholar
Udayarajan, CT, Lucey, JA & Horne, DS 2005 Use of Fourier transform mechanical spectroscopy to study the melting behavior of cheese. Journal of Texture Studies 36 489515Google Scholar
Wang, X & Ye, J 2008 Variation of crystal structure of hydroxyapatite in calcium phosphate cement by the substitution of strontium ions. Journal of Materials Science: Materials in Medicine 19 11831186Google Scholar
Zhang, ZP & Aoki, T 1995 Effect of alkaline earth metals on the crosslinking of casein by micellar calcium phosphate. Journal of Dairy Science 78 16651672Google Scholar