Punsandani Udabage scite author profile

S. We have investigated the effects of adding a range of mineral salts and calcium-chelating agents on the distribution of casein and minerals between the nonpelleted and pelleted phases of milk obtained upon centrifugation at 78 000 g for 90 min. Adding CaCl # or mixtures of NaH # PO % and Na # HPO % to reconstituted skim milk (90 g milk solids\kg) at pH 6n65 increased both pelleted casein and pelleted calcium phosphate. Opposite effects were obtained by adding citrate or EDTA. The change in pelleted calcium phosphate was not simply related to casein release from the micelle. Upon adding 5 mmol EDTA\kg milk, 20 % of the pelleted Ca, 22 % of the pelleted phosphate and 5 % of the micellar casein were removed. Increasing the concentration of EDTA to 10 mmol\kg milk decreased the pelleted Ca by 44 % and the pelleted phosphate by 46 %, and caused 30 % of the micellar casein to be released. The effects of adding phosphate, citrate or EDTA at pH 6n65, followed by the addition of CaCl # , demonstrated the reversibility of the dissolution and formation of the micellar calcium phosphate. There were limits to this reversibility that were related to the amount of colloidal calcium phosphate removed from the casein micelles. Adding CaCl # to milk containing 20 mmol EDTA or 30 mmol citrate\kg milk did not result in complete reformation of casein micelles. Lightscattering experiments confirmed that the dissolution of moderate amounts of colloidal calcium phosphate had little effect on micellar size and were reversible, while the dissolution of larger amounts of colloidal calcium phosphate resulted in large reductions in micellar size and was irreversible.

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Effects of Mineral Salts and Calcium Chelating Agents on the Gelation of Renneted Skim Milk

Udabage

McKinnon

Augustin

2001

Journal of Dairy Science

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The effects of adding CaCl2, orthophosphate, citrate, EDTA, or a mixture of these, to reconstituted skim milk (90 g of solids/kg solution) on the gelation of renneted milk were mediated by changes in Ca2+ activity and the casein micelle. At pH 6.65, the addition of citrate or EDTA, which removed more than 33% of the original colloidal calcium phosphate with the accompanying release of 20% casein from the micelle, completely inhibited gelation. Reformation of the depleted colloidal calcium phosphate and casein in the micelle, by the addition of CaCl2, removed this inhibition. When the minimum requirements for colloidal calcium phosphate and casein in the micelle were met, the coagulation time decreased with increasing Ca2+ activity, leveling off at high Ca2+ activity. The storage modulus of renneted gels, measured at 3 h, increased with increasing colloidal calcium phosphate content of micelles up to a level at which it was approximately 130% of the original colloidal calcium phosphate in the micelles. Further increases in colloidal calcium phosphate by the addition of CaCl2, orthophosphate, or mixtures of these, which did not change the proportion of casein in the micelle, decreased the storage modulus. The gelation of the renneted milk was influenced by Ca2+ activity, the amounts of colloidal calcium phosphate, and casein within the micelle, with the effects of colloidal calcium phosphate and casein within the micelle clearly dominating the storage modulus. These results are consistent with the model of Horne (Int. Dairy J. 8:171-177, 1998) which postulates that, following cleavage of the stabilizing K-casein hairs by rennet, the properties of the rennet gel are determined by the balance between the electrostatic and hydrophobic forces between casein micelles.

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FTIR investigation of spray-dried milk protein concentrate powders

Kher

Udabage

McKinnon

et al. 2007

Vibrational Spectroscopy

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Reconstitution properties of micellar casein powder: Effects of composition and storage

Schokker

Church

Mata

et al. 2011

International Dairy Journal

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Influence of Processing on Functionality of Milk and Dairy Proteins

Augustin

Udabage

2007

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Modified water solubility of milk protein concentrate powders through the application of static high pressure treatment

Udabage

Puvanenthiran

Yoo

et al. 2011

Journal of Dairy Research

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The effects of high pressure (HP) treatment (100-400 MPa at 10-60 °C) on the solubility of milk protein concentrate (MPC) powders were tested. The solubility, measured at 20 °C, of fresh MPC powders made with no HP treatment was 66%. It decreased by 10% when stored for 6 weeks at ambient temperature (~20 °C) and continued to decrease to less than 50% of its initial solubility after 12 months of storage. Of the combinations of pressure and heat used, a pressure of 200 MPa at 40 °C applied to the concentrate before spray drying was found to be the most beneficial for improved solubility of MPC powders. This combination of pressure/heat improved the initial cold water solubility to 85%. The solubility was maintained at this level after 6 weeks storage at ambient temperature and 85% of the initial solubility was preserved after 12 months. The improved solubility of MPC powders on manufacture and on storage are attributed to an altered surface composition arising from an increased concentration of non-micellar casein in the milk due to HP treatment prior to drying. The improved solubility of high protein powders (95% protein) made from blends of sodium caseinate and whey protein isolate compared with MPC powders (~85% protein) made from ultrafiltered/diafiltered milk confirmed the detrimental role of micellar casein on solubility. The results suggest that increasing the non-micellar casein content by HP treatment of milk or use of blends of sodium caseinate and whey proteins are strategies that may be used to obtain high protein milk powders with enhanced solubility.

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The use of sedimentation field flow fractionation and photon correlation spectroscopy in the characterization of casein micelles

Udabage

McKinnon

Augustin

2003

Journal of Dairy Research

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Sedimentation Field Flow Fractionation (SdFFF) was combined with Photon Correlation Spectroscopy (PCS), to characterize changes in the structure of the colloidal particles of reconstituted skim milk of diameter >50 nm (aggregates of casein and calcium phosphate known as casein micelles) with the changes in partitioning (with the addition of salt) of calcium (Ca), inorganic phosphate (Pi) and casein between the serum and colloidal phases of the milk. The number weighted particle size distributions are determined. These are well represented by a log-normal distribution. Methods are presented for estimating the relative contributions of scattering and absorbance to the SdFFF detector signal and for taking both into account when analysing SdFFF data. The values found for the effective density of the casein micelles were in good agreement with the literature and ranged from (1·06–1·08 g cm−3) according to the composition of micelles. The changes in the scattering intensity as determined by PCS correlated with the changes in the particle composition. Although the concentrations of colloidal calcium phosphate (CCP) (1·1–3·5 g/kg milk) and micellar casein (18·1–27·2 g/kg milk) varied considerably only small changes in the size distribution of particles >50 nm diameter were observed except for milk to which 30 mmol Pi+10 mmol Ca/kg milk had been added where the particle size distribution shows a swelling of the particles consistent with a lower than expected value for the particle density. These observations suggest that the micelles have the ability to both lose (depleted micelles) and accommodate (enriched micelles) more casein, calcium and inorganic phosphate in their interior, thus confirming the model of the micelles which postulates an open structure allowing freedom of movement of casein and small ions.

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The influence of milk composition on pH and calcium activity measured in situ during heat treatment of reconstituted skim milk

Chandrapala

McKinnon

Augustin

et al. 2010

Journal of Dairy Research

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The pH and calcium activity of reconstituted skim milk solutions (9-21% w/w milk solids non-fat) on heating and after cooling were studied as a function of milk pH prior to heating (pH 6.2-7.2 at 25 degrees C) and added calcium complexing agents (phosphate or EDTA). The pH decreased as the temperature was raised from 25 to 90 degrees C and the magnitude of the pH decrease was greater with increase in initial pH at 25 degrees C before heating or milk concentration. The pH decrease on heating from 25 to 90 degrees C in skim milk solutions with added calcium complexing agents was lower than that of milk without the addition of these salts. The calcium activity decreased on heating from 25 to 60 degrees C. The magnitude of the change decreased with increase in initial pH at 25 degrees C before heating and milk concentration. The decrease in calcium activity on heating from 25 to 60 degrees C for skim milk solutions with added calcium complexing agents was lower than that of milk solutions without the addition of calcium complexing agents. The changes in pH and calcium activity on heating milk were largely reversible after cooling the milk. The results suggested that the pH and calcium activity at high temperatures are a function of the milk composition. Knowledge of the initial pH prior to heating alone is not sufficient for predicting the changes that occur during heating.

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