Impact of Modifications in Acid Development on the Insoluble Calcium Content and Rheological Properties of Cheddar Cheese

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Impact of Modifications in Acid Development on the Insoluble Calcium Content and Rheological Properties of Cheddar Cheese

M.-R. Lee¹, M. E. Johnson² and J. A. Lucey¹

¹ Department of Food Science, and
² Wisconsin Center for Dairy Research, University of Wisconsin-Madison, Madison 53706

Corresponding author: J. A. Lucey; e-mail: jalucey{at}wisc.edu.

Cheddar cheese was made from milk concentrated by reverse osmosis(RO) to increase the lactose content or from whole milk. Manufacturingparameters (pH at coagulant addition, whey drainage, and milling)were altered to produce cheeses with different total Ca contentsand low pH values (i.e., <5.0) during ripening. The concentrationof insoluble (INSOL) Ca in cheese was measured by cheese juicemethod, buffering by acid-base titration, rheological propertiesby small amplitude oscillatory rheometry, and melting propertiesby UW-Melt Profiler. The INSOL Ca content as a percentage oftotal Ca in all cheeses rapidly decreased during the first weekof aging but surprisingly did not decrease below approximately41% even in cheeses with a very low pH (e.g., ~4.7). InsolubleCa content in cheese was positively correlated (r = 0.79) withcheese pH in both RO and nonRO treatments, reflecting the keyrole of pH and acid development in altering the extent of solubilizationof INSOL Ca. The INSOL Ca content in cheese was positively correlatedwith the maximum loss tangent value from the rheology test andthe degree of flow from the UW-Melt Profiler. When cheeses withpH <5.0 where heated in the rheometer the loss tangent valuesremained low (<0.5), which coincided with limited meltabilityof Cheddar cheeses. We believe that this lack of meltabilitywas due to the dominant effects of reduced electrostatic repulsionbetween casein particles at low pH values (<5.0).

Key Words: calcium • colloidal calcium phosphate • cheese functionality • casein interaction

Abbreviation key: CCP = colloidal calcium phosphate, DOF = degree of flow, G' = storage modulus, G'' = loss modulus, HPHM = high-pH method, INSOL = insoluble, LPHM = low-pH method, LT = loss tangent, LT_max = loss tangent maximum, NONRO = whole milk without reverse osmosis, pH4.6SN = pH 4.6 water-soluble nitrogen, RO = reverse osmosis, SAOR = small amplitude oscillatory rheology

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