Abstract
Abstract Skim milk was ultrasonicated for times up to 30 min either with or without temperature control. Ultrasonication (US) without temperature control resulted in the generation of considerable heat, with the milk reaching ∼ 95 °C within 15 min of treatment. The whey proteins were denatured. Changes to the casein micelle size were observed, with decreases during the early stages of US and increases (because of aggregation) on prolonged treatment. Significant κ-casein dissociated from the micelles. Acid gels prepared from these ultrasonicated samples increased in firmness (final G′) up to a maximum final G′ after ∼ 15 min of US, followed by a decrease from this maximum on prolonged treatment. US with temperature control demonstrated that the denaturation of the whey proteins was entirely due to the heat generated during US, although the casein micelle size was still reduced. Acid gels prepared from ultrasonicated skim milk in which the temperature remained below the denaturation temperature of the whey proteins had low final G′, although a small increase was observed with increasing US time. Acid gels prepared from the samples that were ultrasonicated at temperatures above the denaturation temperature of the whey proteins had higher final G′, which could reach values similar to those obtained by the conventional heating of milk. The results of this study indicate that, in skim milk, most of the effect of US can be related to the heat generated from the treatment, with US itself having only a small effect on the milk when the temperatures are controlled. Industrial relevance The control and the manipulation of the firmness of acid skim milk gels are important in many dairy food applications such as yoghurts and some types of cheese. US is an emerging technology that could be used to process skim milk for use in acid gelled products. This study has demonstrated that acid gel firmness can be substantially manipulated when skim milk is ultrasonically treated before acidification; however, most of the effect is due to the heat generated during US treatment. As the effects of US are similar to those obtained through conventional heating processes, and as US can control spoilage microorganisms, using US under controlled temperature conditions could be an alternative to conventional heating to give desired functional properties and storage stability to milk products. However, the temperature/denaturation/aggregation would need to be carefully controlled to minimize the detrimental effects of excessive heating.
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