New technology for the production of novel protein-rich fibrous structures
Both health and sustainability are drivers for the increased interest in the creation of novel foods comprising a high protein content. The key challenge is the formation of an attractive, stable and palatable food texture, which is mainly determined by the food structure. In this research, new processing routes based on flow are explored to create innovative protein-rich structures (exceeding 10%), and in parallel, insight is gained in the relevant mechanisms of structure formation.
Dense dispersions of sodium caseinate and calcium caseinate, which are derived from milk, were mixed in a conventional mixer and sheared in an in house developed shear cell device. After mixing dense (sodium or calcium) caseinate dispersions, homogenous structures were obtained of which the properties were determined by the dispersed phase added, in this case palm fat. Shearing of dense calcium caseinate dispersions in combination with solidification using the enzyme transglutaminase resulted in completely different structures; highly fibrous structures were produced, which may serve as a basis for the creation of meat analogs. In contrast, after treating dense sodium caseinate dispersions using this novel structuring process, homogenous structures were obtained. It appeared that the intrinsic properties of protein dispersions are important for the formation of fibrous structures using well-defined flow. Based on the differences in performance between the two types of caseinates, tools and parameters can be derived to optimize and control the formation of fibrous products.
In conclusion, the development of equipment that is dedicated to structure food ingredients is promising for the creation of novel foods on the one hand, and for gaining scientific understanding of structure formation on the other hand.
Title thesis: "Flow-induced structuring of dense protein dispersions"