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Foams and surface rheological properties of β-casein, gliadin and glycinin
Authors:Martin A. Bos   Bertus Dunnewind  Ton van Vliet
Affiliation:

a Wageningen Centre for Food Sciences, Department of Food Science, C/o Wageningen University, Food Physics Group, P.O. Box 8129, EV, Wageningen 6700, The Netherlands

b TNO Nutrition and Food Research Institute, P.O. Box 360, AJ, Zeist 3700, The Netherlands

Abstract:
Interfacial rheological properties and their suitability for foam production and stability of two vegetable proteins were studied and compared to β-casein. Proteins used ranged from flexible to rigid/globular in the order of β-casein, gliadin and soy glycinin. Experiments were performed at pH 6.7. Network forming properties were characterised by the surface dilational modulus (determined with the ring trough) and the critical falling film length (Lstill) at which a stagnant protein film will break. Gliadin had the highest dilational modulus, followed by glycinin and β-casein, whereas glycinin formed the strongest film against fracture in the overflowing cylinder. The rate of decrease in the surface tension was studied at the air–water (Wilhelmy plate method) and the oil–water interface (bursting membrane) and the dynamic surface tension during compression and expansion in the caterpillar. Gliadin had the lowest equilibrium interfacial tensions and β-casein the lowest dynamic surface tension during expansion. Hardly any foam could be formed at a concentration of 0.1 g/l by shaking. At a concentration of 1.4 g/l most foam was formed by β-casein, followed by gliadin and glycinin. It seems that in the first place the rate of adsorption is important for foam formation. For the vegetable proteins, adsorption was slow. This resulted in lower foamability, especially for glycinin.
Keywords:Foam formation   Foam stability   Surface rheology   Gliadin   Glycinin   β-Casein
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