Soft matter approach for creating novel protein hydrogels using fractal whey protein assemblies as building blocks

Abstract

In this study, mesoscopic sized fractal assembly (FA) particles were prepared using whey protein isolate; the cold-set gelation properties of FA particles were investigated in-depth. Two types of FA particles (FA-62 and FA-90) with different mean sizes were synthesized through controlled thermal treatment of whey protein solutions at two concentrations (62 g/L and 90 g/L). Particle characteristics e.g. hydrodynamic radius, ζ-potential and surface hydrophobicity were dependent on pH and structure of FA. Transmission electron microscopy (TEM) observation confirmed the fractal morphology and small-angle X-ray scattering (SAXS) analysis suggested an internal fractal structure for the obtained FA particles. Eight cold-set FA protein gels (2 % w/v) were manufactured by controlling two gelling factors at two levels: pH (5.8 and 7.0) and Ca2+ content (5 mM and 10 mM). Rheological characteristics in the large amplitude oscillatory shear regime revealed that pH 7.0 gels were softer and elastic while pH 5.8 gels were harder and brittle. Rheology Pipkin diagrams demonstrated that the strain softening/stiffening and the shear-thinning/thickening behaviors may be fine-tuned by manipulating the key gelation factors: e.g. FA structure, pH, and Ca2+. The entrainment speed-dependent friction coefficient curves showed that at an intermediate velocity regime (6–250 mm s−1), FA-90 particles induced hydrogels had superior lubrication effect compared to FA-62 gels. This work demonstrated a food structure design approach regarding tuning texture and lubrication properties of protein gels without changing protein content and protein composition. The optimized protein hydrogels may be used as texturizer for “cleaner label” food formulas and/or as delivery system for carrying micronutrients.