Gelation and rheological properties of ultrasound-extracted faba bean protein: A comparative study with commercial plant proteins
Abraham Badjona, Beatrice Cherono, Robert Bradshaw, Bipro Dubey
Abstract
Environmental and consumer concerns about dependence on animal-based proteins have sparked interest in sustainable alternatives, with plant-based biopolymers emerging as a promising substitute. The present study comprehensively assessed and compared the rheological and structural properties of commercial plant proteins (pea and soy) and ultrasound-extracted faba bean protein (US-FBP) to provide an extensive overview of their comparative characteristics. At 12 % protein concentration, the exponent n approached zero for soy ( n = 0.32) and pea (n = 0.56), whereas it remained higher for faba bean protein ( n = 0.69) after fitting a viscosity curve to power law model. The least gelation concentration was observed to be 10 % for US-FBP, soy and pea protein. Additionally, in situ gelation indicated strong gel formation by soy (loss factor = 0.19) compared to US-FBP (0.24) and pea protein (0.37). Secondary structure analysis using FTIR spectroscopy and water/oil absorption capacity measurements revealed significant differences between these proteins. This opens interesting possibilities for using a wide range of plant proteins in the design, formulation, and customization of next-generation plant-based foods. • US-FBP and commercial plant proteins viscosity showed different shear thinning behavior. • In situ gelation showed major differences in gel formation mechanism. • Gel strength, water holding capacity profile and viscoelastic properties of US-FBP were different from commercial proteins. • Major structural differences were observed between lab extracted proteins and commercial proteins.