Abstract
This study developed a synergistic approach combining enzymatic hydrolysis and heat-assisted pH-shifting to enhance the emulsification-related functionalities of soy protein isolate (SPI), in order to design plant-based molecular emulsifiers for applications in low-viscosity food emulsions requiring finely dispersed droplets. Trypsin outperformed pepsin at enhancing the emulsifying-related properties of SPI due to specifically cleaving peptide bonds, leading to more significant exposure of hydrophobic domains and disruption of protein aggregates. The subsequent alkaline pH-shifting (pH 10) further dissociated protein aggregates and improved the functional properties of SPI hydrolysates, while acidic pH-shifting (pH 2) caused substantial protein reaggregation and much reduced functionalities. Our results demonstrated that trypsin digestion followed by heat-assisted alkaline pH-shifting tailored SPI into high-performance molecular emulsifiers, capable of creating O/W emulsions with submicron-sized oil droplets ( D4,3 =0.593 μm) which exhibited excellent storage stability ( D4,3 =0.737 μm after 30 days), remarkable thermal resistance ( D4,3 =0.635 μm after 95 °C/60 min heating), and moderate freeze-thaw stability.