New insights into protein-polysaccharide complex coacervation: Dynamics, molecular parameters, and applications

For more than a decade, the discovery of liquid-liquid phase separation within living organisms has prompted colloid scientists to understand the connection between coacervate functionality, phase behavior, and dynamics at a multidisciplinary level. Although the protein-polysaccharide was the first system in which the coacervation phenomenon was discovered and is widely used in food systems, the phase state and relaxation dynamics of protein-polysaccharide complex coacervates (PPCC) have rarely been discussed previously. Consequently, this review aims to unravel the relationship between PPCC dynamics, thermodynamics, molecular architecture, applications, and phase states in past studies. Looking ahead, solving the way molecular architecture spreads to macro-functionality, that is, establishing the relationship between molecular architecture-dynamics-application, will catalyze novel advancements in PPCC research within the field of foods and biomaterials. The discovery of liquid-liquid phase separation in living organisms has prompted colloid scientists to understand the connection between the functionality of coacervates, their phase state, and dynamics at multiple time and spatial scales. Therefore, this review attempts to unravel the relationship between dynamics, thermodynamics, molecular architecture, applications, and phase states of protein-polysaccharide complex coacervation (PPCC). Solving the way molecular architecture spreads to macro-functionality, that is, establishing the relationship between molecular architecture-dynamics-application, will contribute to new developments of PPCC in the field of foods and biomaterials.image

Automated summary

This review examines the phase behavior and relaxation dynamics of protein-polysaccharide complex coacervation (PPCC), and explores the relationship between PPCC dynamics, thermodynamics, molecular architecture, applications, and phase states. Advancements in understanding the connection between molecular architecture-dynamics-application will contribute to new developments in the field of PPCC for foods and biomaterials.