Mechanisms underlying the regulation of oil/water interface behavior by interfacial distribution of myofibrillar proteins and chitosan

A critical challenge in emulsified meat product lies in the suboptimal control of interfacial stability, which compromises product quality through the undesired separation of lipid phases. This study elucidated the mechanisms of myofibrillar protein (MP) and chitosan (CS) in monolayer (MP or CS), complex (MP/CS), and bilayer (CS-MP, MP-CS) interfacial distribution modes on oil/water interfacial behaviors and their impacts on emulsion stability and viscoelasticity. Results highlighted inherent defects of monolayers compared to complex and bilayer interfaces: MP monolayers, while anchoring the oil phase via hydrophobicity, exhibited insufficient long-term stability due to weak intermolecular interactions; CS monolayers demonstrated low adsorption efficiency, large droplet sizes, and viscous-dominated interfacial films, prone to structural collapse. In contrast, MP/CS composite interfaces formed dense membranes through electrostatic synergy, achieving optimal interfacial pressure (∼19.1 mN/m), viscoelastic moduli (E_d ∼40 mN/m, E_v ∼30 mN/m), and adsorption efficiency, significantly inhibiting droplet aggregation. Bilayer interfacial structures were constructed via bulk phase exchange and electrostatic self-assembly of MP and CS in interfacial rheology. CS-MP bilayer interfaces leveraged synergistic effects of MP inner hydrophobic anchorage and CS outer flexible chains, conferring long-term emulsion stability. MP-CS bilayer interfaces, however, were less stable due to insufficient CS inner layer hydrophobicity and loose interfacial adsorption. Multiscale characterization revealed that interfacial film thickness, molecular interactions, adsorption kinetics, and dilatational rheology in different MP and CS distribution modes directly governed macroscopic stability and rheological properties of emulsions. Findings provide theoretical insights for designing functional emulsions and regulating interfacial engineering in emulsified meat products.