Pickering Emulsion Stabilized by Metal-Phenolic Architectures: A Straightforward In Situ Assembly Strategy

Interfacial self-assembly has been a powerful driving force for fabricating functional and therapeutic carriers in emulsion systems. Herein, we reported a straightforward metal-phenolic supramolecular architecture, directly absorbed and crosslinked at the surfaces of oil drops and acted as the regulator between the oil and water interface to stabilize the emulsion systems. The results showed that the diverse interfacial properties and emulsion stability were tuned by the kinds and concentrations of polyphenols as well as the ratios of polyphenols to metal ions. Concretely, the TA-Fe3+ (coordinated by tannin acid and Fe3+)- or EGCG-Fe3+ (coordinated by EGCG and Fe3+)-based solid particles exhibited an increasing amount of interfacial adsorption with an increase in both polyphenol and metal ion concentrations or ratios of Fe3+ to polyphenols, and as a consequence of which, the prepared corresponding emulsions displayed enhanced emulsion stability and diverse interfacial characteristics. The rheological measurement results also exhibited that there was an increasing trend in both G' and G'', with enhanced concentrations or ratios of Fe3+ to polyphenols. Generally, our study not only highlighted a straightforward strategy for the directly interfacial fabrication of emulsions to improve their stability but also advanced the understanding of broadening the application scope of the metal-phenolic networks.

Automated summary

The study utilized metal-phenolic supramolecular architecture to stabilize emulsion systems by directly absorbing and crosslinking on the surfaces of oil drops, with the properties of the emulsions being tuned by controlling the types and concentrations of polyphenols as well as the ratios of polyphenols to metal ions. Increasing concentrations or ratios of Fe3+ to polyphenols resulted in enhanced adsorption on the oil droplet surface, leading to improved emulsion stability.