Litcius/Paper detail

Polyphenol-stabilized coacervates for enzyme-triggered drug delivery

Wonjun Yim, Zhicheng Jin, Yu‐Ci Chang, Carlos Brambila, Matthew N. Creyer, Chuxuan Ling, Tengyu He, Yi Li, Maurice Retout, William F. Penny, Jiajing Zhou, Jesse V. Jokerst

2024Nature Communications42 citationsDOIOpen Access PDF

Abstract

Stability issues in membrane-free coacervates have been addressed with coating strategies, but these approaches often compromise the permeability of the coacervate. Here we report a facile approach to maintain both stability and permeability using tannic acid and then demonstrate the value of this approach in enzyme-triggered drug release. First, we develop size-tunable coacervates via self-assembly of heparin glycosaminoglycan with tyrosine and arginine-based peptides. A thrombin-recognition site within the peptide building block results in heparin release upon thrombin proteolysis. Notably, polyphenols are integrated within the nano-coacervates to improve stability in biofluids. Phenolic crosslinking at the liquid-liquid interface enables nano-coacervates to maintain exceptional structural integrity across various environments. We discover a pivotal polyphenol threshold for preserving enzymatic activity alongside enhanced stability. The disassembly rate of the nano-coacervates increases as a function of thrombin activity, thus preventing a coagulation cascade. This polyphenol-based approach not only improves stability but also opens the way for applications in biomedicine, protease sensing, and bio-responsive drug delivery.

Topics & Concepts

CoacervateDrug deliveryChemistryThrombinProteasePolyphenolBiochemistryEnzymeAntioxidantBiologyOrganic chemistryPlateletImmunologyPolymer Surface Interaction StudiesElectrospun Nanofibers in Biomedical ApplicationsPickering emulsions and particle stabilization