Litcius/Paper detail

Metal–Phenolic Networks as Tunable Buffering Systems

Jingqu Chen, Shuaijun Pan, Jiajing Zhou, Robert Seidel, Sebastian Beyer, Zhixing Lin, Joseph J. Richardson, Frank Caruso

2021Chemistry of Materials52 citationsDOIOpen Access PDF

Abstract

The buffering effects displayed by pH-responsive polymers have recently gained attention in diverse fields such as nanomedicine and water treatment. However, creating libraries of modular and versatile polymers that can be readily integrated within existing materials remains challenging, hence restricting applications inspired by their buffering capacity. Herein, we propose the use of metal–phenolic networks (MPNs) as tunable buffering systems and through mechanistic studies show that their buffering effects are driven by pH-responsive, multivalent metal–phenolic coordination. Owing to such supramolecular interactions, MPNs exhibit ∼twofold and fourfold higher buffering capacity than polyelectrolyte complexes and commercial buffer solutions, respectively. We demonstrate that the MPN buffering effects are retained after deposition onto solid supports, thereby allowing stabilization of aqueous environmental pH for 1 week. Moreover, by using different metals and ligands for the films, the endosomal escape capabilities of coated nanoparticles can be tuned, where higher buffering capacity leads to greater endosomal escape. This study forms a fundamental basis for developing future metal–organic buffering materials.

Topics & Concepts

Supramolecular chemistryNanotechnologyPolyelectrolyteMetalPolymerAqueous solutionNanomedicineModular designMaterials scienceNanoparticleMetal-organic frameworkChemistryCombinatorial chemistryComputer scienceOrganic chemistryMoleculeAdsorptionOperating systemPolymer Surface Interaction StudiesHydrogels: synthesis, properties, applicationsSupramolecular Self-Assembly in Materials
Metal–Phenolic Networks as Tunable Buffering Systems | Litcius