HO/acid self-supplying double-layer electrospun nanofibers based on ZnO and FeO nanoparticles for efficient catalytic therapy of wound infection.

Catalytic therapy based on nanozymes is promising for the treatment of bacterial infections. However, its therapeutic efficacy is usually restricted by the limited amount of hydrogen peroxide and the weak acidic environment in infected tissues. To solve these issues, we prepared polyvinyl alcohol (PVA)-polyacrylic acid (PAA)-iron oxide (FeO)/polyvinyl alcohol (PVA)-zinc peroxide (ZnO) double-layer electrospun nanofibers (PPF/PZ NFs). In this design, PVA serves as the carrier for ZnO nanoparticles (NPs), FeO NPs, and PAA. The double-layer structure of nanofibers can spatially separate the PAA and ZnO to avoid their reaction with each other during preparation and storage, while in the wet wound bed, PVA can dissolve and PAA can provide H ions to promote the generation of hydrogen peroxide and subsequent conversion to hydroxyl radicals for bacteria killing. experimental results demonstrated that PPF/PZ NFs can reduce the methicillin-resistant by 3.1 log (99.92%). Moreover, PPF/PZ NFs can efficiently treat the bacterial infection in a mouse wound model and promote wound healing with negligible toxicity to animals, indicating their potential use as "plug-and-play" antibacterial wound dressings. This work provides a novel strategy for the construction of double-layer electrospun nanofibers as catalytic wound dressings with hydrogen peroxide/acid self-supplying properties for the efficient treatment of bacterial infections.