Abstract

Pathogenic bacteria infections have posed a threat to human health worldwide. Nanomaterials with natural enzymatic activity provide an opportunity for the development of new antibacterial pathways. We successfully constructed iron phosphate nanozyme-hydrogel (FePO₄-HG) with the traits of positive charge and macropores. Interestingly, FePO₄-HG displayed not only peroxidase-like activity under acidic bacterial infectious microenvironment but also superoxide dismutase-catalase-like synergistic effects in neutral or weak alkaline conditions, thus protecting normal tissues from the peroxidase-like protocol with exogenous H₂O₂ damage. Furthermore, the positive charge and macropore structure of FePO₄-HG could capture and restrict bacteria in the range of ROS destruction. Obviously, FePO₄-HG exhibited excellent antibacterial ability against MRSA and AREC with the assistance of H₂O₂. Significantly, the FePO₄-HG + H₂O₂ system could efficiently disrupt the bacterial biofilm formation and facilitate the glutathione oxidation process to rapid bacterial death with low cytotoxicity. Moreover, FePO₄-HG was unsusceptible to bacterial resistance development in MRSA. Animal experiments showed that the FePO₄-HG + H₂O₂ group could efficiently eliminate the MRSA infection and present excellent wound healing without inflammation and tissue adhesions. With further development and optimization, FePO₄-HG has great potential as a new class of antibacterial agents to fight antibiotic-resistant pathogens.