Engineering Platelet Membrane‐Coated Bimetallic MOFs as Biodegradable Nanozymes for Efficient Antibacterial Therapy

Nanocatalytic‐based wound therapeutics present a promising strategy for generating reactive oxygen species (ROS) to antipathogen to promote wound healing. However, the full clinical potential of these nanocatalysts is limited by their low reactivity, limited targeting ability, and poor biodegradability in the wound microenvironment. Herein, a bio‐organic nanozyme is developed by encapsulating a FeZn‐based bimetallic organic framework (MOF) (MIL‐88B‐Fe/Zn) in platelet membranes (PM@MIL‐88B‐Fe/Zn) for antimicrobial activity during wound healing. The introduction of Zn in MIL‐88B‐Fe/Zn modulates the electronic structure of Fe thus accelerating the catalytic kinetics of its peroxidase‐like activity to catalytically generate powerful ROS. The platelet membrane coating of MOF innovatively enhanced the interaction between nanoparticles and the biological environment, further developing bacterial‐targeted therapy with excellent antibacterial activity against both gram‐positive and gram‐negative bacteria. Furthermore, this nanozyme markedly suppressed the levels of inflammatory cytokines and promoted angiogenesis in vivo to effectively treat skin surface wounds and accelerate wound healing. PM@MIL‐88B‐Fe/Zn exhibited superior biodegradability, favourable metabolism and non‐toxic accumulation, eliminating concerns regarding side effects from long‐term exposure. The high catalytic reactivity, excellent targeting features, and biodegradability of these nanoenzymes developed in this study provide useful insights into the design and synthesis of nanocatalysts/nanozymes for practical biomedical applications. Platelet membranes‐coated bimetallic organic frameworks with superior peroxidase activity and effective targeting ability are designed and constructed, which display satisfactory antibacterial effects both in vitro and in vivo. Being biodegradable, the biomimetic nanozyme exhibits excellent in vivo biocompatibility and does not cause adverse effects due to the long‐time residence required for wound healing.