Multifunctional Dual Nano-MOF-Modified Decellularized Small Intestinal Submucosa Membrane Accelerates Healing of Infected Wound

The treatment of complex or chronic skin wounds caused by burns, trauma, surgery, and genetic disorders has been a worldwide challenge. Small intestinal submucosa (SIS) is a biological material that is widely used in wound healing. How to further expand the wound healing application of SIS, especially in repairing infected wounds, remains a hot research topic for many tissue engineering and biomaterial scholars focusing on skin regeneration. This study uses nanometal–organic frameworks (nano-MOFs), which have not been applied to modify the SIS membrane before, to construct multifunctional dual nano-MOFs @ SIS membrane (dnMOF@SISm). Nano-MOFs are functionalized onto the nanofiber of SIS via in situ self-assembly under mild reaction conditions without any toxic reagent or complex instruments. The dnMOF@SISm can release Co2+, Zn2+, and bioactive factors, participating in the whole stage of the repair of infected wounds. In vitro, it can regulate the biological activities of various functional cells such as fibroblasts, endothelial cells, and macrophages and shows good antibacterial ability. In the infected full-thickness skin defect rat model, dnMOF@SISm can release metal ions and ligands, killing pathogenic bacteria colonized on the wound surface at the first stage, and then trigger and accelerate the skin repair process via angiogenesis, immune regulation, and collagen deposition. Above all, an efficient, nontoxic, mild self-assembly strategy realizes the functionalization of dual nano-MOFs on the nanofiber of SIS to expand its clinical application scenarios, especially in infected wounds.