Programmable DNA-Silk fibroin hydrogel scaffold with temporal mechanical reinforcement for mesenchymal stem cells differentiation and accelerated wound healing in a full-thickness skin defect mice model

DNA-based hydrogels have attracted significant attention in biomedical applications due to their programmability, biocompatibility, and tunable functionalities. However, their clinical translation is hindered by high synthesis costs, limited mechanical strength, poor stability, and complex synthesis protocols. In this work, we present a novel DNA-silk fibroin hybrid hydrogel that overcomes these limitations by combining the unique biofunctionality of DNA with the superior mechanical and chemical properties of silk fibroin. Salmon-derived DNA, an abundant and low-cost source, was incorporated with silk fibroin to form hybrid networks via a simple, scalable process. Silk fibroin served as a robust scaffold, enhancing mechanical strength, controlling degradability, and improving structural stability, while the entangled DNA-silk network reduced rapid DNA degradation. The resulting hybrid hydrogel demonstrated temporal mechanical reinforcement and prolonged stability, with in vitro studies demonstrating that the developed hybrid hydrogel enhanced the chondrogenic and osteogenic differentiation of Infrapatellar Fat Pad Mesenchymal Stem Cells (IFP-MSCs). Additionally, hemostatic and in vivo studies demonstrated the potential of DNA-silk fibroin hydrogel as a promising biomaterial for rapid hemostasis and accelerated wound healing. Overall, the developed DNA-silk fibroin hybrid hydrogel offers strong potential for mesenchymal tissue engineering, hemostatic adjuvant and wound healing.