Injectable Intrinsic Photothermal Hydrogel Bioadhesive with On‐Demand Removability for Wound Closure and MRSA‐Infected Wound Healing

Photothermal hydrogel adhesives have yielded promising results for wound closure and infected wound treatment in recent years. However, photothermal hydrogel bioadhesives with on‐demand removability without additional nanomaterials‐based photothermal agents have rarely been reported in the literature. In this work, an injectable intrinsic photothermal hydrogel bioadhesive with an on‐demand removal trait is developed through dynamic cross‐linking of gelatin (Gel), tannic acid (TA) quinone, and borax for closing skin incisions and accelerating methicillin‐resistant Staphylococcus aureus (MRSA) infected wound healing. The TA quinone containing polyphenol and quinone groups with multifunctional adhesiveness and intrinsic photothermal performance confer the hydrogel adhesive with near‐infrared (NIR) responsive antibacterial activity. The cross‐linking of pH‐sensitive boronic ester (polyphenol−B) and Schiff base bonds endow the hydrogel with great self‐healing capacity and on‐demand removability. Moreover, the hydrogel possesses good biocompatibility, injectability, and hemostasis. The in vivo experiment in a rat cutaneous incision model and full‐thickness MRSA‐infected wound model indicate that the smart hydrogel can close wounds efficiently and treat infected ones, demonstrating its superiority in noninvasive treatment of cutaneous incisions and enhancing infected full‐thickness wound healing. A novel intrinsic photothermal hydrogel bioadhesive is designed without adding additional photothermal agents. The hydrogel is capable of closing wounds efficiently and dealing with an infected wound, demonstrating its superiority in noninvasive closing skin incisions and enhancing infected full‐thickness wound healing. The hydrogel adhesive can serve as an attractive all‐in‐one solution for closing open wounds and treating infected wound healing.