Abstract
Diabetic wounds are one of the most serious complications of diabetes mellitus caused by impaired blood vessel formation, nerve damage, excessive inflammation, hypoxia, and persistent infections, which severely affects the quality of life of patients. Conductive hydrogel-based flexible epidermal sensors have great potential for personal medical monitoring and diabetic chronic wound therapy. Combining electrical stimulation (ES) therapy with motor activity monitoring can guide clinical practice and thus radically improve treatment outcomes. In this study, a multifunctional conductive Gel-TBA-LM organohydrogel flexible sensor with antimicrobial, antioxidant, and biocompatible properties was synthesized using gelatin (Gel) and 2,3,4-trihydroxybenzaldehyde (TBA) as the substrates, and liquid metal (LM) as the functional filler. Its mechanical properties and frost resistance were enhanced by the Hofmeister effect and solvent substitution strategy. The Gel-TBA-LM organohydrogel has excellent mechanical properties (1.2 MPa modulus and 400 % strain) and high electrical conductivity (673.76 S/m). The corresponding measurement factor (GF) values were 0.26 (0-50 %) and 2.88 (50-200 %) at 0-200 % strain, thus can sensitively and accurately detect movement behavior of different joints. In addition, the combination of Gel-TBA-LM organohydrogel with ES promotes diabetic wound healing by coordinating angiogenesis and macrophage M2-type polarization through the VEGF/ERK pathway while maintaining vascular cell-neuronal cell intercellular crosstalk. This study provides a valuable reference for the development of multifunctional conductive organohydrogel sensors for chronic diabetic wound repair and personal health monitoring.