Despite the advances in the development of therapeutic wearable wound-healing patches, lack self-healing properties and strong adhesion to diabetic skin, hindering their effectiveness. We propose a unique, wearable patch made from a 3D organo-hydrogel nanocomposite containing polydopamine, titanium dioxide nanoparticles, and silver quantum dots (PDA-TiO2@Ag). The designed patch exhibits ultra-stretchable, exceptional-self-healing, self-adhesive, ensuring conformal contact with the skin even during movement. Our patch demonstrated potent antibacterial activity and significantly accelerated wound healing with a high wound closure rate of 99.2 % after 7 days. Remarkably, it enhanced diabetic skin wound healing compared to that achieved by adipose-derived stem cell (ADSC) therapy in a study involving 30 adult male albino rats. Microscopic analysis highlights the promising hierarchical architecture structure of the patch for wound healing applications, suggesting its potential to create a favorable environment for healing and provide long-lasting benefits. Histopathological analysis and immunohistochemical staining revealed faster healing and enhanced cellular response in the patch-treated group compared to both stem cell and control groups. Notably, the patch promoted complete re-epithelization and a significant increase in vascular endothelial growth factor (VEGF) expression on day 7, indicating improved angiogenesis. This self-healing, multifunctional patch offers a promising alternative to stem cell therapy for accelerating diabetic wound healing, showcasing its potential for clinical translation. The combination of durability, biocompatibility, and antibacterial properties makes the patch a promising candidate for advanced wound management and offering faster, more complete restoration than other approaches.
Keywords: Adipose derived stem cells; Diabetic wound; Organo-hydrogel nanocomposite; Wound healing.
Published by Elsevier Ltd.