In this study, we evaluated the surface characterization of a novel chitosan–silica hybridized membrane and highlighted the substantial role of silica in the wound environment. The chemical coupling of chitosan and silica resulted in a more condensed network compared with pure chitosan, which was eventually able to stably maintain its framework, particularly in the wet state. In addition, we closely observed the wound-healing process along with the surface interaction between chitosan–silica and the wound site using large-surface-area wounds in a porcine model. Our evidence indicates that chitosan–silica exerts a synergetic effect of both materials to promote a remarkable wound-healing process. In particular, the silica in chitosan–silica accelerated wound closure including wound contraction, and re-epithelialization via enhancement of cell recruitment, epidermal maturity, neovascularization, and granulation tissue formation compared with pure chitosan and other commercial dressing materials. This advanced wound dressing material may lead to effective treatment for problematic cutaneous wounds and can be further applied for human skin regeneration.
DEVELOPMENT AND CHARACTERIZATION OF VITAMIN B9 - ELECTROSPRAYED NON-WOVEN SURFACES FOR WOUND HEALING APPLICATIONS
