Coronavesicle-engineered hydrogel sequential photothermal-immunometabolic therapy reprograms tissue microenvironment for diabetic-infected wounds healing.
Bodeng Wu, Shan Lin, Qi Xiu, Mingzhen Zhong, Yiyao Huang, Zhenxun Wang, Xiuhua Wu, Jiangang Mei, Shuhan Liu, Liping Liu, Bo Li, Weilun Pan, Lei Zheng
Abstract
Open AccessPersistent infection and dysregulated tissue microenvironment constitute the primary obstacles hindering the healing of infectious diabetic wounds. Herein, we developed an NIR-responsive hydrogel dressing incorporating polyphenol-engineered plant-derived nanovesicles (termed Coronavesicles) via an in-situ deposition strategy, designed to implement sequential photothermal-immunometabolic therapy for infectious diabetic wounds. The coronavesicles within the hydrogel preferentially adhere to bacterial surfaces to deliver localized photothermal therapy (PTT), wherein subsequent heat-triggered rupture releases intrinsic bioactive constituents to enhance antibacterial efficacy. Following bacterial clearance, the released components from coronavesicles synergistically modulate fibroblast proliferation, alleviate oxidative stress, and reverse macrophage-mediated inflammatory immunity. This multi-pronged therapeutic strategy demonstrates desirable treatment outcomes both in vitro and in vivo. This work contributes to the understanding and future development of engineering plant-derived nanovesicles for diabetic wound management.