伤口愈合
共轭体系
透明质酸
化学
生物物理学
纳米颗粒
体内
材料科学
聚合物
纳米技术
医学
有机化学
生物
外科
解剖
生物技术
作者
Quan Yuan,Jun Yin,Ling Li,Benkai Bao,Xinyi Zhang,Meiqi Li,Yanli Tang
标识
DOI:10.1002/advs.202304048
摘要
Abstract Diabetic chronic wounds are characterized by local hypoxia, impaired angiogenesis, and bacterial infection. In situ, self‐supply of dissolved oxygen combined with the elimination of bacteria is urgent and challenging for chronic nonhealing wound treatment. Herein, an oxygen‐generating system named HA‐L‐NB/PFE@cp involving biological photosynthetic chloroplasts (cp)/conjugated polymer composite nanoparticles (PFE‐1‐NPs@cp) and light‐triggered hyaluronic acid‐based (HA‐L‐NB) hydrogel for promoting diabetic wound healing is introduced. Briefly, conjugated polymer nanoparticles (PFE‐1‐NPs) possess unique light harvesting ability, which accelerates the electron transport rates in photosystem II (PS II) by energy transfer, elevating photosynthesis beyond natural chloroplasts. The enhanced release of oxygen can greatly relieve hypoxia, promote cell migration, and favor antibacterial photodynamic therapy. Additionally, the injectable hydrogel precursors are employed as a carrier to deliver PFE‐1‐NPs@cp into the wound. Under light irradiation, they quickly form a gel by S‐nitrosylation coupling reaction and in situ anchor on tissues through amine‐aldehyde condensation. Both in vitro and in vivo assays demonstrate that the oxygen‐generating system can simultaneously relieve wound hypoxia, eliminate bacteria, and promote cell migration, leading to the acceleration of wound healing. This study provides a facile approach to develop an enhanced oxygen self‐sufficient system for promoting hypoxic tissue, especially diabetic wound healing.
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