Photothermal‐enhanced in situ supramolecular hydrogel promotes bacteria‐infected wound healing in diabetes

Chen Zheng, Xuan Wu, Ming Liu, Yulong Lan, Qian Liu, Erya Cai, Zhiyong Liao, Jianliang Shen
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引用次数: 1

Abstract

Bacterial infection can impede the healing of chronic wounds, particularly diabetic wounds. The high‐sugar environment of diabetic wounds creates a favorable condition for bacterial growth, posing a challenge to wound healing. In clinical treatment, the irregular shape of the wound and the poor mechanical properties of traditional gel adjuvants make them susceptible to mechanical shear and compression, leading to morphological changes and fractures, and difficult to adapt to irregular wounds. Traditional gel adjuvants are prepared in advance, while in situ gel is formed at the site of administration after drug delivery in a liquid state, which can better fit the shape of the wound. Therefore, this study developed an in situ HA/GCA/Fe2+‐GOx gel using a photothermal‐enhanced Fenton reaction to promote the generation of hydroxyl radicals (·OH). The generation of ·OH has an antibacterial effect while promoting the formation of the gel, achieving a dual effect. The addition of double‐bonded adamantane (Ada) interacts with the host‐guest effect of graphene oxide and the double‐bond polymerization of HAMA gel, making the entire gel system more complete. At the same time, the storage modulus (G′) of the gel increased from 130 to 330 Pa, enhancing the mechanical properties of the gel. This enables the gel to have better injectability and self‐healing effects. The addition of GOx can consume glucose at the wound site, providing a good microenvironment for the repair of diabetic wounds. The gel has good biocompatibility and in a diabetic rat wound model infected with S. aureus, it can effectively kill bacteria at the wound site and promote wound repair. Meanwhile, the inflammation of wounds treated with HA/GCA/Fe2+‐GOx + NIR was lighter compared to untreated wounds. Therefore, this study provides a promising strategy for treating bacterial‐infected diabetic wounds.
光热增强原位超分子水凝胶促进糖尿病细菌感染伤口愈合
细菌感染会阻碍慢性伤口的愈合,尤其是糖尿病伤口。糖尿病伤口的高糖环境为细菌生长创造了有利条件,给伤口愈合带来了挑战。在临床治疗中,由于伤口形状不规则,传统凝胶佐剂的机械性能较差,容易受到机械剪切和挤压,导致形态改变和骨折,而且难以适应不规则的伤口。传统凝胶佐剂需要提前制备,而原位凝胶是在给药部位给药后以液态形成的,能更好地适应伤口形状。因此,本研究利用光热增强芬顿反应促进羟基自由基(-OH)的生成,开发了一种原位 HA/GCA/Fe2+-GOx 凝胶。氢氧自由基的生成具有抗菌效果,同时还能促进凝胶的形成,达到双重效果。双键金刚烷(Ada)的加入与氧化石墨烯的主客效应和 HAMA 凝胶的双键聚合相互作用,使整个凝胶体系更加完整。同时,凝胶的储存模量(G′)从 130 Pa 增加到 330 Pa,提高了凝胶的机械性能。这使得凝胶具有更好的注射性和自我修复效果。添加 GOx 可消耗伤口部位的葡萄糖,为糖尿病伤口的修复提供良好的微环境。凝胶具有良好的生物相容性,在糖尿病大鼠感染金黄色葡萄球菌的伤口模型中,它能有效杀死伤口部位的细菌,促进伤口修复。同时,经 HA/GCA/Fe2+-GOx + 近红外处理的伤口炎症较未经处理的伤口轻。因此,这项研究为治疗细菌感染的糖尿病伤口提供了一种很有前景的策略。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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