Xinyue Zhang, Xue Zhan, Chen Hu, Zuqin Dong, Tao Luo, Haihang Li, Xiaoju Fan, Jie Liang, Yafang Chen, Yujiang Fan
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引用次数: 0
摘要
再生伤口愈合敷料的目标是加速皮肤组织再生,恢复伤口部位的正常生理功能。实现这一目标需要生物材料能够修复伤口愈合的不同阶段,同时兼顾材料功能、降解、安全性和组织生长。在这项研究中,我们介绍了一种新型双阶段伤口敷料系统,该系统由甲基丙烯酸酐改性重组人源化 III 型胶原蛋白(rhCol III-MA)和甲基丙烯酸酐改性多巴胺(DMA)(RMDM)组成,后者是通过自由基聚合和 π-π 堆积合成的。在这一系统中,RMDM 被配制成两种具有相同成分的形式:水凝胶和海绵,适用于不同阶段的伤口修复。这些材料在体外显示出良好的血液相容性、生物相容性、抗氧化性和血管生成潜力。此外,体内实验也表明,海绵能在小鼠断尾和肝脏切口模型中迅速止住伤口出血。值得注意的是,在大鼠全厚皮肤伤口模型中,海绵/凝胶(S/G)系统与单独的海绵和凝胶处理相比,可加速伤口愈合,这凸显了海绵和凝胶材料在伤口修复不同阶段的协同作用。因此,这项研究为设计可针对伤口愈合特定阶段的先进生物材料提供了宝贵的见解,这可能在生物医学应用方面具有巨大的潜力。
Light-controlled crosslinked multifunctional "Band-Aids" as dual-stage wound dressing for dynamic wound closure
The objective of regenerative wound healing dressings is to accelerate skin tissue regeneration and restore normal physiological function at wound sites. Achieving this goal requires biomaterials capable of repairing distinct phases of wound healing in a way that balances material function, degradation, safety, and tissue growth. In this study, we introduced a novel dual-stage wound dressing system comprising methacrylic anhydride-modified recombinant humanized type III collagen (rhCol III-MA) and methacrylic anhydride-modified dopamine (DMA) (RMDM), which was synthesized through free radical polymerization and π-π stacking. Within this system, RMDM was formulated into two forms with identical compositions: hydrogel and sponge, tailored for application across various stages of wound repair. These materials displayed favorable hemocompatibility, biocompatibility, antioxidant properties, and angiogenic potential in vitro. Moreover, the in vivo experiments also demonstrated that sponges could rapidly stop the bleeding of wounds in mouse tail amputation and liver incision models. Notably, the sponge/gel (S/G) system accelerated wound healing compared to individual sponge and gel treatments in a rat full-thickness skin wound model, underscoring the synergistic benefits of combining sponge and gel materials for wound repair at different stages. Therefore, this research provides valuable insights into designing advanced biomaterials that can be tailored to specific stages of wound healing, which may have significant potential for biomedical applications.
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