伤口愈合
静电纺丝
材料科学
纳米纤维
巨噬细胞极化
硫酸软骨素
自愈水凝胶
肉芽组织
生物医学工程
透明质酸
肌成纤维细胞
再生(生物学)
成纤维细胞
生物相容性材料
右旋糖酐
生物物理学
细胞外基质
光热治疗
PLGA公司
吡非尼酮
肿胀 的
细胞迁移
巨噬细胞
纳米颗粒
壳聚糖
纳米技术
间充质干细胞
生物材料
卡拉胶
自愈
纤维
控制释放
组织工程
半乳糖胺
化学
作者
W. Yang,Dong Han,Xiaoli Shi,Jiazheng Li,Kai Li,Jiawei Xiang,Yuan Meng,Mingyuan Zhao,Huizhen Sun,Zhuo Ao,Qiang Zhang
标识
DOI:10.1002/adfm.202524234
摘要
ABSTRACT The fascia, a hierarchical composite structure present in the skin, can promote the rapid repair of damaged tissues and reduce the formation of scars. However, its important role in wound repair has been severely neglected. Therefore, we develop a wound dressing with a nanofiber network structure that mimics the skin fascia. Using methacryloyl chondroitin sulfate as a hydrogel substrate, a light‐clickable fascia‐inspired nanofibrous hydrogel (CA‐DAF‐BSA @ PFD) is constructed by electrospinning a dextran shell loaded with pirfenidone albumin nanoparticles (BSA @ PFD) to form a core‐shell fiber network. The hydrogel demonstrates good viscoelasticity, injectability, swelling resistance, antibacterial activity, and biocompatibility. In vitro cell studies demonstrate that CA‐DAF‐BSA @ PFD hydrogel induces macrophage polarization toward the M2 phenotype and inhibits fibroblast differentiation into myofibroblasts. In vivo, CA‐DAF‐BSA @ PFD hydrogel can significantly promote granulation tissue regeneration and effectively reduce the formation of scar tissue by inhibiting excessive collagen deposition and abnormal fibrosis. This core‐shell fiber hydrogel exhibits significant potential as an advanced wound dressing, offering a novel therapeutic strategy for achieving both high‐efficiency and biocompatible tissue repair.
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