丝素
脚手架
氧气
无氧运动
化学
伤口愈合
细菌生长
微生物学
厌氧菌
细菌
膜
过氧化氢
组织工程
生物材料
活性氧
生物相容性
炎症
生物膜
抗菌剂
炎症反应
细胞
细菌细胞结构
人体皮肤
作者
Min Ru,Renyan Huang,Lu Wang,Zuwei Luo,Ying Huang,Renchuan You,Ruoxuan Peng,Shuqin Yan,Qiang Zhang,Shengjie Ling,Weilin Xu
出处
期刊:Biomacromolecules
[American Chemical Society]
日期:2025-09-11
卷期号:26 (10): 6515-6527
被引量:2
标识
DOI:10.1021/acs.biomac.5c00591
摘要
In response to the difficulties posed by anaerobic bacterial infections in wound healing, particularly in light of the increasing prevalence of antibiotic-resistant strains and the complex nature of wound environments, this study introduces a meticulously planned oxygen-generating tissue engineering scaffold to address these obstacles. This scaffold is realized from silk fibroin (SF), poly(vinyl alcohol) (PVA), and calcium peroxide (CPO) by ice crystal-induced self-assembly combined with the ice template method, aiming at a synergistic balance of hydrophilicity, structural stability, mechanocompatibility with biological tissues, controllable oxygen-releasing behavior, and antianaerobic bacterial properties. In particular, the oxygen-generating scaffold containing 2.5% CPO exhibits excellent antianaerobic properties by destroying C. perfringens through a mechanism that disrupts bacterial cell membranes and DNA, as well as promotes the generation of reactive oxygen species. Meanwhile, significant cytotoxic or hemolytic effects were avoided. Subsequent results demonstrated that the oxygen-generating scaffold accelerated the healing process of C. perfringens -infected wounds with results similar to those of amoxicillin. These results emphasize the promise of this new platform in clinical practice for the treatment of anaerobic bacterial infections and establishing a basis for advanced therapeutic strategies.
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