渗出液
生物医学工程
透皮
伤口愈合
材料科学
生物相容性
微型多孔材料
体内
生物污染
瑞巴派特
磨损(机械)
脚手架
丝素
药物输送
化学
伤口闭合
药品
聚二甲基硅氧烷
往复运动
控制释放
药理学
作者
Lei Liu,Jiaming Zhang,Zhiye Qiu,Haotian Ren,Dan Yu,Yujie Gao,Hengqiu Sun,Jindan Wu
标识
DOI:10.1002/adhm.202504202
摘要
Excessive exudate in chronic wounds increases the risk associated with tissue hydration, bacterial infection, and increased inflammation. While Janus dressings enable unidirectional exudate transport, current designs overlook the critical need for maintaining optimal wound humidity and providing on-demand antibacterial/anti-inflammatory treatment to support repair. To address this, a self-pumping trilayered dressing (GCSIP) is developed, integrating polyhexamethylene guanidine-grafted triglycidyl glycerol ether (PHMG-GTE)-modified cotton, ibuprofen-loaded silk fibroin (IBU/SF), and polyurethane (PU). This architecture achieves autonomous, unidirectional fluid transport and drug release via a controlled reflux mechanism triggered upon full saturation of the cotton layer. A precisely engineered microporous array (400 µm pores, 6 mm spacing) is used to optimize directional transport and reflux efficiency. Upon saturation, partial reflux through the array facilitates the release of dissolved SF molecules and 87.6% of the encapsulated ibuprofen (IBU) within 72 h. The released components significantly reduced TNF-α and IL-6 expression in M1 macrophages by 90.4% and 87.6%, respectively. The in vivo results demonstrate excellent biocompatibility and nearly complete wound healing within 15 days, with a residual wound area ratio of only 0.8%. This study establishes an on-demand exudate regulation and drug release mechanism for multifunctional dressings to accelerate wound recovery.
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