自愈水凝胶
止血器
材料科学
止血
生物医学工程
生物相容性材料
纳米技术
生物相容性
严重创伤
膨胀的
脚手架
止血剂
离子键合
组织工程
粘附
组织修复
作者
Xiaoshuai Peng,Fenglei Chen,Yunhui Zhang,Mengyu Wang,Yue Fan,Guan Zheng,Peng Wang,Yuheng Lu,Zhaopeng Cai,Dingcai Wu
摘要
ABSTRACT Uncontrolled traumatic hemorrhage, often complicated by infection and poor healing, accounts for over 30% of trauma‐related deaths worldwide. Injectable hydrogels with robust multi‐bond crosslinked networks, integrating fluidity and in situ stability, are promising for efficient hemostasis, but their crosslinkers’ relatively single structures limit the multifunctionality required for effective trauma management in resource‐scarce environments. Herein, a new class of versatile ε‐polylysine grafted manganese dioxide (EPL‐ g ‐MnO 2 ) nano‐crosslinkers is synthesized to construct an injectable hydrogel (i.e., OSEG hydrogel). Driven by EPL‐ g ‐MnO 2 , OSEG hydrogel rapidly achieves stable wet adhesion and efficient hemostasis in critical injuries (e.g., 24.9 s in a rabbit model of cardiac hemorrhage) via imine, hydrogen, and ionic bonds, which form a robust and multifunctional crosslinked network upon full gelation. In the microenvironment of traumatic wounds, OSEG hydrogel undergoes accelerated degradation to further expose EPL‐ g ‐MnO 2 and spermidine, thereby providing sufficient antibacterial and pro‐healing effects. As a result, OSEG hydrogel achieves a bone volume/total volume 3.3 times that of commercial hemostat SURGIFLO in a rat model of infected cranial defect. This work may inspire the design of advanced injectable hydrogels for synergistic trauma management.
科研通智能强力驱动
Strongly Powered by AbleSci AI