再生(生物学)
神经导管
周围神经损伤
一氧化氮
材料科学
神经损伤
神经生长因子
细胞
周围神经
氧化应激
再生医学
组织工程
炎症
神经科学
外周神经系统
渗透(HVAC)
变性(医学)
生物医学工程
刺激
细胞生物学
纳米技术
生物相容性材料
模块化设计
作者
Xianzhen Dong,Hao Zhang,Junwei Su,Kun Liu,Ziqiang Li,Xinyue Liang,Yuanfang Huo,Junwei Yang,Lesan Yan,Aixi Yu,Honglian Dai
标识
DOI:10.1002/adma.202510948
摘要
Repairing long-segment peripheral nerve injuries remains a significant clinical challenge, hindered by oxidative stress, inflammation, insufficient revascularization, and limited axonal regeneration speeds. This study addresses these barriers by reconstructing the nerve regeneration microenvironment, enhancing cell migration, and accelerating axonal growth. An integrated regenerative microenvironment combining chemical signals, micro/nano structures, and electrical stimulation is developed. Specifically, nitric oxide (NO), a versatile signaling molecule, is dynamically released using sustained and responsive-release strategies to regulate oxidative stress and inflammation effectively. Furthermore, a gelatin-lipoic acid-seleno-lipoic acid (Gel-LA-SA) microgel-based hydrogel is designed, forming interconnected macroporous scaffolds that significantly enhance cell infiltration and growth compared to traditional hydrogels. Additionally, a non-invasive electroactive conduit is constructed to provide external electrical stimulation, promoting nerve cell migration and nerve growth factor secretion. Together, these elements guide axonal regeneration, support rapid revascularization, and enhance nutrient supply. By integrating NO signaling, advanced hydrogel scaffolds, and electrical stimulation, this multifunctional conduit effectively addresses the critical barriers to regenerating nerves across extensive defect sites, offering a promising approach for repairing long-segment peripheral nerve injuries and providing insights into broader applications for neurological disease treatment and tissue regeneration.
科研通智能强力驱动
Strongly Powered by AbleSci AI