材料科学
螺旋(铁路)
再生(生物学)
压电
周围神经
接头(建筑物)
纤维
复合材料
生物医学工程
纳米技术
解剖
结构工程
机械工程
细胞生物学
生物
工程类
医学
作者
Dong Wang,Wenjun He,Changchao Dong,Zhencheng Xiong,Renliang Zhao,Xiangtian Deng,Yunfeng Tang,Zilu Ge,Qian Fang,Danting Ao,Chaoyi Zhang,Wenzheng Liu,Huiqi Xie,Lin Ye,Wei Lin,Xiaowen Zhao,Guanglin Wang
标识
DOI:10.1002/adfm.202510552
摘要
Abstract Over a million individuals worldwide suffer from peripheral nerve injury annually, while traditional nerve conduits face challenges like poor mechanical adaptability, insufficient bioactivity, and nerve regeneration efficacy. Herein, based on biodegradable poly(lactic acid) (PLA), hydrazide nucleator (HNA) is introduced into PLA fibers to improve its oriented crystallization degree and piezoelectricity, while PLA‐HNA fiber‐based nerve conduits with spiral structure (SNCs) is constructed via further fiber merging, twisting, and coiling process. The spiral geometry of SNCs is systematically optimized to improve its piezoelectric response, mechanical flexibility, and extensibility, significantly surpassing conventional PLA‐based hollow nerve conduits (HNC). Furthermore, SNCs are demonstrated to remarkably enhance Schwann cell proliferation and migration. In vivo studies confirmed that SNCs markedly promoted nerve regeneration, comparable to autologous nerve grafts and surpassing HNC greatly. Notably, SNCs enabled robust regeneration across complex anatomical sites such as joint‐associated and vessel‐crossing nerve defects, where motion usually induced deformation and unstable microenvironments. SNCs implantation restored nerve conduction and muscle responsiveness, enhanced myelination and fiber alignment, and minimized fibrosis. The potential mechanisms underlying SNC‐mediated nerve regeneration are explored, highlighting the mechanical‐electrical coupling advantage of the spiral structure in adapting to dynamic environments, and offering promising therapeutic strategies for PNI repair.
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