材料科学
再生(生物学)
牙槽
牙周纤维
纤维
生物医学工程
构造(python库)
组织工程
软组织
脚手架
纳米纤维
纳米技术
接口(物质)
静电纺丝
韧带
再生医学
组织修复
捆绑
软骨
天然组织
作者
Yi Tian,Xuan Li,Yuzhe Chen,Dian Gan,Dao‐Kun Deng,Lin Jing,Fang Li,Wenjie Zhang,Rui‐Xin Wu,Fen Liu,Jia Wang,Bei‐Min Tian,Fa‐Ming Chen,Xiao‐Tao He
标识
DOI:10.1002/adfm.202510486
摘要
Abstract The repair of periodontal complexes poses a significant challenge due to the lack of functional material constructs that can recapitulate the hierarchically interlocked structures of the soft–hard tissue interfaces within periodontium. Here, a bioinspired construct is fabricated by engineering interlocked bone–fiber interfaces within its hierarchical architectures to mimic the multiscale features found in native periodontal ligament (PDL)‒bone enthesis. The 3D‐printed bone module and electrospun fiber module of the bioinspired constructs offered suitable architecture, biomechanics, and cytokine landscapes to recruit reparative cells and promote their osteogenic and fibrogenic differentiation. At the interfaces of the dual‐module construct, the electrospun nanofibers of the fiber module are inserted into the bone module owing to various intermolecular interactions, which facilitate strong conjunction between the dual modules and provided biophysical gradients along the inserted nanofibers, similar to the microstructure and micromechanics of PDL‒bone insertions. When the constructs are placed in periodontal defects in pigs for 12 weeks, the alveolar bone is restored to its native level, and newly formed mature collagen fibers are inserted into the regenerated alveolar bone, culminating in superb integration between the soft and hard tissue interfaces. The findings demonstrate that bioinspired constructs with interlocked bone–fiber interfaces can regenerate complex soft‒hard tissue interfaces in pigs.
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