双层
脚手架
材料科学
生物医学工程
再生(生物学)
软骨
细胞外基质
间充质干细胞
组织工程
基质(化学分析)
关节软骨
关节软骨修复
纳米技术
生物物理学
软骨下骨
仿生材料
软组织
纳米地形
作者
Yuxiang Liu,Wei Xu,Danyang Zhao,Yanmei Li,Zhen Guo,Liang Yuan,Wenmo Gao,Dong Han,Chunhong Ye
标识
DOI:10.1002/adhm.202503547
摘要
Osteochondral defect is a severe health concern, particularly in the elderly, while, with limited medical treatment options. It is urgent to develop osteochondral regeneration scaffolds that integrate multiple biological cues to promote cartilage and subchondral bone repair simultaneously. In this study, osteochondral scaffolds featuring both a mechanical gradient and unidirectional micro-channels are constructed based on a bilayer hydrogel design. The soft layer, composed of a polymeric double network, mimics the mechanical properties of cartilage. The relatively stiff layer, reinforced with nanohydroxyapatite (nHAp), aligns with the subchondral bone feature. The combination of bilayer structure provides a mechanical cue to mimic the heterogeneous modulus of the native osteochondral tissue. The bilayer design contributes to the differentiation of bone mesenchymal stem cells (BMSCs) into chondrocytes and osteoblasts, correspondingly. Moreover, the unidirectional micro-channels crossing the bilayer provide a topological cue, which facilitates the directional migration of cells. In vivo implanting in a rat osteochondral injury model demonstrates enhanced regeneration of cartilage and bone after 12 weeks. These findings suggest that the bilayer hydrogel scaffold, through the integration of mechanical and topological cues, offers a biomimetic 3D extracellular matrix with promising potential for osteochondral repair.
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