细胞生物学
再生(生物学)
化学
软骨发生
肩袖
巨噬细胞
间充质干细胞
重编程
组织工程
热情
生物活性玻璃
自愈水凝胶
炎症
细胞内
生物材料
纤维软骨
巨噬细胞极化
骨溶解
再生医学
生物医学工程
骨髓
M2巨噬细胞
涂层
生物物理学
干细胞
细胞分化
细胞疗法
作者
Bowen Cai,Fanrui Zeng,Kaixiao Xue,Zhi Shen,Chang Qiao,H W Wu,Qunyi Wang,J Y Zhang,Shahin Homaeigohar,Kai Zheng,Bin Zhu,Jiahu Fang
摘要
Abstract Failure of rotator cuff repair largely stems from ineffective regeneration of the tendon–bone interface (TBI), driven by persistent inflammation and excessive reactive oxygen species (ROS) accumulation at the biomaterial tissue interface. Here, we engineer an immunoregulatory suture interface by incorporating cerium-doped mesoporous bioactive glass nanoparticles (Ce-MBGNs) into a gelatin/tannic acid (Gel/TA) coating on polyethylene terephthalate sutures. The hierarchical Gel/TA/Ce-MBGN coating displays uniform morphology, robust adhesion and superior ROS scavenging activity. In vitro, Ce-MBGN-functionalized surfaces markedly promote osteogenic and chondrogenic differentiation of bone marrow mesenchymal stem cells, while polarizing macrophages toward an anti-inflammatory M2 phenotype and substantially reducing intracellular ROS. In a rat rotator cuff repair model, high Ce-MBGN-loaded sutures significantly enhance fibrocartilaginous enthesis regeneration, increase bone mineral density and elevate M2 macrophage infiltration at the TBI. These regenerative effects correlate with suppressed HIF-1α expression in vivo, suggesting that localized redox modulation drives macrophage immunometabolic reprogramming to foster a pro-regenerative microenvironment. This Ce-MBGN-enabled interface engineering strategy simultaneously scavenges ROS, modulates immunity, and supports multi-lineage tissue regeneration at the TBI, offering a promising, clinically translatable approach for immunomodulatory suture design to improve rotator cuff repair outcomes.
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