自愈水凝胶
材料科学
组织工程
聚乙二醇
生物正交化学
纳米技术
细胞骨架
聚合物
生物物理学
生物医学工程
脚手架
再生医学
机械强度
肌球蛋白
再生(生物学)
体内
罗丹明
PEG比率
间充质干细胞
超细纤维
罗丹明B
细胞包封
干细胞
仿生学
作者
Juyeon Kim,Hanjun Hwangbo,Byung-Joon Choi,Dogeon Yoon,GeunHyung Kim
标识
DOI:10.1002/advs.202514319
摘要
Abstract Engineering mechanically resilient hydrogels from naturally derived proteins, such as collagen and gelatin, remains a key challenge in tissue regeneration, particularly when cell compatibility and structural integrity are simultaneously required. Here, a bioorthogonal crosslinking strategy using rhodamine and polyethylene glycol (PEG) is reported to fabricate dense, mechanically reinforced collagen hydrogels. PEG‐mediated dehydration induces spontaneous peptide bond formation between rhodamine and collagen without the need for additional catalysts, yielding fibrous protein networks with enhanced stiffness. To enable anisotropic tissue engineering, this crosslinking method is integrated with wet‐spinning to produce uniaxially aligned collagen filaments. These constructs exhibit high mechanical strength and support human adipose‐derived stem cell (hASC) encapsulation. Mechanotransductive signaling, including cytoskeletal organization and myogenic gene expression, is effectively activated within the aligned filaments. The applicability of cell‐laden filaments in a murine volumetric muscle loss model is demonstrated, which promoted in vitro differentiation and in vivo functional muscle regeneration. This strategy offers a scalable and cytocompatible platform for generating aligned protein‐based scaffolds with tunable mechanical and biological properties, thereby expanding the toolkit for regenerative medicine.
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