自愈水凝胶
丝绸
组织工程
C2C12型
材料科学
肌发生
蜘蛛丝
诱导多能干细胞
药物输送
收缩率
生物物理学
细胞粘附
生物医学工程
粘附
心肌细胞
纳米技术
化学
细胞生物学
胚胎干细胞
复合材料
生物化学
高分子化学
生物
基因
医学
作者
Xuen Jen Ng,Tilman U. Esser,Vanessa T. Trossmann,C. Rudisch,Maren Fiedler,Kaveh Roshanbinfar,Zan Lamberger,Philipp Stahlhut,Gregor Lang,Thomas Scheibel,Felix B. Engel
标识
DOI:10.1002/adhm.202500311
摘要
Tissue engineering enables the production of tissues and organ-like structures as models for drug testing and mechanistical studies or functional replacements for injured tissues. Available cytocompatible materials are limited in number, suffer from insufficient mechanical properties, and cells interacting with them often cause construct shrinkage. As shape is important for function, identifying cytocompatible, shrink-resistant materials are a major aim. Here, it is shown that hydrogels made of interpenetrating networks of collagen-I and recombinant spider silk protein eADF4(C16)-RGD nanofibrils exhibit synergistic and tunable mechanical properties. Composite hydrogels allow cell adhesion and spreading and are resistant to shrinkage mediated by fibroblasts, C2C12 myoblasts, and human induced pluripotent stem cell (hiPSC)-derived cardiomyocytes. Myoblasts differentiate and fuse into myotubes, and hiPSC-cardiomyocytes can be cultured long-term, show spontaneous contractions, and remain drug responsive. Collectively, a novel composite material is developed to overcome the challenge of post-fabrication matrix shrinkage conferring high shape fidelity suitable for tissue engineering.
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