类有机物
组织工程
材料科学
生物医学工程
纳米技术
细胞外基质
3D生物打印
计算机科学
生物材料
挤压
光学透明度
应力松弛
基质(化学分析)
自愈水凝胶
微尺度化学
动态松弛
生物材料
再生医学
形态发生
作者
Austin J. Graham,Michelle W. L. Khoo,Vasudha Srivastava,Sara Viragova,Honesty Kim,Kavita Parekh,Kelsey M. Hennick,Malia Bird,Nadine Goldhammer,Jie Zeng Yu,Grace Hu,Natasha T. Brinkley,Lucas Antonio Pardo,Jasmine S. Amaya,Cameron D. Morley,Nishant Chadha,Paul Lebel,Sanjay Kumar,Jennifer M. Rosenbluth,Tomasz J. Nowakowski
标识
DOI:10.1038/s41563-026-02519-4
摘要
Complex and robust tissue self-organization requires defined initial conditions and dynamic boundaries-neighbouring tissues and extracellular matrix that actively evolve to guide morphogenesis. A major challenge in tissue engineering is identifying material properties that are compatible with controlling initial culture conditions while mimicking dynamic tissue boundaries. Here we describe a highly tunable granular biomaterial, MAGIC matrix, that supports both long-term bioprinting and gold-standard tissue self-organization. We identify that significant stress relaxation at the long timescales and large deformation magnitudes relevant to self-organization is required for optimal morphogenesis. We apply optimized MAGIC matrices toward precise extrusion bioprinting of saturated cell suspensions directly into three-dimensional culture. Carefully controlling initial conditions for tissue growth yields dramatic increases in organoid reproducibility and complexity across multiple tissue types, enabling high-throughput generation of organoid arrays and perfusable three-dimensional microphysiological systems. Our results identify key biomaterial parameters for optimal organoid morphogenesis and lay the foundation for fabricating more complex and reproducible self-organized tissues.
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