类有机物
自愈水凝胶
粘弹性
组织工程
基质(化学分析)
间充质干细胞
材料科学
纳米技术
细胞外基质
生物物理学
纤维蛋白
生物系统
细胞生物学
化学
生物医学工程
生物
医学
高分子化学
复合材料
作者
Yu‐Hsuan Peng,Syuan‐Ku Hsiao,Krishna Gupta,André Ruland,Günter K. Auernhammer,Manfred F. Maitz,Susanne Boye,Johanna Lattner,Claudia Gerri,Alf Honigmann,Carsten Werner,Elisha Krieg
标识
DOI:10.1038/s41565-023-01483-3
摘要
Three-dimensional cell and organoid cultures rely on the mechanical support of viscoelastic matrices. However, commonly used matrix materials lack control over key cell-instructive properties. Here we report on fully synthetic hydrogels based on DNA libraries that self-assemble with ultrahigh-molecular-weight polymers, forming a dynamic DNA-crosslinked matrix (DyNAtrix). DyNAtrix enables computationally predictable and systematic control over its viscoelasticity, thermodynamic and kinetic parameters by changing DNA sequence information. Adjustable heat activation allows homogeneous embedding of mammalian cells. Intriguingly, stress-relaxation times can be tuned over four orders of magnitude, recapitulating mechanical characteristics of living tissues. DyNAtrix is self-healing, printable, exhibits high stability, cyto- and haemocompatibility, and controllable degradation. DyNAtrix-based cultures of human mesenchymal stromal cells, pluripotent stem cells, canine kidney cysts and human trophoblast organoids show high viability, proliferation and morphogenesis. DyNAtrix thus represents a programmable and versatile precision matrix for advanced approaches to biomechanics, biophysics and tissue engineering.
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