Mechanically programming anisotropy in engineered muscle with actuating extracellular matrices

Device Pub Date : 2023-10-01 DOI:10.1016/j.device.2023.100097

Brandon Rios, Angel Bu, Tara Sheehan, Hiba Kobeissi, Sonika Kohli, Karina Shah, Emma Lejeune, Ritu Raman

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引用次数: 3

Abstract

The hierarchical design and adaptive functionalities of biological tissues are driven by dynamic biochemical, electrical, and mechanical signaling between cells and their extracellular matrices. While existing tools enable monitoring and controlling biochemical and electrical signaling in multicellular systems, there is a significant need for techniques that enable mapping and modulating intercellular mechanical signaling. We have developed a magnetically actuated extracellular matrix that serves as a mechanically active substrate for cells and can program morphological and functional anisotropy in tissues such as skeletal muscle. This method improves the ease and efficiency of programming muscle force directionality and synchronicity for applications ranging from medicine to robotics. Additionally, we present an open-source computational framework enabling quantitative analyses of muscle contractility. Our actuating matrices and accompanying tools are broadly applicable across cell types and hydrogel chemistries, and they can drive fundamental studies in mechanobiology as well as translational applications of engineered tissues in medicine and machines.

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机械编程的各向异性工程肌肉与驱动细胞外基质

生物组织的分层设计和自适应功能是由细胞及其细胞外基质之间的动态生化、电和机械信号驱动的。虽然现有的工具能够监测和控制多细胞系统中的生化和电信号，但仍然需要能够绘制和调节细胞间机械信号的技术。我们已经开发了一种磁驱动的细胞外基质，作为细胞的机械活性基质，可以编程组织(如骨骼肌)的形态和功能各向异性。该方法提高了从医学到机器人等应用程序编程肌肉力量方向性和同步性的便利性和效率。此外，我们提出了一个开源的计算框架，可以定量分析肌肉收缩性。我们的驱动基质和配套工具广泛适用于各种细胞类型和水凝胶化学，它们可以推动机械生物学的基础研究以及工程组织在医学和机器中的转化应用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Device

CiteScore

0.70

自引率

0.00%

发文量