Hydrogel Mechanics Influence Growth and Development of Embedded Brain Organoids

Camille S. Cassel de Camps, Saba Aslani, Nicholas Stylianesis, Harris Nami, Nguyen-Vi Mohamed, T. Durcan, C. Moraes
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引用次数: 13

Abstract

Brain organoids are three-dimensional, tissue-engineered neural models derived from induced pluripotent stem cells that enable studies of neurodevelopmental and disease processes. Mechanical properties of the microenvironment are known to be critical parameters in tissue engineering, but the mechanical consequences of the encapsulating matrix on brain organoid growth and development remain undefined. Here, Matrigel® was modified with an interpenetrating network (IPN) of alginate, to tune the mechanical properties of the encapsulating matrix. Brain organoid grown in IPNs were viable, with characteristic formation of neuroepithelial buds. However, organoid growth was significantly restricted in the stiffest matrix tested. Moreover, stiffer matrices skewed cell populations towards mature neuronal phenotypes; with fewer and smaller neural rosettes. These findings demonstrate that mechanics of the culture environment are important parameters in brain organoid development, and show that the self-organizing capacity and subsequent architecture of brain organoids can be modulated by forces arising from growth-induced compression of the surrounding matrix. This study therefore suggests that carefully designing the mechanical properties of organoid encapsulation materials is a potential strategy to direct organoid growth and maturation towards desired structures.
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水凝胶力学对嵌入式脑类器官生长发育的影响
脑类器官是由诱导多能干细胞衍生的三维组织工程神经模型,可用于神经发育和疾病过程的研究。众所周知,微环境的机械特性是组织工程中的关键参数,但封装基质对脑类器官生长和发育的机械影响仍不明确。在这里,用海藻酸盐的互穿网络(IPN)修饰Matrigel®,以调整封装矩阵的机械性能。在ipn中生长的脑类器官是可存活的,具有特征性的神经上皮芽形成。然而,在最硬的基质中,类器官的生长明显受到限制。此外,较硬的基质使细胞群向成熟的神经元表型倾斜;神经结越来越少,越来越小。这些发现表明,培养环境的机制是脑类器官发育的重要参数,并表明脑类器官的自组织能力和后续结构可以通过生长诱导的周围基质压缩产生的力来调节。因此,这项研究表明,仔细设计类器官封装材料的机械性能是指导类器官生长和成熟的潜在策略。
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