High-throughput bioprinting to produce micropatterned neuroepithelial tissues and model TSC2-deficient brain malformations.

IF 4.5 Q1 BIOCHEMICAL RESEARCH METHODS

Cell Reports Methods Pub Date : 2025-09-17 DOI:10.1016/j.crmeth.2025.101177

Negin Imani Farahani, Kenneth Kin Lam Wong, George Allen, Abhimanyu Minhas, Lisa Lin, Shama Nazir, Lisa M Julian

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Abstract

In vitro human pluripotent stem cell (hPSC)-derived models have been crucial in advancing our understanding of the mechanisms underlying neurodevelopment, though knowledge of the earliest stages of brain formation is lacking. Micropatterning of cell populations as they transition from pluripotency through the process of neurulation can produce self-assembled neuroepithelial tissues (NETs) with precise spatiotemporal control, enhancing the fidelity of hPSC models to the early developing human brain and their use in phenotypic assessments. Here, we introduce an accessible, customizable, and scalable method to produce self-assembled NETs using bioprinting to rapidly deposit reproducibly sized extracellular matrix droplets. Matrix addition to the media provides a scaffold that promotes 3D tissue folding, reflecting neural tube development. We demonstrate that these scaffolded NETs (scNETs) exhibit key architectural and biological features of the human brain during normal and abnormal development-notably, hyperproliferation and structural malformations induced by TSC2 deficiency-and provide a robust drug screening tool.

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利用高通量生物打印技术制造微图案化神经上皮组织和tsc2缺陷脑畸形模型。

体外人类多能干细胞（hPSC）衍生的模型在促进我们对神经发育机制的理解方面至关重要，尽管对大脑形成的最早阶段还缺乏了解。细胞群从多能性到神经发育过程的微模式化可以产生具有精确时空控制的自组装神经上皮组织（NETs），从而提高了hPSC模型对早期发育的人类大脑的保真度及其在表型评估中的应用。在这里，我们介绍了一种可访问的、可定制的、可扩展的方法，利用生物打印技术快速沉积可重复大小的细胞外基质液滴来生产自组装的NETs。基质添加到介质中提供了一个支架，促进3D组织折叠，反映神经管的发育。我们证明了这些支架NETs （scNETs）在正常和异常发育期间表现出人类大脑的关键结构和生物学特征，特别是由TSC2缺陷引起的过度增殖和结构畸形，并提供了一个强大的药物筛选工具。

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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