3D-printed microplate inserts for long term high-resolution imaging of live brain organoids.

Mariana Oksdath Mansilla, Camilo Salazar-Hernandez, Sally L Perrin, Kaitlin G Scheer, Gökhan Cildir, John Toubia, Kristyna Sedivakova, Melinda N Tea, Sakthi Lenin, Elise Ponthier, Erica C F Yeo, Vinay Tergaonkar, Santosh Poonnoose, Rebecca J Ormsby, Stuart M Pitson, Michael P Brown, Lisa M Ebert, Guillermo A Gomez
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Abstract

Background: Organoids are a reliable model used in the study of human brain development and under pathological conditions. However, current methods for brain organoid culture generate tissues that range from 0.5 to 2 mm of size, which need to be constantly agitated to allow proper oxygenation. The culture conditions are, therefore, not suitable for whole-brain organoid live imaging, required to study developmental processes and disease progression within physiologically relevant time frames (i.e. days, weeks, months).

Results: Here we designed 3D-printed microplate inserts adaptable to standard 24 multi-well plates, which allow the growth of multiple organoids in pre-defined and fixed XYZ coordinates. This innovation facilitates high-resolution imaging of whole-cerebral organoids, allowing precise assessment of organoid growth and morphology, as well as cell tracking within the organoids, over long periods. We applied this technology to track neocortex development through neuronal progenitors in brain organoids, as well as the movement of patient-derived glioblastoma stem cells within healthy brain organoids.

Conclusions: This new bioengineering platform constitutes a significant advance that permits long term detailed analysis of whole-brain organoids using multimodal inverted fluorescence microscopy.

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用于活体脑器官长期高分辨率成像的 3D 打印微孔板插件。
背景:类器官是研究人脑发育和病理状态的可靠模型。然而,目前的脑有机体培养方法产生的组织大小从 0.5 毫米到 2 毫米不等,需要不断搅拌以保证适当的氧合。因此,这种培养条件不适合全脑类脑器官活体成像,而这是在生理相关的时间范围内(如几天、几周、几个月)研究发育过程和疾病进展所必需的:在此,我们设计了可与标准 24 孔多孔板相适应的三维打印微孔板插入物,可使多个类器官在预定义和固定的 XYZ 坐标上生长。这一创新有助于对整个大脑器质性组织进行高分辨率成像,从而可以对器质性组织的生长和形态进行精确评估,并对器质性组织内的细胞进行长期追踪。我们将这项技术应用于通过脑器质中的神经元祖细胞追踪新皮质的发育,以及健康脑器质中源自患者的胶质母细胞瘤干细胞的移动:结论:这一新的生物工程平台是一项重大进步,它允许使用多模态倒置荧光显微镜对整个脑有机体进行长期详细分析。
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