用于神经类器官内非侵入性电生理学的网状微电极阵列。

A mesh microelectrode array for non-invasive electrophysiology within neural organoids.

作者信息

McDonald Matthew, Sebinger David, Brauns Lisa, Gonzalez-Cano Laura, Menuchin-Lasowski Yotam, Mierzejewski Michael, Psathaki Olympia-Ekaterini, Stumpf Angelika, Wickham Jenny, Rauen Thomas, Schöler Hans, Jones Peter D

机构信息

NMI Natural and Medical Sciences Institute at the University of Tübingen, Markwiesenstr. 55, 72770, Reutlingen, Germany; Max Planck Institute for Molecular Biomedicine, Röntgenstr. 20, 48149, Münster, Germany.

Max Planck Institute for Molecular Biomedicine, Röntgenstr. 20, 48149, Münster, Germany.

出版信息

Biosens Bioelectron. 2023 May 15;228:115223. doi: 10.1016/j.bios.2023.115223. Epub 2023 Mar 11.

DOI:10.1016/j.bios.2023.115223

PMID:36931193

Abstract

Organoids are emerging in vitro models of human physiology. Neural models require the evaluation of functional activity of single cells and networks, which is commonly measured by microelectrode arrays. The characteristics of organoids clash with existing in vitro or in vivo microelectrode arrays. With inspiration from implantable mesh electronics and growth of organoids on polymer scaffolds, we fabricated suspended hammock-like mesh microelectrode arrays for neural organoids. We have demonstrated the growth of organoids enveloping these meshes and the culture of organoids on meshes for up to one year. Furthermore, we present proof-of-principle recordings of spontaneous electrical activity across the volume of an organoid. Our concept enables a new class of microelectrode arrays for in vitro models of three-dimensional electrically active tissue.

摘要

类器官是新兴的人体生理学体外模型。神经模型需要评估单细胞和神经网络的功能活性，这通常通过微电极阵列进行测量。类器官的特性与现有的体外或体内微电极阵列存在冲突。受可植入网状电子器件以及类器官在聚合物支架上生长的启发，我们制造了用于神经类器官的悬浮吊床状网状微电极阵列。我们已经证明了类器官围绕这些网格的生长以及类器官在网格上长达一年的培养。此外，我们展示了跨类器官体积的自发电活动的原理验证记录。我们的概念为三维电活性组织的体外模型带来了一类新型微电极阵列。

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用于神经类器官内非侵入性电生理学的网状微电极阵列。

A mesh microelectrode array for non-invasive electrophysiology within neural organoids.

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