微型三维神经元培养物产生类似发育中皮层的活动模式。

Micro Three-Dimensional Neuronal Cultures Generate Developing Cortex-Like Activity Patterns.

作者信息

Ming Yixuan, Hasan Md Fayad, Tatic-Lucic Svetlana, Berdichevsky Yevgeny

机构信息

Department of Electrical & Computer Engineering, Lehigh University, Bethlehem, PA, United States.

Department of Bioengineering, Lehigh University, Bethlehem, PA, United States.

出版信息

Front Neurosci. 2020 Oct 2;14:563905. doi: 10.3389/fnins.2020.563905. eCollection 2020.

DOI:10.3389/fnins.2020.563905

PMID:33122989

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7573570/

Abstract

Studies aimed at neurological drug discovery have been carried out both and . cell culture models have showed potential as drug testing platforms characterized by high throughput, low cost, good reproducibility and ease of handling and observation. However, neuronal culture models are facing challenges in replicating -like activity patterns. This work reports an culture technique that is capable of producing micro three-dimensional (μ3D) cultures of only a few tens of neurons. The μ3D cultures generated by this method were uniform in size and density of neurons. These μ3D cultures had complex spontaneous synchronized neuronal activity patterns which were similar to those observed in the developing cortex and in much larger 3D cultures, but not in 2D cultures. Bursts could be reliably evoked by stimulation of single neurons. Synchronized bursts in μ3D cultures were abolished by inhibitors of glutamate receptors, while inhibitors of GABA receptors had a more complex effect. This pharmacological profile is similar to bursts in neonatal cortex. Since large numbers of reproducible μ3D cultures can be created and observed in parallel, this model of the developing cortex may find applications in high-throughput drug discovery experiments.

摘要

针对神经药物研发的研究已经在多个方面展开。细胞培养模型已显示出作为药物测试平台的潜力，其特点是高通量、低成本、良好的可重复性以及易于操作和观察。然而，神经元培养模型在复制类似的活动模式方面面临挑战。这项工作报告了一种培养技术，该技术能够产生仅由几十个神经元组成的微型三维（μ3D）培养物。通过这种方法产生的μ3D培养物在神经元的大小和密度上是均匀的。这些μ3D培养物具有复杂的自发同步神经元活动模式，这与在发育中的皮层以及大得多的三维培养物中观察到的模式相似，但在二维培养物中则没有。通过刺激单个神经元可以可靠地诱发爆发。μ3D培养物中的同步爆发被谷氨酸受体抑制剂消除，而γ-氨基丁酸（GABA）受体抑制剂则具有更复杂的作用。这种药理学特征与新生儿皮层中的爆发相似。由于可以并行创建和观察大量可重复的μ3D培养物，这种发育中皮层的模型可能会在高通量药物发现实验中找到应用。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/22da/7573570/c2abe651afa6/fnins-14-563905-g001.jpg

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微型三维神经元培养物产生类似发育中皮层的活动模式。

Micro Three-Dimensional Neuronal Cultures Generate Developing Cortex-Like Activity Patterns.

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