An Open-Source 3D-Printed Recording Stage with Customizable Chambers for Ex Vivo Experiments.

IF 2.7 3区医学 Q3 NEUROSCIENCES

eNeuro Pub Date : 2024-09-13 Print Date: 2024-09-01 DOI:10.1523/ENEURO.0257-24.2024

Preston C Withers, Hunter J Morrill, R Ryley Parrish

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Abstract

Much of what has been discovered concerning neurophysiological mechanisms can be credited to ex vivo biomedical experiments. Beyond these discoveries, ex vivo research techniques have enhanced the global understanding of human physiology and pathology in almost every biomedical specialty. Naturally, ex vivo experiments are among the most desired methods of research, particularly in the field of neuroscience. Ex vivo experiment platforms may be purchased commercially. However, their substantial cost and sometimes limited availability can render them inaccessible to many research labs. Moreover, these manufactured systems are often rigid in function with no possibility of customization, severely narrowing their capabilities. However, developing essential components for ex vivo laboratory systems with a fused deposition modeling printer provides a practical solution to each of these obstacles. Here, we provide the designs and construction process for an easily accessible, highly adaptable recording stage with modifiable submersion chambers using a 3D printer for a total cost under $15.00. With the versatility afforded by the exchangeable custom chambers, the system may be used to conduct research on a variety of ex vivo tissue preparations, paving the way for novel research.

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一种开源 3D 打印记录平台，带有用于体内外实验的可定制腔室。

有关神经生理学机制的许多发现都要归功于体外生物医学实验。除了这些发现之外，体外研究技术还增进了全球对几乎所有生物医学专业领域的人体生理和病理的了解。当然，体外实验是最受欢迎的研究方法之一，尤其是在神经科学领域。体外实验平台可以通过商业途径购买。然而，由于其成本高昂，有时供应有限，许多研究实验室无法使用。此外，这些人工制造的系统通常功能僵化，无法进行定制，严重限制了它们的功能。然而，利用熔融沉积建模（FDM）打印机开发体内外实验室系统的重要组件，为上述障碍提供了切实可行的解决方案。在这里，我们提供了一个易于使用、适应性强的记录台的设计和制造过程，该记录台带有可修改的浸没室，使用三维打印机制造，总成本不到 15 美元。由于可更换的定制腔室提供了多功能性，该系统可用于对各种体外组织制备物进行研究，为新研究铺平了道路。重要声明动物模型的体外研究技术对于大多数医学领域的持续研究至关重要，有关神经元生理学的大部分发现都可归功于此类实验。尽管市场上的设计已被证明非常有用，但由于成本高昂，一些研究人员可能很难获得这些设计。此外，这些系统的实验能力往往受到限制，无法进行修改。我们提出了一种可三维打印的设计，这种设计随时可用、价格低廉、适应性强、完全可定制，能够以有意义的方式推进关键研究。

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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来源期刊

eNeuro Neuroscience-General Neuroscience

CiteScore

5.00

自引率

2.90%

发文量

486

审稿时长

16 weeks

期刊介绍： An open-access journal from the Society for Neuroscience, eNeuro publishes high-quality, broad-based, peer-reviewed research focused solely on the field of neuroscience. eNeuro embodies an emerging scientific vision that offers a new experience for authors and readers, all in support of the Society’s mission to advance understanding of the brain and nervous system.