Design and Validation of a Device for Mitigating Fluid Microgravity Effects in Biological Research in Canister Spaceflight Hardware

Frontiers in Space Technologies Pub Date : 2021-12-22 DOI:10.3389/frspt.2021.797518

W. Nicholson, P. Fajardo-Cavazos, C. Turner, Taylor M. Currie, G. Gregory, T. Jurca, M. Weislogel

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引用次数: 1

Abstract

The major factor influencing the behavior of microbes growing in liquids in space is microgravity. We recently measured the transcriptomic response of the Gram-positive bacterium Bacillus subtilis to the microgravity environment inside the International Space Station (ISS) in spaceflight hardware called Biological Research in Canisters-Petri Dish Fixation Units (BRIC-PDFUs). In two separate experiments in the ISS, dubbed BRIC-21 and BRIC-23, we grew multiple replicates of the same B. subtilis strain in the same hardware, growth medium, and temperature with matching ground control samples (npj Micrograv. 5:1.2019, doi: 10.1038/s41526-018-0061-0). In both experiments we observed similar responses of the transcriptome to spaceflight. However, we also noted that the liquid cultures assumed a different configuration in microgravity (a toroidal shape) compared with the ground control samples (a flat disc shape), leading us to question whether the transcriptome differences we observed were a direct result of microgravity, or a secondary result of the different liquid geometries of the samples affecting, for example, oxygen availability. To mitigate the influence of microgravity on liquid geometry in BRIC canisters, we have designed an insert to replace the standard 60-mm Petri dish in BRIC-PDFU or BRIC-LED sample compartments. In this design, liquid cultures are expected to assume a more disk-like configuration regardless of gravity or its absence. We have: (i) constructed a prototype device by 3D printing; (ii) evaluated different starting materials, treatments, and coatings for their wettability (i.e., hydrophilicity) using contact angle measurements; (iii) confirmed that the device performs as designed by drop-tower testing and; (iv) performed material biocompatibility studies using liquid cultures of Bacillus subtilis and Staphylococcus aureus bacteria. Future microgravity testing of the device in the ISS is planned.

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在筒体航天硬件生物研究中减轻流体微重力效应装置的设计与验证

影响微生物在太空液体中生长行为的主要因素是微重力。我们最近测量了革兰氏阳性细菌枯草芽孢杆菌对国际空间站(ISS)内微重力环境的转录组反应，这是一种名为“罐子-培养皿固定装置生物研究”(BRIC-PDFUs)的航天硬件。在国际空间站的两个独立实验中，我们分别命名为BRIC-21和BRIC-23，在相同的硬件、生长介质和温度下，以匹配的地面对照样品培养了相同的枯草芽孢杆菌菌株的多个重复(npj Micrograv. 5:1.2019, doi: 10.1038/s41526-018-0061-0)。在这两个实验中，我们观察到转录组对太空飞行的相似反应。然而，我们也注意到，液体培养物在微重力下的结构(环形)与地面对照样品(扁平圆盘形状)不同，这让我们质疑，我们观察到的转录组差异是微重力的直接结果，还是影响样品不同液体几何形状的次要结果，例如，氧气的可用性。为了减轻微重力对BRIC罐中液体几何形状的影响，我们设计了一个插入物来取代BRIC- pdfu或BRIC- led样品室中标准的60毫米培养皿。在这种设计中，无论重力或无重力，液体培养物都有望呈现出更像圆盘的结构。我们已经:(i)通过3D打印构建了一个原型设备;(ii)使用接触角测量评估不同的起始材料、处理和涂层的润湿性(即亲水性);(iii)通过落塔测试确认装置的性能符合设计;(iv)使用枯草芽孢杆菌和金黄色葡萄球菌的液体培养物进行材料生物相容性研究。未来该设备将在国际空间站进行微重力测试。

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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Frontiers in Space Technologies

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