Aquavert: Imaging and Microfluidics for Vertical Swimming of Microorganisms

Haley B. Obenshain, Isaias Zarate, Olivia Hedman-Manzano, Jared Goderich, Sungho Lee, Bryant A. Lopez, Emma Varela, Ga-Young Kelly Suh, Douglas A. Pace, Siavash Ahrar
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Abstract

Investigating aquatic microorganisms' swimming and feeding behaviors under well-controlled conditions is of great interest across multiple disciplines. Thus, broader access to resources that enable these investigations is desirable. Given the organisms' microscopic dimensions, an ideal system should combine microscopy to visualize and fluidics to control and modulate their environments. We report an integrated device (Aquavert) that combines DIY microscopy and microfluidics for biomechanical investigations of marine microorganisms, emphasizing vertical swimming. The DIY microscope was developed for modularity, and imaging chambers were secured in vertical orientations (either in portrait or landscape mode). Fluid channels were used to introduce flow and fluid segmentation while remaining upright. Fluid segmentation established two distinct environments (e.g., with and without algae) in neighboring regions inside a chamber. System application with multiple marine larvae (sand dollars, sea urchins, and starfish) and introduction of unicellular algae were demonstrated. Finally, the device's capabilities were extended to fluorescence imaging to visualize tracer beads. The role of gravity is often ignored in conventional plate or microfluidic experiments. Beyond the current application, Aquavert enables investigations of the behavior and physiology of microorganisms where the role of gravity is critical.
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Aquavert:用于微生物垂直游动的成像和微流体技术
在控制良好的条件下研究水生微生物的游泳和摄食行为是多个学科都非常感兴趣的问题。因此,我们需要更广泛地获取资源,以便开展这些研究。考虑到生物的微观尺寸,理想的系统应结合显微镜来观察,并结合流体力学来控制和调节其环境。我们报告了一种集成设备(Aquavert),它结合了 DIY 显微镜和微流体技术,用于海洋微生物的生物力学研究,重点是垂直游泳。DIY 显微镜采用模块化设计,成像室以垂直方向固定(纵向或横向模式)。流体通道用于引入流动和流体分割,同时保持直立。流体分割在成像室内部相邻区域建立了两种不同的环境(例如,有藻类和无藻类)。演示了该系统在多种海洋幼虫(沙元、海胆和海星)中的应用以及单细胞藻类的引入。最后,该装置的功能还扩展到了荧光成像,以观察示踪珠。在传统的平板或微流控实验中,重力的作用往往被忽视。除了目前的应用外,Aquavert 还能对微生物的行为和生理进行研究,其中重力的作用至关重要。
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