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用于离心微流控的低成本无线摄像成像系统的设计与制造。

Design and fabrication of a low-cost wireless camera imaging system for centrifugal microfluidics.

作者信息

Regan Brian, Kinahan David, Daly Philip, O'Kennedy Richard, Collins David

机构信息

School of Biotechnology, Dublin City University, Dublin 9, Ireland.

School of Mechanical Engineering, Dublin City University, Dublin 9, Ireland.

出版信息

HardwareX. 2022 Jan 8;11:e00259. doi: 10.1016/j.ohx.2022.e00259. eCollection 2022 Apr.

DOI:10.1016/j.ohx.2022.e00259
PMID:35509901
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9058586/
Abstract

Centrifugal microfluidic devices offer a robust method for low-volume fluid handling by combining low-cost instrumentation with highly integrated automation. Crucial to the efficacy of Lab-on-a-Disc (LoaD) device operation is the selection of robust valving technology, the design of on-disc fluidic structures, and accurate control of disc spin-speeds (centrifugal force) during operation. The design and refinement of fluidic and valving structures is often guided by inspecting disc operation using high-speed camera systems. This approach involves synchronising image acquisition with disc rotation to visualise liquid flow through a series of images often presented in a video format. Depending on the decisions taken, such systems can cost from €4,000 upwards. This paper outlines the development of a low-cost centrifugal test-stand with an integrated imaging system using a generic wireless camera to record videos directly to a smartphone device. This imaging system can be fabricated using only 3D printers and a low-cost CNC milling machine from widely available materials for approximately €350. High-fidelity imaging of the entire disc for flow visualisation and the recording of real-time colour intensity measurements are facilitated by this standalone device. A vibration analysis study has been performed to determine the rotational velocity range at which the system can be safely operated. Furthermore, the efficacy of the imaging system has been demonstrated by performing real-time colour intensity measurements of dyed water dilutions.

摘要

离心微流控设备通过将低成本仪器与高度集成的自动化相结合,提供了一种用于小体积流体处理的强大方法。对于盘式实验室(LoaD)设备的有效运行而言,关键在于选择可靠的阀控技术、盘上流体结构的设计以及操作过程中对盘旋转速度(离心力)的精确控制。流体和阀控结构的设计与优化通常通过使用高速相机系统检查盘的运行情况来指导。这种方法涉及将图像采集与盘的旋转同步,以通过一系列通常以视频格式呈现的图像来可视化液体流动。根据所做的决策,此类系统的成本可能从4000欧元起。本文概述了一种低成本离心试验台的开发,该试验台配备了一个集成成像系统,使用普通无线摄像头直接将视频记录到智能手机设备上。这种成像系统仅使用3D打印机和低成本的数控铣床,用广泛可得的材料制造,成本约为350欧元。这种独立设备便于对整个盘进行高保真成像以实现流动可视化,并记录实时颜色强度测量值。已经进行了振动分析研究,以确定系统能够安全运行的转速范围。此外,通过对染色水稀释液进行实时颜色强度测量,证明了成像系统的有效性。

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