Study of a Microfluidic System Based One-Step Blood Cell-Free Region for Biomarker Detection

Volume 1: Fluid Mechanics Pub Date : 2019-11-20 DOI:10.1115/ajkfluids2019-5301

Anoop Kanjirakat, R. Sadr

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Abstract

Microfluidic systems are becoming common in the development of point-of-care (PoC) diagnostic systems where various methods are used to efficiently separate blood cells from whole blood. The goal of this research is to develop a passive plasma separator that can easily be integrated into an entire blood-based diagnosis microfluidic platform. In the present work, a one-step process of creating a cell-free region in the flow without the plasma being actively extracted from the whole blood is discussed. Centrifugal force together with a backward facing step is utilized to create a blood cell-free zone. Sensors (typically less than 10 micrometers in size) are proposed to be placed in the cell-free zones for biomarker detection. A detailed numerical study for the design of the microfluidic platform is reported. The two-phase nature of the blood is modeled using a discrete element method (DEM) where blood cells are modeled as spherical constituents with the inclusion of inter-particular interactions. The sizes of the cell-free zones in the microfluidic system are measured for various geometric and flow conditions. An expansion chamber with a larger aspect ratio together with a low Reynold number flow entering it is observed to create a larger cell-free zone.

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基于一步无血细胞区微流体系统的生物标志物检测研究

微流控系统在即时诊断系统(PoC)的发展中变得越来越普遍，其中各种方法被用来有效地从全血中分离血细胞。本研究的目标是开发一种被动血浆分离器，可以很容易地集成到整个血液诊断微流控平台中。在目前的工作中，一个一步的过程，在流动中创造一个无细胞区域，没有血浆被主动地从全血中提取讨论。离心力与向后的台阶一起被用来创造一个无血细胞区。传感器(通常尺寸小于10微米)被建议放置在无细胞区进行生物标志物检测。对微流控平台的设计进行了详细的数值研究。血液的两相性质使用离散元素方法(DEM)建模，其中血细胞被建模为包含特定间相互作用的球形成分。在不同的几何和流动条件下，测量了微流体系统中无细胞区的大小。观察到一个宽高比较大的膨胀室与低雷诺数流一起进入膨胀室可以产生更大的细胞无区。

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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Volume 1: Fluid Mechanics

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