On-chip Mixing, Pumping and Concentrating Effects by Using AC Electrothermal Flow

R. H. Vafaie
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Abstract

Microfluidic manipulation (including: pumping, mixing and concentrating effects) is highly challengeable for bioengineering and on-chip analysis applications such as point-of-care immune-detection systems. In this research we propose a configurable electrode structure to form various manipulation effects including pumping, mixing and concentrating processes by applying an Alternate Current (AC) electrokinetically-driven flow.By applying an inhomogeneous electric field causes temperature rise accompanied by temperature gradients generation inside the microchannel. As a result, an AC electrothermal flow generates inside the channel, which is efficient to generate mixing, pumping and concentrating effects.The proposed system is studied numerically by Finite-Element-Method, Based on the results, a) bulk fluid velocity of 100 µm/s is achieved by exciting the electrodes in pumping mode, b) complete mixing efficiency is observed in mixing mode, c) for antibody-antigen binding process (concentrating mode), the surface reaction increases by the factor of 9 after 5 seconds of sample loading. Results reveal that the system is highly efficient for bio-fluid mediums.AC electrothermal fluid manipulation process was investigated numerically inside a microchannel for biological buffers. Back and forth fluid motions, clockwise/counter-clockwise rotational vortexes and also antibody-antigen linking enhancement were achieved by engineering the specific electrode patterns. The manipulation efficiency improves by increasing both the amplitude of electric potential and the ionic strength of biofluid. As a result, our proposed configurable device is of interest for onchip immunoassays and point-of-care devices.
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利用交流电热流对片内混合、泵送和浓缩的影响
微流控操作(包括:泵送,混合和浓缩效应)对生物工程和芯片上分析应用(如即时免疫检测系统)具有高度挑战性。在这项研究中,我们提出了一种可配置的电极结构,通过应用交流(AC)电动驱动流来形成各种操作效果,包括泵送,混合和浓缩过程。通过施加非均匀电场使微通道内温度升高并产生温度梯度。因此,通道内产生交流电热流,有效地产生混合、泵送和浓缩效果。采用有限元法对该系统进行了数值模拟研究,结果表明:a)在泵送模式下激励电极可获得100 μ m/s的体流体速度;b)在混合模式下观察到完全的混合效率;c)在抗体-抗原结合过程(浓缩模式)中,样品加载5秒后表面反应增加了9倍。结果表明,该系统对生物流体介质具有较高的处理效率。对生物缓冲液微通道内的交流电热流体处理过程进行了数值研究。通过设计特定的电极模式,实现了前后流体运动,顺时针/逆时针旋转漩涡以及抗体-抗原连接增强。通过增加生物流体的电位振幅和离子强度来提高操作效率。因此,我们提出的可配置设备对片上免疫测定和护理点设备很感兴趣。
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