Dielectrophoresis Separation of Platelets Using a Novel Zigzag Microchannel

• Published in: Micromachines (Basel) Vol. 11; no. 10; p. 890
• Main Authors: Guan, Yanfang, Liu, Yansheng, Lei, Hui, Liu, Shihua, Xu, Fengqian, Meng, Xiangxin, Bai, Mingyang, Wang, Xiaoliang, Yang, Gexuan
• Format: Journal Article
• Language: English
• Published: Basel MDPI AG 25.09.2020; MDPI
• Subjects: Acoustics; Blood; Blood platelets; Dielectrophoresis; Electric fields; Electric potential; Electrodes; Engraving; Experimentation; Flow velocity; Inlets; Laboratories; Lasers; Lipids; Medical research; Microchannels; Optimization; Platelets; Red blood cells (RBCs); Separation; Simulation; Software packages; Straight channels; Voltage; zigzag-shape microchannel; United States > US; China
• ISSN: 2072-666X; 2072-666X
• DOI: 10.3390/mi11100890

Platelet separation and purification are required in many applications including in the detection and treatment of hemorrhagic and thrombotic diseases, in addition to transfusions and in medical research. In this study, platelet separation was evaluated using a novel zigzag microchannel fluidic device while leveraging a dielectrophoresis (DEP) electric field using the COMSOL multiphysics software package and additional experimentation. The zigzag-shaped microchannel was superior to straight channel devices for cell separation because the sharp corners reduced the required horizontal distance needed for separation and also contributed to an asymmetric DEP electric field. A perfect linear relationship was observed between the separation distance and the corner angles. A quadratic relationship (R2 = 0.99) was observed between the driving voltage and the width and the lengths of the channel, allowing for optimization of these properties. In addition, the voltage was inversely proportional to the channel width and proportional to the channel length. An optimal velocity ratio of 1:4 was identified for the velocities of the two device inlets. The proposed device was fabricated using laser engraving and lithography with optimized structures including a 0.5 mm channel width, a 120° corner angle, a 0.3 mm channel depth, and a 17 mm channel length. A separation efficiency of 99.4% was achieved using a voltage of 20 V and a velocity ratio of 1:4. The easy fabrication, lower required voltage, label-free detection, high efficiency, and environmental friendliness of this device make it suitable for point-of-care medicine and biological applications. Moreover, it can be used for the separation of other types of compounds including lipids.