Enhancing signals of microfluidic impedance cytometry through optimization of microelectrode array

Chenyang Zhou; Hailong Shen; Huicheng Feng; Zhibin Yan; Bowen Ji; Xichen Yuan; Ruirong Zhang; Honglong Chang

doi:10.1002/elps.202100351

Enhancing signals of microfluidic impedance cytometry through optimization of microelectrode array

Chenyang Zhou, Hailong Shen, Huicheng Feng, Zhibin Yan, Bowen Ji, Xichen Yuan, Ruirong Zhang, Honglong Chang

Research output: Contribution to journal › Article › peer-review

5 Scopus citations

Abstract

Microfluidic impedance cytometry shows a great value in biomedical diagnosis. However, the crosstalk between neighboring microelectrodes strongly weakens the impedance signal. Hereby, we demonstrate a novel microfluidic impedance cytometer consisted of sensing electrodes and ground electrodes (GNDs). The simulation reveals a signal enhancement by more than five times with GNDs compared to that without ones. We also found that the linear correlation between the impedance at a high frequency and that at a low frequency varies as microparticle size changes, which can be used for microparticle classification. The study can help with microelectrode optimization and signal processing for microfluidic impedance analysis.

Original language	English
Pages (from-to)	2156-2164
Number of pages	9
Journal	Electrophoresis
Volume	43
Issue number	21-22
DOIs	https://doi.org/10.1002/elps.202100351
State	Published - Nov 2022

Keywords

impedance cytometry
microfluidics
single-cell analysis

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10.1002/elps.202100351

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abstract = "Microfluidic impedance cytometry shows a great value in biomedical diagnosis. However, the crosstalk between neighboring microelectrodes strongly weakens the impedance signal. Hereby, we demonstrate a novel microfluidic impedance cytometer consisted of sensing electrodes and ground electrodes (GNDs). The simulation reveals a signal enhancement by more than five times with GNDs compared to that without ones. We also found that the linear correlation between the impedance at a high frequency and that at a low frequency varies as microparticle size changes, which can be used for microparticle classification. The study can help with microelectrode optimization and signal processing for microfluidic impedance analysis.",

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AU - Zhou, Chenyang

AU - Shen, Hailong

AU - Feng, Huicheng

AU - Yan, Zhibin

AU - Ji, Bowen

AU - Yuan, Xichen

AU - Zhang, Ruirong

AU - Chang, Honglong

PY - 2022/11

Y1 - 2022/11

N2 - Microfluidic impedance cytometry shows a great value in biomedical diagnosis. However, the crosstalk between neighboring microelectrodes strongly weakens the impedance signal. Hereby, we demonstrate a novel microfluidic impedance cytometer consisted of sensing electrodes and ground electrodes (GNDs). The simulation reveals a signal enhancement by more than five times with GNDs compared to that without ones. We also found that the linear correlation between the impedance at a high frequency and that at a low frequency varies as microparticle size changes, which can be used for microparticle classification. The study can help with microelectrode optimization and signal processing for microfluidic impedance analysis.

AB - Microfluidic impedance cytometry shows a great value in biomedical diagnosis. However, the crosstalk between neighboring microelectrodes strongly weakens the impedance signal. Hereby, we demonstrate a novel microfluidic impedance cytometer consisted of sensing electrodes and ground electrodes (GNDs). The simulation reveals a signal enhancement by more than five times with GNDs compared to that without ones. We also found that the linear correlation between the impedance at a high frequency and that at a low frequency varies as microparticle size changes, which can be used for microparticle classification. The study can help with microelectrode optimization and signal processing for microfluidic impedance analysis.

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KW - single-cell analysis

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Enhancing signals of microfluidic impedance cytometry through optimization of microelectrode array

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Keywords

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