4.6 Article

Time-domain signal averaging to improve microparticles detection and enumeration accuracy in a microfluidic impedance cytometer

Journal

BIOTECHNOLOGY AND BIOENGINEERING
Volume 118, Issue 11, Pages 4428-4440

Publisher

WILEY
DOI: 10.1002/bit.27910

Keywords

disease diagnostics; microfluidics; point-of-care; signal processing

Funding

  1. National Science Foundation [2002511, 2053149]
  2. National Institutes of Health [T32 GM135141]
  3. Div Of Electrical, Commun & Cyber Sys
  4. Directorate For Engineering [2002511] Funding Source: National Science Foundation
  5. Div Of Electrical, Commun & Cyber Sys
  6. Directorate For Engineering [2053149] Funding Source: National Science Foundation

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The novel signal averaging algorithm effectively reduces noise in microfluidic impedance cytometry data, improving counting accuracy and lowering the detection limit. This technique enhances signal-to-noise ratio and accuracy across all experiments conducted, showing potential for next-generation devices with an expanded dynamic range and improved enumeration accuracy in biomedical applications.
Microfluidic impedance cytometry is a powerful system to measure micro and nano-sized particles and is routinely used in point-of-care disease diagnostics and other biomedical applications. However, small objects near a sensor's detection limit are plagued with relatively significant background noise and are difficult to identify for every case. While many data processing techniques can be utilized to reduce noise and improve signal quality, frequently they are still inadequate to push sensor detection limits. Here, we report the first demonstration of a novel signal averaging algorithm effective in noise reduction of microfluidic impedance cytometry data, improving enumeration accuracy, and reducing detection limits. Our device uses a 22 mu m tall x 100 mu m wide (with 30 mu m wide focused aperture) microchannel and gold coplanar microelectrodes that generate an electric field, recording bipolar pulses from polystyrene microparticles flowing through the channel. In addition to outlining a modified moving signal averaging technique theoretically and with a model data set, we also performed a compendium of characterization experiments including variations in flow rate, input voltage, and particle size. Multivariate metrics from each experiment are compared including signal amplitude, pulse width, background noise, and signal-to-noise ratio (SNR). Incorporating our technique resulted in improved SNR and counting accuracy across all experiments conducted, and the limit of detection improved from 5 to 1 mu m particles without modifying microchannel dimensions. Succeeding this, we envision implementing our modified moving average technique to develop next-generation microfluidic impedance cytometry devices with an expanded dynamic range and improved enumeration accuracy. This can be exceedingly useful for many biomedical applications, such as infectious disease diagnostics where devices may enumerate larger-scale immune cells alongside sub-micron bacterium in the same sample.

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