2020
DOI: 10.1007/s00216-020-02497-9
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A neural network approach for real-time particle/cell characterization in microfluidic impedance cytometry

Abstract: Microfluidic applications such as active particle sorting or selective enrichment require particle classification techniques that are capable of working in real time. In this paper, we explore the use of neural networks for fast label-free particle characterization during microfluidic impedance cytometry. A recurrent neural network is designed to process data from a novel impedance chip layout for enabling real-time multiparametric analysis of the measured impedance data streams. As demonstrated with both synt… Show more

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Cited by 69 publications
(54 citation statements)
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“…Most of the presented devices have shown the ability to deal with size heterogeneous samples. Beyond that, it is also possible to provide cell/particle position and accurate characterization at the same time 45,138,140,141 .…”
Section: Conclusion On Methods To Detect Cell/particle Positionmentioning
confidence: 99%
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“…Most of the presented devices have shown the ability to deal with size heterogeneous samples. Beyond that, it is also possible to provide cell/particle position and accurate characterization at the same time 45,138,140,141 .…”
Section: Conclusion On Methods To Detect Cell/particle Positionmentioning
confidence: 99%
“…In 2019, this method was also used to measure the position of particles before and after DEP focusing 128 . More recently, Honrado et al 140 used the new wiring scheme in two consecutive facing pairs of electrodes to measure both the lateral position and the height. The implementation of artificial intelligence approaches instead of classical curve fitting helped to fasten dramatically the extraction of the size, cross-sectional position and velocity from the data obtained.…”
Section: Facing Electrodesmentioning
confidence: 99%
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“…Once the machine learning algorithm builds predicted data of dielectric spectra, one can then backtrack the DEP device parameters. Similarly, Honrado et al [ 131 ] used machine learning to evaluate and record electrical fingerprints for the accurate detection of thousands of red blood cells and yeasts [ 131 ]. The work by Lannin and Honrado [ 128 , 130 , 131 ] shows that machine learning can be employed in the iDEP device as well, since the only integration with the device is the image based analysis and data management with the predictable machine learning algorithms.…”
Section: Knowledge Gaps and Future Directionsmentioning
confidence: 99%
“…Similarly, Honrado et al [ 131 ] used machine learning to evaluate and record electrical fingerprints for the accurate detection of thousands of red blood cells and yeasts [ 131 ]. The work by Lannin and Honrado [ 128 , 130 , 131 ] shows that machine learning can be employed in the iDEP device as well, since the only integration with the device is the image based analysis and data management with the predictable machine learning algorithms. We believe that in the near future, integrating machine learning with real-time data analysis in a DEP device will further enhance our understanding of fluid micro-environments, enabling the optimized manipulation of biological specimens and prediction of sample parameters, such as polarization rate of proteins and dielectric spectra of cells.…”
Section: Knowledge Gaps and Future Directionsmentioning
confidence: 99%