Supervised machine learning in microfluidic impedance flow cytometry for improved particle size determination

Bruijn, Douwe S. de; Eikelder, Henricus R. A. ten; Papadimitriou, Vasileios A.; Olthuis, Wouter; Berg, Albert van den

doi:10.1002/cyto.a.24679

Cited by 7 publications

(5 citation statements)

References 22 publications

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“…157 For electroanalytical methods, there is a strong need for high-throughput real-time signal processing methods; in particular, the use of ML is of great interest to researchers, especially for the analysis of signals obtained with IFC. [158][159][160][161] While most of the studies are applied to the determination of electrical parameters of blood cells, cancer cells and bacteria, the use of these tools for the analysis of MPs has not yet been investigated. The analysis performed with IFC coupled with ML tools shows a promising future for the analysis of MPs for highthroughput applications.…”

Section: Future Trendsmentioning

confidence: 99%

When microplastics meet electroanalysis: future analytical trends for an emerging threat

Mosquera-Ortega,

Rodrigues de Sousa,

Susmel

et al. 2023

Anal. Methods

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Section: Future Trendsmentioning

confidence: 99%

When microplastics meet electroanalysis: future analytical trends for an emerging threat

Mosquera-Ortega,

Rodrigues de Sousa,

Susmel

et al. 2023

Anal. Methods

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“…AI models in single-cell biology aim to extract cellular features from different modalities, such as fluorescence microscopy images, 8 holographic flow cytometry images, 9 electrical signals, 10 RNA-seq, 11 or a combination of these. 12 According to whether the data are labeled, the model's training method is divided into supervised and unsupervised.…”

Section: Ai Models In Microfluidic Single-cell Biologymentioning

confidence: 99%

Enhancing single-cell biology through advanced AI-powered microfluidics

Gao,

2023

Biomicrofluidics

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Microfluidic technology has largely benefited both fundamental biological research and translational clinical diagnosis with its advantages in high-throughput, single-cell resolution, high integrity, and wide-accessibility. Despite the merits we obtained from microfluidics in the last two decades, the current requirement of intelligence in biomedicine urges the microfluidic technology to process biological big data more efficiently and intelligently. Thus, the current readout technology based on the direct detection of the signals in either optics or electrics was not able to meet the requirement. The implementation of artificial intelligence (AI) in microfluidic technology matches up with the large-scale data usually obtained in the high-throughput assays of microfluidics. At the same time, AI is able to process the multimodal datasets obtained from versatile microfluidic devices, including images, videos, electric signals, and sequences. Moreover, AI provides the microfluidic technology with the capability to understand and decipher the obtained datasets rather than simply obtaining, which eventually facilitates fundamental and translational research in many areas, including cell type discovery, cell signaling, single-cell genetics, and diagnosis. In this Perspective, we will highlight the recent advances in employing AI for single-cell biology and present an outlook on the future direction with more advanced AI algorithms.

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“…Considering cytometric measurement limitations, several papers in recent years have worked to establish correction factors to monitor cell location during measurement and improve the classification of particles based on positional compensation. These methods can either rely on the peak amplitude and spacing properties of the time domain cytometric measurement [31] or extracted parameters calculated from the initial measurements, such as opacity [28,30]. For these methods, the accuracy of the model is typically defined as the closeness to the distributive values of the measured parameters.…”

Section: Positional Dependency Compensationmentioning

confidence: 99%

Recent Approaches to Design and Analysis of Electrical Impedance Systems for Single Cells Using Machine Learning

Ferguson,

Zhang,

Palego

et al. 2023

Sensors

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Individual cells have many unique properties that can be quantified to develop a holistic understanding of a population. This can include understanding population characteristics, identifying subpopulations, or elucidating outlier characteristics that may be indicators of disease. Electrical impedance measurements are rapid and label-free for the monitoring of single cells and generate large datasets of many cells at single or multiple frequencies. To increase the accuracy and sensitivity of measurements and define the relationships between impedance and biological features, many electrical measurement systems have incorporated machine learning (ML) paradigms for control and analysis. Considering the difficulty capturing complex relationships using traditional modelling and statistical methods due to population heterogeneity, ML offers an exciting approach to the systemic collection and analysis of electrical properties in a data-driven way. In this work, we discuss incorporation of ML to improve the field of electrical single cell analysis by addressing the design challenges to manipulate single cells and sophisticated analysis of electrical properties that distinguish cellular changes. Looking forward, we emphasize the opportunity to build on integrated systems to address common challenges in data quality and generalizability to save time and resources at every step in electrical measurement of single cells.

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Supervised machine learning in microfluidic impedance flow cytometry for improved particle size determination

Cited by 7 publications

References 22 publications

When microplastics meet electroanalysis: future analytical trends for an emerging threat

When microplastics meet electroanalysis: future analytical trends for an emerging threat

Enhancing single-cell biology through advanced AI-powered microfluidics

Recent Approaches to Design and Analysis of Electrical Impedance Systems for Single Cells Using Machine Learning

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