Aluminum Oxide-Coated Particle Differentiation Employing Supervised Machine Learning and Impedance Cytometry

Overview

Journal IEEE Int Conf Nano Micro Eng Mol Syst

Publisher IEEE

Date 2022 Jul 5

PMID 35782306

Authors

Brandon K Ashley

Jianye Sui

Mehdi Javanmard

Umer Hassan

Affiliations

Soon will be listed here.

Abstract

This article uses a supervised machine learning (ML) system for identifying groups of nanoparticles coated with metal oxides of varying thicknesses using a microfluidic impedance cytometer. These particles generate unique impedance signatures when probed with a multifrequency electric field and finds applications in enabling many multiplexed biosensing technologies. However, current experimental and data processing techniques are unable to sensitively differentiate different metal oxide coated particle types. Here, we employ various machine learning models and collect multiple particle metrics measured. In reported experiments, a 75% accuracy was determined to separate aluminum oxide coated (10nm and 30nm), which is significantly greater than observing only univariate data between different microparticle types. This approach will enable ML models to differentiate such particles with greater accuracies.

Citing Articles

Multi-modal sensing with integrated machine learning to differentiate specific leukocytes targeted by electrically sensitive hybrid particles.

Ashley B, Sui J, Javanmard M, Hassan U Biosens Bioelectron. 2023; 241:115661.

PMID: 37690356 PMC: 10977608. DOI: 10.1016/j.bios.2023.115661.

Nucleic Acid Quantification by Multi-Frequency Impedance Cytometry and Machine Learning.

Kokabi M, Sui J, Gandotra N, Pournadali Khamseh A, Scharfe C, Javanmard M Biosensors (Basel). 2023; 13(3).

PMID: 36979528 PMC: 10046493. DOI: 10.3390/bios13030316.

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