Related papers: MIML: Multiplex Image Machine Learning for High Precision Cell Classification via Mechanical Traits within Microfluidic Systems

MIML: Multiplex Image Machine Learning for High Precision Cell Classification via Mechanical Traits within Microfluidic Systems

URL: http://arxiv.org/abs/2309.08421v2
Date: Wed, 24 Jan 2024 20:25:02 GMT
Title: MIML: Multiplex Image Machine Learning for High Precision Cell Classification via Mechanical Traits within Microfluidic Systems
Authors: Khayrul Islam, Ratul Paul, Shen Wang, and Yaling Liu
Abstract summary: We develop a novel machine learning framework, Multiplex Image Machine Learning (MIML) MIML combines label-free cell images with biomechanical property data, harnessing the vast, often underutilized morphological information intrinsic to each cell. This approach has led to a remarkable 98.3% accuracy in cell classification, a substantial improvement over models that only consider a single data type.
Score: 1.1675184588181313
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Label-free cell classification is advantageous for supplying pristine cells for further use or examination, yet existing techniques frequently fall short in terms of specificity and speed. In this study, we address these limitations through the development of a novel machine learning framework, Multiplex Image Machine Learning (MIML). This architecture uniquely combines label-free cell images with biomechanical property data, harnessing the vast, often underutilized morphological information intrinsic to each cell. By integrating both types of data, our model offers a more holistic understanding of the cellular properties, utilizing morphological information typically discarded in traditional machine learning models. This approach has led to a remarkable 98.3\% accuracy in cell classification, a substantial improvement over models that only consider a single data type. MIML has been proven effective in classifying white blood cells and tumor cells, with potential for broader application due to its inherent flexibility and transfer learning capability. It's particularly effective for cells with similar morphology but distinct biomechanical properties. This innovative approach has significant implications across various fields, from advancing disease diagnostics to understanding cellular behavior.

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