Development of a Microfluidic Flow Cytometer with a Uniform Optical Field (Uni-μFCM) Enabling Quantitative Analysis of Single-Cell Proteins and Its Applications in Leukemia Gating, Tumor Classification, and Hierarchy of Cancer Stem Cells

[Image: see text] Fast and quantitative estimation of single-cell proteins with various distribution patterns remains a technical challenge. Here, a microfluidic flow cytometer with a uniform optical field (Uni-μFCM) was developed, which enabled the translation of multicolor fluorescence signals of...

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Autores principales: Gao, Chiyuan, Zhang, Ting, Wei, Yuanchen, Liu, Qinghua, Ma, Liangliang, Gao, Mengge, Zhao, Xiaosu, Wang, Yixiang, Chen, Deyong, Sun, Lichao, Wang, Junbo, Chen, Jian
Formato: Online Artículo Texto
Lenguaje:English
Publicado: American Chemical Society 2023
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10521140/
https://www.ncbi.nlm.nih.gov/pubmed/37602731
http://dx.doi.org/10.1021/acssensors.3c01060
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author Gao, Chiyuan
Zhang, Ting
Wei, Yuanchen
Liu, Qinghua
Ma, Liangliang
Gao, Mengge
Zhao, Xiaosu
Wang, Yixiang
Chen, Deyong
Sun, Lichao
Wang, Junbo
Chen, Jian
author_facet Gao, Chiyuan
Zhang, Ting
Wei, Yuanchen
Liu, Qinghua
Ma, Liangliang
Gao, Mengge
Zhao, Xiaosu
Wang, Yixiang
Chen, Deyong
Sun, Lichao
Wang, Junbo
Chen, Jian
author_sort Gao, Chiyuan
collection PubMed
description [Image: see text] Fast and quantitative estimation of single-cell proteins with various distribution patterns remains a technical challenge. Here, a microfluidic flow cytometer with a uniform optical field (Uni-μFCM) was developed, which enabled the translation of multicolor fluorescence signals of bound antibodies into targeted protein numbers with arbitrary distributions of biological cells. As the core of Uni-μFCM, a uniform optical field for optical excitation and fluorescence detection was realized by adopting a microfabricated metal window to shape the optical beam for excitation, which was modeled and validated by both numerical simulation and experimental characterization. After the validation of Uni-μFCM in single-cell protein quantification by measuring single-cell expressions of three transcriptional factors from four cell lines of variable sizes and origins, Uni-μFCM was applied to (1) quantify membrane and cytoplasmic markers of myeloid and lymphocytic leukocytes to classify cell lines and normal and patient blood samples; (2) measure single-cell expressions of key cytokines affiliated with gene stabilities, differentiating paired oral and colon tumor cell lines with varied malignancies, and (3) quantify single-cell stemming markers of liver tumor cell lines, cell subtypes, and liver patient samples to determine a variety of lineage hierarchy. By quantitatively assessing complex cellular phenotypes, Uni-μFCM substantially expanded the phenotypic space accessible to single-cell applications in leukemia gating, tumor classification, and hierarchy determination of cancer stem cells.
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spelling pubmed-105211402023-09-27 Development of a Microfluidic Flow Cytometer with a Uniform Optical Field (Uni-μFCM) Enabling Quantitative Analysis of Single-Cell Proteins and Its Applications in Leukemia Gating, Tumor Classification, and Hierarchy of Cancer Stem Cells Gao, Chiyuan Zhang, Ting Wei, Yuanchen Liu, Qinghua Ma, Liangliang Gao, Mengge Zhao, Xiaosu Wang, Yixiang Chen, Deyong Sun, Lichao Wang, Junbo Chen, Jian ACS Sens [Image: see text] Fast and quantitative estimation of single-cell proteins with various distribution patterns remains a technical challenge. Here, a microfluidic flow cytometer with a uniform optical field (Uni-μFCM) was developed, which enabled the translation of multicolor fluorescence signals of bound antibodies into targeted protein numbers with arbitrary distributions of biological cells. As the core of Uni-μFCM, a uniform optical field for optical excitation and fluorescence detection was realized by adopting a microfabricated metal window to shape the optical beam for excitation, which was modeled and validated by both numerical simulation and experimental characterization. After the validation of Uni-μFCM in single-cell protein quantification by measuring single-cell expressions of three transcriptional factors from four cell lines of variable sizes and origins, Uni-μFCM was applied to (1) quantify membrane and cytoplasmic markers of myeloid and lymphocytic leukocytes to classify cell lines and normal and patient blood samples; (2) measure single-cell expressions of key cytokines affiliated with gene stabilities, differentiating paired oral and colon tumor cell lines with varied malignancies, and (3) quantify single-cell stemming markers of liver tumor cell lines, cell subtypes, and liver patient samples to determine a variety of lineage hierarchy. By quantitatively assessing complex cellular phenotypes, Uni-μFCM substantially expanded the phenotypic space accessible to single-cell applications in leukemia gating, tumor classification, and hierarchy determination of cancer stem cells. American Chemical Society 2023-08-21 /pmc/articles/PMC10521140/ /pubmed/37602731 http://dx.doi.org/10.1021/acssensors.3c01060 Text en © 2023 The Authors. Published by American Chemical Society https://creativecommons.org/licenses/by-nc-nd/4.0/Permits non-commercial access and re-use, provided that author attribution and integrity are maintained; but does not permit creation of adaptations or other derivative works (https://creativecommons.org/licenses/by-nc-nd/4.0/).
spellingShingle Gao, Chiyuan
Zhang, Ting
Wei, Yuanchen
Liu, Qinghua
Ma, Liangliang
Gao, Mengge
Zhao, Xiaosu
Wang, Yixiang
Chen, Deyong
Sun, Lichao
Wang, Junbo
Chen, Jian
Development of a Microfluidic Flow Cytometer with a Uniform Optical Field (Uni-μFCM) Enabling Quantitative Analysis of Single-Cell Proteins and Its Applications in Leukemia Gating, Tumor Classification, and Hierarchy of Cancer Stem Cells
title Development of a Microfluidic Flow Cytometer with a Uniform Optical Field (Uni-μFCM) Enabling Quantitative Analysis of Single-Cell Proteins and Its Applications in Leukemia Gating, Tumor Classification, and Hierarchy of Cancer Stem Cells
title_full Development of a Microfluidic Flow Cytometer with a Uniform Optical Field (Uni-μFCM) Enabling Quantitative Analysis of Single-Cell Proteins and Its Applications in Leukemia Gating, Tumor Classification, and Hierarchy of Cancer Stem Cells
title_fullStr Development of a Microfluidic Flow Cytometer with a Uniform Optical Field (Uni-μFCM) Enabling Quantitative Analysis of Single-Cell Proteins and Its Applications in Leukemia Gating, Tumor Classification, and Hierarchy of Cancer Stem Cells
title_full_unstemmed Development of a Microfluidic Flow Cytometer with a Uniform Optical Field (Uni-μFCM) Enabling Quantitative Analysis of Single-Cell Proteins and Its Applications in Leukemia Gating, Tumor Classification, and Hierarchy of Cancer Stem Cells
title_short Development of a Microfluidic Flow Cytometer with a Uniform Optical Field (Uni-μFCM) Enabling Quantitative Analysis of Single-Cell Proteins and Its Applications in Leukemia Gating, Tumor Classification, and Hierarchy of Cancer Stem Cells
title_sort development of a microfluidic flow cytometer with a uniform optical field (uni-μfcm) enabling quantitative analysis of single-cell proteins and its applications in leukemia gating, tumor classification, and hierarchy of cancer stem cells
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10521140/
https://www.ncbi.nlm.nih.gov/pubmed/37602731
http://dx.doi.org/10.1021/acssensors.3c01060
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