Label-Free Leukemia Monitoring by Computer Vision

Minh Doan; Marian Case; Dino Masic; Holger Hennig; Claire McQuin; Juan Caicedo; Shantanu Singh; Allen Goodman; Olaf Wolkenhauer; Huw D. Summers; David Jamieson; Frederik V. Delft; Andrew Filby; Anne E. Carpenter; Paul Rees; Julie Irving

doi:10.1002/cyto.a.23987

Label-Free Leukemia Monitoring by Computer Vision

Minh Doan, Marian Case, Dino Masic, Holger Hennig, Claire McQuin, Juan Caicedo, Shantanu Singh, Allen Goodman, Olaf Wolkenhauer, Huw D. Summers, David Jamieson, Frederik V. Delft, Andrew Filby, Anne E. Carpenter^*, Paul Rees, Julie Irving

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

45 Scopus citations

Abstract

Acute lymphoblastic leukemia (ALL) is the most common childhood cancer. While there are a number of well-recognized prognostic biomarkers at diagnosis, the most powerful independent prognostic factor is the response of the leukemia to induction chemotherapy (Campana and Pui: Blood 129 (2017) 1913–1918). Given the potential for machine learning to improve precision medicine, we tested its capacity to monitor disease in children undergoing ALL treatment. Diagnostic and on-treatment bone marrow samples were labeled with an ALL-discriminating antibody combination and analyzed by imaging flow cytometry. Ignoring the fluorescent markers and using only features extracted from bright-field and dark-field cell images, a deep learning model was able to identify ALL cells at an accuracy of >88%. This antibody-free, single cell method is cheap, quick, and could be adapted to a simple, laser-free cytometer to allow automated, point-of-care testing to detect slow early responders. Adaptation to other types of leukemia is feasible, which would revolutionize residual disease monitoring.

Original language	English
Pages (from-to)	407-414
Number of pages	8
Journal	Cytometry Part A
Volume	97
Issue number	4
DOIs	https://doi.org/10.1002/cyto.a.23987
State	Published - 1 Apr 2020
Externally published	Yes

Keywords

computer vision
deep learning
imaging flow cytometry
label-free
leukemia
machine learning
neural networks

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10.1002/cyto.a.23987

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title = "Label-Free Leukemia Monitoring by Computer Vision",

abstract = "Acute lymphoblastic leukemia (ALL) is the most common childhood cancer. While there are a number of well-recognized prognostic biomarkers at diagnosis, the most powerful independent prognostic factor is the response of the leukemia to induction chemotherapy (Campana and Pui: Blood 129 (2017) 1913–1918). Given the potential for machine learning to improve precision medicine, we tested its capacity to monitor disease in children undergoing ALL treatment. Diagnostic and on-treatment bone marrow samples were labeled with an ALL-discriminating antibody combination and analyzed by imaging flow cytometry. Ignoring the fluorescent markers and using only features extracted from bright-field and dark-field cell images, a deep learning model was able to identify ALL cells at an accuracy of >88\%. This antibody-free, single cell method is cheap, quick, and could be adapted to a simple, laser-free cytometer to allow automated, point-of-care testing to detect slow early responders. Adaptation to other types of leukemia is feasible, which would revolutionize residual disease monitoring.",

keywords = "computer vision, deep learning, imaging flow cytometry, label-free, leukemia, machine learning, neural networks",

author = "Minh Doan and Marian Case and Dino Masic and Holger Hennig and Claire McQuin and Juan Caicedo and Shantanu Singh and Allen Goodman and Olaf Wolkenhauer and Summers, \{Huw D.\} and David Jamieson and Delft, \{Frederik V.\} and Andrew Filby and Carpenter, \{Anne E.\} and Paul Rees and Julie Irving",

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year = "2020",

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doi = "10.1002/cyto.a.23987",

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AU - Doan, Minh

AU - Case, Marian

AU - Masic, Dino

AU - Hennig, Holger

AU - McQuin, Claire

AU - Caicedo, Juan

AU - Singh, Shantanu

AU - Goodman, Allen

AU - Wolkenhauer, Olaf

AU - Summers, Huw D.

AU - Jamieson, David

AU - Delft, Frederik V.

AU - Filby, Andrew

AU - Carpenter, Anne E.

AU - Rees, Paul

AU - Irving, Julie

PY - 2020/4/1

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N2 - Acute lymphoblastic leukemia (ALL) is the most common childhood cancer. While there are a number of well-recognized prognostic biomarkers at diagnosis, the most powerful independent prognostic factor is the response of the leukemia to induction chemotherapy (Campana and Pui: Blood 129 (2017) 1913–1918). Given the potential for machine learning to improve precision medicine, we tested its capacity to monitor disease in children undergoing ALL treatment. Diagnostic and on-treatment bone marrow samples were labeled with an ALL-discriminating antibody combination and analyzed by imaging flow cytometry. Ignoring the fluorescent markers and using only features extracted from bright-field and dark-field cell images, a deep learning model was able to identify ALL cells at an accuracy of >88%. This antibody-free, single cell method is cheap, quick, and could be adapted to a simple, laser-free cytometer to allow automated, point-of-care testing to detect slow early responders. Adaptation to other types of leukemia is feasible, which would revolutionize residual disease monitoring.

AB - Acute lymphoblastic leukemia (ALL) is the most common childhood cancer. While there are a number of well-recognized prognostic biomarkers at diagnosis, the most powerful independent prognostic factor is the response of the leukemia to induction chemotherapy (Campana and Pui: Blood 129 (2017) 1913–1918). Given the potential for machine learning to improve precision medicine, we tested its capacity to monitor disease in children undergoing ALL treatment. Diagnostic and on-treatment bone marrow samples were labeled with an ALL-discriminating antibody combination and analyzed by imaging flow cytometry. Ignoring the fluorescent markers and using only features extracted from bright-field and dark-field cell images, a deep learning model was able to identify ALL cells at an accuracy of >88%. This antibody-free, single cell method is cheap, quick, and could be adapted to a simple, laser-free cytometer to allow automated, point-of-care testing to detect slow early responders. Adaptation to other types of leukemia is feasible, which would revolutionize residual disease monitoring.

KW - computer vision

KW - deep learning

KW - imaging flow cytometry

KW - label-free

KW - leukemia

KW - machine learning

KW - neural networks

UR - https://www.scopus.com/pages/publications/85082746430

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DO - 10.1002/cyto.a.23987

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VL - 97

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EP - 414

JO - Cytometry Part A

JF - Cytometry Part A

IS - 4

ER -

Label-Free Leukemia Monitoring by Computer Vision

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