Automated analysis of phase-contrast optical microscopy time-lapse images: application to wound healing and cell motility assays of breast cancer

Yusuf Sait Erdem; Aydin Ayanzadeh; Berkay Mayalı; Muhammed Balıkçi; Özge Nur Belli; Mahmut Uçar; Özden Yalçın Özyusal; Devrim Pesen Okvur; Sevgi Önal; Kenan Morani; Leonardo Obinna Iheme; Behçet Uğur Töreyin; Devrim Ünay

doi:10.1016/B978-0-323-96129-5.00013-5

Automated analysis of phase-contrast optical microscopy time-lapse images: application to wound healing and cell motility assays of breast cancer

Yusuf Sait Erdem
, Aydin Ayanzadeh
, Berkay Mayalı
, Muhammed Balıkçi
, Özge Nur Belli
, Mahmut Uçar
, Özden Yalçın Özyusal
, Devrim Pesen Okvur
, Sevgi Önal
, Kenan Morani
, Leonardo Obinna Iheme
, Behçet Uğur Töreyin
, Devrim Ünay

Informatics Institute

Research output: Chapter in Book/Report/Conference proceeding › Chapter › peer-review

1 Citation (Scopus)

Abstract

This chapter describes a workflow for analyzing phase-contrast microscopy (PCM) data from two fundamental types of biomedical assays: assays for cell motility and assays for wound healing. The workflow of the analysis is composed of the methods for acquiring, restoring, segmenting, and quantifying biomedical data. In the literature, there have been separate methods aimed at specific stages of PCM data analysis. Nonetheless, there has never been a complete workflow for all stages of analysis. This work is an innovation that proposes an end-to-end workflow for image pre-processing, deep learning segmentation, tracking, and quantification stages in cell motility and wound healing assay analyses. The findings indicate that domain knowledge can be used to make simple but significant improvements to the results of cutting-edge methods. Furthermore, even for deep learning-based methods, pre-processing is clearly a necessary step in the workflow.

Original language	English
Title of host publication	Diagnostic Biomedical Signal and Image Processing Applications with Deep Learning Methods
Publisher	Elsevier
Pages	137-154
Number of pages	18
ISBN (Electronic)	9780323961295
ISBN (Print)	9780323996815
DOIs	https://doi.org/10.1016/B978-0-323-96129-5.00013-5
Publication status	Published - 1 Jan 2023

Bibliographical note

Publisher Copyright:
© 2023 Elsevier Inc. All rights reserved.

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 3 Good Health and Well-being

Keywords

Phase-contrast optical microscopy
breast cancer
cell motility
convolutional neural networks
image processing
pre-processing
quantification
segmentation
tracking
workflow
wound healing

Access to Document

10.1016/B978-0-323-96129-5.00013-5

Cite this

Erdem, Y. S., Ayanzadeh, A., Mayalı, B., Balıkçi, M., Belli, Ö. N., Uçar, M., Yalçın Özyusal, Ö., Pesen Okvur, D., Önal, S., Morani, K., Iheme, L. O., Töreyin, B. U., & Ünay, D. (2023). Automated analysis of phase-contrast optical microscopy time-lapse images: application to wound healing and cell motility assays of breast cancer. In Diagnostic Biomedical Signal and Image Processing Applications with Deep Learning Methods (pp. 137-154). Elsevier. https://doi.org/10.1016/B978-0-323-96129-5.00013-5

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title = "Automated analysis of phase-contrast optical microscopy time-lapse images: application to wound healing and cell motility assays of breast cancer",

abstract = "This chapter describes a workflow for analyzing phase-contrast microscopy (PCM) data from two fundamental types of biomedical assays: assays for cell motility and assays for wound healing. The workflow of the analysis is composed of the methods for acquiring, restoring, segmenting, and quantifying biomedical data. In the literature, there have been separate methods aimed at specific stages of PCM data analysis. Nonetheless, there has never been a complete workflow for all stages of analysis. This work is an innovation that proposes an end-to-end workflow for image pre-processing, deep learning segmentation, tracking, and quantification stages in cell motility and wound healing assay analyses. The findings indicate that domain knowledge can be used to make simple but significant improvements to the results of cutting-edge methods. Furthermore, even for deep learning-based methods, pre-processing is clearly a necessary step in the workflow.",

keywords = "Phase-contrast optical microscopy, breast cancer, cell motility, convolutional neural networks, image processing, pre-processing, quantification, segmentation, tracking, workflow, wound healing",

author = "Erdem, \{Yusuf Sait\} and Aydin Ayanzadeh and Berkay Mayalı and Muhammed Balık{\c c}i and Belli, \{{\"O}zge Nur\} and Mahmut U{\c c}ar and \{Yal{\c c}ın {\"O}zyusal\}, {\"O}zden and \{Pesen Okvur\}, Devrim and Sevgi {\"O}nal and Kenan Morani and Iheme, \{Leonardo Obinna\} and T{\"o}reyin, \{Beh{\c c}et Uğur\} and Devrim {\"U}nay",

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doi = "10.1016/B978-0-323-96129-5.00013-5",

language = "English",

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Erdem, YS, Ayanzadeh, A, Mayalı, B, Balıkçi, M, Belli, ÖN, Uçar, M, Yalçın Özyusal, Ö, Pesen Okvur, D, Önal, S, Morani, K, Iheme, LO, Töreyin, BU & Ünay, D 2023, Automated analysis of phase-contrast optical microscopy time-lapse images: application to wound healing and cell motility assays of breast cancer. in Diagnostic Biomedical Signal and Image Processing Applications with Deep Learning Methods. Elsevier, pp. 137-154. https://doi.org/10.1016/B978-0-323-96129-5.00013-5

Automated analysis of phase-contrast optical microscopy time-lapse images: application to wound healing and cell motility assays of breast cancer. / Erdem, Yusuf Sait; Ayanzadeh, Aydin; Mayalı, Berkay et al.
Diagnostic Biomedical Signal and Image Processing Applications with Deep Learning Methods. Elsevier, 2023. p. 137-154.

Research output: Chapter in Book/Report/Conference proceeding › Chapter › peer-review

TY - CHAP

T1 - Automated analysis of phase-contrast optical microscopy time-lapse images

T2 - application to wound healing and cell motility assays of breast cancer

AU - Erdem, Yusuf Sait

AU - Ayanzadeh, Aydin

AU - Mayalı, Berkay

AU - Balıkçi, Muhammed

AU - Belli, Özge Nur

AU - Uçar, Mahmut

AU - Yalçın Özyusal, Özden

AU - Pesen Okvur, Devrim

AU - Önal, Sevgi

AU - Morani, Kenan

AU - Iheme, Leonardo Obinna

AU - Töreyin, Behçet Uğur

AU - Ünay, Devrim

PY - 2023/1/1

Y1 - 2023/1/1

N2 - This chapter describes a workflow for analyzing phase-contrast microscopy (PCM) data from two fundamental types of biomedical assays: assays for cell motility and assays for wound healing. The workflow of the analysis is composed of the methods for acquiring, restoring, segmenting, and quantifying biomedical data. In the literature, there have been separate methods aimed at specific stages of PCM data analysis. Nonetheless, there has never been a complete workflow for all stages of analysis. This work is an innovation that proposes an end-to-end workflow for image pre-processing, deep learning segmentation, tracking, and quantification stages in cell motility and wound healing assay analyses. The findings indicate that domain knowledge can be used to make simple but significant improvements to the results of cutting-edge methods. Furthermore, even for deep learning-based methods, pre-processing is clearly a necessary step in the workflow.

AB - This chapter describes a workflow for analyzing phase-contrast microscopy (PCM) data from two fundamental types of biomedical assays: assays for cell motility and assays for wound healing. The workflow of the analysis is composed of the methods for acquiring, restoring, segmenting, and quantifying biomedical data. In the literature, there have been separate methods aimed at specific stages of PCM data analysis. Nonetheless, there has never been a complete workflow for all stages of analysis. This work is an innovation that proposes an end-to-end workflow for image pre-processing, deep learning segmentation, tracking, and quantification stages in cell motility and wound healing assay analyses. The findings indicate that domain knowledge can be used to make simple but significant improvements to the results of cutting-edge methods. Furthermore, even for deep learning-based methods, pre-processing is clearly a necessary step in the workflow.

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KW - breast cancer

KW - cell motility

KW - convolutional neural networks

KW - image processing

KW - pre-processing

KW - quantification

KW - segmentation

KW - tracking

KW - workflow

KW - wound healing

UR - https://www.scopus.com/pages/publications/85161175350

U2 - 10.1016/B978-0-323-96129-5.00013-5

DO - 10.1016/B978-0-323-96129-5.00013-5

M3 - Chapter

AN - SCOPUS:85161175350

SN - 9780323996815

SP - 137

EP - 154

BT - Diagnostic Biomedical Signal and Image Processing Applications with Deep Learning Methods

PB - Elsevier

ER -

Erdem YS, Ayanzadeh A, Mayalı B, Balıkçi M, Belli ÖN, Uçar M et al. Automated analysis of phase-contrast optical microscopy time-lapse images: application to wound healing and cell motility assays of breast cancer. In Diagnostic Biomedical Signal and Image Processing Applications with Deep Learning Methods. Elsevier. 2023. p. 137-154 doi: 10.1016/B978-0-323-96129-5.00013-5

Automated analysis of phase-contrast optical microscopy time-lapse images: application to wound healing and cell motility assays of breast cancer

Abstract

Bibliographical note

UN SDGs

Keywords

Access to Document

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