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Automated interpretation of time-lapse quantitative phase image by machine learning to study cellular dynamics during epithelial-mesenchymal transition
L. Strbkova, BB. Carson, T. Vincent, P. Vesely, R. Chmelik
Language English Country United States
Document type Journal Article, Research Support, Non-U.S. Gov't
NLK
Directory of Open Access Journals
from 2019
PubMed Central
from 2009
Europe PubMed Central
from 2009 to 1 year ago
ProQuest Central
from 2019-01-01
ROAD: Directory of Open Access Scholarly Resources
from 1998
- MeSH
- Algorithms MeSH
- Time-Lapse Imaging MeSH
- Epithelial-Mesenchymal Transition * MeSH
- Holography * MeSH
- Machine Learning MeSH
- Publication type
- Journal Article MeSH
- Research Support, Non-U.S. Gov't MeSH
SIGNIFICANCE: Machine learning is increasingly being applied to the classification of microscopic data. In order to detect some complex and dynamic cellular processes, time-resolved live-cell imaging might be necessary. Incorporating the temporal information into the classification process may allow for a better and more specific classification. AIM: We propose a methodology for cell classification based on the time-lapse quantitative phase images (QPIs) gained by digital holographic microscopy (DHM) with the goal of increasing performance of classification of dynamic cellular processes. APPROACH: The methodology was demonstrated by studying epithelial-mesenchymal transition (EMT) which entails major and distinct time-dependent morphological changes. The time-lapse QPIs of EMT were obtained over a 48-h period and specific novel features representing the dynamic cell behavior were extracted. The two distinct end-state phenotypes were classified by several supervised machine learning algorithms and the results were compared with the classification performed on single-time-point images. RESULTS: In comparison to the single-time-point approach, our data suggest the incorporation of temporal information into the classification of cell phenotypes during EMT improves performance by nearly 9% in terms of accuracy, and further indicate the potential of DHM to monitor cellular morphological changes. CONCLUSIONS: Proposed approach based on the time-lapse images gained by DHM could improve the monitoring of live cell behavior in an automated fashion and could be further developed into a tool for high-throughput automated analysis of unique cell behavior.
Brno Univ of Technology Czech Republic
CEITEC Central European Institute of Technology Czech Republic
References provided by Crossref.org
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