Automated classification of cell morphology by coherence-controlled holographic microscopy

Štrbková, Lenka; Zicha, Daniel; Veselý, Pavel; Chmelík, Radim

doi:10.1117/1.jbo.22.8.086008

Cited by 22 publications

(24 citation statements)

References 35 publications

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“…Whole-slide digital pathology (50) and a high-throughput well-plate culture imaging techniques (51,52) require robust, automated methods to identify cells of clinical interest. The classification accuracy from this study of 90-100% is high, similar to other reported values using machine-learning algorithms trained on optical phase map data (8,49,53). A leaveone-out classification analysis (Supporting Information Table S2) suggested predictive power derived from most of the 17 parameters, which could be reduced to five to six principal components, in accordance with other studies (2,8,49).…”

Section: Discussionsupporting

confidence: 89%

“…A leaveone-out classification analysis (Supporting Information Table S2) suggested predictive power derived from most of the 17 parameters, which could be reduced to five to six principal components, in accordance with other studies (2,8,49). Taken together, these results indicate that phase parameters from the pixel histogram and gray-level co-occurrence matrix, as well as cell outline-based morphology features (8,32,53), help to classify adherent cell lines. Combining "two-dimensional" and "three-dimensional" phase parameters into signatures input to machine learning makes the algorithm more flexible, as geometric/two-dimensional parameters are likely more important for classifying cell lines of dissimilar shape, and higher-order parameters more important for classifying cell lines of similar shape.…”

Section: Discussionsupporting

confidence: 86%

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Machine Learning with Optical Phase Signatures for Phenotypic Profiling of Cell Lines

et al. 2019

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Robust and reproducible profiling of cell lines is essential for phenotypic screening assays. The goals of this study were to determine robust and reproducible optical phase signatures of cell lines for classification with machine learning and to correlate optical phase parameters to motile behavior. Digital holographic microscopy (DHM) reconstructed phase maps of cells from two pairs of cancer and non‐cancer cell lines. Seventeen image parameters were extracted from each cell's phase map, used for linear support vector machine learning, and correlated to scratch wound closure and Boyden chamber chemotaxis. The classification accuracy was between 90% and 100% for the six pairwise cell line comparisons. Several phase parameters correlated with wound closure rate and chemotaxis across the four cell lines. The level of cell confluence in culture affected phase parameters in all cell lines tested. Results indicate that optical phase features of cell lines are a robust set of quantitative data of potential utility for phenotypic screening and prediction of motile behavior. © 2019 International Society for Advancement of Cytometry

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Section: Discussionsupporting

confidence: 89%

Section: Discussionsupporting

confidence: 86%

Machine Learning with Optical Phase Signatures for Phenotypic Profiling of Cell Lines

et al. 2019

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“…and ). The eleven quantitative parameters from this study overlap in part with morphological and phase parameters found to be useful in other DHM studies of cancer cells . Several other groups using holographic microscopy techniques have tracked migrating cancer cells , and identified phase textures of adherent cancer cells .…”

Section: Discussionmentioning

confidence: 66%

“…Numerous learning approaches are available and have been used on DHM data sets, including deep learning neural networks to distinguish SW480 colon cancer cells in suspension from white blood cells , anthrax from related microorganisms , and to detect and compensate for DHM background and phase aberrations . Machine learning paired with DHM has also recently been used to detect red blood cell infection by P. falciparum , discriminate between isogenic cell lines of differing metastatic stage , distinguish cancer grades from prostate biopsy microarrays , and distinguish healthy and nutrient‐deprived cancer cells , and live and dead yeast cells . Recent commentaries and reviews highlight recent studies combining these two techniques to advance cancer research .…”

Section: Discussionmentioning

confidence: 99%

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Quantitative assessment of cancer cell morphology and motility using telecentric digital holographic microscopy and machine learning

et al. 2017

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The noninvasive, fast acquisition of quantitative phase maps using digital holographic microscopy (DHM) allows tracking of rapid cellular motility on transparent substrates. On two-dimensional surfaces in vitro, MDA-MB-231 cancer cells assume several morphologies related to the mode of migration and substrate stiffness, relevant to mechanisms of cancer invasiveness in vivo. The quantitative phase information from DHM may accurately classify adhesive cancer cell subpopulations with clinical relevance. To test this, cells from the invasive breast cancer MDA-MB-231 cell line were cultured on glass, tissue-culture treated polystyrene, and collagen hydrogels, and imaged with DHM followed by epifluorescence microscopy after staining F-actin and nuclei. Trends in cell phase parameters were tracked on the different substrates, during cell division, and during matrix adhesion, relating them to F-actin features. Support vector machine learning algorithms were trained and tested using parameters from holographic phase reconstructions and cell geometric features from conventional phase images, and used to distinguish between elongated and rounded cell morphologies. DHM was able to distinguish between elongated and rounded morphologies of MDA-MB-231 cells with 94% accuracy, compared to 83% accuracy using cell geometric features from conventional brightfield microscopy. This finding indicates the potential of DHM to detect and monitor cancer cell morphologies relevant to cell cycle phase status, substrate adhesion, and motility. © 2017 International Society for Advancement of Cytometry.

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Morphology, Motility, and Cytoskeletal Architecture of Breast Cancer Cells Depend on Keratin 19 and Substrate

et al. 2020

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Cancer cells gain motility through events that accompany modulation of cell shape and include altered expression of keratins. However, the role of keratins in change of cancer cell architecture is not well understood. Therefore, we ablated the expression of keratin 19 (K19) in breast cancer cells of the MDA-MB-231 cell line and found that cells lacking K19 become more elongated in culture, with morphological reversion toward the parental phenotype upon transduction of KRT19. Also, the number of actin stress fibers and focal adhesions were significantly reduced in KRT19 knockout (KO) cells. The altered morphology of KRT19 KO cells was then characterized quantitatively using digital holographic microscopy (DHM), which not only confirmed the phenotypic change of KRT19 KO cells but also identified that the K19-dependent morphological change is dependent on the substrate type. A new quantitative method of single cell analysis from DHM, via average phase difference maps, facilitated evaluation of K19-substrate interactive effects on cell morphology. When plated on collagen substrate, KRT19 KO cells were less elongated and resembled parental cells. Assessing single cell motility further showed that while KRT19 KO cells moved faster than parental cells on a rigid surface, this increase in motility became abrogated when cells were plated on collagen. Overall, our study suggests that K19 inhibits cell motility by regulating cell shape in a substrate-dependent manner. Thus, this study provides a potential basis for the altered expression of keratins associated with change in cell shape and motility of cancer cells.

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Automated classification of cell morphology by coherence-controlled holographic microscopy

Cited by 22 publications

References 35 publications

Machine Learning with Optical Phase Signatures for Phenotypic Profiling of Cell Lines

Machine Learning with Optical Phase Signatures for Phenotypic Profiling of Cell Lines

Quantitative assessment of cancer cell morphology and motility using telecentric digital holographic microscopy and machine learning

Morphology, Motility, and Cytoskeletal Architecture of Breast Cancer Cells Depend on Keratin 19 and Substrate

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