Cell segmentation methods for label-free contrast microscopy: review and comprehensive comparison

Vičar, Tomáš; Balvan, Jan; Jaroš, Josef; Jug, Florian; Kolář, Radim; Masařík, Michal; Gumulec, Jaromír

doi:10.1186/s12859-019-2880-8

Cited by 158 publications

(102 citation statements)

References 63 publications

Supporting

Mentioning

102

Contrasting

Order By: Relevance

“…Furthermore, there has been an increased appreciation for the morphological information label-free approaches can provide as a result of algorithmic-based phenotyping. 20-22…”

Section: Methodsmentioning

confidence: 99%

A Self-Supervised Machine Learning Approach for Objective Live Cell Segmentation and Analysis

Robitaille¹,

Byers²,

Christodoulides³

et al. 2021

Preprint

View full text Add to dashboard Cite

Machine learning algorithms hold the promise of greatly improving live cell image analysis by way of (1) analyzing far more imagery than can be achieved by more traditional manual approaches and (2) by eliminating the subjective nature of researchers and diagnosticians selecting the cells or cell features to be included in the analyzed data set. Currently, however, even the most sophisticated model based or machine learning algorithms require user supervision, meaning the subjectivity problem is not removed but rather incorporated into the algorithm’s initial training steps and then repeatedly applied to the imagery. To address this roadblock, we have developed a self-supervised machine learning algorithm that recursively trains itself directly from the live cell imagery data, thus providing objective segmentation and quantification. The approach incorporates an optical flow algorithm component to self-label cell and background pixels for training, followed by the extraction of additional feature vectors for the automated generation of a cell/background classification model. Because it is self-trained, the software has no user-adjustable parameters and does not require curated training imagery. The algorithm was applied to automatically segment cells from their background for a variety of cell types and five commonly used imaging modalities - fluorescence, phase contrast, differential interference contrast (DIC), transmitted light and interference reflection microscopy (IRM). The approach is broadly applicable in that it enables completely automated cell segmentation for long-term live cell phenotyping applications, regardless of the input imagery’s optical modality, magnification or cell type.

show abstract

“…Furthermore, there has been an increased appreciation for the morphological information label-free approaches can provide as a result of algorithmic-based phenotyping. 20-22…”

Section: Methodsmentioning

confidence: 99%

A Self-Supervised Machine Learning Approach for Objective Live Cell Segmentation and Analysis

Robitaille¹,

Byers²,

Christodoulides³

et al. 2021

Preprint

View full text Add to dashboard Cite

show abstract

“…In addition to spot detection, spatially resolved transcriptomics necessitates the ability to distinguish individual and adjacent cells from each other, and a way to characterize the distribution of FISH spots across individual cells. While there are a large number of cell segmentation tools available (reviewed in Meijering, 2012 and Vicar et al, 2019 ), the automated segmentation of densely packed cells and nuclei, either in a cultured monolayer or intact tissue sections remains a challenge. Potential solutions to this may also lie in machine learning and network-based approaches (for example Al-Kofahi et al, 2018 ; Schmidt et al, 2018 ; Berg et al, 2019 ).…”

Section: Analytical and Imaging-based Methods Required To Analyze Spamentioning

confidence: 99%

Pinpointing Cell Identity in Time and Space

Savulescu

Jacobs

Negishi

et al. 2020

Front. Mol. Biosci.

View full text Add to dashboard Cite

Mammalian cells display a broad spectrum of phenotypes, morphologies, and functional niches within biological systems. Our understanding of mechanisms at the individual cellular level, and how cells function in concert to form tissues, organs and systems, has been greatly facilitated by centuries of extensive work to classify and characterize cell types. Classic histological approaches are now complemented with advanced single-cell sequencing and spatial transcriptomics for cell identity studies. Emerging data suggests that additional levels of information should be considered, including the subcellular spatial distribution of molecules such as RNA and protein, when classifying cells. In this Perspective piece we describe the importance of integrating cell transcriptional state with tissue and subcellular spatial and temporal information for thorough characterization of cell type and state. We refer to recent studies making use of single cell RNA-seq and/or image-based cell characterization, which highlight a need for such in-depth characterization of cell populations. We also describe the advances required in experimental, imaging and analytical methods to address these questions. This Perspective concludes by framing this argument in the context of projects such as the Human Cell Atlas, and related fields of cancer research and developmental biology.

show abstract

“…Label-free imaging such as brightfield or phase-contrast microscopy is even less invasive but introduces halo-like artifacts that hamper segmentation; in fact, no feature by itself seems characteristic enough of a cell observed under transmitted light. 91 Challenges like this have popularized interactive machine learning (IML) algorithms ( Figure 2 ; Table 1 ), which use non-linear classifiers (e.g., random forest) to select the best combination of features from a pre-set collection of filters (see above: e.g., edge, texture) by training on user-annotated data. 92 , 93 On the other hand, rather than working with a predetermined set of features like IML, deep learning and artificial neural networks (ANNs) tailor their own filters to the training set from a rather general template that includes a range of non-linear mappings; 94 that is, they look for good features automatically, but, in exchange, the underlying assumptions are practically inaccessible.…”

Section: Detecting Characterizing and Following Cells In Microscopymentioning

confidence: 99%

Bioimage Analysis and Cell Motility

2021

View full text Add to dashboard Cite

Cell segmentation methods for label-free contrast microscopy: review and comprehensive comparison

Cited by 158 publications

References 63 publications

A Self-Supervised Machine Learning Approach for Objective Live Cell Segmentation and Analysis

A Self-Supervised Machine Learning Approach for Objective Live Cell Segmentation and Analysis

Pinpointing Cell Identity in Time and Space

Bioimage Analysis and Cell Motility

Contact Info

Product

Resources

About