Reconstructing cell cycle and disease progression using deep learning

Abstract

We show that deep convolutional neural networks combined with nonlinear dimension reduction enable reconstructing biological processes based on raw image data. We demonstrate this by reconstructing the cell cycle of Jurkat cells and disease progression in diabetic retinopathy. In further analysis of Jurkat cells, we detect and separate a subpopulation of dead cells in an unsupervised manner and, in classifying discrete cell cycle stages, we reach a sixfold reduction in error rate compared to a recent approach based on boosting on image features. In contrast to previous methods, deep learning based predictions are fast enough for on-the-fly analysis in an imaging flow cytometer. The interpretation of information-rich, high-throughput single-cell data is a challenge requiring sophisticated computational tools. Here the authors demonstrate a deep convolutional neural network that can classify cell cycle status on-the-fly.

Keywords

Deep learningConvolutional neural networkJurkat cellsComputer scienceArtificial intelligenceBoosting (machine learning)Dimensionality reductionPattern recognition (psychology)Machine learningArtificial neural networkBiologyT cell

MeSH Terms

Cell CycleCell DivisionComputer SimulationDNADiabetic RetinopathyDisease ProgressionFlow CytometryHumansJurkat CellsMachine LearningMitosisNeural NetworksComputerReproducibility of Results

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Publication Info

Year: 2017
Type: article
Volume: 8
Issue: 1
Pages: 463-463
Citations: 295
Access: Closed

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APA Style

                            
                                
                                    Philipp Eulenberg, 
                                
                                    Niklas Köhler, 
                                
                                    Thomas Blasi
                                
                                et al.
                            
                            (2017). 
                            Reconstructing cell cycle and disease progression using deep learning. 
                            Nature Communications
                            , 8
                            (1)
                            , 463-463.
                            https://doi.org/10.1038/s41467-017-00623-3
                        

Identifiers

DOI: 10.1038/s41467-017-00623-3
PMID: 28878212
PMCID: PMC5587733

Data Quality

Data completeness: 86%