In Silico Labeling: Predicting Fluorescent Labels in Unlabeled Images

Christiansen, Eric; Yang, Samuel J.; Ando, D. Michael; Javaherian, Ashkan; Skibinski, Gaia; Lipnick, Scott; Mount, Elliot; O’Neil, Alison; Shah, Kevan; Lee, Alicia K.; Goyal, Piyush; Fedus, William; Poplin, Ryan; Esteva, Andre; Berndl, Marc; Rubin, Lee L.; Nelson, Philip C.; Finkbeiner, Steven

doi:10.1016/j.cell.2018.03.040

Cited by 521 publications

(475 citation statements)

References 29 publications

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“…Rapid classification of cells according to their phenotypes and/or pathologic conditions is a significant and long‐standing problem . While genomic analysis offers the gold standard , accurate and cost‐effective methods at the single‐cell level are highly valuable and attract intense research efforts . Conventional methods of microscopy and flow cytometry are current tools of choice, but the former requires time‐consuming manual analysis and the latter yields very limited morphology information.…”

Section: Introductionmentioning

confidence: 99%

Deep learning of diffraction image patterns for accurate classification of five cell types

Jin

Wen

et al. 2019

Journal of Biophotonics

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Development of label‐free methods for accurate classification of cells with high throughput can yield powerful tools for biological research and clinical applications. We have developed a deep neural network of DINet for extracting features from cross‐polarized diffraction image (p‐DI) pairs on multiple pixel scales to accurately classify cells in five types. A total of 6185 cells were measured by a polarization diffraction imaging flow cytometry (p‐DIFC) method followed by cell classification with DINet on p‐DI data. The averaged value and SD of classification accuracy were found to be 98.9% ± 1.00% on test data sets for 5‐fold training and test. The invariance of DINet to image translation, rotation, and blurring has been verified with an expanded p‐DI data set. To study feature‐based classification by DINet, two sets of correctly and incorrectly classified cells were selected and compared for each of two prostate cell types. It has been found that the signature features of large dissimilarities between p‐DI data of correctly and incorrectly classified cell sets increase markedly from convolutional layers 1 and 2 to layers 3 and 4. These results clearly demonstrate the importance of high‐order correlations extracted at the deep layers for accurate cell classification.

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Section: Introductionmentioning

confidence: 99%

Deep learning of diffraction image patterns for accurate classification of five cell types

Jin

Wen

et al. 2019

Journal of Biophotonics

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“…Use of image processing algorithms can only partly overcome this deficiency, so there has been interest in developing methods that avoid the use of fluorescence altogether. Several US institutions therefore developed a ML approach called in silico labeling that can predict reliably where fluorescent labels would be applied based on images of the either unlabeled fixed or live biological samples [2]. The researchers designed a model based on deep neural networks, which comprise nodes and links between them and are arranged in multiple layers to allow nested feedback between data and predictions.…”

Section: Ai-driven Data Analysismentioning

confidence: 99%

Internet of instruments

Hunter¹

2018

EMBO Reports

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“…Two recent studies show how the breathtakingly rapid evolution of methods in Machine Learning (ML) might change that situation. Work by Christiansen et al 1 , and Ounkomol et al 2 ., exploits not-yet-mainstream developments in ML to train neural networks (NNs) to harvest this information and make it available to humans.…”

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confidence: 96%

“…Christiansen et al 1 . and Ounkomol et al 2 extend this splendid artificiality to carry out a task quite different from classification.…”

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confidence: 99%

“…Use of NNs to predict fluorescence may turn out to be a case in which recondite computational methods, first developed for military purposes by a nation state, extended by large corporations 1 and institutions 2 in coastal enclaves, ultimately results in worldwide democratization of technical capability and a burst of new knowledge. That outcome isn’t preordained.…”

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confidence: 99%

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