Three-dimensional virtual refocusing of fluorescence microscopy images using deep learning

Wu, Yichen; Rivenson, Yair; Wang, Hongda; Luo, Yilin; Ben-David, Eyal; Bentolila, Laurent A.; Pritz, Christian; Ozcan, Aydogan

doi:10.1038/s41592-019-0622-5

Cited by 193 publications

(149 citation statements)

References 58 publications

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“…Morphology has long been a cue for cell biologists and pathologists to recognize cell type and abnormalities related to disease (Bakal et al, 2007;Chan, 2014;Eddy et al, 2018;Gordonov et al, 2015;Gurcan et al, 2009;López, 2013;Pavillon et al, 2018;Wu et al, 2020;Yin et al, 2013). In this study, we rely on the exquisite sensitivity of deep learned artificial neural networks in recognizing subtle but systematic image patterns to classify different cell types and cell states.…”

Section: Visually Unstructured Properties Of Cell Image Appearance Enmentioning

confidence: 99%

“…However, the often cited weakness of these techniques is the lack of an intuitive explanation of which parts of the data are particularly meaningful in defining the extracted pattern. While in some applications, such as image segmentation, image restoration or mapping between imaging modalities, a well-validated outcome of a network has been satisfactory (Christiansen et al, 2018;Fang et al, 2019b;Guo et al, 2019;Hershko et al, 2019;Hollandi et al, 2019;LaChance and Cohen, 2020;Moen et al, 2019;Nehme et al, 2018;Ounkomol et al, 2018;Ouyang et al, 2018;Rivenson et al, 2019;Wang et al, 2019;Weigert et al, 2018;Wu et al, 2019), there is increasing mistrust in results produced by 'black-box' neural networks. Aside from increasing the confidence, the analysis of the properties -also referred to as 'mechanisms'of the pattern recognition process can potentially generate insight of a biological/physical phenomenon that escapes the analysis driven by human intuition.…”

Section: Interpretation Of Latent Features Discriminating High and Lomentioning

confidence: 99%

“…Whether morphological cues are also informative of the broader spectrum of cell signaling programs that drive hallmark functions in metastatic cells such as shifts in the regulation of metabolism, cell cycle progression, or cell death is less clear, although very recent work, using conventional shape-based machine learning of fluorescently labeled cell lines, suggests this may be the case (Wu et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

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Interpretable deep learning of label-free live cell images uncovers functional hallmarks of highly-metastatic melanoma

Zaritsky

Jamieson

Welf

et al. 2020

Preprint

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Deep convolutional neural networks have emerged as a powerful technique to identify hidden patterns in complex cell imaging data. However, these machine learning techniques are often criticized as uninterpretable "black-boxes" -lacking the ability to provide meaningful explanations for the cell properties that drive the machine's prediction. Here, we demonstrate that the latent features extracted from label-free live cell images by an adversarial auto-encoding deep convolutional neural network capture subtle details of cell appearance that allow classification of melanoma cell states, including the metastatic efficiency of seven patientderived xenograft models that reflect clinical outcome. Although trained exclusively on patientderived xenograft models, the same classifier also predicted the metastatic efficiency of immortalized melanoma cell lines suggesting that the latent features capture properties that are specifically associated with the metastatic potential of a melanoma cell regardless of its origin.We used the autoencoder to generate "in-silico" cell images that amplified the cellular features driving the classifier of metastatic efficiency. These images unveiled pseudopodial extensions and increased light scattering as functional hallmarks of metastatic cells. We validated this interpretation by analyzing experimental image time-lapse sequences in which melanoma cells spontaneously transitioned between states indicative of low and high metastatic efficiency.Together, this data is an example of how the application of Artificial Intelligence supports the identification of processes that are essential for the execution of complex integrated cell functions but are too subtle to be identified by a human expert. -Gurion University of the Negev, Israel (to AZ). We thank Sean Morrison for PDX-derived cell models. We thank Andrew R. Cohen for LEVER. Author ContributionAZ, ESW and GD conceived the study. ESW designed the experimental assay, optimized culture conditions for PDX cells, and trained AN and JC to perform the experiments. AN performed all live imaging and mouse experiments. JC performed additional experiments. UE generated the PDX samples. AZ and ARJ developed analytic tools, analyzed, and interpreted the data. AZ drafted the manuscript. All authors wrote and edited the manuscript and approved its content.GD mentored all authors.

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Section: Visually Unstructured Properties Of Cell Image Appearance Enmentioning

confidence: 99%

Section: Interpretation Of Latent Features Discriminating High and Lomentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Interpretable deep learning of label-free live cell images uncovers functional hallmarks of highly-metastatic melanoma

Zaritsky

Jamieson

Welf

et al. 2020

Preprint

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“…While we have concentrated here on label-free samples, our method has the potential to be adapted to fluorescently-labelled samples and to be combined with state-of-art computational techniques, such as deep learning. For instance, a deep-learning method for deducing zpositions from fluorescence microscopy images was recently described 44 . Our method could incorporate similar computational techniques to make use of the information provided by multiple planes for extending the z-range and enhancing the precision in fluorescence microscopy.…”

Section: Discussionmentioning

confidence: 99%

Multifocal imaging for precise, label-free tracking of fast biological processes in 3D

Hansen

Gong

Wachten

et al. 2020

Preprint

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Many biological processes happen on a nano-to millimeter scale and within milliseconds.Established methods such as confocal microscopy are suitable for precise 3D recordings but lack the temporal or spatial resolution to resolve fast 3D processes and require labeled samples.Multifocal imaging (MFI) allows high-speed 3D imaging but suffers from the compromise between spatial resolution and field-of-view (FOV), requiring bright fluorescent labels and limiting its application. Here, we present a new approach for high-resolution, label-free, highspeed MFI, based on dark-field microscopy and operative over large volumes. We introduce a 3D reconstruction algorithm that increases resolution and depth of the sampled volume without compromising speed and FOV. This allowed us to characterize the flagellar beat of human sperm and surrounding fluid flow with a precision below the Abbe limit, in a large volume, and at high speed. Our MFI concept is cost-effective, can be easily built, and does not rely on object labeling, making it broadly applicable.

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“…Convolutional neural network (CNN) and deep learning approaches have been proposed for several optical applications. Examples include virtual staining of non-stained samples [33], increasing spatial resolution in a large field of view in optical microscopy [34,35], color holographic microscopy with CNN [36], autofocusing and enhancing the depth-of-filed in inline holography [37], lens-less computational imaging by deep learning [38], single-cell-based reconstruction distance estimation by a regression CNN model [39], super-resolution fringe patterns by deep learning holography [40], virtual refocusing in fluorescence microscopy to map 2D images to a 3D surface [41], and several other studies [42][43][44]. Deep-learning based phase recovery by residual CNN model was also suggested [45], but the application is limited because the reference noise-free phase images for deep-learning model are generated by the multi-height phase retrieval approach (8 holograms are recorded at different sample-to-sensor distances).…”

Section: Proposed Deep Learning Model For Phase Recoverymentioning

confidence: 99%

Noise-free quantitative phase imaging in Gabor holography with conditional generative adversarial network

Moon¹,

Jaferzadeh²,

Kim³

et al. 2020

Opt. Express

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This paper shows that deep learning can eliminate the superimposed twin-image noise in phase images of Gabor holographic setup. This is achieved by the conditional generative adversarial model (C-GAN), trained by input-output pairs of noisy phase images obtained from synthetic Gabor holography and the corresponding quantitative noise-free contrast-phase image obtained by the off-axis digital holography. To train the model, Gabor holograms are generated from digital off-axis holograms with spatial shifting of the real image and twin image in the frequency domain and then adding them with the DC term in the spatial domain. Finally, the digital propagation of the Gabor hologram with Fresnel approximation generates a superimposed phase image for the C-GAN model input. Two models were trained: a human red blood cell model and an elliptical cancer cell model. Following the training, several quantitative analyses were conducted on the biochemical properties and similarity between actual noise-free phase images and the model output. Surprisingly, it is discovered that our model can recover other elliptical cell lines that were not observed during the training. Additionally, some misalignments can also be compensated with the trained model. Particularly, if the reconstruction distance is somewhat incorrect, this model can still retrieve in-focus images.

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Three-dimensional virtual refocusing of fluorescence microscopy images using deep learning

Cited by 193 publications

References 58 publications

Interpretable deep learning of label-free live cell images uncovers functional hallmarks of highly-metastatic melanoma

Interpretable deep learning of label-free live cell images uncovers functional hallmarks of highly-metastatic melanoma

Multifocal imaging for precise, label-free tracking of fast biological processes in 3D

Noise-free quantitative phase imaging in Gabor holography with conditional generative adversarial network

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