Digital staining through the application of deep neural networks to multi-modal multi-photon microscopy

Borhani, Navid; Bower, Andrew J.; Boppart, Stephen A.; Psaltis, Demetri

doi:10.1364/boe.10.001339

Cited by 49 publications

(55 citation statements)

References 33 publications

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“…Recently, deep learning has been demonstrated to be an effective virtual staining method. The success of this virtual staining has been illustrated using several different microscopy modalities as input images [49], [51], [126], [127]. Rivenson et al [49] demonstrated the efficacy of the deep learning-based staining using images of a single autofluorescence channel of an unstained tissue and that the technique can be applied to several different tissue types and stains (Masson's Trichrome and Jones stain in addition to the standard H&E).…”

Section: I N S I L I C O L a B E L I N G U S I N G D E E P L E A mentioning

confidence: 99%

Deep-Learning-Based Image Reconstruction and Enhancement in Optical Microscopy

et al. 2020

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This article provides an overview of efforts to advance the field of computational microscopy and optical sensing systems for microscopy using deep neural networks. First, the work overviews the basics of inverse problems in optical microscopy and then outlines how deep learning can be a framework for solving these problems, typically through supervised methods. Then, there is a discussion of use of deep learning to try to obtain single-image super resolution and image enhancement in these data sets.

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Section: I N S I L I C O L a B E L I N G U S I N G D E E P L E A mentioning

confidence: 99%

Deep-Learning-Based Image Reconstruction and Enhancement in Optical Microscopy

et al. 2020

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“…Image registration is the process of bringing in the same system of coordinates, and geometrically aligning, two or more images of the same scene, which may be taken at different times, under different acquisition conditions, or by different sensors 35 . In microscopy imaging, multimodal and/or monomodal registration are typically required to perform side-by-side image comparison, which is often needed to monitor morphological changes and motion, or to perform template-, or atlas-based segmentation, classification, detection, etc [36][37][38][39][40][41] . Furthermore, monomodal registration, e.g.…”

Section: Utilitymentioning

confidence: 99%

HISTOBREAST, a collection of brightfield microscopy images of Haematoxylin and Eosin stained breast tissue

et al. 2020

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Modern histopathology workflows rely on the digitization of histology slides. The quality of the resulting digital representations, in the form of histology slide image mosaics, depends on various specific acquisition conditions and on the image processing steps that underlie the generation of the final mosaic, e.g. registration and blending of the contained image tiles. We introduce HISTOBREAST, an extensive collection of brightfield microscopy images that we collected in a principled manner under different acquisition conditions on Haematoxylin-Eosin (H&E) stained breast tissue. HISTOBREAST is comprised of neighbour image tiles and ensemble of mosaics composed from different combinations of the available image tiles, exhibiting progressively degraded quality levels. HISTOBREAST can be used to benchmark image processing and computer vision techniques with respect to their robustness to image modifications specific to brightfield microscopy of H&E stained tissues. Furthermore, HISTOBREAST can serve in the development of new image processing methods, with the purpose of ensuring robustness to typical image artefacts that raise interpretation problems for expert histopathologists and affect the results of computerized image analysis.

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“…A growing collection of studies have used GANs to synthetically stain images of histological tissue sections, which can save institutions time and money (both in reagents and technologists' time) (Bayramoglu et al, 2017;Borhani et al, 2019;De Biase, 2019;Lahiani et al, 2018;Quiros et al, 2019;Rana et al, 2018;Rivenson, Liu, et al, 2019;Rivenson, Wang, et al, 2019;Xu et al, 2019). GAN models have also been used to remove artificial and natural discolorations in images of stained histological tissue sections, removing artifacts that could perturb deep learning analyses (Bentaieb & Hamarneh, 2018;Ghazvinian Zanjani et al, 2018;Pontalba et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

Preliminary Evaluation of the Utility of Deep Generative Histopathology Image Translation at a Mid-Sized NCI Cancer Center

Levy

Jackson

Sriharan

et al. 2020

Preprint

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Evaluation of a tissue biopsy is often required for the diagnosis and prognostic staging of a disease. Recent efforts have sought to accurately quantitate the distribution of tissue features and morphology in digitized images of histological tissue sections, Whole Slide Images (WSI). Generative modeling techniques present a unique opportunity to produce training data that can both augment these models and translate histologic data across different intra-and-inter-institutional processing procedures, provide cost-effective ways to perform computational chemical stains (synthetic stains) on tissue, and facilitate the creation of diagnostic aid algorithms. A critical evaluation and understanding of these technologies is vital for their incorporation into a clinical workflow. We illustrate several potential use cases of these techniques for the calculation of nuclear to cytoplasm ratio, synthetic SOX10 immunohistochemistry (IHC, sIHC) staining to delineate cell lineage, and the conversion of hematoxylin and eosin (H&E) stain to trichome stain for the staging of liver fibrosis. APPENDIX 1 Mathematical Description of CycleGAN and Pix2Pix Objective FunctionsGANs are tasked with learning a source/target domain Y from latent noise vector Z via mapping G.The loss function for a GAN is specified by:

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Digital staining through the application of deep neural networks to multi-modal multi-photon microscopy

Cited by 49 publications

References 33 publications

Deep-Learning-Based Image Reconstruction and Enhancement in Optical Microscopy

Deep-Learning-Based Image Reconstruction and Enhancement in Optical Microscopy

HISTOBREAST, a collection of brightfield microscopy images of Haematoxylin and Eosin stained breast tissue

Preliminary Evaluation of the Utility of Deep Generative Histopathology Image Translation at a Mid-Sized NCI Cancer Center

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