On the acceptance of “fake” histopathology: A study on frozen sections optimized with deep learning

On the acceptance of “fake” histopathology: A study on frozen sections optimized with deep learning

The fast acquisition process of frozen sections allows surgeons to wait for histological findings during the interventions to base intrasurgical decisions on the outcome of the histology. Compared with paraffin sections, however, the quality of frozen sections is often strongly reduced, leading to a...

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Bibliographic Details
Published in:Journal of pathology informatics 2022-01, Vol.13 (1), p.6-6, Article 100168
Main Authors: Siller, Mario, Stangassinger, Lea Maria, Kreutzer, Christina, Boor, Peter, Bulow, Roman D., Kraus, Theo J.F., von Stillfried, Saskia, Wolfl, Soraya, Couillard-Despres, Sebastien, Oostingh, Gertie Janneke, Hittmair, Anton, Gadermayr, Michael
Format: Article
Language:eng
Subjects:
Artificial neural networks
Deep learning
Diagnosis
Digital imaging
Frozen sections
Generative adversarial networks
Histology
Image enhancement
Image quality
Machine learning
Medical imaging
Optimization
Paraffin sections
Paraffins
Quality assessment
Technical Note
Thyroid cancer
Virtual reality
Whole slide imaging
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Summary:The fast acquisition process of frozen sections allows surgeons to wait for histological findings during the interventions to base intrasurgical decisions on the outcome of the histology. Compared with paraffin sections, however, the quality of frozen sections is often strongly reduced, leading to a lower diagnostic accuracy. Deep neural networks are capable of modifying specific characteristics of digital histological images. Particularly, generative adversarial networks proved to be effective tools to learn about translation between two modalities, based on two unconnected data sets only. The positive effects of such deep learning-based image optimization on computer-aided diagnosis have already been shown. However, since fully automated diagnosis is controversial, the application of enhanced images for visual clinical assessment is currently probably of even higher relevance. Three different deep learning-based generative adversarial networks were investigated. The methods were used to translate frozen sections into virtual paraffin sections. Overall, 40 frozen sections were processed. For training, 40 further paraffin sections were available. We investigated how pathologists assess the quality of the different image translation approaches and whether experts are able to distinguish between virtual and real digital pathology. Pathologists' detection accuracy of virtual paraffin sections (from pairs consisting of a frozen and a paraffin section) was between 0.62 and 0.97. Overall, in 59% of images, the virtual section was assessed as more appropriate for a diagnosis. In 53% of images, the deep learning approach was preferred to conventional stain normalization (SN). Overall, expert assessment indicated slightly improved visual properties of converted images and a high similarity to real paraffin sections. The observed high variability showed clear differences in personal preferences.
ISSN:2153-3539
2229-5089
2153-3539