Improved HER2 Tumor Segmentation with Subtype Balancing using Deep Generative Networks

Tumor segmentation in histopathology images is often complicated by its composition of different histological subtypes and class imbalance. Oversampling subtypes with low prevalence features is not a satisfactory solution since it eventually leads to overfitting. We propose to create synthetic image...

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Veröffentlicht in:	arXiv.org 2022-11
Hauptverfasser:	Öttl, Mathias, Mönius, Jana, Rübner, Matthias, Geppert, Carol I, Qiu, Jingna, Wilm, Frauke, Hartmann, Arndt, Beckmann, Matthias W, Fasching, Peter A, Maier, Andreas, Erber, Ramona, Breininger, Katharina
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Schlagworte:	Computer Science - Computer Vision and Pattern Recognition Conditioning Datasets Diffusion Generative adversarial networks Histopathology Image segmentation Tumors
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creator	Öttl, Mathias Mönius, Jana Rübner, Matthias Geppert, Carol I Qiu, Jingna Wilm, Frauke Hartmann, Arndt Beckmann, Matthias W Fasching, Peter A Maier, Andreas Erber, Ramona Breininger, Katharina
description	Tumor segmentation in histopathology images is often complicated by its composition of different histological subtypes and class imbalance. Oversampling subtypes with low prevalence features is not a satisfactory solution since it eventually leads to overfitting. We propose to create synthetic images with semantically-conditioned deep generative networks and to combine subtype-balanced synthetic images with the original dataset to achieve better segmentation performance. We show the suitability of Generative Adversarial Networks (GANs) and especially diffusion models to create realistic images based on subtype-conditioning for the use case of HER2-stained histopathology. Additionally, we show the capability of diffusion models to conditionally inpaint HER2 tumor areas with modified subtypes. Combining the original dataset with the same amount of diffusion-generated images increased the tumor Dice score from 0.833 to 0.854 and almost halved the variance between the HER2 subtype recalls. These results create the basis for more reliable automatic HER2 analysis with lower performance variance between individual HER2 subtypes.
doi_str_mv	10.48550/arxiv.2211.06150
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subjects	Computer Science - Computer Vision and Pattern Recognition Conditioning Datasets Diffusion Generative adversarial networks Histopathology Image segmentation Tumors
title	Improved HER2 Tumor Segmentation with Subtype Balancing using Deep Generative Networks
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