Human-machine Interactive Tissue Prototype Learning for Label-efficient Histopathology Image Segmentation

W. Pan, Jiangpeng Yan, Hanbo Chen, Jiawei Yang, Zhe Xu, Xiu Li, Jianhua Yao
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引用次数: 1

Abstract

Recently, deep neural networks have greatly advanced histopathology image segmentation but usually require abundant annotated data. However, due to the gigapixel scale of whole slide images and pathologists' heavy daily workload, obtaining pixel-level labels for supervised learning in clinical practice is often infeasible. Alternatively, weakly-supervised segmentation methods have been explored with less laborious image-level labels, but their performance is unsatisfactory due to the lack of dense supervision. Inspired by the recent success of self-supervised learning methods, we present a label-efficient tissue prototype dictionary building pipeline and propose to use the obtained prototypes to guide histopathology image segmentation. Particularly, taking advantage of self-supervised contrastive learning, an encoder is trained to project the unlabeled histopathology image patches into a discriminative embedding space where these patches are clustered to identify the tissue prototypes by efficient pathologists' visual examination. Then, the encoder is used to map the images into the embedding space and generate pixel-level pseudo tissue masks by querying the tissue prototype dictionary. Finally, the pseudo masks are used to train a segmentation network with dense supervision for better performance. Experiments on two public datasets demonstrate that our human-machine interactive tissue prototype learning method can achieve comparable segmentation performance as the fully-supervised baselines with less annotation burden and outperform other weakly-supervised methods. Codes will be available upon publication.
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用于标记高效组织病理学图像分割的人机交互组织原型学习
近年来,深度神经网络在组织病理图像分割方面取得了很大进展,但通常需要大量的注释数据。然而,由于整个幻灯片图像的十亿像素规模和病理学家的日常工作繁重,在临床实践中获得用于监督学习的像素级标签往往是不可行的。另一种方法是使用不那么费力的图像级标签探索弱监督分割方法,但由于缺乏密集的监督,它们的性能不令人满意。受近年来成功的自监督学习方法的启发,我们提出了一个标签高效的组织原型词典构建管道,并提出使用获得的原型来指导组织病理图像分割。特别是,利用自监督对比学习的优势,训练编码器将未标记的组织病理学图像块投影到判别嵌入空间中,这些块被聚类,从而通过高效的病理学家视觉检查识别组织原型。然后,利用编码器将图像映射到嵌入空间中,通过查询组织原型字典生成像素级伪组织掩模;最后,利用伪掩码训练具有密集监督的分割网络,以获得更好的分割性能。在两个公共数据集上的实验表明,我们的人机交互组织原型学习方法可以获得与全监督基线相当的分割性能,并且注释负担更少,优于其他弱监督方法。代码将在出版后提供。
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