Computer-aided systems in histopathology are often challenged by various sources of domain shift that impact the performance of these algorithms considerably. We investigated the potential of using self-supervised pre-training to overcome scanner-induced domain shifts for the downstream task of tumor segmentation. For this, we present the Barlow Triplets to learn scanner-invariant representations from a multi-scanner dataset with local image correspondences. We show that self-supervised pre-training successfully aligned different scanner representations, which, interestingly only results in a limited benefit for our downstream task. We thereby provide insights into the influence of scanner characteristics for downstream applications and contribute to a better understanding of why established self-supervised methods have not yet shown the same success on histopathology data as they have for natural images.
translated by 谷歌翻译
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.
translated by 谷歌翻译
由于形态的相似性,皮肤肿瘤的组织学切片分化为个体亚型可能具有挑战性。最近,基于深度学习的方法证明了它们在这方面支持病理学家的潜力。但是,这些监督算法中的许多都需要大量的注释数据才能进行稳健开发。我们提供了一个公开可用的数据集,该数据集是七个不同的犬皮肤肿瘤的350张全滑图像,其中有13种组织学类别的12,424个多边形注释,包括7种皮肤肿瘤亚型。在评估者间实验中,我们显示了提供的标签的高稠度,尤其是对于肿瘤注释。我们通过训练深层神经网络来进一步验证数据集,以完成组织分割和肿瘤亚型分类的任务。我们的肿瘤尤其是0.7047的类平均Jaccard系数为0.7047,尤其是0.9044。对于分类,我们达到了0.9857的幻灯片级准确性。由于犬皮肤肿瘤对人肿瘤具有各种组织学同源性,因此该数据集的附加值不限于兽医病理学,而是扩展到更一般的应用领域。
translated by 谷歌翻译
评估有丝分裂计数具有已知的高度内和帧间间变异性。已证明计算机辅助系统可降低这种可变性并减少标记时间。然而,这些系统通常高度依赖于其培训领域,并表现出对看不见的域的适用性差。在组织病理学中,这些域移位可以由各种来源产生,包括用于数字化组织学样本的不同滑动扫描系统。有丝分裂域泛化挑战的挑战集中在这种特定领域转变对有丝分裂形象检测的任务。这项工作提出了一种主要的有丝分裂形象检测算法作为挑战的基线,基于域对抗训练。在挑战的测试集上,该算法将F $ _1 $得分为0.7183。相应的网络权重和用于实现网络的代码是公开可用的。
translated by 谷歌翻译