Equipping computational pathology systems with artifact processing pipelines: a showcase for computation and performance trade-offs.

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC ACS Applied Electronic Materials Pub Date : 2024-10-07 DOI:10.1186/s12911-024-02676-z
Neel Kanwal, Farbod Khoraminia, Umay Kiraz, Andrés Mosquera-Zamudio, Carlos Monteagudo, Emiel A M Janssen, Tahlita C M Zuiverloon, Chunming Rong, Kjersti Engan
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Abstract

Background: Histopathology is a gold standard for cancer diagnosis. It involves extracting tissue specimens from suspicious areas to prepare a glass slide for a microscopic examination. However, histological tissue processing procedures result in the introduction of artifacts, which are ultimately transferred to the digitized version of glass slides, known as whole slide images (WSIs). Artifacts are diagnostically irrelevant areas and may result in wrong predictions from deep learning (DL) algorithms. Therefore, detecting and excluding artifacts in the computational pathology (CPATH) system is essential for reliable automated diagnosis.

Methods: In this paper, we propose a mixture of experts (MoE) scheme for detecting five notable artifacts, including damaged tissue, blur, folded tissue, air bubbles, and histologically irrelevant blood from WSIs. First, we train independent binary DL models as experts to capture particular artifact morphology. Then, we ensemble their predictions using a fusion mechanism. We apply probabilistic thresholding over the final probability distribution to improve the sensitivity of the MoE. We developed four DL pipelines to evaluate computational and performance trade-offs. These include two MoEs and two multiclass models of state-of-the-art deep convolutional neural networks (DCNNs) and vision transformers (ViTs). These DL pipelines are quantitatively and qualitatively evaluated on external and out-of-distribution (OoD) data to assess generalizability and robustness for artifact detection application.

Results: We extensively evaluated the proposed MoE and multiclass models. DCNNs-based MoE and ViTs-based MoE schemes outperformed simpler multiclass models and were tested on datasets from different hospitals and cancer types, where MoE using (MobileNet) DCNNs yielded the best results. The proposed MoE yields 86.15 % F1 and 97.93% sensitivity scores on unseen data, retaining less computational cost for inference than MoE using ViTs. This best performance of MoEs comes with relatively higher computational trade-offs than multiclass models. Furthermore, we apply post-processing to create an artifact segmentation mask, a potential artifact-free RoI map, a quality report, and an artifact-refined WSI for further computational analysis. During the qualitative evaluation, field experts assessed the predictive performance of MoEs over OoD WSIs. They rated artifact detection and artifact-free area preservation, where the highest agreement translated to a Cohen Kappa of 0.82, indicating substantial agreement for the overall diagnostic usability of the DCNN-based MoE scheme.

Conclusions: The proposed artifact detection pipeline will not only ensure reliable CPATH predictions but may also provide quality control. In this work, the best-performing pipeline for artifact detection is MoE with DCNNs. Our detailed experiments show that there is always a trade-off between performance and computational complexity, and no straightforward DL solution equally suits all types of data and applications. The code and HistoArtifacts dataset can be found online at Github and Zenodo , respectively.

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为计算病理学系统配备人工制品处理管道:计算与性能权衡的展示。
背景:组织病理学是癌症诊断的黄金标准。它包括从可疑部位提取组织标本,准备玻璃载玻片进行显微镜检查。然而,组织学组织处理程序会产生伪影,这些伪影最终会转移到数字化的玻璃载玻片上,即所谓的全玻片图像(WSI)。伪影是与诊断无关的区域,可能导致深度学习(DL)算法预测错误。因此,在计算病理学(CPATH)系统中检测并排除伪影对于可靠的自动诊断至关重要:本文提出了一种专家混合(MoE)方案,用于从 WSIs 中检测五种明显的伪影,包括受损组织、模糊、折叠组织、气泡和组织学无关的血液。首先,我们训练独立的二元 DL 模型作为专家,以捕捉特定的伪影形态。然后,我们利用融合机制将它们的预测集合起来。我们对最终的概率分布进行概率阈值处理,以提高 MoE 的灵敏度。我们开发了四个 DL 管道来评估计算和性能的权衡。其中包括两个MoE以及最先进的深度卷积神经网络(DCNN)和视觉转换器(ViT)的两个多类模型。我们在外部数据和分布外(OoD)数据上对这些 DL 管道进行了定量和定性评估,以评估人工智能检测应用的通用性和鲁棒性:我们广泛评估了所提出的 MoE 和多类模型。基于 DCNNs 的 MoE 和基于 ViTs 的 MoE 方案优于简单的多类模型,并在来自不同医院和癌症类型的数据集上进行了测试,其中使用(MobileNet)DCNNs 的 MoE 取得了最佳结果。与使用 ViTs 的 MoE 相比,拟议的 MoE 在未见数据上的 F1 和灵敏度得分分别为 86.15% 和 97.93%,推理计算成本更低。与多类模型相比,MoE 的这一最佳性能需要更高的计算权衡。此外,我们还进行了后处理,以创建一个人工痕迹分割掩码、一个潜在的无人工痕迹 RoI 地图、一份质量报告和一个人工痕迹提纯的 WSI,用于进一步的计算分析。在定性评估中,现场专家评估了 MoE 相对于 OoD WSI 的预测性能。他们对工件检测和无工件区域保存进行了评分,其中最高的一致性转化为 0.82 的 Cohen Kappa,这表明基于 DCNN 的 MoE 方案的整体诊断可用性具有很高的一致性:结论:所提出的伪影检测管道不仅能确保可靠的 CPATH 预测,还能提供质量控制。在这项工作中,性能最佳的伪影检测管道是采用 DCNN 的 MoE。我们的详细实验表明,性能和计算复杂度之间总是存在权衡,没有一种直接的 DL 解决方案能同样适用于所有类型的数据和应用。代码和 HistoArtifacts 数据集可分别在 Github 和 Zenodo 上找到。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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