Michel Botros , Onno J. de Boer , Bryan Cardenas , Erik J. Bekkers , Marnix Jansen , Myrtle J. van der Wel , Clara I. Sánchez , Sybren L. Meijer
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The system was designed to identify individual glands, grade dysplasia, and assign a WSI-level diagnosis. The proposed method was evaluated by comparing the performance of our AI system with that of a large international and heterogeneous group of 55 gastrointestinal pathologists assessing 55 digitized biopsies spanning the complete spectrum of BE-related dysplasia. The AI system correctly graded 76.4% of the WSIs, surpassing the performance of 53 out of the 55 participating pathologists. Furthermore, the receiver-operating characteristic analysis showed that the system’s ability to predict the absence (nondysplastic BE) versus the presence of any dysplasia was with an area under the curve of 0.94 and a sensitivity of 0.92 at a specificity of 0.94. These findings demonstrate that this AI system has the potential to assist pathologists in assessment of BE-related dysplasia. 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引用次数: 0
摘要
食管活检组织病理学评估是巴雷特食管(Barrett's esophagus,BE)患者治疗的关键部分,但容易受到观察者变异性的影响,因此需要可靠的诊断方法。人工智能(AI)正成为辅助诊断的强大工具,但它往往依赖于抽象的测试和验证集,而真实世界的行为却不为人知。在本研究中,我们利用深度学习技术开发了一套两阶段人工智能系统,用于对 BE 相关发育不良进行组织病理学评估,以提高病理学工作流程的效率和准确性。该人工智能系统是在 290 张全切片图像(WSIs)上开发和训练的,这些图像在腺体和组织层面都做了注释。该系统旨在识别单个腺体,对发育不良进行分级,并给出 WSI 级别的诊断。通过将我们的人工智能系统的性能与一个由 55 位消化道病理学家组成的大型国际异质小组评估 55 份数字化活检样本的性能进行比较,评估了所提出的方法,这些活检样本涵盖了与 BE 相关的发育不良的所有病变。人工智能系统对 76.4% 的 WSI 进行了正确分级,超过了 55 位参与病理学家中 53 位的表现。此外,ROC 分析表明,该系统预测不存在(非增生异常 BE)与存在任何增生异常的能力的 AUC 为 0.94,灵敏度为 0.92,特异性为 0.94。这些研究结果表明,该人工智能系统具有协助病理学家评估与 BE 相关的发育不良的潜力。该系统的输出结果可为具有挑战性的病例提供可靠、一致的辅助诊断,或用于分流低风险的非增生异常活检组织,从而减轻病理学家的工作量,提高工作效率。
Deep Learning for Histopathological Assessment of Esophageal Adenocarcinoma Precursor Lesions
Histopathological assessment of esophageal biopsies is a key part in the management of patients with Barrett esophagus (BE) but prone to observer variability and reliable diagnostic methods are needed. Artificial intelligence (AI) is emerging as a powerful tool for aided diagnosis but often relies on abstract test and validation sets while real-world behavior is unknown. In this study, we developed a 2-stage AI system for histopathological assessment of BE-related dysplasia using deep learning to enhance the efficiency and accuracy of the pathology workflow. The AI system was developed and trained on 290 whole-slide images (WSIs) that were annotated at glandular and tissue levels. The system was designed to identify individual glands, grade dysplasia, and assign a WSI-level diagnosis. The proposed method was evaluated by comparing the performance of our AI system with that of a large international and heterogeneous group of 55 gastrointestinal pathologists assessing 55 digitized biopsies spanning the complete spectrum of BE-related dysplasia. The AI system correctly graded 76.4% of the WSIs, surpassing the performance of 53 out of the 55 participating pathologists. Furthermore, the receiver-operating characteristic analysis showed that the system’s ability to predict the absence (nondysplastic BE) versus the presence of any dysplasia was with an area under the curve of 0.94 and a sensitivity of 0.92 at a specificity of 0.94. These findings demonstrate that this AI system has the potential to assist pathologists in assessment of BE-related dysplasia. The system’s outputs could provide a reliable and consistent secondary diagnosis in challenging cases or be used for triaging low-risk nondysplastic biopsies, thereby reducing the workload of pathologists and increasing throughput.
期刊介绍:
Modern Pathology, an international journal under the ownership of The United States & Canadian Academy of Pathology (USCAP), serves as an authoritative platform for publishing top-tier clinical and translational research studies in pathology.
Original manuscripts are the primary focus of Modern Pathology, complemented by impactful editorials, reviews, and practice guidelines covering all facets of precision diagnostics in human pathology. The journal's scope includes advancements in molecular diagnostics and genomic classifications of diseases, breakthroughs in immune-oncology, computational science, applied bioinformatics, and digital pathology.