Yannis Schumann, Matthias Dottermusch, Leonille Schweizer, Maja Krech, Tasja Lempertz, Ulrich Schüller, Philipp Neumann, Julia E. Neumann
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We assembled a case series of 139 molecularly characterized spinal cord ependymomas (<i>n</i><sub>MPE</sub> = 84, <i>n</i><sub>SP-EPN</sub> = 55). Self-supervised and weakly-supervised neural networks were used for classification. We employed attention analysis and supervised machine-learning methods for the discovery and quantification of morphological features and their correlation to the diagnoses of experienced neuropathologists. Our best performing model predicted the DNA methylation class with 98% test accuracy and used self-supervised learning to outperform pretrained encoder-networks (86% test accuracy). In contrast, the diagnoses of neuropathologists matched the DNA methylation class in only 83% of cases. Domain-adaptation techniques improved model generalization to an external validation cohort by up to 22%. Statistically significant morphological features were identified per molecular type and quantitatively correlated to human diagnoses. The approach was extended to recently defined subtypes of myxopapillary ependymomas (MPE-(A/B), 80% test accuracy). In summary, we demonstrated the accurate prediction of the DNA methylation class of spinal cord ependymomas (SP-EPN, MPE(-A/B)) using hematoxylin and eosin stained whole-slide images. 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Self-supervised and weakly-supervised neural networks were used for classification. We employed attention analysis and supervised machine-learning methods for the discovery and quantification of morphological features and their correlation to the diagnoses of experienced neuropathologists. Our best performing model predicted the DNA methylation class with 98% test accuracy and used self-supervised learning to outperform pretrained encoder-networks (86% test accuracy). In contrast, the diagnoses of neuropathologists matched the DNA methylation class in only 83% of cases. Domain-adaptation techniques improved model generalization to an external validation cohort by up to 22%. Statistically significant morphological features were identified per molecular type and quantitatively correlated to human diagnoses. The approach was extended to recently defined subtypes of myxopapillary ependymomas (MPE-(A/B), 80% test accuracy). 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引用次数: 0
摘要
根据DNA甲基化,生长在脊髓中的附肢瘤包括两大分子类型,即脊髓(SP-EPN)和肌乳头状附肢瘤(MPE(-A/B)),它们的临床特征和预后各不相同。由于组织形态学诊断与甲基化数据分类之间存在差异,我们询问深度神经网络能否从苏木精和伊红染色的全切片图像中预测脊髓外皮瘤的DNA甲基化类别。利用可解释的人工智能,我们进一步旨在通过识别和量化这些分子上皮瘤类型的独特形态模式,前瞻性地提高基于组织学诊断与 DNA 甲基化分析的一致性。我们收集了 139 例具有分子特征的脊髓上皮瘤(nMPE = 84,nSP-EPN = 55)。采用自我监督和弱监督神经网络进行分类。我们采用了注意力分析和监督机器学习方法来发现和量化形态学特征及其与经验丰富的神经病理学家的诊断之间的相关性。我们性能最好的模型预测 DNA 甲基化类别的测试准确率为 98%,并利用自我监督学习超越了预训练编码器网络(测试准确率为 86%)。相比之下,神经病理学家的诊断只有 83% 的病例与 DNA 甲基化类别相匹配。领域适应技术将模型泛化到外部验证队列的能力提高了 22%。每个分子类型都确定了具有统计学意义的形态特征,并与人类诊断进行了定量关联。该方法已扩展到最近定义的肌乳头状上皮瘤亚型(MPE-(A/B),测试准确率为 80%)。总之,我们利用苏木精和伊红染色的全切片图像准确预测了脊髓上皮瘤(SP-EPN、MPE(-A/B))的 DNA 甲基化类别。我们的方法可作为综合诊断的辅助资源,甚至有助于在各机构间建立基于组织学诊断的标准化、高质量水平--尤其是在低收入国家,因为这些国家可能无法随时提供昂贵的DNA甲基化分析。
Morphology-based molecular classification of spinal cord ependymomas using deep neural networks
Based on DNA-methylation, ependymomas growing in the spinal cord comprise two major molecular types termed spinal (SP-EPN) and myxopapillary ependymomas (MPE(-A/B)), which differ with respect to their clinical features and prognosis. Due to the existing discrepancy between histomorphogical diagnoses and classification using methylation data, we asked whether deep neural networks can predict the DNA methylation class of spinal cord ependymomas from hematoxylin and eosin stained whole-slide images. Using explainable AI, we further aimed to prospectively improve the consistency of histology-based diagnoses with DNA methylation profiling by identifying and quantifying distinct morphological patterns of these molecular ependymoma types. We assembled a case series of 139 molecularly characterized spinal cord ependymomas (nMPE = 84, nSP-EPN = 55). Self-supervised and weakly-supervised neural networks were used for classification. We employed attention analysis and supervised machine-learning methods for the discovery and quantification of morphological features and their correlation to the diagnoses of experienced neuropathologists. Our best performing model predicted the DNA methylation class with 98% test accuracy and used self-supervised learning to outperform pretrained encoder-networks (86% test accuracy). In contrast, the diagnoses of neuropathologists matched the DNA methylation class in only 83% of cases. Domain-adaptation techniques improved model generalization to an external validation cohort by up to 22%. Statistically significant morphological features were identified per molecular type and quantitatively correlated to human diagnoses. The approach was extended to recently defined subtypes of myxopapillary ependymomas (MPE-(A/B), 80% test accuracy). In summary, we demonstrated the accurate prediction of the DNA methylation class of spinal cord ependymomas (SP-EPN, MPE(-A/B)) using hematoxylin and eosin stained whole-slide images. Our approach may prospectively serve as a supplementary resource for integrated diagnostics and may even help to establish a standardized, high-quality level of histology-based diagnostics across institutions—in particular in low-income countries, where expensive DNA-methylation analyses may not be readily available.
期刊介绍:
Brain Pathology is the journal of choice for biomedical scientists investigating diseases of the nervous system. The official journal of the International Society of Neuropathology, Brain Pathology is a peer-reviewed quarterly publication that includes original research, review articles and symposia focuses on the pathogenesis of neurological disease.