Characterization of tumor heterogeneity through segmentation-free representation learning

Jimin Tan, Hortense Le, Jiehui Deng, Yingzhuo Liu, Yuan Hao, Michelle Hollenberg, Wenke Liu, Joshua M Wang, Bo Xia, Sitharam Ramaswami, Valeria Mezzano, Cynthia Loomis, Nina Murrell, Andre L Moreira, Kyunghyun Cho, Harvey I Pass, Kwok-Kin Wong, Yi Ban, Benjamin G Neel, Aristotelis Tsirigos, David Fenyo
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Abstract

The interaction between tumors and their microenvironment is complex and heterogeneous. Recent developments in high-dimensional multiplexed imaging have revealed the spatial organization of tumor tissues at the molecular level. However, the discovery and thorough characterization of the tumor microenvironment (TME) remains challenging due to the scale and complexity of the images. Here, we propose a self-supervised representation learning framework, CANVAS, that enables discovery of novel types of TMEs. CANVAS is a vision transformer that directly takes high-dimensional multiplexed images and is trained using self-supervised masked image modeling. In contrast to traditional spatial analysis approaches which rely on cell segmentations, CANVAS is segmentation-free, utilizes pixel-level information, and retains local morphology and biomarker distribution information. This approach allows the model to distinguish subtle morphological differences, leading to precise separation and characterization of distinct TME signatures. We applied CANVAS to a lung tumor dataset and identified and validated a monocytic signature that is associated with poor prognosis.
通过无分割表征学习表征肿瘤异质性
肿瘤与其微环境之间的相互作用是复杂和异质的。高维多重成像技术的最新发展从分子水平揭示了肿瘤组织的空间组织。然而,由于图像的规模和复杂性,发现和彻底表征肿瘤微环境(TME)仍然具有挑战性。在这里,我们提出了一个自监督表示学习框架 CANVAS,它能发现新型的肿瘤微环境。CANVAS 是一种视觉转换器,可直接获取高维多路复用图像,并通过自我监督的遮蔽图像建模进行训练。与依赖细胞分割的传统空间分析方法不同,CANVAS 无需分割,利用像素级信息,并保留局部形态和生物标记分布信息。这种方法使模型能够区分细微的形态差异,从而精确地分离和描述不同的 TME 特征。我们将 CANVAS 应用于肺部肿瘤数据集,发现并验证了与不良预后相关的单核细胞特征。
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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