Ray-Aided Quadruple Affiliation Network for Calculating Tumor-Stroma Ratios in Breast Cancers

IEEE transactions on image processing : a publication of the IEEE Signal Processing Society Pub Date : 2025-04-23 DOI:10.1109/TIP.2025.3561679

Kunping Yang;Linying Chen;Xi Zheng;Xuanping Li;Junhui Lan;Yi Wu;Julia Y. S. Tsang;Gary M. Tse

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Abstract

Tumor-stroma ratio (TSR), which is the area ratio between two components within tumor beds, namely tumor cells and tumor stroma, has been suggested as a promising prognostic feature in breast cancers. However, due to imperfect datasets, and the similarity between tumor stroma and non-tumor stroma, previous algorithms struggle to delineate tumor beds, especially those of histomorphologies with a fibrotic focus. To overcome these limitations, we propose a novel ray-aided quadruple affiliation network (RQA-Net) for calculating TSRs in breast cancers. RQA-Net uses quadruple branches to segment tumor cells and tumor beds simultaneously, where a crisscross task subtraction module (CTS-Module) is designed to locate tumor stroma, grounded on its affiliation relationships with tumor beds. Moreover, we propose an affiliation loss (Aff-Loss) to force identified tumor beds to incorporate tumor cells to enhance their affiliation relationships. Furthermore, we propose a ray-based hypothesis testing (RH-Testing) to obtain line segments from ray equations in tumor beds that can decorate identified tumor beds by overlapping. In summary, RQA-Net precisely predicts tumor cells and tumor beds, and thus supports the calculation of TSRs. We also create a cancerous dataset (CrD-Set) containing 100 slides with an average resolution of

$50,000\times 50,000$

pixels from real breast cancer cases, which is the first dataset with pixel-wise tumor bed annotations. Experimental results on existing datasets and CrD-Set demonstrate that compared with previous methods, RQA-Net better calculates breast cancer TSRs by precisely identifying tumor cells and tumor beds. The created CrD-Set and codes in this work will be available online at https://github.com/Kunpingyang1992/Breast-Cancer-TSR-Calculation

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计算乳腺癌肿瘤-间质比率的射线辅助四联网络

肿瘤-间质比（TSR）是指肿瘤床内两个组成部分，即肿瘤细胞和肿瘤间质之间的面积比，已被认为是乳腺癌预后的一个有希望的特征。然而，由于数据集的不完善，以及肿瘤间质和非肿瘤间质之间的相似性，以前的算法难以描绘肿瘤床，特别是那些具有纤维化灶的组织形态学。为了克服这些限制，我们提出了一种新的射线辅助四联网络（RQA-Net）来计算乳腺癌的tsr。RQA-Net采用四重分支同时分割肿瘤细胞和肿瘤床，其中基于肿瘤基质与肿瘤床的隶属关系，设计了一个交叉任务减法模块（CTS-Module）来定位肿瘤基质。此外，我们提出了一个隶属关系损失（Aff-Loss），以迫使已识别的肿瘤床纳入肿瘤细胞，以增强它们的隶属关系。此外，我们提出了一种基于射线的假设检验（RH-Testing），从肿瘤床的射线方程中获得线段，这些线段可以通过重叠来修饰已识别的肿瘤床。综上所述，RQA-Net能够精确预测肿瘤细胞和肿瘤床，从而支持tsr的计算。我们还创建了一个癌症数据集（CrD-Set），其中包含100张幻灯片，平均分辨率为50,000美元× 50,000美元，来自真实的乳腺癌病例，这是第一个具有逐像素肿瘤床注释的数据集。在现有数据集和CrD-Set上的实验结果表明，与之前的方法相比，RQA-Net通过精确识别肿瘤细胞和肿瘤床，更好地计算出乳腺癌tsr。在这项工作中创建的crd集和代码将在https://github.com/Kunpingyang1992/Breast-Cancer-TSR-Calculation上在线提供

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IEEE transactions on image processing : a publication of the IEEE Signal Processing Society

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