应用后期融合和转移学习对癌症多倍组织病理学图像进行二元分类

IF 1.7 4区 计算机科学 Q3 COMPUTER SCIENCE, INFORMATION SYSTEMS Data Technologies and Applications Pub Date : 2023-02-24 DOI:10.1108/dta-08-2022-0330
F. Nakach, Hasnae Zerouaoui, A. Idri
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引用次数: 0

摘要

目的组织病理活检成像是目前临床诊断癌症的金标准。病理学家在不同的放大倍数下检查图像以确定肿瘤的类型,因为如果只考虑一个放大倍数,判断可能不准确。本研究探索了迁移学习和后期融合的性能,以构建多尺度集成,融合不同放大倍数的特定深度学习模型,用于乳腺肿瘤切片的二元分类。设计/方法/方法使用三种预训练的深度学习技术(DenseNet 201、MobileNet v2和Inception v3)在乳腺癌症组织病理学图像分类数据集的四个放大因子(40×、100×、200×和400×)上对乳腺肿瘤图像进行分类。为了融合在不同放大因子上训练的模型的预测,使用了不同的聚合器,包括加权投票和使用类别标签和分配给每个类别的概率在幻灯片预测上训练的七个元分类器。使用Scott–Knott统计检验选择表现优异的模型的最佳聚类,并使用Borda计数投票系统对排名靠前的模型进行排名。发现这项研究建议通过构建多重放大组合,将转移学习和后期融合用于组织病理学癌症图像分类,因为它们比单独训练的模型在每次放大时表现更好。独创性/价值最佳多尺度组合的表现优于最先进的集成模型,准确度平均值为98.82%,准确度为98.46%,召回率为100%,F1得分为99.20%。
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Binary classification of multi-magnification histopathological breast cancer images using late fusion and transfer learning
PurposeHistopathology biopsy imaging is currently the gold standard for the diagnosis of breast cancer in clinical practice. Pathologists examine the images at various magnifications to identify the type of tumor because if only one magnification is taken into account, the decision may not be accurate. This study explores the performance of transfer learning and late fusion to construct multi-scale ensembles that fuse different magnification-specific deep learning models for the binary classification of breast tumor slides.Design/methodology/approachThree pretrained deep learning techniques (DenseNet 201, MobileNet v2 and Inception v3) were used to classify breast tumor images over the four magnification factors of the Breast Cancer Histopathological Image Classification dataset (40×, 100×, 200× and 400×). To fuse the predictions of the models trained on different magnification factors, different aggregators were used, including weighted voting and seven meta-classifiers trained on slide predictions using class labels and the probabilities assigned to each class. The best cluster of the outperforming models was chosen using the Scott–Knott statistical test, and the top models were ranked using the Borda count voting system.FindingsThis study recommends the use of transfer learning and late fusion for histopathological breast cancer image classification by constructing multi-magnification ensembles because they perform better than models trained on each magnification separately.Originality/valueThe best multi-scale ensembles outperformed state-of-the-art integrated models and achieved an accuracy mean value of 98.82 per cent, precision of 98.46 per cent, recall of 100 per cent and F1-score of 99.20 per cent.
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来源期刊
Data Technologies and Applications
Data Technologies and Applications Social Sciences-Library and Information Sciences
CiteScore
3.80
自引率
6.20%
发文量
29
期刊介绍: Previously published as: Program Online from: 2018 Subject Area: Information & Knowledge Management, Library Studies
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