BCED-Net: Breast Cancer Ensemble Diagnosis Network using transfer learning and the XGBoost classifier with mammography images.

IF 2.1 Q3 PUBLIC, ENVIRONMENTAL & OCCUPATIONAL HEALTH Osong Public Health and Research Perspectives Pub Date : 2024-10-01 Epub Date: 2024-09-10 DOI:10.24171/j.phrp.2023.0361

Drishti Arora, Rakesh Garg, Farhan Asif

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Abstract

Background: Breast cancer poses a significant global health challenge, characterized by complex origins and the potential for life-threatening metastasis. The critical need for early and accurate detection is underscored by the 685,000 lives claimed by the disease worldwide in 2020. Deep learning has made strides in advancing the prompt diagnosis of breast cancer. However, obstacles persist, such as dealing with high-dimensional data and the risk of overfitting, necessitating fresh approaches to improve accuracy and real-world applicability.

Methods: In response to these challenges, we propose BCED-Net, which stands for Breast Cancer Ensemble Diagnosis Network. This innovative framework leverages transfer learning and the extreme gradient boosting (XGBoost) classifier on the Breast Cancer RSNA dataset. Our methodology involved feature extraction using pre-trained models-namely, Resnet50, EfficientnetB3, VGG19, Densenet121, and ConvNeXtTiny-followed by the concatenation of the extracted features. Our most promising configuration combined features extracted from deep convolutional neural networks-namely Resnet50, EfficientnetB3, and ConvNeXtTiny-that were classified using the XGBoost classifier.

Results: The ensemble approach demonstrated strong overall performance with an accuracy of 0.89. The precision, recall, and F1-score values, which were all at 0.86, highlight a balanced trade-off between correctly identified positive instances and the ability to capture all actual positive samples.

Conclusion: BCED-Net represents a significant leap forward in addressing persistent issues such as the high dimensionality of features and the risk of overfitting.

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BCED-Net：使用迁移学习和 XGBoost 分类器的乳腺癌集合诊断网络与乳房 X 射线照相图像。

背景：乳腺癌是一项重大的全球性健康挑战，其特点是病因复杂，有可能发生危及生命的转移。2020 年，全球将有 685,000 人死于乳腺癌，这凸显了早期准确检测的迫切需要。深度学习在推动乳腺癌的及时诊断方面取得了长足进步。然而，障碍依然存在，如处理高维数据和过拟合风险，因此需要采用新方法来提高准确性和实际应用性：为了应对这些挑战，我们提出了 BCED-Net，即乳腺癌集合诊断网络。这一创新框架在乳腺癌 RSNA 数据集上利用了迁移学习和极端梯度提升（XGBoost）分类器。我们的方法包括使用预先训练好的模型（即 Resnet50、EfficientnetB3、VGG19、Densenet121 和 ConvNeXtTiny）提取特征，然后对提取的特征进行连接。我们最有希望的配置是从深度卷积神经网络（即 Resnet50、EfficientnetB3 和 ConvNeXtTiny）中提取的特征，并使用 XGBoost 分类器进行分类：组合方法的总体性能很高，准确率达到 0.89。精确度、召回率和 F1 分数均为 0.86，在正确识别正向实例和捕获所有实际正向样本的能力之间实现了平衡：BCED-Net 在解决特征的高维度和过拟合风险等长期存在的问题方面实现了重大飞跃。

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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