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用于减少肺癌筛查中假阳性的二维卷积神经网络与三维卷积神经网络对比

2D CNN versus 3D CNN for false-positive reduction in lung cancer screening.

作者信息

Yu Juezhao, Yang Bohan, Wang Jing, Leader Joseph, Wilson David, Pu Jiantao

机构信息

University of Pittsburgh, Departments of Radiology and Bioengineering, Pittsburgh, Pennsylvania, United States.

University of Pittsburgh, Department of Medicine, Pittsburgh, Pennsylvania, United States.

出版信息

J Med Imaging (Bellingham). 2020 Sep;7(5):051202. doi: 10.1117/1.JMI.7.5.051202. Epub 2020 Oct 13.

DOI:10.1117/1.JMI.7.5.051202
PMID:33062802
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7550796/
Abstract

To clarify whether and to what extent three-dimensional (3D) convolutional neural network (CNN) is superior to 2D CNN when applied to reduce false-positive nodule detections in the scenario of low-dose computed tomography (CT) lung cancer screening. We established a dataset consisting of 1600 chest CT examinations acquired on different subjects from various sources. There were in total 18,280 candidate nodules in these CT examinations, among which 9185 were nodules and 9095 were not nodules. For each candidate nodule, we extracted a number of cubic subvolumes with a dimension of by rotating the CT examinations randomly for 25 times prior to the extraction of the axis-aligned subvolumes. These subvolumes were split into three groups in a ratio of for training, validation, and independent testing purposes. We developed a multiscale CNN architecture and implemented its 2D and 3D versions to classify pulmonary nodules into two categories, namely true positive and false positive. The performance of the 2D/3D-CNN classification schemes was evaluated using the area under the receiver operating characteristic curves (AUC). The -values and the 95% confidence intervals (CI) were calculated. The AUC for the optimal 2D-CNN model is 0.9307 (95% CI: 0.9285 to 0.9330) with a sensitivity of 92.70% and a specificity of 76.21%. The 3D-CNN model with the best performance had an AUC of 0.9541 (95% CI: 0.9495 to 0.9583) with a sensitivity of 89.98% and a specificity of 87.30%. The developed multiscale CNN architecture had a better performance than the vanilla architecture did. The 3D-CNN model has a better performance in false-positive reduction compared with its 2D counterpart; however, the improvement is relatively limited and demands more computational resources for training purposes.

摘要

为了阐明在低剂量计算机断层扫描(CT)肺癌筛查场景中应用三维(3D)卷积神经网络(CNN)减少假阳性结节检测时是否以及在多大程度上优于二维CNN。我们建立了一个数据集,该数据集由从不同来源的不同受试者获取的1600例胸部CT检查组成。这些CT检查中共有18280个候选结节,其中9185个是结节,9095个不是结节。对于每个候选结节,在提取与轴对齐的子体积之前,通过将CT检查随机旋转25次,提取了多个尺寸为 的立方子体积。这些子体积按照 的比例分为三组,用于训练、验证和独立测试。我们开发了一种多尺度CNN架构,并实现了其二维和三维版本,以将肺结节分为两类,即真阳性和假阳性。使用接收器操作特征曲线(AUC)下的面积评估二维/三维CNN分类方案的性能。计算了 值和95%置信区间(CI)。最优二维CNN模型的AUC为0.9307(95%CI:0.9285至0.9330),灵敏度为92.70%,特异性为76.21%。性能最佳的三维CNN模型的AUC为0.9541(95%CI:0.9495至0.9583),灵敏度为89.98%,特异性为87.30%。所开发的多尺度CNN架构比普通架构具有更好的性能。与二维CNN模型相比,三维CNN模型在减少假阳性方面具有更好的性能;然而,改进相对有限,并且在训练方面需要更多的计算资源。

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