Recent studies have shown that lung cancer screening using annual low-dose computed tomography (CT) reduces lung cancer mortality by 20% compared to traditional chest radiography. Therefore, CT lung screening has started to be used widely all across the world. However, analyzing these images is a serious burden for radiologists. The number of slices in a CT scan can be up to 600. Therefore, computer-aided-detection (CAD) systems are very important for faster and more accurate assessment of the data. In this study, we proposed a framework that analyzes CT lung screenings using convolutional neural networks (CNNs) to reduce false positives. We trained our model with different volume sizes and showed that volume size plays a critical role in the performance of the system. We also used different fusions in order to show their power and effect on the overall accuracy. 3D CNNs were preferred over 2D CNNs because 2D convolutional operations applied to 3D data could result in information loss. The proposed framework has been tested on the dataset provided by the LUNA16 Challenge and resulted in a sensitivity of 0.831 at 1 false positive per scan.
翻译:最近的研究显示,使用每年低剂量计算断层摄影(CT)对肺癌进行筛查,比传统胸腔放射法减少20%的肺癌死亡率,因此,肺癌筛查开始在全世界广泛使用,但是,分析这些图像对放射学家来说是一个沉重的负担。CT扫描中的切片数量可以高达600个。因此,计算机辅助检测系统对于更快、更准确地评估数据非常重要。在这项研究中,我们提出了一个框架,用以分析使用神经神经网络(CNN)进行的肺癌筛查,以减少假阳性。我们以不同体积大小的方式培训了我们的模型,并表明体积大小在系统性能中起着关键作用。我们还使用了不同的聚变异作用,以显示其力量和对整个准确性的影响。我们更喜欢2DCNN,因为3D数据应用的2D演进操作可能会造成信息损失。拟议框架已经测试了LUNA16挑战(CNN16)提供的数据集,并导致每部0.831次假正扫描的敏感度。