Abstract
PurposeEarly detection of lung cancer is of importance since it can increase patients’ chances of survival. To detect nodules accurately during screening, radiologists would commonly take the axial, coronal, and sagittal planes into account, rather than solely the axial plane in clinical evaluation. Inspired by clinical work, the paper aims to develop an accurate deep learning framework for nodule detection by a combination of multiple planes.MethodsThe nodule detection system is designed in two stages, multiplanar nodule candidate detection, multiscale false positive (FP) reduction. At the first stage, a deeply supervised encoder–decoder network is trained by axial, coronal, and sagittal slices for the candidate detection task. All possible nodule candidates from the three different planes are merged. To further refine results, a three‐dimensional multiscale dense convolutional neural network that extracts multiscale contextual information is applied to remove non‐nodules. In the public LIDC‐IDRI dataset, 888 computed tomography scans with 1186 nodules accepted by at least three of four radiologists are selected to train and evaluate our proposed system via a tenfold cross‐validation scheme. The free‐response receiver operating characteristic curve is used for performance assessment.ResultsThe proposed system achieves a sensitivity of 94.2% with 1.0 FP/scan and a sensitivity of 96.0% with 2.0 FPs/scan. Although it is difficult to detect small nodules (i.e., <6 mm), our designed CAD system reaches a sensitivity of 93.4% (95.0%) of these small nodules at an overall FP rate of 1.0 (2.0) FPs/scan. At the nodule candidate detection stage, results show that the system with a multiplanar method is capable to detect more nodules compared to using a single plane.ConclusionOur approach achieves good performance not only for small nodules but also for large lesions on this dataset. This demonstrates the effectiveness of our developed CAD system for lung nodule detection.
Highlights
Of lung cancer can give better treatment alternatives to patients and increase their survival chances.[5]
The results showed that using maximum intensity projection can improve the performance of deep learning-based Computer-aided detection (CAD) for lung nodule detection
The key contributions of this paper are as follows. (a) Considering the axial plane, the coronal plane, and the sagittal plane, we developed an automatic nodule identification system based on multiplanar convolutional neural networks using transfer learning. (b) We explored the performance and influence of each plane for nodule detection in a CAD system
Summary
Of lung cancer can give better treatment alternatives to patients and increase their survival chances.[5]. The implementation of lung cancer screening reduces the mortality rate of patients, it results in a heavy workload for radiologists. The aim of any CAD system for lung nodule detection is to reach a high sensitivity with a low FP rate. CAD systems still have not been widely used in clinical practice for various reasons, including lack of reimbursement and low sensitivity or high FP rates of the available systems.[8,9] The challenges of this task are mainly the large variety in nodule morphology and the detection of small nodules, which are missed
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