Related papers: A Deep Learning Based Workflow for Detection of Lung Nodules With Chest Radiograph

A Deep Learning Based Workflow for Detection of Lung Nodules With Chest Radiograph

URL: http://arxiv.org/abs/2112.10184v2
Date: Tue, 21 Dec 2021 10:09:07 GMT
Title: A Deep Learning Based Workflow for Detection of Lung Nodules With Chest Radiograph
Authors: Yang Tai, Yu-Wen Fang (Same contribution), Fang-Yi Su, and Jung-Hsien Chiang
Abstract summary: We built a segmentation model to identify lung areas from CXRs, and sliced them into 16 patches. These labeled patches were then used to train finetune a deep neural network(DNN) model, classifying the patches as positive or negative.
Score: 0.0
License: http://creativecommons.org/licenses/by-nc-sa/4.0/
Abstract: PURPOSE: This study aimed to develop a deep learning-based tool to detect and localize lung nodules with chest radiographs(CXRs). We expected it to enhance the efficiency of interpreting CXRs and reduce the possibilities of delayed diagnosis of lung cancer. MATERIALS AND METHODS: We collected CXRs from NCKUH database and VBD, an open-source medical image dataset, as our training and validation data. A number of CXRs from the Ministry of Health and Welfare(MOHW) database served as our test data. We built a segmentation model to identify lung areas from CXRs, and sliced them into 16 patches. Physicians labeled the CXRs by clicking the patches. These labeled patches were then used to train and fine-tune a deep neural network(DNN) model, classifying the patches as positive or negative. Finally, we test the DNN model with the lung patches of CXRs from MOHW. RESULTS: Our segmentation model identified the lung regions well from the whole CXR. The Intersection over Union(IoU) between the ground truth and the segmentation result was 0.9228. In addition, our DNN model achieved a sensitivity of 0.81, specificity of 0.82, and AUROC of 0.869 in 98 of 125 cases. For the other 27 difficult cases, the sensitivity was 0.54, specificity 0.494, and AUROC 0.682. Overall, we obtained a sensitivity of 0.78, specificity of 0.79, and AUROC 0.837. CONCLUSIONS: Our two-step workflow is comparable to state-of-the-art algorithms in the sensitivity and specificity of localizing lung nodules from CXRs. Notably, our workflow provides an efficient way for specialists to label the data, which is valuable for relevant researches because of the relative rarity of labeled medical image data.

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