Detection and Semiquantitative Analysis of Cardiomegaly, Pneumothorax, and Pleural Effusion on Chest Radiographs

Leilei Zhou; Xindao Yin; Tao Zhang; Yuan Feng; Ying Zhao; Mingxu Jin; Mingyang Peng; Chunhua Xing; Fengfang Li; Ziteng Wang; Guoliang Wei; Xiao Jia; Yujun Liu; Xinying Wu; Lingquan Lu

doi:10.1148/ryai.2021200172

Detection and Semiquantitative Analysis of Cardiomegaly, Pneumothorax, and Pleural Effusion on Chest Radiographs

Radiol Artif Intell. 2021 May 19;3(4):e200172. doi: 10.1148/ryai.2021200172. eCollection 2021 Jul.

Authors

Leilei Zhou¹, Xindao Yin¹, Tao Zhang¹, Yuan Feng¹, Ying Zhao¹, Mingxu Jin¹, Mingyang Peng¹, Chunhua Xing¹, Fengfang Li¹, Ziteng Wang¹, Guoliang Wei¹, Xiao Jia¹, Yujun Liu¹, Xinying Wu¹, Lingquan Lu¹

Affiliation

¹ Department of Radiology, Nanjing First Hospital, Nanjing Medical University, Nanjing 210006, China (L.Z., X.Y., T.Z., Y.F., Y.Z., M.J., M.P., C.X., F.L., X.W., L.L.); and Yizhun Medical AI Co., Ltd., Beijing, China (Z.W., G.W., X.J., Y.L.).

Abstract

Purpose: To develop and evaluate deep learning models for the detection and semiquantitative analysis of cardiomegaly, pneumothorax, and pleural effusion on chest radiographs.

Materials and methods: In this retrospective study, models were trained for lesion detection or for lung segmentation. The first dataset for lesion detection consisted of 2838 chest radiographs from 2638 patients (obtained between November 2018 and January 2020) containing findings positive for cardiomegaly, pneumothorax, and pleural effusion that were used in developing Mask region-based convolutional neural networks plus Point-based Rendering models. Separate detection models were trained for each disease. The second dataset was from two public datasets, which included 704 chest radiographs for training and testing a U-Net for lung segmentation. Based on accurate detection and segmentation, semiquantitative indexes were calculated for cardiomegaly (cardiothoracic ratio), pneumothorax (lung compression degree), and pleural effusion (grade of pleural effusion). Detection performance was evaluated by average precision (AP) and free-response receiver operating characteristic (FROC) curve score with the intersection over union greater than 75% (AP75; FROC score75). Segmentation performance was evaluated by Dice similarity coefficient.

Results: The detection models achieved high accuracy for detecting cardiomegaly (AP75, 98.0%; FROC score75, 0.985), pneumothorax (AP75, 71.2%; FROC score75, 0.728), and pleural effusion (AP75, 78.2%; FROC score75, 0.802), and they also weakened boundary aliasing. The segmentation effect of the lung field (Dice, 0.960), cardiomegaly (Dice, 0.935), pneumothorax (Dice, 0.827), and pleural effusion (Dice, 0.826) was good, which provided important support for semiquantitative analysis.

Conclusion: The developed models could detect cardiomegaly, pneumothorax, and pleural effusion, and semiquantitative indexes could be calculated from segmentations.Keywords: Computer-Aided Diagnosis (CAD), Thorax, CardiacSupplemental material is available for this article.© RSNA, 2021.

Keywords: Cardiac; Computer-Aided Diagnosis (CAD); Thorax.

2021 by the Radiological Society of North America, Inc.