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Media type:
E-Article
Title:
EfficientUNet: Modified encoder‐decoder architecture for the lung segmentation in chest x‐ray images
Contributor:
Agrawal, Tarun;
Choudhary, Prakash
Published:
Wiley, 2022
Published in:
Expert Systems, 39 (2022) 8
Language:
English
DOI:
10.1111/exsy.13012
ISSN:
0266-4720;
1468-0394
Origination:
Footnote:
Description:
<jats:title>Abstract</jats:title><jats:p>Chest x‐rays are a widely used medical imaging technique for the early detection of pulmonary diseases. However, the increasing workload and shortage of radiologists have motivated the research community to explore the possibilities in automated diagnosis. Segmentation is the most critical and essential procedure to improve the automatic diagnosis. Irregular lung shape and size with the overlapped lung regions make the identification of lung boundaries difficult. Further, the dense abnormalities often have high‐intensity values that can be interpreted as lung boundaries. UNet is the most popular segmentation architecture among the deep learning community. Despite its high performance, there is scope for improvement. Most of the proposed segmentation models for lung segmentation in chest x‐rays are trained and tested on a same dataset. It is reported that the model trained on one dataset fails when tested on another dataset. The aim of this study is to develop an efficient architecture for accurate lung segmentation in chest x‐rays. The proposed model uses the pre‐trained encoder, and the decoder uses residual learning and batch normalization to improve the performance. The publicly available Shenzhen, Montgomery County, and the NIH datasets are used for the evaluation of the proposed model. It is also validated by cross‐dataset generalization. The proposed model obtained the 96.14% DSC and 92.67% JI value on the Shenzhen dataset, while 98.48% DSC and 97.01% JI value on the MC dataset. For cross‐dataset evaluation, the EfficientUNet reported the DSC value of 95.97% and JI value of 92.34% for the MC dataset. While the DSC value of 94.02% and JI value of 88.86% on the NIH dataset. The obtained results across the different metrics show the efficiency of the proposed model. Unlike, the other state‐of‐the‐art models, the proposed model is evaluated on the lungs that are highly irregular in shape and size due to different pulmonary abnormalities.</jats:p>