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Combining 2D wavelet edge highlighting and 3D thresholding for lung segmentation in thin-slice CT

Departments of ¹ Medical Physics and ² Radiology, School of Medicine, University of Patras, 265 00 Patras, Greece

Correspondence: Lena Costaridou, Department of Medical Physics, School of Medicine, University of Patras, 265 00 Patras, Greece. E-mail: costarid{at}upatras.gr

The first step in lung analysis by CT is the identification of the lung border. To deal with the increased number of sections per scan in thin-slice multidetector CT, it has been crucial to develop accurate and automated lung segmentation algorithms. In this study, an automated method for lung segmentation of thin-slice CT data is presented. The method exploits the advantages of a two-dimensional wavelet edge-highlighting step in lung border delineation. Lung volume segmentation is achieved with three-dimensional (3D) grey level thresholding, using a minimum error technique. 3D thresholding, combined with the wavelet pre-processing step, successfully deals with lung border segmentation challenges, such as anterior or posterior junction lines and juxtapleural nodules. Finally, to deal with mediastinum border under-segmentation, 3D morphological closing with a spherical structural element is applied. The performance of the proposed method is quantitatively assessed on a dataset originating from the Lung Imaging Database Consortium (LIDC) by comparing automatically derived borders with the manually traced ones. Segmentation performance, averaged over left and right lung volumes, for lung volume overlap is 0.983±0.008, whereas for shape differentiation in terms of mean distance it is 0.770±0.251 mm (root mean square distance is 0.520±0.008 mm; maximum distance is 3.327±1.637 mm). The effect of the wavelet pre-processing step was assessed by comparing the proposed method with the 3D thresholding technique (applied on original volume data). This yielded statistically significant differences for all segmentation metrics (p<0.01). Results demonstrate an accurate method that could be used as a first step in computer lung analysis by CT.