2 March 2018 Aorta and pulmonary artery segmentation using optimal surface graph cuts in non-contrast CT
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Abstract
Accurate measurements of the size and shape of the aorta and pulmonary arteries are important as risk factors for cardiovascular diseases, and for Chronicle Obstacle Pulmonary Disease (COPD).1 The aim of this paper is to propose an automated method for segmenting the aorta and pulmonary arteries in low-dose non-ECGgated non-contrast CT scans. Low contrast and the high noise level make the automatic segmentation in such images a challenging task. In the proposed method, first, a minimum cost path tracking algorithm traces the centerline between user-defined seed points. The cost function is based on a multi-directional medialness filter and a lumen intensity similarity metric. The vessel radius is also estimated from the medialness filter. The extracted centerlines are then smoothed and dilated non-uniformly according to the extracted local vessel radius and subsequently used as initialization for a graph-cut segmentation. The algorithm is evaluated on 225 low-dose non-ECG-gated non-contrast CT scans from a lung cancer screening trial. Quantitatively analyzing 25 scans with full manual annotations, we obtain a dice overlap of 0.94±0.01 for the aorta and 0.92±0.01 for pulmonary arteries. Qualitative validation by visual inspection on 200 scans shows successful segmentation in 93% of all cases for the aorta and 94% for pulmonary arteries.
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Zahra Sedghi Gamechi, Zahra Sedghi Gamechi, Andres M. Arias-Lorza, Andres M. Arias-Lorza, Jesper Holst Pedersen, Jesper Holst Pedersen, Marleen de Bruijne, Marleen de Bruijne, } "Aorta and pulmonary artery segmentation using optimal surface graph cuts in non-contrast CT", Proc. SPIE 10574, Medical Imaging 2018: Image Processing, 105742D (2 March 2018); doi: 10.1117/12.2293748; https://doi.org/10.1117/12.2293748
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