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International Journal of Computer Assisted Radiology and Surgery
Published in: International Journal of Computer Assisted Radiology and Surgery 2/2014

01-03-2014 | Original Article

Automated aorta segmentation in low-dose chest CT images

Authors: Yiting Xie, Jennifer Padgett, Alberto M. Biancardi, Anthony P. Reeves

Published in: International Journal of Computer Assisted Radiology and Surgery | Issue 2/2014

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Abstract

Purpose

   Abnormalities of aortic surface and aortic diameter can be related to cardiovascular disease and aortic aneurysm. Computer-based aortic segmentation and measurement may aid physicians in related disease diagnosis. This paper presents a fully automated algorithm for aorta segmentation in low-dose non-contrast CT images.

Methods

   The original non-contrast CT scan images as well as their pre-computed anatomy label maps are used to locate the aorta and identify its surface. First a seed point is located inside the aortic lumen. Then, a cylindrical model is progressively fitted to the 3D image space to track the aorta centerline. Finally, the aortic surface is located based on image intensity information. This algorithm has been trained and tested on 359 low-dose non-contrast CT images from VIA-ELCAP and LIDC public image databases. Twenty images were used for training to obtain the optimal set of parameters, while the remaining images were used for testing. The segmentation result has been evaluated both qualitatively and quantitatively. Sixty representative testing images were used to establish a partial ground truth by manual marking on several axial image slices.

Results

   Compared to ground truth marking, the segmentation result had a mean Dice Similarity Coefficient of 0.933 (maximum 0.963 and minimum 0.907). The average boundary distance between manual segmentation and automatic segmentation was 1.39 mm with a maximum of 1.79 mm and a minimum of 0.83 mm.

Conclusion

   Both qualitative and quantitative evaluations have shown that the presented algorithm is able to accurately segment the aorta in low-dose non-contrast CT images.
Literature
1.
Schwartz S, Taljanovic M, Smyth S, O’Brien M, Rogers L (2007) CT findings of rupture, impending rupture, and contained rupture of abdominal aortic aneurysms. Am J Roentgenol 188(1):57–62
2.
Hu S, Hoffman EA, Reinhardt JM (2001) Automatic lung segmentation for accurate quantitation of volumetric X-ray CT images. IEEE Trans Med Imaging 20:490–498PubMedCrossRef
3.
Schwartz E, Gottardi R, Holfeld J, Loewe C, Czerny M, Langs G (2010) Evaluating deformation patterns of the thoracic aorta in gated CTA sequences, ISBI, pp 21–24
4.
Wang S, Fu L, Yue Y, Kang Y, Liu J (2009) Fast and automatic segmentation of ascending aorta in MSCT volume data, CISP, pp 1–5
5.
Kurkure U, Avila-Montes OC, Kakadiaris IA (2008) Automated segmentation of thoracic aorta in non-contrast CT images, ISBI, pp 29–32
6.
Isgum I, Staring M, Rutten A, Prokop M, Viergever MA, van Ginneken B (2009) Multi-atlas-based segmentation with local decision fusion-application to cardiac and aortic segmentation in CT scans. IEEE Trans Med Imaging 28:1000–1010
7.
Naranjo V, Angulo J, Villanueva E, Alcaniz M, Lopez-Celdada S (2011) Aorta segmentation using the watershed algorithm for an augmented reality system in laparoscopic surgery, ICIP, pp 2649–2652
8.
Burger P, Forbat SM, Mohiaddin RD, Yang GZ (1997) Automatic tracking of the aorta in cardiovascular MR images using deformable models. IEEE Trans Med Imaging 16:581–590PubMedCrossRef
9.
Al-Agamy AO, Osman NF, Fahmy AS (2010) Segmentation of ascending and descending aorta from magnetic resonance flow images, 5th CIBEC, pp 41–44
10.
De Gonzalez AB, Darby S (2004) Risk of cancer from diagnostic X-rays: estimates for the UK and 14 other countries. Lancet 363(9406):345–351CrossRef
11.
Reeves AP, Biancardi AM, Yankelevitz DF, Cham MD Henschke CI (2012) Heart region segmentation from low-dose CT scans: an anatomy based approach, SPIE International Symposium on Medical, Imaging, pp 83142A
12.
13.
Armato SG et al (2011) The lung image database consortium (LIDC) and image database resource initiative (IDRI): a completed reference database of lung nodules on CT scans. Med Phys 38:915–931PubMedCentralPubMedCrossRef
14.
Lee J, Reeves AP (2009) Segmentation of the airway tree from chest CT using local volume of interest, 2nd International workshop of pulmonary image, analysis, pp 333–340
15.
Wala J (2011) Automated pulmonary artery segmentation by vessel tracking in low-dose computed tomography images. Cornell University, Ithaca, Masters Dissertation
16.
Lee J, Reeves AP, Fotin S, Apanasovich T, Yankelevitz D (2008) Human airway measurement from CT images, SPIE International Symposium on Medical, Imaging, p 691518
17.
Fotin SV, Reeves AP, Cham MD, Yankelevitz DF, Henschke CI (2007) Segmentation of coronary arteries from CT angiography images, SPIE International Symposium on Medical, Imaging, pp 651418
18.
Keller B, Reeves AP, Cham MD, Henschke CI, Yankelevitz DF (2007) Semi-automated location identification of catheters in digital chest radiographs, SPIE International Symposium on Medical, Imaging, pp 651410
19.
Lee J, Reeves AP (2010) Segmentation of individual ribs from low-dose chest CT, SPIE International Symposium on Medical, Imaging, p 76243J
Metadata
Title
Automated aorta segmentation in low-dose chest CT images
Authors
Yiting Xie
Jennifer Padgett
Alberto M. Biancardi
Anthony P. Reeves
Publication date
01-03-2014
Publisher
Springer Berlin Heidelberg
Published in
International Journal of Computer Assisted Radiology and Surgery / Issue 2/2014
Print ISSN: 1861-6410
Electronic ISSN: 1861-6429
DOI
https://doi.org/10.1007/s11548-013-0924-5

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