Tellapuri S, Park HS, Kalva SP. Pulmonary arteriovenous malformations. Int J Cardiovasc Imaging. 2019;35(8):1421–8.
Article
Google Scholar
Papagiannis J, Apostolopoulou S, Sarris G, Rammos S. Diagnosis and management of pulmonary arteriovenous malformations. Images Paediatr Cardiol. 2002;4(1):33–49.
Google Scholar
Cummings KW, Bhalla S. Pulmonary vascular diseases. Clin Chest Med. 2015;36(2):235-248 viii.
Article
Google Scholar
Zhou C, et al. Automatic multiscale enhancement and segmentation of pulmonary vessels in CT pulmonary angiography images for CAD applications. Med Phys. 2007;34(12):4567–77.
Article
Google Scholar
Rahaghi FN, et al. Pulmonary vascular morphology as an imaging biomarker in chronic thromboembolic pulmonary hypertension. Pulm Circ. 2016;6(1):70–81.
Article
Google Scholar
Sluimer I, Schilham A, Prokop M, van Ginneken B. Computer analysis of computed tomography scans of the lung: a survey. IEEE Trans Med Imaging. 2006;25(4):385–405.
Article
Google Scholar
Huang W, Yen RT, McLaurine M, Bledsoe G. Morphometry of the human pulmonary vasculature. J Appl Physiol. 1996;81(5):2123–33.
Article
Google Scholar
Jimenez-Carretero D, Bermejo-Peláez S, Nardelli P, Fraga P, Fraile E, Estépar RS, Ledesma-Carbayo MJ. A graph-cut approach for pulmonary artery-vein segmentation in noncontrast CT images. Med Image Anal. 2019;52:144–59.
Article
Google Scholar
Gao Z, Grout RW, Holtze C, Hoffman EA, Saha P. A new paradigm of interactive artery/vein separation in noncontrast pulmonary CT imaging using multiscale topomorphologic opening. IEEE Trans Biomed Eng. 2012;59(11):3016–27. https://doi.org/10.1109/TBME.2012.2212894.
Article
Google Scholar
Charbonnier JP, Brink M, Ciompi F, Scholten ET, Schaefer-Prokop CM, Van Rikxoort EM. Automatic pulmonary artery-vein separation and classification in computed tomography using tree partitioning and peripheral vessel matching. IEEE Trans Med Imaging. 2016;35(3):882–92.
Article
Google Scholar
Zhang Z, Li Y, Shin BS. Robust color medical image segmentation on unseen domain by randomized illumination enhancement. Comput Biol Med. 2022;145:105427.
Article
Google Scholar
Nardelli P, Jimenez-Carretero D, Bermejo-Pelaez D, Ledesma-Carbayo MJ, Rahaghi Farbod N, San Jose Estepar R. Deep-learning strategy for pulmonary artery-vein classification of non-contrast CT images. In: 2017 IEEE 14th international symposium on biomedical imaging (ISBI 2017). 2017. p. 384–87.
Pu J, Leader JK, Sechrist J, Beeche CA, Singh JP, Ocak IK. Automated identification of pulmonary arteries and veins depicted in non-contrast chest CT scans. Med Image Anal. 2022;77:102367.
Article
Google Scholar
Moses D, Sammut C, Zrimec T. Automatic segmentation and analysis of the main pulmonary artery on standard post-contrast CT studies using iterative erosion and dilation. Int J Comput Assist Radiol Surg. 2016;11(3):381–95.
Article
Google Scholar
Nardelli P, Jimenez-Carretero D, Bermejo-Pelaez D, Washko GR, Rahaghi FN, Ledesma-Carbayo MJ, Estepar RSJ. Pulmonary artery-vein classification in CT images using deep learning. IEEE Trans Med Imaging. 2018;37(11):2428–40.
Article
Google Scholar
Bozkurt F, Köse C, Sari A. Segmentation of carotid arteries in CTA images using region-based active contours and classification. In: 2017 international artificial intelligence and data processing symposium (IDAP). Malatya, Turkey, 2017, pp. 1–8. https://doi.org/10.1109/IDAP.2017.8090261
Du H, Shao K, Bao F, Zhang Y, Gao C, Wu W, Zhang C. Automated coronary artery tree segmentation in coronary CTA using a multiobjective clustering and toroidal model-guided tracking method. Comput Methods Prog Biomed. 2021;199:105908.
Article
Google Scholar
Nee LH, et al. White blood cell segmentation for acute leukemia bone marrow images. In: International conference on biomedical engineering. 2012.
Tan C, et al. Vessel enhancement and segmentation of 4D CT lung image using stick tensor voting. Sens Imaging. 2016;17(1):1–16.
Google Scholar
Helmberger M, Urschler M, Pienn M, et al. Pulmonary vascular tree segmentation from contrast-enhanced CT images. arXiv. 2013. https://doi.org/10.48550/arXiv.1304.7140.
Hu S, Hoffman EA, Reinhardt JM. Automatic lung segmentation for accurate quantitation of volumetric X-ray CT images. IEEE Trans Med Imaging. 2001;20(6):490–8.
Article
Google Scholar
Dharmalingham V, Kumar D. A model based segmentation approach for lung segmentation from chest computer tomography images. Multimed Tools Appl. 2020;79(15–16):10003–28.
Article
Google Scholar
Naseri Samaghcheh Z, et al. A new model-based framework for lung tissue segmentation in three-dimensional thoracic CT images. Signal Image Video Process. 2018;12(2):339–46.
Article
Google Scholar
Carvalho LE, et al. 3D segmentation algorithms for computerized tomographic imaging: a systematic literature review. J Digit Imaging. 2018;31(6):799–850.
Article
Google Scholar
Wang Q, et al. HOSVD-based 3D active appearance model: segmentation of lung fields in CT images. J Med Syst. 2016;40(7):176.
Article
Google Scholar
Salama WM, et al. Lung images segmentation and classification based on deep learning: a new automated CNN approach. J Phys Conf Ser. 2021;2128(1):12011.
Article
Google Scholar
Geng H, Tan W-J, Yang J-Z, Bian Z-J, Zhao D-Z. Pulmonary tissue segmentation and quantitative function analysis based on CT image. Xiao Wei Xing Ji Suan Ji Xi Tong. 2016;37(03):581–7.
Google Scholar
Buelow T, Wiemker R, Blaffert T, Lorenz C, Renisch S. Automatic extraction of the pulmonary artery tree from multi-slice CT data. In: SPIE medical imaging. 2005. p. 730–740
Otsu N. A threshold selection method from gray level histograms. IEEE Trans Syst Man Cybern. 1979;9:62–6.
Article
Google Scholar
Tan W, Li X, Zhou Q, Liu P, Yang J. Pulmonary image anatomical structure segmentation dataset and applications. Zhongguo tu xiang tu xing xue bao. 2021;26(9):2111–20.
Google Scholar
Boykov YY. Interactive graph cuts for optimal boundary & region segmentation of objects in n-d images. In: Proceedings of the eighth IEEE international conference on computer vision, vol. 7. IEEE Computer Society; 2001. p. 105–112.
Boykov Y, Veksler O. Graph cuts in vision and graphics: theories and applications. In: Handbook of mathematical models in computer vision. Springer; 2006. p. 79–96.
Goodfellow I, Bengio Y, Courville A. Deep learning, vol. 1. Cambridge: MIT Press; 2016. p. 326–66.
MATH
Google Scholar
Gu J, Wang Z, Kuen J, Ma L, Shahroudy A, Shuai B, Liu T, Wang X, Wang L, Wang G, Cai J. Recent advances in convolutional neural networks. arXiv Preprint. 2015. arXiv:1512.07108.
Zunair H, Ben Hamza A. Sharp U-Net: depthwise convolutional network for biomedical image segmentation. Comput Biol Med. 2021;136:104699.
Article
Google Scholar
Wu R, Xin Y, Qian J, Dong Y. A multi-scale interactive U-Net for pulmonary vessel segmentation method based on transfer learning. Biomed Signal Process Control. 2023;80:104407.
Article
Google Scholar
Chen C, Zhang C, Wang J, Li D, Li Y, Hong J. Semantic segmentation of mechanical assembly using selective kernel convolution UNet with fully connected conditional random field. Measurement. 2023;209:112499.
Article
Google Scholar
Zhou Y, Kong Q, Zhu Y, Su Z. MCFA-UNet: multiscale cascaded feature attention U-Net for liver segmentation. IRBM. 2023;44(4):100789.
Article
Google Scholar
Han J, Wang Y, Gong H. Fundus retinal vessels image segmentation method based on improved U-Net. IRBM. 2022;43(6):628–39.
Article
Google Scholar
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