Abstract
Pulmonary valve disease affects a significant portion of the global population and often occurs in conjunction with other heart dysfunctions. Emerging interventional methods enable percutaneous pulmonary valve implantation, which constitute an alternative to open heart surgery. As minimal invasive procedures become common practice, imaging and non-invasive assessment techniques turn into key clinical tools. In this paper, we propose a novel approach for intervention planning as well as morphological and functional quantification of the pulmonary trunk and valve. An abstraction of the anatomic structures is represented through a four-dimensional, physiological model able to capture large pathological variation. A hierarchical estimation, based on robust learning methods, is applied to identify the patient-specific model parameters from volumetric CT scans. The algorithm involves detection of piecewise affine parameters, fast centre-line computation and local surface delineation. The estimated personalized model enables for efficient and precise quantification of function and morphology. This ability may have impact on the assessment and surgical interventions of the pulmonary valve and trunk. Experiments performed on 50 cardiac computer tomography sequences demonstrated the average speed of 202 seconds and accuracy of 2.2mm for the proposed approach. An initial clinical validation yielded a significant correlation between model-based and expert measurements. To the best of our knowledge this is the first dynamic model of the pulmonary trunk and right ventricle outflow track estimated from CT data.
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Keywords
- Pulmonary Valve
- Pulmonary Trunk
- Pulmonary Valve Replacement
- Percutaneous Pulmonary Valve Implantation
- Expert Measurement
These keywords were added by machine and not by the authors. This process is experimental and the keywords may be updated as the learning algorithm improves.
References
Boudjemline, Y., Agnoletti, G., Bonnet, D., Sidi, D., Bonhoeffer, P.: Percutaneous pulmonary valve replacement in a large right ventricular outflow tract: An experimental study. American College of Cardiology 43, 1082–1087 (2004)
Parr, J., Kirklin, J., Blackstone, E.: The early risk of re-replacement of aortic valves. The Annals of Thoracic Surgery 23(4), 319–322 (1977)
Carnaghan, H.: Percutaneous pulmonary valve implantation and the future of replacement. Science and Technology 20(1), 319–322 (2006)
Schievano, S., Migliavacca, F., Coats, S., Khambadkone, L., Carminati, M., Wilson, N., Deanfield, J., Bonhoeffer, P., Taylor, A.: Percutaneous pulmonary valve implantation based on rapid prototyping of right ventricular outflow tract and pulmonary trunk from mr data. Radiology 242(2), 490–499 (2007)
Schievano, S., Coats, L., Migliavacca, F., Norman, W., Frigiola, A., Deanfield, J., Bonhoeffer, P., Taylor, A.: Variations in right ventricular outflow tract morphology following repair of congenital heart disease: Implications for percutaneous pulmonary valve implantation. Journal of Cardiovascular Magnetic Resonance 9(4), 687–695 (2007)
Bonhoeffer, P., Boudjemline, S.A., Qureshi, Y., Bidois, J.L., Iserin, L., Acar, P., Merckx, J., Kachaner, J., Sidi, D.: Percutaneous insertion of the pulmonary valve. Journal of the American College of Cardiology 39(10), 1664–1669 (in press, 2002)
Piegl, L., Tiller, W.: The NURBS book. Springer, London (1995)
Zheng, Y., Barbu, A., et al.: Fast automatic heart chamber segmentation from 3d ct data using marginal space learning and steerable features. In: ICCV (2007)
Tu, Z.: Probabilistic boosting-tree: Learning discriminativemethods for classification, recognition, and clustering. In: ICCV 2005, pp. 1589–1596 (2005)
Zheng, Y., Barbu, A., Georgescu, B., Scheuering, M., Comaniciu, D.: Four-chamber heart modeling and automatic segmentation for 3-d cardiac ct volumes using marginal space learning and steerable features. IEEE Transactions on Medical Imaging 27(11), 1668–1681 (2008)
Cootes, T.F., Taylor, C.J., Cooper, D.H., Graham, J.: Active shape models-their training and application. Computer Vision and Image Understanding 61(1), 38–59 (1995)
Yang, L., Georgescu, B., Zheng, Y., Meer, P., Comaniciu, D.: 3d ultrasound tracking of the left ventricle using one-step forward prediction and data fusion of collaborative trackers. In: CVPR (2008)
Nollen, G., Schijndel, K., Timmermans, J., Groenink, M., Barentsz, J., Wall, E., Stoker, J., Mulder, B.: Pulmonary artery root dilatation in marfan syndrome: quantitative assessment of an unknown criterion. Heart 87(5), 470–471 (2002)
Ionasec, I.I., Tsymbal, A., Vitanovski, D., Georgescu, B., Zhou, S., Navab, N., Comaniciu, D.: Shape-based diagnosis of the aortic valve. In: SPIE Medical Imaging, Orlando, USA (February 2009)
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Vitanovski, D. et al. (2009). Personalized Pulmonary Trunk Modeling for Intervention Planning and Valve Assessment Estimated from CT Data. In: Yang, GZ., Hawkes, D., Rueckert, D., Noble, A., Taylor, C. (eds) Medical Image Computing and Computer-Assisted Intervention – MICCAI 2009. MICCAI 2009. Lecture Notes in Computer Science, vol 5761. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-04268-3_3
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DOI: https://doi.org/10.1007/978-3-642-04268-3_3
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