Cosmin Adrian Morariu1, Tobias Terheiden2, Daniel Sebastian Dohle3, Konstantinos Tsagakis3, Josef Pauli2. 1. Intelligent Systems, Faculty of Engineering, University of Duisburg-Essen, 47057, Duisburg, Germany. adrian.morariu@uni-due.de. 2. Intelligent Systems, Faculty of Engineering, University of Duisburg-Essen, 47057, Duisburg, Germany. 3. Department of Thoracic and Cardiovascular Surgery, University Clinic Essen, Essen, Germany.
Abstract
PURPOSE: Our goal is to provide precise measurements of the aortic dimensions in case of dissection pathologies. Quantification of surface lengths and aortic radii/diameters together with the visualization of the dissection membrane represents crucial prerequisites for enabling minimally invasive treatment of type A dissections, which always also imply the ascending aorta. METHODS: We seek a measure invariant to luminance and contrast for aortic outer wall segmentation. Therefore, we propose a 2D graph-based approach using phase congruency combined with additional features. Phase congruency is extended to 3D by designing a novel conic directional filter and adding a lowpass component to the 3D Log-Gabor filterbank for extracting the fine dissection membrane, which separates the true lumen from the false one within the aorta. RESULTS: The result of the outer wall segmentation is compared with manually annotated axial slices belonging to 11 CTA datasets. Quantitative assessment of our novel 2D/3D membrane extraction algorithms has been obtained for 10 datasets and reveals subvoxel accuracy in all cases. Aortic inner and outer surface lengths, determined within 2 cadaveric CT datasets, are validated against manual measurements performed by a vascular surgeon on excised aortas of the body donors. CONCLUSIONS: This contribution proposes a complete pipeline for segmentation and quantification of aortic dissections. Validation against ground truth of the 3D contour lengths quantification represents a significant step toward custom-designed stent-grafts.
PURPOSE: Our goal is to provide precise measurements of the aortic dimensions in case of dissection pathologies. Quantification of surface lengths and aortic radii/diameters together with the visualization of the dissection membrane represents crucial prerequisites for enabling minimally invasive treatment of type A dissections, which always also imply the ascending aorta. METHODS: We seek a measure invariant to luminance and contrast for aortic outer wall segmentation. Therefore, we propose a 2D graph-based approach using phase congruency combined with additional features. Phase congruency is extended to 3D by designing a novel conic directional filter and adding a lowpass component to the 3D Log-Gabor filterbank for extracting the fine dissection membrane, which separates the true lumen from the false one within the aorta. RESULTS: The result of the outer wall segmentation is compared with manually annotated axial slices belonging to 11 CTA datasets. Quantitative assessment of our novel 2D/3D membrane extraction algorithms has been obtained for 10 datasets and reveals subvoxel accuracy in all cases. Aortic inner and outer surface lengths, determined within 2 cadaveric CT datasets, are validated against manual measurements performed by a vascular surgeon on excised aortas of the body donors. CONCLUSIONS: This contribution proposes a complete pipeline for segmentation and quantification of aortic dissections. Validation against ground truth of the 3D contour lengths quantification represents a significant step toward custom-designed stent-grafts.
Authors: Stefan Wörz; Hendrik von Tengg-Kobligk; Verena Henninger; Fabian Rengier; Hardy Schumacher; Dittmar Böckler; Hans-Ulrich Kauczor; Karl Rohr Journal: IEEE Trans Biomed Eng Date: 2010-06-21 Impact factor: 4.538
Authors: Daniel Wendt; Matthias Thielmann; Andreas Melzer; Jaroslav Benedik; Ionel Droc; Konstantinos Tsagakis; Daniel S Dohle; Heinz Jakob; John E Abele Journal: Minim Invasive Ther Allied Technol Date: 2013-08 Impact factor: 2.442
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