Abstract: A method and system for analyzing tubular structures, such as vascular bodies, with respect to their geometrical properties and mechanical loading conditions is disclosed. To this end, geometrical and structural models of vascular bodies are generated from standard sets of image data. The method or system works automatically and the tubular structure is analyzed within clinical relevant times by users without engineering background. Most critical in that sense is the integration of novel volume meshing and 3D segmentation techniques. The derived geometrical and structural models distinguish between structural relevant types of tissue, e.g., for abdominal aortic aneurysms the vessel wall and the intra-luminal thrombus are considered separately. The structural investigation of the vascular body is based on a detailed nonlinear Finite Element analysis.

Abstract: A method and system for analyzing tubular structures, such as vascular bodies, with respect to their geometrical properties and mechanical loading conditions is disclosed. To this end, geometrical and structural models of vascular bodies are generated from standard sets of image data. The method or system works automatically and the tubular structure is analyzed within clinical relevant times by users without engineering background. Most critical in that sense is the integration of novel volume meshing and 3D segmentation techniques. The derived geometrical and structural models distinguish between structural relevant types of tissue, e.g., for abdominal aortic aneurysms the vessel wall and the intra-luminal thrombus are considered separately. The structural investigation of the vascular body is based on a detailed nonlinear Finite Element analysis.