Your search keyword '"Cebral, Juan R."' showing total 4 results

1. Local Hemodynamic Conditions Associate with Focal Changes in the Intracranial Aneurysm Wall

Author

Cebral, Juan R., Detmer, Felicitas, Chung, Bong Jae, Choque-Velasquez, Joham, Rezai, Behnam, Lehto, Hanna, Tulamo, Riikka, Hernesniemi, Juha, Niemela, Mika, Yu, Alexander, Williamson, Richard, Aziz, Khaled, Sakur, Sophia, Amin-Hanjani, Sepideh, Charbel, Fady, Tobe, Yasutaka, Robertson, Anne, and Frosen, Juhana

Subjects

Imaging, Three-Dimensional, Risk Factors, Hemodynamics, Hydrodynamics, Models, Cardiovascular, Humans, Intracranial Aneurysm, Stress, Mechanical, Article

Abstract

BACKGROUND AND PURPOSE: Aneurysm hemodynamics has been associated with wall histology and inflammation. We now investigated associations between local hemodynamics and focal wall changes visible intra-operatively. METHODS: Computational fluid dynamics models were constructed from 3D images of 65 aneurysms treated surgically. Aneurysm regions with different visual appearances were identified in intra-operative videos: 1) “atherosclerotic” (yellow), 2) “hyperplastic” (white), 3) “thin” (red), 4) rupture site, and 5) “normal” (similar to parent artery) and marked on 3D reconstructions. Regional hemodynamics was characterized by: wall shear stress (WSS), oscillatory shear index (OSI), relative residence time (RRT), WSS gradient and divergence, gradient oscillatory number (GON), and dynamic pressure (PRE); and compared with the Mann-Whitney test. RESULTS: Hyperplastic regions had lower average WSS (p=0.005) and pressure (p=0.009) than normal regions. Flow conditions in atherosclerotic and hyperplastic regions were similar, but had higher average RRT (p=0.03), and OSI (p=0.04) than thin regions. Hyperplastic regions also had higher average GON (p=0.002) than thin regions. Thin regions had lower average RRT (p

Published

2019

2. Estimation of Aneurysm Wall Motion from 4D Computerized Tomographic Angiography Images

Author

Castro, Marcelo Adrian, Ahumada Olivares, María C., Putman, Christopher M., and Cebral, Juan R.

Subjects

Medical Image Processing, CIENCIAS MÉDICAS Y DE LA SALUD, Wall Shear Stress, purl.org/becyt/ford/3.2 [https], Neurología Clínica, Cerebral aneurysms, purl.org/becyt/ford/3 [https], Medicina Clínica, Radiología, Medicina Nuclear y Diagnóstico por Imágenes, 4D Computerized Tomographic Angiography, Wall Motion

Abstract

It is widely accepted that wall shear stressis associated to aneurysm formation, growthand rupture. Early identification of potential risk factors may contribute to decide the treatment and improve patient care. Previous studies have shown associations between high aneurysm wall shear stress values and both elevated risk of rupture and localization of regions of aneurysm progression. Based on the assumption that damaged regions of the endothelium have different mechanical properties, regions with differentiated wall displacement amplitudes are expected. A previous approach based on the analysis ofbidimensional dynamic tomographic angiography images at a limited number of points during the cardiac cycle showed only small displacements in some patients using that simplified and semi-automatic low resolution methodology. The purpose of this work is to overcome some of those limitations. High time and spatial resolution four dimensional computerized tomographic angiography images of cerebral aneurysms were acquired and analyzed in order to identify and characterize wall motion. Images were filtered andsegmented at nineteentime points during the cardiac cycle.An average image was computed to generate the vascular model. Anunstructured mesh of tetrahedral elements was generated using an advancing front technique. A finite element blood flow simulationwas carried out under personalized pulsatile flow conditions. A fuzzy c-means clustering algorithm was used to estimate regions that exhibit wall motion within the aneurysm sac. A good correlation between localization of regions of elevated wall shear stress and regionsexhibiting wall motion was found. Fil: Castro, Marcelo Adrian. Universidad Tecnológica Nacional. Facultad Regional Buenos Aires; Argentina. Consejo Nacional de Investigaciones Científicas y Técnicas; Argentina Fil: Ahumada Olivares, María C.. Universidad Favaloro; Argentina Fil: Putman, Christopher M. . Inova Fairfax Hospital. Department of Interventional Neuroradiology; Estados Unidos Fil: Cebral, Juan R.. George Mason University. Department of Computational and Data Sciences; Estados Unidos

Published

2013

3. CFD and PIV Analysis of Hemodynamics in a Growing Intracranial Aneurysm

Author

Raschi, Marcelo, Mut, Fernando, Byrne, Greg, Putman, Christopher M., Tateshima, Satoshi, Viñuela, Fernando, Tanoue, Tetsuya, Tanishita, Kazuo, and Cebral, Juan R.

Subjects

Male, Hemorheology, Hemodynamics, Models, Cardiovascular, Humans, Computer Simulation, Intracranial Aneurysm, Middle Aged, Article

Abstract

Hemodynamics is thought to be a fundamental factor in the formation, progression, and rupture of cerebral aneurysms. Understanding these mechanisms is important to improve their rupture risk assessment and treatment. In this study, we analyze the blood flow field in a growing cerebral aneurysm using experimental particle image velocimetry (PIV) and computational fluid dynamics (CFD) techniques. Patient-specific models were constructed from longitudinal 3D computed tomography angiography images acquired at 1-y intervals. Physical silicone models were constructed from the computed tomography angiography images using rapid prototyping techniques, and pulsatile flow fields were measured with PIV. Corresponding CFD models were created and run under matching flow conditions. Both flow fields were aligned, interpolated, and compared qualitatively by inspection and quantitatively by defining similarity measures between the PIV and CFD vector fields. Results showed that both flow fields were in good agreement. Specifically, both techniques provided consistent representations of the main intra-aneurysmal flow structures and their change during the geometric evolution of the aneurysm. Despite differences observed mainly in the near wall region, and the inherent limitations of each technique, the information derived is consistent and can be used to study the role of hemodynamics in the natural history of intracranial aneurysms.

Published

2011

4. Characterization of Cerebral Aneurysms for Assessing Risk of Rupture By Using Patient-Specific Computational Hemodynamics Models

Author

Cebral, Juan R., Castro, Marcelo A., Burgess, James E., Pergolizzi, Richard S., Sheridan, Michael J., and Putman, Christopher M.

Subjects

Adult, Aged, 80 and over, Male, Middle Cerebral Artery, Interventional, Hemodynamics, Intracranial Aneurysm, Pilot Projects, Aneurysm, Ruptured, Middle Aged, Cerebral Angiography, Imaging, Three-Dimensional, Logistic Models, Regional Blood Flow, Risk Factors, Cerebrovascular Circulation, cardiovascular system, Image Processing, Computer-Assisted, Humans, Radiographic Image Interpretation, Computer-Assisted, Female, cardiovascular diseases, Carotid Artery, Internal, Aged

Abstract

BACKGROUND AND PURPOSE: Hemodynamic factors are thought to play an important role in the initiation, growth, and rupture of cerebral aneurysms. This report describes a pilot clinical study of the association between intra-aneurysmal hemodynamic characteristics from computational fluid dynamic models and the rupture of cerebral aneurysms. METHODS: A total of 62 patient-specific models of cerebral aneurysms were constructed from 3D angiography images. Computational fluid dynamics simulations were performed under pulsatile flow conditions measured on a normal subject. The aneurysms were classified into different categories, depending on the complexity and stability of the flow pattern, the location and size of the flow impingement region, and the size of the inflow jet. The 62 models consisted of 25 ruptured and 34 unruptured aneurysms and 3 cases with unknown histories of hemorrhage. The hemodynamic features were analyzed for associations with history of rupture. RESULTS: A large variety of flow patterns was observed: 72% of ruptured aneurysms had complex or unstable flow patterns, 80% had small impingement regions, and 76% had small jet sizes. By contrast, unruptured aneurysms accounted for 73%, 82%, and 75% of aneurysms with simple stable flow patterns, large impingement regions, and large jet sizes, respectively. Aneurysms with small impingement sizes were 6.3 times more likely to have experienced rupture than those with large impingement sizes (P = .01). CONCLUSIONS: Image-based patient-specific numeric models can be constructed in an efficient manner that allows clinical studies of intra-aneurysmal hemodynamics. A simple flow characterization system was proposed, and interesting trends in the association between hemodynamic features and aneurysmal rupture were found. Simple stable patterns, large impingement regions, and jet sizes were more commonly seen with unruptured aneurysms. By contrast, ruptured aneurysms were more likely to have disturbed flow patterns, small impingement regions, and narrow jets.

Published

2005