TY - GEN
T1 - Risk of rupture in abdominal aortic aneurysms and vulnerable plaques
T2 - 10th ASME Summer Bioengineering Conference, SBC2008
AU - Bluestein, Danny
AU - Alemu, Yared
AU - Xenos, Michalis
AU - Rissland, Peter
AU - Sheriff, Jawaad
AU - Gruberg, Luis
AU - Einav, Shmuel
AU - Ricotta, John J.
PY - 2009
Y1 - 2009
N2 - In this study we performed two separate fluid structure interaction (FSI) simulations. A patient-specific Abdominal Aortic Aneurysm (AAA) geometry, and coronary vulnerable plaque (VP) geometry in idealized and in patient based geometries reconstructed from intravascular (IVUS) measurements. The patient specific AAA FSI simulations were carried out with both isotropic and anisotropic wall properties. An orthotropic material model was used to describe wall properties, closely approximating experimental results of AAA specimens [1]. The results predict larger deformations and stress values for the anisotropic material model as compared to the isotropic one. This difference indicates that the isotropic formulation may underestimate the risk of rupture. The ability to quantify stresses developing within the aneurysm wall based on FSI simulations will help clinicians to reach informed decisions in determining rupture risk of AAA and the need for surgical intervention. The risk of rupture of vulnerable plaques was studied in both idealized and patient specific geometries using FSI simulations. The idealized model included vessel wall, fibrous cap, and a lipid core. Regions susceptible to failure and the contribution of the various components were studied. The upstream side of the vulnerable plaque fibrous cap had the highest stresses. The presence of a calcified spot embedded within the fibrous cap proper was studied, and was demonstrated to enhance stresses within the fibrous cap, significantly contributing to its risk of rupture.
AB - In this study we performed two separate fluid structure interaction (FSI) simulations. A patient-specific Abdominal Aortic Aneurysm (AAA) geometry, and coronary vulnerable plaque (VP) geometry in idealized and in patient based geometries reconstructed from intravascular (IVUS) measurements. The patient specific AAA FSI simulations were carried out with both isotropic and anisotropic wall properties. An orthotropic material model was used to describe wall properties, closely approximating experimental results of AAA specimens [1]. The results predict larger deformations and stress values for the anisotropic material model as compared to the isotropic one. This difference indicates that the isotropic formulation may underestimate the risk of rupture. The ability to quantify stresses developing within the aneurysm wall based on FSI simulations will help clinicians to reach informed decisions in determining rupture risk of AAA and the need for surgical intervention. The risk of rupture of vulnerable plaques was studied in both idealized and patient specific geometries using FSI simulations. The idealized model included vessel wall, fibrous cap, and a lipid core. Regions susceptible to failure and the contribution of the various components were studied. The upstream side of the vulnerable plaque fibrous cap had the highest stresses. The presence of a calcified spot embedded within the fibrous cap proper was studied, and was demonstrated to enhance stresses within the fibrous cap, significantly contributing to its risk of rupture.
UR - http://www.scopus.com/inward/record.url?scp=77952628179&partnerID=8YFLogxK
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AN - SCOPUS:77952628179
SN - 9780791843215
T3 - Proceedings of the ASME Summer Bioengineering Conference, SBC2008
SP - 891
EP - 892
BT - Proceedings of the ASME Summer Bioengineering Conference, SBC2008
Y2 - 25 June 2008 through 29 June 2008
ER -