A numerical parametric study of the mechanical action of pulsatile blood flow onto axisymmetric stenosed arteries

Abstract In the present paper, a fluid–structure interaction model is developed, questioning how the mechanical action of the blood onto an atheromatous plaque is affected by the length and the severity of the stenosis. An axisymmetric model is considered. The fluid is assumed Newtonian. The plaque...

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Bibliographic Details
Published in:Medical engineering & physics 2012-12, Vol.34 (10), p.1483-1495
Main Authors: Belzacq, Tristan, Avril, Stéphane, Leriche, Emmanuel, Delache, Alexandre
Format: Article
Language:English
Subjects:
Anisotropy
Biological and medical sciences
Biomechanical Phenomena
Blood flow
Carotid Arteries - pathology
Carotid Arteries - physiopathology
Chemical and Process Engineering
Computerized, statistical medical data processing and models in biomedicine
Constriction, Pathologic - pathology
Constriction, Pathologic - physiopathology
Engineering Sciences
Fluid–structure interaction
Humans
Mechanical Phenomena
Mechanics
Mechanics of materials
Medical sciences
Models and simulation
Models, Biological
Numerical simulation
Physics
Plaque, Atherosclerotic - pathology
Plaque, Atherosclerotic - physiopathology
Pulsatile Flow
Radiology
Stenosis
Vascular biomechanics
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Summary:Abstract In the present paper, a fluid–structure interaction model is developed, questioning how the mechanical action of the blood onto an atheromatous plaque is affected by the length and the severity of the stenosis. An axisymmetric model is considered. The fluid is assumed Newtonian. The plaque is modelled as a heterogeneous hyperelastic anisotropic solid composed of the arterial wall, the lipid core and the fibrous cap. Transient velocity and pressure conditions of actual pulsatile blood flow are prescribed. The simulation is achieved using the Arbitrary Lagrangian Eulerian scheme in the COMSOL commercial Finite Element package. The results reveal different types of behavior in function of the length (denoted L ) and severity (denoted S ) of the stenosis. Whereas large plaques ( L > 10 mm) are mostly deformed under the action of the blood pressure, it appears that shorter plaques ( L < 10 mm) are significantly affected by the shear stresses. The shear stresses tend to deform the plaque by pinching it. This effect is called: “the pinching effect”. It has an essential influence on the mechanical response of the plaque. For two plaques having the same radius severity S = 45%, the maximum stress in the fibrous cap is 50% larger for the short plaque ( L = 5 mm) than for a larger plaque ( L = 10 mm), and the maximum wall shear stress is increased by 100%. Provided that they are confirmed by experimental investigations, these results may offer some new perspectives for understanding the vulnerability of short plaques.
ISSN:1350-4533
1873-4030
DOI:10.1016/j.medengphy.2012.02.010