Abstract EN:

Cardiovascular diseases represent the first cause of mortality in the developed countries, for this reason study of the arteiral structures and their prosthetic substitute take an important place in the fields of biomedical research. In this work, we propose a mechanical model to study the dynamic behavior of a tubular structure made of a hyperelastic, anisotropic, compressible and prestressed material. We have first formulated at boundaries values problem of the mechanical behavior of the arterial wall carotid submitted to conditions that mimics in-vivo conditions. The equations of this model were solved numerically by the method of Runge-Kutta at the fourth order. The intraluminal pressures distributions obtained were compared to the experimental measurements obtained both on healthy subject and on patients with the elastic PseudoXanthome (PXE) disease. These results show that (i) the compressible character of the arterial wall, observed in some healthy subject, influences the distributions of parietal stress and (ii) that the PXE disease modifies some mechanical characteristics of the arterial wall like the compliance and the shear modulus. In a second approach, we have formulated the above theoretical model to study a vascular prosthesis prototype of small diameter submitted to an azimutal shear. Results show that kinematics of deformation reproduce the effects of the azimutal shear generated before and after surgery. The obtained analytical solution made possible the evaluation of the anisotropy and the prestressed effects on the dynamic distributions of stress in the prosthetic structure. This approach will make possible the evaluation of the cardiovascular prosthesis and will lead to improve prosthesis prototype in term of mechanical properties and designing.