Cardiothoracic transplantation and mechanical circulatory support: Acquired
Computational fluid dynamic study of hemodynamic effects on aortic root blood flow of systematically varied left ventricular assist device graft anastomosis design

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Abstract

Objectives

To quantify the range of blood flow parameters in ascending aorta that can result from various angulations of outflow graft anastomosis of a left ventricular assist device (LVAD) to the aortic wall, as a means to understand the mechanism of aortic valve insufficiency.

Methods

A realistic aorta model with LVAD anastomosis was generated from computed tomographic images of a patient. Based on this model, the LVAD anastomosis geometry parameters, such as anastomosis locations, inclination angle, and azimuthal angle (cross-sectional plane) of the graft, were varied, to create 21 models. With the assumption of no flow passing the aortic valve, and a constant flow rate from the LVAD cannula, computational fluid dynamics simulations were used to study the blood flow patterns in the ascending aorta. In addition, pulsatile flows were assumed in the LVAD cannula, with the aortic valve opened during peak systole, for 2 specific anastomosis configurations, to evaluate the influence of the pulsatile flow profile and the transvalvular flow on the aortic flow patterns.

Results

Changes in the inclination angle, from 60° to 120°, or the azimuthal angle, from 90° to 120°, or moving from a lower to a higher anastomosis position, causes significant changes for all flow parameters. A lower anastomosis location, an inclination angle ≥90°, and an azimuthal angle of 60° or 120° are all capable of reducing blood flow stagnation in the aortic root and producing normal wall shear stress and moderate pressure values in the region.

Conclusions

Carefully chosen anastomosis geometry is likely to be able to generate a close-to-normal hemodynamic environment in the aortic root. Greater knowledge of aortic valve remodeling may make possible the creation of favorable flow patterns in the aortic root, through optimization of surgical design to reduce or delay the occurrence of aortic valve insufficiency.

Key Words

left ventricle assistant device
LVAD anastomosis geometry
aortic insufficiency
computational fluid dynamics
wall shear stress at aortic root

Abbreviations and Acronyms

AVI
aortic valve insufficiency
CFD
computational fluid dynamics
CT
computed tomography
LVAD
left ventricular assist device
WSS
wall shear stress

CTSNet classification

26.1
27.2

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