Hemodynamic Evaluation of a Biological and Mechanical Aortic Valve Prosthesis Using Patient-Specific MRI-Based CFD

Overview

Journal Artif Organs

Date 2017 Aug 31

PMID 28853220

Citations 15

Authors

Florian Hellmeier

Sarah Nordmeyer

Pavlo Yevtushenko

Jan Bruening

Felix Berger

Titus Kuehne

Leonid Goubergrits

Marcus Kelm

Affiliations

Soon will be listed here.

Abstract

Modeling different treatment options before a procedure is performed is a promising approach for surgical decision making and patient care in heart valve disease. This study investigated the hemodynamic impact of different prostheses through patient-specific MRI-based CFD simulations. Ten time-resolved MRI data sets with and without velocity encoding were obtained to reconstruct the aorta and set hemodynamic boundary conditions for simulations. Aortic hemodynamics after virtual valve replacement with a biological and mechanical valve prosthesis were investigated. Wall shear stress (WSS), secondary flow degree (SFD), transvalvular pressure drop (TPD), turbulent kinetic energy (TKE), and normalized flow displacement (NFD) were evaluated to characterize valve-induced hemodynamics. The biological prostheses induced significantly higher WSS (medians: 9.3 vs. 8.6 Pa, P = 0.027) and SFD (means: 0.78 vs. 0.49, P = 0.002) in the ascending aorta, TPD (medians: 11.4 vs. 2.7 mm Hg, P = 0.002), TKE (means: 400 vs. 283 cm /s , P = 0.037), and NFD (means: 0.0994 vs. 0.0607, P = 0.020) than the mechanical prostheses. The differences between the prosthesis types showed great inter-patient variability, however. Given this variability, a patient-specific evaluation is warranted. In conclusion, MRI-based CFD offers an opportunity to assess the interactions between prosthesis and patient-specific boundary conditions, which may help in optimizing surgical decision making and providing additional guidance to clinicians.

Citing Articles

Stress Load and Ascending Aortic Aneurysms: An Observational, Longitudinal, Single-Center Study Using Computational Fluid Dynamics.

de Azevedo F, Almeida G, Alvares de Azevedo B, Ibanez Aguilar I, Azevedo B, Teixeira P Bioengineering (Basel). 2024; 11(3).

PMID: 38534478 PMC: 10968135. DOI: 10.3390/bioengineering11030204.

Assessing the impact of turbulent kinetic energy boundary conditions on turbulent flow simulations using computational fluid dynamics.

Jung E, Lee G, Shim E, Ha H Sci Rep. 2023; 13(1):14638.

PMID: 37670027 PMC: 10480182. DOI: 10.1038/s41598-023-41324-w.

Towards Reduced Order Models via Robust Proper Orthogonal Decomposition to capture personalised aortic haemodynamics.

Chatpattanasiri C, Franzetti G, Bonfanti M, Diaz-Zuccarini V, Balabani S J Biomech. 2023; 158:111759.

PMID: 37657234 PMC: 7615718. DOI: 10.1016/j.jbiomech.2023.111759.

Modelling blood flow in patients with heart valve disease using deep learning: A computationally efficient method to expand diagnostic capabilities in clinical routine.

Yevtushenko P, Goubergrits L, Franke B, Kuehne T, Schafstedde M Front Cardiovasc Med. 2023; 10:1136935.

PMID: 36937926 PMC: 10020717. DOI: 10.3389/fcvm.2023.1136935.

A parametric geometry model of the aortic valve for subject-specific blood flow simulations using a resistive approach.

Pase G, Brinkhuis E, De Vries T, Kosinka J, Willems T, Bertoglio C Biomech Model Mechanobiol. 2023; 22(3):987-1002.

PMID: 36853513 PMC: 10167200. DOI: 10.1007/s10237-023-01695-5.