Blood Damage Through a Bileaflet Mechanical Heart Valve: A Quantitative Computational Study Using a Multiscale Suspension Flow Solver

Yun, B. Min; Aidun, Cyrus K.; Yoganathan, Ajit P.

doi:10.1115/1.4028105

Cited by 21 publications

(7 citation statements)

References 47 publications

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“…The TAWSS distribution for cases N, SLP, and NSLP has similar patterns and values except for the elevated values near the top of the ascending aorta on the non‐sinus wall for SLP and on the sinus side for NSLP. The values of the accumulation of viscous shear stress for the normal case are in good agreement with those reported by Min Yun et al OSI distribution displays an interesting change between SLP, NSLP and the normal case, where elevated OSI value regions (~0.5) followed by a steep drop are noticeable in the ascending aorta in SLP (sinus side wall) and NSLP (non‐sinus side wall). The BLP case leads to a similar TAWSS distribution on both walls with a peak value occurring a bit downstream of the sinotubular junction (~x/D = 1.44).…”

Section: Resultssupporting

confidence: 89%

Experimental investigation of the flow downstream of a dysfunctional bileaflet mechanical aortic valve

et al. 2019

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Mechanical heart valve replacement is the preferred alternative in younger patients with severe symptomatic aortic valve disease. However, thrombus and pannus formations are common complications associated with bileaflet mechanical heart valves.This leads to risks of valve leaflet dysfunction, a life-threatening event. In this experimental study, we investigate, using time-resolved planar particle image velocimetry, the flow characteristics in the ascending aorta in the presence of a dysfunctional bileaflet mechanical heart valve. Several configurations of leaflet dysfunction are investigated and the induced flow disturbances in terms of velocity fields, viscous energy dissipation, wall shear stress, and accumulation of viscous shear stresses are evaluated. We also explore the ability of a new set of parameters, solely based on the analysis of the normalized axial velocity profiles in the ascending aorta, to detect bileaflet mechanical heart valve dysfunction and differentiate between the different configurations tested in this study. Our results show that a bileaflet mechanical heart valve dysfunction leads to a complex spectrum of flow disturbances with each flow characteristic evaluated having its own worst case scenario in terms of dysfunction configuration. We also show that the suggested approach based on the analysis of the normalized axial velocity profiles in the ascending aorta has the potential to clearly discriminate not only between normal and dysfunctional bilealfet heart valves but also between the different leaflet dysfunction configurations. This approach could be easily implemented using phase-contrast MRI to follow up patients with bileaflet mechanical heart valves. K E Y W O R D Sbileaflet mechanical heart valve, flow dynamics, shear stress accumulation, valve dysfunction, viscous energy dissipation E250 | DARWISH et Al.

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Section: Resultssupporting

confidence: 89%

Experimental investigation of the flow downstream of a dysfunctional bileaflet mechanical aortic valve

et al. 2019

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“…Future CFD studies can explore new heart valve designs and structural materials and determine how blood-material interactions and hemodynamics can be affected by design changes [ 61 ] with the aim of reducing thrombo-embolic complications associated with these valves, which can lead to improved valve designs. For example, analysis of blood flow characteristics through a BMHV especially around the valve hinge regions can help identify conditions that may increase the risk of blood cell damage [ 22 , 23 ]. An investigation of the effect of the leaflet opening angles on the blood flow also suggested that the opening angle can highly affect the flow downstream of BMHV and that opening angles >80 degrees would be more effective in reducing flow resistance and vortical structures [ 62 ].…”

Section: Resultsmentioning

confidence: 99%

“…Computational fluid dynamics (CFD), along with fluoroscopic or Doppler measurements, have the potential to provide clinically important insights by providing unprecedented hemodynamic detail for prosthetic heart valves [ 17 ]. For example, analysis of blood flow characteristics such as velocity, vortex formation, and turbulent stresses, especially around the valve hinge regions [ 18 , 19 , 20 , 21 ] can help identify conditions that may increase the risk of blood cell damage [ 22 , 23 , 24 ]. Critical turbulent shear stress thresholds of 400 N·m −2 [ 25 ] and 800 N·m −2 [ 26 ] for blood cell damage were reported.…”

Section: Introductionmentioning

confidence: 99%

Adverse Hemodynamic Conditions Associated with Mechanical Heart Valve Leaflet Immobility

et al. 2018

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Artificial heart valves may dysfunction, leading to thrombus and/or pannus formations. Computational fluid dynamics is a promising tool for improved understanding of heart valve hemodynamics that quantify detailed flow velocities and turbulent stresses to complement Doppler measurements. This combined information can assist in choosing optimal prosthesis for individual patients, aiding in the development of improved valve designs, and illuminating subtle changes to help guide more timely early intervention of valve dysfunction. In this computational study, flow characteristics around a bileaflet mechanical heart valve were investigated. The study focused on the hemodynamic effects of leaflet immobility, specifically, where one leaflet does not fully open. Results showed that leaflet immobility increased the principal turbulent stresses (up to 400%), and increased forces and moments on both leaflets (up to 600% and 4000%, respectively). These unfavorable conditions elevate the risk of blood cell damage and platelet activation, which are known to cascade to more severe leaflet dysfunction. Leaflet immobility appeared to cause maximal velocity within the lateral orifices. This points to the possible importance of measuring maximal velocity at the lateral orifices by Doppler ultrasound (in addition to the central orifice, which is current practice) to determine accurate pressure gradients as markers of valve dysfunction.

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“…Among others, Morbiducci et al ( 2009 ), Alemu et al ( 2010 ), and Min Yun et al ( 2014 ) used computational models of bileaflet MHV to study shear-induced platelet activation. The computational study by Hedayat et al ( 2017 ) compared platelet activation in the turbulent flow fields past bileaflet MHV with a model of a BHV and found that the activation potential is higher for MHV.…”

Section: Introductionmentioning

confidence: 99%

Turbulent Systolic Flow Downstream of a Bioprosthetic Aortic Valve: Velocity Spectra, Wall Shear Stresses, and Turbulent Dissipation Rates

2020

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Blood Damage Through a Bileaflet Mechanical Heart Valve: A Quantitative Computational Study Using a Multiscale Suspension Flow Solver

Cited by 21 publications

References 47 publications

Experimental investigation of the flow downstream of a dysfunctional bileaflet mechanical aortic valve

Experimental investigation of the flow downstream of a dysfunctional bileaflet mechanical aortic valve

Adverse Hemodynamic Conditions Associated with Mechanical Heart Valve Leaflet Immobility

Turbulent Systolic Flow Downstream of a Bioprosthetic Aortic Valve: Velocity Spectra, Wall Shear Stresses, and Turbulent Dissipation Rates

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