Measurements of steady flow through a bileaflet mechanical heart valve using stereoscopic PIV

Hutchison, Chris; Sullivan, Pierre E.; Ethier, C. Ross

doi:10.1007/s11517-010-0705-z

Cited by 13 publications

(9 citation statements)

References 30 publications

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“…From the plot, it can be seen that the peak velocity just past the leaflets increased from around 1.2 m/s for the functioning valve to 2.1 m/s for the malfunctioning valve. This is expected because closing one of the leaflets (the leaflet in the negative y-axis) means more fluid is forced The velocity profiles just past the leaflet tips (at 414 mm downstream of the inlet) using the Hutchinson et al run settings and fluid [60] are compared for the two valves in Figure 8. This point was chosen because it was the location of the velocity data available from Blackmore et al [59] for comparison.…”

Section: Resultsmentioning

confidence: 99%

“…In this work a CFD-based, three-dimensional model of a bileaflet artificial heart valve was created in both a functioning and malfunctioning position. The results of simulations were compared with literature [57,59,60] to evaluate the accuracy of the various computational methods. Velocity profiles and contours were also compared between the two valves.…”

Section: Discussionmentioning

confidence: 99%

“…CFD simulations for turbulent flow were carried out with both k-ε and k-ω models for the fully open, functioning valve. The selection of specific CFD simulation results to be used for eddy analysis was based on comparison of the different model results with velocity profiles in the literature for this system [59,60].…”

Section: Flow Simulationmentioning

confidence: 99%

“…For initial literature comparisons and results, properties in the simulation were set to match the values of the test fluid used in the Hutchinson et al experimental system [50]: a kinematic viscosity of 1.57 × 10 −6 m 2 /s and a density of 1796 kg/m 3 . Based on the density, viscosity, and diameter of the system, the inlet velocity was set to 0.445 m/s to obtain a Reynolds number of 7600 (as was used by Hutchinson et al) [60]. The purpose of these runs was to develop validated computational methods before carrying out simulations of blood flow through the valve.…”

Section: Flow Simulationmentioning

confidence: 99%

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Use of Computational Fluid Dynamics to Analyze Blood Flow, Hemolysis and Sublethal Damage to Red Blood Cells in a Bileaflet Artificial Heart Valve

James

Papavassiliou

O’Rear

2019

Fluids

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Artificial heart valves may expose blood to flow conditions that lead to unnaturally high stress and damage to blood cells as well as issues with thrombosis. The purpose of this research was to predict the trauma caused to red blood cells (RBCs), including hemolysis, from the stresses applied to them and their exposure time as determined by analysis of simulation results for blood flow through both a functioning and malfunctioning bileaflet artificial heart valve. The calculations provided the spatial distribution of the Kolmogorov length scales that were used to estimate the spatial and size distributions of the smallest turbulent flow eddies in the flow field. The number and surface area of these eddies in the blood were utilized to predict the amount of hemolysis experienced by RBCs. Results indicated that hemolysis levels are low while suggesting stresses at the leading edge of the leaflet may contribute to subhemolytic damage characterized by shortened circulatory lifetimes and reduced RBC deformability.

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Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Flow Simulationmentioning

confidence: 99%

Section: Flow Simulationmentioning

confidence: 99%

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Use of Computational Fluid Dynamics to Analyze Blood Flow, Hemolysis and Sublethal Damage to Red Blood Cells in a Bileaflet Artificial Heart Valve

James

Papavassiliou

O’Rear

2019

Fluids

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“…Some hemodynamic differences between different valve types are well known since commercial valve prostheses are normally evaluated in vitro according to ISO 5840. Furthermore, hemodynamics of different valve types were investigated in a number of studies . These in vitro and in silico studies were, however, usually done with the prostheses being mounted in a straight pipe and/or generic geometry of the aorta.…”

mentioning

confidence: 99%

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

et al. 2017

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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 5 0.027) and SFD (means: 0.78 vs. 0.49, P 5 0.002) in the ascending aorta, TPD (medians: 11.4 vs. 2.7 mm Hg, P 5 0.002), TKE (means: 400 vs. 283 cm 2 /s 2 , P 5 0.037), and NFD (means: 0.0994 vs. 0.0607, P 5 0.020) than the mechanical prostheses. The differences between the prosthesis types showed great interpatient variability, however. Given this variability, a patientspecific 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.

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The upstream boundary condition influences the leaflet opening dynamics in the numerical FSI simulation of an aortic BMHV

Annerel

Degroote

Claessens

et al. 2012

Numer Methods Biomed Eng

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SUMMARYIn this paper, the influence of the upstream boundary condition in the numerical simulation of an aortic bileaflet mechanical heart valve (BMHV) is studied. Three 3D cases with different upstream boundary conditions are compared. A first case consists of a rigid straight tube with a velocity profile at its inlet. In the second case, the upstream geometry is a contracting left ventricle (LV), positioned symmetrically with respect to the valve. In the last case, the LV is positioned asymmetrical with respect to the valve. The cases are used to simulate the same 3D BMHV. The change in time of the LV volume is calculated such that the flow rate through the valve is identical in each case. The opening dynamics of the BMHV are modelled using fluidstructure interaction (FSI). The simulations show that differences occur in the leaflet movement of the three cases. In particular, with the asymmetric LV, one of the leaflets impacts the blocking mechanism at its open position with a 34% higher velocity than when using the velocity profile, and with an 88% higher velocity than in the symmetric LV case. Therefore, when simulating such an impact, the upstream boundary condition needs to be chosen carefully.

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Measurements of steady flow through a bileaflet mechanical heart valve using stereoscopic PIV

Cited by 13 publications

References 30 publications

Use of Computational Fluid Dynamics to Analyze Blood Flow, Hemolysis and Sublethal Damage to Red Blood Cells in a Bileaflet Artificial Heart Valve

Use of Computational Fluid Dynamics to Analyze Blood Flow, Hemolysis and Sublethal Damage to Red Blood Cells in a Bileaflet Artificial Heart Valve

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

The upstream boundary condition influences the leaflet opening dynamics in the numerical FSI simulation of an aortic BMHV

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