Near Valve Flows and Potential Blood Damage During Closure of a Bileaflet Mechanical Heart Valve

Herbertson, Luke H.; Deutsch, Steven; Manning, Keefe B.

doi:10.1115/1.4005167

Cited by 10 publications

(9 citation statements)

References 33 publications

(41 reference statements)

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“…This is particularly important when considering mechanical valves. Our study demonstrated superior optimization potential when using mechanical valves, but it did not show the increased blood damage potential during leaflet closure reported by other studies (35,36). This limited scope of modeling would thus artificially favor mechanical valves over biological ones.…”

Section: Abnormal Aortic Flow Is Usually Characterized By Several Factorscontrasting

confidence: 65%

Surgical Aortic Valve Replacement: Are We Able to Improve Hemodynamic Outcome?

Yevtushenko

Hellmeier

Bruening

et al. 2019

Biophysical Journal

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Aortic valve replacement (AVR) does not usually restore physiological flow profiles. Complex flow profiles are associated with aorta dilatation, ventricle remodeling, aneurysms, and development of atherosclerosis. All these affect longterm morbidity and often require reoperations. In this pilot study, we aim to investigate an ability to optimize the real surgical AVR procedure toward flow profile associated with healthy persons. Four cases of surgical AVR (two with biological and two with mechanical valve prosthesis) with available post-treatment cardiac magnetic resonance imaging (MRI), including fourdimensional flow MRI and showing abnormal complex post-treatment hemodynamics, were investigated. All cases feature complex hemodynamic outcomes associated with valve-jet eccentricity and strong secondary flow characterized by helical flow and recirculation regions. A commercial computational fluid dynamics solver was used to simulate peak systolic hemodynamics of the real post-treatment outcome using patient-specific MRI measured boundary conditions. Then, an attempt to optimize hemodynamic outcome by modifying valve size and orientation as well as ascending aorta size reduction was made. Pressure drop, wall shear stress, secondary flow degree, helicity, maximal velocity, and turbulent kinetic energy were evaluated to characterize the AVR hemodynamic outcome. The proposed optimization strategy was successful in three of four cases investigated. Although no single parameter was identified as the sole predictor for a successful flow optimization, downsizing of the ascending aorta in combination with the valve orientation was the most effective optimization approach. Simulations promise to become an effective tool to predict hemodynamic outcome. The translation of these tools requires, however, studies with a larger cohort of patients followed by a prospective clinical validation study.

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Section: Abnormal Aortic Flow Is Usually Characterized By Several Factorscontrasting

confidence: 65%

Surgical Aortic Valve Replacement: Are We Able to Improve Hemodynamic Outcome?

Yevtushenko

Hellmeier

Bruening

et al. 2019

Biophysical Journal

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“…When the blood flow passes through the MHV, it will generate a high-pressure drop, resulting in recirculation and stagnation [ 67 – 70 ]. The increase of shear stress will lead to blood damage (hemolysis) and platelet activation.…”

Section: Simulation Of Physical Quantity Dysfunctionmentioning

confidence: 99%

“…Although the shear rate is generally high in large arteries, some cardiovascular disease induces blood flow disturbance and generates stagnant and recirculation regions, significantly reducing the shear rate [ 133 ]. When the blood flows through the MHV, the recirculation, stagnation, vortex structures, and flow separation are obvious, which enhance the probability of occurrence of low shear rates and require the use of the non-Newtonian models [ 21 , 26 , 35 , 67 – 70 ]. In dysfunction MHV simulation, the blood flow behind the dysfunction leaflet has more significant recirculation flow and stagnation.…”

Section: Non-newtonian Blood Flowmentioning

confidence: 99%

Simulation of Mechanical Heart Valve Dysfunction and the Non-Newtonian Blood Model Approach

Chen

Basri

Ismail

et al. 2022

Applied Bionics and Biomechanics

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The mechanical heart valve (MHV) is commonly used for the treatment of cardiovascular diseases. Nonphysiological hemodynamic in the MHV may cause hemolysis, platelet activation, and an increased risk of thromboembolism. Thromboembolism may cause severe complications and valve dysfunction. This paper thoroughly reviewed the simulation of physical quantities (velocity distribution, vortex formation, and shear stress) in healthy and dysfunctional MHV and reviewed the non-Newtonian blood flow characteristics in MHV. In the MHV numerical study, the dysfunction will affect the simulation results, increase the pressure gradient and shear stress, and change the blood flow patterns, increasing the risks of hemolysis and platelet activation. The blood flow passes downstream and has obvious recirculation and stagnation region with the increased dysfunction severity. Due to the complex structure of the MHV, the non-Newtonian shear-thinning viscosity blood characteristics become apparent in MHV simulations. The comparative study between Newtonian and non-Newtonian always shows the difference. The shear-thinning blood viscosity model is the basics to build the blood, also the blood exhibiting viscoelastic properties. More details are needed to establish a complete and more realistic simulation.

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“…These complications are thought to be due to nonphysiologic shear stress levels imposed on blood elements by complex flows through BMHVs [6][7][8]. Thrombus formation in the valves may lead to dislodged emboli that can cause stroke and death [9][10][11], Various experimental studies have been performed on flow through prosthetic heart valves to study the complex flow dynamics [12][13][14][15][16], though experimental studies are often limited to lower spatiotemporal resolution and obstructed viewpoints. Blood damage experiments are also possible, in which human blood can be run through valves and assays are performed to assess blood damage potential [17][18][19], but only give bulk blood damage results.…”

Section: Introductionmentioning

confidence: 99%

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

Yun

Aidun

Yoganathan

2014

Journal of Biomechanical Engineering

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Bileaflet mechanical heart valves (BMHVs) are among the most popular prostheses to replace defective native valves. However, complex flow phenomena caused by the prosthesis are thought to induce serious thromboembolic complications. This study aims at employing a novel multiscale numerical method that models realistic sized suspended platelets for assessing blood damage potential in flow through BMHVs. A previously validated lattice-Boltzmann method (LBM) is used to simulate pulsatile flow through a 23 mm St. Jude Medical (SJM) Regent™ valve in the aortic position at very high spatiotemporal resolution with the presence of thousands of suspended platelets. Platelet damage is modeled for both the systolic and diastolic phases of the cardiac cycle. No platelets exceed activation thresholds for any of the simulations. Platelet damage is determined to be particularly high for suspended elements trapped in recirculation zones, which suggests a shift of focus in blood damage studies away from instantaneous flow fields and toward high flow mixing regions. In the diastolic phase, leakage flow through the b-datum gap is shown to cause highest damage to platelets. This multiscale numerical method may be used as a generic solver for evaluating blood damage in other cardiovascular flows and devices.

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Near Valve Flows and Potential Blood Damage During Closure of a Bileaflet Mechanical Heart Valve

Cited by 10 publications

References 33 publications

Surgical Aortic Valve Replacement: Are We Able to Improve Hemodynamic Outcome?

Surgical Aortic Valve Replacement: Are We Able to Improve Hemodynamic Outcome?

Simulation of Mechanical Heart Valve Dysfunction and the Non-Newtonian Blood Model Approach

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

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