Heart valve function: a biomechanical perspective

Heart valves (HVs) are cardiac structures whose physiological function is to ensure directed blood flow through the heart over the cardiac cycle. While primarily passive structures that are driven by forces exerted by the surrounding blood and heart, this description does not adequately describe their elegant and complex biomechanical function. Moreover, they must replicate their cyclic function over an entire lifetime, with an estimated total functional demand of least 3×10 9 cycles. As in many physiological systems, one can approach HV biomechanics from a multi-length-scale approach, since mechanical stimuli occur and have biological impact at the organ, tissue and cellular scales. The present review focuses on the functional biomechanics of HVs. Specifically, we refer to the unique aspects of valvular function, and how the mechanical and mechanobiological behaviours of the constituent biological materials (e.g. extracellular matrix proteins and cells) achieve this remarkable feat. While we focus on the work from the authors' respective laboratories, the works of most investigators known to the authors have been included whenever appropriate. We conclude with a summary and underscore important future trends.

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A Complex Mitral Valve Reconstruction: A Case Report

The Heart Surgery Forum ◽

10.1532/hsf.648 ◽

2005 ◽

Vol 6 (2) ◽

pp. 27

Author(s):

Dimitrios Buklas ◽

Massimo Massetti ◽

Eric Saloux ◽

Eugenio Neri ◽

Olivier LePage ◽

...

Keyword(s):

Mitral Valve ◽

Surgical Techniques ◽

Mitral Valve Insufficiency ◽

Left Ventricular ◽

Mitral Valve Reconstruction ◽

Mitral Repair ◽

Valve Reconstruction ◽

Valve Insufficiency ◽

Valve Function ◽

Valvular Function

Several techniques are currently in use for mitral valve reconstruction. We report a mitral repair case in which the use of a combination of different surgical techniques resulted in the necessary correction. A 47-year-old woman underwent surgical intervention to treat severe mitral valve insufficiency due to A1/A2/A3 and P2 prolapsed valve tissue. A combination of quadrangular resection, sliding leaflet, single chordal transposition, "flip-over" leaflet, and ring annuloplasty techniques were applied, and postsurgical correct valve function was documented by results of a left ventricular saline filling test and transesophageal echocardiography control. Complex mitral valve repairing techniques can be combined to reestablish valvular function.

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Numerical Study of Blood Flow Through Artificial Heart Valves

IOP Conference Series Materials Science and Engineering ◽

10.1088/1757-899x/1094/1/012120 ◽

2021 ◽

Vol 1094 (1) ◽

pp. 012120

Author(s):

Hussein Togun ◽

Ali Abdul Hussain ◽

Saja Ahmed ◽

Iman Abdul hussain ◽

Huda Shaker

Keyword(s):

Blood Flow ◽

Artificial Heart ◽

Heart Valves ◽

Numerical Study ◽

Artificial Heart Valves ◽

Flow Through

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Experimental Setting for Applying Mechanical Stimuli to Study the Endothelial Response of Ex Vivo Vessels under Realistic Pathophysiological Environments

Life ◽

10.3390/life11070671 ◽

2021 ◽

Vol 11 (7) ◽

pp. 671

Author(s):

Ana Osuna ◽

Anna Ulldemolins ◽

Hector Sanz-Fraile ◽

Jorge Otero ◽

Núria Farré ◽

...

Keyword(s):

Ex Vivo ◽

Low Cost ◽

Technical Information ◽

Rabbit Aorta ◽

Pressure Waveform ◽

Mechanical Stimuli ◽

Experimental Setting ◽

Endothelial Response ◽

Flow Through ◽

Open Source Hardware

This paper describes the design, construction and testing of an experimental setting, making it possible to study the endothelium under different pathophysiological conditions. This novel experimental approach allows the application of the following stimuli to an ex vivo vessel in a physiological bath: (a) a realistic intravascular pressure waveform defined by the user; (b) shear stress in the endothelial layer since, in addition to the pressure waveform, the flow through the vessel can be independently controlled by the user; (c) conditions of hypo/hyperoxia and hypo/hypercapnia in an intravascular circulating medium. These stimuli can be applied alone or in different combinations to study possible synergistic or antagonistic effects. The setting performance is illustrated by a proof of concept in an ex vivo rabbit aorta. The experimental setting is easy to build by using very low-cost materials widely available. Online Supplement files provide all the technical information (e.g., circuits, codes, 3D printer drivers) following an open-source hardware approach for free replication.

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The modelling and dynamic analysis of flow through the aortic valve during the cardiac cycle

PAMM ◽

10.1002/pamm.200701119 ◽

2007 ◽

Vol 7 (1) ◽

pp. 4020033-4020034

Author(s):

Piotr Konderla ◽

Krzysztof Patralski

Keyword(s):

Aortic Valve ◽

Dynamic Analysis ◽

Cardiac Cycle ◽

Flow Through

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In-vitro characterization of flow through mechanical heart valves

Journal of Biomechanics ◽

10.1016/s0021-9290(06)84193-x ◽

2006 ◽

Vol 39 ◽

pp. S306 ◽

Cited By ~ 1

Author(s):

L.P. Dasi ◽

H. Simon ◽

L. Ge ◽

F. Sotiropoulos ◽

A. Yoganathan

Keyword(s):

Heart Valves ◽

Mechanical Heart Valves ◽

In Vitro Characterization ◽

Flow Through

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Numerical simulation of steady turbulent flow through trileaflet aortic heart valves—II. Results on five models

Journal of Biomechanics ◽

10.1016/0021-9290(85)90035-1 ◽

1985 ◽

Vol 18 (12) ◽

pp. 909-926 ◽

Cited By ~ 19

Author(s):

Dana M. Stevenson ◽

Ajit P. Yoganathan ◽

Frank P. Williams

Keyword(s):

Numerical Simulation ◽

Turbulent Flow ◽

Heart Valves ◽

Flow Through

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Highly resolved pulsatile flows through prosthetic heart valves using the entropic lattice-Boltzmann method

Journal of Fluid Mechanics ◽

10.1017/jfm.2014.393 ◽

2014 ◽

Vol 754 ◽

pp. 122-160 ◽

Cited By ~ 16

Author(s):

B. Min Yun ◽

L. P. Dasi ◽

C. K. Aidun ◽

A. P. Yoganathan

Keyword(s):

Lattice Boltzmann Method ◽

Pulsatile Flow ◽

Lattice Boltzmann ◽

Heart Valves ◽

Prosthetic Heart Valves ◽

Spatiotemporal Resolution ◽

Jude Medical ◽

High Spatiotemporal Resolution ◽

Flow Through ◽

Boltzmann Method

AbstractProsthetic heart valves have been widely used to replace diseased or defective native heart valves. Flow through bileaflet mechanical heart valves (BMHVs) have previously demonstrated complex phenomena in the vicinity of the valve owing to the presence of two rigid leaflets. This study aims to accurately capture the complex flow dynamics for pulsatile flow through a 23 mm St Jude Medical (SJM) Regent™ BMHV. The lattice-Boltzmann method (LBM) is used to simulate pulsatile flow through the valve with the inclusion of reverse leakage flow at very high spatiotemporal resolution that can capture fine details in the pulsatile BMHV flow field. For higher-Reynolds-number flows, this high spatiotemporal resolution captures features that have not been observed in previous coarse resolution studies. In addition, the simulations are able to capture with detail the features of leaflet closing and the asymmetric b-datum leakage jet during mid-diastole. Novel flow physics are visualized and discussed along with quantification of turbulent features of this flow, which is made possible by this parallelized numerical method.

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Numerical Simulation of Blood Flow Through Heart Valves

45th AIAA Aerospace Sciences Meeting and Exhibit ◽

10.2514/6.2007-527 ◽

2007 ◽

Author(s):

AliReza Nejadmalayeri ◽

Klaus Hoffmann ◽

Jean-François Dietiker

Keyword(s):

Numerical Simulation ◽

Blood Flow ◽

Heart Valves ◽

Flow Through

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

Journal of Biomechanical Engineering ◽

10.1115/1.4028105 ◽

2014 ◽

Vol 136 (10) ◽

Cited By ~ 16

Author(s):

B. Min Yun ◽

Cyrus K. Aidun ◽

Ajit P. Yoganathan

Keyword(s):

Numerical Method ◽

Heart Valves ◽

Computational Study ◽

Mechanical Heart Valve ◽

Complex Flow ◽

Damage Potential ◽

Spatiotemporal Resolution ◽

Jude Medical ◽

Blood Damage ◽

Flow Through

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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Flow Patterns Downstream of a Mechanical Heart Valve During Systole

Volume 2: Fora, Parts A and B ◽

10.1115/fedsm2007-37488 ◽

2007 ◽

Author(s):

P. Oshkai ◽

F. Haji-Esmaeili

Keyword(s):

Turbulent Flow ◽

Heart Valve ◽

Large Scale ◽

Cardiac Cycle ◽

Mechanical Heart Valve ◽

Opening Angle ◽

Image Velocimetry ◽

Imaging Approach ◽

Systolic Phase ◽

Flow Through

Digital particle image velocimetry is employed to study turbulent flow through a bileaflet mechanical heart valve during systolic phase of a cardiac cycle. Unsteady vortex shedding from the valve’s leaflets displays distinct characteristic frequencies, depending on the opening angle of each leaflet. Small- and large-scale transverse oscillations of the separated shear layers are studied using global quantitative flow imaging approach. Turbulent flow structures including jet-like regions and shed vortices are characterized in terms of patterns of instantaneous and time-averaged velocity, vorticity, and turbulence statistics.

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