CFD Simulation of a Novel Bileaflet Mechanical Heart Valve Prosthesis - An Estimation of the Venturi Passage Formed by the Leaflets

Yokoyama, Yoshimasa; Medart, Daniel; Hormes, Marcus; Schmitz, Christoph; Hamilton, Kathrin; Kwant, P.B.; Takatani, Setsuo; Schmitz‐Rode, Thomas; Steinseifer, Ulrich

doi:10.1177/039139880602901206

Cited by 7 publications

(7 citation statements)

References 4 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In other studies, only part of the cycle is considered (Myers & Porter 2003) and the numerical simulation imposes symmetries (Cheng, Lai & Chandran 2004) so as to decrease the computational cost. In addition, in the majority of the literature, turbulence models are used to avoid the explicit simulation of the smallest scales (Grigioni et al 2005;Yokoyama et al 2006;Alemu & Bluestein 2007, among many others); this substantially reduces the nodes of the mesh and allows for larger integration time steps, but at the expense of the information on the turbulence fine scales whose accurate description is mandatory for the comprehension of the clinical phenomena mentioned above. Recently, Borazjani et al (2007) and Borazjani, Ge & Sotiropulos (2008) considered the full three-dimensional flow dynamics in an axisymmetric aortic root, including fluid-structure interactions.…”

Section: Introductionmentioning

confidence: 99%

Direct numerical simulation of the pulsatile flow through an aortic bileaflet mechanical heart valve

et al. 2009

View full text Add to dashboard Cite

This work focuses on the direct numerical simulation of the pulsatile now through a bileaflet mechanical heart valve under physiological conditions and in a realistic aortic root geometry. The motion of the valve leaflets has been computed from the forces exerted by the fluid on the structure both being considered as a single dynamical system. To this purpose the immersed boundary method, combined with a fluid structure interaction algorithm, has shown to be an inexpensive and accurate technique for such complex flows. Several complete flow cycles have been simulated in order to collect enough phase-averaged statistics, and the results are in good agreement with experimental data obtained for a similar configuration. The flow analysis, strongly relying on the data accessibility provided by the numerical simulation, shows how some features of the leaflets motion depend on the flow dynamics and that the criteria for the red cell damages caused by the valve need to be formulated using very detailed analysis. In particular, it is shown that the standard Eulerian Computation of the Reynolds stresses, usually employed to assess the risk of haemolysis, might not be adequate oil several counts: (i) Reynolds stresses are only one part of the solicitation, the other part being the viscous stresses, (ii) the characteristic scales or the two solicitations are very different and the Reynolds stresses act on lengths much larger than the red cells diameter and (iii) the Eulerian zonal assessment of the stresses completely misses the information of time exposure to the solicitation which is a fundamental ingredient for the phenomenon of haemolysis. Accordingly, the trajectories of several fluid particles have been tracked in a Lagrangian way and the pointwise instantaneous Viscous stress tensor has been computed along the paths. The tensor has been then reduced to an equivalent scalar using the von Mises criterion, and the blood damage index has been evaluated following Grigioni et al. (Biomech. Model Mechanobiol., vol. 4, 2005, p. 249)

show abstract

Section: Introductionmentioning

confidence: 99%

Direct numerical simulation of the pulsatile flow through an aortic bileaflet mechanical heart valve

et al. 2009

View full text Add to dashboard Cite

show abstract

“…In this research framework, Grigioni et al (2005a) performed a numerical simulation on a model of mechanical valve placed in a physiological aortic root shaped model, furnishing indications about the role of Valsava sinus on the fluid dynamic downstream of the valve at mid systole. Yokoyama et al (2006) demonstrated that curved leaflet configuration generates a Venturi effect that is able to reduce the boundary layer separation zones and stabilize the leaflets' position. Ge et al (2003) provided an insight into the complex hemodynamics of a bileaflet MHV at the maximum Reynolds number, putting in evidence that high grid densities are mandatory, in order to fully characterize local aspects of the flow field downstream of the prosthetic valve.…”

Section: Introductionmentioning

confidence: 99%

Numerical simulation of the dynamics of a bileaflet prosthetic heart valve using a fluid–structure interaction approach

Nobili

Morbiducci

Ponzini

et al. 2008

Journal of Biomechanics

128

127

View full text Add to dashboard Cite

“…This region is distinct as far as 2 diameters from the valve but shows a much smaller fluid speed than the principal flow. Some fluid speeds were zero velocities and some were of negative values as seen in figure [5]. The negative velocities oppose the flow direction, some of which appeared upstream of the valve.…”

Section: Resultsmentioning

confidence: 93%

“…At the opened leaflet, the fluid jet carries turbulent velocity fluctuations further downstream than in configuration I. The region of lower counter flow velocities which is in-between the high turbulent diffusivities that resulted from jet velocities is bounded by regions of high shear [5]. This recirculation phenomenon has been known to have a physiological impact.…”

Section: Resultsmentioning

confidence: 96%

“…The first prosthetic heart valve implant of this valve was preformed in 1960, and ever since, attention has been drawn to the study of flow dynamics past such valves and to the investigation of related physiological complications. Among the methods used to study are pulse Doppler ultrasound, laser Doppler anemometry, hot wire-film anemometry, and numerical methods such as computational fluid dynamics [CFD] [3,5]. Recently, particle image velocimetry (PIV) [6] and particle tracking velocimetry [7] were used in in vitro studies of flow dynamics downstream of prosthetic valves.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

MRI: a tool for measuring turbulent intensities in flow systems

Adegbite¹,

Kadem²,

Newling³

2011

Environmental Health and Biomedicine

View full text Add to dashboard Cite

Understanding the fluid-structure interaction and fluid dynamics downstream of an obstruction is crucial in the design and fabrication of devices that find application in both medicine and industry. It is known that the fluid flow patterns downstream of an obstruction may be very complex and are three dimensional, including the formation of vortices, recirculating flow, flow separation and the onset of turbulence. The development of any such pattern of flow might be detrimental to the optimal performance of the flow system. In this work we have used the magnetic resonance imaging (MRI) technique to investigate flow dynamics downstream of an artificial heart valve. MRI is a naturally threedimensional, non-invasive technique that finds application in clinical, biomedical research and materials research. It has the capability to visualize the internal structure of materials and also to quantify mass transport properties. In this in vitro study, we have measured the turbulent diffusivity and velocity downstream of the valve in two configurations (fully opened and partially opened). Our particular implementation of the MRI measurement (known as SPRITE imaging) is unusually robust to fast turbulent flows and has been demonstrated effective at Reynolds numbers on the order 10 5 , much higher than possible with most conventional, clinical MRI techniques. The results showed a low turbulent diffusivity downstream of the fully opened valve configuration, while the turbulent diffusivity is higher downstream of the partially opened valve coupled with a high-velocity fluid jet and recirculating flow. There are distinct differences between the downstream velocity profiles of the two configurations, which have diagnostic implications.

show abstract

CFD Simulation of a Novel Bileaflet Mechanical Heart Valve Prosthesis - An Estimation of the Venturi Passage Formed by the Leaflets

Cited by 7 publications

References 4 publications

Direct numerical simulation of the pulsatile flow through an aortic bileaflet mechanical heart valve

Direct numerical simulation of the pulsatile flow through an aortic bileaflet mechanical heart valve

Numerical simulation of the dynamics of a bileaflet prosthetic heart valve using a fluid–structure interaction approach

MRI: a tool for measuring turbulent intensities in flow systems

Contact Info

Product

Resources

About