Numerical investigation on the effect of bileaflet mechanical heart valve's implantation tilting angle and aortic root geometry on intermittent regurgitation and platelet activation

Abbas, Syed Samar; Nasif, Mohammad Shakir; Al-Waked, Rafat; Said, Mohd Ismid Mohd

doi:10.1111/aor.13536

Cited by 10 publications

(8 citation statements)

References 48 publications

(104 reference statements)

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“…3A), 69 stents, 110,111 and mechanical valves (Fig. 3B) 115,125 have been widely modelled using CFD simulations, as have ex vivo devices and tubing systems. 126 CFD simulations of more geometrically complex medical devices such as ECMO 108 and LVADs (Fig.…”

Section: Computational Fluid Dynamic Modelling Of Blood Flow In Medical Devices and In Vitro Modelsmentioning

confidence: 99%

Evaluating medical device and material thrombosis under flow: current and emerging technologies

et al. 2020

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Section: Computational Fluid Dynamic Modelling Of Blood Flow In Medical Devices and In Vitro Modelsmentioning

confidence: 99%

Evaluating medical device and material thrombosis under flow: current and emerging technologies

et al. 2020

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“…However, in recent years, several authors performed numerical studies on MHV dysfunction [ 2 , 3 , 7 , 25 , 34 – 37 ], and the simulation results show a significant difference from the normal MHV. The non-Newtonian viscosity model plays a role in numerical studies of blood flow through the MHV due to the complex structure of MHV [ 29 – 31 , 36 , 38 – 41 ].…”

Section: Introductionmentioning

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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“…Despite these problems, ALE has been widely used to simulate the FSI between leaflets of the heart valves and cardiac blood flow simply due to its accurate prediction of cardiac mechanics and flow parameters near the BLI, thereby outperforming fixed-grid methods. 112,141,200,217,223,224 The cut cell method is another variant of moving mesh, where the Cartesian mesh is adapted to the moving boundary by recursive reshaping of only the fluid cells that are cut by the fluid–structure interface and has been mainly employed for aortic valves simulations with contact modeling. 12,119,121 However, due to multiple possibilities of shapes the reshaped cells can take, it becomes difficult to apply the cut cell method to three-dimensional moving boundaries.…”

Section: Discussionmentioning

confidence: 99%

“…103 This approach has greater potential to capture novel details of the continuum than that of a purely Lagrangian or Eulerian approach. 104,105…”

Section: Numerical Fsi Methodsmentioning

confidence: 99%

State-of-the-art numerical fluid–structure interaction methods for aortic and mitral heart valves simulations: A review

2021

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Numerical fluid–structure interaction (FSI) methods have been widely used to predict the cardiac mechanics and associated hemodynamics of native and artificial heart valves (AHVs). Offering a high degree of spatial and temporal resolution, these methods circumvent the need for cardiac surgery to assess the performance of heart valves. Assessment of these FSI methods in terms of accuracy, realistic modeling, and numerical stability is required, which is the objective of this paper. FSI methods could be classified based on how the computational domain is discretized, and on the coupling techniques employed between fluid and structure domains. The grid-based FSI methods could be further classified based on the kinematical description of the computational fluid (blood) grid, being either fixed grid, moving grid, or combined fixed–moving grid methods. The review reveals that fixed grid methods mostly cause imprecise calculations of flow parameters near the blood–leaflet interface. Moving grid methods are more accurate, however they require cumbersome remeshing and smoothing. The combined fixed–moving grid methods overcome the shortcomings of fixed and moving grid methods, but they are computationally expensive. The mesh-free methods have been able to encounter the problems faced by grid-based methods; however, they have been only limitedly applied to heart valve simulations. Among the coupling techniques, explicit partitioned coupling is mostly unstable, however the implicit partitioned coupling not only has the potential to be stable but is also comparatively cheaper. This in-depth review is expected to be helpful for the readers to evaluate the pros and cons of FSI methods for heart valve simulations.

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Numerical investigation on the effect of bileaflet mechanical heart valve's implantation tilting angle and aortic root geometry on intermittent regurgitation and platelet activation

Cited by 10 publications

References 48 publications

Evaluating medical device and material thrombosis under flow: current and emerging technologies

Evaluating medical device and material thrombosis under flow: current and emerging technologies

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

State-of-the-art numerical fluid–structure interaction methods for aortic and mitral heart valves simulations: A review

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