Algorithms for Fluid–Structure Interaction

Vigmostad, Sarah C.; Udaykumar, H. S.

doi:10.1007/978-1-4419-7350-4_5

Cited by 5 publications

(10 citation statements)

References 78 publications

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“…While non-invasive imaging modalities make patient-specific modeling a realistic possibility for future clinical use, the process of segmenting images and turning the resulting geometry into a body-fitted or geometrically descriptive mesh for computational analysis is quite time-consuming, and often a major bottleneck in performing such analyses (Dumont et al, 2004; Vigmostad and Udaykumar, 2011). Several groups have developed valuable tools which make segmentation of medical images simpler, and help expedite the meshing process (Steinman et al, 2003; Antiga et al, 2008; Taylor and Steinman, 2010).…”

Section: Towards Patient-specific Fe and Fsi Analysismentioning

confidence: 99%

Patient-specific bicuspid valve dynamics: Overview of methods and challenges

Chandran

Vigmostad

2013

Journal of Biomechanics

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About 1–2% of the babies are born with bicuspid aortic valves instead of the normal aortic valve with three leaflets. A significant portion of the patients with the congenital bicuspid valve morphology suffer from aortic valve stenosis and/or ascending aortic dilatation and dissection thus requiring surgical intervention when they are young adults. Patients with bicuspid aortic valves (BAVs) have also been found to develop valvular stenosis earlier than those with the normal aortic valve. This paper overviews current knowledge of BAVs, where several studies have suggested that the mechanical stresses induced on the valve leaflets and the abnormal flow development in the ascending aorta may be an important factor in the diseases of the valve and the aortic root. The long-term goals of the studies being performed in our laboratory are aimed towards potential stratification of bicuspid valve patients who may be at risk for developing these pathologies based on analyzing the hemodynamic environment of these valves using fluid-structure interaction (FSI) modeling. Patient-specific geometry of the normal tri-cuspid and bicuspid valves are reconstructed from real-time 3D ultrasound images and the dynamic analyses performed in order to determine the potential effects of mechanical stresses on the valve leaflet and aortic root pathology. This paper describes the details of the computational tools and discusses challenges with patient-specific modeling.

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Section: Towards Patient-specific Fe and Fsi Analysismentioning

confidence: 99%

Patient-specific bicuspid valve dynamics: Overview of methods and challenges

Chandran

Vigmostad

2013

Journal of Biomechanics

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“…5, we plot a schematic of the shape of the bottom side of the leaflet during valve closure and opening when £=500. As it was expected [12,14], the leaflet has a convex curvature during opening, and it preserves this type of curvature until the moment of the maximum opening angle. On the other hand, as the fluid decelerates and the valve closes, the leaflet has a concave curvature.…”

Section: Journal Of Biomechanical Engineeringmentioning

confidence: 77%

“…Thus, £=500 corresponds to G= 11,940 Pa. According to the work of Vigmostad et al [14], a physiological value for the shear modulus is G = 5520 Pa. Thus, in the present work, the leaflet has a shear modulus, which is twice as large as the physiological value, but it is more compliant than the one used in the work of De Hart et al [12,13] (G=1.5X 10* Pa and G=30,000 Pa, respectively).…”

Section: Journal Of Biomechanical Engineeringmentioning

confidence: 93%

“…Although they used a coarse mesh, due to memory and CPU-time limitations, their findings were in agreement with experimental results. Recently, Vigmostad et al [14] examined the work of De Hart et al [12] by modeling the leaflet as a flexible rod, which was not allowed to rotate about the point of support. Their findings are in qualitative agreement with the results of De Hart et al as they used a high-resolution mesh and a more compliant leaflet.…”

Section: Introductionmentioning

confidence: 99%

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Dynamics of Flow in a Mechanical Heart Valve: The Role of Leaflet Inertia and Leaflet Compliance

Gkanis

Housiadas

2011

Journal of Biomechanical Engineering

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In this work, we examine the dynamics of fluid flow in a mechanical heart valve when the solid inertia and leaflet compliance are important. The fluid is incompressible and Newtonian, and the leaflet is an incompressible neo-Hookean material. In the case of an inertialess leaflet, we find that the maximum valve opening angle and the time that the valve remains closed increase as the shear modulus of the leaflet decreases. More importantly, the regurgitant volume decreases with decreasing shear modulus. When we examined the forces exerted on the leaflet, we found that the downward motion of the leaflet is initiated by a vertical force exerted on its right side and, later on, by a vertical force exerted on the top side of the leaflet. In the case of solid inertia, we find that the maximum valve opening angle and the regurgitant volume are larger than in the case of an inertialess leaflet. These results highlight the importance of solid compliance in the dynamics of blood flow in a mechanical heart valve. More importantly, they indicate that mechanical heart valves with compliant leaflets may have smaller regurgitant volumes and smaller shear stresses than the ones with rigid leaflets.

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“…This algorithm strongly couples the interface between the solid and the fluid using sub-iterations between partitioned solvers towards a robust and stable solutions for both solid and fluid. At the interface, an immersed interface-like approach 90,91 has been employed to incorporate the moving leaflets on the fluid as a source term in the momentum equation.…”

Section: Fluid-structure Interaction Analysismentioning

confidence: 99%

Computational Mitral Valve Evaluation and Potential Clinical Applications

Chandran

Kim

2014

Ann Biomed Eng

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The mitral valve (MV) apparatus consists of the two asymmetric leaflets, the saddle-shaped annulus, the chordae tendineae, and the papillary muscles. MV function over the cardiac cycle involves complex interaction between the MV apparatus components for efficient blood circulation. Common diseases of the MV include valvular stenosis, regurgitation, and prolapse. MV repair is the most popular and most reliable surgical treatment for early MV pathology. One of the unsolved problems in MV repair is to predict the optimal repair strategy for each patient. Although experimental studies have provided valuable information to improve repair techniques, computational simulations are increasingly playing an important role in understanding the complex MV dynamics, particularly with the availability of patient-specific real-time imaging modalities. This work presents a review of computational simulation studies of MV function employing finite element (FE) structural analysis and fluid-structure interaction (FSI) approach reported in the literature to date. More recent studies towards potential applications of computational simulation approaches in the assessment of valvular repair techniques and potential pre-surgical planning of repair strategies are also discussed. It is anticipated that further advancements in computational techniques combined with the next generations of clinical imaging modalities will enable physiologically more realistic simulations. Such advancement in imaging and computation will allow for patient-specific, disease-specific, and case-specific MV evaluation and virtual prediction of MV repair.

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Algorithms for Fluid–Structure Interaction

Cited by 5 publications

References 78 publications

Patient-specific bicuspid valve dynamics: Overview of methods and challenges

Patient-specific bicuspid valve dynamics: Overview of methods and challenges

Dynamics of Flow in a Mechanical Heart Valve: The Role of Leaflet Inertia and Leaflet Compliance

Computational Mitral Valve Evaluation and Potential Clinical Applications

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