Fluid-Structure Coupled CFD Simulation of the Left Ventricular Flow During Filling Phase

Cheng, Yong; Oertel, Herbert; Schenkel, Torsten

doi:10.1007/s10439-005-4388-9

Cited by 134 publications

(128 citation statements)

References 31 publications

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“…The most natural one is to extract the heart geometry at one chosen moment in the heart cycle and to solve an electrical-fluid-structure interaction (EFSI) problem [27,28,29,30,31,32].…”

Section: Recent Technological Innovations In Imaging Techniques Have mentioning

confidence: 99%

Image-based large-eddy simulation in a realistic left heart

2014

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“…The most natural one is to extract the heart geometry at one chosen moment in the heart cycle and to solve an electrical-fluid-structure interaction (EFSI) problem [27,28,29,30,31,32].…”

Section: Recent Technological Innovations In Imaging Techniques Have mentioning

confidence: 99%

Image-based large-eddy simulation in a realistic left heart

2014

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“…The diastolic phase of the left heart was studied using an IBM method, the ventricular wall was described as a system of connected elastic springs and the flow was forced by imposing a pressure variation at the pulmonary veins connection to the left atrium. 59 The diastolic filling of an ellipsoidal LV was studied coupling a FV solution of the flow equation with a FE description of a ventricular hyperelastic wall, 12 and forcing the system with physiological time histories of the intraventricular pressure and of the mean velocity at the mitral orifice. These studies successfully reproduced the vortex formation process and its dynamics inside the LV chamber.…”

Section: Theoretical Modelsmentioning

confidence: 99%

“…The fluid and structure dynamics were solved simultaneously using FE methods and adopting a non-linear elastic 12 or a hyperelastic 97 representation of the wall properties, while the presence of the cardiac valves was typically accounted imposing simplified boundary conditions at the orifices. In the computational framework of the FV method, the diastolic filling was studied in a model LV, with a fibrous elastic description of a thin ventricular wall based on the IBM approach and the use of an iterative procedure to solve simultaneously the whole system of equations.…”

Section: Fluid-tissue Interactionmentioning

confidence: 99%

Left Ventricular Fluid Mechanics: The Long Way from Theoretical Models to Clinical Applications

Pedrizzetti

Domenichini

2014

Ann Biomed Eng

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Abstract-The flow inside the left ventricle is characterized by the formation of vortices that smoothly accompany blood from the mitral inlet to the aortic outlet. Computational fluid dynamics permitted to shed some light on the fundamental processes involved with vortex motion. More recently, patient-specific numerical simulations are becoming an increasingly feasible tool that can be integrated with the developing imaging technologies. The existing computational methods are reviewed in the perspective of their potential role as a novel aid for advanced clinical analysis. The current results obtained by simulation methods either alone or in combination with medical imaging are summarized. Open problems are highlighted and perspective clinical applications are discussed.

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“…In recent years, computational fluid dynamics (CFD)-based techniques have been used with varying degrees of success for simulating blood flow in the heart [2][3][4][5][6][7]. Most of these techniques employ a moving boundary set-up, where the motion of the walls is prescribed by extracting the dynamics from the four-dimensional imaging data.…”

Section: Introductionmentioning

confidence: 99%

Patient-specific modelling of whole heart anatomy, dynamics and haemodynamics from four-dimensional cardiac CT images

et al. 2011

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There is a growing need for patient-specific and holistic modelling of the heart to support comprehensive disease assessment and intervention planning as well as prediction of therapeutic outcomes. We propose a patient-specific model of the whole human heart, which integrates morphology, dynamics and haemodynamic parameters at the organ level. The modelled cardiac structures are robustly estimated from four-dimensional cardiac computed tomography (CT), including all four chambers and valves as well as the ascending aorta and pulmonary artery. The patient-specific geometry serves as an input to a three-dimensional Navier -Stokes solver that derives realistic haemodynamics, constrained by the local anatomy, along the entire heart cycle. We evaluated our framework with various heart pathologies and the results correlate with relevant literature reports.

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Fluid-Structure Coupled CFD Simulation of the Left Ventricular Flow During Filling Phase

Cited by 134 publications

References 31 publications

Image-based large-eddy simulation in a realistic left heart

Image-based large-eddy simulation in a realistic left heart

Left Ventricular Fluid Mechanics: The Long Way from Theoretical Models to Clinical Applications

Patient-specific modelling of whole heart anatomy, dynamics and haemodynamics from four-dimensional cardiac CT images

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