Sequential Coupling Shows Minor Effects of Fluid Dynamics on Myocardial Deformation in a Realistic Whole-Heart Model

Brenneisen, Jochen; Daub, Anna; Gerach, Tobias; Kovacheva, Ekaterina; Huetter, Larissa; Dössel, Olaf; Loewe, Axel

doi:10.3389/fcvm.2021.768548

Cited by 8 publications

(5 citation statements)

References 36 publications

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“…In this study we create and validate a patient-specific model of blood flow across the four chambers of the heart using and extending the residual-based variational multiscale formulation (RBVMS) [22] of the arbitrary Lagrangian-Eulerian Navier-Stokes-Brinkman equations (ALE-NSB) [23] – [26] . We test the ability of machine learning-based GPEs, which approximate the model and estimate the uncertainty in the approximation, to provide a low-cost surrogate for the full physics-based model.…”

Section: Introductionmentioning

confidence: 99%

Global Sensitivity Analysis of Four Chamber Heart Hemodynamics Using Surrogate Models

Karabelas

Longobardi

Fuchsberger

et al. 2022

IEEE Trans. Biomed. Eng.

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Computational Fluid Dynamics (CFD) is used to assist in designing artificial valves and planning procedures, focusing on local flow features. However, assessing the impact on overall cardiovascular function or predicting longer-term outcomes may requires more comprehensive whole heart CFD models. Fitting such models to patient data requires numerous computationally expensive simulations, and depends on specific clinical measurements to constrain model parameters, hampering clinical adoption. Surrogate models can help to accelerate the fitting process while accounting for the added uncertainty. We create a validated patient-specific four-chamber heart CFD model based on the Navier-Stokes-Brinkman (NSB) equations and test Gaussian Process Emulators (GPEs) as a surrogate model for performing a variance-based global sensitivity analysis (GSA). GSA identified preload as the dominant driver of flow in both the right and left side of the heart, respectively. Left-right differences were seen in terms of vascular outflow resistances, with pulmonary artery resistance having a much larger impact on flow than aortic resistance. Our results suggest that GPEs can be used to identify parameters in personalized whole heart CFD models, and highlight the importance of accurate preload measurements.

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Section: Introductionmentioning

confidence: 99%

Global Sensitivity Analysis of Four Chamber Heart Hemodynamics Using Surrogate Models

Karabelas

Longobardi

Fuchsberger

et al. 2022

IEEE Trans. Biomed. Eng.

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“…The dynamics of non-linear fluid dynamic models may be investigated in the future utilizing the strength of Adams predictor corrector method and BDF method [66][67][68][69].…”

Section: Discussionmentioning

confidence: 99%

Reliable numerical treatment with Adams and BDF methods for plant virus propagation model by vector with impact of time lag and density

Anwar

Naz

Shoaib

2022

Front. Appl. Math. Stat.

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Plant disease incidence rate and impacts can be influenced by viral interactions amongst plant hosts. However, very few mathematical models aim to understand the viral dynamics within plants. In this study, we will analyze the dynamics of two models of virus transmission in plants to incorporate either a time lag or an exposed plant density into the system governed by ODEs. Plant virus propagation model by vector (PVPMV) divided the population into four classes: susceptible plants [S(t)], infectious plants [I(t)], susceptible vectors [X(t)], and infectious vectors [Y(t)]. The approximate solutions for classes S(t), I(t), X(t), and Y(t) are determined by the implementation of exhaustive scenarios with variation in the infection ratio of a susceptible plant by an infected vector, infection ratio of vectors by infected plants, plants' natural fatality rate, plants' increased fatality rate owing to illness, vectors' natural fatality rate, vector replenishment rate, and plants' proliferation rate, numerically by exploiting the knacks of the Adams method (ADM) and backward differentiation formula (BDF). Numerical results and graphical interpretations are portrayed for the analysis of the dynamical behavior of disease by means of variation in physical parameters utilized in the plant virus models.

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“…Most of them focus on some specific feature of the heart function, by surrogating the remaining ones with models of reduced dimensionality: electrophysiology, 13–20 cardiac mechanics and electromechanics 2,21–33 or computational fluid dynamics (CFD) of the blood 4,34–43 . Only few works also consider the interplay between hemodynamics and cardiac mechanics in a fluid–structure interaction (FSI) framework, 44–48 while neglecting or simplifying the electrical processes generating the contraction 49–52 …”

Section: Introductionmentioning

confidence: 99%

“…4,[34][35][36][37][38][39][40][41][42][43] Only few works also consider the interplay between hemodynamics and cardiac mechanics in a fluid-structure interaction (FSI) framework, [44][45][46][47][48] while neglecting or simplifying the electrical processes generating the contraction. [49][50][51][52] Albeit each of the above-mentioned models can provide meaningful insight into the cardiac function in both healthy and pathological conditions, they often neglect the feedback mechanisms that relate the different components. Conversely, fully integrated models featuring multiphysics coupling of electrophysiology, mechanics and fluid dynamics 12,[53][54][55][56] can provide a very accurate description of the physics of the heart, at the price of a high model complexity and large computational cost.…”

mentioning

confidence: 99%

A mathematical model that integrates cardiac electrophysiology, mechanics, and fluid dynamics: Application to the human left heart

Bucelli

Zingaro

Africa

et al. 2023

Numer Methods Biomed Eng

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We propose a mathematical and numerical model for the simulation of the heart function that couples cardiac electrophysiology, active and passive mechanics and hemodynamics, and includes reduced models for cardiac valves and the circulatory system. Our model accounts for the major feedback effects among the different processes that characterize the heart function, including electro‐mechanical and mechano‐electrical feedback as well as force‐strain and force‐velocity relationships. Moreover, it provides a three‐dimensional representation of both the cardiac muscle and the hemodynamics, coupled in a fluid–structure interaction (FSI) model. By leveraging the multiphysics nature of the problem, we discretize it in time with a segregated electrophysiology‐force generation‐FSI approach, allowing for efficiency and flexibility in the numerical solution. We employ a monolithic approach for the numerical discretization of the FSI problem. We use finite elements for the spatial discretization of partial differential equations. We carry out a numerical simulation on a realistic human left heart model, obtaining results that are qualitatively and quantitatively in agreement with physiological ranges and medical images.

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Sequential Coupling Shows Minor Effects of Fluid Dynamics on Myocardial Deformation in a Realistic Whole-Heart Model

Cited by 8 publications

References 36 publications

Global Sensitivity Analysis of Four Chamber Heart Hemodynamics Using Surrogate Models

Global Sensitivity Analysis of Four Chamber Heart Hemodynamics Using Surrogate Models

Reliable numerical treatment with Adams and BDF methods for plant virus propagation model by vector with impact of time lag and density

A mathematical model that integrates cardiac electrophysiology, mechanics, and fluid dynamics: Application to the human left heart

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