Geometric multiscale modeling of the cardiovascular system, between theory and practice

Quarteroni, Alfio; Veneziani, Alessandro; Vergara, Christian

doi:10.1016/j.cma.2016.01.007

Cited by 165 publications

(162 citation statements)

References 200 publications

(332 reference statements)

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“…The lumped parameter models, in particular, find application either individually or as boundary conditions (open or closed loop) to higher order models (1D or 3D) in the geometrical multi-scale method [1,2]. For a patient-specific analysis, however, these models must be adapted to each patient individually.…”

Section: Introductionmentioning

confidence: 99%

Inverse problems in reduced order models of cardiovascular haemodynamics: aspects of data assimilation and heart rate variability

Pant

Corsini

Baker

et al. 2017

J. R. Soc. Interface.

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Inverse problems in cardiovascular modelling have become increasingly important to assess each patient individually. These problems entail estimation of patient-specific model parameters from uncertain measurements acquired in the clinic. In recent years, the method of data assimilation, especially the unscented Kalman filter, has gained popularity to address computational efficiency and uncertainty consideration in such problems. This work highlights and presents solutions to several challenges of this method pertinent to models of cardiovascular haemodynamics. These include methods to (i) avoid ill-conditioning of the covariance matrix, (ii) handle a variety of measurement types, (iii) include a variety of prior knowledge in the method, and (iv) incorporate measurements acquired at different heart rates, a common situation in the clinic where the patient state differs according to the clinical situation. Results are presented for two patient-specific cases of congenital heart disease. To illustrate and validate data assimilation with measurements at different heart rates, the results are presented on a synthetic dataset and on a patient-specific case with heart valve regurgitation. It is shown that the new method significantly improves the agreement between model predictions and measurements. The developed methods can be readily applied to other pathophysiologies and extended to dynamical systems which exhibit different responses under different sets of known parameters or different sets of inputs (such as forcing/excitation frequencies).

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Section: Introductionmentioning

confidence: 99%

Inverse problems in reduced order models of cardiovascular haemodynamics: aspects of data assimilation and heart rate variability

Pant

Corsini

Baker

et al. 2017

J. R. Soc. Interface.

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show abstract

“…While advancements in constructing fully 3-D flow simulations in the arterial tree have recently been made [278], nevertheless considerable difficulties arise in the personalization and calibration of such highly detailed models of patient-specific vasculature (see for instance the works on collagen fiber remodelling in cardiovascular tissues [74,16]). The three models (3-D, 1-D and lumped 0-D), however, can very effectively interplay to form the so-called geometrical multiscale models (see [90,91,209]). …”

Section: Ventricular Afterload and Coupling With The Systemic Circulamentioning

confidence: 99%

“…Since this is insufficient to provide a complete set of Dirichlet data for the fluid equations inside the LV, (3.27) is in fact a defective boundary condition [89]. As such, condition (3.27) is imposed using Lagrange multipliers, which has the benefit that no explicit velocity profile needs to be imposed at the inflow, see [209]. In order to stabilize the velocity at the mitral valve due to flow reversal effects, the tangential component of the velocity field at the inlet, Γ in has to be further constrained to zero (see [172] and the discussion therein), leading to the inflow boundary condition:…”

Section: From Orifice Flow To Detailed Valve Dynamics Modelsmentioning

confidence: 99%

“…3.4), it is necessary to complete the previously described mechano-fluidic models by prescribing physiological preload and afterload conditions to the heart. In the simplest case this can be achieved with lumped parameter models or "0-D models" that account for the characteristic arterial impedance and consist of coupled sub-systems of resistive, inductive and capacitive elements in accordance to the analogy between fluid networks and electrical circuits, see [209]. The standard approximation for the afterload produced by the systemic circulation is the three-element windkessel model [274] dQ dt 35) where the two resistive components and the capacitive element correspond to different parts of the systemic circulation: R a is the peripheral resistance mainly due to small arteries and arterioles, C a the elastic compliance mainly due to the aorta and other large arteries, and R a the characteristic resistance of the aorta.…”

Section: Ventricular Afterload and Coupling With The Systemic Circulamentioning

confidence: 99%

See 1 more Smart Citation

Integrated Heart—Coupling multiscale and multiphysics models for the simulation of the cardiac function

Quarteroni

Lassila

Rossi

et al. 2017

Computer Methods in Applied Mechanics and Engineering

207

205

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“…Many sources of uncertainty can affect the accuracy of image-based CFD results: image acquisition and processing, mathematical modelling assumptions, physical parameter values and boundary condition (BC) settings. In particular, the latter are known to be relevant in the simulation of hemodynamic scenarios (Veneziani & Vergara 2005;Grinberg & Karniadakis 2008;Spilker & Taylor 2010;Gallo et al 2012;D'Elia & Veneziani 2013;Morbiducci et al 2013;Quarteroni et al 2016).…”

Section: Introductionmentioning

confidence: 99%

Uncertainty propagation of phase contrast-MRI derived inlet boundary conditions in computational hemodynamics models of thoracic aorta

Bozzi

Morbiducci

Gallo

et al. 2017

Computer Methods in Biomechanics and Biomedical Engineering

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This study investigates the impact that uncertainty in phase contrast-MRI derived inlet boundary conditions has on patient-specific computational hemodynamics models of the healthy human thoracic aorta. By means of Monte Carlo simulations, we provide advice on where, when and how, it is important to account for this source of uncertainty. The study shows that the uncertainty propagates not only to the intravascular flow, but also to the shear stress distribution at the vessel wall. More specifically, the results show an increase in the uncertainty of the predicted output variables, with respect to the input uncertainty, more marked for blood pressure and wall shear stress. The methodological approach proposed here can be easily extended to study uncertainty propagation in both healthy and pathological computational hemodynamic models.

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Geometric multiscale modeling of the cardiovascular system, between theory and practice

Cited by 165 publications

References 200 publications

Inverse problems in reduced order models of cardiovascular haemodynamics: aspects of data assimilation and heart rate variability

Inverse problems in reduced order models of cardiovascular haemodynamics: aspects of data assimilation and heart rate variability

Integrated Heart—Coupling multiscale and multiphysics models for the simulation of the cardiac function

Uncertainty propagation of phase contrast-MRI derived inlet boundary conditions in computational hemodynamics models of thoracic aorta

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