On the relevance of boundary conditions and viscosity models in blood flow simulations in patient‐specific aorto‐coronary bypass models

Jonášová, Alena; Vimmr, Jan

doi:10.1002/cnm.3439

Cited by 8 publications

(6 citation statements)

References 71 publications

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“…For example, the WK2 model may lead to non-physiological reflections of pulse waves because it lacks a resistance connected to the outlet vessel in series 46 . The addition of such a resistance gives rise to the popular three-element Windkessel model 10, 15,19,[47][48][49][50] . We note that such reflections occur in incompressible flows only if the wall motions are considered, but this study does not consider such motions.…”

Section: Discussionmentioning

confidence: 99%

Parametric analysis of an efficient boundary condition to control outlet flow rates in large arterial networks

McCullough

Coveney

2022

Sci Rep

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Substantial effort is being invested in the creation of a virtual human—a model which will improve our understanding of human physiology and diseases and assist clinicians in the design of personalised medical treatments. A central challenge of achieving blood flow simulations at full-human scale is the development of an efficient and accurate approach to imposing boundary conditions on many outlets. A previous study proposed an efficient method for implementing the two-element Windkessel model to control the flow rate ratios at outlets. Here we clarify the general role of the resistance and capacitance in this approach and conduct a parametric sweep to examine how to choose their values for complex geometries. We show that the error of the flow rate ratios decreases exponentially as the resistance increases. The errors fall below 4% in a simple five-outlets model and 7% in a human artery model comprising ten outlets. Moreover, the flow rate ratios converge faster and suffer from weaker fluctuations as the capacitance decreases. Our findings also establish constraints on the parameters controlling the numerical stability of the simulations. The findings from this work are directly applicable to larger and more complex vascular domains encountered at full-human scale.

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Section: Discussionmentioning

confidence: 99%

Parametric analysis of an efficient boundary condition to control outlet flow rates in large arterial networks

McCullough

Coveney

2022

Sci Rep

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“…A typical example is the three-element Windkessel model (3WK) [ 10 ], a circuit containing only one reactive component (the capacitor), and thus defined as a circuit of order one. Higher order Windkessel models, defined as circuits containing a total number of capacitors and inductors higher than one, have also been proposed [ 11 ]. The choice of the best model for outlet boundary conditions is generally the result of a trade-off between accuracy, model complexity, and number of parameters to estimate.…”

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A Vector Fitting Approach for the Automated Estimation of Lumped Boundary Conditions of 1D Circulation Models

Fevola

Bradde

Triverio

et al. 2023

Cardiovasc Eng Tech

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Purpose The choice of appropriate boundary conditions is a crucial step in the development of cardiovascular models for blood flow simulations. The three-element Windkessel model is usually employed as a lumped boundary condition, providing a reduced order representation of the peripheral circulation. However, the systematic estimation of the Windkessel parameters remains an open problem. Moreover, the Windkessel model is not always adequate to model blood flow dynamics, which often require more elaborate boundary conditions. In this study, we propose a method for the estimation of the parameters of high order boundary conditions, including the Windkessel model, from pressure and flow rate waveforms at the truncation point. Moreover, we investigate the effect of adopting higher order boundary conditions, corresponding to equivalent circuits with more than one storage element, on the accuracy of the model. Method The proposed technique is based on Time-Domain Vector Fitting, a modeling algorithm that, given samples of the input and output of a system, such as pressure and flow waveforms, can derive a differential equation approximating their relation. Results The capabilities of the proposed method are tested on a 1D circulation model consisting of the 55 largest human systemic arteries, to demonstrate its accuracy and its usefulness to estimate boundary conditions with order higher than the traditional Windkessel models. The proposed method is compared to other common estimation techniques, and its robustness in parameter estimation is verified in presence of noisy data and of physiological changes of aortic flow rate induced by mental stress. Conclusion Results suggest that the proposed method is able to accurately estimate boundary conditions of arbitrary order. Higher order boundary conditions can improve the accuracy of cardiovascular simulations, and Time-Domain Vector Fitting can automatically estimate them.

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“…Applying these models as boundary conditions allows for the creation of a pressure distribution profile along the entire vessel, eliminating the need to model the full circulatory system. Jonášová et al (2021) utilized several accurate Windkessel models with 3, 5, and 7 elements, to numerically assess coronary circulation, but they used the Newtonian and shear-thinning blood models, and did not evaluate the fractional flow reserve [11]. Kim et al (2014) compared the invasive and the computed FFR measures of patient-specific left coronary arteries and found remarkably similar results.…”

Section: Introductionmentioning

confidence: 99%

“…The blood suspensions grant blood its non-Newtonian characteristics, that lead to very complex behavior [16]. In the literature, blood is frequently modeled as a shear-thinning fluid that does not factor in the viscoelasticity [11,[17][18][19]. In the study conducted by Pinto et al (2020), three different viscoelastic constitutive models were used to model blood and the results using a Newtonian and a Carreau model for numerical simulations in right coronary arteries (RCAs) were compared.…”

Section: Introductionmentioning

confidence: 99%

Modeling the Five-Element Windkessel Model with Simultaneous Utilization of Blood Viscoelastic Properties for FFR Achievement: A Proof-of-Concept Study

Fernandes,

Sousa,

António

et al. 2023

Mathematics

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Coronary artery diseases (CADs) are a leading cause of death worldwide. Accurate numerical simulations of coronary blood flow, especially in high-risk atherosclerotic patients, have been a major challenge for clinical applications. This study pioneers a novel approach combining the physiologically accurate five-element Windkessel and sPTT models to enhance the accuracy of the hemodynamics and the fractional flow reserve (FFR) parameter. User-defined functions (UDFs) of the outlet pressure boundary condition (Windkessel model) and the viscoelastic characteristics of blood (sPTT model) were developed and dynamically loaded with ANSYS® 2023 software. In a proof-of-concept study, a patient’s left coronary artery with 40% stenosis was provided by the hospital for further analysis. The numerical FFR value obtained in the present work skews only 0.37% from the invasive measurement in the hospital. This highlights the important roles of both blood viscoelasticity and the five-element Windkessel model in hemodynamic simulations. This proof-of-concept of the FFR numerical calculation tool provides a promising comprehensive assessment of atherosclerosis in a fast, accurate, more affordable, and fully non-invasive manner. After validation with more patient cases in the future, this tool could be employed in hospitals and offer a more accurate and individualized approach for the diagnosis and treatment of CAD.

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On the relevance of boundary conditions and viscosity models in blood flow simulations in patient‐specific aorto‐coronary bypass models

Cited by 8 publications

References 71 publications

Parametric analysis of an efficient boundary condition to control outlet flow rates in large arterial networks

Parametric analysis of an efficient boundary condition to control outlet flow rates in large arterial networks

A Vector Fitting Approach for the Automated Estimation of Lumped Boundary Conditions of 1D Circulation Models

Modeling the Five-Element Windkessel Model with Simultaneous Utilization of Blood Viscoelastic Properties for FFR Achievement: A Proof-of-Concept Study

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