A Vector Fitting approach for the automated estimation of lumped boundary conditions of 1D circulation models

TL;DR

This paper introduces a novel method using Time-Domain Vector Fitting to automatically estimate high-order boundary conditions for 1D cardiovascular models, improving simulation accuracy over traditional Windkessel models.

Contribution

It presents a new approach for estimating complex boundary conditions, including higher-order models, using Vector Fitting, which enhances the modeling of blood flow dynamics.

Findings

Accurately estimates boundary conditions of arbitrary order.

Higher order boundary conditions improve simulation accuracy.

Method is robust against noisy data and physiological changes.

Abstract

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 high order boundary conditions, including the Windkessel model, and we investigate their use. 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. The capability of the proposed method is tested on a 1D circulation model consisting of the 55 largest arteries, to demonstrate its accuracy and the usefulness of estimating boundary conditions with order higher than the traditional Windkessel models. The proposed method is verified against 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. 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.