A 1D-0D-3D coupled model for simulating blood flow and transport processes in breast tissue

TL;DR

This paper introduces a multi-scale coupled model combining 1D, 0D, and 3D approaches to simulate blood flow and transport in breast tissue, capturing complex vascular dynamics efficiently.

Contribution

The work develops a novel integrated 1D-0D-3D modeling framework for breast vasculature, enabling detailed and computationally efficient simulations of blood flow and transport processes.

Findings

Realistic blood flow simulations validated against human data

Two coupled models for whole-body and breast-specific vasculature

Efficient modeling of complex vascular and tissue interactions

Abstract

In this work, we present mixed dimensional models for simulating blood flow and transport processes in breast tissue and the vascular tree supplying it. These processes are considered, to start from the aortic inlet to the capillaries and tissue of the breast. Large variations in biophysical properties and flow conditions exist in this system necessitating the use of different flow models for different geometries and flow regimes. Large variations in biophysical properties and flow conditions exist in this system necessitating the use of different flow models for different geometries and flow regimes. In total, we consider four different model types. First, a system of 1D nonlinear hyperbolic PDEs is considered to simulate blood flow in larger arteries with highly elastic vessel walls. Second, we assign 1D linearized hyperbolic PDEs to model the smaller arteries with stiffer vessel walls. The third model type consists of ODE systems (0D models). It is used to model the arterioles and peripheral circulation. Finally, homogenized 3D porous media models are considered to simulate flow and transport in capillaries and tissue within the breast volume. Sink terms are used to account for the influence of the venous and lymphatic systems. Combining the four model types, we obtain two different 1D-0D-3D coupled models for simulating blood flow and transport processes: The first 1D-0D-3D model covers the whole path from the aorta to the breast, while the second model is a sub-model obtained by restriction to breast vasculature and tissue making possible a significant reduction in computational cost. Several numerical experiments are conducted that demonstrate realistic flow simulations compared to existing data on blood flow in human breast and vascular system.