Human blood flow is a multiscale problem: in first approximation, blood is a dense suspension of plasma and deformable red cells. Physiological vessel diameters range from about one to thousands of cell radii. Current computational models either involve a homogeneous fluid and cannot track particulate effects or describe a relatively small number of cells with high resolution but are incapable to reach relevant time and length scales. Our approach is to simplify much further than existing particulate models. We combine well-established methods from other areas of physics in order to find the essential ingredients for a minimalist description that still recovers hemorheology. These ingredients are a lattice Boltzmann method describing rigid particle suspensions to account for hydrodynamic long-range interactions and---in order to describe the more complex short-range behavior of cells---anisotropic model potentials known from molecular-dynamics simulations. Paying detailedness, we achieve an efficient and scalable implementation which is crucial for our ultimate goal: establishing a link between the collective behavior of millions of cells and the macroscopic properties of blood in realistic flow situations. In this paper we present our model and demonstrate its applicability to conditions typical for the microvasculature.
%0 Journal Article
%1 PhysRevE.82.056710
%A Janoschek, F.
%A Toschi, F.
%A Harting, J.
%D 2010
%I American Physical Society
%J Phys. Rev. E
%K csc hpc-europa2 icp jsc sara sfb716 ssc tu/e
%N 5
%P 056710
%R 10.1103/PhysRevE.82.056710
%T Simplified particulate model for coarse-grained hemodynamics simulations
%U https://link.aps.org/doi/10.1103/PhysRevE.82.056710
%V 82
%X Human blood flow is a multiscale problem: in first approximation, blood is a dense suspension of plasma and deformable red cells. Physiological vessel diameters range from about one to thousands of cell radii. Current computational models either involve a homogeneous fluid and cannot track particulate effects or describe a relatively small number of cells with high resolution but are incapable to reach relevant time and length scales. Our approach is to simplify much further than existing particulate models. We combine well-established methods from other areas of physics in order to find the essential ingredients for a minimalist description that still recovers hemorheology. These ingredients are a lattice Boltzmann method describing rigid particle suspensions to account for hydrodynamic long-range interactions and---in order to describe the more complex short-range behavior of cells---anisotropic model potentials known from molecular-dynamics simulations. Paying detailedness, we achieve an efficient and scalable implementation which is crucial for our ultimate goal: establishing a link between the collective behavior of millions of cells and the macroscopic properties of blood in realistic flow situations. In this paper we present our model and demonstrate its applicability to conditions typical for the microvasculature.
@article{PhysRevE.82.056710,
abstract = {Human blood flow is a multiscale problem: in first approximation, blood is a dense suspension of plasma and deformable red cells. Physiological vessel diameters range from about one to thousands of cell radii. Current computational models either involve a homogeneous fluid and cannot track particulate effects or describe a relatively small number of cells with high resolution but are incapable to reach relevant time and length scales. Our approach is to simplify much further than existing particulate models. We combine well-established methods from other areas of physics in order to find the essential ingredients for a minimalist description that still recovers hemorheology. These ingredients are a lattice Boltzmann method describing rigid particle suspensions to account for hydrodynamic long-range interactions and---in order to describe the more complex short-range behavior of cells---anisotropic model potentials known from molecular-dynamics simulations. Paying detailedness, we achieve an efficient and scalable implementation which is crucial for our ultimate goal: establishing a link between the collective behavior of millions of cells and the macroscopic properties of blood in realistic flow situations. In this paper we present our model and demonstrate its applicability to conditions typical for the microvasculature.},
added-at = {2023-09-25T00:01:03.000+0200},
author = {Janoschek, F. and Toschi, F. and Harting, J.},
biburl = {https://puma.ub.uni-stuttgart.de/bibtex/26add741d66c635eb847c0c09e83494bc/lorisburth},
doi = {10.1103/PhysRevE.82.056710},
interhash = {76b6ad1aa44263f68afea7db2c44c295},
intrahash = {6add741d66c635eb847c0c09e83494bc},
journal = {Phys. Rev. E},
keywords = {csc hpc-europa2 icp jsc sara sfb716 ssc tu/e},
month = nov,
number = 5,
numpages = {11},
pages = 056710,
publisher = {American Physical Society},
timestamp = {2023-09-25T00:01:03.000+0200},
title = {Simplified particulate model for coarse-grained hemodynamics simulations},
url = {https://link.aps.org/doi/10.1103/PhysRevE.82.056710},
volume = 82,
year = 2010
}