Add to ORKGHuman 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 ...
Accurate and reliable modeling of cardiovascular hemodynamics has the potential to improve understan...
Many rheological properties of blood, along with transport properties of blood cells can be captured...
Abstract Large-scale simulations of blood flow allow for the optimal evaluation of endothelial shear...
Human blood flow is a multiscale problem: in first approximation, blood is a dense suspension of pla...
Human blood can be approximated as a dense suspension of red blood cells in plasma. Here, we present...
Simulation of human blood flow is a demanding task both in terms of the complexity of applicable mod...
Change of title: Mesoscale hemodynamics with coarse-grained lattice Boltzmann-molecular dynamics sim...
While blood at the macroscopic scale is frequently treated as a continuum by techniques such as comp...
AbstractHistorically, predicting macroscopic blood flow characteristics such as viscosity has been a...
AbstractEfficient flow of red blood cells (RBCs) and white blood cells (WBCs) through the microcircu...
Many diseases are a result of, or are associated with, abnormal blood flow. Usually, these abnormali...
Whole blood is a complex suspension of cells, where the emergent rheology and transport phenomena ar...
There are many important systems which involve the flow of dense suspensions of deformable particle...
Non-particulate continuum descriptions allow for computationally efficient modeling of suspension fl...
We describe here a rigorous and accurate model for the simulation of three-dimensional deformable pa...
Accurate and reliable modeling of cardiovascular hemodynamics has the potential to improve understan...
Many rheological properties of blood, along with transport properties of blood cells can be captured...
Abstract Large-scale simulations of blood flow allow for the optimal evaluation of endothelial shear...
Human blood flow is a multiscale problem: in first approximation, blood is a dense suspension of pla...
Human blood can be approximated as a dense suspension of red blood cells in plasma. Here, we present...
Simulation of human blood flow is a demanding task both in terms of the complexity of applicable mod...
Change of title: Mesoscale hemodynamics with coarse-grained lattice Boltzmann-molecular dynamics sim...
While blood at the macroscopic scale is frequently treated as a continuum by techniques such as comp...
AbstractHistorically, predicting macroscopic blood flow characteristics such as viscosity has been a...
AbstractEfficient flow of red blood cells (RBCs) and white blood cells (WBCs) through the microcircu...
Many diseases are a result of, or are associated with, abnormal blood flow. Usually, these abnormali...
Whole blood is a complex suspension of cells, where the emergent rheology and transport phenomena ar...
There are many important systems which involve the flow of dense suspensions of deformable particle...
Non-particulate continuum descriptions allow for computationally efficient modeling of suspension fl...
We describe here a rigorous and accurate model for the simulation of three-dimensional deformable pa...
Accurate and reliable modeling of cardiovascular hemodynamics has the potential to improve understan...
Many rheological properties of blood, along with transport properties of blood cells can be captured...
Abstract Large-scale simulations of blood flow allow for the optimal evaluation of endothelial shear...