In-stent restenosis, the maladaptive response of a blood vessel to injury caused by the deployment of a stent, is a multiscale system involving a large number of biological and physical processes. We describe a Complex Automata Model for in-stent restenosis, coupling blood flow, drug diffusion, and smooth muscle cell models, all operating on different time scales. The Haemodynamics is handled using a dedicated Lattice Boltzmann simulation. Some details of the coupling of the Lattice Boltzmann simulation to other single scale models are described, together with first simulation results, obtained with a dedicated software environment for Complex Automata simulations
The inherent complexity of biomedical systems is well recognized; they are multiscale, multiscience ...
We describe the clotting process in stented aneurysms with a lattice Boltzmann (LB) model. In additi...
The lattice Boltzmann model is a relatively new development in computational fluid dynamics. Here we...
In-stent restenosis, the maladaptive response of a blood vessel to injury caused by the deployment o...
In-stent restenosis, the maladaptive response of a blood vessel to injury caused by the deployment o...
In-stent restenosis, the maladaptive response of a blood vessel to injury caused by the deployment o...
COAST (Complex Automata Simulation Technique) is a European Union FP6 funded project which has devel...
www.complex-automata.org A simplified description of the system in terms of relevant scales is drawn...
Recent developments of the lattice Boltzmann method for large-scale haemodynamic applications are pr...
Abstract Large-scale simulations of blood flow allow for the optimal evaluation of endothelial shear...
Accurate and reliable modeling of cardiovascular hemodynamics has the potential to improve understan...
AbstractEfficient flow of red blood cells (RBCs) and white blood cells (WBCs) through the microcircu...
AbstractA lattice Boltzmann simulation of blood flow using the Carreau–Yasuda model to calculate the...
The numerical simulation of thrombosis in stented aneurysms is an important issue to estimate the ef...
International audienceIn this work, a modified coupling Lattice Boltzmann Model (LBM) in simulation ...
The inherent complexity of biomedical systems is well recognized; they are multiscale, multiscience ...
We describe the clotting process in stented aneurysms with a lattice Boltzmann (LB) model. In additi...
The lattice Boltzmann model is a relatively new development in computational fluid dynamics. Here we...
In-stent restenosis, the maladaptive response of a blood vessel to injury caused by the deployment o...
In-stent restenosis, the maladaptive response of a blood vessel to injury caused by the deployment o...
In-stent restenosis, the maladaptive response of a blood vessel to injury caused by the deployment o...
COAST (Complex Automata Simulation Technique) is a European Union FP6 funded project which has devel...
www.complex-automata.org A simplified description of the system in terms of relevant scales is drawn...
Recent developments of the lattice Boltzmann method for large-scale haemodynamic applications are pr...
Abstract Large-scale simulations of blood flow allow for the optimal evaluation of endothelial shear...
Accurate and reliable modeling of cardiovascular hemodynamics has the potential to improve understan...
AbstractEfficient flow of red blood cells (RBCs) and white blood cells (WBCs) through the microcircu...
AbstractA lattice Boltzmann simulation of blood flow using the Carreau–Yasuda model to calculate the...
The numerical simulation of thrombosis in stented aneurysms is an important issue to estimate the ef...
International audienceIn this work, a modified coupling Lattice Boltzmann Model (LBM) in simulation ...
The inherent complexity of biomedical systems is well recognized; they are multiscale, multiscience ...
We describe the clotting process in stented aneurysms with a lattice Boltzmann (LB) model. In additi...
The lattice Boltzmann model is a relatively new development in computational fluid dynamics. Here we...