A lattice Boltzmann simulation of clotting in stented aneursysms and comparison with velocity or shear rate reductions

Mathematics and Computers in Simulation

Volumn 72, Issue 2-6, 2006, Pages 108-112

  Chopard, Bastien ^a   Ouared, Rafik ^a   Rüfenacht, Daniel A ^b  

^a UNIVERSITY OF GENEVA   (Switzerland)

^b GENEVA UNIVERSITY HOSPITALS   (Switzerland)

Author keywords

Aneurysms; Blood flow; Clotting model; Stent

Indexed keywords

BLOOD; COMPUTER SIMULATION; MATHEMATICAL MODELS; MEDICAL APPLICATIONS; METRIC SYSTEM; NUMERICAL METHODS; SHEAR FLOW; VELOCITY MEASUREMENT;

ANEURYSMS; BLOOD FLOW; CLOTTING MODELS; STENT;

STATISTICAL MECHANICS;

EID: 33747348478     PISSN: 03784754     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.matcom.2006.05.025     Document Type: Article

References (5)

1. A.M. Artoli, A.G. Hoekstra, P.M.A. Sloot, Mesoscopic simulations of systolic flow in the human abdominal aorta, J. Biomech., in press.
2. Bernsdorf J., Harrison S.E., Smith S.M., Lawford P.V., and Hose D.R. Concurrent numerical simulation of flow and blood clotting using the lattice Boltzmann technique. In: Ma J., and Yang L.T. (Eds). Proceedings of the Eleventh International Conference on Parallel Distributed Systems (2005) 336-340
3. Hirabayashi M., Ohta M., Rüfenacht D.A., and Chopard B. A lattice Boltzmann study of blood flow in stented aneurysms. FGCS (2004)
4. Ouared R., and Chopard B. Lattice Boltzmann simulations of blood flow: non-Newtonian rheology and clotting processes. J. Stat. Phys. 121 (2005) 209-221
5. Williams R.H., and Nollert M.U. Platelet-derived no slows thrombus growth on a collagen type iii surface. Thrombosis J. 2 (2004) 1-11