Title :
Effect of plasma viscosity on blood flow behaviors in microvessels
Author_Institution :
Sch. of Eng., Laurentian Univ., Sudbury, ON, Canada
Abstract :
To pursue a better understanding of the counter intuitive observations of plasma viscosity effects on microscopic blood flows, we have numerically simulated the red blood cell dynamics in shear and channel flows and multiple cell flow behaviors in straight microvessels. Our simulations indicate that, in a high-viscosity suspending medium, red blood cells appear more deformable, and this enhances the cell migration in straight microvessels. Also the cell free layer change with plasma viscosity might be helpful to interpret the increase in functional capillary density observed in hemodilution experiments with high-viscosity plasma expanders. Such information could be important to relevant biomedical applications.
Keywords :
blood; capillarity; cellular transport; haemodynamics; lattice Boltzmann methods; microchannel flow; shear flow; viscosity; blood flow behavior; cell deformation; cell migration; channel flow; functional capillary density; hemodilution experiment; high viscosity plasma expander; high viscosity suspending medium; immersed boundary lattice Boltzmann model; microscopic blood flow; multiple cell flow; plasma viscosity; red blood cell dynamics; shear flow; straight microvessel; Blood; Blood flow; Numerical models; Physiology; Plasmas; Shape; Viscosity; blood flows; lattice Boltzmann method; microcirculation; plasma viscosity; red blood cell;
Conference_Titel :
Defense Science Research Conference and Expo (DSR), 2011
Conference_Location :
Singapore
Print_ISBN :
978-1-4244-9276-3
DOI :
10.1109/DSR.2011.6026811
