Title :
Modeling lipid transport through the transverse clip stenosis
Author :
MacWilliams, B.A. ; Savilonis, B.J. ; Hoffman, A.H.
Author_Institution :
Dept. of Mech. Eng., Worcester Polytech. Inst., MA, USA
Abstract :
A finite-element model is used to determine the internal wall stresses in a rat aorta compressed with a U-shaped clip. These results are correlated with the location of various cell shapes found in vivo. Previous studies with this stenosis found polygonal cells and increased lipid deposition in small regions adjacent to each edge of the clip. The finite-element calculations suggest that the internal wall longitudinal shear stress changes sign rapidly over these small sections. By assuming that the permeability of the polygonal cells is much higher than in normal endothelial cells, the rate of lipoprotein uptake through the endothelium is calculated. As expected, the blood itself provides little resistance to the lipid uptake and significant transfer takes place only in the regions with the elevated permeability
Keywords :
cellular transport and dynamics; finite element analysis; physiological models; U-shaped clip; blood; cell shape; endothelial cells; finite element modelling; internal wall stresses; lipid transport modelling; lipoprotein uptake rate; longitudinal shear stress; permeability; polygonal cells; rat aorta; transverse clip stenosis; Arteries; Blood; Capacitive sensors; Finite element methods; In vivo; Internal stresses; Lipidomics; Mechanical engineering; Permeability; Shape;
Conference_Titel :
Bioengineering Conference, 1988., Proceedings of the 1988 Fourteenth Annual Northeast
Conference_Location :
Durham, NH
DOI :
10.1109/NEBC.1988.19385
