Large Curvature Effect on Pulsatile Entrance Flow in a Curved Tube: Model Experiment Simulating Blood Flow in an Aortic Arch-Reference-Cited by-同舟云学术

Large Curvature Effect on Pulsatile Entrance Flow in a Curved Tube: Model Experiment Simulating Blood Flow in an Aortic Arch

Published:1996-05-01 Issue:2 Volume:118 Page:180-186
ISSN:0148-0731
Container-title:Journal of Biomechanical Engineering
language:en
Short-container-title:

Author:

Naruse T.¹,Tanishita K.¹

Affiliation:

1. Department of Mechanical Engineering, Keio University, 3-14-1 Hiyoshi, Kohoku-ku, Yokohama 223, Japan

Abstract

We measured the velocity profiles of pulsatile entrance flow in a strongly curved tube using a laser-Doppler anemometer in order to simulate blood flow in the aortic arch under various conditions, i.e., a ratio of tube to curvature radius of 1/3, Womersley parameters of 12 and 18, and peak Dean number up to 1200. Axial isovelocity contours of the cross-section showed the potential vortex to be near the entrance, and with the maximum velocity there being skewed towards the inner wall; thereafter shifting towards the outer wall. During the deceleration phase, reverse axial flow occurred near the inner wall, and a region of this flow extended downstream. The large curvature contributes to the enhancement of the secondary flow and flow reversal, which elevates the wall-shear stress oscillations. The location of elevated wall-shear oscillations corresponds to the vessel wall region where atherosclerotic formation frequently occurs; thereby indicating that both the large curvature and pulsatility play key roles in formation of localized atherosclerotic lesions.

Publisher

ASME International

Subject

Physiology (medical),Biomedical Engineering

Link

http://asmedigitalcollection.asme.org/biomechanical/article-pdf/118/2/180/5545790/180_1.pdf

Reference24 articles.

1. Wesolowski S. A. , FriesC. C., Sabin:A. M., and SawyerP. N., “The Significance of Turbulence in Hemic Systems and in the Distribution of the Atherosclerotic Lesion,” Surgery, 1965, Vol. 57, pp. 155–162.

2. Nerem R. M. , and CornhillJ. F., “The Role of Fluid Mechanics in Atherogenesis,” J. Biomech. Engrg., 1980, Vol. 102, pp. 181–189.

3. Tanishita, K., “Gas Transport in Artificial Lungs: Limitations and Improvements,” Ph.D. dissertation. Brown University, 1976.

4. Chang L. T. , and TarbellJ. M., “Numerical Simulation of Fully Developed Sinusoidal and Pulsatile (Physiological) Flow in Curved Tubes,” J. Fluid Mech., 1985, Vol. 161, pp. 175–198.

5. Sakata N. , MachinamiM., ShiroshitaM., and OhnetaG., “Topographical Study on Arteriosclerotic Lesions in the Curving Regions of the Human Internal Carotid Artery,” J. Jpn. Coll. Angiology, 1985, Vol. 25, pp. 1255–1260 (in Japanese).

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