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Multibody Dynamics in Arterial System  

Shin Sang-Hoon (School of Oriental Medicine, Kyunghee University)
Park Young-Bae (School of Oriental Medicine, Kyunghee University)
Rhim Hye-Whon (Biomedical Research Center, KIST)
Yoo Wan-Suk (Department of Mechanical Engineering, Pusan National University)
Park Young-Jae (College of Oriental Medicine, Saemyung University)
Park Dae-Hun (Cancer Experimental Resources Branch, National Cancel Center)
Publication Information
Journal of Mechanical Science and Technology / v.19, no.spc1, 2005 , pp. 343-349 More about this Journal
Abstract
There are many things in common between hemodynamics in arterial systems and multibody dynamics in mechanical systems. Hemodynamics is concerned with the forces generated by the heart and the resulting motion of blood through the multi-branched vascular system. The conventional hemodynamics model has been intended to show the general behavior of the body arterial system with the frequency domain based linear model. The need for detailed models to analyze the local part like coronary arterial tree and cerebral arterial tree has been required recently. Non-linear analysis techniques are well-developed in multibody dynamics. In this paper, the studies of hemodynamics are summarized from the view of multibody dynamics. Computational algorithms of arterial tree analysis is derived, and proved by experiments on animals. The flow and pressure of each branch are calculated from the measured flow data at the ascending aorta. The simulated results of the carotid artery and the iliac artery show in good accordance with the measured results.
Keywords
Multibody Dynamics; Hemodynamics Arterial Tree System; Pulsatile Blood Flow; Vascular Impedance; Input Impedance; Arterial System Model; Forward & Backward Calculation;
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  • Reference
1 Zamir, M., 2000, The Physics of Pulsatile Flow, New York, Springer-Verlag
2 Westerhof, N., Bosman, F., De Vries, C. J. et al., 1969, Analog studies of the human systemic arterial tree, Journal of Biomechanics, Vol. 2, pp. 121-143   DOI   ScienceOn
3 Womersley, J. R., 1955a, Method for the Calculation of Velocity, Rate of Flow and Viscous Drag in Arteries when the Pressure Gradient is Known, Journal of Physiology, Vol. 127, pp. 553-563
4 Womersley, J. R., 1955b, Oscillatory Motion of a Viscous Liquid in a Thin-walled Elastic Tube. I. The Linear Approximation for Long Waves., Philosophical Magazine, Vol. 46, pp. 199-221
5 Womersley, J. R., 1957a, The mathematical Analysis of the Arterial Circulation in a State of Oscillatory Motion, Wright Air Development Center, Technical Report TR 56-614
6 Womersley, J. R., 1957b, Oscillatory Flow in Arteries: The Constrained Elastic Tube as a Model of Arterial Flow and Pulse Transmission, Physics in Medicine and Biology, Vol. 2, pp. 178-187   DOI   ScienceOn
7 Womersley, J. R., 1958, Oscillatory Flow in Arteries: The Reflection of the Pulse wave at Junctions and Rigid Inserts in the Arterial System, Physics in Medicine and Biology, Vol. 2, pp.313-323   DOI   ScienceOn
8 Duan, B. and Zamir, M., 1995, Pressure Peaking in Pulsatile Flow Through Arterial Tree Structures, Annals of Biomedical Engineering Vol. 23, pp. 794-803   DOI
9 Milnor, W. R., 1989, Hemodynamics 2nd ed., Baltimor, Williams & Wilkins
10 Newman, D. L., Greenwald, S. E. and Moodie, T. B., 1983, Reflection From Elastic Discontinuities, Medical & Biological Engineering & Computing, Vol. 21, pp.697-701   DOI
11 Randall, J. E. and Stacy, R. W., 1956, Mechanical Impedance of the Dog's Hind Leg to Pulsatile Blood Flow, American Journal of Physiology, Vol. 187, pp. 94-98
12 Shin, S. H., Park, Y. B. et al., 2004, Multibody Dynamics in Arterial System, Seoul, The second Asian Conference on Multibody Dynamics, pp. 298-305
13 Bergel, D. H., 1961, The Dynamic Elastic Properties of the Arterial Wall, Journal of Physiology, Vol. 156, pp. 458-469
14 A. P. Avolio, 'Multi-branched model of the human arterial system,' Medical & Biological Engineering & Computing, vol. 18, pp. 709-718, 1980   DOI