The use of smoothed particles approach in realistic mathematical model of intracardiac blood flow: Simulation of a self-organizing tornado-like flow

The use of smoothed particles approach in realistic mathematical model of intracardiac blood flow: Simulation of a self-organizing tornado-like flow

We performed computer simulation and visualization of blood flow in the left ventricle by the method of smooth particle hydrodynamics (SPH). This visualization qualitatively describes the evolution of twisted stream and graphically demonstrates the direction of velocity field at each moment of time....

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Veröffentlicht in:Human physiology 2017-03, Vol.43 (2), p.213-221
Hauptverfasser: Bockeria, L. A., Gorodkov, A. Yu, Agafonov, A. V., Zhorzholiani, S. T., Kiknadze, G. I., Mironov, A. A., Talygin, E. A.
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Sprache:eng
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Aorta
Biomedical and Life Sciences
Biomedicine
Blood flow
Computer simulation
Human Physiology
Hydrodynamics
Image processing
Life Sciences
Mathematical models
Segmentation
Velocity
Ventricle
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container_end_page 221
container_issue 2
container_start_page 213
container_title Human physiology
container_volume 43
creator Bockeria, L. A.
Gorodkov, A. Yu
Agafonov, A. V.
Zhorzholiani, S. T.
Kiknadze, G. I.
Mironov, A. A.
Talygin, E. A.
description We performed computer simulation and visualization of blood flow in the left ventricle by the method of smooth particle hydrodynamics (SPH). This visualization qualitatively describes the evolution of twisted stream and graphically demonstrates the direction of velocity field at each moment of time. The geometrical features of the left ventricle are approximated by three-dimensional segmentation of experimental clinical images obtained from multispiral computer tomography (MSCT). The model adequately describes the possible configuration of swirling flow in the left ventricle and is a part of a comprehensive study of swirling flows in different compartments of heart, which comply with a family of the exact solutions of hydrodynamic Navier–Stokes equations for the class of quasipotential 1 swirling flows. Computer visualization shows how simulated by SPH method jet of a model liquid, which is placed in limited space, remains continuity and keeps its clockwise vorticity along the direction of the flow propagation during the whole cycle. Then it turns on approximately 120° by the time of ejection into the aorta. Such structure of the flow provides more effective pumping of blood as a model liquid through the ventricle as compared to a lamellar flow mode.
doi_str_mv 10.1134/S0362119717020049
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subjects Aorta
Biomedical and Life Sciences
Biomedicine
Blood flow
Computer simulation
Human Physiology
Hydrodynamics
Image processing
Life Sciences
Mathematical models
Segmentation
Velocity
Ventricle
title The use of smoothed particles approach in realistic mathematical model of intracardiac blood flow: Simulation of a self-organizing tornado-like flow
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