Title :
A simplified rotational spring model for mitral valve dynamics
Author :
Moorhead, K.T. ; Hann, Christopher E. ; Chase, J. Geoffrey ; Paeme, S. ; Kolh, Phillippe ; Dauby, P.C. ; Desaive, Thomas
Author_Institution :
Cardiovascular Res. Centre, Univ. of Liege, Liege, Belgium
Abstract :
A simple non-linear rotational spring model has been implemented to model the motion of mitral valve, located between the left atrium and ventricle. A measured pressure difference curve was used as the input into the model, which represents an applied torque to the valve chords. Various damping and hysteresis states were investigated to find a model that best matches reported animal data of chord movement during a heartbeat. The study is limited by the use of one dataset from the literature, however results clearly highlight some physiological issues such as the damping and chord stiffness changing within one cardiac cycle. Very good correlation was achieved between modeled and experimental valve angle, indicating good promise for future simulation of cardiac dysfunction, such as mitral regurgitation or stenosis.
Keywords :
biomedical equipment; biomedical measurement; cardiology; damping; diseases; haemodynamics; medical disorders; valves; applied torque; cardiac cycle; cardiac dysfunction; chord movement; chord stiffness; damping; experimental valve angle; heartbeat; hysteresis states; left atrium; left ventricle; measured pressure difference curve; mitral regurgitation; mitral valve dynamics; simple nonlinear rotational spring model; simplified rotational spring model; stenosis; valve chords; Cardiac cycle; damping; hysteresis; mitral valve; non-linear rotational spring;
Conference_Titel :
Control 2010, UKACC International Conference on
Conference_Location :
Coventry
Electronic_ISBN :
978-1-84600-038-6
DOI :
10.1049/ic.2010.0373
