A model for human ventricular tissue
Model Status
This variant of the model was created by Penny Noble of Oxford University, and represents the parameters given for the endocardial cell variant in Ten Tusscher et al. 2004. This file is known to run in OpenCell and COR.
This file is valid CellML and has full unit consistency.
Model Structure
Cardiac arrhythmias and sudden cardiac death are amongst the most common causes of premature death in the devloped world. However despite their prevalance, they remain relatively poorly understood. Mathematical models, which capture the function of the beating human heart, play an important role in cardiac research. In part this is because practical experiments on human hearts are limited, and animal hearts may differ significantly in their anatomy and physiology relative to the human heart. In addition, cardiac arrhythmias are three dimensional phenomena, while experimental observations are mainly limited to surface recordings.
Existing mathematical models of human ventricular cells include:
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>Priebe and Beuckelmann, Electrophysiological Model of the Human Ventricular Myocyte, 1998; and
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Bernus et al. A Computationally Efficient Electrophysiological Model of Human Ventricular Cells, 2002.
However, these models have their limitations, such as the fact that several of the equations are based on animal data. The aim of the 2004 study by ten Tusscher et al., is to develop a new model for human ventricular cells that is based on recent experimetnal data and that is computationally efficient for large-scale spatial simulations. A schematic diagrma of the modl can be seen in the figure below.
The complete original paper reference is cited below:
A model for human ventricular tissue, K.H.W.J. ten Tusscher, D. Noble, P.J. Noble, and A.V. Panfilov, 2004, American Journal of Physiology , 286, H1573-H1589. PubMed ID: 14656705
A schematic diagram describing the ion movement across the cell surface membrane and the sarcoplasmic reticulum, which are described by the Ten Tusscher et al. 2004 mathematical model of the human ventricular myocyte. |