Abstract:
A computer model of the epicardial ventricular cell has been developed from both voltage clamp and action potential data to determine the contribution of the outward K/sup +/ currents to the action potential variation in healthy and diabetic male rats. The epicardial ventricular cell model has two major components: a membrane model and a fluid compartment model. The membrane was represented by the membrane capacitance, the ionic currents, and the membrane pumps and exchanger. The ionic changes of Na/sup +/, Ca/sup 2+/ and K/sup +/ were described for the lumped fluid compartment. Mathematical equations were developed to model the electrical changes observed in the two prominent K/sup +/ channels (the transient outward K/sup +/ current I/sub t/, and the sustained outward K/sup +/ current I/sub sus/) for the epicardial ventricular cells of the normal and streptozotocin-induced diabetic rats. The results conclude that the ventricular cell model can predict epicardial action potentials for the diabetic rats by decreasing the normal density of I/sub t/ by 45% and of I/sub sus/ by 40%.