Title :
Postrepolarization refractoriness in ventricular cardiac cells: a simulation study
Author :
Ferrero, JM, Jr. ; Saiz, J. ; Ferrero, JM, Sr. ; Thakor, NV
Author_Institution :
L.I.B.-D.I.E., Univ. Politecnica de Valencia, Spain
fDate :
6/21/1905 12:00:00 AM
Abstract :
Computer simulations have been used to investigate the mechanisms of postrepolarization refractoriness in cardiac tissue under ischemic conditions at the cellular level. For this purpose, the Luo-Rudy (phase II) model of the cardiac action potential has been used with the formulation of the ATP-sensitive K+ current by Ferrero et al being adopted. Cells were subject to simulated hyperkalemic and hypoxic conditions. Our results show that action potential duration (AFD) progressively decreases with hyperkalemia, while effective refractory period (ERP) has a biphasic behavior with [K+]0. The delay in the recovery from inactivation of the inward sodium current, as a consequence of diastolic depolarization, seems to be responsible for this phenomenon. Under ischemic conditions, this trend is maintained, though both APD and ERP values are significantly lowered
Keywords :
bioelectric potentials; biological tissues; biomembrane transport; cardiovascular system; digital simulation; medical computing; physiological models; ATP-sensitive K+ current; K; Luo-Rudy phase II model; Na; action potential duration; biphasic behavior; cardiac action potential; cardiac tissue; cellular level; diastolic depolarization; effective refractory period; hyperkalemic conditions; hypoxic conditions; inward sodium current; ischemic conditions; postrepolarization refractoriness; simulation study; ventricular cardiac cells; Biomembranes; Cardiac tissue; Computational modeling; Computer simulation; Enterprise resource planning; Integrated circuit modeling; Ischemic pain; Myocardium; Pathology; Strontium;
Conference_Titel :
Computers in Cardiology, 1999
Conference_Location :
Hannover
Print_ISBN :
0-7803-5614-4
DOI :
10.1109/CIC.1999.826014
