ABSTRACT
In this paper, to analyze the functional influence of ischemia on cardiac cell electrical activity and subsequently on ventricular electrical wave conduction, a human ventricular ischemic model was developed, which took into account three major pathophysiological components of ischemias hyperkalaemia, acidosis, and anoxia. This model simulated the action potential (AP) propagations of endocardial, midmycardial and epicardial cells with different levels of ischemia, and the influence of each factor on cell AP was analyzed. Finally the ECG waveform under ischemia was quantified by using a 2D model of human left ventricular tissue based on the anatomical structure of human heart. The experimental results showed that under ischemia action potential durations (APD) were reduced. In most cases, the larger the size of ischemic region or the more severe the ischemic level, the more dramatic the changes in the amplitude of ST-T wave were observed. For the three components of ischemia, hyperkalaemia was the dominant contributor to ST-T wave changes, which was in agreement with the results obtained on animal models.