[Experimental myocardial infarction in the rat. Effect of perindopril]

Abstract

Experimental myocardial infarction is a model of cardiac overload due to amputation of part of the cardiac muscle. The development of cardiac failure depends on the size of the infarct and the time factor. This model of overload is associated with changes of the phenotype of the remaining healthy muscle and with peripheral vascular modifications partially dependent of the activation of pressor and/or deactivation of dilator systems. These changes are proportional to the size of the infarction at a given time after induction of the model. The degree of right ventricular hypertrophy and the decrease in blood pressure reflect the severity of infarction and the deterioration of the remaining myocardial function, affecting the haemodynamics both before and after the left ventricle. The increases in the 1/3 forms of isomyosins, the amount of subendocardial collagen, the biosynthesis, stocking and secretion of ANF are related to the infarct size and degree of overload. Similarly, the concentration of cyclic GMP is proportional to the infarct size. These parameters reflect ventricular overload, the increase of stress and energy deprivation of the remaining healthy muscle. The activation of peripheral pressor systems is also dependent on the infarct size reflects the effect of cardiac pump dysfunction on the kidney, liver, brain and endothelium. Large infarcts are associated with increased circulating renin and renal concentrations, with a decrease in angiotensinogen levels related to its consumption by the renin and to reduced hepatic synthesis and also with increased secretion and biosynthesis of vasopressin by the hypothalamus. In this model, Perindopril is beneficial by decreasing the cardiac load. It reduces the blood pressure, causes regression of bi-auricular and right ventricular hypertrophy. Changes in myosin isoenzyme configuration regress and subendocardial fibrosis and ANF concentrations are normalised. The effects of ACE inhibitors in this context, though very beneficial, are limited by the impossibility of normalising cardiac load and stress when the initial amputation of cardiac contractile mass exceeds 40%.