β-Adrenoceptor blocking effects and plasma levels of bornaprolol and propranolol in man

Summary The -adrenoceptor blocking effects and pharmacokinetics of bornaprolol (FM 24), a new -adrenoceptor blocking agent, have been compared with those of propranolol and a placebo in a double-blind trial in 6 healthy volunteers. Heart rate, systolic and diastolic blood pressures and peak expiratory flow rate were measured at rest and at the end of 3 min vigorous exercise on a bicycle ergometer, before and 2, 24 and 48 h after single oral doses of bornaprolol (120, 240 and 480 mg) and propranolol (40, 80 and 160 mg). Plasma renin activity at rest and the plasma concentrations of the two drugs were determined. Bornaprolol significantly reduced resting heart rate, dose-dependently lowered exercise-induced tachycardia and decreased peak expiratory flow rate and plasma renin activity. In addition, exercise-induced tachycardia was significantly reduced by bornaprolol up to 48 hours after drug intake (pharmacodynamic half-life approximately 63–86 h) and there was a correlation between this reduction and the log plasma bornaprolol concentration over the 48-h period. Thus, bornaprolol behaved in man as a non-cardioselective and long-lasting -adrenoceptor blocking drug, probably devoid of intrinsic sympathomimetic activity.     

Comparison of the effects of dilevalol and propranolol on systemic and regional haemodynamics in healthy volunteers at rest and during exercise

The effects of single oral doses of dilevalol 400 mg and propranolol 80 mg on systemic and regional haemodynamics at rest and after sub-maximal exercise, were compared, in a placebo-controlled, randomised, double-blind, crossover study in 6 healthy male volunteers.At rest, as compared to placebo, neither dilevalol nor propranolol significantly affected arterial pressure and heart rate but, whereas propranolol decreased cardiac output (–27% at 2 h) and tended to increase total peripheral resistance, dilevalol tended to increase cardiac output and decreased total peripheral resistance (–7% at 2 h). Neither dilevalol nor propranolol affected brachial artery diameter. Propranolol tended to decrease brachial artery flow (–20% at 2 h) and to increase brachial vascular resistance (+25% at 2 h), but dilevalol did not and the brachial irrigation ratios did not change. Neither of the drugs affected carotid haemodynamics or plasma atrial natriuretic factor. Both drugs tended to decrease plasma renin activity, and dilevalol (+82% at 2 h) increased norepinephrine more than propranolol (+19% at 2 h).After exercise, dilevalol and propranolol produced similar falls in the induced increases in arterial pressure, heart rate and cardiac output, and had the same effects on regional haemodynamics, plasma renin activity and atrial natriuretic factor. Finally, dilevalol greatly increased plasma norepinephrine.We conclude that the ₂-adrenoceptor agonist activity of dilevalol was clearly expressed at rest, thus inducing vasodilation and counteracting the -adrenoceptor blockade-induced negative chronotropic and inotropic effects. However, during sub-maximal exercise, only the -adrenoceptor antagonist activity of dilevalol was apparent.     

Coronary endothelial cells: a target of ischemia reperfusion and its treatment?

Ischemia/reperfusion injury of the heart is not limited to cardiomyocytes but also extends to coronary vascular cells, and especially coronary endothelium. Indeed, in different animal models, ischemia followed by reperfusion (but not ischemia alone) markedly decreases endothelium-dependent relaxations of coronary arteries, and especially those induced by nitric oxide (NO), while endothelium-independent responses and smooth muscle responsiveness are usually maintained. Such injury to the endothelium appears to depend on the increased production of oxygen-derived free radicals upon reperfusion, leading to an increased degradation of NO and an acute inflammatory response characterized by an increased adhesion of neutrophils to endothelial cells. Indeed, reperfusion injury to the endothelium may be prevented by free radical scavengers, by prevention of adhesion and/or activation of neutrophils, by exogenous NO supply or increased endogenous production of NO, as well as by ischemic preconditioning. Given the essential role of the endothelium and of NO in the regulation of vasomotor tone, as well as platelet and leukocyte function, it is likely that such changes in coronary endothelial function have important adverse consequences in terms of altered perfusion, and increased risk of vasospasm, but also on the long-term risk of thrombosis and atherosclerosis. Although these coronary endothelial alterations have been essentially evaluated in experimental models and are indeed difficult to assess in the human coronary circulation in the context of myocardial infarction, data obtained in healthy volunteers demonstrate that such post-ischemic alterations of endothelial function may be detected in the peripheral circulation, with underlying molecular mechanisms similar to those demonstrated experimentally. A better understanding of the mechanisms responsible for such endothelial injury may lead to the development of new treatments that protect the endothelium during ischemia and reperfusion, but also possibly in other diseases associated with endothelial dysfunction.     

Soluble epoxide hydrolase inhibition improves myocardial perfusion and function in experimental heart failure

The study addressed the hypothesis that soluble epoxide hydrolase (sEH) inhibition, which increases cardiovascular protective epoxyeicosatrienoic acids (EETs), exerts beneficial effects in an established chronic heart failure (CHF) model. In CHF rats, left ventricular (LV) function, perfusion and remodeling were assessed using MRI and invasive hemodynamics after 42-day (starting 8 days after coronary ligation) and delayed 3-day (starting 47 days after coronary ligation) treatments with the sEH inhibitor AUDA (twice 0.25 mg/day). Delayed 3-day and 42-day AUDA increased plasma EETs demonstrating the effective inhibition of sEH. Delayed 3-day and 42-day AUDA enhanced cardiac output without change in arterial pressure, thus reducing total peripheral resistance. Both treatment periods increased the slope of the LV end-systolic pressure-volume relation, but only 42-day AUDA decreased LV end-diastolic pressure, relaxation constant Tau and the slope of the LV end-diastolic pressure-volume relation, associated with a reduced LV diastolic volume and collagen density. Delayed 3-day and, to a larger extent, 42-day AUDA increased LV perfusion associated with a decreased LV hypoxia-inducible factor-1alpha. Both treatment periods decreased reactive oxygen species level and increased reduced-oxidized glutathione ratio. Finally, MSPPOH, an inhibitor of the EET-synthesizing enzyme cytochrome epoxygenases, abolished the beneficial effects of 3-day AUDA on LV function and perfusion. Augmentation of EET availability by pharmacological inhibition of sEH increases LV diastolic and systolic functions in established CHF. This notably results from short-term processes, i.e. increased LV perfusion, reduced LV oxidative stress and peripheral vasodilatation, but also from long-term effects, i.e. reduced LV remodeling.     

Selenium diet-supplementation improves cocaine-induced myocardial oxidative stress and prevents cardiac dysfunction in rats

Chronic cocaine abuse causes cardiac dysfunction and induces oxidative stress. The goal of this study was to evaluate whether an enhanced antioxidant pool, induced by the administration of selenium, may prevent the myocardial dysfunction induced by cocaine. Cocaine was administered for 7 days (15 mg/kg/day, i.p.) to rats pretreated for 4 weeks with selenium (1.16 mg/L/day, p.o.). Cardiac function was evaluated by cardiac index and left ventricular (LV) fractional shortening (FS) measured by echocardiography. The redox ratio and enzymatic activities of glutathione peroxidase (GPX) and superoxide dismutase (SOD) were measured in the LV myocardium. Cocaine administration induced a cardiac dysfunction, as evidenced by a decrease in cardiac index and LV FS as well as by an increase in LV diameters. Moreover, antioxidant markers and redox ratio were altered in rats after cocaine exposure. Selenite supplementation induced a significant limitation of cardiac index and FS alterations observed after cocaine administration. This improvement in cardiac function was associated with a redox ratio recovery while SOD and GPX activities remained unchanged. Thus, selenite reversed both the oxidative stress and the contractile dysfunction induced by cocaine administration. These results suggest a major role of oxidative stress in the cocaine-induced cardiotoxicity.     

Role of arterial smooth muscle tone and geometry in the regulation of peripheral conduit artery mechanics by shear stress

1. Although arterial blood flow is recognized as an important modulator of vascular tone and geometry, the effect of acute changes in shear-stress on conduit artery mechanics has not been fully investigated in humans because of technical limitations. 2. To assess, respectively, the effects of decreases and increases in flow and shear stress on radial artery tone and mechanics, arterial pressure (photoplethysmography), total blood viscosity, radial artery internal diameter, wall thickness (echotracking) and blood flow (Doppler) were measured in healthy volunteers (mean (+/-SEM) age 25 +/- 1 years) during a distal flow arrest (n=12) and hand skin heating (n=18). 3. Radial artery flow decreased from 31 +/- 4 to 7 +/- 1 10(-3) L/min during distal flow arrest (P < 0.001) and increased from 10 +/- 2 to 22 +/- 4 and 69 +/- 6 10(-3) L/min during heating (P < 0.001). At mean arterial pressure, these changes in flow were respectively associated with a parallel flow-dependent reduction and increase in diameter and midwall stress. There was no significant modification in mean elastic modulus. Compliance did not change when flow decreased and only increased at the highest level of flow. Finally, the cross-sectional compliance and incremental modulus were fitted as functions of midwall stress. The decrease in flow was associated with an upward shift of the modulus-midwall stress curve and a downward shift of the compliance-midwall stress curve. The increase in flow was associated with a downward shift of the modulus-midwall stress curve and an upward shift of the compliance-midwall stress curve at each level of wall shear stress. 4. By using two different procedures, we obtained similar results concerning the direct effects of increases and decreases in flow on stiffness of the arterial wall and on arterial compliance and demonstrated the presence of a flow-dependent regulation of arterial smooth muscle tone of peripheral conduit arteries in humans.     

Evidence against a role of inducible nitric oxide synthase in the endothelial protective effects of delayed preconditioning

Preconditioning the heart with brief periods of ischaemia induces delayed endothelial protection against reperfusion injury, but the precise mechanisms involved in this endogenous protein are still unclear. Induction of the type II-nitric oxide synthase (iNOS) acts as a mediator of the preconditioning against myocardial infarction and stunning. The present study was designed to assess whether iNOS also contributes to the delayed endothelial protective effects of preconditioning. Rats were subjected to 20 min ischaemia followed by 60 min reperfusion 24 h after sham surgery or preconditioning (one cycle or 2 min ischaemia/5 min reperfusion and two cycles of 5 min ischaemia/5 min reperfusion). At the end of the reperfusion, coronary segments were removed distal to the site of occlusion and mounted in wire myographs. Ischaemia-reperfusion (I/R) decreased the endothelium-dependent relaxations to acetylcholine (maximal relaxations: sham, 66+/-5%; I/R, 40+/-1%; P<0.05) and this impairment was prevented by preconditioning (maximal relaxation: 61+/-6%). Administration of N-(3-aminomethyl)benzyl)acetaminide (1400W), a highly selective inhibitor for iNOS, 10 min before prolonged ischaemia did not modify the beneficial effect of preconditioning (maximal relaxation: 66+/-5%). These data show that preconditioning induces delayed protection against reperfusion-injury. However, in contrast to the myocytes, these endothelial protective effects of delayed preconditioning do not involve iNOS.