An understanding of the role of the aortic elastic properties indicates their relevance at several sites of cardiovascular function. Acting as an elastic buffering chamber behind the heart (the Windkessel function), the aorta and some of the proximal large vessels store about 50% of the left ventricular stroke volume during systole. In diastole, the elastic forces of the aortic wall forward this 50% of the volume to the peripheral circulation, thus creating a nearly continuous peripheral blood flow. This systolic-diastolic interplay represents the Windkessel function, which has an influence not only on the peripheral circulation but also on the heart, resulting in a reduction of left ventricular afterload and improvement in coronary blood flow and left ventricular relaxation. The elastic resistance (or stiffness), which the aorta sets against its systolic distention, increases with aging, with an increase in blood pressure, and with pathological changes such as atherosclerosis. This increased stiffness leads to an increase in systolic blood pressure and a decrease in diastolic blood pressure at any given mean pressure, an increase in systolic blood velocity, an increase in left ventricular afterload, and a decrease in subendocardial blood supply during diastole, and must be considered a major pathophysiological factor, for example, in systolic hypertension. The elastic properties of the aortic Windkessel can be assessed in vivo in humans in several ways, most easily by measuring the pulse wave velocity along the aorta. The higher this velocity, the higher the elastic resistance, that is, the stiffness. Other methods depend on assessment of the ratio between pulse pressure and aortic volume changes (delata P/delta V), which can be assessed noninvasively by ultrasonic or tomographic methods. All assessments of vessel stiffness have to take into account the direct effect of current blood pressure, and thus judgements about influences of interventions rely on an unchanged blood pressure. Alternatively, to derive the "intrinsic" stiffness of the aortic wall one has to correct for the effect of the blood pressure present. Recently reports about pharmacologic influences on the elastic properties of the aorta have emerged in the literature.(ABSTRACT TRUNCATED AT 400 WORDS)
The influence of several calcium antagonists and antiarrhythmic drugs on digoxin kinetics and actions were investigated in 36 healthy men during digoxin steady state (0.375 mg/day). The subjects were randomly assigned to three subgroups and each group received placebo (control) and two of the following regimens (doses three times a day) in a randomized sequence for 2 wk each: verapamil (80 mg) and nifedipine (10 mg), verapamil (120 mg) and gallopamil (50 mg), or propafenone (150 mg) and quinidine (250 mg). Plasma digoxin concentration (PDC) rose during the cotreatments in the sequence: gallopamil (+16%) less than propafenone (+37%) less than nifedipine (+45%) less than verapamil (almost independent of dose, +69%) less than quinidine (+118%). These increases in PDC correlated closely to decreases in renal digoxin clearances. Renal creatinine clearance was virtually unaffected. The rise of PDC resulted in increased glycoside effects, as measured by the shortening of systolic time intervals and flattening of T wave. There was a linear correlation between PDC and changes in mean corrected electromechanical systole and T wave flattening. We conclude that, in addition to quinidine, other antiarrhythmic drugs and various calcium antagonists interact kinetically with digoxin and that the increasing PDCs are cardioactive.
Chronic garlic powder intake attenuated age-related increases in aortic stiffness. These data strongly support the hypothesis that garlic intake had a protective effect on the elastic properties of the aorta related to aging in humans.
In a double-blind, placebo-controlled study in 6 healthy volunteers, the correlation between beta-adrenoceptor binding, the time course of the effect and plasma concentration kinetics was investigated from 0 to 48 h after a single oral dose of propranolol 240 mg. First, the in vitro beta-adrenoceptor interaction of propranolol was investigated. Propranolol inhibited beta-adrenoceptor binding to rat parotid (beta 1) and reticulocyte (beta 2) membranes in the presence of pooled human plasma with a Ki of about 8 ng/ml plasma. After oral administration of 240 mg propranolol, concentration kinetics in plasma could be described by a Bateman function with a fictive concentration at time 0 of 275 ng/ml plasma, and a mean elimination half-life of 3.5 h. Using the concentration kinetics of propranolol in plasma together with its in vitro beta-adrenoceptor binding characteristics in the presence of placebo plasma from each individual, the time course of antagonism against beta-adrenoceptor mediated effects was predicted. The latter was in agreement with the time course of propranolol-induced inhibition of tachycardia due to orthostasis. After bicycle ergometry, however, the time course of inhibition of tachycardia was shorter than was predicted. Plasma sampled at various times after propranolol administration inhibited beta-adrenoceptor binding of the radioligand 3H-CGP 12177 to rat reticulocyte membranes in a fashion reflecting the time course of inhibition of exercise tachycardia observed in the volunteers. A direct, linear relation was shown between the in vitro inhibition of beta-adrenoceptor binding by the plasma samples withdrawn after propranolol administration and the inhibition of exercise tachycardia observed in parallel. The results show that the concentrations of antagonist present in plasma are representative of the concentrations in the effect compartment. Deep compartments of drug distribution appear irrelevant to the effects of the drugs. The relation between the plasma concentration of propranolol and the reduction in heart rate at various levels of physical effort shows no significant inhibition at rest and increasing IC50-values from orthostasis to 2 min and to 4 min of ergometry. IC50-values after orthostasis are in the range of the Ki-values from in vitro receptor binding studies, whereas the IC50-values after exercise are shifted 2- to 3-fold to the right relative to the Ki-values. This finding is in agreement with increased beta-adrenoceptor stimulation with increasing effort (release of endogenous noradrenaline), which shifts the antagonist concentration-effect curve to the right.(ABSTRACT TRUNCATED AT 400 WORDS)
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