Evaluation of the metabolic responses to inhaled salbutamol in the measurement of beta2-adrenoceptor blockade

The aim of the present study was to evaluate whether metabolic responses to inhaled salbutamol may be used to measure the cardioselectivity of beta-adrenoceptor antagonists. We therefore studied the effects of oral doses of atenolol 50 mg, 100 mg, 200 mg (A50, A100, A200), propranolol 40 mg (P40), and placebo (Pl) on the hypokalaemic (K) and hyperglycaemic (Glu) responses to inhaled salbutamol in five healthy subjects. Increasing doses of atenolol were associated with a progressive attenuation of delta K compared with placebo: -0.72 mmol.l-1 (Pl) vs -0.20 mmol.l-1 (A200). However, delta K with A200 was significantly different from the response with P40: +0.12 mmol.l-1. There were partial reductions in the hyperglycaemic response with the beta-adrenoceptor antagonists, although this was only significant (compared with Pl) for P40: delta Glu 1.92 mmol.l-1 (Pl) vs 0.76 mmol.l-1 (P40). These results show that beta 2-adrenoceptor blockade by atenolol is a dose-dependent phenomenon, which may be measured by the attenuation of salbutamol-induced hypokalaemia. However, beta 2-adrenoceptor blockade by atenolol 200 mg was less than that by propranolol 40 mg. The glucose response to salbutamol was only partially blocked by propranolol and may therefore not be suitable to assess beta 2-adrenoceptor antagonism.     

Quantitative assessment of bronchial beta-adrenoceptor blockade in man.

1. We describe a method for assessing bronchial beta-adrenoceptor blockade quantitatively in man. Specific airway conductance is measured after increasing doses of inhaled salbutamol and the extent to which the dose-response curve is displaced to the right after beta-adrenoceptor blocking drugs is used to assess bronchial beta-adrenoceptor blockade. 2. Salbutamol dose-response curves were plotted for six normal subjects by measuring sGaw 15 min after increasing doses of inhaled salbutamol. Salbutamol produced a 30-70% increase in sGaw. 3. Salbutamol dose response curves were obtained 2 h after oral practolol (100 mg and 200 mg) and oral propranolol (40 mg and 80 mg) on separate days and were displaced to the right. 4. The mean dose ratios for practolol 100 mg and 200 mg were 1.2 and 2.1 and for propranolol 40 mg and 80 mg they were 21 and 61 respectively.     

Bronchial and cardiac beta-adrenoceptor blockade--a comparison of atenolol, acebutolol and labetalol.

Bronchial and cardiac beta-adrenoceptor blockade have been compared in six normal subjects after three beta-adrenoceptor antagonists. Single and double doses of atenolol (50 and 100 mg), acebutolol (100 and 200 mg) and labetalolol (150 and 300 mg) were studied on separate occasions. 2 Salbutamol airway dose-response curves were obtained by measuring the airway response as the change in specific airway conductance (sGaw) after increasing doses of inhaled salbutamol. Bronchial beta-adrenoceptor blockade was assessed after each drug as the dose of salbutamol needed to cause a 50% increase in sGaw (sGaw D50). 3 Cardiac beta-adrenoceptor blockade was assessed after the same doses of each beta-adrenoceptor antagonist, by measuring the percentage reduction in exercise heart rate from control, after exercise for 5 min at 70% of the subject's maximum work rate. 4 Atenolol 50 and 100 mg caused least bronchial beta-adrenoceptor blockade and the greatest reduction in exercise heart rate. 5 Acebutolol 100 and 200 mg and labetalol 150 and 300 mg produced more bronchial beta-adrenoceptor blockade than atenolol. 6 With this approach new beta-adrenoceptor antagonists can be assessed without putting asthmatic patients at risk.     

Beta-adrenoceptor responses to inhaled salbutamol in the elderly.

The purpose of the present study was to evaluate and compare the responsiveness of beta 2-adrenoceptors in elderly and young subjects. Seven healthy elderly volunteers (72 +/- 3 years) were given cumulative doses of inhaled salbutamol (100 micrograms-4000 micrograms) or placebo, following pre-treatment with propranolol 40 mg or placebo. Finger tremor (Tr), plasma potassium (K), and heart rate (HR) were measured at each dose step. There were dose-dependent increases in Tr (P less than 0.001) and HR (P less than 0.001) and falls in K (P less than 0.001), which were completely attenuated by propranolol (P less than 0.001). Comparison with dose-response curves in a group of young (Y) subjects (24 +/- 3 years) given an identical dose protocol of salbutamol showed no evidence of subsensitivity of beta 2-adrenoceptor responses in the elderly (E) group (mean and 95% confidence intervals for maximum responses): delta K -0.90 (-1.1(-)-0.82) mmol l-1 Y, -0.82 (-1.04(-)-0.60) mmol l-1 E, delta Tr 274 (213-335)% Y, 269 (197-342)% E, delta HR 25 (21-28) beats min-1 Y, 26 (21-31) beats min-1 E.     

Assessment of beta-adrenoceptor selectivity of a new beta-adrenoceptor antagonist, bisoprolol, in man

Bisoprolol is a new beta-adrenoceptor antagonist which has shown beta-adrenoceptor selectivity in studies in isolated tissues. Bronchial and cardiac beta-adrenoceptor blockade were assessed in eight normal subjects before and after oral ingestion of placebo, bisoprolol 20 and 40 mg, metoprolol 200 mg and propranolol 80 mg in random order. Bronchial beta-adrenoceptor blockade was assessed as the displacement of the bronchodilator dose-response curve to inhaled isoprenaline after each beta-adrenoceptor blocking drug compared to placebo and expressed as the dose ratio. Bronchodilatation was measured as change in specific airway conductance (sGaw) in the body plethysmograph. Cardiac beta-adrenoceptor blockade was assessed as the percentage reduction in exercise heart rate during the fifth minute of exercise at 70% of the subject's maximum work rate. Bisoprolol 20 and 40 mg caused a 24 and 25% reduction in exercise heart rate respectively, compared to 26% with metoprolol 200 mg and 20% with propranolol 80 mg. The dose ratios for the airway dose-response curves for the four beta-adrenoceptor blocking drugs were 1.04 and 3.4 for bisoprolol 20 and 40 mg, 1.4 for metoprolol 200 mg and 30 for propranolol 80 mg. Both doses of bisoprolol produced considerably less bronchial beta-adrenoceptor blockade than propranolol 80 mg despite causing a greater reduction in exercise heart rate. Bisoprolol 20 mg caused a similar amount of bronchial beta-adrenoceptor blockade and a similar reduction in exercise heart rate as metoprolol 200 mg, confirming that it is cardio-selective in man.     

Selectivity of antagonist and partial agonist activity of celiprolol in normal subjects.

1. The aims of this study were to assess the relative beta 1/beta 2 selectivity of the antagonist and partial agonist activity (PAA) of celiprolol in man. 2. Eight normal males received single oral doses of celiprolol 200 mg (C200), 400 mg (C400) and 800 mg (C800); atenolol 50 mg (A50), 100 mg (A100) and 200 mg (A200); nadolol 40 mg (N40) and placebo (PL), administered in a single-blind, randomised crossover design. 3. At rest, in the presence of low levels of circulating adrenaline and noradrenergic tone, a low dose of celiprolol (C200) showed evidence of beta 1-PAA by significant increases in systolic blood pressure and resting heart rate. At higher doses (C400, C800), beta 2-PAA became evident by a significant increase in postural finger tremor, whereas C200 had no effect. 4. In the presence of a beta 1-adrenoceptor agonist, as assessed by reduction of exercise tachycardia, increasing doses of celiprolol produced significantly less beta 1-adrenoceptor blockade compared with atenolol. Furthermore, there was no increase in beta 1-adrenoceptor blockade beyond C400. 5. In the presence of a beta 2-adrenoceptor agonist, as assessed by blunting of terbutaline-induced chronotropic, hypokalaemic and finger tremor responses, celiprolol exhibited less beta 2-adrenoceptor blockade than comparable doses of atenolol used in clinical practice. 6. Exercise hyperkalaemia was blunted significantly by C400 and C800 in comparison with all doses of atenolol and nadolol.(ABSTRACT TRUNCATED AT 250 WORDS)     

Can the biochemical responses to a beta 2-adrenoceptor stimulant be used to assess the selectivity of beta-adrenoceptor blockers?

The extent to which beta-adrenoceptor blocking drugs counteract the biochemical responses to an infusion of terbutaline, a beta 2-adrenoceptor agonist, has been investigated. In this study the beta 1-selectivity of metoprolol was compared with the non-selective beta-adrenoceptor blocker propranolol. The hypokalaemia produced by an infusion of terbutaline was reduced by low dose (50 mg) and high dose (200 mg) metoprolol and by low dose (40 mg) and high dose (160 mg) propranolol. The effects of propranolol on terbutaline induced hypokalaemia were more marked than those of metoprolol at both low dose (P = 0.01) and high dose (P = 0.05). Furthermore low dose metoprolol had less effect than high dose metoprolol (P = 0.05). The serum potassium appeared to rise slightly after propranolol. Low and high doses of both beta-adrenoceptor blockers markedly reduced the terbutaline-induced hyperglycaemia, but the differences between the two drugs were not statistically significant.     

An assessment of the partial agonist activity of Ro 31-1118, flusoxolol and pindolol in man.

1. The effects of single oral doses of three beta-adrenoceptor partial agonists (Ro 31-1118, flusoxolol and pindolol), two beta-adrenoceptor antagonists (propranolol and atenolol), two beta-adrenoceptor agonists (salbutamol and prenalterol) and placebo on sleeping heart rate, quality of sleep, supine heart rate, exercise heart rate, blood pressure, forearm blood flow and finger tremor were studied in eight healthy male volunteers. 2. Sleeping heart rate was increased by Ro 31-1118, flusoxolol, pindolol, salbutamol and prenalterol and decreased by propranolol and atenolol. 3. None of the drugs studied affected quality of sleep. 4. Supine heart rate was increased by flusoxolol, prenalterol and salbutamol, unaffected by Ro 31-1118 and pindolol and reduced by propranolol and atenolol. 5. Exercise heart rate was reduced by both beta-adrenoceptor antagonists and the three partial agonists and unaffected by salbutamol and prenalterol. 6. Systolic blood pressure was increased by Ro 31-1118, flusoxolol, salbutamol and prenalterol, unaffected by pindolol and reduced by propranolol and atenolol. Diastolic blood pressure was reduced by salbutamol and prenalterol. 7. Forearm blood flow was increased by Ro 31-1118, salbutamol and prenalterol, unchanged by pindolol and flusoxolol and decreased by atenolol and propranolol. 8. Finger tremor was increased by Ro 31-1118, flusoxolol, pindolol, salbutamol, and prenalterol. 9. beta-adrenoceptor partial agonists have different effects on the cardiovascular system and finger tremor to beta-adrenoceptor antagonists. 10. While Ro 31-1118 and flusoxolol are antagonists mainly at the beta 1-adrenoceptor they have agonist activity at both beta 1- and beta 2 adrenoceptors. 11. While pindolol is a non-selective antagonist its agonist activity is mainly at the beta 2-adrenoceptor.     

Time course of the bronchial response to salbutamol after placebo,betaxolol and propranolol

The effects on specific airway conductance (sGaw) of placebo, betaxolol and propranolol following the inhalation of salbutamol were studied in 8 healthy volunteers by whole body plethysmography. Each subject received placebo and single oral doses of betaxolol 40 mg and 80 mg, and propranolol 160 mg, and 320 mg. sGaw was measured before dosing and after 2 h, just before salbutamol was inhaled. It was then measured again after 15 min and 0.5, 1, 2, 3, 4 and 6 h. sGaw 2 h after the beta-blockers did not differ from the value whilst on placebo. The peak response to salbutamol after placebo and both doses of betaxolol was almost identical, whereas it was significantly reduced after propranolol. The AUC of the response to salbutamol over 6 h showed a reduction of 11% after betaxolol and of 19% after propranolol (p less than 0.01 between beta-blockers). The results indicate that, after betaxolol and in contrast to propranolol, a proportion of the bronchial beta 2-receptor population remains available to a beta 2-agonist.     

Comparative effects of bisoprolol and acebutolol in smokers with airway obstruction.

1. The effects of single oral doses of 10 mg bisoprolol and 400 mg acebutolol on respiratory function were studied in nine smokers with airway obstruction in a double-blind, placebo-controlled experiment. 2. The effects of the drugs were assessed by measuring specific airway conductance (sGaw) for 3 h after their administration and by studying their interaction with the bronchodilator response to inhaled salbutamol. 3. sGaw did not change for 3 h after bisoprolol or acebutolol administration. The bronchodilator response to inhaled salbutamol was not affected by bisoprolol but significantly reduced by acebutolol (P less than 0.05 vs placebo). 4. Under these conditions, bisoprolol behaves like a selective beta 1-adrenoceptor antagonist but acebutolol exhibits less beta 1-adrenoceptor selectivity.     

Effects of ICI 141,292 on exercise tachycardia and isoprenaline-induced beta-adrenoceptor responses in man.

The beta-adrenoceptor blocking properties and cardioselectivity of ICI 141, 292 were investigated in healthy male subjects. Seven subjects received in random order oral doses of ICI 141,292 20, 50, 100, 200 and 400 mg, atenolol 50 and 100 mg and placebo. ICI 14 292 had no effect on supine heart rate which was reduced by atenolol 100 mg. ICI 141,292 50, 100 and 200 mg had no effect on standing heart rate which was reduced by 400 mg at 2 h. Both doses of atenolol caused greater reductions. The maximum percent reduction of an exercise tachycardia after ICI 141,292 200 mg (23.9 +/- 3.7%) and 400 mg (24.3 +/- 5.2%) were similar to atenolol 50 mg (27.3 +/- 4.7%) but less than atenolol 100 mg (30.8 +/- 2.9%) (P less than 0.02). Six subjects received in random order single oral doses of ICI 141,292 100, 200 and 400 mg, atenolol 50 mg, propranolol 40 mg and placebo. Following each dose each subject received graded infusions of isoprenaline sulphate until heart rate increased by 40 beats min-1. Dose-response curves were constructed for the changes in heart rate, finger tremor, blood pressure and forearm blood flow produced by each infusion. At the 4 micrograms min-1 dose of isoprenaline, ICI 141,292 200 mg caused more attenuation than atenolol 50 mg but less than propranolol 40 mg in the changes of heart rate, diastolic blood pressure and finger tremor (P less than 0.02). ICI 141,292 400 mg caused more attenuation of the changes of all parameters than atenolol 50 mg but less attenuation of the changes in diastolic blood pressure and finger tremor than propranolol 40 mg (P less than 0.02). These results indicate that ICI 141,292 is a cardioselective beta-adrenoceptor antagonist with partial agonist activity.     

Differential effect of selective beta 1 and nonselective beta-adrenoceptor blockade on epinephrine and atropine response in normal humans.

Sympathetic stimulation with epinephrine (EPI) combined with parasympathetic blockade with atropine was studied in 10 healthy volunteers premedicated with placebo or three different beta-adrenoceptor blockers: atenolol (62.5 micrograms/kg, beta 1-selective), propranolol (62.5 micrograms/kg, nonselective), and pindolol (7.5 micrograms/kg, nonselective with intrinsic sympathomimetic activity, ISA). EPI infusion (0.06 microgram/kg/min) after placebo increased heart rate (HR) and systolic blood pressure (SBP) and decreased diastolic BP (DBP). Pretreatment with atenolol reduced the HR increase, and caused similar changes in BP. In contrast, pretreatment with propranolol and pindolol decreased HR and increased BP. Combined EPI and atropine (15 micrograms/kg) after placebo increased HR by 40% without causing BP changes. Similar HR changes were observed after administration of all beta-adrenoceptor blockers, but whereas a marked pressor response was observed after propranolol and pindolol a blunted response was observed after atenolol. Propranolol and pindolol reduced myocardial oxygen demand estimated by the HR x BP product after EPI, but this response was abolished by atropine. Serum potassium decreased from 3.9 +/- 0.2 to 3.2 +/- 0.3 mM after EPi and atropine. This effect was less after atenolol, and potassium increased after premedication with propranolol and pindolol. Our results show that nonselective beta-adrenoceptor blockade has a favorable effect on potassium homeostasis and oxygen demand parameters during EPI infusion but causes a marked pressor response, contrary to a beta 1-selective agent, during combined sympathetic stimulation and parasympathetic blockade. They also highlight the importance of the vasodilator cholinergic system as a defense mechanism in such situations.     

Modulation of the effects of salbutamol by propranolol and atenolol

Summary Six healthy volunteers were given single oral doses of 8 mg salbutamol, 40 mg propranolol, 100 mg atenolol, 8 mg salbutamol plus 40 mg propranolol and 8 mg salbutamol plus 100 mg atenolol, in a placebo controlled study.Plasma potassium fell following salbutamol and rose following atenolol or propranolol, and the hypokalaemic effect of salbutamol was reversed more effectively by propranolol than by atenolol. Although blood glucose rose after salbutamol, it was unaffected by any of the other treatments. Lying and standing pulse rate rose after salbutamol and fell equally after either -adrenoceptor antagonist, and fell more after salbutamol plus propranolol than after salbutamol plus atenolol. Blood pressure rose after salbutamol and fell after each of the other treatments.Forty milligrams propranolol was thus more effective than 100 mg atenolol in reversing the metabolic effects of 8 mg salbutamol, and was as effective in reversing the cardiovascular effects. In cases of symptomatic salbutamol overdose, propranolol should be considered as an antidote provided the patient is not asthmatic.     

In vivo evidence that isoproterenol may increase heart rate in the rat by mechanisms in addition to activation of cardiac beta(1)- or beta(2)-adrenoceptors

This study demonstrates that the tachycardia produced by systemic injections of the beta-adrenoceptor agonist, isoproterenol (10 microg/kg, i.v.), in conscious rats were not reduced after injection of the selective beta(1)-adrenoceptor antagonist, atenolol (1 mg/kg, i.v.), or after subsequent injection of the beta(1,2)-adrenoceptor antagonist, propranolol (1 mg/kg, i.v.). The hypotensive responses produced by isoproterenol were slightly diminished by atenolol and markedly diminished by propranolol. The tachycardia produced by catecholamines released for cardiac sympathetic nerve terminals were blocked by atenolol. These results suggest that the hypotensive actions of a 10 microg/kg dose of isoproterenol are mediated by activation of beta(1,2)-adrenoceptors whereas the increases in heart rate may be due to activation of another type of beta-adrenoceptor in cardiac pacemaker cells.     

Cardioselectivity of cetamolol compared with atenolol and nadolol

The selectivity of the beta-adrenoceptor blockade produced by single oral doses of cetamolol, atenolol, and nadolol was compared in normal male subjects. Study 1 established the dose at which each drug provides equivalent beta-1 blockade. Beta-1 blockade was estimated using the degree of inhibition of the increased heart rate (HR) response to graded exercise. Cetamolol (30 mg), atenolol (100 mg), and nadolol (80 mg) all attenuated the HR response to a comparable extent. This result established that the dose ratio of cetamolol:atenolol:nadolol of 1.00:3.33:2.67 provides equipotent beta-1 blockade. This ratio of doses was used in Studies 2 and 3 to evaluate the antagonism of beta-2-mediated responses to titrated doses of intravenous isoproterenol (ISO) by low and high doses of each drug. Beta-2 blockade was assessed using the attenuation of ISO-induced reductions in diastolic blood pressure (DBP) in Study 2 and ISO-induced increases in specific airway conductance (sGAW) in Study 3. For within drug comparisons, antagonism of the HR increase induced by ISO (a response mediated by both beta-1 and beta-2 receptors) was also examined. Treatments included cetamolol (15 and 60 mg), atenolol (50 and 200 mg), and nadolol (40 and 160 mg in Study 2; 40 mg only in Study 3). All drugs tested suppressed the HR, DBP, and sGAW responses to ISO, and this blockade was dose dependent. Cetamolol and nadolol produced approximately equipotent beta-1 blockade, whereas cetamolol at both doses produced a less potent beta-2 blockade. Atenolol antagonized ISO effects on all parameters less than either cetamolol or nadolol. Quantitative cardioselectivity indices revealed that cetamolol 60 mg was the most cardioselective and nadolol 40 mg the least. Data from the three studies demonstrate that cetamolol is cardioselective relative to nadolol and that, in contrast to atenolol, cardioselectivity appears to increase at the higher dose.     

Beta-adrenoceptor responses to high doses of inhaled salbutamol in patients with bronchial asthma.

1. Fourteen asthmatics (mean +/- s.e. mean baseline FEV1 62 +/- 6% of predicted) were given cumulative doubling doses of salbutamol by metered-dose inhaler as follows: 100 micrograms, 200 micrograms, 500 micrograms, 1000 micrograms, 2000 micrograms, 4000 micrograms. 2. Airways, tremor, haemodynamic and cyclic AMP responses were measured at each dose increment (made every 20 min). 3. There was a linear log dose-response relationship for each airways parameter (FEV1, VC, sGaw, FEF 50%). The plateau in the dose-response curve was not reached within our dose range. These changes were also mirrored in cyclic AMP responses. 4. There was a wide range in maximum airways response expressed in terms of absolute increase over baseline (95% confidence intervals: delta FEV1 667-1483 ml; delta VC 689-1695 ml; delta sGaw 0.92-4.50 s-1 kPa-1; delta FEF 50% 0.94-2.15 l s-1). Patients with a lower baseline showed a greater response in terms of percent increase in FEV1 (r = -0.83, P less than 0.001). There was however, no correlation between baseline airway calibre and the dose required for maximum bronchodilatation. 5. There were objective increases (mean +/- s.e. mean) in both heart rate (maximum delta HR of 14 +/- 5 beats min-1 at 4000 micrograms) and tremor power (maximum delta Tr of 115 +/- 44% at 2000 micrograms). These were not dose limiting side-effects as subjective symptoms were infrequent at higher doses. 6. Higher than conventional doses of salbutamol given by metered-dose inhaler may produce a distinct improvement in airways response without significant side-effects.(ABSTRACT TRUNCATED AT 250 WORDS)     

Comparison of beta-adrenoceptor selectivity of acebutolol and its metabolite diacetolol with metoprolol and propranolol in normal man

Summary 1. The beta-adrenergic selectivity of diacetolol, the major metabolite of acebutolol, has been compared with that of acebutolol, metoprolol and propranolol in 11 normal subjects.2. Bronchial and cardiac beta-adrenoceptor blockade were assessed on separate occasions after diacetolol 600 mg, acebutolol 400 mg, metoprolol 200 mg, propranolol 80 mg and placebo.3. Bronchial beta-adrenoceptor blockade was assessed as the displacement of the bronchodilator dose response curve to inhaled isoprenaline after each beta blocking drug compared to placebo and expressed as the dose ratio. Bronchodilatation was measured as change in specific airway conductance (sGaw) in the body plethysmograph. Cardiac beta-adrenoceptor blockade was assessed as the percentage reduction in exercise heart rate during the 5th minute of exercise at 70% of the subject's maximum work rate.4. There was a significant reduction in exercise heart rate with all 4 beta-blocking drugs when compared with placebo, 22% for diacetolol, 24% for acebutolol, 25% for propranolol and 28% for metoprolol. The reduction with metoprolol was significantly greater than the reduction with the other three beta-adrenoceptor antagonists.5. Mean dose ratios for the airway isoprenaline dose response curves after each of the 4 beta-blocking drugs were 2.4 for diacetolol, 2.7 for metoprolol, 8 for acebutolol and 72 for propranolol. The difference between diacetolol and metoprolol was not significant.6. Thus diacetolol appears to be more cardioselective than acebutolol and both are more cardioselective than propranolol in man. Metoprolol is probably more cardioselective than diacetolol though interpretation of the differences in exercise heart rate is complicated by the fact that diacetolol has some intrinsic sympathomimetic activity.     

Effects of betaxolol on cardiohemodynamics and coronary circulation in anesthetized dogs: comparison with atenolol and propranolol

Effects of betaxolol, a cardioselective beta-adrenoceptor antagonist, on cardiohemodynamics and coronary circulation were investigated in two kinds of anesthetized open-chest dog preparations in comparison with those of atenolol and propranolol. When administered intravenously, betaxolol, atenolol and propranolol produced dose-dependent decreases in the heart rate (HR), maximum left ventricular dP/dt [+)dP/dt), cardiac output (CO) and mean arterial pressure (MAP). Although all three drugs were almost equipotent in decreasing HR, betaxolol was much less potent than atenolol and propranolol in decreasing (+)dP/dt. Betaxolol decreased the total peripheral resistance (TPR), whereas atenolol and propranolol increased it. In another series of experiments, when administered intravenously, betaxolol, atenolol and propranolol all produced a decrease in the myocardial oxygen consumption (MVO2) and an increase in the atrioventricular conduction time (AVCT). All three drugs were nearly equipotent in decreasing MVO2, although betaxolol was less potent than the other two drugs at higher doses (greater than 300 micrograms/kg). Prolongation of AVCT with propranolol was stronger than those with betaxolol and atenolol. These results suggest that, unlike atenolol and propranolol, the decrease in TPR as well as beta 1-adrenoceptor blockade may be responsible for both the hypotensive effect of betaxolol and the decrease in MVO2 with betaxolol. The result that the cardiodepressant effect of betaxolol was much less potent than those of atenolol and propranolol suggests that betaxolol would be more beneficial than the others in the treatment of ischemic heart disease.     

Enhancement of physiological finger tremor by intravenous isoprenaline infusions in man: evaluation of its role in the assessment of beta-adrenoceptor antagonists.

Graded intravenous isoprenaline infusions produce dose-related increases in finger tremor. The dose-response curves constructed with intra-arterial or intravenous isoprenaline behave similarly in the presence of both atenolol 50 mg and propranolol 40 mg. In Five subjects, practolol 120 mg, atenolol 50 mg, propranolol 40 mg and sotalol 200 mg reduced exercise heart rate by 20.2 +/- 2.3, 21.4 +/- 1.8, 17.4 +/- 2.5, 23.9 +/- 3.6% respectively: the differences were not significant. The corresponding dose-ratios for reduction of an isoprenaline tachycardia were 2.8, 2.3, 19.1 and 16.9 respectively. At doses which had comparable effects on an exercise tachycardia, the non-selective beta-adrenoceptor antagonists, propranolol 40 mg and sotalol 200 mg, attenuated the finger response to isoprenaline (dose ratios 33.3 and greater than 25.0 respectively) more than the beta 1-selective adrenoceptor antagonists, practolol 120 mg and atenolol 50 mg (dose ratios 1.0 and 2.3 respectively). In two out of five subjects, dose-response curves could not be constructed with sotalol, either at a dose of 200 or 100 mg. The enhancement of physiological finger tremor by intravenous infusions of isoprenaline may be useful in the investigation of beta 2-adrenoceptors and their antagonists in man.     

The tremorolytic action of beta-adrenoceptor blockers in essential, physiological and isoprenaline-induced tremor is mediated by beta-adrenoceptors located in a deep peripheral compartment.

The effects of intravenous propranolol 100 micrograms kg-1, sotalol 500 micrograms kg-1, timolol 7.8 micrograms kg-1, atenolol 125 micrograms kg-1 and placebo on essential, physiological and isoprenaline-induced tremor were studied. These beta-adrenoceptor blocker doses produced equal reduction of standing-induced tachycardia in essential tremor patients. Atenolol produced significantly less reduction of essential and isoprenaline-induced tremor than the non-selective drugs, confirming the importance of beta 2-adrenoceptor blockade in these effects. Propranolol and sotalol produced equal maximal inhibition of isoprenaline-induced tremor but propranolol was significantly more effective in reducing essential tremor. The rate of development of the tremorolytic effect was similar in essential, physiological and isoprenaline-induced tremors but all tremor responses developed significantly more slowly than the heart rate responses. It is proposed that these results indicate that the tremorolytic activity of beta-adrenoceptor blockers in essential, physiological and isoprenaline-induced tremor is exerted via the same beta 2-adrenoceptors located in a deep peripheral compartment which is thought to be in the muscle spindles.