Tolerance to peripheral, but not central, effects of ropinirole, a selective dopamine D2-like receptor agonist.

Studies were conducted to determine possible development, and underlying mechanisms, of tolerance to the hypotensive effects of ropinirole (4-[2-(dipropylamino)ethyl]-1-3-dihydro-2H-indol-2-one HCl), a selective dopamine receptor agonist, following twice daily oral administration to cynomolgus monkeys and spontaneously hypertensive rats (SHR). Tolerance to the hypotensive effects of the compound developed in both species within one week of repeated dosing. Tolerance which developed in rats was dose-related and could not be attributed to altered plasma/drug concentrations or be overcome by increasing the i.v. challenge dose of ropinirole. Cross-tolerance was shown to the dopamine receptor agonist bromocriptine. Similar hypotensive responses to bethanidine were seen in rats treated with ropinirole or vehicle. Tolerance to hypolocomotor effects of the compound were not apparent in the same time frame. The dopamine D2 receptor antagonist, domperidone, caused hypertension in ropinirole-but not vehicle-treated rats. Results reported in this paper are not consistent with a down-regulation of peripheral dopamine D2-like receptors but suggest a compensatory increase in basal sympathetic tone.

Muscarinic-receptor functioning in tracheas from normal and ovalbumin-sensitive guinea pigs.

Responses to bilateral vagal nerve stimulation, to field stimulation, and to exogenous methacholine and histamine were compared in tracheas isolated from (a) saline injected (i.p.) and saline-aerosol exposed guinea pigs (control), (b) ovalbumin-sensitized and saline-aerosol exposed (sensitized) guinea pigs, and (c) ovalbumin-sensitized and 2% ovalbumin-aerosol exposed (challenged) guinea pigs. Tracheal pressor responses (cmH2O; 1 cmH2O = 98.1 Pa) to nerve and field stimulation, and maximal responses to methacholine and histamine were significantly increased in animals from group c compared with groups a and b. Dose-response lines in response to the two agonists, expressed as percent maximal contraction, did not differ among the groups. The M1 antagonist pirenzepine (0.1-10 nM) selectively reduced responses to nerve stimulation in all three groups. The M2 antagonist gallamine potentiated responses to nerve or field stimulation in all three groups. We conclude that M1, M2, and M3 muscarinic receptor functioning is similar in control and ovalbumin-sensitized guinea pigs. Changes in post-receptor transduction mechanisms may mediate the increased responsiveness noted in animals from group c.

Muscarinic receptors and parasympathetic neurotransmission in guinea-pig trachea.

Muscarinic receptors involved in cholinergic neurotransmission were studied in isolated innervated guinea-pig tracheas using preganglionic (nerve) and postganglionic (field) stimulation, after blocking sympathetic effects with bethanidine (5 microM). Neostigmine (10 nM) significantly increased responses to nerve and field stimulation. The M1 antagonist pirenzepine (0.1-100 nM) selectively reduced tracheal responses to nerve stimulation in control and in neostigmine-treated tissues. The M2 antagonist gallamine (0.1-100 microM) significantly increased tracheal responses to nerve and field stimulation in control and in neostigmine-treated preparations. At concentrations that increased baseline tone, oxotremorine, arecoline and pilocarpine decreased responses to nerve and field stimulation. Gallamine (30 microM) selectively reduced the inhibitory effects of these agonists on responses to nerve and field stimulation. The findings indicate that cholinergic neurotransmission in guinea-pig trachea is modulated by facilitatory M1 receptors at parasympathetic ganglia and inhibitory M2 receptors at the postganglionic nerve endings.

A dual electrophysiologic test for atrial antireentry and ventricular antifibrillatory studies. Effects of bethanidine, procainamide, and WY-48986.

We have developed a dual electrophysiologic test that allows measurement of both antireentry and antifibrillatory activities of potential antiarrhythmics in the same anesthetized dog. The reentry portion of the model was created surgically by a Y-shaped crushing around the tissue between the superior and inferior vena cava and tissue parallel to the AV groove. The pacing-induced tachycardia that results from circus movements around the tricuspid ring is very persistent in duration and regular in cycle length. The antifibrillatory activities were assessed by determination of the ventricular fibrillation threshold (VFT) using train-stimuli method. Control VFT was measured every 15-20 min in duplicate and followed by induction of atrial reentry. A drug was infused to intervene the atrial tachycardia. After the conversion of the arrhythmia (either by drug regimens or pacing), postdrug VFT was measured, again in duplicate. Bethanidine (20 mg/kg), procainamide (30 mg/kg), and WY-48986 (10 mg/kg), a Class III antiarrhythmic, were evaluated in this dual test. Bethanidine and procainamide prolonged the cycle length of atrial reentry to a greater extent than WY-48986. The atrial arrhythmias were consistently terminated by procainamide and WY-48986 whereas bethanidine converted the tachycardias in one of the five dogs studied. All three agents elevated VFT with bethanidine producing higher values than procainamide and WY-48986. In conclusion, the dual electrophysiologic testing system offers both economic and scientific advantages for the study of modes of action of antiarrhythmic agents.

Ischemia-induced conduction delay and ventricular arrhythmias: comparative electropharmacology of bethanidine sulfate and bretylium tosylate.

Bretylium tosylate and bethanidine sulfate were studied in two models of experimental myocardial ischemia. In anesthetized dogs, left anterior descending coronary artery occlusion during rapid atrial pacing (180-200 min-1) produced ventricular tachycardia and fibrillation within 5 min in 9 of 11 dogs studied. In all cases, arrhythmias were preceded by and appeared to be temporally related to progressive fractionation and delay of electrograms recorded from the ischemic zone. In four dogs, bretylium (10 mg/kg) did not alter the time course of electrogram changes nor the time to onset of arrhythmia. However, in five dogs bethanidine (10 mg/kg) markedly exacerbated conduction changes in the ischemic zone and decreased the time to onset of ventricular arrhythmias (173 +/- 35 vs. 262 +/- 34 s control, mean +/- SEM, p less than 0.05). Bethanidine administration also facilitated ischemia-induced ventricular tachycardia and fibrillation in two dogs that did not exhibit ischemia-induced arrhythmias before receiving the drug. In isolated perfused rabbit hearts, global ischemia produced conduction slowing, depolarization of resting membrane potential, and decreases in amplitude and Vmax that were reproducible in serial 10 min ischemic episodes. Bretylium (10 mg/L) did not affect these parameters under either perfused or ischemic conditions. Although bethanidine (10 mg/L) also did not affect these parameters during perfusion, conduction slowing and depression of Vmax during ischemia were accelerated without affecting the time course of change in resting membrane potential. Both bretylium and bethanidine prolonged action potential duration under perfused conditions, but after 10 min of ischemia this effect was no longer evident. The results demonstrate that differences in the electrophysiologic effects of bretylium and bethanidine are markedly accentuated in the setting of acute ischemia. Although both these agents have been demonstrated to have antifibrillatory effects in other experimental settings, under the conditions of this study, bretylium failed to protect against ischemia-induced arrhythmias and acute bethanidine administration produced a proarrhythmic effect in association with an exacerbation of ischemia-induced conduction changes.

The non-catecholamine-mediated electrophysiological effects of intravenous bethanidine sulfate on the immature mammalian heart.

In a preliminary study, we found that bethanidine sulfate had important electrophysiologic effects on the neonatal canine heart, specifically that bethanidine increased atrial effective and functional refractory periods. Other effects (increase in heart rate blood pressure and enhanced atrioventricular conduction) were thought to be due to a release of endogenous catecholamines. To investigate the non-catecholamine-mediated effects of bethanidine, we administered 10 mg/kg i.v. bethanidine to eight neonatal puppies ages 6-14 days pretreated with 0.6 mg/kg of propranolol and compared them with a control group of six neonates that received propranolol followed by a placebo. In the bethanidine group, the mean atrial effective and functional refractory periods increased significantly from 58 to 109 ms and from 108 to 185 ms, respectively (p less than 0.0001). Bethanidine also caused a decrease in resting heart rate (from 154 beats/min postpropranolol to 144 beats/min postbethanidine, p less than 0.002). These effects were not observed in the placebo group. Wenckebach periodicity during incremental atrial pacing did not change significantly. There was a modest increase in the ventricular refractory periods following bethanidine. Thus, the direct electrophysiologic effects of bethanidine in the neonate include a significant prolongation of atrial refractoriness and a decrease in sinus node automaticity. Ventricular refractory periods, while increased, did not show the dramatic prolongation exhibited by the atrium. The atrial specificity of bethanidine is unique and may prove useful in the treatment of supraventricular arrhythmias in the neonatal period.

Bethanidine increases one type of potassium current and relaxes aortic muscle.

Using a whole-cell voltage-clamp technique, we identified two time- and voltage-dependent K+ currents: an early outward rectifier and a delayed outward rectifier in single vascular smooth muscle cells of rabbit aorta in culture. About 90% of the single cells tested showed a predominant delayed outward K+ current type. Both K+ currents were decreased by tetraethylammonium. In contrast, bethanidine sulphate (10(-4)M), a pharmacological analog of the cardiac antifibrillatory drug, bretylium tosylate, decreased the early outward K+ current, increased the delayed rectifier K+ current type, and hyperpolarized the resting membrane potential. Bethanidine was found to relax vascular smooth muscle. The vasodilatory effect of bethanidine is associated with the activation of a K+ current that is probably involved in keeping the membrane potential at the resting state, thereby depressing the excitability of the aortic vascular smooth muscle.

Bethanidine increased Na+ and Ca2+ currents and caused a positive inotropic effect in heart cells.

The effects of bethanidine sulphate, a pharmacological analog of the cardiac antibrillatory drug, bretylium tosylate, were studied on action potentials (APs) and K+, Na+, and Ca2+ currents of single cultured embryonic chick heart cells using the whole-cell current clamp and voltage clamp technique. Extracellular application of bethanidine (3 X 10(-4) M) increased the overshoot and the duration of the APs and greatly decreased the outward K+ current (IK) and potentiated the inward fast Na+ currents (INa) and the inward slow calcium current (ICa). However, intracellular introduction of bethanidine (10(-4) M) blocked INa. In isolated atria of rat, bethanidine increased the force of contraction in a dose-dependent manner. These findings suggest that when applied extracellularly, bethanidine exerts a potentiating effect on the myocardial fast Na+ current and slow Ca2+ current and an inhibitory effect of IK. The positive inotropic effect of bethanidine could be due, at least in part, to an increase of Ca2+ influx via the slow Ca2+ channel and the Na-Ca exchange. It is suggested that the decrease of IK by bethanidine may account for its antifibrillatory action.

Electrophysiologic and hemodynamic effects of bethanidine sulfate on the immature mammalian heart.

The cumulative electrophysiologic and hemodynamic effects of bethanidine sulfate (2.5, 5, 10 and 15 mg/kg i.v.) were studied in 9 canine neonates and 7 adult dogs. Increased heart rate, blood pressure and enhanced atrioventricular nodal function, observed in both groups, and decreased ventricular refractory periods and inducibility of ventricular arrhythmias seen in the adult, are probably related to a bethanidine-mediated release of catecholamines. However, in spite of the catecholamine release, bethanidine sulfate results in a significant prolongation of atrial refractoriness, this effect being quantitatively more important in the neonate than in the adult.

Studies on bethanidine and meobentine: direct and indirect effects of antifibrillatory drugs.

The electrophysiological effects of bethanidine and meobentine were studied on isolated canine cardiac tissues and the in situ dog heart using standard techniques. The "direct" electrophysiological effects of bethanidine (in the beta-adrenergic-blocked Purkinje fiber) resemble the effects of meobentine in the normal canine Purkinje fiber; both drugs produce use-dependent decreases of the maximum rate of depolarization of phase 0 and action potential amplitude. In addition, meobentine prolongs action potential duration (100%) of Purkinje fibers. In ventricular muscle cells, the only significant effect of meobentine is a decrease in the maximum rate of depolarization. In studies of ouabain-induced tachycardias and 24-h infarct-induced ventricular arrhythmias, bethanidine tends to increase heart rate and/or exacerbate the ectopic activity (due to its sympathomimetic effects), whereas meobentine tends to reduce heart rate and restore normal sinus rhythm. Both bethanidine and meobentine increase ventricular fibrillation threshold. This increase is evident following bethanidine injection after the subsidence of the sympathomimetic effects. Finally, moderate increases of ventricular fibrillation threshold following treatment with meobentine are accompanied by partial cardiac sympathetic blockade, as indicated by reduced chronotropic responses to stellate ganglion stimulation. The antiarrhythmic and antifibrillatory effects of bethanidine and meobentine may be explained by the use-dependent effects of these drugs on phase 0 of the action potential and by their sympatholytic actions on the autonomic nervous system. Meobentine may, in addition, exert antiarrhythmic effects by decreasing automaticity in partially depolarized cells.

Potassium channel blockade: A mechanism for suppressing ventricular fibrillation.

The suppression of ventricular fibrillation by antidysrhythmic drugs is well correlated with their ability to block potassium channels in nerve and cardiac membranes. Blockade of potassium channels reduces electrical inhomogeneities in action potential and conduction parameters that lead to ventricular fibrillation. These actions tend to effectively decrease the electrical size of the heart, which suggests a mechanism for antifibrillatory drug action. The receptor sites for antifibrillatory drug action (IK blockade) appear to be on the outside of the cardiac membrane whereas receptors for antiarrhythmic drug action (INa blockade) appear to be on the inside of the cardiac membrane.

A comparison of the effects of bethanidine, meobentine and quinidine on the electrical activity of rat hearts in vivo and in vitro.

Glass microelectrodes were used to record transmembrane electrical activity from cells located just beneath the endocardial surface of segments of the right ventricular free wall of the rat heart during superfusion and electrical stimulation in vitro at 37 degrees C. The sulphates of bethanidine, meobentine or quinidine (4 to 20 microM) applied in vitro caused a prolongation of action potential duration and a delayed and slowed return of electrical excitability following an action potential. Intracardiac electrical stimulation of the urethane-anaesthetized rat heart in situ was used to measure ventricular refractory periods from the electrocardiogram. Intravenous administration of bethanidine, meobentine or quinidine (10 to 20 mg kg-1) caused a prolongation of ventricular refractory periods. Quinidine had a briefer duration of action than either of the other two drugs tested. Urethane-anaesthetized open-chested rats which were subjected to left coronary artery occlusion displayed ventricular tachyarrhythmias in their electrocardiogram. These arrhythmias occurred during the period of occlusion and even more prominently after release of the occlusion. Intravenous administration of bethanidine, meobentine or quinidine (1 to 20 mg kg-1) protected rats against these arrhythmias. The protective effect of quinidine was briefer than that of either of the other two drugs tested.

Electrophysiological effects of bethanidine sulfate on guinea-pig papillary muscle.

Bethanidine, a chemical analog of bretylium, increased the plateau phase of the action potential of guinea-pig papillary muscle in 2.7 mM K+ Tyrode solution without changing other electrophysiological parameters. In 25 mM K+ Tyrode solution, the amplitude, duration and Vmax of the Ca2+-dependent action potential were increased in a dose-dependent manner by bethanidine. It is speculated that the mechanism of antiarrhythmic effect of bethanidine might be due to the prolongation of action potential by an increase of the slow inward current.

Electrophysiological effects of bethanidine sulfate on canine cardiac Purkinje fibers and ventricular muscle cells.

Bethanidine sulfate is a congener of bretylium tosylate, which has been reported to have antiarrhythmic and antifibrillatory effects. We studied the effects of bethanidine on transmembrane potentials recorded from canine Purkinje fibers and ventricular muscle cells, using standard microelectrode techniques. Normal Purkinje fibers were exposed to bethanidine (10-80 mg/L) for 30-40 min. Bethanidine produced dose-dependent decreases in the maximal rate of depolarization (MRD) and over-shoot of phase 0, but did not affect maximum diastolic potential (MDP). Action potential plateau duration (APD, to -60 mV) was decreased by bethanidine at all cycle lengths of stimulation between 1,000 and 300 ms. Bethanidine depressed the membrane responsiveness curve, and its effects on MRD showed marked use dependence. In ventricular muscle cells, bethanidine 20 mg/L decreased MRD but did not affect MDP or APD. The rate of normal automaticity in Purkinje fibers with MDPs greater than -85 mV was increased to 21.5 +/- 5.6 beats/min after exposure to bethanidine (10 mg/L for 30 min) from control values of 10.2 +/- 5.3 beats/min. Abnormal automaticity (MDPs = -40 to -60 mV) was induced in Purkinje fibers by superfusion with Tyrode solution containing 0.25 mM BaCl2; this activity also was accelerated after exposure to bethanidine 10 mg/L. The effects of bethanidine on automaticity are similar to those of bretylium, and may be caused by release of endogenous catecholamines. In contrast, the effects of bethanidine on action potentials of normal (driven) Purkinje fibers are markedly different from those of bretylium, and resemble those of lidocaine after 30-60 min of exposure.

Changes in active and inactive renin and in angiotensin II across the kidney in essential hypertension and renal artery stenosis.

Investigations were performed in 26 patients with essential hypertension and 24 with unilateral renal artery stenosis. In each patient blood was drawn simultaneously and in triplicate, from both renal veins and aorta, for measurement of plasma concentrations of active and inactive renin and of angiotensin II. In 19 patients estimates of individual renal plasma flow were obtained in order to calculate secretion rates for active and inactive renin, and to assess the contribution of renin secretion rate and of renal plasma flow to the renal vein renin ratio. In patients with essential hypertension there was evidence that the kidney secreted active renin (18% mean increase in renal vein concentration above that of arterial plasma; P less than 0.001), but no evidence of secretion of inactive renin (4% mean increase; NS). There was a tendency for the kidney to extract angiotensin II (8% mean decrease in renal vein concentration below that of arterial plasma; P = 0.07). The affected kidney in patients with renal artery stenosis showed marked secretion of active renin (364% mean increase; P less than 0.001) and also secreted inactive renin (80% mean increase; P less than 0.05) with net generation of angiotensin II across the renal circulation (100% mean increase; P less than 0.05). The contralateral kidney exhibited suppressed secretion of active renin (3% mean increase; NS) with no evidence of secretion of inactive renin (2% mean increase; NS), and marked extraction of angiotensin II (50% mean decrease; P less than 0.001). The correlation between combined secretion rate of active renin by both kidneys and the arterial concentration of active renin in patients with essential and renovascular hypertension taken together was strongly positive (r = 0.82; P less than 0.01). The same correlation for inactive renin was weak (r = 0.32; NS). The correlation between the combined secretion rates of active renin by both kidneys and the circulating plasma concentration of angiotensin II (r = +0.60; P less than 0.05) was both significant and positive. By contrast, the total 'secretion' rate of angiotensin II by both kidneys was inversely related to arterial plasma angiotensin II (r = -0.92; P less than 0.001). This latter relationship suggests an important role for the kidney in clearing angiotensin II from the circulation, this being more marked the higher the arterial angiotensin II concentration.(ABSTRACT TRUNCATED AT 400 WORDS)

Acute electrophysiologic effects of bethanidine sulfate in patients with ventricular tachycardia or fibrillation.

Ten patients with a history of ventricular tachycardia or ventricular fibrillation underwent electrophysiologic study with programmed stimulation before and 90 minutes after oral administration of bethanidine sulfate, 20 mg/kg. Mean plasma bethanidine concentration was 2.62 +/- 2.2 (+/- SD) micrograms/ml at the start of repeat testing. This dose of bethanidine produced no effect on sinus node function, atrioventricular conduction, or atrial or ventricular refractoriness. Ventricular tachycardia or fibrillation, inducible in all patients during the control study, could still be initiated by ventricular stimulation in 9 of 10 patients after bethanidine. Bethanidine suppressed the ability to initiate an arrhythmia in one patient with ventricular fibrillation during control stimulation. Orthostatic hypotension was seen in all patients despite pretreatment with the tricyclic antidepressant, protriptyline, 15 mg every 8 hours. The results suggest that bethanidine has few electrophysiologic effects and is of limited efficacy during electrophysiologic testing in patients with life-threatening ventricular arrhythmias.

Development of ventricular tachyarrhythmias in the conscious canine during the recovery phase of experimental ischemic injury: effect of bethanidine administration.

The antiarrhythmic and antifibrillatory actions of bethanidine were evaluated in two conscious canine models which are capable of developing ventricular tachyarrhythmias during the recovery phase of myocardial infarction. In the first model, nonsustained (n = 3) or sustained (n = 12) ventricular tachycardia (cycle length, 165 +/- 6 ms; mean +/- SD) was initiated by programmed electrical stimulation, 4-9 days after experimental myocardial infarction. Bethanidine was administered in cumulative doses of 2, 4, 8, and 16 mg/kg and programmed stimulation repeated. Bethanidine, in doses of 4, 8, and 16 mg/kg, slowed the cycle length of the tachycardia and allowed slower rates of ventricular pacing to produce equivalent delays at epicardial sites in the ischemic zone. Despite these changes, induction of sustained ventricular tachycardia was prevented in only two of 13 animals. Bethanidine (8 mg/kg i.v. every 8 h, n = 4; 16 mg/kg i.v. every 8 h, n = 5) failed to prevent the development of premature ventricular beats, ventricular tachycardia, and ventricular fibrillation which developed in response to a transient ischemic episode superimposed on the heart that had a previous acute myocardial infarction. No differences in survival at 24 h were observed between saline- (10%, n = 10) and bethanidine-treated (0%, n = 9) groups. These results suggest that bethanidine acts to increase the refractory period and depresses conduction velocity in ischemically injured tissue, slowing the rate of ventricular tachycardia. However, the drug fails to suppress the development of ventricular arrhythmias and ventricular fibrillation in both canine models.

Evaluation of drug-induced changes in myocardial repolarisation using the paced evoked response.

The use of the pace evoked response system in the assessment of drug-induced changes in myocardial repolarisation is reported. Using a conventional pacing electrode lead for both pacing and sensing, this system records the dominantly local repolarisation which follows a controlled (paced) depolarisation from the same site. Measurements of the latency of the ventricular evoked response at matched heart rates before and after drug administration permit the accurate direct comparison of the effects of drugs with class 3 mode of action on cardiac muscle repolarisation. Using this method we have evaluated the effect on the timing of the evoked T wave of two drugs which are known to prolong phase 2 of the action potential. Intravenous amiodarone (5 mg/kg) prolonged the stimulus-peak evoked T wave interval by an average of 39-4 ms (15% of control values); three hours after oral bethanidine (2 mg/kg) this interval increased by an average of 25.8 ms (10% of control values). The effect of therapeutic interventions on the latency of the local paced evoked response provides a simple, accurate assessment of their effect on the cellular action potential duration and constitutes a new tool in electrophysiological investigations.