Drug-disease interactions: reduced beta-adrenergic and potassium channel antagonist activities of sotalol in the presence of acute and chronic inflammatory conditions in the rat

Inflammation may influence response to pharmacotherapy. We investigated the effect of inflammation on response to sotalol, a beta-adrenergic receptor and potassium channel antagonist. Racemic sotalol (40 mg kg(-1)) was administered to healthy, acutely (interferonalpha 2a-induced) and chronically (Mycobacterium butyricum-induced adjuvant arthritis) inflamed male Sprague-Dawley rats (n=4 - 6/group). Another group of interferon-treated rats received 3 mg kg(-1) of anti-TNF antibody infliximab. Electrocardiogram (ECG) recorded and plasma sotalol concentration monitored for 6 h. The study was repeated in acutely inflamed rats following administration of stereochemically pure individual sotalol enantiomers [40 mg kg(-1) S (potassium channel blocker) or 20 mg kg(-1) R (beta-adrenergic/potassium channel blocker)]. Chronic arthritis was readily evident. Acute arthritis was associated with elevated segmented neutrophils and increased plasma nitrite and tumour necrosis factor (TNF) concentrations. Sotalol affected ECG in all rats. In both inflamed groups, however, response to sotalol in prolongation of QT interval (potassium channel sensitivity) was reduced. The effect of PR interval (beta-adrenergic activity) was also reduced following administration of the racemate and R-enantiomer. No significant differences in pharmacokinetics were observed between control and inflamed rats. Infliximab reduced nitrite and TNF concentrations and reversed the effect of acute inflammation on both PR and QT intervals. The reduced electrocardiographic responses to sotalol is likely due to the influence of inflammation on the action of the drug on both beta-adrenergic and potassium channel receptors secondary to over-expression of pro-inflammatory cytokines and/or nitric oxide. Our observation may have therapeutic consequences in all conditions where inflammatory mediators are increased.     

Despite increased plasma concentration,inflammation reduces potency of calcium channel antagonists due to lower binding to the rat heart

1. Rheumatoid arthritis reduces verapamil oral clearance thereby increases plasma concentration of the drug. This coincides with reduced drug effects through an unknown mechanism. 2. The effect of interferon-induced acute inflammation on the pharmacokinetics and electrocardiogram of verapamil (20 mg kg(-1), p.o.) and nifedipine (0.1 mg kg(-1), i.v.) was studied in Sprague-Dawley rats. 3. The effect of both acute and chronic inflammation on radioligand binding to cardiac L-type calcium channels was also investigated. 4. Acute inflammation resulted in increased plasma concentration of verapamil but had no effect on that of nifedipine. Verapamil binding to plasma proteins was unaffected. 5. As has been reported for humans, the increased verapamil concentration coincided with a reduction in the degree to which PR interval is prolonged by the drug. The effect of nifedipine on PR interval was also reduced by inflammation. 6. Maximum binding of (3)H-nitrendipine to cardiac cell membrane was significantly reduced from 63.2+/-2.5 fmol mg(-1) protein in controls to 46.4+/-2.0 in acute inflammation and from 66.8+/-2.2 fmol mg(-1) protein in controls to 42.2+/-2.0 in chronic inflammation. 7. Incubation of the normal cardiac cell membranes with 100 and 1000 pg ml(-1) of rat tissue necrosis factor-alpha did not influence the binding indices to the calcium channels. 8. Our data suggest that the reduced calcium channel responsiveness is because of altered binding to channels.     

Selective Effect of Adjuvant Arthritis on the Disposition of Propranolol Enantiomers in Rats Detected Using a Stereospecific HPLC Assay

Nonstereospecific studies have indicated that the pharmacokinetics of propranolol (PR) are altered in inflammatory conditions such as arthritis. However, as the kinetics and dynamics of PR are stereoselective, we examined the effect of adjuvant arthritis (AA) on the disposition of the individual enantiomers. A novel normal-phase stereospecific HPLC assay for PR was developed involving chiral derivatization with S-(naphthyl)ethyl isocyanate and fluorescence detection. Oral and iv doses of racemic PR were administered to control and AA rats (n = 6). AA had no significant effect on either clearance or S:R ratio after iv doses. On the other hand, after oral doses, clearance was significantly decreased in AA. Although significant for both enantiomers, this effect was more pronounced on the less active R-enantiomer. The AUC R:S ratio was, therefore, significantly altered (AA, 14 ± 3.0; control, 4.3 ± 1.2). Increased total (S + R) plasma concentrations of PR in AA, possibly due to a reduced intrinsic clearance, therefore, reflect mainly increased concentrations of the less active R-enantiomer.     

Pravastatin reverses the down-regulating effect of inflammation on beta-adrenergic receptors: a disease-drug interaction between inflammation, pravastatin, and propranolol

Inflammatory conditions reduce the potency to prolong the PR interval of certain cardiovascular drugs including propranolol, sotalol, and verapamil in rats and humans despite elevated plasma drug concentrations. We tested whether pravastatin restores altered action and disposition of propranolol as well as inflammatory mediators concentrations in the Pre-Adjuvant Arthritis (Pre-AA) Sprague-Dawley rat model. Rats [Healthy/Placebo, Arthritis/Placebo, Healthy/Statin, and Arthritis/Statin groups (n=14-16/group)] received Mycobacterium butyricum on day 0 followed by 6 mg/kg pravastatin or placebo twice daily during days 4-8. PR-interval response to 25 mg/kg oral propranolol was measured on days 0, 4 and 8. On day 8, blood samples were collected for interferon-gamma, interleukin-10, C-reactive protein, and nitrite measurements. Propranolol enantiomer pharmacokinetics were delineated using another 4 groups (healthy n=5, Pre-AA n=9) on day 8. Pre-AA significantly reduced propranolol response despite a 10-fold increase in concentrations. Pravastatin restored the response but not the drug concentrations. Area under the % effect-time curve (% min) was 714+/-214 in Healthy/Placebo, 256+/-249 in Arthritis/Placebo, 1534+/-367 in Healthy/Statin, and 1713+/-393 in Arthritis/Statin. While pravastatin reduced elevated serum interferon-gamma concentration in the Pre-AA model, it did not influence other biomarkers. Pravastatin restores response to propranolol in inflamed rat but has no effect on the elevated propranolol concentrations. This was associated with lower serum interferon-gamma concentrations.     

Single-dose kinetics of oral propranolol, metoprolol, atenolol, and sotalol: relation to lipophilicity

Nine healthy volunteers received single oral doses of the following four beta-adrenergic blocking agents: propranolol (160 mg), metoprolol (100 mg), atenolol (200 mg), and sotalol (320 mg). The kinetics of each drug were determined from multiple serum concentrations measured during 24-48 h after each dose, and in vitro lipid solubility determined using the liquid chromatographic (HPLC) retention index. Oral clearance for the four drugs ranged from 40.2 ml/min/kg for propranolol down to 2.1 for sotalol. Oral clearance was highly correlated (r = 0.99) with in vitro lipid solubility, with propranolol being the most lipophilic drug and sotalol the least. Thus lipophilicity is a physicochemical property of beta-adrenergic blockers that appears to influence their intrinsic clearance after oral dosage.     

Effects of chlorpromazine on the disposition and beta-adrenergic blocking activity of propranolol in the dog

The effects of chlorpromazine (100 mg p.o., 2 hr before propranolol) on the disposition and beta-adrenergic blocking actions of both intravenous (6 mg) and oral (40 mg) propranolol were studied in the dog. Chlorpromazine pretreatment significantly reduced (69%) the oral clearance of propranolol, resulting in significant increases in propranolol bioavailability (159%), and in the total beta-adrenergic blocking activity (111%) after the oral dose. The increase in the total beta-adrenergic blocking activity of oral propranolol after chlorpromazine pretreatment was mostly due to an increased contribution from the parent compound; the apparent activity from active propranolol metabolites was not affected by chlorpromazine. Chlorpromazine pretreatment had no significant influence on the systemic clearance, elimination half-life, apparent volume of distribution, and plasma binding of propranolol, or on the apparent hepatic blood flow. After intravenous propranolol, chlorpromazine pretreatment had no effect on either the total amount of beta-adrenergic blocking activity or the amount of activity attributable to active metabolites. The decreased oral propranolol clearance by chlorpromazine was seen as a shift to the left in the propranolol dose vs. AUC relationship, eliminating the apparent nonlinear kinetic behavior of oral propranolol, and reducing the apparent oral threshold dose. Chlorpromazine's major, if not only, effect on propranolol disposition was to reduce the presystemic elimination of propranolol, possibly through inhibition of its metabolism via a pathway other than ring oxidation.     

Evaluation of potential pharmacodynamic and pharmacokinetic interactions between verapamil and propranolol in normal subjects.

1. Potential pharmacodynamic and pharmacokinetic interactions between verapamil and propranolol were evaluated in two double-blind, randomised, balanced, crossover studies employing the same six healthy males. 2. The first study examined the effect of repeated propranolol administration on the pharmacodynamics and pharmacokinetics of verapamil after single oral and intravenous doses. The second explored the pharmacodynamics and pharmacokinetics of verapamil and propranolol alone and in combination after single and repeated oral doses. 3. The magnitude of the prolongation of PR interval induced by oral and intravenous verapamil was not affected by pre-treatment with propranolol. When verapamil and propranolol were co-administered as single doses, effects on PR interval were additive but, following repeated doses, a trend towards greater than additive prolongation was seen. The arithmetic sum of the effects of the two drugs was 23% (95% C.I. 8-38%) but the measured increase after the combination was 40% (95% C.I. 26-54%). 4. The extent of reduction in heart rate and blood pressure at rest and after exercise following repeated doses of propranolol was not influenced by single oral or intravenous doses of verapamil. The heart rate and blood pressure responses to single and repeated oral doses of verapamil and propranolol in combination were significantly greater than those after either drug alone and approximated to the arithmetic sum of the individual responses. 5. Although repeated administration of propranolol reduced hepatic blood flow as assessed by indocyanine green clearance, there was no evidence of an interaction between the drugs at this level. 6. The pharmacokinetics of verapamil and norverapamil were not significantly affected by prior propranolol. After single doses of verapamil and propranolol in combination, the maximum plasma concentration of propranolol was increased and the oral clearance of verapamil reduced. No pharmacokinetic interaction was observed after repeated doses. 7. These findings provide little evidence of a pharmacodynamic or pharmacokinetic interaction between verapamil and propranolol in normal subjects. Most of the haemodynamic responses to these drugs in combination can be explained by additive drug effects but an interaction affecting AV conduction after repeated doses cannot be excluded. The minor pharmacokinetic interaction between the drugs is unlikely to be relevant to the pharmacodynamic changes.     

Effects of cyclosporin on the pharmacokinetics of propranolol after intravenous and oral administration to control rats and to rats with uranyl nitrate-induced acute renal failure

The effects of cyclosporin on the pharmacokinetics of propranolol have been investigated after intravenous and oral administration of the drugs to control rats and to rats with uranyl nitrate-induced acute renal failure. The effects of intravenous cyclosporin, 30 mg kg(-1), on the pharmacokinetics of intravenous propranolol, 3 mg kg(-1), were significant both in control rats and in rats with uranyl nitrate-induced acute renal failure; after intravenous administration of cyclosporin plasma concentrations of propranolol were significantly lower, the area under the plasma concentration-time curve (AUC) for propranolol from time zero to time infinity was significantly smaller, and the time-averaged total body clearance of propranolol was significantly faster. The effects of oral cyclosporin, 100 mg kg(-1), on the pharmacokinetics of oral propranolol, 10 mg kg(-1), were also significant, both in control rats and in rats with uranyl nitrate-induced acute renal failure; after administration of oral cyclosporin plasma concentrations of propranolol were significantly higher and the AUC of propranolol was significantly greater. These data suggest that cyclosporin increases the elimination of propranolol, and that the first-pass effects of propranolol are reduced, or gastrointestinal absorption of propranolol is increased, or both, by cyclosporin.     

Dissociation between duration of plasma catecholamine and blood pressure responses to beta-adrenergic blockade in normotensive subjects during physical exercise

Summary The influence of acute and chronic treatment with the adrenergic beta-receptor blocking agent propranolol (P) on blood pressure (BP), heart rate (HR) and plasma catecholamine concentration (CA) was studied in 7 normotensive healthy volunteers, and in 5 normotensive patients with cardiac neurosis, at rest, during physical exercise and after sudden withdrawal of the drug. The first oral dose of P 120 mg as well as chronic treatment (3×80 mg/day for 3 months) caused a significant reduction in HR and supine BP. Resting values of CA were not changed. After sudden withdrawal of the long-term therapy with P, supine BP and HR returned to normal, and again, resting levels of CA remained unchanged. A physical exercise test, performed 2 1/2 days after withdrawal of the betablocker, was not indicative of a transient sympathetic hyper-response. Striking effects of the drug on CA were observed during acute and chronic treatment with P when physical exercise was performed (bicycle ergometer, 150 W). Exercise values of CA were about twice as high during P treatment as without the drug, when the exercise test was performed 2 h after the first oral dose. At the same time, however, exercise BP and HR were significantly reduced. Similar reactions during the exercise test were also seen during chronic treatment with P, when the test was performed 2 hours after the last dose of the drug. But, when the exercise test was undertaken during chronic treatment 8 h after drug intake, the drug effect on CA had disappeared, whereas the effects on BP and HR still were present. The dissociation during chronic treatment between the effect on the duration of plasma CA and that of the pharmacodynamic responses to beta-adrenergic blockade with P is the principal finding of the study. A hypothesis is offered for interpretation of the observations. The time interval between measurement of drug effect and drug intake must be carefully observed in assessing different or controversial drug responses.     

Effect of inflammation on the metabolism of antipyrine, lidocaine and propranolol in isolated rat hepatocytes

A decrease of the hepatic intrinsic clearance could contribute to the increase of the plasma concentrations of alpha 1-acid glycoprotein-bound drugs such as propranolol in animals and humans with inflammation. Therefore, the influence of inflammation upon the metabolism of propranolol and another high clearance drug, lidocaine, and of the low clearance drug antipyrine, was studied in isolated rat hepatocytes. For comparative purposes, the influence of the enzyme inhibitor SKF 525A (100 mg/kg i.p.) was also evaluated. Turpentine pretreatment of the rats significantly decreased the metabolism of the three drugs by the hepatocytes; the decrease was least pronounced for propranolol. The inhibitory effect of turpentine-induced inflammation was somewhat lower than that of SKF 525A. These results are in agreement with the results found for the same drugs in the 9,000-g supernatant fraction of the rat liver and point to a marked decrease of intrinsic clearance in some types of inflammation.     

Disposition of exaprolol, a new beta-blocker, in rats

Pharmacokinetics of tritium-labeled exaprolol, 1-(2-cyclohexyl[2,4-3H]-3-isopropylamino-2-propanol, a potent beta-adrenergic blocker, was studied in rats. The assay of the parent drug in plasma and excreta was based on extraction into toluene and TLC. In rats elimination half-lives of exaprolol after iv and oral administration of 26.8 and 40.1 hr, respectively, were found; the bioavailability was 26.7%. After oral administration to rats, the drug was rapidly and completely absorbed. The long retention of exaprolol in tissues of iv injected rats was reflected by the steady-state distribution volume of 59.38 liters/kg and the clearance rate of 1.44 liters/hr/kg. The total 3H excreted in urine within 96 hr after iv or oral administration to rats amounted to 47.9 and 47.1% of dose, respectively, and in feces to 34.2 and 29.8%, respectively. The ratio of 3H-exaprolol to total 3H concentration in plasma, urine, and feces of rats indicated a moderately extensive metabolism of the parent drug. The substance was about 50% bound to human serum albumin. The rat erythrocyte/plasma partition coefficient rose with exaprolol concentration.     

Effects of long-acting propranolol on blood pressure and heart rate in hypertensive Chinese.

In a double-blind, balanced and randomised study we used treadmill exercise to assess the effects of long-acting propranolol (LA propranolol) 160 or 320 mg or placebo, given once daily for 4 weeks, on heart rate (HR) and blood pressure (BP) in 15 Chinese subjects with mild primary hypertension (PHT). We used 24 h ECG monitoring to assess drug effects on HR. Another 18 patients were similarly assessed without exercise. Steady-state plasma propranolol concentrations after LA propranolol 160 and 320 mg were comparable to those after ordinary propranolol 80 and 160 mg daily measured in 11 and 12 separate patients. LA propranolol 160 and 320 mg reduced HR and BP before and during vigorous exercise. LA propranolol 160 and 320 mg reduced HR for 17.6 and 21.4 h of the day, and 320 mg significantly reduced the mean 24 h HR, and the mean maximum HR. The drug effects on BP and HR, and the average plasma propranolol levels after LA propranolol were similar to those reported in European subjects.     

Effects of chlorpromazine on the disposition and beta-adrenergic blocking activity of propranolol in the dog

The effects of chlorpromazine (100mg p.o., 2hr before propranolol) on the disposition and beta-adrenergic blocking actions of both intravenous (6 mg) and oral (40 mg) propranolol were studied in the dog. Chlorpromazine pretreatment significantly reduced (69%) the oral clearance of propranolol, resulting in significant increases in propranolol bioavailability (159%), and in the total beta-adrenergic blocking activity (111%) after the oral dose. The increase in the total beta-adrenergic blocking activity of oral propranolol after chlorpromazine pretreatment was mostly due to an increased contribution from the parent compound; the apparent activity from active propranolol metabolites was not affected by chlorpromazine. Chlorpromazine pretreatment had no significant influence on the systemic clearance, elimination half-life, apparent volume of distribution, and plasma binding of propranolol, or on the apparent hepatic blood flow. After intravenous propranolol, chlorpromazine pretreatment had no effect on either the total amount of beta-adrenergic blocking activity or the amount of activity attributable to active metabolites. The decreased oral propranolol clearance by chlorpromazine was seen as a shift to the left in the propranolol dose vs. AUCrelationship, eliminating the apparent nonlinear kinetic behavior of oral propranolol, and reducing the apparent oral threshold dose. Chlorpromazine's major, if not only, effect on propranolol disposition was to reduce the presystemic elimination of propranolol, possibly through inhibition of its metabolism via a pathway other than ring oxidation.This work was supported by a US Public Health Grant No. HL-22718.     

The effects of oral nitrendipine and propranolol, alone and in combination, on hypertensive patients with special reference to AV conduction.

The effects of oral nitrendipine and oral propranolol, alone and in combination, on AV conduction have been examined in 11 patients with essential hypertension in whom arterial pressure was not adequately controlled despite treatment with thiazide diuretics. The study was performed double-blind. After a drug free period of 1 week, the patients received two 7 day courses of drug therapy after initial control measurements. Five of the eleven patients were randomised to receive nitrendipine 20 mg daily, the other six patients received propranolol (Inderal LA 160 mg daily) for the first week of therapy. During week 2, 10 patients received combined therapy. In the 10 patients who completed the study, oral nitrendipine, given either alone or in combination with oral propranolol, had no significant effect on resting PR, QRS, QT intervals nor on AV conduction as assessed by ambulatory electrocardiography. Propranolol did not affect the resting PR interval but significantly increased PR intervals on the ambulatory ECG recordings during single and combined therapy. However the maximum PR intervals remained within normal limits.     

Erythromycin potentiates PR interval prolonging effect of verapamil in the rat: a pharmacodynamic drug interaction

Calcium channel blockers and macrolide antibiotics account for many drug interactions. Anecdotal reports suggest interactions between the two resulting in severe side effects. We studied the interaction between verapamil and erythromycin in the rat to see whether it occurs at the pharmacokinetics or pharmacodynamic level. Adult male Sprague-Dawley rats received doses of 1 mg/kg verapamil or 100 mg/kg erythromycin alone or in combination (n = 6/group). Serial blood samples (0-6 h) were taken for determination of the drug concentrations using HPLC. Electrocardiograms were recorded (0-6 h) through subcutaneously inserted lead II. Binding of the drugs to plasma proteins was studied using spiked plasma. Verapamil prolonged PR but not QT interval. Erythromycin prolonged QT but not PR interval. The combination resulted in a significant increase in PR interval prolongation and AV node blocks but did not further prolong QT interval. Pharmacokinetics and protein binding of neither drug were altered by the other. Our rat data confirm the anecdotal human case reports that combination of erythromycin and verapamil can result in potentiation of the cardiovascular response. The interaction appears to be at the pharmacodynamic rather than pharmacokinetic level hence may be extrapolated to other calcium channel antagonists.     

Effect of inflammation on kidney function and pharmacokinetics of COX-2 selective nonsteroidal anti-inflammatory drugs rofecoxib and meloxicam

Chronic arthritis adversely affects glomerular function and nonsteroidal anti-inflammatory drugs (NSAIDs) reduce electrolyte urinary excretion. In addition, both acute and chronic inflammations may alter clearance of drugs. We studied (a) the effects of inflammation on the renal function and pharmacokinetics of rofecoxib and meloxicam; (b) whether inflammation could exacerbate reduced electrolytes excretion changes observed with NSAIDs; and (c) the influence of inflammation on distribution of these drugs into the kidney. Single oral doses of rofecoxib (10 mg kg(-1)), meloxicam (3 mg kg(-1)) or placebo were administered to normal or pre-adjuvant arthritic rats. Blood and urine samples were collected for the measurement of plasma nitrite, BUN and creatinine. The urinary excretion of sodium and potassium was also determined. Nitrite, BUN and plasma creatinine were increased starting on day 9 in the groups with inflammation. Sodium and potassium excretion rates were not affected by inflammation. Meloxicam did not alter the electrolyte excretion in any of the groups. Rofecoxib significantly decreased sodium and potassium excretion in normal rats and potassium excretion in inflamed rats. Inflammation significantly increased plasma concentrations of rofecoxib, but not meloxicam. The ratios of the kidney:plasma concentrations were not significantly altered by inflammation following either drug. Inflammation altered kidney function, demonstrated by increases in BUN and plasma creatinine. However, it did not influence the urinary electrolytes excretion. Since we have observed similar patterns of the effect of NSAIDs on kidney under healthy and inflammatory conditions, one may conclude that inflammation does not exacerbate the adverse effect.     

Effects of angiotensin II blockade on inflammation-induced alterations of pharmacokinetics and pharmacodynamics of calcium channel blockers

BACKGROUND AND PURPOSE: Inflammation elevates plasma verapamil concentrations but diminishes pharmacological response. Angiotensin II is a pro-inflammatory mediator. We examined the effect of angiotensin II receptor blockade on the pharmacokinetics and pharmacodynamics of verapamil, as well as the binding properties and amounts of its target protein in calcium channels, in a rat model of inflammation. EXPERIMENTAL APPROACH: We used 4 groups of male Sprague-Dawley rats (220-280 g): inflamed-placebo, inflamed-treated, control-placebo and control-treated. Inflammation as pre-adjuvant arthritis was induced by injecting Mycobacterium butyricum on day 0. From day 6 to 12, 30 mg kg(-1) oral valsartan or placebo was administered twice daily. On day 12, a single oral dose of 25 mg kg(-1) verapamil was administered and prolongation of the PR interval measured and plasma samples collected for verapamil and nor-verapamil analysis. The amounts of the target protein Ca(v)1.2 subunit of L-type calcium channels in heart was measured by Western blotting and ligand binding with (3)H-nitrendipine. KEY RESULTS: Inflammation reduced effects of verapamil, although plasma drug concentrations were increased. This was associated with a reduction in ligand binding capacity and amount of the calcium channel target protein in heart extracts. Valsartan significantly reversed the down-regulating effect of inflammation on verapamil's effects on the PR interval, and the lower level of protein binding and the decreased target protein. CONCLUSIONS AND IMPLICATIONS: Reduced responses to calcium channel blockers in inflammatory conditions appeared to be due to a reduced amount of target protein that was reversed by the angiotensin II antagonist, valsartan.     

Cardiovascular and electrocardiographic effects of the dopamine receptor agonists ropinirole, apomorphine, and PNU-142774E in conscious beagle dogs

To confirm recent in vitro findings, we examined the cardiovascular and electrocardiographic (ECG) effects of the dopamine receptor agonists ropinirole, apomorphine, and PNU-142774E in conscious dogs. Intravenous (i.v.) infusions of ropinirole totaling 20 microg/kg maximally reduced mean arterial pressure (MAP; -16 mm Hg) and the ECG PR interval (-13 milliseconds) and increased heart rate (HR; +29 b/min) and QTc length (+33 ms) at a peak plasma drug concentration (p[drug]) of 3.5 ng/ml. I.V. PNU-142774E was better tolerated through 66 microg/kg and a maximal p[drug] of 5.9 ng/ml with negligible cardiovascular changes and mild QTc reduction (13 ms). Apomorphine (25 microg/kg i.v.) was intermediate to ropinirole and PNU-142774E for emesis and peak changes in MAP (-6 mm Hg), HR (+24 b/min), and QTc (+15 milliseconds) at a mean p[drug] of 3.4 ng/ml. By comparison, the class III antiarrhythmic trecetilide (2.0 mg/kg bolus) increased QTc (+58 ms) without affecting mean arterial pressure or heart rate. This study establishes that in conscious dogs, the selective dopamine receptor agonist PNU-142774E has fewer cardiovascular and emetic effects than ropinirole and apomorphine and supports prior in vitro findings that ropinirole and apomorphine but not the PNU-142774E imidazoquinolin analog sumanirole reduces the delayed rectifier current in HERG transfected cells.     

Stereoselective differences in propranolol disposition in female Sprague-Dawley and Dark Agouti rats.

Although genetic constitution is recognized as an important factor in drug elimination, there is still only a modest amount of information about its impact on stereoselective drug disposition. To examine how strain differences in cytochrome P-450 expression may affect stereoselective drug elimination, the disposition of R- and S-propranolol was examined in female Sprague-Dawley (SD) and Dark Agouti (DA) rats. The half-life of R-propranolol was increased and its apparent oral clearance decreased significantly in DA rats relative to the SD strain [85 +/- 41 min (DA) vs. 26 +/- 10 min (SD) and 0.020 +/- 0.014 liter/min/kg (DA) vs. 0.31 +/- 0.14 liter/min/kg (SD)], respectively. Strain differences in S-propranolol half-life and apparent oral clearance also were observed, but were not as marked [97 +/- 36 min (DA) vs. 52 +/- 35 min (SD) and 0.20 +/- 0.13 liter/min/kg (DA) vs. 0.70 +/- 0.68 liter/min/kg (SD)], respectively. Due to a more pronounced effect of rat strain on the disposition of R-propranolol, the stereoselective S-/R- oral clearance ratio for propranolol was also strain-dependent [10 +/- 3 (DA) vs. 2.1 +/- 0.9 (SD)]. These differences could not be accounted for by propranolol stereoselective plasma protein binding or by a difference in the blood/plasma ratio for R- or S-propranolol in these separate strains. This represents one of the few examples where an increase in stereoselective drug disposition has been observed due to strain differences that diminish drug elimination.     

Comparability of the electrophysiologic responses and plasma and myocardial tissue concentrations of sotalol and its d stereoisomer in the dog.

The relative plasma, myocardial, and skeletal muscle concentrations as well as activities of racemic and d-sotalol were assessed in both anesthetized and conscious dogs. In acute anesthetized experiments, the agents were infused i.v. over a 15-min interval at doses of 1 and 4 mg/kg. Arterial blood samples and punch biopsy specimens from the left ventricular myocardium and skeletal muscle (gastrocnemius) were taken at the completion of each infusion and at periodic intervals for the ensuing 3 h. The drugs were also administered over a 2-week dosing interval to conscious dogs at a dose of 5 mg/kg given twice daily. ECG alterations and venous blood samples were withdrawn on the 1st, 3rd, 7th and 14th day of drug administration. Myocardial and skeletal muscle samples were taken at killing on day 14. In anesthetized dogs, both forms of sotalol decreased heart rate, lowered arterial pressure, prolonged ventricular refractoriness, and caused measurable increases in the PR, QT, and QTc intervals in the absence of any effect on QRS duration. Similar effects on heart rate and QTc and lack of influence on the PR and QRS interval were observed in conscious animals. Tissue drug concentrations were closely correlated with plasma drug levels. Comparable mean steady-state tissue/plasma ratios of 2.26-2.94 were attained immediately following acute i.v. drug infusions. These were larger than those observed following chronic oral drug administration for 14 days. The data, however, clearly demonstrated the equivalence of the plasma and myocardial drug levels obtained in dogs following i.v. infusion of 1 mg/kg or oral administration of 5 mg/kg of dl- or d-sotalol.(ABSTRACT TRUNCATED AT 250 WORDS)