Radioiodinated acebutolol as a new highly selective radiotracer for myocardial perfusion imaging.

Acebutolol was successfully labeled with (125) I via direct electrophilic substitution reaction. Radioiodinated acebutolol was prepared with a maximum radiochemical yield of 96.5 ± 0.3% and in vitro stability up to 72 h. The in vivo biological distribution of radioiodinated acebutolol showed high heart uptake of 37.8 ± 0.14% injected activity/g organ with low lungs and liver uptakes at 5 min post-injection. In vivo receptor blocking study was carried out in mice to evaluate its selectivity to heart. Radioiodinated acebutolol showed fast heart accumulation with high heart/liver ratio, which provides the ability for fast myocardial imaging with significant decrease in the radiation hazards risk on patients. So, radioiodinated acebutolol could be displayed as a radiotracer drug of choice in case of emergency patients for myocardial perfusion imaging.

Acebutolol and alprenolol metabolism predictions: comparative study of electrochemical and cytochrome P450-catalyzed reactions using liquid chromatography coupled to high-resolution mass spectrometry.

A comparative study of the electrochemical conversion and the biotransformation performed by the cytochrome P450 (CYP450) obtained by rat liver microsomes has been achieved to elucidate the oxidation mechanism of both acebutolol and alprenolol. For this purpose, a wide range of reactions such as N-dealkylation, O-dealkoxylation, aromatic hydroxylation, benzyl hydroxylation, alkyl hydroxylation, and aromatic hydroxylation have been examined in this study, and their mechanisms have been compared. Most of the results of the electrochemical oxidation have been found to be in accordance with those obtained by incubating acebutolol and alprenolol in the presence of CYP450, i.e., N-dealkylation, benzyl hydroxylation, and O-dealkoxylation reactions catalyzed by liver microsomes were found to be predicted by the electrochemical oxidation. The difficulty for the electrochemical process to mimic both aromatic and alkyl hydroxylation reactions has also been discussed, and the hypothesis for the absence of aromatic hydroxylated and alkyl hydroxylated products, respectively, for alprenolol and acebutolol, under the anodic oxidation has been supported by theoretical calculation. The present study highlights the potential and limitation of coupling of electrochemistry-liquid chromatography-high-resolution mass spectrometry for the study of phase I and phase II reactions of acebutolol and alprenolol.

Evaluation of chromatographic descriptors for the prediction of gastro-intestinal absorption of drugs.

The use of chromatographic descriptors in QSAR was evaluated. Therefore, retentions were measured on an immobilized artificial membrane system, 2 micellar liquid chromatography systems and 17 orthogonal or disimilar reversed-phase liquid chromatographic systems. It was investigated whether it was possible to model gastro-intestinal absorption as a function of chromatographic retentions applying two linear and one non-linear multivariate modeling technique. In a second step it was evaluated if models built with theoretical descriptors could be improved by adding the measured retention factors to the data set of descriptive variables. It was seen that gastro-intestinal absorption could be modelled in function of chromatographic retention using the non-linear modeling technique multivariate adaptive regression splines (MARS). The best models were obtained using a combination of theoretical and chromatographic descriptors with MARS as modeling technique.

Effect of aging on the pharmacokinetics of acebutolol enantiomers.

Acebutolol (AC) is a chiral beta-blocker that is metabolized to an equipotent chiral metabolite, diacetolol (DC). A stereoselective disposition of AC and DC enantiomers has recently been reported in young healthy subjects. As many physiologic properties affecting drug disposition are progressively altered with increasing age, the effect of aging on the pharmacokinetics of AC and DC enantiomers were investigated in nine subjects ranging from 60 to 75 years after administration of an oral 200-mg dose of racemic AC. Increasing age resulted in a significant prolongation of the elimination t1/2s of R- (r = 0.913) and S-DC (r = 0.811). Also, the S:R ratios of AC urinary excretion (sigma Xu) of enantiomers was significantly correlated with age (r = 0.677). Contribution of declining renal function to age-associated pharmacokinetics changes was subsequently examined. Renal clearance and cumulative urinary excretion of both AC and DC enantiomers were positively correlated with creatinine clearance. In addition, declining creatinine clearance was associated with a subsequent decline in the enantiomer S:R ratio of AC in plasma (AUC S:R, r = 0.807) and urine (sigma Xu S:R r = 0.807). Similarly, a progressive decline in the S:R ratio of DC collected in urine was evident (r = 0.689). Age-related changes in the enantiomers ratios may suggest that an active stereoselective pathway such as renal tubular secretion or nonrenal excretion may be affected in the elderly.

A comparative pharmacokinetic and pharmacodynamic study of conventional and sustained-release preparations of acebutolol in healthy volunteers.

Pharmacokinetics and the degree of beta-blockade of sustained release (SR) acebutolol (500 mg/day) and conventional acebutolol (200 mg tid) were examined after the first oral dose and after 10 days of treatment in ten healthy volunteers. After the first dose, acebutolol Cmax did not significantly differ between the two formulations; however, on day 10 acebutolol Cmax was significantly higher after SR formulation. Cmax of diacetolol, the major metabolite, did not differ between SR and conventional acebutolol neither on day 1 nor on day 10. The dose-corrected relative bio-availability of acebutolol was not different from 100% on day 1 and day 10; however the dose-corrected diacetolol AUC, SR/conventional ratio, was significantly lower than 100% on days 1 and 10. Both acebutolol preparations exerted a significant reduction in exercise tachycardia over 24 h on day 1 and day 10; however, conventional acebutolol exhibited a greater reduction 24 h after the first dose. Exercise-induced increase in systolic blood pressure was similarly inhibited by both treatments except for 24 h after the first dose when systolic blood pressure was significantly higher with SR than with conventional acebutolol. The percent reduction in heart rate during exercise was linearly correlated with log acebutolol plasma concentrations for each treatment regimen. These results suggest that beta-blockade exerted by SR acebutolol in healthy volunteers is equivalent to that of conventional acebutolol.

Pharmacokinetics of acebutolol enantiomers in humans.

The chiral beta-blocker acebutolol (AC) is marketed as a racemic mixture. Both AC and its major metabolite, diacetotol (DC), are chiral, the S-enantiomer possessing beta-blocking activity. The pharmacokinetics of AC and DC enantiomers was determined in 12 healthy subjects following oral administration of 200 mg of AC. Plasma and urine were collected over a 24-hr period and both AC and DC enantiomers were measured utilizing a stereospecific HPLC assay. Concentrations of S-AC were predominant in both plasma and urine [AUC S:R, 1.20 +/- 0.1; cumulative urinary excretion (sigma Xu) S:R, 1.17 +/- 0.05), which corresponded to a significantly greater oral clearance of R-AC (106 +/- 30 L/h) than S-AC (87 +/- 22 L/h). The Cmax of R-DC was significantly greater than for S-DC (S/R 0.7 +/- 0.1). The half-life (t1/2) of R-DC (6.4 +/- 1.6 h) was significantly shorter than that of S-DC (8.8 +/- 2.4 h). The observed AUC values for R- and S-DC were not significantly different. Renal clearance of R-DC (70 +/- 34 mL/min) was significantly greater than that of S-DC (53 +/- 29 mL/min). The data suggest that the first-pass metabolism of R-AC to R-DC is stereoselective. This metabolism, coupled with the stereoselective renal excretion of R-DC is likely a major contributor to the observed stereoselective disposition of AC and its major metabolite in humans.

Quantitative structure-pharmacokinetic relationships (QSPR) of beta blockers derived using neural networks.

This study demonstrates the application of neural networks to predict the pharmacokinetic properties of beta-adrenoreceptor antagonists in humans. A congeneric series of 10 beta-blockers, whose critical pharmacokinetic parameters are well established, was selected for the study. An appropriate neural network system was constructed and tested for its ability to predict the pharmacokinetic parameters from the octanol/water partition coefficient (shake flask method), the pKa, or the fraction bound to plasma proteins. Neural networks successfully trained and the predicted pharmacokinetic values agreed well with the experimental values (average difference = 8%). The neural network-predicted values showed better agreement with the experimental values than those predicted by multiple regression techniques (average difference = 47%). Because the neural networks had a large number of connections, two tests were conducted to determine if the networks were memorizing rather than generalizing. The "leave-one-out" method verified the generalization of the networks by demonstrating that any of the compounds could be deleted from the training set and its value correctly predicted by the new network (average error = 19%). The second test involved the prediction of pharmacokinetic properties of compounds never seen by the network, and reasonable results were obtained for three out of four compounds tested. The results indicate neural networks can be a powerful tool in exploration of quantitative structure-pharmacokinetic relationships.

Influence of cimetidine co-administration on the pharmacokinetics of acebutolol enantiomers and its metabolite diacetolol in a rat model: the effect of gastric pH on double-peak phenomena.

Acebutolol (AC) is a chiral beta-adrenergic receptor-blocking agent, which has been shown to be clinically effective in hypertension. The plasma concentration-time profiles of AC exhibit two peaks following oral administration of racemate for both R- and S-enantiomers. In the present study, the absorption of AC after a single dose was studied as a function of gastric pH in male Sprague-Dawley rats. Furthermore, the effect of cimetidine (CIM) on pharmacokinetic parameters of AC and its metabolite diacetolol (DC) was evaluated. CIM (50 mg kg(-1)) was administered via jugular vein 30 min prior to AC administration to elevate the intragastric pH. AC (50 mg kg(-1)) was administered orally by gavage and serial blood samples were collected before and for 8h after AC administration. Plasma samples were assayed for AC and DC, pharmacokinetic parameters were estimated and compared with those of control. The concentration-time profiles and the pharmacokinetics of AC were unchanged after co-administration of CIM. The oral absorption of AC, as assessed by the area under the plasma concentration-time curve (AUC) and the amount of unchanged drug recovered in the urine were not affected by CIM. The amount of metabolite recovered in the urine and the rate of absorption, however, were significantly altered. These are unlikely to be of clinically importance as we have found that the extent of absorption was not changed. We, therefore, concluded that intragastric elevation of pH has no effect either on generation of multiple peaking or on pharmacokinetic parameters of AC.

Effects of turpentine oil pretreatment on beta-blocker pharmacokinetic parameters in rats.

Turpentine oil treatment (0.2 mL kg-1, s.c.) was used to increase the plasma concentration of alpha 1-acid glycoprotein (0.13 mg mL-1 in control rats) to 1.72 mg mL-1 after 2 days, and allow assessment of its effects on the pharmacokinetics and stereoselective binding of three beta-blockers. Racemates (5 mg kg-1) were administered intravenously to control and turpentine oil-pretreated rats and the plasma concentrations were determined up to 90 min. Stereoselective analysis showed the apparent distribution volume and the area under plasma concentration-time curves (AUC) of R-(+)-propranolol to be, respectively, one-quarter and twice those of the S-(-)-enantiomer and differences in pharmacokinetic parameters between the two were magnified by turpentine oil pretreatment. Pharmacokinetic parameters of oxprenolol enantiomers were essentially similar for the controls but after turpentine oil pretreatment, a higher affinity of the R-(+)-enantiomer for plasma was observed. Acebutolol enantiomers behaved non-stereospecifically throughout. These results were consistent with predictions from the in-vitro stereospecific binding properties of these agents to purified rat alpha 1-acid glycoprotein.

Pharmacokinetic changes of acebutolol after oral administration in rabbits with diabetes mellitus induced by alloxan.

Because physiological changes that potentially alter pharmacokinetics occurs in diabetes mellitus patients, pharamacokinetics of drugs used in the treatment of hypertension was studied using acebutolol as a model anti-hypertensive drug. Thus, the pharmacokinetics of acebutolol was investigated after oral administration of acebutolol (15 mg/kg) to control rabbits and rabbits with acute or chronic diabetes mellitus induced by alloxan. Kidney and liver functions were documented for acute and chronic diabetes mellitus groups based on plasma chemistry data. After oral administration of acebutolol to acute and chronic groups, the plasma concentrations appeared higher; As a result, area under the plasma concentration-time curve from time zero to time infinity10575 and 8668 microg x h/mL for acute and chronic group, respectively. In comparison, the area was apparently smaller in the control group (i.e., 7132 microg x h/mL). The half-life in acute groups was significantly prolonged 8.45 h compared with the half-life in the control group (i.e., 6.30 h). Alteration in acebutolol pharmacokinetics was more pronounced in the acute group as evidenced by the significantly higher values the area under the plasma concentration time curve, absorption rate constant and maximum plasma concentration compared with chronic or control group. Therefore, these observations indicate that acebutolol pharmacokinetics may be affected in patients with diabetes mellitus, especially in the early stage of the disease.

Pharmacokinetics of acebutolol and its main metabolite, diacetolol after oral administration of acebutolol in rabbits with carbon tetrachloride-induced hepatic failure.

Pharmacokinetic characteristics of acebutolol and its main metabolite, diacetolol, following a single 10 mg/kg oral dose, were investigated in rabbits with carbon tetrachloride-induced hepatic failure. Plasma concentrations of acebutolol and diacetolol were determined by a high performance liquid chromatography assay. The area under the plasma concentration-time curves (AUC) and maximum plasma concentration (Cmax) of acebutolol were significantly increased in moderate and severe carbon tetrachloride-induced hepatic failure rabbits. The ratio of the diacetolol to total acebutolol in plasma (i.e., metabolite percentage rate) was significantly decreased in moderate and severe carbon tetrachloride-induced hepatic failure rabbits. Volume of distribution (Vd) and total body clearance (CL1) of acebutolol were significantly decreased in moderate and severe carbon tetrachloride-induced hepatic failure rabbits. Slope of terminal phase (beta) of acebutolol was significantly decreased in hepatic failure rabbits. These findings suggest that the Vd, CL1 and beta of acebutolol were significantly decreased as a result of inhibition of the hepatic metabolism in moderate to severe hepatic failure rabbits. Therefore, dose adjustment may be necessary for acebutolol in hypertensive patients with hepatic damage.

Stereospecific high-performance liquid chromatographic assay of acebutolol in human plasma and urine.

A sensitive high-performance liquid chromatographic technique is described for the separation of R- and S-acebutolol in human plasma and urine. The procedure involves derivatization with the chiral reagent S-(+)-1-(1-naphthyl)ethyl isocyanate. The resulting diastereoisomers are quantified using normal-phase high-performance liquid chromatography with fluorescence detection (220/389 nm). Virtual baseline separation, free from interference, with achieved (resolution factor = 1.45). Excellent linearity (r greater than 0.998) was observed throughout the range 10-500 ng/l and 2-100 mg/l in plasma and urine, respectively. Inter-assay variability was less than 5% for each enantiomer at concentrations of 10 ng/ml. This method is applicable for the determination of the pharmacokinetics, in man, of acebutolol enantiomers in plasma and urine.

Foetoplacental drug clearance in the rabbit: studies with trimazosin, acebutolol and tolmesoxide.

1. An animal model suitable for studying placental extraction of large numbers of drugs without the need for major surgical facilities, has been developed in the anaesthetized New Zealand white rabbit with sampling of both arterial and venous blood of the foetoplacental unit. 2. Three drugs with different routes of metabolism were studied: trimazosin, tolmesoxide and acebutolol. There was no extraction across the foetoplacental unit. 3. The clearance of acebutolol differed significantly in rabbits from different suppliers. 4. These results do not suggest a role for the placenta in drug metabolism. They do, however, suggest a previously undescribed genetic determinant of acebutolol metabolism.

Kinetics of a single dose combination of nifedipine/acebutolol in patients with chronic liver disease.

The plasma kinetics of a nifedipine/acebutolol fixed dose combination were estimated after a single oral dose in patients with chronic liver disease and in a healthy control group of the same age. The drug metabolism evidently slowed down in the group with chronic liver disease. The plasma elimination half-lives of acebutolol, diacetolol and nifedipine of these patients were about twice as long as that in the control group. Doses of these drugs should be accordingly reduced, particularly in cirrhosis.

Pharmacokinetics of acebutolol enantiomers after intravenous administration of racemate in a rat model: a dosing range comparison.

Acebutolol (AC) is a chiral beta-adrenergic blocking drug, possessing intrinsic sympathomimetic activity (ISA), and is useful clinically as the racemate in treating hypertension. Utilizing a stereospecific high-performance liquid chromatographic (HPLC) assay, the enantiomeric disposition of AC and its major metabolite diacetolol (DC) are reported after intravenous administration of single 5, 15, 30, and 50 mg kg-1 doses of racemate to male Sprague-Dawley rats. The mean area under the plasma concentration versus time curve (AUC) values display a linear relationship with respect to the administered dose. No statistical differences are observed in apparent volume of distribution (Vd), terminal elimination half-life (t1/2), total body clearance (Clt), or renal clearance (Clr) with respect to dose administered. Generally, R-S ratios for AUC following AC administration are statistically different from unity (p < 0.05). However, for the 50 mg kg-1 doses the R-S ratio for AUC is not statistically different from one. For DC, the plasma disposition is nonstereoselective in plasma. The amount of R-DC recovered in urine, however, was greater than that of the antipode (R:S = 1.92 +/- 0.29). This study suggests that the enantiomeric disposition of intravenous AC is linear within the investigated range of 5-50 mg kg-1 racemate in rats.

Pharmacokinetics of single oral and multiple intravenous and oral administration of acebutolol enantiomers in a rat model.

Acebutolol (AC), is a chiral, beta-adrenergic blocking agent which possesses partial agonist activity and is metabolized to an equipotent chiral metabolite, diacetolol (DC). The enantiomeric disposition of AC is reported following racemic administration as a single oral (p.o., 50 mg kg(-1)) or as a multiple thrice daily intravenous (i.v.) or p.o. dosing for four days in male Sprague-Dawley rats (n = 6). Enantiomeric concentrations of AC and DC in plasma and urine were determined using a stereospecific HPLC assay. The bioavailabilities of R- and S-enantiomer were 0.40 and 0.39 after single dose administration of AC respectively. These values were increased to 0.51 and 0.53 after multiple dosing. Although no significant differences were found in AUC0-infinity after single i.v. as compared with AUC0-tau after multiple i.v. dosing of AC, the 39 and 45% increase in mean AUC0-tau were found after multiple p.o. dosing over the corresponding AUC0-infinity, for the single p.o. dose of AC for R- and S-enantiomer, respectively. The disposition of DC as well as the urinary excretion of metabolite was stereoselective in favor of R-enantiomer after oral administration of AC. These results indicate that AC enantiomers have low availability and moderate extraction through the first-pass metabolism in a rat model. The higher AUC values after p.o. multiple dosing may suggest a saturable first-pass metabolism of AC.

Effect of adjuvant arthritis on the disposition of acebutolol enantiomers in rats.

Disease states such as arthritis may interact with the kinetics of beta-blockers. Acebutolol (AC) is a chiral beta-blocker which is available as a racemate. The beneficial properties of AC, however, is attributed mainly to the S-(+)-enantiomer. The disposition of AC enantiomers and their active, chiral metabolites, diacetolol (DC) were examined after oral administration to healthy and adjuvant-induced arthritic (AA) female Sprague-Dawley rats. Arthritis was induced by tail base injection of Mycobacterium butyricum. Swelling of hind and forepaws were apparent in 10-16 days in AA but not controls. Control and AA rats were sacrificed at 0.5, 1, 2, 4, 6 and 8 h after a 25 mg/kg oral AC dose and blood was collected (n = 6). Significant three to tenfold increases in the initial plasma concentrations (0.5-2 h) of AC were observed in AA. Enantiomers were equally affected, thus AC S:R ratio was not changed. Higher plasma concentrations of the metabolite were only significant at 2 h. The ratio of DC:AC, however, was unaffected by AA. The DC S:R ratio was significantly decreased at 0.5 and 1 h in AA. The limited protein binding of AC (10%) was neither stereoselective nor affected by AA. Reduced intrinsic clearance in AA may be responsible for these observations.

Pharmacokinetics and multiple peaking of acebutolol enantiomers in rats.

Acebutolol (AC) is a chiral beta-blocker which is extensively metabolized to an active, chiral metabolite, diacetolol (DC). Similar to some other beta-adrenoceptors, AC exhibits multiple peaks in plasma concentration-time curves after oral doses to humans. We examined the suitability of the rat as an animal model and studied the effect of various factors including the route of administration, food, and bile on the pharmacokinetics of AC enantiomers. Pharmacokinetics of AC were delineated after oral (fed and fasted), i.v., and i.p. doses, and after oral and i.v. doses, to intact and bile-duct-ligated female Sprague-Dawley rats, respectively. The possibility of intestinal metabolism or saturable absorption was studied in vitro using everted rat gut. Multiple peaks were present but only after oral doses independent of food intake, suggestive of gastrointestinal tract involvement. Oral absorption of AC enantiomers was incomplete as bioavailability was lower after oral (R, 0.59; S, 0.63) as compared to i.p. off(R, 0.86; S, 0.84) doses. Food reduced bioavailability by 60%. A 250-fold increase in the dose did not alter the absorption kinetics of AC through the everted gut, ruling out the possibility of saturable absorption. No intestinal metabolism was detected in vitro. Enterohepatic recirculation cannot be responsible as ligation of the bile duct did not alter the pattern or route dependence of the multiple peaking. The rat appears to be a suitable animal model; a bile- and food-independent erratic absorption is probably responsible for the observed multiple peaking of AC.

Prediction of absolute bioavailability for drugs using oral and renal clearance following a single oral dose: a critical view.

In order to determine the absolute bioavailability, both oral and intravenous administrations of a drug are often used. Recently a new method has been proposed to determine absolute bioavailability in the absence of intravenous dose. Following a single oral dose, this method requires oral and renal clearance data from normal subjects and renal failure patients. The bioavailability is calculated from a plot of oral against renal clearance following an oral dose, where the inverse of the slope is equal to absolute bioavailability. This study examines the prediction of absolute bioavailability from the proposed method for eight drugs which have a wide range of oral and renal clearance. From this study, it appears that the proposed method may not be reliable for the prediction of absolute bioavailability and further investigation is needed to test the validity of this method.