Clinical pharmacokinetics of beta-adrenoceptor antagonists. An update

The beta-adrenoceptor antagonists have been widely used clinically for over 20 years and their pharmacokinetics have been more thoroughly investigated than any other group of drugs. Their various lipid solubilities are associated with differences in absorption, distribution and excretion. All are adequately absorbed, and some like atenolol, sotalol and nadolol which are poorly lipid-soluble are excreted unchanged in the urine, accumulating in renal failure but cleared normally in liver disease. The more lipid-soluble drugs are subject to variable metabolism in the liver, which may be influenced by age, phenotype, environment, disease and other drugs, leading to more variable plasma concentrations. Their clearance is reduced in liver disease but is generally unchanged in renal dysfunction. All the beta-adrenoceptor antagonists reduce cardiac output and this may reduce hepatic clearance of highly extracted drugs. In addition, the metabolised drugs compete with other drugs for enzymatic biotransformation and the potential for interaction is great, but because of the high therapeutic index of beta-adrenoceptor antagonists, any unexpected clinical effects are more likely to be due to changes in the kinetics of the other drug. Because satisfactory plasma concentration effect relationships have been difficult to establish for most clinical indications, and little dose-related toxicity is seen, plasma beta-adrenoceptor antagonist concentration measurement is usually unnecessary. The investigation of the clinical pharmacokinetics of the beta-adrenoceptor antagonists has added greatly to our theoretical and practical knowledge of pharmacokinetics and made some contribution to their better clinical use.     

Clinical pharmacokinetics of contraceptive steroids. An update

The present article should be read in conjunction with the original review published in the Journal in 1983. There is no new information of major significance about the pharmacokinetics of levonorgestrel, norethisterone (norethindrone) or ethinylestradiol, although it has been shown that the concentrations of these hormones secreted in breast milk are small and mothers taking combined oral contraceptive steroids may breast-feed safely. Both levonorgestrel and ethinylestradiol can be successfully administered from appropriate vaginal formulations, but no clear advantages over oral administration have been demonstrated. Several new progestogens have been investigated. Desogestrel is a prodrug for its active metabolite 3-keto-desogestrel, gestodene is itself an active progestogen and norgestimate is a prodrug acting by conversion to norgestrel and its metabolites. All 3 compounds have good bioavailability with wide intersubject variation. The newer progestogens, like norethisterone and levonorgestrel, are bound to sex hormone binding globulin (SHBG). This causes their plasma concentrations to increase with time, since SHBG is induced by ethinylestradiol even in doses of 30 micrograms daily. The binding capacity and affinity of SHBG do not increase in direct proportion to its concentration. Further drug interactions with oral contraceptive steroids have been described. Contraceptive steroids may inhibit hepatic microsomal enzyme metabolism and increase the plasma concentration and effect of some tricyclic antidepressants, the hydroxylated benzodiazepines, some beta-blocking drugs, methylxanthines, prednisolone and cyclosporin. There are no significant effects on vitamins. Oral contraceptive steroids induce glucuronidation and hence decrease plasma concentrations of some benzodiazepines, clofibric acid, paracetamol (acetaminophen) and possibly morphine. The plasma concentration of ethinylestradiol may be increased by competitive sulphation with paracetamol. Plasma concentrations of contraceptive steroids are decreased by griseofulvin, which induces their hepatic metabolism. The role of other antibiotics remains controversial but there is probably a group of susceptible women who have lower plasma contraceptive hormone concentrations and experience breakthrough bleeding or pregnancy when given broad spectrum antibiotics. This may relate to interruption of the enterohepatic recirculation of ethinylestradiol. Anticonvulsants, other than valproic acid, all induce contraceptive steroid metabolism and therefore lower plasma hormone concentrations, thus reducing contraceptive effectiveness.     

Clinical pharmacokinetics and pharmacological effects of carbamazepine and carbamazepine-10,11-epoxide. An update

Carbamazepine is a first-line drug in the treatment of most forms of epilepsy and also the drug of first choice in trigeminal neuralgia. Furthermore, it is now frequently used in bipolar depression. Most oral formulations of carbamazepine are well absorbed with high bioavailability. The drug is 75% bound to plasma proteins. The degree of protein binding shows little variation between different subjects, and there is no need to monitor free rather than total plasma concentrations. Carbamazepine is metabolised in the liver by oxidation before excretion in the urine. A major metabolite is carbamazepine-10,11-epoxide which is further metabolised by hydration before excretion. This epoxide-diol pathway is induced during long term treatment with carbamazepine. Co-medication with phenytoin or phenobarbitone further induces this metabolic pathway. Some but not all studies indicate an increased metabolism of carbamazepine during pregnancy. The drug crosses the placenta, and the newborns who are exposed to the drug during fetal life eliminate the drug readily after birth. There seems to be no problem to nurse children during treatment with carbamazepine. Metabolism of carbamazepine is comparable in children and adults. Several studies have tried to establish a relationship between plasma carbamazepine and clinical effect in epilepsy, but very few of these are controlled. The best anticonvulsant effect seems to be obtained at plasma concentrations of 15 to 40 mumol/L and a similar optimal plasma concentration range was found in a controlled study in trigeminal neuralgia. Side effects are more frequent at higher plasma concentrations but are also seen within that range. In some patients, with pronounced fluctuation of plasma concentrations during the dosage interval, side effects may be avoided by more frequent dosing. Carbamazepine-10,11-epoxide is a potent anticonvulsant in animal models. During treatment with carbamazepine the plasma concentrations of this metabolite are usually 10 to 50% of those of the parent drug. It has not been possible to establish the relative contribution of the two compounds to the pharmacological effects. The epoxide has therefore been given to humans with the aim of determining the relative potency of the parent drug and its metabolite. After single oral doses of carbamazepine-10,11-epoxide to healthy subjects, the compound was rapidly absorbed. As a mean of 90% of the given dose was recovered in urine as trans-10,11-dihydroxy-10,11-dihydro-carbamazepine, a complete absorption of unchanged epoxide was shown.(ABSTRACT TRUNCATED AT 400 WORDS)     

Effects of liver disease on pharmacokinetics. An update

Liver disease can modify the kinetics of drugs biotransformed by the liver. This review updates recent developments in this field, with particular emphasis on cytochrome P450 (CYP). CYP is a rapidly expanding area in clinical pharmacology. The information currently available on specific isoforms involved in drug metabolism has increased tremendously over the latest years, but knowledge remains incomplete. Studies on the effects of liver disease on specific isoenzymes of CYP have shown that some isoforms are more susceptible than others to liver disease. A detailed knowledge of the particular isoenzyme involved in the metabolism of a drug and the impact of liver disease on that enzyme can provide a rational basis for dosage adjustment in patients with hepatic impairment. The capacity of the liver to metabolise drugs depends on hepatic blood flow and liver enzyme activity, both of which can be affected by liver disease. In addition, liver failure can influence the binding of a drug to plasma proteins. These changes can occur alone or in combination; when they coexist their effect on drug kinetics is synergistic, not simply additive. The kinetics of drugs with a low hepatic extraction are sensitive to hepatic failure rather than to liver blood flow changes, but drugs having a significant first-pass effect are sensitive to alterations in hepatic blood flow. The drugs examined in this review are: cardiovascular agents (angiotensin converting enzyme inhibitors, angiotensin II receptor antagonists, calcium antagonists, ketanserin, antiarrhythmics and hypolipidaemics), diuretics (torasemide), psychoactive and anticonvulsant agents (benzodiazepines, flumazenil, antidepressants and tiagabine), antiemetics (metoclopramide and serotonin antagonists), antiulcers (acid pump inhibitors), anti-infectives and antiretroviral agents (grepafloxacin, ornidazole, pefloxacin, stavudine and zidovudine), immunosuppressants (cyclosporin and tacrolimus), naltrexone, tolcapone and toremifene. According to the available data, the kinetics of many drugs are altered by liver disease to an extent that requires dosage adjustment; the problem is to quantify the required changes. Obviously, this requires the evaluation of the degree of hepatic impairment. At present there is no satisfactory test that gives a quantitative measure of liver function and its impairment. A critical evaluation of these methods is provided. Guidelines providing a rational basis for dosage adjustment are illustrated. Finally, it is important to consider that liver disease not only affects pharmacokinetics but also pharmacodynamics. This review also examines drugs with altered pharmacodynamics.     

Cardiopulmonary bypass and the pharmacokinetics of drugs. An update

Cardiopulmonary bypass is accompanied by profound changes in the organism that may alter the pharmacokinetics of drugs. Drug distribution can be altered, for example, by changes in blood flow and by haemodilution, with a decrease in protein binding; a decrease in the elimination of some drugs can be caused by impairment of renal or hepatic clearance, due, for example, to lowered perfusion and hypothermia. The subject was reviewed in the Journal in 1982, and the emphasis of the present review is on new data related to specific drugs. The following substances are dealt with: benzodiazepines, cephalosporins, digitalis glycosides, general anaesthetics, glyceryl trinitrate (nitroglycerin), lignocaine (lidocaine), muscle relaxants, nitroprusside, opiates, papaverine and propranolol. For many of these substances an abrupt decrease has been observed in serum concentration upon initiation of bypass, which is explained by haemodilution and an increase in distribution due to decreased protein binding. For nitrates and some opiates, adsorption to the bypass apparatus was shown to be important. The gradual increase in serum concentrations seen during cardiopulmonary bypass with some drugs after the initial fall is usually explained by redistribution of the drug and/or decrease in its elimination. The same phenomena are thought to explain why in the post-bypass period a concentration increase occurs, or at least a slower decrease than expected. However, drug elimination has been directly measured in only a few studies. The short duration of the bypass procedure and the continuous changes during the process hamper a rigorous pharmacokinetic evaluation. Studies allowing more precise understanding of the mechanisms underlying the observed concentration changes are needed, but are difficult to design. Similarly, more data are awaited on the pharmacodynamic and clinical consequences of the concentration changes.     

二氢吡啶类钙离子拮抗药物手性分析及其立体选择性药动学研究进展

手性药物与安全有效用药的关系密切,大多数二氢吡啶类药物具有手性碳原子,以消旋体入药,进入体内后产生立体选择性处置特征,可能影响用药的安全有效。该研究围绕该类药物手性拆分及药动学特点,综述了近年来该类药物的手性高效液相色谱法(HPLC)和手性毛细管电泳法(CE)方法选择规律及体内分析应用;列举并比较了该类药物间的立体选择性药动学研究情况,发现该类药物部分具有明显的立体选择性差异,体内药效和毒性也随之不同。     

Effects of antacids on the clinical pharmacokinetics of drugs. An update

Since a previous review by Hurwitz was published in 1977 a large number of reports on drug interactions with antacids have appeared, few of which are of clinical relevance. Tetracyclines form insoluble complex molecules by metal ion chelation with various antacids; tetracycline absorption may be decreased by more than 90% by this interaction. Of the new class of quinolone antibiotics, the absorption of ciprofloxacin and ofloxacin is reduced by 50 to 90% in the presence of aluminium- and magnesium hydroxide-containing antacids. In contrast to early work showing inhibition of the absorption of beta-adrenergic blocking drugs by antacids, subsequent studies did not confirm a reduction in the bioavailability of either atenolol or propranolol during antacid treatment; indeed, they showed an increase in the plasma concentrations of metoprolol when the drug was coadministered with an antacid. The bioavailability of captopril was significantly reduced in the presence of an antacid, and lower plasma concentrations of this angiotensin-converting enzyme inhibitor were accompanied by a reduction of its effect on the systolic blood pressure of the patients. The absorption of the cardiac glycosides digoxin and digitoxin is not inhibited by antacids to a significant degree, although earlier studies had shown a positive effect when the dissolution of the glycoside preparations was relatively poor. Antacids reduce the bioavailability of the H2-receptor antagonists cimetidine and ranitidine only when high antacid doses are used and when the drugs are administered simultaneously. The bioavailability of famotidine was not significantly altered by a potent antacid preparation, although a trend towards reduced absorption was observed. Iron absorption is significantly decreased in the presence of sodium bicarbonate and calcium carbonate, but is nearly complete when coadministered with aluminium-magnesium hydroxide. Nonsteroidal anti-inflammatory drugs such as naproxen, tenoxicam, ketoprofen, ibuprofen and piroxicam are not affected in their absorption by antacid treatment. Theophylline bioavailability is unchanged when the drug is given together with antacids, although its rate of absorption may be altered, leading to a reduction or an increase in the time of the occurrence of peak plasma drug concentrations.     

Newer H2-receptor antagonists. Clinical pharmacokinetics and drug interaction potential

Since H2-receptor antagonists are widely and successfully used in the treatment of peptic ulcer, several alternatives to the standard agents cimetidine and ranitidine have been developed. Promising 'new' candidates might be famotidine and nizatidine. For proper selection of the appropriate drug, its pharmacokinetic properties and interaction potential should be known. All 'old' and 'new' H2-receptor blockers are eliminated relatively rapidly (t 1/2 ranges from 1.5 to 4 hours), mainly by the renal route (glomerular filtration and tubular secretion). They exhibit a linear disposition and their distribution is similar. Absorption is most complete for nizatidine, whereas famotidine demonstrates the lowest effective plasma concentrations. Since etintidine shares the same imidazole ring structure as cimetidine, it can also impair oxidative drug metabolism in the liver. In this respect, the non-interacting famotidine and nizatidine (like ranitidine) offer a definite advantage. Based on their very similar pharmacokinetic and interaction profiles, these 2 H2-receptor antagonists might be regarded as alternatives to the older drugs in this group, and at least some economic benefits might result from the competition they will provide.     

An update on the clinical pharmacokinetics of fexofenadine enantiomers

Introduction: Fexofenadine is administered as a racemic mixture of (R)- and (S)-enantiomers. The plasma concentrations of (R)-fexofenadine in humans are about 1.5-fold higher than those of the (S)-enantiomer. Such differences in the pharmacokinetics between fexofenadine enantiomers are likely to be dependent on stereoselectivity for af?nity to drug-transporters.

Areas covered: This review focuses on elucidation of differences in clinical pharmacokinetics between fexofenadine enantiomers.

Expert opinion: Differences in pharmacokinetics between fexofenadine enantiomers were caused by organic anion transporting polypeptide (OATP) 2B1, with a minor contribution from P-glycoprotein (P-gp). In vitro studies using OATP2B1 cRNA showed that (R)-fexofenadine uptake into oocytes is greater than (S)-enantiomer uptake. P-gp inducers, carbamazepine, and inhibitors such as itraconazole and verapamil show greater effects on the pharmacokinetics of (S)-fexofenadine. Apple juice and grape fruit juice, OATP2B1 inhibitors, significantly decrease the exposure of both fexofenadine enantiomers, particularly the (S)-enantiomer, but do not change the t_1/2. Rifampicin significantly increases plasma concentrations of both enantiomers through inhibition of OATP1B3, whereas enantioselectivity of fexofenadine uptake by OATP1B3-expressing cells has not been observed. Combinations of multiple transporters such as OATP2B1 and P-gp facilitate enantioselective disposition of fexofenadine. Drug-transporters appear to be capable of chiral discrimination for transport of drugs with an asymmetric center.     

Interactions of calmodulin antagonists with calcium antagonists binding sites.

Calmodulin antagonists have calcium entry blocking properties. In order to quantitatively investigate the interactions of these drugs with calcium channels, their effect on [3H]nitrendipine and [3H]d-cis-diltiazem binding to rat cerebral cortex membrane preparations was compared to their inhibitory effect on the activation of cyclic nucleotide phosphodiesterase by calmodulin. The potency of most antagonists to inhibit [3H]nitrendipine binding was correlated with their calmodulin inhibitory potency. However, bepridil (K0.5 = 280 nM), chlorpromazine (K0.5 = 3 microM), triflupromazine (K0.5 = 1.5 microM), imipramine (K0.5 = 3 microM) and propranolol (K0.5 = 14 microM) were much more active on [3H]d-cis-diltiazem binding than on either [3H]nitrendipine binding or calmodulin, suggesting that these compounds bind to higher affinity sites on the calcium antagonist target protein. Moreover, the potencies of these compounds to compete with [3H]d-cis-diltiazem and to inhibit calcium-induced contractions in depolarized smooth muscle were correlated (R = 0.76, p less than 0.02). These data suggest that low concentrations of these hydrophobic drugs which have calcium and calmodulin antagonistic properties inhibit smooth muscle contraction through calcium entry blockade, not calmodulin antagonism.     

Benzodiazepine antagonists. An update of their role in the emergency care of overdose patients.

The benzodiazepine antagonist flumazenil is a very valuable tool in the diagnosis and treatment of intoxications in which benzodiazepines are involved. In case of a positive response, patients will regain consciousness immediately, thus verifying the diagnosis and making a brief history possible to identify other drugs that might be involved. Moreover, invasive diagnostic and therapeutic procedures like gastric lavage, lumbar puncture, mechanical ventilation, etc., may then be unnecessary. In cases of pure benzodiazepine overdose a single injection of flumazenil 0.2mg should be given, followed by individually titrated increments of 0.1 mg/min until the patient is awake and responsive. In these cases a total dose of 2mg is usually sufficient. Higher doses of flumazenil may be necessary in cases of combined drug overdose. Because of its high therapeutic index, the administration of flumazenil is usually not accompanied by serious adverse effects. Benzodiazepine withdrawal syndromes characterised by transient anxiety and depression can occur, but the incidence is low. Increases of blood pressure and heart rate due to a release of catecholamines are possible, which might endanger patients with cardiovascular diseases. In severe cases, seizures have been observed which usually respond well to small doses of benzodiazepine agonists. In all cases of successful treatment it should be remembered that the effect of flumazenil deteriorates after 1 to 2h, which usually leads at first to resedation. In these patients additional bolus injections or a continuous infusion (0.1 to 0.5 mg/h) may be necessary. The effectiveness of flumazenil in cases of alcohol (ethanol) poisoning is questionable and should be further investigated.     

Digitalis. An update of clinical pharmacokinetics, therapeutic monitoring techniques and treatment recommendations

The intestinal absorption of digoxin is essentially a passive non-saturable diffusion process, although a saturable carrier-mediated component also plays an important role. The bioavailability varies between 40 and 100%: the presence of food may reduce the peak serum concentration, but does not reduce the amount of digoxin absorbed. Recent development of a capsule containing a hydroalcoholic vehicle may reduce interindividual variations in absorption. Pharmacokinetic analysis of the distribution of digoxin suggests 3 compartments, the slow distribution phase accounting for the lag time between the inotropic effects and the plasma concentration profile. Digoxin is extensively bound to tissues such as myocardium, renal, skeletal muscle as well as red blood cells, but not to adipose tissue. Plasma protein binding varies between 20 and 30%: displacement of digoxin from protein binding sites does not cause significant clinical effects. As expected, haemodialysis or exchange transfusions do not significantly alter the body load of digoxin. The apparent volume of distribution of digoxin varies between 5 and 7.3 L/kg; this may be reduced by, for example, electrolyte abnormalities which reduce digoxin binding to the myocardium. The elimination half-life of digoxin is 36 hours, with 60 to 80% being excreted unchanged, by passive glomerular filtration and active tubular secretion. The remainder is excreted non-renally. Clearance is therefore dependent on renal function and declines in renal disease and in elderly patients. Digoxin interacts with other drugs at any stage of absorption (e.g. cholestyramine), distribution (e.g. quinidine), metabolism (e.g. phenytoin) or elimination (e.g. diltiazem). Patients should, therefore, be carefully monitored when changing a therapeutic regimen which includes any drugs known to interact with digoxin. Clinical monitoring is more important than therapeutic drug monitoring which should be reserved for suspected toxicity, doubts about efficacy, or in cases of poor compliance. With the advent of newer treatment modalities, digoxin is no longer the treatment of first choice in supraventricular arrhythmias and congestive heart failure. However, with careful monitoring, digoxin remains an important therapeutic option.     

Clinical pharmacokinetic considerations in the elderly. An update

There are numerous studies of drug handling in the elderly, but it is difficult to assess the significance of changes seen in vitro, or after single-dose administration, because they are often compensated by other mechanisms at steady-state. However, a knowledge of these studies is important as the results alert the investigator to possible treatment problems. The high incidence of adverse drug reaction in the elderly population leaves no doubt that improvements in therapy are needed. Research has been directed at seeking patterns of abnormality in the elderly on which to base recommendations for alterations in dosage regimens. The major shortcoming of this approach has been the failure to distinguish between the effect of chronological age on drug pharmacokinetics, and drug kinetics in elderly people with multiple pathology. The latter concern appreciates the variety of factors involved and the importance of treating each patient as an individual: presentation of mean data is confusing and misleading. The objective of drug treatment in any age group, but particularly in the elderly, is to administer the smallest possible dose which gives adequate therapeutic benefit throughout the entire dosage interval with the minimum of side effects. For most drugs the safe starting dose in the elderly is one-third to half that recommended in the young. Vigilance for potential side effects with plasma concentration monitoring, if available, should help keep toxicity to a minimum. When other medications are added or changed, the possibility of interaction should be anticipated. Methods for individualisation of dosage regimens and the use of sustained-release formulations in the elderly are discussed. Dosage alteration in the elderly in terms of reduced dose frequency, rather than dose size, may help improve compliance. A knowledge of the pharmacokinetics of a drug helps determine which approach will be most beneficial.     

Voltage-dependent calcium channels--beyond dihydropyridine antagonists.

The blockade of L-type calcium channels by dihydropyridines, phenylalkylamines and benzothiazepines has been well described and forms the basis of a multibillion dollar market for the treatment of cardiovascular disease and migraine. More recently, neuron-specific calcium channels have become the subject of intense interest regarding their potential as therapeutic targets for the treatment of chronic and neuropathic pain. A number of recently described agents that selectively target neuronal calcium channels have been described and appear promising for a variety of pain conditions.     

Clinical pharmacokinetics of H1-receptor antagonists (the antihistamines)

This article reviews clinical pharmacokinetic data on the H1-receptor antagonists, commonly referred to as the antihistamines. Despite their widespread use over an extended period, relatively little pharmacokinetic data are available for many of these drugs. A number of H1-receptor antagonists have been assayed mainly using radioimmunoassay methods. These have also generally measured metabolites to greater or lesser extents. Thus, the interpretation of such data is complex. After oral administration of H1-receptor antagonists as syrup or tablet formulations, peak plasma concentrations are usually observed after 2 to 3 hours. Bioavailability has not been extensively studied, but is about 0.34 for chlorpheniramine, 0.40 to 0.60 for diphenhydramine, and about 0.25 for promethazine. Most of these drugs are metabolised in the liver, this being very extensive in some instances (e.g. cyproheptadine and terfenadine). Total body clearance in adults is generally in the range of 5 to 12 ml/min/kg (for astemizole, brompheniramine, chlorpheniramine, diphenhydramine, hydroxyzine, promethazine and triprolidine), while their elimination half-lives range from about 3 hours to about 18 days [cinnarizine about 3 hours; diphenhydramine about 4 hours; promethazine 10 to 14 hours; chlorpheniramine 14 to 25 hours; hydroxyzine about 20 hours; brompheniramine about 25 hours; astemizole and its active metabolites about 7 to 20 days (after long term administration); flunarizine about 18 to 20 days]. They also have relatively large apparent volumes of distribution in excess of 4 L/kg. In children, the elimination half-lives of chlorpheniramine and hydroxyzine are shorter than in adults. In patients with alcohol-related liver disease, the elimination half-life of diphenhydramine was increased from 9 to 15 hours, while in patients with chronic renal disease that of chlorpheniramine was very greatly prolonged. Little, if any, published information is available on the pharmacokinetics of these drugs in neonates, pregnancy or during lactation. The relatively long half-lives of a number of the older H1-receptor antagonists such as brompheniramine, chlorpheniramine and hydroxyzine suggest that they can be administered to adults once daily.     

An update on the status of endothelin receptor antagonists for hypertension

Endothelin receptor antagonists (ETRA) are actively developed by the pharmaceutical industry for several cardiovascular indications. In the context of hypertension, preclinical studies are increasingly focused on prevention or regression of end-organ damage and drug combination than on control of arterial pressure in monotherapy, as most experimental models have already been studied. In general, the antihypertensive effect of ETRA is limited but the overwhelming efficacy of this class of drugs to prevent several end-organ damages warrants judicious combination. However, the few studies looking at regression of hypertension-induced cardiovascular alterations proved less successful, suggesting that ETRA should be used early in the treatment of hypertension to obtain full benefit. Judging from the progression of ongoing trials and the development of new trials patients suffering from pulmonary hypertension and heart failure may be the first to benefit from this new class of drugs. However, it is expected that once on the market, responsive subsets of hypertensive patients will be identified and will benefit from end-organ protection.     

Microvascular actions of calcium channel antagonists.

The microvascular actions of three calcium channel antagonists were studied in intact spontaneously hypertensive rats (SHR) provided with a dorsal striated muscle microcirculatory chamber. Verapamil and the dihydropyridine derivatives nifedipine and felodipine reduced mean arterial blood pressure (MAP) in a dose-dependent manner. They dilated arterioles of different sizes, with the most pronounced effect being on the smallest precapillary arterioles. Venular diameters were not affected by the calcium antagonists. Approximately 60% of the small arterioles showed a rhythmic pattern of vasodilatation and constriction. This pattern of spontaneous vasomotion was completely blocked by the calcium channel antagonists, especially those of the dihydropyridine type. It is concluded that (a) small precapillary arterioles play an important role in the vasodilator action of calcium channel antagonists, and (b) arteriolar vasomotion depends on vascular smooth muscle cell calcium influx.     

The pharmacokinetics of extended-release formulations of calcium antagonists and of amlodipine in subjects with different gastrointestinal transit times.

The influence of gastrointestinal (GI) transit times on the pharmacokinetics (PK) of three calcium channel blockers (CCBs), recommended for once-daily dosing, was investigated. In a three-way crossover design, the single-dose PK of a controlled-delivery formulation of 240 mg diltiazem (DIL), an extended-release formulation of 10 mg felodipine (FEL), and 5 mg amlodipine (AML) were compared in two groups of healthy subjects, with either slow (> 35 h) or rapid (< 15 h) GI transit, as assessed by the metal detector method (EAS II). GI transit significantly affected the PK of DIL. Mean PK parameters in the rapid versus slow transit group were the following: trough levels (C24 h): 22.8 +/- 8.3 versus 49.5 +/- 35.7 ng/ml, p < 0.05; AUC 1134.4 +/- 512.7 versus 1704.7 +/- 1185.6 hng/ml, p < 0.05 (one-sided). Neither AUC nor trough levels of FEL and AML were significantly influenced by transit times, nor was Cmax after any of the three treatments. Variations in PK parameters, as indicated by coefficients of variation, were about twofold higher for both DIL and FEL, compared to AML. Variations in mean residence times were significantly lower for AML compared to DIL and FEL (7% vs. 30% and 17%, p < 0.001 and p < 0.002, respectively). Peak-to-trough ratios (Cmax/C24 h mean) were 1.8 +/- 0.9 for DIL, 7.6 +/- 3.5 for FEL, and 1.7 +/- 0.2 for AML. In conclusion, the predictability of pharmacokinetic behavior both in conditions of rapid or slow GI transit is optimized in drugs with intrinsically slow elimination such as amlodipine. The pharmacokinetics of the CCBs with formulation-based once-a-day characteristics are sensitive to GI transit if these processes are rapid enough to interfere with the formulation-specific release profile.