Bioavailability of oral dexamethasone during high dose steroid therapy in neurological patients

The pharmacokinetics and oral biovailability of dexamethasone were studied in 6 patients with neurological disease being treated with high dosages of the drug. A specific high performance liquid chromatographic assay was used to measure dexamethasone concentrations. Unlike the previously published mean figure of 0.78 for the oral bioavailability of the drug given in single doses to healthy volunteers, the mean bioavailability of dexamethasone in the patients studied was 0.53 +/- SD 0.40. It appeared more likely that this incomplete bioavailability was due to presystemic elimination than to poor absorption. The intravenous clearance of the drug was relatively high (0.4902 +/- SD 2291 1 kg-1, approximately 65% of expected hepatic plasma flow), the oral clearance higher (2.5804 +/- SD 3.2181 1 kg-1 h-1) while the absorption rate constant (4.8729 +/- 8.4998 h-1), suggested rapid absorption after oral administration. Prior phenytoin and possibly prior dexamethasone therapy is likely to have contributed to the higher clearance values of the drug in these patients than the values reported in healthy volunteers after single dose studies.     

The effect of pregnancy in humans on the pharmacokinetics of stable isotope labelled phenytoin.

1. To investigate the mechanism of the fall in steady-state plasma phenytoin concentration relative to drug dose that occurs during pregnancy, single dose pharmacokinetic studies with stable isotope labelled phenytoin were carried out at different stages of pregnancy, and 2 to 4 months post-natally, in five epileptic women receiving regular oral therapy with the drug. 2. Steady-state apparent plasma clearances of phenytoin (dose/steady-state concentration) correlated closely with simultaneous plasma clearances of the intravenous stable-isotope drug (measured as dose/AUC) suggesting that the patients were complaint with therapy when their phenytoin dosage requirement increased during the pregnancy, and that the oral drug was fully bioavailable. 3. In retrospect, two of the five subjects were probably studied too early post-natally for phenytoin elimination kinetics to have returned to non-pregnant values. Despite this, (i) the mean +/- s.d. t 1/2 for phenytoin was statistically significantly shorter in pregnancy than post-natally (31 +/- 14 vs 39 +/- 28 h), (ii) the mean +/- s.d. whole plasma clearance was also statistically significant greater (0.025 +/- 0.012 vs 0.021 +/- 0.013 kg-1 h-1) and (iii) the mean +/- s.d. Vmax for phenytoin elimination was statistically significantly greater in pregnancy (1170 +/- 600 mg day-1) than post-natally (780 +/- 470 mg day-1). Although the mean +/- s.d. apparent Km was higher in pregnancy (18.2 +/- 8.4 mg l-1, expressed in terms of whole plasma drug concentrations, compared with 10.2 +/- 7.4 mg l-1 post-natally), the difference was not statistically significant. However, if the apparent Km value was expressed in terms of plasma water phenytoin concentrations the difference (pregnant 2.50 +/- 0.85 mg l-1: post-natally 1.16 +/- 0.65 mg l-1) was statistically significant. 4. Human pregnancy appears to result in an increased capacity to eliminate phenytoin.     

Comparison of the pharmacokinetics of cephradine and cefazolin in pregnant and non-pregnant women

The pharmacokinetics of cephradine, a cephalosporin with a low degree of protein binding, was studied in 12 women after oral and intravenous administration of the drug during and after pregnancy. Six of the 12 women also received a cephalosporin with a high degree of protein binding, cefazolin, intravenously during and after pregnancy. For both drugs most pharmacokinetic parameters were altered in pregnancy. The area under the plasma concentration-time curve (AUC) following intravenous administration was smaller for both drugs during as compared to after pregnancy (mean change 39% for cephradine and 31% for cefazolin). Half-lives of both drugs were significantly shorter during compared with after pregnancy (mean change 26% for cephradine and 35% for cefazolin). Consequently, total body clearance was increased during pregnancy. A significant negative correlation between length of gestation and total clearance per kg bodyweight was seen for cephradine. The bioavailability of oral cephradine did not differ significantly during compared with after pregnancy. It is concluded that the dosage of both cefazolin and cephradine should be increased when treating infections in pregnant women in order to obtain the same antibacterial effect as when treating non-pregnant women.     

Manipulation of rectal absorption rate of phenytoin in man

Rectal absorption of phenytoin and its sodium salt from various dosage forms was studied in man. The rectal dosage forms included fatty suppositories, an aqueous suspension and solutions with various solvents in order to achieve complete dissolution of phenytoin. The plasma concentration of phenytoin was measured by means ofHplc analysis after a single dose of 200 mg phenytoin in a cross-over study in eight volunteers. A comparison was made with oral administration. Compared with oral administration rectal absorption conditions of phenytoin from fatty suppositories or aqueous suspensions were found to be extremely unfavourable. Although the addition of alkali and glycofurol increased the rectal absorption, absorption only occurred with an appreciable rate during the first 30 minutes after administration. This in contrast to a rectal solution using polyethylene glycol 600 as a solvent which did produce a slow but continuous absorption over at least 8 hours. Relative bioavailability after this period of time was calculated to be 50%. We conclude that it is in principle possible to improve the rectal absorption rate and also the bioavailability of phenytoin by increasing the solubility of this drug with non-absorbable agents.In honour of ProfessorHuizinga on the occasion of his retirement.     

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. © 1997 John Wiley & Sons, Ltd.     

Biased estimates of nonrenal clearance.

The goal of the investigation was to critically evaluate published values for oral nonrenal clearance and their postulated dependence on renal function with drugs administered orally to subjects with varying renal function. Derivation of the pertinent equations indicated that the values reported for oral nonrenal clearance tend to systematically overestimate both the true oral and intravenous nonrenal clearances of these drugs. Computations were performed to confirm these findings not only for subjects with normal renal function, but also for patients with renal impairment. The computations evaluated the relevance of bioavailability and renal clearance of a drug for the bias in the estimates of true oral or intravenous nonrenal clearance. The results of the computations showed that the estimates for true oral and intravenous nonrenal clearance derived from oral data exceed systematically the true values in subjects with normal or reduced renal function. Also, a renal function dependent decrease of the true oral or intravenous nonrenal clearance is falsely diagnosed if apparent oral nonrenal clearance values are used for the estimates. The magnitude of bioavailability and renal clearance impact the bias in the estimates derived from oral data. For drugs with predominant renal excretion and small bioavailability the bias is largest. For drugs with predominant nonrenal elimination and large bioavailability the bias is smallest.     

Pharmacokinetic interactions of topiramate

Topiramate is a new antiepileptic drug (AED) that has been approved worldwide (in more than 80 countries) for the treatment of various kinds of epilepsy. It is currently being evaluated for its effect in various neurological and psychiatric disorders. The pharmacokinetics of topiramate are characterised by linear pharmacokinetics over the dose range 100-800 mg, low oral clearance (22-36 mL/min), which, in monotherapy, is predominantly through renal excretion (renal clearance 10-20 mL/min), and a long half-life (19-25 hours), which is reduced when coadministered with inducing AEDs such as phenytoin, phenobarbital and carbamazepine. The absolute bioavailability, or oral availability, of topiramate is 81-95% and is not affected by food. Although topiramate is not extensively metabolised when administered in monotherapy (fraction metabolised approximately 20%), its metabolism is induced during polytherapy with carbamazepine and phenytoin, and, consequently, its fraction metabolised increases. During concomitant treatment with topiramate and carbamazepine or phenytoin, the (oral) clearance of topiramate increases 2-fold and its half-life becomes shorter by approximately 50%, which may require topiramate dosage adjustment when phenytoin or carbamazepine therapy is added or discontinued. From a pharmacokinetic standpoint, topiramate is a unique example of a drug that, because of its major renal elimination component, is not subject to drug interaction due to enzyme inhibition, but nevertheless is susceptible to clinically relevant drug interactions due to induction of its metabolism. Unlike old AEDs such as phenytoin and carbamazepine, topiramate is a mild inducer and, currently, the only interaction observed as a result of induction by topiramate is that with ethinylestradiol. Topiramate only increases the oral clearance of ethinylestradiol in an oral contraceptive at high dosages (>200 mg/day). Because of this dose-dependency, possible interactions between topiramate and oral contraceptives should be assessed according to the topiramate dosage utilised. This paper provides a critical review of the pharmacokinetic interactions of topiramate with old and new AEDs, an oral contraceptive, and the CNS-active drugs lithium, haloperidol, amitriptyline, risperidone, sumatriptan, propranolol and dihydroergotamine. At a daily dosage of 200 mg, topiramate exhibited no or little (with lithium, propranolol and the amitriptyline metabolite nortriptyline) pharmacokinetic interactions with these drugs. The results of many of these drug interaction studies with topiramate have not been published before, and are presented and discussed for the first time in this article.     

Pharmacokinetics of paracetamol (acetaminophen) after intravenous and oral administration

Summary Plasma paracetamol concentrations were measured in 6 volunteers after single intravenous (1000 mg) and oral (500 mg, 1000 mg and 2000 mg) doses of the drug. Paracetamol levels declined multiphasically with a mean clearance after intravenous administration of 352±40 ml/min. A two-compartment open model appeared to describe the decline adequately. Comparison of the areas under the plasma concentration-time curves (AUC) indicated that oral bioavailability increased from 0.63±0.02 after 500 mg, to 0.89±0.04 and 0.87±0.08 after 1000 mg and 2000 mg, respectively. As a consequence of the incomplete bioavailability of paracetamol, as well as its multicompartmental distribution, accurate estimates of its distribution volume and clearance cannot be obtained if the drug is given orally. However, an estimate of its total plasma clearance may be derived from the AUC after a 500 mg oral dose.     

Stable-isotope methodology for the bioavailability study of phenytoin during multiple-dosing regimens

With the highly sensitive and specific gas chromatography-mass spectrometry (GC-MS), plasma concentrations resulting from an intravenous administration of only a small amount of stable isotopically labeled phenytoin (DPH-d10) were determined to obtain information on the accurate clearance values under steady-state conditions attained with unlabeled phenytoin (DPH-d0). A time course of DPH-d10 concentrations was followed simultaneously with DPH-d0 during dosing intervals by GC-MS, with DPH-d5 as an internal standard. The present stable-isotope methodology offered advantages for the estimation of absolute bioavailability of the oral phenytoin dose in patients, while normal therapy was continued and not withdrawn.     

Influence of efflux transporters on drug metabolism: theoretical approach for bioavailability and clearance prediction

Cytochrome P450 enzymes and efflux transporters, expressed in the intestine and/or in the liver, play important roles in drug clearance and oral bioavailability. The relative contribution of transporters and enzymes in drug metabolism is still controversial. Some antiepileptic drugs, such as carbamazepine, phenytoin and phenobarbital (phenobarbitone), show time-dependent and dose-dependent pharmacokinetics due to their inductive effect on both efflux transporters and enzymes. However, steady-state plasma drug concentrations for each antiepileptic drug do not relate to oral daily dose in the same way, with decreased or increased apparent clearance according to the drug. A multicompartment pharmacokinetic model was developed in order to explain these different behaviours using a single mechanism of inductive action. The key for solving these apparent dissimilarities was to consider in the model the unique physiological connection that intestine, liver and bloodstream have. Efflux transporters not only enhance enzymatic competition in relation to first-order processes, but also change the predominance of some elimination routes. For instance, the carbamazepine-10,11-epoxide formation increases at the expense of other carbamazepine metabolites, enhancing both the systemic and presystemic elimination of parent drug. Conversely, the major hepatic metabolism of phenytoin diminishes in favour of its minor intestinal elimination, decreasing the total drug clearance.     

Disposition kinetics and oral bioavailability of vincamine-loaded polyalkyl cyanoacrylate nanoparticles

Hexyl cyanoacrylate nanoparticles loaded with vincamine as a drug model were prepared. Disposition kinetics and oral bioavailability of vincamine in rabbits were compared after administration of an aqueous solution of the drug and an aqueous colloidal suspension of nanoparticles. After intravenous administration, total body clearance of vincamine was equal for both dosage forms, but a longer half-life (X 2) and larger distribution volume (X 2) were observed with the suspension of nanoparticles. After oral administration, the bioavailability of vincamine was considerably greater for the drug loaded onto nanoparticles.     

Clinical pharmacokinetics of metoclopramide

Metoclopramide is rapidly and well absorbed from the gastrointestinal tract, and in man undergoes variable first-pass metabolism (oral bioavailability 32 to 100%). In man, N-4 sulphate conjugation is an important pathway of metabolism and after oral administration the ratio of free to conjugated metoclopramide in urine correlates with the plasma AUC. The elimination half-life of metoclopramide is dose-dependent after both intravenous and oral administration of single doses between 5 and 20mg. Metabolic profiles in animal species studied are very different from man. The clearance of metoclopramide is reduced in patients with renal failure to approximately 50% of normals and the terminal half-life is prolonged; this is despite the fact that renal clearance of free drug accounts for only 20% of the administered dose in normals. Preliminary studies after 'high dose' metoclopramide demonstrate accumulation to high plasma concentrations with linear kinetics, suggesting that current high dose regimens are unnecessarily cumbersome.     

Dose-dependent bioavailability of prazosin in beagle dogs

Prior to the introduction of an intravenous dosage form for use in humans, prazosin pharmacokinetic studies emphasizing clearance, hepatic extraction, and bioavailability were carried out in dogs. Two such canine studies reported significantly different values for the oral bioavailability of prazosin. This study investigated the differences in prazosin oral availability in beagle dogs. Three male animals were administered an intravenous (1 mg/kg) and three different oral doses (15, 5, and 1 mg) with a 7-day washout between study days. The mean predicted bioavailability, based on hepatic clearance and an estimate for liver blood flow, was 74%. The mean absolute bioavailabilities, determined for each dose in each animal by comparing dose-corrected areas under the plasma concentration-time curve, were 82, 27, and 23%. Although good agreement was evident in bioavailability between the 15-mg oral dose and what was predicted, calculated availabilities for the 5-mg and 1-mg oral doses were approximately one-third the predicted value. The results obtained from this study, together with data from the two previous studies, indicate that the bioavailability of prazosin in dogs is dose-dependent. Possible mechanisms for this observation are also presented.     

Yohimbine bioavailability in humans

Summary Pharmacokinetic profiles were determined in seven healthy young male subjects following single oral and intravenous doses of 10 mg of yohimbine hydrochloride.The drug was rapidly eliminated (t_1/2 0.58 h orally and t_1/2 0.68 h intravenously). Following intravenous administration the data fit a two-compartment pharmacokinetic model, with a very rapid distribution phase (t_1/2a was approximately 6 min). Both the oral and the intravenous yohimbine clearance values were high but oral clearance values were much higher (mean 9.77 ml·min^–1·kg^–1 intravenous versus 55.9 ml·min^–1·kg^–1 oral). The oral bioavailability showed great variability, ranging from 7% to 87% (mean value was 33%).The imcomplete oral bioavailability of yohimbine may reflect either incomplete absorption from the gastrointestinal tract or an hepatic first pass effect. Although yohimbine is rapidly absorbed when given orally, the bioavailability is quite variable and considerable individualization of dosing may be necessary when the drug is used orally for clinical indications.Supported in part by NIH grant # MOIRR 0042     

Application of routine monitoring data for determination of the population pharmacokinetics and enteral bioavailability of phenytoin in neonates and infants with seizures

This study investigated the population pharmacokinetics and the enteral bioavailability of phenytoin (PTN) in neonates and infants with seizures. Data from 83 patients were obtained retrospectively from medical records. A 1-compartment model was fitted to the log-transformed concentration data using NONMEM. Between-subject variability and interoccasion variability were modelled exponentially together with a log transform, both-sides exponential residual unexplained variance model. Covariates in nested models were screened for significance. Model robustness was assessed by bootstrapping with replacement (n = 500) from the study data. The parameters of the final pharmacokinetic model were clearance (L/h) = 0.826.[weight (WT, kg) / 70].[1 + 0.0692.(postnatal age (d) - 11)]; volume of distribution (L) = 74.2.[WT (kg) / 70]; absolute enteral bioavailability = 0.76; absorption rate constant (h) = 0.167. The between-subject variability for clearance and volume of distribution was 74.2% and 65.6%, respectively. The interoccasion variability for clearance was 54.4%. The unexplained variability was 51.1%. Final model parameter values deviated from median bootstrap estimates by less than 9%. Phenytoin disposition in neonates and infants can be described satisfactorily by linear pharmacokinetics. The values of allometrically scaled clearance and volume were similar to adult values, suggesting no major kinetic differences between adults and infants on the basis of size alone. Postnatal age independently influenced clearance. Switching from enteral to intravenous routes may require a dosage adjustment. The results of this study provide a basis for more rational prescribing of phenytoin in infants and neonates.     

The effect of administration of phenytoin on the pharmacokinetics of isoxicam

This study was designed to determine whether the disposition of isoxicam is influenced by the coadministration of another acidic drug, highly bound to plasma proteins and extensively metabolized, i.e., phenytoin. Ten healthy volunteers received an oral dose of 200 mg of isoxicam prior to and following the oral administration of phenytoin (100 mg) twice a day for 10 days. Eleven blood samples were drawn during the period following each dose of isoxicam. The area under the isoxicam plasma concentration-time curve (AUC infinity) increased from 389 +/- 66 to 464 +/- 62 micrograms h ml-1 (+/- SEM) (p less than 0.05) after treatment with phenytoin. This increase was due to an increase in isoxicam bioavailability; the absorption rate constant for isoxicam increased correspondingly from 0.34 +/- 0.06 to 1.16 +/- 0.38 h-1 (p less than 0.05). Distribution and clearance of isoxicam were probably not affected as its half-life was not changed, its plasma peak concentration increased, and the time to reach this peak decreased. It is concluded that phenytoin increases the rate and extent of absorption of isoxicam.     

The bioavailability and pharmacokinetics of guanfacine after oral and intravenous administration to healthy volunteers

Guanfacine is a centrally acting alpha-2 adrenergic agonist. The absolute bioavailability, pharmacokinetics, and renal clearance of this antihypertensive drug were investigated in healthy male volunteers. Eighteen subjects received a single oral or intravenous dose of guanfacine 3 mg in a two-way cross-over study design. Blood samples were obtained before dosing and up to 72 hours after dosing for determination of drug levels in plasma. Additional blood samples were obtained for protein binding studies. Urine was collected and pooled for specific intervals up to 96 hours after dosing. The absolute bioavailability of guanfacine after a single oral dose was 81.1%. The elimination half-lives were 13.8 hours and 13.4 hours after oral and intravenous administration, respectively. The volume of distribution results were approximately 6 L/kg by both routes of administration. The mean plasma protein binding results were 71.6%, not influenced by plasma concentration or route of administration. The urinary recovery of guanfacine was 44.3% after oral dosing and 50% after intravenous dosing. Renal clearance of guanfacine was 50% of total body clearance and appeared to be due to a net renal tubular secretory process.     

Relative and absolute bioavailability of cibenzoline capsules and tablets in healthy subjects

Eighteen healthy adult volunteers completed an open-label, four-way crossover study designed to determine the bioequivalency of 160-mg cibenzoline [2-(2,2-diphenylcyclopropyl)-4,5-dihydro-1H-imidazole] capsules and tablets, their relative bioavailability compared with an oral solution of the drug, as well as the absolute bioavailability of these dosage forms compared with an intravenous infusion of the drug. Blood samples obtained at specified times after drug administration were assayed for cibenzoline by HPLC, and pharmacokinetic parameters were estimated from the resulting plasma concentration-time profiles. Comparisons were made between the tablet and capsule to assess bioequivalency, between the solid dosage forms and a solution to assess relative bioavailability, and between the oral forms and an intravenous infusion to assess absolute bioavailability. The pharmacokinetic parameters for each oral dosage form were similar and ratios of mean parameters indicated that the solid dosage forms were bioequivalent and completely bioavailable relative to an oral solution. The ratios of the area under the plasma concentration-time profiles (AUC) for the capsule, tablet, and oral solution to that of the intravenous infusion were 0.85, 0.83, and 0.86, respectively, indicating that orally administered cibenzoline has an absolute bioavailability of approximately 85%.     

A comparative study of the bioavailability of five different phenytoin preparations

The concentration of phenytoin in saliva has been measured in 8 healthy volunteers at intervals after an intravenous dose and after single oral doses of five formulations commercially available in the United Kingdom. The six doses (all 300 mg) were given in random order and at least one week apart. There were no significant differences in the mean values of the peak saliva concentration, the time-to-peak and the area under the saliva concentration-time curve between the five oral formulations. The absolute bioavailability of phenytoin varied between 68 and 74%.     

Influence of bed rest on the pharmacokinetics of phenazone

Summary The pharmacokinetics of a single dose of phenazone was studied in six subjects while ambulant and during bed rest for 3 days. Elimination of the drug was followed for 12 h after oral and intravenous administration. The elimination rate constant and total body clearance were significantly increased during bed rest as compared to the ambulant period, but the differences were small. The apparent volume of distribution decreased significantly. No consistent change due to bed rest was found in the rate of absorption or bioavailability of the oral dose.