Plasma binding and transport of diazepam across the blood-brain barrier. No evidence for in vivo enhanced dissociation.

The tissue uptake of extensively plasma-bound compounds is reportedly inconsistent with the conventional free-drug hypothesis limiting transport to unbound moiety in rapid intracapillary equilibrium with bound complex. Instead, protein-mediated/cell surface enhancement of dissociation has been postulated to occur in the microvasculature. This possibility was investigated by studying the passive transport of diazepam across the blood-brain barrier. Microdialysis probes placed within the vena cava and brain cortex were used to directly compare steady-state, interstitial unbound diazepam levels in both Wistar and genetically analbuminemic rats. The absence of albumin in the latter increased the unbound fraction of diazepam by almost fivefold; however, in both groups, the ratio of unbound concentrations in brain and blood at equilibrium was equal to unity. If enhanced dissociation occurred in the microvasculature, then the unbound brain level should have been greater than that in the systemic circulation. It is probable that earlier findings suggestive of protein-mediated transport reflect a nonequilibrium phenomenon. Comparison of the extent of diazepam's in vivo binding in blood by microdialysis to that estimated in vitro using conventional equilibrium dialysis with microcells showed good agreement, thus validating a widely accepted assumption of equivalency of these two values.

Genetic predisposition to bladder cancer: ability to hydroxylate debrisoquine and mephenytoin as risk factors.

The hypothesis that the frequency distribution of indices of oxidative drug-metabolizing activity is different between patients with bladder cancer (n = 98) and age, sex-matched control subjects (n = 110) has been investigated. Urinary recovery ratios of debrisoquine and R/S ratios of mephenytoin have been measured in an 8-h urine sample after simultaneous administration of debrisoquine (10 mg) and racemic mephenytoin (100 mg). In addition, alcohol consumption, smoking habit, and acetylation phenotype (using 100 mg dapsone as a substrate) have been measured. Patients with bladder cancer were classified on histological criteria as having aggressive (Stage III) (34%) or nonaggressive (Stages I and II) (66%) disease. The median of the frequency distribution of the debrisoquine urinary recovery ratio in patients with aggressive bladder cancer was greater than in control subjects, and only four patients had recovery ratios lower than the mean of the control group. Using logistic regression analysis, efficient debrisoquine metabolism and a synergistic interaction between smoking and ethanol consumption were significant, independent risk factors, while S-mephenytoin hydroxylation and acetylation phenotype were not significant risk factors. In contrast, patients with non-aggressive bladder cancer had a significant, but weaker, association with rapid hydroxylation of S-mephenytoin, which was independent of a significant synergistic interaction between smoking and alcohol consumption. Acetylation phenotype and debrisoquine urinary recovery ratio were not associated with increased risk of nonaggressive cancer. These results are consistent with the concept that oxidative isozymes might be responsible for conversion of environmental agents to proximate bladder carcinogens in nonindustrial-related bladder cancer. They also suggest that different etiological factors are involved in the pathogenesis of aggressive and nonaggressive bladder cancer.

Mephenytoin hydroxylation deficiency in Caucasians: frequency of a new oxidative drug metabolism polymorphism.

The ability of normal subjects to hydroxylate mephenytoin (100 mg) or debrisoquine (10 mg) after oral dosing was investigated in 156 unrelated Caucasians living in middle Tennessee. Urinary recovery of 4-hydroxymephenytoin (4-OH-M) and the urinary S:R enantiomeric ratio of mephenytoin measured in an 8-hr urine sample were investigated as phenotypic traits for mephenytoin, and the urinary metabolic ratio of debrisoquine was used to determine the debrisoquine hydroxylase phenotype. Both urinary 4-OH-M and the S:R ratio of mephenytoin discriminated between extensive (EM) and poor (PM) metabolizers of mephenytoin. The frequencies of PMs for mephenytoin and debrisoquine hydroxylation activity were 2.6% and 7.0%. These two defects in oxidative metabolism were not observed in the same subjects, which suggests that 4-hydroxylation of mephenytoin is a new polymorphism independent of that for debrisoquine.

Effects of age on meperidine disposition.

Elderly patients appear to be more sensitive to meperidine than younger ones; however, the contributions of altered dynamic and kinetic factors are not clear. Accordingly, seven healthy normal men aged 60 to 79 yr were simultaneously given 25 mg meperidine HCl intravenously and the same dose of deuterium-labeled drug either orally or intramuscularly (deltoid). Blood and urine samples collected over 24 hr were analyzed by gas chromatography-mass spectrometry and kinetic data were compared to those previously obtained in a young cohort. Systemic clearance (8.61 +/- 2.22 ml/min/kg), apparent oral clearance (17.5 +/- 5.5 ml/min/kg), terminal t1/2 (6.98 +/- 1.86 hr), and the blood/plasma concentration ratio (0.97 +/- 0.12) in the elderly did not differ from those in younger subjects. In the elderly, however, the initial (2.4 +/- 0.8 l/kg) and the steady-state (4.6 +/- 0.9 l/kg) volumes of distribution were 300% and 135% values in the young. No age differences were found in absorption profiles or bioavailability after oral (F = 0.49 +/- 0.08) or intramuscular (F = 0.94 +/- 0.04) dosing. It appears that age-related alterations in drug disposition per se do not account for changes in clinical efficacy of meperidine in the elderly.

Interethnic differences in genetic polymorphism of debrisoquin and mephenytoin hydroxylation between Japanese and Caucasian populations.

Interethnic differences in debrisoquin and mephenytoin hydroxylation have been compared between normal white (n = 183) and Japanese (n = 100) subjects with the 8-hour urinary metabolic ratio of debrisoquin and the urinary S/R enantiomeric ratio of mephenytoin to identify extensive (EM) and poor (PM) metabolizers. In white subjects the frequency of PMs was 8.7% and 2.7% for debrisoquin and mephenytoin, respectively. In contrast, in Japanese subjects no PMs of debrisoquin were identified, while the incidence of PMs of mephenytoin was 18%. These substantial differences (P less than 0.001) in polymorphic distributions of oxidative drug metabolizing ability have implications for interethnic efficacy and toxicity of drugs and other xenobiotics that are metabolized by the involved cytochrome P-450 isozymes.

Interaction between Aspergillus niger van Tiegh. and Glomus mosseae. (Nicol. & Gerd.) Gerd. & Trappe.

Percent germination and length of hyphae of germinated Glomus mosseae spores, cultivated on water agar, decreased significantly in the presence of Aspergillus niger; this decrease was independent of any change in pH of the medium. Soluble and volatile compounds produced by A. niger significantly decreased percentage spore germination and the hyphal length of G. mosseae on water agar. The decrease caused by volatile compounds was significantly greater when A. niger was grown on malt extract agar. Shoot dry weights of maize and lettuce plants cultivated in soil in pots, and percentage arbuscular mycorrhizal (AM) root colonization of plants grown either in sand: vermiculite tubes inoculated with G. mosseae spores or in soil in pots with soil inoculum, were unaffected by A. niger when this saprobe was inoculated 2 wk after G. mosseae. Shoot dry weights and percentage AM colonization of plants decreased when the saprobic fungus was inoculated at the same time or 2 wk before G. mosseae. However, the metabolic activity resulting from AM colonization, measured as the percentage of mycelium showing succinate dehydrogenase activity, decreased in all treatments. The population of A. niger decreased when inoculated to the rhizosphere of plants at the same time as, or 2 wk after, G. mosseae, but not when it was inoculated 2 wk before G. mosseae. Our results show that G. mosseae decreases the saprobic fungal population through its effect on the plant, whereas A. niger, by the production of soluble or volatile substances, inhibits G. mosseae in its extramatrical stage.

Placental transfer and neonatal effects of diazepam when administered to women just before delivery.

Diazepam 10 mg i.v. was administered to 23 patients (test group) just before delivery. The umbilical cord blood was analysed for diazepam and the well-being of neonates in the test group and in a suitable control group (n = 32) was compared using analysis of covariance. Diazepam was detected in neonatal blood about 0.5 min following its administration to mothers. No significant differences in neonatal well-being were detected between the two groups. However, a highly significant inverse relationship was found between the rectal temperature of the newborn and the concentration of diazepam in umbilical cord blood.

The assessment of bioavailability in the presence of nonlinear elimination.

The simultaneous administration of an oral dose and intravenous tracer dose, as a method to determine bioavailability, was examined by means of computer simulation for drugs exhibiting Michaelis-Menten type elimination. A physiological pharmacokinetic model parameterized for man and including first-order absorption and elimination solely from the liver was employed. This tracer method provided good estimates of the true availability, with an error of 6% or less, over a wide range of dosing and dispositional conditions. Poorer estimates were noted when large doses of drugs with very short half-lives were considered. This poor performance was improved by administering the intravenous tracer at some time after the oral dose but an a priori basis for establishing this time was not apparent. The tracer method, therefore, appears to be a robust means of assessing, in man, oral bioavailability in the presence of Michaelis-Menten type elimination for drugs characterized by the general properties of the physiological model employed and with half-lives in excess of approximately 40 min. These findings together with the statistical power and simplicity of performance of the tracer method indicate that it is a valid technique for the assessment of bioavailability under a wide range of kinetic conditions.

Increased toxicity and reduced clearance of lidocaine by cimetidine.

Cimetidine reduced liver blood flow and the systemic clearance of drugs, such as propranolol, that are highly extracted by the liver. In a randomized placebo-controlled study, we examined the influence of cimetidine, 300 mg four times daily for 1 d, on the disposition of lidocaine, 1 mg/kg body weight by a 10-minute intravenous infusion. Cimetidine reduced the systemic clearance of lidocaine from 766 +/- 50 mL/min to 576 +/- 47 mL/min (p less than 0.05); the apparent volume of distribution at steady-state and the degree of plasma protein binding of lidocaine also were decreased. Five of the six subjects noted lidocaine toxicity during the cimetidine infusion in contrast to one subject on the placebo day. The peak lidocaine concentration (mean +/- SE) was 50% +/- 10% higher when subjects received cimetidine. This study provides additional evidence that the effect of cimetidine on the elimination of other drugs has multiple factors, and shows a previously unrecognized mechanism, involving altered initial drug distribution, whereby the interaction of cimetidine with other drugs may cause toxicity.

Altered distribution of debrisoquine oxidation phenotypes in patients with systemic lupus erythematosus.

Oxidative metabolism in patients with systemic lupus erythematosus (SLE) was studied using the antihypertensive drug, debrisoquine. The metabolism of this drug to its principal metabolite, 4-hydroxydebrisoquine, is catalyzed by a discrete isozyme of cytochrome P-450. The extent of this reaction exhibits genetic polymorphism, with 2 phenotypes, "poor metabolizers" and "extensive metabolizers," discernible in the normal population. We observed the poor metabolizer debrisoquine phenotype in 9 of 42 patients with idiopathic SLE (21%), in contrast with 12 of 147 healthy volunteers (8%), which is a significant difference in frequency (P less than 0.04). These data provide further evidence for altered oxidative metabolism in SLE and support the concept that genetic differences in oxidative metabolism of endogenous compounds, such as sex steroid hormones, or of xenobiotics might influence susceptibility to SLE.

A new method for constant plasma drug concentrations: application to lidocaine.

Optimal intravenous drug therapy often requires the rapid achievement and maintenance of therapeutic plasma drug concentrations. Simple regimens (single bolus and maintenance infusion) can produce wide variations in plasma drug concentrations early in therapy, and more complex regimens require a series of precisely timed infusion rate changes to minimize such variability. A new simple method of delivering an infusion produces a delivery rate that declines exponentially, thereby providing stable plasma concentrations after a bolus dose. The method requires no specialized equipment and no intervention once started. The method has been tested both ex vivo and in normal volunteers receiving lidocaine. Stable lidocaine plasma concentrations are rapidly achieved and maintained within the therapeutic range. Further evaluation of this approach in patients is indicated.

Direct enantiomeric resolution of mephenytoin and its N-demethylated metabolite in plasma and blood using chiral capillary gas chromatography.

A gas chromatographic method was developed for the determination of the R- and S- enantiomers of the anticonvulsant, mephenytoin, and its N-demethylated metabolite, 5-phenyl-5- ethylhydantoin ( PEH ), in plasma and blood. Direct enantiomeric separation of mephenytoin and its internal standard was obtained using a chiral capillary column ( Chirasil -Val) followed by nitrogen specific detection. However, resolution of the enantiomers of PEH and its internal standard required propylation at the 3-position of the hydantoin ring prior to analysis. Similar linear and reproducible standard curves were obtained from both plasma and blood over the concentration range 50 ng/ml to 5 micrograms/ml, and above 100 ng/ml the reproducibility was less than 8% (coefficient of variation). Pronounced stereoselective differences in the plasma concentration--time curves for both mephenytoin and PEH were observed in a normal subject who received a single oral dose of 300 mg racemic mephenytoin. The peak plasma level of S-mephenytoin was only one-fifth that of the R-enantiomer and its elimination half-life was less than 3 h compared to over 70 h for R-mephenytoin. Similarly, S- PEH levels were barely detectable whereas concentrations of R-metabolite steadily increased over 4-6 days before slowly declining.

Phenotypic differences in mephenytoin pharmacokinetics in normal subjects.

The urinary metabolic profile of mephenytoin and its oxidative metabolites indicates significant stereoselective metabolism of its two enantiomers. Also, polymorphic oxidation, which is present in about 2 to 5% of the Caucasian population, has been demonstrated by an impaired ability to 4-hydroxylate this anticonvulsant. In order to determine the consequences of such metabolism, the plasma concentration/time profiles of the enantiomers of mephenytoin and its N-demethylated metabolite, phenylethylhydantoin (PEH), were investigated after a single p.o. dose of racemic mephenytoin in normal subjects with different metabolizing ability for mephenytoin [extensive metabolizer (EM) vs. poor metabolizer (PM) phenotypes]. In the EM subjects, the disposition of S- and R-mephenytoin was markedly different with a 100- to 200-fold difference in mean oral clearance (4.7 vs. 0.027 liters/min) and a 30- to 40-fold difference in elimination half-life (2.1 vs. 76 hr). In these same subjects, R-PEH concentrations significantly accumulated over several days and then very slowly declined with an apparent half-life of about 200 hr. Plasma levels of S-PEH were essentially negligible. In contrast, the stereoselective elimination of mephenytoin was reduced markedly in subjects of the PM phenotype, with the disposition of the S-enantiomer being the same as that for R-mephenytoin, which in turn was similar to that observed for this enantiomer in EMs. Almost comparable plasma levels of S- and R-PEH were also present in PMs. Only a small amount (less than 5%) of unchanged mephenytoin was excreted in the urine regardless of phenotype.(ABSTRACT TRUNCATED AT 250 WORDS)

Oxidative metabolism of encainide: polymorphism, pharmacokinetics and clinical considerations.

The 8-h urinary metabolic profiles of encainide and its oxidized metabolites, O-desmethyl- (ODE), 3-methoxy-O-desmethyl- (MODE), N-desmethyl- (NDE) and N, O-didesmethyl- (DDE) encainide were studied in a group of 112 normal Caucasians. Nine of these subjects (8%) were defective in their ability to 4-hydroxylate debrisoquine. The cumulative frequency distribution of the 8-h recovery ratio of encainide/ODE indicated two distinct populations in complete concordance with the debrisoquine phenotyping. The subjects with an 'extensive metabolizer' (EM) phenotype had a ratio from 0.003 to 0.9 whereas the PM group had values from 7.4 to 48. In addition, no MODE was detected in the urine from 'poor metabolizers' (PM). The oxidative metabolism of encainide, specifically the O-demethylation pathway, is, therefore, polymorphically distributed and controlled by the same genetic factor(s) that determine the 4-hydroxylation of debrisoquine. In EM subjects, ODE and MODE are the major metabolites in plasma and their concentrations are much greater than those of unchanged drug. As ODE is a more potent antiarrhythmic agent than encainide and MODE is at least equipotent, these metabolites significantly contribute to the overall antiarrhythmic effect in EM patients. The low plasma concentrations of ODE and MODE in PM subjects would be expected to result in inefficacious therapy when usual doses of encainide are administered. However, in such individuals, chronic oral therapy results in accumulation of unmetabolized encainide to far higher levels than in EM subjects. As encainide itself has intrinsic antiarrhythmic activity at these concentrations, this generally results in the desired clinical response. Despite pronounced interphenotypic differences in encainide's disposition and pharmacokinetics, the polymorphic oxidative metabolism appears to have limited consequences for the drug's clinical efficacy.

Amiodarone dosing: a proposal based on its pharmacokinetics.

The available data concerning amiodarone dosing may be summarized as follows: (1) there is an empirically demonstrated improvement in lag before onset of antiarrhythmic effect if amiodarone is given initially in large "loading" doses. (2) A regimen such as that described in this article may allow more predictable and safe therapy and should be evaluated in patients, in order to develop uniform dosing guidelines. (3) Amiodarone clearance appears to decrease with time, and for this reason guidance of long-term therapy by plasma concentration determinations could potentially improve safety and efficacy. However, a close correlation between drug levels and drug toxicity and efficacy is lacking. (4) Finally, plasma concentrations, although potentially useful for monitoring long-term therapy, are likely to be unhelpful or misleading during the 4- to 6-week loading period at the beginning of treatment.

Polymorphism of propafenone metabolism and disposition in man: clinical and pharmacokinetic consequences.

The relationship between debrisoquine metabolic phenotype and the pharmacokinetics and pharmacodynamics of propafenone was studied in 28 patients with chronic ventricular arrhythmias (22 extensive metabolizers [EMs] and six poor metabolizers [PMs] of debrisoquine). EMs were characterized by a shorter propafenone elimination half-life (5.5 +/- 2.1 vs 17.2 +/- 8.0, p less than .001), lower average plasma concentration (Cp) (1.1 +/- 0.6 vs 2.5 +/- 0.5 ng/ml/mg daily dosage, p less than .001), and higher oral clearance (1115 +/- 1238 vs 264 +/- 48 ml/min, p less than .001). The active metabolite 5-hydroxypropafenone, assayed in 12 patients, was identified in nine of 10 EMs but in neither of the PMs. A lower incidence of central nervous system side effects was noted in EMs (14% vs 67%, p less than .01). The magnitude of QRS widening at any given propafenone Cp was greater in EMs than PMs. There was no significant difference between EMs and PMs in effective propafenone dose or frequency of antiarrhythmic response. Inhibition of debrisoquine 4-hydroxylation by propafenone was demonstrated both in vivo and in a human liver microsomal system in vitro. We conclude that propafenone is metabolized via the same cytochrome P-450 responsible for debrisoquine's 4-hydroxylation, and that its pharmacokinetics and concentration-response relationships and the incidence of central nervous system side effects are different in patients of different debrisoquine metabolic phenotype.