Differential effects of oral contraceptive steroids on the metabolism of benzodiazepines

Navigating the complex landscape of benzodiazepine- and Z-drug diversity: insights from comprehensive FDA adverse event reporting system analysis and beyond

Introduction

Medications which target benzodiazepine (BZD) binding sites of GABAA receptors (GABAARs) have been in widespread use since the nineteen-sixties. They carry labels as anxiolytics, hypnotics or antiepileptics. All benzodiazepines and several nonbenzodiazepine Z-drugs share high affinity binding sites on certain subtypes of GABAA receptors, from which they can be displaced by the clinically used antagonist flumazenil. Additional binding sites exist and overlap in part with sites used by some general anaesthetics and barbiturates. Despite substantial preclinical efforts, it remains unclear which receptor subtypes and ligand features mediate individual drug effects. There is a paucity of literature comparing clinically observed adverse effect liabilities across substances in methodologically coherent ways.

Methods

In order to examine heterogeneity in clinical outcome, we screened the publicly available U.S. FDA adverse event reporting system (FAERS) database for reports of individual compounds and analyzed them for each sex individually with the use of disproportionality analysis. The complementary use of physico-chemical descriptors provides a molecular basis for the analysis of clinical observations of wanted and unwanted drug effects.

Results and Discussion

We found a multifaceted FAERS picture, and suggest that more thorough clinical and pharmacoepidemiologic investigations of the heterogenous side effect profiles for benzodiazepines and Z-drugs are needed. This may lead to more differentiated safety profiles and prescription practice for particular compounds, which in turn could potentially ease side effect burden in everyday clinical practice considerably. From both preclinical literature and pharmacovigilance data, there is converging evidence that this very large class of psychoactive molecules displays a broad range of distinctive unwanted effect profiles - too broad to be explained by the four canonical, so-called "diazepam-sensitive high-affinity interaction sites". The substance-specific signatures of compound effects may partly be mediated by phenomena such as occupancy of additional binding sites, and/or synergistic interactions with endogenous substances like steroids and endocannabinoids. These in turn drive the wanted and unwanted effects and sex differences of individual compounds.

Drug-drug interactions that alter the exposure of glucuronidated drugs: Scope, UDP-glucuronosyltransferase (UGT) enzyme selectivity, mechanisms (inhibition and induction), and clinical significance

Drug-drug interactions (DDIs) arising from the perturbation of drug metabolising enzyme activities represent both a clinical problem and a potential economic loss for the pharmaceutical industry. DDIs involving glucuronidated drugs have historically attracted little attention and there is a perception that interactions are of minor clinical relevance. This review critically examines the scope and aetiology of DDIs that result in altered exposure of glucuronidated drugs. Interaction mechanisms, namely inhibition and induction of UDP-glucuronosyltransferase (UGT) enzymes and the potential interplay with drug transporters, are reviewed in detail, as is the clinical significance of known DDIs. Altered victim drug exposure arising from modulation of UGT enzyme activities is relatively common and, notably, the incidence and importance of UGT induction as a DDI mechanism is greater than generally believed. Numerous DDIs are clinically relevant, resulting in either loss of efficacy or an increased risk of adverse effects, necessitating dose individualisation. Several generalisations relating to the likelihood of DDIs can be drawn from the known substrate and inhibitor selectivities of UGT enzymes, highlighting the importance of comprehensive reaction phenotyping studies at an early stage of drug development. Further, rigorous assessment of the DDI liability of new chemical entities that undergo glucuronidation to a significant extent has been recommended recently by regulatory guidance. Although evidence-based approaches exist for the in vitro characterisation of UGT enzyme inhibition and induction, the availability of drugs considered appropriate for use as 'probe' substrates in clinical DDI studies is limited and this should be research priority.

Drug Interactions Involving 17α-Ethinylestradiol: Considerations Beyond Cytochrome P450 3A Induction and Inhibition

It is widely acknowledged that drug-drug interactions (DDIs) involving estrogen (17α-ethinylestradiol (EE))-containing oral contraceptives (OCs) are important. Consequently, sponsors of new molecular entities (NMEs) often conduct clinical studies with priority given to OCs as victims of cytochrome P450 (CYP) 3A (CYP3A) induction and inhibition. Such scenarios are reflected in the US Food and Drug Administration-issued guidance documentation related to OC DDI studies. Although CYP3A is important, OCs such as EE are metabolized by sulfotransferase 1E1 and UDP-glucuronosyltransferase (UGT) 1A1, expressed in the gut and liver, and so both can also serve as loci of victim OC DDI. Therefore, for any NME, one should carefully consider its induction and inhibition profile involving CYP3A4/5, UGT1A1, and SULT1E1. As DDI perpetrators, available clinical DDI data indicate that EE-containing OCs can induce (e.g., UGT1A4 and CYP2A6) and inhibit (CYP1A2 ≥ CYP2C19 > CYP3A4/5 > CYP2C8, CYP2B6, CYP2D6, and CYP2C9) various CYP forms. Although available in vitro CYP inhibition data do not explain such a graded inhibitory effect in vivo, it is hypothesized that EE differentially modulates CYP expression via potent agonism of the estrogen receptor expressed in the gut and liver. From the standpoint of the NME as potential OC DDI victim, therefore, it is important to assess its projected (pre-phase I) or known therapeutic index and pharmacokinetic profile (fraction absorbed, absolute oral bioavailability, clearance/extraction class, fraction metabolized by CYP1A2, CYP2C19, CYP2A6, and UGT1A4). Such information can enable the prioritization, design, and interpretation of NME-OC DDI studies.

Drug-Drug Interaction Studies With Oral Contraceptives: Pharmacokinetic/Pharmacodynamic and Study Design Considerations

Oral contraceptives (OCs) are the most widely used form of birth control among women of childbearing potential. Knowledge of potential drug-drug interactions (DDIs) with OCs becomes imperative to provide information on the medication to women of childbearing potential and enable their inclusion in clinical trials, especially if the new molecular entity is a teratogen. Although a number of DDI guidance documents are available, they do not provide recommendations for the design and conduct of OC DDI studies. The evaluation of DDI potential of a new molecular entity and OCs is particularly challenging because of the availability of a wide variety of combinations of hormonal contraceptives, different doses of the ethinyl estradiol, and different metabolic profiles of the progestin component. The aim of this review is to comprehensively discuss factors to be considered such as pharmacokinetics (PK), pharmacodynamics (PD), choice of OC, and study population for the conduct of in vivo OC DDI studies. In this context, metabolic pathways of OCs, the effect of enzyme inhibitors and inducers, the role of sex hormone-binding globulin in the PK of progestins, current evidence on OC DDIs, and the interpretation of PD end points are reviewed. With the emergence of new tools like physiologically based PK modeling, the decision to conduct an in vivo study can be made with much more confidence. This review provides a comprehensive overview of various factors that need to be considered in designing OC DDI studies and recommends PK-based DDI studies with PK end points as adequate measures to establish clinical drug interaction and measurement of PD end points when there is basis for PD interaction.

Drug interactions between hormonal contraceptives and psychotropic drugs: a systematic review

OBJECTIVE

To examine whether the co-administration of hormonal contraceptives (HC) and psychotropic drugs commonly used to treat anxiety and/or depression results in safety or efficacy concerns for either drug.

METHODS

We searched PubMed and Cochrane libraries for clinical or pharmacokinetic (PK) studies that examined co-administration of any HC with psychotropic drugs [selective serotonin reuptake inhibitors (SSRIs), serotonin-norepinephrine reuptake inhibitors (SNRIs), tricyclic antidepressants (TCAs), oral benzodiazepines, bupropion, mirtazapine, trazadone, buspirone, hydroxyzine, monoamine oxidase inhibitors (MAOIs), or atypical antipsychotics] in reproductive aged women.

RESULTS

Of 555 articles identified, 22 articles (18 studies) met inclusion criteria. We identified 5 studies on SSRIs, four on TCAs, one on bupropion, three on atypical antipsychotics and five on oral benzodiazepines. No articles met inclusion criteria for SNRIs, mirtazapine, trazadone, buspirone, hydroxyzine or MAOIs. Overall, clinical studies did not demonstrate differences in unintended pregnancy rates when HCs were administered with and without psychotropic drugs or in psychotropic drug treatment outcomes when psychotropic drugs were administered with and without HCs. PK studies did not demonstrate changes in drug exposure related to contraceptive safety, contraceptive effectiveness or psychotropic drug effectiveness for most classes of psychotropic drugs. However, limited PK data raise concern for HCs increasing systemic exposure of amitriptyline and imipramine (both TCAs), theoretically posing safety concerns.

CONCLUSION

Limited quality and quantity evidence on use of psychotropic drugs and HCs suggests low concern for clinically significant interactions, though no data exist specifically for non-oral formulations of HC. Given the high frequency of use for both HCs and psychotropic drugs among reproductive-age women in the US, this review highlights a need for further research in this area.

The effect of oral contraceptives on the pharmacokinetics of melatonin in healthy subjects with CYP1A2 g.-163C>A polymorphism

The effect of oral contraceptives (OCs) on melatonin metabolism was studied in 29 subjects genotyped for CYP1A2 SNP g.-163C>A polymorphism. Plasma melatonin and 6-OH-melatonin concentrations were measured after a 6-mg dose of melatonin using a validated liquid chromatography/mass spectrometry method. The mean melatonin AUC and C(max) values were 4- to 5-fold higher in OC users than in non-OC users (P < .0001), whereas the weight-adjusted clearance was significantly lower in OC users (P < .0001). No significant difference in melatonin pharmacokinetics between the genotypes and no additional effect by the genotype on the OC-induced increase in melatonin exposure were evident. Melatonin exposure had no significant effect on the subjects' state of alertness. In conclusion, a significant inhibitory effect of OCs on the CYP1A2-catalyzed melatonin metabolism was seen; thereby, OC use can alter CYP1A2-phenotyping results.

Mechanisms of Pharmacokinetic and Pharmacodynamic Drug Interactions Associated with Ritonavir-Enhanced Tipranavir

Tipranavir is a nonpeptidic protease inhibitor that has activity against human immunodeficiency virus strains resistant to multiple protease inhibitors. Tipranavir 500 mg is coadministered with ritonavir 200 mg. Tipranavir is metabolized by cytochrome P450 (CYP) 3A and, when combined with ritonavir in vitro, causes inhibition of CYP1A2, CYP2C9, CYP2C19, CYP2D6, and CYP3A in addition to induction of glucuronidase and the drug transporter P-glycoprotein. As a result, drug-drug interactions between tipranavir-ritonavir and other coadministered drugs are a concern. In addition to interactions with other antiretrovirals, tipranavir-ritonavir interactions with antifungals, antimycobacterials, oral contraceptives, statins, and antidiarrheals have been specifically evaluated. For other drugs such as antiarrhythmics, antihistamines, ergot derivatives, selective serotonin receptor agonists (or triptans), gastrointestinal motility agents, erectile dysfunction agents, and calcium channel blockers, interactions can be predicted based on studies with other ritonavir-boosted protease inhibitors and what is known about tipranavir-ritonavir CYP and P-glycoprotein utilization. The highly complex nature of drug interactions dictates that cautious prescribing should occur with narrow-therapeutic-index drugs that have not been specifically studied. Thus, the known interaction potential of tipranavir-ritonavir is reported, and in vitro and in vivo data are provided to assist clinicians in predicting interactions not yet studied. As more clinical interaction data are generated, better insight will be gained into the specific mechanisms of interactions with tipranavir-ritonavir.

Pharmacokinetic Drug Interactions Involving 17??-Ethinylestradiol

17alpha-Ethinylestradiol (EE) is widely used as the estrogenic component of oral contraceptives (OC). In vitro and in vivo metabolism studies indicate that EE is extensively metabolised, primarily via intestinal sulfation and hepatic oxidation, glucuronidation and sulfation. Cytochrome P450 (CYP)3A4-mediated EE 2-hydroxylation is the major pathway of oxidative metabolism of EE. For some time it has been known that inducers of drug-metabolising enzymes (such as the CYP3A4 inducer rifampicin [rifampin]) can lead to breakthrough bleeding and contraceptive failure. Conversely, inhibitors of drug-metabolising enzymes can give rise to elevated EE plasma concentrations and increased risks of vascular disease and hypertension. In vitro studies have also shown that EE inhibits a number of human CYP enzymes, such as CYP2C19, CYP3A4 and CYP2B6. Consequently, there are numerous reports in the literature describing EE-containing OC formulations as perpetrators of pharmacokinetic drug interactions. Because EE may participate in multiple pharmacokinetic drug interactions as either a victim or perpetrator, pharmaceutical companies routinely conduct clinical drug interaction studies with EE-containing OCs when evaluating new chemical entities in development. It is therefore critical to understand the mechanisms underlying these drug interactions. Such an understanding can enable the interpretation of clinical data and lead to a greater appreciation of the profile of the drug by physicians, clinicians and regulators. This article summarises what is known of the drug-metabolising enzymes and transporters governing the metabolism, disposition and excretion of EE. An effort is made to relate this information to known clinical drug-drug interactions. The inhibition and induction of drug-metabolising enzymes by EE is also reviewed.

Drug glucuronidation in clinical psychopharmacology

Glucuronidation is a phase II metabolic process and one of the most common pathways in the formation of hydrophilic drug metabolites. At least 33 families of uridine diphosphate-glucuronosyltransferases have been identified in vitro, and specific nomenclature similar to that used to classify the cytochrome (CYP) P450 system has been established. The UGT1 and UGT2 subfamilies represent the most important of these enzymes in human drug metabolism. Factors affecting glucuronidation include the following: cigarette smoking, obesity, age, and gender. In addition, several drugs have been found in vitro to be substrates, inhibitors, or inducers of UGT enzymes. Induction or inhibition of both UGT and CYP isoforms may occur simultaneously. Some important drug interactions involving glucuronidation have been documented and others can be postulated. This review summarizes the relevant literature pertaining to drug glucuronidation and its implications for clinical psychopharmacology.

Serum time course of naltrexone and 6 beta-naltrexol levels during long-term treatment in drug addicts

The pharmacokinetics of naltrexone have been scarcely explored in patients during chronic treatment despite the observation that the pharmacological effect of the drug is related to its plasma concentrations. In this study we investigated the time course of serum levels of naltrexone and its active metabolite, 6 beta-naltrexol, in 13 heroin addicts (3 F, 10 M; age 22-32 years) in the 24 h after 100 mg of naltrexone orally. Six patients were studied once, at different times during chronic treatment, whereas in seven patients the study was done at the beginning and after 1 month of naltrexone treatment. Four of these patients also repeated the study after 3 months of naltrexone treatment. Serum naltrexone and 6 beta-naltrexol were assayed by GLC with a nitrogen-phosphorus detector. Our results showed large differences among patients in serum naltrexone and 6 beta-naltrexol levels. On the other hand, there were no differences in serum time course of both substances in the same patient over 3 months. Peak levels and AUCs of naltrexone were lower than those of 6 beta-naltrexol in ten addicts and higher than those of the metabolite in three patients. No significant differences in the apparent half-lives of the two drugs were detected among groups. These data are consistent with the occurrence of a decreased first-pass metabolism of naltrexone in three patients leading to a larger availability of an oral dose. The increased bioavailability of the drug is not very important for opioid receptor antagonist activity but may play a role in naltrexone treatment safety.

Influence of oral contraceptive use and cigarette smoking, alone and together, on antipyrine pharmacokinetics

The pharmacokinetics of antipyrine following a single 1-g intravenous dose was determined in 63 healthy women. Subjects were divided into 4 groups as follows: 1) cigarette smokers using low-dose oral contraceptives (n = 15); 2) nonsmokers using low-dose oral contraceptives (n = 12); 3) cigarette smokers not using oral contraceptives (n = 10); and 4) controls, neither cigarette smokers nor oral contraceptive users. Plasma antipyrine concentrations during 24 to 48 hours after dosage were measured by high-performance liquid chromatography. Mean kinetic variables in the nonsmoking, non-oral contraceptive using control group were: volume of distribution, 37.7 L; elimination half-life, 13.2 hours; and clearance, 34.4 mL/min. In cigarette smoking, non-oral contraceptive users versus controls, elimination half-life was reduced (8.0 vs. 13.2 hours, P < 0.05) and clearance increased (56.0 vs. 34.4 mL/min, P < 0.05). In nonsmoker oral contraceptive users, the reverse was true (elimination half-life was significantly increased: 16.6 vs. 13.2 hours, P < 0.05; and clearance was significantly decreased: 24.8 vs. 34.4 mL/min, P < 0.05). In smokers who were using oral contraceptives, values were not significantly different from controls (elimination half-life, 11.2 hours; clearance, 39.5 mL/min). Volume of distribution did not differ among the four groups. Thus the opposing effects on antipyrine clearance of the induction of metabolism by cigarette smoking and the inhibition due to low dose oral contraceptive use in effect negate each other when combined in humans.

Oral contraceptive effects on methylprednisolone pharmacokinetics and pharmacodynamics

OBJECTIVE

Oral contraceptive (OC) steroids alter the disposition of numerous drugs, including corticosteroids. We investigated the pharmacokinetics and pharmacodynamics of methylprednisolone.

METHODS

Twelve women (six women used OC steroids and six women did not) received intravenous methylprednisolone (0.6 mg/kg ideal body weight). Methylprednisolone disposition was assessed from plasma concentrations. Pharmacodynamic parameters measured were plasma cortisol, whole blood histamine (reflecting basophils), and blood helper T lymphocytes.

RESULTS

Methylprednisolone clearance was significantly decreased in the women who used OC steroids (0.298 versus 0.447 L/hr/kg), resulting in a longer elimination half-life (2.20 versus 1.72 hours). With use of indirect response models, significant differences were observed with the cortisol and basophil responses. A larger value for the concentration that inhibits the zero-order production rate by 50% (0.37 versus 0.11 ng/ml) was observed in the women who used OC steroids for suppression of cortisol secretion, indicating less sensitivity to the suppressive effects of methylprednisolone. Greater net suppression of basophils was observed in the users of OC steroids (area under the response curve, 694 versus 401 ng x hr/ml). No differences were observed for helper T-cell responses.

CONCLUSION

OC steroids appear to inhibit methylprednisolone metabolism. However, mixed changes in several responses occur, indicating that women can probably receive similar doses of methylprednisolone irrespective of OC steroid use.

Pharmacokinetic considerations in the adolescent: non-cytochrome P450 metabolic pathways

The non-oxidative metabolic reactions of methylation, acetylation, sulfation, glucuronidation, conjugation with amino acids (primarily with glycine), glutathione conjugation and esterase hydrolysis function to detoxify and enhance the elimination of drugs and pro-drugs, many of them as phase II reactions subsequent to oxidation. While the influence of maturation has been recognized in the development of hepatic oxidative capacity and specific pathways studied, considerably less attention has focused on the maturational effect in non-oxidative metabolism despite its role in drug deactivation, detoxification, and elimination. Consequently phase II metabolic capacities during adolescence remain primarily speculative. Conflicting data about one of these pathways, glucuronidation, suggest unexplored puberty- or gender-related phenomena influencing function in this system.

Pharmacokinetics of droloxifene in mice, rats, monkeys, premenopausal and postmenopausal patients

The pharmacokinetics of droloxifene have been studied in female mice, rats, monkeys, and premenopausal and postmenopausal patients. Droloxifene was rapidly and almost completely absorbed after oral dosing. The bioavailability was 8% in mice, 18% in rats and 11% in monkeys due to extensive first-pass metabolism. Droloxifene is widely distributed as demonstrated by its large volume of distribution and the fact that radioactivity in most tissues and organs was higher than in the blood. After oral dosing, the serum and plasma concentrations of unchanged drug declined with terminal half-lives of 1.6 h in mice, 4.3 h in rats, 10.6 h in monkeys and 25 h in patients. The systemic clearance was in the order of mice > rats > monkeys, and nearly equalled the hepatic blood flow in each species. Most of the 14C from [14C]-droloxifene administered orally and i.v. to rats and monkeys was excreted in the faeces. Droloxifene was metabolized extensively by phase I and phase II metabolism. 3-methoxy-4-hydroxy droloxifene was the major metabolite in rat faeces. The metabolites in rat and monkey faeces were not so different qualitatively. Pharmacokinetic parameters were not significantly different between premenopausal and postmenopausal patients.

Factors and conditions affecting the glucuronidation of oxazepam

The aim of the present work was to investigate the impact of disease states and environmental and host factors on the glucuronidation of oxazepam. Glucuronidation represents quantitatively one of the most important metabolic conjugation pathways (phase II) in man for the inactivation and detoxication of xenobiotics and endogenous compounds and the liver is the major site for it to take place. Far less attention has been paid to the conjugation reactions in previous clinical research in this field compared to the immense interest in the oxidative biotransformation pathways (phase I). This fact is mainly due to the latter giving rise to active or reactive metabolites with a toxicological potential. The metabolism of oxazepam expresses exclusively the capacity for glucuronide formation. It was a prerequisite to establish the bioavailability of oxazepam prior to succeeding studies on the oral disposition of the drug. A preparation for intravenous administration was created. Clearance was chosen as measurement of the capacity to glucuronidate oxazepam. Severe decompensated liver disease was associated with a significant decrease in oxazepam clearance, that became even more obvious when corrected for by a diminished binding to plasma proteins. This increase in free fraction of oxazepam was substantial and could mainly be accounted for by low plasma albumin values. The results are in part a settlement with earlier studies on glucuronidation in liver disease and they may undoubtedly be ascribed to the severe degree of liver disease. For the first time it was shown that hypothyroidism led to a decline in the clearance and metabolism of oxazepam and paracetamol that is mainly biotransformed by glucuronidation. It was concluded that the enzymes responsible for glucuronidation in hypothyroidism are under the influence of thyroid hormones as is the case with oxidative enzymes. Further studies focused on the effect of host and environmental factors on glucuronidation. A commercially available very low calorie product for the treatment of obesity resulted in a decrease in oxazepam clearance and a lack of co-factors as a consequence of the low calorie intake was explanatorily proposed. Beta-adrenoceptor antagonists are often prescribed together with other drugs and close knowledge on interactions is mandatory but insufficient in regard of drugs being glucuronidated. Despite the mutual metabolic pathway labetalol exerted no dispositional alterations concerning oxazepam. It was moreover suggested that very elderly subjects between the age of 80 to 94 years had a reduced clearance of oxazepam.(ABSTRACT TRUNCATED AT 400 WORDS)

Drug glucuronidation in humans

Glucuronidation is a major metabolic pathway for a large number of drugs in humans. Conjugation of drugs and other chemicals with glucuronic acid is catalyzed by the multigene UDP-glucuronosyltransferase family. It is believed that a number (unspecified at present) of glucuronosyltransferase isozymes, which probably differ in terms of substrate specificity and regulation, contribute to drug glucuronidation. Factors known to influence the pharmacokinetics of glucuronidated drugs in man, presumably via an effect on specific glucuronosyltransferases, include age (especially the neonatal period), cigarette smoking, diet, certain disease states, coadministered drugs, ethnicity, genetics and hormonal effects.

Influence of oral contraceptives on drug therapy

Interferences between drugs and oral contraceptives are considered to alter pharmacokinetics and thus the efficacy of steroidal hormones. It should be noted, however, that steroids can also modify the metabolism and pharmacodynamic effects of various substances. To the present knowledge, phase I (i.e., oxidation, demethylation) and phase II reactions (conjugation) are concerned. Drugs sharing those enzymatic systems with oral contraceptives experience either an increase in bioavailability by inhibition of oxidative metabolism or undergo accelerated elimination by induced conjugation. Such interaction may be of practical interest in subjects who take oral contraceptives and are simultaneously treated with antidepressants, antihypertensives, insulin, synthetic glucocorticoids, theophylline, and caffeine.

Glucuronidation of 7-hydroxy-4-methylcoumarin by human liver microsomes. Inhibition by certain drugs

Glucuronidation of 7-hydroxy-4-methylcoumarin (7-OH-4-MC) was comparable in three of the four human liver samples studied. In liver sample IV the glucuronidation rate of 7-OH-4-MC was almost 40% of that in the other samples. That might be due to interindividual variation in the capacity to glucuronidate. Glucuronidation rates were not reduced in the one human liver sample which displayed mild centrilobular cholestasis on histopathology. Furosemide (FR), salicylic acid (SA), lorazepam (Z) and menthol (MT) inhibited the glucuronidation of 7-OH-4-MC to varying degrees (30-90%). Paracetamol (PA) and 5-hydroxytryptamine (HT) were not inhibitors of the glucuronidation of 7-OH-4-MC. These findings suggest the presence of other UDP-glucuronosyltransferase (UDPGT) isozymes in the human liver microsomes which are responsible for the glucuronidation of PA and HT than those which glucuronidate 7-OH-4-MC.

Pharmacokinetic drug interactions with oral contraceptives

Oral contraceptive steroids are used by an estimated 60 to 70 million women world-wide. Over the past 20 years there have been both case reports and clinical studies on the topic of drug interactions with these agents. Some of the interactions are of definite therapeutic relevance, whereas others can be discounted as being of no clinical significance. Pharmacological interactions between oral contraceptive steroids and other compounds may be of 2 kinds: (a) drugs may impair the efficacy of oral contraceptive steroids, leading to breakthrough bleeding and pregnancy (in a few cases, the activity of the contraceptive is enhanced); (b) oral contraceptive steroids may interfere with the metabolism of other drugs. A number of anticonvulsants (phenobarbital, phenytoin, carbamazepine) are enzyme-inducing agents and thereby increase the clearance of the oral contraceptive steroids. Valproic acid has no enzyme-inducing properties, and thus women on this anticonvulsant can rely on their low dose oral contraceptive steroids for contraceptive protection. Researchers are now beginning to unravel the molecular basis of this interaction, with evidence of specific forms of cytochrome P450 (P450IIC and IIIA gene families) being induced by phenobarbital. Rifampicin, the antituberculous drug, also induces a cytochrome P450 which is a product of the P450IIIA gene subfamily. This isozyme is one of the major forms involved in 2-hydroxylation of ethinylestradiol. Broad spectrum antibiotics have been implicated in causing pill failure; case reports document the interaction, and general practitioners are convinced that it is real. The problem remains that there is still no firm clinical pharmacokinetic evidence which indicates that blood concentrations of oral contraceptive steroids are altered by antibiotics. However, perhaps this should not be a surprise, given that the incidence of the interaction may be very low. It is suggested that an individual at risk will have a low bioavailability of ethinylestradiol, a large enterohepatic recirculation and gut flora particularly susceptible to the antibiotic being used. Two drugs, ascorbic acid (vitamin C) and paracetamol (acetaminophen), give rise to increased blood concentrations of ethinylestradiol due to competition for sulphation. The interactions could have some significance to women on oral contraceptive steroids who regularly take high doses of either drug. Although on theoretical grounds adsorbents (e.g. magnesium trisilicate, aLuminium hydroxide, activated charcoal and kaolin) could be expected to interfere with oral contraceptive efficacy, there is no firm evidence that this is the case. Similarly, there is no evidence that smoking alters the pharmacokinetics of oral contraceptive steroids. These agents are now well documented as being able to alter the pharmacokinetics of other concomitantly administered drugs.(ABSTRACT TRUNCATED AT 400 WORDS)

Doxylamine and diphenhydramine pharmacokinetics in women on low-dose estrogen oral contraceptives

Thirteen women chronically using low-dose estrogen-containing oral contraceptives (50 micrograms or less of ethinyl estradiol or its equivalent for a minimum of 3 months) and 12 age-matched drug-free control women received a single 25 mg oral dose of doxylamine succinate in the fasting state. Ten women taking oral contraceptives and ten controls received a single 50 mg oral dose of diphenhydramine hydrochloride. Multiple plasma samples drawn during 30 hours following the dose of doxylamine, and 12 hours after diphenhydramine dosage, were analyzed by gas chromatography using nitrogen-phosphorus detection. Mean pharmacokinetic variables for doxylamine in control and oral contraceptive groups were: peak plasma concentration, 103 vs 100 ng/ml; time of peak, 2.40 vs 1.87 hours after dosage, elimination half-life, 10.1 vs 10.2 hours; and total clearance, 3.70 vs 3.88 ml/min/kg. Mean pharmacokinetic variables for diphenhydramine in control and oral contraceptive groups were: peak plasma concentration, 63.7 vs 73.8 ng/ml; time of peak, 2.7 vs 2.2 hours after dosage; elimination half-life, 6.0 vs 5.1 hours; and total clearance, 21.8 vs 25.5 ml/min/kg. None of these differences were statistically significant. Thus, low-dose estrogen-containing oral contraceptives do not significantly influence the pharmacokinetics of the antihistamines doxylamine or diphenhydramine.

Antipyrine pharmacokinetics in women receiving conjugated estrogens

The pharmacokinetics of a single 1.0 to 1.2-g intravenous dose of antipyrine was studied in 22 healthy female volunteers aged 28 to 70 years (mean, 45 years). Eleven subjects had been taking a conjugated estrogen preparation for at least 3 months; the other 11 subjects who were not taking conjugated estrogens and who were matched for age, weight, and smoking patterns, served as a control group. Plasma antipyrine concentrations were determined by high-pressure liquid chromatography (HPLC) in multiple plasma samples drawn 24 to 48 hours after dosage. Mean +/- SE pharmacokinetic variables in control and conjugated-estrogen groups were volume of distribution, 0.57 +/- 0.02 versus 0.56 +/- 0.02 L/kg; elimination half-life, 11.0 +/- 0.82 versus 12.6 +/- 0.89 hours; and clearance, 0.63 +/- 0.06 versus 0.54 +/- 0.03 mL/min/kg. None of the differences was significant. Although antipyrine clearance is significantly impaired by oral contraceptives, there is no evidence of altered antipyrine pharmacokinetics from treatment with conjugated estrogens.

Alprazolam pharmacokinetics in women on low-dose oral contraceptives

Sixteen women chronically using low-dose estrogen-containing oral contraceptive steroids (OCs) and 23 drug-free control women received a single 1-mg oral dose of alprazolam. Multiple plasma samples drawn during 48 hours after the dose were analyzed by electron-capture gas-liquid chromatography. There were no significant differences between controls and oral contraceptive users in alprazolam volume of distribution (1.27 versus 1.39 L/kg), elimination half-life (11.9 versus 12.3 hours), total clearance (1.36 versus 1.39 mL/min/kg), or total area under the plasma concentration versus time curve (227 versus 243 ng/mL X hr). Alprazolam free fraction in plasma was slightly but significantly greater in the oral contraceptive group as opposed to the control group (28.4 versus 27.0% unbound), respectively. However, comparison of free clearance between groups revealed no significant difference (4.61 versus 4.89 mL/min/kg, respectively). Thus, low-dose estrogen-containing oral contraceptives do not significantly influence the metabolic clearance of alprazolam.

Pharmacokinetics of oxaprozin in women receiving conjugated estrogen

The kinetics of a single 1200 mg oral dose of oxaprozin, a nonsteroidal antiinflammatory agent of the propionic acid class, was studied in 22 healthy female volunteers aged 21 to 64 years. Eleven subjects had been taking a conjugated estrogen preparation for at least 3 months; the other 11 subjects served as control women who were not taking conjugated estrogens. Mean pharmacokinetic variables in control and conjugated estrogen groups were: volume of distribution, 15.1 vs 14.1 l; elimination half-life, 59.8 vs 54.2 h; clearance, 3.2 vs 3.1 ml/min; peak plasma concentration, 84.8 vs 90.7 micrograms/ml, respectively. None of the differences were significant. However, the time of peak concentration (8.9 vs 4.0 h) was significantly longer in the control group than in the conjugated estrogen group, respectively (p less than 0.05). Oxaprozin clearance, accomplished by a combination of oxidation and conjugation, is unimpaired by coadministration of conjugated estrogens.

Impairment of caffeine clearance by chronic use of low-dose oestrogen-containing oral contraceptives

The effect of chronic (greater than 3 months) administration of low-dose oestrogen-containing (less than 50 micrograms oestrogen) oral contraceptives (OCS) on the pharmacokinetics of caffeine has been examined in a treated females matched with 9 non-smoking, drug-free, healthy control females of similar age, weight and ethnic origin. Each subject received 162 mg caffeine base orally after an overnight fast. OCS subjects had a prolonged elimination half-life of caffeine, (mean 7.88 h vs 5.37 h in the controls). This was the result of marked impairment of the plasma clearance of caffeine (1.05 vs 1.75 ml/min/kg, respectively) with no change in apparent volume of distribution (0.685 in OCS vs 0.7501/kg in the control group). The absorption parameters determined were peak plasma caffeine concentration (3.99 vs 4.09 micrograms/ml) and time to peak concentration after drug administration (1.52 vs 0.79), which was moderately prolonged in OCS users. Thus, caffeine clearance, previously reported to be a specific marker of cytochrome P-448 activity in man, is decreased by chronic OCS use. This suggests that OCS may cause significant impairment of this enzyme activity as assessed in vivo. With chronic caffeine consumption, OCS users are predicted to have an increased steady-state plasma caffeine concentration as compared to non-OCS users.

Benzodiazepine drug-drug interactions commonly occurring in clinical practice

Pharmacokinetic drug-drug interactions which involve currently available benzodiazepines may be classified into two major categories: interactions which affect benzodiazepine rate of absorption, and interactions which affect clearance and, therefore, elimination half-life. Ethanol is the prototype for absorptive interactions. Concurrent ethanol use and oral ingestion of benzodiazepine derivatives uniformly slows the rate but does not change the extent of benzodiazepine absorption. Interactions which affect benzodiazepine clearance affect only those derivatives which are oxidatively metabolized or cleared as a function of hepatic blood flow (high first-pass clearance). Conjugated benzodiazepines are not implicated in such interactions. Rifampin and chronic ethanol use induce benzodiazepine oxidation, while cimetidine, oral contraceptives, ethanol (acute ingestion), disulfiram, isoniazid, and propranolol inhibit benzodiazepine oxidation. In addition, ethanol, cimetidine and isoniazid decrease first-pass hepatic extraction of triazolam, enhancing its systemic availability and decreasing oral clearance. The pharmacokinetic consequence of induction of benzodiazepine oxidation is higher clearance and decreased steady-state concentrations during chronic dosing. Conversely, inhibition of benzodiazepine oxidation decreases clearance and increases steady-state benzodiazepine concentrations during chronic dosing. Because a correlation of benzodiazepine plasma concentration and pharmacological effect is not established, the pharmacodynamic consequences of these interactions are not currently well characterized.