Elimination Of Phenytoin Research Articles

Participation of Monocarboxylate Transporter 8, But Not P-Glycoprotein, in Carrier-Mediated Cerebral Elimination of Phenytoin across the Blood-Brain Barrier.

In this study, we investigated in detail the transport of phenytoin across the blood-brain barrier (BBB) to identify the transporter(s) involved in BBB-mediated phenytoin efflux from the brain. We evaluated the brain-to-blood efflux transport of phenytoin in vivo by determining the brain efflux index (BEI) and uptake in brain slices. We additionally conducted brain perfusion experiments and BEI studies in P-glycoprotein (P-gp)-deficient mice. In addition, we determined the mRNA expression of monocarboxylate transporter (MCT) in isolated brain capillaries and performed phenytoin uptake studies in MCT-expressing Xenopus oocytes. [14C]Phenytoin brain efflux was time-dependent with a half-life of 17min in rats and 31min in mice. Intracerebral pre-administration of unlabeled phenytoin attenuated BBB-mediated phenytoin efflux transport, suggesting carrier-mediated phenytoin efflux transport across the BBB. Pre-administration of P-gp substrates in rats and genetic P-gp deficiency in mice did not affect BBB-mediated phenytoin efflux transport. In contrast, pre-administration of MCT8 inhibitors attenuated phenytoin efflux. Moreover, rat MCT8-expressing Xenopus oocytes exhibited [14C]phenytoin uptake, which was inhibited by unlabeled phenytoin. Our data suggest that MCT8 at the BBB participates in phenytoin efflux transport from the brain to the blood.

DRESS after IV phenytoin associated with cytochrome P450 CYP2C9*3 homozygosity

Phenytoin is a first-generation antiepileptic drug, which is used in the treatment of focal seizures and as standard of care for patients with benzodiazepine-refractory status epilepticus. Elimination of phenytoin occurs primarily via CYP enzyme–dependent hepatic clearance. The first step is the para-hydroxylation from active phenytoin to inactive hydroxy-phenytoin, which is dependent on CYP2C9 and, to a lesser extent, on CYP2C19. A considerable disparity in CYP2C9 alleles exists, and the frequency varies among different ancestry groups, the CYP2C9*3 allele being less frequent in Caucasians and more frequent in Asian populations.1,2 Homozygosity for the CYP2C9*3 allele leads to a significant reduction in enzyme activity, resulting in increased plasma levels of phenytoin.3

Omeprazole inhibits oxidative drug metabolism. Studies with diazepam and phenytoin in vivo and 7-ethoxycoumarin in vitro.

The effect of treatment with omeprazole, a substituted benzimidazole, on the elimination of diazepam and phenytoin was studied in two groups of 8 subjects. Omeprazole given orally in a daily dose of 40 mg over 7 days decreased diazepam plasma clearance from 22.4 +/- 2.8 to 10.1 +/- 1.5 ml/kg X h and prolonged the half-life of diazepam from 36.9 +/- 4.1 to 85.0 +/- 14.7 h. Plasma concentrations of desmethyldiazepam, a diazepam metabolite, were reduced after omeprazole treatment. Omeprazole also reduced the plasma clearance of phenytoin from 25.1 +/- 2.0 to 21.4 +/- 1.8 ml/kg X h and prolonged its half-life from 20.7 +/- 1.9 to 26.3 +/- 2.7 h. Renal excretion of the major metabolite of phenytoin (p-hydroxyphenyl-phenyl-hydantoin) was not changed. Omeprazole did not affect the volume of distribution and the plasma protein binding of either diazepam or phenytoin. In vitro studies with human liver microsomes showed that omeprazole in equimolar concentrations (0.5 mM) was a stronger inhibitor than cimetidine of 7-ethoxycoumarin deethylase activity. These data confirm that omeprazole interferes with the elimination of other drugs by an inhibition of the drug-metabolizing monooxygenase system of the human liver.

Activated Charcoal Does Not Reduce Duration of Phenytoin Toxicity in Hospitalized Patients

Phenytoin toxicity frequently results in a prolonged inpatient admission. Several publications avow multidose activated charcoal (MDAC) will enhance the elimination of phenytoin. However, these claims are not consistent, and the mechanism of enhanced eliminaiton is unproven. The aim of this investigation is to compare the time to reach a clinical composite end point in phenytoin overdose patients treated with no activated charcoal (NoAC), single-dose activated charcoal (SDAC), and MDAC. This was a retrospective study using electronic poison center data. Patients treated in a health care facility with phenytoin concentrations >20 mg/L were included. Patients were grouped by use of SDAC, MDAC, and NoAC. The primary end points were either time to resolution of symptoms, hospital discharge, or the case was closed by a toxicologist. After applying inclusion and exclusion criteria, 132 cases were included for analysis. There were 88 NoAC, 13 SDAC, and 31 MDAC cases. The groups were similar in symptomatology, age, and chronicity of expsoure. Mean peak phenytoin concentrations (SD) were 42 mg/L (12), 41 mg/L (11), and 42 mg/L (11) for NoAC, SDAC, and MDAC, respectively. Mean time to reach the study end point was 39 hours [95% confidence interval (CI), 31-48], 52 hours (95% CI, 36-68), and 60 hours (95% CI, 45-75) for NoAC, SDAC, and MDAC, respectively. The groups appeared similar with respect to peak phenytoin concentrations and prevalence of signs and symptoms. In this observational series, the use of activated charcoal was associated with increased time to reach the composite end point of clinical improvement.

Use of multi-dose activated charcoal in phenytoin toxicity secondary to genetic polymorphism

Introduction. Phenytoin is metabolised in the liver by cytochrome (CYP)2C9 and 2C19 enzymes. Due to saturation of enzyme capacity, the elimination half-life is prolonged at supratherapeutic levels. Genetic polymorphisms of CYP2C9 and 2C19 are reasonably common and further prolong the elimination of phenytoin. There are conflicting reports regarding whether multiple-dose activated charcoal (MDAC) significantly increases the clearance of phenytoin in poisoning. Case report. We present 3 patients with phenytoin toxicity and very slow elimination secondary to reduced CYP enzyme function from genetic polymorphisms. MDAC was used in two patients and led to rapid and large reductions in the measured elimination half-lives. This is contrasted with very prolonged elimination in a third patient who did not receive MDAC. Conclusion. MDAC may play a role in the management of chronic phenytoin toxicity, especially in those with very slow endogenous elimination secondary to genetic polymorphisms.

Population pharmacokinetics of phenytoin in critically ill children

The objective was to study the population pharmacokinetics of bound and unbound phenytoin in critically ill children, including influences on the protein binding profile. A population pharmacokinetic approach was used to analyze paired protein-unbound and total phenytoin plasma concentrations (n = 146 each) from 32 critically ill children (0.08-17 years of age) who were admitted to a pediatric hospital, primarily intensive care unit. The pharmacokinetics of unbound and bound phenytoin and the influence of possible influential covariates were modeled and evaluated using visual predictive checks and bootstrapping. The pharmacokinetics of protein-unbound phenytoin was described satisfactorily by a 1-compartment model with first-order absorption in conjunction with a linear partition coefficient parameter to describe the binding of phenytoin to albumin. The partitioning coefficient describing protein binding and distribution to bound phenytoin was estimated to be 8.22. Nonlinear elimination of unbound phenytoin was not supported in this patient group. Weight, allometrically scaled for clearance and volume of distribution for the unbound and bound compartments, and albumin concentration significantly influenced the partition coefficient for protein binding of phenytoin. The population model can be applied to estimate the fraction of unbound phenytoin in critically ill children given an individual's albumin concentration.

CYP2C9 Amino Acid Residues Influencing Phenytoin Turnover and Metabolite Regio- and Stereochemistry

Phenytoin has been an effective anticonvulsant agent for over 60 years, although its clinical use is complicated by nonlinear pharmacokinetics, a narrow therapeutic index, and metabolically based drug-drug interactions. Although it is well established that CYP2C9 is the major cytochrome P450 enzyme controlling metabolic elimination of phenytoin through its oxidative conversion to (S)-5-(4-hydroxyphenyl)-5-phenylhydantoin (p-HPPH), nothing is known about the amino acid binding determinants within the CYP2C9 active site that promote metabolism and maintain the tight stereocontrol of hydroxy metabolite formation. This knowledge gap was addressed here through the construction of nine active site mutants at amino acid positions Phe100, Arg108, Phe114, Leu208, and Phe476 and in vitro analysis of the steady-state kinetics and stereochemistry of p-HPPH formation. The F100L and F114W mutants exhibited 4- to 5-fold increases in catalytic efficiency, whereas the F100W, F114L, F476L, and F476W mutants lost >90% of their phenytoin hydroxylation capacity. This pattern of effects differs substantially from that found previously for (S)-warfarin and (S)-flurbiprofen metabolism, suggesting that these three ligands bind within discrete locations in the CYP2C9 active site. Only the F114L, F476L, and L208V mutants altered phenytoin's orientation during catalytic turnover. The L208V mutant also uniquely demonstrated enhanced 6-hydroxylation of (S)-warfarin. These latter data provide the first experimental evidence for a role of the F-G loop region in dictating the catalytic orientation of substrates within the CYP2C9 active site.

Paradoxical urinary phenytoin metabolite ( S)/( R) ratios in CYP2C19*1/ *2 patients

Phenytoin (PHT) is primarily metabolized to 5-(4′-hydroxyphenyl)-5-phenylhydantoin ( p-HPPH), accounting for 67–88% of an administered dose in humans. p- HPPH is formed by the cytochrome (CYP) 450 enzymes CYP2C9 and CYP2C19, then glucuronidated and excreted into the urine. CYP2C9 catalyses the prochiral formation of ( R) and ( S)- p-HPPH, and is approximately 40 times more stereoselective towards the formation of the ( S) isomer whereas CYP2C19 is not stereoselective. Because of differential stereoselectivity, polymorphisms in the genes can alter the ( S)/( R)- p-HPPH ratios. Genotyping for CYP2C9 and CYP2C19 was accomplished by a Taqman based assay. Twelve and twenty-four hour urine samples were collected from 45 epilepsy patients taking PHT under steady-state conditions and ( S)/( R) ratios of p-HPPH were determined by chiral HPLC separation. The mean urinary ( S)/( R) ratio in the 12–24 h urine collection in subjects homozygous for CYP2C9*1/*1, CYP2C19*1/*1 was 24.2 ± 3.1( n = 21), whereas ratios in CYP2C9*1/ *2 and CYP2C9*1/ *3 subjects, were 11.1 ± 3.3( n = 7) and 2.7 ± 0.6( n = 2), respectively. One CYP2C9*2/*3 patient had a ratio of 2.1. Unexpectedly, CYP2C9*1/ *1, CYP2C19*1/ *2 subjects had a mean ( S)/( R) ratio as low as 12.9 ± 1.7( n = 12). Our results are generally consistent with single dose PHT studies. However, the ( S)/( R)- p-HPPH ratios for the CYP2C9*1/ *1, CYP2C19*1/ *2 subjects, expected to be in the range of 30–40, were only 12.9, suggesting some undetected linkage disequilibrium between CYP2C9 and CYP2C19 genes that could affect PHT elimination. Furthermore, our study suggests that measurement of urine ratios cannot be used as a marker for genotype determination.

Piperine in food: Interference in the pharmacokinetics of phenytoin

This study was carried out to explore the effect of piperine-containing food in altering the pharmacokinetics of phenytoin, an anti-epileptic drug with a narrow therapeutic index. A preliminary pharmacokinetic study was carried out in mice by administering phenytoin (10 mg) orally, with or without piperine (0.6 mg). Subsequently, oral pharmacokinetics of phenytoin was carried out in six healthy volunteers in a crossover design. Phenytoin tablet (300 mg) was given 30 minutes after ingestion of a soup (melahu rasam) with or without black pepper. A further study of intavenous pharmacokinetics of phenytoin (1 mg) in rats with or without oral pretreatment with piperine (10 mg) was also conducted. The phenytoin concentration in the serum was analyzed by HPLC. The study showed a significant increase in the kinetic estimates of Ka, AUC(0-10) and AUC(0-infinity) in the piperine-fed mice. Similarly, in human volunteers piperine increased Ka, AUC(0-48), AUC(0-infinity), and delayed elimination of phenytoin. Intravenous phenytoin in the oral piperine-treated rat group showed a significant alteration in the elimination phase indicating its metabolic blockade. The significance of this finding in epileptic patients maintained on phenytoin therapy requires further investigation. This study may also have implications in the case of other drugs having a low therapeutic index.

Effects of Paeoniae Radix, a traditional Chinese medicine, on the pharmacokinetics of phenytoin.

Phenytoin (PHT), one of the most widely prescribed antiepileptic drugs, has been reported to be associated with numerous drug-drug interactions. However, there are far fewer reports about the pharmacokinetic interactions between PHT and traditional Chinese medicines (TCMs). Paeoniae Radix (PR), one of the well-known TCMs, is used as an adjunct in some epileptic patients. In the present work, we studied the influences of PR on the pharmacokinetics of PHT in rats to identify the possible interactions between PR and PHT. A single dose of PHT (100 mg/kg) alone or in combination with PR extract (300 mg/kg) was administered by gavage to male SD rats. Serial blood samples of PHT were obtained for up to 24 h post-administration and measured by high-performance liquid-chromatography. The free (unbound) plasma concentrations of PHT were determined by fluorescence polarization immunoassay. The plasma concentrations were used to construct pharmacokinetic profiles by plotting drug concentration-time curves. All data were subsequently processed by the computer program WINNONLIN. Statistical comparisons of pharmacokinetic parameters were performed with the unpaired Student t-test. The mean maximum plasma concentration of PHT was attained 2 h after oral administration of PHT alone and 4-6 h after oral administration of PHT in combination with PR. The plasma level of PHT declined with a half-life of 5.38 h after PHT alone and 4.03 h after PHT and PR given together. No statistically significant differences were obtained in most of the pharmacokinetic parameters (Cmax, AUC, t1/2, MRT and CL/F) and protein binding rates of PHT between the two treatments. However, significant differences in Tmax and Vd/F between groups were noted. The significant increase in Tmax indicated that simultaneous oral administration of PR delayed the absorption of PHT. The delayed absorption of PHT might lead to its slow onset of clinical effect. There were no significant differences in Cmax, AUC, t1/2, MRT and CL/F of PHT between the two groups, showing that PR could not significantly affect the extent of absorption, metabolism and elimination of PHT. No significant difference in protein binding rate was found, indicating that PR might not significantly alter the protein binding of PHT. While a significant decrease in Vd/F was noted, the mechanism underlying the apparently decreased Vd/F of PHT influenced by PR needs further study.

Disposition, elimination, and bioavailability of phenytoin and its major metabolite in horses.

To determine pharmacokinetics and excretion of phenytoin in horses. 6 adult horses. Using a crossover design, phenytoin was administered (8.8 mg/kg of body weight, IV and PO) to 6 horses to determine bioavailability (F). Phenytoin also was administered orally twice daily for 5 days to those same 6 horses to determine steady-state concentrations and excretion patterns. Blood and urine samples were collected for analysis. Mean (+/- SD) elimination half-life following a single IV or PO administration was 12.6+/-2.8 and 13.9+/-6.3 hours, respectively, and was 11.2+/-4.0 hours following twice-daily administration for 5 days. Values for F ranged from 14.5 to 84.7%. Mean peak plasma concentration (Cmax) following single oral administration was 1.8+/-0.68 microg/ml. Steady-state plasma concentrations following twice-daily administration for 5 days was 4.0+/-1.8 microg/ml. Of the 12.0+/-5.4% of the drug excreted during the 36-hour collection period, 0.78+/-0.39% was the parent drug phenytoin, and 11.2+/-5.3% was 5-(phydroxyphenyl)-5-phenylhydantoin (p-HPPH). Following twice-daily administration for 5 days, phenytoin was quantified in plasma and urine for up to 72 and 96 hours, respectively, and p-HPPH was quantified in urine for up to 144 hours after administration. This excretion pattern was not consistent in all horses. Variability in F, terminal elimination-phase half-life, and Cmax following single or multiple oral administration of phenytoin was considerable. This variability makes it difficult to predict plasma concentrations in horses after phenytoin administration.

Elimination of phenytoin in toxic overdose

Phenytoin is widely used for the management of seizures. Fortunately overdosage with this drug is rare. We performed a prospective study to investigate the elimination kinetics of phenytoin in toxic overdose. All patients were only on phenytoin and not on other anticonvulsants. Phenytoin toxicity was defined by clinical features and correlated with drug levels. Daily phenytoin levels were obtained until they were less than or equal to 15 mcg/ml. Nine patients with age ranging from 20 to 66-years-old were recruited. Sex ratio was male:female, 5:4. Initial phenytoin levels ranged from 34 to 57.5 mcg/ml. Serum phenytoin levels of three patients remained relatively constant for 2–5 days before declining in a steady fashion. Phenytoin levels of the remaining patients declined in an almost linear manner. Regression analysis of all patients showed that the slope terms were highly significant (with low P-values) and corresponding R 2 values were close to 1. Different patients have different rates of metabolism; in seven of nine patients, levels declined between 4.6 and 5.9 mcg/ml per day. Knowledge of the rate of elimination assists the clinician in deciding on the best time to reinstitute phenytoin therapy.

Charcoal hemoperfusion in the treatment of phenytoin overdose

In the case of phenytoin, a drug that is generally highly protein bound, there is a lack of consensus on the use of charcoal hemoperfusion in cases of overdose. We performed charcoal hemoperfusion on a phenytoin-overdosed patient to assess the effectiveness of this treatment. The plasma concentrations of total and free phenytoin fell rapidly, from 40.0 μg/mL and 3.6 μg/mL to 16.2 μg/mL and 1.5 μg/mL, respectively, after 3 hours of hemoperfusion. The total phenytoin elimination half-life was 3.9 hours. The fraction of protein-bound phenytoin was constant (90.8% ± 0.5%) before, during, and after the procedure. The relations between the in vitro protein binding and adsorption of phenytoin to activated charcoal were also examined. Interestingly, bound phenytoin was found to dissociate from plasma proteins in the presence of activated charcoal and subsequently became adsorbed to the activated charcoal. Considering that phenytoin is bound to albumin with a large number of binding sites (n = 6) and a small binding constant (K = 6 × 103/mol/L), the extent of adsorption to activated charcoal may depend on the magnitude of the binding constant of the drug to plasma proteins. The current results suggest that charcoal hemoperfusion is effective for the removal of drugs that bind to plasma proteins with a low binding constant.

Omeprazole and the cytochrome P450 system

Enzymes of the cytochrome P450 superfamily play a key role in xenobiotic metabolism. Their properties and significance are discussed with particular reference to interactions with the H+,K(+)-ATPase blocker, omeprazole. Such interactions include both inhibitory (subfamily 2C) and inducing effects (subfamily 1A). Delayed metabolic elimination of diazepam, warfarin, carbamazepin and phenytoin is probably due to omeprazole competition for the concerned isoform of subfamily 2C; however, these effects are modest to negligible in magnitude and, for phenytoin, not consistently reproducible. Also, induction of subfamily 1A is only minor as assessed from the resultant changes in N-3-demethylation of caffeine, a reaction specific to this subfamily. Concerns about a possible activation of procarcinogens that might arise from subfamily 1A induction appear ill-founded given the fact that cruciferous vegetables such as broccoli and Brussels sprouts are potent inducers, but rather seem to lower the incidence of certain types of cancer. Likewise, the idea that the toxicity of acetaminophen might increase upon subfamily 1A induction appears far-fetched, mainly because much stronger inducers of subfamily 1A (cigarette smoke and charcoaled beef) are unable to alter acetaminophen metabolism.

Effect of Continuous Hemofiltration on Phenytoin Elimination

Phenytoin is frequently used to treat seizure episodes in critically ill patients. Some of these patients have acute renal failure, requiring continuous hemofiltration to help maintain fluid and solute balance. We evaluated the removal of phenytoin in patients who received the drug while undergoing continuous hemofiltration treatment. Arterial and ultrafiltrate sample pairs were collected for phenytoin concentration determination. The ultrafiltrate drug concentrations were almost identical to the free serum phenytoin concentrations. Thus the ultrafiltrate/arterial drug concentration ratios resembled the percentages of serum free drug. Between 0.32 and 0.78 mg of phenytoin/h was removed by hemofiltration. The magnitude of hemofiltration phenytoin removal was related to the free drug concentration, total serum drug concentration, and ultrafiltration flow rate. When the ultrafiltration flow rate was low, the amount of phenytoin removed by hemofiltration was small relative to the usual daily dose. However, in patients with renal failure in whom serum phenytoin protein binding is substantially reduced, continuous hemofiltration at a high ultrafiltration rate may remove a clinically significant amount of the drug. Higher daily doses of phenytoin may be needed to maintain the therapeutic effect. Serum drug concentration monitoring will be necessary to determine the optimal dosage regimen.

Increased Elimination of Phenytoin in Patients Receiving Enteral Feeding

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One-point Feedback Control Method for Phenytoin Dosage Adjustment

Routine clinical pharmacokinetic data collected from patients receiving phenytoin have been analysed to propose a new and simple equation to aid the dosage adjustment of this drug. The data were analysed using NONMEM, a computer program designed for population pharmacokinetic analysis that allows pooling of data. The rate equation for the elimination of phenytoin can be written as Do = kCssn, which fits the steady-state serum concentration (Css) and daily dose data (Do). The parameter n is the kinetic order and the parameter k is an arbitrary rate constant. From the above equation, D2 = D1C1 -nC2n can be derived, which forms the basis of predicting the dosage, D2, to obtain a desired Css, C2, using one initial Css, C1, obtained with an initial dose, D1, and using a population value of n. The value of n for phenytoin was estimated to be 0.312 in this study. The predictive performance of this equation was compared with the Richens and Dunlop nomogram and Bayesian feedback method using two or more steady-state concentration/dose pairs from each of 78 outpatients. This equation allowed the prediction of a dose needed to produce a desired steady-state concentration with errors comparable with the Bayesian feedback method for therapeutic drug monitoring.

Pharmacokinetic Simulation of the Effect of Multiple-Dose Activated Charcoal in Phenytoin Poisoning—Report of Two Pediatric Cases

Activated charcoal is commonly used to inhibit the absorption of phenytoin after acute overdose. There are also reports of multiple-dose activated charcoal (MDAC) increasing the clearance of phenytoin in adults. We describe our experience modeling phenytoin pharmacokinetics during therapy with MDAC in the treatment of two cases of acute phenytoin poisoning in children. After extensive attempts at modeling the serum phenytoin concentrations, simulations were performed to identify the possible consequences of MDAC administration. Phenytoin elimination was more rapid than was expected, based on previously reported phenytoin pharmacokinetic parameters. Moreover, the time to peak phenytoin concentration and time course of phenytoin intoxication appeared to be shorter than available reports of phenytoin intoxication treated with a single dose of activated charcoal. MDAC may prevent continued phenytoin absorption and increase phenytoin elimination rate via gastrointestinal dialysis. The effect of MDAC on the clearance of phenytoin can be described by a first-order elimination rate constant of approximately 0.02-0.04/h.

Elimination of phenytoin increases during pregnancy

Elimination of phenytoin increases during pregnancy

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.