Interactions of Phenobarbital and Phenytoin with Carbamazepine and Its Metabolites' Concentrations, Concentration Ratios, and Level/Dose Ratios in Epileptic Children

Summary: The effects of phenytoin (PHT) or phenobarbital (PB) comedication on the concentrations, concentration ratios, and level/dose ratios of carbamazepine (CBZ) and its metabolites were investigated. The hetero-induction effects of CBZ metabolism by PHT or PB were clearly demonstrated. Serum CBZ level/dose ratios in patients with CBZ polytherapy were decreased while CBZ- l0,11-epoxide (CBZ-E) and trans -l0,11-dihydroxy-10, 1-dihydro-CBZ (CBZ-H) concentrations were increased as compared with those of patients receiving CBZ alone. The concentration ratios of CBZ-H/CBZ and CBZ-E/ CBZ were also greater in patients receiving CBZ +PHT or CBZ+PB than in patients receiving CBZ alone. In addition, positive correlations between serum PHT concentration and CBZ-H/CBZ or CBZ-E/CBZ concentration ratios were observed. There were no significant differences in CBZ-H/CBZ-E concentration ratios, the free fractions of CBZ and its metabolites, and CBZ-E or CBZ-H 1eveYdose ratios among the three groups of patients. Because this approach investigates the in vivo relation between the substrates and products of the enzymes involved in CBZ biotransformation, more detailed information about the drug interactions was obtained. The results suggest that the PHT has a potent induction effect on CBZ epoxidase, whereas PB is a moderate inducer.     

Felbamate Increases Phenytoin but Decreases Carbamazepine Concentrations

Felbamate (FBM), a novel antiepileptic drug, was observed to have opposite effects on the serum concentrations of phenytoin (PHT) and carbamazepine (CBZ). Data from two male subjects who stabilized while they received both PHT and CBZ, with serum concentration fluctuations of less than 20 and 25%, respectively, form the basis of this report. Both patients required a greater than or equal to 20% reduction in PHT dose while receiving 38-40 mg/kg/day of FBM. When FBM was tapered to less than 20 mg/kg/day, a sudden drop in PHT concentrations occurred in both patients. As PHT concentrations rose, CBZ concentrations fell in both patients. The CBZ epoxide to parent ratio increased to 0.46 and 0.39, respectively during FBM treatment. The ratios were 0.18 in both patients when not receiving FBM. CBZ concentrations returned to baseline values after FBM was discontinued. This unusual and unexpected effect of FBM on two standard antiepileptic drugs underscores the need for evaluating pharmacokinetic interactions before major drug trials.     

Drug Interaction Profile of Topiramate

Summary: In separate studies, potential pharmacokinetic interactions of topiramate (TPM) with phenytoin (PHT), carbamazepine (CBZ), and valproate (VPA) were evaluated. TPM was added to the baseline antiepileptic drug (AED) at a dosage of up to 800 mg/day, after which the baseline drug was discontinued, when possible. Addition of TPM produced no change in plasma levels of CBZ or CBZ epoxide (CBZ-E). Modest increases in PHT plasma levels in six of 12 patients treated with PHT and TPM, and a small mean decrease in VPA levels noted in patients receiving VPA with TPM, were considered unlikely to require adjustments in the dosage of the concomitant AED when TPM is added or discontinued. When patients were changed from concomitant therapy with PHT or CBZ to TPM monotherapy, TPM clearance was reduced by approximately 50%, suggesting that an adjustment in TPM dose may be required when PHT or CBZ is discontinued from TPM-treated patients. A slight increase in plasma TPM levels during monotherapy compared to concomitant therapy with VPA was considered clinically insignificant and not likely to require TPM dosage adjustment. In another study, oral clearance of digoxin was slightly increased when TPM was added, resulting in a small decrease in peak plasma levels of digoxin. In vitro studies conducted to date on a number of specific cy-tochrome P450 isoforms show an effect of TPM only on the CYP2C_meph isoform. The risk for clinically meaningful changes in plasma levels of traditional AEDs when TPM is added to or discontinued from concomitant regimens appears to be minimal. However, adjustments in TPM dosages are likely to be needed when potent enzyme inducers, such as PHT or CBZ, are added or discontinued. TPM has a relatively low propensity for clinically significant drug interactions, and its pharmacokinetic and drug interaction profiles represent a clear advance over those of the traditional AEDs.     

Acute Oral Loading of Carbamazepine-CR and Phenytoin in a Double-Blind Randomized Study of Patients at Risk of Seizures

Summary: The serum levels and side effects of, an acute oral loading dose-schedule of carbamazepine (C) divitabs [CBZ controlled release (CR)] and phenytoin (PHT) were assessed in patients at risk of seizures. CBZ-CR and PHT were administered to 42 adult patients (21 each) at a dosage of 20 mg/kg with a minimum and maximum dosage of 1,200 and 1,600 mg in patients weighing 80 kg, respectively. CBZ-CR was given as single loading dose; PHT was split, with two thirds of the dose administered at 0 h and one third administered 2 h later. The 24-and 36-h doses were assessed according to the nystagmus status at 24 h. Mean CBZ serum levels (percentage of subjects with level >4 μg/ml shown in parentheses) were 0.0 (0%), 5.2 (62%), 6.7 (81%), 6.8 (95%), and 6.1 μg/ml(95%) at 0, 4, 8, 24, and 48 h after loading, respectively, and mean PHT levels (percentage of subjects with PHT level >10 μg/ml in parentheses) were 0.1 (0%), 13.2 (86%), 16.3 (loo%), 16.3 (l00%), and 15.4 pg/ml (82%). One subject in the CBZ group and 3 in the PHT group vomited. Clinical effects did not differ significantly between treatment groups and are reported. Acute doses of CBZ-CR 20 mg/kg and PHT 20 mg/kg (two-thirds at 0 h and one-third at 2 h) provided therapeutic levels in most patients in G4 h and were well tolerated.     

Aging Variabilities of Level-Dose Relationship in Antiepileptic Monopharmacy—with Reference to Drug Interaction between Mono- and Bipharmacy

Abstract: The influences of age, dose and comedication on the dose-level relationship were investigated using the ratio of plasma level to dose per body weight (/μg/ml/mg/ kg/day) as an index in patients who had received the therapeutic doses of antiepileptic drug(s) for a long term. Samples of the blood concentrations were taken from 1,922 patients ranging in age from one to 40: 1,567 measured values were obtained under medication with pheno-barbital (PB), phenytoin (PHT), carbamazepine (CBZ) or valproate (VPA) alone, and 2,201 under medication with any two of the above-mentioned antiepileptic drugs.

• 1) With regard to PB, PHT, CBZ and VPA, when used alone, the L/D ratio was the lowest in the youngest age group, increased toward the latter half of teens, reached a peak at about age 20 and slightly decreased in the rest between the 20s and 30s. The age when the L/D ratio changes with aging is consistent with the age when the body weight of children obviously increases. As a result, during such a term, the fairly constant blood concentration can be maintained without overtly changing the daily dose.
• 2) In the same age group given a single antiepileptic drug, the L/D ratio for PHT steeply increased at the dose of 4 in adults or 5 mg/kg/day in children, while the ratio rather decreased for CBZ and VPA. Clinical considerations should be paid to the fact that there was a non-linear relationship between the dose and the plasma concentration not only of PHT but of CBZ and VPA, and that the turning points were all within the range of therapeutic doses. Namely, that the plasma concentration of PHT is liable to reach a toxic level if the dose is slightly over the critical dose is well known. On the contrary, the innocent increase in the CBZ or VPA dosage only with the aim of obtaining the so-called therapeutic concentration is not always a rational plan of medication because of the nature of the reversed non-linear relationship between these two drugs.
• 3) As regards the interaction of the two antiepileptic drugs, PHT showed no definite tendency with any partner drug; PB showed an increase in the L/D ratio when used in combination with PHT, CBZ or VPA; and CBZ and VPA showed decreases in the L/D ratio when used in combination, regardless of a partner drug. These findings should be borne in mind when we have to deal with polytherapy.

     

Concentrations and Effects of Oral Midazolam are Greatly Reduced in Patients Treated with Carbamazepine or Phenytoin

Midazolam is a short-acting benzodiazepine which is used as an oral hypnotic agent in several countries. We studied the pharmacokinetic and pharmacody-namic aspects of an oral 15–mg dose of midazolam in 6 patients with epilepsy who are also taking carbamazepine (CBZ) or phenytoin (PHT). We compared results with those obtained in 7 noninduced control subjects. Plasma concentrations and effects of midazolam were measured for 10 h. In patients with epilepsy, the area under the plasma concentration-time curve (AUC) of midazolam (mean 2 SEM) was only 5.7% (0.60 ± 0.16 vs. 10.5 ± 0.6 μg - min/ml), and the peak midazolam concentration was 7.4% (5.2 ± 1.2 vs. 70.4 ± 9.0 μg/ml) of its value in control subjects (p < 0.001). The elimination half-life (t1/2) of midazolam was 1.3 ± 0.2 h in patients and 3.1 ± 0.1 h in controls (p < 0.001). The low plasma midazolam concentrations in the patient group were associated with reduced pharmacodynamic effects as compared with control subjects [e.g., the Critical Flicker Fusion Test (CFFT), p < 0.05]. Induction of CYP3A (cytochrome P-450IIIA) enzymes by CBZ and PHT is the most likely explanation of the great difference in the pharmacokinetic and pharmacodynamic profiles of oral midazolam in the two groups.     

Aging variabilities of level-dose relationship in antiepileptic monopharmacy--with reference to drug interaction between mono- and bipharmacy

The influences of age, dose and comedication on the dose-level relationship were investigated using the ratio of plasma level to dose per body weight (microgram/ml/mg/kg/day) as an index in patients who had received the therapeutic doses of antiepileptic drug(s) for a long term. Samples of the blood concentrations were taken from 1,922 patients ranging in age from one to 40: 1,567 measured values were obtained under medication with phenobarbital (PB), phenytoin (PHT), carbamazepine (CBZ) or valproate (VPA) alone, and 2,201 under medication with any two of the above-mentioned antiepileptic drugs. With regard to PB, PHT, CBZ and VPA, when used alone, the L/D ratio was the lowest in the youngest age group, increased toward the latter half of teens, reached a peak at about age 20 and slightly decreased in the rest between the 20s and 30s. The age when the L/D ratio changes with aging is consistent with the age when the body weight of children obviously increases. As a result, during such a term, the fairly constant blood concentration can be maintained without overtly changing the daily dose. In the same age group given a single antiepileptic drug, the L/D ratio for PHT steeply increased at the dose of 4 in adults or 5 mg/kg/day in children, while the ratio rather decreased for CBZ and VPA. Clinical considerations should be paid to the fact that there was a non-linear relationship between the dose and the plasma concentration not only of PHT but of CBZ and VPA, and that the turning points were all within the range of therapeutic doses.(ABSTRACT TRUNCATED AT 250 WORDS)     

Pregabalin drug interaction studies: lack of effect on the pharmacokinetics of carbamazepine, phenytoin, lamotrigine, and valproate in patients with partial epilepsy

PURPOSE: Pregabalin (PGB) is an alpha2-delta ligand with demonstrated efficacy in epilepsy, neuropathic pain, and anxiety disorders. PGB is highly efficacious as adjunctive therapy in patients with refractory partial seizures. METHODS: Given its efficacy as adjunctive therapy, the potential for interaction of PGB with other antiepileptic drugs (AEDs) was assessed in patients with partial epilepsy in open-label, multiple-dose studies. Patients received PGB, 600 mg/day (200 mg q8h) for 7 days, in combination with their individualized maintenance monotherapy with valproate (VPA), phenytoin (PHT), lamotrigine (LTG), or carbamazepine (CBZ). RESULTS: Trough steady-state concentrations of CBZ (and its epoxide metabolite), PHT, LTG, and VPA were unaffected by concomitant PGB administration. Likewise, PGB steady-state pharmacokinetic parameter values were similar among patients receiving CBZ, PHT, LTG, or VPA and, in general, were similar to those observed historically in healthy subjects receiving PGB alone. The PGB-AED combinations were generally well tolerated. PGB may be added to VPA, LTG, PHT, or CBZ therapy without concern for pharmacokinetic drug-drug interactions.     

Influence of D-Cycloserine on the Anticonvulsant Activity of Phenytoin and Carbamazepine Against Electroconvulsions in Mice

Summary: Purpose: D-Cycloserine (DCS) is a high-efficacy partial agonist at the strychnine-insensitive glycine modulatory site within the N-methyl+-aspartate (NMDA)-receptor/ionophore complex. Previous studies demonstrated that DCS exhibits anticonvulsant activity in a variety of experimental epilepsy models. In this study, we determined the influence of DCS in subprotective doses on the anticonvulsant action of phenytoin (PHT) and carbamazepine (CBZ) in mice. Methods: Two electroconvulsive tests were used, i.e., determination of seizure threshold and maximal electro-shock seizures. Antiepileptic drug-induced motor and long-term memory deficits were quantified by using the chimney test and the passive-avoidance test, respectively. In addition, plasma levels of PHT and CBZ were measured by fluorescence polarization immunoassay to exclude any pharmacokinetic interactions. Results: DCS, when used alone in doses of 80 and 160 mg/kg, significantly increased the threshold for electro-convulsive seizures. DCS in a wide range of doses (1.25–40 mg/kg) was combined with either PHT or CBZ and tested in electroconvulsive tests. DCS, at doses of 2.5 and 10 mg/kg, was the most effective in potentiating the threshold-increasing action of PHT; higher doses of DCS (20 and 40 mg/kg) were required to achieve a similar effect of CBZ. In maximal electroshock-induced seizures, DCS (10 mg/kg) augmented the protective action of PHT, but was ineffective at a dose of 40 mg/kg with CBZ. DCS did not potentiate the neurotoxicity produced by PHT and CBZ in the chimney test. Both PHT and CBZ induced impairments of long-term memory; PHT-induced memory adverse effects were counteracted by DCS (10 mg/kg). There was no such effect on CBZ-induced memory impairment, and a worsening influence was observed. Any pharmacokinetic interactions were excluded by measuring total and free plasma levels of both antiepileptic drugs. Conclusion: Our results suggest that combining DCS with PHT and CBZ may be beneficial in treating epileptic seizures.     

Pharmacokinetic and Dose Tolerability Study of ADD 94057 in Comedicated Patients with Partial Seizures

ADD 94057, a metabolite of fluzinamide, manufactured by the A. H. Robins Company, blocks chemically- and electrically-induced seizures in animals. The primary objective of this open add-on study was to evaluate patient tolerability of ADD 94057 at ascending target plasma concentrations. Nine subjects with medically refractory seizures were receiving phenytoin (PHT, 3), carbamazepine (CBZ, 3), or both (3). A pharmacokinetic profile after a single oral 400-mg dose of ADD 94057 was used to calculate ADD 94057 dosages. After a 4-week baseline period, patients were treated for 4 weeks with weekly ADD 94057 dosage escalations. Two patients completed the study at their assigned highest dosage level; the other patients finished the study at lower dosages. The patients receiving PHT (but not CBZ) tolerated higher plasma concentrations of ADD 94057 than did patients receiving CBZ, alone or in combination with PHT. Adverse experiences included headache, ataxia, blurred vision, diplopia, dizziness, lightheadedness, and mild confusion. Eight of nine patients had reductions in seizure frequency from baseline.     

Tiagabine versus phenytoin and carbamazepine as add-on therapies: effects on abilities, adjustment, and mood

The effects of tiagabine (TGB) on abilities and on adjustment and mood are as yet incompletely understood. These effects were compared with those of phenytoin (PHT) and carbamazepine (CBZ) in an add-on study. Patients included in the analysis were adults with uncontrolled partial seizures who at study entry were on CBZ alone (n=153) or on PHT alone (n=124). Of the patients receiving CBZ, 82 were randomized to add-on TGB and 71 were randomized to add-on PHT during the double-blind period. Of the patients receiving PHT, 58 were randomized to add-on TGB and 66 were randomized to add-on CBZ. Eight tests of mental abilities and three of mood and adjustment were given prior to assignment of add-on treatment and after up to 16 weeks of add-on treatment. For the baseline CBZ group, analyses were done to search for differential changes from baseline in the test scores of the add-on TGB and add-on PHT groups, and for the baseline PHT group in the add-on TGB and add-on CBZ groups. In the baseline CBZ group, no differences in test scores were found between PHT and TGB. In the baseline PHT group for the area of abilities, patients treated with TGB had improved verbal fluency, as well as quicker responses on a test of perceptual/motor speed compared with patients treated with CBZ. For the baseline PHT group in the area of adjustment and mood, patients treated with TGB reported less positive mood and more financial concerns compared to patients treated with CBZ. Overall, add-on TGB showed few or no differences in comparison with add-on CBZ and add-on PHT.     

A multicenter randomized controlled trial on the clinical impact of therapeutic drug monitoring in patients with newly diagnosed epilepsy. The Italian TDM Study Group in Epilepsy

PURPOSE: To assess the clinical impact of monitoring serum concentrations of antiepileptic drugs (AEDs) in patients with newly diagnosed epilepsy. METHODS: One-hundred eighty patients with partial or idiopathic generalized nonabsence epilepsy, aged 6 to 65 years, requiring initiation of treatment with carbamazepine (CBZ), valproate (VPA), phenytoin (PHT), phenobarbital (PB), or primidone (PRM) were randomly allocated to two groups according to an open, prospective parallel-group design. In one group, dosage was adjusted to achieve serum AED concentration within a target range (10-20 microg/ml for PHT, 15-40 microg/ml for PB, 4-11 microg/ml for CBZ, and 40-100 microg/ml for VPA), whereas in the other group, dosage was adjusted on clinical grounds. Patients were followed up for 24 months or until a change in therapeutic strategy was clinically indicated. RESULTS: Baseline characteristics did not differ between the two groups. Most patients with partial epilepsy were treated with CBZ, whereas generalized epilepsies were most commonly managed with PB or VPA. PHT was used only in a small minority of patients. A total of 116 patients completed 2-year follow-up, and there were no differences in exit rate from any cause between the monitored group and the control group. The proportion of assessable patients with mean serum drug levels outside the target range (mostly below range) during the first 6 months of the study was 8% in the monitored group compared with 25% in the control group (p < 0.01). There were no significant differences between the monitored group and the control group with respect to patients achieving 12-month remission (60% vs. 61%), patients remaining seizure free since initiation of treatment (38% vs. 41%), and time to first seizure or 12-month remission. Frequency of adverse effects was almost identical in the two groups. CONCLUSIONS: Only a small minority of patients were treated with PHT, the drug for which serum concentration measurements are most likely to be useful. With the AEDs most commonly used in this study, early implementation of serum AED level monitoring did not improve overall therapeutic outcome. and the majority of patients could be satisfactorily treated by adjusting dose on clinical grounds. Monitoring the serum levels of these drugs in selected patients and in special situations is likely to be more rewarding than routine measurements in a large clinic population.     

Inhibition of Carbamazepine and Phenytoin Metabolism by Nafimidone, a New Antiepileptic Drug

When nafimidone (NFM), a new antiepileptic drug, was given to six patients already taking carbamazepine (CBZ) and phenytoin (PHT) as part of a late phase I pilot efficacy trial, it reduced CBZ elimination by 76-87% and reduced PHT elimination by 38-77%. CBZ and PHT levels rose within 24 h after NFM was started, and began to decline within 12 h after NFM was stopped. The inhibitory effect on CBZ metabolism persisted throughout the course of 1 year of long-term follow-up in all five patients who continued with the drug after completion of the pilot study. Inhibition of PHT elimination persisted in three of the patients, but PHT elimination returned to baseline rates in the other two patients during long-term follow-up. The inhibition of CBZ and PHT metabolism is probably due to binding of cytochrome P-450 by NFM or a metabolite and thus inhibition of the hepatic microsomal mixed-function oxidase system.     

A comparative study of the effect of carbamazepine and valproic acid on the pharmacokinetics and metabolic profile of topiramate at steady state in patients with epilepsy

PURPOSE: To compare the influence of enzyme-inducing comedication and valproic acid (VPA) on topiramate (TPM) pharmacokinetics and metabolism at steady state. METHODS: Three groups were assessed: (a) patients receiving TPM mostly alone (control group, n =13); (b) patients receiving TPM with carbamazepine (CBZ; n = 13); and (c) patients receiving TPM with VPA (n = 12). TPM and its metabolites were assayed in plasma and urine by liquid chromatography-mass spectrometry (LC-MS). RESULTS: No significant differences were found in TPM oral (CL/F) and renal (CL(r)) clearance between the VPA group and the control group. Mean TPM CL/F and CL(r) were higher in the CBZ group than in controls (2.1 vs. 1.2 L/h and 1.1 vs. 0.6L/h, respectively; p < 0.05). In all groups, the urinary recovery of unchanged TPM was extensive and accounted for 42-52% of the dose (p > 0.05). Urinary recovery of 2,3-O-des-isopropylidene-TPM (2,3-diol-TPM) accounted for 3.5% of the dose in controls, 2.2% in the VPA group (p > 0.05), and 13% in the CBZ group (p < 0.05). The recovery of 10-hydroxy-TPM (10-OH-TPM) was twofold higher in the CBZ group than in controls, but it accounted for only <2% of the dose. The plasma concentrations of TPM metabolites were severalfold lower than those of the parent drug. CONCLUSIONS: Renal excretion remains a major route of TPM elimination, even in the presence of enzyme induction. The twofold increase in TPM-CL/F in patients taking CBZ can be ascribed, at least in part, to stimulation of the oxidative pathways leading to formation of 2,3-diol-TPM and 10-OH-TPM. VPA was not found to have any clinically significant influence on TPM pharmacokinetic and metabolic profiles.     

Comparison between premortem and postmortem serum concentrations of phenobarbital, phenytoin, carbamazepine and its 10,11-epoxide metabolite in institutionalized patients with epilepsy

The last premortem serum concentrations of phenobarbital (PB), phenytoin (PHT), carbamazepine (CBZ) and its CBZ-10,11-epoxide metabolite (CE) were compared with the corresponding postmortem serum concentrations in 16 adult patients of an epilepsy centre. Based on complete postmortem examinations, 12 individuals showed a known cause of death (KCD) and four patients succumbed from sudden unexplained death (SUD). The last premortem and the postmortem serum levels of PB (r = 0.991), PHT (r = 0.986), CBZ (r = 0.985) and CE (r = 0.936) were highly correlated. However, the regression analysis indicated that, except for CE, the premortem concentrations were significantly higher than the postmortem concentrations, i.e. 65% for PB, 34% for PHT, and 16% for CBZ. Varying time lapses (4-62 h) between death and serum sampling during autopsy did not significantly influence the ratio of premortem to postmortem serum levels for PB, PHT, CBZ, and CE (p > 0.1). Furthermore we found no significant differences between the premortem and the postmortem serum concentration ratios CE/CBZ. Considering the above variables, the data of SUD and KCD patients were comparable. Postmortem decrease in anticonvulsant serum concentrations, especially for PB and PHT, should be considered in order to avoid misinterpretation in respect to so-called 'subtherapeutic' serum levels and noncompliance in context with SUD or fatal intoxication.     

Lack of an effect of valproate concentration on lamotrigine pharmacokinetics in developmentally disabled patients with epilepsy

PURPOSE: to describe the population pharmacokinetics of lamotrigine (LTG) in developmentally disabled (DD) patients with epilepsy and (2) to determine if there is an effect of valproate (VPA) concentration on the extent of the pharmacokinetic interaction between VPA and LTG. METHOD: a NONMEM population analysis of steady-state LTG serum concentrations was conducted in patients receiving LTG either as mono or polytherapy with either an enzyme inducer (IND)-carbamazepine (CBZ), phenytoin (PHT), phenobarbital (PB) or an inhibitor (VPA). RESULTS: sixty-two patients (33.6+/-11.3 years, 47+/-9.9 kg) receiving LTG monotherapy (n=19) or polytherapy with VPA (n=15), inducer(s) (n=32) or both (n=5) were evaluated. LTG dose of 369+/-236 mg per day (8.1+/-5.9 mg/kg per day) achieved LTG plasma concentrations of 6.8+/-3.3 microg/ml. The observed LTG monotherapy, LTG+IND, and LTG+VPA oral clearance (Cl/F) were 0. 69+/-0.2, 1.60+/-0.65 and 0.2+/-0.05 ml/kg per min, respectively. The final LTG Cl/F model was dependent on body weight, concomitant VPA, and either single or multiple inducers. Including the serum concentrations of CBZ, PHT, or VPA in the model, did not significantly improve estimates of Cl/F. CONCLUSION: LTG Cl/F in DD patients is similar to literature values for ambulatory adult patients; however, low weight adult patients have higher elimination rates, as well as an increased response to enzyme induction. VPA inhibition of LTG Cl/F is maximal within the usually accepted therapeutic range for VPA.     

Effects of antiepileptic drugs on sleep architecture: a pilot study

OBJECTIVES: The effects of antiepileptic drugs (AEDs) on sleep architecture are not well understood, especially in patients with localization-related epilepsy, in whom seizures themselves can disrupt sleep. To clarify the effects of AEDs on sleep architecture, we performed a prospective study, looking at sleep architecture in patients with epilepsy admitted for video-EEG monitoring. METHODS: Adult patients with localization-related epilepsy treated with a single AED and admitted between 10/1997 and 04/2001 were included. Control patients on no AEDs were also included. Both groups were withdrawn from other AEDs. Overnight polysomnography was recorded and was scored according to the standard method. Adult patients with localization-related epilepsy on no medication were also recorded and served as controls. Patients with no seizure during the recording and no seizure in the 24 h preceding the recording were analyzed in this paper. Patients with a seizure in the 24 h preceding the recording and patients with a seizure during the recording were analyzed separately. RESULTS: A total of 72 nights were recorded in 39 patients, and patients taking each AED were compared to controls. We did not find any statistically significant effect of carbamazepine (CBZ). Phenytoin (PHT) disrupted sleep by increasing stage 1 sleep (PHT: 13.2+/-7.3%; control: 7.7+/-4.8%; P=0.008), and decreasing slow wave sleep (SWS) (PHT: 7.9+/-4.2%; control: 11.3+/-4.4%; P=0.03) and REM sleep (PHT: 13.9+/-6.2; control: 18.8+/-5.1; P=0.01). Valproic acid (VPA) disrupted sleep by increasing stage 1 sleep (VPA: 16.8+/-9.8%; control: 7.7+/-4.8%; P=0.007). Gabapentin (GBP) improved sleep by increasing SWS (GBP: 19.4+/-4.2%; control: 11.3+/-4.4%; P=0.0009). PHT and VPA disrupt sleep in the absence of seizures, while CBZ and lamotrigine have no significant effects. GBP improves sleep by increasing SWS. CONCLUSIONS: AEDs have differing effects on sleep structure, which can be beneficial or detrimental. Consideration of these potential effects is important in maintaining optimal sleep in patients with epilepsy.     

Cytogenetic Effects of Phenytoin and/or Carbamazepine on Human Peripheral Leukocytes

The cytogenetic effects of phenytoin (PHT) and/or carbamazepine (CBZ) were studied to determine clastogenic potential. Comparative analysis of chromosome breakage and sister chromatid exchange (SCE) was performed between 18 patients with epilepsy receiving PHT and/or CBZ and 10 healthy nontreated controls. These studies failed to detect a significant increase in chromosome aberrations or SCEs in groups of treated individuals as compared with controls. No correlation was observed between the rate of either chromosome damage or SCEs and age, sex, drug blood level, or daily dose. The results indicate no detectable chromosome damaging effects of PHT alone, CBZ alone, or a combination of these two antiepileptic drugs (AEDs).     

The Short-Term Impact of Adjunctive Tiagabine on Health-Related Quality of Life

Summary: Combinations of tiagabine (TGB), carbamazepine (CBZ), and phenytoin (PHT) were compared for their impact on health-related quality of life (HRQOL) and adverse effects related to treatment efficacy for people with frequent complex partial seizures. Two independent, randomized, double-blind clinical trials for efficacy and safety were conducted simultaneously with treatment groups: CBZ+PHT versus CBZ+TGB, and PHT+CBZ versus PHT+TGB. Treatment was initiated at week 0 and continued through week 16. HRQOL was evaluated with the QOLIE-89. Treatment success was defined as ≥50% reduction in complex partial seizures. Among patients who achieved a ≥50% reduction in seizures, addition of TGB to baseline PHT enhanced patient perceptions of attention/concentration (13%; p = 0.002), memory (17%; p = 0.042), and language subscales (22%; p = 0.004). Addition of CBZ to PHT led to positive change in the work/driving/social relations subscale (14%; p = 0.004). These improvements were significantly different only between visits, not between the two treatment groups. Seizure worry subscale scores showed improvement among all treatment groups and was probably related to participation in the clinical trial. These exploratory analyses suggest a possible early positive effect of TGB on patient-perceived cognitive domains using the QOLIE-89. These findings are limited by the small sample size and could be related to reduction in seizures.     

Clinical Pharmacology of Lamotrigine

Summary: The pharmacokinetics and pharmacodynamics of lamotrigine (LTG), a new antiepileptic drug (AED), were studied in healthy volunteers. In an open dose-escalating study, LTG 240 mg produced peak plasma concentrations of around 3 μg/mg with no significant adverse events. Subsequent pharmacokinetic studies revealed complete oral absorption, first-order kinetics with a mean half-life of approximately 1 day, and elimination mainly as a glucuronide in the urine. Early studies in patients with epilepsy revealed more rapid metabolism when given with enzyme-inducing AEDs and delayed metabolism by valproate. A placebo-controlled, double-blind study compared LTG 120 and 240 mg with phenytoin (PHT) 500 and 1,000 mg, and diazepam (DZP) 10 mg. Visual analogue scales showed sedation after PHT 1,000 mg and DZP 10 mg, but not after LTG. Smooth pursuit eye movements and adaptive tracking were impaired by DZP and PHT 1,000 mg. LTG did not affect these variables. A comparison of LTG 150 and 300 mg and carbamazepine (CBZ) 200, 400, and 600 mg demonstrated impairment of smooth pursuit and saccadic eye movements by CBZ 600 and 400 mg, but not by LTG. Additionally, CBZ 600 mg impaired adaptive tracking and increased body sway and heart rate. These studies have shown LTG to have desirable and predictable pharmacokinetic properties for an AED. Pharmacodynamic effects were absent, suggesting a high therapeutic index.