Clinical Side Effects of Phenobarbital, Primidone, Phenytoin, Carbamazepine, and Valproate During Monotherapy in Children

The rate of onset of side effects was examined in 392 pediatric outpatients who received long-term monotherapy with phenobarbital (PB), primidone (PRM), phenytoin (PHT), carbamazepine (CBZ), or valproate (VPA) for epilepsy or febrile convulsions. The severity of side effects (based on need to alter treatment), the nature of each drug's most common side effects, and the doses and plasma levels of occurrence were recorded. Our results show that usually accepted therapeutic ranges are well tolerated. Indeed, although some form of side effect occurred in 50% of patients, treatment had to be changed in only 18% and the drug had to be stopped in only 7%. In decreasing order, the rates for side effects were PHT (71%) greater than PB (64%) greater than CBZ (43%) greater than VPA (43%) greater than PRM (29%). Serious side effects requiring withdrawal of treatment occurred at the following rates: PHT (10%) greater than VPA (8%) greater than PRM (8%) greater than PB (4%) greater than CBZ (3%). Among our patients, the best tolerated antiepileptic drug (AED) was CBZ, and the least tolerated was PHT. Behavioral disorders were most common with PB, neurologic disorders with PHT, digestive tract disorders with VPA, and gingival hyperplasia and hirsutism with PHT. Behavioral disorders involving excitement seen with PB and PRM occurred most commonly at low plasma levels. Behavioral disorders involving depression seen with PB and VPA, those involving excitement seen with PHT and VPA, and digestive disorders seen with VPA occurred particularly when plasma levels were high.     

抗癫痫药体外诱导鼠星形胶质细胞多药耐受基因P-糖蛋白的表达

目的：了解常用抗癫痫药（AED）对大鼠大脑上 星形胶质细胞多药耐受基因（MDR1）的诱导作用,探讨难治性癫痫的耐药机制。方法：给予不同浓度的苯巴比妥钠（PB）、苯妥英钠（PHT）、卡马西平（CBZ）和丙戊酸钠（VPA）持续作用于培养的新生鼠大脑皮质星形胶质细胞,分别在给药后10、20和30d,用免疫细胞化学法检测MDR1的标志物P－糖蛋白（Pgp)的表达率。结果,无药物作用的正常星形胶质细胞Pgp的表达率在各时点均小于5％,低浓度组各药在各时点Pgp的表达率与对照组比较差异无显著意义,有效血药浓度组仅PB20mg/L,PB40mg/L和PHT20mg/L在30d时Pgp表达增强;给药后10d,高浓度组各药Pgp表达率无明显增高;20d时PB、PHT和VPA组Pgp表达增强;30d时4种AED均有Pgp表达增强。结论AED可以诱导MDR1表达增强,且与剂量和时间相关。AED诱导的MDR1表达增强可能参与了难治性癫痫的形成。     

Congenital malformations due to antiepileptic drugs

To identify the major risk factors for the increased incidence of congenital malformations in offspring of mothers being treated for epilepsy with antiepileptic drugs (AEDs) during pregnancy and, to determine the relative teratogenic risk of AEDs, we prospectively analyzed 983 offspring born in Japan, Italy, and Canada. The incidence of congenital malformations in offspring without drug exposure was 3.1%, versus an incidence with drug exposure of 9.0%. The highest incidence in offspring exposed to a single AED occurred with primidone (PRM; 14.3%), which was followed by valproate (VPA; 11.1%), phenytoin (PHT; 9.1%), carbamazepine (CBZ; 5.7%), and phenobarbital (PB; 5.1%). The VPA dose and level positively correlated with the incidence of malformations. This study first determined a cut-off value of VPA dose and level at 1000 mg/day and 70 microg/ml, respectively, to avoid the occurrence of malformations. The incidence of malformations increases as the number of drugs increases, and as the total daily dose increases. Specific combinations of AEDs such as VPA + CBZ and PHT + PRM + PB produced a higher incidence of congenital malformations. The incidence of malformations was not associated with any background factors studied except for the presence of malformations in siblings. These results indicate that the increased incidence of congenital malformations was caused primarily by AEDs, suggesting that malformations can be prevented by improvements in drug regimen, and by avoiding polypharmacy and high levels of VPA (more than 70 microg/ml) in the treatment of epileptic women of childbearimg age.     

Pharmacology of Cortical Epileptic Afterdischarges in Rats

Summary: Afterdischarges (ADS) elicited by electrical stimulation of the sensorimotor cortical area are characterized by rhythmic spikes and spike-wave complexes in the EEG and by clonic face and forelimb seizures. We studied the sensitivity of such ADS to phenytoin (PHT), carbamazepine (CBZ), phenobarbital (PB), primidone (PRM), and valproate (VPA) in 78 adult male Wistar rats with implanted electrodes. Neither PHT (30 and 60 mg/kg intraperitoneally, i.p.) nor CBZ (25 and 50 mg/kg i.p.) suppressed cortical ADS. Indeed, ADS were prolonged by higher doses of both drugs. PRM had a similar effect: A dose of 40 mg/kg transiently shortened ADS, but a dose of 80 mg/kg prolonged ADS. PB (20 and 40 mg/kg) and VPA (200 and 400 mg/kg) were effective in suppressing ADS. Higher doses of VPA and PB reduced the intensity of motor phenomena related to the stimuli but had no effect on the motor correlates of ADS. These findings suggest that cortically induced ADS are not a good model of secondarily generalized seizures. The response to VPA and PB suggests that cortical ADS may represent a model of myoclonic seizures.     

Efficacy and Adverse Effects of Established and New Antiepileptic Drugs*

Summary: Antiepileptic drug (AED) selection is based primarily on efficacy for specific seizure types and epileptic syndromes. However, efficacy is often similar for the different AEDs, and other properties such as adverse effects, pharmacokinetic properties, and cost may also be of importance. For idiopathic generalized epilepsies with absence, tonic-clonic, and myoclonic seizures, the AED of choice is valproate (VPA). Secondarily generalized epilepsies with tonic, atonic, and other seizure types are difficult to treat with any single AED or combination of AEds. The AEDs of choice for absence seizures are ethosuximide (ESM) and VPA. For control of primary generalized tonic-clonic seizures, any of the other major AEDs can be effective. If VPA cannot be prescribed, carbamazepine (CBZ), phenobarbital (PB), phenytoin (PHT), or primidone (PRM) may be effective, but ESM or a benzodiazepine (BZD) must be added to control associated absence or myoclonic seizures. The AEDs of first choice for partial epilepsies with partial and secondarily generalized tonic-clonic seizures are CBZ and PHT. Increasing evidence suggests that VPA is a good alternative when CBZ and PHT fail. PB and PRM are second-choice selections because of adverse effects. A combination of two of the five standard AEDs may be necessary to treat intractable seizures, but no studies have been done to indicate an optimal combination. Other epilepsy syndromes such as neonatal and infantile epilepsies, febrile epilepsy, alcoholic epilepsy, and status epilepticus require specific AED treatment. Ultimately, AED selection must be individualized. No “drug of choice” can be named for all patients. The expected efficacy for the seizure type, the importance of the expected adverse effects, the pharmacokinetics, and the cost of the AEDs all must be weighed and discussed with the patient before a choice is made. A number of new AEDs with unique mechanisms of action, pharmacokinetic properties, and fewer adverse effects hold important promise of improved epilepsy treatment.     

Conversion from carbamazepine or oxcarbazepine to topiramate in adolescents and adults with epilepsy

Objective – To explore effectiveness, tolerability and changes in quality of life in patients with epilepsy converting to topiramate (TPM) from carbamazepine (CBZ) or oxcarbazepine (OXC) due to insufficient effectiveness and/or tolerability. Methods – A multicenter, open‐label, non‐interventional trial was used to examine patients (≥ 12 years) with epilepsy, changing to TPM monotherapy from baseline mono‐ or combination therapy with CBZ or OXC. TPM was added to the existing antiepileptic drug (AED) treatment and started at a dose of 25 mg once daily. The dose was titrated up with 25 mg/day increments, once every 1–2 weeks, until a final dose between 50 and 200 mg/day was reached. On the basis of clinical judgment, the treating physician decided whether or not the existing AED treatment with CBZ or OXC could then be withdrawn. Type and number of seizures, preferred TPM dose, quality of life (QOLIE‐10 questionnaire), subjective perception of improvement and adverse events (AE) were documented. Results – 140 patients (53.5% women, mean age 47 years) decided to switch to TPM due to insufficient effectiveness (75% of patients) and/or poor tolerability (80%) of the CBZ/OXC treatment. Average duration of follow‐up was 24 weeks with an overall discontinuation rate of 19.3%, mainly due to AEs (12.1%). At study endpoint, the intended shift to TPM monotherapy was achieved in 73% of patients at a median TPM dose of 100 mg/day. A seizure reduction of ≥ 50% was achieved in 91% of patients in the last scheduled period (weeks 12–26); 62% of patients entering that period remained seizure free. Quality of life at endpoint improved significantly when compared with baseline for all domains of QOLIE‐10 (P < 0.001). Most frequent AEs (reported by ≥ 5% of patients) were paresthesia (9.3%), weight loss (7.9%), convulsions (5.7%) and memory disorders (5.0%). Conclusion – In patients with epilepsy, previously not satisfactorily treated with CBZ or OXC, conversion to TPM may result in an improvement in seizure control as well as in quality of life.     

Effects of Discontinuation of Phenytoin, Carbamazepine, and Valproate on Concomitant Antiepileptic Medication

We report a prospective, controlled study of the effects of the reduction and discontinuation of phenytoin (PHT) (22 patients), carbamazepine (CBZ) (23 patients), and valproate (VPA) (25 patients) with concomitant antiepileptic drugs (AEDs). The principal changes in the serum concentrations of concomitant AEDs were (a) phenobarbital (PB) concentrations decreased by a mean of 30% on discontinuation of PHT; (b) total CBZ concentrations increased by a mean of 48% and free CBZ concentrations increased by a mean of 30% on discontinuation of PHT, with no change in CBZ-10, 11-epoxide (CBZ-E) concentrations; (c) VPA concentrations increased by a mean of 19% on discontinuation of PHT; (d) VPA concentrations increased by a mean of 42% on discontinuation of CBZ; (e) ethosuximide (ESM) concentrations increased by a mean of 48% on discontinuation of CBZ; (f) PHT concentrations decreased by a mean of 26% on discontinuation of CBZ; (g) PHT free fraction decreased from a mean of 0.11 to 0.07 on discontinuation of VPA; and (h) the mean concentrations of total and free CBZ increased by a mean of 10 and 16%, respectively, on VPA discontinuation, with a concomitant mean 24% decrease in total CBZ-E and a 22% decrease in free CBZ-E. Apart from the decrease in PB concentrations on PHT discontinuation, all significant changes had occurred by 1 week after the end of AED discontinuation. The implication for clinical practice is that a serum AED concentration at this time reflects the new steady state. Free concentrations did not add any clinically useful information to that gained from analysis of total serum concentrations.     

Effects of antiepileptic drugs on delivery and early childhood--comparison among mono-therapies of valproic acid, phenytoin, carbamazepine and phenobarbital

The effects of antiepileptic drugs (AED) on infants during pregnancy and delivery were studied in a total of 82 epileptic mothers on various monotherapies; 29 cases receiving valproic acid (VPA), 20 receiving phenytoin (PHT), 18 on carbamazepine (CBZ) and 15 on phenobarbital (PB). While AED serum concentrations were low in most cases of VPA, PHT and PB except for one case of VPA which exceeded therapeutic limits, concentrations were within therapeutic levels in many cases of CBZ. Conclusion: When compared with normal controls, abnormal deliveries such as caesarian section were seen more frequently in epileptic mothers under AED treatment. In addition, infants in PB cases were shown to have significantly lower mean birth length, weight and head circumference, suggesting that PB may retard fetal growth. The incidence of malformation in cases of VPA, PHT, CBZ and PB, was 10.3%, 5.0%, 0% and 6.7%, respectively. There were five types of malformation: in VPA cases, spina bifida, Siamese twins and ventricular septal defect tended to be severe, while in PHT and PB cases, cor biloculare and hypospadias respectively were observed. In cases of VPA, serum levels in the umbilical cord were found to be 150% higher than those in the mother.     

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.     

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.     

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.

     

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.     

Interactions Between Anticonvulsants and Other Commonly Prescribed Drugs

Summary: Many drug interactions can be demonstrated, but only a few are so clinically significant that they necessitate adjusting drug dosages. The same drug combination may produce changes of variable extent or direction in different individuals. The reasons for this variability include genetic control of the rate and inducibility of drug metabolism, and environmental factors such as contact with chemicals. Among antimicrobial agents, chloramphenicol may cause accumulation of phenytoin (PHT) and phenobarbital (PB), and isoniazid may cause PHT, carbamazepine (CBZ), and primidone (PRM) to accumulate. Erythromycin may cause accumulation of CBZ. Among antiulcer agents, antacids may reduce PHT concentration while cimetidine may cause accumulation of PHT, CBZ, and diazepam (DZP). Salicylates displace strongly binding drugs such as PHT, DZP, or valproate (VPA) from the binding sites in plasma proteins, which may lead to some decline of the total plasma level with an increase in the unbound drug percentage. Conversely, anticonvulsants may influence the dosage requirements of oral anticoagulants by inducing their metabolism. Failures of oral contraceptives have been attributed to anticonvulsants in some patients. Probably the most predictable interaction that necessitates dosage adjustment is accumulation of PB caused by VPA. Intentional inhibition of PRM metabolism by nicotinamide serves as an example of attempts to utilize an interaction for improved therapeutic effect.     

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)     

Evaluation of the Mechanisms of Antiepileptic Drug-Related Chronic Leukopenia

Summary: Antiepileptic drug (AED)-related chronic leukopenia [white blood cell (WBC) count <4,000/μl] is a dilemma, especially when the AED is effective in controlling seizures. We evaluated the possible mechanisms of leukopenia in 7 patients. Mean WBC count was 3,000/μ1 with a mean of 42% polymorphonuclear leukocytes (PMN). The AEDs were carbamazepine (CBZ) alone in 1 patient or CBZ combined with phenytoin (PHT), primidone (PRM), phenobarbital (PB) and/or valproate (VPA) in 5 patients; one patient was receiving PHT only. Bone marrow (BM) aspirates and PMN antibody studies using chemiluminescence were normal. Two liver-spleen scans showed mild relative splenomegaly. After exercise, WBC count (n = 7) increased by 54% (SEM 12%), while the WBC counts in controls (n = 5) increased by 52 ±16%. Antinuclear antibodies (Hep-2) were absent in 6 patients and positive (1:160) in 1. PMN adhesion to nylon wool was decreased (54 ±10% in patients vs. 80 ± 5% in controls: n = 13, p < 0.00s). Our data, particularly the appropriate WBC response to the stress of exercise, and normal BM examinations suggest that continuation of AED therapy when leukopenia is stable and the percentage of PMN is normal is probably safe. Caution should be used if the absolute PMN count is consistently <1,000/μl. BM examinations need not be performed routinely for every patient with neutropenia due to AEDs, especially if the leukopenia fluctuates in the range of 2,000–4,000 cells/μ1.     

Therapeutic antiepileptic drug monitoring: thirteen years of experience in the Laboratory of Clinical Neuropharmacology in the Chair and Department of Developmental neurology

Determining antiepileptic drug (AED) concentration in biological fluids and calculating its dosage on this basis is a long-term method in the treatment of epilepsy. This facilitates the treatment and increases the safety of patients in the aspect of suitable seizure control and reduced risk of side effects. This report presented the range and the number of antiepileptic drug concentration determined during thirteen years activity of Laboratory of Clinical Neuropharmacology in the Department of Developmental Neurology. There was also a number of drug concentrations particularly often determined presented, compared and discussed. Moreover, there were also analyses of subtherapeutic, therapeutic and potentially toxic concentration decomposition presented for subsequent AEDs. The frequency of conventional drug and of slow released forms for VPA and CBZ was compared. VPA appeared to be the most frequently monitored drug and CBZ occurred to be the next one. The concentrations of PHT, PB, PRM and ETH were more rarely determined. In the observed period of time the number of LPP concentration determined in the therapeutic range amounted to 69%, the least frequently the potentially toxic levels were determined--11%. Normal concentrations i.e. therapeutic ones were most often determined for CBZ (77%) and subtherapeutic levels were determined mostly for PHT.     

Plasma levels of antiepileptic agents in the treatment of epilepsy

From a total of 560 different epileptics visited during 16 months, we have practiced 140 plasmatic dosifications of antiepileptic drugs according to EMIT technic. The antiepileptic drugs studied were: PB, DPH, PRM, VPA, CBZ and ESM. In this study only the 70 patients treated with PB in monotherapy or combined with DPH, CBZ, VPA and PRM are considered. From the 70 patients, 45 have been controlled; from them 21 (46,5%) did not reach efficient levels from anyone of the used antiepileptics. From the 70 patients 25 have been partially or bad controlled, 20 of them (80%) had PB in efficient levels, 13 (52%) had the other antiepileptic in efficient levels, 12 (47%) had both antiepileptics in efficient levels and 4 (16%) had no antiepileptic drug in efficient levels in spite of using the efficient dose in mg/Kg/day. The conclusions of this results are: we reached a good effect by using PB alone or combined under the considered efficient levels in a 46.5% of the patients; the bad controlled patients, kept on being bad controlled in spite of having 80% of them PB, the other antiepileptic or both in efficient levels.     

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.