Drug interactions with valproic acid

Population pharmacokinetics of valproic acid in adult Chinese patients with bipolar disorder

PURPOSE

To develop and validate a population pharmacokinetic (PPK) model of valproic acid (VPA) in adult Chinese patients with bipolar disorder, and provide guidance for individualized therapy in this population.

METHODS

A total of 1104 serum concentrations from 272 patients were collected in this study. The data analysis was performed using a nonlinear mixed-effects modeling approach. Covariates included demographic parameters, biological characteristics, and concomitant medications. Bootstrap validation (1000 runs), normalized prediction distribution error (NPDE), and external validation of 50 patients were employed to evaluate the final model.

RESULTS

A one-compartment model with first-order absorption and elimination was developed for VPA extended-release tablets. VPA clearance was significantly influenced by three variables: sex (12% higher in male patients), daily dose (increasing with the 0.13 exponent), and body weight (increasing with the 0.56 exponent). Typical values for the absorption rate constant (K_a), apparent clearance (CL/F), and apparent distribution volume (V/F) for a female patient weighing 70 kg administered VPA 1000 mg/day were 0.18 h^-1, 0.46 L/h, and 12.84 L, respectively. The results of model evaluation indicated a good stable and precise performance of the final model.

CONCLUSIONS

A qualified PPK model of VPA was developed in Chinese patients with bipolar disorder. This model could be used as a suitable tool for the personalization of VPA dosing for bipolar patients.

Valproic Acid in the Treatment of Migraines

Migraine headaches can be a disabling condition for patients. Fortunately, most patients can be successfully managed in the outpatient setting, however, there are a number of patients who may not respond to the abortive treatments that they have been prescribed. These patients often present to the emergency department (ED) for further assistance with the management of their condition. Migraines are the fourth most common cause of ED visits and are associated with an estimated annual cost of $17 billion in the United States. Familiarity with abortive treatments is critical for providers in the ED as are treatments, such as valproic acid, that may be considered in patients who do not respond to other treatment options. Many providers are more familiar with the role of valproic acid in the treatment of mood and seizure disorders, but its tolerability and the successes reported in the primary literature make it a reasonable consideration for patients with migraine who fail to respond to other therapies. This article briefly summarizes the therapies considered first line for abortive treatment in the setting of migraines and provides an overview of the primary literature describing the use of valproic acid in these patients.

Accuracy of Calculated Free Valproate Levels in Adult Patients With Status Epilepticus

OBJECTIVE

To test the accuracy of an equation in adult patients with status epilepticus that calculates the free concentration of serum valproic acid (fVPA) from the total concentration of serum valproic acid (tVPA) and serum albumin.

METHODS

All adult patients with status epilepticus who were treated at a Swiss academic medical center between 2005 and 2018 with concurrent measurements of tVPA, fVPA, and serum albumin were included. fVPA was categorized as subtherapeutic, therapeutic (5-10 mg/L), or supratherapeutic. Agreement was defined as the proportion of measured and calculated fVPA falling within the same category.

RESULTS

Of 676 patients with status epilepticus, 104 had 506 measurements, with a median of 3 (interquartile range [IQR] 1.5-6.5) per patient. The median tVPA was 43.5 mg/L (27.4-63.6), with measured fVPA 9.1 mg/L (4.5-14.7) and calculated fVPA 10.1 mg/L (7.0-13.0), respectively. The median deviation of calculated from measured fVPA was -0.8 mg/L (-3.2 to 2.5) with 336 measurements >1 mg/L. While the association between measured and calculated fVPA was linear (regression coefficient 1.1, 95% confidence interval 0.9-1.2, p < 0.0001), the agreement on effective drug levels did not match in 39.8% of measurements regardless of serum albumin levels, with calculated fVPA overestimating measured fVPA in 30.4%. tVPA and serum albumin independently influenced the accuracy of the calculated fVPA in the multivariable model.

CONCLUSIONS

Calculated fVPA is inaccurate when using the proposed equation in adult patients with status epilepticus, calling for drug monitoring based on measured fVPA in this context.

Pharmacokinetics of thiotepa in high-dose regimens for autologous hematopoietic stem cell transplant in Japanese patients with pediatric tumors or adult lymphoma

Purpose

Thiotepa is used in high-dose chemotherapy (HDT) before autologous hematopoietic stem cell transplantation (HSCT) to treat solid tumors and hematological malignancies. This Phase 1 study was conducted to establish the pharmacokinetics (PK) of thiotepa in a Japanese population.

Methods

HDT/HSCT was performed in pediatric patients (≥ 2 years) with solid tumors or brain tumors (thiotepa 200 mg/m²/day IV-infused over 24 h on HSCT Days − 12, − 11, − 5, and − 4 and melphalan 70 mg/m²/day IV-infused over 1 h on Days − 11, − 5, and − 4) and adult patients (≥ 16 years) with malignant lymphoma (thiotepa 200 mg/m²/day 2-h IV-infusion on HSCT Days − 4 and − 3 plus busulfan 0.8 mg/kg 2-h IV-infusion every 6 h from HSCT Days − 8 to − 5). Pharmacokinetics of thiotepa were assessed following initial dose. Safety and efficacy were also evaluated.

Results

Nine pediatric and 10 adult patients were enrolled. Mean volume of distribution (V_z) of thiotepa normalized with body surface area (BSA) was lower for pediatric patients (16.4 L/m²) compared with adult patients (26.4 L/m²) as expected due to the higher specific surface area of children. Clearance and biological half-life were similar between pediatric and adult patients. Two serious adverse events (cardiac arrest and pulmonary edema) were observed. Survival rate (Day 100 post-HSCT) was 77.8% (95% CI 36.5–93.9%) for pediatric patients and 100% for adult patients.

Conclusion

Thiotepa elimination was comparable in pediatric and adult patients with cancer. Lower V_z in pediatric compared with adult patients was expected. HDT with thiotepa prior to autologous HSCT was well tolerated.

Study registration

Japic CTI-163433.

Electronic supplementary material

The online version of this article (10.1007/s00280-019-03914-2) contains supplementary material, which is available to authorized users.

In vivo effects of naproxen, salicylic acid, and valproic acid on the pharmacokinetics of trichloroethylene and metabolites in rats

It was recently demonstrated that some drugs modulate in vitro metabolism of trichloroethylene (TCE) in humans and rats. The objective was to assess in vivo interactions between TCE and three drugs: naproxen (NA), valproic acid (VA), and salicylic acid (SA). Animals were exposed to TCE by inhalation (50 ppm for 6 h) and administered a bolus dose of drug by gavage, equivalent to 10-fold greater than the recommended daily dose. Samples of blood, urine, and collected tissues were analyzed by headspace gas chromatography coupled to an electron capture detector for TCE and metabolites (trichloroethanol [TCOH] and trichloroacetate [TCA]) levels. Coexposure to NA and TCE significantly increased (up to 50%) total and free TCOH (TCOHtotal and TCOHfree, respectively) in blood. This modulation may be explained by an inhibition of glucuronidation. VA significantly elevated TCE levels in blood (up to 50%) with a marked effect on TCOHtotal excretion in urine but not in blood. In contrast, SA produced an increase in TCOHtotal levels in blood at 30, 60, and 90 min and urine after coexposure. Data confirm in vitro observations that NA, VA, and SA affect in vivo TCE kinetics. Future efforts need to be directed to evaluate whether populations chronically medicated with the considered drugs display greater health risks related to TCE exposure.

Valproate as a mainstay of therapy for pediatric epilepsy

This article reviews relevant pharmacologic and clinical information gathered for valproate since it was introduced into clinical practice 37 years ago and the application of this information for the treatment of childhood epilepsy. Valproate is available for oral and parenteral use. Oral forms are almost completely bioavailable but the rate of absorption varies between formulations. The Chrono tablet formulation has not been adapted for children aged <6 years, in whom the oral solution or syrup, requiring two or three daily administrations, has been used until recently. A new formulation specifically adapted for children, Chronosphere, administrated once or twice daily, is a modified-release formulation of valproate that minimizes fluctuations in serum drug concentrations during a dosage interval. Plasma protein binding is 80-94% and tends to decrease with increasing drug concentration. Valproate elimination is markedly decreased in newborns compared with older children and adults. Elimination by glucuronidation only becomes fully effective by the age of 3-4 years. In children aged 2-10 years receiving valproate, plasma clearances are 50% higher than those in adults. Over the age of 10 years, pharmacokinetic parameters approximate those of adults. Valproate can increase plasma concentrations of concomitant drugs, such as phenobarbital and lamotrigine, by inhibiting their metabolism. As a result of its broad spectrum of efficacy in a wide range of seizure types and epilepsy syndromes, valproate is a drug of choice for children with newly diagnosed epilepsy (focal or generalized), idiopathic generalized epilepsy, epilepsies with prominent myoclonic seizures or with multiple seizure types, and photosensitive epilepsies. In the group of cognitive epilepsies, in which severe spike and wave discharges are accompanied by cognitive deterioration, valproate, ethosuximide, or both should be tested before using corticosteroids. In comparative trials with carbamazepine, phenytoin, and phenobarbital in focal epilepsy and with ethosuximide in absence epilepsy, valproate was as effective and showed a favorable tolerability profile, with minimal adverse cognitive and CNS effects. The low potential for paradoxical seizure aggravation and the long-term efficacy of the drug are additional important factors that contribute to its excellent profile. Intravenous valproate may be effective for the treatment of convulsive and non-convulsive status epilepticus that is refractory to conventional drugs. In infants, potential benefits should be carefully weighed against the risk of liver toxicity. Gastrointestinal intolerance is a relatively frequent, dose-related adverse effect of the drug in children. Bodyweight increase and tremor may be observed in older children and adolescents. Despite the challenge of newer drugs, valproate remains a gold standard antiepileptic drug for the treatment of children.

Effect of probenecid on the pharmacokinetics of carbamazepine in healthy subjects

OBJECTIVES

Carbamazepine (CBZ) undergoes biotransformation by CYP3A4 and CYP2C8, and glucuronide conjugation. There has been no clear demonstration to reveal the role of glucuronidation in the disposition of CBZ. We evaluated the effect of probenecid, a UDP-glucuronosyltransferase inhibitor, on the pharmacokinetics of CBZ in humans.

METHODS

In a randomized, open-label, two-way crossover study, ten healthy male subjects were treated twice daily for 10 days with 500 mg probenecid or with a matched placebo. On day 6, a single dose of 200 mg CBZ was administered orally. Concentrations of CBZ and CBZ 10,11-epoxide (CBZ-E) in plasma and urine were measured.

RESULTS

Probenecid decreased the area under the plasma concentration-time curve (AUC) of CBZ from 1253.9 micromol h/l to 1020.7 micromol h/l (P < 0.001) while increasing that of CBZ-E from 137.6 micromol h/l to 183.5 micromol h/l (P = 0.033). The oral clearance of CBZ was increased by probenecid by 26% (90% confidence interval, 17-34%; P < 0.001). Probenecid increased the AUC ratio of CBZ-E/CBZ from 0.11 to 0.16 (P < 0.001). However, probenecid had minimal effect on the recovery of the conjugated and free forms of CBZ and CBZ-E in urine.

CONCLUSION

Although probenecid showed a minimal effect on the glucuronidation of CBZ and CBZ-E, it increased CBZ biotransformation to CBZ-E, most likely reflecting the induction of CYP3A4 and CYP2C8 activities, in humans. These results demonstrate that glucuronide conjugation plays a minor role in the metabolism of CBZ and CBZ-E in humans, and that probenecid has an inducing effect on the disposition of CBZ.

Teratogenicity of sodium valproate

The teratogenicity of the widely popular antiepileptic drug (AED) and mood stabiliser sodium valproate (also known as valproate, VPA) has been evidenced by previous research; however, these findings have often been limited by a small population sample of exposed women and a retrospective study design. Many factors contribute to the teratogenicity of VPA. These include the number of drugs that are co-administered, drug dosage, differences in maternal and/or infant metabolism, the gestational age of the fetus at exposure, and hereditary susceptibility. VPA has been associated with a variety of major and minor malformations, including a 20-fold increase in neural tube defects, cleft lip and palate, cardiovascular abnormalities, genitourinary defects, developmental delay, endocrinological disorders, limb defects, and autism. It has been suggested that polytherapy treatment in epileptic pregnant women increases the risk of teratogenicity in offspring. Furthermore, there is an established relationship between VPA dose and adverse outcome. Large single doses of VPA potentially cause high peak levels in the fetal serum resulting in deleterious effects. Currently there is an increase in the number of national and international pregnancy registries being formed in an effort to better identify the teratogenic effects of AEDs. These efforts hope to enhance our understanding of AEDs and their associated risks by addressing past study limitations.

Drug treatment of epilepsy in elderly people: focus on valproic Acid

Despite old age being the commonest time of life to develop epilepsy, relatively little is known about the condition in later years. Antiepileptic drugs (AEDs) are the mainstay of treatment and valproic acid (VPA) has been prescribed for older patients with seizures for over 35 years. VPA is available in a variety of formulations. The drug is generally rapidly absorbed, although there are no data on the extent of oral absorption in the elderly. The volume of distribution (Vd) and elimination half-life have been compared in older and younger patients. One study reported no change in either parameter between elderly and younger patients (Vd: 0.16 vs 0.14 L/kg; elimination half-life: 15.3 vs 13.0h), the other found an increase in both for older patients (Vd: 0.19 vs 0.13 L/kg; elimination half-life 14.9 vs 7.2h). Total VPA clearance is similar in young and elderly subjects. The drug does not induce the metabolism of hepatic enzymes, but can act as a metabolic inhibitor, raising plasma concentrations of lamotrigine, phenobarbital (phenobarbitone), carbamazepine-10-11-epoxide, lorazepam, nimodipine and zidovudine. Concomitant use of VPA may also lead to an elevation in phenytoin, diazepam, warfarin, amitriptyline and chlorpromazine concentrations. A number of enzyme-inducing AEDs such as phenytoin, phenobarbital, primidone and carbamazepine can increase the clearance of VPA. Plasma concentrations of VPA may also rise when the drug is administered with felbamate, stiripentol, aspirin (acetylsalicylic acid), naproxen, phenylbutazone, isoniazid, fluoxetine and chlorpromazine. The majority of elderly patients present with partial and/or secondary generalised seizures, although a few have long-standing primary generalised seizures. Results from meta-analyses and randomised studies of patients comparing VPA with other AED monotherapies suggest that the drug is as effective as carbamazepine, phenytoin and phenobarbital in treating these seizure types. Although some of these studies recruited older patients, there have been no randomised double-blind trials examining the efficacy of VPA with other AEDs in an exclusively elderly cohort. There is no direct correlation between efficacy and plasma VPA concentrations. The majority of older patients require lower doses of AEDs than younger adults. Higher VPA doses may be needed in patients taking drugs which induce hepatic microsomal enzymes. Once-daily dosing of the controlled-release preparation can help to improve compliance and may render some frail elderly people seizure free. There is a perception that the elderly are generally more susceptible to the adverse effects of AEDs than younger adults, although there are few data to validate this claim. Dose-dependent and idiosyncratic reactions may be more frequent. Common adverse effects of VPA include gastrointestinal symptoms and tremor. Slow-dose escalation and controlled-release preparations may minimise these. In summary, VPA is a long established AED. Its broad spectrum of action and dosing schedule are favourable properties for its use in older people. To accurately establish the place of this and other AEDs in treating elderly patients with epilepsy, well designed clinical trials are urgently required in this vulnerable population.

The effect of valproic acid on drug and steroid glucuronidation by expressed human UDP-glucuronosyltransferases

Valproic acid glucuronidation kinetics were carried our with three human UGT isoforms: UGT1A6, UGT1A9, and UGT2B7 as well as human liver and kidney microsomes. The glucuronidation of valproic acid was typified by high K(m) values with microsomes and expressed UGTs (2.3-5.2mM). The ability of valproic acid to interact with the glucuronidation of drugs, steroids and xenobiotics in vitro was investigated using the three UGT isoforms known to glucuronidate valproic acid. In addition to this the effect of valproic acid was investigated using two other UGT isoforms: UGT1A1 and UGT2B15 which do not glucuronidate valproic acid. Valproic acid inhibited UGT1A9 catalyzed propofol glucuronidation in an uncompetitive manner and UGT2B7 catalyzed AZT glucuronidation competitively (K(i)=1.6+/-0.06mM). Valproate significantly inhibited UGT2B15 catalyzed steroid and xenobiotic glucuronidation although valproate was not a substrate for this UGT isoform. No significant inhibition of UGT1A1 or UGT1A6 by valproic acid was observed. These data indicate that valproic acid inhibition of glucuronidation reactions is not always due to simple competitive inhibition of substrates.

Pharmacological and therapeutic properties of valproate: a summary after 35 years of clinical experience

Thirty-five years since its introduction into clinical use, valproate (valproic acid) has become the most widely prescribed antiepileptic drug (AED) worldwide. Its pharmacological effects involve a variety of mechanisms, including increased gamma-aminobutyric acid (GABA)-ergic transmission, reduced release and/or effects of excitatory amino acids, blockade of voltage-gated sodium channels and modulation of dopaminergic and serotoninergic transmission. Valproate is available in different dosage forms for parenteral and oral use. All available oral formulations are almost completely bioavailable, but they differ in dissolution characteristics and absorption rates. In particular, sustained-release formulations are available that minimise fluctuations in serum drug concentrations during a dosing interval and can therefore be given once or twice daily. Valproic acid is about 90% bound to plasma proteins, and the degree of binding decreases with increasing drug concentration within the clinically occurring range. Valproic acid is extensively metabolised by microsomal glucuronide conjugation, mitochondrial beta-oxidation and cytochrome P450-dependent omega-, (omega-1)- and (omega-2)-oxidation. The elimination half-life is in the order of 9 to 18 hours, but shorter values (5 to 12 hours) are observed in patients comedicated with enzyme-inducing agents such as phenytoin, carbamazepine and barbiturates. Valproate itself is devoid of enzyme-inducing properties, but it has the potential of inhibiting drug metabolism and can increase by this mechanism the plasma concentrations of certain coadministered drugs, including phenobarbital (phenobarbitone), lamotrigine and zidovudine. Valproate is a broad spectrum AED, being effective against all seizure types. In patients with newly diagnosed partial seizures (with or without secondary generalisation) and/or primarily generalised tonic-clonic seizures, the efficacy of valproate is comparable to that of phenytoin, carbamazepine and phenobarbital, although in most comparative trials the tolerability of phenobarbital was inferior to that of the other drugs. Valproate is generally regarded as a first-choice agent for most forms of idiopathic and symptomatic generalised epilepsies. Many of these syndromes are associated with multiple seizure types, including tonic-clonic, myoclonic and absence seizures, and prescription of a broad-spectrum drug such as valproate has clear advantages in this situation. A number of reports have also suggested that intravenous valproate could be of value in the treatment of convulsive and nonconvulsive status epilepticus, but further studies are required to establish in more detail the role of the drug in this indication. The most commonly reported adverse effects of valproate include gastrointestinal disturbances, tremor and bodyweight gain. Other notable adverse effects include encephalopathy symptoms (at times associated with hyperammonaemia), platelet disorders, pancreatitis, liver toxicity (with an overall incidence of 1 in 20,000, but a frequency as high as 1 in 600 or 1 in 800 in high-risk groups such as infants below 2 years of age receiving anticonvulsant polytherapy) and teratogenicity, including a 1 to 3% risk of neural tube defects. Some studies have also suggested that menstrual disorders and certain clinical, ultrasound or endocrine manifestations of reproductive system disorders, including polycystic ovary syndrome, may be more common in women treated with valproate than in those treated with other AEDs. However, the precise relevance of the latter findings remains to be evaluated in large, prospective, randomised studies.

In vitro evaluation of valproic acid as an inhibitor of human cytochrome P450 isoforms: preferential inhibition of cytochrome P450 2C9 (CYP2C9)

AIMS

To evaluate the potency and specificity of valproic acid as an inhibitor of the activity of different human CYP isoforms in liver microsomes.

METHODS

Using pooled human liver microsomes, the effects of valproic acid on seven CYP isoform specific marker reactions were measured: phenacetin O-deethylase (CYP1A2), coumarin 7-hydroxylase (CYP2A6), tolbutamide hydroxylase (CYP2C9), S-mephenytoin 4'-hydroxylase (CYP2C19), dextromethorphan O-demethylase (CYP2D6), chlorzoxazone 6-hydroxylase (CYP2E1) and midazolam 1'-hydroxylase (CYP3A4).

RESULTS

Valproic acid competitively inhibited CYP2C9 activity with a Ki value of 600 microM. In addition, valproic acid slightly inhibited CYP2C19 activity (Ki = 8553 microM, mixed inhibition) and CYP3A4 activity (Ki = 7975 microM, competitive inhibition). The inhibition of CYP2A6 activity by valproic acid was time-, concentration- and NADPH-dependent (KI = 9150 microM, Kinact=0.048 min(-1)), consistent with mechanism-based inhibition of CYP2A6. However, minimal inhibition of CYP1A2, CYP2D6 and CYP2E1 activities was observed.

CONCLUSIONS

Valproic acid inhibits the activity of CYP2C9 at clinically relevant concentrations in human liver microsomes. Inhibition of CYP2C9 can explain some of the effects of valproic acid on the pharmacokinetics of other drugs, such as phenytoin. Co-administration of high doses of valproic acid with drugs that are primarily metabolized by CYP2C9 may result in significant drug interactions.

Investigation of phenobarbital-carbamazepine-valproic acid interactions using population pharmacokinetic analysis for optimisation of antiepileptic drug therapy: an overview

Antiepileptic drugs are associated with a wide range of drug interactions. Although monotherapy with antiepileptic drugs is preferred, patients with multiple seizure types or refractory disease generally require various combinations of antiepileptic drugs. Pharmacokinetic interactions between antiepileptic drugs represent a major complication of epilepsy treatment with polytherapy. It is important to be aware of possible interactions, so as to anticipate clinical effects and to reduce the risk of both toxicity and seizures worsening when a drug is added to, or withdrawn from, the patient's antiepileptic drug regimen. This report is an overview of the drug-drug interactions between antiepileptic drugs (phenobarbital<-->carbamazepine, carbamazepine<-->valproic acid and phenobarbital<-->valproic acid) by population pharmacokinetic analysis.

Population-based investigations of drug relative clearance using nonlinear mixed-effect modelling from information generated during the routine clinical care of patients

Interpatient variability in drug disposition and response is a therapeutic premise, and thus evaluation and management of such variability are the basis for individualized pharmacotherapy. If the mathematical approach to determining drug doses were accurate and practical, the use of calculated doses could reduce the potential for toxicity and decrease the need for repetitious drug assays. The major strength of the population pharmacokinetics approach is that useful information can be extracted from sparse data collected during routine clinical care. Population pharmacokinetics can be defined as the study of the variability in serum drug concentrations between individuals when standard dosage regimens are administered. An approach to population pharmacokinetic data analysis has been implemented in the Nonlinear Mixed Effects Model (NONMEM) computer program. This report shows the feasibility of using a simple pharmacokinetic screen approach to estimate the population mean relative drug clearance and detecting drug-drug interaction by use of NONMEM. In clinical application of multiple trough screen or multiple peak screen, the variability of drug relative clearance within the population is assessed and a mathematical relationship between drug relative clearance and individual patient characteristics, such as age, body weight, gender, disease state or drug interaction with concomitant drug is derived. In this report I describe this approach and its application using several examples previously reported by us and others.

Valproate population pharmacokinetics in children

OBJECTIVE

A population analysis of the kinetics of valproic acid (VPA) in children with epilepsy was performed in order to characterize the covariates which influence VPA clearance (CL).

METHODS

A total of 770 steady-state serum concentration samples was analysed. These were collected during VPA therapy from 255 children, aged 0.1-14 years and weighting 4-74 kg. Age, total body weight (TBW), VPA daily dose, sex and comedication with carbamazepine (CBZ) were considered as covariates. Population analysis was made with NONMEM program, assuming a one-compartment model, fixing the VPA absorption rate, bioavailability and distribution volume at values found in the literature. The results of the population pharmacokinetics analysis were validated in a group of 45 epileptic patients.

RESULTS

The final regression model for VPA clearance, that included TBW (kg), daily dose (mg/kg) and CBZ comedication as covariates with a significant influence on this parameter, was as follows: CL (L/h) = 0.012 TBW0.715 DOSE0.306(1.359 CBZ). The coefficient of variation for interpatient variability in CL was 21.4% and the residual variability estimated was 23.9% for a concentration of 65 mg/l. In order to estimate the predictive performance of the selected final model, predictions of the VPA serum concentrations were calculated and compared with VPA measured concentrations in the validation group. This assessment revealed an important improvement in the predictive performance of VPA concentrations in comparison with the basic model that did not include any covariates (root squared mean error: 19.50 vs. 39.73 mg/l).

CONCLUSION

A population pharmacokinetic model is proposed to estimate the individual CL for paediatric patients receiving VPA in terms of patient's dose, weight and concomitant CBZ, in order to establish a priori dosage regimens.

Modelling of the pharmacodynamic interaction between phenytoin and sodium valproate

Treatment of epilepsy with a combination of antiepileptic drugs remains the therapeutic choice when monotherapy fails. In this study, we apply pharmacokinetic-pharmacodynamic modelling to characterize the interaction between phenytoin (PHT) and sodium valproate (VPA). Male Wistar rats received a 40 mg kg(-1) intravenous dose of PHT over 5 min either alone or in combination with an infusion of VPA resulting in a steady-state concentration of 115.5+/-4.9 microg ml(-1). A control group received only the infusion of VPA. The increase in the threshold for generalized seizure activity (ATGS) was used as measure of the anticonvulsant effect. PHT pharmacokinetics was described by a pharmacokinetic model with Michaelis-Menten elimination. The concentration-time course and plasma protein binding of PHT were not altered by VPA. The pharmacokinetic parameters Vmax and Km were, respectively, 294+/-63 microg min(-1) and 7.8+/-2.4 microg ml(-1) in the absence of VPA and 562+/-40 microg min(-1) and 15.6+/-0.9 microg ml(-1) upon administration in combination with VPA. A delay of the onset of the effect relative to plasma concentrations of PHT was observed. The assessment of PHT concentrations at the effect site was based on the effect-compartment model, yielding mean ke0 values of 0.128 and 0.107 min(-1) in the presence and absence of VPA, respectively. A nonlinear relationship between effect-site concentration and the increase in the TGS was observed. The concentration that causes an increase of 50% in the baseline TGS (EC50%TGS) was used to compare drug potency. A shift of EC50%TGS from 13.27+3.55 to 4.32+/-0.52 microg ml(-1) was observed upon combination with VPA (P<0.01). It is concluded that there is a synergistic pharmacodynamic interaction between PHT and VPA in vivo.

A mechanistic approach to antiepileptic drug interactions

OBJECTIVE

To describe the primary types of antiepileptic drug (AED) interactions by using a mechanistic approach.

DATA SOURCES

A literature search was performed using MEDLINE and bibliographies of recent review articles and published abstracts.

DISCUSSION

AEDs are associated with a wide range of drug interactions, including hepatic enzyme induction and inhibition and protein-binding displacement. Hepatic induction by AEDs affects the metabolism of a limited number of drugs with low therapeutic indices. Anticipation of induction interactions and careful clinical monitoring may alleviate potential problems. Most commonly used AEDs are eliminated through hepatic metabolism catalyzed by the cytochrome P450 (CYP) and uridine diphosphate glucuronosyltransferase (UGT) enzymes. Phenytoin, phenobarbital, and carbamazepine induce CYP and UGT enzymes. Lamotrigine is a weak inducer of UGT. Valproate is a broad-spectrum inhibitor of UGT enzymes, epoxide hydrolase, and CYP2C enzymes. Felbamate induces CYP3A4, but inhibits CYP2C19 substrates. Topiramate inhibits only CYP2C19 substrates. Ethosuximide, gabapentin, tiagabine, and vigabatrin are neither inducers nor inhibitors of drug metabolism. Hepatic enzyme inhibition usually occurs because of competition at the enzyme site. Knowledge of the specific metabolic enzymes involved in the metabolism of AEDs allows clinicians to predict potential interactions.

CONCLUSIONS

By understanding the mechanisms of drug interactions, the pharmacist can play a key role in patient care by anticipating and preventing AED drug interactions.

Assessment and treatment of bipolar disorder in the elderly

The aetiology of late-onset bipolar disorder is heterogeneous because the disease is more likely to have a secondary (i.e. a medical disorder or medication-induced) cause in older than in younger patients. Elderly patients with bipolar disorder typically require lithium dosages that are 25 to 50% lower than those used in younger individuals. Information on the use of valproic acid (sodium valproate) in elderly patients with bipolar disorder is limited but encouraging. In contrast, there is virtually no information regarding the use of carbamazepine or other drugs in this patient group. Electroconvulsive therapy is well tolerated by older people and can be useful for these patients.

Population-based investigation of valproic acid relative clearance using nonlinear mixed effects modeling: influence of drug-drug interaction and patient characteristics

Nonlinear mixed effects modeling (NONMEM) was used to estimate the effects of drug-drug interaction on valproic acid relative clearance values using 792 serum levels gathered from 400 pediatric and adult patients with epilepsy (age range, 0.3-54.8 years) during their clinical routine care. Patients received valproic acid as monopharmacy or in combination with either the antiepileptic drugs, phenobarbital, or carbamazepine. The final model describing valproic acid relative clearance was CL (mL/hr/kg) = 15.6.TBW (kg)-0.252.DOSE (mg/kg/day)0.183.0.898GEN.COPB.COCBZ, where COPB equals 1.10 if the patient is treated with phenobarbital, a value of unity otherwise, and COCBZ equals 0.769.DOSE (mg/kg/day)0.179 if the patient is treated with carbamazepine, a value of unity otherwise. Valproic acid relative clearance was highest in the very young and decreased in a weight-related fashion in children, with minimal changes observed in adults. This pattern was consistent whether valproic acid was administered alone or coadministered with phenobarbital or carbamazepine. When valproic acid was coadministered with phenobarbital or carbamazepine, valproic acid relative clearance increased as compared with that in monopharmacy. Its magnitude in the presence of carbamazepine increased in a valproic acid daily dose-related fashion. Concomitant administration of phenobarbital and valproic acid resulted in a 10% increase on valproic acid relative clearance. The clearance in female patients was approximately 10% less than that in male patients.

Established antiepileptic drugs

Despite the recent entry into the market-place of a range of new pharmacological treatments for epilepsy, most patients still receive the standard antiepileptic drugs. This review considers the clinical place and practical use of these agents. Detailed consideration is given to carbamazepine, phenytoin, sodium valproate, phenobarbital and ethosuximide, with lesser emphasis on primidone, clobazam and clonazepam. Individualization of therapy, polypharmacy, refractory epilepsy, therapeutic drug monitoring, pregnancy, withdrawing treatment, epilepsy prophylaxis and referral to an epilepsy centre are also discussed. The paper concludes with a statement of 12 basic rules in prescribing established antiepileptic drugs.

Comparison of the steady-state pharmacokinetics of topiramate and valproate in patients with epilepsy during monotherapy and concomitant therapy

PURPOSE

The steady-state pharmacokinetics of valproate (VPA) and topiramate (TPM) were compared during VPA monotherapy, concomitant VPA and TPM therapy, and TPM monotherapy to evaluate pharmacokinetic interactions.

METHODS

After a 3-week baseline period, 12 patients receiving VPA monotherapy (500 to 2,250 mg every 12 h) received TPM at three escalating doses (from 100 to 200 to 400 mg every 12 h), each for 2 weeks. Thereafter, the VPA dose was tapered by 25% weekly. Blood and urine samples were collected over 12-h intervals during VPA monotherapy and at the end of each stage of TPM dose escalation and TPM monotherapy.

RESULTS

All patients reached TPM monotherapy, and nine achieved satisfactory seizure control for > or = 2 weeks without VPA. TPM plasma peak concentration (C(max)) and area under the concentration-versus-time curve during a 12-h dosing interval (AUC(0-12)) were slightly higher (17%; n = 8) during TPM monotherapy than during concomitant VPA therapy. TPM oral and renal clearances (n = 8) were 25.9 +/- 4.6 and 11.6 +/- 3.2 ml/min during TPM monotherapy and were 29.8 +/- 4.2 and 12.4 +/- 2.7 ml/min during VPA concomitant therapy. VPA AUC(0-12) decreased (11.3%; n = 10) with the addition of TPM 400 mg every 12 h. VPA oral clearance was 12.8 +/- 4.1 ml/min during monotherapy and was 13.8 +/- 4.0, 14.1 +/- 3.9, and 14.5 +/- 5.2 ml/min during coadministration of TPM 100, 200, and 400 mg every 12 h, respectively. Cognitive dysfunction, observed in some patients receiving high doses of VPA with TPM, reversed or improved with VPA dose reduction and discontinuation. The lower-than-normal prestudy platelet count measured in one patient increased to normal levels when VPA was discontinued.

CONCLUSIONS

Because changes in TPM and VPA pharmacokinetics were small, it is unlikely that their concomitant use will have a significant impact on the clinical condition of the patient.

The emerging role of valproate in bipolar disorder and other psychiatric disorders

Although valproate, a simple branched-chain fatty acid, is generally considered to be an antiepileptic agent, a large literature dating back to 1966 describes its use in primary psychiatric disorders. The significant role that gamma-aminobutyric acid plays in mood provided the rationale to examine valproate in this regard. Numerous uncontrolled as well as placebo- and lithium-controlled studies verified the drug's efficacy in the short-term management of bipolar and schizoaffective disorders. The response appears to be independent of response to traditional therapies such as lithium, neuroleptics, and carbamazepine, and may be maintained for extended periods of time. Valproate should be considered not only in patients with mood disorders who are intolerant of or nonresponsive to traditional therapies, but also in those with rapid cycling, electroencephalographic abnormalities, head trauma antedating the onset of psychiatric illness, or any other factor suggesting an organic component. Preliminary uncontrolled studies suggest that the drug may also eventually play a role in the management of panic disorder and behavioral dyscontrol (agitation, aggression, temper outbursts). Its adverse event profile is well known from years of experience in the management of epilepsy and does not appear to be altered in the presence of psychiatric disorders. Similarly, the drug-drug interaction potential of valproate is reasonably well known, although further research into interactions with psychotropic agents is warranted.

Adverse effects of established and new antiepileptic drugs: an attempted comparison

Seizures are but one aspect of the negative impact epilepsy has on patients' lives. Adverse effects of antiepileptic treatment may affect the patient's quality of life to an even greater extent than the occurrence of seizures. Adverse effects of antiepileptic drugs (AEDs) are common, and because the differences in efficacy are often marginal, adverse effects may be the most important factor in choosing the best AED for the patient. The search for more efficient and less toxic agents is constantly ongoing. Current evidence suggests that the new generation of AEDs is as efficient as the established AEDs and exhibits fewer adverse effects, but the scientific evidence from randomised clinical trials comparing established and new AEDs with each other is still pending.

Life threatening intoxication with sodium valproate

Two female epileptics, 19 and 27 years old, were admitted after ingestion of an overdose of sodium valproate. The patients were comatose for 6 and 7 days and required mechanical ventilation for 7 and 10 days. Both patients were in deep coma for several days after serum concentrations had dropped into the therapeutic range. Serum concentrations of sodium valproate were 3348 mumol/L (482 mg/mL) in one patient and more than 10,000 mumol/L (1440 mg/mL) in the other. Drug elimination followed first order kinetics, and the plasma half-lives of sodium valproate were 19 and 20 hours, respectively. Their anemia, leucopenia and thrombocytopenia required transfusion. Liver enzymes were only moderately elevated, but one of the patients developed acute pancreatitis. There were no apparent sequelae two weeks after discharge from the hospital.

Valproic acid intensifies the depressant action of phenobarbital and ethanol by a pharmacodynamic mechanism

This investigation was designed to determine whether valproic acid (VPA) affects the pharmacodynamics of the depressant action of phenobarbital (PB) and ethanol. Rats received sodium valproate iv, 150 mg/kg, or saline, followed 20 min later by a constant infusion of either PB or ethanol until onset of anesthesia. At that time the concentrations of the depressant drugs in biological fluids were determined. In order to induce anesthesia, VPA-treated rats required significantly lower PB total serum concentrations (36% reduction) as well as lower PB cerebrospinal fluid concentrations (20% reduction). Similarly, the ethanol dose required to induce onset of sleep was about 35% lower, and the serum ethanol concentrations at that endpoint were 44% lower in the VPA-treated group as compared to corresponding controls. These results indicate that VPA accentuates the effect of the depressant action of ethanol and PB on the central nervous system.

A double-blind, placebo-controlled interaction study between oxcarbazepine and carbamazepine, sodium valproate and phenytoin in epileptic patients

1. The effect of carbamazepine (CBZ), sodium valproate (VPA) and phenytoin (PHT) on the pharmacokinetics of oxcarbazepine (OXC) was explored in three groups of 12 epileptic patients taking one of these drug as monotherapy. 2. Each patient took a single 600 mg dose of OXC followed 7 days later by 3 weeks' treatment with OXC 300 mg thrice daily and matched placebo in random order. 3. Seven untreated patients, acting as controls, were prescribed the single OXC dose and 3 weeks' active treatment only. 4. In those patients completing the study, the area under the concentration-time curve (AUC) at steady-state for hydroxycarbazepine (OHCZ), the active metabolite of OXC, was significantly lower in the CBZ-treated group than in controls (P < 0.05). 5. No other differences in AUCs or elimination half-lives for OHCZ were found between treated and untreated patients following single or multiple OXC dosing. 6. Median AUCs of CBZ, VPA and PHT during a dosage interval did not differ significantly after treatment with OXC and placebo. 7. Ten patients completing the study complained of side-effects during treatment with OXC compared with one taking placebo (P < 0.01). 8. There were no important changes in cognitive function testing during administration of OXC compared with placebo. 9. Standard doses of OXC can be given as add-on therapy in epileptic patients receiving CBZ, VPA or PHT without producing a clinically relevant pharmacokinetic interaction.

Pharmacokinetics and pharmacodynamics of valproate analogs in rats. II. Pharmacokinetics of octanoic acid, cyclohexanecarboxylic acid, and 1-methyl-1-cyclohexanecarboxylic acid

The pharmacokinetics of valproic acid (VPA) and three structural analogs, octanoic acid (OA), cyclohexanecarboxylic acid (CCA), and 1-methyl-1-cyclohexanecarboxylic acid (MCCA), were examined in female Sprague-Dawley rats. All four carboxylic acids evidenced dose-dependent disposition. A dose-related decrease in total body clearance was observed for each test compound, suggesting the presence of saturable elimination processes. Furthermore, the apparent volume of distribution for these compounds was, with the exception of CCA, dose-dependent, indicating that binding to proteins in serum and/or tissues may be saturable. Both VPA and MCCA exhibited enterohepatic recirculation, although the degree of recirculation appeared to be dose- and compound-dependent. Significant quantities of both VPA and MCCA were excreted in the urine as base-labile conjugates, presumably representing glucuronides. In contrast, OA and CCA were not excreted in the urine as base-labile conjugates and did not evidence enterohepatic recirculation. CCA displayed apparent Michaelis-Menten kinetics, although the calculated Km was dose-dependent. The results suggest that relatively minor changes in chemical structure have a marked influence on the metabolism and disposition of low molecular weight carboxylic acids.

Interaction of felbamate with several other antiepileptic drugs against seizures induced by maximal electroshock in mice

The anticonvulsant effects of felbamate (FBM) alone or in combination with phenytoin (PHT), carbamazepine (CBZ), valproate (VPA), or phenobarbital (PB) were investigated against maximal electroshock (MES) seizures in mice. Nonprotective doses of the prototype antiepileptic drugs (AEDs) enhanced the protective effects of FBM against electrically induced seizures, as shown by significant reduction of FBM ED50 values. Toxicity as determined by rotorod test was not significantly potentiated, however, and the protective index (PI = TD50/ED50) of FBM was increased by > 100% for each AED interaction. The increase in anticonvulsant potency of FBM after its combination with nonprotective doses of AEDs could not be accounted for by a pharmacokinetic mechanism.

Drug interactions in epilepsy

The abolition of seizures using a single antiepileptic agent can be expected in more than 80% of patients, although not necessarily with the first drug tried. The remainder often receive polypharmacy, and current evidence suggests that perhaps only around 10% of these benefit significantly in terms of improved seizure control. Many more experience complicated drug interactions. Carbamazepine, phenytoin, phenobarbital, and primidone (metabolized in part to phenobarbital) all induce the synthesis of hepatic monooxygenase and conjugating enzymes. This will result in an acceleration in the metabolism of other lipid-soluble drugs with likely attenuation of their pharmacological effects. Valproate, on the other hand, is a minor enzyme inhibitor. Pharmacokinetic interactions are almost invariable when more than one antiepileptic drug is coprescribed. The extent and direction of interactions with combinations of these drugs are varied and unpredictable. Discontinuation of an enzyme inducer or inhibitor will influence the concentrations of the remaining drug(s). Pharmacodynamic interactions also cause problems in epileptic patients. A number of commonly prescribed psychoactive drugs, such as tricyclic antidepressants and neuroleptics, can worsen seizure control by reducing the convulsion threshold. In addition, there seems little doubt that ethanol abuse and withdrawal can precipitate seizures in susceptible patients. Antiepileptic polypharmacy is more likely to impair cognitive function than the same drugs used singly. In addition, the more antiepileptic drugs received by a patient in the first trimester of pregnancy, the higher the risk of teratogenesis in the exposed infant. Drug interactions prolong and complicate the process of new drug assessment, particularly when introduced in treated patients with refractory epilepsy. The candidate antiepileptic drug may alter the concentration of concomitant therapy, or its own breakdown may be influenced by coprescribed enzyme inducers or inhibitors. Even if the new drug is excreted unchanged by the kidney, unexpected interactions can be uncovered. Pharmacodynamic interactions need not always be detrimental. Currently, there is no rational approach to the treatment of intractable epilepsy. As more new drugs with single mechanisms of action become available, the potential exists for combining these synergistically. This approach may revolutionize the pharmacological management of the epileptic patient in the 21st century.

Anticonvulsants in pregnancy

OBJECTIVE

To review the potential problems and their management associated with the use of anticonvulsant drugs during pregnancy.

DATA SOURCES

Studies published between 1968 and 1990 assessing the effect of pregnancy on the pharmacokinetics of anticonvulsant drugs, the teratogenicity of anticonvulsants, breast feeding and anticonvulsants and use of the oral contraceptive pill in patients taking anticonvulsant medication, were reviewed.

RESULTS OF DATA SYNTHESIS

In general, plasma levels fall during pregnancy and rise during the puerperium. A number of factors including possible reduced absorption, increased volume of distribution, reduced protein binding, increased clearance and noncompliance, contribute to this fall in plasma concentration. All anticonvulsants are potentially teratogenic. The incidence of fetal malformations is higher in patients treated with multiple anticonvulsant drugs and on higher dosages with higher plasma levels. Anticonvulsants are excreted in low concentrations in breast milk. All anticonvulsants except valproic acid have been associated with failure of the oral contraceptive pill. This is due to liver enzyme induction of these drugs.

CONCLUSION

As plasma levels of anticonvulsants fall during pregnancy, concentrations should be monitored regularly. Due to the fall in protein binding, marginally low total plasma levels of highly protein bound drugs may not reflect reduced unbound levels, and hence an increase in dosage may not be required. In order to reduce teratogenicity, one should aim to use a single anticonvulsant drug and the lowest dosage able to achieve seizure control. In general, breast feeding is not contraindicated.

Alterations in the renal excretion of valproate and its metabolites after chronic treatment

Urinary excretion of valproate (VPA, administered as its sodium salt) and its various metabolites was studied in rats before and after 6 weeks of chronic treatment with intraperitoneal (i.p.) injection of 200 mg/kg VPA three times daily. Urinary excretion was determined after i.p. injection of a single dose of 200 mg/kg VPA, to which [14C]labeled VPA had been added to yield a dose of 1 microCi/kg body weight. Unlabeled VPA and metabolites were determined in urine by gas chromatography-mass spectrometry (GC-MS). After injection of a single dose of VPA before onset of chronic treatment, approximately 40-50% of the dose administered was excreted in the urine within 24 h, mainly in the form of conjugated VPA and omega-oxidation products, i.e., 5-hydroxy-VPA and 2-propyl-glutaric acid. After chronic treatment, urinary excretion of total radioactivity increased approximately 75% as compared with activity before chronic treatment, demonstrating a marked increase in elimination rate of VPA during prolonged administration. Determination of VPA and metabolites in urine by GC-MS indicated that this enhanced elimination resulted mainly from increases in glucuronidation and beta-oxidation of VPA, whereas omega-oxidation was apparently not altered or was even reduced. The data strongly indicate that at least in rats VPA produces induction of its own metabolism during prolonged treatment.

Enzyme induction and inhibition

The rate and extent of drug metabolism significantly influences drug effect. Enzyme induction by increasing the metabolism of drugs may result in important drug interactions. Other implications of enzyme induction include alterations in the metabolism of endogenous substrates, vitamins and activity of extrahepatic enzyme systems. Similarly a wide range of drugs may produce clinically significant drug interactions following enzyme inhibition. Assessment of enzyme induction and inhibition in man involves diverse methods including the use of model drugs.

A micromethod for the estimation of free levels of anticonvulsant drugs in serum

A micromethod for estimating free levels of phenobarbitone, phenytoin and carbamazepine in patients' sera is described. Serum samples are subjected to a process of ultrafiltration, the filtrates treated with acetonitrile and the drug concentration quantified using high performance liquid chromatography. The stability of free levels in specimens before and after storage is investigated. The method is reproducible and mean recovery exceeds 98.5% showing that there is no significant absorption of drug onto the filters used. There is no interference from other substances normally present in patients' sera and there is a good correlation between results obtained by this method and a fluorescence polarisation immunoassay with correlation coefficient between 0.975 and 0.999. Serum samples can be stored for a lengthy period before ultrafiltration without adverse effects. The relevance of the method to patient care is discussed.

Effect of phenytoin, carbamazepine, and valproic acid on caffeine metabolism

Three groups of non-smoking epileptic patients without liver disease receiving antiepileptic monotherapy have been compared with 10 healthy non-smoking volunteers. Group 1 received phenytoin (n = 10), Group 2 carbamazepine (n = 10) and Group 3 valproic acid (n = 6). Cytochrome P-450 activity was monitored by measuring urinary 6-beta-hydroxycortisol output and systemic antipyrine clearance. Both, 6-beta-hydroxycortisol output and antipyrine clearance were significantly enhanced in patients on phenytoin and carbamazepine, but not in those on valproic acid. On the other hand, phenytoin alone increased the clearance of caffeine from 1.5 (controls) to 3.6 ml.min-1.kg-1, and reduced its half life from 4.8 to 2.4 h. Carbamazepine and valproic acid had no effect on caffeine metabolism. The results are in keeping with the well known heterogeneity of the hepatic monooxygenase system, as phenytoin and carbamazepine induce different panels of cytochrome P-450 isoenzymes. Phenytoin treatment may impair the validity of the caffeine liver function test.

Thyroid hormone concentrations in epileptic patients

Anticonvulsants are associated with decreased serum thyroid hormone concentrations. We have studied thyroid function in 54 epileptic patients on a variety of drugs (19 on carbamazepine, 13 on phenytoin, 10 on sodium valproate, 12 on polypharmacy). For comparison, 14 untreated epileptics and 11 healthy unmedicated volunteers were included as controls. Total thyroxine (T4) concentrations were reduced in patients taking enzyme-inducing drugs (carbamazepine and/or phenytoin) compared with both controls and patients taking sodium valproate. Similar differences were shown with each individual drug. All nine patients whose circulating T4 was below the lower limit of the reference range were taking enzyme inducers. Free thyroxine concentrations were also reduced in individuals treated with carbamazepine and phenytoin with five values falling beneath the reference range. Tri-iodothyronine and thyrotropin appeared unaffected by anticonvulsant administration. Thyrotropin releasing hormone stimulation revealed no true hypothyroidism. The lowering effect of anticonvulsant drugs on circulating total and free T4 was not exhibited by the non-inducing sodium valproate. These data support the influence of enzyme induction as a likely mechanism for reduced thyroxine concentrations in treated epileptic patients.

The inducing and inhibiting effects of sodium valproate in vivo on the biotransformation systems of xenobiotics in isolated rat hepatocytes

1. The induction and inhibition of some biotransformation enzymes by valproate have been studied in hepatocytes isolated from rats treated with sodium valproate either i.p. or by subcutaneous implantation of osmotic pumps. 2. When valproate was given i.p., the cytochromes P-450 and b5, and aldrin epoxidase and glutathione S-transferase activities were significantly induced. 3. In contrast, valproate administered by osmotic pumps induced 7-ethoxycoumarin-O-deethylase activity, whereas aldrin expoxidase and glutathione S-transferase activities were significantly inhibited. At a valproate serum concentration of about 100 micrograms/ml for 2 weeks a significant induction of the cytochromes P-450 and b5 was observed. 4. Since there is a large difference between the half-lives of valproate in man and rodent, constant-rate delivery of valproate represents a better model for induction studies than i.p. injection.

Effects of sodium valproate on haem biosynthesis in man: implications for seizure management in the porphyric patient

The short-term effects of sodium valproate (VPA) on haem biosynthesis were assessed in a placebo-controlled crossover trial in eight healthy male subjects who ingested VPA 500 mg t.i.d. and matched placebo for 5 days. All showed augmented activity of leucocyte 5-aminolaevulinate synthase (ALA-S) activity, the rate-limiting enzyme of the haem biosynthetic pathway, following 3 and 5 days of VPA treatment (P less than 0.001). This was accompanied by increased urinary excretion of 5-aminolaevulinic acid (ALA; P less than 0.02) and total porphyrins (P less than 0.01). Mean (+/- SD) total VPA concentrations on day 3 (89 +/- 16 mg 1-1) and day 5 (91 +/- 22 mg 1-1) were within the target range for the drug. The long-term effects of VPA administration were examined in epileptic patients on established monotherapy. Leucocyte ALA-S activity (P less than 0.001), and daily urinary excretion of porphobilinogen (P less than 0.01) and total porphyrins (P less than 0.01) were all higher than in age-matched controls. No significant differences in erythrocyte ALA-dehydratase, porphobilinogen deaminase and uroporphyrinogen decarboxylase activities were found between the groups. These data suggest that VPA is porphyrinogenic in man and cannot be recommended as safe for seizure management in the porphyric patient.

Effect of sodium valproate on carbamazepine disposition and psychomotor profile in man

1 The effect of sodium valproate (VPA; 500 mg thrice daily for 7 days) and matched placebo on the disposition and psychomotor profile of a single dose of carbamazepine (CBZ; 10 mg kg-1) was studied in eight healthy male subjects using a randomised balanced crossover design. 2 VPA alone had no effect on antipyrine clearance, urinary 6 beta-hydroxycortisol excretion and a battery of psychomotor function tests after 3 days' treatment despite achieving a mean steady-state concentration (90 +/- 6 mg 1(-1)) well within the target range (50-100 mg 1(-1)) for the drug. 3 VPA pre-treatment did not alter total CBZ area under the concentration-time curve (AUC 0-59 h) but did prolong CBZ elimination half life by 12% (P less than 0.01). AUC 0-59 h for free plasma CBZ was 13% higher (P less than 0.02) and half-life of unbound CBZ 16% longer (P less than 0.02) during VPA treatment. CBZ-10,11 epoxide (CBZ-E) levels (52%) and CBZ-E/CBZ ratios (45%) were both elevated by concurrent VPA (P less than 0.05) and free CBZ fraction was increased by 7% (P less than 0.02). 4 The sole effect of VPA on the psychomotor profile of CBZ was prolongation of card sorting time (P less than 0.05), although CBZ-related side effects were reported as more severe when VPA was also taken (P less than 0.01). 5 These data suggest that VPA displaces CBZ from plasma protein binding sites and inhibits the metabolism of both the parent drug and its epoxide.(ABSTRACT TRUNCATED AT 250 WORDS)

Valproic acid-induced increase in carnitine acetyltransferase in rat hepatocytes is not due to an induction of peroxisomes

Valproic acid induced a dose-dependent increase in carnitine acetyltransferase (CAT) activity in rat hepatic mitochondrial fractions isolated by differential centrifugation. An increase in CAT and carnitine palmitoyltransferase (CPT) also occurred in cultured rat hepatocytes in a concentration-and time-dependent fashion. A maximal increase of 8-fold in the activity of CAT and 2-fold in the activity of CPT was induced by 3 mM valproic acid in 72 h. Valproic acid had no effect on cytochrome P-450 levels in cultured rat hepatocytes. Electron-microscopic examination of rat hepatocytes showed that there was no increase in the number of peroxisomes but there was a marked proliferation of mitochondria in parallel with an increase in glutathione level and succinic dehydrogenase in the liver cells after incubation with valproic acid in vitro.

Free drug concentration monitoring in clinical practice. Rationale and current status

Recent advances in techniques to determine free drug concentrations have lead to a substantial increase in the monitoring of this parameter in clinical practice. The majority of drug binding to macromolecules in serum can be accounted for by association with albumin and alpha 1-acid glycoprotein. Albumin is the primary binding protein for acidic drugs, while binding to alpha 1-acid glycoprotein is more commonly observed with basic lipophilic agents. Alterations in the concentrations of either of these macromolecules can result in significant changes in free fraction. Diseases such as cirrhosis, nephrotic syndrome and malnourishment can result in hypoalbuminaemia. Burn injury, cancer, chronic pain syndrome, myocardial infarction, inflammatory diseases and trauma are all associated with elevations in the concentration of alpha 1-acid glycoprotein. Treatment with a number of drugs has also been shown to increase alpha 1-acid glycoprotein serum concentrations. A wide variety of biological fluids have been examined for their ability to provide an estimation of free drug concentration at receptor sites. The most useful fluid for estimating free drug concentrations appears to be plasma or serum, with subsequent treatment of the sample to separate free and bound drug by an appropriate technique. The two most widely used methods are equilibrium dialysis and ultrafiltration. Of these two, ultrafiltration has the greatest utility clinically because it is rapid and relatively simple. The major difficulty associated with this method involves the binding of drug to the ultrafilters, but significant progress has been made in solving this problem. Several authors have endorsed the routine use of free drug concentration monitoring. Data examining the clinical usefulness of free drug concentration monitoring for phenytoin, carbamazepine, valproic acid, disopyramide and lignocaine (lidocaine) are reviewed. While available evidence suggests that free concentrations may correlate with clinical effects better than total drug concentrations, there are insufficient data to justify the recommendation of the routine use of free drug concentration monitoring for any of these agents at present.

Serum protein binding of tolbutamide in patients treated with antiepileptic drugs

The possible development of a displacement interaction involving tolbutamide, in epileptic patients, has been explored by studying the serum protein binding of this drug in vitro in 199 samples of sera from patients treated with antiepileptic agents included in a programme of therapeutic drug monitoring. 82 of the samples were from patients receiving a single drug, 86 from patients treated with 2 drugs, and 31 from patients treated with 3 drugs. The free fraction of tolbutamide was higher in serum from patients treated with antiepileptic drugs than in serum from untreated 'normal' volunteers. The increase was more marked the greater the number of antiepileptic drugs administered. Valproate appeared to be the most powerful displacing agent.

Valproate as psychotropic agent. Interactions and adverse cerebral reactions

Recent data stress the psychotropic actions of valproate in schizo-affective disorder. Four patients are reported presenting an altered state of consciousness and prominent EEG dysfunction following combined valproate/neuroleptic drug treatment. Similar cerebral reactions have been reported in anti-epileptic poly- and monotherapy, and the pathogenetic considerations are discussed. Further investigations of the interactions of valproate with other psychotropic agents are highly mandatory.

Valproate: an updated review

Valproate in all its aspects is comprehensively surveyed. Previous reviews covering various aspects such as mechanism of action, clinical pharmacology, clinical efficacy in epilepsy, febrile convulsions and other neurological disorders, side effects, teratogenicity and intoxications are discussed and updated (161 references).

Decrease of valproate-induced hyperammonemia in normal subjects by lipid ingestion

Sodium valproate (VPA), a branched short-chain fatty acid, always causes a hyperammonemia of renal origin in fasting man. The intake of medium-length, straight-chain fatty acids abolishes the VPA-induced hyperammonemia, and VPA free fraction increases concomitantly. Accordingly, fatty acids could be useful in preventing and treating hyperammonemia-accompanied stuporous states which are complications of VPA medication.