Antiepileptic Drug Mechanisms of Action

Summary: Established antiepileptic drugs (AEDs) decrease membrane excitability by interacting with neurotransmitter receptors or ion channels. AEDs developed before 1980 appear to act on sodium channels, γ-ami-nobutyric acid type A (GABA_A) receptors, or calcium channels. Benzodiazepines and barbiturates enhance GABA_A receptor-mediated inhibition. Phenytoin (PHT), carbamazepine (CBZ), and possibly valproate (VPA) decrease high-frequency repetitive firing of action potentials by enhancing sodium-channel inactivation. Ethosuximide (ESM) and VPA reduce a low threshold (T-type) calcium-channel current. The mechanisms of action of the new AEDs are not fully established. Gabapentin (GBP) binds to a high-affinity site on neuronal membranes in a restricted regional distribution of the central nervous system. This binding site may be related to a possible active transport process of GBP into neurons; however, this has not been proven, and the mechanism of action of GBP remains uncertain. Lamotrigine (LTG) decreases sustained high-frequency repetitive firing of voltage-dependent sodium action potentials that may result in a preferential decreased release of presynaptic glutamate. The mechanism of action of oxcarbazepine (OCBZ) is not known; however, its similarity in structure and clinical efficacy to CBZ suggests that its mechanism of action may involve inhibition of sustained high-frequency repetitive firing of voltage-dependent sodium action potentials. Vigabatrin (VGB) irreversibly inhibits GABA transaminase, the enzyme that degrades GABA, thereby producing greater available pools of presynaptic GABA for release in central synapses. Increased activity of GABA at postsynaptic receptors may underlie the clinical efficacy of VGB.     

Antiepileptic Drug Mechanisms of Action

Summary: Clinically used antiepileptic drugs (AEDs) decrease membrane excitability by interacting with ion channels or neurotransmitter receptors. Currently available AEDs appear to act on sodium channels, GABA_A receptors, or calcium channels. Phenytoin, carbamazepine, and possibly valproate (VPA) decrease high-frequency repetitive firing of action potentials by enhancing sodium channel inactivation. Benzodiazepines and barbiturates enhance GABA_A receptor-mediated inhibition. Ethosuximide and possibly VPA reduce a low-threshold calcium current. The mechanisms of action of AEDs currently under development are less clear. Lamotrigine may decrease sustained high-frequency repetitive firing. The mechanisms of action of felbamate are unknown. Gabapentin (GBP) appears to bind to a specific binding site in the central nervous system with a restricted regional distribution, but the identity of the binding site and the mechanism of action of GBP remain uncertain.     

Clinical Significance of Animal Seizure Models and Mechanism of Action Studies of Potential Antiepileptic Drugs

Summary: More than 50 million persons worldwide suffer from epilepsy, many of whom are refractory to treatment with standard antiepileptic drugs (AEDs). Fortunately, new AEDs commercialized since 1990 are improving the clinical outlook for many patients. Our growing understanding of anticonvulsant mechanisms and the relevance of preclinical animal studies to clinical antiepileptic activity have already contributed to the design of several new AEDs and should be increasingly beneficial to further efforts at drug development. Mechanisms have been identified for older AEDs [phenytoin (PHT), carbamazepine (CBZ), valproate (VPA), barbiturates, benzodiazepines (BZDs), ethosuximide (ESM)] and newer AEDs [vigabatrin (VGB), lamotrigine (LTG), gabapentin (GBP) tiagabine (TGB), felbamate (FBM), topiramate (TPM)]. Several novel anticonvulsant mechanisms have recently been discovered. FBM appears to be active at the strychnine-insensitive glycine binding site of the NMDA receptor. TPM is active on the kainate/AMPA subtype of glu-tamate receptor and at a potentially novel site on the GABA_A receptor. For several reasons, availability of a single AED with multiple mechanisms of action may be preferred over availability of multiple AEDs with single mechanisms of action. These reasons include ease of titration, lack of drug-drug interactions, and reduced potential for pharmacodynamic tolerance.     

Influence of Different Methylxanthines on the Anticonvulsant Action of Common Antiepileptic Drugs in Mice

The protective activity of carbamazepine (CBZ, 60 min before testing), phenobarbital (PB, 120 min), phenytoin (PHT, 120 min), and valproate (VPA, 30 min) alone or concurrent with methylxanthine derivatives was evaluated against maximal electroshock-induced seizures (MES) in male mice. All drugs were administered intraperitoneally (i.p.), and the protection offered by antiepileptic drugs (AEDs) was expressed as ED50 in mg/kg. Caffeine sodium benzoate in doses of 0.0595-0.476 mmol/kg (11.55-92.4 mg/kg) distinctly reduced the anticonvulsant efficacy of PB, in the highest dose tested with an increase in ED50 value from 19.5 to 38 mg/kg. This methylxanthine derivative in the dose range of 0.119-0.476 mmol/kg (23.1-92.4 mg/kg) also efficiently inhibited the protective action of PHT. When combined with caffeine (0.238 and 0.476 mmol/kg), the ED50 of PHT was raised from 12 to 17 and 24 mg/kg, respectively. In doses of 0.238 and 0.476 mmol/kg, caffeine also diminished the efficacy of CBZ and VPA, and at the highest dose tested the methylxanthine elevated the respective ED50s from 13 to 20.5 mg/kg and from 270 to 420 mg/kg. Generally caffeine sodium benzoate (up to 0.476 mmol/kg) did not affect the plasma levels of studied AEDs, and only at 0.476 mmol/kg did it significantly decrease the level of PHT. Among the other methylxanthines, pentoxifylline (0.238-0.476 mmol/kg; 66.3-132.5 mg/kg) and diprophylline (0.952 mmol/kg; 242.1 mg/kg) inhibited the protective potential of PHT and the respective ED50s were raised from 12 to 16.5, 15.5, and 14 mg/kg. No significant alterations in PHT plasma levels were observed.(ABSTRACT TRUNCATED AT 250 WORDS)     

Overview of the Safety of Newer Antiepileptic Drugs

Summary: Standard antiepileptic drugs (AEDs) are associated with a wide variety of acute and chronic adverse events and with many interactions with each other and with non-AEDs that complicate patient management. The safety and interaction profiles of the newer AEDs have also been intensively studied. Safety data are available for six of the newer AEDs, lamotrigine (LTG), vigabatrin (VGB), gabapentin (GBP), tiagabine (TGB), felbamate (FBM), and topiramate (TPM). The potential for the most recently developed AEDs for producing rare idiosyncratic reactions cannot be ascertained until additional patient exposures have been reported from careful postmarketing surveillance.     

Serum Bilirubin Levels with Antiepileptic Drugs

The incidence of reduced bilirubin levels in 168 outpatients with epilepsy, compared with levels in 69 controls, has been investigated. Highly significant (p less than 0.001) reductions in average bilirubin levels were noted for carbamazepine (CBZ), phenytoin (PHT), phenobarbital (PB), and multiple drug groups. A marginally significant (p less than 0.05) reduction in bilirubin levels occurred in patients treated with valproate (VPA) which, unlike the other drugs, has not been shown to induce hepatic enzymes.     

Pharmacokinetics and Interaction Profile of Topiramate: Review and Comparison with Other Newer Antiepileptic Drugs

Summary: Standard antiepileptic drugs (AEDs) have a number of pharmacokinetic shortcomings, and AEDs with more favorable profiles would be preferred. The pharmacokinetics and interaction profile of the recently developed AED topiramate (TPM), is reviewed and compared with those of other newer AEDs including lamotrigine (LTG), gabapentin (GBP), vigabatrin (VGB), and oxcarbazepine (OCBZ). Although none of these agents meets all of the criteria of the "ideal" AED from the pharmacokinetic standpoint, a number of these drugs, including TPM, have desirable properties that distinguish them from the older AEDs and should contribute to their clinical utility.     

Antiepileptic Drugs in Mood-Disordered Patients

Summary:  Bipolar disorder is a common, recurrent, often severe mental disorder that, without adequate treatment, is associated with high rates of morbidity and mortality. We review the evidence on the efficacy of a spectrum of antiepileptic drugs (AED) in bipolar disorder. Most studies have been carried out with carbamazepine (CBZ), valproate (VPA), and lamotrigine (LTG). All three of these AEDs have been shown to be of value in the management of patients with bipolar illnesses. VPA and CBZ seem to exert stronger antimanic effects and, to a lesser degree, acute antidepressant efficacy. LTG seems to be effective against depression and mania, with a more robust activity against depression. No firm evidence supports a role for vigabatrin, tiagabine, topiramate, or levetiracetam in these disorders.     

Interaction of Felbamate with Several Other Antiepileptic Drugs Against Seizures Induced by Maximal Electroshock in Mice

Summary: 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.     

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.     

Update on the Mechanism of Action of Antiepileptic Drugs

Summary: Novel antiepileptic drugs (AEDs) are thought to act on voltage-sensitive ion channels, on inhibitory neurotransmission or on excitatory neurotransmission. Two successful examples of rational AED design that po tentiate GABA-mediated inhibition are vigabatrin (VGB) by irreversible inhibition of GABA-transaminase, and ti-agabine (TGB) by blocking GAB A uptake. Lamotrigine (LTG) prolongs inactivation of voltage-dependent sodium channels. The anticonvulsant action of remacemide (RCM) is probably largely due to blockade of NMDA receptors and prolonged inactivation of sodium channels induced by its desglycinated metabolite. Felbamate (FBM) apparently blocks NMDA receptors, potentiates GABA-mediated responses, blocks L-type calcium channels, and possibly also prolongs sodium channel inactivation. Similarly, to piramate (TPM) has multiple probable sites of action, including sodium channels, GABA receptors, and glutamate (AMPA) receptors. Gabapentin (GBP) apparently has a completely novel type of action, probably involving potentiation of GABA-mediated inhibition and possibly also inactivation of sodium channels. The therapeutic advantages of the novel AEDs are as yet only partially explained by our present understanding of their. Mechanisms of action.     

Effect of Antiepileptic Drugs on Growth of Murine Lymphoid Tumor Cells in Single-Cell Culture

The effect of three commonly used antiepileptic drugs (AEDs), phenytoin (PHT), carbamazepine (CBZ), and valproate (VPA), on the growth of lymphoid tumor cells was assessed in vitro. A single-cell culture method was used to determine growth rates by direct visualization. The amount of free drug was determined by ultrafiltration to ascertain its correlation to therapeutic drug levels. VPA slowed the growth of B-myeloma (FO) and T-lymphoma (AKR-1) cells significantly within the range of therapeutic drug levels. CBZ and PHT likewise inhibited cell growth in both lineages but at two to four times the therapeutic level of free drug. CBZ was shown to have long-term effects on FO and AKR-1 cells, demonstrated by the reduced growth rates of cloned lines for 2-3 months after drug removal. Cloned sublines of myeloma cells secreting lambda light chain (J558L) treated with CBZ or PHT had a higher frequency of lambda light chain secretion loss mutations than the nontreated parent line.     

Mechanisms of Idiosyncratic Hypersensitivity Reactions to Antiepileptic Drugs

Summary: Hypersensitivity reactions to the aromatic antiepileptic drugs (AEDs) phenytoin (PHT) and carbamazepine (CBZ) appear to have an immune etiology. Current models of drug hypersensitivity center around the concept of drug bioactivation to reactive metabolites that irreversibly modify cellular proteins. These modified proteins are believed to initiate (or serve as targets of) an autoimmune-like attack on specific drug-modified proteins in target organs (e.g., liver, skin) of susceptible individuals. Consistent with this model, antibodies to drug-modified and native proteins have been identified in the sera of patients experiencing several drug hypersensitivity reactions. New models must incorporate an understanding of the mechanisms by which drug-modified proteins are processed and presented to the immune system in the appropriate context to culminate in the clinical manifestations of "hypersensitivity." Idiosyncratic toxicities associated with new AEDs, such as lamotrigine and felbamate, appear mechanistically distinct from PHT and CBZ hypersensitivity but may involve similar processes: bioactivation, detoxification, covalent adduct formation, processing and presentation of antigen to the immune system, and consequent formation of antibody and T-cell immune effectors. The goal of research is to develop a "susceptibility profile" for identifying individuals at risk for these forms of drug toxicity.     

Mechanisms of Action of New Antiepileptic Drugs

Summary: Our understanding of how new antiepileptic drugs work mirrors what we know about how currently marketed antiepileptic compounds exert their action–that information is scarce and elusive. The mechanism of action of antiepileptic drugs is nevertheless inextricably linked to epileptogenesis itself, and investigations of several promising new compounds are underway to establish the levels at which these drugs act. Compounds act on synapses and membranes as well as affecting receptors, neurotransmitters, and peptides. The most extensive data are available on drugs that inhibit the action of GABA or its receptors, including new benzodiazepine-like agents and barbituric-acid derivatives. The few drugs that act by inhibiting the effects of excitatory amino acids are reviewed. Finally, the maximal electroshock test is an empirical method to determine the antiepileptic properties of a drug; several agents under development have been effective in this screening technique.     

Advances in the Pharmacotherapy of Epilepsy

Summary: Three new antiepileptic drugs (AEDs) are likely to be approved in the United States by the Food and Drug Administration in the near future. In general, all three have good safety profiles, causing only mild, well-tolerated side effects. Felbamate (FBM) is effective in the treatment of partial seizures and Lennox-Gastaut epilepsy. FBM appears to have a broader spectrum of antiepileptic activity than carbama-zepine (CBZ) or phenytoin (PHT). Gabapentin (GBP) was designed to be a structured analogue of γ-aminobutyric acid (GABA). GBP is most effective in the maximal electroshock model of seizures but may have a different mechanism of action than CBZ and PHT. Unique pharmacokinetic properties (no hepatic metabolism and no protein binding) may make GBP especially useful for certain patients, such as those with hepatic disease and elderly patients who are receiving multiple medications. The overall profile of activity of la-motrigine (LTG) is similar to that of PHT and may act on voltage-sensitive sodium channels to stabilize neuronal membranes. LTG is effective in partial seizures, and there is some indication that LTG may be helpful in primary generalized seizures. The long half-life and lack of effect on other AEDs will make LTG easy to dose and add to a patient's existing regimen. These new agents will provide physicians with more effective medications from which to choose in the treatment of the patient with epilepsy.     

Comparison of AccuLevel and TDx: Evaluation of On-Site Monitoring of Antiepileptic Drugs

Therapeutic drug monitoring, an important aid in antiepileptic drug (AED) therapy, has a lag time before results are obtained from clinical laboratories. The AccuLevel test is an enzyme immunochromatographic method for quantitative measurement of AEDs including phenobarbital (PB), phenytoin (PHT), and carbamazepine (CBZ), with results available within 20 min. A comparison between AccuLevel and TDx, (fluorescence polarization immunoassay) was conducted in 233 paired blood samples from patients with AED therapy, including 12 Eskimo children receiving treatment in Greenland. Forty-five blood samples were analyzed for PB, 80 for PHT, and 108 for CBZ. Linear regression analysis showed good agreement between the two methods (r = 0.951, 0.958, and 0.945, respectively). The test is easy to perform, but care must be taken to follow the correct procedure, or inaccuracies will result. That happened in some of our results. A reduction in lag time, using on-site drug monitoring, was demonstrated. The AccuLevel is a rapid, accurate, and convenient method for use in AED monitoring.     

Effect of Felbamate on Phenytoin and Carbamazepine Serum Concentrations

Felbamate (FBM) is a novel antiepileptic drug (AED) undergoing clinical trials in the United States. During a double-blind, cross-over clinical trial, patients received concomitant phenytoin (PHT) and carbamazepine (CBZ). Dosages of PHT and CBZ were adjusted to maintain serum concentrations +/- 20 and +/- 25% of baseline values. All patients required a PHT dosage decrease of 10-30% during active FBM treatment to maintain stable concentrations. CBZ serum concentrations decreased significantly in patients receiving active FBM. The mean decrease was 1.3 micrograms/ml and occurred in 30 of 32 patients. Therefore, FBM apparently causes a bidirectional effect on the serum concentrations of PHT and CBZ when all three drugs are taken concomitantly.     

Antiepileptic Drug Monitoring at the Epilepsy Clinic: A Prospective Evaluation

To assess the value of on site therapeutic drug monitoring at the epilepsy clinic, management decisions were recorded before and immediately after antiepileptic drug (AED) concentrations became available. In the first year of this prospective study, 632 [277 carbamazepine (CBZ), 170 phenytoin (PHT), 113 valproate (VPA), and 72 phenobarbital (PB)] assays were performed during 488 clinic attendances in 182 actively managed epileptic patients. The results of drug analysis led to alterations in management at 114 patients visits, i.e., 23% of those monitored. Dosage was increased in response to the circulating AED concentration in 12% of consultations and decreased in another 7.5%. Unsuspected poor compliance was uncovered in eight patients, and in three others an AED was added or discontinued on the basis of the assay result. The time of the next appointment was rearranged in 58 attendances. Only 50% of results were in the "therapeutic" ranges for the four major AEDs. Dosage was adjusted (50 up, 16 down) after 54% of low results. "Therapeutic" levels were followed by a change in AED dose (52 up, 31 down) in 26%. Only 29% of concentrations above the "therapeutic" range persuaded the doctor to alter the dosage regimen, and in 20% of these an increase in dose was recommended. On-site AED monitoring had an immediate impact on clinical decision-making in greater than 23% of consultations but in a form more subtle than the simple quest for a therapeutic result.     

Effect of Aminophylline and Enprofylline on the Protective Efficacy of Common Antiepileptic Drugs Against Electroconvulsions in Mice

The anticonvulsant potency of phenobarbital (PB) (120 min before the test), phenytoin (PHT) (120 min), carbamazepine (CBZ) (60 min), valproate (VPA) (30 min), and acetazolamide (60 min) alone or in combination with either aminophylline (50 mg/kg, 30 min) or enprofylline (46.2 mg/kg, 30 min) was measured against maximal electroshock-induced convulsions in mice. All drugs were administered intraperitoneally (i.p.), and the protective efficacy of each drug was expressed as ED50 in milligrams per kilogram. Aminophylline decreased anticonvulsant activity of PB, PHT, CBZ, and VPA, increasing the respective ED50 values from 16 to 28 mg/kg, 7.4 to 14 mg/kg, 18 to 26 mg/kg, and 260 to 335 mg/kg. On the contrary, enprofylline in the equimolar dose did not exert such effect. Furthermore, neither aminophylline nor enprofylline affected anticonvulsant action of acetazolamide. The present data favor enprofylline as a preferable drug for treatment of obstructive lung diseases in epilepsy patients. However, accurate pharmacokinetic data in mice and men for both xanthines are necessary if one attempts to compare their cerebral and pulmonary actions.