COX-2 inhibition controls P-glycoprotein expression and promotes brain delivery of phenytoin in chronic epileptic rats

Epileptic seizures drive expression of the blood-brain barrier efflux transporter P-glycoprotein via a glutamate/cyclooxygenase-2 mediated signalling pathway. Targeting this pathway may represent an innovative approach to control P-glycoprotein expression in the epileptic brain and to enhance brain delivery of antiepileptic drugs.Therefore, we tested the effect of specific cyclooxygenase-2 inhibition on P-glycoprotein expression in two different status epilepticus models. Moreover, the impact of a cyclooxygenase-2 inhibitor on expression of the efflux transporter and on brain delivery of an antiepileptic drug was evaluated in rats with recurrent spontaneous seizures.The highly selective cyclooxygenase-2 inhibitors SC-58236 and NS-398 both counteracted the status epilepticus-associated increase in P-glycoprotein expression in the parahippocampal cortex and the ventral hippocampus. In line with our working hypothesis, a sub-chronic 2-week treatment with SC-58236 in the chronic epileptic state kept P-glycoprotein expression at control levels. As described previously, enhanced P-glycoprotein expression in chronic epileptic rats was associated with a significant reduction in the brain penetration of the antiepileptic drug phenytoin. Importantly, the brain delivery of phenytoin was significantly enhanced by sub-chronic cyclooxygenase-2 inhibition in rats with recurrent seizures.In conclusion, the data substantiate targeting of cyclooxygenase-2 in the chronic epileptic brain as a promising strategy to control the expression levels of P-glycoprotein despite recurrent seizure activity. Cyclooxygenase-2 inhibition may therefore help to increase concentrations of antiepileptic drugs at the target sites in the epileptic brain. It needs to be further evaluated whether the approach also enhances efficacy.     

Celecoxib treatment restores pharmacosensitivity in a rat model of pharmacoresistant epilepsy

Background and purpose:

A functional link between seizure-induced P-glycoprotein overexpression at the blood–brain barrier and therapeutic failure has been suggested by several studies using rodent epilepsy models and human epileptic tissue. Recently, we reported that interference with the mechanisms that up-regulate P-glycoprotein in response to seizure activity might provide a novel approach to control its expression in the epileptic brain. Based on these data, we hypothesized that blocking the appropriate signalling cascade by cyclooxygenase-2 inhibition should improve brain penetration of antiepileptic drugs and help to overcome drug resistance.

Experimental approach:

Effects of the selective cyclooxygenase-2 inhibitor celecoxib on the response to the P-glycoprotein substrate, phenobarbital, was evaluated in a chronic model of drug-resistant temporal lobe epilepsy in rats. Drug-resistant rats selected from this model exhibit a marked overexpression of P-glycoprotein in the hippocampus and other limbic brain regions.

Key results:

Responders and non-responders were selected from a group of rats with spontaneous recurrent seizures after prolonged treatment with phenobarbital at maximum tolerated doses. The efficacy of phenobarbital was re-evaluated following a 6 day treatment with celecoxib and the frequency of spontaneous recurrent seizures was significantly reduced in both groups of rats, phenobarbital responders or non-responders selected from the previous drug trial.

Conclusions and implications:

Pretreatment with the cyclooxygenase-2 inhibitor restored the anticonvulsant activity of phenobarbital in rats that failed to exhibit a relevant response before celecoxib treatment. Our data provide further support for a novel therapeutic approach to overcome transporter-mediated drug resistance in epilepsies.     

Combined effects of epileptic seizure and phenobarbital induced overexpression of P-glycoprotein in brain of chemically kindled rats

Background and purpose:

The multidrug resistance of epilepsy may result from the overexpression of P-glycoprotein, but the mechanisms are unclear. We investigated whether the overexpression of P-glycoprotein in the brains of subjects with pharmacoresistant epilepsy resulted from both drug effects and seizure activity.

Experimental approach:

Kindled rats were developed by injecting a subconvulsive dose of pentylenetetrazole (33 mg·kg⁻¹·day⁻¹, i.p.) for 28 days. Groups were then treated with an oral dose of phenobarbital (45 mg·kg⁻¹·day⁻¹) for 40 days. In accord with behavioural observations, P-glycoprotein activity in brain was assessed using brain-to-plasma concentration ratios of rhodamine 123. P-glycoprotein levels in the brain regions were further evaluated using RT-PCR and Western blot analysis. The distribution of phenobarbital in the brain was assessed by measuring phenobarbital concentrations 1 h following its oral administration.

Key results:

The kindling significantly increased P-glycoprotein activity and expression. Good associations were found among P-glycoprotein activity, expression and phenobarbital concentration in the hippocampus. Short-term treatment with phenobarbital showed good anti-epileptic effect; the maximum effect occurred on day 14 when overexpression of P-glycoprotein was reversed. Continuous treatment with phenobarbital had a gradually reduced anti-epileptic effect and on day 40, phenobarbital exhibited no anti-epileptic effect; this was accompanied by both a re-enhancement of P-glycoprotein expression and decreased phenobarbital concentration in the hippocampus. P-glycoprotein function and expression were also increased in age-matched normal rats treated with phenobarbital.

Conclusions and implications:

The overexpression of P-glycoprotein in the brain of subjects with pharmacoresistant epilepsy is due to a combination of drug effects and epileptic seizures.     

Seizure-induced up-regulation of P-glycoprotein at the blood-brain barrier through glutamate and cyclooxygenase-2 signaling

Increased expression of drug efflux transporters at the blood-brain barrier accompanies epileptic seizures and complicates therapy with antiepileptic drugs. This study is concerned with identifying mechanistic links that connect seizure activity to increased P-glycoprotein expression at the blood-brain barrier. In this regard, we tested the hypothesis that seizures increase brain extracellular glutamate, which signals through an N-methyl-d-aspartate (NMDA) receptor and cyclooxygenase-2 (COX-2) in brain capillaries to increase blood-brain barrier P-glycoprotein expression. Consistent with this hypothesis, exposing isolated rat or mouse brain capillaries to glutamate for 15 to 30 min increased P-glycoprotein expression and transport activity hours later. These increases were blocked by 5H-dibenzo[a,d]cyclohepten-5,10-imine (dizocilpine maleate) (MK-801), an NMDA receptor antagonist, and by celecoxib, a selective COX-2 inhibitor; no such glutamate-induced increases were seen in brain capillaries from COX-2-null mice. In rats, intracerebral microinjection of glutamate caused locally increased P-glycoprotein expression in brain capillaries. Moreover, using a pilocarpine status epilepticus rat model, we observed seizure-induced increases in capillary P-glycoprotein expression that were attenuated by administration of indomethacin, a COX inhibitor. Our findings suggest that brain uptake of some antiepileptic drugs can be enhanced through COX-2 inhibition. Moreover, they provide insight into one mechanism that underlies drug resistance in epilepsy and possibly other central nervous system disorders.     

Glutamate is critically involved in seizure-induced overexpression of P-glycoprotein in the brain

About 30% of patients with epilepsy do not respond adequately to drug therapy, making pharmacoresistance a major problem in the treatment of this common brain disorder. Mechanisms of intractability are not well understood, but may include limitation of antiepileptic drug access to the seizure focus by overexpression of the drug efflux transporter P-glycoprotein (Pgp) at the blood-brain barrier. Increased expression of Pgp has been determined both in epileptogenic brain tissue of patients with intractable epilepsy and in rodent models of temporal lobe epilepsy, including the pilocarpine model. The mechanisms underlying the increase of Pgp after seizures are unclear. We have recently suggested that the excitatory neurotransmitter glutamate, which is excessively released by seizures, is involved in the seizure-induced overexpression of Pgp in the brain. This hypothesis was evaluated in the present study in the pilocarpine model in rats. After 90 min of status epilepticus (SE), diazepam was administered, followed by either vehicle or the glutamate receptor antagonist MK-801 (dizocilpine). Following SE in vehicle treated rats, Pgp expression in brain capillary endothelial cells increased about twofold in the hippocampus, which was completely prevented by MK-801. Furthermore, neurodegeneration developing in the hippocampus and parahippocampal regions was reduced by the glutamate antagonist. In contrast, the Pgp inhibitor tariquidar did not affect the SE-induced overexpression of Pgp or neurodegeneration in most regions examined. The data indicate that seizure-induced glutamate release is involved in the regulation of Pgp expression, which can be blocked by MK-801. The finding that MK-801 counteracts both Pgp overexpression and neuronal damage when administered after SE may offer a clinically useful therapeutic option in patients with refractory SE.     

Evaluation of transport of common antiepileptic drugs by human multidrug resistance-associated proteins (MRP1, 2 and 5) that are overexpressed in pharmacoresistant epilepsy

Resistance to antiepileptic drugs (AEDs) is one of the most serious problems in the treatment of epilepsy. Accumulating experimental evidence suggests that increased expression of the drug efflux transporter P-glycoprotein (Pgp) at the blood-brain barrier may be involved in the mechanisms leading to AED resistance. In addition to Pgp, increased expression of several multidrug resistance-associated proteins (MRPs) has been determined in epileptogenic brain regions of patients with pharmacoresistant epilepsy. However, it is not known whether AEDs are substrates for MRPs. In the present experiments, we evaluated whether common AEDs are transported by human MRPs (MRP1, 2 and 5) that are overexpressed in AED resistant epilepsy. For this purpose, we used a highly sensitive assay (concentration equilibrium transport assay; CETA) in polarized kidney cell lines (LLC, MDCKII) transfected with human MRPs. The assay was validated by known MRP substrates, including calcein-AM (MRP1), vinblastine (MRP2) and chloromethylfluorescein diacetate (CMFDA; MRP5). The directional transport determined with these drugs in MRP-transfected cell lines could be blocked with the MRP inhibitor MK571. However, in contrast to transport of known MRP substrates, none of the common AEDs (carbamazepine, valproate, levetiracetam, phenytoin, lamotrigine and phenobarbital) used in this study was transported by MRP1, MRP2 or MRP5. A basolateral-to-apical transport of valproate, which could be inhibited by MK571 and probenecid, was determined in LLC cells (both wildtype and transfected), but the specific transporter involved was not identified. The data indicate that common AEDs are not substrates for human MRP1, MRP2 or MRP5, at least in the in vitro models used in this study.     

Prevention of seizure-induced up-regulation of endothelial P-glycoprotein by COX-2 inhibition

In the epileptic brain, seizure activity induces expression of the blood-brain barrier efflux transporter, P-glycoprotein, thereby limiting brain penetration and therapeutic efficacy of antiepileptic drugs. We recently provided the first evidence that seizures drive P-glycoprotein induction through a pathway that involves glutamate-signaling through the NMDA receptor and cyclooxygenase-2 (COX-2). Based on these data, we hypothesized that selective inhibition of COX-2 could prevent seizure-induced P-glycoprotein up-regulation. In the present study, we found that the highly selective COX-2 inhibitors, NS-398 and indomethacin heptyl ester, blocked the glutamate-induced increase in P-glycoprotein expression and transport function in isolated rat brain capillaries. Importantly, consistent with this, the COX-2 inhibitor, celecoxib, blocked seizure-induced up-regulation of P-glycoprotein expression in brain capillaries of rats in vivo. To explore further the role of COX-2 in signaling P-glycoprotein induction, we analyzed COX-2 protein expression in capillary endothelial cells in brain sections from rats that had undergone pilocarpine-induced seizures and in isolated capillaries exposed to glutamate and found no change from control levels. However, in isolated rat brain capillaries, the COX-2 substrate, arachidonic acid, significantly increased P-glycoprotein transport activity and expression indicating that enhanced substrate flux to COX-2 rather than increased COX-2 expression drives P-glycoprotein up-regulation. Together, these results provide the first in vivo proof-of-principle that specific COX-2 inhibition may be used as a new therapeutic strategy to prevent seizure-induced P-glycoprotein up-regulation at the blood-brain barrier for improving pharmacotherapy of drug-resistant epilepsy.     

Several major antiepileptic drugs are substrates for human P-glycoprotein

One of the current hypotheses of pharmacoresistant epilepsy proposes that transport of antiepileptic drugs (AEDs) by drug efflux transporters such as P-glycoprotein (Pgp) at the blood-brain barrier may play a significant role in pharmacoresistance in epilepsy by extruding AEDs from their intended site of action. However, several recent in vitro studies using cell lines that overexpress efflux transporters indicate that human Pgp may not transport AEDs to any relevant extent. In this respect it has to be considered that most AEDs are highly permeable, so that conventional bi-directional transport assays as used in these previous studies may fail to identify AEDs as Pgp substrates, particularly if these drugs are not high-affinity substrates for Pgp. In the present study, we used a modified transport assay that allows evaluating active transport independently of the passive permeability component. In this concentration equilibrium transport assay (CETA), the drug is initially added at identical concentration to both sides of a polarized, Pgp-overexpressing cell monolayer instead of applying the drug to either the apical or basolateral side for studying bi-directional transport. Direct comparison of the conventional bi-directional (concentration gradient) assay with the CETA, using MDR1-transfected LLC cells, demonstrated that CETA, but not the conventional assay, identified phenytoin and phenobarbital as substrates of human Pgp. Furthermore, directional transport was determined for lamotrigine and levetiracetam, but not carbamazepine. Transport of AEDs could be completely or partially (>50%) inhibited by the selective Pgp inhibitor, tariquidar. However, transport of phenobarbital and levetiracetam was also inhibited by MK571, which preferentially blocks transport by multidrug resistance transporters (MRPs), indicating that, in addition to Pgp, these AEDs are substrates of MRPs. The present study provides the first direct evidence that several AEDS are substrates of human Pgp, thus further substantiating the transporter hypothesis of pharmacoresistant epilepsy.     

Modification of the antiepileptic actions of phenobarbital and phenytoin by the taurine transport inhibitor, guanidinoethane sulfonate

We investigated whether chronic administration of guanidinoethane sulfonate, an inhibitor of taurine uptake, could modify the antiepileptic actions of phenobarbital and phenytoin on maximal electroshock seizures in mice. Treatment with 1% guanidinoethane sulfonate decreased the taurine concentration in the brain to 76% of the control value. Under these conditions, neither the severity of tonic convulsions of maximal electroshock seizures nor the threshold for tonic extension caused by electroshock was altered. However, treatment with guanidinoethane sulfonate lessened the antiepileptic actions of phenobarbital and phenytoin on electroshock seizures. The brain concentrations of phenobarbital and phenytoin were unaltered by administration of guanidinoethane sulfonate. The brain concentrations of guanidinoethane sulfonate and total guanidino compounds were unchanged by the injection of either phenobarbital or phenytoin. It is suggested that the observed loss of anticonvulsive potency of phenobarbital and phenytoin may have been related to the decrease in taurine concentration produced by guanidinoethane sulfonate.     

Evaluation of epileptic dogs as an animal model of human epilepsy

In 126 epileptic dogs with spontaneously recurring generalized tonic-clonic (grand mal) seizures, epidemiological aspects and the efficacy of chronic oral treatment with common antiepileptic drugs were studied. Furthermore, the pharmacokinetics of antiepileptic drugs in dogs was compared with the values known for man. As in man, idiopathic epilepsy appeared to be more common than symptomatic epilepsy in dogs. There was a preponderance of male vs. female animals. When the breeds of the epileptic dogs were compared to the distribution of breeds in the hospital population, breed-related differences in the prevalence of epilepsy were found. The highest prevalence was seen in Cocker spaniels, Miniature schnauzers, Collies and Bassets. The total prevalence of dogs with epilepsy was 0.55%. Comparison of pharmacokinetics of antiepileptic drugs showed that some drugs were suited for maintenance therapy in dogs (primidone, phenobarbital, ethosuximide, trimethadione) whereas others appeared not to be ideally suited because of their short half-lives (phenytoin, carbamazepine, valproic acid, diazepam, clonazepam, nitrazepam). This was confirmed by the evaluation of antiepileptic drug efficacy in epileptic dogs. 46 dogs were treated with primidone at daily doses of 14-104 mg/kg for 6-60 months. During medication with primidone, effective plasma levels of its metabolite phenobarbital could be maintained. Complete control of seizures or a reduction of seizure frequency by at least 75% was achieved in 39% of the dogs at phenobarbital concentrations of 5-49 micrograms/ml. Similar figures were obtained during chronic treatment with phenobarbital at daily doses of 2.5-13 mg/kg.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of acutely and chronically administered venlafaxine on the anticonvulsant action of classical antiepileptic drugs in the mouse maximal electroshock model

The influence of acute and chronic treatments with intraperitoneal venlafaxine, a selective serotonin/norepinephrine reuptake inhibitor, on the anticonvulsant activity of selected antiepileptic drugs was studied in the maximal electroshock test in mice. Venlafaxine (12.5 and 25 mg/kg), given either acutely or chronically, significantly increased the electroconvulsive threshold. Moreover, both acute and chronic venlafaxine, applied at the highest subprotective dose of 6.25 mg/kg, enhanced the anticonvulsant effect of valproate, without affecting the protective action of carbamazepine, phenobarbital and phenytoin. The antidepressant did not affect brain concentration of valproate, indicating that the interaction between the two drugs seems pharmacodynamic in nature. Despite the lack of effect on the antielectroshock action of the remaining antiepileptics, acute venlafaxine increased the brain concentration of phenobarbital, while chronic venlafaxine reduced the brain level of phenytoin. In terms of adverse effects, acute/chronic venlafaxine and antiepileptic drugs alone, as well as their combinations, did not produce significant motor or long-term memory deficits in mice. Summing up, it seems that venlafaxine may be considered as a safe drug for the clinical use in patients with epilepsy and depressive disorders.     

黄连治疗癫痫的协同作用及对P-糖蛋白介导的抗癫痫药脑转运的调节作用

目的 考察黄连协同抗癫痫药治疗癫痫的疗效及黄连对P-糖蛋白介导的抗癫痫药透过血脑屏障的影响,评价黄连对癫痫的防治作用。方法 选用P-糖蛋白抑制剂维拉帕米和常用抗癫痫药卡马西平,使用戊四唑和士的宁制备小鼠癫痫模型,观察并对比卡马西平单用与联用低、中、高剂量黄连的小鼠潜伏期、惊厥率和死亡率的差异。小鼠分组并灌胃卡马西平、卡马西平加黄连及卡马西平加维拉帕米后,测定脑组织卡马西平浓度并比较。结果 黄连可显著增强卡马西平对抗戊四唑、士的宁所引起的癫痫作用,延长潜伏期和降低惊厥率(P<0.05),明显提高卡马西平的脑浓度(P<0.05)。结论 黄连对癫痫的治疗有良好的增效作用。     

Standard antiepileptic drugs fail to block epileptiform activity in rat organotypic hippocampal slice cultures

BACKGROUND AND PURPOSE: Earlier studies had demonstrated that tonic-clonic seizure-like events (SLEs) resembling electrographic correlates of limbic seizures in animals and humans can be induced in organotypic hippocampal slice cultures (OHSCs). We have explored OHSCs for their suitability to serve as in vitro models of limbic seizures for studying seizure mechanisms and screening new antiepileptic compounds. EXPERIMENTAL APPROACH: OHSCs were cultivated according to the interface method. Neuronal activity and extracellular potassium concentration were recorded under submerged conditions. SLEs were induced by lowering magnesium concentration or by applying the potassium channel blocker 4-aminopyridine. The effects of standard antiepileptic drugs (AEDs), carbamazepine, phenytoin, valproic acid, clonazepam, diazepam and phenobarbital sodium on SLEs were analysed. KEY RESULTS: In more than 93% of OHSCs, AEDs did not prevent the induction of SLEs or stop ongoing seizure activity even when toxic concentrations were applied. This pharmacoresistance was independent of the method of seizure provocation, postnatal age at explantation (P2-P10) and cultivation time in vitro (2 months). SLEs were reversibly blocked by glutamate antagonists or the GABA(A)-agonist muscimol. CONCLUSIONS AND IMPLICATIONS: We present a simple to establish in vitro model of tonic-clonic SLEs that is a priori pharmacoresistant and thus has an advantage over animal models of pharmacoresistant seizures in which responders and non-responders can be sorted out only after an experiment. OHSCs could be suitable for exploring mechanisms of pharmacoresistant seizures and be used for the identification of new anticonvulsive compounds eventually effective in drug refractory epilepsy.     

Effect of phenytoin on sodium and calcium currents in hippocampal CA1 neurons of phenytoin-resistant kindled rats.

About 20-30% of patients with epilepsy continue to have seizures despite carefully monitored treatment with antiepileptic drugs. The mechanisms explaining why some patients' respond and others prove resistant to antiepileptic drugs are poorly understood. It has been proposed that pharmacoresistance is related to reduced sensitivity of sodium channels in hippocampal neurons to antiepileptic drugs such as carbamazepine or phenytoin. In line with this proposal, a reduced effect of carbamazepine on sodium currents in hippocampal CA1 neurons was found in the rat kindling model of temporal lobe epilepsy (TLE), i.e. a form of epilepsy with the poorest prognosis of all epilepsy types in adult patients. To address directly the possibility that neuronal sodium currents in the hippocampus play a crucial role in the pharmacoresistance of TLE, we selected amygdala-kindled rats with respect to their in vivo anticonvulsant response to phenytoin into responders and nonresponders and then compared phenytoin's effect on voltage-activated sodium currents in CA1 neurons. Furthermore, in view of the potential role of calcium current modulation in the anticonvulsant action of phenytoin, the effect of phenytoin on high-voltage-activated calcium currents was studied in CA1 neurons. Electrode-implanted but not kindled rats were used as sham controls for comparison with the kindled rats. In all experiments, the interval between last kindled seizure and ion channel measurements was at least 5 weeks. In kindled rats with in vivo resistance to the anticonvulsant effect of phenytoin (phenytoin nonresponders), in vitro modulation of sodium and calcium currents by phenytoin in hippocampal CA1 neurons did not significantly differ from respective data obtained in phenytoin responders, i.e. phenytoin resistance was not associated with a changed modulation of the sodium or calcium currents by this drug. Compared to sham controls, phenytoin's inhibitory effect on sodium currents was significantly reduced by kindling without difference between the responder and nonresponder subgroups. Further studies in phenytoin-resistant kindled rats may help to elucidate the mechanisms that can explain therapy resistance.     

Impact of seizure activity on free extracellular phenytoin concentrations in amygdala-kindled rats

Access of antiepileptic drugs (AEDs) to the epileptic focus region is considered to be influenced by seizure-associated changes in blood-brain barrier (BBB) function and blood flow. Enhanced leakiness of the BBB has been reported as a consequence of seizure activity, and this is controversially discussed to either favor accumulation of AEDs in epileptic tissue or to limit free extracellular concentrations of AEDs due to enhanced protein extravasation. On the other hand, multidrug transporter overexpression has been described following seizure activity, which can limit brain penetration of AEDs in brain regions involved in seizure generation and spread. Aim of the present study was to determine, how these complex alterations at the BBB influence penetration of a standard AED to the site of seizure initiation. Microdialysis experiments were performed in amygdala-kindled rats and in electrode-implanted, non-kindled rats with the microdialysis probe located directly adjacent to the stimulation-recording depth electrode. Penetration of the AED phenytoin to the extracellular fluid in the focus region was investigated at different time points in relation to seizure activity elicited in kindled rats. Integrity of the BBB was determined by Evans blue. Access of phenytoin to the amygdala proved to be comparable in non-kindled, electrode-implanted control rats and in kindled rats 2 h or fourteen days following a single generalized seizure. When a single generalized seizure was elicited 10 min following phenytoin administration, average phenytoin brain dialysate levels were significantly lower (up to 45%) than those of control animals. During a self-sustained status epilepticus, phenytoin access to the site of seizure initiation tended to be lower in the early phase following drug administration, but reached control level 2 h later. The data clearly demonstrate that seizure-induced alterations in BBB integrity and function do not increase extracellular brain levels of phenytoin in affected brain regions, but rather tend to decrease the free concentration of phenytoin in the extracellular compartment.     

Evaluation of therapeutic drug level monitoring of phenobarbital, phenytoin and carbamazepine in Iranian epileptic patients

OBJECTIVE: The antiepileptic drugs phenobarbital, phenytoin and carbamazepine are widely used for the treatment of partial and tonic-clonic seizures. Large inter-individual differences in pharmacokinetics of these drugs, and the intermittent nature of epileptic attacks, increase the need for therapeutic drug level monitoring of these drugs. MATERIAL AND METHODS: In this study, data from the therapeutic drug monitoring of phenobarbital, carbamazepine and phenytoin in 328 epileptic patients were evaluated. Serum levels of drugs were determined in a University Department of Pharmacology by high-performance liquid chromatography. RESULTS: In this study, approximately 56% of patients were treated with 1; 30% with 2; and 14% with 3 antiepileptic drugs. In patients receiving 1 antiepileptic drug, the percentages treated with phenobarbital, carbamazepine and phenytoin were 41, 38 and 21%, respectively. In patients who received carbamazepine, serum levels in 40% of the patients were in the range of 4-8 microg/ml and more than in the range 4-12 microg/ml in 74% of the patients. In phenobarbital-treated patients, serum levels in 73% of the patients were in therapeutic range of 10-40 microg/ml, and about 44% of phenytoin-treated patients had serum levels in therapeutic range of 10-20 microg/ml. Approximately 50% of carbamazepine- and phenytoin-treated patients and approximately 70% of phenobarbital-treated patients were completely controlled. The frequency of concentrations within the therapeutic ranges decreased in patients using more than 1 antiepileptic drug. In patients who received both phenobarbital and sodium valproate, serum levels of phenobarbital were significantly (p < 0.05) greater than in patients who were taking this drug in combination with carbamazepine or phenytoin. CONCLUSION: Our results indicate that serum levels of antiepileptic drugs, and the percentage of patients with complete seizure control are comparable with results obtained in other populations in previous studies.     

Novel approaches to anticonvulsant drug discovery

Introduction: The history of epilepsy dates back to 2000 BC. Yet, it was not until 1912 that the activity of the first antiepileptic, phenobarbital was discovered by accident. After this discovery, the next antiepileptic drugs to be discovered (phenytoin and primidone) were based on the phenobarbital's structure. Then, in 1960, carbamazepine was developed empirically, while in 1962, valproate demonstrated anticonvulsant activity against experimental seizures. The next antiepileptic drugs synthesized were either modifications of the existing drugs (such as oxcarbazepine and pregabalin) or completely novel chemical structures (lacosamide, perampanel and retigabine).

Areas covered: The present paper briefly refers to the history of epilepsy and development of antiepileptic drugs. Further, the paper provides a discussion on the antiepileptogenic effects of antiepileptic drugs in terms of the constant percentage of epileptic patients with refractory seizures. The authors also review the likely factors involved in the false refractoriness (such as through the use of caffeine-containing beverages and smoking). Finally, the authors consider future directions in the search of novel antiepileptic drugs.

Expert opinion: In spite of the considerable number of newer antiepileptic drugs, the number of drug-resistant epileptic patients remains unchanged. This may be rather an indication of the suitability of the currently available discovery procedures for effective antiepileptic drugs in the whole population of epileptic patients. The authors, however, believe that it is likely that models of mimic chronic epilepsy will help bridge the gaps and aid in the discovery of novel antiepileptic drugs – ones that can effectively modify the course of the disease.     

Evaluation of the role of P-glycoprotein in the uptake of paroxetine, clozapine, phenytoin and carbamazapine by bovine retinal endothelial cells

Expression of the drug transport proteins, including P-glycoprotein (Pgp), in the brain vascular endothelium represents a challenge for the effective delivery of drugs for the treatment of several central nervous system (CNS) disorders including depression, schizophrenia and epilepsy. It has been hypothesized that Pgp plays a major role in drug efflux at the blood-brain barrier, and may be an underlying factor in the variable responses of patients to CNS drugs. However, the role of Pgp in the transport of many CNS drugs has not been directly demonstrated. To explore the role of Pgp in drug transport across an endothelial cell barrier derived from the central nervous system, the expression and activity of Pgp in bovine retinal endothelial cells (BRECs) and the effects of representative CNS drugs on Pgp activity were examined. Significant Pgp expression in BRECs was demonstrated by western analyses, and expression was increased by treatment of the cells with hydrocortisone. Intracellular accumulation of the well-characterized Pgp-substrate Taxol was markedly increased by the non-selective transporter inhibitor verapamil and the Pgp-selective antagonist PGP-4008, demonstrating that Pgp is active in these endothelial cells. In contrast, neither verapamil nor PGP-4008 affected the intracellular accumulation of [3H]paroxetine, [14C]phenytoin, [3H]clozapine or [14C]carbamazapine, indicating that these drugs are not substrates for Pgp. Paroxetine, clozapine and phenytoin were shown to be Pgp inhibitors, while carbamazapine did not inhibit Pgp at any concentration tested. These results indicate that Pgp is not likely to modulate patient responses to these drugs.     

Neuronal MDR-1 gene expression and persistent low levels of anticonvulsants in a child with refractory epilepsy

SUMMARY: It is estimated that 20-25% of epileptic patients fail to achieve good control with antiepileptic drug (AED) treatment; thus, refractory epilepsy (RE) has been described in patients who have adequate therapeutic levels of AEDs without control of seizures. Multidrug resistance genes have been reported to be highly expressed in brain of patients with RE. Persistent low plasma levels of AEDs and high brain expression of the multidrug resistance product P-glycoprotein (P-gp) have been previously communicated in a case report of RE secondary to tuberous sclerosis. Here, the authors report a case of an 8-year-old boy diagnosed with partial RE with focal seizures who was admitted to hospital for a severe episode of subintrant crisis. The patient received polytherapy with carbamazepine (CBZ), phenytoin (PHT), and valproic acid (VA); however, habitual doses of these AEDs failed to control the patient's symptoms. AED blood levels were monitored for 25 consecutive days and showed low values in 8/25 (33%) for CBZ, 10/25 (40%) for PHT, and 25/25 (100%) for VA of samples studied. Because the patient developed focal status epilepticus, surgical treatment by callosotomy was done, resulting in a significant improvement in epileptic symptoms. The immunostaining of brain specimens showed significantly increased expression of P-gp not only in vascular endothelial cells and related astrocytes but also in neurons. Overexpression of P-gp in the brain does not explain the low blood levels of AEDs described in these cases. Different mechanisms such as drug-drug interactions and drug transporters can be involved in the results observed. The P-gp overexpression and/or its pharmacologic induction should be considered as a potential mechanism responsible for drug resistance to epilepsy treatment and highly suspected in patients with persistent subtherapeutic AEDs plasma levels.     

Polymorphic variants of the multidrug resistance gene Mdr1a and response to antiepileptic drug treatment in the kindling model of epilepsy

Allelic variants of the human P-glycoprotein encoding gene MDR1 (ABCB1) are discussed to be associated with different clinical conditions including pharmacoresistance of epilepsy. However, conflicting data have been reported with regard to the functional relevance of MDR1 allelic variants for the response to antiepileptic drugs. To our knowledge, it is not known whether functionally relevant genetic polymorphisms also occur in the two genes (Mdr1a/Abcb1a, Mdr1b/Abcb1b) coding for P-glycoprotein in the brain of rodents. Therefore, we have started to search for polymorphisms in the Mdr1a gene, which governs the expression of P-glycoprotein in brain capillary endothelial cells in rats. In the kindling model of temporal lobe epilepsy, subgroups of phenytoin-sensitive and phenytoin-resistant rats were selected in repeated drug trials. Sequencing of the Mdr1a gene coding sequence in the subgroups revealed no general differences between drug-resistant and drug-sensitive rats of the Wistar outbred strain. A comparison between different inbred and outbred rat strains also gave no evidence for polymorphisms in the Mdr1a coding sequence. However, in exon-flanking intron sequences, four genetic variants were identified by comparison between these rats strains.

In conclusion, the finding that Wistar rats vary in their response to phenytoin, while having the same genetic background, argues against a major impact of Mdr1a genetics on pharmacosensitivity to antiepileptic drugs in the amygdala kindling model.