Doru Georg Margineanu

Levetiracetam inhibits the high-voltage-activated Ca2+ current in pyramidal neurones of rat hippocampal slices

The effect of the new antiepileptic drug levetiracetam (LEV; KEPPRA) on the neuronal high-voltage-activated (HVA) Ca(2+) current was investigated on pyramidal neurones, visually identified in the CA1 area of rat hippocampal slices. Nystatin-perforated patch clamp recordings were made under experimental conditions designed to study HVA Ca(2+) currents. The HVA current, activated by steadily increasing voltage-ramps, was reversibly eliminated by Cd(2+) and depressed by either nimodipine, or omega-Conotoxin GVIA. After 30 min perfusion of the slices with LEV 32 microM, the current decayed to 55+/-9% (mean+/-SEM; n=9) of the initial value, which is significantly (P<0.05, two-tailed t-test) lower than the rundown to 84+/-10% in a control group (n=10) of neurones. The limited, but significant depression of the neuronal HVA Ca(2+) current, produced by LEV at a clinically relevant concentration, might contribute to the antiepileptic action of the drug.

Levetiracetam does not modulate neuronal voltage-gated Na+and T-type Ca2+currents

This study investigated whether the mechanism of action of levetiracetam (LEV) is related to effects on neuronal voltage-gated Na+ or T-type Ca2+currents. Rat neocortical neurones in culture were subjected to the whole-cell mode of voltage clamping under experimental conditions designed to study voltage-gated Na+ current. Additionally, visually identified pyramidal neurones in the CA1 area of rat hippocampal slices were subjected to the whole-cell mode of voltage clamping under experimental conditions designed to study low-voltage-gated (T-type) Ca2+ current. LEV (10 microM-1 mM) did not modify the Na+ current amplitude and did not change (200 microM) the steady-state activation and inactivation, the time to peak, the fast kinetics of the inactivation and the recovery from the steady-state inactivation of the Na+ current. Likewise, LEV (32-100 microM) did not modify the amplitude and did not change the steady-state activation and inactivation, the time to peak, the fast kinetics of the inactivation and the recovery from the steady-state inactivation of the T-type Ca2+current. In conclusion, neuronal voltage-gated Na+ channels do not appear directly involved in the antiepileptic mechanism of action of LEV, and LEV was devoid of effect on the low-voltage-gated (T-type) Ca2+ current in hippocampal neurones.

Reduction of voltage-operated potassium currents by levetiracetam : a novel antiepileptic mechanism of action?

Levetiracetam (ucb L059; Keppra) is a novel antiepileptic drug. Its effects on action potential generation and voltage-operated potassium currents were studied in acutely isolated hippocampal CA1 neurones from rat and guinea pig, using the patch-clamp technique in the whole-cell configuration. (i) Levetiracetam reduced repetitive action potential generation and affected the single action potential. Levetiracetam, 100 microM, decreased the total number of action potentials and reduced the total depolarisation area of repetitive action potentials by 21%. Furthermore, levetiracetam increased the duration of the first action potential slightly, prolonged that of the second action potential by 13% and decreased the slope of rise by 23%. (ii) Levetiracetam decreased the voltage-operated potassium current. Without effect on sodium and A-type potassium currents, levetiracetam, 100 microM, reduced the delayed rectifier current by 26%. The concentration of half-maximal block was 47 microM for guinea pig and 6 microM for rat neurones. Thus, the reduction of repetitive action potential generation by levetiracetam can be attributed, unexpectedly, to a moderate reduction of the delayed rectifier potassium current, as supported by a simulation of action potential generation. This suggests that a reduction of potassium currents may contribute to the antiepileptic effect(s) of levetiracetam.

Brivaracetam (ucb 34714) inhibits Na + current in rat cortical neurons in culture

Brivaracetam (ucb 34714; BRV), a new antiepileptic drug (AED) candidate, is a pyrrolidone derivative displaying a markedly higher affinity than levetiracetam (LEV; Keppra) to the synaptic vesicle protein SV2A, shown to be the brain-specific binding site of LEV. The higher affinity for SV2A correlates significant antiepileptic activity in animal epilepsy models in vitro and in vivo. Since many AEDs act upon inhibiting neuronal Na(+) currents, this study explored putative activity of BRV on the properties of these currents. Voltage-activated Na(+) currents were recorded by whole-cell patch-clamp on neuronal somas of rat neocortical neurons, grown in dissociated cell culture for up to 12 days. BRV, dissolved at the desired final concentration (between 0.2microM and 1mM) was applied by a multi-barrel pipette system near the soma of the recorded neuron. BRV produced a concentration-dependent inhibition of voltage-dependent Na(+) currents with IC(50) values of 41microM at the holding potential of -100mV, and of 6.5microM at the holding potential of -60mV. The voltage-dependence of activation and the kinetics of fast inactivation were not modified in the presence of BRV (30microM). Conversely, the recovery from fast inactivation was significantly slower and the voltage of half-maximal inactivation was shifted toward hyperpolarized value after BRV perfusion in a concentration-dependent manner. Furthermore, BRV (30microM) induced a significant use-dependent block at 50Hz stimulation frequency. These results indicate that BRV is able to modulate the voltage-activated Na(+) inflow in cortical neurons, which conceivably might contribute to the antiepileptic activity of this drug.

Levetiracetam has no significant γ-aminobutyric acid-related effect on paired-pulse interaction in the dentate gyrus of rats

Gamma-aminobutyric acid (GABA)ergic mechanisms of the novel antiepileptic drug, levetiracetam (Keppra), have been both favored and rejected. Since paired-pulse interaction is accepted in functionally assessing GABAergic mechanisms, we investigated whether levetiracetam affects the paired-pulse inhibition/facilitation of the field potentials, evoked in the dentate gyrus of urethane-anesthesized rats. This model revealed a strong paired-pulse inhibition at 20-ms interstimulus interval, a noteworthy paired-pulse facilitation at 80-ms interstimulus interval, and a moderate paired-pulse inhibition at 500-ms interstimulus interval. Bicuculline (3 mg/kg/h, i.v.) and baclofen (10 mg/kg, i.v.) markedly depressed paired-pulse inhibition at 20-ms interstimulus interval, while clonazepam (1 mg/kg, i.p.), diazepam (10 mg/kg, i.v.), and phenobarbital (40 mg/kg, i.v.) enhanced it. Bicuculline also depressed paired-pulse inhibition at 500-ms interstimulus interval. Bicuculline, baclofen, and diazepam reduced paired-pulse facilitation at 80-ms interstimulus interval. Distinct from these GABA(A) receptor- and GABA(B) receptor-related drugs, levetiracetam (17 and 540 mg/kg, i.v.) had no significant effect on either paired-pulse interaction in this model, a result not favoring any major role of GABAergic mechanisms in its antiseizure action.

Absence of negative impact of levetiracetam on cognitive function and memory in normal and amygdala-kindled rats.

The effect of the new antiepileptic drug (AED) levetiracetam (LEV, Keppra) on cognitive function was studied in normal and amygdala-kindled rats by using the Morris water maze test. In addition, we investigated the effect of LEV on long-term potentiation (LTP) in rat hippocampal slices. Sodium valproate (VPA) was used as comparator in all studies. Clonazepam (CZP) and carbamazepine (CBZ) were used in normal rats. The results indicated that doses of LEV known to suppress motor seizures did not alter cognitive performance. In contrast, similar doses of the classic AEDs all decreased learning performance of the rats. Likewise, VPA did alter LTP but LEV was inactive. Amygdala-kindled rats were more sensitive than normal rats to the effects of VPA. These results suggest that LEV may be devoid of negative impact on cognition in epileptic patients.

Is the persistent sodium current a specific target of anti-absence drugs?

The persistent Na+ current (INaP) has been proposed as the putative target of the anti-absence antiepileptic drugs. Accordingly, the effect of reference anti-absence drugs ethosuximide (ESM) and valproate (VPA), and of the new antiepileptic drug levetiracetam (LEV), on INaP have been tested in CA1 hippocampal neurons and compared to the classic anticonvulsant phenytoin (PHT) and the neuroprotective agent riluzole (RIL). Whole-cell patch-clamp recordings of the slowly inactivating current, fully characterized as INaP, were performed with a standard voltage-step protocol on thin hippocampal slices prepared from rat brain. Both PHT (100 μM) and RIL (10 μM) strongly depressed INaP, whereas ESM (1 mM) induced a slight decrease of INaP and VPA (1 mM) had no effect. Likewise, 60- min perfusion with relevant concentrations of LEV (10, 32 or 100 μM) did not modify INaP. In conclusion, these data question the impact of INaP depression as an anti-absence mechanism, and also discalim the involvement of INaP in the antiepileptic mechanism of LEV.

Differential effects of cation-chloride co-transport-blocking diuretics in a rat hippocampal slice model of epilepsy

The cation-Cl- co-transport-blocking loop diuretics have clinically known anticonvulsant activity, though they can also induce seizures. We explored the effects of ethacrynic acid (ETA), furosemide (FUR) and bumetanide (BUM), prototypical blockers of cation-Cl- co-transport, on the epileptiform field potentials induced in CA3 area of hippocampal slices from 5-weeks-old rats by a high K+-low Ca2+ perfusion fluid. That milieu induces frequent spontaneous field bursts, making single fimbrial stimuli to evoke several repetitive population spikes, of increased amplitude. ETA (0.25-1 mM) concentration-dependently reduced spontaneous field bursting, up to terminating it. FUR, 5 mM also inhibited spontaneous field bursting, while BUM (12.5-100 microM) only presented an inconsistent tendency. Both ETA and FUR showed a less marked ability to depress the evoked responses, but approximately mM concentrations significantly reduced the number of repetitive population spikes and their amplitude. BUM only modestly reduced population spike amplitude, without concentration-dependence. This study shows that K+-Cl- co-transport-blocking diuretics ETA and FUR inhibit high K+-induced epileptiform activity in hippocampal slices from (nearly) adult rats, while the Na+-K+-2Cl- co-transport-preferring diuretic BUM had only negligible activity. These results support that neuronal K+-Cl- co-transport-blockade provides antiepileptic effects.

H3 agonist immepip markedly reduces cortical histamine release, but only weakly promotes sleep in the rat.

Presynaptic H3 receptors exert negative control on brain histamine synthesis and release and may thereby play a key role in the control of the sleep/wake cycle. This suggests that pharmacological stimulation by H3 receptor agonists may potentially decrease wakefulness and induce sleep. This study reports the effect of a potent and selective H3 agonist, immepip, on EEG assessed sleep/wake phases in Sprague-Dawley rats at doses that significantly modulate brain histamine release. Immepip injected intraperitoneally (i.p.) at 5 or 10 mg kg(-1) induced a sustained decrease in cortical histamine efflux as measured by in vivo microdialysis. In a separate experiment, rats were prepared for EEG/EMG recording and evaluated during the dark phase of their light/dark cycle. The results showed that the same i.p. doses of 5 and 10 mg kg(-1) of immepip was devoid of any significant impact on the sleep/wake phases (active awake, drowsiness and slow wave sleep), except for a slight, albeit significant, decrease in sleep onset latency. These results reveal that a marked H3 receptor agonist-mediated reduction in cortical histamine release is not corroborated by a significant sleep promoting effect and therefore question the hypnotic potential of H3 agonists.

The connexin 36 blockers quinine, quinidine and mefloquine inhibit cortical spreading depression in a rat neocortical slice model in vitro.

A protocol for inducing cortical spreading depression (SD) on rat neocortical slices in vitro, upon local application of calibrated approximately nl drops of KCl, 3M was used to elicit SD events, recorded at two different points on the slice. This in vitro model was validated by the inhibition of SD episodes by the NMDA antagonist MK-801 (20 microM), the reference SD blocker. Quinine, its stereoisomer quinidine, and mefloquine consistently inhibited the SD episodes. Quinine and quinidine, 100 and 200 microM reduced the duration, while mefloquine, 100 and 200 microM reduced the amplitude of SD events, all in a concentration-dependent manner. These compounds have been reported to block gap junctions, specifically the neuronal connexin (Cx) 36, but they also exert other cellular effects. While further investigation is warranted to settle whether SD inhibition in vitro by quinine, quinidine and mefloquine reflects an involvement of neuronal Cx36 channels in SD generation/propagation, these results bear potential drug-discovery relevance for the migraine with aura.