NMDA receptor-mediated depolarizing after-potentials in the basal dendrites of CA1 pyramidal neurons.

It was shown recently that the basal dendrites of cortical pyramidal neurons generate NMDA-spikes. In the present study, we made whole-cell recordings from hippocampal CA1 pyramidal neurons and examined whether NMDA receptor activation was involved in synaptic responses. At low input stimulus intensity, EPSPs with a fast decay time were induced. As the intensity of stimulation was increased in the presence of GABA receptor antagonists, a depolarizing after-potential (DAP) was generated in addition to a fast decaying potential. A DAP was never observed when the input was applied to the apical dendrites. The DAP was suppressed by hyperpolarization or by NMDA receptor antagonists, but not by Na+, K+, or Ca2+ channel blockers. One possible mechanism is that the morphology of the basal dendrites favors DAP generation. A compartmental model simulation showed that synaptic inputs to thinner shorter dendrites generated a potential that resembled a DAP. Our study shows that a synaptic input to the basal dendrites of a hippocampal pyramidal neuron can generate a NMDA receptor-mediated potential in the presence of GABA receptor blockade.

A large sustained Ca2+ elevation occurs in unstimulated spines during the LTP pairing protocol but does not change synaptic strength.

Synapses in the CA1 region of the hippocampus undergo bidirectional synaptic modification in response to different patterns of activity. Postsynaptic Ca2+ elevation can trigger either synaptic strengthening or weakening, depending on the properties of the local Ca2+ signal. During the pairing protocol for long-term potentiation (LTP) induction, the cell is depolarized under voltage-clamp and is given low-frequency synaptic stimulation. As an initial step toward understanding the Ca2+ dynamics during this process, we used confocal microscopy to study the Ca2+ signals in spines evoked by the depolarization itself. This depolarization activates voltage-dependent Ca2+ channels (VDCC), but whether these channels inactivate rapidly or remain functional throughout the long depolarizations used in the pairing protocol remains unknown. Cells were depolarized to 0 mV for 2-3 min. This depolarization led to a large initial elevation of Ca2+ in spines that never decayed back to resting levels. The maintained signal was close to the Kd of the low-affinity (5 microM) Ca2+ dye, Magnesium Green. We attempted to determine the functional role of this elevation, using the Ca2+-channel blocker D-890. The addition of D-890 in the internal solution produced a nearly complete abolition of the Ca2+ elevation during depolarization. Under these conditions, the NMDA conductance was normal, but LTP was almost completely blocked. This might suggest the importance of VDCC in LTP; however, we found that high concentrations of D-890 can directly inhibit calmodulin protein kinase II (CaMKII), an enzyme required for LTP induction. Thus, whereas D-890 is a useful tool for blocking postsynaptic VDCC, it cannot be used to study the contribution of these channels to plasticity. We conclude that the activation of VDCC produces a large and persistent elevation of Ca2+ in all spines, but does not produce either LTP or long-term depression (LTD) in the absence of synaptic stimulation. The possible reasons for this are discussed.

Verapamil block of large-conductance Ca-activated K channels in rat aortic myocytes.

The effects of verapamil on the large conductance Ca-activated K (BK) channel from rat aortic smooth muscle cells were examined at the single channel level. Micromolar concentrations of verapamil produced a reversible flickering block of the BK channel activity. Kinetic analysis showed that verapamil decreased markedly the time constants of the open states, without any significant change in the time constants of the closed states. The appearance of an additional closed state-specifically, a nonconducting, open-blocked state--was also observed, whose time constant would reflect the mean residence time of verapamil on the channel. These observations are indicative of a state-dependent, open-channel block mechanism. Dedicated kinetic (group) analysis confirmed the state-dependent block exerted by verapamil. D600 (gallopamil), the methoxy derivative of verapamil, was also tested and found to exert a similar type of block, but with a higher affinity than verapamil. The permanently charged and membrane impermeant verapamil analogue D890 was used to address other important features of verapamil block, such as the sidedness of action and the location of the binding site on the channel protein. D890 induced a flickering block of BK channels similar to that observed with verapamil only when applied to the internal side of the membrane, indicating that D890 binds to a site accessible from the cytoplasmic side. Finally, the voltage dependence of D890 block was assessed. The experimental data fitted with a Langmuir equation incorporating the Woodhull model for charged blockers confirms that the D890-binding site is accessed from the internal mouth of the BK channel, and locates it approximately 40% of the membrane voltage drop along the permeation pathway.

Mechanism of verapamil block of a neuronal delayed rectifier K channel: active form of the blocker and location of its binding domain.

1. The mechanism of verapamil block of the delayed rectifier K currents (I K(DR)) in chick dorsal root ganglion (DRG) neurons was investigated using the whole-cell patch clamp configuration. In particular we focused on the location of the blocking site, and the active form (neutral or charged) of verapamil using the permanently charged verapamil analogue D890. 2. Block by D890 displayed similar characteristics to that of verapamil, indicating the same state-dependent nature of block. In contrast with verapamil, D890 was effective only when applied internally, and its block was voltage dependent (136 mV/e-fold change of the on rate). Given that verapamil block is insensitive to voltage (Trequattrini et al., 1998), these observations indicate that verapamil reaches its binding site in the uncharged form, and accesses the binding domain from the cytoplasm. 3. In external K and saturating verapamil we recorded tail currents that did not decay monotonically but showed an initial increase (hook). As these currents can only be observed if verapamil unblock is significantly voltage dependent, it has been suggested (DeCoursey, 1995) that neutral drug is protonated upon binding. We tested this hypothesis by assessing the voltage dependence of the unblock rate from the hooked tail currents for verapamil and D890. 4. The voltage dependence of the off rate of D890, but not of verapamil, was well described by adopting the classical Woodhull (1973) model for ionic blockage of Na channels. The voltage dependence of verapamil off rate was consistent with a kinetic scheme where the bound drug can be protonated with rapid equilibrium, and both charged and neutral verapamil can unbind from the site, but with distinct kinetics and voltage dependencies.

The origins of two-state spontaneous membrane potential fluctuations of neostriatal spiny neurons.

In vivo intracellular recordings of spontaneous activity of neostriatal spiny cells revealed two-state behavior, i.e., characteristic shifts of membrane potential between two preferred levels. The more polarized level, called the Down state, varied among neurons from -61 to -94 mV. The more depolarized level, called the Up state, varied among neurons form -71 to -40 mV. For any one neuron, the membrane potential in the Up and Down states was constant over the period of observation (from 15 min to 4 hr), and the cells spent little time in transition between states. The level of membrane potential noise was higher in the Up state than in the Down state. Spontaneous membrane potential fluctuations were not abolished by experimental alteration of the membrane potential, but the time spent in each state was altered when intracellular current was used to vary the baseline membrane potential. Neither the sodium nor the calcium action potential that could be evoked by depolarization of spiny neurons was required for the occurrence of spontaneous shifts of membrane potential. Blockade of these action potentials using intracellular injection of QX314 and D890, respectively, altered neither the incidence of the membrane potential shifts nor the preferred membrane potential in either state. In contrast, antagonism of voltage-dependent potassium channels with intracellular cesium altered membrane potential shifts. In the presence of QX314 and D890, intracellular injection of cesium caused little or no change in the Down state and a large depolarizing shift in the Up state (to about -20 mV). Under these circumstances, the neuron responded to current in a nearly linear manner, and membrane conductance was found to be increased in the Up state, attributable to a membrane conductance with the same reversal potential as that of the synaptic potential evoked by cortical stimulation. These results indicate that the event underlying the Up state is a maintained barrage of synaptic excitation, but that the membrane potential achieved during the Up state in neostriatal spiny neurons is determined by dendritic potassium channels that clamp the membrane potential at a level determined by their voltage sensitivity. Neostriatal spiny neurons ordinarily receive enormously powerful excitation, which would drive the cells to saturation, and probably destroy them, if it were not for these potassium currents.

Trypsin increases availability and open probability of cardiac L-type Ca2+ channels without affecting inactivation induced by Ca2+.

The patch-clamp technique was employed to investigate the response of single L-type Ca2+ channels to the protease trypsin applied to the intracellular face of excised membrane patches from guinea pig ventricular myocytes. Calpastatin and ATP were used to prevent run-down of Ca2+ channel activity monitored with 96 mM Ba2+ as charge carrier in the presence of 2.5 microM (-)-BAYK 8644. Upon application of trypsin (100 micrograms/ml) channel activity was enhanced fourfold and remained elevated upon removal of trypsin, as expected of a proteolytic, irreversible modification. The trypsin effect was not mediated by a proteolytic activation of protein kinases, as evidenced by the insensitivity of this effect to protein kinase inhibitors. Trypsin-modified Ca2+ channels exhibited the usual run-down phanomenon upon removal of calpastatin and ATP. In ensemble average currents trypsin-induced changes of channel function are apparent as a threefold increase in peak current and a reduction in current inactivation. At the single channel level these effects were based on about a twofold increase in both Ca2+ channels' availability and open probability. Neither the actual number of channels in the patch nor their unitary conductance as well as reversal potential was changed by trypsin. The Ca(2+)-induced inactivation was not impaired, as judged by a comparable sensitivity of trypsin-modified Ca2+ channels to intracellular Ca2+. Similarly, trypsin treatment did not affect the sensitivity of Ca2+ channels to phenylalkylmine inhibition. The observed alterations in channel function are discussed in terms of possible structural correlates.

Quaternary diltiazem can act from both sides of the membrane in ventricular myocytes.

A quaternary derivative of diltiazem (quat-DTZ) was tested to determine whether diltiazem approaches L-type Ca2+ channels from the outside or inside of the cell membrane. In single ventricular myocytes, both extra- and intracellular application of quat-DTZ effectively blocked the L-type Ca2+ channel current, whereas D890 was effective only when applied intracellularly. These results strongly suggest that diltiazem binds to the channel from the outside as well as the inside of the membrane in a manner different from that of phenylalkylamines.

D600 binding sites on voltage-sensors for excitation-contraction coupling in frog skeletal muscle are intracellular.

Charge movements were measured in frog cut twitch fibres mounted in a double Vaseline gap chamber at 14 degrees C with 30 microM D600 in the external solution. TEST-minus-CONTROL current traces appear normal with a hump current component (I gamma) embedded in the decay phase of the early current component (I beta) in the ON-segment and an exponentially decaying current transient in the OFF-segment. When a conditioning depolarization to 0 mV is applied at around 6 degrees C, charge movement is greatly reduced but not completely suppressed and no hump component can be visualized in the ON-segment. In addition, an extra capacitive component is generated having a time course slower than, and a polarity opposite to, that of the usual charge movement. This extra component makes the transients in both the ON- and OFF-segments appear bisphasic. When temperature is restored to 14 degrees C, the biphasic nature is greatly enhanced. After the application of a conditioning hyperpolarization, the shape of the TEST-minus-CONTROL current trace is converted back to that before paralysis, but the total amount of charge reprimed is less than 100% of control. In general, more Q beta is reprimed than Q gamma, and the amount of Q gamma reprimed varies over a wider range from fibre to fibre than that of Q beta. Extracellularly applied D890 cannot reproduce the blocking effect of D600 whereas intracellularly applied D890 can. As D890 is permanently charged and cannot permeate through the plasma membranes, it can be concluded that the binding sites for D600/D890 on the charge movement macromolecules must be on the myoplasmic side. This adds another parallelism between the charge movement entities and L-type calcium channels. However, the specific prerequisites for the blockage of the former not shared by the latter differentiates the two physiological units.

Synthesis and identification of the N-glucuronides of norgallopamil and norverapamil, unusual metabolites of gallopamil and verapamil.

N-Glucuronides of norgallopamil and norverapamil were found as biliary metabolites after administering the corresponding tertiary amines, gallopamil and verapamil, to rats. The structures of these unusual metabolites were established by comparison with spectral data of synthesized authentic standards and by enzymic hydrolysis of the conjugates. The N-glucuronide standards were synthesized by coupling the secondary amines to either glucuronic acid or to methyl tetra-O-acetyl-beta-D-glucopyranuronate. On i.p. dosing of rats with gallopamil or verapamil, 13 and 2% of the dose, respectively, appeared in the bile as the N-glucuronide of the secondary amine metabolite over an 8-hr period. Administration of norgallopamil resulted in approximately 25% of the dose being excreted as N-glucuronide conjugate in the bile. Substantially more of the S- than R-enantiomer of both gallopamil and verapamil was converted to the corresponding secondary amine N-glucuronide. The observed high S/R ratios suggest enantio-selectivity in this pathway could contribute to the observed stereoselectivity in other routes of metabolism of the parent tertiary amines.

D 600 block of L-type Ca2+ channel in vascular smooth muscle cells: comparison with permanently charged derivative, D 890.

It has been reported that D 600 blocks the high-threshold Ca2+ channel (L-type) from the outside in isolated vascular and ileal smooth muscle cells of the rabbit (Y. Ohya, K. Terada, K. Kitamura, and H. Kuriyama. Pfluegers Arch. 408: 80-82, 1987). We have reinvestigated this hypothesis by comparing the effects of external and internal applications of D 600 and the permanently charged quaternary derivative D 890 on the whole cell Ca2+ current (Ica) recorded in vascular smooth muscle cells isolated from the rabbit portal vein. At low frequencies of stimulation (0.05 Hz), externally applied D 600 inhibited Ica in a dose-dependent fashion, with a complete block occurring at 10(-4) M. D 600 was approximately 1,000 times more potent than D 890 for causing inhibition of Ica using this protocol. During a train of stimulations at 0.5 Hz, D 600 (10(-6) M) produced a minor additional frequency-dependent block of Ica, as shown in other preparations. During superfusion with D 890 (10(-4) M), a similar protocol produced little if any decline in the amplitude of Ica. No evidence of block could be detected during intracellular dialysis of D 600 (10(-4) M). At the same concentration, intracellular application of D 890 produced a slow block of Ica. To test whether D 600 could be effectively dialysed using a patch micropipette, similar experiments were performed in cardiac ventricular myocytes. In this preparation, intracellular dialysis of D 600 induced a rapid inhibition of the Ica.(ABSTRACT TRUNCATED AT 250 WORDS)

Block of contracture in skinned frog skeletal muscle fibers by calcium antagonists.

The ability of a number of calcium antagonistic drugs including nitrendipine, D600, and D890 to block contractures in single skinned (sarcolemma removed) muscle fibers of the frog Rana pipiens has been characterized. Contractures were initiated by ionic substitution, which is thought to depolarize resealed transverse tubules in this preparation. Depolarization of the transverse tubules is the physiological trigger for the release of calcium ion from the sarcoplasmic reticulum and thus of contractile protein activation. Since the transverse tubular membrane potential cannot be measured in this preparation, tension development is used as a measure of activation. Once stimulated, fibers become inactivated and do not respond to a second stimulus unless allowed to recover or reprime (Fill and Best, 1988). Fibers exposed to calcium antagonists while fully inactivated do not recover from inactivation (became blocked or paralyzed). The extent of drug-induced block was quantified by comparing the height of individual contractures. Reprimed fibers were significantly less sensitive to block by both nitrendipine (10 degrees C) and D600 (10 and 22 degrees C) than were inactivated fibers. Addition of D600 to fibers recovering from inactivation stopped further recovery, confirming preferential interaction of the drug with the inactivated state. A concerted model that assumed coupled transitions of independent drug-binding sites from the reprimed to the inactivated state adequately described the data obtained from reprimed fibers. Photoreversal of drug action left fibers inactivated even though the drug was initially added to fibers in the reprimed state. This result is consistent with the prediction from the model. The estimated KI for D600 (at 10 degrees and 22 degrees C) and for D890 (at 10 degrees C) was approximately 10 microM. The estimated KI for nitrendipine paralysis of inactivated fibers at 10 degrees C was 16 nM. The sensitivity of reprimed fibers to paralysis by D600 and D890 was similar. However, inactivated fibers were significantly less sensitive to the membrane-impermeant derivative (D890) than to the permeant species (D600), which suggests a change in the drug-binding site or its environment during the inactivation process. The enantomeric dihydropyridines (+) and (-) 202-791, reported to be calcium channel agonists and antagonists, respectively, both caused paralysis, which suggests that blockade of a transverse tubular membrane calcium flux is not the mechanism responsible for antagonist-induced paralysis. The data support a model of excitation-contraction coupling involving transverse tubular proteins that bind calcium antagonists.

Gas chromatographic determination of gallopamil and norgallopamil in human plasma.

A highly sensitive gas chromatographic assay is described for the simultaneous determination of gallopamil, a calcium channel blocking agent, and its major metabolite, norgallopamil. A multi-step extraction procedure is employed followed by on-column capillary gas chromatographic analysis using nitrogen-selective detection. Acetylation of norgallopamil is performed to enable accurate quantification of the metabolite. Linearity was achieved over the range 1-50 ng/ml for both analytes. Assay specificity, precision and accuracy were investigated.

Effect of D890 on membrane properties of neocortical neurons.

D890, a derivative of the Ca2+ channel antagonist D600, was intracellularly applied from conventional microelectrodes into pyramidal neurons of neocortical slices. The effects of D890 were ascertained by evaluating alterations in membrane properties following drug administration and by comparing these neurons to untreated controls. The amplitude of action potentials (APs) evoked by depolarizing current pulses was attenuated by up to 30% within about 15 min after impalement with D890-containing electrodes. AP rate of rise was reduced by up to 80% and duration was increased. These effects were dependent upon the rate of stimulation. When depolarizing pulses were delivered at low rates of stimulation (e.g. 0.1 Hz), the overshoot of evoked APs declined by about 10%. At higher frequencies (greater than 2 Hz) the AP overshoot decreased by up to 90%. These effects were mostly reversible on decreasing the frequency of stimulation. A half maximal effect was attained at about 1 Hz, when APs of control neurons were unaltered. In neurons impaled with D890-containing electrodes, depolarizing current pulses delivered in the presence of tetraethylammonium (TEA) and tetrodotoxin elicited high threshold calcium spikes which had a duration between 20 and 200 ms. In the early phase of D890 application, the duration of Ca2+ spikes decreased in a reversible frequency-dependent manner; after prolonged application, however, the recovery was incomplete. On the average, Ca2+ spike amplitude and duration decreased by 20% and 50%, respectively, suggesting that D890 usually produces an incomplete blockade of the underlying CA current. The duration of the slow envelope of orthodromically evoked epileptiform paroxysmal depolarizing shifts (DSs), induced by bath application of 10(-5) M bicuculline, was frequency dependent and consistently increased from about 20 ms to 150 ms (half amplitude width) at frequencies above 0.5 Hz. In the presence of D890, the action potentials superimposed on the slow envelope of the DS were attenuated, but neither the amplitude nor the frequency-dependent progressive prolongation of the DS was altered. Application of TEA in the presence of bicuculline (10(-5) M) increased the amplitude and duration of the DS in neurons impaled with D890-containing electrodes. Under these conditions, the durations of DSs evoked by low frequency orthodromic stimulation (greater than 0.5 Hz) were still progressively prolonged, while, in the same neuron, directly evoked Ca2+ spikes progressively decreased in amplitude and duration.(ABSTRACT TRUNCATED AT 400 WORDS)

High-performance liquid chromatographic (HPLC) assay using fluorescence detection for the simultaneous determination of gallopamil and norgallopamil in human plasma.

Gallopamil is a calcium-channel antagonist with reported activity in experimental animals three to five times higher than that of verapamil. An automated high-performance liquid chromatographic (HPLC) method with fluorescence detection is described for the simultaneous determination of gallopamil and its metabolite norgallopamil in plasma. Gallopamil was well resolved from norgallopamil and other metabolites, allowing simultaneous quantitation of both drugs. The detection limit for both gallopamil and norgallopamil was 0.9 ng/ml. This method has been successfully used for the determination of gallopamil and norgallopamil following the administration of 25-, 37.5-, and 50-mg oral doses of drug.

Suppression of charge movement in frog skeletal muscle by D600.

Charge movements in intact frog twitch fibres were studied using a three-microelectrode voltage-clamp technique. When high potassium solution was applied transiently to the muscle fibres at low temperature in the presence of D600, the fibres became paralysed and, concomitantly, charge movement disappeared. The amount of charge suppressed by the paralysis treatment was about 70-100% of that in control experiments. This paralysing action of D600 is not shared by its derivative D890. The requirement of conditioning potassium contracture is, most likely, related to prolonged membrane depolarization, as voltage-clamped depolarization to 0 mV lasting tens of seconds also suppressed charge movement. When paralysed fibres were warmed, the main charge component (Q beta) was reprimed. By contrast, the hump charge component (Q gamma) was only reprimed in some of the fibres. Other than by warming, as paralysed fibre could be revived by stimulating it with large suprathreshold pulses but not by voltage-clamped hyperpolarization to -160 mV for tens of seconds. The paralysing action of D600 described here appears to be unrelated to its ability in blocking Ca2+ channels.

Effects of the calcium antagonist gallopamil (D600) upon excitation-contraction coupling in toe muscle fibres of the frog.

1. The effects of the Ca2+ antagonist gallopamil (D600) upon force development in short skeletal muscle fibres (m. lumbricalis digiti IV) of the frog were investigated under voltage-clamp control, using two flexible internal micro-electrodes (temperature = 6-7 degrees C). 2. In the presence of 5-100 microM-gallopamil muscle fibres developed one normal phasic contracture when they were depolarized from a holding potential of -90 to 0 mV. Subsequent depolarizations caused no mechanical response (paralysis). However, the ability to contract could be restored by hyperpolarizing the membrane to potentials between -120 and -150 mV. 3. In the absence of gallopamil, mechanical refractoriness could be fully reversed within 5-7 s by repolarizing the fibre from 0 to -120 mV. In the presence of 100 microM-gallopamil, no detectable restoration occurred within the first minute at -120 mV, and 45 to 100% of maximum force was eventually reached after 6 min of restoration. 4. The potential V at which the 'steady state' 50% of maximum force of a refractory fibre was restored shifted from -51 mV under normal conditions to -83 and -90 mV in the presence of 5 and 100 microM-gallopamil, respectively. 5. Paralysis in the presence of gallopamil and recovery from paralysis during hyperpolarization could also be observed when 2 mM-Cd2+ was applied to the external solution, i.e. when most Ca2+ channels in the T-tubular system were blocked. 6. Gallopamil shifted the threshold for activation of force to more negative potentials. Fibres developed force when they were depolarized to membrane potentials between -60 and -80 mV, whereby a fast phase of activation was followed by a slower one. Upon repolarization relaxation likewise occurred in a fast and a slow phase. 7. High concentrations of gallopamil (greater than 500 microM) caused a slowly developing contracture, independent of membrane potential (-90 or 0 mV). 8. It is proposed that gallopamil binds to a receptor at the force-controlling system in the T-tubular membrane (potential sensor) with a high affinity in the depolarized state and a lower affinity at negative potentials. Therefore association of gallopamil mainly leads to stabilization of the inactive state (paralysis) but can also stabilize the active state.

Motor cortical epileptic foci in vivo: actions of a calcium channel blocker on paroxysmal neuronal depolarizations.

Focal epileptiform activity was induced by local application of penicillin to the surface of the rat motor cortex. Neurons located within the epileptic focus displayed typical paroxysmal depolarization shifts (PDS). The participation of membrane calcium currents in the generation of PDS was examined by injecting the quaternized calcium entry blocker D890 into single neurons by iontophoresis or by pressure pulses. After intracellular injections of D890, PDS were depressed in amplitude by up to 55%. In a few cases the depression of PDS following intracellular application of D890 was preceded by a transient increase. Similar increases of PDS amplitude were obtained by injections of the calcium chelator EGTA. Control experiments in preparations without epileptic activity revealed that excitatory potentials elicited by thalamic stimulation and Cl(-)-dependent inhibitory postsynaptic potentials evoked by epicortical stimulation were not affected by intracellular D890. In these experiments successful intracellular drug application was verified by monitoring the transient shift of the Cl(-)-equilibrium potential induced by injection of KCl together with D890. It is concluded that in the penicillin-induced epileptic focus of the motor cortex Ca2+ inward currents participate in the generation of neuronal PDS.

Participation of intracellular sites in the action of Ca2+ channel blockers.

The action of phenylalkylamine Ca2+ channel blockers D890 and D888 on Ca2+ uptake and neurotransmitter amino acid release were studied. D890, the quaternary derivative of D600, did not inhibit veratrine-induced 45Ca2+ uptake or the release of neurotransmitter amino acids from rat cerebrocortical synaptosomes, except at high concentrations (200 microM) when it was probably acting extracellularly in a non-specific manner. This contrasted with the more potent (10-50 microM) inhibitory actions of D600 and D888, and may be due to the inability of D890 to cross the synaptic plasma membrane. (-)D888 was shown to cross cell membranes and accumulate in the intracellular compartment of cerebrocortical slices and synaptosomes, where it was associated predominantly with the soluble cytoplasmic fraction.

Anticonvulsant effects of calcium channel blockers in partial and generalized model epilepsies.

The calcium channel blockers D890 and verapamil reduced neuronal calcium currents in single snail neurons with intra- and extracellular applications, respectively. Epileptic discharges of single neurons in the rat's motor cortex (in vivo) were depressed in amplitude by intracellular injection of D890. Focal seizure discharges and generalized tonic-clonic seizure activity in the cerebral cortex of the rat were reduced by intracerebroventricular perfusion of verapamil. In non-epileptic rats verapamil failed to exert a depressive effect on somatosensory evoked potentials and on the waves of the spontaneous EEG.