Lateral geniculate multiple-unit activity related to metrazol potentiated after-discharges

The effects of bilateral and unilateral frontal lesions on visual cortical hypersynchronous bursting and behavioral activity

Photically evoked after-discharge (PhAD) bursting was examined in albino rats following either bilateral or unilateral dorsal frontal lesions. The initial effect of either type of frontal lesion was to significantly suppress PhAD occurrence. However, after repeated exposure to the PhAD recording environment no difference could be seen between the lesioned and control animals. In addition, no difference in PhAD could be detected between the two visual cortices in any of the groups. Spontaneous alternation and open-field activity were also tested. Both frontally lesioned groups of animals were significantly more active than control animals in the initial stages of testing. These findings indicate that the frontal cortex can inhibit brain stem mechanisms which are responsible for behavioral arousal and the modulation of hypersynchronous bursting in the cortex. However, because no difference was seen between the two visual cortices in any of the groups, it is suggested that this mechanism is not a strictly unilateral mechanism.

Benzodiazepine antagonists abolish electrophysiological effects of sodium valproate in the rat

A hypothesis was considered that anti-epileptic potency of sodium valproate (VPA) may be associated with its action via the benzodiazepine system. The ability of anti-petit mal drugs to suppress the slow secondary negative wave (SNW) of the visually evoked potential was used as a sensitive electrophysiological "tag" for comparison of VPA (200 mg/kg, i.p.) and Diazepam (5 mg/kg, i.p.) effects. Both drugs induced a profound inhibition of the SNW. Benzodiazepine antagonists Ro 5-3663 (2 mg/kg, i.p.) and Ro 15-1788 (5 mg/kg, i.p.) caused recovery of the SNW amplitude within several minutes of injection. Both antagonists abolished immobility and sedation produced by VPA and Diazepam. The possibility should be considered that therapeutic effects of VPA are mediated through the benzodiazepine receptor coupled to GABA.

Pharmacologic analysis of sodium valproate-induced suppression of secondary components of visual evoked potentials in albino rats

Sodium Valproate (VPA) administered to rats in a dose of 10 or 200 mg/kg IP suppressed the slow negative wave (SNW) and photically-induced afterdischarge (SAD) of VEP (when they were present) within 15-30 min. The recovery of VEP amplitude began at 3 hr. This effect was antagonized by subconvulsive doses of convulsant benzodiazepine RO 5-3663 (2 mg/kg) and metrazol (15 mg/kg) but not by picrotoxin (2 mg/kg) and naloxone (10 mg/kg). The SNW suppression may be attributed to a disinhibitory action of a system located presynaptically on recurrent collaterals of the output neurons, or nerve terminals of inhibitory interneurons or both. Alternative conjecture suggests that VPA depolarizes the dendritic tree masking thereby somatic inhibition produced by recurrent circuits.

Effects of bemegride on the sensory responses of neurons in the hippocampus and brain stem reticular formation

Administration of subconvulsant doses of bemegride results in extensive enhancement of sensory responsiveness to auditory, visual, somatosensory and vibrissa stimulation of neurons in the medullary and mesencephalic reticular formation (RF). This effect is not altered by cord transection. Most neurons in the dorsal hippocampus do not show enhanced sensory responsiveness. In the minority of hippocampal neurons which do show enhancement the effect is much less extensive than that seen in the RF despite larger doses of bemegride. The enhancement of RF neuronal response may involve the reversal of repetition induced response attenuation ('habituation') and reductions in response threshold. During EEG seizures the firing of neurons in RF and hippocampus are temporally correlated with the spikes in the cortical EEG. The effects of bemegride on RF neurons are similar to those previously reported for strychnine and pentylenetetrazol and preliminary studies with physostigmine and bicuculline. These findings further extend the concept that a relatively selective enhancement of the sensory responses of brain stem reticular formation neurons may be indicative of a general neuronal effect of convulsants which may play an important role in the initiation of sensory-induced seizures.

Thalamocortical coupling and component properties of visually evoked afterdischarge

Dorsal lateral geniculate nucleus (dLGN) multiple-unit activity (MUA) and single visual evoked responses (VER) followed by afterdischarge (AD) were examined in lightly restrained albino rats. It was found that VER AD spike components are initially quite prominent, exceeding at times the amplitude of the broad surface negative wave components. As VER AD progresses toward termination spike amplitude systematically declines. Wave amplitude, however, remains relatively stable until spike components disappear. Averaged dLGN MUA and VER AD responses to photic stimuli suggest the existence of a precise time-locked relationship between peak dLGN MUA and VER AD spike components. It is proposed that thalamic and cortical mechanisms sustaining VER AD bursting might be operative during sensory information ;processing, serving to sustain neural activity functionally related to stimulus input.

Comparative effects of pentylenetetrazol on the sensory responsiveness of lateral geniculate and reticular formation neurons

The responses of bulbar and mesencephalic reticular formation (MRF) neurons to visual, auditory and/or somatosensory stimuli were considerably enhanced after subconvulsant doses of pentylenetetrazol (PTZ) in a similar fashion suggesting a general action of PTZ on reticular formation (RF) neurons. PTZ enhanced MRF responses evoked by electrical stimuli in the lateral geniculate nucleus (LGN) or cochlear nucleus but only modestly enhanced LGN neuronal responses. These findings indicate that the effects of this convulsant on the first brain sensory 'relay' nuclei and primary sensory receptors do not appear to be sufficient to account for the extensive PTZ-induced enhancement of RF neuronal responses, and direct effects of PTZ on the reticular formation may play a major role in this enhancement.

Photically evoked potentials and afterpotentials recorded from the visual cortex of the unanesthetized hedgehog

Evoked potentials to visual stimuli (VEP) were recorded from the visual cortex of the unanesthetized hedgehog (Erinaceus europaeus), a primitive placental mammal with relatively little differentiation of cortex and thalamus. The VEPs consisted of several distinct positive and negative voltage deflections. Reproducibility of the response was high, as indicated from the small intrasession and intersession response variability. Rhythmic afterpotentials (AP), previously reported for higher mammals, were readily elicited. They had a lower frequency (3/sec) than APs observed in other mammals. The use of the hedgehog in electrophysiological and psychophysiological research is suggested because data obtained from this primitive placental mammal may shed light on CNS functions of higher mammals, as well as mammalian forms 'lower' on the evolutionary scale.

Visual cortical hypersynchronous bursting as an index of shifts in behavioral state

Photically evoked after-discharge (PhAD) bursting was examined in lightly restrained albino rats during habituation of a leg flexion response. The initial effect of iterative footshock (200 trials, 0.17 mA, 2.5 msec duration, separated by 1.0 sec) was to block PhAD bursting. As response habituation developed PhAD reappeared at reduced levels, subsequently returning to control levels as habituation progressed and became complete. The number of spindles per PhAD burst was suppressed for a brief period which coincided with response sensitization. These results are interpreted as demonstrating that phasic shifts in behavioral state are reflected by PhAD parameters. In addition, the possible relationship between cortical information processing and PhAD bursting is discussed with reference to putative neural mechanisms involved.

Differential effects of convulsants on visually evoked responses in the albino rat

Visually evoked responses (VERs) were recorded from primary visual cortex in unanesthetized albino rats during pharmacological modulation by one of the following convulsant agents: Physostigmine, picrotoxin, strychnine and Metrazol. The data were analyzed in terms of effects on VER components. The rat VER consists of six distinct waves constituted by three positive peaks (P1--P3) and three negative peaks (N1--N3). Results indicate a differential convulsant action on VER components. The administration of picrotoxin, resulted in a suppression of the peak amplitude of P1--N1 and delayed peak latencies of all components. Strychnine reliably shortened P1, N1 and P2 peak latencies, significantly increased N3 peak latency and only suppressed P3--N3 amplitude. Physostigmine essentially suppressed all component amplitudes but only increased peak latencies for P2 and P3 components. Metrazol, in general, was found to be relatively ineffective in the alteration of any VER component in a systematic manner. The data are discussed in terms of differential modes of convulsant action on the visual system. The results are likewise discussed with respect to their implications for convulsant modulation of photically evoked after-discharges.

Effects of dipropylacetic acid on late components of the photically evoked potential and afterdischarge in rat

The effects of dipropylacetic acid (DPA) on primary, secondary and afterdischarge waves of the photically evoked potential were examined. It was observed that DPA selectively attenuated late wave components and afterdischarge. A thalamic locus of action for these effects is postulated.

Comparison of effects of bicuculline, strychnine, and picrotoxin with those of pentylenetetrazol on photically evoked afterdischarges

The effects of bicuculline, strychnine, and picrotoxin on photically evoked afterdischarges (PhADs) in rat visual cortex were compared with those of pentylenetetrazol (a known PhAD potentiator) and a diazepam (a known PhAD suppressor) challenge. Bicuculline was found to augment PhADs in a manner similar to that found with pentylenetetrazol, with the exception that potentiation only occurred at convulsive levels whereas pentylenetetrazol augmentation occurred at both subconvulsive and convulsive levels. Diazepam suppressed bicuculline-potentiated PhADs. Picrotoxin was found to have some limited augmenting effect on PhAD activity but in a manner unlike that observed with either bicuculline or pentylenetetrazol. Strychnine had no systematic augmenting effect on PhADs. These results were discussed in terms of the possible role of GABA in thalamic systems responsible for PhAD production.

Influence of delta9-tetrahydrocannabinol and cannabidiol on photically evoked after-discharge potentials

Two cannabinoids, delta9-tetrahydrocannabinol and cannabidiol, and several reference drugs were compared relative to their effects in a recently developed anticonvulsant test system, the after-discharge potentials of the visually evoked response; the potentials were recorded electrophysiologically from electrodes permanently mounted over the visual cortices of conscious rats. In anticonvulsant doses, trimethadione and ethosuximide produced an extensive depression of after-discharge activity, whereas diphenylhydantoin and cannabidiol exerted no such effect. In contrast, anticonvulsant doses of delta9-tetrahydrocannabinol and subconvulsant doses of pentylenetetrazol markedly increased after-discharge activity, which may represent a manifestation of their central nervous system excitatory properties. The data from the present study support our previously published ovservations from several other anticonvulsant tests that indicate the anticonvulsant characteristics of cannabidiol resemble those of diphenylhydantoin rather than those of trimethadione and that the central excitatory properties of delta9-tetrahydrocannabinol distinguish it from cannabidiol. The results consistently suggest that the cannabinoids will be effective against grand mal but not absence seizures.

Food-deprivation induced arousal: evidence against "behavioral inhibition" in electrocortical hypersynchrony

Hypersynchronous activity was recorded from the visual cortex of the rat in the form of photically evoked after-discharges following 0, 24, 48, and 72 hr. of food deprivation. After-discharge activity was affected at only the 48-hr. level of deprivation and only in terms of a decrease in the frequency of occurrence. All other measures—after-discharge burst duration, after-discharge spindle amplitudes, and spindle waves per after-discharge burst—were unaffected by conditions of food deprivation. These results are discussed in terms of evidence against the uniform role of behavioral inhibition in hypersynchronous brain activity.

The photically evoked afterdischarge: a model for the study of drugs useful in the treatment of petit mal epilepsy

Lightly restrained albino rats were administered dipropylacetic acid, trimethadione, diphenylhydantoin, saline, and a pentylenetetrazol challenge. The results were attributed to the locus of action of the anticonvulsants and strongly support the usefulness of the photically evoked after discharge as a model for the evaluation of thalamically active drugs, with particular reference to those useful in the control of petit mal epilepsy.

Metrazol potentiated after-discharges: dose-response relationships and effects of selective lesions

In Experiment 1 the dose-response effects of pentylentetrazol (Metrazol) on photically evoked after-discharge (PhAD) parameters were examined. Metrazol potentiated PhAD activity by affecting all measured parameters - PhAD frequency, amplitude, burst duration and spindle composition - in particular PhAD burt duration and spindle composition. A mimimum effective dose of 10 mg/Kg of Metrazol was required for some statistically reliable potentiation. Metrazol dosage levels of 20 and 25 mg/Kg induced lengthy bouts of EEG spindling and spiking as well as near maximized PhAD component augmentation. In Experiment 2 stereotaxically oriented knife-cuts isolated the thalamus from cortical and/or midbrain and brainstem input. Such lesions did not block the capacity of Metrazol to potentiate PhADs, although the lesions altered evoked activity. These findings are discussed in terms of the current thought of Metrazol action and thalamic mechanisms in the control of after-discharge activity.

Diazepam modification of evoked and spontaneous lateral geniculate activity

The effects of diazepam on evoked and spontaneous activity of dorsal lateral geniculate nucleus (dLGN) principal (P) and inhibtory (I) cells were examined in rats. In the majority of P cells tested both spontaneous and evoked activity were suppressed following diazepam treatment with these effects being altered little by a pentylenetetrazol (Metrazol) challenge. In two P cells, which were offresponding to photic pulse stimulation, evoked and spontaneous activity was enhanced by diazepam but again these effects were altered little by the Metrazol challenge. I cell spontaneous activity was suppressed by diazepam and augmented by the Metrazol challenge; however, post-stimulus activity was relatively unaffected by either treatment. These results were discussed in terms of support for a functional re-evaluation of the rat dLGN.

Principal cells in lateral geniculate: effects of metrazol on capacity to after-discharge

The effect of metrazol on the capacity of dorsal lateral geniculate nucleus (dLGN) principal (P) cells to repetitively burst (after-discharge) following visual system stimulation was examined in P cells which differed in terms of response patterns to visual stimulation (latency of initial spike, extent of repetitive bursting, and on- or off-type responding cells). Twenty-seven P cells were examined in as many subjects. Metrazol augmented repetitive bursting irrespective of the type of P cell as long as repetitive bursting was present in the pre-metrazol period. P cells that displayed only a single initial burst to photic stimulation did not exhibit after-discharge bursting during the metrazol challenge. In all but one cell metrazol enhanced baseline firing rate. These results are discussed in terms of the putative nature of inhibition in the rat dLGN.

Pharmacological suppression of photically evoked after-discharges in rats: incremental dose, hippocampal EEG and behavioral activity correlates

In subjects lightly restrained (Experiment I) pharmacological arousal via pilocarpine, physostigmine, or amphetamine administration, as compared to saline and methyl atropine treated controls, suppressed photically evoked after-discharge (PhAD) activity in visual cortex, while concomitantly inducing rhythmical slow-wave activity (RSA) in dorsal hippocampus. Incremental doses of amphetamine and pilocarpine correspondingly suppressed PhAD parameters in a dose-response fashion. While physostigmine treatment resulted in significant PhAD suppression, this effect could not be quantified in a dose-response manner. Incrementally increased cholinergic blockade via atropine administration also suppressed PhAD bursting yet simultaneously induced large amplitude irregular slow-wave activity (LIA) in dorsal hippocampus. When tested under identical conditions but in an unrestrained environment (Experiment II) PhADs were similarly suppressed with the concomitant induction of hippocampal patterns as specified in Experiment I; however, general ambulatory activity (grid-crossing) was differentially affected by the drugs. Amphetamine and atropine markedly enhanced while pilocarpine and physostigmine suppressed such activity. In both experiments, previously established PhAD-movement, PhAD-RSA-LIA, and RSA-LIA-movement relationships, occurring as hypothesized in amphetamine, methyl atropine, and saline treated animals, did not remain fully intact during cholinergic alteration.