Neuronal responses to putative neurotransmitters during penicillin epileptogenesis

Detailed spectral profile analysis of penicillin-induced epileptiform activity in anesthetized rats

Penicillin model is a widely used experimental model for epilepsy research. In the present study we aimed to portray a detailed spectral analysis of penicillin-induced epileptiform activity in comparison with basal brain activity in anesthetized Wistar rats. Male Wistar rats were anesthetized with i.p. urethane and connected to an electrocorticogram setup. After a short period of basal activity recording, epileptic focus was induced by injecting 400IU/2 microl penicillin-G potassium into the left lateral ventricle while the cortical activity was continuously recorded. Basal activity, latent period and the penicillin-induced epileptiform activity periods were then analyzed using both conventional methods and spectral analysis. Spectral analyses were conducted by dividing the whole spectrum into different frequency bands including delta, theta (slow and fast), alpha-sigma, beta (1 and 2) and gamma (1 and 2) bands. Our results show that the most affected frequency bands were delta, theta, beta-2 and gamma-2 bands during the epileptiform activity and there were marked differences in terms of spectral densities between three investigated episodes (basal activity, latent period and epileptiform activity). Our results may help to analyze novel data obtained using similar experimental models and the simple analysis method described here can be used in similar studies to investigate the basic neuronal mechanism of this or other types of experimental epilepsies.

Effects of second generation tetracyclines on penicillin-epilepsy-induced hippocampal neuronal loss and motor incoordination in rats

Epileptic seizures cause pathological changes such as sclerosis and pyramidal neuronal loss in the hippocampus. Experimentally, epilepsy can be induced by application of various chemicals directly to the cerebral cortex. In this study, epilepsy was induced in rats by intracortical application of 500 IU penicillin G, and the effect of minocycline and doxycycline on the resulting motor incoordination (rotarod) and hippocampal neuronal loss in CA1, CA2 and CA3 fields (optical fractionator method) were investigated. The rotarod performance was reduced in the epilepsy group to 285.1+/-6.9 s (P<0.05 vs. sham-300 s). Minocycline and doxycycline increased this performance to 297.4+/-1.0 s and 296.9+/-1.2 s respectively. No significant difference was detected between minocycline and doxycycline. The present results also showed that the number of neurons (x10(3)) in the sham group was 150+/-9. In the penicillin-epileptic rats, the number was decreased to 105+/-7 (P<0.01). Minocycline, but not doxycycline (125+/-8), significantly increased the number to 131+/-3 (P<0.05). In conclusion, the second generation tetracycline minocycline decreased the loss of hippocampal neurons and motor incoordination in penicillin-epileptic rats. Minocycline could protect against a variety of neurological insults including epilepsy.

Relation between responsiveness to neurotransmitters and complexity of epileptiform activity in rat hippocampal CA1 neurons

PURPOSE

Our previous works suggested that sensitivity of neurons with chaotic firing patterns to stimuli is significantly greater than that in neurons with periodic firing patterns, which shows that responsiveness of neurons may depend on the complexity of the firing series. This study was performed to determine the relation between responsiveness of the hippocampal CA1 neurons with epileptiform activity (EA) to neurotransmitters and their complexity of firing series.

METHODS

Firing series of CA1 neurons were recorded extracellularly in rat hippocampal slice. Approximate entropy was used to describe the complexity of the interspike interval (ISI) series. EA was induced by local application of penicillin (1,000 IU/ml). The change of firing rate induced by neurotransmitters (glutamate and gamma-aminobutyric acid) was compared with that of the degree of complexity of ISI series in the process of EA.

RESULTS

The excitatory responses to glutamate and the inhibitory responses to gamma-aminobutyric acid in CA1 neurons appeared to be decreased during the process of penicillin-induced EA. However, during this same process, the approximate entropy of the ISI series also was decreased significantly.

CONCLUSIONS

The results suggest that the reduced responses to neurotransmitters of the CA1 neurons appear to be closely related to the onset of EA. Furthermore, these neurons show that the changes in responsiveness are closely parallel to the decrease of degree of complexity of firing series during penicillin epileptogenesis.

Nigral influence on focal epilepsy

The substantia nigra (SN) has been proposed as a structure involved in epileptiform phenomena. Previous investigations demonstrated that SN is able to elicit hippocampal rhythmic slow activity (RSA) as well as to inhibit hippocampal interictal spikes induced by parenteral administration of penicillin. The present series of experiments was carried out in order to characterize the action of SN on a focal model of hippocampal epilepsy. Experiments were performed on encéphale isolé cats in which steady epileptiform activity was induced by locally applied penicillin. Electrical stimulation of SN pars reticulata (pr) caused a statistically significant decrease of hippocampal spike frequency and amplitude in 30% of the total number of stimulation sessions. Stimulation of SN pars compacta (pc) was even more effective. It induced inhibitory effects on hippocampal spikes in 91% of the cases. In 30% of the cats, RSA was noted on hippocampal recordings in correspondence to nigral activation. Experimental data support the hypothesis that the SNpc influences hippocampal excitability: a differential role may be played by SNpc and SNpr in the control of seizure processes.

Intracellular recordings in pericruciate neurons during spike and wave discharges of feline generalized penicillin epilepsy

Concurrent EEG and intracellular recordings from pericruciate neurons of cats obtained before and after i.m. injection of penicillin inducing the syndrome of feline generalized penicillin epilepsy (FGPE) characterized by spike and wave (SW) discharge in the EEG, display large excitatory postsynaptic potentials (EPSPs) at the time of the EEG 'spike' which alternate with hyperpolarizing potentials occurring in coincidence with the EEG 'wave' component of the SW complex. The large EPSPs trigger discharges of single or multiple high-frequency action potentials which do not show a progressive decrement in amplitude nor an appreciable increase in duration. These bursts thus differ in some respects from typical paroxysmal depolarization shifts. The hyperpolarizing potentials show an early phase which is reversed by intracellular Cl- injection or diffusion and thus behaves like a classical inhibitory postsynaptic potential (IPSP). The late phase is unaffected by Cl-. Hyperpolarizing potentials of pericruciate neurons induced by antidromic activation of the cerebral peduncle (CP) or by direct cortical stimulation are not altered after i.m. injections of penicillin at doses sufficient to induce generalized SW discharge. The early phase of hyperpolarization both before and after i.m. penicillin is reversed by intracellular Cl- injection or diffusion, the late phase remains unchanged. The early phase thus represents a classical IPSP, which does not appear to be affected by the low brain penicillin concentrations sufficient to induce generalized SW discharge. It is concluded that this form of epileptic discharge cannot be attributed to blockage of phasic (presumably somatic) postsynaptic inhibition by penicillin. These results indicate that to regard all forms of epileptic discharge as the consequence of a blockage of gamma-aminobutyric acid-mediated phasic postsynaptic inhibition acting on the soma represents an unduly restrictive view of epileptogenesis.

The epileptogenic action of 6-aminomethyl-3-methyl,1-4H-1,2,6-benzothiadiazine-1,1-diazide hydrochloride (TAG): non-specific versus specific antitaurine pathogenesis

Cortical superfusion with 6-aminomethyl-3-methyl, 1-4H-1,2,6-benzothiadiazine-1,1-diazide hydrocholoride (TAG) at a concentration which selectively blocks taurine (Tau) action fails to modify electroencephalographic (EEG) activity, cortical neuronal firing and caudate-induced inhibition of cortical neuronal activity. Higher concentrations of TAG increase neuronal firing rate and eventually induce EEG interictal spikes that can be suppressed by topical gamma-aminobutyric acid (GABA), but not by glycine or beta-alanine. Topical Tau consistently enhances the epileptiform activity. It is concluded that specific blockade of Tau does not affect any of the physiological function under observation and that the epileptogenic effect of TAG is due to its GABA antagonistic action.

Penicillin-induced epileptiform activity does not prevent ocular dominance shifts in monocularly deprived kittens

Epileptiform activity was induced in the visual cortex with penicillin to test whether it would prevent the ocular dominance shift that normally occurs in monocularly deprived kittens. The eyelids of one eye of 5-week-old kittens were sutured shut for several days. During this period, whenever the kittens were in the light, aqueous penicillin in artificial cerebrospinal fluid (CSF) or just CSF was applied in a cylinder mounted over the visual cortex. Electroencephalograms monitored during the period of deprivation indicated nearly continuous interictal spiking in the visual cortex. Extracellular recordings were made of cells in the region directly under the position of the cylinder. 14C-labeled 2-deoxyglucose autoradiography in a control kitten showed that this area had considerably increased metabolism during epileptiform activity. The majority of cortical cells were dominated by the non-deprived eye in both epileptic and control kittens, with no noticeable difference between them. These preliminary observations indicate that the disruption of cortical activity that occurs during interictal epileptiform activity does not prevent the ocular dominance shift in monocularly deprived kittens.

Neuronal sensitivity to GABA and glutamate in generalized epilepsy with spike and wave discharges

In awake but painlessly immobilized cats the extracellular activity of the same cortical neurons was recorded before and for 2 to 5 h after the injection of penicillin G (350,000 IU/kg, i.m.) during the development of generalized epilepsy with bilaterally synchronous spike and wave discharges. Possible changes in their sensitivity to microiontophoretically applied glutamate and GABA during this period were searched for using computer-generated periejection histograms at intervals of about 30 min. In contrast to reported studies in other models of epilepsy, glutamate excited and GABA depressed virtually all neurons tested during fully developed spike and wave epilepsy. Spike height was not apparently affected either by the amino acids or by the development of epilepsy. Comparison of relative thresholds for the above effects on rhythmical neuronal activity associated with spike and wave discharge versus effects on random neuronal activity during the interburst periods, supported the idea that spikes and waves result from strong excitatory and inhibitory synaptic drives of the neurons. In all neurons until the appearance of spike and wave discharges, changes in the effect of amino acids, if observed, were small and statistically nonsignificant. This suggests that the hyperexcitability of cortical neurons which reportedly leads to the appearance of spike and wave discharges depends on mechanisms other than an increase in sensitivity to glutamate or a desensitization to GABA. Sometimes the sensitivity to GABA decreased later in this experimental model when the very frequent appearance of spike and wave discharges eventually led to EEG tonic-clonic seizures.

Penicillin induced hyperexcitability in the in vitro hippocampal slice can be unrelated to impairment of somatic inhibition

The effects induced by penicillin (PEN) upon the synaptic responses of CA1 hippocampal pyramidal cells (HPCs) were studied in the 'in vitro' slice. Low concentrations of PEN (0.17-0.34 mM) evoked an increase in amplitude and duration of the orthodromic excitatory post-synaptic potential induced by stratum radiatum, while stimuli which were subthreshold in control conditions became effective in eliciting action potentials. These changes were not paralleled by any decrease of the recurrent inhibitory post-synaptic potential due to inhibitory interneurons located at or near the soma. However, the latter decreased and then disappeared as PEN concentrations were brought to levels higher than 0.68 mM. Since low concentrations of PEN increase CA1 HPCs responsiveness without decreasing somatic inhibition, it is concluded that this action is probably due to a reduced dendritic inhibitory mechanism.

Enhanced response of cortical neurons to thalamic stimuli precedes the appearance of spike and wave discharges in feline generalized penicillin epilepsy

Peristimulus time histograms of extracellularly recorded action potential discharges of cortical neurons in response to single shock and/or repetitive stimulation of 'specific' and 'non-specific' nuclei of the thalamus were studied after i.m. penicillin injection during a period corresponding to that of the development of spike and wave (SW) discharges of feline generalized penicillin epilepsy (FGPE). After i.m. penicillin cortical neurons displayed an enhancement of both the excitatory and 'inhibitory' phases of their responses to single shock stimulation of n. centralis medialis (NCM). This increase was even more pronounced for responses induced by repetitive stimulation of NCM at the frequencies inducing typical recruiting responses. These changes always preceded the appearance of SW discharges. Changes of the responses of cortical neurons to single shock and repetitive stimulation of 'specific' thalamic nuclei after penicillin were weak and inconsistent, although when observed were characterized by an enhancement of both excitatory and 'inhibitory' phases. The latter appeared not to decrease after i.m. penicillin. These data suggest that the appearance of SW discharges of FGPE is closely related to an increased responsiveness of cortical neurons to thalamocortical volleys arising from the so-called 'non-specific' nuclei. This facilitation of the recruiting process is accompanied by an increase of both excitatory and 'inhibitory' phases of the cortical neuronal responses induced by the volleys.

Participation of cortical recurrent inhibition in the genesis of spike and wave discharges in feline generalized penicillin epilepsy

Cortical recurrent inhibition (RI) evoked in pericruciate cortex by antidromic stimulation of the cerebral peduncle (CP) was studied in normal cats and in cats exhibiting the signs of feline generalized penicillin epilepsy (FGPE) following the i.m. injection of penicillin. Two measures of RI evoked by antidromic CP stimulation were used: (i) the averaged focal potential in the pericruciate gyrus; and (ii) the duration of the suppression or diminution of extracellularly recorded action potential (ap) discharge of antidromically activated pericruciate neurons measured in peristimulus time histograms (PSTHs). After i.m. injection of 350,000 IU/kg of penicillin RI remained preserved as long as only generalized spike and wave (SW) discharges appeared in the EEG, although in 5/17 neurons a modest to moderate reduction in the duration of RI occurred once SW discharges had appeared in the EEG. This inconstant reduction was probably not caused by a direct anti-inhibitory action of penicillin, but is a consequence of the increased number of ap discharges curtailing RI. At the small concentrations of penicillin existing in brain in FGPE its anti-inhibitory action evident with larger concentrations cannot be demonstrated. When focal or generalized tonic-clonic (T-C) seizures occurred, RI was reduced in slightly more than half of the instances for a few minutes before the onset of these seizures. This suggests that the transition from SW discharge to T-C seizure may be caused by a breakdown of RI.