Kindling-induced potentiation in the piriform cortex

The Phenomenology of Limbic Kindling

Kindling is a model of epilepsy whereby repeated administration of brief low-intensity trains of electrical stimulation come to elicit electrographic and behavioral manifestations of seizure. In the absence of overt tissue damage, an animal that has been kindled is rendered in a permanent state of increased susceptibility to seizures. A number of persistent biochemical and physiological alterations in function accompany kindling, some of which may impact upon behavior of the organism for a long period of time despite the absence offurther seizure activation. The sensitivity of limbic structures to kindling may contribute to the behavioral categories of cognition and affect that are particularly impacted by the kindling process. The increased proclivity for seizure disorders that characterizes kindling is not restricted to the initial kindling stimulus, but generalizes to other agents with convulsive properties. This paper provides an overview of the phenomenology of kindling, describes some of the conditions necessary for its induction, and some of the functional alterations that accompany its development and endure when overt convulsive behavior has subsided. Finally, a series of studies in our laboratory is presented which provides evidence of chemically induced kindling by repeated low-level exposure to some pesticides, namely those of the chlorinated hydrocarbon class.

Resection of piriform cortex predicts seizure freedom in temporal lobe epilepsy

Objective

Transsylvian selective amygdalo‐hippocampectomy (tsSAHE) represents a generally recognized surgical procedure for drug‐resistant mesial temporal lobe epilepsy (mTLE). Although postoperative seizure freedom can be achieved in about 70% of tsSAHE, there is a considerable amount of patients with persisting postoperative seizures. This might partly be explained by differing extents of resection of various tsSAHE target volumes. In this study we analyzed the resected proportions of hippocampus, amygdala as well as piriform cortex in regard of postoperative seizure outcome.

Methods

Between 2012 and 2017, 82 of 103 patients with mTLE who underwent tsSAHE at the authors’ institution were included in the analysis. Resected proportions of hippocampus, amygdala and temporal piriform cortex as target structures of tsSAHE were volumetrically assessed and stratified according to favorable (International League Against Epilepsy (ILAE) class 1) and unfavorable (ILAE class 2–6) seizure outcome.

Results

Patients with favorable seizure outcome revealed a significantly larger proportion of resected temporal piriform cortex volumes compared to patients with unfavorable seizure outcome (median resected proportional volumes were 51% (IQR 42–61) versus (vs.) 13 (IQR 11–18), P = 0.0001). Resected proportions of hippocampus and amygdala did not significantly differ for these groups (hippocampus: 81% (IQR 73–88) vs. 80% (IQR 74–92) (P = 0.7); amygdala: 100% (IQR 100–100) vs. 100% (IQR 100–100) (P = 0.7)).

Interpretation

These results strongly suggest temporal piriform cortex to constitute a key target resection volume to achieve seizure freedom following tsSAHE.

The role of dopamine D2-like receptors in a "depotentiation-like effect" of deep brain stimulation in kindled rats

The mechanisms involved in the anti-seizure effects of low-frequency stimulation (LFS) have not been completely determined. However, G_i-protein-coupled receptors, including D₂-like receptors, may have a role in mediating these effects. In the present study, the role of D₂-like receptors in LFS' anti-seizure action was investigated. Rats were kindled with semi-rapid (6 stimulations per day), electrical stimulation of the hippocampal CA1 area. In LFS-treated groups, subjects received four trials of LFS at 5 min, 6 h, 24 h, and 30 h following the last kindling stimulation. Each LFS set occurred at 5 min intervals, and consisted of 4 trains. Each train contained 200, 0/1 ms long, monophasic square wave pulses at 1 Hz. Haloperidol (D₂-like receptors antagonist, 2 µm) and/or bromocriptine (D₂-like receptors agonist 2 µg/µlit) were microinjected into the lateral ventricle immediately after the last kindling, before applying LFS. Obtained results showed that applying LFS in fully-kindled subjects led to a depotentiation-like decrease in kindling-induced potentiation and reduced the amplitude and rise slope of excitatory and inhibitory post-synaptic currents in whole-cell recordings from CA1 pyramidal neurons. In addition, LFS restored the kindling-induced, spatial learning and memory impairments in the Barnes maze test. A D₂-like receptor antagonist inhibited these effects of LFS, while a D₂-like receptor agonist mimicked these effects. In conclusion, a depotentiation-like mechanism may be involved in restoring LFS' effects on learning and memory, and synaptic plasticity. These effects depend on D₂-like receptors activity.

The persistence of long-term potentiation in the projection from ventral hippocampus to medial prefrontal cortex in awake rats

A potentially vital pathway in the processing of spatial memory is the pathway from ventral hippocampus to medial prefrontal cortex (vHPC-mPFC). To assess long-term potentiation (LTP) induction and maintenance across days in this pathway, the effects of several induction paradigms were compared in awake, freely moving rats. Two different high-frequency stimulation (HFS) protocols generated LTP lasting no longer than 1 week. However, after delivering HFS on three consecutive days, LTP lasted an average of 20 days, due mainly to the greater initial induction. Thus the pathway does not require extensive multi-day stimulation to induce LTP, as for other intra-neocortical pathways, but also it does not exhibit the extremely long-lasting and stable LTP previously observed in area CA1 and the dentate gyrus. By using bilaterally placed stimulating and recording electrodes, we found that HFS in one vHPC generated responses and LTP in the contralateral mPFC, even when the ipsilateral mPFC was inactivated by CNQX. We attribute this crossed response to a polysynaptic pathway from the vHPC to the contralateral mPFC. Finally, we found that repeated overnight exposure to an enriched environment also potentiated the vHPC-mPFC response, but this too was a transient effect lasting < 9 days, declining to baseline even before the enriched environment treatment was completed. Overall, these findings are consistent with the view that potentiation of vHPC-mPFC pathway may play a key role in promoting the hippocampus-mPFC interplay that, over days, leads to long-term storage in the frontal cortex of memories that are independent of the hippocampus.

Changes in neuromodulatory effect of adenosine A1 receptors on piriform cortex field potentials in amygdala kindled rats

Adenosine exerts its anticonvulsants effect through different brain regions including piriform cortex. In this study, the effect of amygdala kindled seizures on adenosine A1 receptor-mediated neuromodulation in piriform cortex pyramidal neurons was tested at 24 h and 1 month after kindling. Animals were kindled by daily electrical stimulation of amygdala. Field potentials were recorded from layer II of piriform cortex pyramidal cells following stimulation of the lateral olfactory tract. Obtained results showed that N6-cyclohexyladenosine (CHA), a selective adenosine A1 receptor agonist (1, 10 and 100 microM; i.c.v.), reduced A1 slope and B1 amplitude of field potentials in both kindled and non-kindled (control) rats. However, its effects on kindled animals were more potent at 24 h, but not 1 month post-kindling. 8 cyclopenthyl-1,3-dimethylxanthine (CPT), a selective adenosine A1 receptor antagonist (50 microM, i.c.v.), had no significant effect on the field potential parameters. However, CPT (50 microM, i.c.v.) pretreatment eliminated effects of CHA (10 microM; i.c.v.) on the field potentials. These results indicate that activation of adenosine A1 receptors has an inhibitory effect on the field potentials of piriform cortex pyramidal neurons and the efficiency of adenosine A1 receptor neuromodulation in piriform cortex is increased at short-term (24 h) but return to normal at long-term (1 month) after kindling implementation.

Neocortical kindling is associated with opposing alterations in dendritic morphology in neocortical layer V and striatum from neocortical layer III

Previous research has shown that seizures kindled in the corpus callosum result in a persistent enhancement of the callosal-neocortical evoked response but only a transient reduction in layer III pyramidal cell morphology. To date, there are no reports on the direct effects of repeated seizures on dendritic morphology in layer V, the pyramidal layer thought to mediate the kindling-induced enhanced evoked response. This experiment examined the effect of repeated seizures elicited from the corpus callosum, at the level of the frontal neocortex, on the morphology of sensorimotor frontal (Fr1) and occipital (OC1) neocortical layer V, as well as striatal and neuronal dendrites, in male rats. After 25 days of electrically elicited seizures or handling control, rats were sacrificed either 2 days or 3 weeks following the last seizure and processed for Golgi-Cox staining. Analysis of the impregnated pyramidal cell dendrites indicated a significant increase in the amount of dendritic length and branching in rats 2 days, but a decrease 3 weeks, following the last seizure. There was no effect at the distant occipital site. The differential effect between layer V pyramidal neurons and layer III pyramidal neurons suggests that these areas play different roles in the expression of seizures and the adaptation of the brain to the persistent effect of kindling.

Epileptogenic insult causes a shift in the form of long-term potentiation expression

The relationship between epilepsy, modeled here by pentylenetetrazol kindling, and learning deficits, modeled here by long-term potentiation (LTP), was studied. The field excitatory postsynaptic potentials and population spikes (PS) were recorded from strata radiatum and pyramidale, respectively, in urethane-anesthetized rat dorsal hippocampus CA1 area upon stimulation of Schaffer collaterals. To induce LTP, a 100 Hz primed-burst stimulation protocol was used. Experiments were carried out at approximately 30 days after the last pentylenetetrazol dose. The effects of voltage dependent calcium channel blocker verapamil and N-methyl-D-aspartate receptor antagonist MK-801 on LTP expression were examined. Tetanic stimulation elicited both field excitatory postsynaptic potential LTP and PS LTP in control animals, and LTP-induction of the PS in control animals was attenuated by MK-801, but not by verapamil. By contrast, kindled rats showed LTP of the PS only. MK-801 reduced the extent of potentiation of PS amplitude and verapamil inhibited the PS amplitude potentiation, completely. The results suggest that seizure induction modifies mechanisms underlying LTP induction and causes a shift in the form of LTP expression. The pentylenetetrazol-kindling-induced increase in PS LTP is sensitive to verapamil and not to MK-801 and therefore primarily dependent on activation of voltage dependent calcium channels rather N-methyl-D-aspartate receptors. Kindling may lead to a shift in synaptic plasticity thresholds much like the shift that occurs during aging, and such alterations may contribute to deficits in learning and memory.

Kindling and status epilepticus models of epilepsy: rewiring the brain

This review focuses on the remodeling of brain circuitry associated with epilepsy, particularly in excitatory glutamate and inhibitory GABA systems, including alterations in synaptic efficacy, growth of new connections, and loss of existing connections. From recent studies on the kindling and status epilepticus models, which have been used most extensively to investigate temporal lobe epilepsy, it is now clear that the brain reorganizes itself in response to excess neural activation, such as seizure activity. The contributing factors to this reorganization include activation of glutamate receptors, second messengers, immediate early genes, transcription factors, neurotrophic factors, axon guidance molecules, protein synthesis, neurogenesis, and synaptogenesis. Some of the resulting changes may, in turn, contribute to the permanent alterations in seizure susceptibility. There is increasing evidence that neurogenesis and synaptogenesis can appear not only in the mossy fiber pathway in the hippocampus but also in other limbic structures. Neuronal loss, induced by prolonged seizure activity, may also contribute to circuit restructuring, particularly in the status epilepticus model. However, it is unlikely that any one structure, plastic system, neurotrophin, or downstream effector pathway is uniquely critical for epileptogenesis. The sensitivity of neural systems to the modulation of inhibition makes a disinhibition hypothesis compelling for both the triggering stage of the epileptic response and the long-term changes that promote the epileptic state. Loss of selective types of interneurons, alteration of GABA receptor configuration, and/or decrease in dendritic inhibition could contribute to the development of spontaneous seizures.

Olfactory Associative Discrimination: A Model for Studying Modifications of Synaptic Efficacy in Neuronal Networks Supporting Long-term Memory

This review summarizes research that correlates behavioral performance and cellular physiology leading to modifications in the neuronal networks supporting long-term memory in the mammalian brain. Rats were trained in an olfactory associative discrimination task in which natural odors were replaced by mimetic olfactory stimulations. Olfactory learning induced synaptic modifications that affected behavioral performance along the central olfactory pathways. Starting with an early increase in monosynaptic efficacy in the dentate gyrus on the first session, a polysynaptic modification appeared later on in this hippocampal network, when rats began to make associations between cues and rewards. Therefore, only when rats made consistent associations did a long-term potentiation in the synapses of the piriform cortex pyramidal neurons appear. These modifications may correspond to the long-term storage of the meaning of the cue-reward association in a specific cortical area. Based on these cumulative results, a hypothesis is proposed to account for how, when, and where synaptic modifications in neural networks are required to constitute long-term memory.

Facilitation of male-like coital behavior in female rats by kindling

Kindling is a model of epilepsy and brain plasticity. When applied to the medial preoptic area (MPOA) of non-copulating male rats kindling induces masculine sexual behavior. In order to test if kindling could facilitate male-like coital behavior in female rats, sexually naive females were ovariectomized and kindled in the amygdala (AMG) or the MPOA until an intermediate stage (between 1 and 3, MPOA1-3) or until stage 5 (MPOA5 group). Once kindling was established, females were treated with 2.5 mg/Kg of testosterone propionate (TP) for 15 days. Male-like coital behavior was evaluated on days 5, 10 and 15 of treatment. Subjects were then injected with a TP dose of 5 mg/kg for 15 days and tested in the same way as with the lower dose. The number of mounts was significantly increased and the mount latency was significantly reduced in the MPOA1-3 group when tested 5 days after treatment with the low dose of TP. The same facilitation was observed in MPOA1-3 and MPOA5 groups on day 10 of treatment with the low dose of TP. When the animals were under the high dose of TP treatment, the number of intromissions was increased in all experimental groups (including the AMG kindled group) in comparison to sham animals. In a second experiment we evaluated if the facilitation of male-like coital behavior induced by kindling was produced by a modification of the response of the vomeronasal system to sexually relevant cues. Ovariectomized females were stimulated until they reached kindling stage 2, then they were treated with 2.5 mg/kg of TP for 5 days. After animals were exposed for 90 min to clean sawdust or sawdust soiled by estrous females they were perfused. Fos was detected by immunocytochemistry along the vomeronasal pathway. No differences were found in Fos responses between sham and MPOA kindled females. The facilitation of masculine sexual behavior observed in AMG kindled females may be a consequence of the propagation of the AD to other brain regions involved in the expression of masculine sexual behavior. We propose that masculine sexual behavior is facilitated in MPOA kindled female rats by local neural changes produced by this kind of stimulation without modifying the response of the vomeronasal system to sexually relevant cues.

Neural growth, neural damage and neurotrophins in the kindling model of epilepsy

Do seizures change the brain? Studies on the kindling model--a widely used animal model of epilepsy--suggest that they do. Dr. Racine, one of the pioneers in the kindling field, describes the basic phenomena of kindling, and discusses the possible roles of cell growth and cell death in this model.

Cortical layer III pyramidal dendritic morphology normalizes within 3 weeks after kindling and is dissociated from kindling-induced potentiation

This experiment examined the effect of a 3-week rest after electrical kindling on kindling-induced potentiation and the morphology of frontal (Fr1) neocortical layer III pyramidal cell dendrites in both male and female rats. Repeated elicitation of afterdischarge resulted in an increase in the severity of the behavioural seizures and afterdischarge duration. The late component of the transcallosal evoked responses was significantly larger 1 and 21 days following the last kindling session in both male and female rats. Analysis of the Golgi-Cox impregnated pyramidal cell dendrites indicated no significant difference in the amount of apical and basilar dendritic, branching, length, and spine density in both male and female rats, relative to their respective control groups, 21 days following the last kindling session. There was, however, one exception, the male group showed a significant increase in apical spine density. The persistent expression of kindling-induced potentiation appears to be dissociated from the renormalized pyramidal cell dendritic morphology.

Development of long-lasting potentiation effects in the dentate gyrus during pentylenetetrazol kindling

In the present study kindling was induced in rats by repeated intraperitoneal injection of pentylenetetrazol (PTZ) once every 48 h. The resulting seizure stages were registered after each PTZ application. The development of PTZ-induced kindling and the time course of possible potentiation effects in the dentate gyrus were examined. The efficacy of perforant pathway transmission to the granule cells was tested in every second kindling session by measuring the monosynaptic evoked field potentials recorded in the dentate gyrus following single test stimuli of the perforant pathway at different times after PTZ injection in freely moving animals. The data suggest that establishment of a PTZ kindling is associated with the development of long-lasting potentiation of the field potentials. After completion of kindling it was demonstrated that kindled rats also show a diminished learning performance. The relationship between the development of potentiation phenomena in hippocampal substructures and learning impairment is discussed.

Does the kindling model of epilepsy contribute to our understanding of multiple chemical sensitivity?

Multiple chemical sensitivity (MCS) is a phenomenon whereby individuals report an increased sensitivity to low levels of chemicals in the environment. Kindling is a model of synaptic plasticity whereby repeated low-level electrical stimulation to a number of brain sites leads to permanent increases in seizure susceptibility. Stimulation that is initially subthreshold for subclinical seizure provocation comes, over time, to elicit full-blown motor seizures. Kindling can also be induced by chemical stimulation, and repeated exposures to some pesticides have been shown to induce signs of behavioral seizure, facilitate subsequent electrical kindling, and induce subclinical electrographic signs of hyperexcitability in the amygdala. Many of the symptoms of MCS suggest that CNS limbic pathways involved in anxiety are altered in individuals reporting MCS. Limbic structures are among the most susceptible to kindling-induced seizures, and persistent cognitive and emotional sequelae have been associated with temporal lobe epilepsy (TLE) in humans and kindling in animals. Thus, a number of parallels exist between kindling and MCS phenomena, leading to initial speculations that MCS may occur via a kindling-like mechanism. However, kindling requires the activation of electrographic seizure discharge and has thus been primarily examined as a model for TLE. Events leading to the initial evocation of a subclinical electrographic seizure have been much less well studied. It is perhaps these events that may serve as a more appropriate model for the enhanced chemical responsiveness characteristic of MCS. Alternatively, kindling may be useful as a tool to selectively increase sensitivity in subcomponents of the neural fear circuit to address questions relating the role of anxiety in the development and expression of MCS.

The lesional and epileptogenic consequences of lithium-pilocarpine-induced status epilepticus are affected by previous exposure to isolated seizures: effects of amygdala kindling and maximal electroshocks

In temporal lobe epilepsy, the occurrence of seizures seems to correlate with the presence of lesions underlying the establishment of a hyperexcitable circuit. However, in the lithium-pilocarpine model of epilepsy, neuronal damage occurs both in the structures belonging to the circuit of initiation and maintenance of the seizures (forebrain limbic system) as in the propagation areas (cortex and thalamus) and in the circuit of remote control of seizures (substantia nigra pars reticulata). To determine whether or not we could protect the brain from lesions and epileptogenesis induced by status epilepticus and identify cerebral structures involved in the genesis of epilepsy, we studied the effects of the chronic exposure to non-deleterious seizures, either focalized with secondary generalization (amygdala kindling, kindled-pilocarpine rats), or primary generalized (ear-clip electroshocks, electroshock-pilocarpine rats) on neuronal damage and epileptogenesis induced by lithium-pilocarpine status epilepticus. These animals were compared to rats subjected to status epilepticus but not pretreated with seizures (sham-kindled-pilocarpine or sham-electroshock-pilocarpine rats). Compared to sham-pilocarpine rats, neuronal damage was prevented in the limbic system of the kindled-pilocarpine rats, except in the hilus of the dentate gyrus and the entorhinal cortex, while it was enhanced in rats pretreated with electroshocks, mainly in the entorhinal and perirhinal cortices. Most sham-kindled- and sham-electroshock-pilocarpine rats (92-100%) developed recurrent seizures after a silent period of 40-54days. Likewise, all kindled-pilocarpine rats developed spontaneous seizures after the same latency as their sham controls, while only two of 10 electroshock-pilocarpine rats became epileptic after a delay of 106-151days. The present data show that the apparent antiepileptic properties of electroshocks correlate with extensive damage in midbrain cortical regions, which may prevent the propagation of seizures from the hippocampus and inhibit their motor expression. Conversely, the extensive neuroprotection of the limbic system but not the hilus and entorhinal cortex provided by amygdala kindling does not prevent epileptogenesis. Thus, the hilus, the entorhinal and/or perirhinal cortex may be key structure(s) for the establishment of epilepsy.

Kindling causes persistent in vivo changes in firing rates and glutamate sensitivity of central piriform cortex neurons in rats

The present experiments were undertaken to study whether amygdala kindling induces persistent alterations in the functional status of neurons of the central piriform cortex, a subregion of the piriform cortex identified previously as a site involved in the kindling process. Extracellular, single-unit recordings of piriform cortex neurons were made in anesthetized fully kindled rats at an interval of at least five weeks after the last seizure. Electrode implanted but not kindled rats served as sham controls. An additional group of non-implanted rats was used as naive controls. Spontaneously firing piriform cortex neurons were characterized in all groups by smooth, sharp, biphasic (i.e. positive/negative) action potentials with a duration of 0.8-1.8 ms, and were primarily located at the border between piriform cortex layers II and III. In kindled rats, neurons in the central piriform cortex exhibited a significantly higher firing rate compared to controls. Based on median group values, the increase in basal activity in kindled rats averaged about 90%. The responsiveness of piriform cortex neurons to neurotransmitters was tested by microiontophoretic application of glutamate, N-methyl-D-aspartate and GABA. Piriform cortex neurons of kindled rats exhibited a significantly lower responsiveness to the excitatory effect of glutamate than naive controls. A lowered glutamate responsiveness was also seen in sham controls. No significantly altered transmitter sensitivities of piriform cortex neurons from kindled rats were seen with N-methyl-D-aspartate or GABA. The data indicate that amygdala kindling causes persistent interictal changes in both basal activity and glutamate responsiveness of central piriform cortex neurons which could contribute to the abnormal hyperexcitability characteristic of kindling.

Dorsal hippocampal kindling produces long-lasting changes in the origin of spontaneous discharges in the piriform versus perirhinal cortex in vitro

In an in vitro slice preparation of the amygdala-piriform-perirhinal cortex (A-P area), it was shown previously (McIntyre, D.C., Plant, J. R., 1993. Long-lasting changes in the origin of spontaneous discharges from amygdala-kindled rats: piriform vs. perirhinal cortex in vitro, Brain Res. 624, 268-276) that the infrequent spontaneous field potentials that initially originated in or near the perirhinal (PRh) cortex of slices from control rats began instead in the piriform (Pir) cortex of amygdala-kindled rats. This change in onset was only observed in the A-P area ipsilateral to the kindled amygdala. In the present experiment, we determined whether similar changes in activity were evident following kindling from a different limbic site, the dorsal hippocampus (DH). Kindling of the DH resulted in changes in the origin of the spontaneous discharges in the A-P area similar to amygdala kindling but, importantly, the changes involved both hemispheres. In addition, the origin of spontaneous discharges in slices from partial kindled rats (those that received as many hippocampal afterdischarges as the fully kindled rats but had not developed generalized convulsive responses) initially were similar to control tissue, but, during 0 Mg(2+) perfusion, changed more quickly than control tissue to mimic the profile of generalized kindled rats. The enduring changes in A-P area excitability caused by previous generalized kindling highlights the importance of the A-P area in convulsive generalization of limbic-kindled seizures.

Potentiation of late components in olfactory bulb and piriform cortex requires activation of cortical association fibers

Previous research has demonstrated that repeated high-frequency stimulation of the granule cell layer of the olfactory bulb (OB) produces an enduring potentiation of late components (PLC) in potentials evoked in the OB and piriform cortex (PC), while leaving the monosynaptic EPSP produced by OB mitral cells in PC pyramidal cells unaltered. Two experiments were conducted using male Long-Evans rats with chronically implanted electrodes to assess the relative contribution to this potentiation of the two main fiber systems that interconnect the OB and PC: the lateral olfactory tract (LOT), which contains mitral cell axons that synapse on PC pyramidal cells, and the PC association fiber system, which consists of the axons of PC pyramidal cells that synapse on several cell populations within the PC and on granule cells in the OB. The results indicate that stimulation of PC association fibers is both necessary and sufficient to duplicate the pattern of potentiation seen following OB stimulation in previous experiments. LOT stimulation had no consistent effect, and coactivation of the LOT and PC association fibers was no more effective than activation of PC association fibers alone. Possible mechanisms underlying this effect are discussed, including (1) long-term potentiation (LTP) at synapses made by the axons of PC pyramidal cells on neurons in the OB and PC; and (2) repetitive firing in PC pyramidal cells due to regenerative excitation in a population of deep cells in the PC and endopiriform nucleus.

Development of kindling-prone and kindling-resistant rats: selective breeding and electrophysiological studies

Because of the growing need for an animal model of complex partial seizures based on a genetic predisposition, we combined the kindling model of epilepsy with selective-breeding procedures to develop two new lines (or strains) of rats that are kindling-prone or kindling-resistant. The selection of these strains was based on their rates of amygdala kindling. From a parent population of Long Evans hooded and Wistar rats, the males and females that showed the fastest and slowest amygdala kindling rates were selected and bred. Similar selection procedures continued through F11, although there was little or no overlap in the distribution of kindling rates for the two new strains (FAST and SLOW) by F6. Examination of both local and propagating seizure profiles of the new strains from F6 to F10 revealed that the FAST and SLOW rats had similar amygdala afterdischarge (AD) thresholds and associated AD durations. Also, the convulsion profiles of the stage-5 responses were similar, although the severity was greater in the FAST rats. Clearly the selection was not based on local mechanisms controlling the threshold for amygdala AD evocation, but rather for the spread of AD from the focus and the recruitment of other structures, ultimately triggering convulsive seizures. Although evoked potentials and potentiation effects were similar between the strains, the SLOW rats showed a greater paired-pulse depression, raising the possibility that they differ in inhibitory mechanisms. The specificity of strain differences for the amygdala and its associated networks is described in our accompanying paper (McIntyre et al., 1999. FAST and SLOW amygdala kindling rat strains: Comparison of amygdala, hippocampal, piriform and perirhinal cortex kindling. Epilepsy Res. 35, 197-209). These strains should provide many clues to the dispositional differences between individuals for the development of epilepsy originating in temporal lobe structures.

Correlations between electrophysiological observations of synaptic plasticity modifications and behavioral performance in mammals

Within the past century it has been well established that most mature neurons lose their ability to divide. Since then, it has been assumed that behavioral performance leads to synaptic changes in the brain. The existence of these potential changes has been demonstrated in numerous experiments, and different mechanisms contributing to synaptic plasticity have been discovered. Many structures involved in different types of learning have now been identified. This article reviews the different methods used with mammals to detect electrophysiological modifications in synaptic plasticity following behavior. Evidence of long-term potentiation and long-term depression has been found in the hippocampus and cerebellum, respectively, and empirical data has been used to correlate these mechanisms with specific learning performance. Similar observations were made recently in the septum and amygdala. These phenomena seem to be involved in maintaining the performance in the cortical areas of the brain. Ongoing attempts to find the relationship between behavioral performance and modifications in synaptic efficacy allow to speculate upon the dynamics of cellular mechanisms that contribute to the ability of mammals to modify wide neuronal networks in the brain during their life.

Alternate-site kindling in the guinea-pig results in accelerated seizure progression and generalization

In rats, the concurrent alternate elicitation of epileptiform activity in two forebrain structures can result in both the rapid production of severe seizures and the development of fully generalized seizures in one (dominant) site, while arresting the progress of seizure activity at intermediate stages in the other (suppressed) site. The latter phenomenon is known as kindling antagonism. In this study, we examined alternate-site kindling in the guinea-pig as they fail to express fully generalized (stage 5) convulsions during single-site kindling. We assessed both seizure stage and afterdischarge duration following inter-hemispheric alternate-site kindling stimulation of the amygdala and medial septal areas. Alternating-site kindling of the medial septal and amygdaloid areas bypassed the normal inhibitory mechanisms in some guinea-pigs, enabling them to reach a stage 5 seizure. Furthermore, alternate-site kindled guinea-pigs demonstrated three (absolute, relative, and mutual) types of kindling antagonism. Guinea-pig kindling as a model of human partial epilepsy is discussed.

Duration of NMDA-dependent synaptic potentiation in piriform cortex in vivo is increased after epileptiform bursting

Stimulation of afferent fibers with current pulse trains has been reported to induce long-term potentiation (LTP) in piriform cortex in vitro but not in vivo. LTP has been observed in vivo only when trains are paired with behavioral reinforcement and as a consequence of kindled epileptogenesis. This study was undertaken in the urethan-anesthetized rat to determine if the reported failures to observe pulse-train evoked LTP in vivo may be related to a lesser persistence rather than lack of occurrence, if disinhibition might facilitate induction, and to examine the nature of the relationship between seizure activity and LTP. Stimulation of afferent fibers in the lateral olfactory tract with theta-burst trains under control conditions potentiated the monosynaptic field excitatory postsynaptic potential (EPSP) by approximately the same extent (20.3 +/- 2%; n = 12) as reported for the slice. However, in contrast to the slice, potentiation in vivo decayed to a low level within 1-2 h after induction (70% loss in 1.5 h, on average). The N-methyl--aspartate (NMDA)-receptor antagonists -APV and MK-801 blocked the induction of this decremental potentiation. Pharmacological reduction of gamma-aminobutyric acid-mediated inhibition at the recording site did not increase the duration of potentiation. In contrast, theta-burst stimulation applied after recovery from a period of epileptiform bursting induced stable NMDA-dependent potentiation. Mean increase in the population EPSP was approximately the same as under control conditions (21 +/- 2%; n = 6), but in five of six experiments there was little or no decay in potentiation for the duration of the monitoring period (</=6 h). It is concluded that seizure activity has an enabling action on the induction of persistent synaptic potentiation by stimulus trains that bypasses the need for behavioral reinforcement.

Large frequency potentiation induced by 2 Hz stimulation in the hippocampus of epileptic El mice

El mouse has been found to be characteristics with hippocampal disinhibition, and has been suggested decrease in GABAergic synaptic transmission [Ono et al., Brain Res. 745 (1997) 165-172; Fueta et al. , Brain Res. 779 (1998) 324-328]. The efficacy of GABAergic synapses can be modulated in response to trains of low frequency stimulation. The frequency potentiation of a population spike (PS) and the field excitatory postsynaptic potential (fEPSP) induced by a low frequency stimulation (2 Hz for 15 s) were recorded for the CA3 subfield, and PS alone for the CA1 subfield and dentate gyrus. PS frequency potentiation was greater in El mice than in non-epileptic control ddY mice. Especially the CA3 subfield exhibited a high PS frequency potentiation (300+/-73%) compared to age-matched ddY mice (64+/-24%). However, EPSP frequency potentiation was similar in El and ddY mice. The degree of PS frequency potentiation in CA3 was decreased by the reduction of extracellular Ca2+ from 2 to 1 mM in both strains, suggesting presynaptic involvement. The potentiation in El mice was suppressed by AMPA/kainate type receptor antagonist 6-cyano-7-nitroquinoxaline-2,3-dion (CNQX), but more than half of the control value remained at 5 microM, whereas the potentiation in ddY mice was abolished at this concentration. N-methyl-d-aspartate (NMDA) type receptor antagonist 3-3 (2-carboxypiperazine-4-yl) propyl-1-phosphonate (10 microM; CPP) did not affect the potentiation. Bicuculline (5 microM), GABAA receptor antagonist, did not increase the amplitude of PS during stimulation but induced epileptic (multiple PSs) potentials. High PS frequency potentiation of El mice was mimicked to the degree of that in ddY mice by a low dose of GABAB receptor agonist baclofen (3 microM). The suppression by baclofen was partially reversed by the antagonist saclofen (500 microM). The large frequency potentiation in young El mice, which do not have seizure-susceptibility, indicates an intrinsic property in El mice. It is suggested that the high synchronization of CA3 neurons in El mice is due to a little activation of GABAB receptor activation and also to enhancement of non-NMDA type synaptic transmission.

Long-term enhancement of entorhinal-dentate evoked potentials following 'modified' ECS in the rat

Electroconvulsive therapy (ECT) is widely used as a treatment for drug-resistant depression. The animal analogue of ECT is electroconvulsive shock (ECS) seizures. We have recently shown that repeated ECS seizures cause a long-lasting, perhaps permanent, enhancement in entorhinal-dentate evoked potentials in the rat. Our study, however, involved 'unmodified' ECS, whereas in clinical practice ECT is now usually given in its 'modified' form (with near-threshold currents, a short-acting barbiturate, muscle relaxant and oxygen). We have therefore repeated our experiments using modified ECS. Entorhinal-dentate evoked potentials were measured in Long-Evans rats before and after: (1) eight modified ECS seizures; or (2) eight sham modified ECS trials. Despite the use of the modified procedure, a significant and long-lasting enhancement in population spike amplitude was seen in the ECS group. We conclude that the modified procedure does not protect rats against the long-lasting enhancement of evoked potentials. Similar changes may be occurring in the brains of patients subjected to modified ECT.

Delayed development of spontaneous seizures and prolonged convulsive state in rats after massed stimulation of the anterior piriform cortex

We studied the short- and long-term epileptogenic effects of massed stimulation (MS) of the piriform cortex. Sprague-Dawley rats with electrodes implanted bilaterally in the anterior piriform cortex and the dorsal and ventral hippocampi underwent MS: electrical stimulation of the left piriform cortex every 5 min for 6 h (afterdischarge threshold, 60 Hz, 1 ms, 1 s). Animals were retested (5 stimulations) 3-4 times later at different time points to check for the kindled state. Our data showed that MS resulted in delayed development of severe epilepsy. The interval between MS and the first appearance of convulsive response (2 weeks) was characterized by deep refractoriness to seizure (silent period). Unexpectedly, dramatic seizure activity occurred 4-7 weeks after MS. This was manifested by (1) generalized tonic-clonic convulsions with multiple failings, which were elicited repeatedly during retest; (2) frequent progression of elicited generalized convulsions into a prolonged (> 8 min) postictal convulsive state expressed mainly by continuous partial seizures and even new bouts of generalized seizures, and (3) development of mild spontaneous seizures. We found that epileptiform activity predominated in the ventral hippocampus. Mossy fiber sprouting was also most pronounced in this area. We propose that the MS resulted in formation of pathological circuits which involve both piriform cortex and ventral hippocampus and lead to severe epilepsy.

Piriform cortex efferents to the entorhinal cortex in vivo: kindling-induced potentiation and the enhancement of long-term potentiation by low-frequency piriform cortex or medial septal stimulation

The entorhinal cortex receives input from many cortical areas and mediates the flow of information between these sites and the hippocampal formation. Long-term synaptic plasticity in cortical efferents to the entorhinal cortex may contribute to the transmission of neural activity to the hippocampus, as well as the storage of information, but little is known about plasticity in these pathways. We describe here the use of evoked field potential recordings from chronically implanted electrodes in the rat entorhinal cortex to investigate synaptic plasticity in the large piriform (olfactory) cortex projection to the superficial layers of the entorhinal cortex. Both kindling-induced potentiation and long-term potentiation (LTP) were tested. In addition, we attempted to modulate LTP induction by the co-induction of frequency potentiation and by the co-activation of the medial septum. Epileptogenic kindling stimulations of the piriform cortex (1-s, 60-Hz trains 3 times/day for 5 days) were found to result in a reliable potentiation of field responses evoked by piriform cortex test pulses. Non-epileptogenic tetanization of the piriform cortex with 400-Hz 16-pulse trains reliably resulted in LTP effects. These effects could be augmented by embedding brief LTP induction stimuli within 11-pulse, 15-Hz trains that alone produce only frequency potentiation. Co-activating the medial septum with 10-Hz trains, just prior to tetanization of the piriform cortex, augmented LTP of piriform cortex inputs to the entorhinal cortex in an input-specific manner. All potentiation effects were found to last for periods of weeks. These findings demonstrate that both epileptogenic and non-epileptogenic piriform cortex stimulation induces lasting potentiation of population field responses in the entorhinal cortex of the awake rat. The LTP effects were inducible in a graded manner and were sensitive to the temporal context of stimulation. The finding that low-frequency activation of the septum can enhance plasticity in the entorhinal cortex adds to a body of data indicating a role for the medial septum in contributing to theta activity and plasticity in both the entorhinal cortex and hippocampal formation.

Epileptiform activity in the piriform cortex of the in vitro isolated guinea pig brain preparation

Brief intracerebral injections of bicuculline in the anterior portion of the piriform cortex of the isolated guinea pig brain preparation induce a transient, localized disinhibition confined to the site of drug application. The epileptiform activity generated at the bicuculline focus propagates and induces secondary excitability changes in remote cortical regions within the olfactory lobe. Long lasting changes in synaptic potentials were observed in the posterior piriform cortex, where long-projective cortico-cortical fibers originating from the site of bicuculline injection terminate. The activation of rhythmic, transient afterdischarges at the bicuculline focus was critical for the development of persistent 'epileptiform' associative synaptic potentials in remote cortical regions. When transient afterdischarges were prevented, epileptiform associative potentials in the posterior piriform cortex appeared only transiently and vanished within 20 min. The persistent secondary changes in synaptic excitability that occur in cortical regions distant from the acutely-induced primary epileptic focus may represent one of the transition mechanisms toward chronic epileptogenesis.

The role of the piriform cortex in kindling

In epilepsy research, there is growing interest in the role of the piriform cortex (PC) in the development and maintenance of limbic kindling and other types of limbic epileptogenesis leading to complex partial seizures, i.e. the most common type of seizures in human epilepsy. The PC ("primary olfactory cortex") is the largest area of the mammalian olfactory cortex and receives direct projections from the olfactory bulb via the lateral olfactory tract (LOT). Beside the obvious involvement in olfactory perception and discrimination, the PC, because of its unique intrinsic associative fiber system and its various connections to and from other limbic nuclei, has been implicated in the study of memory processing, spread of excitatory waves, and in the study of brain disorders such as epilepsy with particular emphasis on the kindling model of temporal lobe epilepsy with complex partial seizures. The interest in the kindling model is based primarily on the following observations. (1) The PC contains the most susceptible neural circuits of all forebrain regions for electrical (or chemical) induction of limbic seizures. (2) During electrical stimulation of other limbic brain regions, broad and large afterdischarges can be observed in the ipsilateral PC, indicating that the PC is activated early during the kindling process. (3) The interictal discharge, which many consider to be the hallmark of epilepsy, originates in the PC, independent of which structure serves as the kindled focus. (4) Autoradiographic studies of cerebral metabolism in rat amygdala kindling show that, during focal seizures, the area which exhibits the most consistent increase in glucose utilization is the ipsilateral paleocortex, particularly the PC. (5) During the commonly short initial afterdischarges induced by stimulation of the amygdala at the early stages of kindling, the PC is the first region that exhibits induction of immediate-early genes, such as c-fos. (6) The PC is the most sensitive brain structure to brain damage by continuous or frequent stimulation of the amygdala or hippocampus. (7) Amygdala kindling leads to a circumscribed loss of GABAergic neurons in the ipsilateral PC, which is likely to explain the increase in excitability of PC pyramidal neurons during kindling. (8) Kindling of the amygdala or hippocampus induces astrogliosis in the PC, indicating neuronal death in this brain region. Furthermore, activation of microglia is seen in the PC after amygdala kindling. (9) Complete bilateral lesions of the PC block the generalization of seizures upon kindling from the hippocampus or olfactory bulb. Incomplete or unilateral lesions are less effective in this regard, but large unilateral lesions of the PC and adjacent endopiriform nucleus markedly increase the threshold for induction of focal seizures from stimulation of the basolateral amygdala (BLA) prior to and after kindling, indicating that the PC critically contributes to regulation of excitability in the amygdala. (10) Potentiation of GABAergic neurotransmission in the PC markedly increases the threshold for induction of kindled seizures via stimulation of the BLA, again indicating a critical role of the PC in regulation of seizure susceptibility of the amygdala. Microinjections of NMDA antagonists or sodium channel blockers into the PC block seizure generalization during kindling development. (11) Neurophysiological studies on the amygdala-PC slice preparation from kindled rats showed that kindling of the amygdala induces long-lasting changes in synaptic efficacy in the ipsilateral PC, including spontaneous discharges and enhanced susceptibility to evoked burst responses. The epileptiform potentials in PC slice preparations from kindled rats seem to originate in neuron at the deep boundary of PC. Spontaneous firing and enhanced excitability of PC neurons in response to kindling from other sites is also seen in vivo, substantiating the fact that kindling induces long-lasting changes in the PC c

Propagation of epileptiform potentials in the guinea-pig piriform cortex is sustained by associative fibres

The role of the associative connections in the propagation of epileptiform discharges originating from an acute, localized epileptic focus in the anterior piriform cortex has been characterized recently in the in vitro isolated guinea-pig brain preparation. The present study demonstrates that the dorsal propagation of epileptiform synaptic potentials generated in APC is carried by long-projective associative fibres. Current source density analysis of the field potential profiles evoked by stimulation of the lateral olfactory tract has been utilized to describe the functional circuit activated in rostral and caudal regions of the piriform cortex, before and after the induction of a bicuculline epileptic focus in the anterior piriform cortex. Separate stimulation of the lateral olfactory tract at two sites, caudal and rostral to a tract incision, activates epileptiform potentials that are generated at the site of primary focus in the anterior piriform cortex and travel along associative fibres. Selective cutting of the long-projective associative fibres abolishes the epileptic associative potential in the cortical regions caudal to the section. The present study demonstrates directly that epileptiform potentials propagate along associative fibres to cortical regions that are synaptically related to the focus of origin. Such a pattern of propagation may sustain the generation of secondary foci in cortical regions remote from the primary epileptic focus.

Arrest of seizure progression during electrical kindling in guinea-pigs with prior pentylenetetrazol-induced convulsions

A number of comparative differences in the kindling phenomenon have been observed between guinea-pigs and rats. These differences likely reflect different mechanisms underlying brain plasticity. In this study, guinea-pigs were used to examine the kindling transfer phenomenon between peripheral pentylenetetrazol injection and electrical kindling of the amygdala. The changes in afterdischarge characteristics and behavioural seizures during electrical kindling were compared between animals that had experienced three PTZ-induced convulsions and PTZ-naive controls. We report that on the first electrical kindling session the PTZ-convulsed guinea-pigs displayed lower AD thresholds, enhanced AD durations and seizures, but that their seizures did not progress with repeated daily kindling stimulation.

Differential sensitivity of various temporal lobe structures in the rat to kindling and status epilepticus induction

Using focal brain stimulation (kindling), discrete seizures can be triggered from many neuroanatomic sites with varying degrees of facility. From several of these sites, protracted seizures or status epilepticus (SE) also can be triggered. To date, no comparison has been made between different brain sites in their sensitivity both to kindling and to SE development. In this report, we have compared the kindling profiles of three amygdala nuclei, namely the basal (BL), central (CE), and medial (ME) nuclei, to the adjacent piriform (PIR) and perirhinal (PRH) cortices. In addition, three weeks following kindling, the susceptibility of each kindled site to status epilepticus (SE) was assessed by exposing the site to 60 min of electrical stimulation. We observed that (a) during the course of daily kindling, the afterdischarge threshold dropped progressively and significantly in all structures, (b) the rate of kindling in the PRH and PIR cortices and the CE amygdala was significantly faster than either the BL or ME amygdala, (c) when discrete convulsions were triggered, the latency to forelimb clonus in the PRH cortex and CE amygdala was significantly shorter than the other three structures, and (d) despite being slower to kindle than most other sites, stimulation of the BL nucleus most readily triggered SE. The kindling data suggest that discharges triggered from the PRH and CE more readily access motor systems supporting limbic convulsions than discharges triggered from the BL, ME nuclei or the PIR cortex. On the other hand, the SE data indicate that the mechanisms and circuits associated with the development of discrete kindled seizures are not identical to those associated with the induction of limbic SE.

Post-activation potentiation in the neocortex. III. Kindling-induced potentiation in the chronic preparation

Previous experiments have shown the neocortex to be very resistant to the induction of long-term potentiation in chronic preparations. We show here that kindling-induced potentiation effects can be reliably produced in the neocortex of awake, freely moving rats. These effects develop rather slowly. In sites contralateral to the stimulation electrode, potentiation effects did not become clear until the animals had received about 5 days or more of stimulation. Ipsilateral sites required even longer (approximately 10 days), and both sites required more than 13 days to reach asymptotic levels of potentiation. Both monosynaptic and polysynaptic components were present in the neocortical field potentials. When population spikes were absent, the surface negative monosynaptic EPSP component tended to show a potentiation effect. If population spikes were present, they were generally enhanced while the monosynaptic population EPSP tended to be depressed. Consequently, the apparent depression may have been due to competing field currents. The later polysynaptic components (15-28 ms latency to peak) always showed a potentiation effect with 5 or more kindling stimulations and is presumed to result from activation of cortico-cortical associational fibers. All of these effects were long-lasting, showing little decay over a period of several weeks.

Long-term changes in entorhinal-dentate evoked potentials induced by electroconvulsive shock seizures in rats

Entorhinal-dentate evoked potentials were measured in rats before and after: (1) eight electroconvulsive shock (ECS) seizures, or (2) matched handling. In animals that received ECS, evoked potentials were significantly enhanced, as evidenced by a long-lasting increase in the amplitude of the population spike. This increase in population-spike amplitude lasted for at least 3 months after the last ECS trial. No evoked-potential changes were observed in the subjects that received matched handling. These data suggest that ECS seizures produce long-lasting, perhaps permanent, changes in the brain.

Evolution of afterdischarge and seizure characteristics during electrical kindling of the guinea-pig

Interspecies comparisons may help us understand the mechanisms which underlie brain plasticity. In this study, we examined the electrical kindling phenomenon in the amygdala, piriform and perirhinal regions of the guinea-pig. The changes in afterdischarge (AD) characteristics and behavioural seizures were assessed under different stimulation intervals and parameters as well as under reduced inhibitory neurotransmitter systems. We report that the guinea-pigs displayed a number of similarities with other species, such as the progressive increases in AD characteristics and seizure behaviours, but also a number of differences, such as the behavioural manifestations of the seizures, failing to reach a fully generalized tonic-clonic seizure and an apparent insensitivity to both low-frequency stimulation and reduced GABA and catecholamine levels.

Specific [3H]L-glutamate binding and [3H]D-aspartate release in the hippocampus of rat after pentylenetetrazol kindling and long-term potentiation

In the present study, the time-course of changes in glutamate binding and aspartate release in the rat hippocampus following tetanization of perforant pathway and of pentylenetetrazol-induced kindling was investigated. The K+ (48 mM)-stimulated [3H]D-aspartate release from hippocampal slices and the specific [3H]L-glutamate binding to crude synaptic membranes of the hippocampus were measured 1, 4 and 24 h after the last tetanization train or one, five and nine weeks after the last pentylenetetrazol injections, respectively. The tetanization of the fascia dentata was followed by a significant increase in K(+)-stimulated [3H]D-aspartate release from hippocampal slices only 1 h after the last tetanization train, but the specific [3H]L-glutamate binding was enhanced 4 h afterwards. No further deviations from controls have been seen 24 h after tetanization. After pentylenetetrazol kindling, the K(+)-stimulated amino acid release from hippocampal slices was not changed. However, at one week as well as at five and nine weeks after the pentylenetetrazol kindling the specific [3H]L-glutamate binding in the hippocampus was significantly increased by about 50% compared to controls. From these findings it can be assumed that after long-term potentiation induction presynaptic transmitter release and post- (and/or pre-)synaptic glutamate binding are elevated with a different time course only in the early phase of potentiation. In contrast, kindling results in a long lasting increase in activity state of glutamatergic transmission. Therefore, it can be concluded that differences of the synaptic excitability following long-term potentiation and kindling are reflected by a different activation of glutamatergic system in the central nervous system.

Long-lasting changes in the origin of spontaneous discharges from amygdala-kindled rats: piriform vs. perirhinal cortex in vitro

The origin of spontaneous field potentials in coronal slices of the amygdala-piriform-perirhinal area (A-P area) from amygdala-kindled and control rats was assessed. In Expt. 1, the field potentials initially originated in the perirhinal (PRh) cortex of control tissue while they originated in the piriform (Pir) cortex of amygdala-kindled tissue. In Expt. 2, this kindling-based change was observed in the A-P area ipsilateral but not contralateral to the kindled amygdala. In both experiments, subsequent exposure to perfusion medium containing 0 Mg2+ resulted in the genesis of strong discharges in both control and kindled tissues. After 2-3 h of such treatment, the origin of spontaneous discharges in control tissue changed from the PRh to the Pir area and persisted in a reduced form during reperfusion with medium containing Mg2+. This change in origin of the discharges in control tissue appeared similar to that seen in previously kindled tissue. In Expt. 3, during exposure to 0 Mg2+, the response of the basolateral amygdala (BLA) was compared with the Pir and PRh areas. Independent of the PRh discharge, the BLA discharge closely followed the Pir discharge both in time and morphology. These lasting changes in the ipsilateral A-P area in vitro must be related in vivo to the change which allows the kindled A-P area to participate in the triggering of generalized limbic-kindled convulsions.

Increased spontaneous unit discharge rates following electrical kindling in the rat

Changes in neuronal excitability that persist after seizures may play a key role in epilepsy. In this study, extracellular single unit recording techniques were used to investigate the changes in cell discharge patterns that result from kindling in vivo. The spontaneous activity of piriform and perirhinal cortical units in chronically implanted adult rats was recorded before, during and after kindling the amygdala. We observed that kindling-induced seizures resulted in a prolonged and dramatic increase in the rate of spontaneous background neuronal discharge in both the piriform and perirhinal regions.

Roles of the NMDA and quisqualate/kainate receptors in the induction and expression of kindled bursts in rat hippocampal slices

We used combinations of NMDA and quisqualate/kainate (Q/K) receptor antagonists and low Mg2+ (0.1 mM) solutions to study the respective roles of these receptors during in vitro kindling of interictal bursts in the CA3 area of rat hippocampal slices. Intracellular and extracellular recordings in CA3 showed that Q/K receptors were not necessary for the induction of kindling once the Mg2+ block of NMDA was alleviated, but that the expression of bursts kindled via NMDA-driven mechanisms was Q/K-dependent.

Long-term potentiation in rat piriform cortex following discrimination learning

The behavioral conditions for induction of long-term potentiation (LTP) elicited by unilateral patterned electrical stimulation of the lateral olfactory tract (LOT) was studied in piriform cortex. A group of animals was trained to discriminate two natural odors while another group was trained to discriminate a patterned stimulation (bursts of 4 pulses at 100 Hz repeated at 160-ms intervals) used as an olfactory cue, versus a natural odor. Both groups were successful in the discrimination and no statistical significant difference was observed in behavioral data between these two groups on series of 5 successive daily training sessions. With animals trained to perform the task with the artificial cue, monosynaptic responses evoked by single pulse stimulation of the LOT were collected, prior to and just after each of the successive training sessions. Comparisons with behavioral data collected at the beginning and the end of a training session revealed that the population synaptic responses increased with the percentage of correct responses performed by the animals. This increase (LTP) was progressive and present only when significant discrimination between the two cues was observed. A positive correlation was found between the increase in monosynaptic responses and the level of performance. Responses elicited by control electrodes were slightly depressed at the end of the discrimination learning series. In addition, when a group of naive animals was pseudoconditioned, giving the patterned electrical stimulation for the same number of sessions but without any olfactory training, no LTP was recorded.(ABSTRACT TRUNCATED AT 250 WORDS)

NMDA receptor-dependent formation of long-term potentiation in the rat medial amygdala neuron in an in vitro slice preparation

Population spike was recorded from the medial and central nucleus of the amygdala (AMG) in an in vitro slice preparation following stimulation of the stria terminalis (ST). The population spike was completely suppressed by 6-cyano-7-nitroquinoxaline-2,3-dione (10 microM), a non-NMDA receptor antagonist, but not affected by 3-[(+)-2-carboxypiperazine-4-yl-]-propyl-1-phosphonic acid (CPP) (20 microM), a competitive NMDA receptor antagonist. Tetanic stimulation to the ST induced long-term potentiation (LTP) in both the medial and central AMG. Tetanic stimulation of 20 s in duration and 50 Hz in frequency most effectively potentiated the population spike. All the NMDA antagonists tested, such as CPP (20 microM), (+)-5-methyl-10,11-dihydro-5H-dibenzo-[a,d]-cyclohepten-5,10- imine-hydrogen maleate (30 microM) and 7-chlorokynurenic acid (30 microM), significantly depressed the formation of LTP in the medial AMG. 2-Amino-3-phosphonopropionate (1 mM), a metabotropic glutamate receptor antagonist, and intracerebral ventricular injection of ilet activating protein had no significant effects on the formation of LTP. Furthermore, the LTP formation of EPSP was completely blocked in BAPTA [bis-(2-aminophenoxy)-ethane-N,N,N',N'-tetraacetic acid]-loaded medial AMG neurons. These results indicate that Ca2+ influx mainly through NMDA receptors is crucial for the induction of LTP in the ST-medial AMG neuron synapses.

Two types of neuroplasticities in the kindling phenomenon: effects of chronic MK-801 and methamphetamine

Using the low-frequency kindling technique, we studied the effects of chronic MK-801 and chronic methamphetamine (MAP) administration on hippocampal kindling seizure development. In experiment 1, MK-801 (0.05, 0.1 mg/kg i.p.) was administered 2 h before each electrical stimulation until kindling developed into stage-3 seizure. In experiment 2, we started daily electrical stimulations two weeks after the last injection of chronic MAP administration (6 mg/kg/day, 14 days). The number of stimulating pulses required for the triggering of epileptic afterdischarge (pulse-number threshold, PNT) was used as an indicator of the seizure threshold. PNT, afterdischarge duration (ADD) and behavioral seizure stage (BSS) of each induced seizure in the initial stage of kindling; the kindling rates for stage 3 and stage 5 seizures; seizure parameters at the completion of kindling of the drug-treated groups were recorded and compared to the values of each saline-treated control group. Our result showed that MK-801 administration prior to each electrical stimulation selectively and significantly increased PNT in the initial stage of kindling without affecting other seizure parameters. Chronic pretreatment of MAP caused a selective and significant decrease of PNT of the first two stimulations in the kindling process. Taken together with the previous studies, these results suggest that long-term potentiation plays an important role in the development of the excitability of seizure focus but not of the induced seizure's propagation in the hippocampal kindling phenomenon. Clinically MK-801 seems to be a more efficacious drug in preventing the induction of seizures than in suppressing the acquired seizures.

Hippocampal kindling leads to different changes in paired-pulse depression of local evoked field potentials in CA1 area and in fascia dentata

Monosynaptic evoked field potentials (EPs) in response to paired-pulse stimulation (20 ms interval) were recorded in area CA1 and fascia dentata of the same animal in the course of development of a kindled focus in the CA1 region. A significant reduction of paired pulse depression in response to medium and high stimulation intensity was found in CA1. A similar change was found in the fascia dentata in response to medium intensity stimulation of the angular bundle. In contrast, at high intensity, paired pulse depression was enhanced in the fascia dentata in the course of kindling. These results indicate that kindling epileptogenesis is accompanied by regionally different changes in recurrent inhibition: a reduction in CA1 and intensity dependent changes in fascia dentata.