Kindling of audiogenic seizures in Wistar rats: an EEG study

The EEG of 20 Wistar rats inbred for audiogenic seizures was recorded during 40 daily auditory stimuli 90 s long. The first stimuli provoked wild running, with no cortical EEG abnormality, and then a tonic phase with a characteristic EEG of a brief flat trace 2 to 3 s long followed by low-amplitude regular activity, 10 to 12 c/s, lasting 40 to 60 s. The lack of paroxysmal EEG patterns suggests that the cortex plays only a minor role in audiogenic seizure development. After 5 to 15 daily stimuli, the EEG during the running period exhibited brief spike and spike-wave discharges preceding the EEG pattern of the tonic phase. After a few more daily stimuli these paroxysmal discharges progressively increased in amplitude and duration, overlapping with the regular activity of the tonic phase. After 20 to 30 stimuli, only high-amplitude spikes and spike-waves, 1 to 10 c/s, were seen for 40 to 120 s. The modified EEG persisted 2 to 4 months after daily stimulation was discontinued. Thus, with stimulus repetition, a paroxysmal discharge progressively involved cortical structures. These data suggest that repetition of audiogenic seizures induced a phenomenon related to kindling in Wistar rats susceptible to sound-induced epilepsy.     

El mouse as a model of focal epilepsy: a review

The El mouse is a model of hereditary sensory precipitated temporal lobe epilepsy. All adult El mice given rhythmic vestibular stimulation (e.g. tossing, rocking) during development will experience tonic-clonic convulsions when given similar stimulation as adults. The seizures have prodromal, convulsive, and postictal stages. EEG and 2-deoxyglucose studies have localized the seizures to the temporal lobe, with onset in the hippocampus. El mice have a decreased threshold for convulsion by electrical or pharmacologic stimulation. A variety of anticonvulsant medications eliminate El mouse seizures, including phenytoin (PHT), phenobarbital (PB), valproate (VPA), and ethosuximide (ESM). Anatomic studies have shown subtle differences in the thalamus and hippocampus of El mice. Immunohistochemistry of the El mouse hippocampus has revealed changes in peptidergic and gabaergic cell populations. Numerous biochemical differences have been found between El and nonconvulsive mice, including increased acetylcholine (ACh), dopamine (DA), GABA, serotonin (5-HT), and decreased norepinephrine (NE).     

Clinical and electroencephalographic features of simple partial seizures

The clinical and electroencephalographic features of 87 simple partial seizures in 14 patients were studied with video-EEG telemetry. The patients were able to respond to verbal stimuli during all seizures and, later, could clearly recall ictal events. To determine whether the EEG changes in simple partial seizures could be reliably observed, a reader blindly reviewed four EEGs of equal duration for each seizure. These EEGs consisted of one ictal and three nonictal recordings obtained at predetermined times before the seizure. There were 27 motor seizures (mean duration, 86 seconds; range, 2 to 250 seconds), all involving clonic movements of the head and/or upper extremities; 8 (30%) of these had a sensory component (pain in 6, paresthesia in 2). An EEG change, usually localized spikes or sharp waves over the contralateral or both rolandic regions, was identifiable in nine (33%) of the motor seizures. The 60 nonmotor seizures (mean duration, 63 seconds; range, 8 to 375 seconds) involved a variety of symptoms, including somatosensory/special sensory (3 seizures), autonomic (26 seizures), cognitive (1 seizure), affective (14 seizures), and mixed, or more than one category of nonmotor symptoms (16 seizures). In only nine (15%) of the nonmotor seizures was there an ictal EEG change, usually localized spikes or paroxysmal theta activity over the temporal region. Overall, among the 87 simple partial seizures, only 18 (21%) revealed ictal EEG changes. Thus, a normal EEG is common during simple partial seizures and does not exclude the diagnosis.     

Kindling of audiogenic seizures in the rat

A strain of Wistar rats was inbred in our laboratory for its susceptibility to sound. The seizures are characterized by one or two wild running fits which terminate in a tonic dorsiflexion with open mouth, followed by a catatonic state. During the tonic phase of the seizure, the cortical EEG is flattened for 2 to 3 s. Then, a slow and regular low-voltage (9-12 c/s) activity is observed during 40 to 60 s. When these animals are submitted to daily sound-stimulations, the behavioral as well as the EEG manifestations of the audiogenic seizures change progressively. After 5 to 30 exposures, the wild running becomes disorganized by occurrence of myoclonic jerks of the limbs and the body. In some animals, the tonic extension disappears and a myoclonic seizure develops progressively with facial and forelimb clonus, rearing and falling. In other animals, the tonic phase still occurs and is followed by a generalized clonic phase. During both the myoclonic and the tonicoclonic seizures, rhythmic spikes, polyspikes and spike and waves of high amplitude (1-10 c/s) during 40 to 120 s are observed on EEG recordings. These EEG modifications often outlast the sound stimulation. The pharmacological reactivity in rats exposed to single or repeated audiogenic seizures is similar: phenytoin and carbamazepine suppress both kinds of seizures at low doses whereas ethosuximide is efficacious only at high doses. In order to know whether the repeated exposure to sound or the repetition of seizures are responsible of the observed changes in audiogenic seizures, animals susceptible to sound were exposed daily to the seizure-inducing sound after previous injection of Diazepam, which prevented them from convulsing. On the other hand, sound susceptible animals were injected daily with a dose of PTZ inducing one or several convulsions without exposure to sound. None of these treatments ever facilitated the development of kindled audiogenic seizures. The progressive modification of behavioral and EEG modifications occurring when audiogenic seizures are repeated suggests that kindling has developed, the seizure extending from the brainstem to forebrain structures.     

The Development of EEG Background Activities in El Mouse

Abstract: The development of background activities of cortical EEG in El mouse, the seizure susceptible mutant strain of ddN mouse, were investigated. Furthermore, it was compared to that of the ddN control mouse.
The average peak frequency of EEG background activity was much slower than that of the ddN mouse. After seizures in the El mouse were completed, the average energy distribution rates of the main frequency band, theta band, have decreased because of an increase in the delta band compared to those in seizure-free periods (the 5th to 8th week).     

The development of EEG background activities in El mouse

The development of background activities of cortical EEG in El mouse, the seizure susceptible mutant strain of ddN mouse, were investigated. Furthermore, it was compared to that of the ddN control mouse. The average peak frequency of EEG background activity was much slower than that of the ddN mouse. After seizures in the El mouse were completed, the average energy distribution rates of the main frequency band, theta band, have decreased because of an increase in the delta band compared to those in seizure-free periods (the 5th to 8th week).     

Current trends in electroencephalography

Several recent articles re-emphasize the value of clinical electrophysiology: in localizing epileptogenesis, predicting effectiveness of epilepsy surgery, and disclosing a mechanism of benign Rolandic epilepsy of childhood.A review of the role of EEG in the diagnosis of epilepsy indicated that epileptiform activity will appear in 50% of initial awake recordings of adults with epilepsy and in 85% of subjects undergoing two recordings. This contrasts with the appearance of spikes in only 4 of 1000 normal persons. Several studies focused on the value of electroencephalography in extratemporal epilepsy: 62% of patients with neocortical epilepsy had at least one localizing ictal EEG; occipital and temporal neocortical seizures were localized in a greater proportion than frontal or parietal attacks. Interictal spikes, if unifocal, always arose from the epileptogenic region in a study of their seizure localizing value. Such congruence augured for better seizure control by focal resection in two studies reviewed herein.Studies indicating the value of interictal temporal lobe spikes and scalp-recorded seizures in lateralising a temporal seizure focus are reviewed. One study found EEG to be slightly more reliable for lateralization of temporal epileptogenesis than MRI.In patients with benign Rolandic seizures, enhanced motor evoked potentials (MEPs) were obtained from transcranial magnetic stimulation when this was applied 50-80 msec after electrical stimulation of the thumb whereas this interval inhibited the MEP in normal subjects. This suggests that afferent cutaneous input abnormally and synchronously activates a large population of sensory neurons; such activation is subsequently transmitted to the motor cortex to produce the focal spikes in this condition.Finally, advances in non-invasive technology have redefined and limited the need for invasive monitoring in children with intractable seizure disorders.     

Repetition of audiogenic seizures in genetically epilepsy-prone rats induces cortical epileptiform activity and additional seizure behaviors.

Repetition of seizures appears to increase severity in a number of seizure models, but the nature of these severity increases has not been elucidated in naturally occurring genetic epilepsy models. The genetically epilepsy-prone rat (GEPR) is highly susceptible to many seizure provoking stimuli, and high intensity acoustic stimuli induce audiogenic seizures (AGS). The role of forebrain structures in AGS in the GEPR has not been clear, and the presence of cortical epileptiform EEG activity in the GEPR is controversial. The present study examined the effects of 21 daily AGS repetitions on behavior and EEG activity recorded from the cortex of two GEPR substrains that exhibit moderate (GEPR-3) or severe AGS (GEPR-9). The results indicated that AGS repetition induced seizure severity increases in both GEPR substrains and resulted in prominent cortical epileptiform EEG activity. The AGS behavioral patterns remained distinctly different in the two substrains throughout seizure repetition. In each substrain a different additional behavioral phase was expressed; the GEPR-9 exhibited post-tonic clonus, and the GEPR-3 exhibited facial and forelimb clonus. These findings indicate that seizure repetition results in expansion of the neuronal network subserving AGS to involve forebrain structures. The medial geniculate body and amygdala appear to be part of this expanded network, and long-term potentiation, which was reported in the pathway between the latter brain structures, may be involved. These data suggest that recruitment of forebrain structures into the AGS neuronal network appears to be essential for production of the additional ictal behaviors evoked by AGS repetition.     

Slow-frequency repetitive transcranial magnetic stimulation in a patient with focal cortical dysplasia

PURPOSE: To evaluate the effect of slow-frequency repetitive transcranial magnetic stimulation (SF-rTMS) on interictal epileptiform activity and seizure frequency in a patient with medically refractory partial seizures due to focal cortical dysplasia. METHODS: A 9-cm circular coil was positioned over the area of cortical dysplasia. One hundred stimuli given at 0.5 Hz at 5% below motor threshold were given biweekly for four consecutive weeks. The EEG was recorded for 30 min before and after the first 100 stimuli. The number of seizures during the month of stimulation was compared with that of the month before stimulation. RESULTS: Stimulation was associated with a 70% reduction in the frequency of seizures and a 77% reduction in the frequency of interictal spikes. No seizures occurred during stimulation. CONCLUSIONS: SF-rTMS was safe and well tolerated in this patient. The reduction in seizures and interictal spikes associated with SF-rTMS supports the concept of SF-rTMS-induced cortical inhibition.     

Epilepsia arithmetices revisited

Three patients whose epileptic seizures are precipitated by arithmetic calculations are reported and their clinical and EEG features analysed along with those of 7 previous cases. The seizure disorder, in general, was characterised by an onset, in adolescence, of myoclonic jerks with or without tonic-clonic seizures and generalised bisynchronous 2-5 Hz spike-and-wave discharges in the EEG. Problems involving processing of spatial information were among the tasks which induced the dysrhythmia. The specificity and the consistency of the seizure-provoking stimuli suggest that in these patients the cortical areas responsible for calculations and related functions are abnormally hyperexcitable and the repeated stimulation during cognitive activities triggers seizure discharges. Two or our patients responded well to clobazam during a follow-up period of 6 months.     

Reduced uptake and release of 5-hydroxytryptamine and taurine in the cerebral cortex of epileptic El mice

Inbred mutant El mice are highly susceptible to convulsive seizures upon 'throwing' stimulation, and the inhibition of 5-hydroxytryptamine (5-HT) and taurine activities appears to be involved in the El mouse seizures. Uptake and release of [3H]5-HT and [3H]taurine into and from cerebral neurocortical slices using a superfusion system were investigated in both non-stimulated and stimulated El mice [El(-), El(+)] and in ddY mice, which do not have a convulsive disposition. Release was defined as 40 mM K+-stimulated release. 5-HT and taurine uptake in El(+) was lower than El(-) but no difference in either uptake was found between ddY and El(-). Release of 5-HT and taurine in El(-) was higher than in ddY whereas their release in El(+) was lower than in El(-). The taurine level in the cerebral neocortex of El(-) and El(+) was higher than in ddY. These results suggest that the synaptic function of the 5-HT and taurine containing neurons is suppressed and that dysfunction of these inhibitory neurons is involved in the seizure susceptibility in the El mice.     

Animal Models of Inherited Epilepsy

A significant proportion of the childhood epilepsies have a genetic component. Therefore, animal models that can be bred for seizure expression may provide important information regarding the mechanisms by which molecular defects result in the neuronal hyperexcitability states collectively termed “epilepsy.” Because of the rate and ease of breeding, rodent models are the most commonly used. The genetically epilepsy-prone rat has motor seizures in response to auditory stimuli. It is likely that the seizures are generated in the inferior colliclus because of an abnormality in the noradrenergic system. The seizure predisposition is inherited as an autosomal dominant trait. The genetic absence epilepsy rat has age-related spontaneous seizures characterized by motor arrest and head drops that are correlated with generalized spike-wave on the electroencephalogram (EEG). The seizure generating mechanism appears to be located in the lateral thalamic nuclei. The epileptic mongolian gerbil demonstrates behavioral arrest followed by myoclonic, tonic, and tonic-clonic seizures in response to unfamiliar environments. The underlying neuroanatomy involves hippocampal-cortical interactions indicative of a partial epilepsy. The tottering mouse has absence and myoclonic seizures, a 6- to 7-Hz ictal spike-wave EEG, and noradrenergic hyperinnervation that are linked to a mutation on chromosome 8. Hippocampal network hyperexcitability has been found with normal neuronal intrinsic properties. Stargazer is a mouse mutant with almost identical clinical and electrographic features as found in tottering. However, the genetic defect is located on chromosome 15 and no abnormalities of norepinephrine have been discovered. The El mouse demonstrates ictal automatisms in response to vestibular stimulation. Metabolic and structural abnormalities have been found in the hippocampus. Linkage to chromosomes 9 and 2 have been reported recently. The dilute brown agouiti mouse demonstrates motor seizures in response to auditory stimuli. Chromosomes 4 and 17 are linked to seizure expression. Thus, a variety of models exist to study the genetic, biochemical, structural and electrophysiological mechanisms that underlie the predisposition and expression of the inherited epilepsies.     

The Absence of Interictal Spikes with Documented Seizures Suggests Extratemporal Epilepsy

PURPOSE: To determine the demographic and clinical characteristics of patients who have documented epileptic seizures on long-term video-EEG monitoring who do not have interictal spikes. METHODS: The records of 1,223 monitoring studies from 919 patients who underwent noninvasive long-term video-EEG monitoring were reviewed. In 28 patients (3.0% of monitored patients, 4.4% of patients with electrographic evidence of epilepsy), no interictal spikes were found despite the occurrence of at least one recorded electrographic seizure. The demographic, medical, neuropsychological, and EEG data of these patients were compared with those of 28 matched control patients with documented interictal spikes. RESULTS: Extratemporal seizures were significantly more frequent in the patients with at least one recorded epileptic seizure but without interictal spikes compared with patients with epileptic seizures and interictal spikes (p = 0.031). The only other significant difference between the groups (p = 0.016) was a later age at seizure onset (18.3 vs. 10.7 years) for the patients without interictal spikes. Age at evaluation, gender, handedness, clinical seizure type, family history of epilepsy, history of febrile seizures, neuropsychological testing, and neurologic and psychiatric history did not differ between the two groups. CONCLUSIONS: In patients with documented epilepsy without interictal spikes on EEG monitoring, the possibility of an extratemporal focus should be considered.     

Electroencephalographic Characteristics of Audiogenic Seizures Induced in Metaphit-Treated Small Rodents

Adult male mice, rats, and guinea pigs were subjected to intense sound stimulation of an electric bell (100 dB, 12 kHz for 60 s) after a single intraperitoneal (i.p.) injection of metaphit (1-(1-(3 isothiocyanatophenyl)-cyclohexyl)piperidine) (50 mg/kg). When the animals were tested 24 h after administration of metaphit, audiogenic seizures were observed. None of the control saline-injected animals had convulsions. EEG recordings demonstrated the appearance of paroxysmal activity and spike-wave complexes in the trace from cortical and hippocampal electrodes, with frequency and amplitude increasing with time. Behaviorally, myoclonic jerks of facial muscles, ears, and neck appeared, but no correlation was noted between EEG and the motor phenomena. Auditory stimulation was necessary to elicit the full-blown sequence of seizure responses consisting of wild running followed by clonic and then tonic extension. At the time of seizures, repetitive high-amplitude spikes and waves appeared in the EEG, followed by profound EEG and behavioral depression. None of the animals died during or immediately after seizures. The seizure response to sound stimulation of mice, rats, and guinea pigs was phenomenologically similar, with minor differences in quantitative pattern of convulsive components, which suggests that all three animal species share the common property of extreme susceptibility to audiogenic stimulation caused by metaphit administration.     

Seizure susceptibility of neuropeptide-Y null mutant mice in amygdala kindling and chemical-induced seizure models

Neuropeptide Y (NPY) administered exogenously is anticonvulsant, and, NPY null mutant mice are more susceptible to kainate-induced seizures. In order to better understand the potential role of NPY in epileptogenesis, the present studies investigated the development of amygdala kindling, post-kindling seizure thresholds, and anticonvulsant effects of carbamazepine and levetiracetam in 129S6/SvEv NPY(+/+) and NPY(-/-) mice. In addition, susceptibility to pilocarpine- and kainate-induced seizures was compared in NPY(+/+) and (-/-) mice. The rate of amygdala kindling development did not differ in the NPY(-/-) and NPY(+/+) mice either when kindling stimuli were presented once daily for at least 20 days, or, 12 times daily for 2 days. However, during kindling development, the NPY(-/-) mice had higher seizure severity scores and longer afterdischarge durations than the NPY(+/+) mice. Post-kindling, the NPY(-/-) mice had markedly lower afterdischarge thresholds and longer afterdischarge durations than NPY (+/+) mice. Carbamazepine and levetiracetam increased the seizure thresholds of both NPY (-/-) and (+/+) mice. In addition, NPY (-/-) mice had lower thresholds for both kainate- and pilocarpine-induced seizures. The present results in amygdala kindling and chemical seizure models suggest that NPY may play a more prominent role in determining seizure thresholds and severity of seizures than in events leading to epileptogenesis. In addition, a lack of NPY does not appear to confer drug-resistance in that carbamazepine and levetiracetam were anticonvulsant in both wild type (WT) and NPY null mutant mice.     

Suppression of Interictal Spikes and Seizures by Stimulation of the Vagus Nerve

The effects of electrical stimulation of the vagus nerve, a proposed treatment for patients with intractable epilepsy, on focal interictal spikes produced by penicillin and EEG secondarily generalized seizures induced by pentylenetetrazol were assessed in rats. Interictal spike frequency was reduced by 33% during 20 s of stimulation (p < 0.001) and remained low for ≤3 min. Amplitude of residual spikes was also decreased. Cardiac and respiratory rates were suppressed. Cooling the nerve proximal to the point of stimulation abolished the EEG and respiratory effects. A similar reduction in spike frequency of 39% was obtained by heating the animals' tail (p < 0.01). Vagal stimulation at onset of seizures reduced mean seizure duration from 30.2 ± 15.7 s without stimulation to 5.0 ± 1.8 s (p < 0.01). Only the EEG equivalent of the clonic phase of the seizure was affected. These findings suggest that vagus nerve stimulation can be a potent but nonspecific method to reduce cortical epileptiform activity, probably through an indirect effect mediated by the reticular activating system.     

Changes of EEG synchronization during low-frequency electric stimulation of the seizure onset zone

PURPOSE: To assess whether EEG synchronization changes during short-term low-frequency electrical stimulation of the seizure onset zone. METHODS: In 10 patients (34+/-11 years) with pharmaco-resistant epilepsy the seizure onset zone (9 temporal lobe, 1 frontal lobe) was electrically stimulated at 1Hz for 5min via intracranial electrodes. Bipolar stimuli were applied and four pulse widths (0.05, 0.1, 0.5, and 1.0ms) were tested. Stimulation amplitudes were held fixed at 1mA for strip electrodes and at 2mA for depth electrodes. Changes of EEG synchronization were assessed by the eigenvalue dynamics of the cross-correlation matrix computed from a 2.5s sliding window. RESULTS: 37 stimulations were performed. We observed EEG desynchronization in 49% (18/37), an increase of EEG synchronization in 27% (10/37) and an EEG pattern with no significant change of synchronization in 24% (9/37). EEG synchronization most frequently occurred when stimulating with a pulse width of 0.5ms. In a patient with bilateral independent seizure onsets stimulation effects on EEG synchronization were different for each side. In the patient with the shortest duration of temporal lobe epilepsy, stimulation triggered periodic epileptic spikes phase-locked to stimulation. One patient experienced an aura during stimulation, which did not evolve into a seizure, and in one patient a sub-clincial seizure occurred. DISCUSSION: Low-frequency stimulation of the seizure onset zone is associated with different changes of EEG synchronization and its effects depend on the widths of the stimulation pulses. It may be an appropriate stimulation technique for long-term studies assessing whether synchronized or desynchronized brain dynamics prevent seizure occurrence.     

Paroxysmal discharges in the EL mouse, a genetic model of epilepsy

The EL/Suz (EL) mouse is a strain that is highly susceptible to convulsive seizures after repeated sensory stimulation. Its control strain, DDY/Jc1 (DDY), is less susceptible under similar conditions. The seizure prone phenotype is the result of differences at several genetic loci. In vivo electrical recordings from the seizure prone EL mouse brain have shown that the appearance of abnormal discharges in the hippocampus are critical to the onset of generalized seizures, indicating that the hippocampus plays an important role in EL mouse seizure activity. In the present study, electrophysiological differences between EL and DDY mice (9–15 weeks of age) were examined by comparing field potentials recorded from the dentate granule cell layer of hippocampal brain slices from mice that had not been stimulated to induce seizures. In control physiological solution, no significant differences were observed in characteristics of perforant path evoked field potentials or in paired pulse depression of evoked field potentials using 20 to 300 ms interstimulus intervals. After 60 min of disinhibition following bicuculline (10 μM) exposure, however, prolonged large amplitude potentials, paroxysmal discharges, were evoked by perforant path stimulation in the dentate gyrus of EL mice but were absent in the DDY strain. Paroxysmal discharges were curtailed by APV and were similar to responses recorded from the dentate gyrus in hippocampal brain slices from temporal lobe epileptic patients. The field response to hilar stimulation was identical in both strains and was composed of a single population spike before and after bicuculline exposure. Mossy fiber terminals were not present in the molecular layer of either strain. We propose that the mechanisms leading to a greater likelihood of paroxysmal discharge generation in EL mouse may be important in the development and/or generation of epileptic seizures in this mouse strain and may be a significant phenotypic difference between the EL mouse and its parent strain.     

Changes in brain thyrotropin-releasing hormone (TRH) of seizure-prone El mice

We examined the anticonvulsant effects of DN-1417 an analog of the thyrotropin-releasing hormone (TRH) in seizure-prone El mice. Changes in both immunoreactive TRH (IR-TRH) and TRH receptor binding activity in discrete brain regions of El mice were also measured before and after sensitization and during the postictal period, and they were compared with those in the ddY mice. Intraperitoneal injection of DN-1417 with 150 and 450 mg/kg significantly increased the El mouse seizure threshold in a dose-dependent manner. IR-TRH in the hippocampus of El mice, which was significantly lower than in ddY mice, significantly increased after sensitization. During the postictal period, however, it slowly decreased again and then gradually recovered to the preconvulsive level without any change in TRH receptor binding. In the striatum of El mice, although TRH receptor binding was significantly higher than in ddY mice, it was not affected by sensitization. These findings indicate that the hippocampal TRH system may play an inhibitory role in El mouse seizures whereas the striatal TRH system may be important for its seizure susceptibility.     

红藻氨酸诱导大鼠癫痫发作的电生理机制研究

目的　探讨红藻氨酸 ( KA)诱导大鼠复杂部分性癫痫发作的 EEG特点以及可能的电生理起搏点位置。方法　在立体定位指引下 ,将 EEG记录电极植入 1 2只大鼠双侧海马、额叶皮质或杏仁核中 ,其中 8只为实验组 ,4只为对照组。手术后 1周在大鼠清醒状态下 ,连续描记 KA或盐水注射后 EEG 1 2 0 min,观察 EEG波形、波幅以及频率的变化特点并记录每次电发作的起搏点位置。结果　 ( 1 ) KA注射后大鼠 EEG表现出多种形式的放电波形 ,典型波形有单棘波、多棘波、多相棘波、正相棘波、棘节律、节律性慢波、棘慢波等。 ( 2 )大鼠在凝视发作以及自动症发作时海马、杏仁核和额叶皮质均有异常放电。 ( 3) KA注射后大鼠电发作起搏点不固定。 ( 4 )各导放电频率多数情况下一致 ,偶有不一致现象。 ( 5 )存在亚临床放电。结论　 ( 1 ) KA注射后大鼠 EEG表现为多种形式的电发作活动 ;( 2 )大鼠在复杂部分性发作过程中不仅有边缘系统参与 ,也有边缘外额叶皮质参与 ;( 3)KA模型中 ,电发作起搏点不固定 ,KA注射后大鼠脑内可能存在一个异常的神经元网络 ,在网络中存在放电不均衡现象。