Noda Epileptic Rat Research Articles

Regional excitatory and inhibitory amino acid concentrations in Noda epileptic rat (NER) brain.

We measured regional concentrations of excitatory and inhibitory amino acids in Noda epileptic rat (NER) brains to investigate the mechanisms responsible for spontaneous generalized seizures. Compared with Fisher 344 (F344) rats and F1 hybrid (female NER x male F344 rat) rats, NERs had significantly higher concentrations of glycine in the cerebellum. NERs and F1 hybrid rats had significantly lower concentrations of taurine in the cerebellum than did F344 rats. Although our findings do not explain sufficiently the mechanisms directly responsible for spontaneous seizures, they suggest that the cerebellum of NER may be in an excited state to dampen seizures, while the cerebellum of F1 hybrid rats may also be slightly excited to inhibit milder forms of seizures. Further studies, including microdialysis and receptor binding assays, will be required to elucidate these mechanisms.

Elevated neuropeptide Y and corticotropin-releasing factor in the brain of a novel epileptic mutant rat: Noda epileptic rat

Noda epileptic rat (NER) is a new epileptic rat strain, which was developed by inbreeding rats with spontaneous tonic–clonic seizures in a stock of Crj:Wistar. In the present study, possible changes of two neuropeptides, neuropeptide Y (NPY) and corticotropin-releasing factor (CRF), in the brains of NER were investigated. Increased contents of immunoreactive (IR) NPY were found in the striatum and amygdala of 8-week NERs with partial seizure, while these changes extended to the limbic region including hippocampus in 16-week NERs with fully developed generalized tonic–clonic seizure. IR-CRF were elevated only in the entorhinal and pyriform cortex of both 8-week and 16-week NERs. Generalized tonic–clonic seizure in NERs induced a transient increase of NPY mRNA in the granular layer of dentate gyrus. These results suggest that NPY metabolism in the limbic brain contributes to the seizure susceptibility in this model of epilepsy.

P–490 - The role of hippocampus in acoustic priming-induced seizure in Noda epileptic rats (NER).

P–490 - The role of hippocampus in acoustic priming-induced seizure in Noda epileptic rats (NER).

Abnormality of Ca2+ Channels in CA3 Pyramidal Neurons of Noda Epileptic Rats (NERs)

Purpose: The Noda epileptic rat (NER), which was found in a colony of Crj‐Wistar rats, shows spontaneous tonic‐clonic convulsions. After 8–16 weeks of age, a long‐lasting depolarization shift accompanied by repetitive firing is observed in the CA3 pyramidal neurons of the hippocampus in NERs with seizures. This electrophysiologic study using hippocampal slice preparations from NERs was performed to determine whether this abnormal firing in CA3 neurons developed with age. and its probable relationship with the abnormality of Ca2+ channels was investigated pharmacologically. Methods: Hippocampal slices (400 μm) were prepared from NERs and normal Wistar rats (age, 4–24 weeks). A single rectangular pulse stimulus of 0.1‐ms duration was delivered to the mossy fibers every 5 s through a bipolar electrode placed in the granule cell layer of the dentate gyrus. A microelectrode was introduced into the pyramidal cell layer of CA3 for intracellular recording. A Ca2+ spike was elicited by applying a depolarizing pulse (1 nA, 120 ms) in the cell through the recording electrode filled with 3 M KCI under a blockade of Na+ and K+ channels by using 1 μM tetrodotoxin and 10 mM tetraethylammo‐nium added to the artificial cerebrospinal fluid (CSF), respectively. Nicardipine (1–100 nM), a Ca2+ channel blocker, was applied to the bath. Repeated weekly acoustic stimuli applied to NERs beginning at 3 weeks of age induced tonicxlonic convulsions from 6 weeks of age. Results: Twenty‐four slices from 12 NERs and 12 slices from 10 normal Wistar rats were used. The resting membrane potentials of CA3 neurons did not show any significant differences between the NER and Wistar rats tested. When a single stimulus was delivered to the mossy fibers of NERs >6 weeks of age, the CA3 neurons showed a long‐lasting depolarization shift (60.3 ± 5.8 ms; n = 3) accompanied by repetitive firing and an afterhyperpolarization after the abnormal firing. In addition, when higher stimulus intensities (>I2 V) were given, the abnormal firings were also evoked in the CA3 neurons of 4‐ to 5‐week‐old NERs when they did not show any seizures, although the depolarization shift in younger NERs (28.1 ± 1.9 ms; n = 3) was shorter than that in NERs older than 6 weeks. These abnormal firings were evoked in ∼30% of all the CA3 neurons of NERs tested in both groups. The age‐matched Wistar rats showed only a single action potential after a single mossy‐fiber stimulation. The input impedances of the CA3 neurons with abnormal firing (before 6 weeks of age, 24.9 ± 6.4 MR; after 6 weeks of age, 28.2 ± 1.6 MΩ) were lower than those without abnormal firing (37.8 ± 2.8 MΩ) and those of Wistar rats (40.1 ± 3.4 Ma). Bath application of nicardipine (10 nM) inhibited this long‐lasting depolarization shift accompanied by repetitive firing and an afterhyperpolarization without affecting the first spikes induced by mossy‐fiber stimulation. Furthermore, nicardipine (10 nM) inhibited the Ca2+ spikes elicited by applying a depolarizing pulse to neurons of NERs with seizures, although a higher dose (100 nM) did not affect those in Wistar rats. Conclusions: These findings indicate that the abnormal excitability of the CA3 pyramidal neurons in NERs is due to an abnormality in their Ca2+ channels. The abnormal excitability of NERs at an age when they did not display tonic‐clonic convulsions suggests that the hippocampus probably serves as an epileptogenic focus in NERs.

Development of Acoustic Priming‐Induced Abnormal Excitation in the Hippocampus of the Noda Epileptic Rat (NER)

Purpose: The Noda epileptic rat (NER), which was found in a colony of Crj:Wistar rats, shows spontaneous tonicxlonic convulsions at a frequency of approximately once per 30 h. However, weekly applied acoustic priming consistently induces tonic‐clonic convulsion with sound stimuli. When NERs were given sound stimuli (95 dB, 8 kHz, 30 s) weekly from age 3 weeks, the percentage of animals with audiogenic seizures increased with age and was 100% after age 9 weeks. The audiogenic‐response score to quantify the intensity of seizure responses also increased with age. Frontal cortical and hippocampal electroencephalograms (EEGs) showed low‐voltage spike‐and‐wave complexes during tonic convulsions, which evolved into high‐amplitude spike‐ or polyspike‐and‐wave complexes during clonic convulsion. Immediately after cessation of the seizures, the EEG showed a flattening or diffuse slowing. To elucidate the development of the seizure induction by acoustic priming, we examined the epileptiform discharges in the in‐terictal EEG as a function of age. Methods: The acoustic priming was applied to NERs from age 7 to 35 weeks. Cortical and hippocampal EEGs were recorded weekly during the interictal stage for 15 min after a 15‐min habituation by using implanted electrodes. Results: Sporadic spikes were observed predominantly in the hippocampus with age, although they were rarely synchronized in the cortex. Hippocampal spikes were observed in two (33.3%) of six animals at age 7–10 weeks, 23 (82.4%) of 28 animals at age 11–15 weeks, 12 (85.7%) of 14 animals at age 16–19 weeks, and 21 (100%) of 21 animals at age >20 weeks. This development of abnormal hippocampal discharges with acoustic priming was in line with the development of convulsive seizures. Conclusions: Development of hippocampal excitation induced by acoustic priming is thought to lead to the induction of convulsive seizures in the NERs.

Induction of convulsive seizures by acoustic priming in a new genetically defined model of epilepsy (Noda epileptic rat: NER).

Noda epileptic rat (NER) is a mutant rat, found in a Crj: Wistar colony, which exhibits a tonic clonic convulsion spontaneously about once per 30 h from 14 weeks of age. We performed modified acoustic priming, that is, repeated weekly sound stimulations from 3 weeks of age. In addition, characteristics of audiogenic seizure (AGS), and ictal/interictal electroencephalograms (EEGs) were examined. We also studied the effect of repeated weekly stimulations from 14 weeks of age on AGS susceptibility in another NER. From 9 weeks of age, the NER primed from 3 weeks of age had a high incidence (100%) of AGS: a typical seizure was composed of sudden wild running and/or jumping (WRJ) followed by clonic or tonic-clonic convulsion. The severity and the duration of the AGS were intensified and prolonged with an increase in age, respectively. By contrast, the NER repeatedly stimulated from the age of 14 weeks, rarely showed AGS (20-40(%). The majority of the seizures in this NER were WRJ. The cortical and hippocampal EEG during the tonic convulsion showed a low-voltage spike-wave (5-7 Hz). This evolved into a high-amplitude spike- or polyspike-waves associated with the clonic convulsion. Immediately after cessation of the seizures, the EEG showed a flattening or diffuse slowing. In interictal EEG analysis, sporadic spikes predominantly in the hippocampus and spike-wave bursts in both the cortex and hippocampus occurred from 11 and 20 weeks of age, respectively. These results indicate that AGS susceptibility in NER can be induced consistently by modified acoustic priming and this rat strain is a new genetic model useful for experimental studies of human epilepsy.

P-256 - Development of acoustic priming-induced excitation of hippocampus in Noda epileptic rats (NER)

P-256 - Development of acoustic priming-induced excitation of hippocampus in Noda epileptic rats (NER)

P-257 - Acoustic priming-induced abnormal excitation of auditory pathway in Noda epileptic rats (NER)

P-257 - Acoustic priming-induced abnormal excitation of auditory pathway in Noda epileptic rats (NER)

P-494 - Effects of auditory priming on CA3 pyramidal neurons of Noda epileptic rats (NER)

P-494 - Effects of auditory priming on CA3 pyramidal neurons of Noda epileptic rats (NER)

Induction of Seizures and Ictal Electroencephalogram in a New Genetically Defined Rat, Noda Epileptic Rats.

Induction of Seizures and Ictal Electroencephalogram in a New Genetically Defined Rat, Noda Epileptic Rats.

てんかん動物(SERとNER)を用いた抗てんかん薬の評価

Epileptic model animals, Spontaneously epileptic rat (SER) and Noda epileptic rats (NER), were examined to determine if they were useful for the evaluation of acute and chronic antiepileptic drugs. SER is a double mutant (zi/zi, tm/tm) exhibits tonic convulsion and absence-like seizures. The antiepileptic profile of a single application of conventional drugs in SER was similar to those found in human epilepsy. Novel antiepileptics such as topiramate, clobazam, and piracetam were successfully evaluated with SER for their anticonvulsant effects. The antiepileptic effects of repeated administrations of novel drugs could also be evaluated with this animal. The long-lasting effects of the antiepileptics were similar to those in human epilepsy. In SER hippocampal slices, long-lasting depolarization shift accompanying repetitive firing obtained in CA3 pyramidal cells with a single stimulation of the mossy fibers was inhibited by topiramate, but the firing induced by applying a depolarizing pulse in the cell was not affected, suggesting that the drug interferred with synaptic transmission in the mossy fiber-CA3 system of SER. Thus SER can also be empolyed for elucidating the mechanisms underlying the antiepileptic effects of the drug in question. Recently, a novel epileptic model animal NER, was developed. The clinical features resemble the tonicclonic seizures in human epilepsy. Multiple high voltage spikes appear in cotical EEG during seizures. The audiogenic seizures were induced by acoustic priming of a bell sound which had been given weekly to the NER since 3 weeks of age. This audiogenic seizure was inhibited by the conventional antiepileptics. Thus, both SER and NER are useful models for evaluating the acute and chronic antiepileptic effects of novel drugs.

P-498 - Automatic seizure recording using a novel image analyzing system in a genetically defined rat, Noda epileptic rats (NER)

P-498 - Automatic seizure recording using a novel image analyzing system in a genetically defined rat, Noda epileptic rats (NER)

P-499 - Induction of seizures developed by acoustic priming in a new genetically defined rat, Noda epileptic rats (NER)

P-499 - Induction of seizures developed by acoustic priming in a new genetically defined rat, Noda epileptic rats (NER)