Feline Temporal Lobe Epilepsy: Review of the Experimental Literature.

Accumulating evidence suggests that epileptic seizures originating from the temporal lobe (TL) occur in cats. Typically, affected animals have clinically focal seizures with orofacial automatisms including salivation, facial twitching, lip smacking, chewing, licking, and swallowing. Motor arrest and autonomic and behavioral signs also may occur. Many affected cats have magnetic resonance imaging (MRI) changes within the hippocampus or histopathologically confirmed hippocampal sclerosis or necrosis. From the 1950s to the 1980s, cats frequently were used as animal models for neurophysiological experiments and electrophysiological studies, from which important basic knowledge about epilepsy originated, but which has been rarely cited in clinical veterinary studies. These studies were reviewed. Experimental research on cats showed the widespread anatomical connections among TL structures. The ictal clinical signs originating from the hippocampus, amygdala, or lateral temporal cortex are similar, because of their dense interconnections. The ictal signs can be divided into autonomic, somatic, and behavioral. For research purposes, a 6-stage system was established, reflecting the usual sequential progression from focal to generalized seizure: attention response (1), arrest (2), salivation, licking (3), facial twitching (4), head turning or nodding (5), and generalized clonic convulsions (6). Knowledge of this data may help in recognizing low-stage (stage 1 or stage 2) epileptic seizures in clinical practice. Early experimental research data are in accordance with recent clinical observations regarding ictal clinical signs of TL epileptic seizures in cats. Furthermore, the research data supports the idea that TL epilepsy represents a unique clinical entity with a specific seizure type and origin in cats.

Sleep and arousal mechanisms in experimental epilepsy: epileptic components of NREM and antiepileptic components of REM sleep.

Neural generators related to different sleep components have different effects on seizure discharge. These sleep-related systems can provoke seizure discharge propagation during nonrapid eye movement (NREM) sleep and can suppress propagation during REM sleep. Experimental manipulations of discrete physiological components were conducted in feline epilepsy models, mostly in the systemic penicillin epilepsy model of primary generalized epilepsy and the amygdala kindling model of the localization-related seizure disorder, temporal lobe epilepsy. The sleep-wake state distribution of seizures was quantified before and after discrete lesions, systemic and localized drug administration, and/or photic stimulation, as well as in relation to microdialysis of norepinephrine. We found that (1) neural generators of synchronous EEG oscillations--including tonic background slow waves and phasic "arousal" events (sleep EEG transients such as sleep spindles and k-complexes)--combine to promote electrographic seizure propagation during NREM and drowsiness, and antigravity muscle tone permits seizure-related movement; (2) neural generators of asynchronous neuronal discharge patterns reduce electrographic seizures during alert waking and REM sleep, and skeletal motor paralysis blocks seizure-related movement during REM; (3) there are a number of similarities between amygdala-kindled kittens and children with Landau-Kleffner Syndrome (LKS) that suggest a link among seizures, sleep disorders, and behavioral abnormalities/regression.

Long-lasting effects of feline amygdala kindling on monoamines, seizures and sleep.

This report describes the relationship between monoamines, sleep and seizures before and 1-month after amygdala kindling in young cats (<1 year old; n=8; six female and two male). Concentrations (fmoles of norepinephrine or NE, dopamine or DA and serotonin or 5-HT) were quantified in consecutive, 5-min microdialysis samples (2 microl/min infusion rate) from amygdala and locus ceruleus complex (LC) during four, 6-8-h polygraphic recordings before (n=2) and 1 month post-kindling (n=2); 5-min recording epochs were temporally adjusted to correspond to dialysate samples and differentiated according to dominant sleep or waking state (lasting > or =80% of 5-min epoch) and degree of spontaneous seizure activity (number and duration of focal versus generalized spikes and spike trains and behavioral seizure correlates). Post-kindling records in each cat were divided into two groups (n=1 record each) based on higher or lower spontaneous EEG and behavioral seizure activity and compared to pre-kindling records. We found: (1) before and after kindling, NE and 5-HT but not DA concentrations were significantly lower in sleep than waking at both sites; (2) after kindling, each cat showed cyclic patterns, as follows: (a) higher NE, 5-HT and DA concentrations accompanied increased seizure activity with delayed sleep onset latency and increased sleep fragmentation (reduced sleep state percentages, number of epochs and/or epoch duration) in one recording versus (b) lower monoaminergic concentrations accompanied reduced seizure activity, rapid sleep onset and reduced sleep disruption in the other recording. The alternating, post-kindling pattern suggested "rebound" effects which could explain some controversies in the literature about chronic effects of kindling on monoamines and sleep-waking state patterns.

Monoamines and seizures: microdialysis findings in locus ceruleus and amygdala before and during amygdala kindling.

We used microdialysis to determine extracellular concentrations of norepinephrine (NE), dopamine (DA) and serotonin (5-HT) before and during a 1-day amygdala kindling paradigm. Subjects were young cats (<1 year old; n=8; 6 female, 2 male). Consecutive 5-min samples (2 microl/min infusion rate) were obtained from left amygdala and ipsilateral locus ceruleus complex (LC) under 3 experimental conditions lasting 1-h each (n=12 samples per cat per condition): (1) just before amygdala stimulation (baseline), (2) during focal afterdischarge (AD) and (3) during generalized AD. ADs were elicited by electrical stimulation applied to establish thresholds immediately before dialysate collection as well as during each sample collected in focal vs. generalized AD conditions. Sample concentrations were time-adjusted to correspond with sleep vs. waking state and/or focal vs. generalized ADs. Seizure activity was indexed by AD threshold (mA) and duration (s) as well as number and duration of specific clinically evident (behavioral) seizure manifestations. Main results were: (1) Lower baseline concentrations (fmoles per sample) of NE, DA and 5-HT correlated with subsequent increases in duration of focal and generalized AD as well as number of behavioral seizure correlates. (2) When compared to baseline levels, NE, DA and 5-HT concentrations significantly increased only in amygdala during focal AD and in both amygdala and LC during generalized AD. (3) NE and 5-HT concentrations were higher than DA at both collection sites and were selectively associated with increased wakefulness throughout the study.

Physiological basis: how NREM sleep components can promote and REM sleep components can suppress seizure discharge propagation.

OBJECTIVES: To describe how the neural generators of different sleep components can provoke seizure discharge propagation during NREM sleep and can suppress it during REM sleep. METHODS: Experimental manipulations of discrete physiological components were conducted in feline epilepsy models (n=64), mostly in the systemic penicillin epilepsy model of primary generalized epilepsy and the amygdala kindling model of the localization-related seizure disorder, temporal lobe epilepsy. Procedures included seizure induction as well as quantifying norepinephrine concentrations (microdialysis) and the sleep-waking state distribution of seizures before and after lesions, systemic and localized drug administration and/or photic stimulation. RESULTS: (1) Neural generators of synchronous EEG oscillations, including tonic background slow waves and phasic 'arousal' events (sleep EEG transients such as sleep spindles, k-complexes), can combine to promote electrographic seizure propagation during NREM and drowsiness; anti-gravity muscle tone permits seizure-related movement. (2) Neural generators of asynchronous neuronal discharge patterns can reduce electrographic seizures during alert waking and REM sleep; skeletal motor paralysis blocks seizure-related movement during REM. (3) Etiology of the seizure disorder can interact with sleep and arousal mechanisms to determine sleep-waking state distribution of interictal and ictal events. CONCLUSIONS: Differential effects of NREM versus REM sleep components on seizure discharge propagation are to some extent non-specific and in other ways specific to seizure etiology.

Monoamines and sleep: microdialysis findings in pons and amygdala.

This is the first microdialysis report comparing concentrations (pg/microliter) of norepinephrine (NE), serotonin (5-HT) and dopamine (DA) derived from feline locus ceruleus complex (LC) and amygdala. NE and 5-HT declined progressively from waking to slow-wave-sleep (SWS) and then to rapid-eye-movement (REM) sleep. Concentrations of DA did not change at either collection site across the sleep-wake cycle. We conclude that release of NE and 5-HT release modulates physiologic components related to the sleep-wake cycle, but DA does not.

Vasodilatory actions of the dietary peptide carnosine.

The objective of this study was to test the hypothesis that the dietary dipeptide carnosine (beta-alanine-L-histidine) causes direct decreases in arterial tone. Isolated descending thoracic aortic rings from male Sprague-Dawley rats were used for all studies. Preconstriction of vessels was accomplished with phenylephrine. Carnosine (0.625-20 mM) produced dose-dependent vascular relaxation (P < 0.05) that was independent of endothelium. The constituent amino acid L-histidine did not produce any significant relaxation over the same dose range, whereas beta-alanine actually produced dose-dependent vasoconstriction (P < 0.05). The soluble guanylate cyclase inhibitor methylene blue (10(-5) M) significantly decreased the relaxation produced by carnosine (P < 0.05). Measurement of cyclic GMP in the presence and absence of methylene blue after carnosine and phenylephrine exposure was also done. Methylene blue 10(-5) M resulted in a decrease in cyclic GMP levels from 65.3 +/- 15.6 fmol/mg protein to 8.6 +/- 0.9 fmol/mg of protein (P = 0.001). We conclude that carnosine produces relaxation of isolated rat aorta independent of endothelium. The effect of carnosine is at least in part mediated via cyclic GMP production and is not reproduced by its constituent amino acids, L-histidine and beta-alanine.

The alpha 2-adrenoreceptor agonist clonidine suppresses seizures, whereas the alpha 2-adrenoreceptor antagonist idazoxan promotes seizures in amygdala-kindled kittens: a comparison of amygdala and pontine microinfusion effects.

PURPOSE: We sought to determine whether local, in vivo microinfusion of an alpha 2-adrenoreceptor agonist and antagonist into either the amygdala or the pons (locus ceruleus, LC) would have contrasting effects on evoked amygdala-kindled seizure susceptibility. METHODS: The study population consisted of 6 amygdala-kindled kittens, each undergoing the same protocol, in which the amygdala microinfusion paradigm preceded the pontine microinfusion series. Microinfusions (1 microliter) of the alpha 2-agonist clonidine (CLON) and the alpha 2-antagonist idazoxan (IDA) were made over 1 min through cannulas adjacent to stimulating electrodes in the kindled amygdala or through cannulas adjacent to recording electrodes in the ipsilateral LC. Order of administered drugs (CLON vs. IDA) and dosages (n = 3 each) was partly counterbalanced. Focal and convulsive seizure thresholds were evaluated 10-12 min postinfusion and compared to thresholds obtained during two interspersed control conditions (vehicle control = 1 microliter microinfusion of sterile saline; sham control = needle insertion only). RESULTS: CLON significantly increased focal and generalized seizure thresholds, whereas IDA significantly reduced seizure thresholds when compared to controls. Magnitude of effects was dose dependent and more potent after pontine than amygdala microinfusion. CONCLUSIONS: Our results confirm and extent findings of previous researchers who used unlocalized in vivo manipulations to show that norepinephrine (NE) is a highly antiepileptic agent in the amygdala kindling preparation. With further investigation, the results may ultimately lead to development of microinfusion techniques as an alternative treatment option for limbic epilepsy.

The alpha 2 adrenoreceptor agonist clonidine suppresses seizures, whereas the alpha 2 adrenoreceptor antagonist idazoxan promotes seizures: pontine microinfusion studies of amygdala-kindled kittens.

This is the first report showing that microinfusion of alpha 2 adrenoreceptor agonists and antagonists into the vicinity of the locus ceruleus (LC) have contrasting effects on evoked amygdala-kindled seizure susceptibility. Microinfusion (1 microliter) of the alpha 2 agonist clonidine (CLON) and of the alpha 2 antagonist idazoxan (IDA) were made over 1 min through cannulae in the LC ipsilateral to the kindled amygdala in 6 kittens. Order of administered drugs (CLON vs. IDA) and dosages (n = 3 each) were partly counterbalanced. Focal and convulsive seizure thresholds were evaluated 10-12 min post-infusion and compared to thresholds obtained during two, interspersed control conditions (vehicle control = 1 microliter microinfusion of sterile saline; sham control = needle insertion only). CLON significantly elevated focal and generalized seizure thresholds, whereas IDA significantly reduced seizure thresholds when compared to controls. Magnitude of effects was dose-dependent. These findings confirm that norepinephrine (NE) is a potent antiepileptic agent. Results also suggest that pontine microinfusions could eventually provide an alternative treatment option for medically refractory limbic epilepsy.

Brainstem stimulation during sleep evokes abnormal rhythmic activity in thalamic neurons in feline penicillin epilepsy.

Some periods in the sleep-waking cycle are more seizure prone than others. In absence epilepsy, transition periods between nonrapid-eye-movement (nonREM) sleep and waking or REM sleep can be more seizure prone that stable states. One feature of transition periods that is hypothesized to promote seizure activity is the presence of coincident activity in ascending brainstem reticular formation (RF) arousal systems with synchronized thalamo-cortical activity. To evaluate this hypothesis we examined the state-dependent effects of low intensity RF stimulation on thalamic single unit activity in control conditions and following systemic penicillin-G administration to adult cats. In control conditions, RF stimulation during waking and REM sleep typically evoked a short-latency action potential in thalamic neurons. The same stimulation during nonREM sleep commonly evoked a high frequency burst of action potentials followed by a period of suppressed discharge. In 16/26 neurons, a second rebound burst of action potentials followed the period of discharge suppression. The average interval between the initial and rebound bursts was 75.1 +/- 6.0 ms, which was similar to the interburst interval recorded in these same cells during spontaneous EEG spindles. Following administration of penicillin-G, RF stimulation during nonREM sleep evoked high frequency burst firing, followed by 1-2 rebound bursts in 21/22 thalamic neurons. The average evoked interburst interval was 152.5 +/- 7.3 ms, a value comparable to the interburst interval displayed by these same cells during spontaneous spike-wave seizure activity (157.8 +/- 8.7 ms). RF-evoked rhythmic discharges were dependent upon the presence of thalamocortical synchronization, as responses evoked during waking and REM sleep in penicillin treated cats were similar to those observed in control conditions.

Circadian rhythm, sleep, and epilepsy.

This review article: (1) describes the circadian distribution of ictal and interictal events; (2) differentiates transitional arousal, non-rapid eye movement and rapid eye movement sleep components and their substrates; (3) suggests the means by which the neural generators of these seizure-prone vs. seizure-resistant sleep and arousal states modulate the timing of different seizure manifestations; (4) considers clinical and mechanistic findings for the reciprocal effects of seizures and antiepileptic drugs upon the sleep-wake cycle; and (5) assesses clinical and basic mechanisms of sleep deprivation effects upon seizures.

Paroxysmal microarousals in amygdala-kindled kittens: could they be subclinical seizures?

Amygdala-kindled kittens exhibit frequent epileptiform EEG transients, often in conjunction with phasic arousal events of sleep [k-complexes, pontogeniculo-occipital (PGO) waves, and/or sleep spindles]. In this study, paroxysmal microarousals occurred throughout the sleep-wake cycle after kindling, but were most frequent during seizure-prone states of slow-wave sleep (SWS) and the transition into rapid-eye-movement sleep (REM). Their incidence correlated with interictal sleep fragmentation as well as onset of spontaneous convulsions. Results could reflect transsynaptic kindling effects on brainstem and forebrain arousal mechanisms with which amygdala is reciprocally connected. Increased discharge rates of neural generators for normal EEG and behavioral arousal could disrupt sleep at some times and recruit epileptic neurons in the kindled focus to precipitate seizures at others. Alternatively, epileptiform EEG paroxysms were accompanied by subtle behavioral stereotypes (a head nod, limb elevation, eye twitch, lip smack, or a combination of these). Behavioral correlates were elements of partial kindled seizures, suggesting that paroxysmal microarousals may be subclinical seizures. Whether or not the microarousals are true seizures, our findings may link ictal onset and interictal sleep disorders to a subclinical paroxysmal arousal disorder and suggest a common epileptic mechanism.

Ontogeny of feline temporal lobe epilepsy. III: Spontaneous sleep and arousal disorders in amygdala-kindled kittens.

We report the ontogeny and persistence of sleep and arousal disorders in amygdala-kindled kittens. We also identify procedural differences that may explain discrepancies in the literature on postkindling sleep disorders. The study population consisted of 12 preadolescent kittens kindled between 2.5 and 6.5 months of age, 8 of which were followed to adulthood (> or = 1 year), and 8 unkindled implanted control animals. Sleep and seizure patterns were monitored on 12-24-h polygraphic or split-screen video recordings of EEG and behavioral activity. Kindled kittens displayed spontaneous seizure and interictal sleep anomalies that persisted to adulthood, as follows. As compared with neurosurgical controls, kindled kittens exhibited slow-wave sleep (SWS) and REM sleep insomnia at least 1 year after kindling and 1-5 months after convulsions, regardless of postictal recording delay. Sleep and arousal defects in kindled kittens were similar to but more pronounced than those in kindled adult cats, possibly because kittens spontaneously became epileptic. Detection of postkindling SWS insomnia could be masked by brief scoring epochs (less than the preferred 1-min epoch for cats); recurrent behavioral arousals after kindling frequently aborted 1-min SWS epochs but often did not interrupt 30-s SWS epochs (based on 1-min vs. 30-s minimum duration scoring criteria). Detection of postkindling REM sleep insomnia could be masked in kittens with alternating patterns of REM loss and REM rebound; all these kittens showed periodic bouts of REM onset from waking after kindling. Different data collection and analysis procedures influence detection of sleep and arousal disorders in amygdala-kindled cats when replication of findings is attempted. We conclude that these differences explain some controversies regarding the nature and prevalence of sleep disturbances in the kindling literature in temporal lobe epilepsy (TLE).

The alpha 2-agonist clonidine suppresses seizures, whereas the alpha 2-antagonist idazoxan promotes seizures--a microinfusion study in amygdala-kindled kittens.

This is the first report showing that local, in vivo microinfusion of alpha 2-adrenoreceptor agonists and antagonists have contrasting effects on amygdala-kindled seizure susceptibility. Microinfusions (1 microliter) of the alpha 2-agonist clonidine (CLON) and of the alpha 2-antagonist idazoxan (IDA) were made over 1 min through cannulae adjacent to stimulating electrodes in five amygdala-kindled kittens. Order of administered drugs (CLON vs. IDA) and dosages (n = 3 each) was partly counterbalanced. Focal and convulsive seizure thresholds were evaluated 10-12 min post-infusion and compared to thresholds obtained during two, interspersed control conditions (vehicle control: 1 microliter microinfusion of sterile saline; sham control: needle insertion only). CLON significantly elevated focal and generalized seizure thresholds, whereas IDA significantly reduced seizure thresholds when compared to controls. Magnitude of effects was dose-dependent. Results confirm and extend previous findings which employed unlocalized, in vivo manipulations to show that norepinephrine is a potent antiepileptic agent in the amygdala kindling preparation.

Ontogeny of feline temporal lobe epilepsy, II: Stability of spontaneous sleep epilepsy in amygdala-kindled kittens.

We previously described a model of spontaneous "sleep epilepsy" in kindled kittens with temporal lobe epilepsy (TLE). We now describe the postkindling course of this model from preadolescence to maturity and suggest pathophysiologic mechanisms. Spontaneous epilepsy, particularly generalized tonic-clonic convulsions (GTCs), developed 1h to 4 months after amygdala kindling and persisted to adulthood. At first, GTCs were detected only in sleep; later, convulsions also occurred during wakefulness. Two factors were consistently associated with the sequential onset of sleep and waking GTCs: seizure clusters and anatomic seizure localization. (1) Seizure clusters. Cats with infrequent or unclustered GTCs continued to exhibit "sleep epilepsy," defined by convulsions occurring exclusively during sleep. In contrast, cats with frequent seizure clusters developed recurrent or terminal convulsive status in conjunction with GTCs during waking and sleep. Severe seizure manifestations therefore appeared to contribute to the dissociation of convulsions from the sleep-wake cycle. (2) Anatomical seizure localization. Focal seizure origin appeared to differentiate sleep from waking GTCs. Onset during sleep was first recorded in the kindled amygdala, whereas onset during waking was initially detected outside the temporal lobe. Findings thus suggest secondary "kindling" of multifocal epilepsy. Secondary epileptogenesis is consistent with "transsynaptic" kindling effects. This phenomenon is defined in mature animals by rapid secondary site kindling (transfer) and subtle morphologic changes distal to the stimulating electrode. Transfer may be accentuated by youth, because kittens developed spontaneous seizure foci in previously unstimulated tissue. Moreover, multifocal interactions and diffuse cell loss were implicated as possible mechanisms. Collectively, the findings indicate complications with early onset TLE in kindled cats. Onset during youth can have an unfavorable prognosis, reflected by recurrent status epilepticus and multifocal epilepsy with convulsions distributed throughout the sleep-wake cycle.

Pontine regulation of REM sleep components in cats: integrity of the pedunculopontine tegmentum (PPT) is important for phasic events but unnecessary for atonia during REM sleep.

Transection, lesion and unit recording studies have localized rapid eye movement (REM) sleep mechanisms to the pons. Recent work has emphasized the role of pontine cholinergic cells, especially those of the pedunculopontine tegmentum (PPT). The present study differentiated REM sleep deficits associated with lesions of the PPT from other pontine regions implicated in REM sleep generation, including those with predominantly cholinergic vs non-cholinergic cells. Twelve hour polygraphic recordings were obtained in 18 cats before and 1-2 weeks after bilateral electrolytic or radio frequency lesions of either: (1) PPT, which contains the dorsolateral pontine cholinergic cell column; (2) laterodorsal tegmental nucleus (LDT), which contains the dorsomedial pontine cholinergic cell column; (3) locus ceruleus (LC), which contains mostly noradrenergic cells; or (4) subceruleus (LC alpha, peri-LC alpha and the lateral tegmental field), which also contains predominantly noncholinergic cells. There were three main findings: (i) Only lesions of PPT and subceruleus significantly affected REM sleep time. These lesions produced comparable reductions in REM sleep time but influenced REM sleep components quite differently: (ii) PPT lesions, estimated to damage 90 +/- 4% of cholinergic cells, reduced the number of REM sleep entrances and phasic events, including ponto-geniculooccipital (PGO) spikes and rapid eye movements (REMs), but did not prevent complete atonia during REM sleep: (iii) Subceruleus lesions eliminated atonia during REM sleep. Mobility appeared to arouse the cat prematurely from REM sleep and may explain the brief duration of REM sleep epochs seen exclusively in this group. Despite the reduced amount of REM sleep, the total number of PGO spikes and REM sleep entrances increased over baseline values. Collectively, the results distinguish pontine loci regulating phasic events vs atonia. PPT lesions reduced phasic events, whereas subceruleus lesions created REM sleep without atonia. Severe REM sleep deficits after large pontine lesions, including PPT and subceruleus, might be explained by simultaneous production of both REM sleep syndromes. However, extensive loss of ACh neurons in the PPT does not disrupt REM sleep atonia.

Spontaneous sleep epilepsy in amygdala-kindled kittens: a preliminary report.

We describe a model of 'sleep epilepsy' after amygdala kindling in kittens. Seizure activity was evaluated at different times in the sleep-wake cycle. Susceptibility was documented by thresholds for evoked convulsions in kittens without spontaneous seizures (n = 5) and by polygraphic or split-screen video recordings in kittens with spontaneous seizures (n = 6). There were 3 main findings: (1) subconvulsive seizures occurred randomly in waking and slow-wave-sleep (SWS); (2) convulsive seizure activity peaked during SWS, especially during the transition from SWS into rapid-eye-movement (REM) sleep; (3) generalized seizure activity was suppressed during stable REM sleep. Seizure patterns thus resemble clinical data designating convulsive temporal lobe epilepsy (TLE) the prototypic pure sleep epilepsy, whereas complex-partial TLE can occur at any time. Prominent secondary TLE generalization during the REM transition suggested involvement of brainstem regions which generate REM onset and innervate the temporal lobe. Adrenergic cells of the locus ceruleus discharge at progressively reduced rates during the transition into REM. Decreased norepinephrine release at this time might disinhibit epileptic neurons in the kindled focus, thus encouraging seizure propagation during the REM transition.

Lesions producing REM sleep without atonia disinhibit the acoustic startle reflex without affecting prepulse inhibition.

This study determined whether the brainstem motor inhibition system that mediates muscle atonia during rapid eye movement (REM) sleep is involved in the elicitation and prepulse inhibition of the acoustic startle reflex. Electrolytic or neurotoxic (glutamate) lesions were made in the dorsolateral pontine tegmentum or the medial medulla, respectively, to produce the syndrome of REM sleep without atonia. Startle responses were released during REM sleep following the lesions. However, the amount of startle suppression produced by auditory prepulse after the lesion did not differ from that seen in intact controls. We conclude that REM sleep suppression of the acoustic startle responses is mediated by the system responsible for tonic motor inhibition, but auditory prepulse inhibition of the acoustic startle is not.

The ontogeny of feline temporal lobe epilepsy: kindling a spontaneous seizure disorder in kittens.

We describe the ontogeny of feline temporal lobe epilepsy after amygdala kindling in 24 cats, aged 2.5 months to over 1 year. In so doing, we report the first experimental model of spontaneous epilepsy in immature animals. Preadolescent kittens (n = 12 less than or equal to 6.5 months) are far more likely to develop epilepsy, indexed by spontaneous seizures, than are adult cats (n = 12 greater than 1 year). Moreover, youth accelerated the development of epilepsy. The younger the kitten at the beginning of kindling, the more probable and rapid the onset of spontaneous seizures. Failed postictal depression was the most reliable precursor of spontaneous seizures in immature cats. However, spontaneous epilepsy continued after postictal refractory periods stabilized and was still present when kittens matured to adulthood. Collectively, the results suggest that failed inhibition contributes to the onset of spontaneous epilepsy in immature animals but that other morphologic, physiological and/or chemical changes might sustain epilepsy afterwards.

Effects of systemic atropine sulfate administration on the frequency content of the cat sensorimotor EEG during sleep and waking.

Sensorimotor electroencephalogram (EEG) frequencies in cats were evaluated with power spectral analysis before and after 3 doses of atropine sulfate. All doses of atropine tested caused enhanced EEG slow waves (0-7 Hz) and spindles (8-15 Hz) during waking immobility, and postdrug frequency profiles during slow-wave sleep and waking immobility were identical. With 0.75 mg/kg atropine, movement (head movement, locomotion) resulted in EEG desynchronization and reduced power in all frequencies less than 24 Hz. After 1.5 or 3.0 mg/kg atropine, power in low frequencies remained elevated during movement, but power in spindle frequencies was significantly reduced compared with other states. During active REM sleep after 1.5 mg/kg atropine, power in spindle frequencies was significantly lower than that during quiet REM sleep. These results indicate that the sensorimotor cortical EEG in cats is under the control of multiple systems. At least 1 of these systems is active during movement, and its actions are resistant to muscarinic receptor blockade.