Flurothyl Seizures Research Articles

Intraventricular administration of gabapentin in the rat increases flurothyl seizure threshold

Introduction: We investigated efficacy of prolonged intraventricular gabapentin (GBP) infusion in the rat flurothyl epilepsy model. Methods: Sprague–Dawley rats, under anesthesia, were implanted with bilateral Alzet model 2001 osmotic pumps. The pumps infused GBP 80 μg/μL (3.8 mg/day) or isotonic saline control at 1.0 μL/h into each ventricle for 5 days. After 5 days of GBP infusion, seizures were induced by flurothyl dripped onto filter paper. Time to first myoclonic jerk, first partial seizure and first tonic–clonic seizure was recorded by an observer unaware of the treatment group. Determination of seizures was behavioral. Results: Data were obtained from 54 rats. First tonic–clonic seizure was at 295.8 ± 58.8 s ( n = 28) for control rats, versus 338.0 ± 89.9 s ( n = 26) for rats with GBP in the pump ( p = 0.049). First myoclonic jerk occurred at 158.7 ± 20.8 versus 164.6 ± 33.5 s ( p = 0.44, n.s.). Regression of time to seizure versus weight was not significant. No animal had measurable serum levels (<1 μg/ml) of GBP. The distribution of GBP in brain was not studied, but qualitative observations of methylene blue dye installed in the pumps showed dye in periventricular white matter and also over cortex, especially ipsilaterally. Discussion: GBP instilled into the lateral ventricles by pump for 5 days delays onset of generalized tonic–clonic seizures produced by flurothyl in the rat. Time to first myoclonic or partial seizure was not influenced. Effects were not due to systemic absorption of GBP. This study provides a proof-in-principle for intraventricular therapy with AEDs.

Irradiation exacerbates cortical cytopathology in the Eker rat model of tuberous sclerosis complex, but does not induce hyperexcitability

Tuberous sclerosis complex (TSC) is an autosomal dominant disorder characterized by multi-organ pathologies. Most TSC patients exhibit seizures, usually starting in early childhood. The neuropathological hallmarks of the disease - cortical tubers, containing cytopathological neuronal and glial cell types - appear to be the source of seizure initiation. However, the contribution of these aberrant cell populations to TSC-associated epilepsies is not fully understood. To gain further insight, investigators have attempted to generate animal models with TSC-like brain abnormalities. In the current study, we focused on the Eker rat, in which there is a spontaneous mutation of the TSC2 gene (TSC2+/-). We attempted to exacerbate TSC-like brain pathologies with a "second-hit" strategy - exposing young pups to ionizing irradiation of different intensities, and at different developmental timepoints (between E18 and P6). We found that the frequency of occurrence of dysmorphic neurons and giant astrocytes was strongly dependent on irradiation dose, and weakly dependent on timing of irradiation in Eker rats, but not in irradiated normal controls. The frequency of TSC-like pathology was progressive; there were many more abnormal cells at 3 months compared to 1 month post-irradiation. Measures of seizure propensity (flurothyl seizure latency) and brain excitability (paired-pulse and post-tetanic stimulation studies in vitro), however, showed no functional changes associated with the appearance of TSC-like cellular abnormalities in irradiated Eker rats.

Flurothyl seizures susceptibility is increased in prenatally methamphetamine-exposed adult male and female rats

The purpose of the present study was to examine the effect of prenatal methamphetamine (MA) exposure on flurothyl seizures. Adult prenatally MA-exposed male rats had decreased threshold of the first fasciculation and clonic seizure. In adult female rats, prenatal MA exposure decreased the threshold of the first fascicualtion in diestrous females, while there were no changes in proestrous or estrous females. The tonic–clonic seizure threshold was not altered by prenatal MA exposure.

Cognitive impairment following status epilepticus and recurrent seizures during early development: support for the “two-hit hypothesis”

Prolonged seizures in immature rats result in minimal behavioral consequences when the animals are studied later in life. Likewise, early-onset seizures are associated with minimal morphological changes. However, it is known that seizures early in life result in changes in the brain that make it more vulnerable to subsequent seizure-induced injury (the so-called two-hit hypothesis). Whether this heightened vulnerability occurs immediately after the first seizure is not known. In this study, immature rats were exposed to status epilepticus (SE) followed by a series of 25 flurothyl-induced seizures, SE alone, 25 flurothyl-induced seizures alone, or no seizures. Rats exposed to SE and flurothyl seizures performed significantly poorer in the water maze 2 weeks following the last seizure compared with the other groups. No histological lesions were seen in any of the four groups. This study suggests that SE renders the immature brain vulnerable to further seizure-induced injury and this enhanced vulnerability occurs very quickly after the SE.

Detrimental effects of the ketogenic diet on cognitive function in rats.

The ketogenic diet (KD) is a high-fat, low-carbohydrate, and low-protein diet that is widely used to treat epilepsy in children. Although the KD has been shown to be efficacious in the treatment of childhood epilepsy, the long-term effects of the KD on brain development are not clear. The objective of this study was to examine the long-term effects of the KD on visual-spatial memory, activity level, and emotionality in immature rats after status epilepticus (SE). Weanling rats were subjected to lithium/pilocarpine-induced SE or saline injections and were then randomized to either the KD or regular rat diet, both fed ad libitum. One month later, rats were evaluated for visual-spatial memory in the water maze, activity level in the open field test, and emotionality with the handling test. Spontaneous recurrent seizures were measured using videotaping, and seizure susceptibility was tested with flurothyl inhalation. Brains were weighed and examined for mossy fiber sprouting and cell loss. Although rats treated with the KD were active and seemed healthy, their weight gain was substantially lower than that in rats that received regular rat diet. The KD reduced the number of spontaneous seizures but had no discernible effect on flurothyl seizure susceptibility. KD-fed rats, with or without SE, had significantly impaired visual-spatial learning and memory compared with rats that were fed regular diet. The KD had minimal effects on activity level and emotionality. Rats that were treated with the KD had significantly impaired brain growth. No differences in pathology scores between the KD and regular diet groups were seen after SE. Despite reducing the number of spontaneous seizures after SE, the KD resulted in severe impairment in visual-spatial memory and decreased brain growth, with no effect on mossy fiber sprouting. This study raises concerns about the long-term effects of the KD on brain development.

The effect of electrical stimulation of the subthalamic nucleus on seizures is frequency dependent.

Animal studies and anecdotal human case reports have indicated that the subthalamic nucleus (STN) may be a site of anticonvulsant action. We tested the hypothesis that continuous electrical stimulation of the STN inhibits seizures acutely. We determined the effects of three stimulation frequencies, 130 Hz, 260 Hz, and 800 Hz, on generalized clonic and tonic-clonic flurothyl seizures. Adult male rats were implanted with concentric bipolar stimulating electrodes in the STN bilaterally. After recovery, rats underwent flurothyl seizures to compare the effects of each stimulation frequency on seizure threshold. Rats were tested 4 times, twice in the stimulated condition, and twice in the unstimulated condition. The order of trials was random, except that stimulation trials alternated with control trials. Flurothyl seizure thresholds under each stimulation condition were compared with control values from the same animal. Bilateral stimulation of the STN at 130 Hz produced a significant increase in the seizure threshold for clonic flurothyl seizures, whereas stimulation at 260 Hz did not appear to have any effect on seizures. STN stimulation at 800 Hz significantly lowered seizure threshold for tonic-clonic seizures. We conclude that electrical stimulation of the STN can be anticonvulsant, but the effects appear to depend on the stimulation frequency and the type of seizure.

Correlation between extracellular glucose and seizure susceptibility in adult rats.

In adult diabetic patients, periods of hyperglycemia may be associated with exacerbation of focal seizures. Our objective was to determine in the adult rats the correlation between seizure susceptibility and extracellular glucose concentration in two models of seizures. Male rats were injected with two doses of streptozocin (40 mg/kg IP) on 2 consecutive days to induce diabetic hyperglycemia. Controls either received vehicle or were not injected. After 2 weeks, blood glucose concentration was measured, and the rats were subjected to flurothyl seizure test. Another group of rats received glucose solution (20%, 5 ml IP) 30 minutes before testing to induce nondiabetic hyperglycemia. Thresholds for flurothyl-induced clonic and tonic-clonic seizures were determined. Finally, in vitro epileptiform activity was induced in the entorhinal cortex-hippocampal slices from naive rats by perfusing with magnesium-free medium with various glucose concentrations. In additional slices, paired-pulse paradigm was determined in the perforant path. Susceptibility to clonic and tonic-clonic flurothyl-induced seizures positively correlated with blood glucose concentrations as the increased glucose concentration was associated with proconvulsant effects. Similarly, in the in vitro experiments, epileptiform activity was promoted by increased and suppressed by decreased glucose concentrations. Data indicate that, in the adult rats, high glucose concentrations are associated with proconvulsant effects.

Developmental aspects of the basal ganglia and therapeutic perspectives

ABSTRACT Development and sex hormones play an important role in the expression of seizures. Sex‐specific differences in the development of seizure‐suppressing neuronal networks may account, at least in part, for age‐ and sex‐related susceptibility to seizures. The substantia nigra pars reticulata is a site involved in the control of seizures. In adult male rats, there are two distinct GABA A sensitive regions within the substantia nigra pars reticulata, which mediate opposite effects in flurothyl seizures. Muscimol infused into the anterior region is anticonvulsant while similar infusions into the posterior region are proconvulsant. These two regions differ morphologically, and utilize different efferent networks. In contrast, in postnatal day 15 male rats, there is no such differentiation and muscimol infusions have only proconvulsant effects. The hallmark of the female substantia nigra pars reticulata is the fact that muscimol‐mediated proconvulsant effects cannot be demonstrated in any region at any age. The sex‐related difference in nigral seizure control may be related to the lack of testosterone in females. Accordingly, neonatal castration of males results in the loss of the “proconvulsant” region. The “male” type of the substantia nigra pars reticulata effects can be induced by exogenous testosterone administration in neonatally castrated male or in female rats. The phenotype of nigral GABAergic neurons, as characterized by GABA A receptor subunit composition, muscimol‐induced electrophysiological responses, and connectivity of output networks may each be altered by the presence of testosterone. Better understanding of the influence of the endocrine system on brain development and neuronal activity may provide new insight into the treatment of age‐ and sex‐dependent seizure disorders.

Sex differences in androgen and estrogen receptor expression in rat substantia nigra during development: an immunohistochemical study

Gonadal hormones are important regulators of sexual differentiation of the CNS. Exposure to testosterone and estrogen during development causes permanent organizational differences between males and females. We previously described functional sex-related differences of the GABA Aergic circuits of the rat substantia nigra pars reticulata (SNR) involved in the control of flurothyl seizures. This sexual differentiation of the SNR is regulated by postnatal testosterone. To assess whether the organizing effects of testosterone in the SNR are mediated via the androgen receptor (AR) and/or estrogen receptors (ER), we used immunohistochemistry to study the ontogeny of AR, ERα and ERβ expression in SNR and substantia nigra pars compacta (SNC) of male and female rats. Rats on the day of birth [postnatal day (PN) 0] and at PN1, PN5, PN15 and PN30 were used. AR- and ERβ-immunopositive cells were present in SNR and SNC in both sexes and at all ages. ERα was not detected in male and female SNC at PN0–PN1. In both substantia nigra (SN) regions, there were developmentally regulated sex differences in AR, ERα and ERβ immunoreactivity. In the SN, each receptor showed specific intracellular localization: AR was present in the nucleus, ERα and ERβ were present both in nuclear and extranuclear compartments. ERα was detected also in processes. At PN0–PN1, quantitative analysis revealed sex and regional differences in the distribution of SN cells expressing AR and ERα, while ERβ were equally present in both sexes. The presence of gonadal steroid receptors in the SN suggests that the biological effects of gonadal hormones in the CNS extend beyond reproduction-related functions and may affect and modify motor behaviors (including seizures) in a sex-specific manner. Based on the ontogeny of SNR ERβ, we hypothesize that postnatal injections of testosterone may regulate the nigral GABA A system through the aromatization pathway and activation of ERβ.

Differences in hippocampal mitotic activity within the dorsal and ventral hippocampus following flurothyl seizures in mice

To date, there is little information regarding the regional division (dorsal and ventral) of hippocampal mitotic activity at either baseline or following seizures. To determine the regional distribution of hippocampal mitotic activity, animals were given seizures followed by injections of 5-bromo-2′-deoxyuridine (label for mitotic cells). Our results indicate that the baseline and seizure-induced levels of mitotic activity (neurogenesis) are greater in the dorsal hippocampus as compared to the ventral hippocampus. Moreover, seizures were able to significantly increase mitotic activity in both dorsal and ventral hippocampus with a greater proportional increase from baseline in the ventral hippocampus as compared to the dorsal hippocampus. These results suggest that the amount of mitotic activity differs between the dorsal and ventral hippocampus and suggests that seizure activity is capable of differentially driving mitotic activity in the dorsal and ventral hippocampus.

Altered flurothyl seizure induction latency, phenotype, and subsequent mortality in a mouse model of juvenile neuronal ceroid lipofuscinosis/batten disease.

Juvenile neuronal ceroid lipofuscinosis (JNCL), or Batten disease, is a pediatric neurodegenerative disease characterized by vision loss, seizure activity, cognitive decline, and premature death. Discovery of the Batten disease-related gene, CLN3, led to creation of a Cln3 protein-deficient mouse model (Cln3-/-), which recapitulates some of the histopathologic characteristics of the human condition. We hypothesized that lack of Cln3 would alter seizure-related behavioral parameters. Using flurothyl gas inhalation, we examined seizure-induction latencies in Cln3-/- mice and wildtype (wt) controls at time points that represent late neonatal, immature, mature, and aged time points. We examined latency to first myoclonic jerk (LMJ), latency to loss of posture (LOP), and subsequent mortality. Our results demonstrate an age-dependent alteration of seizure-induction latencies in Cln3-/-. Immature Cln-/- mice aged 35-42 days had an increased latency to both LMJ and LOP compared with age-matched wt controls. There were no significant latency differences between Cln3-/- and wt at other time points examined. Mortality after generalized seizure was high in both Cln3-/- and wt animals at late neonatal and immature developmental stages. No mortality was seen in wt mice past maturity at 6 weeks. Mature and aged Cln3-/- animals retained a vulnerability to death after seizure activity. These results suggest that a deficiency of Cln3 protein in the Batten model mice may result in age-dependent alteration of the neuroanatomic and biochemical substrates involved in seizure propagation and recovery. This may be important in understanding seizures, neurodegeneration, and premature death in human Batten disease.

Lack of robust anticonvulsant effects of muscimol microinfusions in the anterior substantia nigra of kindled rats

The substantia nigra pars reticulata is thought to control the spread of seizures in various seizure models. Potentiation of γ-aminobutyrate (GABA)-mediated transmission in this region by intranigral administration of drugs such as muscimol has been shown to inhibit seizure propagation in such models, including the kindling model of epilepsy. More recent studies have shown that the effects on seizures are site-specific within the substantia nigra pars reticulata. Using flurothyl to induce clonic seizures, it was reported that bilateral microinfusions of muscimol into the anterior substantia nigra pars reticulata were anticonvulsant, while similar infusions into the posterior pars reticulata were proconvulsant. This prompted us to reevaluate the effects of intranigral muscimol in the kindling model with particular emphasis on the anterior substantia nigra pars reticulata. In amygdala kindled rats, muscimol was bilaterally infused into the anterior pars reticulata at doses of either 60 or 120 ng. Thirty minutes later, the threshold for induction of afterdischarges in the amygdala and the threshold for generalized seizures were determined in each rat. Furthermore, severity and duration of seizures at threshold currents were recorded. Unexpectedly, muscimol failed to increase seizure thresholds or to significantly reduce seizure severity or duration of motor seizures, although there was a moderate reduction in motor seizure duration in several rats. The data indicate that, in contrast to flurothyl seizures, in kindled rats the anterior pars reticulata of the substantia nigra is not a site at which muscimol causes robust anticonvulsant effects.

Behavioral and metabolic features of repetitive seizures in immature and mature rats

Seizure incidence varies significantly with age, with seizure susceptibility particularly high during the first few years of life. Of significant concern is what effects do brief, repetitive seizures have on the developing brain. We approached this issue by examining the change in seizure threshold, and related markers of neuronal activity and metabolic activity (c-fos mRNA and 2-deoxyglucose [2DG]), as a function of repetitive seizure episodes in immature and mature rats. Starting on postnatal day 15 (P15) (immature) or P60 (adult) rats were given two flurothyl seizures a day for 5 days (nine or ten seizures). The seizure latency profile, our measure of threshold, in immature versus adult rats across the 5-day testing period was different. In immature rats, threshold for the second seizure on each day was significantly lower than for the first seizure, suggesting that there was little refractoriness after the first seizure of the day. In contrast, the mature animal had a significantly longer threshold latency to the second seizure for the first 3 days of testing. The immature animal was also more likely than the adult to exhibit tonic extension as a feature of the first seizure of the day. Following repetitive seizures, more regions of the CNS showed c-fos mRNA expression in the immature animal than adults, suggesting that repetitive seizures in the immature animal activated a greater percentage of the brain. Compared with the effects of a single seizure, repetitive seizures resulted in less 2DG labeling in most regions of the brain (except the hippocampus); in the immature brain this difference was more distinct than in adults. The consequences of repetitive seizures in the immature animal results in distinctly different seizure behavior and neuronal activity pattern (c-fos expression) than that observed in the mature animal.

Effect of ganaxolone on flurothyl seizures in developing rats.

To determine the effects of a newly synthesized epalon, ganaxolone (GNX), on primarily generalized seizures in rats of various ages during development. Epalons are classified as neuroactive steroids that interact at unique site of the GABAA receptor-Cl- channel complex in the central nervous system. Sprague-Dawley male rats were used at 9, 15, 30, and 60 postnatal days (PN). GNX dissolved in 2-hydroxypropylbeta-cyclodextrine was administered intraperitoneally in different doses at various time points before flurothyl testing. The incidence and threshold of clonic and tonic-clonic flurothyl seizures were evaluated. Behavioral changes were also assessed. In all age groups, the effects of GNX were dose dependent and more prominent 10 min after its administration. In PN 60 and PN 30 rats, GNX had dose-dependent anticonvulsant effects; tonic-clonic seizures were more sensitive to GNX treatment than clonic seizures. In PN 15 and PN 9 rats, GNX demonstrated dose-and time-dependent anticonvulsant effects against both types of flurothyl-induced seizures. GNX was more effective in PN 15 rats than in other age groups, but at doses that altered motor behavior. GNX has anticonvulsant effects against flurothylinduced seizures in all age groups tested. Its effects are more prominent in the two younger age groups, especially in PN 15 rats, but are associated with motor side effects.

Malnutrition increases dentate granule cell proliferation in immature rats after status epilepticus.

Nutritional insults early in life have a profound and often permanent effect on the development of the central nervous system. A direct relationship between malnutrition and epilepsy has not been established; however, it is believed that inadequate nutrition may predispose the brain to seizures. This study was designed to determine whether neonatally malnourished rats are different from nourished rats in terms of flurothyl seizure susceptibility at postnatal day (P)15, in the behavioral manifestations of seizures, and in status epilepticus-induced hippocampal injury. Sprague-Dawley rat pups were maintained on a starvation regimen from P2 until P17. Age-matched control rats were not exposed to starvation. At P15, all animals were exposed to flurothyl-induced status epilepticus. At P17, the rats received a single injection of bromodeoxyuridine (50 mg/kg intraperitoneal) to determine the extent of genesis of new cells in the dentate gyrus. At P18, the rats were killed, and the brains were processed for histology and immunohistochemistry. Preliminary analysis indicates that early malnutrition did not modify flurothyl seizure susceptibility or the behavioral manifestations of seizures at P15. Histological assessment did not reveal any evidence of hippocampal cell loss after status epilepticus in either group. Malnutrition per se induced an increase in the genesis of new cells in the anterior dentate granule cell layer. Although exposure to status epilepticus augmented the expression of new cells in the dentate gyrus in both groups, this expression was more pronounced in the malnourished group. The findings suggest that malnutrition early in life alters dentate plasticity but not the susceptibility to flurothyl seizures. Although status epilepticus can increase the expression of new cells in the dentate gyrus in immature rats, malnutrition followed by status epilepticus further increases dentate granule cell proliferation.

Prenatal Methotrexate Exposure Decreases Seizure Susceptibility in Young Rats of Two Strains

Effects of prenatal exposure to methotrexate (MTX) administered in Sprague–Dawley (one 5 mg/kg dose of MTX on gestational day 15; E15) or Wistar (one 5 mg/kg dose of MTX on E14 or E15 or two such doses on E15) pregnant rat dams were studied in developing offspring. Young Sprague–Dawley rats were subjected to rapid kindling on postnatal days (PN) 15 and 16, and to flurothyl seizures on PN 15 and PN 30. Offspring of the Wistar strain were tested in flurothyl on PN 30. In Sprague–Dawley rats, prenatal exposure to MTX decreased susceptibility to kindling-induced seizures on PN 15 and to flurothyl-induced clonic seizures on PN 30. In Wistar rats, a single dose of MTX on E15 was ineffective, but two doses significantly decreased susceptibility to flurothyl-induced seizures. Additionally, due to a shorter duration of pregnancy in Wistar rats, exposure to a single dose of MTX on E14 also decreased susceptibility to flurothyl seizures. MTX, as folic acid antagonist, interferes with DNA synthesis. However, unlike other treatments that suppress DNA synthesis (such as methylazoxymethanol exposure or X-ray radiation), MTX exposure results in anticonvulsant effects in surviving offspring. The data suggest that not all prenatal impairments of DNA have proconvulsant features postnatally.

Long-term effects of neonatal seizures: a behavioral, electrophysiological, and histological study

Previous studies have demonstrated that recurrent seizures during the neonatal period lead to permanent changes in seizure threshold and learning and memory. The pathophysiological mechanisms for these changes are not clear. To determine if neonatal seizures cause changes in hippocampal excitability or inhibition, we subjected rats to 50 flurothyl-induced seizures during the first 10 days of life (five seizures per day). When the rats were adults, we examined seizure threshold using flurothyl inhalation, and learning and memory in the water maze. In separate groups of animals, we evaluated in vivo paired-pulse facilitation and inhibition in either CA1 with stimulation of the Schaffer collaterals or dentate gyrus with stimulation of the perforant path. Following these studies, the animals were sacrificed and the brains evaluated for mossy fiber sprouting with the Timm stain. Compared to control animals, rats with 50 flurothyl seizures had a reduced seizure threshold, impaired learning and memory in the water maze, and sprouting of mossy fibers in the CA3 pyramidal cell layer and molecular layer of the dentate gyrus. No significant differences in impaired paired-pulse inhibition was noted between the flurothyl-treated and control rats. This study demonstrates that recurrent neonatal seizures result in changes of neuronal connectivity and alterations in seizure susceptibility, learning and memory. However, the degree of impairment following 50 seizures was modest, demonstrating that the immature brain is remarkably resilient to seizure-induced damage.

Age-dependent differences in flurothyl seizure sensitivity in mice treated with a ketogenic diet

Despite strong clinical data confirming the anticonvulsant efficacy of a ketogenic diet (KGD) in pediatric patients, corroborative experimental data in young animals are limited. In the present study, the effects of a KGD on flurothyl seizure susceptibility were examined in normal juvenile mice after a dietary duration of 3, 7, or 12 days, and in adult mice for 15 days. In all groups of KGD-treated mice, blood β-hydroxybutyrate levels were significantly elevated over those measured in controls. The present KGD was anticonvulsant (i.e. delayed onset) against the first (clonic) flurothyl-induced seizure for juvenile mice treated for either 7 or 12 days, but not for juvenile mice and adult mice fed the diet for 3 and 15 days, respectively. While this KGD was not anticonvulsant against the second (tonic extension) seizure induced by flurothyl in any of the juvenile groups, it significantly delayed tonic extension in the adult group. In addition, juvenile mice fed a KGD exhibited a lower mortality rate following flurothyl-induced seizures compared to mice fed a standard diet. In our discussion of animal models of the KGD, we highlight the need to understand better the impact of important variables such as dietary composition, genetic background, and mode of seizure induction in the study of the KGD.

Effect of seizures on cerebral hypoxic–ischemic lesions in immature rats

The present investigation was designed to study the effect of chemically induced seizures on cerebral hypoxic–ischemic (HI) damage in immature animals. Accordingly, cerebral HI was produced in 7-day postnatal (p7) rats and p13 rats by combined unilateral common carotid artery ligation and hypoxia with 8% oxygen. Seizures were induced chemically by the subcutaneous injection of kainic acid (KA) or inhalation of flurothyl vapor. Three types of experiments were conducted in each age group and for each convulsant. In some animals (group 1), seizures were produced at 24 h and again at 6 h prior to HI. In groups 2 and 3, seizures were induced 2 h or 24 h post HI, respectively. The results indicate that in group 1 animals, the first seizure significantly reduced duration of the second seizure challenge 18 h later at both p7 and p13 ( p=0.001). Histologic examination of brains of animals in group 1 subjected to seizures prior to HI and their HI-only controls showed that seizures prior to HI conferred protection against cerebral damage. This effect was significant for flurothyl seizures in p13 rats for all cerebral regions, especially hippocampal CA1 ( p=0.0004), and in p7 rats for hippocampus ( p=0.04) and particularly cerebral cortex ( p=0.007). For KA seizures, the protective effect was only significant in p13 rats and was limited to hippocampal CA regions and subiculum ( p=0.0009). Histologic assessment of cerebral lesions of p7 and p13 rats in the other two groups showed no significant difference between the animals subjected to seizures 2 h or 24 h post HI and their HI-only controls ( p>0.05). In conclusion, the results of the present study provide no evidence that seizures in early postnatal development aggravate pre-existing cerebral HI damage. They do suggest that seizures prior to HI or prior to a second seizure confer tolerance to both conditions.

Consequences of neonatal seizures in the rat: morphological and behavioral effects.

Whereas neonatal seizures are a predictor of adverse neurological outcome, there is controversy regarding whether seizures simply reflect an underlying brain injury or can cause damage. We subjected neonatal rats to a series of 25 brief flurothyl-induced seizures. Once mature the rats were compared with control littermates for spatial learning and activity level. Short-term effects of recurrent seizures on hippocampal excitation were assessed by using the intact hippocampus formation preparation and long-term effects by assessing seizure threshold. Brains were analyzed for neuronal loss, sprouting of granule cell axons (mossy fibers), and neurogenesis. Compared with controls, rats subjected to neonatal seizures had impaired learning and decreased activity levels. There were no differences in paired-pulse excitation or inhibition or duration of afterdischarges in the intact hippocampal preparation. However, when studied as adults, rats with recurrent flurothyl seizures had a significantly lower seizure threshold to pentylenetetrazol than controls. Rats with recurrent seizures had greater numbers of dentate granule cells and more newly formed granule cells than the controls. Rats with recurrent seizures also had sprouting of mossy fibers in CA3 and the supragranular region. Recurrent brief seizures during the neonatal period have long-term detrimental effects on behavior, seizure susceptibility, and brain development.