Intravenous infusion of docosahexaenoic acid increases serum concentrations in a dose-dependent manner and increases seizure latency in the maximal PTZ model.

Docosahexaenoic acid (DHA) is an omega-3 polyunsaturated fatty acid (n-3 PUFA) that has been shown to raise seizure thresholds in the maximal pentylenetetrazole model following acute subcutaneous (s.c.) administration in rats. Following s.c. administration, however, the dose-response relationship for DHA has shown an inverted U-pattern. The purposes of the present experiment were as follows: (1) to determine the pattern of serum unesterified concentrations resulting from the intravenous (i.v.) infusions of various doses of DHA, (2) to determine the time course of these concentrations following the discontinuation of the infusions, and (3) to determine whether seizure protection in the maximal PTZ model would correlate with serum unesterified DHA levels. Animals received 5-minute i.v. infusions of saline or 25, 50, 100, or 200mg/kg of DHA via a cannula inserted into one of the tail veins. Blood was collected during and after the infusions by means of a second cannula inserted into the other tail vein (Experiment 1). A separate group of animals received saline or 12.5-, 25-, 50-, 100-, or 200 mg/kg DHA i.v. via a cannula inserted into one of the tail veins and were then seizure-tested in the maximal PTZ model either during infusion or after the discontinuation of the infusions. Slow infusions of DHA increased serum unesterified DHA concentrations in a dose-dependent manner, with the 200-mg/kg dose increasing the concentration approximately 260-fold compared with saline-infused animals. Following discontinuation of the infusions, serum concentrations rapidly dropped toward baseline, with half-lives of approximately 40 and 11s for the 25-mg/kg dose and 100-mg/kg dose, respectively. In the seizure-tested animals, DHA significantly increased latency to seizure onset in a dose-dependent manner. Following the discontinuation of infusion, seizure latency rapidly decreased toward baseline. Overall, our study suggests that i.v. infusion of unesterified DHA results in transient anticonvulsant effects which parallel unesterified DHA serum concentrations.

Intraperitoneal administration of docosahexaenoic acid for 14days increases serum unesterified DHA and seizure latency in the maximal pentylenetetrazol model.

Docosahexaenoic acid (DHA) is an omega-3 polyunsaturated fatty acid (n-3 PUFA) which has been shown to raise seizure thresholds following acute administration in rats. The aims of the present experiment were the following: 1) to test whether subchronic DHA administration raises seizure threshold in the maximal pentylenetetrazol (PTZ) model 24h following the last injection and 2) to determine whether the increase in seizure threshold is correlated with an increase in serum and/or brain DHA. Animals received daily intraperitoneal (i.p.) injections of 50mg/kg of DHA, DHA ethyl ester (DHA EE), or volume-matched vehicle (albumin/saline) for 14days. On day 15, one subset of animals was seizure tested in the maximal PTZ model (Experiment 1). In a separate (non-seizure tested) subset of animals, blood was collected, and brains were excised following high-energy, head-focused microwave fixation. Lipid analysis was performed on serum and brain (Experiment 2). For data analysis, the DHA and DHA EE groups were combined since they did not differ significantly from each other. In the maximal PTZ model, DHA significantly increased seizure latency by approximately 3-fold as compared to vehicle-injected animals. This increase in seizure latency was associated with an increase in serum unesterified DHA. Total brain DHA and brain unesterified DHA concentrations, however, did not differ significantly in the treatment and control groups. An increase in serum unesterified DHA concentration reflecting increased flux of DHA to the brain appears to explain changes in seizure threshold, independent of changes in brain DHA concentrations.

Selective reduction of excitatory hippocampal sharp waves by docosahexaenoic acid and its methyl ester analog ex-vivo.

Excitatory sharp waves (SPWs) originating from the hippocampus are considered to model the interictal "spikes" that occur in people with temporal lobe epilepsy. Docosahexaenoic acid (DHA) is an omega-3 polyunsaturated fatty acid that has been reported to reduce neuronal excitability in vitro. The effect of DHA on hippocampal SPWs, however, is not known. Our goal was to determine whether DHA suppresses SPWs in thick mouse hippocampal slices, and to compare its effects with those of oleic acid (OA, control) and the standard anticonvulsant carbamazepine (CBZ). Also tested, were DHA's structural PUFA analogs n-3 docosapentaenoic acid (n-3 DPA), n-6 docosapentaenoic acid (n-6 DPA) and DHA-methyl ester (DHA-Me). The possible involvement of GABAergic activity was also examined using GABA receptor blockers. Extracellular recordings from CA1 and CA3 regions in hippocampal slices revealed that DHA reduced the incidence of SPWs. CBZ also reduced the incidence of SPWs and was 5 time more potent than DHA. DHA's effects on SPWs was abolished in the presence of GABA-receptor blockers, suggesting involvement of the GABA system in reducing excitatory SPWs. (14)C-DHA application to the slices confirmed the incorporation of DHA into membrane phospholipids. N-3 DPA and n-6 DPA, however, which also incorporate into phospholipids, had no effect on SPWs, while DHA-Me, a DHA analog that does not incorporate into membrane phospholipids, was effective at reducing them. We conclude that DHA, but not its n-3 and n-6 analogs, reduces network excitability of the recurrent CA3 circuitry in the mouse hippocampus. This reduction may be mediated by DHA in its unesterified form, and is likely related to a modulatory effect of DHA on GABAergic activity.

A minimum of 3 months of dietary fish oil supplementation is required to raise amygdaloid afterdischarge seizure thresholds in rats--implications for treating complex partial seizures.

Complex partial seizures, which typically originate in limbic structures such as the amygdala, are often resistant to antiseizure medications. Our goal was to investigate the effects of chronic dietary supplementation with n-3 polyunsaturated fatty acids (PUFAs) derived from fish oil on seizure thresholds in the amygdala, as well as on blood and brain PUFA levels. The acute effects of injected n-3 PUFAs--eicosapentaenoic acid (EPA) and docosahexaenoic acid (DHA)--were also tested in the maximal pentylenetetrazol (PTZ) seizure model. In amygdala-implanted subjects, fish oil supplementation significantly increased amygdaloid afterdischarge thresholds, as compared with controls at 3, 5, and 7 months after the start of supplementation. Fish oil supplementation also increased serum EPA and DHA concentrations. DHA concentration in the pyriform-amygdala area increased in the fish-oil treated group by 17-34%, but this effect did not reach statistical significance (P=0.065). DHA significantly increased the latency to seizure onset in the PTZ seizure model, whereas EPA had no significant effect. These observations suggest that chronic dietary fish oil supplementation can raise focal amygdaloid seizure thresholds and that this effect is likely mediated by DHA rather than by EPA.

Increases in seizure latencies induced by subcutaneous docosahexaenoic acid are lost at higher doses.

Docosahexaenoic acid (DHA) is a polyunsaturated fatty acid (PUFA) which has been found to have anticonvulsant properties. Our group has previously reported in a pilot study that the acute administration of subcutaneous (s.c.) DHA increases seizure latencies in the maximal pentylenetetrazole (PTZ) seizure test, however it loses its effect at higher doses. The purpose of the present experiments was (1) to confirm that DHA loses its effect at higher doses, (2) to correlate the anticonvulsant properties of DHA with DHA levels in the different lipid pools of serum and (3) to evaluate whether an anticonvulsant dose of DHA resulted in an increase in DHA release from the brain phospholipids following induction of seizure. In the first experiment, male Wistar rats were injected s.c. with 200, 300, 400 or 600 mg/kg of DHA, or 400mg/kg oleic acid (OA, isocaloric control), and seizure tested with the maximal PTZ test 1h post injection (Experiment 1). In a second experiment, subjects received either: (1) an effective dose of DHA (400mg/kg), (2) a higher, non-effective dose (600 mg/kg; based on the findings of Experiment 1), or (3) OA (400mg/kg). Subjects were sacrificed 1h post injection and blood was collected for fatty acid analysis (Experiment 2). In the third experiment, subjects were injected with either the effective dose of DHA (400mg/kg) or OA (400mg/kg). One hour post lipid injection, animals received either PTZ or saline, and animals were euthanized via microwave fixation. Brain were extracted and unesterified fatty acid concentrations were measured (Experiment 3). Experiment 1 confirmed that DHA loses its effects at higher doses in the maximal PTZ test. The 400mg/kg dose was maximally effective but effects were lost at 600 mg/kg. Experiment 2 showed that only the unesterified DHA pool in serum was statistically increased by an acute injection of s.c. DHA (P<0.05, as compared to OA), whereas esterified DHA pools were unchanged (P>0.05). Curiously, unesterified DHA levels were similar in both the 400mg/kg and 600 mg/kg dosage groups. Experiment 3 showed that an anticonvulsant dose of DHA (400mg/kg) did not increase DHA release from brain phospholipids following seizure induction (P>0.05). In conclusion, DHA has anticonvulsant properties when injected s.c., but these properties are lost at higher doses. The anticonvulsant effects of DHA are accompanied by increased levels of unesterified DHA in the serum, but not in increased DHA release from brain phospholipids.

Cytogenesis in the adult rat dentate gyrus is increased following kindled seizures but is unaltered in pharmacological models of absence seizures.

The production of new neurons continues throughout adulthood in the dentate gyrus of the hippocampal formation, and is believed to play a role in hippocampus-dependent learning and memory. Seizure-induced changes in adult neurogenesis have been examined primarily in convulsive rodent seizure models, but not in models of nonconvulsive absence seizures. This study examined progenitor cell proliferation in the gamma-hydroxybutyrate (GHB) model of typical absence seizures and the AY-9944 model of atypical absence seizures, and compared these results with changes seen in the rat amygdala kindling model. Kindled subjects were found to have 189% more proliferating cells than sham-kindled control subjects, whereas no significant difference was found between the GHB or AY-9944 model and control subjects. These results suggest that changes in adult neurogenesis in models of absence seizures do not occur, and that seizure-induced enhancement of neurogenesis could depend on the characteristics of the seizure discharge.

Acute administration of docosahexaenoic acid increases resistance to pentylenetetrazol-induced seizures in rats.

OBJECTIVE: Docosahexaenoic acid (DHA), an omega-3 fatty acid, has been reported to raise seizure thresholds. The purpose of the present study was to test the acute anticonvulsant effects of unesterified DHA in rats, using the maximal pentylenetetrazol (PTZ) seizure model, and also to examine DHA incorporation and distribution into blood serum total lipids and brain phospholipids and unesterified fatty acids. Sedation was measured to monitor for the potential toxicity of DHA. METHODS: Male Wistar rats received subcutaneous injections of saline, oleic acid (OA), or DHA. An initial pilot study (Experiment 1) established 400mg/kg as an effective dose of DHA in the maximal PTZ seizure test. A subsequent time-response study, using 400mg/kg (Experiment 2), established 1 hour as an effective postinjection interval for administering DHA subcutaneously. A final study (Experiment 3) comprised two different groups. The first group ("seizure-tested rats") received saline, OA, or DHA (400mg/kg) subcutaneously, and were seizure tested in the maximal PTZ test 1 hour later to confirm the seizure latency measurements at that time. The second group ("assay rats") received identical subcutaneous injections of saline, OA, or DHA (400mg/kg). One hour postinjection, however, they were sacrificed for assay rather than being seizure tested. Assays involved the analysis of serum and brain DHA. Sedation was measured in both Experiment 3 groups during the 1-hour period prior to seizure testing or sacrifice. RESULTS: As noted above, 400mg/kg proved to be an effective subcutaneous dose of DHA (Experiment 1), and 1 hour proved to be the most effective injection-test interval (Experiment 2). In Experiment 3, in the seizure-tested animals, subcutaneous administration of 400mg/kg of DHA significantly increased latency to PTZ seizure onset 1 hour postinjection relative to the saline- and OA-injected controls, which did not differ significantly from each other (P>0.05). In the assay animals, no significant effects of treatment on blood serum total lipids or on brain phospholipid or unesterified fatty acid profiles (P>0.05) were observed. There were also no differences in sedation among the three groups (P>0.05). CONCLUSION: DHA increases resistance to PTZ-induced seizures without altering measures of sedation and, apparently, without changing DHA concentrations in serum or brain.

Comparative study of five antiepileptic drugs on a translational cognitive measure in the rat: relationship to antiepileptic property.

RATIONALE: Antiepileptic drugs (AEDs) have been available for many years; yet, new members of this class continue to be identified and developed due to the limitations of existing drugs, which include a propensity for cognitive impairment. However, there is little preclinical information about the cognitive effects they produce, which clinically include deficits in attention and slowing of reaction time. OBJECTIVES: The purpose of this study was to profile two first-generation AEDs, phenytoin and valproate, and three second-generation AEDs, levetiracetam, pregabalin and lacosamide. Initially, each drug was examined across a range of well characterised preclinical seizure tests, and then each drug was evaluated in the five-choice serial reaction time test (5-CSRTT) based on efficacious doses from the seizure tests. MATERIALS AND METHODS: Each AED was tested for anti-seizure efficacy in either (1) the maximal electroshock seizure test, (2) s.c. PTZ seizure test, (3) amygdala-kindled seizures and (4) the genetic absence epilepsy rat of Strasbourg model of absence seizures. On completion of these studies, each drug was tested in rats trained to asymptotic performance in the 5-CSRTT (0.5 s SD, 5 s ITI, 100 trials). Male rats were used in all studies. RESULTS: Each AED was active in at least one of the seizure tests, although only valproate was active in each test. In the 5-CSRT test, all drugs with the exception of levetiracetam, significantly slowed reaction time and increased omissions. Variable effects were seen on accuracy. The effect on omissions was reversed by increasing stimulus duration from 0.5 to 5 s, supporting a drug-induced attention deficit. Levetiracetam had no negative effect on performance; indeed, reaction time was slightly increased (i.e. faster). CONCLUSIONS: These results highlight somewhat similar effects of phenytoin, valproate, pregabalin and lacosamide on attention and reaction time, and comparison to efficacious doses from the seizure tests support the view that there may be a better separation with the newer AEDs. Levetiracetam had no detrimental effect in the 5-CSRTT, which may be consistent with clinical experience where the drug is considered to be well tolerated amongst the AED class.

Dietary enrichment with medium chain triglycerides (AC-1203) elevates polyunsaturated fatty acids in the parietal cortex of aged dogs: implications for treating age-related cognitive decline.

Dogs demonstrate an age-related cognitive decline, which may be related to a decrease in the concentration of omega-3 polyunsaturated fatty acids (n-3 PUFA) in the brain. Medium chain triglycerides (MCT) increase fatty acid oxidation, and it has been suggested that this may raise brain n-3 PUFA levels by increasing mobilization of n-3 PUFA from adipose tissue to the brain. The goal of the present study was to determine whether dietary MCT would raise n-3 PUFA concentrations in the brains of aged dogs. Eight Beagle dogs were randomized to a control diet (n = 4) or an MCT (AC-1203) enriched diet (n = 4) for 2 months. The animals were then euthanized and the parietal cortex was removed for phospholipid, cholesterol and fatty acid determinations by gas-chromatography. Dietary enrichment with MCT (AC-1203) resulted in a significant increase in brain phospholipid and total lipid concentrations (P < 0.05). In particular, n-3 PUFA within the phospholipid, unesterified fatty acid, and total lipid fractions were elevated in AC-1203 treated subjects as compared to controls (P < 0.05). Brain cholesterol concentrations did not differ significantly between the groups (P > 0.05). These results indicate that dietary enrichment with MCT, raises n-3 PUFA concentrations in the parietal cortex of aged dogs.

The effects of a ketogenic diet on ATP concentrations and the number of hippocampal mitochondria in Aldh5a1(-/-) mice.

BACKGROUND: Succinic semialdehyde dehydrogenase (SSADH) deficiency is an inborn error of GABA metabolism characterized clinically by ataxia, psychomotor retardation and seizures. A mouse model of SSADH deficiency, the Aldh5a1(-/-) mouse, has been used to study the pathophysiology and treatment of this disorder. Recent work from our group has shown that the ketogenic diet (KD) is effective in normalizing the Aldh5a1(-/-) phenotype, although the mechanism of the effect remains unclear. METHODS: Here, we examine the effects of a KD on the number of hippocampal mitochondria as well as on ATP levels in hippocampus. Electron microscopy was performed to determine the number of mitochondria in the hippocampus of Aldh5a1(-/-) mice. Adenosine triphosphate (ATP) levels were measured in hippocampal extracts. RESULTS: Our results show that the KD increases the number of mitochondria in Aldh5a1(-/-) mice. We also show that Aldh5a1(-/-) mice have significant reductions in hippocampal ATP levels as compared to controls, and that the KD restores ATP in mutant mice to normal levels. GENERAL SIGNIFICANCE: Taken together, our data suggest that the KD's actions on brain mitochondria may play a role in the diet's ability to treat murine SSADH deficiency.

Assessing the metabolic and toxic effects of anticonvulsant doses of polyunsaturated fatty acids on the liver in rats.

Polyunsaturated fatty acids (PUFA), at high doses, have been demonstrated to possess anticonvulsant properties in animal seizure models. Little is known, however, about the possible metabolic or adverse effects of PUFA at these high, anticonvulsant doses. The goal of the present study was to assess the metabolic and potential adverse effects of high-dose PUFA administration to rats. Adult male rats received a fatty acid mixture containing alpha-linolenic and linoleic acid in a 1 to 4 ratio, intraperitoneally, for 3 wk. After sacrifice, livers were isolated and analyzed for fatty acid composition and for mRNA expression of HMG-CoA lyase, catalase, and glutathione S-transferases A1 and A4, markers for ketosis, antioxidant defense, and phase II xenobiotic metabolism, respectively. Chronic administration of the PUFA mixture decreased hepatic levels of total lipids--and several fatty acids within total lipids--without altering mRNA expression of HMG-CoA lyase, a metabolic marker of ketosis. The PUFA mixture did not affect mRNA expression of catalase or glutathione S-transferases A1 and A4, which are involved in antioxidant defense and phase II xenobiotic metabolism. These findings suggest that PUFA, given for 3 wk at anticonvulsant doses, result in significant changes in liver lipid metabolism, but do not alter measured genetic markers of liver toxicity.

A ketogenic diet rescues the murine succinic semialdehyde dehydrogenase deficient phenotype.

Succinic semialdehyde dehydrogenase (SSADH) deficiency is a heritable disorder of GABA degradation characterized by ataxia, psychomotor retardation and seizures. To date, there is no effective treatment for SSADH deficiency. We tested the hypothesis that a ketogenic diet (KD) would improve outcome in an animal model of SSADH deficiency, the SSADH knockout mouse (Aldh5a1-/-). Using a 4:1 ratio of fat to combined carbohydrate and protein KD we set out to compare the general phenotype, in vivo and in vitro electrophysiology and [35S]TBPS binding in both Aldh5a1-/- mice and control (Aldh5a1+/+) mice. We found that the KD prolonged the lifespan of mutant mice by >300% with normalization of ataxia, weight gain and EEG compared to mutants fed a control diet. Aldh5a1-/- mice showed significantly reduced mIPSC frequency in CA1 hippocampal neurons as well as significantly decreased [35S]TBPS binding in all brain areas examined. In KD fed mutants, mIPSC activity normalized and [35S]TBPS binding was restored in the cortex and hippocampus. The KD appears to reverse toward normal the perturbations seen in Aldh5a1-/- mice. Our data suggest that the KD may work in this model by restoring GABAergic inhibition. These data demonstrate a successful experimental treatment for murine SSADH deficiency using a KD, giving promise to the idea that the KD may be successful in the clinical treatment of SSADH deficiency.

The anticonvulsant effects of allopregnanolone against amygdala-kindled seizures in female rats.

It has long been known that the steroid hormone progesterone has anticonvulsant actions. These have been documented both in animals and humans. In 2003, we reported that progesterone's first metabolite, 5alpha-dihydroprogesterone (5alpha-DHP), has strong anticonvulsant effects in amygdala-kindled female rats. These occur without sedation, and involve suppression of the kindled amygdala focus, as well as the secondarily generalized kindled seizure. The purpose of this study was to investigate the anticonvulsant actions of progesterone's secondary metabolite, allopregnanolone, in the amygdala kindling model. Adult female Wistar rats were implanted with chronic indwelling electrodes in the right amygdala, and kindled to 30 stage 5 seizures. Varying doses of allopregnanolone were then administered to each subject in randomized order, and the effects on the kindled amygdala focus and the secondarily generalized kindled seizure were observed. Immediately before each drug trial, ataxia was rated using the Löscher scale. Complete suppression of the generalized kindled convulsion was seen in all subjects, with an ED(50) of 1.1 mg/kg. Ataxia--scored as Löscher stage 2 or higher--was seen at higher doses, with a TD(50) of 8.6 mg/kg. The therapeutic index for suppression of the generalized convulsion was 7.8. Even at the highest doses tested, however, there was no suppression of the kindled amygdala focus. Allopregnanolone has anticonvulsant effects--and a good therapeutic index--against the secondarily generalized component of amygdala-kindled seizures.

A ketogenic diet and diallyl sulfide do not elevate afterdischarge thresholds in adult kindled rats.

INTRODUCTION: Acetone has been shown to have broad-spectrum anticonvulsant actions in animal seizure models and has been hypothesized to play a role in the anticonvulsant mechanism of the ketogenic diet (KD). The present study examined the ability of a KD to elevate amygdaloid afterdischarge thresholds (ADT) in fully kindled rats. The effects of the KD were studied in the presence and absence of diallyl sulfide (DAS), an inhibitor of acetone metabolism. METHODS: Twenty-four adult male rats were kindled to 30 stage 5 seizures. Afterdischarge thresholds (ADT) were determined. Subjects were then administered one of the following diets: (1) KD+V (vehicle; KD+V); (2) KD+DAS; (3) control diet+V (CD+V); (4) CD+DAS. They were stimulated every second day. Blood sampling was performed every second day--on non-stimulating days--to determine levels of glucose, beta-hydroxybutyrate, acetoacetate, and acetone. After 20 days, ADTs were re-determined. RESULTS: Blood acetone concentrations were significantly higher in the KD+DAS group as compared to the other groups, although they did not reach "therapeutic levels". None of the treatments, however, elevated ADTs. CONCLUSIONS: The KD was unable to elevate amygdaloid ADTs in fully kindled rats. Although subjects in the KD+DAS group achieved significant elevations of blood acetone, these concentrations (e.g. 0.2 mM) were much lower than those (>2.0 mM) previously shown to confer anticonvulsant activity. There appears to be large difference between humans and rats in their ability to produce elevated blood acetone levels on the KD. These data suggest that adult rats are not ideal subjects for modeling the anticonvulsant actions of the KD.

The ketogenic diet causes a reversible decrease in activity level in Long-Evans rats.

Individuals with epilepsy also often exhibit symptoms of attention deficit hyperactivity disorder (ADHD). The ketogenic diet, which is a high fat, low protein, and low carbohydrate diet used in the treatment of intractable epilepsy, also appears to improve symptoms of ADHD in individuals with both disorders. Previous research suggests that the diet decreases the activity level of rats. The purpose of the present research was to further investigate the effects of the ketogenic diet on activity level, using an animal model. Two experiments were conducted. The first experiment examined the time frame and reversibility of the effect of the diet on activity level. The second experiment examined the relationship between activity level and anxiety level. In both experiments, adult male Long-Evans rats were placed on either a ketogenic diet or a control diet. The results of the first experiment show that the ketogenic diet can cause a decrease in activity level within 24 h and that the results are reversible. The results of Experiment 2 show that the decrease in activity level is not linked to a change in anxiety level. The ketogenic diet may be of use in the treatment of ADHD.

Deoxycorticosterone's anticonvulsant effects in infant rats are blocked by finasteride, but not by indomethacin.

Deoxycorticosterone (DOC) is a steroid hormone that suppresses seizures in both humans and animals. At higher doses, DOC's anticonvulsant actions are accompanied by sedation and ataxia. The mechanism of DOC's anticonvulsant actions is not known, although it has been suggested that they may relate to DOC's secondary metabolite 3-alpha-5-alpha-tetrahydrodeoxycorticosterone (THDOC). The present study was designed to study the relation of DOC's anticonvulsant actions to its primary and secondary metabolites in 15-day-old rats. It was found that DOC's anticonvulsant and ataxic effects were suppressed by finasteride, which blocks the formation of DOC's primary metabolite, 3-alpha-5-alpha-dehydrodeoxycorticosterone (DHDOC). They were not suppressed by indomethacin (INDO), which blocks the conversion of DHDOC into THDOC. The direct anticonvulsant effects of DHDOC and THDOC were also tested. DHDOC and THDOC were both potent anticonvulsants in 15-day old rats. Both also caused ataxia at high doses. DHDOC had a therapeutic index (TI) of 3.2, however, which was better than either DOC (TI = 1.2) or THDOC (TI = 1.5). It appears that DOC itself is not anticonvulsant, but that its anticonvulsant effects may relate to both its primary and secondary metabolites. DOC's primary metabolite, DHDOC--with its good TI--deserves a test in the treatment of childhood seizures.

Kindled seizures enhance young neuron survival in the adult rat dentate gyrus.

New neurons continue to be generated throughout adulthood in the dentate gyrus of mammals. This process of neurogenesis is believed to play a role in some forms of learning and memory. Hippocampal-dependent learning tasks have been shown to specifically enhance the survival of new granule neurons. The present study examined the effects of kindled seizures in rats on the survival of young neurons born before the kindling began. Kindled seizures within the perforant path input to the dentate gyrus triggered between 1 and 2 weeks following the injection of bromodeoxyuridine (BrdU), were found to increase the number of BrdU and NeuN co-labeled cells in the granule cell layer by 128% 1 month later. The number of co-labeled cells was not correlated with measures of seizure severity. These results demonstrate that kindled seizures enhance the survival of new born neurons in the adult rat dentate gyrus which may reflect the actions of an activity-dependent mechanism normally involved in hippocampal-dependent learning and memory.

The antidepressant properties of the ketogenic diet.

BACKGROUND: The ketogenic diet is used to treat epilepsy refractory to anticonvulsant medication. Individuals with epilepsy often have behavioral problems and deficits in attention and cognitive functioning. The ketogenic diet has been found to effect improvements in these domains. It has also been suggested that the ketogenic diet may act as a mood stabilizer. METHODS: The present research used the Porsolt test, an animal model of depression, to determine whether the ketogenic diet has antidepressant properties. Porsolt test scores of rats on the ketogenic diet were compared with those of rats on a control diet. RESULTS: The rats on the ketogenic diet spent less time immobile, suggesting that rats on the ketogenic diet, like rats treated with antidepressants, are less likely to exhibit "behavioral despair." CONCLUSIONS: It is concluded that the ketogenic diet may have antidepressant properties.

The effect of kindled seizures on the locomotory behavior of Long-Evans rats.

The incidence of attention deficit hyperactivity disorder (ADHD) is higher in children with epilepsy than in the general childhood population. The origin of the symptoms of ADHD seen in children with epilepsy is unknown. This experiment used an animal model to investigate whether seizures could be a cause of the hyperactivity sometimes associated with epilepsy. Sixteen male Long-Evans rats were implanted with electrodes, and 8 of them were kindled until generalized stage 5 seizures were elicited. Eight subjects were handled, but not kindled. The behavior of the rats in the two groups was compared in an open field test. The time spent in four behaviors was measured: exploratory behavior, immobility, eating, and grooming. Rats were tested after 5 stage 5 seizures, after 10 stage 5 seizures, after 15 stage 5 seizures, after a 2-week rest period, and after 5 more stage 5 seizures. Data were analyzed using the Mann-Whitney rank sum test. Twenty-four hours after a seizure, the kindled rats displayed a greater level of exploratory behavior than did the controls. They were not found to differ on any other measure. After a 2-week rest period, the group difference in behavior disappeared. When kindling was reinitiated, the kindled rats again showed increased exploratory behavior. The findings suggest that the increased exploratory behavior found in the kindled rats resulted from recent seizure activity. It may be that the hyperactivity seen in some children with epilepsy also results from recent seizure activity.

Kindling induces the mRNA expression of methyl DNA-binding factors in the adult rat hippocampus.

We have investigated the gene expression responses of a family of methyl CpG-binding domain-containing factors (MeCP2, MBD1, MBD2, and MBD3) in the hippocampus of electrically kindled rats. Expression was examined in both amygdala- and partial perforant-pathway-kindled subjects, 24 h and 28 days following the final stimulation. In general, the responses of MBDs 2 and 3 paralleled each another, both temporally and spatially. The expression of both genes was significantly elevated in all hippocampal subfields at 24 h following either the fifth stage 5 seizure (amygdala kindling) or the 15th stimulation of the perforant pathway. This induced expression was transient, however, as the expression of both genes returned to control levels by 28 days. This pattern of response contrasted to that observed for MeCP2 and MBD1. MeCP2 displayed no change in expression either 24 h or 28 days after amygdala kindling, but did display a late-developing, significant increase in expression in the dentate gyrus at 28 days following perforant-pathway kindling. The expression of MBD1 was unchanged by partial perforant-pathway kindling, but was induced in the dentate gyrus 28 days after amygdala kindling. These results demonstrate that electrical kindling alters the hippocampal expression of methyl DNA-binding factors, but does not affect each factor equivalently. The responsive patterns observed suggest that this family of transcriptional regulators can be differentially altered in the hippocampus by seizure activity.