Cognitive dysfunction after experimental febrile seizures

Dubé, Céline M.; Zhou, Junli; Hamamura, Mark J; Zhao, Qian; Ring, Alex; Abrahams, J J; McIntyre, Katherine; Nalcioğlu, Orhan; Shatskih, Tatiana; Baram, Tallie Z.; Holmes, Gregory L.

doi:10.1016/j.expneurol.2008.10.003

Cited by 104 publications

(122 citation statements)

References 55 publications

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“…In particular, a loss of distal dendritic inhibition in seizure rats may affect spatial coding by a direct entorhinal to CA1 distal-dendritic excitation (Brun et al, 2008;Leung, 2011). Abnormal place cell activity was found in animals with early-life seizures (Dube et al, 2009(Dube et al, , 2010. Attenuation in GABA B R function may be a critical component of epilepsy, and it may participate in a role of ''seizures beget seizures'' (Tsai et al, 2008).…”

Section: Significance and Implications Of Resultsmentioning

confidence: 99%

“…As a model of febrile seizures, hyperthermia-induced seizures in immature rats (Baram et al, 1997) were found to increase longterm seizure susceptibility and induce spontaneous seizures (Dube et al, 2010), without significant cell loss or sustained brain damage (Dube et al, 2000). Additionally, long-term behavioral changes have been reported after hyperthermic seizures (Chang et al, 2003;Dube et al, 2000Dube et al, , 2009Dube et al, , 2010. Long-term physiological changes after febrile seizure models include alteration of intrinsic membrane currents and an increased in GABA A receptor-mediated transmission in hippocampal slices in vitro (Chen et al, 1999).…”

Section: Introductionmentioning

confidence: 99%

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Loss of dendritic inhibition in the hippocampus after repeated early-life hyperthermic seizures in rats

Boyce

Leung

2013

Epilepsy Research

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"Loss of dendritic inhibition in the hippocampus after repeated early-life hyperthermic seizures in rats." (2013) Summary Seizures are relatively common in children and are a risk factor for subsequent temporal lobe epilepsy. To investigate whether early-life seizures themselves are detrimental to the proper function of the adult brain, we studied whether dendritic excitation and inhibition in the hippocampus of adult rats were altered after hyperthermia-induced seizures in immature rats. In particular, we hypothesized that apical dendritic inhibition in hippocampal CA1 pyramidal cells would be disrupted following hyperthermia-induced seizures in early life. Seizure rats were given three hyperthermia-induced seizures per day for three days from postnatal day (PND) 13 to 15; control rats were handled similarly but not heated. At PND 65-75, paired-pulse inhibition in area CA1 was evaluated under urethane anesthesia, using CA3 and medial perforant path (MPP) stimulation to excite the proximal and distal apical-dendrites, respectively, and the evoked field potentials were analyzed by current source density. There was no difference in the CA1 response to single-pulse stimulation of CA3 or MPP. In control rats, a high-intensity CA3 stimulus inhibited a subsequent MPP-evoked CA1 distal dendritic excitatory sink, and the inhibition at 150-200 ms was blocked by a GABA B receptor antagonist. Seizure as compared to control rats showed a decrease in a CA3-evoked inhibition of the CA1 distal dendritic excitation, 30-400 ms after the CA3 stimulus. In addition, seizure as compared to control rats showed a reduced early (20-80 ms) inhibition of a CA1 mid-apical dendritic sink following paired-pulse CA3 stimulation. In conclusion, long-term alterations in dendritic inhibition in CA1 were found following early-life seizures.

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Section: Significance and Implications Of Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Loss of dendritic inhibition in the hippocampus after repeated early-life hyperthermic seizures in rats

Boyce

Leung

2013

Epilepsy Research

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“…In humans, it is more difficult to discern the relationship of the epilepsy and the cognitive defects (122). Temporal lobe or limbic seizures propagate through the same neuronal pathways that are engaged in learning and memory processes (111). Thus, seizures might directly cause such problems; alternatively, the abnormalities that result in the seizures might independently provoke cognitive dysfunction.…”

Section: Cognitive Vulnerability During Agingmentioning

confidence: 99%

The Brain, Seizures and Epilepsy Throughout Life: Understanding a Moving Target

Baram

2012

Epilepsy Curr

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The Scope of the Problem The incidence of seizures and of epilepsy varies throughout life, peaking in neonates and children and increasing again after the age of 50 (1-4). In addition to the quantitative measure of the incidence of seizures, the type of seizures (and of epilepsy syndromes) varies with age: for example, febrile seizures take place in infants and children (1, 5-7), whereas the incidence of post-stroke epilepsy increases in adults compared with children (1,3,8). What is the basis of these age-dependent variations? What are the age-specific properties of the brain that contribute to the probability of seizure generation and to the nature of the resulting seizure?A second, reciprocal aspect of the interaction of the age of the brain and seizures involves the effects of a seizure on the structure and function of neurons and neuronal networks. Here, again, clinical evidence suggests that the consequences of a seizure might vary with age. For example, the consequences of status epilepticus (SE) in young children seem to depend on the inciting etiology (9, 10), and, in general, mortality and cognitive outcomes are more favorable than in the adult and elderly individual (11)(12)(13)(14). In contrast, status epilepticus in adult and aging individuals can have major detrimental effects on cognitive function and even survival (14-16). What is the basis of these age-dependent variations? What are the age-specific properties of the brain that modulate the effects of seizures on neuronal integrity and function?These questions are of paramount clinical importance because they should provide clues for developing age-specific diagnostic tools, prognostic models, and intervention strategies. Thus, while the answers to these questions are not fully elucidated, the questions provide a framework for discussing the salient elements of the evolving interaction between the brain and seizures throughout life.The following paragraphs highlight a few of the many facts that influence age-specific seizures and the age-specific consequences of seizures. Because most of the direct information about seizures throughout the life-span often derives from animal models, these are discussed. The author regrets that this overview is not comprehensive and likely omits a number of important publications. Nonetheless, this review serves to illustrate crucial features of the topic. Age-Specific Brain Properties Influence Seizures That Are Generated During Each AgeWhereas brain development from embryonic life to senescence is a continuum, here it is divided into four stages: the neonatal, childhood, adulthood, and aging epochs. The Neonatal Brain and Age-Specific Neonatal SeizuresThe neonatal brain is in a stage of rapid flux from both structural and functional perspectives. Neurons are still being born, circuits are being formed, and synapses are being established (17,18). Synaptic currents are often slower (19), neurotransmitters play trophic roles (20), and circuits are not fully mature (21). These facts predict that seizures may propag...

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“…The repeated-FS also caused long-lasting deficits in synaptic plasticity in CA1 pyramidal cells and reduced tyrosine phosphorylation of the NMDA-receptor subunit NR2A (96). Recently, an abnormal firing rate and poor stability of hippocampal CA1 place cells have been suggested as a basis for the deficits in eFS-induced hippocampal-dependent memory (97).…”

Section: Do Fs Affect the Behavior In Later Life?mentioning

confidence: 99%

“…Furthermore, the development of noninvasive methods such as MRI (97) to detect the future effects of FS on hippocampal malfunction is required.…”

Section: Do Fs Affect the Behavior In Later Life?mentioning

confidence: 99%

Novel Etiological and Therapeutic Strategies for Neurodiseases: Mechanisms and Consequences of Febrile Seizures: Lessons From Animal Models

Koyama

Matsuki

2010

J Pharmacol Sci

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Abstract. Febrile seizures (FS) are the most common type of convulsive events in infancy and childhood. Genetic and environmental elements have been suggested to contribute to FS. FS can be divided into simple and complex types, the former being benign, whereas it is controversial whether complex FS have an association with the development of temporal lobe epilepsy (TLE) in later life. In the hippocampus of TLE patients, several structural and functional alterations take place that render the region an epileptic foci. Thus, it is important to clarify the cellular and molecular changes in the hippocampus after FS and to determine whether they are epileptogenic. To achieve this goal, human studies are too limited because the sample tissues are only available from adult patients in the advanced and drug-resistant stages of the disease, masking the underlying etiology. These facts have inspired researchers to take advantage of well-established animal models of FS to answer the following questions: 1) How does hyperthermia induce FS? 2) Do FS induce neuroanatomical changes? 3) Do FS induce neurophysiological changes? 4) Do FS affect the behavior in later life? Here we introduce and discuss accumulating reports to answer these questions.

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Cognitive dysfunction after experimental febrile seizures

Cited by 104 publications

References 55 publications

Loss of dendritic inhibition in the hippocampus after repeated early-life hyperthermic seizures in rats

Loss of dendritic inhibition in the hippocampus after repeated early-life hyperthermic seizures in rats

The Brain, Seizures and Epilepsy Throughout Life: Understanding a Moving Target

Novel Etiological and Therapeutic Strategies for Neurodiseases: Mechanisms and Consequences of Febrile Seizures: Lessons From Animal Models

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