A Single-Cell Transcriptomic Atlas of Human Neocortical Development during Mid-gestation.

We performed RNA sequencing on 40,000 cells to create a high-resolution single-cell gene expression atlas of developing human cortex, providing the first single-cell characterization of previously uncharacterized cell types, including human subplate neurons, comparisons with bulk tissue, and systematic analyses of technical factors. These data permit deconvolution of regulatory networks connecting regulatory elements and transcriptional drivers to single-cell gene expression programs, significantly extending our understanding of human neurogenesis, cortical evolution, and the cellular basis of neuropsychiatric disease. We tie cell-cycle progression with early cell fate decisions during neurogenesis, demonstrating that differentiation occurs on a transcriptomic continuum; rather than only expressing a few transcription factors that drive cell fates, differentiating cells express broad, mixed cell-type transcriptomes before telophase. By mapping neuropsychiatric disease genes to cell types, we implicate dysregulation of specific cell types in ASD, ID, and epilepsy. We developed CoDEx, an online portal to facilitate data access and browsing.

Transient Disruption of Adenosine Signaling During Embryogenesis Triggers a Pro-epileptic Phenotype in Adult Zebrafish.

Adenosinergic signaling has important effects on brain function, anatomy, and physiology in both late and early stages of development. Exposure to caffeine, a non-specific blocker of adenosine receptor, has been indicated as a developmental risk factor. Disruption of adenosinergic signaling during early stages of development can change the normal neural network formation and possibly lead to an increase in susceptibility to seizures. In this work, morpholinos (MO) temporarily blocked the translation of adenosine receptor transcripts, adora1, adora2aa, and adora2ab, during the embryonic phase of zebrafish. It was observed that the block of adora2aa and adora2aa + adora2ab transcripts increased the mortality rate and caused high rate of malformations. To test the susceptibility of MO adora1, MO adora2aa, MO adora2ab, and MO adora2aa + adora2ab animals to seizure, pentylenetetrazole (10 mM) was used as a convulsant agent in larval and adult stages of zebrafish development. Although no MO promoted significant differences in latency time to reach the seizures stages in 7-day-old larvae, during the adult stage, all MO animals showed a decrease in the latency time to reach stages III, IV, and V of seizure. These results indicated that transient interventions in the adenosinergic signaling through high affinity adenosine receptors during embryonic development promote strong outcomes on survival and morphology. Additionally, long-term effects on neural development can lead to permanent impairment on neural signaling resulting in increased susceptibility to seizure.

Abnormal Cell Sorting Underlies the Unique X-Linked Inheritance of PCDH19 Epilepsy.

X-linked diseases typically exhibit more severe phenotypes in males than females. In contrast, protocadherin 19 (PCDH19) mutations cause epilepsy in heterozygous females but spare hemizygous males. The cellular mechanism responsible for this unique pattern of X-linked inheritance is unknown. We show that PCDH19 contributes to adhesion specificity in a combinatorial manner such that mosaic expression of Pcdh19 in heterozygous female mice leads to striking sorting between cells expressing wild-type (WT) PCDH19 and null PCDH19 in the developing cortex, correlating with altered network activity. Complete deletion of PCDH19 in heterozygous mice abolishes abnormal cell sorting and restores normal network activity. Furthermore, we identify variable cortical malformations in PCDH19 epilepsy patients. Our results highlight the role of PCDH19 in determining cell adhesion affinities during cortical development and the way segregation of WT and null PCDH19 cells is associated with the unique X-linked inheritance of PCDH19 epilepsy.

Estudio de las epilepsias según la edad de inicio, controladas durante 3 años en una unidad de neuropediatría de referencia regional / A study of epilepsy according to the age at onset and monitored for 3 years in a regional reference paediatric neurology unit

OBJETIVO: Estudio de las epilepsias según la edad de inicio de las crisis y la etiología, de los pacientes controlados en una unidad de neuropediatría durante 3 años. PACIENTES Y MÉTODOS: Estudio de cohortes históricas. Revisión de historias de niños con epilepsia de la base de datos de neuropediatría controlados del 1 de enero de 2008 al 31 de diciembre de 2010. RESULTADOS: De 4.595 ni˜nos atendidos en el periodo, se estableció el diagnóstico de epilepsia en 605 (13,17%), siendo 277 (45,79%) epilepsias sintomáticas, 156 (25,79%) idiopáticas y 172 (28,43%) criptogénicas. La epilepsia de ausencias y la epilepsia benigna de la infancia con paroxismos centrotemporales son los síndromes epilépticos idiopáticos con mayor prevalencia, y las encefalopatías prenatales las epilepsias sintomáticas más prevalentes. El 26,12% iniciaron su epilepsia el primer a˜no, siendo sintomáticas el 67,72%. Se han considerado refractarias el 25,29% de las epilepsias; el 42,46% asocia déficit cognitivo, el 26,45% afectación motora y el 9,92% trastorno del espectro autista, siendo más frecuentes a menor edad de inicio. CONCLUSIONES: La ausencia de una clasificación universalmente aceptada de los síndromes epilépticos dificulta trabajos como este, empezando por la terminología. Una clasificación útil es la etiológica, con 2 grupos: un gran grupo con las etiologías establecidas o síndromes genéticos muy probables, y otro de casos sin causa establecida. La edad de inicio de la epilepsia en cada grupo etiológico añade orientación pronóstica. El pronóstico de la epilepsia lo ensombrecen la refractariedad y las alteraciones asociadas del neurodesarrollo, siendo peor en general a más precoz inicio y en etiologías concretas

OBJECTIVE: A study of epilepsy, according to the age at onset of the crisis and its causes, monitored by a Paediatric Neurology Unit over a period of three years. PATIENTS AND METHODS: Historical cohorts study was conducted by reviewing the Paediatric Neurology medical records data base of epileptic children followed-up from 1 January 2008 to 31 December 2010. RESULTS: A total of 4,595 children were attended during the study period. The diagnosis of epilepsy was established in 605 (13.17%): 277 (45.79%) symptomatic, 156 (25.79%) idiopathic, and 172 (28.43%) with cryptogenic epilepsy. Absence epilepsy and benign childhood epilepsy with centro-temporal spikes are the idiopathic epileptic syndromes most prevalent, and the most prevalent symptomatic epilepsies are prenatal encephalopathies. More than one-quarter (26.12%) of epilepsies began in the first year of life, and 67.72% were symptomatic. Refractory epilepsy was observed in 25.29%, 42.46% with cognitive impairment, 26.45% with motor involvement, and 9.92% with an autism spectrum disorder, being more frequent at an earlier age of onset. CONCLUSIONS: The absence of a universally accepted classification of epileptic syndromes makes tasks like this difficult, starting with the terminology. A useful classification would be aetiological, with two groups: a large group with established aetiology, or very likely genetic syndromes, and another with no established cause. The age of onset of epilepsy in each aetiological group helps in the prognosis, which is worsened by refractoriness and associated neurodevelopmental disorders, and are generally worse at an earlier onset and in certain aetiologies

Transient epileptiform signaling during neuronal network development: regulation by external stimulation and bimodal GABAergic activity.

A predominance of excitatory activity, with protracted appearance of inhibitory activity, accompanies cortical neuronal development. It is unclear whether or not inhibitory neuronal activity is solicited exclusively by excitatory neurons or whether the transient excitatory activity displayed by developing GABAergic neurons contributes to an excitatory threshold that fosters their conversion to inhibitory activity. We addressed this possibility by culturing murine embryonic neurons on multi-electrode arrays. A wave of individual 0.2-0.4 mV signals ("spikes") appeared between approx. 20-30 days in culture, then declined. A transient wave of high amplitude (>0.5 mV) epileptiform activity coincided with the developmental decline in spikes. Bursts (clusters of ≥3 low-amplitude spikes within 0.7s prior to returning to baseline) persisted following this decline. Addition of the GABAergic antagonist bicuculline initially had no effect on signaling, consistent with delayed development of GABAergic synapses. This was followed by a period in which bicuculline inhibited overall signaling, confirming that GABAergic neurons initially display excitatory activity in ex vivo networks. Following the transient developmental wave of epileptiform signaling, bicuculline induced a resurgence of epileptiform signaling, indicating that GABAergic neurons at this point displayed inhibitory activity. The appearance of transition after the developmental and decline of epileptiform activity, rather than immediately after the developmental decline in lower-amplitude spikes, suggests that the initial excitatory activity of GABAergic neurons contributes to their transition into inhibitory neurons, and that inhibitory GABAergic activity is essential for network development. Prior studies indicate that a minority (25%) of neurons in these cultures were GABAergic, suggesting that inhibitory neurons regulate multiple excitatory neurons. A similar robust increase in signaling following cessation of inhibitory activity in an artificial neural network containing 20% inhibitory neurons supported this conclusion. Even a minor perturbation in GABAergic function may therefore foster initiation and/or amplification of seizure activity, as well as perturbations in long-term potentiation.

Effect of prenatal pentylenetetrazol-induced kindling on learning and memory of male offspring.

Current data concerning the effects of maternal seizure during pregnancy on newborns are limited. This study was carried out to investigate the effect of prenatal pentylenetetrazol (PTZ)-induced kindling on learning and memory of offspring. Female Wistar rats were kindled with i.p. injections of 25 mg/kg of PTZ on day 13 of their pregnancy. The spatial performance and passive avoidance learning of pups were tested at 7 weeks and 12 weeks of age using Morris water maze (MWM) task and shuttle-box apparatus, respectively. We found, for the first time, that prenatal exposure to maternal seizure induced by PTZ leads to a significant impairment of learning and memory. In addition, the number of live birth was significantly lower in kindled rats compared to control. In MWM studies, the young offspring of kindled rats had poor spatial learning ability. The frequent tonic-clonic seizures in pregnancy was also associated with a poor memory as evidenced by decrease in distance swam in the target quadrant by the offspring of the kindled mother in the adulthood. Data obtained from shuttle-box studies showed that retention latencies of pups born to kindled dams were significantly reduced compared to those born to control dams. The hippocampus, amygdala and frontal cortex are very important for memory consolidation and our data suggest that subsequent developmental events are not sufficient to overcome the adverse effects of prenatal exposure to maternal seizures to these regions of the brain. These observations may have clinical implications for cognitive and memory dysfunction associated with epilepsy during pregnancy.

A semi-automated method for epileptiform transient detection in the EEG of the fetal sheep using time-frequency analysis.

Perinatal hypoxia remains a significant cause of brain damage. Currently there are no biomarkers to detect the at risk brain. Recent research, however, suggests that the appearance of epileptiform transients in the first 6-8 hours after hypoxia (the latent phase of injury) are predictive of neural outcome. To quantify this further a key need is to automate EEG signal analysis to aid clinical staff with the vast amounts of complex data to review. In this study, we present a semi-automated method for spike detection in the fetal sheep EEG. The method utilizes the short time Fourier transform and peak separation to extract spikes. The performance of the method was found to be high in sensitivity and selectivity over 3 distinct time points.

Neurodevelopment in seizure-prone and seizure-resistant rat strains: recognizing conflicts in management.

Cytoarchitectural alterations during central nervous system (CNS) development are believed to underlie aberrations in brain morphology that lead to epilepsy. We have recently reported marked reductions in hippocampal and white matter volumes along with relative ventriculomegaly in a rat strain bred to be seizure-prone (FAST) compared to a strain bred to be seizure-resistant (SLOW) (Gilby et al., 2002, American Epilepsy Society 56th Annual Meeting). This study was designed to investigate deviations in gene expression during late-phase embryogenesis within the brains of FAST and SLOW rats. In this way, we hoped to identify molecular mechanisms operating differentially during neurodevelopment that might ultimately create the observed differences in brain morphology and/or seizure susceptibility. Using Superarray technology, we compared the expression level of 112 genes, known to play a role in neurodevelopment, within whole brains of embryonic day 21 (E21) FAST and SLOW rats. Results revealed that while most genes investigated showed near equivalent expression levels, both Apolipoprotein E (APOE) and the beta2 subunit of the voltage-gated sodium channel (SCN2beta) were significantly underexpressed in brains of the seizure-prone embryos. Currently, these transcripts have no known interactions during embryogenesis; however, they have both been independently linked to seizure disposition and/or neurodevelopmental aberrations leading to epilepsy. Thus, alterations in the timing and/or degree of expression for APOE and SCN2beta may be important to developmental cascades that ultimately give rise to the differing brain morphologies, behaviors, and/or seizure vulnerabilities that characterize these strains.

Basic developmental rules and their implications for epilepsy in the immature brain.

The construction of the human brain with its 10(15) synapses follows a set of complex developmentally and environmentally regulated steps. A series of sequences have been described that are instrumental, in the sense that a failure of any one of them leads to dramatic, life-long consequences. Hence the importance of determining the sequential maturation of neurons, synapses and cortical maps. It is also important to determine how network-driven events become installed, as neuronal activity intervenes in all of these steps and modulates, for better or worse, the outcome. A fundamental consequence of these sequential events is that any disruption will have very different consequences depending on when it occurs, indeed, "when is as important as what". An obvious aspect of these general features is related to seizures. In fact, the developing brain has both a higher incidence of seizures in human and animal models, and experiences seizures that can produce long-lasting consequences that are also stage-dependent. This seminar and the series of slides presented are an introduction to these issues, summing up several studies made notably by INMED researchers during the last two decades (http://www.inmednet.com). It concentrates on four basic developmental rules: i) the generation by very immature neurons, of very large currents mediated by the activation of receptors in neurons that bear no synapses. This is due to the release of GABA that diffuses to distal sites and acts as a paracrine factor; ii) the excitatory/inhibitory shift of the actions of GABA during development because of a progressive reduction in the intracellular chloride concentration; iii) the sequential formation of GABAergic synapses and networks before glutamatergic ones, implying that, at an early stage, all the excitatory drive will be GABAergic; iv) the presence, at an early stage, of a unique, primitive pattern in all developing structures, this pattern disappears when most GABAergic synapses have shifted to their adult configuration. Several consequences of these sequences are described including: i) a control of neuronal migration by GABA-acting drugs, and the possibility that migration disorders are also generated by environmental factors that include the effects of GABA-acting agents; ii) If GABA excites immature neurons and inhibits adult one, then GABA-acting agents will also produce different effects on the mother and the embryo; iii) early brain oscillations are generated by the periphery and propagate centrally - notably to the sensory-motor cortex, suggesting that peripherally-generated movements may provide an important signal for the formation of cortical maps, in keeping with the importance of embryonic movements; iv) "seizures beget seizures" in the developing brain. This has now been shown in a triple chamber with the two intact hippocampi that we developed, and with which it has been possible to show that only recurrent seizures that include high frequency oscillations can transform the naïve, contralateral hippocampus to an epileptic one that seizes spontaneously. Most interestingly, at an early developmental stage, when GABA excites many neurons and the density of glutamatergic synapses is not sufficiently high, purely glutamatergic seizures cannot lead to long-term consequences, the additional excitatory drive provided by GABAergic synapses is needed. In other words, at that stage, blocking GABA synapses generates seizures, as in adults, but these do not lead to long-term consequences. The mechanisms that underlie these differences is due to the need for high frequency oscillations (> 80 Hz or so), and these can only be generated when GABA synapses are operative in the developing brain: GABA receptor antagonists are ictogenic, but not epileptogenic. To facilitate teaching purposes the paper is published together with supplemental data (as a PowerPoint presentation included in the accompanying DVD), thus allowing an overview of important developmental steps and their implications.

Relationship between evolving epileptiform activity and delayed loss of mitochondrial activity after asphyxia measured by near-infrared spectroscopy in preterm fetal sheep.

Early onset cerebral hypoperfusion after birth is highly correlated with neurological injury in premature infants, but the relationship with the evolution of injury remains unclear. We studied changes in cerebral oxygenation, and cytochrome oxidase (CytOx) using near-infrared spectroscopy in preterm fetal sheep (103-104 days of gestation, term is 147 days) during recovery from a profound asphyxial insult (n= 7) that we have shown produces severe subcortical injury, or sham asphyxia (n= 7). From 1 h after asphyxia there was a significant secondary fall in carotid blood flow (P < 0.001), and total cerebral blood volume, as reflected by total haemoglobin (P < 0.005), which only partially recovered after 72 h. Intracerebral oxygenation (difference between oxygenated and deoxygenated haemoglobin concentrations) fell transiently at 3 and 4 h after asphyxia (P < 0.01), followed by a substantial increase to well over sham control levels (P < 0.001). CytOx levels were normal in the first hour after occlusion, was greater than sham control values at 2-3 h (P < 0.05), but then progressively fell, and became significantly suppressed from 10 h onward (P < 0.01). In the early hours after reperfusion the fetal EEG was highly suppressed, with a superimposed mixture of fast and slow epileptiform transients; overt seizures developed from 8 +/- 0.5 h. These data strongly indicate that severe asphyxia leads to delayed, evolving loss of mitochondrial oxidative metabolism, accompanied by late seizures and relative luxury perfusion. In contrast, the combination of relative cerebral deoxygenation with evolving epileptiform transients in the early recovery phase raises the possibility that these early events accelerate or worsen the subsequent mitochondrial failure.

Brain damage in preterm infants: etiological pathways.

Preterm newborns represent a high-risk population for brain damage, primarily affecting the white matter, and for related neurodevelopmental disabilities. Determinants of brain damage have been extensively investigated, but there are still many controversies on how these factors can influence the developing brain and provoke damage. The concept of etiological pathway, instead of a single determinant, appears to better explain pathogenetic mechanisms: the brain damage may represent the final outcome of exposure to several combinations of risk factors in the same pathway or in different pathways and can change according to the gestational age. The aim of this article is to review the current knowledge on the pathogenesis of brain damage in preterm infants, within the frame of two main theoretical models, the ischemic and the inflammatory pathway. The relationship between the two pathways and the contribution of genetic susceptibility to ischemic and/or inflammatory insult, in modulating the extent and severity of brain damage, is also discussed.

Prenatal contributions to epilepsy: lessons from the bedside.

While epilepsy can present at any age, this condition often occurs because of adverse events early in life. Pathogenetic mechanisms also cause deleterious consequences to the brain during prenatal life. For the epileptologist to fully appreciate developmental epileptogenesis, one must apply an ontogenetic approach (i.e. "nature-nurture-niche") in order to study the epileptic condition from a fetal neurology perspective. Genetic susceptibility can involve pre-fertilization and post-fertilization mechanisms that dictate the timing and form of major malformations associated with specific epileptic syndromes. Maternal, fetal, and placental disease conditions also contribute to either brain malformations or injuries, depending on events during the first or second half of pregnancy. Sequential stages during prenatal brain development, from embryonic through perinatal periods, specify which gray and white matter structures may be adversely altered, with later expression of seizures in the context of motor, cognitive and behavioral deficits. Translational research from bench to bedside should consider the acquired causes of pediatric and adult epilepsies in the context of the patient's genetic environment.

Molecular biology and ontogeny of gamma-aminobutyric acid (GABA) receptors in the mammalian central nervous system.

gamma-Aminobutyric acid (GABA) is the predominant inhibitory neurotransmitter in the mammalian central nervous system. After release from nerve terminals, GABA binds to at least two classes of postsynaptic receptors (ie, GABAA and GABAB), which are nearly ubiquitous in the brain. GABAA receptors are postsynaptic heteropentameric complexes that display unique physiologic and pharmacologic properties based on subunit composition. Activation of GABAA receptors in mature neurons results in membrane hyperpolarization, which is mediated principally by inward chloride flux, whereas in early stages of brain development, GABAA receptor activation causes depolarization of the postsynaptic membrane. GABA, receptors reside both presynaptically and postsynaptically, exist as heterodimers and are coupled to voltage-dependent ion channels through interactions with heterotrimeric G proteins. This review summarizes the molecular biology and ontogeny of GABAA and GABAB receptors, highlighting some of their putative roles during normal brain development as well as in disease states such as epilepsy.

Striking differences in glucose and lactate levels between brain extracellular fluid and plasma in conscious human subjects: effects of hyperglycemia and hypoglycemia.

Brain levels of glucose and lactate in the extracellular fluid (ECF), which reflects the environment to which neurons are exposed, have never been studied in humans under conditions of varying glycemia. The authors used intracerebral microdialysis in conscious human subjects undergoing electrophysiologic evaluation for medically intractable epilepsy and measured ECF levels of glucose and lactate under basal conditions and during a hyperglycemia-hypoglycemia clamp study. Only measurements from nonepileptogenic areas were included. Under basal conditions, the authors found the metabolic milieu in the brain to be strikingly different from that in the circulation. In contrast to plasma, lactate levels in brain ECF were threefold higher than glucose. Results from complementary studies in rats were consistent with the human data. During the hyperglycemia-hypoglycemia clamp study the relationship between plasma and brain ECF levels of glucose remained similar, but changes in brain ECF glucose lagged approximately 30 minutes behind changes in plasma. The data demonstrate that the brain is exposed to substantially lower levels of glucose and higher levels of lactate than those in plasma; moreover, the brain appears to be a site of significant anaerobic glycolysis, raising the possibility that glucose-derived lactate is an important fuel for the brain.

Focal cortical dysplasia: a neuropathological and developmental perspective.

Focal cortical dysplasia (FCD) is a rare, sporadic disorder which is a recognised cause of chronic epilepsy. It is proposed to result from disordered neuronal migration and differentiation and has characteristic histological features which include disturbed cortical lamination, large abnormal neurons and the presence of large balloon cells with glassy eosinophilic cytoplasm and pleomorphic eccentric nuclei. These latter express both glial and neuronal markers indicative of abnormal neuroglial differentiation. In this paper we review the current literature on the neuropathology of FCD and discuss potential mechanisms. We focus on growth factors, signalling pathways and candidate genes with known roles in Drosophila and vertebrate brain development that could be responsible for the developmental brain changes seen in FCD. At issue are the factors that influence cell fate and differentiation and which regulate neural migration. Some of the molecular pathways, such as those involving the Notch and the Wnt pathways have particularly important roles in neuroglial differentiation in vertebrates, and these are proposed as potential candidates.

Mechanisms underlying epileptogenesis in cortical malformations.

The presence of developmental cortical malformations is associated with epileptogenesis and other neurological disorders. In recent years, animal models specific to certain malformations have been developed to study the underlying epileptogenic mechanisms. Teratogens (chemical, thermal or radiation) applied during cortical neuroblast division and migration result in lissencephaly and focal cortical dysplasia. Animals with these malformations have a lowered seizure threshold as well as histopathologies typical of those found in human dysgenic brains. Alterations that may promote epileptogenesis have been identified in lissencephalic brains, such as increased numbers of bursting types of neurons, and abnormal connections between hippocampus, subcortical heterotopia, and neocortex. A distinct set of pathological properties is present in animal models of 4-layered microgyria, induced with cortical lesions made during late stages of cortical neuroblast migration. Hyperexcitability has been demonstrated in cortex adjacent to the microgyrus (paramicrogyral zone) in in vitro slice preparations. A number of observations suggest that cellular differentiation is delayed in microgyric brains. Other studies show increases in postsynaptic glutamate receptors and decreases in GABA(A) receptors in microgyric cortex. These alterations could promote epileptogenesis, depending on which cell types have the altered receptors. The microgyrus lacks thalamic afferents from sensory relay nuclei, that instead appear to project to the paramicrogyral region, thereby increasing excitatory connectivity within this epileptogenic zone. These studies have provided a necessary first step in understanding molecular and cellular mechanisms of epileptogenesis associated with cortical malformations.

Evidence of enhanced kindling and hippocampal neuronal injury in immature rats with neuronal migration disorders.

PURPOSE: Neuronal migration disorders (NMD) are often found in patients with epilepsy. However, the mechanisms linking these two pathologies are not yet fully understood. In this study, we evaluated whether NMD increased kindling seizure susceptibility and seizure-induced acute neuronal damage in the immature brain. METHODS: Experimental NMD were produced by exposing pregnant rats (gestation day 15) to methylazoxymethanol acetate (MAM, 25 mg/kg, ip). Seizures were induced in rat pups (postnatal day 15) transplacentally exposed to MAM and controls by hippocampal kindling. Afterdischarge (AD) threshold and duration, seizure stage, and number of stimulations required to reach each seizure stage were recorded. Acute seizure-induced damage was histologically assessed in Nissl-stained and silver-impregnated hippocampal tissue 24 h after kindling. RESULTS: Rat pups with NMD had a significantly lower AD threshold than controls (91+/-18 vs. 163+/-23 microA; p < 0.05). Furthermore, rats with NMD required fewer stimulations to reach seizure stage 3.5 and 4 than did controls. Additionally, rats with NMD had longer AD the second day of stimulation (2,094+/-416 s vs. 1,755+/-353 s; p < 0.05). Histologic examination revealed that in rats with NMD, acute seizure-induced neuronal hippocampal damage occurred bilaterally in CA3 hippocampal neurons. CONCLUSIONS: The lowered AD threshold and more rapid kindling to stages 3.5 and 4 indicate that in the presence of severe NMD, hippocampal kindling is facilitated. Furthermore, this study suggests that in the immature brain, seizure-induced hippocampal neuronal damage occurs if there is an underlying pre-existing pathology.

[The neurobiological bases of epileptogenesis in the developing brain]. / Neirobiologicheskie osnovy épileptogeneza razvivaiushchegosia mozga.

The basics of neurophysiological, neurochemical and molecular mechanisms of epileptogenesis in early ontogeny are discussed. The role of developmental neuropathology, synaptogenesis; the role of glutamatergic and GABA-ergic transmitter systems are summarized. The candidates of genes in the childhood epilepsies, developmental changes in the expression of genes of voltage-gated ionic channels and receptor genes are reviewed.