Neurocysticercosis : a possible cause of epileptiform fits in people residing in villages served by the Bethanie clinic in the North West Province

Manoto, S.N. (Solly Ntoagae)

12 August 2008

A study to detect human taeniasis and cysticercosis was conducted in four village communities served by the Bethanie clinic in the North West Province. It was selected because of reports of people being diagnosed with epileptiform episodes (fits/seizures). The total population of the four villages is estimated at 13 947 and many house holders rear pigs in small numbers for both meat and an immediate income. The primary aims of the work were to conduct in the study area a census of all small scale pig producers and a survey of rural village consumers – both by means of a structured questionnaire. In the former, to review pig husbandry practices, slaughter and marketing of pigs and in the latter, to provide information on pork consumption, sanitation as well as people’s knowledge of Taenia solium. From the questionnaires the total number of patients with recorded seizures in the study area, within the selected time frame were determined. Stool samples from consenting participants were screened for T. solium. A descriptive analysis of retrospective data was conducted to determine the proportional morbidity of neurocysticercosis from the medical records of patients diagnosed with seizures in an attempt to establish possible sources of infection and routes of transmission. Secondary objectives were to determine more accurately the total pig population in the study area and to determine the prevalence of cysticercosis in pigs through inspection of those slaughtered at an approved abattoir – surprisingly all found to be negative. The questionnaires revealed a poor understanding of the disease, poor sanitation and hygiene, poor methods of pig husbandry and poor meat inspection and control in rural smallholder communities. There was no significant statistical difference in the proportion of households reporting evidence of epilepsy, between those who owned pigs and those that did not. The incidence of high risk behavior is common, and there is a strong evidence of a tendency towards an association between epilepsy, consumption habits and various epidemiological factors which were considered as possible risk factors. The fact that no T. solium proglottids were found in the faecal samples collected is elaborated on. It is considered unlikely, but possible that the consumer/farmer information days played a significant role in the outcome of this study. / Dissertation (MSc (Veterinary Science))--University of Pretoria, 2007. / Paraclinical Sciences / unrestricted

Taeniasis

Cysticercosis

Epileptiform

UCTD

Associação entre alterações eletroencefalográficas interictais, ressonância magnética e resultado cirúrgico de pacientes com epilepsia de lobo temporal / Association of interictal epileptiform discharges, magnetic resonance and surgical outcome of patients with temporal lobe epilepsy

Barbosa, Patricia Horn, 1980-

26 August 2018

Orientador: Fernando Cendes / Tese (doutorado) - Universidade Estadual de Campinas, Faculdade de Ciências Médicas / Made available in DSpace on 2018-08-26T20:41:16Z (GMT). No. of bitstreams: 1 Barbosa_PatriciaHorn_D.pdf: 4694168 bytes, checksum: 4b2bdfa4847274a2d3a88005c77669d2 (MD5) Previous issue date: 2015 / Resumo: Epilepsia de lobo temporal resulta com freqüência em refratariedade ao tratamento medicamentoso. Alguns fatores prognósticos da epilepsia focal e seu tratamento já foram descritos, mas outros ainda estão por ser melhor conhecidos. Nosso objetivo foi investigar associação entre alterações no EEG pré e pós-operatório e na ressonância de crânio pré-operatória com o resultado cirúrgico de pacientes com epilepsia de lobo temporal. Pacientes com epilepsia focal refratária submetidos a cirurgia após investigação não invasiva foram reavaliados. Calculamos o período livre de crises até a recorrência. Realizamos análise visual da RM crânio pré-operatória buscando sinais de atrofia hipocampal e alterações sutis no hipocampo contralateral. Revisamos exames de EEG pré e pós-operatórios buscando inicialmente a presença ou ausência de descargas epileptiformes. Posteriormente, quantificamos atividade epileptiforme interictal e buscamos associação com recorrência de crises. Utilizamos os testes estatísticos qui-quadrado e Fisher, quando adequados, e construímos curvas de sobrevivência de Kaplan-Meier, considerando recorrência de crises como desfecho, com comparação pelo método de Mantel. Na primeira parte do estudo foram incluídos 86 pacientes com atrofia hipocampal. EEG pré-operatório unilateral não se associou a resultado cirúrgico favorável; EEG pós-operatório com presença de atividade epileptiforme interictal não se associou a resultado cirúrgico desfavorável; RM cranio com hipocampo contralateral alterado se associou tanto a resultado cirúrgico desfavorável, quanto com bilateralidade nos EEGs pré-operatórios. Na segunda parte do estudo, com 129 pacientes incluídos, não encontramos associação significativa entre presença de atividade epileptiforme interictal no EEG pós-operatório e resultado cirúrgico. As curvas de sobrevivência dos grupos com descargas epileptiformes presentes versus ausentes não foram estatisticamente diferentes (p=0,09), porem observamos uma tendência, o que motivou a terceira parte. Desta forma, demonstramos, através da quantificação da atividade epileptiforme, associação entre descargas pouco frequentes no EEG pós-operatório com resultado cirúrgico favorável. Finalmente, na tentativa de estabelecer o EEG pós-operatório como preditor de recorrência de crises, não encontramos, com a amostra disponível, associação entre EEG pós-operatório com atividade epileptiforme pouco frequente e resultado cirúrgico favorável. Estes resultados demonstram que é importante valorizar alterações sutis no volume, conformação, eixo e sinal do hipocampo menos afetado na indicação de cirurgia de pacientes com epilepsia de lobo temporal e atrofia hipocampal. O resultado cirúrgico dos pacientes com hipocampo contralateral normal é mais favorável. Alteração eletrográfica bitemporal no EEG pré-operatório, em geral, está associada a alteração estrutural sutil no hipocampo contralateral, que muitas vezes não é valorizada. Tal achado corrobora evidências previamente descritas de que pacientes com EEG pré-operatório bitemporal tem prognóstico cirúrgico menos favorável. Os dados relacionados à análise quantitativa de descargas epileptiformes no EEG pós-operatório mostraram associação entre atividade epileptiforme e resultado cirúrgico. Tal achado sugere que o EEG pode ser uma ferramenta útil no seguimento clínico pós-operatório. Em conclusão, nossos resultados indicaram dois fatores importantes no prognóstico de controle de crises após cirurgia em ELT: presença de alteração hipocampal contralateral mesmo que sutil, e espículas em uma frequência maior que 4 por um período de 15 minutos / Abstract: Temporal lobe epilepsy is frequently linked to medical refractoriness. Many clinical prognostic data on focal epilepsy have repeatedly been described, while surgical outcome factors are yet to be fully known. We presently look into an association between interictal epileptiform discharges in pre and postoperative EEG, as well as preoperative brain magnetic resonance imaging, and surgical outcome of temporal lobe epilepsy. Patients with medically refractory focal epilepsy submitted to surgery following non invasive investigation were reassessed. We calculated time until seizure recurrence. We visually analysed preoperative MRI searching for signs of hipoccampal atrophy, as well as subtle contralateral hipoccampal changes. We reviewed pre and postoperative EEGs concerning presence or absence of interictal epileptiform discharges. Later on, we quantified interictal discharges and tested association with seizure freedom. We used chi square or Fisher¿s exact test, when most adequate. We also built Kaplan-Meier¿s survival curves setting seizure recurrence as endpoint, and compared curves by Mantel method. We initially included 86 patients with hipoccampal atrophy. Preoperative unilateral EEG was not associated with favorable surgical outcome; presence of IED in postoperative EEG was not associated with unfavorable outcome; contralateral hipoccampal changes on preoperative MRI was strongly associated with unfavorable surgical outcome, as well as with bilateral preoperative EEGs. We then studied postoperative EEGs of 129 individuals. There was not a significant association between postoperative EEG and surgical outcome. Survival curves of group of patients with interictal discharges present and absent were not statistically different (p=0.09), but we observed a tendency in that direction. Therefore, we were able to demonstrate through manual quantification of epileptiform discharges that postoperative EEG direct association with surgical outcome. Our ultimate goal was to establish postoperative EEG as predictor of seizure recurrence. Unfortunately we were not able to demonstrate it with data available on our sample. These results highlight importance of assessing subtle changes in volume, form, axis and signal intensity on contralateral hipoccampus prior to indication of surgery in patients with temporal lobe epilepsy with hipoccampal atrophy. Surgical outcome is more favorable when contralateral hipoccampus is normal. Bilateral discharges over temporal electrodes in pre-operative EEG are associated with subtle structural changes on contralateral hipoccampus, which may be underestimated. Such findings is in agreement with previously described evidence of bitemporal preoperative EEG associated with less favorable surgical outcome. Quantification data on postoperative EEG sets forth direct association with epileptiform discharges and surgical outcome. Such finding suggests EEG may be a useful tool in postoperative followup. In conclusion, our results indicate two important prognostic factors for seizure control in surgically treated temporal lobe epilepsy patients: presence of contralateral signs of hipoccampal sclerosis, even if subtle, and interictal epileptiform discharges occuring in a frequency higher than 4 at 15 minutes period / Doutorado / Neurociencias / Fisiopatologia Médica

Epilepsia do lobo temporal

Epilepsia - Cirurgia

Eletroencefalografia

Temporal lobe epilepsy

Epilepsy - Surgery

Interictal epileptiform discharges

Long Time Constant May Endorse Sharp Waves and Spikes Than Sharp Transients in Scalp Electroencephalography: A Comparison of Both After-Slow Among Different Time Constant and High-Frequency Activity Analysis / 頭皮脳波の長い時定数で棘波・鋭波と鋭一過性波と適切に判別することができる: 異なる時定数における後続徐波解析と、高周波活動解析の比較研究

Sultana, Shamima

23 March 2022

付記する学位プログラム名: 充実した健康長寿社会を築く総合医療開発リーダー育成プログラム / 京都大学 / 新制・課程博士 / 博士(医科学) / 甲第23816号 / 医科博第137号 / 新制||医科||9(附属図書館) / 京都大学大学院医学研究科医科学専攻 / (主査)教授 伊佐 正, 教授 林 康紀, 教授 村井 俊哉 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

Epileptiform discharge

Total area

Total duration

Paroxysmal depolarization shifts

High-frequency activity

491

A Mathematical Model of CA1 Hippocampal Neurons with Astrocytic Input

Ferguson, Katie

January 2009

Over time astrocytes have been thought to function in an auxiliary manner, providing neurons with metabolic and structural support. However, recent research suggests they may play a fundamental role in the generation and propagation of focal epileptic seizures by causing synchronized electrical bursts in neurons. It would be helpful to have a simple mathematical model that represents this dynamic and incorporates these updated experimental results. We have created a two-compartment model of a typical neuron found in the hippocampal CA1 region, an area often thought to be the origin of these seizures. The focus is on properly modeling the astrocytic input to examine the pathological excitation of these neurons and subsequent transmission of the signals. In particular, we consider the intracellular astrocytic calcium fluctuations which are associated with slow inward currents in neighbouring neurons. Using our model, a variety of experimental results are reproduced, and comments are made about the potential differences between graded and “all-or-none” astrocytes.

applied math

neuroscience

mathematical model

astrocyte

hippocampus

epilepsy

epileptiform burst

seizure

pyramidal neuron

CA1 neuron

Applied Mathematics

A Mathematical Model of CA1 Hippocampal Neurons with Astrocytic Input

Ferguson, Katie

January 2009

Over time astrocytes have been thought to function in an auxiliary manner, providing neurons with metabolic and structural support. However, recent research suggests they may play a fundamental role in the generation and propagation of focal epileptic seizures by causing synchronized electrical bursts in neurons. It would be helpful to have a simple mathematical model that represents this dynamic and incorporates these updated experimental results. We have created a two-compartment model of a typical neuron found in the hippocampal CA1 region, an area often thought to be the origin of these seizures. The focus is on properly modeling the astrocytic input to examine the pathological excitation of these neurons and subsequent transmission of the signals. In particular, we consider the intracellular astrocytic calcium fluctuations which are associated with slow inward currents in neighbouring neurons. Using our model, a variety of experimental results are reproduced, and comments are made about the potential differences between graded and “all-or-none” astrocytes.

applied math

neuroscience

mathematical model

astrocyte

hippocampus

epilepsy

epileptiform burst

seizure

pyramidal neuron

CA1 neuron

Applied Mathematics

Epileptiform Activity Induced Alterations In Ca2+ Dynamics And Network Physiology Of Hippocampal Neurons - In Vitro Studies

Srinivas, V Kalyana

12 1900

Epilepsy is characterized by the hyperexcitability of individual neurons and hyper synchronization of groups of neurons (networks). The acquired changes that take place at molecular, cellular and network levels are important for the induction and maintenance of epileptic activity in the brain. Epileptic activity is known to alter the intrinsic properties and signaling of neurons. Understanding acquired changes that cause epilepsy may lead to innovative strategies to prevent or cure this neurological disorder. Advances in in vitro electrophysiological techniques together with experimental models of epilepsy are indispensible tools to understand molecular, cellular and network mechanisms that underlie epileptiform activity. The aim of the study was to investigate the epileptiform activity induced alterations in Ca2+ dynamics in apical dendrites of hippocampal subicular pyramidal neurons in slices and changes in network properties of cultured hippocampal neurons. We have also made attempts to develop an in vitro model of epilepsy using organotypic hippocampal slice cultures. In the first part of the present study, investigations on the basic properties of dendritic Ca2+ signaling in subicular pyramidal neurons during epileptiform activity are described. Subiculum, a part of the hippocampal formation is present, adjacent to the CA1 subfield. It acts as a transition zone between the hippocampus and entorhinal cortex. It receives inputs directly from the CA1 region, the entorhinal cortex, subcortical and other cortical areas. Several forms of evidences support the role of subiculum in temporal lobe epilepsy. Pronounced neuronal loss has been reported in various regions of the hippocampal formation (CA1 and CA3) leaving the subiculum generally intact in human epileptic tissue. It has been observed that epileptic activity is generated in subiculum in cases where the CA3 and CA1 regions are damaged or even absent. However, it is not clear how subicular neurons protect themselves from epileptic activity induced neuronal death. It is widely accepted that epileptiform activity induced neuronal damage is a result of an abnormally large influx of Ca2+ into neuronal compartments. In the present study, combined hippocampus / entorhinal cortical brain slices were exposed to zero Mg2+ + 4-amino pyridine artificial cerebrospinal fluid (ACSF) to generate spontaneous epileptiform discharges. Whole cell current-clamp recordings combined with Ca2+ imaging experiments (by incorporating Oregon green BAPTA-1 in the recording pipette) were performed on subicular pyramidal neurons to understand the changes in [Ca2+]i transients elicited in apical dendrites, in response to spontaneous epileptic discharges. To understand the changes occurring with respect to control, experiments were performed (in both control and in vitro epileptic conditions) where [Ca2+]i transients in dendrites were elicited by back propagating action potentials following somatic current injections. The results show clear distance-dependent changes in decay kinetics of [Ca2+]i transients (τdecay), without change in the amplitude of the [Ca2+]i transients, in distal parts (95–110 µm) compared to proximal segments (30–45 µm) of apical dendrites of subicular pyramidal neurons under in vitro epileptic condition, but not in control conditions. Pharmacological agents that block Ca2+ transporters viz. Na+/Ca2+ exchangers (Benzamil), plasma membrane Ca2+-ATPase pumps (Calmidazolium) and smooth endoplasmic reticulum Ca2+-ATPase pumps (Thapsigargin) were applied locally to the proximal and distal part of the apical dendrites in both experimental conditions to understand the molecular aspects of the Ca2+ extrusion mechanisms. The relative contribution of Na+/Ca2+ exchangers in Ca2+ extrusion was higher in the distal apical dendrite in in vitro epileptic condition. Using computer simulations with NEURON, biophysically realistic models were built to understand how faster decay of [Ca2+]i transients in the distal part of apical dendrite associated with [Ca2+]i extrusion mechanisms affect excitability of the neurons. With a linear increase in the density of Na+/Ca2+ exchangers along the apical dendrite, the decrease in τ decay values of [Ca2+]i transients in distal regions seen in experimental epileptic condition was reproduced in simulation. This linear increase in Na+/Ca2+ exchangers lowered the threshold for firing in response to consecutive synaptic inputs to the distal apical dendrite. Our results thus, show the existence of a novel neuroprotective mechanism in distal parts of the apical dendrite of subicular pyramidal neurons under in vitro epileptic condition with the Na+/Ca2+ exchangers being the major contributors to this mechanism. Although the enhanced contribution of Na+/Ca2+ exchangers helps the neuron in removing excess [Ca2+]i loads, it paradoxically makes the neuron hyperexcitable to synaptic inputs in the distal parts of the apical dendrites. Thus, the Na+/Ca2+ exchangers may actually protect subicular pyramidal neurons and at the same time contribute to the maintenance of epileptiform activity. In the second part of the study, neuronal network topologies and connectivity patterns were explored in control and glutamate injury induced epileptogenic hippocampal neuronal networks, cultured on planar multielectrode array (8×8) probes. Hyper synchronization of neuronal networks is the hallmark of epilepsy. To understand hyper synchronization and connectivity patterns of neuronal networks, electrical activity from multiple neurons were monitored simultaneously. The electrical activity recorded from a single electrode mainly consisted of randomly fired single spikes and bursts of spikes. Simultaneous measurement of electrical activity from all the 64 electrodes revealed network bursts. A network burst represents the period (lasting for 0.1–0.2 s) of synchronized activity in the network and, during this transient period, maximum numbers of neurons interact with each other. The network bursts were observed in both control and in vitro epileptic networks, but the frequency of network bursts was more in the latter, compared to former condition. Time stamps of individual spikes (from all 64 electrodes) during such time-aligned network burst were collected and stored in a matrix and used to construct the network topology. Connectivity maps were obtained by analyzing the spike trains using cross-covariance analysis and graph theory methods. Analysis of degree distribution, which is a measure of direct connections between electrodes in a neuronal network, showed exponential and Gaussian distributions in control and in vitro epileptic networks, respectively. Quantification of number of direct connections per electrode revealed that the in vitro epileptic networks showed much higher number of direct connections per electrode compared to control networks. Our results suggest that functional two-dimensional neuronal networks in vitro are not scale-free (not a power law degree distribution). After brief exposure to glutamate, normal hippocampal neuronal networks became hyperexcitable and fired a larger number of network bursts with altered network topology. Quantification of clustering coefficient and path length in these two types of networks revealed that the small-world network property was lost once the networks become epileptic and this was accompanied by a change from an exponential to a Gaussian network. In the last part of the study, we have explored if an excitotoxic glutamate injury (20 µM for 10 min) that produces spontaneous, recurrent, epileptiform discharges in cultured hippocampal neurons can induce epileptogenesis in hippocampal neurons of organotypic brain slice cultures. In vitro models of epilepsy are necessary to understand the mechanisms underlying seizures, the changes in brain structure and function that underlie epilepsy and are the best methods for developing new antiseizure and antiepileptogenic strategies. Glutamate receptor over-activation has been strongly associated with epileptogenesis. Recent studies have shown that brief exposure of dissociated hippocampal neurons in culture to glutamate (20 µM for 10 min) induces epileptogenesis in surviving neurons. Our aim was to extend the in vitro model of glutamate injury induced epilepsy to the slice preparations with intact brain circuits. Patch clamp technique in current-clamp mode was employed to monitor the expression of spontaneous epileptiform discharges from CA1 and CA3 neurons using several combinations of glutamate injury protocols. The results presented here represent preliminary efforts to standardize the glutamate injury protocol for inducing epileptogenesis in organotypic slice preparations. Our results indicate that glutamate injury protocols that induced epileptogenesis in dissociated hippocampal neurons in culture failed to turn CA1 and CA3 neurons of organotypic brain slice cultures epileptic. We also found that the CA1 and CA3 neurons of organotypic brain slice cultures are resilient to induction of epileptogenesis by glutamate injury protocols with 10 times higher concentrations of glutamate (200µM) than that used for neuronal cultures and long exposure periods (upto 30 min). These results clearly show that the factors involved in induction of epileptiform activity after glutamate injury in neuronal cultures and those involved in making the neurons in organotypic slices resilient to such insults are different, and understanding them could give vital clues about epileptogenesis and its control. The resilience of CA1 and CA3 neurons seen could be due to differences in homeostatic plasticity that operate in both these experimental systems. However, further studies are required to corroborate this hypothesis.

Calcium - Biophysics

Neurons - Physiology

Epilepsy

Hippocampus

Brain Slices

Hippocampal Neurons

Epileptic Seizure

Epileptogenesis

Epileptiform Activity

Hippocampal Neuronal Network

Apical Dendrites

Pyramidal Neurons

Neurophysiology

GABAA Receptor Mediated Phasic and Tonic Inhibition in Subicular Pyramidal Neurons

Sah, Nirnath

January 2013

GABA is the major inhibitory neurotransmitter in the central nervous system. It binds to two types of receptors –ionotropic GABAA and metabotropic GABAB. The GABAA receptor directly gates a Clionophore that causes hyperpolarization in mature excitatory neurons while GABAB receptor mediates a slower hyperpolarizing response via G-protein coupled receptor (GPCR) activated potassium channels. This signaling mechanism gets further complicated by the heterogeneous GABA receptor subunit composition that influences the response kinetics in the postsynaptic membrane. In this thesis, the focus has been to decipher the role of GABAA receptors in relation to cellular excitability in the subiculum under physiological and pathophysiological conditions. The subiculum, considered as the output structure of hippocampus, modulates information flow from hippocampus to various cortical and sub-cortical areas and has been implicated in learning and memory, rhythm generation and various neurological disorders. It gates hippocampal activity with its well orchestrated and fine tuned intrinsic and local network properties. Over the years many studies have shown the involvement of subiculum in temporal lobe epilepsy where it forms the focal point of epileptiform activities with altered cellular and network properties. The subiculum is characterized by the presence of a significant population of burst firing neurons that lead local epileptiform activity. By virtue of its bursting nature and recurrent connections, it is a potential site for seizure generation and maintenance. Epileptiform activities are dynamic in nature and change temporally and spatially according to the alterations in electrophysiological properties of neurons. Transitions to different electrical activities in neurons following a prolonged challenge with epileptogenic stimulus have been shown in other brain structures, but not in the subiculum. Considering the importance of the subicular burst firing neurons in the propagation of epileptiform activity to the entorhinal cortex, we have explored the phenomenon of electrophysiological phase transitions in the burst firing neurons of the subiculum in an in vitro brain slice model of epileptogenesis. Whole-cell patch clamp and extracellular field recordings revealed a distinct phenomenon in the subiculum wherein an early hyperexcitable phase was followed by a late suppressed phase upon continuous perfusion with epileptogenic 4-amino pyridine and magnesium-free medium. The late suppressed phase was characterized by inhibitory post-synaptic potentials (IPSPs) in pyramidal excitatory neurons and bursting activity in local fast spiking interneurons at a frequency of 0.1-0.8 Hz. The IPSPs were mediated by GABAA receptors that coincided with excitatory synaptic inputs to attenuate action potential discharge. These IPSPs ceased following a cut between the CA1 and subiculum. Our results suggest the importance of feedforward inhibition in the suppression of epileptiform activity in subiculum to mediate a homeostatic response towards the induced hyper-excitability. GABA release from presynaptic nerve endings activates postsynaptic GABAA receptors, which evoke faster phasic inhibitory postsynaptic currents (IPSCs) and non-inactivating inhibitory tonic current, mediated through extrasynaptic GABAA receptors. These receptors are heteropentameric GABA-gated channels assembled from 19 possible subunits (α1-6, β1-3, γ1-3, δ, π, ρ1-3, θ, and ε). The 2 major subunits involved in tonic GABAA currents in the hippocampus are α5 and δ subunits. Tonic GABAA receptor mediated inhibitory current plays an important role in neuronal physiology as well as pathophysiology such as mood disorders, insomnia, epilepsy, autism spectrum disorders and schizophrenia. While the alterations of various electrical properties due to tonic inhibition have been studied in neurons from different regions, its influence on intrinsic subthreshold resonance in pyramidal excitatory neurons having hyperpolarization-activated cyclic nucleotide-gated (HCN) channels is not known. In the present study, we show the involvement of α5βγ GABAA receptors in mediating picrotoxin sensitive tonic current in subicular pyramidal neurons using known pharmacological agents that target specific GABAA receptor subunits. We further investigated the contribution of tonic conductance in regulating subthreshold electrophysiological properties using current clamp and dynamic clamp experiments. Our experiments suggest that tonic GABAergic inhibition can actively modulate subthreshold properties of subicular pyramidal neurons including resonance due to HCNchannels that may potentially alter the response dynamics in an oscillating neuronal network.

Neurophysiology, Subiculum

GABA Receptors

Glutamate Receptors

Hippocampus

Subiculum

Epilepsy

Subicular Pyramidal Neurons

Epileptogenesis

Subicular Burst Firing Neurons

Epilepsy Models

Subicular Inhibitory Neurons

Epileptiform Activity

Neurophysiology

Localização de Fontes de Descargas Generalizadas em Pacientes com Epilepsia Mioclônica Juvenil / Location of Discharge Sources generalized in Patients with Juvenile Myoclonic Epilepsy

Gomes, Sidcley Pereira

28 May 2010

Made available in DSpace on 2016-08-17T14:53:09Z (GMT). No. of bitstreams: 1 Sidcley Pereira Gomes.pdf: 4576085 bytes, checksum: 5969f56106d77776c17330c476ba26de (MD5) Previous issue date: 2010-05-28 / One important information for the classification of epilepsy is the cortical localization of the discharges source. Juvenile myoclonic epilepsy (JME) is an idiopathic generalized epilepsy (IGE) that typically presents generalized tonic-clonic, myoclonic, or absence seizures, or a combination of these. In typical cases of JME, the seizures are usually bilateral and symmetric, and EEG shows generalized interictal epileptiform discharges and a generalized seizure pattern that also is bilaterally synchronous. Despite of the generalized pattern of this type of epilepsy, there are some electroencephalographic and clinical features that suggest focal origin for the discharges. In this work, EEG recordings of six patients were analyzed in order to find evidences for this cortical origin in JME. The analysis of the signals was based on independent component analysis (ICA) for separating epileptiform discharges from artifacts and other brain sources; then the discharge components were used to spatially localize its source. In the six patients the dipole sources were localized mainly in the frontal region, what suggests an important participation of the frontal lobe for this kind of epilepsy. / Uma informação importante para a classificação da epilepsia é a localização cortical das suas fontes de descargas. A epilepsia mioclônica juvenil (EMJ) é uma epilepsia generalizada idiopática (EIG), que tipicamente apresenta crises tônico-clônicas, mioclônicas , crises de ausênica ou uma combinação destas. Em casos típicos de EMJ, as crises são geralmente bilaterais e simétricas, e o EEG mostra descargas epileptiformes interictais generalizadas em um padrão geralmente sincrônico. A despeito dos padrões generalizados deste tipo de epilepsia, há algumas características eletroencefalográficas e clínicas que sugerem uma origem focal para estas descargas. Neste trabalho, os registros de EEG de seis pacientes foram analisados, afim de encontrar evidências para uma origem cortical em EMJ. O processamento dos sinais foi baseado na técnica de análise de componentes independentes (ICA), com a finalidade de separar descargas epileptiformes de artefatos e de outras fontes cerebrais. Após esse processo, as componentes de descargas foram usadas para localizar espacialmente suas fontes. Em seis pacientes, as fontes dipolo foram localizadas principalmente nas regiões frontais, o que sugere uma importante participação do lobo frontal para esse tipo de epilepsia.

EEG

ICA

Epileptiforme

Descargas Generalizadas

Epilepsia e Mioclônica Juvenil

EEG

ICA

Epileptiform

Generalized Discharges

Epilepsy and Juvenile Myoclonic

Modélisation de la variabilité de l'activité électrique dans le cerveau / Modeling the variability of electrical activity in the brain

Hitziger, Sebastian

14 April 2015

Cette thèse explore l'analyse de l'activité électrique du cerveau. Un défi important de ces signaux est leur grande variabilité à travers différents essais et/ou différents sujets. Nous proposons une nouvelle méthode appelée "adaptive waveform learning" (AWL). Cette méthode est suffisamment générale pour permettre la prise en compte de la variabilité empiriquement rencontrée dans les signaux neuroélectriques, mais peut être spécialisée afin de prévenir l'overfitting du bruit. La première partie de ce travail donne une introduction sur l'électrophysiologie du cerveau, présente les modalités d'enregistrement fréquemment utilisées et décrit l'état de l'art du traitement de signal neuroélectrique. La principale contribution de cette thèse consiste en 3 chapitres introduisant et évaluant la méthode AWL. Nous proposons d'abord un modèle de décomposition de signal général qui inclut explicitement différentes formes de variabilité entre les composantes de signal. Ce modèle est ensuite spécialisé pour deux applications concrètes: le traitement d'une série d'essais expérimentaux segmentés et l'apprentissage de structures répétées dans un seul signal. Deux algorithmes sont développés pour résoudre ces problèmes de décomposition. Leur implémentation efficace basée sur des techniques de minimisation alternée et de codage parcimonieux permet le traitement de grands jeux de données.Les algorithmes proposés sont évalués sur des données synthétiques et réelles contenant des pointes épileptiformes. Leurs performances sont comparées à celles de la PCA, l'ICA, et du template-matching pour la détection de pointe. / This thesis investigates the analysis of brain electrical activity. An important challenge is the presence of large variability in neuroelectrical recordings, both across different subjects and within a single subject, for example, across experimental trials. We propose a new method called adaptive waveform learning (AWL). It is general enough to include all types of relevant variability empirically found in neuroelectric recordings, but can be specialized for different concrete settings to prevent from overfitting irrelevant structures in the data. The first part of this work gives an introduction into the electrophysiology of the brain, presents frequently used recording modalities, and describes state-of-the-art methods for neuroelectrical signal processing. The main contribution of this thesis consists in three chapters introducing and evaluating the AWL method. We first provide a general signal decomposition model that explicitly includes different forms of variability across signal components. This model is then specialized for two concrete applications: processing a set of segmented experimental trials and learning repeating structures across a single recorded signal. Two algorithms are developed to solve these models. Their efficient implementation based on alternate minimization and sparse coding techniques allows the processing of large datasets. The proposed algorithms are evaluated on both synthetic data and real data containing epileptiform spikes. Their performances are compared to those of PCA, ICA, and template matching for spike detection.

Électroencéphalographie (EEG)

Potentiels évoqués (ERP)

Pointes épileptiformes

Variabilité du signal

Apprentissage de dictionnaires

Codage parcimonieux

Electroencephalography (EEG)

Event-related potentials (ERP)

Epileptiform spikes

Signal variability

Dictionary learning

Sparse coding

Optical imaging and two-photon microscopy study of hemodynamic changes contralateral to ictal focus during epileptiform discharges

Truong, Van Tri

04 1900

Il est relativement bien établi que les crises focales entraînent une augmentation régionale du flot sanguin dans le but de soutenir la demande énergétique en hémoglobine oxygénée des neurones épileptiques. Des changements hémodynamiques précoces ont également été rapportés dans la région homologue controlatérale, bien que ceci ait été moins bien caractérisé. Dans cette étude, notre objectif est de mieux caractériser, lors de crises focales, la nature des changements hémodynamiques précoces dans la région homologue controlatérale au foyer épileptique. L'imagerie optique intrinsèque (IOI) et la microscopie deux-photons sont utilisées pour étudier les changements hémodynamiques dans la région homologue controlatérale au site de crises focales induites par l’injection de 4-aminopyridine (4-AP) dans le cortex somatosensitif ipsilatéral de souris. Dans l'étude d'IOI, des changements de l’oxyhémoglobine (HbO), de la désoxyhémoglobine (HbR) et du débit sanguin cérébral ont été observées dans la région homologue controlatérale au site de crises focales lors de toutes les crises. Toutefois, ces changements étaient hétérogènes, sans patron cohérent et reproduisible. Nos expériences avec la microscopie deux-photons n’ont pas révélé de changements hémodynamiques significatifs dans la région homotopique controlatérale lors de trains de pointes épileptiques. Nos résultats doivent être interprétés avec prudence compte tenu de plusieurs limitations: d’une part absence de mesures électrophysiologiques dans la région d’intérêt controlatérale au foyer simultanément à l’imagerie deux-photons et à l'IOI; d’autre part, lors des expériences avec le deux-photons, incapacité à générer de longues décharges ictales mais plutôt des trains de pointes, couverture spatiale limitée de la région d’intérêt controlatérale, et faible puissance suite au décès prématuré de plusieurs souris pour diverses raisons techniques. Nous terminons en discutant de divers moyens pour améliorer les expériences futures. / It has been well demonstrated that focal seizures are associated with a significant increase in regional cerebral blood flow to actively supply discharging neurons with oxygenated hemoglobin. There is also some evidence to suggest that focal seizures elicit early hemodynamic changes in the contralateral homotopic area, although this has been less well documented. In this study, we aim to better characterize the nature of early hemodynamic responses contralateral to the epileptic focus during seizures. We used intrinsic optical imaging (IOI) and two-photon laser microscopy to measure the hemodynamic changes in the homotopic contralateral area following focal seizures induced by an injection of 4-aminopyridine (4-AP) in the mouse somatosensory neocortex. In the study using IOI, oxyhemoglobin (HbO), deoxyhemoglobin (HbR) and cerebral blood flow (CBF) changes were observed in the homotopic area contralateral to the focus during all seizures. However, these changes were rather heterogenous, lacking any consistent or reproducible pattern. Our two-photon study showed no significant hemodynamic changes at the capillary level in the homotopic area contralateral to the ictal focus during epileptic spike trains. However, these findings must be interpreted cautiously in light of several limitations we encountered during the experiments. Specifically, we were unable to simultaneously record electrophysiology in the contralateral homotopic area. Furthermore, during our two-photon experiments, we failed to induce long ictal discharges (inducing only spike trains) had a limited sampling of the contralateral homotopic area and reduced power as a result of low mice survival rate. We conclude by providing alternatives to possibly improve future experiments.

Réponse hémodynamique

Imagerie optique intrinsèque

Deux-photons

Épilepsie

Décharges épileptiformes

Région homologue controlatérale

Hemodynamic

Two-photon

Intrinsic optical imaging

Epileptiform discharges

Homotopic contralateral area