Incessant transitions between active and silent states in cortico-thalamic circuits and altered neuronal excitability lead to epilepsy

Nita, Dragos Alexandru

13 April 2018

La ligne directrice de nos expériences a été l'hypothèse que l'apparition et/ou la persistance des fluctuations de longue durée entre les états silencieux et actifs dans les réseaux néocorticaux et une excitabilité neuronale modifiée sont les facteurs principaux de l'épileptogenèse, menant aux crises d’épilepsie avec expression comportementale. Nous avons testé cette hypothèse dans deux modèles expérimentaux différents. La déafférentation corticale chronique a essayé de répliquer la déafférentation physiologique du neocortex observée pendant le sommeil à ondes lentes. Dans ces conditions, caractérisées par une diminution de la pression synaptique et par une incidence augmentée de périodes silencieuses dans le système cortico-thalamique, le processus de plasticité homéostatique augmente l’excitabilité neuronale. Par conséquent, le cortex a oscillé entre des périodes actives et silencieuses et, également, a développé des activités hyper-synchrones, s'étendant de l’hyperexcitabilité cellulaire à l'épileptogenèse focale et à des crises épileptiques généralisées. Le modèle de stimulation sous-liminale chronique (« kindling ») du cortex cérébral a été employé afin d'imposer au réseau cortical une charge synaptique supérieure à celle existante pendant les états actifs naturels - état de veille ou sommeil paradoxal (REM). Dans ces conditions un mécanisme différent de plasticité qui s’est exprimé dans le système thalamo-corticale a imposé pour des longues périodes de temps des oscillations continuelles entre les époques actives et silencieuses, que nous avons appelées des activités paroxysmiques persistantes. Indépendamment du mécanisme sous-jacent de l'épileptogenèse les crises d’épilepsie ont montré certaines caractéristiques similaires : une altération dans l’excitabilité neuronale mise en évidence par une incidence accrue des décharges neuronales de type bouffée, une tendance constante vers la généralisation, une propagation de plus en plus rapide, une synchronie augmentée au cours du temps, et une modulation par les états de vigilance (facilitation pendant le sommeil à ondes lentes et barrage pendant le sommeil REM). Les états silencieux, hyper-polarisés, de neurones corticaux favorisent l'apparition des bouffées de potentiels d’action en réponse aux événements synaptiques, et l'influence post-synaptique d'une bouffée de potentiels d’action est beaucoup plus importante par rapport à l’impacte d’un seul potentiel d’action. Nous avons également apporté des évidences que les neurones néocorticaux de type FRB sont capables à répondre avec des bouffées de potentiels d’action pendant les phases hyper-polarisées de l'oscillation lente, propriété qui peut jouer un rôle très important dans l’analyse de l’information dans le cerveau normal et dans l'épileptogenèse. Finalement, nous avons rapporté un troisième mécanisme de plasticité dans les réseaux corticaux après les crises d’épilepsie - une diminution d’amplitude des potentiels post-synaptiques excitatrices évoquées par la stimulation corticale après les crises - qui peut être un des facteurs responsables des déficits comportementaux observés chez les patients épileptiques. Nous concluons que la transition incessante entre des états actifs et silencieux dans les circuits cortico-thalamiques induits par disfacilitation (sommeil à ondes lentes), déafférentation corticale (épisodes ictales à 4-Hz) ou par une stimulation sous-liminale chronique (activités paroxysmiques persistantes) crée des circonstances favorables pour le développement de l'épileptogenèse. En plus, l'augmentation de l’incidence des bouffées de potentiels d’actions induisant une excitation post-synaptique anormalement forte, change l'équilibre entre l'excitation et l'inhibition vers une supra-excitation menant a l’apparition des crises d’épilepsie. / The guiding line in our experiments was the hypothesis that the occurrence and / or the persistence of long-lasting fluctuations between silent and active states in the neocortical networks, together with a modified neuronal excitability are the key factors of epileptogenesis, leading to behavioral seizures. We addressed this hypothesis in two different experimental models. The chronic cortical deafferentation replicated the physiological deafferentation of the neocortex observed during slow-wave sleep (SWS). Under these conditions of decreased synaptic input and increased incidence of silent periods in the corticothalamic system the process of homeostatic plasticity up-regulated cortical cellular and network mechanisms and leaded to an increased excitability. Therefore, the deafferented cortex was able to oscillate between active and silent epochs for long periods of time and, furthermore, to develop highly synchronized activities, ranging from cellular hyperexcitability to focal epileptogenesis and generalized seizures. The kindling model was used in order to impose to the cortical network a synaptic drive superior to the one naturally occurring during the active states - wake or rapid eye movements (REM) sleep. Under these conditions a different plasticity mechanism occurring in the thalamo-cortical system imposed long-lasting oscillatory pattern between active and silent epochs, which we called outlasting activities. Independently of the mechanism of epileptogenesis seizures showed some analogous characteristics: alteration of the neuronal firing pattern with increased bursts probability, a constant tendency toward generalization, faster propagation and increased synchrony over the time, and modulation by the state of vigilance (overt during SWS and completely abolished during REM sleep). Silent, hyperpolarized, states of cortical neurons favor the induction of burst firing in response to depolarizing inputs, and the postsynaptic influence of a burst is much stronger as compared to a single spike. Furthermore, we brought evidences that a particular type of neocortical neurons - fast rhythmic bursting (FRB) class - is capable to consistently respond with bursts during the hyperpolarized phase of the slow oscillation, fact that may play a very important role in both normal brain processing and in epileptogenesis. Finally, we reported a third plastic mechanism in the cortical network following seizures - a decreasing amplitude of cortically evoked excitatory post-synaptic potentials (EPSP) following seizures - which may be one of the factors responsible for the behavioral deficits observed in patients with epilepsy. We conclude that incessant transitions between active and silent states in cortico-thalamic circuits induced either by disfacilitation (sleep), cortical deafferentation (4-Hz ictal episodes) and by kindling (outlasting activities) create favorable circumstances for epileptogenesis. The increase in burst-firing, which further induce abnormally strong postsynaptic excitation, shifts the balance of excitation and inhibition toward overexcitation leading to the onset of seizures.

Le complexe Centremédian/Parafasciculaire du Thalamus cible du traitement des mouvements anormaux par stimulation cérébrale profonde : approche expérimentale sur des modèles rongeurs de la maladie de Parkinson et des dystonies.

Dupuis, Loréline

22 November 2011

Ce travail s’est focalisé sur l’implication, longtemps négligée, du complexe centremédian/parafasciculaire (CM/Pf) du thalamus dans le fonctionnement physiopathologique des ganglions de la base (GB), avec pour objectif principal d’évaluer le potentiel thérapeutique du ciblage de ce noyau dans le traitement chirurgical par stimulation cérébrale profonde (SCP) des mouvements anormaux. Notre étude a porté dans un premier temps sur un modèle de la maladie de Parkinson (MP) chez le rat. La SCP à haute fréquence (SHF) du CM/Pf réduit différents troubles parkinsoniens (akinésie et négligence sensorimotrice) ainsi que les dyskinésies L‐Dopa induites. Cependant, la mise en évidence d’une action négative du traitement dopaminergique sur les effets anti‐parkinsoniens de cette stimulation compromet l’intérêt de cette cible dans le cadre de la MP dont la L‐Dopa reste le traitement de référence. Au niveau cellulaire, la SHF‐CM/Pf interfère très largement avec les effets de la lésion dopaminergique dans le réseau des GB, confirmant la position clé de ce complexe dans la modulation de l’activité des GB. De plus, la comparaison des effets comportementaux et cellulaires de la SHF de cette cible avec celle du noyau subthalamique, cible actuellement privilégiée dans le traitement de la MP, montre des spécificités en relation notamment avec une action sélective de la manipulation du CM/Pf sur le noyau entopédonculaire (EP), homologue chez le rongeur du globus pallidus interne dont l’implication dans les dyskinésies est bien documentée. Notre étude électrophysiologique in vivo confirme la relation entre activité du Pf et manifestation des dyskinésies en mettant en évidence une réactivité du Pf au traitement chronique à la L‐Dopa. Nous avons également montré que la lésion dopaminergique entraine une diminution de l’expression d’un marqueur métabolique de l’activité neuronale dans le Pf qui est complètement normalisée par la SHF, suggérant pour la première fois que la SHF pourrait corriger une diminution d’activité du noyau ciblé. Enfin, la relation étroite entre l’EP et le CM/Pf nous a encouragé à évaluer les effets de la SCP du Pf sur les dystonies sachant que celles‐ci sont traitées par SCP du globus pallidus interne. Nous avons montré, sur le modèle de hamster dtsz, que l’induction des dystonies est favorisée par la SCP à basse fréquence du Pf alors qu’elle est retardée par la SHF appliquée de façon subchronique (9 jour), ce qui met en évidence l’implication du CM/Pf dans cette autre affection motrice liée aux GB. / The involvement of the centremedian/parafascicular (CM/Pf) thalamic complex has long been neglected in the pathophysiological functioning of basal ganglia (BG). However, this complex forms a functional loop with the BG suggesting that it could be a new target for the surgical treatment by deep brain stimulation (DBS) of BG‐related disorders such as Parkinson's disease (PD). In this context, we evaluated the therapeutic potential of CM/Pf‐DBS in a rat PD model. DBS at high frequency (HFS) of CM/Pf alleviates PD symptoms (akinesia, sensorimotor neglect) as well as L‐Dopa‐induced dyskinesias. However, our observation that chronic L‐Dopa suppresses the antiparkinsonian benefits provided by CM/Pf‐HFS compromises the interest of this target for PD. At cellular level, CM/Pf‐HFS widely impacts the dopaminergic denervation‐induced changes in the BG, showing that CM/Pf is a key node for modulating BG function. Comparison of the behavioral and cellular effects of HFS of CM/Pf versus subthalamic nucleus, the currently preferred target for PD treatment, led us to suggest that their differential impact on akinesia and dyskinesia may be due to a selective action of CM/Pf‐HFS on entopeduncular nucleus (EP), the rodent homologous of internal globus pallidus, whose involvement in dyskinesia is already documented. In vivo electrophysiological recordings of CM/Pf neurons provided further support for the relationship between CM/Pf and dyskinesia. We also showed that the dopaminergic lesion resulted in a decreased gene expression of a metabolic marker of neuronal activity in the CM/Pf, which is completely normalized by HFS, providing the first evidence that HFS may be able to correct a decrease in activity of the targeted nucleus. Finally, given the close relationship between EP and CM/Pf and knowing that internal globus pallidus is a target for DBS in dystonia, we evaluated the effects of CM/Pf‐DBS in an animal model of this disorder, the dtsz hamster. We found that the stress induction of dystonia in this model is delayed by subchronic CM/Pf HFS whereas it is favored by low frequency stimulation providing evidence forthe involvement of CM/Pf in another BG‐related movement disorder.

Complexe centremédian&#8208

Parafaciculaire du thalamus

Maladie de Parkinson

Dystonies

Ganglions de laBase

Stimulation cérébrale profonde

L&#8208

Dopa

Parkinson's disease

Dystonia

Basal ganglia

Deep brain stimulation

L-Dopa

Altered Olfactory Processing of Stress Related Body Odors and Artificial Odors in Patients with Panic Disorder

Wintermann, Gloria-Beatrice, Donix, Markus, Joraschky, Peter, Gerber, Johannes, Petrowski, Katja

06 February 2014

Background: Patients with Panic Disorder (PD) direct their attention towards potential threat, followed by panic attacks, and increased sweat production. Onés own anxiety sweat odor influences the attentional focus, and discrimination of threat or non-threat. Since olfactory projection areas overlap with neuronal areas of a panic-specific fear network, the present study investigated the neuronal processing of odors in general and of stress-related sweat odors in particular in patients with PD. Methods: A sample of 13 patients with PD with/ without agoraphobia and 13 age- and gender-matched healthy controls underwent an fMRI investigation during olfactory stimulation with their stress-related sweat odors (TSST, ergometry) as well as artificial odors (peach, artificial sweat) as non-fearful non-body odors. Principal Findings: The two groups did not differ with respect to their olfactory identification ability. Independent of the kind of odor, the patients with PD showed activations in fronto-cortical areas in contrast to the healthy controls who showed activations in olfaction-related areas such as the amygdalae and the hippocampus. For artificial odors, the patients with PD showed a decreased neuronal activation of the thalamus, the posterior cingulate cortex and the anterior cingulate cortex. Under the presentation of sweat odor caused by ergometric exercise, the patients with PD showed an increased activation in the superior temporal gyrus, the supramarginal gyrus, and the cingulate cortex which was positively correlated with the severity of the psychopathology. For the sweat odor from the anxiety condition, the patients with PD showed an increased activation in the gyrus frontalis inferior, which was positively correlated with the severity of the psychopathology. Conclusions: The results suggest altered neuronal processing of olfactory stimuli in PD. Both artificial odors and stress-related body odors activate specific parts of a fear-network which is associated with an increased severity of the psychopathology.

Amygdala

Angst

Gyrus cinguli

Riechschleimhaut

Schweiß

Thalamus

TU Dresden

Publikationsfonds

Amygdala

Anxiety

Cingulate cortex

Olfactory receptor neurons

Peaches

Psychological stress

Sweat

Thalamus

Technical University Dresden

Publication funds

ddc:610

rvk:XA 10000

Effets électrophysiologiques de la stimulation du cortex moteur sur les noyaux somatosensorielslatéraux du thalamus : étude expérimentale sur un modèle de stimulation du cortex moteur chez le chat / Electrophysiological effects of Motor Cortex stimulation on the ventro-postero-lateral nucleus of the somatosensory thalamus : an experimental study on a cat model of motor cortex stimulation

Kobaïter Maarawi, Sandra

02 July 2013

La stimulation du cortex moteur (SCM) est une technique neurochirurgicale utilisée chez l'Homme comme traitement de dernier recours pour les douleurs neuropathiques rebelles. Elle a été développée sur des bases empiriques. Ce travail vise à une meilleure compréhension des mécanismes d'action de la SCM qui restent incomplètement élucidés à ce jour. L'objectif de cette thèse est d'étudier les effets électrophysiologiques de la SCM au niveau thalamique, chez un modèle de chat. La première partie de cette étude a consisté à établir une cartographie stéréotaxique du cortex moteur (CM) de cet animal, inexistante dans la littérature. À partir de cette cartographie, nous avons pu établir et valider un modèle de SCM chez cet animal, implanté de façon mini-invasive. La deuxième partie de ce travail a consisté à recueillir et analyser les changements électrophysiologiques de l'activité extracellulaire unitaire des cellules du noyau ventro-postéro-latéral (VPL) du thalamus, induits par différents protocoles de SCM. Nos résultats montrent une modulation de l'activité des cellules du VPL par la SCM, qui varie en fonction de la nature nociceptive ou non de la cellule thalamique. La SCM augmente l'activité des cellules non nociceptives et diminue celle des cellules nociceptives. Pour une cellule donnée, l'effet observé est indépendant de la correspondance somatotopique entre la région du CM stimulée et la localisation sur le corps du champ récepteur de la cellule enregistrée. Ce travail a ainsi permis de montrer l'existence d'une neuro-modulation différentielle du VPL par la SCM en fonction de la nature de la cellule thalamique / Motor cortex stimulation (MCS) is a neurosurgical technique developed on empirical basis and currently used as last solution for patients suffering from refractory neuropathic pain. The present work is a new attempt among other contemporary studies aiming to understand the mechanisms of action of MCS, which remain incompletely elucidated at that time. The main objective of this thesis is to study the electrophysiological effect of MCS at the thalamic level, in a cat model. The first part of this work aims to establish the stereotactic somatotopic map of the cat motor cortex (MC), not available so far in the literature. Based on this mapping, we created and validated a cat model of MCS, using a mini-invasive electrode implantation. The second part of this study included a recording and analysis of the potential changes of the unitary extracellular activity of cells located in the thalamic ventro-postero-lateral (VPL) nucleus, induced by different MCS protocols. Our results indicate a modulation of the VPL cells activity after MCS, depending on the nociceptive or non-nociceptive nature of the recorded thalamic cell. MCS increases the activity of non-nociceptive cells and decreases that of nociceptive cells. For a given cell the matching between the somatotopy of the MC stimulated region and the receptive field localization of the recorded thalamic cell is not a prerequisite for obtaining such a modulation. In conclusion, the present work has proven a neuro-modulatory differential effect of MCS on nociceptive and non-nociceptive cells in the thalamic VPL nucleus

Cortex moteur

Cartographie stéréotaxique

Stimulation du cortex moteur

Douleur

Noyau ventro-postéro-latéral

Thalamus

Chat

Motor cortex

Stereotactic mapping

Motor cortex stimulation

Pain

Ventral posterior lateral nucleus

Thalamus

In vivo Extracellular unitary recording

Cat

612.8

Altered Olfactory Processing of Stress Related Body Odors and Artificial Odors in Patients with Panic Disorder

Wintermann, Gloria-Beatrice, Donix, Markus, Joraschky, Peter, Gerber, Johannes, Petrowski, Katja

06 February 2014

Background: Patients with Panic Disorder (PD) direct their attention towards potential threat, followed by panic attacks, and increased sweat production. Onés own anxiety sweat odor influences the attentional focus, and discrimination of threat or non-threat. Since olfactory projection areas overlap with neuronal areas of a panic-specific fear network, the present study investigated the neuronal processing of odors in general and of stress-related sweat odors in particular in patients with PD. Methods: A sample of 13 patients with PD with/ without agoraphobia and 13 age- and gender-matched healthy controls underwent an fMRI investigation during olfactory stimulation with their stress-related sweat odors (TSST, ergometry) as well as artificial odors (peach, artificial sweat) as non-fearful non-body odors. Principal Findings: The two groups did not differ with respect to their olfactory identification ability. Independent of the kind of odor, the patients with PD showed activations in fronto-cortical areas in contrast to the healthy controls who showed activations in olfaction-related areas such as the amygdalae and the hippocampus. For artificial odors, the patients with PD showed a decreased neuronal activation of the thalamus, the posterior cingulate cortex and the anterior cingulate cortex. Under the presentation of sweat odor caused by ergometric exercise, the patients with PD showed an increased activation in the superior temporal gyrus, the supramarginal gyrus, and the cingulate cortex which was positively correlated with the severity of the psychopathology. For the sweat odor from the anxiety condition, the patients with PD showed an increased activation in the gyrus frontalis inferior, which was positively correlated with the severity of the psychopathology. Conclusions: The results suggest altered neuronal processing of olfactory stimuli in PD. Both artificial odors and stress-related body odors activate specific parts of a fear-network which is associated with an increased severity of the psychopathology.

info:eu-repo/classification/ddc/610

ddc:610

Localisation of Traumatic Brain Injury / Lokalisering av traumatisk hjärnskada

Sharma, Yogesh, Hägglund, MIchael Zewde

January 2023

TBI stands for Traumatic Brain Injury and refers to damage to the brain resulting from an external physical force, such as a blow, jolt, or penetrating injury to the head. Common causes of TBI include falls, motor vehicle accidents, sports injuries, and violence and has been linked to thousands of deaths and injuries in the US and the EU alike. This thesis was aimed to localise certain TBI to a specific part of the brain by exerting similar loading conditions on an Finite Element Method (FEM) of the rat brain as physical experiments conducted on living rats. By comparing the strain in 7 vital parts of the brain to injury diagnosis conducted in the physical experiments, an effort was made to link localised strain to injury diagnosis. The results indicate that strain in the thalamus and hypothalamus are linked with a loss of consciousness while strain in the hypothalamus coupled with the neocortex correlates greatly with activity-based behaviour changes. Lastly, injury associated with emotional changes are believed to stem from large strains in the neocortex. There is a theory suggesting that the structure of myeline, which provides support in motion and movement patterns of biological systems in humans and animals (known as biomechanical kinematics), could have an impact. However, more studies are needed to confirm and determine the exact cause. / TBI, från engelskans Traumatic Brain Injury, står för Traumatisk Hjärn Skada och syftar på en skada i hjärnan till följd av enyttre fysisk kraft, såsom ett slag, stöt eller genomträngande skada i huvudet. Vanliga orsaker till TBI inkluderar fall, motorfordonsolyckor, sportskador och våld och har kopplats till tusentals dödsfall och skadade i både USA och EU. Denna rapport syftar till att försöka lokalisera viss TBI till en specifik del av hjärnan genom att utöva liknandebelastningsförhållanden på en finit elementmetod (FEM) modell av råtthjärnan som fysiska experimentutförs på levande råttor. Genom att jämföra belastningen i 7 vitala delar av hjärnan med skadediagnos som utfördes i de fysiska experimenten gjordes en ansträngning för att koppla lokaliserad belastning till skadediagnos. Resultaten indikerar att skada i thalamus och hypotalamus är kopplade till en förlust av medvetande medan belastning i hypotalamus i kombination med neocortex korrelerar kraftigtmed aktivitetsbaserade beteendeförändringar. Slutligen är skador i samband med känslomässiga förändringartros härröra från skada i neocortex. Det finns teori som tyder på attstruktur av myelin, som ger stöd i rörelse och rörelsemönster av biologiskasystem hos människor och djur (känd som biomekanisk kinematik), kan ha en inverkan.Det behövs dock fler studier för att bekräfta och fastställa den exakta orsaken.

Traumatic Brain Injury (TBI)

Rat brain

Finite Element Method (FEM)

strain

localisation

thalamus

hypothalamus

neocortex

Traumatisk hjärnskada (TBI)

Råtthjärna

Finita Element Metod (FEM)

belastning

lokalisering

thalamus

hypotalamus

neocortex

Medical Engineering

Medicinteknik

Les morphologies du thalamus, du corps géniculé latéral et de la radiation optique n'influencent pas les ondes alpha EEG / Morphology of thalamus, LGN and optic radiation do not influence EEG alpha waves

Renauld, Emmanuelle

January 2015

Résumé : Au repos, l'activité du cerveau d'un humain sain est caractérisée par de larges fluctuations dans la bande de fréquences de 8-13 Hz d'un électroencéphalogramme (EEG), connue sous le nom de bande alpha. Bien qu'il soit établi que son activité varie d'un individu à l'autre, peu d'études se sont intéressées à la façon dont elle peut être reliée aux variations morphologiques des structures du cerveau. Entre autres, on pense que le corps géniculé latéral (CGL) et ses fibres efférentes (la radiation optique) jouent un rôle clé sur l'activité alpha, bien qu'il n'est pas certain que leur forme ou leur grosseur contribuent à sa variabilité inter-individuelle. Considérant l'utilisation courante d'EEG dans la recherche fondamentale ou clinique, ce sujet est important, mais difficile à traiter vu les problèmes associés à une bonne segmentation du CGL et de la radiation optique. Pour cette raison, nous avons utilisé la résonance magnétique de diffusion (IRMd), la résonance magnétique fonctionnelle (IRMf) et l'EEG sur 20 sujets sains pour mesurer la structure et la fonction, respectivement. L'analyse de la structure a nécessité une nouvelle approche semi-automatique pour segmenter le CGL et la radiation optique, qui nous a permis de mesurer plusieurs variables, telles que le volume et la position. Ces mesures correspondent bien aux connaissances sur la morphologie de ces structures basées sur des études post-mortem, et pourtant, nous avons trouvé que leur variabilité inter-sujet n'influençait pas la puissance des ondes alpha ou leur fréquence-type (p>0.05). Ces résultats suggèrent que la variabilité alpha soit médiée par d'autres sources structurelles. Notre méthodologie pourra servir pour de futures recherches sur l'influence de l'anatomie sur la fonction en IRMf, tomographie par émission de positron (TEP), EEG, etc., ou pour améliorer les recherches cliniques sur la radiation optique. / Abstract : At rest, healthy human brain activity is characterized by large electroencephalography (EEG) fluctuations in the 8-13 Hz range, commonly referred to as the alpha band. Although it is well known that EEG alpha activity varies across individuals, few studies have investigated how this may be related to underlying morphological variations in brain structure. Specifically, it is generally believed that the lateral geniculate nucleus (LGN) and its efferent fibres (optic radiation, OR) play a key role in alpha activity, yet it is unclear whether their shape or size variations contribute to its inter-subject variability. Given the widespread use of EEG alpha in basic and clinical research, addressing this is important, though difficult given the problems associated with reliably segmenting the LGN and OR. For this, we employed a multi-modal approach and combined diffusion magnetic resonance imaging (dMRI), functional magnetic resonance imaging (fMRI) and EEG in 20 healthy subjects to measure structure and function, respectively. For the former, we developed a new, semi-automated approach for segmenting the OR and LGN, from which we extracted several structural metrics such as volume, position and diffusivity. Although these measures corresponded well with known morphology based on previous post-mortem studies, we nonetheless found that their inter-subject variability was not significantly correlated to alpha power or peak frequency (p > 0.05). Our results therefore suggest that alpha variability may be mediated by an alternative structural source and our proposed methodology may in general help in better understanding the influence of anatomy on function.

Thalamus

Ondes alpha

LGN

IRMd

Tractographie

EEG

IRMf

CGL

Radiation optique

IRM

Optic radiation

dMRI

MRI

fMRI

Alpha waves

Tractography

Identification of b-catenin and other RNAs in developing thalamic axons

Davey, John William

January 2009

This thesis provides evidence for the presence of multiple RNAs in the axons and growth cones of developing thalamic cells, particularly the mRNA for the cell adhesion and Wnt-signalling-related molecule b-catenin. After many decades of effort, mRNAs have been shown to be present in the axons of many different systems in recent years. Furthermore, these mRNAs have been shown to be locally translated at the growth cone, and this local translation is required for axons to turn in response to multiple guidance cues. As studies accumulate, it is becoming clear that different axonal systems contain different complements of mRNAs and have different requirements for local translation. One axonal system which has not been investigated to date is the thalamocortical tract. The nuclei of the thalamus are connected to the areas of the cortex via bundles of axons which travel from the thalamus to the cortex via the ventral telencephalon during embyronic development. These axons make a number of turns and are guided by many cues and other axonal tracts before innervating their cortical target. In this thesis, a quantitative real-time polymerase chain reaction (qRT-PCR) approach is developed to isolate multiple mRNAs from developing thalamic axons in vitro, including b-catenin mRNA, b-actin mRNA, 18S ribosomal RNA and ten other mRNAs. The method used should be suitable for use with other axonal systems and also for testing the effect of guidance cues on mRNA expression in axons. The qRT-PCR results for b-catenin, b-actin and 18S have been validated using in situ hybridisation. Analysis of in situ hybridisation results indicates that b-catenin and 18S, but not b-actin, are upregulated in the growth cone compared to the axon. As b-catenin has been shown to be involved in axon guidance via Slit and ephrin guidance cues in other axonal systems, and these guidance cues act upon thalamocortical axons, the identification of b-catenin mRNA in thalamic axons is an important step towards a full understanding of the thalamocortical system. The results presented here indicate that local protein synthesis is likely to occur in thalamic axons as it does in other axonal systems, and that local translation is likely to be important for thalamic axonal responses to guidance cues and other axonal tracts.

612.8

Topographie de l’activité EEG en fuseaux au cours du sommeil chez des enfants et adultes autistes

Chicoine, Marjolaine

07 1900

Les fuseaux de sommeil sont des ondes électroencéphalographiques reflétant les mécanismes électrophysiologiques de protection du sommeil. Les adultes autistes ont un sommeil léger et moins de fuseaux de sommeil que des adultes neurotypiques. L’étude vérifie si les enfants autistes montrent également moins de fuseaux de sommeil que les enfants neurotypiques et documente leur évolution avec l’âge. Nous avons enregistré le sommeil de 34 adultes (16 autistes) et 26 enfants (13 autistes) et comparé la quantité de fuseaux de sommeil enregistrés aux électrodes préfrontales (Fp1, Fp2) et centrales (C3, C4). Les deux groupes montrent une diminution similaire des fuseaux en vieillissant. Le groupe d’enfants autistes montre moins de fuseaux que le groupe témoin aux électrodes Fp2 et C4; les adultes autistes montrent significativement moins de fuseaux que les adultes contrôles aux deux électrodes centrales. Le mauvais sommeil des autistes pourrait être causé par une faible protection du sommeil déjà présente en bas âge. / Autism is characterized by poor sleep maintenance. Sleep spindles are electroencephalographic markers representing a sleep protective mechanism. Autistic adults display less spindles than matched controls. This study investigates sleep spindle activity in children and adults with and without autism. The sleep of 34 adults (16 autistics) and 26 children (13 autistics) was recorded. Sleep spindles were counted and compared between groups at prefrontal (Fp1, Fp2) and central (C3, C4) electrodes. Both diagnostic groups showed a similar decrease in sleep spindle with age. Autistic children had significantly less spindles than controls at Fp2 and C4; adults with autism had significantly less spindles than controls at the two central electrodes. Poor sleep in children and adults with autism may be due to impaired protective mechanisms. The developmental pattern of sleep spindle topography suggests an atypical maturational course of the thalamo-cortical loop in autism.

Fuseaux de sommeil

Autisme

Ontogénie

Cortex

Thalamus

Sleep spindles

Autism

Ontogeny

Thalamic Afferents to Reorganized Auditory Cortices in Postnatally Deafened Cats

Corley, Sarah Beth

01 January 2007

Deafness affects approximately 40 million people in the United States. However, little is known about how the brain reorganizes itself in response to this major loss of inputs. Preliminary studies of neonatally deafened cats reveals that the auditory cortical area, the auditory field of the anterior ectosylvian sulcus (FAES), is reorganized as a visual area and is involved in the control of visual orientation behaviors. The plastic changes in neuronal connectivity that underlie this cortical reorganization are not known, but it is our hypothesis that sensory driving via thalamocortical inputs must change from auditory to visual thalamic origins. The present study used neuroanatomical tracing techniques in two hearing adult cats and two adult cats deafened at birth to determine the thalamic origin of projections to the FAES. When tracer was injected into the FAES of hearing animals, MGm, MGv, Pom, and dorsal thalamic nuclei showed retrogradely labeled cell bodies indicative of their projection to the FAES. When tracer was injected into the FAES of the neonatally deafened animals, MGm, MGv, Sgl, Pom, and dorsal thalamic nuclei also showed retrogradely labeled cells. In the deafened animals, no retrogradely labeled neurons were identified in the primary visual thalamic areas. Because essentially the same thalamic regions project to the FAES but relay different sensory messages in hearing and deafened animals, it must be concluded that neuronal plasticity occurred prior to the thalamocorticals projection. Therefore, therapeutic efforts to ameliorate the effects of deafness might best address thalamic rather than cortical mechanisms of plasticity and neuronal reorganization.

field of anterior ectosylvian sulcus

auditory system

sensory system

cortical reorganization

thalamus

FAES

deafness

Anatomy

Medicine and Health Sciences

Nervous System