An investigation of the potential use of Tc-HMPAO-SPECT scanning in decompression illness

Evans, Sian Amanda

January 1994

No description available.

610

Cerebral imaging; Divers

An expert system for the visualization of medical image data

Wells, Matthew

January 1993

This work starts from the premise that, given the current considerable growth in medical imaging, there is a need to develop a method that allows the information thus gathered to be used to its optimum - not only as a separate data set but also within the context of other related data. From this has grown the concept of a visualization tool which aids the visual comprehension of data present in an image by using information both internal and external to it. As a result, key medical features should be identified, labelled and presented in a clear and meaningful manner. The development of the visualization tool has been achieved through the use of blackboard-based expert system. As well as providing a method for integrating the different models used, the blackboard shell has enabled all aspects of the visualization process to be centrally supervised using a powerful and flexible control mechanism that permits both goal directed and data driven behaviour within the system. The modular approach that has been applied permits the model-based processes of feature recognition to be developed as quasi-independent systems. Two feature recognition models have been developed and these are interfaced to the rest of the tool through a set of feature dependent experts that contain knowledge about how and when to use these models to their optimum. In addition, further modification to the prototype shell used has permitted the development and application of a feature sensitive search strategy. All components of the visualization tool have been tested separately and as a whole using real medical image data from a relatively low resolution source and have been proved to work. The regions and features information applied proved the viability of the overall-performance of the knowledge based feature models and allowed the results to be visually presented in a concise and original manner that provided additional information to an image without loss of the original information.

610.28

Brain scanning; Cerebral imaging

Epileptic syndromes with continuous spike-waves during slow-sleep: new insights into pathophysiology from functional cerebral imaging

De Tiège, Xavier

08 June 2009

Epileptic syndromes with continuous spikes and waves during slow sleep (CSWS) are age-related epileptic encephalopathy characterized by the development of various psychomotor regressions in close temporal concordance with the appearance of the electroencephalogram (EEG) pattern of CSWS (Tassinari et al., 2000). This EEG pattern consists in sleep-related activation and diffusion of spike-wave discharges during usually more than 85% of non-rapid eye movement (non-REM) sleep (Tassinari et al., 2000). A minority of the CSWS cases has been associated to cortical or thalamic lesions (symptomatic cases), while in the other cases, the aetiology is unknown. We reported two families combining benign childhood epilepsy with centro-temporal spikes (BCECS), which is the most common form of idiopathic epilepsy in childhood, and cryptogenic epilepsy with CSWS in first-degree relatives. As idiopathic epilepsies are by definition epilepsies related to a genetic predisposition, these data suggests the existence of a continuum ranging from asymptomatic carriers of centro-temporal spikes to cryptogenic epilepsies with CSWS. This hypothesis is further supported by common clinical characteristics between BCECS and epilepsies with CSWS (Fejerman et al., 2000). Epileptic syndromes with CSWS are characterized by an acute phase defined by the emergence of psychomotor deficits, various types of seizures and CSWS activity at around three to eight years of age (Holmes and Lenck-Santini, 2006; Veggiotti et al., 2001). This acute phase is followed by a recovery phase in which patients’ clinical condition improves together with the remission of CSWS pattern, which spontaneously occur at around 15 years of age but may be prompted by using antiepileptic drugs (AED) including corticosteroids (Holmes and Lenck-Santini, 2006; Veggiotti et al., 2001). This biphasic evolution suggests that CSWS activity largely contributes to the psychomotor deficits observed in these patients (Holmes and Lenck-Santini, 2006; Van Bogaert et al., 2006). However, some authors still consider CSWS activity as an epiphenomenon reflecting the underlying brain pathology, rather than the direct cause of the psychomotor regression (Aldenkamp and Arends, 2004). The pathophysiological mechanisms of how CSWS activity could actually lead to psychomotor regression are still poorly understood. Functional cerebral imaging techniques such as positron emission tomography (PET) or functional magnetic resonance imaging (fMRI), represent unique ways to non-invasively study the impact of epileptic activity on normal brain function. The PET technique using [18F]-fluorodeoxyglucose (FDG) gives information about the regional neuronal glucose consumption via the neurometabolic coupling while the fMRI technique studies the regional perfusional changes directly related to specific events of interest via the neurovascular coupling. We applied both FDG-PET and EEG combined with fMRI (EEG-fMRI) techniques to epileptic children with CSWS to better approach the functional repercussions of CSWS activity on neurophysiological functions and to determine the potential pathophysiological link between CSWS activity and psychomotor regression. In a first FDG-PET study, we determined the regional cerebral glucose metabolic patterns at the acute phase of CSWS in 18 children. We found three types of metabolic patterns: the association of focal hypermetabolism with distinct hypometabolism in 10 patients, focal hypometabolism without any associated area of increased metabolism in five children, and the absence of any significant metabolic abnormality in three patients. The hypermetabolic brain areas were anatomically related to an EEG focus. This anatomical relationship was clearly less consistent for hypometabolic regions. The metabolic abnormalities involved mainly the associative cortices. The metabolic heterogeneity found in these children could be due to the use of corticosteroids before PET as it was significantly associated with the absence of focal hypermetabolism. At the group level, patients with at least one hypermetabolic brain areas showed significant increased metabolism in the right parietal region that was associated to significant hypometabolism in the prefrontal cortex. This finding was interpreted as a phenomenon of remote inhibition of the frontal lobes by highly epileptogenic and hypermetabolic posterior cortex. This hypothesis was supported by effective connectivity analyses which demonstrated the existence of significant changes in the metabolic relationship between these brain areas in this group of children compared to the control group or to the group of children without any significant hypermetabolic brain area. This remote inhibition hypothesis would be reinforced by the demonstration, at the recovery phase of CSWS, of a common resolution of hypermetabolism at the site of epileptic foci and hypometabolism in distant connected brain areas. We thus performed a second FDG-PET study to determine the evolution of cerebral metabolism in nine children recovering from CSWS. At the acute phase of CSWS, all children had a metabolic pattern characterized by the association of focal hypermetabolism with distinct focal hypometabolic areas. The evolution to CSWS recovery was characterized by a complete or almost complete regression of both hypermetabolic and hypometabolic abnormalities. At the group level, the altered effective connectivity found at the acute phase between focal hypermetabolism (centro-parietal regions and right fusiform gyrus) and widespread hypometabolism (prefrontal and orbito-frontal cortices, temporal lobes, left parietal cortex, precuneus and cerebellum) markedly regressed at recovery. These results were of particular interest because they strongly suggested that the metabolic abnormalities observed during the acute phase of CSWS were mainly related to the neurophysiological effects of CSWS activity and not to the underlying cause of the epileptic disease. Moreover, this study confirmed that phenomena of remote inhibition do occur in epileptic syndromes with CSWS. EEG-fMRI is a functional cerebral imaging technique that allows non-invasive mapping of haemodynamic changes directly associated to epileptic activity. In a first EEG-fMRI study, we determined the clinical relevance of the perfusional changes linked to interictal epileptic discharges in a group of seven children with pharmacoresistant focal epilepsy. This study showed that the EEG-fMRI technique is a promising tool to non-invasively localize the epileptic focus and its repercussion on normal brain function in children with epilepsy. Then, to further demonstrate the involvement of CSWS activity in the neurophysiological changes detected by FDG-PET, we used the EEG-fMRI technique to study the perfusional changes directly related to the epileptic activity in an epileptic girl with CSWS. This patient developed a cognitive and behavioural regression in association with a major increase in frequency and diffusion of the spike-wave discharges during the awake state (spike index: 50-75%) and non-REM sleep (spike index: 85-90%). The patient’s neuropsychological profile was dominated by executive dysfunction and memory impairment. During runs of secondarily generalized spike-wave discharges, EEG-fMRI demonstrated deactivations in the lateral and medial fronto-parietal cortices, posterior cingulate gyrus and cerebellum together with focal relative activations in the right frontal, parietal and temporal cortices. These results suggested that the neuropsychological impairment in this case could be related to specific cortical dysfunction secondary to the spread of the epileptic activity from focal hypermetabolic foci. Taken together, both FDG-PET and EEG-fMRI investigations performed in epileptic children with CSWS have shown increases in metabolism/perfusion at the site of the epileptic focus that were associated to decreases in metabolism/perfusion in distinct connected brain areas. These data highly suggest that the neurophysiological effects of CSWS activity are not restricted to the epileptic focus but spread to connected brain areas via a possible mechanism of surrounding and/or remote inhibition. This mechanism is characterised by an epilepsy-induced inhibition of neurons that surround or are remote from the epileptic focus and connected with it via cortico-cortical or polysynaptic pathways (Witte and Bruehl, 1999). The existence of surrounding and remote inhibition phenomena have been well documented in different types of animal models of focal epilepsy using various functional cerebral imaging methods such as autoradiography or optical imaging (Bruehl et al., 1998; Bruehl and Witte, 1995; Witte et al., 1994). Their occurrence in human epilepsy have also been suspected in temporal or extra-temporal lobe epilepsies using FDG-PET, EEG-fMRI or single photon emission computed tomography (SPECT) (Blumenfeld et al., 2004; Schwartz and Bonhoeffer, 2001; Van Paesschen et al., 2003; Van Paesschen et al., 2007). Moreover, the demonstration of the regression of distant hypometabolic areas after surgical resection or disconnection of the epileptic focus further suggest that such inhibition mechanism do occur in epilepsy (Bruehl et al., 1998; Jokeit et al., 1997). On a clinical point of view, the demonstration of the existence of such inhibition mechanisms in epilepsies with CSWS brings new important insights for the understanding of the pathophysiological mechanisms involved in the psychomotor regression observed in these conditions. Indeed, these data highly suggest that the psychomotor regression is not only related to the neurophysiological impairment at the site of the epileptic foci but also to epilepsy-induced neurophysiological changes in distant connected brain areas.

Imagerie fonctionnelle cérébrale

TEP

EEG-IRMf

Epilepsy

children

functional cerebral imaging

PET

EEG-fMRI

Epilepsie

enfants

Effets du vieillissement normal sur la production lexicale : approche pluridisciplinaire / Cerebral organization of semantic language in physiological and physiopathological conditions

Boudiaf, Naïla

23 November 2016

Le vieillissement normal est associé à des difficultés cognitives même en absence de pathologies sous-jacentes. Les fonctions cognitives sont connues pour être sensibles à l’effet de l’âge, à l'exception de la fonction langagière qui fait débat. Cependant, les personnes âgées rapportent des difficultés de production lexicale qui sont également présentes dans des maladies neurodégénératives comme la maladie d’Alzheimer. L’objectif de ce travail de thèse a été de caractériser l’évolution des processus cognitifs impliqués dans la production lexicale sur le plan comportemental puis de caractériser les modifications cérébrales neurofonctionnelles et vasculaires associées. Dans une première étude en psychologie comportementale incluant 72 participants sains, âgés de 30 à 84 ans, nous avons montré un effet différentiel de l’âge sur les processus de dénomination orale et les processus d’associations sémantiques. La dénomination orale était bien préservée dans le vieillissement normal en termes de compétence, mais elle semblait être affectée par un ralentissement cognitif généralisé. Par contre, nous avons observé un ralentissement plus important des processus d’associations sémantiques qui est probablement dû à un contrôle exécutif moins efficace. Une deuxième étude en IRM fonctionnelle a confirmé ces résultats et a suggéré la mise en place de mécanismes compensatoires pour palier ces difficultés cognitives. Enfin, nous avons caractérisé les modifications de perfusion cérébrale basale et fonctionnelle dans une dernière étude en IRM fonctionnelle vasculaire. Nous avons montré le lien entre ces modifications et les capacités cognitives chez les mêmes participants sains, ainsi que chez des patients atteints de troubles cognitifs à des stades précoces. Cette approche multimodale combinant la psychologie expérimentale, la neuropsychologie, la neuroimagerie et l’imagerie de perfusion cérébrale a permis d’obtenir un tableau neurocognitif plus complet afin de décrire les modifications cognitives, cérébrales et vasculaires qui interviennent dans le vieillissement normal lors de la production du langage. / Normal aging is associated with cognitive difficulties in many domains except for language, which is still under debate. However, older adults report difficulties in lexical production, which are also known to be associated with pathological aging, such as Alzheimer’s disease. This work aimed first to characterize the changes in the cognitive processes involved in lexical production using a behavioral approach, then to characterize the associated neurofunctional and vascular changes using fMRI. In the first study including 72 healthy participants, aged between 30 and 84 years, we showed a differential aging effect on lexical production and semantic processing. Naming was well preserved in terms of competences in normal aging; nevertheless, it was affected by the general cognitive slowdown. However, semantic processing was more affected by aging, probably due to inefficient executive control. The second study using fMRI confirmed these results and suggested the establishment of compensatory mechanisms to overcome cognitive difficulties. Finally, in the third study using vascular fMRI we described basal and functional cerebral perfusion modifications in normal aging as well as at early stages of pathological aging. We showed a strong relationship between the hemodynamical properties and the cognitive abilities. This multidisciplinary approach combining behavioral, neuropsychological, neurofunctional and cerebral perfusion imaging studies, provided a more complete picture of cerebral and cognitive changes in lexical production during normal aging.

Langage sémantique

Comportement

Imagerie cérébrale

Semantics

Behavior

Cerebral imaging

150

610

Optimisation des techniques non invasives d'IRM de perfusion cérébrale et d'imagerie spectroscopique par résonance magnétique pour l'exploration des pathologies cérébrales / Optimization of non-invasive MRI techniques of weighted perfusion and spectroscopic imaging

Lecocq, Angèle

12 December 2014

L'IRM de perfusion et de spectroscopie restent encore peu utilisées en raison de leur mise en oeuvre difficile et de leur manque de quantification. L'objectif de ces travaux a été d'optimiser et de valider des techniques IRM totalement non invasives chez l'Homme en vue d'applications cliniques permettant une exploration sur un large volume cérébral et une quantification absolue des paramètres de perfusion et du métabolisme cérébraux. Concernant la perfusion, 3 séquences de type marquage de spins,PASL PICORE, PASL FAIR et pCASL, ont été comparées en termes de sensibilité et de reproductibilité. pCASL a ensuite été intégrée dans un protocole de recherche sur des patients atteints de sclérose en plaques ou SEP. Quant au métabolisme cérébral, un protocole a été mis en place afin d'accéder à une quantification absolue et pseudo absolue des métabolites par la normalisation du signal de l'eau issue de la CSI par la densité de protons acquise en IRM. Cette technique a été validée en CSI 2D puis transposée en 3D avec la séquence EPSI sur deux orientations différentes : CACP et CACP+15°afin de constituer des valeurs normatives fiables des métabolites principaux sur tout le cerveau. L'élaboration de ces techniques en spectroscopie a abouti à une étude sur des patients souffrant de SEP démontrant la faisabilité de l'utilisation de ces techniques en clinique. Ces travaux démontrent que la quantification absolue en IRM de perfusion et en IRM de spectroscopie peut être obtenue sur un large volume cérébral de manière fiable sur un système IRM disponible en environnement clinique dans un temps d'acquisition acceptable à travers les corrections diverses spécifiques à chaque imagerie. / Conventional MRI's lack of specificity in clinical routine limits our ability to perform correct diagnoses or follow-ups of pathological diseases. Two forms of NMR imaging, perfusion weighed and spectroscopic imaging provide information about two closely related characteristics :cerebral perfusion and metabolism. However, these techniques are not widely used due to the complexity of implementation and a lack of quantification.The general aim was to optimize and validate completely non-invasive NMR techniques for further human clinical applications in the context of exploring large cerebral volumes and determining absolute or pseudo-absolute quantification of cerebral perfusion and metabolism. Concerning perfusion, three arterial spin labeling sequences, PASL PICORE, PASL FAIR and pCASL, were compared in terms of sensitivity and reproducibility. The pCASL sequence was then integrated to a protocol applied to patients suffering from multiple sclerosis. In relation to metabolism, a protocol was applied in order to access absolute and pseudo-absolute metabolite quantification by water SI normalization from MRI proton density. This technique was validated on 2D CSI and then on 3D with EPSI sequence with two orientations, AC-PC and AC-PC+15 in order to generate reliable normative values of metabolites for the whole brain. The use of those spectroscopic techniques on patients suffering from multiple sclerosis allowed demonstrating the feasibility in clinic.This work demonstrates that reliable absolute quantification in perfusion weighted and spectroscopic imaging can be obtained with extensive coverage and with an acquisition time compatible with the reality of clinical exams.

IRM de perfusion

IRM de spectroscopie

Quantification absolue

Large couverture

Imagerie cérébrale

Perfusion imaging

Spectroscopic Imaging

Absolute quantification

Large coverage

Cerebral imaging

Etude des réseaux neuronaux impliqués dans les troubles de la marche et le freezing dans la maladie de Parkinson / Study of the cerebral networks involved in gait disorders and freezing in Parkinson's disease

Maillet, Audrey

07 December 2012

Les troubles de la marche et le freezing entraînent une invalidité sévère et ont un impact important sur la qualité de vie des patients souffrant de la maladie de Parkinson (MP). Ceci est d'autant plus vrai que ces troubles répondent mal aux traitements actuels, médicamenteux et chirurgicaux. Leurs mécanismes physiopathologiques sont largement incompris. Toutefois, leur résistance aux traitements courants suggère l'extension du processus lésionnel vers des structures non-dopaminergiques concourant au contrôle de la locomotion. L'implication du noyau pédonculopontin (PPN) a été évoquée. L'objectif de cette étude était de mieux comprendre les circuits neuronaux impliqués dans ces troubles, ainsi que leur modulation par les médicaments dopaminergiques et la stimulation du PPN. Les contraintes d'immobilité de la tête, liées à l'utilisation de la technique de tomographie par émission de positons (TEP), excluant la réalisation d'une épreuve effective de marche, la tâche a été effectuée en imagerie mentale. Les mêmes réseaux neuronaux sont en effet activés lors de la réalisation effective et la représentation mentale d'un mouvement, sous réserve que l'imagerie mentale motrice soit réalisée selon une perspective dite kinesthésique. Il était donc nécessaire, au préalable, de vérifier l'aptitude des patients à imager leur marche selon cette modalité. Nos données vont dans ce sens, et montrent qu'il est possible d'améliorer cette capacité à travers une préparation spécifique. De plus, l'utilisation d'un protocole comportemental d'imagerie mentale reposant sur la loi de Fitts a permis de familiariser les patients avec la tâche d'imagerie mentale en amont de la réalisation des examens TEP, mais aussi de vérifier leur engagement dans cette dernière durant les acquisitions cérébrales. Les résultats obtenus à l'issue de l'étude menée en imagerie cérébrale confirment la complexité de la physiopathologie des troubles locomoteurs, et suggèrent notamment différents niveaux d'atteinte, à l'étage cortical, sous cortical, et du tronc cérébral, selon la nature dopa-sensible ou dopa-résistante du trouble concerné. En particulier, la dérégulation frontale semble confirmée. De plus, un dysfonctionnement du tronc cérébral pourrait être lié à l'émergence des troubles de la marche et du freezing. Nous avons également constaté une implication pariétale, mais son rôle compensateur, ou pathologique, reste encore à définir. Le freezing dopa-sensible pourrait en partie refléter l'expression aggravée de la bradykinésie parkinsonienne, étant donné l'efficacité de la lévodopa sur ce symptôme. La stimulation de la région des PPN semble quant à elle restaurer une boucle cortico-cérebello-thalamo-corticale, facilitant le mouvement dans le cas des troubles dopa-résistants. Des investigations complémentaires, sur un échantillon plus large de patients, sont donc nécessaires pour approfondir ces résultats. Une meilleure compréhension de la physiopathologie de ces troubles est en effet indispensable pour le développement de nouvelles thérapeutiques dans le but d'améliorer la prise en charge des patients souffrant de ces troubles invalidants, et ainsi leurs répercussions en termes de santé publique. / Gait disorders, including freezing of gait are frequent and disabling symptoms that lead to severe decrease of the quality of life on patients from Parkinson's disease (PD). This is emphasized by the fact that those difficulties respond poorly to current medical and surgical treatments. The underlying pathophysiology remains largely unknown. However, the resistance to actual treatments suggests the extension of the degenerative process towards non-dopaminergic structures. Involvement of the pedonculopontine nucleus (PPN) has been proposed. The aim of the study was to better understand the neural networks involved in those troubles, as well as their modulation by dopaminergic drugs and PPN stimulation. The constraints related to stillness of the head during Positron Emission Tomography (PET) exclude, necessarily, the realization of an effective gait. This task has been accomplished using mental moor imagery. The same mural networks are, indeed, activated during the actual execution and the mental representation of movement, under the assumption that motor mental imaging is undertaken from a kinesthetic perspective. Thus, it was necessary, preliminarily to this study, to control the ability of patients to imagine themselves walking from a kinesthetic point of view. Our data validate this condition. Moreover, they show that it is possible to improve this ability through a specific training. What is more, the use of a behavioral protocol, based on Fitt's law, helped the patients to familiarize themselves with this approach, before PET acquisitions, but also to control their correct performance during PET scan. The results, which have been obtained in cerebral imaging confirm the complexity of the underlying mechanisms of gait disorders, and suggest notably different levels of deregulation, on a cortical, sub-cortical and brainstem. In particular, frontal deregulation appears to be confirmed. Moreover, a deregulation of the brainstem could be more particularly involved in gait disorders apparition. We have also evidenced parietal implication, but its exact compensatory or pathologic role remains to be determined. Levodopa-responsive freezing seems to be a consequence of worsened parkinsonian bradykinesia. PPN stimulation seems able to restore a functional cortico-cerebello-cortical loop, facilitating movement. Complementarily studies, on a larger selection of patients, are thus necessary to complete those results. A better understanding of pathophysiology is, as a matter of fact, necessary for the development of new therapeutics in order to improve the therapy of patients from those very invalidating troubles, and thus, to reduce their impact on public health.

Maladie de Parkinson

Troubles de la marche

Freezing

Imagerie mentale

Dopathérapie/stimulation du PPN

Parkinson's disease

Gait disorders

Freezing of gait

Functional cerebral imaging

Mental imagery

Dopatherapy/PPN stimulation

610

Réorganisation fonctionnelle et structurale des cortex auditifs, visuels et associatifs chez les sourds profonds congénitaux ou prélinguaux

Vachon, Patrick

04 1900

En raison de l’utilisation d’un mode de communication totalement différent de celui des entendants, le langage des signes, et de l’absence quasi-totale d’afférences en provenance du système auditif, il y a de fortes chances que d’importantes modifications fonctionnelles et structurales s’effectuent dans le cerveau des individus sourds profonds. Les études antérieures suggèrent que cette réorganisation risque d’avoir des répercussions plus importantes sur les structures corticales situées le long de la voie visuelle dorsale qu’à l’intérieur de celles situées à l’intérieur de la voie ventrale. L’hypothèse proposée par Ungerleider et Mishkin (1982) quant à la présence de deux voies visuelles dans les régions occipitales, même si elle demeure largement acceptée dans la communauté scientifique, s’en trouve aussi relativement contestée. Une voie se projetant du cortex strié vers les régions pariétales postérieures, est impliquée dans la vision spatiale, et l’autre se projetant vers les régions du cortex temporal inférieur, est responsable de la reconnaissance de la forme. Goodale et Milner (1992) ont par la suite proposé que la voie dorsale, en plus de son implication dans le traitement de l’information visuo-spatiale, joue un rôle dans les ajustements sensori-moteurs nécessaires afin de guider les actions. Dans ce contexte, il est tout à fait plausible de considérer qu’un groupe de personne utilisant un langage sensori-moteur comme le langage des signes dans la vie de tous les jours, s’expose à une réorganisation cérébrale ciblant effectivement la voie dorsale. L’objectif de la première étude est d’explorer ces deux voies visuelles et plus particulièrement, la voie dorsale, chez des individus entendants par l’utilisation de deux stimuli de mouvement dont les caractéristiques physiques sont très similaires, mais qui évoquent un traitement relativement différent dans les régions corticales visuelles. Pour ce faire, un stimulus de forme définie par le mouvement et un stimulus de mouvement global ont été utilisés. Nos résultats indiquent que les voies dorsale et ventrale procèdent au traitement d’une forme définie par le mouvement, tandis que seule la voie dorsale est activée lors d’une tâche de mouvement global dont les caractéristiques psychophysiques sont relativement semblables. Nous avons utilisé, subséquemment, ces mêmes stimulations activant les voies dorsales et ventrales afin de vérifier quels pourraient être les différences fonctionnelles dans les régions visuelles et auditives chez des individus sourds profonds. Plusieurs études présentent la réorganisation corticale dans les régions visuelles et auditives en réponse à l’absence d’une modalité sensorielle. Cependant, l’implication spécifique des voies visuelles dorsale et ventrale demeure peu étudiée à ce jour, malgré plusieurs résultats proposant une implication plus importante de la voie dorsale dans la réorganisation visuelle chez les sourds. Suite à l’utilisation de l’imagerie cérébrale fonctionnelle pour investiguer ces questions, nos résultats ont été à l’encontre de cette hypothèse suggérant une réorganisation ciblant particulièrement la voie dorsale. Nos résultats indiquent plutôt une réorganisation non-spécifique au type de stimulation utilisé. En effet, le gyrus temporal supérieur est activé chez les sourds suite à la présentation de toutes nos stimulations visuelles, peu importe leur degré de complexité. Le groupe de participants sourds montre aussi une activation du cortex associatif postérieur, possiblement recruté pour traiter l’information visuelle en raison de l’absence de compétition en provenance des régions temporales auditives. Ces résultats ajoutent aux données déjà recueillies sur les modifications fonctionnelles qui peuvent survenir dans tout le cerveau des personnes sourdes, cependant les corrélats anatomiques de la surdité demeurent méconnus chez cette population. Une troisième étude se propose donc d’examiner les modifications structurales pouvant survenir dans le cerveau des personnes sourdes profondes congénitales ou prélinguales. Nos résultats montrent que plusieurs régions cérébrales semblent être différentes entre le groupe de participants sourds et celui des entendants. Nos analyses ont montré des augmentations de volume, allant jusqu’à 20%, dans les lobes frontaux, incluant l’aire de Broca et d’autres régions adjacentes impliqués dans le contrôle moteur et la production du langage. Les lobes temporaux semblent aussi présenter des différences morphométriques même si ces dernières ne sont pas significatives. Enfin, des différences de volume sont également recensées dans les parties du corps calleux contenant les axones permettant la communication entre les régions temporales et occipitales des deux hémisphères. / Due to the use of a mode of communication completely different from hearing people, Due to [the use of] a communication mode completely different from hearing people, the sign language and the absence of afferences from the auditory system, it is likely that significant functional and structural changes take place in the brains of profoundly deaf individuals. Previous studies suggest this reorganization may have greater impact on cortical structures located along the dorsal visual pathway than within the regions located inside the ventral pathway. The hypothesis, widely accepted by the scientific community, proposed by Ungerleider and Mishkin (1982) for the presence of two visual pathways in the occipital regions is also fairly contested. According to this hypothesis, one stream projecting from the striate cortex to the posterior parietal regions is involved in spatial vision and a second stream projecting to regions of the inferior temporal cortex underlying form recognition. Goodale and Milner (1992) subsequently proposed that the dorsal pathway, in addition to its involvement in the processing of visuospatial information, takes part in the necessary sensorymotor adjustments to guide actions. In this context, it is plausible to consider that a group of people using sensorimotor language (e.g., sign language) in their everyday life, the cerebral reorganization is more suited to target the dorsal pathway. The first objective of the study is to explore both visual pathways, especially the dorsal pathway, in hearing subjects by the use of two similar motion stimuli that evoke different types of processing. This was done with a form-from-motion stimuli and a global motion stimuli. Our results indicate that both dorsal and ventral pathways process forms defined by motion, while only the dorsal pathway is activated during a task of global motion whose psychophysical characteristics are relatively similar. Subsequently, we used these stimuli to activate the dorsal and ventral stream to investigate functional differences in the visual and auditory brain regions in profoundly deaf individuals. Several studies show cortical reorganization in the visual and auditory areas in response to the absence of a sensory modality. However, few studies have explored the specific involvement of dorsal and ventral visual streams, despite several results suggesting greater involvement of the dorsal pathway in visual reorganization with the deaf population. Following the use of functional brain imaging to investigate these issues, our results differed from the hypothesis suggesting a reorganization specifically targeting the dorsal pathway. Rather, our results indicate a non-specific reorganization to the different types of stimulations used. Indeed, the superior temporal gyrus was activated with the deaf following the presentation of our visual stimuli, regardless of their complexity. The group of deaf participants also showed activation of the posterior association cortex, possibly recruited to process visual information in the absence of competition from the temporal auditory regions. These results add to data already collected on the functional changes that may occur throughout the brains of deaf people, however, the anatomical correlates of deafness remains unknown in this population. A third study aimed to explore the structural changes occurring in the brains of prelingual and congenital profoundly deaf. Our results show that several brain regions appear to be different between the groups of participants composed of the deaf and hearing. Our analysis showed volume increases of up to 20% in the frontal lobe, including Broca's area and adjacent regions involved in motor control and language production. The temporal lobes also presented some morphometric differences even if they are not significant. Though not significant, the temporal lobes also presented some morphometric differences. Finally, differences in volume were also found in parts of the corpus callosum considered to carry fibers connecting the temporal and occipital lobes of both hemispheres.

réorganisation inter/intramodale

inter/intramodal reorganization

surdité

deafness

voies visuelles dorsale et ventrale

dorsal and ventral visual streams

vision

vision

plasticité

plasticity

morphométrie

morphometry

sourd

deaf

imagerie cérébrale

cerebral imaging

forme définie par le mouvement

form-from-motion

Réorganisation fonctionnelle et structurale des cortex auditifs, visuels et associatifs chez les sourds profonds congénitaux ou prélinguaux

Vachon, Patrick

04 1900

En raison de l’utilisation d’un mode de communication totalement différent de celui des entendants, le langage des signes, et de l’absence quasi-totale d’afférences en provenance du système auditif, il y a de fortes chances que d’importantes modifications fonctionnelles et structurales s’effectuent dans le cerveau des individus sourds profonds. Les études antérieures suggèrent que cette réorganisation risque d’avoir des répercussions plus importantes sur les structures corticales situées le long de la voie visuelle dorsale qu’à l’intérieur de celles situées à l’intérieur de la voie ventrale. L’hypothèse proposée par Ungerleider et Mishkin (1982) quant à la présence de deux voies visuelles dans les régions occipitales, même si elle demeure largement acceptée dans la communauté scientifique, s’en trouve aussi relativement contestée. Une voie se projetant du cortex strié vers les régions pariétales postérieures, est impliquée dans la vision spatiale, et l’autre se projetant vers les régions du cortex temporal inférieur, est responsable de la reconnaissance de la forme. Goodale et Milner (1992) ont par la suite proposé que la voie dorsale, en plus de son implication dans le traitement de l’information visuo-spatiale, joue un rôle dans les ajustements sensori-moteurs nécessaires afin de guider les actions. Dans ce contexte, il est tout à fait plausible de considérer qu’un groupe de personne utilisant un langage sensori-moteur comme le langage des signes dans la vie de tous les jours, s’expose à une réorganisation cérébrale ciblant effectivement la voie dorsale. L’objectif de la première étude est d’explorer ces deux voies visuelles et plus particulièrement, la voie dorsale, chez des individus entendants par l’utilisation de deux stimuli de mouvement dont les caractéristiques physiques sont très similaires, mais qui évoquent un traitement relativement différent dans les régions corticales visuelles. Pour ce faire, un stimulus de forme définie par le mouvement et un stimulus de mouvement global ont été utilisés. Nos résultats indiquent que les voies dorsale et ventrale procèdent au traitement d’une forme définie par le mouvement, tandis que seule la voie dorsale est activée lors d’une tâche de mouvement global dont les caractéristiques psychophysiques sont relativement semblables. Nous avons utilisé, subséquemment, ces mêmes stimulations activant les voies dorsales et ventrales afin de vérifier quels pourraient être les différences fonctionnelles dans les régions visuelles et auditives chez des individus sourds profonds. Plusieurs études présentent la réorganisation corticale dans les régions visuelles et auditives en réponse à l’absence d’une modalité sensorielle. Cependant, l’implication spécifique des voies visuelles dorsale et ventrale demeure peu étudiée à ce jour, malgré plusieurs résultats proposant une implication plus importante de la voie dorsale dans la réorganisation visuelle chez les sourds. Suite à l’utilisation de l’imagerie cérébrale fonctionnelle pour investiguer ces questions, nos résultats ont été à l’encontre de cette hypothèse suggérant une réorganisation ciblant particulièrement la voie dorsale. Nos résultats indiquent plutôt une réorganisation non-spécifique au type de stimulation utilisé. En effet, le gyrus temporal supérieur est activé chez les sourds suite à la présentation de toutes nos stimulations visuelles, peu importe leur degré de complexité. Le groupe de participants sourds montre aussi une activation du cortex associatif postérieur, possiblement recruté pour traiter l’information visuelle en raison de l’absence de compétition en provenance des régions temporales auditives. Ces résultats ajoutent aux données déjà recueillies sur les modifications fonctionnelles qui peuvent survenir dans tout le cerveau des personnes sourdes, cependant les corrélats anatomiques de la surdité demeurent méconnus chez cette population. Une troisième étude se propose donc d’examiner les modifications structurales pouvant survenir dans le cerveau des personnes sourdes profondes congénitales ou prélinguales. Nos résultats montrent que plusieurs régions cérébrales semblent être différentes entre le groupe de participants sourds et celui des entendants. Nos analyses ont montré des augmentations de volume, allant jusqu’à 20%, dans les lobes frontaux, incluant l’aire de Broca et d’autres régions adjacentes impliqués dans le contrôle moteur et la production du langage. Les lobes temporaux semblent aussi présenter des différences morphométriques même si ces dernières ne sont pas significatives. Enfin, des différences de volume sont également recensées dans les parties du corps calleux contenant les axones permettant la communication entre les régions temporales et occipitales des deux hémisphères. / Due to the use of a mode of communication completely different from hearing people, Due to [the use of] a communication mode completely different from hearing people, the sign language and the absence of afferences from the auditory system, it is likely that significant functional and structural changes take place in the brains of profoundly deaf individuals. Previous studies suggest this reorganization may have greater impact on cortical structures located along the dorsal visual pathway than within the regions located inside the ventral pathway. The hypothesis, widely accepted by the scientific community, proposed by Ungerleider and Mishkin (1982) for the presence of two visual pathways in the occipital regions is also fairly contested. According to this hypothesis, one stream projecting from the striate cortex to the posterior parietal regions is involved in spatial vision and a second stream projecting to regions of the inferior temporal cortex underlying form recognition. Goodale and Milner (1992) subsequently proposed that the dorsal pathway, in addition to its involvement in the processing of visuospatial information, takes part in the necessary sensorymotor adjustments to guide actions. In this context, it is plausible to consider that a group of people using sensorimotor language (e.g., sign language) in their everyday life, the cerebral reorganization is more suited to target the dorsal pathway. The first objective of the study is to explore both visual pathways, especially the dorsal pathway, in hearing subjects by the use of two similar motion stimuli that evoke different types of processing. This was done with a form-from-motion stimuli and a global motion stimuli. Our results indicate that both dorsal and ventral pathways process forms defined by motion, while only the dorsal pathway is activated during a task of global motion whose psychophysical characteristics are relatively similar. Subsequently, we used these stimuli to activate the dorsal and ventral stream to investigate functional differences in the visual and auditory brain regions in profoundly deaf individuals. Several studies show cortical reorganization in the visual and auditory areas in response to the absence of a sensory modality. However, few studies have explored the specific involvement of dorsal and ventral visual streams, despite several results suggesting greater involvement of the dorsal pathway in visual reorganization with the deaf population. Following the use of functional brain imaging to investigate these issues, our results differed from the hypothesis suggesting a reorganization specifically targeting the dorsal pathway. Rather, our results indicate a non-specific reorganization to the different types of stimulations used. Indeed, the superior temporal gyrus was activated with the deaf following the presentation of our visual stimuli, regardless of their complexity. The group of deaf participants also showed activation of the posterior association cortex, possibly recruited to process visual information in the absence of competition from the temporal auditory regions. These results add to data already collected on the functional changes that may occur throughout the brains of deaf people, however, the anatomical correlates of deafness remains unknown in this population. A third study aimed to explore the structural changes occurring in the brains of prelingual and congenital profoundly deaf. Our results show that several brain regions appear to be different between the groups of participants composed of the deaf and hearing. Our analysis showed volume increases of up to 20% in the frontal lobe, including Broca's area and adjacent regions involved in motor control and language production. The temporal lobes also presented some morphometric differences even if they are not significant. Though not significant, the temporal lobes also presented some morphometric differences. Finally, differences in volume were also found in parts of the corpus callosum considered to carry fibers connecting the temporal and occipital lobes of both hemispheres.

réorganisation inter/intramodale

inter/intramodal reorganization

surdité

deafness

voies visuelles dorsale et ventrale

dorsal and ventral visual streams

vision

vision

plasticité

plasticity

morphométrie

morphometry

sourd

deaf

imagerie cérébrale

cerebral imaging

forme définie par le mouvement

form-from-motion

Epileptic syndromes with continuous spike-waves during slow-sleep: new insights into pathophysiology from functional cerebral imaging

De Tiege, Xavier

08 June 2009

Epileptic syndromes with continuous spikes and waves during slow sleep (CSWS) are age-related epileptic encephalopathy characterized by the development of various psychomotor regressions in close temporal concordance with the appearance of the electroencephalogram (EEG) pattern of CSWS (Tassinari et al. 2000). This EEG pattern consists in sleep-related activation and diffusion of spike-wave discharges during usually more than 85% of non-rapid eye movement (non-REM) sleep (Tassinari et al. 2000). <p>A minority of the CSWS cases has been associated to cortical or thalamic lesions (symptomatic cases), while in the other cases, the aetiology is unknown. We reported two families combining benign childhood epilepsy with centro-temporal spikes (BCECS), which is the most common form of idiopathic epilepsy in childhood, and cryptogenic epilepsy with CSWS in first-degree relatives. As idiopathic epilepsies are by definition epilepsies related to a genetic predisposition, these data suggests the existence of a continuum ranging from asymptomatic carriers of centro-temporal spikes to cryptogenic epilepsies with CSWS. This hypothesis is further supported by common clinical characteristics between BCECS and epilepsies with CSWS (Fejerman et al. 2000).<p>Epileptic syndromes with CSWS are characterized by an acute phase defined by the emergence of psychomotor deficits, various types of seizures and CSWS activity at around three to eight years of age (Holmes and Lenck-Santini, 2006; Veggiotti et al. 2001). This acute phase is followed by a recovery phase in which patients’ clinical condition improves together with the remission of CSWS pattern, which spontaneously occur at around 15 years of age but may be prompted by using antiepileptic drugs (AED) including corticosteroids (Holmes and Lenck-Santini, 2006; Veggiotti et al. 2001). This biphasic evolution suggests that CSWS activity largely contributes to the psychomotor deficits observed in these patients (Holmes and Lenck-Santini, 2006; Van Bogaert et al. 2006). However, some authors still consider CSWS activity as an epiphenomenon reflecting the underlying brain pathology, rather than the direct cause of the psychomotor regression (Aldenkamp and Arends, 2004). The pathophysiological mechanisms of how CSWS activity could actually lead to psychomotor regression are still poorly understood.<p>Functional cerebral imaging techniques such as positron emission tomography (PET) or functional magnetic resonance imaging (fMRI), represent unique ways to non-invasively study the impact of epileptic activity on normal brain function. The PET technique using [18F]-fluorodeoxyglucose (FDG) gives information about the regional neuronal glucose consumption via the neurometabolic coupling while the fMRI technique studies the regional perfusional changes directly related to specific events of interest via the neurovascular coupling. We applied both FDG-PET and EEG combined with fMRI (EEG-fMRI) techniques to epileptic children with CSWS to better approach the functional repercussions of CSWS activity on neurophysiological functions and to determine the potential pathophysiological link between CSWS activity and psychomotor regression.<p>In a first FDG-PET study, we determined the regional cerebral glucose metabolic patterns at the acute phase of CSWS in 18 children. We found three types of metabolic patterns: the association of focal hypermetabolism with distinct hypometabolism in 10 patients, focal hypometabolism without any associated area of increased metabolism in five children, and the absence of any significant metabolic abnormality in three patients. The hypermetabolic brain areas were anatomically related to an EEG focus. This anatomical relationship was clearly less consistent for hypometabolic regions. The metabolic abnormalities involved mainly the associative cortices. The metabolic heterogeneity found in these children could be due to the use of corticosteroids before PET as it was significantly associated with the absence of focal hypermetabolism. At the group level, patients with at least one hypermetabolic brain areas showed significant increased metabolism in the right parietal region that was associated to significant hypometabolism in the prefrontal cortex. This finding was interpreted as a phenomenon of remote inhibition of the frontal lobes by highly epileptogenic and hypermetabolic posterior cortex. This hypothesis was supported by effective connectivity analyses which demonstrated the existence of significant changes in the metabolic relationship between these brain areas in this group of children compared to the control group or to the group of children without any significant hypermetabolic brain area. <p>This remote inhibition hypothesis would be reinforced by the demonstration, at the recovery phase of CSWS, of a common resolution of hypermetabolism at the site of epileptic foci and hypometabolism in distant connected brain areas. We thus performed a second FDG-PET study to determine the evolution of cerebral metabolism in nine children recovering from CSWS. At the acute phase of CSWS, all children had a metabolic pattern characterized by the association of focal hypermetabolism with distinct focal hypometabolic areas. The evolution to CSWS recovery was characterized by a complete or almost complete regression of both hypermetabolic and hypometabolic abnormalities. At the group level, the altered effective connectivity found at the acute phase between focal hypermetabolism (centro-parietal regions and right fusiform gyrus) and widespread hypometabolism (prefrontal and orbito-frontal cortices, temporal lobes, left parietal cortex, precuneus and cerebellum) markedly regressed at recovery. These results were of particular interest because they strongly suggested that the metabolic abnormalities observed during the acute phase of CSWS were mainly related to the neurophysiological effects of CSWS activity and not to the underlying cause of the epileptic disease. Moreover, this study confirmed that phenomena of remote inhibition do occur in epileptic syndromes with CSWS. <p>EEG-fMRI is a functional cerebral imaging technique that allows non-invasive mapping of haemodynamic changes directly associated to epileptic activity. In a first EEG-fMRI study, we determined the clinical relevance of the perfusional changes linked to interictal epileptic discharges in a group of seven children with pharmacoresistant focal epilepsy. This study showed that the EEG-fMRI technique is a promising tool to non-invasively localize the epileptic focus and its repercussion on normal brain function in children with epilepsy. Then, to further demonstrate the involvement of CSWS activity in the neurophysiological changes detected by FDG-PET, we used the EEG-fMRI technique to study the perfusional changes directly related to the epileptic activity in an epileptic girl with CSWS. This patient developed a cognitive and behavioural regression in association with a major increase in frequency and diffusion of the spike-wave discharges during the awake state (spike index: 50-75%) and non-REM sleep (spike index: 85-90%). The patient’s neuropsychological profile was dominated by executive dysfunction and memory impairment. During runs of secondarily generalized spike-wave discharges, EEG-fMRI demonstrated deactivations in the lateral and medial fronto-parietal cortices, posterior cingulate gyrus and cerebellum together with focal relative activations in the right frontal, parietal and temporal cortices. These results suggested that the neuropsychological impairment in this case could be related to specific cortical dysfunction secondary to the spread of the epileptic activity from focal hypermetabolic foci. <p>Taken together, both FDG-PET and EEG-fMRI investigations performed in epileptic children with CSWS have shown increases in metabolism/perfusion at the site of the epileptic focus that were associated to decreases in metabolism/perfusion in distinct connected brain areas. These data highly suggest that the neurophysiological effects of CSWS activity are not restricted to the epileptic focus but spread to connected brain areas via a possible mechanism of surrounding and/or remote inhibition. This mechanism is characterised by an epilepsy-induced inhibition of neurons that surround or are remote from the epileptic focus and connected with it via cortico-cortical or polysynaptic pathways (Witte and Bruehl, 1999). The existence of surrounding and remote inhibition phenomena have been well documented in different types of animal models of focal epilepsy using various functional cerebral imaging methods such as autoradiography or optical imaging (Bruehl et al. 1998; Bruehl and Witte, 1995; Witte et al. 1994). Their occurrence in human epilepsy have also been suspected in temporal or extra-temporal lobe epilepsies using FDG-PET, EEG-fMRI or single photon emission computed tomography (SPECT) (Blumenfeld et al. 2004; Schwartz and Bonhoeffer, 2001; Van Paesschen et al. 2003; Van Paesschen et al. 2007). Moreover, the demonstration of the regression of distant hypometabolic areas after surgical resection or disconnection of the epileptic focus further suggest that such inhibition mechanism do occur in epilepsy (Bruehl et al. 1998; Jokeit et al. 1997). On a clinical point of view, the demonstration of the existence of such inhibition mechanisms in epilepsies with CSWS brings new important insights for the understanding of the pathophysiological mechanisms involved in the psychomotor regression observed in these conditions. Indeed, these data highly suggest that the psychomotor regression is not only related to the neurophysiological impairment at the site of the epileptic foci but also to epilepsy-induced neurophysiological changes in distant connected brain areas. <p><p> / Doctorat en Sciences médicales / info:eu-repo/semantics/nonPublished

Médecine pathologie humaine

Tomography, Emission

Diagnostic imaging

Brain -- Imaging

Epilepsy in children -- Pathophysiology

Tomographie par émission

Imagerie pour le diagnostic

Cerveau -- Imagerie

Imagerie fonctionnelle cérébrale

TEP

EEG-IRMf

Epilepsy

children

functional cerebral imaging

PET

EEG-fMRI

Epilepsie

enfants