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Influence of Primary Somatosensory Cortex on Hand Motor Circuitry and the Role of Stimulation ParametersJacobs, Mark F. 10 1900 (has links)
<p>The primary somatosensory cortex (SI) is important for hand function and influences motor circuitry in the primary motor cortex (M1). Areas 3a, 1 and 2 of SI have direct connectivity with M1. Much of our present knowledge of this connectivity and its relevance to hand function is based on animal research. However, less is known about the neural mechanisms that underpin hand function in humans. The present study investigated the influence of SI on corticospinal excitability as well as inhibitory and excitatory neural circuitry within M1 before and after continuous theta-burst stimulation (cTBS). Additionally, stimulation parameters influence the direction and magnitude of cTBS after-effects. Thus, current direction and frequency of cTBS were manipulated. Two experiments were performed. In Experiment 1, motor-evoked potentials (MEPs) were recorded from the first-dorsal interosseous (FDI) muscle bilaterally before and after 50 Hz cTBS over left SI. In a second condition, the orientation of cTBS was reversed. Experiment 2 measured MEPs, short-latency intracortical inhibition (SICI) and intracortical facilitation (ICF) from the right FDI following a modified 30 Hz cTBS over left SI or M1. The results of Experiment 1 and 2 demonstrate that SI influences M1 circuitry such that MEPs are facilitated following cTBS over SI. However, MEPs are suppressed when the current direction is reversed. CTBS at 30 Hz delivered over M1 suppressed excitatory circuitry that generates MEPs and ICF. The findings from the thesis suggest that SI influences hand motor circuitry and is likely a mechanism by which somatosensory information modulates hand motor function.</p> / Bachelor of Science (BSc)
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Applications of Deep Transcranial Magnetic Stimulation in Older Adults with Treatment-Resistant Depression / Deep Transcranial Magnetic Stimulation for Geriatric DepressionDi Passa, Anne-Marie January 2024 (has links)
This thesis discusses current insights into the applications of deep transcranial magnetic stimulation (dTMS) in older adults with treatment-resistant depression (TRD). / Objectives: To examine current evidence of clinical efficacy and applications of deep transcranial magnetic stimulation (dTMS) among older adults with treatment-resistant depression (TRD).
Methods: In Study 1, we conducted a systematic review of existing literature on the clinical efficacy of dTMS across psychiatric and cognitive disorders. Studies eligible for inclusion were clinical trials which were required to have a sham/control condition to mitigate confounding variables and to strengthen our assessment of efficacy. This dissertation specifically aimed to discuss these findings in the context of older adults with depression, as a means to investigate whether available evidence supporting the clinical efficacy of dTMS for depression is generalizable to older populations. In Study 2, we analyzed recruitment data from a pilot study investigating the effects of dTMS in older adults with TRD. Specifically, we aimed to evaluate the effectiveness of various recruitment strategies by using an enrollment-cost analysis, as well as comparing enrollment rates (i.e., enrolled participants/referrals received) for each recruitment method. Moreover, we identified potential facilitators and barriers to recruitment following a verbal thematic analysis of qualitative interview data.
Results: In Study 1, most substantial evidence (n = 6 studies) within the literature supports the clinical efficacy of the dTMS H1-coil for the treatment of depressive episodes in patients with bipolar disorder (BD) or major depressive disorder (MDD). Only one randomized controlled trial was conducted in older adults with TRD. This trial reported higher remission rates in the active dTMS arm compared to the sham dTMS arm following treatment with the H1-coil. In study 2, we found (1) health provider outreach within the affiliated inpatient and outpatient mental health clinics and (2) Facebook, to be the most effective recruitment strategies. Lastly, social support from research staff (n = 15; 88.24%) and the time-intensiveness aspect of dTMS treatments (n = 6; 35.29%) were the most frequently identified facilitators and barriers to recruitment, respectively.
Conclusions: While there is notable evidence supporting the clinical efficacy of the dTMS H1-coil for the treatment of depressive episodes, the majority of such evidence is based on findings from younger-to-middle aged groups. Thus, the generalizability of dTMS treatment efficacy to older adults remains less understood. Further sham-controlled studies are needed to determine the clinical efficacy of dTMS in older adults and to improve evidence-based care in the field of geriatric psychiatry. Importantly, we aimed to address this underrepresentation of older adults in clinical research by analyzing recruitment strategies and examining facilitators and barriers to recruitment. Future research is warranted to examine facilitators and barriers to recruitment in older adults with depression, particularly the importance of social support, which may offer valuable insights on how to overcome the issue of underrepresentation. / Thesis / Master of Science (MSc) / Brain stimulation therapies, such as deep transcranial magnetic stimulation (dTMS), show promising results for treatment-resistant depression (TRD). However, the applications of dTMS remain overlooked in geriatric populations with TRD, limiting the generalizability of such treatments to older adults. This dissertation aimed to examine current evidence supporting the use of dTMS in older adults with depression. In Study 1, we conducted a systematic review of available evidence on the clinical efficacy of dTMS across psychiatric and cognitive disorders. We found most evidence supporting the clinical efficacy of dTMS for the treatment of depressive episodes. However, the underrepresentation of older adults in such research was highly prevalent, with only one study being focused on older adults. In Study 2, we explored the effectiveness of diverse recruitment methods used in an ongoing dTMS trial for older adults with depression. Additionally, we identified potential facilitators and barriers to recruitment. Overall, the most effective recruitment strategies were (1) health provider outreach within the affiliated inpatient and outpatient mental health clinics and (2) Facebook advertising. Furthermore, social support from research staff and high time commitment of dTMS treatments were identified as facilitators and barriers to recruitment, respectively. These findings highlight the importance of conducting dTMS research in older adults to address the issue of underrepresentation and to improve evidence-based care in this special population.
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Disruptions to human speed perception induced by motion adaptation and transcranial magnetic stimulation.Burton, Mark P., McKeefry, Declan J., Barrett, Brendan T., Vakrou, Chara, Morland, A.B. 11 1900 (has links)
No / To investigate the underlying nature of the effects of transcranial magnetic stimulation (TMS) on speed perception, we applied repetitive TMS (rTMS) to human V5/MT+ following adaptation to either fast- (20 deg/s) or slow (4 deg/s)-moving grating stimuli. The adapting stimuli induced changes in the perceived speed of a standard reference stimulus moving at 10 deg/s. In the absence of rTMS, adaptation to the slower stimulus led to an increase in perceived speed of the reference, whilst adaptation to the faster stimulus produced a reduction in perceived speed. These induced changes in speed perception can be modelled by a ratio-taking operation of the outputs of two temporally tuned mechanisms that decay exponentially over time. When rTMS was applied to V5/MT+ following adaptation, the perceived speed of the reference stimulus was reduced, irrespective of whether adaptation had been to the faster- or slower-moving stimulus. The fact that rTMS after adaptation always reduces perceived speed, independent of which temporal mechanism has undergone adaptation, suggests that rTMS does not selectively facilitate activity of adapted neurons but instead leads to suppression of neural function. The results highlight the fact that potentially different effects are generated by TMS on adapted neuronal populations depending upon whether or not they are responding to visual stimuli. / BBSRC
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The contribution of human cortical area V3A to the perception of chromatic motion: a transcranial magnetic stimulation studyMcKeefry, Declan J., Burton, Mark P., Morland, A.B. January 2010 (has links)
No / Area V3A was identified in five human subjects on both a functional and retinotopic basis using functional magnetic resonance imaging techniques. V3A, along with other visual areas responsive to motion, was then targeted for disruption by repetitive transcranial magnetic stimulation (rTMS) whilst the participants performed a delayed speed matching task. The stimuli used for this task included chromatic, isoluminant motion stimuli that activated either the L-M or S-(L+M) cone-opponent mechanisms, in addition to moving stimuli that contained only luminance contrast (L+M). The speed matching task was performed for chromatic and luminance stimuli that moved at slow (2 degrees/s) or faster (8 degrees/s) speeds. The application of rTMS to area V3A produced a perceived slowing of all chromatic and luminance stimuli at both slow and fast speeds. Similar deficits were found when rTMS was applied to V5/MT+. No deficits in performance were found when areas V3B and V3d were targeted by rTMS. These results provide evidence of a causal link between neural activity in human area V3A and the perception of chromatic isoluminant motion. They establish area V3A, alongside V5/MT+, as a key area in a cortical network that underpins the analysis of not only luminance but also chromatically-defined motion.
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Investigating Task-Order Coordination in Dual-Task SituationsKübler, Sebastian 25 May 2021 (has links)
Bisherige Studien liefern Hinweise für das Auftreten von aktiven Prozessen der Reihenfolgekoordination in Doppelaufgaben. Diese Prozesse sind notwendig für die Regulation der Bearbeitungsreihenfolge von zwei Aufgaben. Bisher ist jedoch wenig über die kognitiven und neuronalen Mechanismen bekannt, die diesen Prozessen zugrunde liegen. Ziel der vorliegenden Dissertation war deshalb die Überprüfung eines Modells aktiver Reihenfolgekoordination in Doppelaufgaben. Das Modell nimmt an, dass diese Prozesse auf Repräsentationen zurückgreifen, die Informationen über die Verarbeitungssequenz zweier Aufgaben enthält. Zusätzlich macht das Modell Annahmen über (1) den Ort der Verarbeitung und (2) den genauen Inhalt dieser Repräsentationen. Weiterhin enthält das Modell die Annahmen, dass (3) der präfrontale Kortex kausal in Reihenfolgekoordination involviert ist und dass (4) diese Prozesse von unterschiedlichen Kriterien beeinflusst werden.
In dieser Dissertation wurde das Model in einer Reihe von vier Studien überprüft. Dazu wurde ein Doppelaufgabenparadigma mit zufällig wechselnder Aufgabenreihenfolge verwendet. Ich konnte zeigen, dass die Reihenfolgerepräsentationen im Arbeitsgedächtnis aufrechterhalten und aktiv verarbeitet werden. Ich konnte weiterhin zeigen, dass diese Repräsentationen nur Information über die Sequenz der Aufgaben enthalten. Spezifische Aufgabeninformation wird hingegen separat repräsentiert. Durch den Einsatz transkranieller Magnetstimulation konnte ich zudem nachweisen, dass der präfrontale Kortex eine kausale Rolle für Reihenfolgekoordination spielt. Darüber hinaus konnte ich zeigen, dass Anforderungen an Reihenfolgekoordinationsprozesse in Situationen, in denen Probanden ein von außen vorgegebenes Reihenfolgekriterium befolgen, erhöht sind im Vergleich zu Situationen, in denen Probanden ein auf einer freien Wahl basierendes Kriterium nutzen können. Die Implikationen dieser Ergebnisse werden unter Berücksichtigung des vorgeschlagenen Modells diskutiert. / Evidence from behavioral as well as neurophysiological studies indicates the occurrence of active task-order coordination processes in dual-task situations. These processes are required for planning and regulating the processing sequence of two tasks that overlap in time. So far, however, the cognitive and neural mechanisms underlying active task-order coordination are highly underspecified. To tackle this issue, in the present dissertation I tested a model of task-order coordination in dual-task situations. This model assumes that task-order coordination relies on representations that contain information about the processing sequence of the two component tasks. In addition, the model includes assumptions about the (1) locus of processing as well as (2) the exact content of these order representations. The model further assumes that (3) the lateral prefrontal cortex is causally involved in implementing task-order coordination processes and that (4) these processes are affected by different order criteria.
I tested this model in a series of four studies by applying a dual-task paradigm with randomly changing task order. I demonstrated that task-order representations are actively maintained and processed in working memory during dual tasking. Moreover, I found that these order representations only contain information about the processing sequence of tasks, whereas specific component task information is represented separately. By applying transcranial magnetic stimulation, I also provided evidence for the causal role of the lateral prefrontal cortex for task-order coordination. Furthermore, I showed that the demands on task-order coordination are increased when participants have to adhere to an external and mandatory order criterion compared to when they can use an internally generated order criterion that is based on free choice. The implications of these results as well as an outlook for future research will be discussed in the framework of the proposed model.
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Neuroplasticity: induction and modulation by external stimulation and pharmacological intervention / Neuroplastizität: Induktion und Modulation mittels externer Stimulation und pharmakologischer InterventionKuo, Min-Fang 06 July 2007 (has links)
No description available.
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Impact d’une sieste sur plasticité cérébrale induite par stimulation magnétique transcrânienneSekerovic, Zoran 09 1900 (has links)
Chez l’humain, différents protocoles de stimulation magnétique transcrânienne répétée
(SMTr) peuvent être utilisés afin de manipuler expérimentalement la plasticité cérébrale au
niveau du cortex moteur primaire (M1). Ces techniques ont permis de mieux comprendre le
rôle du sommeil dans la régulation de la plasticité cérébrale. Récemment, une étude a montré que lorsqu’une première session de stimulation SMTr au niveau de M1 est suivie d’une nuit de sommeil, l’induction subséquente de la plasticité par une deuxième session SMTr est augmentée. La présente étude a investigué si ce type de métaplasticité pouvait également bénéficier d’une sieste diurne. Quatorze sujets en santé ont reçu deux sessions de intermittent theta burst stimulation (iTBS) connue pour son effet facilitateur sur l’excitabilité corticale. Les sessions de stimulation étaient séparées par une sieste de 90 minutes ou par une période équivalente d’éveil. L’excitabilité corticale était quantifiée en terme d’amplitude des potentiels évoqués moteurs (PEM) mesurés avant et après chaque session de iTBS. Les résultats montrent que la iTBS n’est pas parvenue à augmenter de manière robuste l’amplitude des PEMs lors de la première session de stimulation. Lors de la deuxième session de stimulation, la iTBS a produit des changements plastiques variables et ce peu importe si les sujets ont dormi ou pas. Les effets de la iTBS sur l’excitabilité corticale étaient marqués par une importante variabilité inter et intra-individuelle dont les possibles causes sont discutées. / In humans, various repetitive transcranial magnetic stimulation (rTMS) protocols can
be used to modulate motor cortical plasticity. These techniques have shed light on the role of
sleep in neural plasticity regulation. Recent work has demonstrated that when a night of sleep follows one session of rTMS over the hand motor cortex (M1), the capacity to induce
subsequent plasticity by another rTMS session in M1 is enhanced. The present study
investigated whether such metaplasticity could also benefit from a day nap. Fourteen healthy
participants received two sessions of intermittent theta burst stimulation (iTBS) known for its
excitatory effects on cortical excitability over M1 spaced by either a 90-minute nap or an
equivalent amount of wake. Motor cortical excitability was measured in terms of amplitude of
motor evoked potentials (MEP), which were assessed before iTBS and after the stimulation.
Results show that the first iTBS session did not induce significant change in MEP amplitude.
The second iTBS session induced variable plastic changes regardless of whether participants slept or stayed awake. The effects of iTBS on motor cortical excitability were highly variable within and between individuals. The possible causes of such variability are discussed.
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Les effets de la similarité physique dans l’observation d’actions : études comportementales et neurophysiologiquesDésy, Marie-Christine 06 1900 (has links)
Il a été suggéré que la similarité physique entre un observateur et une action observée facilite la perception et la compréhension d’action. Par exemple, l’observation d’un acteur exécutant des gestes de la main ayant une signification culturelle est associée à une augmentation de l’excitabilité corticospinale lorsque les deux individus sont de la même ethnicité (Molnar-Szakacs et al., 2007). La perception tactile serait également facilitée lorsqu’un individu regarde un modèle de sa propre race être touché (Serino et al., 2009), tandis que des études en imagerie cérébrale fonctionnelle suggèrent la présence d’activations plus importantes dans le cortex cingulaire lorsqu’un sujet observe une personne de son propre groupe racial ressentir de la douleur (Xu et al., 2009). Certaines études ont lié ces résultats à un mécanisme de résonance motrice, possiblement associé au système des neurones miroirs (SNM), suggérant que la représentation de l’action dans les aires motrices est facilitée par la similarité physique. Toutefois, la grande majorité des stimuli utilisés dans ces études comportent une composante émotionnelle ou culturelle pouvant masquer les effets purement moteurs liant la similarité physique à un mécanisme de résonance motrice. De plus, la sélectivité de l’activation du SNM face à des stimuli biologiques a récemment été remise en question en raison de biais méthodologiques.
La présente thèse présente trois études visant à évaluer l’effet de la similarité physique et des caractéristiques biologiques d’un mouvement sur la résonance motrice à l’aide de mesures comportementales et neurophysiologiques. À cet effet, l’imitation automatique de mouvements de la main, l’excitabilité corticospinale et la désynchronisation du rythme électroencéphalographique mu ont servi de marqueurs de l’activité du SNM. Dans les trois études présentées, la couleur de la peau et l’aspect biologique du stimulus observé ou imité ont été systématiquement manipulés.
Nos données confirment la sélectivité du SNM pour le mouvement biologique en démontrant une réponse imitative plus rapide et une désynchronisation du rythme mu plus prononcée lors de la présentation de stimuli biologiques comparativement à des stimuli non-biologiques répliquant les aspects physiques du mouvement humain. Les deux mêmes mesures montrent une réponse neurophysiologique et comportementale équivalente lorsque l’action est exécutée par un agent de couleur similaire ou dissimilaire au participant. Nous rapportons aussi un effet surprenant de la similarité physique sur l’excitabilité corticospinale, où l’observation d’une action exécutée par un agent de couleur différente est associée à une activation plus grande du cortex moteur primaire droit de participants de sexe féminin.
Prises dans leur ensemble, ces données suggèrent que la similarité physique avec une action observée ne module généralement pas l’activité du SNM au niveau des aires sensorimotrices en l’absence de composantes culturelles et émotionnelles. De plus, les résultats présentés suggèrent que le SNM est sélectif au mouvement biologique plutôt qu’à l’aspect kinématique du mouvement. / It has been suggested that physical similarity with an observed model facilitates action perception and understanding. For example, increased corticospinal excitability is found in participants observing actors of their own ethnicity performing culture-specific hand movements (Molnar-Szakacs et al., 2007). Tactile perception is also said to be increased when individuals watch a model of the same race being touched (Serino et al., 2009). Moreover, imaging data suggest that stronger activations are observed in the cingulate cortex when a subject observes a person of their own race feeling pain (Xu et al., 2009). Some studies have linked these findings with a motor resonance mechanism, possibly associated with the mirror neuron system (MNS), suggesting that action representation in motor areas is facilitated by physical similarity. However, most of the observed stimuli in those studies include emotional or cultural components, which may blur the link between physical similarity and motor resonance per se.
The present thesis is comprised of three studies that aimed at evaluating the effect of physical similarity on motor resonance using stimuli that are purely motor in nature. The effect of physical similarity on motor responses during action observation was assessed with behavioral and electrophysiological measures. To this end, imitation of simple finger movements, as well as corticospinal excitability and mu rhythm desynchronization during passive observation of simple finger movements was evaluated, using stimuli that were similar or dissimilar to the participant in terms of skin color. In line with previous results, observation of biological movement resulted in faster reaction times and greater mu desynchronization compared to non-biological movement. Physical similarity with the imitated or observed hand did not affect imitation speed or mu desynchronization. It did, however, have a surprising effect on corticospinal excitability, where the amplitude of transcranial magnetic stimulation-induced motor evoked potentials was greater in the right hemisphere of female participants observing hand movement executed by hands of a different color.
These data suggest that physical similarity with an observed action in terms of skin color does not modulate MNS activity in sensorimotor cortex when cultural and emotional components are absent. The present results also strengthen the notion that the motor cortex node of the MNS is tuned to the biological nature of an observed action.
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Kortikale Repräsentation der humanen aurikulären Muskulatur: Eine Untersuchung mittels robotergestützter und neuronavigationsbasierter transkranieller Magnetstimulation / Cortical representation of the auricular muscles in humans: A robotic and neuronavigated TMS mapping studyMeincke, Jonna 13 December 2016 (has links)
No description available.
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Développement et fonctionnement des mécanismes de résonance motrice chez l'humainLepage, Jean-Francois 06 1900 (has links)
La découverte dans le cerveau du singe macaque de cellules visuo-motrices qui répondent de façon identique à la production et la perception d’actes moteurs soutient l’idée que ces cellules, connues sous le nom de neurones-miroirs, encoderaient la représentation d’actes moteurs. Ces neurones, et le système qu’ils forment, constitueraient un système de compréhension moteur; par delà la simple représentation motrice, il est également possible que ce système participe à des processus de haut niveau en lien avec la cognition sociale.
Chez l’humain adulte, des études d’imagerie récentes montrent d’importants chevauchements entre les patrons d’activité liés à l’exécution d’actes moteurs et ceux associés à la perception d’actions. Cependant, malgré le nombre important d’études sur ce système de résonance motrice, étonnamment peu se sont penchées sur les aspects développementaux de ce mécanisme, de même que sa relation avec certaines habiletés sociales dans la population neurotypique. De plus, malgré l’utilisation répandue de certaines techniques neurophysiologiques pour quantifier l’activité de ce système, notamment l’électroencéphalographie et la stimulation magnétique transcrânienne, on ignore en grande partie la spécificité et la convergence de ces mesures dans l’étude des processus de résonance motrice.
Les études rassemblées ici visent à combler ces lacunes, c'est-à-dire (1) définir l’existence et les propriétés fonctionnelles du système de résonance motrice chez l’enfant humain, (2) établir le lien entre ce système et certaines habiletés sociales spécifiques et (3) déterminer la validité des outils d’investigation couramment utilisés pour mesurer son activité.
Dans l’article 1, l’électroencéphalographie quantitative est utilisée afin de mesurer l’activité des régions sensorimotrices chez un groupe d’enfants d’âge scolaire durant la perception d’actions de la main. On y démontre une modulation de l’activité du rythme mu aux sites centraux non seulement lors de l’exécution de tâches motrices, mais également lors de l’observation passive d’actions. Ces résultats soutiennent l’hypothèse de l’existence d’un système de résonance motrice sensible aux représentations visuelles d’actes moteurs dans le cerveau immature.
L’article 2 constitue une étude de cas réalisée chez une jeune fille de 12 ans opérée pour épilepsie réfractaire aux médicaments. L’électroencéphalographie intracrânienne est utilisée afin d’évaluer le recrutement du cortex moteur lors de la perception de sons d’actions. On y montre une modulation de l’activité du cortex moteur, visible dans deux périodes distinctes, qui se reflètent par une diminution de la puissance spectrale des fréquences beta et alpha. Ces résultats soutiennent l’hypothèse de l’existence d’un système de résonance motrice sensible aux représentations auditives d’actions chez l’enfant.
L’article 3 constitue une recension des écrits portant sur les données comportementales et neurophysiologiques qui suggèrent la présence d’un système de compréhension d’action fonctionnel dès la naissance. On y propose un modèle théorique où les comportements d’imitation néonataux sont vus comme la résultante de mécanismes d’appariement moteurs non inhibés.
Afin de mesurer adéquatement la présence de traits empathiques et autistique dans le but de les mettre en relation avec l’activité du système de résonance motrice, l’article 4 consiste en une validation de versions françaises des échelles Empathy Quotient (Baron-Cohen & Wheelwright, 2004) et Autism Spectrum Quotient (Baron-Cohen et al., 2001) qui seront utilisées dans l’article 5. Les versions traduites de ces échelles ont été administrées à 100 individus sains et 23 personnes avec un trouble du spectre autistique. Les résultats répliquent fidèlement ceux obtenus avec les questionnaires en version anglaise, ce qui suggère la validité des versions françaises.
Dans l’article 5, on utilise la stimulation magnétique transcrânienne afin d’investiguer le décours temporel de l’activité du cortex moteur durant la perception d’action et le lien de cette activité avec la présence de traits autistiques et empathiques chez des individus normaux. On y montre que le cortex moteur est rapidement activé suivant la perception d’un mouvement moteur, et que cette activité est corrélée avec les mesures sociocognitives utilisées. Ces résultats suggèrent l’existence d’un système d’appariement moteur rapide dans le cerveau humain dont l’activité est associée aux aptitudes sociales.
L’article 6 porte sur la spécificité des outils d’investigation neurophysiologique utilisés dans les études précédentes : la stimulation magnétique transcrânienne et l’électroencéphalographie quantitative. En utilisant ces deux techniques simultanément lors d’observation, d’imagination et d’exécution d’actions, on montre qu’elles évaluent possiblement des processus distincts au sein du système de résonance motrice.
En résumé, cette thèse vise à documenter l’existence d’un système de résonance motrice chez l’enfant, d’établir le lien entre son fonctionnement et certaines aptitudes sociales et d’évaluer la validité et la spécificité des outils utilisés pour mesurer l’activité au sein de ce système. Bien que des recherches subséquentes s’avèrent nécessaires afin de compléter le travail entamé ici, les études présentées constituent une avancée significative dans la compréhension du développement et du fonctionnement du système de résonance motrice, et pourraient éventuellement contribuer à l’élaboration d’outils diagnostiques et/ou de thérapeutiques chez des populations où des anomalies de ce système ont été répertoriées. / The discovery of cells in the macaque brain that respond both to action production and perception brings support to the hypothesis that these mirror-neurons (MN) code for the representation of action. These cells, and the system they form (the so-called mirror neuron system; MNS), appear to underlie action understanding by simulating the perceived action into the observer’s brain. Beyond simple action understanding, it has been suggested that this system contributes to higher-order processes related to social cognition.
In human adults, recent imaging studies have shown important ovelaps in the activity patterns during both action production and execution, supporting the existence of a system similar to that shown in monkeys. However, surprisingly few studies have investigated the presence and the development of the MNS in the human child, and its relationship with socio-cognitive abilities in healthy individuals. Moreover, we still ignore the specificity of measures widely used to assess this system.
The studies that follow aim at clarifying these issues. More specifically, the main objectives of this work are to : (1) establish the existence and the properties of motor resonance mechanisms in children; (2) clarify the relationship between activity of the MNS and social abilities in healthy individuals; and (3) determine the specificity of neurophysiological tools widely used to measure MNS activity in humans.
In the first article, quantitative electroencephalography is used to assess the activity of sensorimotor regions in a group of school-age children during the observation of simple hand movements. We show a modulation of mu rhtyhm activity at central sites not only during motor production, but also during passive action observation. These results support the existence of an action-execution pairing system sensitive to visual actions in the immature brain.
In the second article, we present an experiment conducted in a 12 year-old child undergoing presurgical monitoring for intractable epilepsy. Intracranial electroencephalography is used to assess motor cortex involvement in the perception of action-related sounds. We show a modulation of motor cortex activity at two distinct time-periods in the alpha and beta bands. These results suggest the presence of a motor matching system sensitive to auditory stimuli in the child’s brain.
In the third article, we present an overview of behavioral and neurophysiological data supporting the idea that an action-understanding system is present from birth in humans. We propose a theoretical model whereby neonatal imitation is the result on an uninhibited motor resonance system.
In order to adequatly measure the presence of empathic and autistic traits in healhy individuals to assess their link with motor resonance, article 4 consists of a french validation of questionnaires used in the fifth article, the Empathy Quotient (Baron-Cohen & Wheelwright, 2004) and the Autism Spectrum Quotient (Baron-Cohen et al., 2001). Translated versions of these scales were administered to 100 healthy adults and 23 individuals with autistic spectrum disorders. Our results replicate faithfully those obtained with the original version of the scales.
In the fifth article, transcranial magnetic stimulation is used to assess the timecourse of motor cortex activity during action observation, as well as its relationship with empthic and autistic traits in healthy individuals. We show that the motor cortex is rapidly modulated following movement onset, and that its activity correlates with specific socio-cognitives measures. These results suggest the presence of a rapid mechanism taking place in the motor resonance system that is related to social ability.
The sixth acticle aims at clarifying the specificity of the neurophysiological tools used in the preceeding studies to quantify MNS, namely transcranial magnetic stimulation and quantitative electroencephalography. Using both techniques simultaneously during action observation, imagination and execution, we show that these measures capture different aspects of motor resonance.
In summary, this thesis aims at documenting the existence of a motor resonance mechanism in children, establishing the relationship between MNS activity and socio-cognitive traits and assessing the specificity of the measures used to quantify activity within this system. Although further studies are needed to complete the task begun here, these studies contribute significantly to our understanding of the development and function of motor resonance mechanism is humans. In the long run, they could contribute to the elaboration of diagnostic markers, and ultimately therapeutic targets, in clinical populations where abnormalities of this system have been documented.
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