Porovnání účinnosti psychoterapie a repetitivní transkraniální magnetické stimulace v léčbě psychogenního přejídání. / The comparsion of the effect of psychothrapy and repetitive transcranial magnetic stimulation in treatment of binge eating disorder.

Jaššová, Katarína

January 2019

Introduction: Among eating disorders, the binge eating is the most common disorder with prevalence to 7,8%. It is frequently connected with overweight, or obesity. Current treatment of binge eating is based on psychotherapy, pharmacotherapy and regime approach. Recently, repetitive transcranial magnetic stimulation appears as hopeful therapeutic method, for example used with success as an alternative therapy to treatment of resistant major depresion. Because of its non-invasiveness, good tolerability and minimal side effects, new options of its use are studied. It seems to be a promising therapeutic method for treatment of eating disorders. Dorsolateral prefrontal cortex is considered as main experimental target of stimulation for treatment of binge eating disorder. Methods: Study was conceived randomized double-blind placebo controlled. The active group was stimulated by high-frequency rTMS, with stimulation parameters: frequency 10Hz, 1500 pulses, 107s inter-train, 100 % minimal motor threshold and 10 sessions of stimulation. The control grooup was stimulated by sham rTMS coil. Both groups completed FCQ-S and FCQ- T questionnaire before stimulation, after 10. session and one month after 10. session. Results: We noticed statistically significant decrease of craving in FCQ-S questionnaire after 10. session...

The Functional Dissection of Motion Processing Pathways in the Human Visual Cortex Using fMRI-Guided TMS

Strong, Samantha Louise

January 2015

Motion-selectivity in human visual cortex comprises a number of different cortical loci including V1, V2, V3A, V3B, hV5/MT+ and V6 (Wandell et al., 2007). This thesis sought to investigate the specific functions of V3A and sub-divisions of hV5/MT+ (TO-1 and TO-2) by using transcranial magnetic stimulation (TMS) to transiently disrupt cortical activations within these areas during psychophysical tasks of motion perception. The tasks were chosen to coincide with previous non-human primate and human neuroimaging literature; translational, radial and rotational direction discrimination tasks and identification of the position of a focus of expansion. These results assert that TO-1 and TO-2 are functionally distinct subdivisions of hV5/MT+, as we have shown that both TO-1 and TO-2 are responsible for processing translational motion direction whilst only TO-2 is responsible for processing radial motion direction. In ipsilateral space, it was found that TO-1 and TO-2 both contribute to the processing of ipsilateral translational motion. Taken in a wider context, further results also suggested that these areas may form part of a network of cortical areas contributing to perception of self-motion (heading/egomotion), as TO-2 was not found to be responsible for processing the position of the central focus of expansion (imperative for self-direction). Instead, area V3A has been implicated as functionally responsible for processing this attribute of vision. Overall it is clear that TO-1, TO-2 and V3A have specific, distinct functions that contribute towards both parallel and serial motion processing pathways within the human brain. / Life Science Research

Usefulness and Limits of Tractography for Surgery in the Precentral Gyrus: A Case Report

Wende, Tim, Wilhelmy, Florian, Kasper, Johannes, Prasse, Gordian, Franke, Christian, Arlt, Felix, Frydrychowicz, Clara, Meixensberger, Jürgen, Nestler, Ulf

23 January 2024

The resection of tumors within the primary motor cortex is a constant challenge. Although tractography may help in preoperative planning, it has limited application. While it can give valuable information on subcortical fibers, it is less accurate in the cortical layer of the brain. A 38-year-old patient presented with paresis of the right hand and focal epileptic seizures due to a tumor in the left precentral gyrus. Transcranial magnetic stimulation was not applicable due to seizures, so microsurgical resection was performed with preoperative tractography and intraoperative direct electrical stimulation. A histopathological assessment revealed a diagnosis of glioblastoma. Postoperative magnetic resonance imaging (MRI) showed complete resection. The paresis dissolved completely during follow-up. Surgery within the precentral gyrus is of high risk and requires multimodal functional planning. If interpreted with vigilance and consciousness of the underlying physical premises, tractography can provide helpful information within its limitations, which is especially subcortically. However, it may also help in the identification of functional cortex columns of the brain in the presence of a tumor.

info:eu-repo/classification/ddc/610

ddc:610

The Investigation of Theta-burst Stimulation over Primary Somatosensory Cortex on Tactile Temporal Order Judgment

Lee, Kevin

10 1900

<p>Temporal order judgment (TOJ) refers to one’s ability to successively report the temporal order of two tactile stimuli delivered to independent skin sites. The brain regions involved in processing TOJ remain unclear. Research has shown that TOJ performance can be impaired with a conditioning background stimuli and this phenomenon, known as TOJ synchronization (TOJ-S), is suggested to be mediated by inhibitory neural mechanisms within the primary somatosensory cortex (SI) that create perceptual binding across the two skin sites. Continuous theta-burst stimulation (cTBS) over SI impairs tactile spatial and temporal acuity. This dissertation examines the effects of cTBS on TOJ and TOJ-S performance on the hand. In Experiment 1, TOJ and TOJ-S were measured from the right hand before and for up to 34 minutes following 50 Hz cTBS over SI. In Experiment 2, same measurements were obtained bilaterally for up to 42 minutes following 30 Hz cTBS over SI. Compared to pre-cTBS values, TOJ was impaired for up to 42 minutes on the right hand following 30 Hz cTBS. TOJ-S performance was improved for up to 18 minutes on the right hand following 50 Hz cTBS. These experiments reveal two major findings. First, cTBS act upon different inhibitory circuits that are suggested to mediate TOJ and TOJ-S. Second, cTBS parameters may dictate cTBS effects over SI excitability. The findings of this work not only emphasize the significant contributions of SI on tactile temporal perception, it provides novel insight of the underlying neural mechanisms of cTBS effects on SI cortical excitability.</p> / Master of Science in Kinesiology

Temporal Order judgment

Transcranial Magnetic Stimulation

Primary Somatosensory Cortex

Behavioral Neurobiology

Motor Control

Other Kinesiology

Systems Neuroscience

Behavioral Neurobiology

Comprendre l’interaction entre la douleur et le système moteur : une étude novatrice combinant la stimulation magnétique transcrânienne et l’électroencéphalographie / Understanding the interaction between pain and motor system : an innovative study combining transcranial magnetic stimulation and electroencephalography

Martel, Marylie

January 2016

Résumé : L’interaction entre la douleur et le système moteur est bien connue en clinique et en réadaptation. Il est sans surprise que la douleur est un phénomène considérablement invalidant, affectant la qualité de vie de ceux et celles qui en souffrent. Toutefois, les bases neurophysiologiques qui sous-tendent cette interaction demeurent, encore aujourd’hui, mal comprises. Le but de la présente étude était de mieux comprendre les mécanismes corticaux impliqués dans l’interaction entre la douleur et le système moteur. Pour ce faire, une douleur expérimentale a été induite à l’aide d’une crème à base de capsaïcine au niveau de l’avant-bras gauche des participants. L'effet de la douleur sur la force des projections corticospinales ainsi que sur l’activité cérébrale a été mesuré à l’aide de la stimulation magnétique transcrânienne (TMS) et de l’électroencéphalographie (EEG), respectivement. L’analyse des données EEG a permis de révéler qu'en présence de douleur aiguë, il y a une augmentation de l’activité cérébrale au niveau du cuneus central (fréquence têta), du cortex dorsolatéral préfrontal gauche (fréquence alpha) ainsi que du cuneus gauche et de l'insula droite (toutes deux fréquence bêta), lorsque comparée à la condition initiale (sans douleur). Également, les analyses démontrent une augmentation de l'activité du cortex moteur primaire droit en présence de douleur, mais seulement chez les participants qui présentaient simultanément une diminution de leur force de projections corticales (mesurée avec la TMS t=4,45, p<0,05). Ces participants ont également montré une plus grande connectivité entre M1 et le cuneus que les participants dont la douleur n’a pas affecté la force des projections corticospinales (t=3,58, p<0,05). Ces résultats suggèrent qu’une douleur expérimentale induit, chez certains individus, une altération au niveau des forces de projections corticomotrices. Les connexions entre M1 et le cuneus seraient possiblement impliquées dans la survenue de ces changements corticomoteurs. / Abstract : The interaction between pain and the motor system is well-known in clinic. For instance, it is well documented that pain significantly complicates the rehabilitation of the patients. The aim of the present study was to better understand the cortical mechanisms underlying the interaction between pain and the motor system. Nineteen healthy adults participated in the study. The effect of pain (induced with a capsaicin cream) on brain activity and on the corticomotor system was assessed with electroencephalography (EEG) and transcranial magnetic stimulation (TMS), respectively. For EEG, 15 non-overlapping, 2-seconds artifacts were randomly selected for each participant. Intracranial source current density and functional connectivity was determined using sLORETA software. When participants experienced experimentally-induced inflammatory pain, their resting state brain activity increased significantly in the central cuneus (theta frequency), left dorsolateral prefrontal cortex (alpha frequency), and both left cuneus and right insula (beta frequency; all ts >3.66; all ps<0.01). A pain-evoked increase in the right primary motor cortex (M1) activity was also observed (beta frequency), but only among participants who showed a simultaneous reduction in the strength of the corticospinal projections (quantified using the recruitment curves obtained with TMS; t=4.45, p<0.05). These participants further showed greater beta motor-cuneus connectivity than participants for whom pain did not affect M1 somatotopy (t=3.58, p<0.05). These results suggest that pain-evoked increases in M1 beta power are intimately tied to alterations in corticospinal system. Moreover, we provide evidence that beta motor-cuneus connectivity is related to the corticomotor alterations induced by pain.

Douleur

Système moteur

Excitabilité corticale

Connectivité fonctionnelle

Stimulation magnétique transcrânienne

Électroencéphalographie

Pain

Motor system

Cortical excitability

Functional connectivity

Transcranial magnetic stimulation

Electroencephalography

Dynamics of cognitive control and flexibility in the anterior cingulate and prefrontal cortices

Boschin, Erica

January 2013

The body of work hereby presented aims at better defining the specific mechanisms underlying cognitive control and flexibility, and to investigate the neural substrates that might support these dynamics. More specifically, the anterior cingulate (ACC), dorsolateral prefrontal (dlPFC) and frontopolar (FPC) cortices have been proposed to play a fundamental role in monitoring and detecting the presence of environmental contingencies that require the recruitment of cognitive control (such as competition between responses in the presence of conflicting information), implementing cognitive control, and supporting higher-order cognitive processing, respectively. This thesis investigates the effects of damage to these regions, and of interference with their activity, on these processes. It also argues for the importance of dissociating possible separate cognitive control components that might differently contribute to behavioural adjustments (such as caution and attention/task-relevant processing), and provides one of the first attempts to quantify them within the parameters of a mathematical model of choice response-time, the Linear Ballistic Accumulator (LBA). The results confirm the crucial role of the dlPFC in modulating behavioural adjustments, as both damage and interference with this region’s activity significantly affect measures of conflict-induced behavioural adaptation. It is hypothesized that dlPFC might drive behavioural adjustments by encoding recent conflict history and/or supporting the automatization of a newly advantageous behavioural strategy during the early stages after a change in conflict levels. When a task does not involve competition between a habit and instructed behaviour, lesions or interference with ACC’s activity do not appear to affect behaviour in a manner that is consistent with the classic conflict-monitoring framework. It is suggested that its role might be better described as a more general monitoring and confirmatory mechanism that evaluates both actual and potential outcomes of an action, in order to proactively guide adjustments away from contextually disadvantageous responses. Finally, lesions to the FPC do not affect abstract-rule integration, but do impair the early stages of acquisition of a new abstract rule, when a previously rewarded rule stops being rewarded, and specifically when acquisition is dependent on self-initiated exploration. This suggests a role for FPC in the evaluation of multiple concurrent options in order to aid the development of new behavioural strategies.

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Electrophysiological indices of graded attentional and decision-making processes

Gould, Ian C.

January 2011

In everyday life we regularly update our expectations about the locations at which sensory events may occur, and about the motor responses that are appropriate in a given situation. The experiments in this thesis investigated the neural correlates of perceptual processes and motor preparation during human decision making, and the regions that causally contribute to decision making in the human brain. In Chapter 3, I used electroencephalography (EEG) to investigate whether alpha-band (~8-14 Hz) oscillations provide a graded index of participants’ preparatory attentional states. Time-frequency analysis revealed that manipulating spatial certainty regarding the location of an upcoming visual target led to parametric changes in the lateralization of preparatory occipito-parietal alpha oscillations, and to parametric modulation of parieto-central beta-band (~15-25 Hz) power typically associated with response preparation. In Chapter 4, I used EEG to investigate whether evolution of lateralization of sensorimotor alpha- and beta-band activity reflected participants’ evolving expectations about an upcoming motor response. Lateralization of activity in both frequency bands varied parametrically with the available evidence, suggesting such lateralized activity correlates with participants’ internal decision variables. Further analysis identified unique contributions to lateralized and non-lateralized oscillatory activity due to the prior evidence, evidence update, and surprise related to the observed information at each stage of the task. In Chapter 5, I extended the paradigm developed in Chapter 4 for use with online repetitive transcranial magnetic stimulation (TMS) and concurrent EEG recording. Delivery of TMS during decision making allowed investigation of the causal role played by a left hemisphere medial intraparietal region that is the putative human homologue of the macaque medial intraparietal cortex (MIP). MIP stimulation disrupted decision-making behaviour by biasing participants’ decisions against contralateral-to-stimulation (i.e., right-handed) responses. Comparison of the magnitude of TMS-induced changes in behaviour and beta-band activity demonstrated that the intraparietal cortex plays a causal role both in decision making and in the appearance of beta-band activity over the motor cortex. In Chapter 6, the broader consequences of the experimental work presented in this thesis are discussed, in addition to promising directions for future research.

153.83

Excitabilité du système miroir : une étude de stimulation magnétique transcrânienne sur le chant et le langage

Royal, Isabelle

09 1900

La perception de mouvements est associée à une augmentation de l’excitabilité du cortex moteur humain. Ce système appelé « miroir » sous-tendrait notre habileté à comprendre les gestes posés par une tierce personne puisqu’il est impliqué dans la reconnaissance, la compréhension et l’imitation de ces gestes. Dans cette étude, nous examinons de quelle façon ce système miroir s’implique et se latéralise dans la perception du chant et de la parole. Une stimulation magnétique transcrânienne (TMS) à impulsion unique a été appliquée sur la représentation de la bouche du cortex moteur de 11 participants. La réponse motrice engendrée a été mesurée sous la forme de potentiels évoqués moteurs (PÉMs), enregistrés à partir du muscle de la bouche. Ceux-ci ont été comparés lors de la perception de chant et de parole, dans chaque hémisphère cérébral. Afin d’examiner l’activation de ce système moteur dans le temps, les impulsions de la TMS ont été envoyées aléatoirement à l’intérieur de 7 fenêtres temporelles (500-3500 ms). Les stimuli pour la tâche de perception du chant correspondaient à des vidéos de 4 secondes dans lesquelles une chanteuse produisait un intervalle ascendant de deux notes que les participants devaient juger comme correspondant ou non à un intervalle écrit. Pour la tâche de perception de la parole, les participants regardaient des vidéos de 4 secondes montrant une personne expliquant un proverbe et devaient juger si cette explication correspondait bien à un proverbe écrit. Les résultats de cette étude montrent que les amplitudes des PÉMs recueillis dans la tâche de perception de chant étaient plus grandes après stimulation de l’hémisphère droit que de l’hémisphère gauche, surtout lorsque l’impulsion était envoyée entre 1000 et 1500 ms. Aucun effet significatif n’est ressorti de la condition de perception de la parole. Ces résultats suggèrent que le système miroir de l’hémisphère droit s’active davantage après une présentation motrice audio-visuelle, en comparaison de l’hémisphère gauche. / The perception of movements is associated with increased activity in the human motor cortex. This system underlies our ability to understand one’s actions, as it is implicated in the recognition, understanding and imitation of actions. In this study, we investigated the involvement and lateralization of this “mirror neuron” system (MNS) in the perception of singing and speech. Transcranial magnetic stimulation (TMS) was applied over the mouth representation of the motor cortex in 11 participants. The generated motor response was measured in the form of motor evoked potentials (MEPs), recorded from the mouth muscle. The MEPs were compared for the singing and speech conditions in each cerebral hemisphere. Furthermore, to investigate the time course of the MNS activation, TMS pulses were randomly emitted in 7 time windows (ranging from 500 to 3500 milliseconds after stimulus onset). The stimuli for the singing condition consisted in 4-second videos of singers producing a 2-note ascending interval. Participants had to judge whether the sung interval matched a written interval, previously presented on the screen. For the speech condition, 4-second videos of a person explaining a proverb were shown. Participants had to decide whether this explanation matched a written proverb previously displayed on the screen. Results show that the MEP amplitudes were higher after stimulation of the right hemisphere in the singing condition. More specifically, sending TMS pulses between 1000 and 1500 milliseconds over the right hemisphere yielded higher MEPs as compared to the left hemisphere. No effect was found in the speech condition. These results suggest that the right MNS is more activated after an audiovisual motor presentation compared to the left hemisphere.

Système miroir

Mirror neuron system

Stimulation magnétique transcrânienne

Transcranial magnetic stimulation

Cortex moteur

Motor cortex

Chant

Singing

Parole

Speech

Latéralisation

Lateralization

Expérience subjective et différences individuelles dans l'intégration d'informations visuelle et kinesthésique

Dumont, Laurence

12 1900

L’expérience subjective accompagnant un mouvement se construit a posteriori en intégrant différentes sources d’informations qui s’inter-influencent à différents moments tant avant qu’après le mouvement. Cette expérience subjective est interprétée par un modèle d’attribution bayésien afin de créer une expérience d’agentivité et de contrôle sur les mouvements de son propre corps. Afin de déterminer l’apport de l’interaction entre les paramètres considérés par le modèle d’attribution et d’investiguer la présence de disparités inter-individuelles dans la formation de l’expérience subjective du mouvement, une série de 90 pulsations simples de stimulation magnétique transcrânienne (SMT) sur le cortex moteur primaire (M1) suivi de multiples questions sur l’expérience subjective reliée au mouvement provoqué a été effectuée chez 20 participants normaux. Les données objectives du mouvement ont été recueillies par électromyographie (EMG) et capture du mouvement. Un modèle de régression a entre autres été effectué pour chaque participant afin de voir quelle proportion du jugement subjectif pouvait être expliqué par des indices objectifs et cette proportion variait grandement entre les participants. Les résultats de la présente étude indiquent la présence d’une capacité individuelle à se former des jugements subjectifs reflétant adéquatement la réalité comme en témoigne la cohérence entre les différentes mesures d’acuité et plusieurs variables mesurant l’expérience subjective. / Subjective experience is built after the fact by integrating different sources of information that interact with each other at different moments (before, during and after the movement). In order to create subjective experience of agency and control, the characteristics of the movement are interpreted by a Bayesian model. To determine the impact of the interaction between the parameters that enter in that Bayesian attribution model and to investigate possible disparities in the formation of subjective experience of movement between individuals, a series of 90 pulses of single-pulse transcranial magnetic stimulation (TMS) followed by four questions on the subjective experience relative to the movement was conducted on 20 normal subjects. Objective data about the movement was gathered using electromyography (EMG) and motion capture. Individual regression models have been conducted to determine the proportion of the subjective judgements that varied accordingly to the objective parameters of the movement; this proportion varied greatly between participants. The present study proposes that there is an individual capacity to form subjective judgements that adequately represent the reality, as suggested by coherence between different accuracy measures and different variables measuring the subjective experience.

Expérience subjective

Agentivité

Contrôle

Modèle d'attribution

Mouvement

Transcranial magnetic stimulation

Subjective experience

Control

Agency

Attribution model

Movement

Stimulation magnétique transcranienne du cortex moteur a visée antalgique : recherche clinique, approche des mécanismes, effet placebo, valeur pédictive / Transcranial magnetic stimulation of motor cortex for pain relief : clinical research, approach to mechanisms, placebo effect, predictive value

André-Obadia, Nathalie

02 December 2013

La stimulation magnétique répétitive transcrânienne (rTMS) du cortex moteur à visée antalgique réunit deux conditions extrêmement intéressantes: un accès non invasif à une cible corticale éloquente et, par la modulation de son activité, la possibilité d'influencer le transfert et l'intégration du message nociceptif. L'objectif de cette thèse est d'évaluer comment une approche de recherche clinique permet à la fois de progresser dans la compréhension des mécanismes qui sous-tendent l'effet antalgique de la rTMS et d'optimiser cet effet chez le patient. Une première étude paramétrique, concernant la technique de stimulation, a montré que l'orientation du courant était cruciale pour le développement d'un effet antalgique, l'orientation la plus favorable étant celle activant des interneurones corticaux. Nous n'avons toutefois pas objectivé de modification spécifique d'une composante sensorielle de la douleur en rapport avec cet effet local, ni une influence liée au caractère somatotopique de la stimulation. Ainsi, l'efficacité de la stimulation ne semble pas tributaire de sa localisation en regard de la représentation corticale du territoire douloureux. L'action sur la composante sensorielle de la douleur n'expliquant pas à elle seule l'effet antalgique de la rTMS, nous avons analysé les interactions entre effet antalgique et effet placebo : la rTMS a une efficacité propre, indépendante de l'effet placebo et lorsqu'elle est efficace, elle majore l'effet d'une séance placebo réalisée par la suite, par un phénomène de conditionnement. La rTMS active facilite les mécanismes de contrôle central de la douleur grâce à ses connexions à distance et à son action sur les systèmes endorphiniques, également impliqués dans l'effet antalgique du placebo. A la lumière de ces résultats, nous avons analysé les critères cliniques sur lesquels reposent l'efficacité à long terme des procédures de stimulation épidurale antalgique du cortex moteur et la valeur prédictive de la rTMS: l'efficacité de la rTMS apparaît comme un marqueur utile pour prédire l'efficacité au long cours de la stimulation corticale épidurale, lorsque la douleur est évaluée non seulement dans sa dimension sensorielle pure mais également à travers son retentissement psychologique global. L'ensemble de ces travaux suggère une action multiple de la rTMS s'exerçant probablement dans les 3 sphères (sensori-discriminative, affective et cognitive) qui sous- tendent la perception et le vécu de la douleur chronique / Repetitive transcranial magnetic stimulation (rTMS) of the motor cortex allows a non- invasive access to an eloquent cortical area and, by the modulation of its activity, the possible interference with central integration of pain. ln this thesis we have applied clinical research methods to enhance the understanding of the mechanisms of pain relief by rTMS and to optimize its clinical effect in chronic pain patients. A first parametrical study, concerning technical aspects of the stimulation, showed the crucial role of current orientation to increase the magnitude of analgesic effects, a postero-anterior orientation promoting interneuronal activation being superior to a latero-medial direction. We found neither a selective modification of sensorial component of pain nor a somatotopic effect of the stimulation: indeed, rTMS analgesic efficacy was not dependent upon stimulation being applied to the cortical representation of the painful territory. The impossibility to explain the whole analgesic effect of rTMS by an isolated modulation of sensory components of pain prompted us to study the interactions between real and placebo rTMS analgesic effects. Active rTMS has a specific analgesic effect, and, when efficacious, it was able to enhance the placebo effect of subsequent sham stimulation. The value of rTMS to adequately predict the long-term efficacy of invasive motor cortex epidural stimulation (surgically implanted MCS) was assessed in a further study. The analgesic efficacy of single-point rTMS proved to be useful to predict the long-term outcome of surgically implanted MCS, provided that such outcome assessment was not exclusively founded on pain intensity but also on the psychological consequences of chronic pain. These results suggest that rTMS exerts its analgesic effects at multiple levels, and probably modifies the 3 different spheres (sensori-discriminative, affective and cognitive) at the origin of perception and consequences of chronic pain in daily life

Douleur neuropathique

Cortex moteur

Mécanismes

Effet placébo

Valeur prédictive

Neuropathic pain

Motor cortex

Mecanisms

Placebo

Predictive value

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