Global ETD Search

81	Modifications électro-physiologiques chez la personne aphasique : : de l’étude des réseaux du langage en TMS à la prédiction de la récupération de l’aphasie / Electrophysiological modification in people with apahsia: : from language networks to the prediction of recovery from aphasia Glize, Bertrand 20 December 2017 (has links) L’aphasie est un symptôme fréquent après un AVC et a un impact majeur social, économique, médical et psychologique sur les patients. Des études récentes ont tenté avec peu de succès de rechercher des critères pronostiques cliniques précoces de récupération d’une aphasie. L’enjeu de cette possibilité de prédiction est un enjeu majeur clinique et scientifique et peut influencer la prise en charge ré-éducative décidée dès les premiers jours après l’AVC. De plus, l’étude clinico-physiologique de la récupération du langage permettrait de mieux comprendre les mécanismes de plasticité cérébrale mis en jeux. Tout d’abord, nous allons nous intéresser chez le sujet sain à l’implication du cortex moteur dans des tâches de perception, renforçant l’idée que cette structure anatomique jouerait un rôle plus étendu que celui auquel elle a été reléguée pendant de nombreuses années, puis nous allons explorer des facteurs prédictifs de la récupération de l’aphasie, les facteurs langagiers dans un premier temps et des facteurs électrophysiologiques, notamment via la TMS explorant l’intégrité du cortex moteur, et leur contribution dans la prédiction de la récupération. / Considering the high incidence of post-stroke aphasia and its significant social and economic impact, better understanding the mechanisms of language recovery in order to predict patient’s outcome and to optimize rehabilitation is a clinical and scientific challenge. Here we aimed to study whether the motor cortex is involved in speech and language perception, suggesting this structure could play a crucial role. Then, we investigated whether some language features could contribute to the prognosis of aphasia recovery. Finally, we investigated whether the anatomofunctional evaluation of the corticomotor pathway using TMS could improve the prediction of post stroke aphasia recovery. Aphasie Cortex moteur Stimulation magnétique transcrânienne Pronostic Aphasia Motor cortex Transcranial magnetic stimulation Prognosis
82	Instrumentation biomédicale et étude des applications sur des effets de champs magnétiques / Biomedical Instrumentation and Study of Magnetic Field Effect Applications Pérez Olivas, Huetzin, Aaron 14 December 2015 (has links) La dynamique de culture de cellules peut être modifié lors de l'application de champs magnétiques fluctuants afin d’stimuler la prolifération et longévité de cellules mais sans affecter leur viabilité. Cela se fait avec les conditions expérimentales et paramètres optimales. Dans cette thèse je montre l’étude à différents types de cellules tels que l’Entamoeva histolitica et invadens, les lynphosites humains et l’HEK-293E pour obtenir quelques paramètres importants qui puissent nous permettre à mieux comprendre les effets subis par elles quand un champ magnétique est appliqué. L’objective de mon travail est d’étudier la culture de cellules et sa dynamique quand elle ressent un champ magnétique d’une certaine intensité, a une certaine fréquence, le nombre de fois d’application et les effets que le champ peut l’induire. Je considère aussi la concentration de fluides paramagnétiques dans le milieu de culture chargé d’amplifier l’effet de stimulation. Finalement, je parlerais de la conception d’une instrumentationcapable de pourvoir aux cellules les meilleures conditions de reproduction telle que la température, espace, distribution efficace du champ magnétique et sa forme de radiation. La conception d’une nouvelle instrumentation qui puisse tenir en compte des nouvelles variables est aussi traitée. Cette même instrumentation s’est révélée très robuste pour être aussi appliquée dans d’autres sujets d’étude biomédicale avec des faibles modifications. Son utilisation en diagnostique de dislocation de la hanche, la mesure de fréquences dans la région gastroesophagea pour étudier la dynamique du métabolisme. / This thesis has the objective to determine the effect produced by weak magnetic field stimulation on the following types of cell cultures: Entamoeba histolytica, Entamoeba invadens, human lymphocyte, and HEK- 293T.Changes in cell’sproliferation and longevity without affecting their viability are thus studied. We intend to understand the effect produced by the magnetic field and gadolinium in the different levels of cell organization (organelle, macro molecules, and chemical reactions).We are mainly interested in asserting the behavior of cells in a controlled manner, for example when applying oscillating magnetic fields at different frequencies and time intervals as well as the addition of certain concentrations of super-paramagnetic fluid in the growing medium. Here I present effects on the cell motility of Entamoeba invadens cell cultures and the change in the natural cell behavior, such as controlled agglutination, cell movement velocity, membrane structural form. I also present the effects and dynamic responses on the growth of Entamoeba cells by applying an oscillating magnetic field in specific audio frequencies such as 100 Hz, 800 Hz, 1500 Hz, and 2500Hz, at six minutes time periodic intervals. Instrumentation magnétique Biomédecine Stimulation magnétique Magnetic instrumentation Biomedicine Magnetic stimulation 538
83	The Influence of Area 5 on the Excitation of Primary Motor Cortex Mackenzie, Tanner 11 1900 (has links) Using functional magnetic resonance imaging in humans, Brodmann's area 5 (BA5) is observed to be activated during the suppression of motor output in the context of a NO-GO task. In monkeys, BA5 is associated with somatosensation and specifically linked with motor preparation. The goal of this thesis is to investigate BA5 influences on corticospinal excitability prior to the onset of movement, in the context of a GO/NO-GO paradigm. To achieve this goal, paired-pulse TMS is used to probe the functional connectivity between BA5 and ipsilateral primary motor cortex (M1) for a muscle specific to the hand. Three experiments are performed that investigate the differences in corticospinal output to the hand in a GO task versus a NO-GO task and the stimulation parameters that reveal such differences. Results indicate that BA5 is able to condition M1 prior to movement in a task-specific manner. Further, motor evoked potentials (MEPs) are suppressed in the context of a NO-GO task relative to a GO task, and task-specific differences rely on the intensity and direction of induced current in the cortex. In conclusion, data from this thesis contribute to our understanding of the role of BA5 in motor control. / Thesis / Master of Science in Kinesiology neurophysiology transcranial magnetic stimulation Brodmann's area 5 brain stimulation cerebral cortex
84	Transcranial Magnetic Stimulation as a Diagnostic Tool for Assessing Motor Impairment of Spinal Cord Injured Individuals Gonzalez, Claudia C. 12 1900 (has links) <p> Clinical diagnosis, classification of injury and the reliable and detailed description of a patient's neurological status are key factors in determining intervention, rehabilitation programs and predicting recovery. The American Spinal Injury Association (ASIA) impairment scale (AIS) is a standardized method for spinal cord injury (SCI) classification and neurologic status examination. Studies have revealed the AIS classification to be a general assessment tool that fails to explain the varying degrees and patterns of neurological damage, especially in individuals with incomplete injuries. In addition, intragroup variability can be attributed to inaccuracies in examinations and improper assessment tools that have limited research findings. Transcranial Magnetic Stimulation (TMS) has been used as a non-invasive method of evaluating the integrity of the motor nervous system. The primary purpose of this study was to evaluate TMS as an assessment tool to describe motor impairment of SCI individuals. A second purpose of this study was to assess AIS accuracy and sensitivity to muscle activation by using surface electromyographic (sEMG) techniques during clinical examinations. Six incomplete SCI participants were clinically assessed to obtain their individual motor scores from key muscles following AIS assessment criteria. TMS was then used to stimulate the motor cortex to elicit motor evoked potentials (MEPs) in 4 key muscles. MEPs correlated with motor scores, where significantly higher and lower MEPs corresponded to the highest and lowest motor scores, respectively. Of the 48 muscles analyzed, 18 received a motor score of zero; however MEPs were obtained in 7 of these 18 muscles. In general, MEPs paralleled motor function as assessed by the AIS. Results suggest that TMS may provide information on the relationship between corticospinal integrity and the quality of motor function. In addition, TMS demonstrated adequate validity and sensitivity to SCI individual differences. MEPs provided additional information regarding the existence of spared neuronal pathways not identified by standard clinical evaluations. The therapeutic potential of these motor pathways has yet to be explored. EMG activity was significantly correlated to motor scores and MEPs however; EMG analysis revealed some inaccuracies in muscle examinations and supported MEP data. Results suggest that the implementation of electrophysiological assessment tools may be more sensitive to detect motor damage, adaptive movement patterns and overall muscle activation that may be misinterpreted during clinical examinations.</p> / Thesis / Master of Science (MSc)
85	Investigating the Effects of Glucose and Sweet Taste on Corticospinal and Intracortical Excitability Toepp, Stephen 08 1900 (has links) Transcranial magnetic stimulation (TMS) is commonly used to measure corticospinal and intracortical excitability in basic and clinical neuroscience. However, the effect of glucose on TMS-based measures is not well defined, despite a potentially impactful influence on precision and reliability. Here, a double-blinded placebo-controlled study was used to test the effects of glucose on two commonly used TMS measures: short-interval intracortical inhibition (SICI), and the area under the motor evoked potential recruitment curves (AURC). SICI and AURC are thought to reflect inhibitory (GABAergic) and excitatory (glutamatergic) neurotransmission respectively. Healthy males (N=18) each participated in four sessions. Session 1 involved TMS familiarization and acquisition of an individualized blood glucose response curve. During sessions 2, 3 and 4, dependent measures were taken before (T0) and twice after (T1 & T2) drinking 300 mL of solution containing glucose (75 g), sucralose-sweetened placebo (control for sweetness) or plain water (control for time). The T1 and T2 measurements were started 5 minutes prior to the blood glucose peak observed during Session 1. Blood glucose and mean arterial pressure (MAP) were also monitored. Sucralose, but not water or glucose increased AURC and none of the treatments altered SICI. There was no association between blood glucose level and TMS measures, but in all three conditions MAP rose after consumption of the drink. There was a positive correlation between the rise in blood pressure and the relative increase in AURC at the higher stimulus intensities. Eleven participants returned for a fifth session to quantify the smallest detectible change in the AURC measurements and it was confirmed that significant changes were real while non-significant differences in measurement means fell within the range of expected measurement error. This study also suggests a relationship between corticospinal excitability and autonomic tone. Additional investigation is required to understand the mediating factors of this association. / Thesis / Master of Science (MSc) glucose transcranial magnetic stimulation blood pressure corticospinal excitability intracortical excitability Primary Motor Cortex
86	Pain Observation, Empathy, and the Sensorimotor System: Behavioural and Neurophysiological Explorations Galang, Carl Michael January 2020 (has links) Previous research has established that observing another in pain activates both affective and sensorimotor cortical activity that is also present during the first-hand experience of pain. Some researchers have taken this “mirroring” response as indicative of empathic processing. However, very little work has explored the downstream behavioral effects of empathic pain observation. The aim of this dissertation is to begin to fill this gap in the literature by exploring the relationship between empathic pain observation, overt motor behaviours, and sensorimotor activity. In chapters 2-4, I provide robust evidence that observing pain inflicted on another person leads to faster reaction time responses. This effect is shown to be temporally extended (by at least 500ms after pain observation), effector-general (affecting both finger and foot responses), influenced by top-down (i.e., instructions to explicitly empathize) but not bottom-up (i.e., the perceived level of pain) factors, and is not influenced by adaptive (approach/withdraw) behaviours. In chapter 5, I show that sensorimotor activity, measured via TMS-induced Motor Evoked Potentials, increases while observing another in pain regardless whether the observer is preparing to make an action vs. passively observing the stimuli. These results run counter to the literature, and I provide several explanations for why these results were found. Lastly, in chapter 6, I show that sensorimotor activity, measured via Mu and Beta suppression, also increases while observing another in pain regardless whether the observer is preparing to make an action vs. passively observing the stimuli. Interestingly, I do not find significant correlations between sensorimotor activity during pain observation and faster reaction times after pain observation. I embed these findings in relation to the wider social neuroscience of empathy literature and discuss several limitations and challenges in empirically measuring “empathy” as a psychological construct. Overall, this dissertation furthers our understanding of empathy for pain by highlighting the behavioural consequences of pain observation and its connection (or rather, lack thereof) to sensorimotor activity during pain observation. / Thesis / Doctor of Philosophy (PhD) / Past research suggests that overlapping brain activity during the first-hand experience of pain and pain observation may be indicative of empathy. However, very little work has been done to explore how pain observation influences overt behaviours. This thesis investigates this issue by having participants complete a reaction time task while watching videos of needles stabbing a person’s hand. The findings reported in this thesis suggests that observing another in pain facilitates motor behaviours (i.e., faster reaction times); this facilitation extends 500ms after pain observation, affects both the hand and feet, is accentuated by instructing participants to explicitly empathize, and is not influenced by approach vs. withdraw movements. Brain activity in the motor system was also found to increase during pain observation. Overall, this thesis begins the discussion of how empathic pain observation influences explicit motor behaviours, and how such behaviours may be related to brain activity. Empathy Pain Observation Sensorimotor System Reaction Time Transcranial Magnetic Stimulation Electroencephalography
87	Distinct contributions of extrastriate body area and temporoparietal junction in perceiving one's own and others' body Cazzato, Valentina, Mian, E., Serino, A., Mele, S., Urgesi, C. 22 July 2014 (has links) No / The right temporoparietal cortex plays a critical role in body representation. Here, we applied repetitive transcranial magnetic stimulation (rTMS) over right extrastriate body area (EBA) and temporoparietal junction (TPJ) to investigate their causative roles in perceptual representations of one's own and others' body. Healthy women adjusted size-distorted pictures of their own body or of the body of another person according to how they perceived the body (subjective task) or how others perceived it (intersubjective task). In keeping with previous reports, at baseline, we found an overall underestimation of body size. Crucially, EBA-rTMS increased the underestimation bias when participants adjusted the images according to how others perceived their own or the other woman's body, suggesting a specific role of EBA in allocentric body representations. Conversely, TPJ-rTMS increased the underestimation bias when participants adjusted the body of another person, either a familiar other or a close friend, in both subjective and intersubjective tasks, suggesting an involvement of TPJ in representing others' bodies. These effects were body-specific, since no TMS-induced modulation was observed when participants judged a familiar object. The results suggest that right EBA and TPJ play active and complementary roles in the complex interaction between the perceptions of one's own and other people's body. Adult ; Body image ; Female ; Humans ; Parietal lobe ; Temporal lobe ; Transcranial magnetic stimulation ; Visual cortex ; Young adult
88	Induced deficits in speed perception by transcranial magnetic stimulation of human cortical areas V5/MT+ and V3A McKeefry, Declan J., Burton, Mark P., Vakrou, Chara, Barrett, Brendan T., Morland, A.B. 02 July 2008 (has links) No / In this report, we evaluate the role of visual areas responsive to motion in the human brain in the perception of stimulus speed. We first identified and localized V1, V3A, and V5/MT+ in individual participants on the basis of blood oxygenation level-dependent responses obtained in retinotopic mapping experiments and responses to moving gratings. Repetitive transcranial magnetic stimulation (rTMS) was then used to disrupt the normal functioning of the previously localized visual areas in each participant. During the rTMS application, participants were required to perform delayed discrimination of the speed of drifting or spatial frequency of static gratings. The application of rTMS to areas V5/MT and V3A induced a subjective slowing of visual stimuli and ( often) caused increases in speed discrimination thresholds. Deficits in spatial frequency discrimination were not observed for applications of rTMS to V3A or V5/MT+. The induced deficits in speed perception were also specific to the cortical site of TMS delivery. The application of TMS to regions of the cortex adjacent to V5/MT and V3A, as well as to area V1, produced no deficits in speed perception. These results suggest that, in addition to area V5/MT+, V3A plays an important role in a cortical network that underpins the perception of stimulus speed in the human brain. / BBSRC Transcranial Magnetic Stimulation (TMS) V5/MT+ fMRI Retinotopic mapping Speed perception Psychophysics V3A REF 2014
89	Dopaminergic Modulation of Neuroplasticity in Humans- Contribuition of Receptor Subtypes and Dosage Fresnoza, Shane 04 September 2014 (has links) No description available. 570 English Dopamine Transcranial magnetic stimulation Transcranial direct current stimulation Neuroplasticity Neuromodulation Paired associative stimulation dopamine receptors Biologie (PPN619462639)
90	Motor Control and Perception during Haptic Sensing: Effects of Varying Attentional Demand, Stimuli and Age Master, Sabah 28 November 2012 (has links) This thesis describes a series of experiments in human observers using neurophysiological and behavioural approaches to investigate the effects of varying haptic stimuli, attentional demand and age on motor control and perception during haptic sensing (i.e., using the hand to seek sensory information by touch). In Experiments I-IV, transcranial magnetic stimulation (TMS) was used to explore changes in corticomotor excitability when participants were actively engaged in haptic sensing tasks. These studies showed that corticospinal excitability, as reflected in motor evoked potential (MEP) amplitude, was greatly enhanced when participants were engaged in different forms of haptic sensing. Interestingly, this extra corticomotor facilitation was absent when participants performed finger movements without haptic sensing or when attention was diverted away from haptic input by a concurrent cognitive task (Exp I). This provided strong evidence that the observed corticomotor facilitation was likely central in origin and related to haptic attention. Neuroimaging has shown activation of the parieto-frontal network likely subserves this aspect of haptic perception. Further, this haptic-specific corticomotor facilitation was finely modulated depending on whether participants focused attention on identifying material (texture) as opposed to geometric properties of scanned surfaces (Exp II). With regards to aging effects, haptic-related corticomotor facilitation was associated with higher recognition accuracy in seniors (Exp III). In line with this, seniors exhibited similar levels of haptic-related corticomotor facilitation to young adults when task demands were adjusted for age (Exp IV). Interestingly, both young and senior adults also showed substantial corticomotor facilitation in the ‘resting’ hand when the ipsilateral hand was engaged in haptic sensing (Exp IV). Simply touching the stimulus without being required to identify its properties (no attentional task demands) produced no extra corticomotor facilitation in either hand or age group, attesting again to the specificity of the effects with regards to haptic attention. In Experiments V-VI, the ability to recognise 2-D letters by touch was investigated using kinematic and psychophysical measures. In Experiment V, we characterized how age affected contact forces deployed at the fingertip. This investigation showed that older adults exhibited lower normal force and increased letter-to-letter variability in normal force when compared to young adults. This difference in contact force likely contributed to longer contact times and lower recognition accuracy in older adults, suggesting a central contribution to age-related declines in haptic perception. Consistent with this interpretation, Experiment VI showed that haptic letter recognition in older adults was characterized not only by lower recognition accuracy but also by substantial increases in response times and specific patterns of confusion between letters. All in all, these investigations highlight the critical interaction of central factors such as attentional demand with aging effects on motor and perceptual aspects of haptic sensing. Of particular significance is the clear demonstration that corticomotor excitability is greatly enhanced when a haptic sensing component (i.e., attending to specific haptic features) is added to simple finger movements performed at minimal voluntary effort levels (typically <15 % of the maximal effort). These observations underline the therapeutic potential of active sensory training strategies based on haptic sensing tasks for the re-education of motor and perceptual deficits in hand function (e.g., subsequent to a stroke). The importance of adjusting attentional demands and stimuli is highlighted, particularly with regards to special considerations in the aging population. haptic tms transcranial magnetic stimulation sensing aging perception motor control attention touch tactile discrimination corticospinal excitability motor cortex hand

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