Global ETD Search

1	The relationship between gaze and information pickup during action observation : implications for motor skill (re)learning D'Innocenzo, Giorgia January 2018 (has links) The aim of the present thesis was to investigate the relationship between individuals' allocation of overt visual attention during action observation and their consequent pickup of information. Four interrelated studies were conducted to achieve this. In Study 1 we examined the effects of visual guidance - colour highlighting of relevant aspects of the action - on observational learning of the golf swing. The results showed that the visual guides facilitated novices' intake of information pertaining to the model's posture, which was reflected in faster learning. In the remaining studies, transcranial magnetic stimulation and eye tracking data were acquired concurrently to measure the interaction between gaze behaviour and motor resonance - a neurophysiological index of the motor system's engagement with a viewed action, and thus a correlate of information extraction. In Study 2, we directed observers' gaze to distinct locations of the display while they viewed thumb adduction/abduction movements. The results showed that, by directing gaze to a location that maximised the amount of thumb motion across the fovea, motor resonance was maximised relative to a free viewing condition. In Study 3 we examined the link between gaze and motor resonance during the observation of transitive actions. Participants viewed reach-to-grasp actions with natural gaze, or while looking at a target- or an effector- based visual guide. The results showed that the effector-based guide disrupted natural gaze behaviour, and this was associated with a reversal of the motor resonance response. In Study 4 we showed novice and skilled golfers videos of the golf swing and of a reach-grasp-lift action. The results revealed that, for both actions, the extent of motor resonance was related to the location of participants' fixations. The present work provides the first evidence of a relationship between gaze and motor resonance and highlights the importance of appropriate gaze behaviour for observational learning.
2	The Effects of Exercise Training on Shoulder Neuromuscular Control Lin, Yin-Liang 23 February 2016 (has links) The human shoulder complex relies on the sensorimotor system to maintain stability. The sensorimotor system includes sensory feedback, control of the central nervous system and motor output. Exercise is considered an important part of shoulder rehabilitation and sports training to help improve control of the sensorimotor system. However, few studies have investigated the effect of exercise on the sensorimotor system. The first study of this dissertation explored the central control of the deltoid and rotator cuff (infraspinatus). Although both the deltoid and infraspinatus contribute to shoulder abduction, the results from this study showed that the modulation of their corticospinal excitability was affected differently by elevation angle. This could be explained by the fact that they play different roles at the shoulder: the deltoid is a prime mover while the infraspinatus is a stabilizer. The second study of this dissertation investigated scapular proprioception, which has not been assessed in previous studies. The findings of this study demonstrated that joint position sense errors of the overall shoulder joint mainly came from the glenohumeral joint. Scapular proprioception may need to be tested separately in addition to overall shoulder proprioception. In the third study, the effect of the exercise on shoulder sensorimotor system was investigated by measuring shoulder kinematics, shoulder joint position sense and cortical excitability before and after a four-week exercise training program. This protocol included strengthening and neuromuscular exercises targeting rotator cuff and scapular muscles. After the training protocol, although strength increased overall, the only observed sensorimotor adaptations were a decrease in upper trapezius activation and a decrease in the corticospinal excitability of the supraspinatus. There were no changes in other key parameters. Exercises focusing on specific muscles, combined with low-intensity closed-chain exercises, were not found to improve shoulder joint position sense or scapular kinematics. Combined with the findings of the decrease in corticospinal excitability of the supraspinatus and no change in muscle activity of the rotator cuff, it appears that while the exercises increased rotator cuff strength, these gains did not transfer to an increase in muscle activation during motion. This dissertation includes previously published co-authored material. Corticospinal excitability Electromyography Kinematics Proprioception Scapula Sensorimotor system
3	Changes in corticospinal excitability induced by neuromuscular electrical stimulation Mang, Cameron Scott Unknown Date No description available. corticospinal excitability neuromuscular electrical stimulation motor cortex transcranial magnetic stimulation stimulation frequency
4	Changes in corticospinal excitability induced by neuromuscular electrical stimulation Mang, Cameron Scott 11 1900 (has links) This thesis describes experiments designed to investigate the effects of neuromuscular electrical stimulation (NMES) on corticospinal (CS) excitability in humans. NMES delivered at 100 Hz was more effective for increasing CS excitability than 10-, 50-, or 200-Hz NMES. CS excitability increases occurred after 24 min of 100-Hz NMES, were strongest in the stimulated muscle, and were mediated primarily at a supraspinal level. NMES of the common peroneal nerve of the leg increased CS excitability in multiple leg muscles, whereas NMES of the median nerve of the hand increased CS excitability in only the muscle innervated by that nerve. Additionally, CS excitability for the hand increased after 40 min of relatively high intensity and frequency NMES but not after 2 h of lower intensity and frequency NMES. These results have implications for identifying optimal NMES parameters to augment CS excitability for rehabilitation after central nervous system injury. corticospinal excitability neuromuscular electrical stimulation motor cortex transcranial magnetic stimulation stimulation frequency
5	Time Course of Corticospinal Excitability in Simple Reaction Time Tasks Kennefick, Michael January 2014 (has links) The process of movement execution can be separated into two sections; the foreperiod and the response time. The foreperiod represents the time between the warning signal (WS) and the presentation of the imperative “go” signal, and the response time incorporates both the reaction time (RT) and the movement time (Schmidt & Lee, 2011). Transcranial magnetic stimulation (TMS) was used to probe corticospinal excitability (CE) which has been measured in a variety of RT tasks during both the foreperiod and the response time periods. The purpose of the two studies in this thesis was to measure when and at what rate changes in CE occur in both simple and complex tasks. The results of the first experiment indicated that CE levels quickly increased from baseline with the presentation of the WS. This was followed by a holding period in which CE was held constant until a decline in CE occurred prior to the presentation of the IS. This decline was followed by a rapid increase in CE as the movement was initiated and released. Importantly, even though levels of CE were decreasing relative to the start of the decline, participants were still in a heightened state as they prepared to release their movements. Furthermore, it is suggested that selective inhibitory control mechanisms were at least partly responsible for the decline prior to the IS. The results of the second experiment indicated that MEP amplitudes in a simple task were significantly larger compared to those in a complex task relative to both the IS and the onset of electromyography. These findings suggest that simple and complex tasks achieve differing levels of corticospinal excitability, and it is suggested that the complex requires the use of the cerebellum, which suppresses excitatory projections to the thalamus, and consequently to the motor cortex. Transcranial Magnetic Stimulation Corticospinal Excitability Motor Preparation Simple Reaction Time Task Time Course Complexity
6	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
7	Influence des modalités de contraction musculaire sur les effets neuroplastiques de l'exercice / Influence of the muscle mode of contraction on the exercise induced neuroplastic effects Garnier, Yoann 08 November 2018 (has links) Parallèlement aux adaptations cardiovasculaires et neuromusculaires, les exercices mono-articulaires ou locomoteurs peuvent induire des changements neuroplastiques de muscles impliqués ou non dans l’exercice. Si l’effet de paramètres de l’exercice, comme l’intensité ou la durée, sur les changements neuroplastiques ont déjà été étudiés, l’effet du mode de contraction musculaire reste, quant à lui, moins connu. L’objectif de cette thèse a été d’évaluer les effets du mode de contraction musculaire sur les changements neuroplastiques consécutifs à un exercice locomoteur ou mono-articulaire. La première étude a montré que l’augmentation de l’excitabilité corticospinale d’un muscle non-impliqué dans l’exercice (muscle de la main), observée suite à un exercice de marche/ course, n’était pas modulée par le mode de contraction des muscles extenseurs du genou. En revanche, une modulation spécifique des réseaux intracorticaux par le mode de contraction impliqué lors d’un exercice a été mise en évidence par l’application d’un protocole de stimulation associative jumelée. Des observations similaires ont été faites dans une seconde étude investiguant les changements corticospinaux observés au niveau des muscles extenseurs du genou impliqués dans des exercices mono-articulaires fatigants, effectués dans un mode de contraction concentrique ou excentrique. Une troisième étude a montré que pour un exercice de marche/ course réalisé à même fréquence cardiaque en montée, à plat ou en descente, la modalité en descente induisait une fatigue musculaire des extenseurs du genou plus importante, avec des altérations contractiles plus marquée. La quatrième étude a montré que seule la modalité en descente induisait une augmentation de l’excitabilité corticospinale, et une réduction de l’inhibition corticale des muscles extenseurs du genou. Les travaux de cette thèse proposent que le mode de contraction musculaire lors d’un exercice n’est, en lui-même, pas un facteur prépondérant des changements neuroplastiques observés pour des muscles impliqués dans l’exercice. Ces changements neuroplastiques seraient au contraire dépendant de la magnitude de la fatigue neuromusculaire induite, elle-même dépendante du mode de contraction musculaire. / Along with cardiovascular and neuromuscular changes, mono-articular and locomotor exercises may induced neuroplastic changes from muscles involved, or non-involved, in the exercise. If the effect of exercise intensity or duration on neuroplastic changes has been previously investigated, the effect of the mode of muscle contraction remains unclear. The aim of this thesis was to investigate the effects of the mode of muscle contraction on neuroplastic changes induced a locomotor or a single-joint exercise. The first study showed that the increase in the corticospinal excitability of a non-exercised hand muscle, observed after a walking/ running exercise, was not modulated by the knee extensors mode of muscle contraction. However, a specific modulation of the intracortical networks by the mode of muscle contraction was evidenced using a paired-associative stimulation protocol. Similar findings were made in a second study that investigated corticospinal changes in the knee extensors following a fatiguing single-joint exercise, performed in either a concentric or an eccentric mode of muscle contraction. A third study showed that for a walking/ running exercise performed at the same heart rate in either a inline, a level or a decline condition, the latter condition induced a greater magnitude of neuromuscular fatigue of the knee extensors, with greater contractile impairments. The fourth study reported that only a decline exercise induced an increase in the corticospinal excitability, and a reduction of the cortical inhibition of the knee extensors. Altogether, findings from this thesis suggest that the mode of muscle contraction during an exercise is not, per se, a main factor responsible for neuroplastic changes observed in exercised muscles. Rather, these changes may depend upon the magnitude of neuromuscular fatigue induced, which could depend upon the mode of muscle contraction involved during exercise. Concentrique Excentrique Neuroplasticité Excitabilité corticospinale Fatigue neuromusculaire Locomotion Concentric Eccentric Neuroplasticity Corticospinal excitability Neuromuscular fatigue Locomotion 612.04 613.7
8	Examining Neural Alterations as the Origins of Disability in Patients Following Anterior Cruciate Ligament Reconstruction Lepley, Adam Scott 01 August 2014 (has links) No description available. Kinesiology Sports Medicine Biomechanics Spinal-reflexive excitability corticospinal excitability intracortical ecitability neuromuscular control quadriceps muscle stair gait anterior cruciate ligament
9	Adaptations fonctionnelles et nerveuses à l'entraînement par vibration locale : du sujet sain à la rééducation / FUNCTIONAL AND NEURAL ADAPTATIONS TO LOCAL VIBRATION TRAINING : FROM HEALTHY SUBJECTS TO REHABILITATION Souron, Robin 08 December 2017 (has links) La recherche de méthodes permettant de lutter contre le déconditionnement neuromusculaire à la suite par exemple d’une opération chirurgicale ou d’une immobilisation prolongée intéresse la communauté scientifique depuis de nombreuses années. Ce projet visait à proposer la technique de vibration locale (LV) comme une méthode alternative aux méthodes classiquement utilisées (e.g. vibration corps entier, stimulation électrique neuromusculaire) pour lutter contre ce déconditionnement neuromusculaire. Le premier objectif de ce travail de thèse était de déterminer les effets d’une application aigüe de LV sur la fonction neuromusculaire des muscles fléchisseurs dorsaux et extenseurs du genou de sujets sains. Nos résultats montrent une modulation de l’excitabilité du système nerveux central en réponse à l’application aigüe de LV, ce qui nous a permis d’envisager de potentielles adaptations si cette technique était utilisée de façon répétée sur plusieurs semaines. Ainsi, la seconde orientation de ce travail était d’évaluer les effets d’une application chronique (entraînement) de LV sur les propriétés fonctionnelles (force, hauteur de saut) et nerveuses (mesurées par stimulation magnétique transcrânienne) de sujets sains, jeunes et âgés. Nos résultats ont montré qu’un entraînement par LV était efficace pour améliorer les capacités fonctionnelles de ces deux populations, ces gains s’accompagnant d’adaptations nerveuses. Ces travaux nous ont alors conduits à la mise en place d’une dernière étude (en cours) à visée clinique, qui évaluait l’efficacité de LV en rééducation post-ligamentoplastie du ligament croisé antérieur du genou. / There is a need to find new methods to limit neuromuscular deconditioning that occurs after a surgery or prolonged immobilization. This thesis aimed to assess local vibration (LV) training as an alternative to methods classically used (e.g. whole body vibration, neuromuscular electrical stimulation) to fight against neuromuscular deconditioning. The first aim of this project was to determine the effects of a 30-min acute exposure to LV on the neuromuscular function of dorsiflexor and knee extensor muscles in a healthy population. Our results showed that acute LV intervention changed central nervous system excitability, allowing us to consider long-term adaptations to prolonged LV. Thus, the second aim of this thesis was to assess the effects of a chronic application (training) of LV on functional (maximal strength, squat jump performance) and neural (assessed with transcranial magnetic stimulation) properties of healthy young and old subjects. Our results showed that 4 to 8 weeks of LV increase functional capacities that were due to neural adaptations. Based on these results, an on-going study assessing the effectiveness of LV during a rehabilitation program for subjects who suffered from anterior cruciate ligament lesion has been proposed. Vibration locale Entrainement Stimulation Magnétique Transcrânienne Electromyographie Fonction neuromusculaire Excitabilité cortico-spinale Rééducation LOCAL VIBRATION TRAINING Transcranial magnetic stimulation Electromyography Neuromuscular function Corticospinal excitability Rehabilitation program
10	Effets aigus des étirements statiques et dynamiques sur le système neuromusculaire / Acute effects of static and dynamic stretching on the neuromuscular system Opplert, Jules-Antoine 06 June 2019 (has links) Dans un contexte de performance sportive, de réhabilitation ou de santé, les étirements sont couramment utilisés dans le but de préparer le système neuromusculaire à l’exercice subséquent. Si la littérature montre majoritairement que les étirements altèrent de façon aigue la performance musculaire et/ou fonctionnelle, il existe toutefois des études dont les résultats diffèrent, suggérant l’influence d’un certain nombre de facteurs sur la variabilité des réponses du système neuromusculaire. Pour une meilleure compréhension de cette variabilité et des mécanismes impliqués, cette thèse avait pour objectif d’examiner l’influence de différents paramètres sur le système neuromusculaire : la durée d’étirement, le groupe musculaire et la modalité d’étirement. Au travers de quatre études, il a été montré que les étirements statiques pouvaient altérer la production de force maximale et les propriétés neuromusculaires indépendamment de la durée d’étirement. Cependant, il est apparu que ces modulations étaient spécifiques au muscle, et plus précisément à la raideur relative du système musculo-tendineux. Indépendamment de la durée d’étirement, les étirements statiques ne seraient pas efficaces pour préparer le système neuromusculaire à une activité musculaire subséquente, et notamment pour des muscles raides. Plus particulièrement, les étirements dynamiques ne paraissent pas plus efficaces. Même si les effets néfastes ont été diminués comparativement aux étirements statiques, ils ne favoriseraient pas davantage la production de force ni la commande nerveuse. Toutefois, il est intéressant de noter qu’une durée courte d’étirements dynamiques peut réduire la résistance passive à l’étirement, et donc augmenter potentiellement l’amplitude articulaire maximale, sans affecter les capacités de production de force. Finalement, les étirements dynamiques pourraient être envisagés comme une activité musculaire dynamique, qui compense partiellement les effets néfastes de l’étirement sur la performance musculaire. D’un point de vue pratique, ceci suggère que ce type d’étirements peut être réalisé avant une performance, mais néanmoins accompagnés d’une activité musculaire de plus haute intensité, afin d’optimiser les effets de l’échauffement musculaire sur le système neuromusculaire. En définitive, la variabilité des réponses du système neuromusculaire serait dépendante de facteurs spécifiques, tels que la modalité d’étirement et la raideur relative du système musculo-tendineux, soulignant l’importance de les prendre en considération dans la pratique. / Stretching is traditionally incorporated into pre-exercise routines in health, rehabilitation and sporting environments to condition the neuromuscular system for exercise. While a large body of evidence reported that stretching may acutely impair the subsequent muscular performance, some conflicting results highlight possible mitigating factors of neuromuscular responses variability. Because the limited data available do not present a clear consensus, the aim of this thesis was to investigate the effects of different factors on neuromuscular responses to stretch: the muscle group, the stretch duration and modality. By means of four studies, it has been shown that static stretching may alter maximal voluntary torque and neuromuscular properties, irrespective of the stretch duration. However, these modulations were dependent on the muscle group, and more specifically on the intrinsic stiffness of the muscle-tendon system. Regardless of the stretch duration, static stretching appears to be not effective, or even detrimental, to prepare the musculotendinous system for subsequent exercises, and especially for stiff muscles. It is also relevant that dynamic stretching was not better than static stretching. Even if stretch-induced impairments were mitigated compared to static stretching, dynamic stretching would not optimize muscle strength capacities and central nervous system. However, a short duration of dynamic stretching may be sufficient to reduce passive resistive torque, and therefore potentially increase maximal range of motion, without affecting muscle strength capacities. Finally, dynamic stretching could be considered as dynamic muscle activity, which would partly counteract deleterious muscle-tendon stretching effects. From a practical point of view, dynamic stretching could be a part of warm-up procedure, but should be associated to stronger contractions to optimize the improvement in muscle strength capacities. In summary, the variability of neuromuscular responses to stretch would be dependent on specific factors, such as stretching modality and relative stiffness of the musculotendinous system, emphasizing the importance of taking it into consideration in practice. Etirements statiques Etirements dynamiques Activité musculaire Raideur musculo-Tendineuse Propriétés contractiles Excitabilité corticospinale Static stretching Dynamic stretching Muscle activity Muscle-Tendon stiffness Contractile properties Corticospinal excitability 796

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