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271	Les effets d’une commotion cérébrale d’origine sportive sur le fonctionnement cognitif de l’enfant évalués à l’aide de potentiels évoqués cognitifs et de tests neuropsychologiques Baillargeon-Blais, Annie 09 1900 (has links) Les commotions cérébrales d’origine sportive sont fréquentes chez les athlètes professionnels et semblent l’être tout autant chez les jeunes sportifs. Chez l’adulte, les symptômes se résorbent dans la majorité des cas assez rapidement (7-10 jours), mais la récupération peut s’avérer différente chez les jeunes. Plusieurs études utilisant les potentiels évoqués cognitifs ont découvert des anomalies cérébrales en l’absence de symptômes cliniques observables chez l'adulte. Toutefois, peu de données scientifiques sont disponibles sur les répercussions d’un tel impact sur le cerveau en développement. Le but de l’étude était de déterminer s’il existe une relation entre l’âge de survenue au moment de la commotion et la gravité des déficits. Cette étude transversale a évalué le fonctionnement cognitif de sportifs par des tests neuropsychologiques ainsi que les mécanismes neuronaux de l’orientation de l’attention (P3a) et de mise à jour de l’information en mémoire de travail (P3b) à l’aide de potentiels évoqués cognitifs. Les athlètes étaient répartis selon trois groupes d’âge [9-12 ans (n=32); 13-16 ans (n=34); adultes (n=30)], la moitié ayant subi une commotion dans la dernière année. Les comparaisons entre les groupes ont été effectuées par une série d’ANOVAs. Comparativement au groupe contrôle, les adolescents commotionnés présentaient des déficits de mémoire de travail. Les athlètes commotionnés démontraient une réduction de l’amplitude de la P3b comparativement aux non-commotionnés. Les résultats illustrent la présence de déficits neurophysiologiques persistants et ce, au moins six mois suivant l’impact. Les enfants semblent aussi sensibles que les adultes aux effets délétères d’une commotion cérébrale et les conséquences s’avèrent plus sévères chez l’adolescent. / Sport-related concussions are common injuries among professional athletes as well in adolescents and children participating in organized sports. Although the majority of concussions resolve rapidly in adults (7-10 days), recovery could be different in younger athletes. Several studies using event-related potentials show that adult athletes have cerebral anomalies in the absence of clinical symptoms. However, the consequences of a sport-related concussion on the developing brain are less known. The purpose of this study was to determine whether age differences exist with respect to cognitive functioning following a sport-related concussion. This cross-sectionnal study assessed cognitive functioning using standardized neuropsychological tests as well the neuronal mechanisms associated with the re-orienting attention (P3a) and with the update of information in working memory (P3b), using event-related potentials. Athletes were divided into three age groups [9-12 yrs (n=32); 13-16 yrs (n=34); and adults (n=30)] half of whom suffered from a sport-related concussion. Group comparisons were investigated with a series of ANOVAs. Specifically, concussed adolescents showed persistent deficits in working memory compare with their non injured counterparts. Concussed athletes from all age groups had significantly lower amplitude for the P3b component of their ERPs compared to their non injured teammates. No age-related differences for ERP’s were found among the concussed groups. These data suggest persistent neurophysiological deficits that are present at least 6 months following a concussion. Children appear to be as sensitive as adults to the consequences of a concussion and adolescents seem experience the most severe outcomes. commotion cérébrale enfants potentiels évoqués cognitifs neuropsychologie sport concussion children event-related potential neuropsychology
272	Microstructural and metabolic changes in the brains of concussed athletes Henry, Luke 07 1900 (has links) Les commotions cérébrales ont longtemps été considérées comme une blessure ne comportant que peu ou pas de conséquences. Cependant, la mise à la retraite forcée de plusieurs athlètes de haut niveau, liée au fait d'avoir subi des commotions cérébrales multiples, a porté cette question au premier plan de la culture scientifique et sportive. Malgré la sensibilisation croissante du public et la compréhension scientifique accrue des commotions cérébrales, il reste encore beaucoup d’inconnus au sujet de ces blessures. En effet, il est difficile de comprendre comment cette atteinte peut avoir des effets si profonds malgré le fait qu’elle n’entraîne apparemment pas de conséquences physiques apparentes lorsque les techniques traditionnelles d’imagerie cérébrale sont utilisées. Les techniques de neuroimagerie fonctionnelle ont cependant contribué à répondre aux nombreuses questions entourant les conséquences des commotions cérébrales ainsi qu'à accroître la compréhension générale de la physiopathologie de commotions cérébrales. Bien que les techniques de base telles que l'imagerie structurelle comme les scans TC et IRM soient incapables de détecter des changements structurels dans la grande majorité des cas (Ellemberg, Henry, Macciocchi, Guskiewicz, & Broglio, 2009; Johnston, Ptito, Chankowsky, & Chen, 2001), d'autres techniques plus précises et plus sensibles ont été en mesure de détecter avec succès des changements dans le cerveau commotionné. Des études d’IRM fonctionelle ont entre autres établi une solide relation entre les altérations fonctionnelles et les symptômes post-commotionels (Chen, Johnston, Collie, McCrory, & Ptito, 2007; Chen et al., 2004; Chen, Johnston, Petrides, & Ptito, 2008; Fazio, Lovell, Pardini, & Collins, 2007). Les mesures électrophysiologiques telles que les potentiels évoqués cognitifs (ERP) (Gaetz, Goodman, & Weinberg, 2000; Gaetz & Weinberg, 2000; Theriault, De Beaumont, Gosselin, Filipinni, & Lassonde, 2009; Theriault, De Beaumont, Tremblay, Lassonde, & Jolicoeur, 2010) et la stimulation magnétique transcrânienne ou SMT (De Beaumont, Brisson, Lassonde, & Jolicoeur, 2007; De Beaumont, Lassonde, Leclerc, & Theoret, 2007; De Beaumont et al., 2009) ont systématiquement démontré des altérations fonctionnelles chez les athlètes commotionnés. Cependant, très peu de recherches ont tenté d'explorer davantage certaines conséquences spécifiques des commotions cérébrales, entre autres sur les plans structural et métabolique. La première étude de cette thèse a évalué les changements structurels chez les athlètes commotionnés à l’aide de l'imagerie en tenseur de diffusion (DTI) qui mesure la diffusion de l'eau dans la matière blanche, permettant ainsi de visualiser des altérations des fibres nerveuses. Nous avons comparé les athlètes commotionnés à des athlètes de contrôle non-commotionnés quelques jours après la commotion et de nouveau six mois plus tard. Nos résultats indiquent un patron constant de diffusion accrue le long des voies cortico-spinales et dans la partie du corps calleux reliant les régions motrices. De plus, ces changements étaient encore présents six mois après la commotion, ce qui suggère que les effets de la commotion cérébrale persistent bien après la phase aiguë. Les deuxième et troisième études ont employé la spectroscopie par résonance magnétique afin d'étudier les changements neurométaboliques qui se produisent dans le cerveau commotionné. La première de ces études a évalué les changements neurométaboliques, les aspects neuropsychologiques, et la symptomatologie dans la phase aiguë post-commotion. Bien que les tests neuropsychologiques aient été incapables de démontrer des différences entre les athlètes commotionnés et non-commotionnés, des altérations neurométaboliques ont été notées dans le cortex préfrontal dorsolatéral ainsi que dans le cortex moteur primaire, lesquelles se sont avérées corréler avec les symptômes rapportés. La deuxième de ces études a comparé les changements neurométaboliques immédiatement après une commotion cérébrale et de nouveau six mois après l’atteinte. Les résultats ont démontré des altérations dans le cortex préfrontal dorsolatéral et moteur primaire dans la phase aiguë post-traumatique, mais seules les altérations du cortex moteur primaire ont persisté six mois après la commotion. Ces résultats indiquent que les commotions cérébrales peuvent affecter les propriétés physiques du cerveau, spécialement au niveau moteur. Il importe donc de mener davantage de recherches afin de mieux caractériser les effets moteurs des commotions cérébrales sur le plan fonctionnel. / Concussions had long been considered an injury of little to no consequence. However, the forced retirement of several high profile athletes due to the impact of having suffered multiple concussions has pushed the issue to the forefront of scientific and sports culture alike. Despite the growing public awareness and the ever-expanding scientific understanding of concussions there is still much that remains unknown about these injuries. Indeed, understanding how an injury can have such profound effects, though mostly transient, without any apparent physical consequence continues to confound how concussions are conceptualized in research. Neuroimaging techniques have helped answer many of the questions surrounding the physical consequences of concussions on the brain as well as increasing the general understanding of the pathophysiology of concussions. While basic structural imaging techniques such as CT scans and MRI are unable to detect any structural changes in the vast majority of cases (Ellemberg, et al., 2009; Johnston, et al., 2001), other more precise and sensitive techniques have been able to successfully detect changes in the concussed brain. Functional MRI studies have further established a strong relationship between functional alterations and post-concussion symptoms (Chen, et al., 2007; Chen, et al., 2004; Chen, et al., 2008; Fazio, et al., 2007). Electrophysiological measures such as ERP (Gaetz, et al., 2000; Gaetz & Weinberg, 2000; Theriault, et al., 2009; Theriault, et al., 2010) and TMS (De Beaumont, Brisson, et al., 2007; De Beaumont, Lassonde, et al., 2007; De Beaumont, et al., 2009) have consistently demonstrated alterations in concussed athletes. However, there has been very little research that has attempted to further explore the specific structural and metabolic aspects of concussion. The first study assessed structural changes in concussed athletes using diffusion tensor imaging which measures water diffusion in white matter. We compared concussed athletes with non-concussed control athletes in the days immediately after injury and again six months later. Our results indicated a consistent pattern of increased diffusion along neural tracts of the cortical spinal tract and in the corpus callosum underlying motor cortex. Furthermore, these changes were still present six months after injury suggesting that the effects of concussion are persistent past the acute phase. The second and third studies employed magnetic resonance spectroscopy as a means of investigating the neurometabolic changes that occur in the concussed brain. The first of these studies investigated the neurometabolic changes, neuropsychological aspects, and symptomatology in the acute post-injury phase. While neuropsychological testing was unable to show differences between concussed and non-concussed athletes, neurometabolic alterations were noted in the dorsal lateral prefrontal cortex as well as in primary motor cortex which correlated with reported symptoms. The second study investigated neurometabolic changes immediately after concussion and again six months after injury. Results indicated alterations in the dorsolateral prefrontal and primary motor cortices in the acute post-injury phase, but only those in primary motor cortex persisted to the six month time point. Commotion cérébrale Neuro-imagerie Traumatisme axonal Neurometabolism Concussion Neuroimaging Traumatic axonal Injury Neurometabolism
273	L'effet des coups de tête et des commotions cérébrales sur le fonctionnement cognitif des joueurs de soccer Couture, Sandra January 2009 (has links) Mémoire numérisé par la Division de la gestion de documents et des archives de l'Université de Montréal Commotion cérébrale Coups de tête Soccer Potentiels évoqués cognitifs Déficits cognitifs Concussion Heading Soccer Event-related potentials Cognitive impairment
274	Mild Traumatic Brain Injury : Studies on outcome and prognostic factors Lannsjö, Marianne January 2012 (has links) Objectives: To explore the prevalence and structure of self-reported disability after mild traumatic brain injury and the impact of traumatic brain pathology on such outcome. Material and methods: In study 1-3, symptoms data were collected by use of Rivermead Post-concussion Symptoms Questionnaire (RPQ) and data on global function by use of Glasgow Outcome Scale Extended (GOSE) from 2602 patients at 3 months after MTBI. RPQ data were subject to factor and Rasch-analyses Head CT data from 1262 patients were used in a prediction analysis that also included age and gender. In study 4, MRI and symptoms data were collected at 2-3 days and at 3-7 months follow-up after MTBI in 19 patients. Global function was assessed at follow-up by use of the Rivermead Head Injury Follow-Up Questionnaire (RHIFUQ) and GOSE. Results: I. Most respondents reported no remaining symptoms but 24% reported ≥3 and 10% ≥7 remaining symptoms. The factor analysis demonstrated that all symptoms are correlated but also identified subgroups of symptoms. II. Rasch-analysis of RPQ showed disordered category function, local dependency of items, poor targeting of persons to items and indications of 3 or more dimensions. There was no differential item functioning. III. Head CT pathology with no need for acute intervention was observed in 52 patients (4%) but was not associated with either frequency of remaining symptoms or global outcome at 3 months post injury. Female gender and age over 30 years were associated with less favourable outcome with respect to symptoms and GOSE. IV. Post-acute MRI indicated trauma-related pathology in one patient and follow-up MRI indicated loss of brain volume in 4 patients. Conclusions: A substantial proportion of patients with MTBI report remaining problems at three months after MTBI. RPQ is useful but not optimal to assess symptoms outcome after MTBI and calculation of a total sum score is not recommended. Female gender and older age are negative prognostic factors while brain pathology according to CT has no effect on self-reported outcome. Loss of brain volume after MTBI according to MRI may be a sensitive marker of traumatic brain pathology and deserves further studies. Rehabilitation Mild Traumatic Brain Injury Rasch-analysis prediction outcome head CT pathology Magnet Resonance Imaging
275	Neuroelectric Indices of Emotional Processing in Individuals with History of Concussion Magera, Nicholas P 05 1900 (has links) Concussions are a common type of traumatic brain injury resulting in a series of physical, emotional, and psychosocial symptoms. Following a concussion, emotional processing is thought to be altered through small functional and structural disruptions that impact information processing pathways, which may eventually manifest as behavioral impairments. Thus, the use of both behavioral and functional outcomes may be effective for assessing the changes in emotional processing that may occur following a concussion. The primary purpose of this study was to examine behavioral and neurocognitive differences in response to emotional face images between individuals with and without a history of concussion. Fifty participants (18 female; 32 male) were recruited and assigned to either the concussed (n = 23; Mage = 24.1 ± 1.0) or non-concussed (n = 27; Mage = 23.2 ± 0.6) group based on medical and self-reported concussion history. Participants completed a modified emotional oddball paradigm where representative positive (smiling), negative (frowning), and neutral faces from the Radboud Faces Database were displayed. Neuroelectric measures of P3 amplitude and latency, as well as behavioral measures of response accuracy and reaction time were assessed during the experiment. The concussion group showed significant reductions in accuracy, but no difference in reaction time compared to the non-concussed group. An increase (i.e., slower) in P3 latency was also found in the concussed group, with no observed group differences in P3 amplitude. Findings suggest that concussions may lead to chronic neuroelectric and behavioral deficits in classifying emotional, facial expressions. Concussion TBI ERP P3 P300 Emotion Oddball EEG Psychology, Physiological Health Sciences, Mental Health Health Sciences, Pathology
276	The effects of injury management protocol in college athletes with sports-related head injury evidrnce based recommendations / Thomas, Shannon Lee. January 2004 (has links) Thesis (M.A.)--Miami University, Dept. of Speech Pathology and Audiology, 2004. / Title from first page of PDF document. Includes bibliographical references (p. 54-59).
277	The establishment of normative data on Xhosa-speaking high school learners using the ImPACT 3.0 programme Salman-Godlo, Noluthando Cikizwa January 2006 (has links) Concussion is a common form of brain injury, especially amongst sports players of all age groups. ImPACT is a valid and reliable measure of a variety of cognitive functions commonly affected by such injuries, which allows for objective return-to-play decision making (Iverson, Lovell, & Collins, 2003). However, studies show that the transfer of such tests from one ethnic group to another without appropriate standardization is highly problematic (Ardila, 1995). Thus, the relative absence of South African normative data for the ImPACT 3.0 programme is an issue for concern. Consequently, this study aimed to establish norms for semi-rural Xhosa-speaking schoolboys with an advantaged education (ages 14, 16 and 18) for the ImPACT 3.0 programme as administered in English. Administrative and linguistic difficulties that were experienced by individuals during completion of the battery were also identified. Finally, the study included a comparison of the percentile scores of this sample to the USA norms for boys of a similar age group. Subtests scores were generated for 70 schoolboys and the data were then subjected to statistical analysis. A significant difference between English proficiency of the Grade 8 and Grade 12 boys was found. This indicates the importance of including an English proficiency test with the ImPACT battery when assessing such populations. No other significant differences were found between these age group samples. Although this requires further investigation, the comparison of the USA and SA percentiles suggests the use of local norms for this population. South African boys in this study consistently scored lower than the USA sample. Finally, it is recommended that symptom selfreports should be verbally investigated with each boy after testing, given indications of comprehension problems. In closing, limitations and future possible studies are discussed. Brain -- Concussion -- South Africa Sports injuries -- Psychological spects Neuropsychological tests ImPACT 3.0
278	"Glory is temporary, brain injury may be forever" : a neuropsychological study on the cumulative effects of sports-related concussive brain injury amongst Grade 12 school boy athletes Whitefield, Victoria Jane January 2007 (has links) The study investigated the long-term neuropsychological effects of repetitive mild traumatic brain injury (MTBI) due to participation in a contact sport amongst South African final year male high school athletes (N=189). The sample was divided by sports affiliation (Contact n = 115; Non-Contact n = 74) and concussion history (2+ Concussion n = 43; 0 Concussion n = 108). Comparative subgroups were statistically equivalent for age, education and estimated IQ (P > 0.05), with the Contact sport groups having markedly higher incidences of concussion than controls (p < 0.000). Measures included the ImPACT Verbal and Visual Memory, Visuomotor Speed and Reaction Time Composites, Digit Symbol Substitution and Digit Symbol Incidental Recall (immediate and delayed), the ImPACT Symptom Scale and a Post-concussion Symptom (PCS) questionnaire. Independent t-tests on cognitive measures at pre-and post-season revealed a predominant trend of Contact and 2+ Concussion groups performing worse, although only ImPACT Reaction Time at pre-season reached significance (p = 0.014). PCS comparisons revealed an overwhelming tendency of enhanced symptoms for Contact and 2+ Concussion groups with total scores being significantly different in most instances at pre-and post-season. Fatigue and aggression were the symptoms most pervasively high for the Contact and 2+ Concussion groups. Dependent t-test analyses at pre- versus post-season, revealed significant practice effects for the Contact group, not in evidence for controls on ImPACT Visual Motor Speed and Digit Symbol Incidental Recall-Delayed. Overall the results imply the possible presence of lingering neurocognitive and symptomatic concussion sequelae amongst South African final year high school participants of a contact sport. The indications gain potency when understood against the background of (i) Brain Reserve Capacity threshold theory, and (ii) the known risk of Type II error in group MTBI research, that might result in under-emphasis of subtle effects and miscalculation of cost-benefit risks. Clinical implications, and the need for prospective case-based research to ratify the results of this predominantly cross-sectional study, are discussed. Sports injuries Sports injuries -- Psychological aspects Brain damage Brain -- Concussion Neuropsychological tests Head -- Wounds and injuries
279	The bidirectional gut-brain-microbiota axis as a potential nexus between traumatic brain injury, inflammation, and disease Sundman, Mark H., Chen, Nan-kuei, Subbian, Vignesh, Chou, Ying-hui 11 1900 (has links) As head injuries and their sequelae have become an increasingly salient matter of public health, experts in the field have made great progress elucidating the biological processes occurring within the brain at the moment of injury and throughout the recovery thereafter. Given the extraordinary rate at which our collective knowledge of neurotrauma has grown, new insights may be revealed by examining the existing literature across disciplines with a new perspective. This article will aim to expand the scope of this rapidly evolving field of research beyond the confines of the central nervous system (CNS). Specifically, we will examine the extent to which the bidirectional influence of the gut-brain axis modulates the complex biological processes occurring at the time of traumatic brain injury (TBI) and over the days, months, and years that follow. In addition to local enteric signals originating in the gut, it is well accepted that gastrointestinal (GI) physiology is highly regulated by innervation from the CNS. Conversely, emerging data suggests that the function and health of the CNS is modulated by the interaction between 1) neurotransmitters, immune signaling, hormones, and neuropeptides produced in the gut, 2) the composition of the gut microbiota, and 3) integrity of the intestinal wall serving as a barrier to the external environment. Specific to TBI, existing pre-clinical data indicates that head injuries can cause structural and functional damage to the GI tract, but research directly investigating the neuronal consequences of this intestinal damage is lacking. Despite this void, the proposed mechanisms emanating from a damaged gut are closely implicated in the inflammatory processes known to promote neuropathology in the brain following TBI, which suggests the gut-brain axis may be a therapeutic target to reduce the risk of Chronic Traumatic Encephalopathy and other neurodegenerative diseases following TBI. To better appreciate how various peripheral influences are implicated in the health of the CNS following TBI, this paper will also review the secondary biological injury mechanisms and the dynamic pathophysiological response to neurotrauma. Together, this review article will attempt to connect the dots to reveal novel insights into the bidirectional influence of the gut-brain axis and propose a conceptual model relevant to the recovery from TBI and subsequent risk for future neurological conditions. Gut-brain axis Traumatic Brain Injury Concussion Gut Microbiota Chronic Traumatic Encephalopathy Neurodegenerative disease Neuroinflammation Microglia Intestinal dysfunction
280	Impacts à la tête au hockey sur glace : effets du jeu sécuritaire, de l’agressivité et de l’historique de commotions cérébrales chez les adolescents québécois Chevrier, Martin 04 1900 (has links) No description available. Impact à la tête Accéléromètre Hockey Commotion cérébrale Head impact Accelerometer Concussion

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