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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
71

Localization of cortical potentials evoked by balance disturbances

Marlin, Amanda January 2011 (has links)
The ability to correct balance disturbances is essential for maintaining upright stability. Recent literature highlights a potentially important role for the cerebral cortex in controlling compensatory balance reactions. The objective of this research was to provide a more detailed understanding of the specific neurophysiologic events occurring at the cortex following balance disturbances. More specifically, the focus was to determine whether the N1, a cortical potential evoked during balance control, and the error-related negativity (ERN), a cortical potential measured in response to errors during cognitive tasks, have similar cortical representation, revealing a similar link to an error detection mechanism. It was hypothesized that the N1 and ERN would have the same generator located in the anterior cingulate cortex (ACC). Fourteen healthy young adults participated in a balance task (evoked N1) and a flanker task (evoked ERN). Temporally unpredictable perturbations to standing balance were achieved using a lean and release cable system. Electromyography and centre of pressure were measured during the balance task. Reaction times and error rates were measured during the flanker task. Electroencephalography was recorded during both tasks. Source localization was performed in CURRY 6 using a single fixed coherent dipole model to determine the neural generator of the N1 and ERN. The results revealed that the locations of the N1 and ERN dipoles were different. The mean (n=9) distance between N1 and ERN dipoles was 25.46 ± 8.88 mm. The mean Talairach coordinates for the ERN dipole were (6.47 ± 3.08, -4.41 ± 13.15, 41.17 ± 11.63) mm, corresponding to the cingulate gyrus (Brodmann area 24). This represents the ACC, supporting results from previous literature. The mean Talairach coordinates for the N1 dipole were (5.74 ± 3.77, -11.81 ± 10.84, 53.73 ± 7.30) mm, corresponding to the medial frontal gyrus (Brodmann area 6). This is the first work to localize the source of the N1. It is speculated that the generator of the N1 is the supplementary motor area and that it represents the generation of a contingency motor plan to shape the later phases of the compensatory balance response based on sensory feedback from the perturbation.
72

Vocal and instrumental musicians: Electrophysiologic and psychoacoustic analysis of pitch discrimination and production

Nikjeh, Dee Adams 01 June 2006 (has links)
Neurological evidence indicates that instrumental musicians experience changes in the auditory system following skill acquisition and sensory training; yet, little is known about auditory neural plasticity in formally trained vocal musicians. Furthermore, auditory pitch discrimination and laryngeal control are recognized as essential skills for vocal musicians; however, the relationship between physiological variables, perceptual abilities, and vocal production is unclear. Electrophysiologic and psychoacoustic measures were used to examine pitch production accuracy as well as pre-attentive and active pitch discrimination between nonmusicians and two classes of musicians. Participants included 40 formally trained musicians (19 vocalists/21 instrumentalists) and 21 nonmusician controls. All were right-handed young adult females with normal hearing. Stimuli were harmonic tone complexes approximating the physical characteristics of piano tones and represented the mid-frequency range of the untrained female vocal register extending from C4 to G4 (F0 = 261.63-392 Hz). Vocal pitch recordings were spectrally analyzed to determine pitch production accuracy. Difference limens for frequency (DLFs) were obtained by an adaptive psychophysical paradigm. Pre-attentive auditory discrimination was assessed by auditory evoked potentials (AEPs), including the mismatch negativity (MMN). A standard tone (G4 = 392 Hz) and three deviants differing in frequency (1.5%, 3%, and 6% below) were presented in a multi-deviant paradigm. All musicians demonstrated superior pitch perception and vocal production compared to nonmusicians. Pitch perception and production accuracy did not significantly differ between vocalists and instrumentalists; however, pitch production accuracy was most consistent within the vocalist group. Music training appears to facilitate both auditory perception and vocal production regardless of music specialty. Pitch perception and production were correlated skills only for instrumental musicians. Vocalists demonstrated minimal variability for both skills so that perception and production were not correlated. These two skills may be independent abilities between which a relationship develops with training. AEP analysis revealed an influence of musical expertise on neural responses as early as 50 ms after onset of musically relevant stimuli. MMN responses indicate that vocal musicians as well as instrumental musicians have superior sensory memory representations for acoustic parameters of harmonic stimuli and imply that auditory neural sensitivity is developed by intense music training.
73

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.
74

Localization of cortical potentials evoked by balance disturbances

Marlin, Amanda January 2011 (has links)
The ability to correct balance disturbances is essential for maintaining upright stability. Recent literature highlights a potentially important role for the cerebral cortex in controlling compensatory balance reactions. The objective of this research was to provide a more detailed understanding of the specific neurophysiologic events occurring at the cortex following balance disturbances. More specifically, the focus was to determine whether the N1, a cortical potential evoked during balance control, and the error-related negativity (ERN), a cortical potential measured in response to errors during cognitive tasks, have similar cortical representation, revealing a similar link to an error detection mechanism. It was hypothesized that the N1 and ERN would have the same generator located in the anterior cingulate cortex (ACC). Fourteen healthy young adults participated in a balance task (evoked N1) and a flanker task (evoked ERN). Temporally unpredictable perturbations to standing balance were achieved using a lean and release cable system. Electromyography and centre of pressure were measured during the balance task. Reaction times and error rates were measured during the flanker task. Electroencephalography was recorded during both tasks. Source localization was performed in CURRY 6 using a single fixed coherent dipole model to determine the neural generator of the N1 and ERN. The results revealed that the locations of the N1 and ERN dipoles were different. The mean (n=9) distance between N1 and ERN dipoles was 25.46 ± 8.88 mm. The mean Talairach coordinates for the ERN dipole were (6.47 ± 3.08, -4.41 ± 13.15, 41.17 ± 11.63) mm, corresponding to the cingulate gyrus (Brodmann area 24). This represents the ACC, supporting results from previous literature. The mean Talairach coordinates for the N1 dipole were (5.74 ± 3.77, -11.81 ± 10.84, 53.73 ± 7.30) mm, corresponding to the medial frontal gyrus (Brodmann area 6). This is the first work to localize the source of the N1. It is speculated that the generator of the N1 is the supplementary motor area and that it represents the generation of a contingency motor plan to shape the later phases of the compensatory balance response based on sensory feedback from the perturbation.
75

Aprendizagem de pista simbólicana atenção espacial : padrão comportamental e correlatos neurais

Silvestrin, Mateus January 2016 (has links)
Orientador: Prof. Dr. André Mascioli Cravo / Dissertação (mestrado) - Universidade Federal do ABC, Programa de Pós-Graduação em Neurociência e Cognição, 2016. / Uma série de estudos tem mostrado que saber onde determinado alvo será apresentado facilita seu processamento. Em muitos desses trabalhos, uma pista simbólica (como uma seta) é utilizada para guiar a orientação da atenção espacial. Entretanto, os mecanismos que regem o aprendizado e a atualização de pistas simbólicas visuoespaciais ainda são amplamente desconhecidos. Para esclarecermos melhor estes mecanismos, investigamos: (1) os padrões comportamentais da aprendizagem e atualização de pistas simbólicas e (2) os mecanismos neurais subjacentes a estes processos. Foi utilizada uma versão modificada do paradigma de orientação de atenção espacial de Posner juntamente com registro eletroencefalográfico. Nessa tarefa, os participantes deviam aprender a cada bloco qual das cores em um anel de cores servia de pista simbólica e utilizá-la para orientar a atenção e fazer a discriminação de um alvo. A tarefa incluía uma condição rara de pista inválida. Os resultados apontaram rápida aprendizagem da pista simbólica, porém a interpretação dos correlatos eletrofisiológicos ficou prejudicada por aparente contaminação das tentativas válidas pelas inválidas. Um novo experimento foi feito sem pistas inválidas e com a utilização de um distrator em metade dos blocos. Novamente, efeitos da aprendizagem da pista foram observados após uma única exposição, com ganhos em tempo de reação e acurácia. A presença do distrator limitou o benefício da pista. Como correlatos eletrofisiológicos foram identificados dois componentes no período entre pista e alvo: um componente semelhante à negatividade precoce de direcionamento atencional (EDAN) e uma negatividade tardia. Esses potenciais se intensificavam ao longo do bloco. Também foi observada tendência de dessincronização contralateral na banda alfa em eletrodos parieto-occipitais com intensificação com o avanço do bloco. Esses resultados sugerem que alguns correlatos eletrofisiológicos típicos da utilização de pistas simbólicas não se estabelecem imediatamente com sua aprendizagem, estando ausentes nas primeiras utilizações componentes como a negatividade anterior de direcionamento atencional (ADAN) e a positividade tardia de direcionamento atencional (LDAP), enquanto outros (EDAN e dessincronização contralateral de alfa) já são identificáveis. Adicionalmente, o padrão dos correlatos eletrofisiológicos permite levantar a hipótese de que nessa etapa inicial haja um papel preponderante da memória operacional para utilização das pistas simbólicas ainda não estabelecidas completamente. / Several studies have shown that knowing where a target will be presented facilitates its processing. Many of these works use symbolic cues (for instance, arrows) to guide spatial attention orienting. However, the mechanisms that rule the learning and updating of symbolic visuospatial cues are still unknown. To clarify these mechanisms, we investigated: (1) behavioral patterns of learning and updating symbolic cues and (2) neural mechanisms underlying these processes. A modified version of Posner¿s paradigm of attention orienting was used, along with eletroencephalografic recording. Participants had to learn which color from a colorwheel was the cue on each experimental block and use it to guide attention to facilitate the discrimination of a target. The task included a rare condition of invalid cues. Results showed fast learning of symbolic cues, however the interpretation of eletrphysiological correlates was impaired by an apparent contamination of the valid condition by the invalid one. A new experiment was done without invalid cues and including a distractor on half of the blocks. Once again, effects of cue learning were present after a single exposition, with gains in reaction time and accuracy. Distractor presence limited cueing benefits. As neural correlates, two components in the period between cue and target were identified: a component similar to the early directing attention negativity (EDAN) and a late negativity. These potentials were enhanced throughout the block. A tendency of contralateral desyncronization on parieto-occipital electrodes, increasing along the block, was also present. These results suggest that some typical eletrophysiological correlates of symbolic cueing in visuospatial attention are not immediately established with learning, since the anterior directing attention negativity (ADAN) and the late directing attention positivity (LDAP) are absent, while others (EDAN and alpha desynchronization) are already identifiable. Additionally, the pattern of eletrophysiological correlates found allows us to hypothesize that, in this initial stage, there is a heavy role for working memory in using symbolic cues that are not completely established.
76

ELECTROPHYSIOLOGICAL AND BEHAVIORAL MEASURES OF TACTILE AND AUDITORY PROCESSING IN CHILDREN WITH AUTISM SPECTRUM DISORDER

Girija Suhas Kadlaskar (9161390) 29 July 2020 (has links)
<p>Touch plays a key role in facilitating social communication and is often presented in conjunction with auditory stimuli such as speech. Individuals with autism spectrum disorder (ASD) frequently show atypical behavioral responsivity to both tactile and auditory stimuli, which is associated with increased ASD symptomatology. However, as discussed throughout Chapter 1, the neural mechanisms associated with responsivity to tactile and auditory stimuli in ASD are not fully understood. For example, some have argued that differences in responding to tactile and auditory stimuli may be attributed to sensory and perceptual factors, whereas others suggest that these differences could be related to atypicalities in allocation of attention to incoming stimuli. In Chapter 2, I address these competing hypotheses by examining early and late ERP components (indicative of perceptual and attentional processing respectively) in response to tactile and auditory stimuli. Next, despite the evidence suggesting that touch plays a role in modulating attention in typical development (TD), it is unclear whether touch cues affect the response of the phasic alerting network – a subcomponent of attention – in ASD and TD, and whether the alerting response may be atypical in children with ASD. In Chapter 3, I address this gap in the literature by examining whether tactile cues presented at different intervals before auditory targets facilitate reaction times differently in children with ASD and TD. Lastly, because prior research has shown associations between sensory and attentional processes and ASD symptomatology, in Chapters 2 and 3, I examine the associations of neural and behavioral indices of tactile and auditory processing with ASD symptomatology and language skills in children with ASD and TD. </p><p>In Chapter 2, I show that children in both the ASD and TD groups do not exhibit differences in both early and later neurological responses to tactile and auditory stimuli, suggesting that under certain experimentally-controlled conditions, behavioral differences to tactile and auditory stimuli may not be attributable to atypicalities in perceiving or attending to the incoming sensory input. However, neural responsivity to tactile and auditory stimuli is linked with sensory responsivity and social skills in all children. Specifically, reduced early contralateral activation to tactile stimuli is related to increased tactile symptoms, and reduced early amplitudes to auditory oddball stimuli are associated with impairments in reciprocal social communication in children with ASD as well as when examined across all children, and greater tendency of overall sensory hyper-reactivity. Additionally, in the TD group, greater later amplitudes to touch and auditory oddball stimuli are related to differences in reciprocal social communication and sensory reactivity respectively, indicating that patterns of allocation of attention may be related to ASD-like traits in typical development. Lastly, there is an association between greater sensitivity to changes to a stream of auditory stimuli and expressive language skills in all children. These results suggest that, although there are no group differences between neurological responses to tactile and auditory stimuli in ASD and TD, individual neural differences may be related to sensory and socio-communicative skills in all children. </p><p>In Chapter 3, I show that although children with ASD responded more slowly than children with TD, both groups displayed faster reaction times as a result of tactile cues before auditory targets, suggesting equivalent phasic alerting in response to tactile stimuli. Longer intervals between cues and targets benefitted children in both groups resulting in faster reaction times. Contrary to my hypotheses, touch-related behavioral facilitation was not associated with ASD symptomatology and language skills. </p>Taken together, the results of these studies suggest that, at least in certain contexts and with certain cues, children with ASD may show typical neurological processing in response to tactile and auditory stimuli, and that touch may facilitate the response of the alerting network similarly in ASD and TD. Therefore, everyday behavioral differences in response to tactile and auditory stimuli may be related to the specific nature of the stimuli as well as social contexts in which such stimuli are more likely to be encountered. Differences between processing rich and dynamic sensory stimuli experienced in the outside world vs experimentally-controlled sensory stimuli presented in the laboratory settings are discussed in Chapter 4. Additionally, I argue that individual responses expected in social vs non-social experimental settings may affect neural and behavioral responses in individuals with ASD. Finally, future research directions are discussed.
77

The perceptual basis of meaning acquisition: Auditory associative word learning and the effect of object modality on word learning in infancy and adulthood

Cosper, Samuel H. 19 November 2020 (has links)
The world in which we live is filled with sensory experiences. Language provides us with a manner in which to communicate these experiences with one another. In order to partake in this communication, it is necessary to acquire labels for things we see, hear, feel, smell, and taste. Much is known about how we learn words for things we can see, but this bias in the literature leaves many open questions about words attributed to other modalities. This cumulative dissertation aims to close this gap by investigating how both 10- to-12-month old infants and adults map novel pseudowords onto environmental sounds in an auditory associative word learning task with the aim to explore how humans learn words for things that cannot be seen, such as thunder, siren, and, lullaby. Infants were found, via event-related potentials (ERPs), to be successful at auditory associative word learning, while adults are much stronger learners in multimodal audio-visual conditions. Across the lifespan, sensory modality was found to affect word learning differently in infants than in adults. Where infants benefitted from unimodal auditory word learning, adults were more successful in multimodal audiovisual paradigms. Furthermore, the modality of the object being labelled modulated the temporal onset and the topological distribution of the N400 ERP component of violated lexical-semantic expectation. Lastly, the temporal congruency of presented stimuli affected word learning in adults in an inverted manner to other forms of statistical learning. Word learning is sensitive to age, modality, and means of presentation, providing evidence for various intertwined learning mechanisms and bringing us a step closer towards understanding human linguistic cognition.
78

Improving Brain-Computer Interface Performance: Giving the P300 Speller Some Color.

Ryan, David B. 17 August 2011 (has links) (PDF)
Individuals who suffer from severe motor disabilities face the possibility of the loss of speech. A Brain-Computer Interface (BCI) can provide a means for communication through non-muscular control. Current BCI systems use characters that flash from gray to white (GW), making adjacent character difficult to distinguish from the target. The current study implements two types of color stimulus (grey to color [GC] and color intensification [CI]) and I hypotheses that color stimuli will; (1) reduce distraction of nontargets (2) enhance target response (3) reduce eye strain. Online results (n=21) show that GC has increased information transfer rate over CI. Mean amplitude revealed that GC had earlier positive latency than GW and greater negative amplitude than CI, suggesting a faster perceptual process for GC. Offline performance of individual optimal channels revealed significant improvement over online standardized channels. Results suggest the importance of a color stimulus for enhanced response and ease of use.
79

Association Between Academic Performance and Electrocortical Processing of Cognitive Stimuli in College Students

Wolf, Mary Menn 17 March 2011 (has links) (PDF)
Because event-related potentials (ERPs) can reflect individual differences in intellectual ability, individual differences in college grade-point average (GPA) may be associated with specific individual ERP waves, such as the P300. However, P300 amplitude is higher in women than in men and varies across the menstrual cycle, factors that could confound the association between GPA and ERPs. In this regard, our objective was to determine whether differences in GPA are reflected in ERPs while standardling for sex and menstrual phase. After participants provided informed consent, we obtained GPAs from 22 right-handed college students (11 male, age range 22 to 26 and 10 female, age range 17 to 24) at a university with high admission and retention standards. We assessed menstrual phase by measuring luteinizing hormone levels across the cycle. We then obtained ERPs for each male participant and ERPs during each phase of the menstrual cycle for each female participant in an object-recognition visual pop-out protocol using Net Station Software (Electrical Geodesics, Inc., Eugene, Oregon) and E-prime Software (Psychology Software Tools, Inc., Sharpsburg, Pennsylvania). Males had larger P300s than females. The male and female high GPA was significantly different from the low GPA male and female groups. High GPA in females and males were associated with a positive peak at approximately 689 ms that was not present in the low-GPA male group and was significantly diminished in low-GPA females. Electro-cortical processing of cognitive stimuli differs between college students with high and low GPAs.
80

The Effects of Long-Term Physical Activity on Food Attention Allocation in College Freshmen Women

Compton, Sharla Elizabeth 13 September 2013 (has links) (PDF)
Purpose: The purpose of this study was to examine the effects of long-term (24 weeks) physical activity on attention allocated toward food in college freshmen women. Methods: Seventy-nine freshmen college women wore a multi-function pedometer for 24 weeks after being randomly assigned to a daily step level: 10,000; 12,500; or 15,000. After at least 16 weeks of intervention, participants were given a cognitive viewing task (pictures of food and flowers) with the neural response measured using electroencephalogram (EEG) and event-related potentials (ERPs). P300s and LPPs are components of the ERP indicating increased attention to stimuli. Results: There was a significant difference in daily step counts between groups. No interaction between step group and picture condition (food vs. flowers) was found for any of the three ERP (event-related potential) variables (P300 amplitude, P300 latency, LPP amplitude). The 12,500 group showed a significantly elevated response in comparison to the other groups for both food and flowers (F=8.84; P=0.0002). Additionally, subjective rating of hunger was significantly lower in the 15,000 step group (F=4.72; P=0.0030). Conclusion: It appears that long-term increases in physical activity are capable of reducing neural orientation toward hedonic food cues as well as subjective hunger ratings. In addition to increasing energy expenditure, increases in long-term physical activity may also influence the physiological drive to consume food.

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