Global ETD Search

61	Large-Scale Cortical Functional Connectivity Underlying Visuospatial Attention Unknown Date (has links) The endogenous, or voluntary, control of visuospatial attention relies upon interactions within a frontoparietal dorsal attention network (DAN) and this network’s top-down influence on visual occipital cortex (VOC). While these interactions have been shown to occur during attention tasks, they are also known to occur to some extent at rest, but the degree to which task-related interactions reflect either modulation or reorganization of such ongoing intrinsic interactions is poorly understood. In addition, it is known that in spatial neglect—a syndrome following unilateral brain lesions in which patients fail to attend to the contralesional side of space—symptom severity covaries with disruptions to intrinsic interhemispheric interactions between left and right homologous regions of the DAN; however, similar covariance with disruptions to intrahemispheric interactions within the DAN, and between the DAN and VOC, has not been demonstrated. These issues are addressed herein via the measurement of both undirected and directed functional connectivity (UFC, DFC) within the DAN and between the DAN and VOC. UFC and DFC were derived from correlations of, and multivariate vector autoregressive modeling of, fMRI BOLD time-series, respectively. Time-series were recorded from individuals performing an anticipatory visuospatial attention task and individuals at rest, as well as from stroke patients either with or without neglect and age-matched healthy controls. With regard to the first issue, the results show that relative to rest, top-down DAN-to-VOC influence and within-DAN coupling are elevated during task performance, but also that intrinsic connectivity patterns are largely preserved during the task. With regard to the second issue, results show that interhemispheric imbalances of intrahemispheric UFC and DFC both within the DAN and between the DAN and VOC strongly correlate with neglect severity, and may co-occur with functional decoupling of the hemispheres. This work thus demonstrates that the intrinsic functional integrity of the DAN and its relationship to VOC is crucial for the endogenous control of visuospatial attention during tasks, and that the compromise of this integrity due to stroke likely plays a role in producing spatial neglect. / Includes bibliography. / Dissertation (Ph.D.)--Florida Atlantic University, 2016. / FAU Electronic Theses and Dissertations Collection Cognitive neuroscience. Sensorimotor integration. Space perception. Selectivity (Psychology) Recognition (Psychology) Brain mapping.
62	Spatiotemporal brain dynamics of the resting state Unknown Date (has links) Traditionally brain function is studied through measuring physiological responses in controlled sensory, motor, and cognitive paradigms. However, even at rest, in the absence of overt goal-directed behavior, collections of cortical regions consistently show temporally coherent activity. In humans, these resting state networks have been shown to greatly overlap with functional architectures present during consciously directed activity, which motivates the interpretation of rest activity as day dreaming, free association, stream of consciousness, and inner rehearsal. In monkeys, it has been shown though that similar coherent fluctuations are present during deep anesthesia when there is no consciousness. These coherent fluctuations have also been characterized on multiple temporal scales ranging from the fast frequency regimes, 1-100 Hz, commonly observed in EEG and MEG recordings, to the ultra-slow regimes, < 0.1 Hz, observed in the Blood Oxygen Level Dependent (BOLD) signal of functi onal magnetic resonance imaging (fMRI). However, the mechanism for their genesis and the origin of the ultra-slow frequency oscillations has not been well understood. Here, we show that comparable resting state networks emerge from a stability analysis of the network dynamics using biologically realistic primate brain connectivity, although anatomical information alone does not identify the network. We specifically demonstrate that noise and time delays via propagation along connecting fibres are essential for the emergence of the coherent fluctuations of the default network. The combination of anatomical structure and time delays creates a spacetime structure in which the neural noise enables the brain to explore various functional configurations representing its dynamic repertoire. / Using a simplified network model comprised of 3 nodes governed by the dynamics of FitzHugh-Nagumo (FHN) oscillators, we systematically study the role of time delay and coupling strength in the Using a simplified network model comprised of 3 nodes governed by the dynamics of FitzHugh-Nagumo (FHN) oscillators, we systematically study the role of time delay and coupling strength in the generation o f the slow coherent fluctuations. We find that these fluctuations in the BOLD signal are significantly correlated with the level of neural synchrony implicating that transient interareal synchronizations are the mechanism causing the emergence of the ultra slow coherent fluctuations in the BOLD signal. / by Young-Ah Rho. / Thesis (Ph.D.)--Florida Atlantic University, 2009. / Includes bibliography. / Electronic reproduction. Boca Raton, Fla., 2009. Mode of access: World Wide Web. Brain mapping Sensorimotor integration Perceptual-motor processes Intersensory effects Movement sequences
63	The Role of Dorsal Anterior Cingulate Cortex in the Motor Control Unknown Date (has links) We sought to better understand human motor control by investigating functional interactions between the Supplementary Motor Area (SMA), dorsal Anterior Cingulate Cortex (dACC), and primary motor cortex (M1) in healthy adolescent participants performing visually coordinated unimanual finger-movement and n-back working memory tasks. We discovered modulation of the SMA by the dACC by analysis of fMRI BOLD time series recorded from the three ROIs (SMA, dACC, and M1) in each participant. Two measures of functional interaction were used: undirected functional connectivity was measured using the Pearson product-moment correlation coefficient (PMCC), and directed functional connectivity was measured from linear autoregressive (AR) models. In the first project, task-specific modulation of the SMA by the dACC was discovered while subjects performed a coordinated unimanual finger-movement task, in which the finger movement was synchronized with an exogenous visual stimulus. In the second project, modulation of the SMA by the dACC was found to be significantly greater in the finger coordination task than in an n-back working memory, in which the same finger movement signified a motor response indicating a 0-back or 2-back working memory match. We thus demonstrated in the first study that the dACC sends task-specific directed signals to the supplementary motor area, suggesting a role for the dACC in top-down motor control. Finally, the second study revealed that these signals were significantly greater in the coordinated motor task than in the n-back working memory task, suggesting that the modulation of the SMA by the dACC was associated with sustained, continuous motor production and/or motor expectation, rather than with the motor movement itself. / Includes bibliography. / Dissertation (Ph.D.)--Florida Atlantic University, 2015. / FAU Electronic Theses and Dissertations Collection Brain mapping Cerebral cortex -- Anatomy Cognitive neuroscience Computational neuroscience Movement sequences Perceptual motor learning Sensorimotor integration
64	The Effect of Thermal Stimulation on Corticospinal Excitability Ansari, Yekta 21 June 2019 (has links) This thesis describes a series of experiments to investigate the effect of thermal stimulation on corticospinal excitability using transcranial magnetic stimulation (TMS). Experiment I showed that innocuous cooling or warming of a single digit, produced short-lasting and mixed patterns of modulation only during actual thermal stimulation, with the inhibition being the most common pattern observed. In line with this finding, cooling stimulation applied to a larger area (i.e. multi-digits) produced variable but more sustained modulation in motor evoked potential (MEP) amplitude in the post-cooling phase (Exp II). Notably, the responses to cooling in terms of either suppressed or enhanced corticospinal excitability tended to be fairly consistent in a given individual with repeated applications. When examining possible sources of the observed variable MEP modulation, we found that individual characteristics such as age, sex and changes in skin temperature had no major influences. We hypothesized that the variability of responses might be related to individual differences in the excitability of intra-cortical circuits involved in sensorimotor integration. To test this hypothesis, we performed Experiment III using conditioning TMS paradigms. This experiment revealed that TMS markers of sensorimotor integration (SAI and SAF levels) were good predictors of individual variations in cooling-induced modulation in corticospinal excitability. This provided evidence supporting the role of SAI and SAF as markers to predict individual’s response to focal thermal stimulation. The identification of such predictors could enhance the therapeutic applicability of this form of stimulation in neurorehabilitation. Collectively, these findings advance our understanding of the neurophysiological basis of thermal stimulation and shed light on the development of a more rational application of neurofacilitation techniques based on afferent stimulation in clinical populations, such as stroke survivors. Motor Evoked Potentials Peripheral Stimulation Thermal Stimulation Short-latency afferent inhibition Sensorimotor Integration Transcranial Magnetic Stimulation
65	Motor training and cervical spine manipulation: effects on sensorimotor integration Bosse, Jessica 01 July 2012 (has links) Altered afferent input resulting from neck joint dysfunction has become a growing area of study. Cervical spine manipulation, specifically in individuals with subclinical neck pain (SNCP); induces neurological changes, suggesting it has a positive neuromodulatory effect on brain processing. The effects of manipulation on motor learning in individuals with SCNP have not been investigated until now. Studies in this thesis sought to develop and investigate a novel motor training task to be coupled with cervical spine manipulation to investigate its effects on individual’s ability to process new task information. The studies revealed significant changes in neural activity specific to the cerebellum and sensorimotor integration following a complex motor training task as compared to a simple repetitive task, suggesting that those specific regions are involved in processing of more complex motor skill learning tasks. This novel task was then coupled with manipulation which revealed significant activation increases in cortical and decreases in subcortical brain regions following manipulation. Regions specific to sensorimotor integration (SMI) showed increased activation in both the manipulation and passive head movement control groups, corroborating with the results from the first study. The use of a complex motor training task is a useful tool for determining intervention effects on neural processing in individuals with SCNP. / UOIT Sensorimotor integration Cerebellum Motor learning Subclinical neck pain Somatosensory evoked potentials
66	The effect of experimental pain on motor training performance and sensorimotor integration Dancey, Erin Margaret 01 July 2012 (has links) Sensorimotor integration (SMI) is the ability of the central nervous system (CNS) to integrate afferent (incoming) information from different body parts and formulate appropriate motor output to muscles. Effective sensorimotor integration is essential when learning new skills and when performing tasks at home and in the workplace (Rothwell &Rosenkranz, 2005). The overall aim of this thesis is to investigate the effect of acute experimental pain on sensorimotor processing. The primary outcome is the effect of acute experimental pain on somatosensory evoked potential (SEP) peaks. Secondary outcomes include the effect of pain on motor performance and the interactive effect of pain and motor training on SEP peaks. As expected for the placebo condition, no significant differences were found in any of the post-placebo peaks. Contrary to what was expected for the placebo condition, the only peak to be significantly different post-motor learning was the N24 peak. Contrary to what was expected, there were no significant differences for any of the peaks following capsaicin application. One of the secondary outcomes was the interactive effect of pain and motor learning on SEP peaks. The only peak to show any significant differences post-intervention/post-motor learning was the N24 peak. Another secondary outcome was the effect of pain on motor performance. In terms of accuracy, no significant differences were found for either condition following motor learning. However, the data does show a trend towards improved accuracy for the subjects in the intervention group while the subjects in the placebo show a trend towards decreased accuracy. As expected, there was a significant decrease in reaction time for both conditions post-motor learning. However, contrary to what was expected, reaction time decreased to a greater extent in the intervention condition as compared to the placebo condition. It was anticipated that the reaction time would decrease to a greater extent in the placebo condition as it was hypothesized that pain would negatively impact motor performance. It is suspected that the effect of the pain induced by the capsaicin made the motor training task more difficult and participants would have had to focus greater attentional resources to learn the task which lead to the enhanced performance following motor training. / UOIT Sensorimotor integration SMI Motor performance Effect of pain Somatosensory evoked potential SEP
67	Functional Dissection of the Sensory Rays in Caenorhabditis elegans Male Mating Behavior Koo, Pamela Kristine 2010 December 1900 (has links) The nematode Caenorhabditis elegans, with its sequenced genome, compact nervous system and stereotyped behaviors is an ideal model organism in which to study the integration of sensory input with motor output. Male mating behavior is among the most complex of these behaviors and males utilize a number of sensory organs in its execution. Among these are the rays, which are nine pairs of sensory organs that are arranged laterally along the male tail. Each ray is composed of two ultra-structurally distinct neuron types, an A type and a B type, surrounded by a glia-like structural cell. Though compositionally identical, each pair of rays maintains a unique, genetically-hardwired identity based on wiring, morphology, and neurotransmitter fate. Three techniques were used to investigate the role of the rays in male mating behavior. First, cauterization of the tips of the rays removed their sensory endings, leading to ray neuron death. Second, a heterologous light-activated cation channel was utilized to activate specific ray neuron types. Finally, ray neuron types were genetically targeted to undergo apoptosis by expression of heterologous caspases. The results show that the rays play important roles in multiple steps of male mating behavior, including contact response, scanning, and turning. The rays as a whole mediate posture change and backing during contact response. The ability to respond to hermaphrodite contact is shared among the rays, as is initiation of backward locomotion, though all rays are required for efficient, prolonged backward scanning. Both A and B neuron types appear capable of initiating contact response. Direct activation of B neurons through ChR2 causes a contact response-like ventral tail flexure, and elimination of both A and B neurons reduces contact response. A neurons additionally have a unique role in turning. C. elegans nematode male mating behavior rays sensorimotor integration neuroscience genetics
68	Reduced multisensory integration in individuals with schizophrenia evidence from psychophysical studies / Williams, Lisa E. January 2009 (has links) Thesis (Ph. D.)--University of California, San Diego, 2009. / Title from first page of PDF file (viewed July 7, 2009). Available via ProQuest Digital Dissertations. Vita. Includes bibliographical references.
69	To grip and not to slip : sensorimotor mechanisms in reactive control of grasp stability Häger Ross, Charlotte January 1995 (has links) The reactive control of fingertip forces maintaining grasp stability was examined in man during a prehensile task. Blindfolded subjects used the precision grip between the tips of index finger and thumb to restrain an object that was subjected to unpredictable load forces. These were delivered tangential to the parallel grip surfaces of the object. Load forces, grip forces (perpendicular to the grip surfaces) and position of the object were recorded.Subjects automatically adjusted the grip forces to loads of various amplitudes and rates. Thereby they maintained a reliable safety margin against frictional slips without using excessive grip forces. A rapid rise in grip force lasting about 0.2 s was triggered after a short delay following the onset of a sustained ramp load increase. This 'catch-up' response caused a quick restoration of an adequate grip:load force ratio that prevented frictional slips. If the ramp load continued to increase after the catchup response, the grip force also increased in parallel with the load change in a 'tracking' manner. Consequently, during the hold phases of 'ramp-and-hold' loads, the employed grip forces were approximately proportional to the load amplitude. Sensory information about the rate of change of the load force parametrically scaled the 'catchup' and 'tracking' responses.Following anesthetic block of sensory input from the digits, the grip responses were both delayed and attenuated or even abolished. To compensate for these impairments, subjects had to voluntarily maintain exceedingly high grip forces to prevent the object from slipping. The grip control improved slightly during hand and forearm support conditions that allowed marked wrist movements to occur in response to the loading. This indicates that signals from receptors in muscles, joints or skin areas proximal to the digits can to some extent be used to adjust grip forces during impaired digital sensibility. In contrast, these signals had only minor influence on the control during normal digital sensibility.Grip responses to loads delivered in various directions revealed that the load direction, in relation to gravity and to the hand's geometry, represents intrinsic task variables in the automatic processes that maintain a stable grasp. The load direction influenced both the response latencies and the magnitudes of the grip responses. The response latencies were shortest for loads in directions that were the most critical with regard to the consequences of frictional slippage, i.e., loads directed away from the palm or in the direction of gravity. Recordings of signals in cutaneous afferents innervating the finger tips demonstrated that these effects on the response latencies depended on differences in the time needed by the central nervous system to implement the motor responses. The short latencies in the most ‘criticar load directions may reflect the preparation of a default response, while additional central processing would be needed to execute the response to loads in other directions. Adjustments to local frictional anisotropies at the digit-object interface largely explained the magnitude effects.In conclusion, grip responses are automatically adjusted to the current loading condition during unpredictable loading of a hand held object. Subjects call up a previously acquired sensorimotor transform that supports grasp stability by preventing both object slippage and excessive grip forces. Cutaneous sensory information about tangential forces and frictional conditions at the digit-object interface is used to initiate and scale the grip responses to the current loading conditions, largely in a predictive manner. / <p>Diss. (sammanfattning) Umeå : Umeå universitet, 1995, Härtill 5 uppsatser</p> / digitalisering@umu human hand precision grip grasp force friction cutaneous mechanoreceptors sensorimotor integration motor control
70	Evaluation of the psychomotor education programme of a community based early childhood programme at the Dalton Trust Education Centre (KwaZulu-Natal, South Africa) in support of school preparation. Meusel, Rossella Rachele. January 2010 (has links) The early years of a child's growth and development are crucial for health, wellbeing and success in later life. Adequate stimulation during the pre-school years is a critical factor that can be associated with higher levels of achievement and better adjustment in school (Arnold, Barlett., Gowani, & Merali, 2006). Some children, for example those growing in contexts of adversity, are in particular need of pre-school assistance. This research evaluates a one-year implementation of the Psychomotor Education Programme (PMEP) at the Dalton Trust Education Centre, KwaZulu-Natal, South Africa. PMEP is an educational programme that stimulates the child‟s psychomotor functions and supports the development of the whole child through play in the pre-school years. An evaluation of the programme was required to establish if the PMEP had achieved the envisaged objectives of improving preparedness of children for their entrance into the formal school system. This summative evaluation used focus group discussions to collect data on whether the outcomes had been achieved from the perspective of the trained and experienced family facilitators who had participated in the PMEP. The participants were asked about the strengths, weaknesses, opportunities and threats of the PMEP. The areas identified as being attributable to the PMEP include social-emotional competence, self-awareness, emotional regulation and autonomy. The participants reported that PMEP had enabled the children to achieve the learning outcomes described by the Revised National Curriculum Statement (South African Department of Education, 2005). However, further research is needed to overcome the difficulty of maintaining the achieved outcomes in a new environment, such as the formal school context, where methods of teaching and resources may differ substantially from those provided by the PMEP. / Thesis (M.Soc.Sc.)-University of KwaZulu-Natal, Pietermaritzburg, 2010. Perceptual-motor learning. Child development. Sensorimotor integration. Education, Preschool. Early childhood education. Readiness for school.

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