Global ETD Search

101	Applying the Inhibitory Cascade Model to Molar Series of Two Human Population Samples Rohrer, Thomas Talbird Chiaviello 10 November 2022 (has links) No description available. Physical Anthropology Dental Anthropology molar development Inhibitory Cascade Model inhibitory cascade molar initiation inter-populational variation human variation Gullah-Geechee Seminole
102	Functional Imaging of Spinal Locomotor Networks Nagaraja, Chetan January 2016 (has links) Movement is necessary for the survival of most animals. The spinal cord contains neuronal networks that are capable of motor coordination and of producing different movements. In particular, a very reduced neuronal network in the spinal cord can produce simple rhythmic outputs even in the absence of descending or sensory inputs. This basic circuit was discovered by Thomas Graham Brown (reported in 1911) and is termed central pattern generator. For over a century a large number of studies have been carried out in order to identify the neuronal components that are part of these networks. In project 1 we focused on Renshaw cells, which are a population of spinal interneurons expressing the alpha-2 subunit of the nicotinic acetylcholine receptors (Chrna2). Renshaw cells are the only identified central targets for motor neuron inputs, and in turn they mediate inhibition of the motor neurons. We analyzed the activity pattern of Renshaw cells on a cell-population level in neonates when the circuit is still developing. At segment 1 of the lumbar spinal cord, Renshaw cells show significantly greater activity response to functional sensory and motor inputs from rostral compared to the caudal segments. Contrarily, the suppression of the monosynaptic stretch reflex was more pronounced when caudal roots were stimulated. Our data underline the importance of sensory input during motor circuit development and help to understand the functional organization of Renshaw cell connectivity. Several neurons that play distinct roles in locomotor central pattern generation have been identified with the help of genetics. For instance, the V0 population of spinal interneurons are identified by the expression of transcription factor developing brain homeobox 1 (Dbx1). V0 neurons are necessary for producing an alternating rhythm at all locomotor speeds. In project 2 we have looked at a population of dorsally derived ventrally projecting interneurons that express the transcription factor doublesex and mab-3 related transcription factor 3 (Dmrt3). On a behavioral level Dmrt3 neurons are involved in regulating coordination across different locomotor speeds. On a microcircuit level, we have shown that individual Dmrt3 neurons show distinct frequencies of oscillations for a constant locomotor rhythm. In addition, removal of inhibitory neurotransmission from Dmrt3 neurons results in uncoupling of rhythm in motor neurons. In project 3 the activity patterns in populations of flexor related motor neurons are characterized during fictive locomotion in neonatal mice. An interesting and intriguing finding in project 3 is the presence of multiple rhythmicities in motor neurons. Multiple rhythmicities are seen even when the locomotor output shows a constant frequency. Central pattern generators two-photon microscopy locomotor rhythm multiple rhythmicities inhibitory neurotransmission
103	Functional connectivity of layer II/III and V GABAergic Martinotti cells in the primary somatosensory (barrel) cortex of mice Walker, Florian 10 February 2016 (has links) No description available. 570 Barrel cortex Martinotti cell Cortical circuitry Inhibitory interneurons Biologie (PPN619462639)
104	ATTENTIONAL BIAS AND ALCOHOL ABUSE Weafer, Jessica Jane 01 January 2012 (has links) Selective attention towards alcohol-related cues (i.e., “attentional bias”) is thought to reflect increased incentive motivational value of alcohol and alcohol cues acquired through a history of heavy alcohol use, and as such attentional bias is considered to be a clinically relevant factor contributing to alcohol use disorders. This dissertation consists of two studies that investigated specific mechanisms through which attentional bias might serve to promote alcohol abuse. Study 1 compared magnitude of attentional bias in heavy (n = 20) and light (n = 20) drinkers following placebo and two doses of alcohol (0.45 g/kg and 0.65 g/kg). Heavy drinkers displayed significantly greater attentional bias than did moderate drinkers following placebo. However, heavy drinkers displayed a dose-dependent decrease in response to alcohol. Individual differences in attentional bias under placebo were associated with both self-reported and laboratory alcohol consumption, yet bias following alcohol administration did not predict either measure of consumption. These findings suggest that attentional bias is strongest before a drinking episode begins, and as such might be most influential in terms of initiation of alcohol consumption. Study 2 addressed theoretical accounts regarding potential reciprocal interactions between attentional bias and inhibitory control that might promote excessive alcohol consumption. Fifty drinkers performed a measure of attentional bias and a novel task that measures the degree to which alcohol-related stimuli can increase behavioral activation and reduce the ability to inhibit inappropriate responses. As hypothesized, inhibitory failures were significantly greater following alcohol images compared to neutral images. Further, heightened attentional bias was associated with greater response activation following alcohol images. These findings suggest that alcohol stimuli serve to disrupt mechanisms of behavioral control, and that heightened attentional bias is associated with greater disruption of control mechanisms following alcohol images. Taken together, these studies provide strong evidence of an association between attentional bias in sober individuals and alcohol consumption, suggesting a pronounced role of attentional bias in initiation of consumption. Further, findings show that attention to alcohol cues can serve to disrupt mechanisms of inhibitory control that might be necessary to regulate drinking behavior, suggesting a potential means through which attentional bias might promote consumption. Attentional Bias Inhibitory Control Alcohol Heavy Drinkers Behavioral Activation Psychology Substance Abuse and Addiction
105	The relationship between inhibitory control and System 1 and System 2 processes in deductive and spatial reasoning. Graham, Charlotte January 2007 (has links) Dual Processing theory proposes that the ability to over ride associative (System 1) in favour of analytical (System 2) processed in deductive reasoning may depend on inhibitory control. The present study applies this association to a spatial reasoning task by adapting a mental rotation task to a multichoice format including System 1 (mirror) and System 2 (rotated image) responses. Fifty undergraduate volunteers from the University of Canterbury responded to a Stroop task as a measure of inhibitory control that was compared with System 1 and System 2 responding from a spatial and a deductive reasoning task. It was expected that people with weaker inhibitory potential would make more System 1 and fewer System 2 responses in both deductive and visual-spatial reasoning tasks. Contrary to expectation System 2 responding dominated for both tasks and correlations between both reasoning tasks and measures of inhibitory control were non-significant. The differing idiosyncratic demands of each task may have obscured any common variables associated with inhibitory control. This research initiated a test for the presence of System 1 and System 2 in spatial reasoning. cognition reasoning inhibitory control deductive reasoning spatial reasoning System 1 and System 2 belief bias
106	Computational approach to anti-cancer drug discovery Rana, Ambar. 09 July 2011 (has links) Access to abstract permanently restricted to Ball State community only / Access to thesis permanently restricted to Ball State community only / Department of Chemistry Lungs--Cancer--Chemotherapy.
107	Adaptive map alignment in the superior colliculus of the barn owl : a neuromorphic implementation Huo, Juan January 2010 (has links) Adaptation is one of the basic phenomena of biology, while adaptability is an important feature for neural network. Young barn owl can well adapt its visual and auditory integration to the environmental change, such as prism wearing. At first, a mathematical model is introduced by the related study in biological experiment. The model well explained the mechanism of the sensory map realignment through axongenesis and synaptogenesis. Simulation results of this model are consistent with the biological data. Thereafter, to test the model’s application in hardware, the model is implemented into a robot. Visual and auditory signals are acquired by the sensors of the robot and transferred back to PC through bluetooth. Results of the robot experiment are presented, which shows the SC model allowing the robot to adjust visual and auditory integration to counteract the effects of a prism. Finally, based on the model, a silicon Superior Colliculus is designed in VLSI circuit and fabricated. Performance of the fabricated chip has shown the synaptogenesis and axogenesis can be emulated in VLSI circuit. The circuit of neural model provides a new method to update signals and reconfigure the switch network (the chip has an automatic reconfigurable network which is used to correct the disparity between signals). The chip is also the first Superior Colliculus VLSI circuit to emulate the sensory map realignment. 571.1
108	Unraveling the impact of IL1RAPL1 mutations on synapse formation : towards potential therapies for intellectual disability / Exploration de l’impact des mutations dans IL1RAPL1 sur la formation et la fonction des synapses : vers des thérapies potentielles pour la déficience intellectuelle Ramos, Mariana 09 October 2015 (has links) L’intégrité des synapses neuronales est primordiale pour le développement et le maintien des capacités cognitives. Des mutations dans des gènes codant pour des protéines synaptiques ont été trouvées chez des patients atteints de déficience intellectuelle (DI), qui est une maladie neurodéveloppementale ayant des conséquences sur les fonctions intellectuelles et adaptatives. Ce travail de thèse porte sur l’étude de l’un de ces gènes, IL1RAPL1, dont les mutations sont responsables d’une forme non-syndromique de DI liée au chromosome X, et sur le rôle de la protéine IL1RAPL1 dans la formation et le fonctionnement des synapses. IL1RAPL1 est une protéine trans-membranaire qui est localisée dans les synapses excitatrices où elle interagit avec les protéines post-synaptiques PSD-95, RhoGAP2 et Mcf2l. De plus, IL1RAPL1 interagit en trans- avec une protéine phosphatase présynaptique, PTPd, via son domaine extracellulaire. Nous avons étudié les conséquences fonctionnelles de deux nouvelles mutations qui affectent le domaine extracellulaire d’IL1RAPL1 chez des patients présentant une DI. Ces mutations conduisent soit à une diminution de l’expression de la protéine, soit à une réduction de l’interaction avec PTPd affectant ainsi la capacité d’IL1RAPL1 à induire la formation de synapses excitatrices. En absence d’IL1RAPL1, le nombre ou la fonction des synapses excitatrices est diminué, ce qui mène à un déséquilibre entre les transmissions synaptiques excitatrice et inhibitrice dans des régions spécifiques du cerveau. Dans le cas particulier de l’amygdale latérale, nous avons montré que ce déséquilibre conduit à des défauts de mémoire associative chez la souris déficiente en Il1rapl1. L’ensemble des résultats qui font partie de ce travail montre que l’interaction IL1RAPL1/PTPd est essentielle pour la formation des synapses et suggère que les déficits cognitifs des patients avec une mutation dans il1rapl1 proviennent du déséquilibre de la balance excitation/ inhibition. Ces observations ouvrent des perspectives thérapeutiques visant à rétablir cette balance dans les réseaux neuronaux affectés. / Preserving the integrity of neuronal synapses is important for the development and maintenance of cognitive capacities. Mutations on a growing number of genes coding for synaptic proteins are associated with intellectual disability (ID), a neurodevelopmental disease characterized by deficits in adaptive and intellectual functions. The present work is dedicated to the study of one of those genes, IL1RAPL1, and the role of its encoding protein in synapse formation and function. IL1RAPL1 is a trans-membrane protein that is localized at excitatory synapses, where it interacts with the postsynaptic proteins PSD-95, RhoGAP2 and Mcf2l. Moreover, the extracellular domain of IL1RAPL1 interacts trans-synaptically with the presynaptic phosphatase PTPd. We studied the functional consequences of two novel mutations identified in ID patients affecting this IL1RAPL1 domain. Those mutations lead either to a decrease of the protein expression or of its interaction with PTPd, affecting in both cases the IL1RAPL1-mediated excitatory synapse formation. In the absence of IL1RAPL1, the number or function of excitatory synapses is perturbed, leading to an imbalance of excitatory and inhibitory synaptic transmissions in specific brain circuits. In particular, we showed that this imbalance in the lateral amygdala results in associative memory deficits in mice lacking Il1rapl1. Altogether, the results included in this work show that IL1RAPL1/PTPd interaction is essential for synapse formation and suggest that the cognitive deficits in ID patients with mutations on IL1RAPL1 result from the imbalance of the excitatory and inhibitory transmission. These observations open therapeutic perspectives aiming to reestablish this balance in the affected neuronal circuits. Déficience intellectuelle Synapses IL1RAPL1 Balance excitation/inhibition Intellectual disability Synapses IL1RAPL1 Excitatory/inhibitory balance 612.8
109	Unraveling the impact of IL1RAPL1 mutations on synapse formation : towards potential therapies for intellectual disability / Exploration de l’impact des mutations dans IL1RAPL1 sur la formation et la fonction des synapses : vers des thérapies potentielles pour la déficience intellectuelle Ramos, Mariana 09 October 2015 (has links) L’intégrité des synapses neuronales est primordiale pour le développement et le maintien des capacités cognitives. Des mutations dans des gènes codant pour des protéines synaptiques ont été trouvées chez des patients atteints de déficience intellectuelle (DI), qui est une maladie neurodéveloppementale ayant des conséquences sur les fonctions intellectuelles et adaptatives. Ce travail de thèse porte sur l’étude de l’un de ces gènes, IL1RAPL1, dont les mutations sont responsables d’une forme non-syndromique de DI liée au chromosome X, et sur le rôle de la protéine IL1RAPL1 dans la formation et le fonctionnement des synapses. IL1RAPL1 est une protéine trans-membranaire qui est localisée dans les synapses excitatrices où elle interagit avec les protéines post-synaptiques PSD-95, RhoGAP2 et Mcf2l. De plus, IL1RAPL1 interagit en trans- avec une protéine phosphatase présynaptique, PTPd, via son domaine extracellulaire. Nous avons étudié les conséquences fonctionnelles de deux nouvelles mutations qui affectent le domaine extracellulaire d’IL1RAPL1 chez des patients présentant une DI. Ces mutations conduisent soit à une diminution de l’expression de la protéine, soit à une réduction de l’interaction avec PTPd affectant ainsi la capacité d’IL1RAPL1 à induire la formation de synapses excitatrices. En absence d’IL1RAPL1, le nombre ou la fonction des synapses excitatrices est diminué, ce qui mène à un déséquilibre entre les transmissions synaptiques excitatrice et inhibitrice dans des régions spécifiques du cerveau. Dans le cas particulier de l’amygdale latérale, nous avons montré que ce déséquilibre conduit à des défauts de mémoire associative chez la souris déficiente en Il1rapl1. L’ensemble des résultats qui font partie de ce travail montre que l’interaction IL1RAPL1/PTPd est essentielle pour la formation des synapses et suggère que les déficits cognitifs des patients avec une mutation dans il1rapl1 proviennent du déséquilibre de la balance excitation/ inhibition. Ces observations ouvrent des perspectives thérapeutiques visant à rétablir cette balance dans les réseaux neuronaux affectés. / Preserving the integrity of neuronal synapses is important for the development and maintenance of cognitive capacities. Mutations on a growing number of genes coding for synaptic proteins are associated with intellectual disability (ID), a neurodevelopmental disease characterized by deficits in adaptive and intellectual functions. The present work is dedicated to the study of one of those genes, IL1RAPL1, and the role of its encoding protein in synapse formation and function. IL1RAPL1 is a trans-membrane protein that is localized at excitatory synapses, where it interacts with the postsynaptic proteins PSD-95, RhoGAP2 and Mcf2l. Moreover, the extracellular domain of IL1RAPL1 interacts trans-synaptically with the presynaptic phosphatase PTPd. We studied the functional consequences of two novel mutations identified in ID patients affecting this IL1RAPL1 domain. Those mutations lead either to a decrease of the protein expression or of its interaction with PTPd, affecting in both cases the IL1RAPL1-mediated excitatory synapse formation. In the absence of IL1RAPL1, the number or function of excitatory synapses is perturbed, leading to an imbalance of excitatory and inhibitory synaptic transmissions in specific brain circuits. In particular, we showed that this imbalance in the lateral amygdala results in associative memory deficits in mice lacking Il1rapl1. Altogether, the results included in this work show that IL1RAPL1/PTPd interaction is essential for synapse formation and suggest that the cognitive deficits in ID patients with mutations on IL1RAPL1 result from the imbalance of the excitatory and inhibitory transmission. These observations open therapeutic perspectives aiming to reestablish this balance in the affected neuronal circuits. Déficience intellectuelle Synapses IL1RAPL1 Balance excitation/inhibition Intellectual disability Synapses IL1RAPL1 Excitatory/inhibitory balance 612.8
110	Hedonic Versus Predictive Inhibition of Avoidance Responding in Rats Lipscomb, Robert Scrivener 12 1900 (has links) Traditional two-process theory predicts that a conditioned stimulus (CS) paired with shock offset on Pavlovian trials will inhibit operant avoidance responding. Two explanations of the inhibitory mechanism involved were compared: contemporaneous pairing of CS with a hedonic relief reaction versus the predictive, discriminative relationship of CS to the non-shock interval. The pattern of avoidance inhibition associated with cessation CSs paired with electric shocks of constant duration was expected to be different from the pattern accompanying cessation CSs paired with shocks of variable duration. Mean rates of responding by the two groups were compared by analysis of covariance using baseline as the covariate. Neither CS displayed any reliably observable effects on avoidance rates. Possible procedural flaws and compatible improvements are discussed. inhibitory mechanisms Conditioned response. Avoidance (Psychology) hedonic relief reactions avoidance responding

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