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Neurons In The Monkey Amygdala Detect Eye Contact During Naturalistic Social InteractionsMosher, Clayton Paul January 2014 (has links)
Eye contact is a fundamental means of social interaction among primates. In both humans and non-human primate societies, eye contact precedes and signals aggression or prosocial behaviors. Initiating and maintaining short periods of eye contact is essential during social interactions that build trust and promote cooperation. How the brain detects and orchestrates social exchanges mediated by eye contact remains an open question in neuroscience. Theories of social neuroscience speculate that the social brain in primates contains neurons specialized to detect and respond to eye-contact. This dissertation reports the discovery and characterization of a class of neurons, located in the amygdala of monkeys, that is activated selectively during eye contact. The discovery of these cells was facilitated by (1) characterization of the response properties of neurons in the amygdala during a canonical image-viewing task and (2) development of a reliable and quantifiable method for eliciting naturalistic eye contact between monkeys in the laboratory setting. The functional role of eye contact cells remains to be determined. The data presented in this dissertation confirm the role of the amygdala in social behaviors and allows for the formulation of new hypotheses about the cellular mechanisms within the amygdala that support complex social interactions among primates.
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Parietal neurophysiology during sustained attentional performance: assessment of cholinergic contribution to parietal processingBroussard, John Isaac 20 September 2007 (has links)
No description available.
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Crossing the scalesTelenczuk, Bartosz 14 November 2011 (has links)
Während seiner normalen Funktion generiert das Gehirn starke elektrische Signale, die technisch gemessen werden können. Das schon seit über einem Jahrhundert bekannte Phänomen ermöglicht es die Signalverarbeitung im Gehirn räumlich und zeitlich zu beobachten. Heute versteht man die zellulären Prozesse die zur Generierung der elektrischen Signale in einzelnen Neuronen führen. Jedoch rekrutieren die meisten neuronalen Ereignisse große Populationen von Zellen, dessen Aktivität zeitlich und räumlich koordiniert ist. Diese Koordinierung führt dazu, dass ihre elektrische Aktivität auch weit von den Quellen gemessen werden kann, sodass die Beobachtung des Gehirns auch nicht invasiv auf der Schädeloberfläche mittels dem sogenannten Elektroenzephalogramm (EEG) möglich ist. Der zeitliche Verlauf des Signals hängt nicht nur von den Eigenschaften einzelner Zellen ab sondern auch von ihrer Wechselwirkung mit anderen Neuronen, die oft komplex oder gar nicht bekannt ist. Diese Komplexität verhindert die Auswertung der gemessen Signale im Bezug auf die Anzahl von aktiven Neuronen, die Art der Antwort (Inhibition, Exzitation), die Synchronisationsstärke und den Einfluss anderer aktiver Prozesse (wie zum Beispiel: Lernen, Aufmerksamkeit usw.). In dieser Arbeit werden die Zusammenhänge zwischen diesen mikroskopischen Parametern (einzelne Neurone) und ihrer makroskopischen Wirkung (EEG) experimentell, datenanalytisch und theoretisch untersucht. / During its normal function the brain generates strong and measurable electric signals. This phenomenon, which has been known for more than a century, makes it possible to investigate the signal processing in the brain. Nowadays the cellular processes taking part in the generation of the electric signals are well understood. However, most of the neuronal events recruit large populations of cells, whose activities are coordinated spatially and temporally. This coordination allows for summation of activities generated by many neurons leading to extracellular electric signals that can be recorded non-invasively from the scalp by means of electroencephalography (EEG). The temporal structure of the EEG signal does not depend only on the properties of single neurons, but also on their interactions that may be very complex. The complexity hinders the evaluation of the recoded signal with respect to the number of active neurons, the type of response, the degree of synchronisation and the contribution of other processes (such as, learning and attention). In the thesis, the relations between the microscopic (single-neuron) and their macroscopic (EEG) properties will be investigated by means of experimental, data-analytic and theoretical approaches.
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Disruptions to human speed perception induced by motion adaptation and transcranial magnetic stimulation.Burton, Mark P., McKeefry, Declan J., Barrett, Brendan T., Vakrou, Chara, Morland, A.B. 11 1900 (has links)
No / To investigate the underlying nature of the effects of transcranial magnetic stimulation (TMS) on speed perception, we applied repetitive TMS (rTMS) to human V5/MT+ following adaptation to either fast- (20 deg/s) or slow (4 deg/s)-moving grating stimuli. The adapting stimuli induced changes in the perceived speed of a standard reference stimulus moving at 10 deg/s. In the absence of rTMS, adaptation to the slower stimulus led to an increase in perceived speed of the reference, whilst adaptation to the faster stimulus produced a reduction in perceived speed. These induced changes in speed perception can be modelled by a ratio-taking operation of the outputs of two temporally tuned mechanisms that decay exponentially over time. When rTMS was applied to V5/MT+ following adaptation, the perceived speed of the reference stimulus was reduced, irrespective of whether adaptation had been to the faster- or slower-moving stimulus. The fact that rTMS after adaptation always reduces perceived speed, independent of which temporal mechanism has undergone adaptation, suggests that rTMS does not selectively facilitate activity of adapted neurons but instead leads to suppression of neural function. The results highlight the fact that potentially different effects are generated by TMS on adapted neuronal populations depending upon whether or not they are responding to visual stimuli. / BBSRC
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