Systematic examination of the impact of pre-stimulus alpha- mu and gamma band oscillations on perception : correlative and causal manipulation in mouse and human

Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Brain and Cognitive Sciences, 2012.
Cataloged from PDF version of thesis.
Includes bibliographical references.
The over-arching hypothesis that drives my work is that neural dynamics, fluctuating on millisecond to second time scales, powerfully impact perception. In this thesis, I employ correlative electrophysiological recording methods and causal optogenetic control of neural circuits to systematically test the importance of dynamics in the expression of pre-stimulus oscillations on perception. Specifically, I test the prediction that alpha oscillations expressed in a given sensory representation within a neocortical map predict diminished sensory capability in that region of sensory space, while gamma oscillations predict enhanced capacity. My model system throughout is primary somatosensory neocortex and tactile perception: I combine studies from human and mouse to benefit from the relative merits of each preparation. Several prior studies support this more generally stated view of oscillatory dynamics -- alpha predicting diminished and gamma predicting enhanced perceptual capacity. However, there is significant disagreement on even this broad assumption. Leading researchers have argued that alpha in fact predicts enhanced detection of tactile stimuli (e.g., Nicolelis and Fanselow, 2002). Further, there remains significant discord over whether gamma oscillations predict enhanced ability and, even if they do so, whether their expression is a causal contributor to this increased capacity or whether gamma is an epiphenomenal by-product of other beneficial shifts in neural dynamics. My thesis directly addresses these basic questions as to the predictive value of these oscillations, and favors the view that alpha and gamma are in general predictive of perception as stated. Further, I provide unique causal data showing that, under the conditions of our experiments, entrainment of a realistic and local gamma oscillation in neocortex can enhance stimulus detection. I also address important questions as to the independence of different frequency bands expressed in pre-stimulus os
by Dominique L. Pritchett.
Ph.D.