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Nicholas J Priebe
Professor
Department of NeuroscienceMechanisms underlying response properties of neurons in primary sensory cortex using both electrophysiology and imaging in vivo.nico@austin.utexas.edu
Phone: 512-232-0802
Office Location
NHB 2.112
Postal Address
100 E 24TH ST
AUSTIN, TX 78712-
Nicholas Priebe received his Ph.D. in Physiology from the University of California, San Francisco in 2001 after studying adaptation in motion-selective neurons with Stephen Lisberger. Dr. Priebe was a postdoctoral fellow with David Ferster at Northwestern University, investigating the mechanisms underlying neronal responses in primary vusual cortex. The massive expansion of cerebral cortex is a hallmark of the human brain. We know that the cortex plays an essential role in our perceptions and actions. Sensory inputs from the periphery are transformed in the cortex, allowing us to generate appropriate motor outputs. Dr. Priebe's lab studies the cortical circuitry and the computations that underlie such transformations, using vision as a model system. In visual cortex, neuronal circuitry performs the computations that extract motion, orientation and depth information about the visual environment from subcortical inputs. For example, primary visual cortex (V1) is the cortical location in which information from the two eyes is first integrated, ultimately allowing us to perceive depth in our visual field. By understanding the circuitry that underlies these kinds of computations, we gain insight into similar computations that occur throughout cortex.
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I am interested in mechanisms underlying response properties of neurons in primary sensory cortex using both electrophysiology and imaging in vivo. As sensory information moves from the periphery to the cortex the representation of the world is systematically transformed. Understanding the basis for these transformations sheds light on how the brain makes sense of the complicated world in which we reside.
Research Summary:
The massive expansion of cerebral cortex is a hallmark of the human brain. We know that the cortex plays an essential role in our perceptions and actions. Sensory inputs from the periphery are transformed in the cortex, allowing us to generate appropriate motor outputs. My lab studies the cortical circuitry and the computations that underlie such transformations, using vision as a model system. In visual cortex, neuronal circuitry performs the computations that extract motion, orientation and depth information about the visual environment from subcortical inputs. For example, primary visual cortex (V1) is the cortical location in which information from the two eyes is first integrated, ultimately allowing us to perceive depth in our visual field. By understanding the circuitry that underlies these kinds of computations, we gain insight into similar computations that occur throughout cortex.
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Benjamin Scholl, Sari Andoni and Nicholas J. Priebe.
Functional characterization of spikelet activity in the primary visual cortex
J. Physiol. in press.Benjamin Scholl, Jagruti J. Pattadkal, Geoff A. Dilly, Nicholas J. Priebe* and Boris V. Zemelman*.
Local integration accounts for weak selectivity of mouse neocortical parvalbumin interneurons
Neuron. 2015 87:424-436.Jude F. Mitchell*, Nicholas J. Priebe* and Cory T. Miller.
Motion dependence of smooth pursuit eye movements in the marmoset
J. Neurophys. 2015 113(10): 3954-3960.Nicholas J. Priebe and Aaron W. McGee.
Mouse vision as a gateway for understanding how experience shapes neural circuits
Front Neural Circuits. 2014.Andrew Y.Y. Tan*, Yuzhi Chen*, Benjamin Scholl*, Eyal Seidemann' and Nicholas J. Priebe'.
Sensory stimulation shifts visual cortex from synchronous to asynchronous states
Nature. 2014 509(7499):226-229.
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