Date: September 17, 2020. 13:00
Location: Online (webinar)
To attend this webinar please register here.
Title: Rapid State Changes Account for Apparent Brain and Behavior Variability
Affiliation: University of Oregon
Neural and behavioral responses to sensory stimuli are notoriously variable from trial to trial. Does this mean the brain is inherently noisy or that we don’t completely understand the nature of brain and behavior? Here we monitor the state of activity of the animal through videography of the face, including pupil and whisker movements, as well as walking, while also monitoring the ability of the animal to perform a difficult auditory or visual task. We find that the state of the animal is continuously changing and is never stable. The animal is constantly becoming more or less activated (aroused) on a second and subsecond scale. These changes in state are reflected in all of the neural systems we have measured, including cortical, thalamic, and neuromodulatory activity. Rapid changes in cortical activity are highly correlated with changes in neural responses to sensory stimuli and the ability of the animal to perform auditory or visual detection tasks. On the intracellular level, these changes in forebrain activity are associated with large changes in neuronal membrane potential and the nature of network activity (e.g. from slow rhythm generation to sustained activation and depolarization). Monitoring cholinergic and noradrenergic axonal activity reveals widespread correlations across the cortex. However, we suggest that a significant component of these rapid state changes arise from glutamatergic pathways (e.g. corticocortical or thalamocortical), owing to their rapidity. Understanding the neural mechanisms of state-dependent variations in brain and behavior promises to significantly “denoise” our understanding of the brain.
Bio: After serving thirty years as faculty at the Yale School of Medicine, David McCormick brought his research laboratory to the University of Oregon, where he is currently Director of the Institute for Neuroscience and Professor of Biology.
Interests: Cellular mechanisms by which the cerebral cortex operates, both normally and abnormally, using a variety of electrophysiological and advanced imaging techniques.