Phase sequences of posterior parietal cortex ensembles and sequence learning
University Of California-Irvine, Irvine CA
Investigators
Linked publications, trials & patents
Abstract
DESCRIPTION (provided by applicant): Learning sequences is part of our daily lives, from getting dressed to remembering the event sequence of our day. Humans and other animals who develop mental disorders both have problems with many types of sequence learning. The objective of the proposed research is to understand how spatial sequences are learned and encoded by brain circuits so future experiments can measure deficits in brain coding of sequences that may underlie mental disorders. Currently, an animal model of how the normal brain accomplishes sequence learning does not exist and is necessary for understanding what goes wrong to produce deficits. Our laboratory has made progress towards developing a model of sequence learning by recording simultaneously from many neurons in the brain while rats learn to navigate to a series of spatial locations arranged around a circular arena. This task has allowed us to begin to understand how part of the brain, the hippocampus, encodes where the animal is in this spatial sequence; however, we do not yet know how the brain translates this information about position in the sequence into a motor response to navigate to the next reward location. Previous research suggests that the parietal cortex may translate an appropriate motor response for the current position in the sequence. Therefore, I will investigate the brain mechanism for translating information about position in a sequence to an appropriate motor response. In three different experiments, I will assess: a) the frames of reference (person centered vs world centered) that are used when spatial cues are encoded in the parietal cortex; b) activity patterns in the parietal cortex during sequence learning; c) contributions of the parietal cortex to encoding learned sequences (specifically, what happens when the parietal cortex is inhibited during particular portions of spatial sequence learning and memory). These initial experiments will provide a foundation for the neural basis of sequence learning so that we can assess deficits in brain coding of sequences that may underlie psychiatric disorders.
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