Impairments in cognitive control and memory present serious challenges to daily living for individuals with a variety of neurological and neuropsychiatric impairments. Understanding relevant brain mechanisms is key to the development of better diagnostic tools and improved treatment strategies. This proposed research focuses on a specific capability that is at the intersection of cognitive control and memory - behavioral flexibility, which refers to the ability to learn appropriate responses based on current situational context. Although this ability is clearly relevant for real-world memory challenges, tools for quantification of behavioral flexibility capabilities in individuals with neurological and neuropsychiatric impairments are limited, as is our understanding of relevant brain mechanisms. Under this proposed award, we will therefore refine a novel method we have developed for quantifying behavioral flexibility and the cognitive and brain processing that supports this capability. Brain mechanisms will be studied via the integration of various powerful technologies and analysis methodologies that allow us to determine how interactivity between key cognitive control and memory brain networks support behavioral flexibility. We will use sensitive eye-movement tracking measures of memory in conjunction with neuroimaging with functional magnetic resonance imaging (fMRI), as well as connectivity and graph theoretical analyses to identify brain network interactions that are important for behavioral flexibility. Furthermore, we will examine how damage to these networks due to ischemic stroke impairs behavioral flexibility using a voxel-based lesion-deficit mapping approach in stroke survivors. These methods will collectively provide information regarding normal network function in healthy individuals as well as the nature of network dysfunction in individuals with brain lesions. Execution of the proposed project will require a considerable extension of the applicant's current background and will be supported by an integrated training plan involving course work, instruction in advanced neuroimaging and eye-tracking methods by experts, as well as career-development training that will enable the applicant to conduct high- quality, independent neuroscience research.
Memory impairments are a serious public health burden that result in significant decreases in life quality for those affected. However, current approaches to assess and treat memory impairment are limited. This project will improve assessment of memory impairment and advance understanding of the brain mechanisms for learning and memory, therefore paving the way for improved treatments.
| Wang, Jane X; Cohen, Neal J; Voss, Joel L (2015) Covert rapid action-memory simulation (CRAMS): a hypothesis of hippocampal-prefrontal interactions for adaptive behavior. Neurobiol Learn Mem 117:22-33 |
| Wang, Jane X; Voss, Joel L (2015) Long-lasting enhancements of memory and hippocampal-cortical functional connectivity following multiple-day targeted noninvasive stimulation. Hippocampus 25:877-83 |
| Ryals, Anthony J; Wang, Jane X; Polnaszek, Kelly L et al. (2015) Hippocampal contribution to implicit configuration memory expressed via eye movements during scene exploration. Hippocampus 25:1028-41 |
| Wang, Jane X; Rogers, Lynn M; Gross, Evan Z et al. (2014) Targeted enhancement of cortical-hippocampal brain networks and associative memory. Science 345:1054-7 |
| Wang, Jane X; Voss, Joel L (2014) Brain networks for exploration decisions utilizing distinct modeled information types during contextual learning. Neuron 82:1171-82 |
