Individual-specific engagement of cortical resources for standing balance control in aging and post stroke
Emory University, Atlanta GA
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Abstract
Project Summary Our long-term goal is to identify neural mechanisms of healthy and impaired balance to guide mechanistically- based predictors, assessments, and interventions for addressing balance and gait impairments common in aging and neurological disorders. It is well-known clinically that engagement of cortical resources in balance control is an indicator of fall risk in older adults including stroke survivors, as inferred by the degradation of balance and/or gait performance when a concurrent cognitive task shifts attention away from balance control scientific barrier to improving prognostic tools, preventive strategies, and interventions for balance impairments is that we lack an understanding of how and when cortical resources are engaged in balance control, particularly with balance task difficulty. An innovation of our proposal is to identify direct, mechanistic measures of cortical activity during reactive balance. We will combine MPI Tingâs expertise in the neuromechanics of reactive balance control and MPI Borichâs expertise in human electrophysiology to identify relationships between brain activity and motor function to improve stroke rehabilitation. Our objective is to identify cortical activity signatures that distinguish individual-, task-, and group-level differences in the engagement of cortical resources for balance control amongst young adults (Aim 1), older adults (Aim 2), and older adults with unilateral cortical lesions due to stroke (Aim 3). We will measure electroencephalographic (EEG), electromyographic (EMG), and biomechanical signals during reactive balance recovery to support-surface translations. We propose to use both clinically feasible electrode-based analysis approaches, as well as mechanistically-important anatomically informed functional analyses using high-density EEG in combination with structural and functional MRI scans. We hypothesize that cortical activity signatures during balance control increase in an individual-, age-, and disease-specific manner as balance task difficulty increases. Within groups, we predict individual variability in cortical activity to be explained by balance challenge, i.e., balance task difficulty normalized to step threshold, a measure of balance function. However, between groups, we predict cortical activity signatures and their relation to balance challenge will differ. Aims are motivated by preliminary EEG data during reactive balance showing in 1) young adults, cortical activity is localized over leg sensorimotor cortical regions and increases with balance task difficulty; 2) older adults, cortical activity is distributed over frontal cortical regions and is engaged at lower balance task difficulty than in young adults; and 3) stroke survivors, slowed cortical activity is associated with greater post-stroke gait impairment and distributed over frontal cortical regions in the contralesional hemisphere If successful, we will identify neurophysiological indicators of balance health that will be broadly applicable across the lifespan, and across neurological and orthopedic balance disorders to significantly advance the necessary scientific framework to enable precision-medicine strategies for personalized, mechanistic assessments and interventions to improve quality of life those with poor balance health.
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