4.5 Article

Functional Near-infrared Spectroscopy Reveals the Compensatory Potential of Pre-frontal Cortical Activity for Standing Balance in Young and Older Adults

Journal

NEUROSCIENCE
Volume 452, Issue -, Pages 208-218

Publisher

PERGAMON-ELSEVIER SCIENCE LTD
DOI: 10.1016/j.neuroscience.2020.10.027

Keywords

balance; ageing; sensorimotor control; cognitive demands; compensation hypothesis; fNIRS

Categories

Funding

  1. National Health and Medical Research Council of Australia [GNT1036234, APP1135761]
  2. Australian Research Council [FT150101406]

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The study found that older adults exhibit a limit to PFC activity and increased postural sway at higher levels of balance task demand, while younger adults perform better under similar conditions. This suggests that PFC activity compensates for sensorimotor deficits in older adults to maintain stability, but reaches a cognitive resource limit in easier balance tasks compared to younger adults. Increasing cortical capacity in older people may improve their balance.
Recent evidence suggests increased activity of the pre-frontal cortex (PFC) is associated with sensorimotor disturbances of standing balance. Here we manipulate sensorimotor inputs and concurrently load cognitive resources in order to investigate the functional role of PFC activity during standing balance, and how this changes with healthy ageing. Healthy younger (n = 24; mean age = 20.8 years) and older (n = 25; mean age = 70.6 years) adults maintained balance while sensorimotor inputs were manipulated by removing vision, reducing the base of support, and reducing proprioceptive feedback. To load cognitive resources, each balance condition was undertaken alone or simultaneously with a cognitive task (dual-task). Functional near infrared spectroscopy (fNIRS) measured PFC activity and a force-plate measured postural sway. When comparing dual-tasks relative to single balance tasks (dual-task effect), at lower levels of balance task demand, the older adults exhibited increased PFC activity and similar levels of postural sway. However, at higher levels of balance task demand, a limit to PFC activity was observed and postural sway became more unstable in older adults. In contrast, for younger adults at higher levels of balance task demand, the dual-task effect resulted in an increase in PFC activity and postural sway was not unduly affected. These results suggest that PFC activity is compensating for sensorimotor deficits to maintain stability, and that a cognitive resource limit is reached for easier balance tasks in older people compared to younger people. These results suggest that increasing cortical capacity in older people may improve their balance. (C) 2020 IBRO. Published by Elsevier Ltd. All rights reserved.

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