Preventing Falls in Older Adults: New Interventions to Promote More Effective Change-in-support Balance Reactions

Overview

Journal J Electromyogr Kinesiol

Publisher Elsevier

Specialty Physiology

Date 2007 Sep 4

PMID 17766146

Citations 37

Authors

Brian E Maki

Kenneth C-C Cheng

Avril Mansfield

Carol Y Scovil

Stephen D Perry

Amy L Peters

Sandra McKay

Tracy Lee

Aaron Marquis

Philippe Corbeil

Geoff R Fernie

Barbara Liu

William E McIlroy

Affiliations

Soon will be listed here.

Abstract

"Change-in-support" (CIS) balance-recovery reactions that involve rapid stepping or reaching movements play a critical role in preventing falls; however, age-related deficits in the neuro-musculoskeletal systems may impede ability to execute these reactions effectively. This review describes four new interventions aimed at reducing fall risk in older adults by promoting more effective CIS reactions: (1) balance training, (2) balance-enhancing footwear, (3) safer mobility aids, and (4) handrail cueing systems. The training program uses unpredictable support-surface perturbations to counter specific CIS control problems associated with aging and fall risk. Pilot testing has demonstrated that the program is well-tolerated by balance-impaired older adults, and a randomized controlled trial is now in progress. The balance-enhancing footwear insole improves control of stepping reactions by compensating for age-related loss of plantar cutaneous sensation. In a clinical trial, subjects wore the insole for 12 weeks with no serious problems and no habituation of the balance-enhancing benefits. The mobility-aid intervention involves changes to the design of pickup walkers so as to reduce impediments to lateral stepping. Finally, work is underway to investigate the effectiveness of handrail cueing in attracting attention to the rail and ensuring that the brain registers its location, thereby facilitating more rapid and accurate grasping.

Citing Articles

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The suppression of lower leg electromyography when walking in textured foot orthoses.

Robb K, Perry S Exp Brain Res. 2024; 242(10):2367-2380.

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Multimodal training protocols on unstable rather than stable surfaces better improve dynamic balance ability in older adults.

Rizzato A, Bozzato M, Rotundo L, Zullo G, De Vito G, Paoli A Eur Rev Aging Phys Act. 2024; 21(1):19.

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Reduced adaptability to balance perturbations in older adults with probable cognitive impairment after a severe fall.

Voss M, Zieschang T, Schmidt L, Hackbarth M, Koschate J, Stuckenschneider T PLoS One. 2024; 19(7):e0305067.

PMID: 38985810 PMC: 11236103. DOI: 10.1371/journal.pone.0305067.

Training Postural Balance Control with Pelvic Force Field at the Boundary of Stability.

Omofuma I, Santamaria V, Ai X, Agrawal S Bioengineering (Basel). 2023; 10(12).

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