Characterizing the limits of human stability during motion: perturbative experiment validates a model-based approach for the Sit-to-Stand task

Characterizing the limits of human stability during motion: perturbative experiment validates a model-based approach for the Sit-to-Stand task

Falls affect a growing number of the population each year. Clinical methods to assess fall risk usually evaluate the performance of specific motions such as balancing or Sit-to-Stand. Unfortunately, these techniques have been shown to have poor predictive power, and are unable to identify the portio...

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Bibliographic Details
Published in:Royal Society open science Vol. 7; no. 1; p. 191410
Main Authors: Holmes, Patrick D, Danforth, Shannon M, Fu, Xiao-Yu, Moore, Talia Y, Vasudevan, Ram
Format: Journal Article
Language:English
Published: England The Royal Society 01-01-2020
Subjects:
biomechanics
fall risk
feedback control
locomotion
mathematical model
Organismal and Evolutionary Biology
reachability
mathematical model
biomechanics
reachability
fall risk
feedback control
locomotion
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Summary:Falls affect a growing number of the population each year. Clinical methods to assess fall risk usually evaluate the performance of specific motions such as balancing or Sit-to-Stand. Unfortunately, these techniques have been shown to have poor predictive power, and are unable to identify the portions of motion that are most unstable. To this end, it may be useful to identify the set of body configurations that can accomplish a task under a specified control strategy. The resulting strategy-specific boundary between stable and unstable motion could be used to identify individuals at risk of falling. The recently proposed Stability Basin is defined as the set of configurations through time that do not lead to failure for an individual under their chosen control strategy. This paper presents a novel method to compute the Stability Basin and the first experimental validation of the Stability Basin with a perturbative Sit-to-Stand experiment involving forwards or backwards pulls from a motor-driven cable with 11 subjects. The individually-constructed Stability Basins are used to identify when a trial fails, i.e. when an individual must switch from their chosen control strategy (indicated by a step or sit) to recover from a perturbation. The constructed Stability Basins correctly predict the outcome of trials where failure was observed with over accuracy, and correctly predict the outcome of successful trials with over accuracy. The Stability Basin was compared to three other methods and was found to estimate the stable region with over more accuracy in all cases. This study demonstrates that Stability Basins offer a novel model-based approach for quantifying stability during motion, which could be used in physical therapy for individuals at risk of falling.
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Electronic supplementary material is available online at https://doi.org/10.6084/m9.figshare.c.4796289.
ISSN:2054-5703
2054-5703
DOI:10.1098/rsos.191410