Complementary mechanisms for upright balance during walking

Lateral balance is a critical factor in keeping the human body upright during walking. Two important mechanisms for balance control are the stepping strategy, in which the foot placement is changed in the direction of a sensed fall to modulate how the gravitational force acts on the body, and the la...

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Published inPLOS ONE Vol. 12; no. 2; p. e0172215
Main Authors Reimann, Hendrik, Fettrow, Tyler D., Thompson, Elizabeth D., Agada, Peter, McFadyen, Bradford J., Jeka, John J.
Format Journal Article
LanguageEnglish
Published United States Public Library of Science (PLoS) 24.02.2017
Public Library of Science
Subjects
Adult
Adults
Ankle
Ankle - physiology
Ankle Joint
Ankle Joint - physiology
Balance
Biology and Life Sciences
Biomechanical Phenomena
Biomechanics
Body mass
Brain research
Center of pressure
Diagnosis
Feet
Female
Foot
Foot - physiology
Gait
Gait - physiology
Gravity
Humans
Kinematics
Kinesiology
Lateral stability
Locomotion
Locomotion - physiology
Male
Medicine
Medicine and Health Sciences
Movement
Movement disorders
Neurological diseases
Older people
Physical Sciences
Physiological aspects
Physiology
Placement
Postural Balance
Posture
Posture - physiology
Q
R
Research and Analysis Methods
Research Article
Robotics
Science
Strategy
Torque
Vestibular system
Walking
Young Adult
Canada
United States > US
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Summary:Lateral balance is a critical factor in keeping the human body upright during walking. Two important mechanisms for balance control are the stepping strategy, in which the foot placement is changed in the direction of a sensed fall to modulate how the gravitational force acts on the body, and the lateral ankle strategy, in which the body mass is actively accelerated by an ankle torque. Currently, there is minimal evidence about how these two strategies complement one another to achieve upright balance during locomotion. We use Galvanic vestibular stimulation (GVS) to induce the sensation of a fall at heel-off during gait initiation. We found that young healthy adults respond to the illusory fall using both the lateral ankle strategy and the stepping strategy. The stance foot center of pressure (CoP) is shifted in the direction of the perceived fall by ≈2.5 mm, starting ≈247 ms after stimulus onset. The foot placement of the following step is shifted by ≈15 mm in the same direction. The temporal delay between these two mechanisms suggests that they independently contribute to upright balance during locomotion, potentially in a serially coordinated manner. Modeling results indicate that without the lateral ankle strategy, a much larger step width is required to maintain upright balance, suggesting that the small but early CoP shift induced by the lateral ankle strategy is critical for upright stability during locomotion. The relative importance of each mechanism and how neurological disorders may affect their implementation remain an open question.
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Competing Interests: The authors have declared that no competing interests exist.
Conceptualization: HR EDT PA JJJ.Data curation: HR TDF.Formal analysis: HR TDF.Funding acquisition: HR JJJ.Investigation: HR TDF.Methodology: HR EDT PA JJJ.Project administration: JJJ.Resources: JJJ.Software: HR PA.Supervision: HR BJM JJJ.Validation: HR TDF.Visualization: HR.Writing – original draft: HR.Writing – review & editing: HR TDF BJM JJJ.
ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0172215