The Effects of Constraining Head Rotation on Eye and Whole-Body Coordination During Standing Turns at Different Speeds
Issued Date
2022-10-01
Resource Type
ISSN
10658483
eISSN
15432688
Scopus ID
2-s2.0-85138496225
Pubmed ID
35977716
Journal Title
Journal of Applied Biomechanics
Volume
38
Issue
5
Start Page
301
End Page
311
Rights Holder(s)
SCOPUS
Bibliographic Citation
Journal of Applied Biomechanics Vol.38 No.5 (2022) , 301-311
Suggested Citation
Hollands M., Khobkhun F., Ajjimaporn A., Robins R., Richards J. The Effects of Constraining Head Rotation on Eye and Whole-Body Coordination During Standing Turns at Different Speeds. Journal of Applied Biomechanics Vol.38 No.5 (2022) , 301-311. 311. doi:10.1123/jab.2021-0117 Retrieved from: https://repository.li.mahidol.ac.th/handle/20.500.14594/85495
Title
The Effects of Constraining Head Rotation on Eye and Whole-Body Coordination During Standing Turns at Different Speeds
Author(s)
Other Contributor(s)
Abstract
A limitation of the ability to rotate the head with respect to the upper body has been associated with turning problems; however, the extent of head constraints on whole-body coordination has not been fully determined. The aim of this study was to limit head on body rotation and observe the effects on whole-body coordination during standing turns at various speeds. Twelve participants completed standing turns at 180°. A Vicon motion system and a BlueGain Electrooculography system were used to record movement kinematics and measure horizontal eye movements, respectively. All participants were tested at 3 randomized speeds, and under 2 conditions with or without their head constrained using a head, neck, and chest brace which restricted neck movement. A repeated-measures analysis of variance found a significant main effect of turning speed on the onset latency of all segments, peak head–thorax angular separation, and step characteristics. Constraining the head rotation had multiple significant effects including delayed onset latency and decreased intersegmental coordination defined as peak head segmental angular separations, increased total step and step duration, and decreased step size. This indicates the contribution of speed, head, and neck constraints, which have been associated with falls during turning and whole-body coordination.