Adaptation effects in static postural control by providing simultaneous visual feedback of center of pressure and center of gravity

BACKGROUND: The benefit of visual feedback of the center of pressure (COP) on quiet standing is still debatable. This study aimed to investigate the adaptation effects of visual feedback training using both the COP and center of gravity (COG) during quiet standing. METHODS: Thirty-four healthy young...

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Autores principales: Takeda, Kenta, Mani, Hiroki, Hasegawa, Naoya, Sato, Yuki, Tanaka, Shintaro, Maejima, Hiroshi, Asaka, Tadayoshi
Formato: Online Artículo Texto
Lenguaje:English
Publicado: BioMed Central 2017
Materias:
Original Article
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5518099/
https://www.ncbi.nlm.nih.gov/pubmed/28724444
http://dx.doi.org/10.1186/s40101-017-0147-5
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author Takeda, Kenta
Mani, Hiroki
Hasegawa, Naoya
Sato, Yuki
Tanaka, Shintaro
Maejima, Hiroshi
Asaka, Tadayoshi
author_facet Takeda, Kenta
Mani, Hiroki
Hasegawa, Naoya
Sato, Yuki
Tanaka, Shintaro
Maejima, Hiroshi
Asaka, Tadayoshi
author_sort Takeda, Kenta
collection PubMed
description BACKGROUND: The benefit of visual feedback of the center of pressure (COP) on quiet standing is still debatable. This study aimed to investigate the adaptation effects of visual feedback training using both the COP and center of gravity (COG) during quiet standing. METHODS: Thirty-four healthy young adults were divided into three groups randomly (COP + COG, COP, and control groups). A force plate was used to calculate the coordinates of the COP in the anteroposterior (COP(AP)) and mediolateral (COP(ML)) directions. A motion analysis system was used to calculate the coordinates of the center of mass (COM) in both directions (COM(AP) and COM(ML)). The coordinates of the COG in the AP direction (COG(AP)) were obtained from the force plate signals. Augmented visual feedback was presented on a screen in the form of fluctuation circles in the vertical direction that moved upward as the COP(AP) and/or COG(AP) moved forward and vice versa. The COP + COG group received the real-time COP(AP) and COG(AP) feedback simultaneously, whereas the COP group received the real-time COP(AP) feedback only. The control group received no visual feedback. In the training session, the COP + COG group was required to maintain an even distance between the COP(AP) and COG(AP) and reduce the COG(AP) fluctuation, whereas the COP group was required to reduce the COP(AP) fluctuation while standing on a foam pad. In test sessions, participants were instructed to keep their standing posture as quiet as possible on the foam pad before (pre-session) and after (post-session) the training sessions. RESULTS: In the post-session, the velocity and root mean square of COM(AP) in the COP + COG group were lower than those in the control group. In addition, the absolute value of the sum of the COP − COM distances in the COP + COG group was lower than that in the COP group. Furthermore, positive correlations were found between the COM(AP) velocity and COP − COM parameters. CONCLUSIONS: The results suggest that the novel visual feedback training that incorporates the COP(AP)–COG(AP) interaction reduces postural sway better than the training using the COP(AP) alone during quiet standing. That is, even COP(AP) fluctuation around the COG(AP) would be effective in reducing the COM(AP) velocity.
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spelling pubmed-55180992017-08-16 Adaptation effects in static postural control by providing simultaneous visual feedback of center of pressure and center of gravity Takeda, Kenta Mani, Hiroki Hasegawa, Naoya Sato, Yuki Tanaka, Shintaro Maejima, Hiroshi Asaka, Tadayoshi J Physiol Anthropol Original Article BACKGROUND: The benefit of visual feedback of the center of pressure (COP) on quiet standing is still debatable. This study aimed to investigate the adaptation effects of visual feedback training using both the COP and center of gravity (COG) during quiet standing. METHODS: Thirty-four healthy young adults were divided into three groups randomly (COP + COG, COP, and control groups). A force plate was used to calculate the coordinates of the COP in the anteroposterior (COP(AP)) and mediolateral (COP(ML)) directions. A motion analysis system was used to calculate the coordinates of the center of mass (COM) in both directions (COM(AP) and COM(ML)). The coordinates of the COG in the AP direction (COG(AP)) were obtained from the force plate signals. Augmented visual feedback was presented on a screen in the form of fluctuation circles in the vertical direction that moved upward as the COP(AP) and/or COG(AP) moved forward and vice versa. The COP + COG group received the real-time COP(AP) and COG(AP) feedback simultaneously, whereas the COP group received the real-time COP(AP) feedback only. The control group received no visual feedback. In the training session, the COP + COG group was required to maintain an even distance between the COP(AP) and COG(AP) and reduce the COG(AP) fluctuation, whereas the COP group was required to reduce the COP(AP) fluctuation while standing on a foam pad. In test sessions, participants were instructed to keep their standing posture as quiet as possible on the foam pad before (pre-session) and after (post-session) the training sessions. RESULTS: In the post-session, the velocity and root mean square of COM(AP) in the COP + COG group were lower than those in the control group. In addition, the absolute value of the sum of the COP − COM distances in the COP + COG group was lower than that in the COP group. Furthermore, positive correlations were found between the COM(AP) velocity and COP − COM parameters. CONCLUSIONS: The results suggest that the novel visual feedback training that incorporates the COP(AP)–COG(AP) interaction reduces postural sway better than the training using the COP(AP) alone during quiet standing. That is, even COP(AP) fluctuation around the COG(AP) would be effective in reducing the COM(AP) velocity. BioMed Central 2017-07-19 /pmc/articles/PMC5518099/ /pubmed/28724444 http://dx.doi.org/10.1186/s40101-017-0147-5 Text en © The Author(s). 2017 Open AccessThis article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The Creative Commons Public Domain Dedication waiver (http://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated.
spellingShingle Original Article
Takeda, Kenta
Mani, Hiroki
Hasegawa, Naoya
Sato, Yuki
Tanaka, Shintaro
Maejima, Hiroshi
Asaka, Tadayoshi
Adaptation effects in static postural control by providing simultaneous visual feedback of center of pressure and center of gravity
title Adaptation effects in static postural control by providing simultaneous visual feedback of center of pressure and center of gravity
title_full Adaptation effects in static postural control by providing simultaneous visual feedback of center of pressure and center of gravity
title_fullStr Adaptation effects in static postural control by providing simultaneous visual feedback of center of pressure and center of gravity
title_full_unstemmed Adaptation effects in static postural control by providing simultaneous visual feedback of center of pressure and center of gravity
title_short Adaptation effects in static postural control by providing simultaneous visual feedback of center of pressure and center of gravity
title_sort adaptation effects in static postural control by providing simultaneous visual feedback of center of pressure and center of gravity
topic Original Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5518099/
https://www.ncbi.nlm.nih.gov/pubmed/28724444
http://dx.doi.org/10.1186/s40101-017-0147-5
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