Computational approach to assess postural tests under microgravity conditions

Computational approach to assess postural tests under microgravity conditions

Human vestibular system is extremely fragile and rapidly degrades when gravity is significantly lower than the gravity of Earth. Unfortunately, current balance assessment tools, including state-of-start computerized centre-of-mass measurement platforms, cannot be used in space because of the low gra...

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Main Authors: Brazovskii Konstantin, Fokin Vasilii, Tolmachev Ivan, Pekker Jacov, Hachaturyan David
Format: Article
Language:English
Published: EDP Sciences 2016-01-01
Series:MATEC Web of Conferences
Online Access:http://dx.doi.org/10.1051/matecconf/20164805001
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spelling doaj-9cc318e31bcb4e96804049a970e3a0302021-02-02T01:55:18ZengEDP SciencesMATEC Web of Conferences2261-236X2016-01-01480500110.1051/matecconf/20164805001matecconf_tomsk2016_05001Computational approach to assess postural tests under microgravity conditionsBrazovskii Konstantin0Fokin Vasilii1Tolmachev Ivan2Pekker Jacov3Hachaturyan David4National Research Tomsk Polytechnic UniversitySiberian State Medical UniversitySiberian State Medical UniversitySiberian State Medical UniversityNational Research Tomsk Polytechnic UniversityHuman vestibular system is extremely fragile and rapidly degrades when gravity is significantly lower than the gravity of Earth. Unfortunately, current balance assessment tools, including state-of-start computerized centre-of-mass measurement platforms, cannot be used in space because of the low gravity. Thus, a problem of developing new methods to assess postural stability under microgravity conditions is very important. This paper describes a distance-based criterion to estimate multidimensional measurements and its application for postural tests assessment. It has been shown that proposed criterion may be effectively used to estimate the equilibrium function by means of low-end hardware, which does not rely on the gravitational force. The criterion was compared against several known indexes and its ability to distinguish disorders of the balance has been studied.http://dx.doi.org/10.1051/matecconf/20164805001
collection DOAJ
language English
format Article
sources DOAJ
author Brazovskii Konstantin
Fokin Vasilii
Tolmachev Ivan
Pekker Jacov
Hachaturyan David
spellingShingle Brazovskii Konstantin
Fokin Vasilii
Tolmachev Ivan
Pekker Jacov
Hachaturyan David
Computational approach to assess postural tests under microgravity conditions
MATEC Web of Conferences
author_facet Brazovskii Konstantin
Fokin Vasilii
Tolmachev Ivan
Pekker Jacov
Hachaturyan David
author_sort Brazovskii Konstantin
title Computational approach to assess postural tests under microgravity conditions
title_short Computational approach to assess postural tests under microgravity conditions
title_full Computational approach to assess postural tests under microgravity conditions
title_fullStr Computational approach to assess postural tests under microgravity conditions
title_full_unstemmed Computational approach to assess postural tests under microgravity conditions
title_sort computational approach to assess postural tests under microgravity conditions
publisher EDP Sciences
series MATEC Web of Conferences
issn 2261-236X
publishDate 2016-01-01
description Human vestibular system is extremely fragile and rapidly degrades when gravity is significantly lower than the gravity of Earth. Unfortunately, current balance assessment tools, including state-of-start computerized centre-of-mass measurement platforms, cannot be used in space because of the low gravity. Thus, a problem of developing new methods to assess postural stability under microgravity conditions is very important. This paper describes a distance-based criterion to estimate multidimensional measurements and its application for postural tests assessment. It has been shown that proposed criterion may be effectively used to estimate the equilibrium function by means of low-end hardware, which does not rely on the gravitational force. The criterion was compared against several known indexes and its ability to distinguish disorders of the balance has been studied.
url http://dx.doi.org/10.1051/matecconf/20164805001
work_keys_str_mv AT brazovskiikonstantin computationalapproachtoassessposturaltestsundermicrogravityconditions
AT fokinvasilii computationalapproachtoassessposturaltestsundermicrogravityconditions
AT tolmachevivan computationalapproachtoassessposturaltestsundermicrogravityconditions
AT pekkerjacov computationalapproachtoassessposturaltestsundermicrogravityconditions
AT hachaturyandavid computationalapproachtoassessposturaltestsundermicrogravityconditions
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