TY - JOUR
T1 - Decreased Postural Complexity in Overweight to Obese Children and Adolescents
T2 - A Cross-Sectional Study
AU - Wiesinger, Hans-Peter
AU - Buchecker, Michael
AU - Mueller, Erich
AU - Stoeggl, Thomas
AU - Birklbauer, Jurgen
N1 - Wiesinger: Department of Sport and Exercise Science, University of Salzburg, Salzburg, Austria
PY - 2022/4/28
Y1 - 2022/4/28
N2 - IntroductionAlthough a few studies suggest that young overweight to obese children and adolescents (YO) may have impaired postural control compared to young normal-weight (YN) peers, little information exists about how these two groups differ in the quality of the underlying balance strategies employed. Hence, the aim of the present study was a first comprehensive examination of the structural complexity of postural sways in these two cohorts during quiet bilateral standing. MethodsNineteen YO secondary school students (13.0 +/- 1.4 years; male = 10, female = 9) were carefully matched to YN controls (13.0 +/- 1.5 years) for age, sex, height, and school. Mediolateral (ML) and anteriorposterior (AP) acceleration signals were recorded with an inertial measurement unit (IMU) positioned at the trunk while standing barefoot in two conditions: firm and foam support surface. The magnitude of postural fluctuations was obtained using the root mean square (RMS). The temporal structure of the signals was analyzed via sample entropy (SEn), largest Lyapunov exponent (LyE), and detrended fluctuation analysis (alpha-DFA) algorithm. Reliability was assessed using a test-retest design. ResultsIn both groups, foam standing caused higher postural fluctuations (higher RMS values) and reduced structural complexity (lower SEn values, higher LyE values, higher alpha-DFA values). In comparison to YN, YO exhibited a higher RMSAP. Especially in ML direction, the acceleration signals of the YO had higher repeatability (smaller SEn values), greater long-range correlations (higher alpha-DFA values), and lower local stability (higher LyE values). However, these observations were largely independent of the task difficulty. Except for alpha-DFA(AP), the IMU approach proved reliable to characterize posture control. DiscussionOur outcomes confirm postural control deficits in YO compared to their YN peers and indicate impaired regulatory mechanisms reflected as rigidity. Such less complex patterns usually reflect diverse pathologies, are detrimental to compensate for internal or external perturbations, and are attributed to lower adaptability and task performance. Without targeted balance stimuli, YO likely end in a lifelong vicious circle of mutually dependent poor balance regulation and low physical activity.
AB - IntroductionAlthough a few studies suggest that young overweight to obese children and adolescents (YO) may have impaired postural control compared to young normal-weight (YN) peers, little information exists about how these two groups differ in the quality of the underlying balance strategies employed. Hence, the aim of the present study was a first comprehensive examination of the structural complexity of postural sways in these two cohorts during quiet bilateral standing. MethodsNineteen YO secondary school students (13.0 +/- 1.4 years; male = 10, female = 9) were carefully matched to YN controls (13.0 +/- 1.5 years) for age, sex, height, and school. Mediolateral (ML) and anteriorposterior (AP) acceleration signals were recorded with an inertial measurement unit (IMU) positioned at the trunk while standing barefoot in two conditions: firm and foam support surface. The magnitude of postural fluctuations was obtained using the root mean square (RMS). The temporal structure of the signals was analyzed via sample entropy (SEn), largest Lyapunov exponent (LyE), and detrended fluctuation analysis (alpha-DFA) algorithm. Reliability was assessed using a test-retest design. ResultsIn both groups, foam standing caused higher postural fluctuations (higher RMS values) and reduced structural complexity (lower SEn values, higher LyE values, higher alpha-DFA values). In comparison to YN, YO exhibited a higher RMSAP. Especially in ML direction, the acceleration signals of the YO had higher repeatability (smaller SEn values), greater long-range correlations (higher alpha-DFA values), and lower local stability (higher LyE values). However, these observations were largely independent of the task difficulty. Except for alpha-DFA(AP), the IMU approach proved reliable to characterize posture control. DiscussionOur outcomes confirm postural control deficits in YO compared to their YN peers and indicate impaired regulatory mechanisms reflected as rigidity. Such less complex patterns usually reflect diverse pathologies, are detrimental to compensate for internal or external perturbations, and are attributed to lower adaptability and task performance. Without targeted balance stimuli, YO likely end in a lifelong vicious circle of mutually dependent poor balance regulation and low physical activity.
KW - Detrended fluctuation analysis
KW - Inertial measurement unit
KW - largest Lyapunov exponent
KW - Reproducibility
KW - Root mean square
KW - Sample entropy
UR - https://www.webofscience.com/api/gateway?GWVersion=2&SrcApp=pmu_pure&SrcAuth=WosAPI&KeyUT=WOS:000794511800001&DestLinkType=FullRecord&DestApp=WOS
U2 - 10.3389/fnhum.2022.850548
DO - 10.3389/fnhum.2022.850548
M3 - Original Article
C2 - 35572009
SN - 1662-5161
VL - 16
JO - FRONTIERS IN HUMAN NEUROSCIENCE
JF - FRONTIERS IN HUMAN NEUROSCIENCE
M1 - 850548
ER -