Control of Upright Stance over Inclined Surfaces

Overview

Journal Exp Brain Res

Specialty Neurology

Date 2007 Feb 7

PMID 17279384

Citations 21

Authors

Rinaldo Andre Mezzarane

Andre Fabio Kohn

Affiliations

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Abstract

The present work investigated the control of upright posture on inclined surfaces (14 degrees). Such conditions could, for example, change the contributions of muscle spindles resulting in alterations in postural sway. Subjects stood in quiet stance over a force platform positioned in one of three different fixed positions: horizontal (H), toes-up (ankle dorsi-flexion, D) and toes-down (ankle plantar-flexion, P). The experiments were done in the presence and also in the absence of vision. The analysis of the resulting sway was based on the power spectrum of the center of pressure displacement in the anterior-posterior direction (CP_ap). Analysis of the electromyogram (EMG) of the leg muscles and evaluation of the level of presynaptic inhibition (PSI) of the soleus (SO) Ia afferents complemented the study. The results showed that the spectrum of the CP_ap changed with the inclination of the surface of support. In condition D a higher instability was found as reflected by the higher spectral amplitudes at lower frequencies (below 0.3 Hz). On the other hand, the CP_ap of subjects in condition P contained increased amplitudes at high frequencies (above 0.3 Hz) and smaller amplitudes at low frequencies. The modifications found in the CP_ap power spectra when standing over an inclined surface may indicate changes in both short-term and long-term systems of postural control. These results do not seem to be associated with changes in group Ia feedback gain since no changes in the level of PSI were found among the three standing conditions. The SO EMG increased in condition P but did not change in condition D. On the other hand, the tibialis anterior had a tendency towards increased bursting activity in condition D. Eye closure caused an increase in the power of the oscillations at all spectral frequencies in the three standing conditions (H, P or D) and also a change in the profile of the CP_ap power spectrum. This may suggest a nonlinearity in the postural control system. The control of the slow component of the postural sway was more dependent on vision when the subject was in condition D, probably in association with the biomechanical constraints of standing on a toes-up ramp. A conclusion of this work was that, depending on the postural demand (direction of the ramp of support), the ensuing proprioceptive and biomechanical changes affect differentially the fast and slow mechanisms of balance control.

Citing Articles

Effect of forward and backward sloped support surfaces on postural equilibrium and ankle muscles activity.

Atsawakaewmongkhon S, Couillandre A, Hamaoui A PLoS One. 2024; 19(6):e0305840.

PMID: 38935639 PMC: 11210767. DOI: 10.1371/journal.pone.0305840.

Effect of Vision and Surface Slope on Postural Sway in Healthy Adults: A Prospective Cohort Study.

Aghapour M, Affenzeller N, Peham C, Lutonsky C, Tichy A, Bockstahler B Life (Basel). 2024; 14(2).

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Does vibration frequency and location influence the effect of neck muscle vibration on postural sway? A cross-sectional study in asymptomatic participants.

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PMID: 37552270 DOI: 10.1007/s00221-023-06680-z.

Effects of voluntary contraction on the soleus H-reflex of different amplitudes in healthy young adults and in the elderly.

Batista-Ferreira L, Rabelo N, da Cruz G, Costa J, Elias L, Mezzarane R Front Hum Neurosci. 2023; 16:1039242.

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No Difference in the Acute Effects of Randomization vs. Blocking of Units of Lower-Extremity Proprioceptive Training on Balance and Postural Control in Young Healthy Male Adults.

Ivusza P, Hortobagyi T, Sebesi B, Gaspar B, Fesus A, Varga M Front Physiol. 2022; 13:824651.

PMID: 35557968 PMC: 9086394. DOI: 10.3389/fphys.2022.824651.

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