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Literature DB >> 11600329

The translating platform paradigm: perturbation displacement waveform alters the postural response.

L A Brown¹, J L Jensen, T Korff, M H Woollacott.

Abstract

The translating platform paradigm is widely used to investigate the regulation of upright standing and locomotion. This study investigated how the displacement waveform characteristics underlying the translating platform perturbation are revealed in the resulting postural response. Eight participants experienced a series of backward-directed perturbations using a hydraulically driven forceplate. Two ranges of platform displacement (5 and 15 cm) in combination with two peak velocities (40 and 60 cm/s) were achieved using three distinct waveforms for platform displacement: (a) RAMP: ramp onset and ramp offset, (b) Ramp-to-Parabola (R-P): ramp onset with parabolic offset and (c) SINE: sine-wave onset with sine wave offset. Our findings indicated that the unique and distinctive acceleration and deceleration characteristics that result from the three different platform displacement waveforms significantly altered the postural response to the perturbation.

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Year: 2001 PMID： 11600329 DOI： 10.1016/s0966-6362(01)00131-x

Source DB: PubMed Journal: Gait Posture ISSN： 0966-6362 Impact factor: 2.840

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Cited

15 in total

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3. Deceleration affects anticipatory and reactive components of triggered postural responses.

Authors: Mark G Carpenter; Alf Thorstensson; Andrew G Cresswell
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4. Scaling of plantarflexor muscle activity and postural time-to-contact in response to upper-body perturbations in young and older adults.

Authors: Christopher J Hasson; Graham E Caldwell; Richard E A Van Emmerik
Journal: Exp Brain Res Date: 2009-06-06 Impact factor: 1.972

5. A feedback model explains the differential scaling of human postural responses to perturbation acceleration and velocity.

Authors: Torrence D J Welch; Lena H Ting
Journal: J Neurophysiol Date: 2009-04-08 Impact factor: 2.714

10. Dynamic Neuromuscular Control of the Lower Limbs in Response to Unexpected Single-Planar versus Multi-Planar Support Perturbations in Young, Active Adults.

Authors: Bart Malfait; Filip Staes; Aijse de Vries; Annemie Smeets; Malcolm Hawken; Mark A Robinson; Jos Vanrenterghem; Sabine Verschueren
Journal: PLoS One Date: 2015-07-29 Impact factor: 3.240

The translating platform paradigm: perturbation displacement waveform alters the postural response.

1. Task-level feedback can explain temporal recruitment of spatially fixed muscle synergies throughout postural perturbations.

2. Adaptive changes in postural strategy selection in chronic low back pain.

3. Deceleration affects anticipatory and reactive components of triggered postural responses.

4. Scaling of plantarflexor muscle activity and postural time-to-contact in response to upper-body perturbations in young and older adults.

5. A feedback model explains the differential scaling of human postural responses to perturbation acceleration and velocity.

6. Anticipatory control of impending postural perturbation in elite springboard divers.

Review 7. Reactive Balance Responses After Mild Traumatic Brain Injury: A Scoping Review.

8. Ankle dorsiflexor strength relates to the ability to restore balance during a backward support surface translation.

9. Effect of lateral perturbations on psychophysical acceleration detection thresholds.

10. Dynamic Neuromuscular Control of the Lower Limbs in Response to Unexpected Single-Planar versus Multi-Planar Support Perturbations in Young, Active Adults.