Speed-related spinal excitation from ankle dorsiflexors to knee extensors during human walking

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Speed-related spinal excitation from ankle dorsiflexors to knee extensors during human walking. / Iglesias, Caroline; Nielsen, Jens Bo; Marchand-Pauvert, Véronique.

In: Experimental Brain Research, Vol. 188, No. 1, 2008, p. 101-110.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Iglesias, C, Nielsen, JB & Marchand-Pauvert, V 2008, 'Speed-related spinal excitation from ankle dorsiflexors to knee extensors during human walking', Experimental Brain Research, vol. 188, no. 1, pp. 101-110. https://doi.org/10.1007/s00221-008-1344-6

APA

Iglesias, C., Nielsen, J. B., & Marchand-Pauvert, V. (2008). Speed-related spinal excitation from ankle dorsiflexors to knee extensors during human walking. Experimental Brain Research, 188(1), 101-110. https://doi.org/10.1007/s00221-008-1344-6

Vancouver

Iglesias C, Nielsen JB, Marchand-Pauvert V. Speed-related spinal excitation from ankle dorsiflexors to knee extensors during human walking. Experimental Brain Research. 2008;188(1):101-110. https://doi.org/10.1007/s00221-008-1344-6

Author

Iglesias, Caroline ; Nielsen, Jens Bo ; Marchand-Pauvert, Véronique. / Speed-related spinal excitation from ankle dorsiflexors to knee extensors during human walking. In: Experimental Brain Research. 2008 ; Vol. 188, No. 1. pp. 101-110.

Bibtex

@article{ffe475b02d5711ddb7b4000ea68e967b,
title = "Speed-related spinal excitation from ankle dorsiflexors to knee extensors during human walking",
abstract = "Automatic adjustments of muscle activity throughout the body are required for the maintenance of balance during human walking. One mechanism that is likely to contribute to this control is the heteronymous spinal excitation between human ankle dorsiflexors and knee extensors (CPQ-reflex). Here, we investigated the CPQ-reflex at different walking speeds (1-6 km/h) and stride frequencies (0.6-1.3 Hz) in healthy human subjects to provide further evidence of its modulation, and its role in ensuring postural stability during walking. The CPQ-reflex was small or absent at walking speeds below 2-3 km/h, then increased with walking speeds about 3-4 km/h, and reached a plateau without any further change at walking speeds from 4 to 6 km/h. The reflex showed no modulation when the stride cycle was varied at constant speed (4 km/h; short steps versus long steps). These changes were unlikely to be only caused by changes in the background EMG activity and modifications in peripheral input, and likely reflected central modulation of transmission in the involved reflex pathways as well. It is suggested that the purpose of the reflex is to ensure knee stability at moderate-to-high walking speeds.",
author = "Caroline Iglesias and Nielsen, {Jens Bo} and V{\'e}ronique Marchand-Pauvert",
note = "CURIS 2008 5200 048",
year = "2008",
doi = "10.1007/s00221-008-1344-6",
language = "English",
volume = "188",
pages = "101--110",
journal = "Experimental Brain Research",
issn = "0014-4819",
publisher = "Springer",
number = "1",

}

RIS

TY - JOUR

T1 - Speed-related spinal excitation from ankle dorsiflexors to knee extensors during human walking

AU - Iglesias, Caroline

AU - Nielsen, Jens Bo

AU - Marchand-Pauvert, Véronique

N1 - CURIS 2008 5200 048

PY - 2008

Y1 - 2008

N2 - Automatic adjustments of muscle activity throughout the body are required for the maintenance of balance during human walking. One mechanism that is likely to contribute to this control is the heteronymous spinal excitation between human ankle dorsiflexors and knee extensors (CPQ-reflex). Here, we investigated the CPQ-reflex at different walking speeds (1-6 km/h) and stride frequencies (0.6-1.3 Hz) in healthy human subjects to provide further evidence of its modulation, and its role in ensuring postural stability during walking. The CPQ-reflex was small or absent at walking speeds below 2-3 km/h, then increased with walking speeds about 3-4 km/h, and reached a plateau without any further change at walking speeds from 4 to 6 km/h. The reflex showed no modulation when the stride cycle was varied at constant speed (4 km/h; short steps versus long steps). These changes were unlikely to be only caused by changes in the background EMG activity and modifications in peripheral input, and likely reflected central modulation of transmission in the involved reflex pathways as well. It is suggested that the purpose of the reflex is to ensure knee stability at moderate-to-high walking speeds.

AB - Automatic adjustments of muscle activity throughout the body are required for the maintenance of balance during human walking. One mechanism that is likely to contribute to this control is the heteronymous spinal excitation between human ankle dorsiflexors and knee extensors (CPQ-reflex). Here, we investigated the CPQ-reflex at different walking speeds (1-6 km/h) and stride frequencies (0.6-1.3 Hz) in healthy human subjects to provide further evidence of its modulation, and its role in ensuring postural stability during walking. The CPQ-reflex was small or absent at walking speeds below 2-3 km/h, then increased with walking speeds about 3-4 km/h, and reached a plateau without any further change at walking speeds from 4 to 6 km/h. The reflex showed no modulation when the stride cycle was varied at constant speed (4 km/h; short steps versus long steps). These changes were unlikely to be only caused by changes in the background EMG activity and modifications in peripheral input, and likely reflected central modulation of transmission in the involved reflex pathways as well. It is suggested that the purpose of the reflex is to ensure knee stability at moderate-to-high walking speeds.

U2 - 10.1007/s00221-008-1344-6

DO - 10.1007/s00221-008-1344-6

M3 - Journal article

C2 - 18340438

VL - 188

SP - 101

EP - 110

JO - Experimental Brain Research

JF - Experimental Brain Research

SN - 0014-4819

IS - 1

ER -

ID: 4262088