Neural Mechanisms and Functional Correlates of Altered Postural Responses to Perturbed Standing Balance with Chronic Low Back Pain

Overview

Journal Neuroscience

Specialty Neurology

Date 2016 Nov 6

PMID 27771534

Citations 14

Authors

Jesse V Jacobs

Carrie L Roy

Juvena R Hitt

Roman E Popov

Sharon M Henry

Affiliations

Soon will be listed here.

Abstract

This study sought to determine the effects of chronic low back pain (LBP) on the cortical evoked potentials, muscle activation, and kinematics of postural responses to perturbations of standing balance. Thirteen subjects with chronic, recurrent, non-specific LBP and 13 subjects without LBP participated. The subjects responded to unpredictably timed postural perturbations while standing on a platform that randomly rotated either "toes up" or "toes down". Electroencephalography (EEG) was used to calculate the negative peak (N1) and subsequent positive peak (P2) amplitudes of the perturbation-evoked cortical potentials. Passive-marker motion capture was used to calculate joint and center-of-mass (CoM) displacements. Surface electromyography was used to record muscle onset latencies. Questionnaires assessed pain, interference with activity, fear of activity, and pain catastrophizing. Results demonstrated that subjects with LBP exhibited significantly larger P2 potentials, delayed erector spinae, rectus abdominae, and external oblique onset latencies, as well as smaller trunk extension yet larger trunk flexion, knee flexion, and ankle dorsiflexion displacements compared to subjects without LBP. For the subjects with LBP, CoM displacements significantly and positively correlated with knee displacements as well as activity interference and fear scores. The P2 potentials significantly and negatively correlated with CoM displacements as well as activity interference, catastrophizing, and fear scores. These results demonstrate that people with LBP exhibit altered late-phase cortical processing of postural perturbations concomitant with altered kinematic and muscle responses, and these cortical and postural response characteristics correlate with each other as well as with clinical reports of pain-related fears and activity interference.

Citing Articles

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Measurement properties of 72 movement biomarkers aiming to discriminate non‑specific chronic low back pain patients from an asymptomatic population.

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Changes in cortical activation during upright stance in individuals with chronic low back pain: An fNIRS study.

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The association of fear of movement and postural sway in people with low back pain.

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Mobile Brain Imaging to Examine Task-Related Cortical Correlates of Reactive Balance: A Systematic Review.

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