Absence of Nonlinear Coupling Between Electric Vestibular Stimulation and Evoked Forces During Standing Balance

• Published in: Frontiers in human neuroscience Vol. 15; p. 631782
• Main Authors: Hannan, Kelci B., Todd, Makina K., Pearson, Nicole J., Forbes, Patrick A., Dakin, Christopher J.
• Format: Journal Article
• Language: English
• Published: Switzerland Frontiers Research Foundation 25.03.2021; Frontiers Media S.A
• Subjects: Balance; Bandwidths; Confidence intervals; coupling; electric vestibular stimulation; galvanic vestibular stimulation; Headspace; linearity; Neuroscience; Noise; Posture; Questionnaires; random waveform; Research methodology; vestibular; Vestibular system; Wavelet transforms; coupling; linearity; cross-frequency coupling; electric vestibular stimulation; random waveform; galvanic vestibular stimulation; vestibular
• ISSN: 1662-5161; 1662-5161
• DOI: 10.3389/fnhum.2021.631782

The vestibular system encodes motion and orientation of the head in space and is essential for negotiating in and interacting with the world. Recently, random waveform electric vestibular stimulation has become an increasingly common means of probing the vestibular system. However, many of the methods used to analyze the behavioral response to this type of stimulation assume a linear relationship between frequencies in the stimulus and its associated response. Here we examine this stimulus-response frequency linearity to determine the validity of this assumption. Forty-five university-aged subjects stood on a force-plate for 4 min while receiving vestibular stimulation. To determine the linearity of the stimulus-response relationship we calculated the cross-frequency power coupling between a 0 and 25 Hz bandwidth limited white noise stimulus and induced postural responses, as measured using the horizontal forces acting at the feet. Ultimately, we found that, on average, the postural response to a random stimulus is linear across stimulation frequencies. This result supports the use of analysis methods that depend on the assumption of stimulus-response frequency linearity, such as coherence and gain, which are commonly used to analyze the body’s response to random waveform electric stimuli.