When “Noise” Isn’t Simply Noise: Deterministic Postural Drive During Noisy Galvanic Vestibular Stimulation (nGVS)
Dominique Rice, Kelci B. Hannan, Malynn Ewer, Christopher J DakinAge- and disease-related vestibular decline contributes to dizziness and postural instability, motivating interventions such as noisy galvanic vestibular stimulation (nGVS). nGVS is often applied at imperceptible amplitudes and interpreted through a stochastic resonance (SR) mechanism, but because galvanic stimulation directly modulates vestibular afferents, even imperceptible currents may deterministically influence balance. The present study tested whether low nGVS stimulus amplitudes (< 1mA), commonly used in stochastic resonance paradigms, directly drive postural behavior. Twenty healthy young adults stood on a force plate with feet together and eyes closed under two surface conditions (rigid and 10-cm foam). Participants completed 300-s trials with band-limited (0–30 Hz), zero-mean nGVS at ±0, 0.1, 0.2, 0.3, 0.5, and 0.7 mA in randomized order. Coupling between the stimulation waveform and mediolateral ground-reaction force was quantified using coherence and time-cumulant density. Group mean coherence became significant primarily at higher amplitudes (0.5–0.7 mA) for both surfaces, while time-cumulant density revealed significant time-locked vestibular-evoked response components beginning at much lower amplitudes (down to 0.1 mA), including an early component (~135–155 ms) and a later prominent component (~360–410 ms). Individually, significant coherence was prevalent at 0.5–0.7 mA (15–19 of 20 participants, depending on surface and amplitude), whereas cumulant-based responses were observed in a subset as low as 0.1 mA. Responses were more evident on foam, consistent with increased vestibular reliance under reduced somatosensory reliability. These findings show that low-amplitude nGVS can produce stimulus-locked postural output, implying that balance changes during imperceptible nGVS amplitudes may reflect deterministic vestibular drive, SR-like facilitation, or both.