Balance, Autonomic Response, and Sensory Modulation to Dosage of Mechanical Vagal Stimulation in Healthy Adults (BARVANS)

mechanical VNs in humans, induced by a combination of non-painful physiological neck movements, effectively reduces the HR at rest in humans, without any side effects in the short- and long-term. Indeed, HR reduction is a proxy for the VN increased activity among healthy subjects and patients with systemic diseases or autonomic diseases. Mechanical VNs had been successfully adopted in two clinical trials among chronic pain patients (NCT05345496, NCT05360589), but due to the early stage of these new VNs and the clear advantages of this method, studies refining the stimulation protocol are suitable. Thus, the study aims to investigate the possible dose-dependent effects of mVNs on different physiological parameters in humans. 3 protocols of mVNs will be compared consisting of (1) 4 minutes (2 minutes on each side); (2) 12 minutes (3 sessions of 2 minutes of stimulation, with 2 minutes of rest for each side); (3) 16 minutes (8 minutes on each side). The following outcomes will be assessed before and after the stimulation: HR at rest, HRV, balance on standing, perceived intensity and modulation of mechanical stimuli on the skin of the forehead, and the abdomen, gastrointestinal transit, and a fecal sample from the closest intestinal emptying. A total sample of at least 96 healthy subjects (48 females) aged between 18 and 60 are expected to participate. The bidirectional communication between internal organs and the brain via the VN is a well-established scientific fact. Indeed, VNs has beneficial effects on manifold pathological conditions in humans. However, easy-to-apply, non-invasive, and effective VNs methods and standardized protocols are lacking. The here proposed project aims at refining and critically assessing mVNs methods - a prerequisite for exploring the clinical utility of mVNs and fostering its therapeutic potential given the fundamental role of the VN in regulating health and disease. Results obtained from this project will provide data on mVNs on gut microbiota dynamics and the potential benefits for pain modulation, equilibrium impairments, and gastrointestinal dysfunctions.