The objective of this study in healthy volunteers is to evaluate whether the composition of the gut microbiota and sleep quality influence the susceptibility to develop peripheral and central sensitization of pain pathways. In two different experimental sessions, the following factors will be tested: the influence of the composition of the gut microbiota on the susceptibility to develop peripheral sensitization of nociceptors, and the susceptibility to develop central sensitization of pain pathways. To assess susceptibility to peripheral sensitization, a solution of capsaicin (the active component of chili pepper) will be applied to the skin to induce neurogenic inflammation produced by the release of substances from nociceptors at the peripheral level. This neurogenic inflammation is characterized by a transient redness of the skin that will be measured with an infrared camera. To evaluate the susceptibility to sensitization at the central level, a high frequency electrical stimulation will be applied to the skin. This stimulation induces an increase in sensitivity to mechanical stimulation secondary to central sensitization. The intensity, extent and duration of this mechanical hyperalgesia will therefore be used as a measure of susceptibility to central sensitization. A stool sample and a blood sample will be taken. These samples will be used to characterize the composition of the intestinal microbiota, as well as the metabolites produced by this microbiota. These analyses will allow a comparison of the composition of the microbiota and the metabolites in subjects with a tendency to develop low vs. high sensitization at the peripheral and central levels. Similarly, sleep quality and average sleep duration will be assessed using questionnaires and a measurement of the participant's activity using a wrist movement sensitive bracelet. This information will be used to assess whether some of the interindividual variability in developing peripheral or central sensitization might be related to differences in sleep quality. Finally, systemic inflammation could be a factor modulated by sleep and gut microbiota, influencing pain perception and susceptibility to sensitization. For this reason, systemic pro- and anti-inflammatory cytokines will be measured in the blood sample.
Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
OTHER
Masking
SINGLE
Enrollment
140
The participants will be screened for inclusion and exclusion criteria and will be asked to fill the following questionnaires : Pittsburgh Sleep Quality Index, State and Trait Anxiety Questionnaire, Pain Catastrophizing Scale Fear of Pain Questionnaire, Perceived Stress Scale, Beck Depression Inventory, and questionnaires to assess their health status and the use of medications. A blood sample (to measure pro- and anti-inflammatory cytokines and perform metabolomic analyses) will be obtained. Enrolled participants will be given a wearable actimeter to assess daily total sleep duration during one week before the first experimental session. They will also be requested to complete daily a sleep diary during one week before each experimental session, and a food diary before the first experimental session. A fecal sample (to assess gut microbiota composition and perform metabolomic analyses) will be collected between the screening visit and the first experimental session.
The extent of neurogenic inflammation induced by topical capsaicin will be used as a measure of the susceptibility to sensitize at peripheral level. A solution of capsaicin will be applied to the skin of the left or right volar forearm for 30 minutes. The capsaicin-induced neurogenic inflammation can be quantified by assessing the intensity, extent and duration of the capsaicin-induced cutaneous flare response using thermal infrared imaging. Using heat stimuli delivered to the treated skin and surrounding skin, the intensity and duration of the capsaicin-induced hyperalgesia will also be assessed. The experimental session will last approximately two hours.
The extent of secondary mechanical hyperalgesia induced by high-frequency electrical stimulation (HFS) of the skin of the left or right volar forearm will be used as a measure of the susceptibility to develop central sensitization. The stimulation will be delivered using a multi-pin electrode designed to preferentially activate epidermal free nerve endings. The strength, spatial extent and duration of the HFS-induced changes in pinprick sensitivity will be characterized by using calibrated mechanical pinprick stimuli. The experimental session will last approximately one hour.
UCLouvain, IONS
Woluwe-Saint-Lambert, Belgium
RECRUITINGCorrelation between composition of the intestinal microbiota and its metabolites and the susceptibility of sensitization at the peripheral and central levels.
A stool sample and a blood sample will be taken. These samples will be used to characterize the composition of the intestinal microbiota, as well as the metabolites produced by this microbiota. These analyses will allow a comparison of the composition of the microbiota and the metabolites in subjects with a tendency to develop low vs. high sensitization at the peripheral and central levels. The gut microbiota composition will be analyzed using 16S rDNA sequencing. Untargeted metabolite profiling, in fecal and blood samples, will be performed using liquid chromatography (LC) coupled with tandem mass spectrometry (MS-MS) platforms.
Time frame: one week
Correlation between sleep quality and the susceptibility of sensitization at the peripheral and central levels.
Sleep quality will be assessed using questionnaires and a measurement of the participant's sleep using a wrist movement sensitive bracelet. This information will be used to assess whether some of the inter-individual variability in developing peripheral or central sensitization might be related to differences in sleep quality.
Time frame: five weeks
Correlation between sleep duration and the susceptibility of sensitization at the peripheral and central levels.
Average sleep duration will be assessed using questionnaires and a measurement of the participant's sleep using a wrist movement sensitive bracelet. This information will be used to assess whether some of the inter-individual variability in developing peripheral or central sensitization might be related to differences in sleep duration.
Time frame: five weeks
Correlation between levels of systemic pro- and anti-inflammatory cytokines measured by multiplex assays and the susceptibility of sensitization at the peripheral and central levels.
Systemic inflammation could be an important factor modulated by sleep and the gut microbiota, influencing nociception and sensitization at peripheral and central levels. Plasma concentrations (pg/mL) of several pro-inflammatory (TNFa, IL-6, IL-1b, MCP-1) and anti-inflammatory (IL-10) markers will me measured using commercially available multiplex assays.
Time frame: one week
Correlation between pupil diameter and the susceptibility of sensitization at the peripheral and central levels.
During sensory stimulation, an infrared camera will be used to measure pupil diameter which has been shown to constitute an indirect correlate of stimulus-evoked phasic variations in activity of the locus coeruleus.
Time frame: five weeks
Correlation between heart rate variability and the susceptibility of sensitization at the peripheral and central levels.
In order to measure autonomic reactivity to pain stimuli, the heart rate variability will be measured by recording electrocardiography during experimental sessions.
Time frame: five weeks
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