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Not Yet RecruitingNCT07212829

The Added Value of Transcranial Direct Current Stimulation (tDCS) During Exercise for People With Chronic Widespread Pain

Unravelling the Epigenetic Mechanisms of Exercise-induced Pain in Chronic Widespread Pain: DNA Methylation Regulation of the Brain-derived Neurotrophic Factor Expression and Its Modulation by Transcranial Direct Current Stimulation

Status
Not Yet Recruiting
Phase
N/A
Study type
Interventional
Enrollment
120 (estimated)
Sponsor
Vrije Universiteit Brussel · Academic / Other
Sex
All
Age
18 Years – 70 Years
Healthy volunteers
Accepted

Summary

Many people with chronic widespread pain (CWP) feel more pain and fatigue after exercise. This makes it hard to stay active. Unfortunately, the investigators do not fully understand why this happens and how to prevent it. The primary goal of this study is to explore the underlying genetic and epigenetic mechanisms of BDNF gene in response to exercise, and investigate if transcranial direct current stimulation (tDCS) during exercise works to improve worsening symptoms response to exercise in people with CWP. The investigators designed a randomized crossover study and will enroll 60 patients with CWP and 60 healthy controls. Participants will undergo 2 interventions in random order: 1) exercise + active tDCS, and 2) exercise + sham tDCS. Participants will visit the hospital twice with at least one week in between the visits.

Detailed description

Many people with chronic widespread pain (CWP), such as those with fibromyalgia, experience increased pain in response to exercise, which discourages continued physical activity. Although abnormal gene expression via epigenetic mechanisms has been implicated in CWP, the underlying mechanisms by which exercise exacerbates symptoms remain unclear. DNA methylation is one way that environmental factors like exercise can alter gene expression, and brain-derived neurotrophic factor (BDNF) plays a central role in both neuroplasticity and pain processing. The investigators hypothesize that aberrant expression of the BDNF gene contributes to post-exercise symptom flares in CWP. Transcranial direct current stimulation (tDCS) has been shown to modulate neuroplasticity and influence gene expression, making it a promising approach to normalize BDNF regulation during exercise. In this randomized crossover trial, 60 CWP patients and 60 healthy controls will each undergo two sessions: (1) exercise with active tDCS and (2) exercise with sham tDCS. Each participant will visit the hospital twice, with at least one week between sessions. During each session, participants will receive one bout of submaximal aerobic exercise (20 min), along with a single session of active or sham tDCS (30 min) simultaneously. The order of interventions will be well-balanced and randomly allocated to each participant. We will measure pain intensity, serum BDNF protein levels, and BDNF gene methylation before and after each session. To capture longer-term effects, participants will also complete online symptom assessments at 8 hours, 24 hours, 48 hours, and 7 days post-exercise. The primary objective of this study is to determine how active versus sham tDCS during exercise influences BDNF expression, DNA methylation patterns, and pain intensity in CWP patients. The secondary objectives are to 1) compare these tDCS-induced changes between CWP patients and healthy controls; and 2) identify factors that influence tDCS/exercise-induced changes, including baseline BDNF levels, DNA methylation patterns, genetic polymorphisms and Lifestyle variables (e.g., physical activity). By elucidating the epigenetic regulation of BDNF in exercise-induced pain and evaluating tDCS as a modulatory intervention, this study seeks to identify biomarkers of symptom exacerbation and develop non-pharmacological strategies that enable CWP patients to remain active without worsening their pain.

Conditions

Interventions

TypeNameDescription
DEVICEActive tDCStDCS is performed using a monophasic current device. Pairs of silicon sponge sur-face electrodes (35 cm2) are soaked in saline and positioned as follows: the anode is placed over the region of the dorsolateral prefrontal cortex (DLPFC) per the international 10/20 system at point F3 (left DLPFC), and the cathode is placed on the contralateral supraorbital area (FP2 site). For active tDCS, the current is ramped up for 30 seconds until the center electrode reaches a target intensity of 2 mA, then remains for 29 minutes before dropping for another 30s.
BEHAVIORALAerobic exerciseParticipants will perform a moderate aerobic exercise (AE, known as aerobic power index), using a cycle er-gometer. The exercise intensity is moderate and individually tailored based on each participant's estimated maximum heart rate (HRmax), calculated using the validated formula: HRmax = 211 - (0.64 × age).
DEVICESham tDCStDCS is performed using a monophasic current device. Pairs of silicon sponge sur-face electrodes (35 cm2) are soaked in saline and positioned as follows: the anode is placed over the region of the dorsolateral prefrontal cortex (DLPFC) per the international 10/20 system at point F3 (left DLPFC), and the cathode is placed on the contralateral supraorbital area (FP2 site). In the sham condition, current is ramped up to 2.0 mA for 30 seconds and then ramped down to 0 mA, with the total session duration matched to the active condition. This procedure was used to mimic the tingling sensa-tions typically experienced at the beginning of stimulation. Participants received identical instructions, session timing, and room setup across conditions.

Timeline

Start date
2026-02-01
Primary completion
2027-12-30
Completion
2028-06-30
First posted
2025-10-08
Last updated
2026-01-08

Locations

1 site across 1 country: Belgium

Source: ClinicalTrials.gov record NCT07212829. Inclusion in this directory is not an endorsement.