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Effects of Non Invasive Brain Stimulation During Prolonged Experimental Pain

Sponsor
Aalborg University (Other)
Overall Status
Completed
CT.gov ID
NCT04246853
Collaborator
(none)
44
Enrollment
1
Location
2
Arms
5.9
Actual Duration (Months)
7.4
Patients Per Site Per Month

Study Details

Study Description

Brief Summary

Non invasive brain stimulation (NIBS) of the primary motor cortex (M1) through transcranial direct current stimulation (tDCS) has been widely investigated in research and clinical settings in order to modulate brain plasticity and improve clinical pain. Interestingly, newly developed paradigms i.e. tDCS of the resting state motor network have proved higher modulatory effects in terms of corticospinal excitability when compared to traditional M1 tDCS.

However, little is known about the effects of tDCS on the frequency changes of alpha oscillations (alpha peaks).

Interestingly, previous studies show a correlation between reduced frequencies of alpha peaks during 1-hour experimental pain in comparison to baseline.

The present study aims to investigate the effects of tDCS of the resting state motor network on the frequency and power of alpha peaks during prolonged experimental pain during 24 hours.

Condition or Disease Intervention/Treatment Phase
  • Device: Transcranial direct current stimulation (tDCS) of the resting state motor network
 N/A

Detailed Description

There is evidence that chronic pain alters the frequency of alpha peaks. Specifically, recent studies showed a correlation between decreased frequency of alpha peaks and perceived pain. Furthermore, a correlation was found between high pain sensitivity and slower alpha oscillations during prolonged pain during 1 hour.

To date, the effects of prolonged experimental pain during 24 hours on brain oscillations has not been explored. Moreover, it is unknown whether non invasive brain stimulation (NIBS) through transcranial direct current stimulation (tDCS) can revert these pain-related feature.

It is hypothesized that prolonged pain during 24 hours will reduce the frequency of alpha peaks and tDCS of the resting state motor network will revert it to baseline values.

Furthermore, it is thought that decreased frequency of alpha peaks will be correlated with perceived pain intensity on Day 1 (before receiving the first tDCS session).

Study Design

Study Type:
Interventional
Actual Enrollment :
44 participants
Allocation:
Randomized
Intervention Model:
Parallel Assignment
Intervention Model Description:
The current studies have a randomized, parallel, sham-controlled and double-blinded design.The current studies have a randomized, parallel, sham-controlled and double-blinded design.
Masking:
Triple (Participant, Investigator, Outcomes Assessor)
Masking Description:
Double-blinding is performed by a third-party which is not part of the research group
Primary Purpose:
Basic Science
Official Title:
Effects of Non Invasive Brain Stimulation on Experimental Pain
Actual Study Start Date :
Feb 1, 2020
Actual Primary Completion Date :
Jul 30, 2020
Actual Study Completion Date :
Jul 30, 2020

Arms and Interventions

Arm Intervention/Treatment
Active Comparator: Active tDCS of the resting state motor network

The active comparator is the Active tDCS group. The active tDCS will target the resting-state motor network and will apply a distributed direct current during the whole session. (The TIME during the direct current is applied is the only difference with Sham tDCS) Each tDCS session lasts 20 minutes and applies a total current of 4mA.

Device: Transcranial direct current stimulation (tDCS) of the resting state motor network
Transcranial direct current stimulation (tDCS) delivers a low intensity current of up to 4 mA per session through small and circular shaped electrodes applied over the scalp. This induces a weak but focal electrical field that may modify the excitability of the underlying cortical target in a polarity and activity dependent fashion.
Sham Comparator: Sham tDCS of the resting state motor network

This study has a parallel design and 2 groups: Active tDCS and Sham tDCS. Sham tDCS applies a standard sham protocol consisting of ramping up and down during 30 seconds at the beginning and at the end of each tDCS session. Each tDCS session lasts 20 minutes and applies a total current of 4mA.

Device: Transcranial direct current stimulation (tDCS) of the resting state motor network
Transcranial direct current stimulation (tDCS) delivers a low intensity current of up to 4 mA per session through small and circular shaped electrodes applied over the scalp. This induces a weak but focal electrical field that may modify the excitability of the underlying cortical target in a polarity and activity dependent fashion.

Outcome Measures

Primary Outcome Measures

  1. Frequency of alpha peaks [24 hours]

    The frequency of alpha peaks will be extracted through electroencephalography (EEG) in the sensorimotor areas (Central-Parietal) of the brain. It is hypothesized that the frequency of alpha peaks will be reduced due to prolonged pain. It is expected that tDCS of the resting state motor network will revert the frequency to baseline values or even higher.

  2. Perceived pain intensity [24 hours]

    Perceived pain intensity will be rated in a 0-10 Numerical rating scale (NRS): 0 no pain and 10 worst pain imaginable. Prolonged pain will increase perceived pain intensity. It is expected that active tDCS will not be able to reduce perceived pain intensity in comparison to sham tDCS.

Secondary Outcome Measures

  1. Amplitude of alpha peak [24 hours]

    Similar to the primary outcome, the amplitude of the alpha peak will be extracted through EEG in the sensorimotor area. It is expected that prolonged pain will be able to reduce the amplitude of alpha peaks and tDCS will increase it back to baseline values or even higher.

  2. Power of alpha oscillations [24 hours]

    Spectral analysis will be performed on alpha activity and it is expected that this outcome will be reduced by prolonged pain and tDCS of the resting state motor network will be able to normalize it.

Other Outcome Measures

  1. Amplitude of Mu-oscillations during motor imagery [24 hours]

    Amplitude of Mu-oscillations will be extracted from EEG during motor imagery tasks (abduction-adduction of index finger). It is expected that prolonged pain and motor imagery will produce a desynchronization of Mu-oscillations and on the contrary active tDCS will be able to synchronize it back similar to pain-free state.

Eligibility Criteria

Criteria

Ages Eligible for Study:
21 Years to 50 Years
Sexes Eligible for Study:
All
Accepts Healthy Volunteers:
Yes
Inclusion Criteria:
  • Right-handed healthy men and women in the age 21-50 years who speak and understand English
Exclusion Criteria:

  • Lack of ability to cooperate

  • History of chronic pain or current acute pain

  • Pregnancy

  • Drug addiction defined as the use of cannabis, opioids or other drugs

  • Present and previous neurologic, musculoskeletal or mental illnesses

  • Chili allergies

  • Current use of medications that may affect the trial

  • Contraindications to rTMS application (history of epilepsy, metal implants in head or jaw, etc.)

  • Failure to pass the questionnaire for tDCS

Contacts and Locations

Locations

Site City State Country Postal Code
1 Aalborg University Aalborg Nordylland Denmark 9000

Sponsors and Collaborators

  • Aalborg University

Investigators

None specified.

Study Documents (Full-Text)

None provided.

More Information

Publications

None provided.
Responsible Party:
Luisina Gregoret, Biomedical engineer, Aalborg University
ClinicalTrials.gov Identifier:
NCT04246853
Other Study ID Numbers:
  • N-20180092
First Posted:
Jan 29, 2020
Last Update Posted:
Nov 20, 2020
Last Verified:
Nov 1, 2020
Individual Participant Data (IPD) Sharing Statement:
Undecided
Plan to Share IPD:
Undecided
Studies a U.S. FDA-regulated Drug Product:
No
Studies a U.S. FDA-regulated Device Product:
No

Study Results

No Results Posted as of Nov 20, 2020