Clinical and Neurophysiological Effects of tDCS to Visual and Motor Cortex in Migraine

NCT ID: NCT06468189

Last Updated: 2025-04-25

Basic Information

• Recruitment Status: ACTIVE_NOT_RECRUITING
• Clinical Phase: NA
• Total Enrollment: 80 participants
• Study Classification: INTERVENTIONAL
• Study Start Date: 2024-03-01
• Study Completion Date: 2025-11-30

Brief Summary

tDCS can be offered as an alternative to migraine patients who have frequent and severe attacks and who are resistant to or unresponsive to preventive drug therapy. Additionally, this technique may also be an option for patients who refuse or have contraindications to taking anti-migraine medications. A decrease in headache severity and frequency is expected with this neuromodulation applied to migraine patients with frequent attacks. Based on this hypothesis; This tested whether simultaneous modulation of motor (M1, left) and visual cortex (O1 or O2, ipsilateral) with tDCS applied for 3 consecutive days is an effective treatment for migraine patients for the following specific purposes . No significant undesirable effects are expected, except for possible side effects that are simple and do not require medical intervention, such as tingling or itching in the area where the electrodes are attached, moderate fatigue, mild headache, nausea at a rate of less than 3%, and insomnia at a rate of less than 1%. . The research will be conducted within the framework of ethical principles and in accordance with the good clinical practice protocol.

A) The primary purpose of this study is to determine whether transcranial direct current stimulation applied simultaneously to the motor and visual cortex in migraine patients provides a significant reduction in pain due to migraine attacks compared to sham tDCS. Additionally, to evaluate the effects of this treatment, They will be measured changes in the number of migraine attacks, abortive medication intake (e.g., opioids, triptans), as well as overall improvement in cognitive status and quality of life. In addition, electrophysiological EEG evaluations, before and after treatment, and the results of these measurements, as a potential biomarker in migraine, will be compared in the active and sham groups.

B) It is aimed to determine whether the clinical effects of tDCS are long-lasting. Therefore, It will compared whether there is a difference in improvement of migraine-related pain between active and sham tDCS at pre-treatment (baseline) assessments as well as at 1, 2, and 3 months after treatment.

C) Finally, it will be examined whether tDCS treatment applied for 3 consecutive days in migraine patients is safe. Safety will be evaluated through neuropsychological testing and adverse event reporting.

Detailed Description

Headache disorders are quite common. In the 2016 Global Burden of Disease Study, migraine was the second highest cause of disability overall and the most common disease causing disability in young adults (15-49 years). When there are frequent or severe migraine attacks, pharmacological agents are used to reduce the frequency of migraine attacks. Standard migraine prophylactic treatments show either low efficacy or undesirable side effects, and most of them are licensed for other diseases and not for migraine. Additionally, some migraine patients are hesitant to choose pharmacological treatment. Compliance with these treatments is also quite low in the medication-using group. Recently used calcitonin gene-related peptide (CGRP) monoclonal antibody treatments are quite expensive treatments. Therefore, there remains a need for an effective, tolerable and affordable prophylactic treatment for migraine.

Migraine is complex, involving several circuits of both the central and peripheral nervous system and has a still unclear pathophysiology. Trigeminovascular activation is the key event of migraine pain, mostly related to the peripheral nervous system, but the central nervous system also plays a role in the formation and perception of migraine. The cerebral cortex of migraineurs is hypersensitive (overexcitable) to external stimuli, possibly due to altered functional connectivity in subcortical structures, including the thalamus. This resulting "thalamo-cortical dysrhythmia" and changes in excitability can be controlled with non-invasive neuromodulation techniques such as transcranial magnetic stimulation (TMS) and transcranial direct current stimulation (tDCS).

Non-invasive neuromodulation is applied to various forms of primary headaches and is recommended as an easily applicable method for both episodic and chronic migraine. So far, only single pulse transcranial magnetic stimulation (sTMS), vagus nerve stimulation (VNS), and supraorbital neurostimulation have been approved by the FDA for the treatment of migraine. Transcranial direct current stimulation (tDCS; direct current stimulation) is an electrical stimulation method used for non-invasive brain stimulation, where a weak electrical current of approximately 2 milliamps is applied through two scalp electrodes with a portable battery-powered system. tDCS is an electrical stimulation technique in which low-amplitude direct current is applied to the skull via surface electrodes, thereby modulating neural brain activity. The applied current changes the transmembrane neuronal potential and thus affects the level of excitability. Depending on the polarity of the active electrodes, tDCS can increase or decrease cortical excitability. tDCS has been shown to trigger changes in neuropsychological and motor activity in the brain. Protocols with variable session numbers (1-20 days) applied to different targeted brain regions provide promising results in pain syndromes by regulating pain-related pathways in various ways. Stimulation of the motor cortex with tDCS has already been shown to relieve pain in patients with traumatic spinal cord injury and other chronic pain syndromes, including fibromyalgia. Migraine patients are often hypersensitive to pain. A treatment that targets areas of the brain involved in the experience of pain may also help reduce pain in migraine patients. According to the results of systematic review and meta-analysis of studies conducted so far; tDCS has been evaluated as an effective, reliable method that can improve migraine symptoms by activating the motor cortex or activating/inhibiting the visual cortex. Additionally, tDCS treatment repeated for days over a period of 4 weeks or longer is effective in reducing migraine pain severity and attack duration. The benefit of tDCS may persist for at least 4 weeks after completion of the last tDCS session. Both anodal and cathodal stimulation have been evaluated as effective for reducing migraine pain severity. The study protocol present here aims to test a unique protocol with simultaneous anodal stimulation to the motor area and cathodal stimulation to the visual cortex. In the meta-analyses conducted so far; In future clinical studies using tDCS in migraine, the importance of simultaneously measuring neuronal activity using EEG or fMRI(Functional magnetic resonance imaging)( is also emphasized in order to better understand the underlying mechanisms of action. Electrophysiological techniques, such as quantitative electroencephalography (qEEG), provide important information about brain functioning at rest and during sensory stimulation. A large amount of data has demonstrated the presence of some excitability changes in the occipital cortex during the interictal period of migraine patients.While some studies have demonstrated hyperexcitability, only a few studies have been able to document a decrease in occipital excitability. This increase in occipital excitability has recently been recognized as an inhibition phenomenon, and a new term "hyperresponsiveness" in migraine has come into use in the last decade. This hyperexcitability has been demonstrated in many neurophysiological and neuroimaging studies as loss of habituation to recurrent stimuli. Clearly, spectral analysis of different frequency bands of qEEG helps us understand the intrinsic activity of the migraineur brain. Differences in peak latency, amplitude, and synchronization of EEG frequency bands in response to sensory stimulation have been reported in migraine patients compared with healthy subjects. In this study, it is planned to make comparative evaluations in the following months with EEG recordings to be taken before and after simultaneous motor cortex and visual cortex stimulation. In this way, the relationship between anodal and cathodal transcranial direct current stimulation and different frequency bands in the occipital region will be determined by comparing the active treatment and sham groups.

Review studies and recent studies from our country have shown that tDCS treatment is an effective and safe prophylactic treatment in migraine patients with allodynia in both short and long-term follow-ups. In order to obtain better clinical evidence in this field, as emphasized in the Cochrane analysis conducted in 2018; Randomized controlled studies with larger samples and clinically meaningful long-term results are needed. In these studies, it is planned to test the clinical effect of a protocol combination, which has been shown to be particularly effective, in prophylaxis in migraine patients in a large sample group, while also evaluating its neurophysiological responses in active and sham groups.

Conditions

Migraine

Study Design

• Allocation Method: RANDOMIZED
• Intervention Model: PARALLEL
• Primary Study Purpose: TREATMENT
• Blinding Strategy: DOUBLE

Study Groups

tDCS

tDCS Interictal application will be performed during the attack-free period. Experimental group, 3 consecutive sessions, cathodal to occipital cortex (O1 or O2, ipsilateral); anodal to M1 (left)

Group Type: EXPERIMENTAL

transcranial direct stimulation

Intervention Type: DEVICE

Mars-01(Marslab, Turkey) transcranial direct current stimulation device works with a 9 volt battery and consists of two 5x5 (25 cm2) electrodes (anode and cathode). 3 consecutive sessions (days), cathodal to occipital cortex (O1 or O2, ipsilateral); Anodal application will be made to M1 (left). Active stimulation is 2mA tDCS with a 0 to 30 second acceleration period of 20 minutes per session. Placebo stimulation will be applied according to the device's own sham software protocol. Accordingly, the current consists of 30 seconds of increase from 0 to 2mA(milliamp), 10 seconds of stimulation, 30 seconds of decrease to 0 and 20 minutes of current-free application.

Sham

Control group, 3 consecutive sessions of sham stimulation to the same locations.

Group Type: SHAM_COMPARATOR

Sham treatment

Intervention Type: DEVICE

The same device used for stimulation will be used, but no stimulation will be given.

Interventions

transcranial direct stimulation

Mars-01(Marslab, Turkey) transcranial direct current stimulation device works with a 9 volt battery and consists of two 5x5 (25 cm2) electrodes (anode and cathode). 3 consecutive sessions (days), cathodal to occipital cortex (O1 or O2, ipsilateral); Anodal application will be made to M1 (left). Active stimulation is 2mA tDCS with a 0 to 30 second acceleration period of 20 minutes per session. Placebo stimulation will be applied according to the device's own sham software protocol. Accordingly, the current consists of 30 seconds of increase from 0 to 2mA(milliamp), 10 seconds of stimulation, 30 seconds of decrease to 0 and 20 minutes of current-free application.

Intervention Type: DEVICE

Sham treatment

The same device used for stimulation will be used, but no stimulation will be given.

Intervention Type: DEVICE

Eligibility Criteria

Inclusion Criteria

• Episodic migraine without aura and with aura, with frequent attacks (>4 or more), diagnosed according to the International Classification of Headache Disorders; The diagnosis must meet the 2018 ICHD-3 criteria for migraine without aura and migraine with aura.
• Patients whose previous prophylactic treatments have failed and who cannot or do not want to use treatments for various reasons
• The duration of the disease must be at least 12 months.
• Not having received any botulinum toxin treatment in the last 3 months
• Having the mental functionality and education to understand the scales used
• Patients who volunteered to participate in the research.

Exclusion Criteria

• Pregnancy or breastfeeding
• People with clinical evidence of brain damage
• Metallic implant head
• Heart battery
• History of seizures and chronic pain associated with other pathologies
• Other major neurological or major neuropsychiatric diseases;
• Other chronic pain syndromes;
• Other types of primary or secondary headaches;

• Minimum Eligible Age: 18 Years
• Maximum Eligible Age: 55 Years
• Eligible Sex: ALL
• Accepts Healthy Volunteers: No

Sponsors

Alanya Alaaddin Keykubat University

OTHER

Sponsor Role: collaborator

Saglik Bilimleri Universitesi

OTHER

Sponsor Role: collaborator

Istanbul Medipol University Hospital

OTHER

Sponsor Role: lead

Responsible Party

Prof. Lutfu Hanoglu, MD

Prof. Dr.

Responsibility Role: PRINCIPAL_INVESTIGATOR

Principal Investigators

Lütfü Hanoğlu, Prof. DR. MD

Role: PRINCIPAL_INVESTIGATOR

Medipol University

Locations

İstanbul Medipol University

Istanbul, Beykoz, Turkey (Türkiye)

Countries

Turkey (Türkiye)

Other Identifiers

2023IMU_Migraine_tDCS

Identifier Type: -

Identifier Source: org_study_id