Influence of Brain Oscillation-Dependent TMS on Motor Function

Purpose

Background: When people have a stroke, they often have difficulty moving their arms and hands. Transcranial magnetic stimulation (TMS) can improve how well people with and without stroke can move their arms and hands. But the effects of TMS are minor, and it doesn t work for everyone. Researchers want to study how to time brain stimulation so that the effects are more consistent. Objective: To understand how the brain responds to transcranial magnetic stimulation so that treatments for people with stroke can be improved. Eligibility: Adults ages 18 and older who had a stroke at least 6 months ago Healthy volunteers ages 50 and older Design: Participants will have up to 5 visits. At visit 1, participants will be screened with medical history and physical exam. Participants with stroke will also have TMS and surface electromyography (sEMG). For TMS, a brief electrical current will pass through a wire coil on the scalp. Participants may hear a click and feel a pull. Muscles may twitch. Participants may be asked to do simple movements during TMS. For sEMG, small electrodes will be attached to the skin and muscle activity will be recorded. At visit 2, participants will have magnetic resonance imaging (MRI). They will lie on a table that slides into a metal cylinder in a strong magnetic field. They will get earplugs for the loud noise. At visit 3, participants will have TMS, sEMG, and electroencephalography (EEG). For EEG, small electrodes on the scalp will record brainwaves. Participants will sit still, watch a movie, or do TMS. Participants may be asked to have 2 extra visits to redo procedures.

Conditions

  • Healthy
  • Stroke
  • Normal Physiology
  • Aging

Eligibility

Eligible Ages
Between 18 Years and 120 Years
Eligible Sex
All
Accepts Healthy Volunteers
Yes

Inclusion Criteria

  • Healthy younger adults: - Ages 18 years to less than 50 years. (18 to 49) - Willingness/ability to provide informed consent. - Ability to induce a motor evoked potential in the muscle target of the upper extremity, as evaluated during the TMS Screening. - Healthy older adults: - Age 50 and over - Willingness/ability to provide informed consent. - Ability to induce a motor evoked potential in the muscle target of the upper extremity, as evaluated during the TMS Screening. - Stroke patients: - Age 18 and over. - Unilateral or bilateral upper limb paresis with the ability to voluntarily contract a finger, hand, wrist, or elbow muscle in the affected arm(s). - Stroke onset > 6 months prior to participation. - Intact M1 sufficient to induce motor evoked potentials in the affected upper extremity following ipsilesional TMS, as evaluated during the TMS Screening. - Willingness/ability to provide informed consent. - If the investigator feels the individual s capacity to provide informed consent is questionable, the NIH Human Subjects Protection Unit (HSPU) will be requested to determine the individual s ability to consent.

Exclusion Criteria

  • Healthy younger and older adults: - Presence of severe neurological or medical disorder (e.g., Parkinson s disease or multiple sclerosis). - History of seizures. - Chronic use of antipsychotic drugs (e.g., chlorpromazine or clozapine), tri-cyclic or other anti-depressants, benzodiazepines, or prescription stimulants. - TMS contraindications, such as: - Pacemaker, implanted pump, stimulator, cochlear implant, or metal objects inside the eye or skull. - Diagnosed severe hearing loss. - Current pregnancy. - Staff from our section. - Stroke patients: - Presence of severe neurological or medical disorder, other than stroke (e.g., Parkinson s disease or multiple sclerosis). - History of brainstem stroke. - History of seizures. - Chronic use of antipsychotic drugs (e.g., chlorpromazine or clozapine), benzodiazepines, or prescription stimulants. - TMS contraindications, such as: - Pacemaker, implanted pump, stimulator, cochlear implant, or metal objects inside the eye or skull. ---Diagnosed severe hearing loss. - Current pregnancy. - Staff from our section.

Study Design

Phase
Study Type
Observational
Observational Model
Cohort
Time Perspective
Prospective

Arm Groups

ArmDescriptionAssigned Intervention
Healthy volunteers Healthy volunteers age 18 and older
Stroke patients Stroke patients aged 18 and older

Recruiting Locations

National Institutes of Health Clinical Center
Bethesda, Maryland 20892
Contact:
For more information at the NIH Clinical Center contact Office of Patient Recruitment (OPR)
800-411-1222
prpl@cc.nih.gov

More Details

Status
Recruiting
Sponsor
National Institute of Neurological Disorders and Stroke (NINDS)

Study Contact

Catherine L Blumhorst, C.R.N.P.
(301) 451-1335
cathy.blumhorst@nih.gov

Detailed Description

Study Description: We will study if corticospinal excitability, intracortical inhibition and intracortical facilitation vary across different sensorimotor alpha and beta electroencephalography (EEG) waveform oscillation phases in healthy adults and chronic stroke patients. In young healthy adults, sensorimotor cortical neuronal spiking is highest at sensorimotor alpha oscillation troughs and lowest at sensorimotor alpha oscillation peaks. Short interval cortical inhibition (SICI) is unaffected by alpha phase, consistent with alpha phase representing a form of transient, pulsed excitation, unaffected by gamma-aminobutyric acid (GABA)-mediated inhibition. In contrast to sensorimotor alpha, motor evoked potential (MEP) amplitudes are not maximal at the trough phase of the sensorimotor beta rhythm. Objectives: TMS is a potential adjunct therapy for post-stroke neurorehabilitation. So far, it has been customarily applied uncoupled from brain oscillatory activity, resulting in variability in the biological response to each stimulus, small effect sizes and significant inter-individual variability. Alpha band oscillatory activity is linked to cortical excitation and inhibition, motor function and cognitive processing. It is possible that TMS effects could be more consistent when applied to specific phases or phase angles of ongoing brain oscillatory activity. For example, corticospinal excitability (as measured with TMS) in healthy humans varies depending on the sensorimotor alpha and beta oscillatory phase during which TMS is delivered. There is no information available on intracortical facilitation and inhibition as a function of beta phase angle in healthy humans. In Experiments 1 and 3 we have been assessing alpha phase-dependent corticospinal excitability measures. In Experiment 2, we will assess beta and secondarily alpha phase-dependent intracortical inhibitory and facilitatory circuits in young and older adults. Endpoints: For experiments 1 and 3, the primary outcome measure is corticospinal excitability. For Experiment 2, the primary outcome is SICI. Exploratory outcome measures may include MEP amplitude variability, SICI, short intracortical facilitation (SICF) and intracortical facilitation (ICF) and TMS-induced oscillations.