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Modulation of Motor Function by Stimulation of the Central and Peripheral Nervous System

Early Phase 1
Completed
Conditions
Motor Function of Healthy Physiology
Interventions
Device: tACS
Device: CPNS
Device: tDCS
Device: TMS
Registration Number
NCT00453505
Lead Sponsor
National Institute of Neurological Disorders and Stroke (NINDS)
Brief Summary

Objectives

Noninvasive stimulation of the central and peripheral nervous system, including transcranial magnetic stimulation (TMS), transcranial direct and alternating current stimulation (tDCS and tACS, respectively) and cutaneous/peripheral nerve stimulation (C/PNS) alone or paired with TMS (paired associative stimulation, PAS), has been increasingly used in the investigation of cortical plasticity and as a possible adjuvant strategy in neurorehabilitation. It has been shown that TMS, tDCS, tACS and C/PNS can modulate motor function in healthy volunteers, as well as in patients with neurological disorders such as stroke.

One fundamental problem is that the optimal parameters of stimulation to modulate motor function by all of these techniques are not known. The purpose of this protocol is to explore within safe guidelines, the effects of different stimulation parameters on motor cortical function, on oscillatory brain dynamics measured with magnetoencephalography (MEG) and electroencephalography (EEG), on eye movements, and on fMRI activation. In addition, this protocol will be used to train new fellows coming to NINDS Human Cortical Physiology Section (HCPS) in the use of TMS, tDCS, tACS and C/PNS techniques.

We expect that information emerging from these studies will allow us to 1) optimize experimental protocols or stimulation parameters to collect pilot data in healthy volunteer for future patient-oriented hypothesis-driven protocols,2)to collect pilot data for power analysis for future patient-oriented hypothesis driven protocols, and 3) to train new fellows in the use of these different methods.

Study Population

Up to 1500 healthy volunteers, age 18 and older.

Design

Healthy volunteers will receive one or more of the following types of stimulation alone or in combination: (1) single- and paired-pulse TMS with inter-stimulus intervals of greater than 1s and up to 20s and intensities of up to 100% of stimulator output; (2) 1 Hz TMS for up to 30mins and up to 115% of resting motor threshold (RMT) intensity; (3) tDCS applied at an intensity of up to 4 mA for a duration of up to 60mins, as long the total charge does not exceed 7.2 C; (4) tACS applied at a peak-to-peak intensity of up to 4 mA for a duration of up to 60 minutes, minutes, as long the total charge does not exceed 7.2 C; (5) C/PNS applied alone with intensities below 130% of the peripherally-elicited-motor-threshold for up to 2 hours, or intensities up to 300% of sensory threshold when C/PNS is paired with TMS. All of these parameters of stimulation and procedures have safely been used as previously reported in the literature. Sham stimulations will be delivered for each modality as scientifically needed. Some substudies may involve recording of behavior or brain activity only (such as behavioral testing, MRI, and MEG) if brain stimulation targets are unknown. This information can help design future brain stimulation protocols.

Each subject may participate in up to 20 sessions. A single session may last no longer than 8 hours to allow for initial testing paradigm followed by retests or performing other components of the same substudy later in the day. Appropriate rest breaks and meal breaks will occur during long sessions. Subjects participate in one experimental session per day under this protocol. The 20 experimental sessions will be scheduled over a twenty-year period. CTDB is used to track the number of sessions per subject so it does not exceed 20 sessions. The AIs are responsible for entering the subjects/sessions into CTDB.

We will test the effects of these different forms of stimulation on motor cortical excitability, cognitive and motor behavioral tasks, and brain state measures derived from neuroimaging data (i.e. - MRI, fMRI, MEG and EEG). Stimulation may be applied before, after, or during physiological (i.e. motor evoked potentials, M-wave, F-wave, or H-Reflexes), neuroimaging or behavioral measures.

Under this protocol, we conduct:

Exploratory Sub-studies: These substudies are exploratory in nature and are conducted in order to develop information to generate better informed future hypotheses and/or power analyses. We have set an upper limit of 40 subjects per sub-study.

Hypothesis-Testing Sub-studies: Hypothesis-testing sub-studies are studies with specific hypotheses to be tested. These sub-studies undergo statistical and PIRC review after 6 subjects per group (e.g., after 12 subjects, 6 per arm, if two groups are studied), before additional subjects can be recruited. Together, the P.I. and PIRC will decide whether to continue the sub-study with more subjects without an amendment or whether an amendment or protocol would be necessary. A memo requesting a review of hypothesis-testing sub-studies for possible additional enrollment (beyond 6) will be sent to PIRC and the statistical reviewer.

This protocol is ...

Detailed Description

Objectives

Noninvasive stimulation of the central and peripheral nervous system, including transcranial magnetic stimulation (TMS), transcranial direct and alternating current stimulation (tDCS and tACS, respectively) and cutaneous/peripheral nerve stimulation (C/PNS) alone or paired with TMS (paired associative stimulation, PAS), has been increasingly used in the investigation of cortical plasticity and as a possible adjuvant strategy in neurorehabilitation. It has been shown that TMS, tDCS, tACS and C/PNS can modulate motor function in healthy volunteers, as well as in patients with neurological disorders such as stroke.

One fundamental problem is that the optimal parameters of stimulation to modulate motor function by all of these techniques are not known. The purpose of this protocol has been to explore within safe guidelines, the effects of different stimulation parameters on motor cortical function, on oscillatory brain dynamics measured with magnetoencephalography (MEG) and electroencephalography (EEG), on eye movements, and on fMRI activation. In addition, this protocol was used to train new fellows coming to NINDS Human Cortical Physiology Section (HCPS) in the use of TMS, tDCS, tACS and C/PNS techniques.

We expected that information emerging from these studies would allow us to 1) optimize experimental protocols or stimulation parameters to collect pilot data in healthy volunteers for future patient-oriented hypothesis-driven protocols, 2) to collect pilot data for power analysis for future patient-oriented hypothesis driven protocols, and 3) to train new fellows in the use of these different methods.

As instructed, we had stopped recruitment under this protocol at the time we were informed by the NIH IRB that they determined this to be a thematic protocol (August 6, 2019). The four specific aims addressed under this protocol are:

1. Aim 1. To identify resting behavioral and physiological substrates for neuromodulation of motor behavior

2. Aim 2. To identify task-dependent behavioral and physiological substrates for neuromodulation of motor behavior

3. Aim 3. To understand variability, rigor or/and reproducibility of brain stimulation effects.

As instructed, the purpose of this amendment is to request authorization to proceed with data analysis and publication. No new experiments will be carried out under this protocol.

Study Population

Up to 1500 healthy volunteers, age 18 and older.

Design

No new experiments will be carried out under this protocol. Previously, healthy volunteers received one or more of the following types of stimulation alone or in combination: (1) single- and paired-pulse TMS with inter-stimulus intervals of greater than 1s and up to 20s and intensities of up to 100% of stimulator output; (2) 1 Hz TMS for up to 30mins and up to 115% of resting motor threshold (RMT) intensity; (3) tDCS applied at an intensity of up to 4 mA for a duration of up to 60mins, as long the total charge does not exceed 7.2 C; (4) tACS applied at a peak-to-peak intensity of up to 4 mA for a duration of up to 60 minutes, as long the total charge does not exceed 7.2 C; (5) C/PNS applied alone with intensities below 130% of the peripherally-elicited-motor-threshold for up to 2 hours, or intensities up to 300% of sensory threshold when C/PNS is paired with TMS. All of these parameters of stimulation and procedures have safely been used as previously reported in the literature. Sham stimulations were delivered for each modality as scientifically needed. Some sessions included recording of behavior or brain activity (such as behavioral testing, MRI, and MEG) if brain stimulation targets were unknown. This information was used to inform the design of brain stimulation protocols.

Each subject was able to participate in up to one experimental session per day, and up to 20 total sessions over a twenty year period under this protocol. A single session lasted no longer than 8 hours. Appropriate rest breaks and meal breaks occured during long sessions. CTDB was used to track the number of sessions per subject to ensure they did not exceed 20 sessions. Protocol AIs were responsible for entering the subjects/sessions into CTDB.

We previously tested the effects of different forms of stimulation on motor cortical excitability, cognitive and motor behavioral tasks, and brain state measures derived from neuroimaging data (i.e. - MRI, fMRI, MEG and EEG). Stimulation was be applied before, after, or during physiological (i.e. motor evoked potentials, M-wave, F-wave, or H-Reflexes), neuroimaging or behavioral measures.

Outcome Measures

No new outcome measures are proposed. Changes in motor cortical excitability were previously measured as the change in the average peak-to-peak amplitude of a motor evoked potential (MEP) as measured with EMG. Neuroimaging measures included changes in oscillatory brain activity power as measured with EEG or MEG, changes in BOLD fMRI activation or changes in functional connectivity (i.e. covarying fluctuations in BOLD or spectral power across the brain). Behavioral outcome measures focused on changes in performance as a function of learning, or as a function of applied brain stimulation.

Recruitment & Eligibility

Status
COMPLETED
Sex
All
Target Recruitment
1007
Inclusion Criteria

Not provided

Exclusion Criteria

Not provided

Study & Design

Study Type
INTERVENTIONAL
Study Design
PARALLEL
Arm && Interventions
GroupInterventionDescription
3atACSHealthy Volunteers
4aCPNSHealthy Volunteers
2tDCSHealthy Volunteers
2atDCSHealthy Volunteers
1aTMSHealthy Volunteers
3tACSHealthy Volunteers
4CPNSHealthy Volunteers
1TMSHealthy Volunteers
Primary Outcome Measures
NameTimeMethod
To identify task-dependent behavioral and physiological substrates for neuromodulation of motor behavior Aimin data analysis

in data analysis

To understand variability, rigor or/and reproducibility of brain stimulation effects.in data analysis

in data analysis

To identify resting behavioral and physiological substrates for neuromodulation of motor behavior Aimin data analysis

in data analysis

Secondary Outcome Measures
NameTimeMethod

Trial Locations

Locations (1)

National Institutes of Health Clinical Center

🇺🇸

Bethesda, Maryland, United States

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