Measuring the Latency Connectome in the Central Nervous Systems Using Neuroimaging and Neurophysiological Techniques

Completed

• Conditions: Healthy Volunteers
• Interventions: Device: TMS; Device: MRI

• Registration Number: NCT03223636
• Lead Sponsor: National Institute of Neurological Disorders and Stroke (NINDS)

Brief Summary

Background:

Little is known about the time it takes for nerve signals to go from one area of the brain to another. Using advanced methods for brain research, researchers want to look at the time it takes to send messages between different brain areas. They also want to develop new tests.

Objectives:

To develop tests to measure the sizes of nerve fibers in the peripheral nerve system and in the brain. Also to find out the different speeds that information travels in nerve fibers.

Eligibility:

Healthy, right-handed people ages 18-70

Design:

Participants will be screened with medical history and a physical exam.

Participants will have up to 7 visits depending on the tests they choose. Visits last about 2-4 hours and may involve the following tests:

* Physical exam

* Urine tests

* Magnetic resonance imaging (MRI). Participants lie on a table that slides into a scanner. They will be in the scanner for up to 1 hour. For some scans, sensors are placed on the skin. They will get earplugs for loud noises.

* Small, sticky pads on the skin will electrically stimulate nerves in the forearm.

* Transcranial magnetic stimulation (TMS). A wire coil will be held to the scalp. A brief electrical current passes through the coil to affect brain activity.

* Electroencephalography. TMS will be given to the brain. Small electrodes on the scalp measure brain activity. Participants may do small tasks.

* Electrodes on the scalp will send an electrical current to the brain.

* A cone with magnetic detectors will be lowered onto the head to record brain activity. Participants will perform various tasks.

Detailed Description

Objectives:

We are proposing the development and assessment of an MRI and neurophysiology-based experimental and theoretical framework to measure peripheral and intercortical latencies and latency distributions in the living human. This entails combining and integrating neurophysiological and neuroimaging so that we can eventually generate latency and latency distribution matrices for central nervous systems (CNS) using neuroimaging techniques. Neuroimaging and neurophysiological studies in the peripheral nerve system (PNS) will provide essential data for proof-of-concept and for validating this approach.

Study Population:

We intend to study up to 40 healthy volunteers. Each subject will complete 1 to 8 visits involving various measurements with different neuroimaging and neurophysiological techniques.

Design:

This is an exploratory study that consists of different measurements using multimodal neurophysiological and neuroimaging techniques. Diffusion magnetic resonance imaging (MRI), mean apparent propagator (MAP)-MRI, AxCaliber MRI, multiple pulsed field gradient MRI, and resting-state functional MRI will be performed in 1 to 2 visits. In another 1 to 5 visits, we will use neurophysiological techniques including peripheral electrical stimulation, transcranial magnetic stimulation (TMS), electroencephalography (EEG) and magnetoencephalography (MEG) with various experimental paradigms to correlate with the latency and latency distribution matrices generated by neuroimaging techniques. All these techniques are exploratory and success or failure of one of them does not have immediate implications for the others.

Outcome Measures:

We will measure average axon diameter (AAD) and axon diameter distributions (ADD), as well as compute white matter pathway trajectories using diffusion MRI and MAP-MRI data, and use resting-state functional MRI to measure blood oxygenation level-dependent signal to identify salient cortical regions in which many of these tracts terminate. For proof-of-concept measurements in the PNS, compound muscle action potential or surface compound nerve action potential on the skin will be measured following peripheral nerve stimulation. For TMS , we will measure motor evoked potential (MEP) amplitude. Cortical evoked potential in different cortical areas induced by TMS will be measured in EEG recordings. We will study millisecond coupling delays between different cortical areas with MEG. We will measure time and phase delays as computed from whole-head signals in the subject. Coherence analysis for cortical activity with EEG and MEG recordings between different cortical areas will be performed. We will attempt to correlate MRI measurements with the individual physiological measurements.

Study Timeline

• Study First Submitted: 2017-07-19
• Study First Submitted QC: 2017-07-19
• Study First Posted: 2017-07-21
• Study Start: 2017-10-02
• Primary Completion: 2020-11-12
• Study Completion: 2021-02-26
• Status Verified: 2021-03
• Last Update Submitted: 2021-04-29
• Last Update Posted: 2021-04-30

Recruitment & Eligibility

• Status: COMPLETED
• Sex: All
• Target Recruitment: 16

Inclusion Criteria

Not provided

Exclusion Criteria

Not provided

Study & Design

• Study Type: OBSERVATIONAL
• Study Design: Not specified

Arm && Interventions

Group	Intervention	Description
Healthy Volunteers	TMS	Healthy Volunteers
Healthy Volunteers	MRI	Healthy Volunteers

Primary Outcome Measures

Name	Time	Method
measure motor evoked potential (MEP) amplitude	throughout	For TMS, we will measure motor evoked potential (MEP) amplitude

Trial Locations

Locations (1)

National Institutes of Health Clinical Center; 🇺🇸 Bethesda, Maryland, United States