Spinal Cord Associative Plasticity Study

NCT ID: NCT05163639

Last Updated: 2025-05-01

Basic Information

• Recruitment Status: RECRUITING
• Clinical Phase: EARLY_PHASE1
• Total Enrollment: 92 participants
• Study Classification: INTERVENTIONAL
• Study Start Date: 2021-09-10
• Study Completion Date: 2026-06-30

Brief Summary

Spinal cord associative plasticity (SCAP) is a combined cortical and spinal electrical stimulation technique developed to induce recovery of arm and hand function in spinal cord injury.

The proposed study will advance understanding of SCAP, which is critical to its effective translation to human therapy. The purpose of the study is to:

1. Determine whether signaling through the spinal cord to the muscles can be strengthened by electrical stimulation.

2. Improve our understanding of the spinal cord and how it produces movement.

3. Determine whether spinal surgery to relieve pressure on the spinal cord can improve its function.

Aim 1 is designed to advance mechanistic understanding of spinal cord associative plasticity (SCAP).

Aim 2 will determine whether SCAP increases spinal cord excitability after the period of repetitive pairing. In rats, SCAP augments muscle activation for hours after just 5 minutes of paired stimuli.

Whereas Aims 1 and 2 focused on the effects of paired stimulation in the context of uninjured spinal cord, Aim 3 assesses whether paired stimulation can be effective across injured cord segments. Aim 3 will incorporate the experiments from Aim 1 and 2 but in people with SCI, either traumatic or pre-operative patients with myelopathy in non-invasive experiments, or targeting myelopathic segments in intraoperative segments.

Detailed Description

For people with cervical spinal cord injury (SCI), regaining hand function is their highest priority. Currently there are no effective treatments for people living with paralysis or profound weakness after SCI. The goal of this project is to translate a promising therapy for improving arm and hand function after partial spinal cord injury to humans. The approach promotes repair of residual brain to spinal cord connections using combined motor cortex and spinal cord stimulation.

The direct brain to spinal cord connection is critical for skilled hand movement in health, and for the loss of movement after injury. After spinal cord injury, many nerve connections for movement are preserved. These connections can be strengthened by electrical stimulation.

The investigator has previously demonstrated that pairing brain and spinal cord stimulation strengthens spinal connections in rats. But it is unknown whether this is also applicable in humans. This study is designed to test this in people undergoing spine surgery for pain or decreased movement as well as non-invasively in people with traumatic spinal cord injury. There are three main goals of this project. First, the investigator will stimulate brain and spinal cord (intra-operatively and non-invasively) to try to study the influence of the timing of pairing brain and spinal cord stimulation. Second, the investigator will study how repeating the optimal timing (spinal cord associative plasticity; SCAP) will influence muscle responses over a longer period of time when relatively uninjured parts of the spinal cord are targeted. Finally, the investigator will study how the influence of this protocol changes when injured parts of the cord are targeted. Stimulation of brain and spinal cord intra-operatively will be performed with the same devices that maintain safety during the surgery, while non-invasive stimulation will be performed with non-significant risk devices.

Participants: Uninjured volunteers, individuals with chronic (> 1 year) cervical SCI, and individuals with cervical myelopathy or radiculopathy requiring clinically indicated decompressive surgery will be recruited. SCI and myelopathy participants will have partially retained motor function in the hand, scoring 1-4 (out of 5) on manual muscle testing of finger extension, finger flexion, or finger abduction in left or right hand. Participants will also require detectable F-wave responses of the left or right abductor pollicis brevis (APB) to median nerve stimulation and/or first dorsal interosseous muscle (FDI) to ulnar nerve stimulation.

Conditions

Cervical Spinal Cord Injury; Tetraplegia/Tetraparesis; Cervical Myelopathy

Study Design

• Allocation Method: NON_RANDOMIZED
• Intervention Model: CROSSOVER
• Primary Study Purpose: BASIC_SCIENCE
• Blinding Strategy: NONE

Study Groups

1. Uninjured participants - Immediate and lasting effects of non-invasive paired stimulation

Participants will take part in the following to examine the immediate effects of combining cortical and spinal stimulation: A) Non-invasive pairing of cortical and spinal stimulation; B) Non-invasive repeated pairing of cortical and spinal stimulation (SCAP).

Group Type: EXPERIMENTAL

Non-invasive pairing of cortical and spinal stimulation

Intervention Type: PROCEDURE

Transcranial magnetic stimulation (TMS) threshold, Transcutaneous spinal cord stimulation (TSCS) threshold, and peripheral and central motor conduction times will be determined. In the active intervention, two TMS pulse intensities will be tested: 90% and 120% of motor threshold. Two conditioning TSCS pulse intensities will be tested: 50% and 90% of response threshold. Single TSCS pulses will be delivered timed to arrive in the cervical spinal cord at a range of intervals from 30ms before to 30ms after the TMS pulse. The control conditions will include TMS only TSCS only and non-convergent pairing latency pairing stimulation.

Non-invasive repeated pairing of cortical and spinal stimulation (SCAP)

Intervention Type: PROCEDURE

Thresholds will be determined as above. Immediately prior to repetitive pairing, a set of 12 TMS pulses will be delivered at 120% threshold to measure the baseline cortical MEP. Likewise, a set of 12 TSCS pulses will be delivered at 120% of threshold to establish the baseline spinal MEP. For each session, baseline maximal pinch dynamometry will be determined. Immediately after the SCAP protocol is completed, response to TMS, TSCS, and maximal pinch dynamometry will be measured again every 10 minutes over the subsequent hour. The control conditions will include TMS only TSCS only and non-convergent pairing latency pairing stimulation.

2. Intraoperative participants - Immediate effects of paired stimulation

Participants will take part in the following if they have been scheduled for a clinically indicated cervical surgery to examine the immediate effects of combining cortical and spinal stimulation: A) Non-invasive pairing of cortical and spinal stimulation; B) Intraoperative pairing of cortical and spinal stimulation.

Group Type: EXPERIMENTAL

Non-invasive pairing of cortical and spinal stimulation

Intervention Type: PROCEDURE

Transcranial magnetic stimulation (TMS) threshold, Transcutaneous spinal cord stimulation (TSCS) threshold, and peripheral and central motor conduction times will be determined. In the active intervention, two TMS pulse intensities will be tested: 90% and 120% of motor threshold. Two conditioning TSCS pulse intensities will be tested: 50% and 90% of response threshold. Single TSCS pulses will be delivered timed to arrive in the cervical spinal cord at a range of intervals from 30ms before to 30ms after the TMS pulse. The control conditions will include TMS only TSCS only and non-convergent pairing latency pairing stimulation.

Intraoperative pairing of cortical and spinal stimulation

Intervention Type: PROCEDURE

The surgeon will position spinal cord electrodes on the epidural surface one level rostral (typically C4/C5) to the site of myelopathy. Spinal and cortical thresholds will be determined. Investigator will then test the immediate effects of paired stimulation by stimulating the cortex at 120% of threshold and the spinal cord at 90% of threshold at various latencies relative to the time of synchronous convergence. The control intervention will include cortical only (120%) spinal only (90%) and non-convergent latency pairing stimulation.

3. Intraoperative participants - Lasting effects of SCAP

Participants will take part in the following if they have been scheduled for a clinically indicated cervical surgery, to examine the lasting effects of repeated cortical and spinal stimulation: A) Non-invasive repeated pairing of cortical and spinal stimulation (SCAP); B) Intraoperative repeated pairing of cortical and spinal stimulation (SCAP).

Group Type: EXPERIMENTAL

Non-invasive repeated pairing of cortical and spinal stimulation (SCAP)

Intervention Type: PROCEDURE

Thresholds will be determined as above. Immediately prior to repetitive pairing, a set of 12 TMS pulses will be delivered at 120% threshold to measure the baseline cortical MEP. Likewise, a set of 12 TSCS pulses will be delivered at 120% of threshold to establish the baseline spinal MEP. For each session, baseline maximal pinch dynamometry will be determined. Immediately after the SCAP protocol is completed, response to TMS, TSCS, and maximal pinch dynamometry will be measured again every 10 minutes over the subsequent hour. The control conditions will include TMS only TSCS only and non-convergent pairing latency pairing stimulation.

Intraoperative repeated pairing of cortical and spinal stimulation (SCAP)

Intervention Type: PROCEDURE

Intraoperative: Spinal and cortical thresholds will be determined. Immediately prior to repetitive pairing, a set of 12 baseline cortical pulses and 12 baseline spinal pulses will be delivered at 120% threshold. SCAP protocol will be applied, both of which have been successful at inducing lasting effects in the rat. After pairing, cortical stimulation at 120% of threshold and spinal cord stimulation at 120% threshold will be repeated every 10 minutes for the duration of surgery. In a subset of patients repeated pairing will be conducted with a latency that investigator does not expect will induce SCAP, or with electrodes placed over the ventral epidural surface. The control intervention will include repeated pairing at a non-convergent latency, as well as pairing of cortical stimulation with ventral epidural stimulation.

4. Chronic cervical SCI participants - Lasting effects of non-invasive SCAP

Participants with chronic cervical SCI will take part in the following, to examine the lasting effects of repeated cortical and spinal stimulation: A) Non-invasive repeated pairing of cortical and spinal stimulation (SCAP).

Group Type: EXPERIMENTAL

Non-invasive repeated pairing of cortical and spinal stimulation (SCAP)

Intervention Type: PROCEDURE

Thresholds will be determined as above. Immediately prior to repetitive pairing, a set of 12 TMS pulses will be delivered at 120% threshold to measure the baseline cortical MEP. Likewise, a set of 12 TSCS pulses will be delivered at 120% of threshold to establish the baseline spinal MEP. For each session, baseline maximal pinch dynamometry will be determined. Immediately after the SCAP protocol is completed, response to TMS, TSCS, and maximal pinch dynamometry will be measured again every 10 minutes over the subsequent hour. The control conditions will include TMS only TSCS only and non-convergent pairing latency pairing stimulation.

5. Intraoperative participants - Lasting effects of SCAP at or below myelopathic region

Participants will take part in the following if they have been scheduled for a clinically indicated cervical surgery, to examine the lasting effects of repeated cortical and spinal stimulation: A) Non-invasive repeated pairing of cortical and spinal stimulation (SCAP); B) Intraoperative repeated pairing of cortical and spinal stimulation (SCAP) at or below myelopathic region.

Group Type: EXPERIMENTAL

Non-invasive repeated pairing of cortical and spinal stimulation (SCAP)

Intervention Type: PROCEDURE

Thresholds will be determined as above. Immediately prior to repetitive pairing, a set of 12 TMS pulses will be delivered at 120% threshold to measure the baseline cortical MEP. Likewise, a set of 12 TSCS pulses will be delivered at 120% of threshold to establish the baseline spinal MEP. For each session, baseline maximal pinch dynamometry will be determined. Immediately after the SCAP protocol is completed, response to TMS, TSCS, and maximal pinch dynamometry will be measured again every 10 minutes over the subsequent hour. The control conditions will include TMS only TSCS only and non-convergent pairing latency pairing stimulation.

Intraoperative repeated pairing of cortical and spinal stimulation (SCAP) at or below myelopathic region

Intervention Type: PROCEDURE

As per the intervention 'Intraoperative repeated pairing of cortical and spinal stimulation (SCAP)' targeted at or below myelopathic region.

Interventions

Non-invasive pairing of cortical and spinal stimulation

Transcranial magnetic stimulation (TMS) threshold, Transcutaneous spinal cord stimulation (TSCS) threshold, and peripheral and central motor conduction times will be determined. In the active intervention, two TMS pulse intensities will be tested: 90% and 120% of motor threshold. Two conditioning TSCS pulse intensities will be tested: 50% and 90% of response threshold. Single TSCS pulses will be delivered timed to arrive in the cervical spinal cord at a range of intervals from 30ms before to 30ms after the TMS pulse. The control conditions will include TMS only TSCS only and non-convergent pairing latency pairing stimulation.

Intervention Type: PROCEDURE

Intraoperative pairing of cortical and spinal stimulation

The surgeon will position spinal cord electrodes on the epidural surface one level rostral (typically C4/C5) to the site of myelopathy. Spinal and cortical thresholds will be determined. Investigator will then test the immediate effects of paired stimulation by stimulating the cortex at 120% of threshold and the spinal cord at 90% of threshold at various latencies relative to the time of synchronous convergence. The control intervention will include cortical only (120%) spinal only (90%) and non-convergent latency pairing stimulation.

Intervention Type: PROCEDURE

Non-invasive repeated pairing of cortical and spinal stimulation (SCAP)

Thresholds will be determined as above. Immediately prior to repetitive pairing, a set of 12 TMS pulses will be delivered at 120% threshold to measure the baseline cortical MEP. Likewise, a set of 12 TSCS pulses will be delivered at 120% of threshold to establish the baseline spinal MEP. For each session, baseline maximal pinch dynamometry will be determined. Immediately after the SCAP protocol is completed, response to TMS, TSCS, and maximal pinch dynamometry will be measured again every 10 minutes over the subsequent hour. The control conditions will include TMS only TSCS only and non-convergent pairing latency pairing stimulation.

Intervention Type: PROCEDURE

Intraoperative repeated pairing of cortical and spinal stimulation (SCAP)

Intraoperative: Spinal and cortical thresholds will be determined. Immediately prior to repetitive pairing, a set of 12 baseline cortical pulses and 12 baseline spinal pulses will be delivered at 120% threshold. SCAP protocol will be applied, both of which have been successful at inducing lasting effects in the rat. After pairing, cortical stimulation at 120% of threshold and spinal cord stimulation at 120% threshold will be repeated every 10 minutes for the duration of surgery. In a subset of patients repeated pairing will be conducted with a latency that investigator does not expect will induce SCAP, or with electrodes placed over the ventral epidural surface. The control intervention will include repeated pairing at a non-convergent latency, as well as pairing of cortical stimulation with ventral epidural stimulation.

Intervention Type: PROCEDURE

Intraoperative repeated pairing of cortical and spinal stimulation (SCAP) at or below myelopathic region

As per the intervention 'Intraoperative repeated pairing of cortical and spinal stimulation (SCAP)' targeted at or below myelopathic region.

Intervention Type: PROCEDURE

Eligibility Criteria

Inclusion Criteria

(All participants)

• Age between 18-80 years.
• Must have stable prescription medication for 30 days prior to screening
• Must be able to: abstain from alcohol, smoking and caffeine consumption on the day of each experiment; abstain from recreational drugs for the entirety of the study; commit to study requirements (i.e., 7 visits); provide informed consent.

(Able-bodied participants)

• No known central or peripheral neurological disease or injury.

(SCI participants - including patients scheduled for intraoperative procedures)

• Score of 1-4 (out of 5) on manual muscle testing of finger extension, finger flexion, or finger abduction in left or right hand.

• Clinical indication for cervical spine surgery.

Exclusion Criteria

(All participants)

• Personal or extensive family history of seizures;
• Ventilator dependence or patent tracheostomy site;
• Use of medications that significantly lower seizure threshold, such as amphetamines, neuroleptics, dalfampridine, and bupropion;
• History of stroke, brain tumor, brain abscess, or multiple sclerosis;
• History of moderate or severe head trauma (loss of consciousness for greater than one hour or evidence of brain contusion or hemorrhage or depressed skull fracture on prior imaging);
• History of implanted brain/spine/nerve stimulators, aneurysm clips, ferromagnetic metallic implants in the head (except for inside mouth); cochlear implants; cardiac pacemaker/defibrillator; intracardiac lines; currently increased intracranial pressure; or other contraindications to brain or spine stimulation;
• Significant coronary artery or cardiac conduction disease; recent history of myocardial infarction and heart failure with an ejection fraction of less than 30% or with a New York Heart Association Functional Classification of Class III or IV;
• Recent history (within past 6 months) of recurrent autonomic dysreflexia, defined as a syndrome of sudden rise in systolic pressure greater than 20 mm Hg or diastolic pressure greater than 10 mm Hg, without rise in heart rate, accompanied by symptoms such as headache, facial flushing, sweating, nasal congestion, and blurry vision (this will be closely monitored during all screening and testing procedures);
• History of significant hearing problems;
• History of bipolar disorder;
• History of suicide attempt;
• Active psychosis;
• Recent history (>1 year) of chemical substance dependency or significant psychosocial disturbance;
• Heavy alcohol consumption (greater than equivalent of 5oz of liquor) within previous 48 hours;
• Open skin lesions over the face, neck, shoulders, or arms;
• Pregnancy; and
• Unsuitable for study participation as determined by study physician.

INTRA-OPERATIVE

(For experiments involving cortical stimulation)

• Epilepsy;
• A history of skull surgery with metal implants;
• Cochlear implants;
• Patients with aneurysm stents in neck or brain blood vessels;
• Evidence of skull shrapnel; (For experiments involving spinal cord stimulation)
• Stimulation devices in the neck or chest (e.g., vagal nerve stimulation, cardiac patients with pacemakers)

• Minimum Eligible Age: 18 Years
• Maximum Eligible Age: 80 Years
• Eligible Sex: ALL
• Accepts Healthy Volunteers: Yes

Sponsors

National Institute of Neurological Disorders and Stroke (NINDS)

NIH

Sponsor Role: collaborator

Weill Medical College of Cornell University

OTHER

Sponsor Role: collaborator

Bronx Veterans Medical Research Foundation, Inc

OTHER

Sponsor Role: collaborator

Columbia University

OTHER

Sponsor Role: lead

Responsible Party

Jason Carmel

Associate Professor

Responsibility Role: PRINCIPAL_INVESTIGATOR

Principal Investigators

Jason B Carmel, M.D., Ph.D.

Role: PRINCIPAL_INVESTIGATOR

Columbia University

Locations

Bronx Veterans Medical Research Foundation, Inc

New York, New York, United States

Site Status: RECRUITING

Columbia University Irving Medical Center

New York, New York, United States

Site Status: RECRUITING

Weill Cornell Medicine

New York, New York, United States

Site Status: RECRUITING

Countries

United States

Central Contacts

Jason B Carmel, M.D., Ph.D.

Role: CONTACT

jbc28@cumc.columbia.edu

917-301-1882

Noam Y Harel, M.D., Ph.D.

Role: CONTACT

noam.harel@mssm.edu

212-241-7317

Facility Contacts

Noam Y Harel, M.D., Ph.D.

Role: primary

Noam.harel@va.gov

718-584-9000 ext. 1742

Jason B Carmel, MD, PhD

Role: primary

jbc28@cumc.columbia.edu

212-305-6616

Michael S Virk, M.D., Ph.D.

Role: primary

miv2010@med.cornell.edu

(503) 494-4723

Other Identifiers

1R01NS124224-01

Identifier Type: NIH

Identifier Source: secondary_id

View Link

AAAT6563

Identifier Type: -

Identifier Source: org_study_id