Condition
Location

8 Transcutaneous Spinal Cord Stimulation Trials Near You

Power is an online platform that helps thousands of patients discover FDA-reviewed trials every day. Every trial we feature meets safety and ethical standards, giving patients an easy way to discover promising new treatments in the research stage.

Learn More About Power
No Placebo
Highly Paid
Stay on Current Meds
Pivotal Trials (Near Approval)
Breakthrough Medication
The purpose of this study is to deepen our understanding of children who have a cervical spinal cord injury obtained in utero or at birth and examine the effects of tailored activity-based recovery training (ABRT) in combination with transcutaneous spinal cord stimulation (scTS). This is a within subjects, pre-post design study. Neurophysiological, sensorimotor, and autonomic assessments will occur pre, interim, and post 40 sessions of ABRT in conjunction with scTs.
No Placebo Group

Trial Details

Trial Status:Enrolling By Invitation
Trial Phase:Unphased
Age:3 - 8
Sex:All

6 Participants Needed

The purpose of this research study is to assess the effects of receiving transcutaneous spinal stimulation while performing walking exercises compared to completing walking exercises without spinal stimulation for individuals with hemiplegic TBI.

Trial Details

Trial Status:Not Yet Recruiting
Trial Phase:Unphased
Age:18 - 65
Sex:All

30 Participants Needed

This study will help the investigators better understand the changes in short-term excitability and long-term plasticity of corticospinal, reticulospinal and spinal neural circuits and how the changes impact the improvements of spinal cord stimulation (SCS) mediated motor function.
No Placebo Group

Trial Details

Trial Status:Recruiting
Trial Phase:Unphased
Age:16 - 65
Sex:All

120 Participants Needed

The goal of this clinical trial is to determine whether people with paralysis due to a spinal cord injury can benefit from breathing short intermittent bouts of air with low oxygen (O2) combined with slightly higher levels of carbon dioxide (CO2), interspaced by breathing room air. The technical name for this therapeutic air mixture is 'acute intermittent hypercapnic-hypoxia,' abbreviated as AIHH. Following exposure to the gas mixture, participants will receive non-invasive electrical stimulation to the spinal cord paired with specific and targeted exercise training. The main question this trial aims to answer is: Can the therapeutic application of AIHH, combined with non-invasive electrical stimulation to the spinal cord plus exercise training, increase the strength of muscles involved in breathing and hand function in people with paralysis due to a spinal cord injury? Participants will be asked to attend a minimum of five study visits, each separated by at least a week. During these visits, participants will be required to: * Answer basic questions about their health * Receive exposure to the therapeutic air mixture (AIHH) * Undergo non-invasive spinal electrical stimulation * Complete functional breathing and arm strength testing * Undergo a single blood draw * Provide a saliva sample Researchers will compare the results of individuals without a spinal cord injury to those of individuals with a spinal cord injury to determine if the effects are similar.

Trial Details

Trial Status:Recruiting
Trial Phase:Unphased
Age:18 - 65
Sex:All

29 Participants Needed

TSCS for Spinal Cord Injury

New York, New York
This project will focus on a novel approach to stabilizing blood pressure (BP) during inpatient rehabilitation after acute SCI. After SCI, people have unstable blood pressure, ranging from too low (orthostatic hypotension) to too high (autonomic dysreflexia). Unstable BP often interferes with performing effective physical rehabilitation after SCI. A critical need exists for the identification of safe, practical and effective treatment options that stabilize BP after traumatic SCI. Transcutaneous Spinal Cord Stimulation (TSCS) has several advantages over pharmacological approaches: (1) does not exacerbate polypharmacy, (2) can be activated/deactivated rapidly, and (3) can be applied in synergy with physical exercise. The study team is asking the key question: "What if applying TSCS earlier after injury could prevent the development of BP instability?" To facilitate adoption of TSCS for widespread clinical use, the study team plans to map and develop a parameter configuration that will result in an easy to follow algorithm to maximize individual benefits, while minimizing the burden on healthcare professionals. This project will provide the foundational evidence to support the feasible and safe application of TSCS in the newly injured population, thereby overcoming barriers to engagement in prescribed inpatient rehabilitation regimens that are imposed by BP instability.
No Placebo Group

Trial Details

Trial Status:Recruiting
Trial Phase:Unphased
Age:18 - 89
Sex:All

50 Participants Needed

It has been demonstrated that the human lumbosacral spinal cord can be neuromodulated with epidural (ESS) and transcutaneous (TSS) spinal cord stimulation to enable recovery of standing and volitional control of the lower limbs after complete motor paralysis due to spinal cord injury (SCI). The work proposed herein will examine and identify distinct electrophysiological mechanisms underlying transcutaneous spinal stimulation (TSS) and epidural spinal stimulation (ESS) to define how these approaches determine the ability to maintain self-assisted standing after SCI.

Trial Details

Trial Status:Recruiting
Trial Phase:Unphased
Age:22 - 60
Sex:All

60 Participants Needed

Transcutaneous electrical stimulation (tcES) of the spinal cord has shown great promise in restoring upper extremity function after spinal cord injury (SCI). More recently, the use of invasive, epidural electrical stimulation of the spinal cord has also demonstrated promise in restoring upper extremity function post-stroke. However, the effect of stimulation parameters such as electrode configuration and stimulation frequency on excitability of the nervous system remains unknown preventing the opportunity to fully exploit this noninvasive stimulation paradigm. Additionally, the utility of noninvasive tcES in the stroke population remains unexplored. This project utilizes a comprehensive set of neurophysiological techniques, in combination with carefully chosen motor tasks, to directly link and assess the effects of stimulation parameters on neural excitability and upper extremity function during and following the delivery of cervical tcES in individuals with SCI and stroke. The fundamental knowledge gained from this project will ultimately improve the implementation of this novel and non-invasive neuromodulatory tool through an improved understanding of how tcES can facilitate recovery of function.
No Placebo Group
Pivotal Trial (Near Approval)

Trial Details

Trial Status:Recruiting
Trial Phase:Phase 2, 3
Age:18 - 75
Sex:All

30 Participants Needed

Spinal cord injury (SCI) can make it hard for the body to self-regulate some of its automatic functions like blood pressure, breathing, and heart rate. This can also make it hard for those living with SCI to exercise or complete their usual daily activities. The goal of this randomized trial is to test combinatory therapy of moderate arm-crank exercise paired with non-invasive transcutaneous spinal cord stimulation (tSCS) for cardiovascular recovery in adults aged 21-65 following chronic motor-complete spinal cord injury (SCI) at or above the thoracic sixth spinal segment (≥T6). The main questions the study aims to answer are: * Conduct tSCS mapping to determine the most effective location and stimulation intensity for BP control in individuals with motor-complete SCI ≥ T6. * Evaluate the effects 8 weeks of targeted tSCS paired with arm-crank exercise compared to sham stimulation with exercise on improving cardiovascular function in individuals with motor-complete SCI ≥T6. * Evaluate the dosage-response of 8 weeks vs. 16 weeks of targeted tSCS paired with arm-crank exercise on cardiovascular function in individuals with motor-complete SCI ≥T6. * Explore the mechanisms involved in cardiovascular recovery with long-term tSCS paired with arm-crank exercise. Participants will: * Receive either transcutaneous spinal cord stimulation or "sham" spinal cord stimulation while exercising on an arm-crank bicycle in the first 8 weeks. * Come in for approximately 60 visits over a 6-month period. This includes 2, 8-week periods where the investigators will ask participants to come in 3x per week for spinal cord stimulation and exercise. * During assessment visits the researchers will perform a variety of exams including a neurologic, cardiovascular, pulmonary, physical, and autonomic exam, and will ask questions about quality of life and functioning. Researchers will compare those who receive tSCS and do moderate arm-crank exercise to those who receive a sham stimulation and do moderate arm-crank exercise to see if tSCS is effective at improving cardiovascular and autonomic functioning in those with SCI.

Trial Details

Trial Status:Recruiting
Trial Phase:Unphased
Age:21 - 65
Sex:All

16 Participants Needed

Learn More About Power

Why We Started Power

We started Power when my dad was diagnosed with multiple myeloma, and I struggled to help him access the latest immunotherapy. Hopefully Power makes it simpler for you to explore promising new treatments, during what is probably a difficult time.

Bask
Bask GillCEO at Power
Learn More About Trials

Frequently Asked Questions

How much do clinical trials pay?
Each trial will compensate patients a different amount, but $50-100 for each visit is a fairly common range for Phase 2–4 trials (Phase 1 trials often pay substantially more). Further, most trials will cover the costs of a travel to-and-from the clinic.
How do clinical trials work?
After a researcher reviews your profile, they may choose to invite you in to a screening appointment, where they'll determine if you meet 100% of the eligibility requirements. If you do, you'll be sorted into one of the treatment groups, and receive your study drug. For some trials, there is a chance you'll receive a placebo. Across trials 30% of clinical trials have a placebo. Typically, you'll be required to check-in with the clinic every month or so. The average trial length is 12 months.
How do I participate in a study as a "healthy volunteer"?
Not all studies recruit healthy volunteers: usually, Phase 1 studies do. Participating as a healthy volunteer means you will go to a research facility several times over a few days or weeks to receive a dose of either the test treatment or a "placebo," which is a harmless substance that helps researchers compare results. You will have routine tests during these visits, and you'll be compensated for your time and travel, with the number of appointments and details varying by study.
What does the "phase" of a clinical trial mean?
The phase of a trial reveals what stage the drug is in to get approval for a specific condition. Phase 1 trials are the trials to collect safety data in humans. Phase 2 trials are those where the drug has some data showing safety in humans, but where further human data is needed on drug effectiveness. Phase 3 trials are in the final step before approval. The drug already has data showing both safety and effectiveness. As a general rule, Phase 3 trials are more promising than Phase 2, and Phase 2 trials are more promising than phase 1.
Do I need to be insured to participate in a medical study ?
Clinical trials are almost always free to participants, and so do not require insurance. The only exception here are trials focused on cancer, because only a small part of the typical treatment plan is actually experimental. For these cancer trials, participants typically need insurance to cover all the non-experimental components.
What are the newest clinical trials ?
Most recently, we added Spinal Stimulation for Traumatic Brain Injury, Spinal Cord Stimulation for Upper Extremity Function and Spinal Cord Stimulation + Arm Bike for Spinal Cord Injury to the Power online platform.