Clinical Research Directory

ExaStim Upper Limb Home Use Clinical Validation Study

This is a multi-center, observational, single-arm, 6-week home study to evaluate the safety and efficacy of transcutaneous spinal cord stimulation via the ExaStim system for 4 consecutive weeks used in the home setting for individuals with traumatic spinal cord injury. The study consists of a baseline evaluation and 1-week training period (Week 0), a 4-week stimulation period (Weeks 1-4), and a follow-up visit (Week 5), for a total expected duration of participation for each subject of six weeks.

Augmenting Rehabilitation Outcomes and Functional Neuroplasticity Using Epidural Stimulation of Cervical Spinal Cord

The goal of this study is to investigate the effects of cervical epidural spinal stimulation with upper extremity training. This is an investigational study. The device used for epidural spinal stimulation (ESS) to deliver spinal stimulation is called the CoverEdgeX 32 Surgical Lead system. This device is approved by the Food and Drug Administration (FDA) for the treatment of severe pain and to manage chronic pain when other treatments have not been effective. In this study, the device is considered an investigational device because it is not approved for use in the treatment of spinal cord injury

Spinal Stimulation for Upper Extremity Recovery in the Home

The purpose of this research is to evaluate the safety, feasibility, and tolerability of non-invasive spinal stimulation used in the home and/or community in combination with a functional home exercise program for the upper extremities (arm/hand function) as well as their combined impacts on changes in upper extremity function. The expected duration of participation in this study is about 31-33 hours over a 13-25-week period. Enrollees in this study will be randomly assigned to one of two groups: 1) upper extremity functional task-specific training combined with non-invasive transcutaneous spinal stimulation, or 2) waitlist control, which involves the same intervention, but with a 12-week delayed start. Participants complete initial testing (one time if in group one and three times \[at weeks 0, 8, and 12\] if in group two), 24 1-hour training sessions (2x/week in home with caregiver/companion support and 1x/week with research team in person or via video conference for 8 weeks), a post-treatment evaluation, and a final evaluation (4 weeks after post-treatment).

Improving Upper Extremity Function and Trunk Stability After Cervical Spinal Cord Injury (SCI)

Ninety-nine individuals meeting the study's inclusion/exclusion criteria will be enrolled in this study. The objective of this study is to evaluate three different therapeutic approaches to synergistically retrain functional movement patterns of the upper extremities in combination with trunk stabilization to promote neurologic and functional recovery after SCI. Each subject will complete 40 sessions of intervention. Subjects will also complete a Baseline Evaluation (week 0), Re-Evaluation (week 4), Post Treatment Evaluation (week 8), and a Follow-Up Evaluation (week 12).

Rebuilding Inter-limb Transfer in Cervical SCI

The purpose of this study in people living with cervical Spinal Cord Injury (SCI) is to examine the effects of paired neurostimulation (i.e., PCMS) combined with contralateral motor training on inter-limb transfer of ballistic motor and hand dexterity skills.

Nerve Transfer to Improve Function in High Level Tetraplegia

The goal of this observational study is to determine if nerve transfer surgeries improve upper extremity function and quality of life in patients with a high level cervical spinal cord injury. Participants will: * undergo standard of care pre- and post-op testing and study exams * complete pre- and post-questionnaires * undergo standard of care nerve transfer surgeries * follow-up with surgeon at 6/12/18/24/36 and potentially at 48 months * attend therapy at local therapist for up to 2 years postop.

Incomplete Cervical SCI Without Instability

A multicenter, international, prospective, observational case series patient cohort with incomplete cervical SCI without instability will be enrolled to obtain information and data that could inform the feasibility of administering a set of additional core and optional outcome assessments in cervical SCI patients to capture the aspects of neurologic impairment. Baseline, intraoperative, and postoperative characteristics, including demographics, injury details, treatment details, neurological assessments, gait and balance assessments and upper extremity assessments, will be recorded for adult patients.

Spinal Cord Neuromodulation for Spinal Cord Injury

This study is designed to assess the strategy of using spinal cord stimulation to improve the ability to move in spinal cord injured humans.

Connect-One: Early Feasibility Study of Connexus® Brain-Computer Interface (BCI)

The Connect-One Study is an early feasibility study to obtain preliminary device safety information for the Connexus Brain-Computer Interface (BCI). The Connexus BCI is intended to be used as: (1) an assistive communication device to decode imagined language correlates and speech for patients with impaired communication as a result of severe loss of voluntary motor control; and (2) to provide control of computer devices for individuals with severe loss of voluntary motor control of the upper extremity.

Precise Robotically IMplanted Brain-Computer InterfacE

The PRIME Study is a first-in-human early feasibility study to evaluate the initial clinical safety and device functionality of the Neuralink N1 Implant and R1 Robot device designs in participants with tetraparesis or tetraplegia. The N1 Implant is a skull-mounted, wireless, rechargeable implant connected to electrode threads that are implanted in the brain by the R1 Robot, a robotic electrode thread inserter.

Feasibility and Safety of a Combined Augmented Reality and Functional Electrical Stimulation System

Cervical spinal cord injury (cSCI) can result in substantial loss of upper-limb function, with associated socio-economic impact on affected individuals and the healthcare system. Evidence suggests that non-invasive neuromodulation such as functional electrical stimulation (FES) therapy can contribute to regaining upper-limb function, which is a top priority for this population. This pilot study will involve individuals with cSCI using a device that combines augmented reality (AR) and functional electrical stimulation (FES) for 20, one-hour sessions over a 10-week period. The sessions will include upper-limb rehabilitation where individuals will interact with different objects with the aid of the AR +FES system. The primary objective is to assess safety and feasibility, measured by the absence of serious adverse events and participants' ability to independently set up and use the system. Secondary objectives include adherence to the intervention and user feedback through structured interviews. Exploratory outcomes will examine preliminary efficacy using clinical measures such as the Spinal Cord Independence Measure (SCIM) and the Graded Redefined Assessment of Strength, Sensation and Prehension (GRASSP).

Feasibility of the BrainGate2 Neural Interface System in Persons With Tetraplegia (BG-Tablet-01)

People with brainstem stroke, advanced amyotrophic lateral sclerosis (ALS, also known as Lou Gehrig's disease), or other disorders can become unable to move or speak despite being awake and alert. In this project, the investigators seek to further translate knowledge about interpreting brain signals related to movement, and to further develop an intracortical brain-computer interface (iBCI) that could restore rapid and intuitive use of communication apps on tablet computers by people with paralysis.

Targeting Cervical Epidural Spinal Cord Stimulation for Functional Recovery

The proposed study seeks to understand how the cervical spinal cord should be stimulated after injury through short-term physiology experiments that will inform a preclinical efficacy trial. The purpose of this study is to determine which cervical levels epidural electrical stimulation (EES) should target to recruit arm and hand muscles effectively and selectively in spinal cord injury (SCI).

A User-friendly, Non-invasive Neuro-orthosis That Restores Volitionally Controlled Grasp Functions for SCI Survivors With Tetraplegia

The goal of this pilot clinical study is to investigate the NeuroLife EMG-FES Sleeve System, a closed-loop approach to functional electrical stimulation, in adults (n=12) with chronic (\>12 months) tetraplegia due to spinal cord injury. Briefly, the NeuroLife EMG-FES System is a completely non-invasive system (surface electrodes only, no implantable components) worn on the forearm which has up to 160 electrodes that can record electromyography (EMG), or muscle activity, and also electrically stimulate (FES) muscles. The main questions this study aims to answer are: 1) What is the safety, feasibility, and early efficacy of the NeuroLife EMG-FES system on upper extremity outcomes in chronic SCI survivors with tetraplegia, and 2) Can EMG be used as a biomarker of recovery over time in chronic SCI participants undergoing rehabilitation? Participants will complete an intensive, task-oriented rehabilitation protocol using the NeuroLife EMG-FES System (3x/week x 12 weeks) in an outpatient setting. We will assess functional outcomes using standardized clinical measures of hand and arm function at six timepoints.

VOICE: An Early Feasibility Study of a Precise Robotically Implanted Brain-Computer Interface for Communication Restoration

The VOICE Study is an early feasibility study to evaluate the initial clinical safety and efficacy of the N1 and R1 Systems device design concept in providing an ability to communicate. The Neuralink N1 Implant is intended to provide the ability to communicate to individuals with severe and irreversible speech production impairment. It is indicated for adults with neurological conditions of the central speech pathways who have impaired upper limb function. The N1 Implant is a skull-mounted, wireless, rechargeable implant connected to electrode threads that are implanted in the brain by the R1 Robot, a robotic electrode thread inserter.

GB-PRIME: An Early Feasibility Study of a Precise Robotically Implanted Brain-Computer Interface for the Control of External Devices

The GB-PRIME Study is an early feasibility study designed to assess the clinical safety and functionality of the Neuralink N1 Implant and R1 Robot. This study involves participants who have tetraparesis, tetraplegia, or a diagnosis that may lead to these conditions. The N1 Implant is a wireless, rechargeable device mounted on the skull, connected to electrode threads that are inserted into the brain by the R1 Robot, which is a robotic device specifically designed for this procedure.

Efficacy of a Brain-Computer Interface Controlled Functional Electrical Stimulation Therapy for Spinal Cord Injury Neurorehabilitation

The study's main goal is to determine the efficacy of a therapy with brain-computer interface controlled functional electrical stimulation for neurorehabilitation of spinal cord injury patients' upper limbs. For this purpose, a randomized controlled trial will be performed to compare the clinical and physiological effects of the brain-computer interface therapy with those of a sham intervention comprised by the application of functional electrical stimulation independently of brain-computer interface control.

UAE-PRIME: A Feasibility Study of a Precise Robotically Implanted Brain-Computer Interface for the Control of External Devices

The UAE-PRIME Study is a feasibility study designed to assess the initial clinical safety and functionality of the Neuralink N1 Implant and R1 Robot. This study involves participants who have tetraparesis, tetraplegia, or a diagnosis that may lead to these conditions. The N1 Implant is a wireless, rechargeable device mounted on the skull, connected to electrode threads that are inserted into the brain by the R1 Robot, which is a robotic device specifically designed for this procedure.

CAN-PRIME: Precise Robotically Implanted Brain-Computer Interface for the Control of External Devices

The CAN-PRIME Study is to test the safety and functionality of Neuralink's N1 Implant and R1 Robot in people who have difficulty moving their arms and legs (tetraparesis or tetraplegia). The N1 Implant is a small, wireless device placed in the skull. It connects to tiny threads inserted into the brain by the R1 Robot, which is a machine designed to carefully place these threads. This study will help researchers learn how well the implant and robot work and if they are safe for use.

Spinal Cord Associative Plasticity Study

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.

COMMAND Early Feasibility Study: Implantable BCI to Control a Digital Device for People With Paralysis

The Synchron motor neuroprosthesis (MNP) is intended to be used in subjects with severe motor impairment, unresponsive to medical or rehabilitative therapy and a persistent functioning motor cortex. The purpose of this research is to evaluate safety and feasibility. The MNP is a type of implantable brain computer interface which bypasses dysfunctional motor neurons. The device is designed to restore the transmission of neural signal from the cerebral cortex utilized for neuromuscular control of digital devices, resulting in a successful execution of non-mechanical digital commands.

Study of Individualized, Precise and Standardized Cervical Open-door Surgery for Cervical Spinal Stenosis

To evaluate the safety and effectiveness of individualized, precise and standardized open-door posterior cervical surgery through a single-center, exploratory clinical study, so as to provide a more reliable basis for the treatment of cervical spinal stenosis.

Neurostimulation for Respiratory Function After Spinal Cord Injury

The purpose of this research study is to learn more about the connections between the brain, nerves, and diaphragm after experiencing a cervical spinal cord injury (SCI).The main question it aims to answer is: Changes in respiratory function and recovery using stimulation and respiratory exercise training in spinal cord-injured individuals. Participants will complete a maximum of 55 study visits. They will be asked to complete about 40 treatment sessions which include multiple stimulation sessions over the scalp and neck, followed by about 60 minutes of respiratory training. Assessment sessions will be completed prior at baseline, after 20 sessions and after 40 sessions of study treatment.

Robot-assisted Vs. Conventional Occupational Therapy of the Upper Limb in Individuals with Cervical Spinal Cord Injury

The goal of this clinical trial is to learn the effects of robot-assisted therapy using the ArmeoSpring on upper limb function compared to conventional occupational therpay in individuals with cervical spinal cord injury (cSCI). The main questions it aims to answer are: \- Which of the two forms of therapy, robot-assisted therapy or conventional occupational therapy, is more effective in terms of improving arm and hand function? The study is designed as a cross-over trial, which means that each participant will receive both therapy forms consecutively, whereas the order is assigned randomly (either robot-assisted therapy first and then occupational therapy, or vice versa). In addition to their clinical routine therapy , participants will: * complete a baseline assessment * practice one therapy form (either robot-assisted or occupational therapy) with one arm for 6 weeks (3 x 30 min per week) * complete a intermediate assessment * practice the other therapy form (either occupational or robot-assisted therapy) with one arm for 6 weeks (3 x 30 min per week) * complete a post assessment * complete a follow-up assessment (if the post assessment was completed prior to 150 days post-injury)