Clinical Research Directory

Home-Based Digital Rehabilitation Program Optimized With Transcutaneous Spinal Cord Stimulation for Upper Limb Functional Enhancement in Tetraplegia (HOPE): A Safety, Efficacy, and Feasibility Study

Individuals with chronic cervical spinal cord injury (SCI) and tetraplegia commonly experience persistent impairment in upper limb function, leading to reduced independence and quality of life. Transcutaneous spinal cord stimulation (tSCS) is a non-invasive neuromodulation technique that has demonstrated potential to improve upper limb strength and function when combined with rehabilitation. However, access to tSCS is limited in Singapore due to cost, regulatory barriers, and the need for frequent outpatient therapy. This study evaluates the safety, efficacy, and feasibility of a home-based digital rehabilitation program incorporating tSCS delivered using a commercially available neuromuscular electrical stimulation (NMES) device. Using a prospective, open-label single-case experimental design with multiple baselines across participants, individuals with chronic, non-progressive cervical SCI will receive daily home-based tSCS combined with an mobile application-guided upper limb exercise program. Upper limb function, quality of life, feasibility, and safety outcomes will be assessed longitudinally over a 22-week study period.

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.

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.

Development and Validation of a New Questionnaire for Caregivers to Assess Hip Pain in Quadriplegic Pediatric Patients: Non-Ambulatory Hip Pain Questionnaire

The goal of this clinical trial is twofold: 1. to develop a questionnaire for care givers to assess hip pain in quadriplegic pediatric patients who are not able to communicate it independently 2. to validate this questionnaire in a cohort of 100 pediatric patients with quadriplegia Researchers will : 1. involve 10 experts (8 multiprofessional clinicians and 2 parents) in a Delphi approach to develop the questionnaire 2. assess construct validity and reliability of the questionnaire submitting it to 100 care givers of pediatric patients with quadriplegia, and comparing results with the Revised Face Legs Activity Cry and Consolability (r-FLACC) Scale assessed by the physiatrist during the visit Participants will: 1. as experts, firstly answer open questions on this topic, secondly evaluate each item of the new questionnaire by means of a 5-point Liekert scale 2. as caregivers of pediatric patients with quadriplegia, fill out the questionnaire within 2 weeks after the visit

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.

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.