Neuromodulation of Ankle Muscles in Persons With SCI
Last updated on July 2021Recruitment
- Recruitment Status
- Recruiting
- Estimated Enrollment
- Same as current
Summary
- Conditions
- Foot Drop
- Spastic Gait
- Spinal Cord Injuries
- Type
- Interventional
- Phase
- Not Applicable
- Design
- Allocation: RandomizedIntervention Model: Crossover AssignmentMasking: None (Open Label)Primary Purpose: Basic Science
Participation Requirements
- Age
- Between 18 years and 85 years
- Gender
- Both males and females
Description
Spinal cord injury can result in impaired walking ability and decreased independence in daily activities such as standing and transfers. The ability to voluntarily control the ankle muscles is an important component of walking that is impacted by changes in the corticospinal tract and the spinal ref...
Spinal cord injury can result in impaired walking ability and decreased independence in daily activities such as standing and transfers. The ability to voluntarily control the ankle muscles is an important component of walking that is impacted by changes in the corticospinal tract and the spinal reflex circuits. These changes have been associated with the inability to dorsiflex the ankle during swing phase (foot drop) and uncontrollable muscle spasms and stiffness in the ankle during terminal stance (spasticity), as well as during transfers. In order to improve functional outcomes and further develop rehabilitation techniques, the underlying contributions of the corticospinal tract and spinal reflex circuit to ankle control needs to be better understood. Non-invasive tools that target the corticospinal and spinal reflex circuit are being used in clinical settings in order to improve functional outcomes in persons with spinal cord injury. Whole body vibration (WBV) is a non-invasive tool that has been shown to increase voluntary motor output and decrease spasticity in persons with spinal cord injury. These improvements in function may be due to changes in the corticospinal tract and spinal reflex circuits. In order to determine the relative contributions of the corticospinal tract and spinal reflex circuits to increased voluntary ankle control and decreased spasticity, we will measure changes in the corticospinal tract and spinal reflex excitability before and after a single session of vibration. We will then determine which change (corticospinal or spinal) contributes more to increased voluntary ankle control and decreased spasticity. This information will help guide future research to further improve walking ability in persons with spinal cord injury.
Tracking Information
- NCT #
- NCT04238013
- Collaborators
- Eunice Kennedy Shriver National Institute of Child Health and Human Development (NICHD)
- Investigators
- Principal Investigator: Edelle Field-Fote, PT, PhD Director of Spinal Cord Injury Research