Transcutaneous Spinal Stimulation: Safety and Feasibility for Trunk Control in Children With Spinal Cord Injury
|ClinicalTrials.gov Identifier: NCT03975634|
Recruitment Status : Recruiting
First Posted : June 5, 2019
Last Update Posted : August 26, 2019
Paralysis of trunk muscles and the inability to sit upright is one of the major problems facing adults and children with spinal cord injury (SCI). Activity-based locomotor training has resulted in improved trunk control in children with spinal cord injury, though full recovery is not achieved in all children. Transcutaneous spinal stimulation' (TcStim), a stimulation applied over the skin to the sensory nerves and spinal cord, is a promising tool that may further enhance improvements to trunk control. The purpose of this study is to determine the feasibility (can we do it) and safety of Transcutaneous Stimulation (TcStim) in children with SCI to acutely improve sitting upright and when used with activity-based locomotor training (AB-LT). Thus, can we provide this therapy to children and do so safely examining a child's immediate response and cumulative response relative to safety and comfort.
Eight participants in this study will sit as best they can with and without the stimulation (i.e. stimulation applied across the skin to the nerves entering the spinal cord and to the spinal cord) and their immediate response (safety, comfort, trunk position) recorded. Then, two participants will receive approximately 40 sessions of activity-based locomotor training in combination with the stimulation. Their cumulative response of stimulation (i.e. safety, comfort, feasibility) across time will be documented. Participation in this study may last up to 3 days for the 8 participants being observed for acute response to stimulation and up to 9 weeks for the participants being observed for cumulative response to training with stimulation. We will monitor the participants throughout the testing and training for their response to the stimulation (i.e. safety) and their comfort.
|Condition or disease||Intervention/treatment||Phase|
|Spinal Cord Injuries||Device: Transcutaneous Spinal Stimulation||Not Applicable|
Similar to adults, children with severe spinal cord injury (SCI) suffer the devastating consequences of limb and trunk muscle paralysis rendering them unable to sit upright, stand, or walk. Unique to pediatric-onset SCI, nearly 100% of children injured under the age of 10 develop neuromuscular scoliosis with approximately 65% requiring surgical intervention. Given the importance of muscle activity and load-bearing for musculoskeletal development, SCI-induced trunk muscle paralysis during rapid growth contributes significantly to the onset and progression of scoliosis. Current physical rehabilitation interventions after pediatric-onset SCI are based on the premise of permanence of SCI-induced paralysis and the inability to restore intrinsic trunk control. As a result, thoraco-lumbosacral braces remain the standard of care for upright sitting support without clear efficacy for reducing the incidence of neuromuscular scoliosis.
Advances in rehabilitation after SCI, for adult and pediatric populations, capitalize on the intrinsic capacity of spinal neuronal networks for generation of motor output below the lesion in response to sensory input during activity-based locomotor training (AB-LT). Our recent work demonstrated remarkable improvements in trunk control as measured by the Segmental Assessment of Trunk Control (SATCo) in all 21 participants with SCI, age range: 17 months-12 years at enrollment and mean time since injury 1.5 years (range 1 month-6 years), receiving AB-LT across 60 sessions. Sensory-afferent driven activation of the intrinsic synergies between the lower limb and trunk extensor muscles above, across and below the lesion likely underlies the physiological adaptations responsible for these gains. While all children improved, not all attained full trunk control. Incorporation of neuromodulatory techniques, such as epidural spinal cord stimulation, further challenges the limits for SCI recovery previously thought possible. There are recent reports of individuals with chronic complete SCI regaining the capacity to stand and walk with stimulation. Transcutaneous spinal stimulation (TcStim) provides a non-invasive neuromodulatory tool that may, similar to epidural stimulation, increase the central state of excitability below the lesion, thereby enabling greater capacity for integration of sensory input and augment motor output to potentiate trunk motor recovery. Children with SCI may not only benefit from novel neurotherapeutic interventions, but also may demonstrate even greater improvements due to inherent plasticity present during development. Previous studies demonstrated the efficacy of TcStim to acutely improve sitting posture and trunk muscle activation in adults with SCI. In children with cerebral palsy, TcStim combined with AB-LT significantly improved locomotion compared to AB-LT alone. Our overall objective is to demonstrate 'proof-of-principle', as a necessary first step, that TcStim is a feasible and safe approach to a therapeutic intervention targeting trunk control in children with SCI. If found to be feasible and safe, then future studies will employ TcStim in combination with restorative rehabilitation for children with SCI to examine the effect on trunk control.
|Study Type :||Interventional (Clinical Trial)|
|Estimated Enrollment :||10 participants|
|Intervention Model:||Single Group Assignment|
|Masking:||None (Open Label)|
|Primary Purpose:||Device Feasibility|
|Official Title:||Transcutaneous Spinal Stimulation: Augmenting Training for Attaining Intrinsic Trunk Control in Children With Spinal Cord Injury|
|Actual Study Start Date :||August 12, 2019|
|Estimated Primary Completion Date :||April 2020|
|Estimated Study Completion Date :||June 2020|
Experimental: Transcutaneous spinal stimulation
Safety and feasibility outcome measures are collected during application of transcutaneous spinal stimulation while trunk control is assessed at 3 time points (acute) and/or while transcutaneous stimulation is applied in combination with activity-based locomotor training (40 sessions, 1.5 hours/day, 5 days/week; stimulation will be applied intermittently for no more than 10 minutes at a time during training)
Device: Transcutaneous Spinal Stimulation
Safety and feasibility will be monitored during transcutaneous spinal stimulation in children with spinal cord injury
- Incidence of skin irritation [ Time Frame: 1 week for Aim 1, 9 weeks for Aim 2 ]Skin color, particularly change in skin color to pink indicating irritation in the location of the stimulating electrode placement will be assessed prior to stimulation experiments and immediately after; incidence of pink- or redness or irritation and time (minutes-days) to dissipation will be recorded.
- Faces Pain Scale-Revised (scale 0-10) [ Time Frame: 1 week for Aim 1, 9 weeks for Aim 2 ]Faces Pain Scale - Revised is a self-report measure of pain intensity developed for children (C.L. Hicks et al. Pain 93 (2001). It will be used to score the sensation of pain on 0 (min - no pain)-to-10 (max - worst pain ever) metric. The scale depicts 6 facial expressions: first - face with a neutral expression corresponds to pain score of 0, next facial expression is scored as 2, etc. The faces scale will be presented to the participant (ages 3-8) prior to the experiment for baseline measurement, during stimulation and following the experiment.
- Visual Analog Scale (0-10) [ Time Frame: 1 week for Aim 1, 9 weeks for Aim 2 ]To assess pain in the participants ages 8 and above, Visual Analog Scale (self-reported measure) will be presented with 0 corresponding to no pain and 10 corresponding to the "worst pain ever"; the scale will be presented at baseline measurement, during stimulation and following the experiment.
- Blood pressure [ Time Frame: 1 week for Aim 1, 9 weeks for Aim 2 ]
continuous beat-by-beat blood pressure (mmHg) recordings will be made using Finapress finger cuff system for 5 minutes prior to and 5 minutes immediately following stimulation while the child is sitting; Brachial arm blood pressure will be periodically measured during stimulation (mmHg).
systolic and diastolic blood pressure values will be compared with the established norms for typically developing children (age and height matched);
- number of requests to stop the stimulation [ Time Frame: 1 week for Aim 1, 9 weeks for Aim 2 ]Number of participants requesting (or number of request per participant within experimental sessions) to stop stimulation due to pain, fatigue or any other reason (documented)
- Angular excursions of trunk during trunk control assessments [ Time Frame: 3 days for Aim 1, 9 weeks for Aim 2 ]trunk kinematics (degrees of flexion/extension) in cervical, thoracic and lumbar regions;
- Heart rate [ Time Frame: 1 week for Aim 1, 9 weeks for Aim 2 ]
heart rate (beats per minute) will be continuously monitored and recorded using 3-lead ECG electrocardiogram.
The slope and correlation coefficient between beat-by-beat blood pressure and R-R intervals (ms) (measured from ECG) for 5 minutes prior to and 5 minutes immediately following stimulation will be used to assess spontaneous baroreflex sensitivity, indication of autonomic regulation of the cardiovascular function
- Compliance rate [ Time Frame: 1 week for Aim 1, 9 weeks for Aim 2 ]Compliance - number of sessions missed and reason, willingness to continue participation.
- Center of pressure displacement during trunk control assessment [ Time Frame: 1 week for Aim 1, 9 weeks for Aim 2 ]the distance (mm) of the center of pressure displacement will be measured in mediolateral; anterior -posterior directions during reaching tasks while the participant is sitting on the force plate
Please refer to this study by its ClinicalTrials.gov identifier (NCT number): NCT03975634
|Contact: Lisa Clayton, B.S.||502-333-8152||LisaClayton@KentuckyOneHealth.org|
|United States, Kentucky|
|Department of Neurosurgery, University of Louisville||Recruiting|
|Louisville, Kentucky, United States, 40202|
|Contact: Lisa Clayton, BS 502-333-8152 LisaClayton@KentuckyOneHealth.org|
|Principal Investigator:||Andrea L Behrman, PhD, PT||University of Louisville|