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| Name | Class |
|---|---|
| University of Alberta | OTHER |
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The purpose of this study is to examine interventions with paradigms involving upper and lower extremity cycling (A&L cycling) with A&L cycling with functional electrical stimulation (FES) (A&L_FES group), A&L cycling with FES and transcutaneous Spinal Cord Stimulation (A&L_tSCS group), and control Body Weight Supported Treadmill Training (BWSTT) to potentially restore functional abilities (i.e., walking) in individuals with an incomplete spinal cord injury. The researchers hypothesize there will be improved walking function following these interventional groups.
Spinal cord injury (SCI) occurs at an annual rate of 50-60 per million in North America. Paralysis is also accompanied by drastic changes in independence and quality of life. SCI occurs mostly among younger individuals, half in people 16-30 years of age. Two-thirds of all SCIs are incomplete (iSCI), with some preserved neural connections relaying information to and from the brain. People with iSCI benefit most from improvements in walking. In addition to increasing independence, walking helps persons with iSCI remain active, with a variety of beneficial health-related outcomes. Therapy that can significantly increase sensorimotor function to these individuals living with iSCI for multiple decades would be hugely significant.
Currently, the most common strategies for restoring walking after an iSCI are manually intensive, including over ground walking with weight and balance support provided by multiple therapists, or with the use of expensive robotic support with controversial outcomes. Thus, the overarching goal of this proposal is to investigate if a non-specific gait rehabilitation paradigm based on motor-assisted arms and legs cycling, motor-assisted arms and legs cycling with functional electrical stimulation (FES) to the main muscles of the legs (A&L_FES group), or motor-assisted arms and legs cycling with FES to the main muscles of the legs and transcutaneous spinal cord stimulation (tSCS) at the cervical level (A&L_tSCS group) in AIS C and D iSCI individuals generalizes to improvements in walking that outperform conventional gait specific training, e.g., body-weight supported treadmill training (BWSTT; control group) (clinical assessments). The researchers will also investigate biomechanical and motor coordination changes and adaptations tied to these functional improvements (biomechanical assessments), and the neural mechanisms that explain functional improvements and their retention over time (neurophysiological assessments).
In the clinical assessments the researchers will investigate the clinically-relevant gait improvements afforded by the cycling intervention by measuring the walking gains with a battery of standard clinical tests focused on motor function, sensation, balance and spasticity. In the biomechanical assessments the researchers will focus on studying the detailed biomechanical basis for the gait improvements by using motion tracking, force plates, and EMG measurement to monitor the kinematics and kinetics of gait, and neuromuscular coordination. In the neurophysiological assessments the researchers will investigate the neuroplastic mechanisms underlying the gait improvements by conducting a battery of physiological tests to detect changes in the strength of descending and ascending spinal pathways.
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| Label | Type | Description | Intervention Names |
|---|---|---|---|
| A&L_tSCS group | Experimental | This paradigm combines A&L_FES with transcutaneous spinal cord stimulation (tSCS)applied with cathodic electrodes at the C3-C4 and C6-C7 spinous processes and anodic electrodes at the iliac crests. The stimulation intensity is set to trigger a spinal evoked potential, ensuring a strong but tolerable sensation at the cathode sites without evoking direct motor responses in the arm or leg EMG. |
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| A&L_FES group | Sham Comparator | This paradigm uses a commercially available motorized ergometer that link the arms & legs mechanically to support voluntary arm and leg cycling and provide reciprocal movements that resemble those during walking. FES is used to assist the the voluntary leg movements, which also enhances proprioceptive feedback. Specifically, functional electrical stimulation (FES) is applied to the major muscles of both legs-including the quadriceps, hamstrings, and gluteus maximus-using pairs of surface electrodes. For sham transcutaneous spinal cord stimulation (tSCS), electrodes will be placed but no tSCS current will be delivered. |
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| BWSTT group | Active Comparator | This is the control intervention. Participants will first be assisted by physical therapists/trainers to wear any necessary lower extremity braces along with a padded walking harness. They will then be helped onto the treadmill, either from a wheelchair via a ramp or by walking with physical assistance. Once on the treadmill, they will be clipped into the body weight support system, assisted to a standing position, and provided with the appropriate level of body weight support to facilitate successful stepping. |
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| Name | Type | Description | Arm Group Labels | Other Names |
|---|---|---|---|---|
| A&L cycling | Device | Participants will complete simultaneous arms and legs cycling for 60min of active cycling. Targeted exercise intensity is 70-85% of the age-predicted maximum heart rate. Cycling resistance will be modified for continuous challenge. A target speed 10% above the highest speed at which each study participant is able to cycle voluntarily without motor, FES, or tSCS assistance will be selected during the first session and maintained throughout all training sessions. Once a participant can complete 60 minutes of continuous cycling at a specific resistance for two consecutive training sessions, the resistance will be increased to the next setting level at the mid-point of the subsequent session. Upon completion of each session, the physical therapists/researcher will complete skin checks to ensure no adverse effects have occurred. Heart rate, blood pressure, and oxygen saturation will be recorded. Participants will complete 3 training sessions per week for 12 weeks. |
| Measure | Description | Time Frame |
|---|---|---|
| Change in 10-meter walking test (10MWT) | The 10-meter walking test (10MWT) is a physical function test measuring the total time to ambulate 10 meters in order to calculate walking speed in meters per second. A shorter time indicates a better walking speed. | Changes across baseline, after 3 weeks of training, after 6 weeks of training, after 9 weeks of training, after 12 weeks of training, and 6 months after completing training. |
| Measure | Description | Time Frame |
|---|---|---|
| Change in 6-minute walking test (6MWT) | The 6-minute walking test (6MWT) is a physical function test measuring the total distance walked in a span of six minutes will be assessed. A longer distance indicates a better walking distance. | Changes across baseline, after 3 weeks of training, after 6 weeks of training, after 9 weeks of training, after 12 weeks of training, and 6 months after completing training. |
| Measure | Description | Time Frame |
|---|---|---|
| Change in motor and sensory scores (ASIA) | The American Spinal Injury Association Impairment Scale (AISA) is a standardized neurological examination used to assess the sensory and motor levels which were affected by the spinal cord injury. A clinician will assess sensory and strength in both upper and lower extremities to provide both a neurologic level of injury and classification level. The five classification levels, ranging from complete loss of neural function in the affected area (Grade A) to completely normal (Grade E). A score closer to Grade E is a better outcome. |
Inclusion Criteria:
Exclusion Criteria:
SCI T12 and below (or lacking upper motorneuron injury)
Complete paraplegia or tetraplegia (classified as AIS A)
AIS B incomplete paraplegia or tetraplegia
Presence of progressive neurologic disease
Unable to give informed consent to participate in the study
Significant other disease (ex: cardiological or heart disease, renal, hepatic, malignant tumors, mental or psychiatric disorders) that would prevent participants from fullym engaging in study procedures
Weight over 160 kg (352 lbs)
TMS contraindications
FES and tSCS contraindications
Pregnancy
Prisoners
Cisgender
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| Name | Affiliation | Role |
|---|---|---|
| Jose L Pons, PhD | Shirley Ryan AbilityLab | Principal Investigator |
| Facility | Status | City | State | ZIP | Country | Contacts |
|---|---|---|---|---|---|---|
| Shirley Ryan AbilityLab | Chicago | Illinois | 60611 | United States |
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| ID | Term |
|---|---|
| D013119 | Spinal Cord Injuries |
| ID | Term |
|---|---|
| D013118 | Spinal Cord Diseases |
| D002493 | Central Nervous System Diseases |
| D009422 | Nervous System Diseases |
| D020196 | Trauma, Nervous System |
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| Body weight supported treadmill training (BWSTT) | Device | The physical therapists/researchers will assist the patient with donning any necessary lower extremity braces and a padded walking harness. The patient will be assisted onto the treadmill via a ramp while seated in a wheelchair or by ambulation with physical assistance, clipped into the body weight support system, assisted to stand, and provided the appropriate amount of body weight support to allow for successful stepping for 60 minutes of active walking. During BWSTT, physical therapists/trainers will adjust treadmill speed or incline and the degree of body weight support to challenge participants. Participants will be instructed to exercise with a targeted intensity of 70-85% of the age-predicted maximum heart rate. Upon completion of each session, the harness will be doffed with skin checks to ensure no adverse effects have occurred. Heart rate, blood pressure, and oxygen saturation will be recorded. Participants will complete 3 training sessions per week for 12 weeks. |
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| Change in balance with the Berg balance scale (BBS) | Change in static and dynamic sitting and standing balance will be assessed using the Berg balance scale (BBS). Items are scored from zero to four. A higher score indicates better balance and decreased fall risk. | Changes across baseline, after 6 weeks of training, after 12 weeks of training, and 6 months after completing training. |
| Change in walking ability with the WISCI | The Walking Index for Spinal Cord Injury (WISCI) assesses the ability of a person to walk after spinal cord injury. It consists of a rank ordering at the impairment level from most severe (0) to least severe (20) based on the amount of physical assistance required and use of assistive devices and/or braces while walking a 10-meter distance. A higher score indicates better walking ability. | Changes across baseline, after 6 weeks of training, after 12 weeks of training, and 6 months after completing training. |
| Change in Modified Ashworth Scale (MAS) | The Modified Ashworth Scale (MAS) is a physical function test measuring spasticity on a 6-point ordinal scale. A score of 0 on the scale indicates no increase in tone while a score of 4 indicates rigidity. Tone is scored by passively moving the individual's limb and assessing the amount of resistance to movement felt by the examiner. A lower score is a better outcome. | Changes across baseline, after 6 weeks of training, after 12 weeks of training, and 6 months after completing training. |
| Change in step length | Step length is the distance between the point of initial contact of one foot and the point of initial contact of the opposite foot. Typically a longer step length is a better outcome, ideally with equal measurements between left and right limbs. | Changes across baseline, after 6 weeks of training, after 12 weeks of training, and 6 months after completing training. |
| Change in step time | Step time is the amount of time that passes between the point of initial contact of one foot and the initial contact of the opposite foot. Typically a shorter step time is a better outcome, ideally with equal measurements between left and right limbs. | Changes across baseline, after 6 weeks of training, after 12 weeks of training, and 6 months after completing training. |
| Change in double support time | Double support time is the amount of time that passes during which both feet are simultaneously in contact with the ground in a gait cycle. Typically a shorter double support time is a better outcome. | Changes across baseline, after 6 weeks of training, after 12 weeks of training, and 6 months after completing training. |
| Change in range of motion (ROM) | Joint angle and angular velocity will be computed with the anatomical neutral position as frame of reference in the sagittal plane and flexion and extension resulting in positive and negative joint angles, respectively. Range of motion will be calculated as the difference between the maximum and minimum hip, knee, and ankle joint angles. A larger range of motion is a better outcome. | Changes across baseline, after 6 weeks of training, after 12 weeks of training, and 6 months after completing training. |
| Change in joint-joint cyclogram area | The area inside joint-joint cyclograms (e.g., hip-knee) will be calculated. A larger cyclogram area is a better outcome. | Changes across baseline, after 6 weeks of training, after 12 weeks of training, and 6 months after completing training. |
| Change in the number of muscle synergies | Activation patterns and bipolar EMG signals of the leg muscles (gluteus medius, gluteus maximus, rectus femoris, adductor longus, medial hamstrings, tibialis anterior, and gastrocnemius medialis) and arm muscles (delta anterior, delta posterior, biceps brachii, triceps brachii) will be assessed bilaterally during walking. Muscle synergies will be identified from the EMG signals. A higher number of synergies is a better outcome. | Changes across baseline, after 6 weeks of training, after 12 weeks of training, and 6 months after completing training. |
| Changes in interlimb (upper-lower limb) modulation | This will be assessed by measuring changes in the magnitude and pattern of H-reflex suppression in the soleus (ankle extensor) of the leg during arm cycling. Features closer to that of a healthy individual is a better outcome. | Changes across baseline, after 6 weeks of training, after 12 weeks of training, and 6 months after completing training. |
| Changes in the strength of cortico-spinal connectivity | This will be measured using TMS of the motor cortex known to produce a motor evoked potential (MEP) in the main muscles of the leg, and peak-to-peak amplitude of the MEP and recruitment curves of MEP amplitude as a function of TMS strength will be calculated and constructed. Recruitment curves closer to that of a healthy individual is a better outcome. | Changes across baseline, after 6 weeks of training, after 12 weeks of training, and 6 months after completing training. |
| Changes in strength of periphery and somatosensory cortex | This will be measured using cutaneous electrodes on the arm and leg skin surface and recording the somatosensory evoked potentials (SSEPs) over the primary somatosensory cortex using electroencephalography (EEG) electrodes; peak-to-peak amplitude of the SEP and recruitment curves of SEP amplitude as a function of stimulus strength will be calculated and constructed. Recruitment curves closer to that of a healthy individual is a better outcome. | Changes across baseline, after 6 weeks of training, after 12 weeks of training, and 6 months after completing training. |
| Changes across baseline, after 6 weeks of training, after 12 weeks of training, and 6 months after completing training. |
| Change in functional gait assessment (FGA) | The FGA is a 10-item test, scored on a four point ordinal scale. A higher score indicates decreased fall risk and is a better outcome. It measures dynamic balance and postural stability during walking tasks (such as fast walking, backward walking, stepping over an obstacle) in the clinical setting. Patients are allowed to use an assistive device for certain items. | Changes across baseline, after 6 weeks of training, after 12 weeks of training, and 6 months after completing training. |
| D014947 | Wounds and Injuries |