Veterans who suffer strokes often have disturbances in the ability to walk that reduces independence and quality of life. Alterations in gait combined with general decreased activity are associated with reduced muscle strength of the paretic leg. This leads to cardiovascular deconditioning and reduced quality of life. There is a new and novel battery powered device (Keeogo powered orthotic exoskeleton) that uses motors that assist knee movement while walking, sitting down, and standing up. The Keeogo monitors hip movement to assist the knee, making it simple to learn how to use. If successful, this project will show how this device will help improve the ability to walk and provide evidence to support larger clinical trials in a home and community setting to improve mobility, increase muscle mass and strength in the legs, as well as improve general health and quality of life. Lastly, this device could be used to increase motivation and confidence in a person to walk for longer periods of time and distance, providing the ability to walk in places that were previously inaccessible.
Ninety percent of stroke survivors have clinically significant gait impairments that lead to secondary medical complications, including cardiovascular deconditioning and reduced quality of life (QOL). Several rehabilitative interventions that increase the level of activity and mobility have been shown to be beneficial. Challenges posed by most of these locomotor gait training interventions require recurring visits to a rehabilitation center. The recent development of novel powered exoskeletons offers a potential mechanism for stroke survivors to improve mobility in the home and community. Although the predominant research using these devices have been in persons with spinal cord injury, there are currently two devices are commercially available for use in patients with stroke and additional devices are being developed. The Keeogo powered orthotic exoskeleton is a novel device intended for persons with stroke who can ambulate but have gait impairment. This device consists of a ridged orthotic structure placed over clothing on the legs and batteries to the power motors that assist both knees in gait movement. The system monitors hip movement driven by the user and interprets this movement to apply the appropriate assistance at the knee joint. This unique approach makes learning intuitive, enabling the user only to acclimate to the system rather than learning how to control the device to initiate the desired movement. This proposal is a randomized controlled pilot study. Fifteen veterans with chronic stroke (\>6months) and who retain some ability to take steps but have impaired gait will be recruited. Ten participants will be randomized into the exoskeleton group and 5 into the control group. Both groups will be asked to complete 36 one-hour sessions of ambulation training. The exoskeleton group will train using the Keeogo powered orthotic exoskeleton and the control group will train without using their own conventional aide. The primary aim is to determine the efficacy of training with this exoskeleton and its ability to improve transfers to standing and sitting as assessed by the five times sit-to-stand test. A secondary aim will be to assess effects of the device during overground ambulation. Outcome measurements to investigate changes of knee range of motion and loading of the paretic limb. An exploratory outcome of changes in energy expenditure during ambulation with and without the powered exoskeleton. Additional exploratory outcome measures of QOL will be determined.
Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
TREATMENT
Masking
NONE
Enrollment
22
A new and novel type of robotic-device (Keeogo, B-temia, Inc.) was developed to provide powered assistance at the knee for persons with stroke. This device provides assistance for both knee extension and knee flexion during ambulation, transfers to standing and sitting, in addition to ascending and descending stairs. As this device isn't able to fully control the movement, it requires the ability of the patient to stand and initiate stepping. The approach the Keeogo uses to monitor the desired movement in order to appropriately provide assistance. This promotes intuitive learning for the user, minimizing the amount of instruction and practice needed to effectively ambulate allowing users to independently ambulate within one session. This device does not restrict leg movement, so the user can side-step and walk backwards. However, it does not provide assistance during these movements.
Ambulation training will consist of mobility activities affecting daily life including: walking; squatting (or getting in and out of a chair); bending, kneeling or stooping (for picking an item up off of the floor); and ascending and descending stairs. Sessions will be monitored and tailored to the individual, based on their functional ability and to ensure their safety.
James J. Peters VA Medical Center, Bronx, NY
The Bronx, New York, United States
Five Times Sit to Stand Test (5xSTS)
The 5xSTS is used to determine leg power and an aspect of transfer skill. This test will be used to assess a level of improved function while wearing the device. The test will also be used to assess a level of improved function not while wearing the device.
Time frame: Change from Baseline after completing 36 training sessions (approximately three months time)
Energy Expenditure
A portable metabolic cart will assess oxygen consumption during the two ambulation conditions (i.e., with and without the device) over a 6-minute period
Time frame: Change from Baseline after completing 36 training sessions (approximately 3 months time)
The Ratio of Stance Time of Each Limb During Ambulation
Stepping parameters will be assessed using an instrumented carpet to determine if the paretic limb has more equitable and symmetrical load.
Time frame: Change from Baseline after completing 36 training sessions (approximately three months time)
Six Minute Walk Test (6MWT)
The 6MWT was used to assess walking endurance and was conducted on a straight 12-meter length in the hospital hallway, with a small cone marking each end of the length. Participants were instructed to walk as far as possible, at a self-selected comfortable pace, for 6 minutes while a trainer followed behind them. Participants were allowed to slow down, stop, and rest if necessary if they felt fatigued during the test. The number of completed lengths (of the 12-meter stretch of the hospital hallway) was recorded and the distance in meters was calculated.
Time frame: Change from Baseline after completing 36 training sessions (approximately three months time)
Ten Meter Walk Test (10MWT)
The 10MWT was used to assess gait speed. Participants were instructed to walk at their own comfortable pace along a 14-meter flat course in the hospital hallway while a trainer followed behind them. The initial and final two meters were used for acceleration and deceleration, respectively, while the middle ten meters of the course were times in seconds. Participants were allowed two trails, and the fastest elapsed time was used to calculate gait speed in meters/seconds.
Time frame: Change from Baseline after completing 36 training sessions (approximately three months time)
Timed Up and Go (TUG) Test
The Timed Up and Go (TUG) Test was used as a reliable, objective measure of functional mobility. The participant was seated, with their back against the seatback, in a free-standing straight-backed chair with arms and a seat height of 17 inches. Participants were instructed to stand, walk three meters at a comfortable pace to a marked line, turn, walk back to the chair, and sit down. Timing started at the "start" command and stopped when the participant's buttocks touched the chair. Participants were allowed one practice trial prior to the timed trial.
Time frame: Change from Baseline after completing 36 training sessions (approximately three months time)
Step Length of Paretic (Pa) Lower Extremities (LE)
Step lengths of the paretic (Pa) Lower Extremities were objective indices of spatiotemporal gait quality and were assessed with an instrumented pressure carpet (GaitRite Carpet, CIR Systems Inc., Franklin, NJ). Participants were instructed to walk at a comfortable, self-selected pace on a sensor equipped carpet that provided step length among other parameters. At least six consecutive steps on the carpet were needed to calculate the spatiotemporal parameters of the participant's gait.
Time frame: Change from Baseline after completing 36 training sessions (approximately three months time)
Step Length of Non-paretic (NP) Lower Extremities (LE)
Step lengths of the non-paretic (NP) Lower Extremities were objective indices of spatiotemporal gait quality and were assessed with an instrumented pressure carpet (GaitRite Carpet, CIR Systems Inc., Franklin, NJ). Participants were instructed to walk at a comfortable, self-selected pace on a sensor equipped carpet that provided step length among other parameters. At least six consecutive steps on the carpet were needed to calculate the spatiotemporal parameters of the participant's gait.
Time frame: Change from Baseline after completing 36 training sessions (approximately three months time)
Stair Climb Power Test (SCPT)
The Stair Climb Power Test was used as a measure of lower extremity (LE) power and functional mobility. Participants were instructed to ascend a flight of 10 stairs as fast as possible, using the handrail as needed for safety. Participants stood at the base of the first step. Timing started on the assessor's "go" command and stopped when both feet of the participant reached the top of the tenth step.
Time frame: Change from Baseline after completing 36 training sessions (approximately three months time)
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