Clinical Trial Details
— Status: Completed
Administrative data
| NCT number |
NCT03924752 |
| Other study ID # |
H19178 |
| Secondary ID |
|
| Status |
Completed |
| Phase |
N/A
|
| First received |
|
| Last updated |
|
| Start date |
February 13, 2021 |
| Est. completion date |
March 15, 2021 |
Study information
| Verified date |
January 2022 |
| Source |
Georgia Institute of Technology |
| Contact |
n/a |
| Is FDA regulated |
No |
| Health authority |
|
| Study type |
Interventional
|
Clinical Trial Summary
The increased metabolic and biomechanical demands of ambulation limit community mobility in
persons with lower limb disability due to neurological damage. There is a critical need for
improving the locomotion capabilities of individuals who have walking impairments due to
disease to increase their community mobility, independence, and health. Robotic exoskeletons
have the potential to assist these individuals by increasing community mobility to improve
quality of life. While these devices have incredible potential, current technology does not
support dynamic movements common with locomotion such as transitioning between different
gaits and supporting a wide variety of walking speeds. One significant challenge in achieving
community ambulation with exoskeletons is providing an adaptive control system to accomplish
a wide variety of locomotor tasks. Many exoskeletons today are developed without a detailed
understanding of the effect of the device on the human musculoskeletal system. This research
is interested in studying the question of how the control system affects human biomechanics
including kinematic, kinetics and muscle activation patterns. By optimizing exoskeleton
controllers based on human biomechanics and adapting control based on task, the biggest
benefit to patient populations will be achieved to help advance the state-of-the-art with
assistive hip exoskeletons.
Description:
One significant challenge in achieving community ambulation with exoskeletons is providing an
adaptive control system to accomplish a wide variety of locomotor tasks. Many exoskeletons
today are developed without a detailed understanding of the effect of the device on the human
musculoskeletal system. The study is interested in exploring the question of how the control
system affects human biomechanics including kinematic, kinetics and muscle activation
patterns. By optimizing exoskeleton controllers based on human biomechanics and adapting
control based on task, this work will be able to provide the biggest benefit to patients and
advance the state-of-the-art with assistive hip exoskeletons. A large patient population that
could benefit from lower limb assistive technology are stroke survivors, which is the
specific population this proposal targets. One common characteristic of stroke survivors who
regain their ability to walk is that the hip muscles are overtaxed due to distal weakness.
The investigators propose to use a powered hip exoskeleton to augment their proximal
musculature, which needs to produce significant power output in most locomotion activities
such as standing up, walking, and going up stairs or slopes. Another biomechanical aspect of
stroke survivors is an asymmetric gait in terms of kinematics, kinetics and muscle
activations. The research team will examine what kind of exoskeleton assistance is most
beneficial to stroke survivors for enhancing community ambulation. The hypothesis is that
since the gait is asymmetric, the controller will need to be asymmetric to provide optimal
assistance to aid in mobility. The group's long-term research goal is to create powered
assistive exoskeletons devices that are of great value to individuals with serious lower limb
disabilities by improving clinical outcomes such as walking speed and community ambulation
ability. The overall objective of the proposed project is to study the biomechanical effects
of using a hip exoskeleton with adaptive controllers for assisting stroke survivors with
lower limb deficits to improve their community ambulation capabilities. The central
hypothesis overarching both aims is that exoskeleton control that adapts to environmental
terrain will improve mobility metrics for human exoskeleton users on community ambulation
tasks. The rationale is that since human biomechanics change based on task, exoskeleton
controllers likewise need to optimize their assistance levels to match what the human is
doing. The first aim of the proposed study is to determine the benefit of exoskeleton control
that adapts to the environment for improving community ambulation capability. The team has
previously designed and extensively tested an autonomous hip exoskeleton in able-bodied
subjects on a treadmill. The investigators plan to extend their control framework to over
ground walking and tune assistance magnitude and timing levels to enable efficient locomotion
over stairs and ramps on their novel terrain park. The investigators plan to compare a
controller that adapts its assistance strategy based on locomotion task to a static
controller as well as not wearing the exoskeleton. The primary hypothesis for this aim is
that exoskeleton control that adapts to environmental terrain will improve mobility metrics
such as task completion speed for human exoskeleton users on community ambulation tasks. The
expected outcome of these aims will be an increased understanding of the biomechanical and
clinical effects in applying hip assistance with a robotic exoskeleton in community
ambulation tasks such as overground walking, ramps and stairs. This work will serve as a
foundational start for a broader planned study of optimizing controllers to improve
biomechanics in the walking impaired using powered hip autonomous exoskeletons.
