Amputation Clinical Trial
Official title:
The Active Knee Prosthesis Will be Tested to Evaluate How Well it Improves the Gait Symmetry and Reduces the Metabolic Cost of an Amputee During Walking. The Prosthesis Will be Attached to the Socket of the Amputee.
The purpose of this study is to develop a robust, low-power, stable, and light weight,
active knee prosthetic device that can dramatically increase gait symmetry and walking
economy of a transfemoral amputee during walking.
State of the art prosthetic knees can be classified into three main classes: a) mechanically
passive, b) variable-damping, and c) powered. Although the devices within each of these
classes offer some advantages for above-knee amputees, their overall performance still
presents some deficiencies. Artificial knees in the first two groups are predominantly
damping devices, incapable of providing positive power output. Moreover, current powered
prostheses are heavy and inefficient in their energy consumption, and/or they have a limited
range of motion. To overcome such inadequacies, we have designed a novel prosthetic knee
device with a biomimetic approach.
The design of the active knee prosthesis is inspired by the antagonistic muscle anatomy of
the human knee joint. This device mimics the synergistic muscle activity at the knee using a
double series-elastic actuator (SEA) system that resembles the major mono-articular muscle
groups that help flex and extend the knee joint. The agonist-antagonist SEA knee
architecture will allow for precise force control of the knee joint, mimicking the
spring-like behavior of the human knee, as well as providing adequate energy for forward
progression of the body. The SEA has been previously developed and tested on legged robots.
Also, the SEA has been successfully applied to the development of an actuated ankle-foot
orthoses (AAFO) at MIT AI Lab.
The mechanical architecture of the active knee prosthesis allows for independent engagement
of flexion and extension tendon-like, series springs for the control of joint position and
impedance, as well as net joint torque. Furthermore, this architecture permits a joint
rotation with near zero friction, allowing the controller to take advantage of the passive
dynamics of the system, thus, augmenting the overall energetic efficiency of the system.
Healthy participants with above-knee amputations will be recruited. Participants will meet
the following eligibility criteria. They will be experienced at prosthesis ambulation, with
a capacity of ambulation at least at a K3 level (i.e. having the ability or potential for
ambulation with variable cadence). Additionally, amputee participants will be generally
healthy and will have no other musculoskeletal problems or any known cardiovascular,
pulmonary or neurological disorders.
The research objective is to evaluate the efficacy of an active knee prosthesis that is
designed to increase gait symmetry, speed, and to lower metabolic energy demands during
walking.
For each amputee participant, a complete study will include three separate experimental
sessions conducted in three different locations. These locations are: The Biomechatronics
Group, MIT Media Laboratory; the Holodeck room in CSAIL at MIT; and the Indoor Track at
MIT's Johnson Athletic Center. The time between experimental sessions will be approximately
one to two weeks and the time duration of each session will be two to three hours. For each
session, an amputee study participant will be asked to walk at slow, normal, and fast paces
for two different conditions. The experimental conditions are:
1. Using an assigned commercially, available knee prosthesis (e.g. Otto Bock C-Leg or
Ossur Rheo)
2. Using the active knee prosthesis
In the first session, each amputee participant will be scheduled to visit the
Biomechatronics Group in The MIT Media Laboratory. The main purpose of this session is to
qualitatively assess the degree to which the active prosthesis can improve amputee gait.
Morphological data (for example, height, weight, limb length and circumference) of the
participant will be recorded using the biomechanical data collection form. These data will
be used during analysis of data gathered during the gait research sessions.
Each participant will be asked to walk along a 30-foot level walkway in the Biomechatronics
Group. During the session, each participant will be asked to walk at slow, normal and fast
paces for each of two walking conditions. For each condition and speed, approximately 10-15
trials will be performed. Parallel bars will be utilized to prevent any injury to the
subject if he were to lose balance and fall. A safely harness attached to the ceiling will
also be utilized if the subject makes that request. In addition, a member of the laboratory
staff will also accompany the study participant to catch him in the event of a fall, if
necessary. The participant may ask to rest or to terminate their participation in the study
at any time.
Each participant will be walking on the platform 60-90 times for the entire first session,
which should take approximately 2 hours. When using the active prosthesis with the walking
program, our researchers will tune the parameters of the walking program to the
participant's own gait pattern. The parameters used to tune the walking program will be
recorded for use in Sessions 2 and 3.
In the second session, amputee study participants will be scheduled to visit the Holodeck
room in CSAIL at MIT (Rm 33-339), that has installed the motion capture system to measure
human movement. The main purpose of this session is to collect knee state, torque and power
on amputees walking at slow, moderate and fast speeds. These active knee prosthetic data
will then be compared to conventional prosthetic knee behaviors measured at the same three
speeds.
Each participant will be asked to walk along a 30-foot level walkway in the Holodeck room in
CSAIL at MIT. Before conducting experiments, one of the investigators will place reflective
markers on the participant's skin with tape at specific points over joints of their body.
These special markers are then seen by the cameras in the room (See Data Collection
Instruments). During the session, each participant will be asked to walk at slow, normal and
fast paces for each of two walking conditions. For each condition and speed, approximately
10-15 trials will be performed. Motion data is collected from cameras in the room and from
the force plates that are placed in the walkway. As the device has been setup in the first
session, two members of the laboratory staff will walk on each side of the participant
throughout the experiment. The second session should take between 2 and 3 hours.
In the third session, each transfemoral amputee participant will be scheduled to visit the
Indoor Track of the Johnson Athletic Center at MIT, which is located at the 2nd floor of the
Athletic Center. The main purpose of this session is to test if the active knee prosthesis
does, in fact, reduce the metabolic cost of amputee walking.
During the session, each participant will be asked to wear a Cosmed Oxygen Consumption (VO2)
mask that will measure the metabolic rate. Two members of the laboratory staff will walk on
each side of the participant throughout the experiment. The procedure for the experiment
will be as follows:
The participant will be asked to wear the VO2 system and first walk for 8 minutes on the
track with an assigned commercially, available above knee prosthesis (Otto Bock C-Leg or
Ossur Rheo) to establish a control metabolic rate. After resting for 8 minutes, he/she will
wear the active prosthesis and get acclimated to the device by walking for 5 minutes. He/she
will then walk on the track for 8 minutes as we measure his/her metabolic rate with the
device. The participant will then rest for another 8 minutes. This protocol will be repeated
two additional times, and the entire experiment will take approximately 3 Hrs. Throughout
the study, each participant will be videotaped and photographed to document the effect of
the prosthesis on walking.
;
Endpoint Classification: Efficacy Study, Intervention Model: Single Group Assignment, Masking: Open Label, Primary Purpose: Diagnostic
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