Journal of NeuroEngineering and
Rehabilitation
BioMed Central
Open Access
Research
A pneumatically powered knee-ankle-foot orthosis (KAFO) with
myoelectric activation and inhibition
Gregory S Sawicki*1,2 and Daniel P Ferris1,3,4
Address: 1Human Neuromechanics Laboratory, School of Kinesiology, University of Michigan, 401 Washtenaw Avenue, Ann Arbor, Michigan,
48109-2214, USA, 2Department of Mechanical Engineering, University of Michigan, Ann Arbor, Michigan, USA, 3Department of Biomedical
Engineering, University of Michigan, Ann Arbor, Michigan, USA and 4Department of Physical Medicine and Rehabilitation, University of
Michigan, Michigan, Ann Arbor, USA
Email: Gregory S Sawicki* - gsawicki@umich.edu; Daniel P Ferris - ferrisdp@umich.edu
* Corresponding author
Published: 23 June 2009
Journal of NeuroEngineering and Rehabilitation 2009, 6:23
doi:10.1186/1743-0003-6-23
Received: 27 January 2009
Accepted: 23 June 2009
This article is available from: http://www.jneuroengrehab.com/content/6/1/23
© 2009 Sawicki and Ferris; licensee BioMed Central Ltd.
This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/2.0),
which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
Abstract
Background: The goal of this study was to test the mechanical performance of a prototype kneeankle-foot orthosis (KAFO) powered by artificial pneumatic muscles during human walking. We
had previously built a powered ankle-foot orthosis (AFO) and used it effectively in studies on
human motor adaptation, locomotion energetics, and gait rehabilitation. Extending the previous
AFO to a KAFO presented additional challenges related to the force-length properties of the
artificial pneumatic muscles and the presence of multiple antagonistic artificial pneumatic muscle
pairs.
Methods: Three healthy males were fitted with custom KAFOs equipped with artificial pneumatic
muscles to power ankle plantar flexion/dorsiflexion and knee extension/flexion. Subjects walked
over ground at 1.25 m/s under four conditions without extensive practice: 1) without wearing the
orthosis, 2) wearing the orthosis with artificial muscles turned off, 3) wearing the orthosis activated
under direct proportional myoelectric control, and 4) wearing the orthosis activated under
proportional myoelectric control with flexor inhibition produced by leg extensor muscle activation.
We collected joint kinematics, ground reaction forces, electromyography, and orthosis kinetics.
Results: The KAFO produced ~22%–33% of the peak knee flexor moment, ~15%–33% of the peak
extensor moment, ~42%–46% of the peak plantar flexor moment, and ~83%–129% of the peak
dorsiflexor moment during normal walking. With flexor inhibition produced by leg extensor
muscle activation, ankle (Pearson r-value = 0.74 ± 0.04) and knee ( r = 0.95 ± 0.04) joint kinematic
profiles were more similar to the without orthosis condition compared to when there was no
flexor inhibition (r = 0.49 ± 0.13 for ankle, p = 0.05, and r = 0.90 ± 0.03 for knee, p = 0.17).
Conclusion: The proportional myoelectric control with flexor inhibition allowed for a more
normal gait than direct proportional myoelectric control. The current orthosis design provided
knee torques smaller than the ankle torques due to the trade-off in torque and range of motion
that occurs with artificial pneumatic muscles. Future KAFO designs could incorporate cams, gears,
or different actuators to transmit greater torque to the knee.
Page 1 of 16
(page number not for citation purposes)
Journal of NeuroEngineering and Rehabilitation 2009, 6:23
Background
Powered lower-limb orthoses (i.e. robotic exoskeletons)
can be useful tools for assisting gait rehabilitation therapy
and studying the neuromechanics and energetics of
human locomotion [1-3]. A primary goal of these devices
is to replace or restore a portion of the torque and/or
mechanical work performed by the biological muscle-tendons acting at the joints (e.g. ankle, knee or hip) during
locomotion. Ideally, the mechanical assistance is delivered while maintaining overall kinetic and kinematic patterns similar to normal walking so that they provide little
disruption to gait.
In our previous research, we built and tested lightweight
carbon-fiber ankle-foot orthoses (AFO) with artificial
pneumatic muscles capable of powering both ankle
plantar flexion and dorsiflexion during human walking
[1,4,5]. We concentrated our initial efforts on the ankle
because it plays a crucial functional role during normal
walking. The healthy plantar flexors (e.g. soleus, gastrocnemius) aid in (1) forward propulsion (2) swing initiation and (3) body-weight support [6-8] during walking.
The plantar flexors are a major source of mechanical
energy, contributing 35%–50% of the total positive
mechanical work over a stride [9-11]. Most of this work is
performed at push-off, when ankle muscle-tendons help
drive the step-to-step transition, propelling the body
upward and forward to maintain steady walking speed
[12].
Muscle-tendons spanning the knee also greatly influence
normal walking dynamics and should be considered in
the design of assistive devices. Healthy knee extensors and
flexors act both to absorb and generate energy at different
phases over the walking stride. During initial stance, the
knee joint extensors prevent the leg from buckling: acting
to support body-weight while performing negative
mechanical work (e.g. similar to a shock absorber). During mid- and late stance, the knee generates mechanical
energy, some of which may be recycled energy stored previously in elastic tissues during the absorption phase [12].
At the stance-swing transiton, the knee muscle-tendons
stabilize the limb during push-off and then absorb energy
to control leg motion during swing.
Several powered orthoses have been tested to aid the knee
during human walking. Some of the designs provided
real-time mechanical assistance using quasi-passive magnetorheological variable dampers [13], linear hydraulic
actuators [14], electric actuators [15-18] and variable stiffness actuator springs [19]. Artificial pneumatic muscles
have recently been tested on a powered hip orthosis [20],
but we are unaware of any device that has used artificial
pneumatic muscles to provide torque assistance at the
knee. In addition, perhaps because of added hardware
http://www.jneuroengrehab.com/content/6/1/23
and software design complexity, few devices have been
described that can simultaneously provide active torque
to drive both ankle plantar/dorsiflexion and knee flexion/
extension. It is difficult to evaluate the performance of
most of the prototypes because gait analysis data from
users walking in them is limited [21].
The overall goal of this study was to extend our pneumatically powered ankle orthosis concept to the knee, and test
its performance on healthy human walkers. We built a
unilateral powered knee-ankle-foot orthosis (KAFO) with
antagonistic pairs of artificial pneumatic muscles at both
the ankle (i.e. plantar flexor and dorsiflexor) and the knee
(i.e. extensors and flexors). The orthosis pneumatic muscles were controlled using surface electromyography
recordings from the user's own biological muscles (i.e.
proportional myoelectric control).
The added complexity of a KAFO powered by antagonistic
pairs of artificial pneumatic muscles could limit its performance. First, actuator force-length properties [5] and
smaller moment arms could lead to reduced torque from
artificial pneumatic muscles acting at the knee. Second,
antagonistic artificial muscle pairs under proportional
myoelectric control could result in co-activation reducing
the net assistance torque. We evaluated the performance
of our powered KAFO in the context of two key questions:
(1) Would the KAFO deliver assistance torque at the knee
joint with timing and magnitude similar to that of the biological muscle-tendon moments during normal walking
without the orthosis? (2) Would using leg extensor muscle EMG signals to inhibit flexor artificial pneumatic muscles lead to improved gait kinematics than direct
proportional myoelectric control that includes co-activation of antagonistic artificial muscles?
To address these questions we compared overground
walking trials without the orthosis (baseline), with the
KAFO unpowered, and with the KAFO powered under
two distinct proportional myoelecric control modes. The
first control mode allowed co-activation of artificial extensor and flexor muscles (at both joints) (PM – direct proportional myoelectric). The second, modeled after
reciprocal inhibition observed in humans [22], prevented
co-activation by inhibiting flexor activation when the
antagonist extensor was active (PMFI – proportional myoelectric control with flexor inhibition).
Methods
Subjects
We tested three healthy male subjects (body mass 91.9 ±
17.2 kg; height 187.0 ± 3.4 cm, mean ± s.d.). Each subject
read and signed a consent form prepared according the
Declaration of Helsinki and the protocol was approved by
Page 2 of 16
(page number not for citation purposes)
Journal of NeuroEngineering and Rehabilitation 2009, 6:23
the University of Michigan Institutional Review Board for
human subject research.
Orthosis hardware
We constructed a single (left leg only), custom-fit kneeankle-foot orthosis for each subject (Figure 1). The kneeankle-foot orthosis (KAFO) concept was extended from
our previously described ankle-foot orthosis (AFO)
designs [4,5,23]. The lightweight orthosis (mass 2.9 ± 1.3
kg) consisted of a polypropylene foot section, a carbon
fiber shank and a carbon fiber thigh. Hinge joints allowed
free ankle dorsi-plantar flexion and knee flexion-extension.
We attached six artificial pneumatic muscles to each
orthosis. The pneumatic muscles were an ankle dorsiflexor, an ankle plantar flexor, two knee extensors, and
two knee flexors. Each artificial pneumatic muscle was
attached to the orthosis with stainless steel brackets. We
positioned each bracket in order to achieve the largest
Figure 1 of Michigan Knee-Ankle-Foot Orthosis (KAFO)
University
University of Michigan Knee-Ankle-Foot Orthosis
(KAFO). Two pictures of the unilateral (left leg) knee-anklefoot orthosis (KAFO) with artificial pneumatic muscles display the thigh and shank sections made from carbon-fiber and
the foot section made from polypropylene. The orthoses
were custom molded from a cast unique to each subject.
Hinge joints at the ankle and knee allowed free motion in the
sagittal plane. We used steel brackets to attach two artificial
pneumatic muscles (a plantar flexor and a dorsiflexor)
around the ankle and four around the knee (two extensors
and two flexors). Each artificial pneumatic muscle had a compression load transducer mounted in series on the proximal
steel bracket attachment and a release valve for quick connection to the pressurized air source. A special shoe was
worn over the foot section during walking trials.
http://www.jneuroengrehab.com/content/6/1/23
possible artificial muscle moment arm while maintaining
the normal joint range of motion. Additional details on
specifications for the orthoses and their components can
be found in Table 1.
We used eight (4 for the ankle pneumatic muscles, 4 for
the knee pneumatic muscles) parallel proportional pressure regulators (valve PPC0445A-ACA-OAGABA09 and
solenoid 45A-L00_DGFK-1BA, MAC Valves, Inc. Wixom,
MI) to supply compressed air to each artificial muscle via
nylon tubing (0–6.2 bar). Analog-controlled solenoid
valves in parallel with the air supply tubing improved
exhaust dynamics (35A-AAA-0DAJ-2KJ, MAC Valves, Inc.,
Wixom, MI).
Artificial pneumatic muscle control
We implemented a physiologically-inspired controller
that incorporated the user's own surface electromyography to dictate the timing and magnitude of artificial muscle forces (i.e. proportional myoelectric control). We
chose to control each artificial pneumatic muscle with an
electromyography signal generated by a biological muscle
with analogous mechanical action. That is, artificial extensors were controlled by biological extensors and artificial
flexors were controlled by biological flexors. More specifically, at the ankle we used tibialis anterior to control the
artificial dorsiflexor and soleus to control the artificial
plantar flexor. At the knee, we used vastus lateralis to control the two artificial knee extensors and medial hamstrings to control the two artificial knee flexors.
We programmed two proportional myoelectric control
modes using a real-time computer interface (dSPACE Inc.,
Northville, MI; 1000 Hz sampling). The first allowed coactivation of artificial extensor and flexor muscles (proportional myoelectric, PM) and the second prevented coactivation by inhibiting flexor activation when the antagonist extensor was active (proportional myoelectric with
flexor inhibition, PMFI). In both cases we amplified, high
pass filtered (fc = 50 Hz), full-wave rectified, low pass filtered (fc = 10 Hz) and then applied a threshold and gain
to convert the raw voltage recorded from surface electrodes to the voltage commanding the pneumatic hardware. The time between the control signal onset and
initial rise of artificial muscle tension (~50 ms) of the
device was comparable to response times of human muscles [23].
Protocol
At the start of the session, subjects walked for 10 minutes
on a motorized treadmill at 1.25 m/s wearing the KAFO
unpowered (i.e. with artificial muscles turned off). During
the unpowered treadmill walking bout we tuned the proportional myoelectric controller gains and thresholds for
each artificial muscle. The same gains and thresholds were
Page 3 of 16
(page number not for citation purposes)
Journal of NeuroEngineering and Rehabilitation 2009, 6:23
http://www.jneuroengrehab.com/content/6/1/23
Table 1: Knee-ankle-foot orthosis specifications
Orthosis
Component Mass (g)
Mean
SD
Artificial Muscle
Load Cell
Blow Valve
Thigh
Shank
Foot
128
94
152
1089
1408
388
7
0
0
90
89
34
Total
2884
134
Muscle Length (cm)
Artificial Muscles
Plantarflexor
Dorsiflexor
Medial Knee Extensor
Lateral Knee Extensor
Medial Knee Flexor
Lateral Knee Flexor
used in the PM and PMFI control modes. For the artificial
plantar flexor we used G = 0.17 ± 0.06 V/μV, Th = 18.7 ±
5.5 μV; dorsiflexor G = 0.22 ± 0.03 V/μV, Th = 24.7 ± 5.0
μV; knee extensors G = 0.37 ± 0.07 V/μV, Th = 7.3 ± 6.8
uV; and knee flexors G = 0.30 ± 0.07 V/μV, Th = 15.0 ± 8.9
μV. We chose the threshold to eliminate background
noise and the gain to get a saturated control signal (10 V)
at peak for at least five consecutive steps.
Subjects then completed five overground walking trials at
1.25 m/s with the orthosis in three different conditions:
(1) unpowered, (2) powered under proportional myoelectric control (PM) and (3) powered under proportional
myoelectric control with flexor inhibition (PMFI) (i.e. a
total of 15 overground trials). Following the orthosis trials, subjects completed five more overground trials at 1.25
m/s without wearing the orthosis in order to establish a
baseline for comparisons.
Data collection and analysis
We collected joint kinematics, ground reaction forces, surface electromyography and artificial muscle force data
during over ground walking trials at 1.25 m/s. To ensure
that trials were within ± 0.05 m/s of the target speed, we
used infrared timers triggered at beginning and end of the
~12 meter walkway. For all reported time series data, we
first formed profiles for a normalized stride cycle using
foot-switches placed in the shoe (1200 Hz, B&L Engineering, Tustin, CA, USA) to mark consecutive left heel strikes
(0% and 100% of the stride). For each subject, we averaged the stride normal data from each of the five trials in
each condition (Without, Unpowered, PM, PMFI) to get
stride cycle average time-series profiles. For each condition we averaged across subjects to form the mean stride
cycle average time-series traces reported in figures.
Joint Kinematics
To compute ankle, knee and hip joint angles we used an
8-camera video system (frame rate 120 Hz, Motion Analysis Corporation, Santa Rosa, CA, USA) to record the positions of twenty-nine reflective markers on the subjects'
Moment Arm Length (cm)
Mean
SD
Mean
SD
47.5
38.5
34.0
34.0
29.0
31.0
2.3
4.4
5.2
1.0
3.0
2.0
10.3
11.3
3.2
2.8
4.0
3.2
1.0
1.6
0.6
0.8
1.0
1.0
pelvis and lower limbs. We used custom software (Visual
3D, C-Motion, Rockville, MD, USA) to smooth the raw
marker data (4th-order low pass Butterworth, fc = 6 Hz)
and calculate joint angles (relative to neutral standing
posture) and angular velocities.
Ground Reaction Forces and Joint Kinetics
We used a single force platform (sampling rate 1200 Hz,
Advanced Mechanical Technology Inc., Watertown, MA,
USA) to record the ground reaction force under the left
foot. Combining ground reaction force data and joint kinematic data, we used inverse dynamics to calculate ankle,
knee and hip joint net muscle-tendon moments and powers over the stride (Visual 3D software, C-Motion, Rockville, MD, USA). We used standard regression equations
to estimate subjects' anthropometry [24] and adjusted
foot and shank parameters to account for added orthosis
mass and inertia. We divided moments (N-m) by subject
plus orthosis mass to make them mass-specific (N-m/kg).
We quantified the mass-specific mechanical work delivered by the ankle and knee moments for one leg over the
stride. First we integrated the positive and negative portions of the ankle and knee mechanical power curves separately, then summed the portions and finally divided by
the subject plus orthosis mass.
Orthosis Mechanics
We used single-axis compression load transducers (1200
Hz, Omega Engineering, Stamford, CT, USA) to record the
forces produced by the artificial pneumatic muscles during orthosis walking trials (Figure 1). We measured the
artificial muscle moment arms with the ankle and knee
joints in the neutral position during upright standing posture (Table 1). We multiplied moment arm length and
smoothed artificial muscle force data (4th-order low pass
Butterworth, fc = 6 Hz) to compute orthosis ankle and
knee torques. To determine the mechanical power delivered by the orthosis, we multiplied the orthosis torques
and joint angular velocities. We divided torques (N-m) by
subject plus orthosis mass to make them mass-specific (N-
Page 4 of 16
(page number not for citation purposes)
Journal of NeuroEngineering and Rehabilitation 2009, 6:23
m/kg). We computed the mass-specific positive (and negative) mechanical work delivered by the orthosis ankle
and knee torques over the stride in the same manner as
was done for the mechanical work performed by the joint
net muscle-tendon moments.
Electromyography
We recorded lower-limb surface electromyography (EMG)
(1200 Hz, Konigsberg Instruments, Inc., Pasadena, CA,
USA) from the left soleus (Sol), tibialis anterior (TA), vastus lateralis (VL) and medial hamstrings (MH) using bipolar electrodes (inter-electrode distance 3.5 cm) centered
over the belly of the muscle along its long axis. We performed simple functional tests (i.e. joint flexion or extension against resistance) to verify that our electrode
placements gave appropriate signals for each muscle.
EMG amplifier bandwidth filter was 12.5 Hz – 920 Hz.
We placed electrodes to minimize cross-talk and taped
them down to minimize movement artifact. We high-pass
filtered (4th-order Butterworth, fc = 50 Hz), rectified and
low-pass filtered (4th-order Butterworth, fc = 10 Hz) each
of the EMG signals (i.e. linear envelope).
http://www.jneuroengrehab.com/content/6/1/23
PMFI-to-Without pairings. Similarly, for orthosis kinetics,
we correlated the mean stride cycle average time-series for
the orthosis ankle and knee torque and power curves during the powered conditions (PM and PMFI) to the ankle
and knee joint net muscle-tendon moment and power
curves during walking without the orthosis (Without) (i.e.
PM-Without and PMFI-Without pairings).
We used JMP statistical software (SAS Institute, Inc. Cary,
NC, USA) to perform repeated measures analysis of variance tests (ANOVAs) on (1) the r-values from the above
described Pearson product moment correlations, and (2)
the positive and negative mechanical work values calculated from ankle and knee joint mechanical power curves
(without) and ankle and knee orthosis power curves (PM
and PMFI) (two-way tests: subject, mode). When we
found a significant effect (p < 0.05) we used post-hoc
Tukey Honestly Significant Difference (THSD) tests to
determine specific differences between means. We performed statistical power analyses for each test (see Tables
2 and 3).
Results
Statistical Analyses
To assess the effect of orthosis control mode (PM or PMFI)
on orthosis mechanical performance (joint kinematics
and joint kinetics) we performed Pearson product
moment correlations (i.e. r-values). For joint kinematics,
we correlated the mean stride cycle average time-series for
ankle, knee and hip joint angles for PM-to-Without and
Without orthosis versus unpowered orthosis
All three subjects were able to walk comfortably while
wearing the knee-ankle-foot orthosis (KAFO) with artificial pneumatic muscles turned off. Kinetic (net joint muscle-tendon moments and powers), kinematic (joint
angles), and surface electromyography profiles for walk-
Table 2: Moment, Power and Angle Correlations to Without Orthosis Walking
Pearson r-value
PM
PMFI
ANOVA p-value;
Power
Mean
SE
Mean
SE
0.85
0.05
0.76
0.11
Orthosis Ankle
Torque
Orthosis Ankle
Power
Orthosis Knee
Torque
Orthosis Knee
Power
Ankle Angle
0.53
0.11
0.72
0.07
-0.01
0.21
0.55
0.04
-0.03
0.06
0.17
0.11
0.49
0.13
0.74
0.04
Knee Angle
0.90
0.03
0.95
0.03
Hip Angle
0.98
0.01
0.98
0.00
p = 0.28
P = 0.14
*p = 0.04
P = 0.70
p = 0.09
P = 0.42
p = 0.33
P = 0.12
*p = 0.05
P = 0.80
p = 0.17
P = 0.24
p = 0.71
P = 0.06
THSD
PMFI > PM
PMFI > PM
Values are Mean ± Standard Error for n = 3 subjects.
*Indicates a p-value of less than 0.05 showing significant differences between conditions.
Statistical power, P, is reported under the p-value.
Tukey Honestly Significant Difference (THSD) results are reported for metrics with significance.
PM = proportional myoelectriccontrol PMFI = proportional myoelectric control with flexor inhibition
Page 5 of 16
(page number not for citation purposes)
Journal of NeuroEngineering and Rehabilitation 2009, 6:23
http://www.jneuroengrehab.com/content/6/1/23
Table 3: Mechanical Work Summary
Work (J/kg)
Without
ANKLE
KNEE
Orthosis PM
Orthosis PMFI
Mean
SE
Mean
SE
Mean
SE
Pos.
0.21
0.03
0.18
0.03
0.21
0.02
Neg.
0.25
0.03
0.10
0.02
0.11
0.02
Pos.
0.05
0.02
0.06
0.02
0.09
0.03
Neg.
0.31
0.02
0.04
0.02
0.06
0.03
ANOVA p-value;
Power
THSD
p = 0.52
P = 0.11
*p = 0.03
P = 0.76
PM < WO
PMFI < WO
p = 0.65
P = 0.09
*p = 0.003
P = 0.99
PM < WO
PMFI < WO
Values are Mean ± Standard Error for n = 3 subjects.
*Indicates a p-value of less than 0.05 showing significant differences between conditions.
Statistical power, P, is reported under the p-value.
Tukey Honestly Significant Difference (THSD) results are reported for metrics with significance.
PM = proportional myoelectric control PMFI = proportional myoelectric control with flexor inhibition
ing with the orthosis unpowered were similar to those
walking without the orthosis (Figures 2, 3, 4).
Orthosis ankle joint performance: PM versus PMFI
Soleus and tibialis anterior electromyography (EMG) patterns were nearly identical for the two proportional myoelectric control conditions (PM vs. PMFI) but the control
signals generated were markedly different (Figures 4, 5).
Due to the flexor inhibition algorithm, the control signal
voltage was much lower for the artificial dorsiflexor during the stance phase (~3 V versus 0 V) in the PMFI versus
PM control mode.
Artificial muscle force patterns reflected the differences in
control signals between the proportional myoelectric control modes. With direct proportional myoelectric control
(PM), the artificial plantar flexor force peaked late in
stance at 645 ± 57 N (mean ± SEM). With the flexor inhibition algorithm (PMFI), the peak artificial plantar flexor
force was only 533 ± 71 N. Artificial dorsiflexor forces followed a similar trend, peaking early in stance at 388 ± 27
N during powered walking under PM control but reaching
a peak of only 196 ± 60 N during PMFI (Figure 5).
The flexor inhibition controller (PMFI) reduced co-activation of the antagonist artificial plantar flexor and dorsiflexors compared to direct proportional myoelectric
control (PM), but it also reduced net torque magnitudes
(Figure 5). In PM control mode, the orthosis delivered
0.67 ± 0.09 N-m/kg peak plantar flexor torque near the
end of the stance phase and -0.31 ± 0.08 N-m/kg peak
dorsiflexor torque early in the stance phase (Figure 5).
These values were ~46% and ~129% of peak biological
plantar flexor and dorsiflexor net muscle-tendon
moments from walking without the orthosis (Figure 6). In
PMFI control mode, peak ankle orthosis torques were
reduced to 0.62 ± 0.09 N-m/kg peak plantar flexor and 0.20 ± 0.09 N-m/kg peak dorsiflexor (Figure 5). These
were 42% and 83% of peak biological plantar flexor and
dorsiflexor net muscle-tendon moments (Figure 6).
Despite reductions in peak torque magnitudes for PMFI
versus PM control, the orthosis torque patterns during
PMFI and PM control were equally similar to the ankle
moment during walking without the orthosis. The Pearson product moment correlation (r-value) for ankle
torque was not significantly different for PMFI-Without
(0.76 ± 0.11) versus PM-Without (0.85 ± 0.05) (p = 0.28)
(Table 2).
The flexor inhibition algorithm (PMFI) resulted in greater
mechanical power generation at the orthosis ankle joint
compared to direct proportional myoelectric control
(PM). Biological ankle muscle-tendon positive mechanical power peaked at 2.19 ± 0.38 W/kg during normal
walking at 1.25 m/s without the orthosis. During powered
walking under direct PM control, the orthosis peak positive power was 1.45 ± 0.35 W/kg (Figure 6). With PMFI
control, the orthosis peak positive power was 1.88 ± 0.28
W/kg, a 30% increase over PM control. Furthermore, the
orthosis ankle positive mechanical work also tended
higher during powered walking with PMFI control (0.21 ±
0.02 J/kg) versus PM control (0.18 ± 0.03 J/kg) (Table 3).
The ankle mechanical power Pearson product moment
correlation for PMFI-Without (0.72 ± 0.07) was significantly higher than the correlation for PM-Without (0.53 ±
0.11) (p = 0.04) (Table 2).
Page 6 of 16
(page number not for citation purposes)
Journal of NeuroEngineering and Rehabilitation 2009, 6:23
http://www.jneuroengrehab.com/content/6/1/23
WITHOUT
UNPOWERED
PM
PMFI
+ Plantarflexion
2.0
Total
Net
Ankle
Moment
(N-m/kg)
-0.5
+ Extension
1.2
Total
Net
Knee
Moment
(N-m/kg)
-0.5
+ Extension
1.0
Total
Net
Hip
Moment
(N-m/kg)
-1.2
100 0
100 0
0
Stride Cycle (%)
Stride Cycle (%)
100
Stride Cycle (%)
Figureknee
Ankle,
2 and hip total net joint moments
Ankle, knee and hip total net joint moments. Mean (thick lines) + 1 standard deviation (thin lines) stride cycle average
(0%-left heel strike to 100%-left heel strike) total net joint moments for the ankle, knee and hip. Plotted values were normalized by subject mass (N-m/kg). The total moment was measured externally and included contributions from biological muscletendons and orthosis artificial muscles (except for the hip in all conditions and for the ankle and knee in the without orthosis
condition). Data across rows (from left to right) were for walking at 1.25 m/s overground with the orthosis unpowered
(Unpowered, gray), powered under proportional myoelectric control (PM, red) and powered under proportional myoelecric
control with flexor inhibition (PMFI, blue). In each panel, traces are compared to normal walking without wearing the orthosis
(Without, black). Dotted vertical lines mark the stance-swing transition at ~60% of the stride cycle. Positive values indicate
ankle plantar flexor, knee extensor and hip extensor moments.
The ankle joint artificial muscles did a poor job absorbing
mechanical energy under both proportional myoelectric
control modes. Except for early in stance, when net orthosis dorsiflexor torque absorbed energy to prevent foot
drop, the ankle orthosis performed very little negative
mechanical work (Figure 6). In both control modes (PM
and PMFI), the orthosis performed ~40% less negative
work than the biological ankle muscle-tendon moment
during walking without the orthosis (p = 0.03) (Table 3).
The total net ankle joint moment (net orthosis ankle
torque + biological ankle net muscle-tendon moment)
was qualitatively similar between the powered walking
conditions (PM versus PMFI) and walking without the
orthosis (Figure 2).
Ankle joint kinematics during walking without the orthosis were much more similar to ankle joint kinematics during powered walking with flexor inhibition (PMFI)
compared to powered walking without flexor inhibition
(PM). With direct proportional myoelectric control (PM),
the ankle joint was more dorsiflexed both early in stance
and late in swing when compared to normal walking
without the orthosis. In contrast, the ankle angle profile
during powered walking under PMFI control was very
similar to walking without the orthosis (Without) (Figure
Page 7 of 16
(page number not for citation purposes)
Journal of NeuroEngineering and Rehabilitation 2009, 6:23
WITHOUT
UNPOWERED
http://www.jneuroengrehab.com/content/6/1/23
PMFI
PM
+ Plantarflexion
30
Ankle
Angle
(deg)
-15
+ Extension
15
Knee
Angle
(deg)
-70
+ Extension
25
Hip
Angle
(deg)
-40
0
100 0
Stride Cycle (%)
100
100 0
Stride Cycle (%)
Stride Cycle (%)
Figureknee
Ankle,
3 and hip joint angles
Ankle, knee and hip joint angles. Three subject mean (thick lines) + 1 SD (thin lines) stride cycle average (0%-left heel
strike to 100%-left heel strike) joint angles (deg) for the ankle, knee and hip. Data across rows (from left to right) are for walking at 1.25 m/s overground with the orthosis unpowered (Unpowered, gray), powered under proportional myoelectric control
(PM, red) and powered under proportional myoelecric control with flexor inhibition (PMFI, blue). In each panel, traces are
compared to normal walking without wearing the orthosis (Without, black). Dotted vertical lines mark the stance-swing transition at ~60% of the stride cycle. Angles are measured with reference to quiet standing posture. Positive angles indicate ankle
plantarflexion, knee extension and hip extension.
3). The Pearson product moment correlation for ankle
angle was significantly higher for PMFI-Without (0.74 ±
0.04) versus PM-Without (0.49 ± 0.13) time-series comparisons (p = 0.05) (Table 2).
When compared to normal walking without the orthosis
(Without), ankle muscle electromyography (soleus and
tibilais anterior) patterns were altered during powered
walking under both proportional myoelectric control
modes. During powered walking with direct proportional
myoelectric control (PM), soleus muscle activity was
slightly greater than normal early in stance and tibialis
anterior activity was markedly higher than normal in early
swing (Figure 4). Although perhaps slightly attenuated,
there were similar increases in muscle activity during powered walking with flexor inhibition (PMFI) (Figure 4).
Orthosis knee joint performance: PM versus PMFI
Knee artificial muscle co-activation was nearly eliminated
with the flexor inhibition algorithm (PMFI) compared to
direct proportional myoelectric control (PM). During
powered walking in PM control, the artificial knee extensors and flexors were co-activated over the entire stride.
The two artificial knee extensors combined to produce
peak forces in mid-stance of 629 ± 72 N. The two artificial
flexors combined to produce a nearly constant force over
the stride, peaking at 472 ± 147 N. During powered walking in PMFI control, both peak knee extensor (494 ± 79
Page 8 of 16
(page number not for citation purposes)
Journal of NeuroEngineering and Rehabilitation 2009, 6:23
WITHOUT
UNPOWERED
http://www.jneuroengrehab.com/content/6/1/23
PMFI
PM
210
Sol
(uV)
0
220
TA
(uV)
0
120
VL
(uV)
0
140
MH
(uV)
0
0
100 0
Stride Cycle (%)
100
100 0
Stride Cycle (%)
Stride Cycle (%)
Figureand
Ankle
4 knee muscle surface electromyography
Ankle and knee muscle surface electromyography. Three subject mean (thick lines) + 1 SD (thin lines) stride cycle average (0%-left heel strike to 100%-left heel strike) electromyography amplitudes (uV) for the knee-ankle-foot orthosis control
muscles at the ankle (Sol – soleus and TA – tibialis anterior) and the knee (VL – vastus lateralis and MH – medial hamstrings).
Data across rows (from left to right) are for walking at 1.25 m/s overground with the orthosis unpowered (Unpowered, gray),
powered under proportional myoelectric control (PM, red) and powered under proportional myoelecric control with flexor
inhibition (PMFI, blue). In each panel, traces are compared to normal walking without wearing the orthosis (Without, black).
Dotted vertical lines mark the stance-swing transition at ~60% of the stride cycle.
Page 9 of 16
(page number not for citation purposes)
Journal of NeuroEngineering and Rehabilitation 2009, 6:23
http://www.jneuroengrehab.com/content/6/1/23
Ankle PM Control
Ankle PMFI Control
160
EMG
(uV)
80
0
10
Control
Signals
(V)
5
0
800
Artificial
Pneumatic
Muscle 400
Forces
(N)
0
1.0
+ Plantarflexion
Orthosis
Net
Torque
(N-m/kg)
-0.3
0
100
Stride Cycle (%)
0
100
Stride Cycle (%)
Figure 5 (see legend on next page)
Page 10 of 16
(page number not for citation purposes)
Journal of NeuroEngineering and Rehabilitation 2009, 6:23
http://www.jneuroengrehab.com/content/6/1/23
Figure 5 ankle
Orthosis
(see previous
joint control
page)
Orthosis ankle joint control. Data are mean (solid lines) + 1 SD (thin lines where reported) for three subjects walking at
1.25 m/s with the knee-ankle-foot orthosis powered in two control modes: direct proportional myoelectric control (PM, left
column) and proportional myoelectric control with flexor inhibition (PMFI, right column). Each column (from top to bottom)
shows: surface electromyography (μV) from the users' soleus (black) and tibialis anterior (grey); processed pneumatic control
signals (V) for the artificial plantarflexor (black) and dorsifelxor (grey); the forces (N) generated by the antagonistic artificial
muscles (plantar flexor in black and dorsiflexor in grey); and the resulting net artificial muscle torque (N-m/kg) delivered at the
ankle joint (PM, left column in red and PMFI, right column in blue). Plantar flexor torque is positive. All data are plotted over a
stride cycle from left heel strike (0%) to left heel strike (100%). Dashed vertical lines at 60% of the stride mark the stanceswing transition. Horizontal lines on the electromyography traces indicate the threshold setting (μV) above which a proportional control signal is generated (plantar flexor in black and dorsiflexor in grey).
N) and peak knee flexor (162 ± 18 N) forces were reduced
(Figure 7).
The orthosis knee net joint torque was drastically different
during powered walking with PM versus PMFI control.
During walking in direct proportional myoelectric control
(PM), the knee artificial flexors and extensors co-activated, stiffening the joint, and delivered a small net flexor
torque over the entire stride (Figure 7). The knee orthosis
torque pattern did not coincide (in magnitude or timing)
with the biological knee net muscle-tendon moments
(Figure 8). For powered walking under PM control mode,
the powered knee peak extensor torque was 0.10 ± 0.03 Nm/kg and peak flexor torque was -0.13 ± 0.02 N-m/kg.
These reached only 22% of peak biological knee extensor
(0.45 ± 0.10 N-m/kg) and 33% of peak biological knee
flexor (-0.39 ± 0.03 N-m/kg) net muscle-tendon moments
from walking without the orthosis (Figure 8). In contrast,
during PMFI, the peak knee orthosis extensor torque during powered walking was 50% higher (0.15 ± 0.04 N-m/
kg) than during powered walking under PM control. Furthermore, the timing of the orthosis knee torque during
PMFI was more similar to normal walking when compared to PM. The Pearson product moment correlation for
knee torque was greater for PMFI-Without (0.55 ± 0.04)
compared to PM-Without (-0.01 ± 0.21) (p = 0.09) (Table
2). Although the flexor inhibition controller had better
orthosis extensor torque timing and magnitude, the knee
orthosis peak flexor torque during PMFI was smaller (0.06 ± 0.03) than during PM. The knee orthosis peak
flexor torque during PMFI was only 15% of biological
knee flexor peak net muscle-tendon moment during walking without the orthosis (Figure 7).
Total net knee joint moment (net orthosis knee torque +
biological knee net muscle-tendon moment) was qualitatively more similar to walking without the orthosis with
PMFI versus PM control (Figure 2).
Mechanical power delivered by the orthosis knee joint
was greater with the flexor inhibition control algorithm
(PMFI) compared to the direct proportional myoelectric
control (PM). The Pearson product moment correlation
for knee mechanical power was higher for PMFI-Without
(0.17 ± 0.11) versus PM-Without (-0.03 ± 0.06) (p = 0.33)
(Table 2). However, the orthosis knee was poor at absorbing mechanical energy for both powered conditions. The
orthosis knee artificial muscles absorbed significantly less
mechanical energy than biological knee muscle-tendons
during normal walking (p = 0.003) (Figure 8) (Table 3).
During powered walking under PM, the knee net orthosis
torque performed -0.04 ± 0.02 J/kg negative work versus 0.06 ± 0.03 J/kg during walking under PMFI control.
The flexor inhibition controller (PMFI) produced knee
kinematics that were similar to walking without the orthosis (Figure 3). With PM control, the knee was more flexed
during stance and less flexed during swing than normal
walking. Increased knee flexion was absent during powered walking under PMFI control. The Pearson product
moment correlation for knee angle was greater for PMFIWithout (0.95 ± 0.03) compared to PM-Without (0.90 ±
0.03), but not significantly so (p = 0.17) (Table 2).
Knee muscle electromyography was different in both
powered walking conditions (PM and PMFI) when compared to normal walking without the orthosis (Without).
For vastus lateralis, during powered walking with direct
proportional myoelectric control (PM), muscle activity
was greater than normal throughout stance and late in
swing. For medial hamstrings, activity was markedly
higher than during the stance-swing transition (Figure 4).
Knee muscle activity patterns were similar for powered
walking under direct PM and the flexor inhibition (PMFI)
control (Figure 4).
Hip joint kinetics and kinematics: PM versus PMFI
Total hip joint net muscle moments (Figure 2) and hip
joint kinematics (Figure 3, Table 2) during powered walking were similar to normal walking without the orthosis
(Without). This was true for both proportional myoelectric control modes (PM and PMFI).
Page 11 of 16
(page number not for citation purposes)
Journal of NeuroEngineering and Rehabilitation 2009, 6:23
http://www.jneuroengrehab.com/content/6/1/23
Ankle PM Control
Ankle PMFI Control
+ Plantarflexion
1.7
Net
Moment
(N-m/kg)
-0.4
3.0
Mechanical
Power
(W/kg)
-1.5
0
100
Stride Cycle (%)
0
100
Stride Cycle (%)
Figure 6 ankle joint kinetics
Orthosis
Orthosis ankle joint kinetics. Data traces are mean (solid lines) + 1 SD (thin lines) from the left leg of three subjects who
walked overground at 1.25 m/s with a knee-ankle-foot orthosis powered in two control modes. In the left column, data from
powered trials with direct proportional myoelectric control (PM, red) for net torque (N-m/kg) (top) generated by the ankle
joint artificial muscles and the resulting mechanical power (W/kg) (bottom) is compared with the net ankle muscle-tendon
moment (N-m/kg) and mechanical power (W/kg) recorded during walking without the orthosis (black). The right column
shows similar data for powered trials using proportional myoelectric control with a flexor inhibition algorithm (PMFI, blue).
Stride cycles begin (0%) and end (100%) at left heel strike. Dotted vertical lines mark the stance-swing transition at ~60% of the
stride cycle. Plantar flexor torque/moment is positive. Positive mechanical power indicates energy generation and negative
mechanical power indicates energy absorption.
Discussion
The addition of a flexor inhibition algorithm (PMFI) to
the standard proportional myoelectric controller (PM)
allowed naïve users of the powered knee-ankle-foot
orthosis to walk with their normal gait. The flexor inhibition algorithm reduced artificial pneumatic muscle coactivation and produced joint kinematics and joint kinetics at both the knee and ankle that were similar to walking
without the orthosis (Figures 2, 3, 6 and 8). A modified
version of the controller that would more closely mimic
human neurophysiology might include inhibition of artificial extensor muscles from leg flexor electromyography
during swing [22,25]. This modification could potentially
result in gait dynamics even more similar to normal unassisted walking.
In general, proportional myoelectric control has specific
advantages and disadvantages for control of lower limb
robotic orthoses compared to other control approaches.
The advantages are: 1) it provides an effective way to scale
the magnitude of the orthosis mechanical assistance due
to its physiological nature [3,26], 2) it appears to lead to
a greater reduction in biological muscle recruitment compared to kinematic based control algorithms [27], and 3)
it easily allows the nervous system to adapt orthosis control for novel motor tasks. The disadvantages are: 1) it can
Page 12 of 16
(page number not for citation purposes)
Journal of NeuroEngineering and Rehabilitation 2009, 6:23
http://www.jneuroengrehab.com/content/6/1/23
Knee PM Control
Knee PMFI Control
100
EMG
(uV)
50
0
10
Control
Signals
(V)
5
0
1000
Artificial
Pneumatic
Muscle
Forces
(N)
500
0
+ Extension
0.25
Orthosis
Net
Torque
(N-m/kg)
-0.15
0
100
Stride Cycle (%)
0
100
Stride Cycle (%)
Figure 7 (see legend on next page)
Page 13 of 16
(page number not for citation purposes)
Journal of NeuroEngineering and Rehabilitation 2009, 6:23
http://www.jneuroengrehab.com/content/6/1/23
Figure 7 knee
Orthosis
(see previous
joint control
page)
Orthosis knee joint control. Data are mean (solid lines) + 1 SD (thin lines where reported) for three subjects walking at
1.25 m/s with the knee-ankle-foot orthosis powered in two control modes: direct proportional myoelectric control (PM, left
column) and proportional myoelectric control with flexor inhibition (PMFI, right column). Each column (from top to bottom)
shows: surface electromyography (μV) from the users' vastus lateralis (black) and medial hamstrings (grey); processed pneumatic control signals (V) for the artificial knee extensor (black) and knee flexor (grey); the forces (N) generated by the antagonistic artificial muscles (extensors in black and flexors in grey); and the resulting net artificial muscle torque (N-m) delivered at
the knee joint (PM, left column in red and PMFI, right column in blue). Knee extensor torque is positive. All data are plotted
over a stride cycle from left heel strike (0%) to left heel strike (100%). Dashed vertical lines at 60% of the stride mark the
stance-swing transition. Horizontal lines on the electromyography traces indicate the threshold setting (μV) above which a
proportional control signal is generated (knee extensor in black and knee flexor in grey).
Knee PM Control
Knee PMFI Control
+ Extension
0.7
+ Extension
Net
Moment
(N-m/kg)
-0.4
0.8
Mechanical
Power
(W/kg)
-1.3
0
100
Stride Cycle (%)
0
100
Stride Cycle (%)
Figure 8 knee joint kinetics
Orthosis
Orthosis knee joint kinetics. Data traces are mean (solid lines) + 1 SD (thin lines) from the left leg of three subjects who
walked overground at 1.25 m/s with a knee-ankle-foot orthosis powered in two control modes. In the left column, data from
powered trials with direct proportional myoelectric control (PM, red) for net torque (N-m/kg) (top) generated by knee joint
artificial muscles and the resulting mechanical power (W/kg) (bottom) is compared with the net ankle muscle-tendon moment
(N-m/kg) and mechanical power (W/kg) recorded during walking without the orthosis (black). The right column shows similar
data for powered trials using proportional myoelectric control with a flexor inhibition algorithm (PMFI, blue). Stride cycles
begin (0%) and end (100%) at left heel strike. Dotted vertical lines mark the stance-swing transition at ~60% of the stride cycle.
Knee extensor torque/moment is positive. Positive mechanical power indicates energy generation and negative mechanical
power indicates energy absorption.
Page 14 of 16
(page number not for citation purposes)
Journal of NeuroEngineering and Rehabilitation 2009, 6:23
be difficult to obtain a reliable and consistent myoelectric
signal due to the surface electrode interface [26], 2) choosing the appropriate threshold and gain requires tuning
[28], and 3) the complexity of the musculoskeletal system
includes many synergistic muscles that are not all easily
accessible with surface electromyography [29]. Development of small wireless intramuscular electrodes and adaptive control algorithms could substantially attenuate these
disadvantages in the near future [30,31].
A common question about proportional myoelectric control as a means for operating powered orthoses for neurological rehabilitation is "why use a neural signal that is
weak and disordered to guide robotic assistance?". The
answer to that question is based on motor learning theory. Motor learning is directly related to how our nervous
system detects motor error. When inappropriate electrical
signals are sent to the muscles of a limb, the proprioceptive (and visual) feedback about the limb's performance
allows the nervous system to determine if there was error
in the performance. Performance error is the major impetus for dynamic motor adaptation [32,33]. A neurologically impaired human that sends a weak and noisy
electrical signal to their muscles will have difficulty deducing when the signal was appropriate and when it was
inappropriate. This is especially true if the proprioceptive
feedback is also weak and noisy. Proportional myoelectric
control of artificial pneumatic muscles on a robotic orthosis provides a way to amplify the consequences of the electrical signal sent to the biological muscles. This makes it
easier for the nervous system to detect performance error
and alter the subsequent electrical commands to the muscles. This approach could be considered similar in a way
to the error amplification control algorithm suggested by
Patton and colleagues for robotic rehabilitation devices
[34,35].
http://www.jneuroengrehab.com/content/6/1/23
shell materials, larger circumference artificial pneumatic
muscles, cams, gears, Bowden cable transmission [36,37]
or different actuators (e.g. pneumatic cylinders) to alleviate limitations in knee torque production.
Consistent with our previous results using a powered
ankle-foot orthosis [28,38], the artificial muscles performed more positive mechanical work than negative
mechanical work during the gait cycle (Table 3). This is
likely related to the inherent mechanical characteristics of
artificial pneumatic muscles. Although artificial muscles
can perform negative work, their force-length properties
result in a steep linear increase in force as they lengthen
(assuming constant activation) [39-41]. The large increase
in artificial muscle force during stretch makes it difficult to
perform extended negative mechanical work against inertial loads like human body mass. It would be possible to
decrease the activation amplitude of an artificial pneumatic muscle as it lengthens to keep force relatively stable,
but this does not seem easy for the human nervous system
to do with proportional myoelectric control [28,38].
Thus, for robotic orthoses intended to perform primarily
negative mechanical work (e.g. at the knee joint), it might
be preferable to use actuators that can provide variable
damping [21,42].
Powered knee-ankle-foot orthoses have promising clinical
and basic science applications. We have successfully
applied our ankle device and its control architecture to
assist individuals with incomplete spinal cord injury during locomotor training [43] and to study neural adaptation [27-29,44] and metabolic energy consumption in
neurally intact human walkers [38,45,46]. Future studies
will aim to extend these research paradigms to the knee
and ultimately, the hip.
Competing interests
The current orthosis design provided less mechanical
assistance about the knee than about the ankle. This is
largely due to the trade off in torque and range of motion
that occurs with artificial pneumatic muscles. The knee
joint undergoes about twice the angular displacement of
the ankle joint during human walking (Figure 3). To provide for the greater range of motion at the knee, the
moment arms of the artificial knee muscles were only
about one third of the moment arms for the artificial
ankle muscles. Artificial pneumatic muscles can only
shorten about one third of their resting length and cannot
be stretched substantially beyond their resting length
without breaking. Using greater moment arms for the
knee artificial muscles would have required greater artificial muscle displacements than what was possible.
Another factor limiting energy transmission from artificial
muscles to the user's joint is compliance in the orthosis
carbon fiber shell [5]. Future designs could include stiffer
The authors declare that they have no competing interests.
Authors' contributions
GSS recruited subjects, managed data collections, completed data analysis and drafted the manuscript. DPF conceived of the study, provided guidance on experimental
design and helped edit the manuscript. All authors read
and approved the final manuscript.
Acknowledgements
The work was supported by the Christopher Reeve Paralysis Foundation
(FAC2-0101) and the National Science Foundation (BES-0347479). We
would like to thank Catherine Kinnaird, Keith Gordon and other members
of the Human Neuromechanics Laboratory for assisting with data collection. Ammanath Peethambaran, C.O. and Jarod Butler, C.O. of the University of Michigan Orthotics and Prosthetics Center helped construct the
orthoses.
Page 15 of 16
(page number not for citation purposes)
Journal of NeuroEngineering and Rehabilitation 2009, 6:23
References
1.
2.
3.
4.
5.
6.
7.
8.
9.
10.
11.
12.
13.
14.
15.
16.
17.
18.
19.
20.
21.
22.
23.
Ferris DP, Sawicki GS, Domingo A: Powered lower limb orthoses
for gait rehabilitation. Topics in Spinal Cord Injury Rehabilitation
2005, 11:34-49.
Sawicki GS, Gordon KE, Ferris DP: Powered lower limb
orthoses: applications in motor adaptation and rehabilitation. In Proceedings of the IEEE International Conference on Rehabilitation Robotics; Chicago, IL IEEE; 2005.
Ferris DP, Sawicki GS, Daley MA: A physiologist's perspective on
robotic exoskeletons for human locomotion. International Journal of Humanoid Robotics 2007, 4:507-528.
Ferris DP, Gordon KE, Sawicki GS, Peethambaran A: An improved
powered ankle-foot orthosis using proportional myoelectric
control. Gait Posture. 2006, 23(4):425-428.
Gordon KE, Sawicki GS, Ferris DP: Mechanical performance of
artificial pneumatic muscles to power an ankle-foot orthosis.
Journal of Biomechanics 2006, 39:1832-1841.
Neptune RR, Kautz SA, Zajac FE: Contributions of the individual
ankle plantar flexors to support, forward progression and
swing initiation during walking. Journal of Biomechanics 2001,
34:1387-1398.
Meinders M, Gitter A, Czerniecki JM: The role of ankle plantar
flexor muscle work during walking. Scandinavian Journal of Rehabilitation Medicine 1998, 30:39-46.
Gottschall JS, Kram R: Energy cost and muscular activity
required for propulsion during walking. Journal of Applied Physiology 2003, 94:1766-1772.
Eng JJ, Winter DA: Kinetic analysis of the lower limbs during
walking: what information can be gained from a threedimensional model? Journal of Biomechanics 1995, 28:753-758.
Teixeira-Salmela LF, Nadeau S, Milot MH, Gravel D, Requiao LF:
Effects of cadence on energy generation and absorption at
lower extremity joints during gait. Clinical Biomechanics 2008,
23:769-778.
Umberger BR, Martin PE: Mechanical power and efficiency of
level walking with different stride rates. Journal of Experimental
Biology 2007, 210:3255-3265.
Kuo AD, Donelan JM, Ruina A: Energetic consequences of walking like an inverted pendulum: step-to-step transitions. Exerc
Sport Sci Rev. 2005, 33(2):88-97.
Mavroidis C, Nikitczuk J, Weinberg B, Danaher G, Jensen K, Pelletier
P, Prugnarola J, Stuart R, Arango R, Leahey M, et al.: Smart portable
rehabilitation devices. Journal of Neuroengineering and Rehabilitation
2005, 2:18.
Zoss AB, Kazerooni H, Chu A: Biomechanical Design of the Berkeley Lower Extremity Exoskeleton (BLEEX). IEEE/ASME
Transactions on Mechatronics 2006, 11:128-138.
Kawamoto H, Sankai Y: Power assist system HAL-3 for gait disorder person. In Computer Helping People with Special Needs: 8th
International Conference, ICCHP 2002 Edited by: Miesenberger K, Klaus
J, Zagler W. Berlin: Springer Verlag; 2002:196-203.
Zoss A, Kazerooni H: Design of an electrically actuated lower
extremity exoskeleton. Advanced Robotics 2006, 20:967-988.
Pratt JE, Krupp BT, Morse CJ, Collins SH: The RoboKnee: an
exoskeleton for enhancing strength and endurance during
walking. In IEEE International Conference on Robotics and Automation;
New Orleans, LA IEEE Press; 2004:2430-2435.
Fleischer C, Hommel G: A human–exoskeleton interface utilizing electromyography. Ieee Transactions on Robotics 2008,
24:872-882.
Cullell A, Moreno JC, Rocon E, Forner-Cordero A, Pons JL: Biologically based design of an actuator system for a knee-anklefoot orthosis. Mechanism and Machine Theory 2009, 44:860-872.
do Nascimento BG, Vimieiro CBS, Nagem DAP, Pinotti M: Hip
orthosis powered by pneumatic artificial muscle: voluntary
activation in absence of myoelectrical signal. Artificial Organs
2008, 32:317-322.
Dollar AM, Herr H: Lower extremity exoskeletons and active
orthoses: Challenges and state-of-the-art. Ieee Transactions on
Robotics 2008, 24:144-158.
Enoka RM: Neuromechanics of Human Movement 4th edition. Champaign, IL: Human Kinetics; 2008.
Ferris DP, Czerniecki JM, Hannaford B: An ankle-foot orthosis
powered by artificial pneumatic muscles. Journal of Applied Biomechanics 2005, 21:189-197.
http://www.jneuroengrehab.com/content/6/1/23
24.
25.
26.
27.
28.
29.
30.
31.
32.
33.
34.
35.
36.
37.
38.
39.
40.
41.
42.
43.
44.
45.
46.
Zatsiorsky V, Seluyanov V: The mass and inertial characteristics
of the main segments of the human body. In Biomechanics VIIIB Edited by: Matsui HaK K. Champaign, IL: Human Kinetics;
1983:1152-1159.
Crone C, Hultborn H, Jespersen B, Nielsen J: Reciprocal Ia inhibition between ankle flexors and extensors in man. J Physiol.
1987, 389:163-185.
Parker P, Englehart K, Hudgins B: Myoelectric signal processing
for control of powered limb prostheses. J Electromyogr Kinesiol.
2006, 16(6):541-548.
Cain SM, Gordon KE, Ferris DP: Locomotor adaptation to a
powered ankle-foot orthosis depends on control method. J
Neuroeng Rehabil. 2007, 4:48.
Gordon KE, Ferris DP: Learning to walk with a robotic ankle
exoskeleton. Journal of Biomechanics 2007, 40:2636-2644.
Kinnaird CR, Ferris DP: Medial Gastrocnemius Myoelectric
Control of a Robotic Ankle Exoskeleton. IEEE Trans Neural Syst
Rehabil Eng. 2009, 17(1):31-37.
Farrell TR, Weir RF: A comparison of the effects of electrode
implantation and targeting on pattern classification accuracy for prosthesis control. IEEE Transactions on Biomedical Engineering 2008, 55:2198-2211.
Ohnishi K, Weir RF, Kuiken TA: Neural machine interfaces for
controlling multifunctional powered upper-limb prostheses.
Expert Rev Med Devices 2007, 4:43-53.
Emken JL, Benitez R, Sideris A, Bobrow JE, Reinkensmeyer DJ: Motor
adaptation as a greedy optimization of error and effort. Journal of Neurophysiology 2007, 97:3997-4006.
Scheidt RA, Dingwell JB, Mussa-Ivaldi FA: Learning to move amid
uncertainty. Journal of Neurophysiology 2001, 86:971-985.
Patton JL, Stoykov ME, Kovic M, Mussa-Ivaldi FA: Evaluation of
robotic training forces that either enhance or reduce error
in chronic hemiparetic stroke survivors. Exp Brain Res. 2006,
168(3):368-383.
Reinkensmeyer DJ, Patton JL: Can robots help the learning of
skilled actions? Exerc Sport Sci Rev. 2009, 37(1):43-51.
Veneman JF, Ekkelenkamp R, Kruidhof R, Helm FCT van der, Kooij H
van der: Design of a series elastic and bowdencable-based
actuation system for use as torque-actuator in exoskeletontype training robots. Rehabilitation Robotics, 2005 ICORR 2005 9th
International Conference on 2005:496-499.
Sulzer JS, Peshkin MA, Patton JL: MARIONET: An ExotendonDriven Rotary Series Elastic Actuator for Exerting Joint
Torque. In IEEE International Conference on Rehabilitation Robotics; Chicago, IL IEEE; 2005.
Sawicki GS, Ferris DP: Mechanics and energetics of level walking with powered ankle exoskeletons. Journal of Experimental
Biology 2008, 211:1402-1413.
Davis S, Tsagarakis N, Canderle J, Caldwell DG: Enhanced modelling and performance in braided pneumatic muscle actuators. International Journal of Robotics Research 2003, 22:213-227.
Klute GK, Czerniecki JM, Hannaford B: Artificial muscles: Actuators for biorobotic systems. International Journal of Robotics
Research 2002, 21:295-309.
Reynolds DB, Repperger DW, Phillips CA, Bandry G: Modeling the
dynamic characteristics of pneumatic muscle. Annals of Biomedical Engineering 2003, 31:310-317.
Walsh CJ, Endo K, Herr H: A quasi-passive leg exoskeleton for
load-carrying augmentation. International Journal of Humanoid
Robotics 2007, 4:487-506.
Sawicki GS, Domingo A, Ferris DP: The effects of powered anklefoot orthoses on joint kinematics and muscle activation during walking in individuals with incomplete spinal cord injury.
J Neuroeng Rehabil. 2006, 3:3.
Kao PC, Ferris DP: Motor adaptation during dorsiflexionassisted walking with a powered orthosis. Gait Posture 2009,
29:230-236.
Sawicki GS, Ferris DP: Mechanics and energetics of incline walking with robotic ankle exoskeletons. Journal of Experimental Biology 2009, 212:32-41.
Sawicki GS, Ferris DP: Powered ankle exoskeletons reveal the
metabolic cost of plantar flexor mechanical work during
walking with longer steps at constant step frequency. Journal
of Experimental Biology 2009, 212:21-31.
Page 16 of 16
(page number not for citation purposes)