A minimal set of muscles (8 to 16) were identified as candidates for implantation in a clinical system to provide walking function to individuals with complete paraplegia using functional electrical stimulation (FES). Three subjects with complete motor and sensory paraplegia had percutaneous intramuscular electrodes implanted in all major muscles controlling the trunk, hips, knees, and ankles. Stimulation patterns for walking with FES were generated for different sets of eight and 16 muscles. The quality and repeatability of the resulting gait produced by walking patterns consisting of various combinations of muscles were determined. Most eight-channel stimulation patterns resulted in scissoring or insufficient hip flexion, preventing forward progression. One eight-channel system allowed a maximum speed of 0.1 m/s with a cadence of 22 steps/min and a stride length less than 0.3 m. Improved walking performance was observed with 16 channels of stimulation. This ranged from slow step- to gait at 0.1 m/s to smooth reciprocal gait at 0.5 m/s. In all three subjects, the favored combination of 16 channels included erector spinae for trunk extension; gluteus maximus, posterior portion of adductor magnus and hamstrings for hip extension; tensor fasciae latae and either sartorius or iliopsoas for hip flexion; vastus lateralis/intermedius for knee extension; and tibialis anterior/peroneous longus for ankle dorsiflexion. In one subject the 16-channel FES system provided repeatable day-to-day gait averaging 0.4 m/s, 58 steps/min and a stride length at 0.8 m. A maximum repeatable walking distance with 16 channels was 34 m. Multiple 34-m trials were possible with minimal rests between walks. Fatigue of both the hip extensors and upper body was a limiting factor. The selection of target muscles for implantation is critical to the performance of FES systems. This study provides guidelines to muscle selection for walking with FES based on objective measures of gait performance. The findings indicate that a 16-channel FES system for total implantation is feasible for repeatable short distance, independent, walker-support walking in paraplegia.
[1]
E. Marsolais,et al.
Synthesis of paraplegic gait with multichannel functional neuromuscular stimulation
,
1994
.
[2]
T. Bajd,et al.
Gait restoration in paraplegic patients: a feasibility demonstration using multichannel surface electrode FES.
,
1983,
Journal of rehabilitation R&D.
[3]
T. Bajd,et al.
The use of a four-channel electrical stimulator as an ambulatory aid for paraplegic patients.
,
1983,
Physical therapy.
[4]
R. D'ambrosia,et al.
The RGO Generation II: muscle stimulation powered orthosis as a practical walking system for thoracic paraplegics.
,
1989,
Orthopedics.
[5]
E. B. Marsolais,et al.
Function and strength of electrically stimulated hip flexor muscles in paraplegia
,
1994
.
[6]
E. Marsolais,et al.
Functional electrical stimulation for walking in paraplegia.
,
1987,
The Journal of bone and joint surgery. American volume.
[7]
H Thoma,et al.
Functional electrostimulation of paraplegics: experimental investigations and first clinical experience with an implantable stimulation device.
,
1984,
Orthopedics.
[8]
E. Isakov,et al.
Biomechanical and physiological evaluation of FES-activated paraplegic patients.
,
1986,
Journal of rehabilitation research and development.
[9]
Dennis D. Roscoe,et al.
An Externally Powered, Multichannel, Implantable Stimulator for Versatile Control of Paralyzed Muscle
,
1987,
IEEE Transactions on Biomedical Engineering.
[10]
K H Lee,et al.
Electrically induced flexion reflex in gait training of hemiplegic patients: induction of the reflex.
,
1976,
Archives of physical medicine and rehabilitation.
[11]
A. Scheiner,et al.
Design and clinical application of a double helix electrode for functional electrical stimulation
,
1994,
IEEE Transactions on Biomedical Engineering.
[12]
R. Kobetic,et al.
Development and operation of portable and laboratory electrical stimulation systems for walking in paraplegic subjects
,
1989,
IEEE Transactions on Biomedical Engineering.