Toward the restoration of hand use to a paralyzed monkey: brain-controlled functional electrical stimulation of forearm muscles

Loss of hand use is considered by many spinal cord injury survivors to be the most devastating consequence of their injury. Functional electrical stimulation (FES) of forearm and hand muscles has been used to provide basic, voluntary hand grasp to hundreds of human patients. Current approaches typic...

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Bibliographic Details
Published in:PloS one 2009-06, Vol.4 (6), p.e5924-e5924
Main Authors: Pohlmeyer, Eric A, Oby, Emily R, Perreault, Eric J, Solla, Sara A, Kilgore, Kevin L, Kirsch, Robert F, Miller, Lee E
Format: Article
Language:English
Subjects:
Algorithms
Animals
Biomedical engineering
Brain
Brain - pathology
Brain injury
Computational Biology/Computational Neuroscience
Contraction
Control systems
Cortex (motor)
Electric Stimulation
Electric Stimulation Therapy - methods
Electrical stimuli
Electrodes, Implanted
Electromyography
Engineering
Forearm
Forearm - pathology
Hand
Hand - pathology
Haplorhini
Injuries
International conferences
Kalman filters
Kinematics
Medical research
Medicine
Monkeys
Movement - physiology
Muscle contraction
Muscle function
Muscle, Skeletal - pathology
Muscles
Nerve Block
Nervous system
Neuroscience
Neuroscience/Motor Systems
Paralysis
Paralysis - therapy
Patients
Physiology
Prostheses
Prosthetics
Reproducibility of Results
Restoration
Robotics
Spinal cord injuries
Stability
Stimulation
Tracking
Wrist
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Description
Summary:Loss of hand use is considered by many spinal cord injury survivors to be the most devastating consequence of their injury. Functional electrical stimulation (FES) of forearm and hand muscles has been used to provide basic, voluntary hand grasp to hundreds of human patients. Current approaches typically grade pre-programmed patterns of muscle activation using simple control signals, such as those derived from residual movement or muscle activity. However, the use of such fixed stimulation patterns limits hand function to the few tasks programmed into the controller. In contrast, we are developing a system that uses neural signals recorded from a multi-electrode array implanted in the motor cortex; this system has the potential to provide independent control of multiple muscles over a broad range of functional tasks. Two monkeys were able to use this cortically controlled FES system to control the contraction of four forearm muscles despite temporary limb paralysis. The amount of wrist force the monkeys were able to produce in a one-dimensional force tracking task was significantly increased. Furthermore, the monkeys were able to control the magnitude and time course of the force with sufficient accuracy to track visually displayed force targets at speeds reduced by only one-third to one-half of normal. Although these results were achieved by controlling only four muscles, there is no fundamental reason why the same methods could not be scaled up to control a larger number of muscles. We believe these results provide an important proof of concept that brain-controlled FES prostheses could ultimately be of great benefit to paralyzed patients with injuries in the mid-cervical spinal cord.
ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0005924