Research Article: Robotics

Electromyography-Controlled Exoskeletal Upper-Limb–Powered Orthosis for Exercise Training After Stroke

Stein, Joel MD; Narendran, Kailas M.Eng; McBean, John MS; Krebs, Kathryn OTR/L; Hughes, Richard PT, MS, NCS

From the Department of Physical Medicine and Rehabilitation, Harvard Medical School, Boston, Massachusetts (JS, KK, RH); Spaulding Rehabilitation Hospital, Boston, Massachusetts (JS, KK, RH); Active Joint Brace Research Lab, Department of Mechanical Engineering, Massachusetts Institute of Technology, Boston, Massachusetts (KN, JM); and Myomo, Inc., Boston, Massachusetts (KN, JM).

All correspondence and requests for reprints should be addressed to Joel Stein, MD, Spaulding Rehabilitation Hospital, 125 Nashua St., Boston, MA 02114.

Mr. Narendran and Mr. McBean both own equity stakes in Myomo, Inc., which licenses the technology described in this article from MIT.

Editor’s Note: Video demonstration of this device is available at www.AJPMR.com.

American Journal of Physical Medicine & Rehabilitation 86(4):p 255-261, April 2007. | DOI: 10.1097/PHM.0b013e3180383cc5

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Abstract

Stein J, Narendran K, McBean J, Krebs K, Hughes R: Electromyography-controlled exoskeletal upper-limb–powered orthosis for exercise training after stroke. Am J Phys Med Rehabil 2007;86:255–261.

Objective:

Robot-assisted exercise shows promise as a means of providing exercise therapy for weakness that results from stroke or other neurological conditions. Exoskeletal or “wearable” robots can, in principle, provide therapeutic exercise and/or function as powered orthoses to help compensate for chronic weakness. We describe a novel electromyography (EMG)-controlled exoskeletal robotic brace for the elbow (the active joint brace) and the results of a pilot study conducted using this brace for exercise training in individuals with chronic hemiparesis after stroke.

Design:

Eight stroke survivors with severe chronic hemiparesis were enrolled in this pilot study. One subject withdrew from the study because of scheduling conflicts. A second subject was unable to participate in the training protocol because of insufficient surface EMG activity to control the active joint brace. The six remaining subjects each underwent 18 hrs of exercise training using the device for a period of 6 wks. Outcome measures included the upper-extremity component of the Fugl-Meyer scale and the modified Ashworth scale of muscle hypertonicity.

Results:

Analysis revealed that the mean upper-extremity component of the Fugl-Meyer scale increased from 15.5 (SD 3.88) to 19 (SD 3.95) (P = 0.04) at the conclusion of training for the six subjects who completed training. Combined (summated) modified Ashworth scale for the elbow flexors and extensors improved from 4.67 (±1.2 SD) to 2.33 (±0.653 SD) (P = 0.009) and improved for the entire upper limb as well. All subjects tolerated the device, and no complications occurred.

Conclusion:

EMG-controlled powered elbow orthoses can be successfully controlled by severely impaired hemiparetic stroke survivors. This technique shows promise as a new modality for assisted exercise training after stroke.

Erratum

In the article by Stein et al., published in the April 2007 issue of the American Journal of Physical Medicine & Rehabilitation, errors occurred in the modified Ashworth Scale data reported and its analysis. Reanalysis of the data reveal that there is only a slight reduction in the average Ashworth scores in the muscles measured (reduced from a mean of 1.59 per muscle to 1.46; P = 0.4) and in the mean summated Ashworth scores for the elbow flexors and extensors (reduced from 4.67 to 4.17; P = 0.3). Neither of these changes are statistically significant. Figure 4 should appear as follows.

The authors regret the error.

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American Journal of Physical Medicine & Rehabilitation. 87(8):689, August 2008.

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Electromyography-Controlled Exoskeletal Upper-Limb–Powered Orthosis for Exercise Training After Stroke