News Release

Candidates for bionic hand reconstruction

Peer-Reviewed Publication

Journal of Neurosurgery Publishing Group

Algorithm for Bionic Hand Reconstruction in Patients with Global Brachial Plexopathies

image: Algorithm for bionic hand reconstruction in patients with global brachial plexopathies. The long arrow pointing downward indicates the order of clinical steps of the algorithm. If two electromyographic (EMG) signals are detected during EMG signal identification, the third step (nerve transfer and/or free functional muscle transplantation) is left out (curved arrow). view more 

Credit: ©AANS 2017.

CHARLOTTESVILLE, VA (JANUARY 17, 2017). Bionic hand? No longer only an image conjured by science fiction, bionic hands return functionality in cases of traumatic nerve and muscle loss. Certainly something to consider if you've lost your hand in an accident, but what if you still retain your hand, albeit a useless one? What would make a person voluntarily trade in a biological hand composed of flesh, blood, and bone for a prosthesis consisting of wires and synthetic material? And would the results be well worth the loss?

An answer to these questions can be found in a new Journal of Neurosurgery article, "Algorithm for bionic hand reconstruction in patients with global brachial plexopathies," by Laura A. Hruby, M.D., and colleagues from the Medical University of Vienna and the University of Applied Sciences FH Campus (Vienna). These researchers offer a treatment algorithm, or protocol, for identifying patients with global (flail arm) brachial plexus injuries who are likely to benefit from trading in their insensate and nonfunctional hand for a myoelectric prosthetic device.

Background

The brachial plexus is a network of sensory and motor fibers originating from spinal nerves in the lower cervical and upper thoracic spine that coalesce to form nerves that serve the shoulder, arm, and hand. A traumatic injury to the brachial plexus can cause these fibers to overstretch, sometimes avulsing (tearing) the spinal nerve roots from the spinal cord.

Traumatic brachial plexus injuries with nerve root avulsions occur most often in young adults. A variety of surgical procedures can be performed to restore nerve and muscle activity. Following these procedures, the shoulder and upper arm often regain stability and movement, and in some cases hand and finger movement can be restored--at least partially. In other cases, for a variety of reasons surgery fails and the hand remains a useless appendage.

Without use of the hand, the patient's life changes dramatically. Depending on occupation, the patient's economic livelihood may be jeopardized. Daily activities of living become difficult. Body image is transformed in a negative fashion, and chronic pain may become a new companion.

The Study

The authors recount their experience with patients who sought treatment for global brachial plexus injuries at the Center for Advanced Restoration of Extremity Function in Vienna between 2011 and 2015. In 16 patients, the nerve injury was so severe that no currently available biological intervention could restore adequate hand function. The authors offered these patients a bionic alternative: replacement of the useless biological hand with a myoelectric prosthetic device--a bionic hand.

The authors describe a treatment algorithm that they have developed for bionic hand reconstruction. It comprises several steps:

  1. Physical and psychological assessment of the patient. Patients must have useful shoulder and elbow function but no motor ability or sensation in the hand. In addition, patients must be able to face the challenges ahead.
  2. Identification of electromyographic signals in muscles of the forearm. Two separate signals are necessary to control a bionic hand. If fewer than two signals are present, surgical procedures may be performed.
  3. Optional: Surgery to perform selective nerve transfer and/or transplantation of healthy muscle to improve nerve conduction and muscle activation in the forearm when at least two electromyographic signals are not present.
  4. Brain Training: This biofeedback training allows the patient to target reinnervated muscles to control movement of the hand and forearm.
  5. Hybrid hand fitting. Patients are trained to use a prosthetic device with their own biosignals prior to hand amputation.
  6. Elective amputation of the useless biological hand.
  7. Replacement of the biological hand with a myoelectric prosthetic device, followed by additional training and testing of bionic hand function.

The authors report outcomes in the five patients in whom sufficient follow-up was obtained (at least 3 months after final prosthetic fitting). At the time the paper was written, the other 11 patients were still moving through earlier steps of the algorithm. Functional outcomes were assessed using the Action Research Arm Test (ARAT), the Southampton Hand Assessment Procedure (SHAP), and the Disabilities of the Arm, Shoulder, and Hand (DASH) questionnaire. Significant improvements in hand function were seen in all five patients and continued throughout the follow-up period.

Interestingly, deafferentation pain (a chronic pain syndrome often experienced by patients with global brachial plexus injuries), which had been severe in three of the five patients, lessened after patients became accustomed to working with the bionic hand. According to the authors, "patients reported a subjectively observed correlation between daily wearing time of the prosthesis and pain reduction. Thus when the prosthetic device could not be worn due to regular maintenance, pain was reported to increase again within days."

Imagine having increased hand-like function and less deafferentation pain. Would you trade in your useless biological hand for a bionic hand if one was offered? For some, the choice may be easier than you think.

When asked about the study, the senior investigator, Oskar C. Aszmann, M.D., Ph.D., stated, "For more than 25 years, I have dealt with patients suffering from devastating peripheral nerve lesions. Bionic reconstruction, as described in this paper, has been a real game changer since it offers hope and real help for patients who otherwise have none."

Accompanying this paper is an interesting editorial by Mustafa Nadi, M.D., and Rajiv Midha, M.D., M.Sc., F.R.C.S.C., describing global brachial plexus injuries as well as the current state of surgical procedures used to reconstruct hand function and their limited results. The authors discuss the present study and express interest in future reports on outcomes in other patients following the treatment algorithm at the Center for Advanced Restoration of Extremity Function.

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Paper: Hruby LA, Sturma A, Mayer JA, Pittermann A, Salminger S, Aszmann OC: Algorithm for bionic hand reconstruction in patients with global brachial plexopathies. Journal of Neurosurgery, published online, ahead of print, January 17, 2017; DOI: 10.3171/2016.6.JNS16154.

Disclosure: The authors report no conflict of interest concerning the materials or methods used in this study or the findings specified in this paper.

Funding: This study was funded by the Christian Doppler Research Foundation of the Austrian Council for Research and Technology Development and the Austrian Federal Ministry of Science, Research, and Economy.

Editorial: Nadi M, Midha R: Myoelectric functional hand prosthesis for total brachial plexus Injury. Journal of Neurosurgery, published online, ahead of print, January 17, 2017; DOI: 10.3171/2016.7.JNS161501.

Disclosure: The authors report no conflict of interest.

For additional information, please contact: Ms. Jo Ann M. Eliason, Communications Manager, Journal of Neurosurgery Publishing Group, One Morton Drive, Suite 200, Charlottesville, VA 22903. Email: jaeliason@thejns.org; Phone: 434-982-1209; Fax: 434-924-2702.

Since 1944 the Journal of Neurosurgery has been recognized by neurosurgeons and other medical specialists the world over for its authoritative clinical articles, cutting-edge laboratory research papers, renowned case reports, expert technical notes, and more. Each article is rigorously peer reviewed. The Journal of Neurosurgery is published monthly by the JNS Publishing Group, the scholarly journal division of the American Association of Neurological Surgeons. Other peer-reviewed journals published by the JNS Publishing Group each month include Neurosurgical Focus, the Journal of Neurosurgery: Spine, and the Journal of Neurosurgery: Pediatrics. All four journals can be accessed at http://www.thejns.org.

Founded in 1931 as the Harvey Cushing Society, the American Association of Neurological Surgeons (AANS) is a scientific and educational association with more than 8,300 members worldwide. The AANS is dedicated to advancing the specialty of neurological surgery in order to provide the highest quality of neurosurgical care to the public. All active members of the AANS are certified by the American Board of Neurological Surgery, the Royal College of Physicians and Surgeons (Neurosurgery) of Canada or the Mexican Council of Neurological Surgery, AC. Neurological surgery is the medical specialty concerned with the prevention, diagnosis, treatment and rehabilitation of disorders that affect the entire nervous system including the brain, spinal column, spinal cord, and peripheral nerves. For more information, visit http://www.AANS.org.


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