Reanimating hand function after spinal cord injur y using ner ve transfer surger y

Loss of arm and hand function is a devastating consequence of cervical spinal cord injury. Tendon transfer surgery has traditionally been used to restore key functions including elbow extension, wrist extension and grasp and pinch. The more recent development of nerve transfer surgery enables direct restoration of voluntary control of these functions. While both types of surgery are safe and effective, nerve transfer surgery results in a more open, flexible and natural hand, with more subtle control for a range of activities of daily living. lifelong sens-orimotor from per per age in age. Age at injury, and injuries caused by falls have increased over time. 2 Over half of the injuries affect the cervical spinal cord, 1 leading to tetraplegia, that is, some degree of paralysis in all four limbs as well as the trunk. In tetraplegia, the degree of impairment of the upper limb, including the hand, will vary depending on the level and completeness of injury. Loss of function is greater the higher the level of injury. For example, individuals with C6 level of injury are able to move their arms and extend their wrists, but have little or no voluntary use of their hands. Injuries above C6 result in the inability to actively extend the elbow to reach for objects. Loss arm


Jodie Hahn, B Occ Ther (Hons), B Ergonomics
is an Occupational Therapist who specialises in upper limb rehabilitation post-cervical spinal cord injury. She has been involved in a number of projects and publications related to understanding and maximising patient outcomes and experience of nerve transfers for upper limb re-animation for people with tetraplegia. S pinal cord injury (SCI) leads to severe lifelong impairment of sensorimotor function. The annual crude incidence rates of traumatic SCI vary from 12.1 per million to 57.8 per million, with leading causes being motor vehicle accidents, falls, violence and sports activities. 1 There is a bimodal distribution, with one peak in the age group 15 to 29 years, and the second in the age group above 40 years of age.

Natasha van Zyl, MB ChB, FRACS
Age at injury, and injuries caused by falls have increased over time. 2 Over half of the injuries affect the cervical spinal cord, 1 leading to tetraplegia, that is, some degree of paralysis in all four limbs as well as the trunk. In tetraplegia, the degree of impairment of the upper limb, including the hand, will vary depending on the level and completeness of injury.
Loss of function is greater the higher the level of injury. For example, individuals with C6 level of injury are able to move their arms and extend their wrists, but have little or no voluntary use of their hands. Injuries above C6 result in the inability to actively extend the elbow to reach for objects. Loss of hand and arm function is one of the most devastating consequences of spinal cord injury because of the severe impact on activities of daily living (ADL) and subsequent dependence on others, loss of privacy and loss of vocational opportunities. Loss of the use of one's hand results in the inability to grasp and manipulate objects of different sizes, heaviness and textures, inability to point and gesture, and inability to use common everyday implements (e.g. toothbrush, cutlery, pens). Therefore, people with tetraplegia report that limited hand and arm function is often more profoundly disabling and of greater importance than their inability to walk. 3,4 The key movements for improving independence in tetraplegia are elbow extension for reach and pushing a manual wheelchair, wrist extension, and hand opening and closing for grasp, pinch and release. Different treatment strategies have been directed to improving or restoring these movements, as even modest improvements in arm and hand function can have a substantial impact on potential for employment, independence and quality of life.
Rehabilitation has traditionally involved strengthening muscles above the level of injury and, in recovering muscle groups, maintaining range of movement in the upper limb joints, providing assistive technology, adaptive Reanimating hand function after spinal cord injury using nerve transfer surgery equipment and tools where appropriate, and training a repertoire of compensatory strategies to accomplish tasks. Among the compensatory strategies is the tenodesis grasp, which, in individuals who have voluntary wrist extension, provides a means of hand opening and closing through passive forces developed in the long finger and thumb flexors during wrist flexion and extension. Encouraging a tenodesis grasp involves improving or supporting active wrist extension, and reducing the resting length of the long flexors of the fingers and thumb, so that the fingers passively flex and the thumb approximates the fingers when the wrist is extended. An effective tenodesis grasp only enables the picking up of light objects as no power is generated.
Tendon transfer surgery to reconstruct arm and hand function in people with tetraplegia has a long and successful history. This type of surgery involves the transfer of the tendon from a functioning muscle to a new site, with the goal of reproducing lost movement at a specific joint, and reducing reliance on adaptive equipment. 5 Tendon transfers redistribute expendable, non-paralysed muscle function to that of paralysed muscles to restore a number of key functions including elbow extension, wrist extension and grasp and pinch. 6 More recent surgical developments include nerve transfer surgery. 7,8 First developed as a surgical technique to reconstruct the brachial plexus or peripheral nerves after injury, nerve transfer surgery is now being applied to reanimate hand function in people with tetraplegia. Where a single tendon transfer can only be used to restore one function and is essentially a compensatory strategy, nerve transfers can allow for direct reanimation (restoration of voluntary control) of more than one muscle. The process involves taking working "donor" nerves from expendable muscles not affected by the spinal injury and coapting them to the "recipient" nerves of paralysed muscles. For example, to restore finger and thumb extension, the nerve(s) to the supinator muscle can be transferred to the posterior interosseous nerve. Supination of the forearm is still possible as it is one of the functions of the biceps muscle. Nerve transfer surgery can be used in combination with tendon transfer surgery to increase the options for upper limb reconstruction and the number of functions that can be restored. However, there are nerve transfer options for people with higher levels of SCI where tendon transfers are not possible.
Identifying the most appropriate candidates for such procedures requires a thorough knowledge of the functional anatomy of the upper limb and a detailed pre-operative assessment preferably by an interdisciplinary team. Evaluation of the range of movement, muscle strength and presence of spasticity are important components in determining the surgical procedure most appropriate for a specific patient, along with hand  The pattern of recovery post-injury and time since injury also influence decision making. Potential candidates for surgery should be re-assessed at appropriate intervals up to the day of surgery to track recovery, and potential surgical procedures should be delayed or reconsidered if significant natural recovery is apparent. As there may be direct damage to the motor neurons within the injury zone resulting in a lower motor neuron injury, characterising the pattern of upper and lower motor neuron injury has implications for nerve transfer surgery. Lower motor neuron injury in the donor nerve may compromise its utility and, in the recipient nerve, it has implications for the timing of nerve transfer surgery, with surgery preferable before 12 months post-SCI to maximise outcomes. Assessing the relative proportions of upper and lower motor neuron injury in recipient nerves is not straightforward and the degree of lower motor neuron injury may vary considerably. In general, a muscle's response to surface electrical stimulation provides a good indication of the health of the peripheral nerve. Traditional motor and sensory nerve conduction studies combined with electromyography can demonstrate characteristics of impaired motor neuron function such as slowed motor conduction, reduced amplitude of compound action potentials, and fibrillations. 9 Intraoperative stimulation can more directly examine the conduction along the nerve. However, neurophysiological techniques do not provide a complete picture of peripheral nerve health.
Direct assessment of peripheral nerves after SCI, through biopsies taken intraoperatively, has shown that the majority of both donor and recipient nerves sampled had morphological abnormalities. The most common abnormalities were myelin thickening and folding, demyelination, inflammation and a reduction in density of large myelinated axons. Other changes noted were a thickened perineurium, oedematous endoneurium and Renaut bodies. 10 Numerous single case reports describing new surgical procedures or small retrospective case series have shown that nerve transfer surgery is feasible, safe, and effective. However, the reporting quality of these studies is not high, with lack of clarity regarding inclusion and exclusion criteria and consecutive recruitment. The Medical Research Council strength grading, 11 with videotapes included as supplementary material, has been the major approach used for measurement of outcomes rather than standardised functional outcome measures of hand function (e.g. the Grasp-Release Test 12 ) or of independence. Rigorous prospective studies of nerve transfer surgery using standardised outcome measures in this population are lacking, as are reports of outcomes for combinations of multiple nerve and tendon transfer surgeries.
Our research group recently published the largest prospective, consecutive case series of nerve transfers (total of 59 procedures in 27 limbs) undertaken at a single centre in the tetraplegic population to date. 13 In ten of the participants, nerve transfers were performed in one hand to restore grasp and pinch while tendon transfers were performed on the other. Assessments of muscle power, grasp and pinch strength, upper limb function, independence in activities of daily living, and hand opening ability, were undertaken before surgery, and at 12 and 24 months post-surgery. Where prior to surgery none of the participants were able to register forces in grasp and pinch dynamometry tests, at the 24 month time-point there were significant improvements in their grasp and pinch strength, ability to pick up and release objects of different sizes in tests of hand function, and in their independence.
The outcomes in hands where grasp and pinch had been reconstructed with nerve transfers were similar to those reconstructed with tendon transfers, however the appearance of the hands was different. Using nerve transfers to re-animate grasp and pinch results in a more open, flexible and natural hand, with more subtle control for finer tasks and social interactions.
While nerve transfer surgery has been shown to be safe and effective and to have results comparable to those of tendon transfers, further research is needed. Areas requiring further investigation include: the longer-term outcomes of surgery, both functionally and from the individual's perspective; how to maximise an individual's use of the improved function in daily activities; and how an understanding of the health of donor and recipient nerves can be used in patient selection, predicting outcomes and determining the optimal timing of surgery.