Positioning and General Management of Upper Limbs in Spinal Cord Injury


Original Editor - Ewa Jaraczewska based on the course by Wendy Oelofse

Top Contributors - Ewa Jaraczewska, Jess Bell, Tarina van der Stockt and Naomi O'Reilly  

Introduction[edit | edit source]

Range of motion (ROM) limitations and joint contracture can significantly limit functional abilities in patients with a spinal cord injury. Shoulder ROM problems are related to functional limitations, disability, and perceived health. In addition, patients with tetraplegia can suffer from upper limb spasticity, which is reported to be one of the most difficult health complications after SCI.[1][2]These complications include restriction in activities of daily living (ADLs), pain and fatigue, sleep disturbance, and safety, leading to contractures, pressure ulcers, infections, and negative self-image. [2]This article will discuss therapeutic strategies, including appropriate positioning, stretching, strengthening, the tenodesis grasp and spasticity management, which can help to maintain the range of motion and facilitate function.

Maintaining Range of motion[edit | edit source]

Upper Limb Positioning[edit | edit source]

Goals:

  1. To increase and/or maintain range of motion
  2. To prevent and/or decrease upper limb (UL) pain
  3. To prevent UL injury

Positioning in Supine [3][edit | edit source]

The following are recommended positions for the upper limb when a person with tetraplegia is in bed:

File:Copy of Photo crucifix position.jpg
Crucifix position

Shoulders

  • Crucifix position with shoulders in external rotation. Avoid extreme position and use progression ("serial positioning) to reach the end range and eliminate stressing the tissue.
  • In an open position.
  • Some shoulder abduction and external rotation, with position alteration as needed.
  • Shoulders in a mid-position or slight protraction.
  • Scapula "pulled back."

Elbows

  • Extension, but not hyperextension.
  • With overactive biceps, maintain the elbow extension using a soft splint, a vacuum splint, or a pillow wrapped around the forearm.

Wrist

  • Extension or dorsiflexion up to 45 degrees
  • The appropriate position maintained using the splint, or the pillow

Thumb

  • Position in opposition to maintaining the web space
  • Night splint vs hand resting splint at night, or
  • A rolled-up towel in the web space to maintain the web space.
  • Position the hands higher than the shoulders to prevent gravitational swelling

Positioning in Sitting[edit | edit source]

A wheelchair sitting posture of a person with cervical-level spinal cord injury is often characterised by:

  • Rounded shoulders with increased thoracic kyphosis
  • Tendency to progress to a more slouched posture throughout the day
  • Forward head posture
  • Reliance on the upper extremities to maintain balance

Recommended posture improvement strategies:

  • wheelchair seating system adaptations
  • arms out to the side
  • adequate support for the weight of the upper limb

Upper Limb Stretching and Strengthening Programs[edit | edit source]

Stretching[edit | edit source]

Stretching is a common technique used by therapists to treat and prevent contractures. The importance of stretch on joint mobility has yet to be proven clinically. However, some studies indicate that the effects of a stretch accumulate over time.[4] It is recommended that regular stretching should become a home maintenance program for people with spinal cord injury to demonstrate clinically important effects on joint mobility. [4] Stretching the following tissues should be included in the upper limb treatment plan for a person with upper and lower tetraplegia:

Strengthening[edit | edit source]

Patients with tetraplegia depend on their upper limbs to perform activities of daily living, which include transfers and wheelchair propulsion. In addition, good proximal muscle stability (scapula, shoulder) allows for better arm and hand function. On the other hand, poor scapula position can contribute to neck and shoulder pain and inadequate shoulder stability.[5] Loss of shoulder stability and overload of the shoulder girdle due to daily requirements placed upon upper limbs in patients with cervical spinal cord injury cause shoulder, elbow and hand pathologies.

The most common shoulder pathologies include:[6]

Clinical and physical alteration in the elbow joint:[6]

General Principles for Strengthening Exercises[edit | edit source]

  • The same principles as the principles of strengthening the able-bodied population
  • The correct and early diagnosis of possible shoulder malfunctions with a subsequent treatment plan
  • Progressive increases in resistance to increase muscle strength of innervated muscles
  • Starting with active assisted, gravity-eliminated exercises
  • Observe muscle fatigue when exercising partially innervated muscles, as they require longer recovery time

Strengthening exercise program examples[3][edit | edit source]

  • Scapular retraction
  • Shoulder external rotation
  • Shoulder diagonal extension or abduction
  • Serratus anterior strengthening exercises
Tenodesis Grasp

Tenodesis Grasp[edit | edit source]

Individuals with " C6 and C7 tetraplegia use a tenodesis grasp to compensate for weak or absent active finger movement to manipulate objects during daily activities."[3] The grasp function is achieved by actively extending the wrist, closing the fingers, and flexing a thumb until the index finger is touched.[7]

General Guidelines[edit | edit source]

  • Daily passive range of motion of the wrist and fingers is required
  • Do not overstretch the fingers in extension during passive range of motion exercises
  • Family and caregiver education about stretching and weight bearing
  • During weight-bearing tasks or transfers, the fingers are in flexion
  • Retain tendon tightness in the fingers for a future tenodesis grasp

Characteristics of Tenodesis Grasp[edit | edit source]

Position of wrist and fingers

  • With active wrist extension movement, there is passive flexion of the fingers. With wrist flexion, the fingers extend to release an object. [3]

Position of thumb

  • Thumb in: helps to develop a lateral pinch [3]
  • Pulp-to-pulp pinch when the thumb touches the pulps of your fingers [3]

You can read more about tenodesis grasp here.

Upper Limb Spasticity Management[edit | edit source]

Typical patterns of upper limb spasticity include shoulder adduction and internal rotation, elbow flexion, forearm pronation, wrist flexion, thumb flexion, adduction and first webspace tightness, and finger flexion.[8][9]

The following negative experiences were reported by patients with a spinal cord injury with the presence of spasticity:

  • Stiffness all-day
  • Interference with sleep
  • Painful spasms
  • The perceived link between spasticity and pain
  • Intensification of pain before a spasm
  • Muscle contracture [8]
  • Difficulty with hygiene [8]
  • Pressure ulcers [8]
  • Poor cosmesis negatively impacts self-esteem and body image [8]


Goals for spasticity management:

  1. To diminish spasticity
  2. To allow voluntary movements
  3. To improve the ability to independently perform ADLs (transfers, dressing, and toileting)

Therapeutic Strategies[edit | edit source]

Positioning

  • Posture influences reflexes
  • Wheelchair seating system
  • Fatigue can increase spasticity

Neurodynamic mobilisation

Neurodynamic mobilisation is a"group of techniques that aim to place the neuraxis in tension and stretch it with appropriate mobilisation through certain postures, along with the application of slow, rhythmic movements of the joints intended to reach the peripheral nerves and the spinal cord".[2] [10]

Example: Median nerve neurodynamic mobilisation

  • Patient position: supine, shoulder girdle depressed, the glenohumeral joint extended, abducted, and laterally rotated; the elbow in extension, the forearm in supination, wrist, fingers, and thumb in extension.
  • Twelve minutes during each session; sessions were conducted five times weekly for four weeks.
  • Slow, rhythmic oscillations of wrist flexion and extension.
  • Twenty oscillations were performed each minute for 3 minutes; the process was performed thrice during the same session, with a 1-minute interval between consecutive attempts.

Self-applied vibration to the upper limb

Participants with higher spasticity demonstrated decreased spasticity after focal UE vibration, although there was no clear effect on grasp, transport and release function. [11]

Passive movement

  • Joint-by-joint passive range should be performed
  • Stretching is to be performed slowly
  • The intensity of passive movement to become therapeutic is unknown[12]
  • According to Harvey et al.[4], when the range of motion is limited, stretching should be done for long periods (from 20 minutes to up to 12 hours). A prolonged stretch can be accomplished with splint use

Other treatment interventions

  • Neurodevelopmental Therapy (NDT)[13]
  • Hippotherapy [14]
  • Prolonged standing [15]
  • Electrical stimulation (patterned electrical stimulation (PES) or patterned neuromuscular stimulation (PNS), functional electrical stimulation (FES) and transcutaneous electrical nerve stimulation (TENS)
    • "Electrical stimulation applied to individual muscles may produce a short-term decrease in spasticity. There is also some concern that long-term use of electrical stimulation may increase spasticity."[16]

Upper Limb Reconstruction in Tetraplegia[edit | edit source]

Reconstruction surgeries can improve upper limb function for individuals with upper and lower tetraplegia. The two types of reconstructive procedures are nerve transfers and tendon transfers. The following examples represent an incomplete list of currently available procedures.

Nerve transfers[edit | edit source]

Nerve transfers are complementary to tendon transfer techniques. A combination of nerve and tendon transfers is often the best solution for some patients with tetraplegia. [17] The nerve transfer procedure involves cutting and reconnecting a functional nerve from the above injury zone and reconnecting it to a nonfunctional nerve from below the injury zone, which serves a more important function. [18]

  • Thumb and finger flexion reconstruction with brachialis-to-anterior interosseus nerve transfer with an in situ lateral antebrachial cutaneous nerve graft
  • Active extension of the fingers with supinator-to-posterior interosseous nerve transfer complements brachialis-to-anterior interosseus nerve transfer
    • Post-op therapeutic protocol includes immediate elbow, wrist and fingers passive range of motion
    • Weight-bearing activities started two weeks post surgery
    • Active exercises of the donor's muscles started two or three weeks post surgery
    • When the recipient's muscles started contracting, physiotherapy intervention focused on co-contraction exercises, motor education, and a strengthening exercise program[19]
  • Fingers pinch and grasp with musculocutaneous to median nerve transfer

Benefits of nerve transfer procedures:

  • Restore muscle groups without altering their biomechanics
  • Do not require prolonged immobilisation
  • Potential reconstructions are available when no tendon transfer options exist
  • Offer a greater than 1:1 functional exchange: sacrificing one simple function can potentially restore multiple functions

Tendon Transfers[edit | edit source]

Tendon transfers are the most commonly accepted intervention for restoring hand function in persons with tetraplegia. The procedure includes cutting the distal end of a functional muscle and its reattachment at the insertion site of a nonfunctional muscle. Tendon transfers are performed to restore a grasp and release of fingers, thumb, and elbow extension in patients with a C5 and below spinal cord injury. Reconstruction of finger extension through tendon transfers in patients with tetraplegia remains difficult.

The following examples represent tendon transfer procedures in patients with upper and lower tetraplegia:[20]

  • Weak or no wrist extension with brachioradialis to the extensor carpi radialis brevis tendon transfer. Note: Some of these patients require additional posterior deltoid transfer to counteract the brachioradialis
  • No elbow extension with posterior deltoid transfer
  • Fingers flexion with an opponens transfer

Resources[edit | edit source]

References[edit | edit source]

  1. Reinholdt C, Fridén J. Selective release of the digital extensor hood to reduce intrinsic tightness in tetraplegia. Journal of Plastic Surgery and Hand Surgery. 2011 Apr 1;45(2):83-9.
  2. 2.0 2.1 2.2 Saxena A, Sehgal S, Jangra MK. Effectiveness of Neurodynamic Mobilization versus Conventional Therapy on Spasticity Reduction and Upper Limb Function in Tetraplegic Patients. Asian Spine J. 2021 Aug;15(4):498-503.
  3. 3.0 3.1 3.2 3.3 3.4 3.5 Oelofse W. Positioning and General Management of Spinal Cord Injury - Occupational Therapy Course. Plus 2022
  4. 4.0 4.1 4.2 Harvey LA, Katalinic OM, Herbert RD, Moseley AM, Lannin NA, Schurr K. Stretch for the treatment and prevention of contracture: an abridged republication of a Cochrane Systematic Review. J Physiother. 2017 Apr;63(2):67-75.
  5. Dunn J, Wangdell J. Improving upper limb function. Rehabilitation in Spinal Cord Injuries. 2020 Feb 1:372.
  6. 6.0 6.1 Oliveira RC, Freitas LB, Gomes RR, Cliquet Júnior A. Orthopedic related comorbidities in spinal cord-injured individuals. Acta Ortopédica Brasileira. 2020 Jul 31;28:199-203.
  7. Suszek-Corradetti M. Rehabilitation path for patients with spinal cord injury from critical condition to optimal independence in everyday life on the example of the activities of the Montecatone Rehabilitation Institute in Italy. Archives of Physiotherapy & Global Researches. 2020 Jul 1;24(2).
  8. 8.0 8.1 8.2 8.3 8.4 Barnham IJ, Alahmadi S, Spillane B, Pick A, Lamyman M. Surgical interventions in adult upper limb spasticity management: a systematic review. Hand Surgery and Rehabilitation. 2022 Apr 28.
  9. Hashemi M, Sturbois-Nachef N, Keenan MA, Winston P. Surgical Approaches to Upper Limb Spasticity in Adult Patients: A Literature Review. Front Rehabil Sci. 2021 Aug 31;2:709969.
  10. Castilho J, Ferreira LAB, Pereira WM, Neto HP, Morelli JGDS, Brandalize D, Kerppers II, Oliveira CS. Analysis of electromyographic activity in spastic biceps brachii muscle following neural mobilization. J Bodyw Mov Ther. 2012 Jul;16(3):364-368.
  11. Mirecki MR, Callahan S, Condon KM, Field-Fote EC. Acceptability and impact on spasticity of a single session of upper extremity vibration in individuals with tetraplegia. Spinal Cord Series and Cases. 2022 Feb 5;8(1):1-6.
  12. Dunn J, Wangdell J. Improving upper limb function. Rehabilitation in Spinal Cord Injuries. 2020 Feb 1:372.
  13. Li S, Xue S, Li Z, Liu X. Effect of baclofen combined with neural facilitation technique on the reduction of muscular spasm in spinal cord injury. Neural Regeneration Research,2007;2(8):510-512
  14. Lechner HE, Feldhaus S, Gudmundsen L, Hegemann D, Michel D, Zäch GA, Knecht H. The short-term effect of hippotherapy on spasticity in patients with spinal cord injury. Spinal Cord. 2003 Sep;41(9):502-5.
  15. Shields RK, Dudley-Javoroski S. Monitoring standing wheelchair use after spinal cord injury: a case report. Disabil Rehabil. 2005 Feb 4;27(3):142-6.
  16. Davis R. Spasticity following spinal cord injury. Clinical Orthopaedics and Related Research®. 1975 Oct 1;112:66-75.
  17. Ledgard JP, Gschwind CR. Evidence for the efficacy of new developments in reconstructive upper limb surgery for tetraplegia. Journal of Hand Surgery (European Volume). 2020 Jan;45(1):43-50.
  18. Brown JM. Nerve transfers in tetraplegia I: Background and technique. Surg Neurol Int. 2011;2:121.
  19. Waris E, Palmgren-Soppela T, Sommarhem A. Nerve Transfer of Brachialis Branch to Anterior Interosseus Nerve Using In Situ Lateral Antebrachial Cutaneous Nerve Graft in Tetraplegia. The Journal of Hand Surgery. 2022 Apr 1;47(4):390-e1.
  20. Freehafer AA. Tendon transfers in tetraplegic patients: the Cleveland experience. Spinal Cord. 1998 May;36(5):315-9.
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