Review Article Fractures, Dislocations, and Fracture-Dislocations of the Spine

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Journal of Bone and Joint Surgery, 1970;52:1534-1551.
© 1970 by The Journal of Bone and Joint Surgery, Inc

Review Article Fractures, Dislocations, and Fracture-Dislocations of the Spine

FRANK HOLDSWORTH M.B., M.CHIR., F.R.C.S.¹

¹ From the Spinal Injuries Centre, Sheffield

Over 1000 patients with traumatic paraplegia or tetraplegiaand many more with fractures and dislocations of the spine withoutdamage to the central nervous system have been observed andtreated at the Sheffield Spinal Injuries Centre. The vertebrallesions with or without injury to the spinal cord or nerve rootshave been classified on the basis of the clinical and roentgenographicfindings into five groups:

1. Pure flexion which causes a wedgefracture which is stable.

2. Flexion-rotation which producesan unstable fracture-dislocation with rupture of tue posteriorligament complex, separation of the spinous processes, a slicefracture near the upper border of the lower vertebra, and dislocationof the lower articular processes of the upper vertebra.

3. Extensionwhich causes rupture of the intervertebral disc and the anteriorcommon ligament along with avulsion of a small bone fragmentfrom the anterior border of the dislocated vertebra. The dislocationalmost always reduces spontaneously and is stable in flexion.

4.Vertebral compression which results in a fracture of the endplate as the nucleus of the intervertebral disc is forced intothe vertebral body and causes it to burst with outward displacementof fragments of the body. Since the ligaments remain intactthis comminuted fracture is stable.

5. Shearing which resultsin forward displacement of the whole vertebra and an unstablefracture of the articular processes or pedicles.

Accurate diagnosisand prognosis of the neurological lesion depend on knowledgeof the anatomy of the spinal cord and nerve roots, a carefulneurological examination shortly after the original injury andrepeated examinations thereafter, comparison of the level ofspinal injury with the level of paraplegia or tetraplegia, differentiationbetween paraplegia and tetraplegia of immediate and delayedonset, and the appropriate therapy of the various types andlevels of lesion.

Simple wedge fractures were treated by bedrest for two to three weeks, mobilization of the back, and ambulationwith a back support.

Rotational fracture-dislocations in thecervical, thoracolumbar, or lumbar spine were almost invariablyassociated with tetraplegia or paraplegia. Cervical fracture-dislocationswith or without tetraplegia were treated by skull-caliper traction.Thoracolumbar or lumbar fracture-dislocations without paraplegiawere treated on a plaster bed for twelve weeks followed by aback support for a few weeks. The thoracolumbar fracture-dislocationswith paraplegia were never treated by the plaster bed methodbut rather by open reduction of the dislocation, and maintenanceof the reduction by internal fixation with double plating ofthe spinous processes. Spontaneous fusion was sufficiently advancedafter eight to twelve weeks to get the patient out of bed. Ifthe plates cut out of the bone after twelve weeks, they wereremoved. Patients with loss of sensation resulting from paraplegiaor tetraplegia were turned every two hours to avoid pressuresores.

Extension dislocations in the cervical spine, if theyhad reduced spontaneously, were fitted with a collar to holdthe head and neck in sligh flexion for a period of eight totwelve weeks. For dislocations in this region which had notreduced spontaneously, manual manipulation under endotrachealanesthesia was employed. Reduction was maintained by skull tongsapplied prior to manipulation. If after four weeks there wasroentgenographic evidence of new bone indicating Spontaneousfusion, traction was continued for four to six weeks more followedby a neck collar for an additional six weeks. If new bone didnot appear on the roentgenograms after four weeks, anteriorfusion was performed followed by skull traction for an additionaleight weeks.

Vertical compression burst fractures in the cervicalspine were treated by skull traction for six weeks followedby a neck collar. In the lumbar spine, burst fractures withoutparaplegia were treated by immobilization in a plaster bed foreight to twelve weeks followed by back support. The plasterbed was never used in burst fractures with paraplegia.

Shearfractures were always associated with complete paraplegia. Thesefractures were usually stable and did not require operativereduction except when the displacement was great.

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