A dynamic study of thoracolumbar burst fractures

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Wilcox, Ruth K.¹; Boerger, Thomas O.²; Allen, David J.²; Barton, David C.¹; Limb, David²; Dickson, Robert A.²; Hall, Richard M.¹

A dynamic study of thoracolumbar burst fractures

J Bone Joint Surg. November 2003;85A(11):2184-2189

©2003 The Journal of Bone and Joint Surgery, Incorporated

Affiliations

¹School of Mechanical Engineering, University of Leeds, Leeds LS2 9JT, United Kingdom

²Musculo-Skeletal Services, CSB, St. James’s Hospital, Leeds LS9 7TF, United Kingdom
Abstract

Background: The degree of canal stenosis following a thoracolumbar burst fracture is sometimes used as an indication for decompressive surgery. This study was performed to test the hypothesis that the final resting positions of the bone fragments seen on computed tomography imaging are not representative of the dynamic canal occlusion and associated neurological damage that occurs during the fracture event.

Methods: A drop-weight method was used to create burst fractures in bovine spinal segments devoid of a spinal cord. During impact, dynamic measurements were made with use of transducers to measure pressure in a synthetic spinal cord material, and a high-speed video camera filmed the inside of the spinal canal. A corresponding finite element model was created to determine the effect of the spinal cord on the dynamics of the bone fragment.

Results: The high-speed video clearly showed the fragments of bone being projected from the vertebral body into the spinal canal before being recoiled, by the action of the posterior longitudinal ligament and intervertebral disc attachments, to their final resting position. The pressure measurements in the synthetic spinal cord showed a peak in canal pressure during impact. There was poor concordance between the extent of postimpact occlusion of the canal as seen on the computed tomography images and the maximum amount of occlusion that occurred at the moment of impact. The finite element model showed that the presence of the cord would reduce the maximum dynamic level of canal occlusion at high fragment velocities. The cord would also provide an additional mechanism by which the fragment would be recoiled back toward the vertebral body.

Conclusions: A burst fracture is a dynamic event, with the maximum canal occlusion and maximum cord compression occurring at the moment of impact. These transient occurrences are poorly related to the final level of occlusion as demonstrated on computed tomography scans.

Clinical Relevance: In a thoracolumbar burst fracture, the final position of the fragments, as seen on computed tomography images at presentation, probably does not represent the maximum level of canal occlusion or peak cord pressure and therefore does not represent the probable damage to the cord tissue that occurred at the moment of impact.
Links

DOI: 10.2106/00004623-200311000-00020

PubMed: 14630851

WoS: 000186423600020

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2012	Stemper BD, Baisden JL, Yoganandan N, Pintar FA, DeRosia J, Whitley P, Paskoff GR, Shender BS. Effect of loading rate on injury patterns during high rate vertical acceleration. In: Proceedings of the 2012 International IRCOBI Conference on the Biomechanics of Injury. September 12-14, 2012; Dublin, Ireland.217-224.
2006	Jones CF, Reed SG, Cripton PA, Hall RM. The effect of cerebrospinal fluid on spinal cord deformation in an in vitro burst fracture model. In: Proceedings of the 2nd Ohio State University Injury Biomechanics Symposium. May 17-19, 2006; Columbus, OH.
2008	Greaves CY, Gadala MS, Oxland TR. A three-dimensional finite element model of the cervical spine with spinal cord: an investigation of three injury mechanisms. Ann Biomed Eng. March 2008;36(3):396-405.
2008	Zhu Q, Lane C, Ching RP, Gordon JD, Fisher CG, Dvorak MF, Cripton PA, Oxland TR. Translational constraint influences dynamic spinal canal occlusion of the thoracic spine: an in vitro experimental study. J Biomech. 2008;41(1):171-179.
2011	Saari A, Itshayek E, Cripton PA. Cervical spinal cord deformation during simulated head-first impact injuries. J Biomech. September 23, 2011;44(14):2565-2571.
2011	Stemper BD, Storvik SG, Yoganandan N, Baisden JL, Fijalkowski RJ, Pintar FA, Shender BS, Paskoff GR. A new PMHS model for lumbar spine injuries during vertical acceleration. J Biomech Eng. August 2011;133(8):081002.
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