Analysis and prevention of spinal column deformity following cervical laminectomy, I:​ pathogenetic analysis of postlaminectomy deformities

Saito, Tetsufumi<sup>1</sup>; Yamamuro, Takao<sup>1</sup>; Shikata, Jitsuhiko<sup>1</sup>; Oka, Masanori<sup>1</sup>; Tsutsumi, Sadami<sup>1</sup>

Affiliations

¹Department of Orthopaedic Surgery, Faculty of Medicine, Kyoto University

Abstract and keywords

Postlaminectomy deformities were simulated in the cervical or cervicothoracic spine by the use of a displacement incremental method based on finite-element analysis combined with composite material and spanning element theory. The simulation analyses revealed that the primary cause of postlaminectomy deformity was the resection of one or more spinous processes and/or posterior ligaments (ie, ligamenta flava, supraspinous, and interspinous ligaments). After their removal, the tensile stresses that were preoperatively distributed through the posterior ligaments were transferred to the facets. This led to an imbalance of the stresses on the spinal bodies, causing deformity. The gravitational center of the head determined whether the deformity would develop as a kyphosis or increasing lordosis. As the elastic modulus of the soft tissue composites (eg, end plates, ligaments, and facets) increased, a kyphotic deformity changed gradually from swan-neck deformity, to extreme kyphotic deformity with a large curvature, and finally to a straightening deformity. Progressive kyphotic deformity is found only in children.

Keywords: cervical spine laminectomy; postoperative deformity

Links

DOI: 10.1097/00007632-199105000-00002

PubMed: 2052990

WoS: A1991FL14000002

Ovid: 00007632-199105000-00002

History

Accepted: 1989-05-28

Cited Works (4)

Year	Entry
1970	Yamada H. Strength of Biological Materials. Evans FG, ed. Baltimore, MD: Williams & Wilkins Company; 1970.
1977	Svesnsson NL, Valliappan S, Wood RD. Stress analysis of human femur with implanted Charnley prosthesis. J Biomech. 1977;10(9):581-588.
1973	Evans FG. Mechanical Properties of Bone. Springfield, IL: Charles C. Thomas; 1973.
1978	Penning L. Normal movements of the cervical spine. Am J Roentgen. February 1978;130(2):317-326.

Cited By (20)

Year	Entry
1998	Yoganandan N, Kumaresan S, Pintar FA. Pediatric cervical spine biomechanics using finite element models. In: Proceedings of the 1998 International IRCOBI Conference on the Biomechanics of Impact. September 16-18, 1998; Göteberg, Sweden.349-363.
1998	Yang KH, Zhu F, Luan F, Zhao L, Begeman PC. Development of a finite element model of the human neck. In: Proceedings of the 42nd Stapp Car Crash Conference. November 2-4, 1998; Tempa, AZ. Warrendale, PA: Society of Automotive Engineers:195-205. SAE 983157.
1999	Kumaresan S, Yoganandan N, Pintar FA. Finite element analysis of the cervical spine: a material property sensitivity study. Clin Biomech (Bristol, Avon). January 1999;12(1):41-53.
2001	Yoganandan N, Kumaresan S, Pintar FA. Biomechanics of the cervical spine, II: cervical spine soft tissue responses and biomechanical modeling. Clin Biomech (Bristol, Avon). January 2001;16(1):1-27.
1997	Maurel N, Lavaste F, Skalli W. A three-dimensional parameterized finite element model of the lower cervical spine, study of the influence of the posterior articular facets. J Biomech. September 1997;30(9):921-931.
2006	Wheeldon JA, Pintar FA, Knowles S, Yoganandan N. Experimental flexion/extension data corridors for validation of finite element models of the young, normal cervical spine. J Biomech. 2006;39(2):375-380.
2000	Kumaresan S, Yoganandan N, Pintar FA, Maiman DJ, Kuppa S. Biomechanical study of pediatric human cervical spine: a finite element approach. J Biomech Eng. February 2000;122(1):60-71.
1994	Bozic KJ, Keyak JH, Skinner HB, Bueff UH, Bradford DS. Three-dimensional finite element modeling of a cervical vertebra an investigation of burst fracture mechanism. J Spinal Disord. April 1994;7(2):102-110.
1997	Kumaresan S, Yoganandan N, Pintar FA, Voo LM, Cusick JF, Larson SJ. Finite element modeling of cervical laminectomy with graded facetectomy. J Spinal Disord. February 1997;10(1):40-46.
1996	Yoganandan N, Kumaresan SC, Voo L, Pintar FA, Larson SJ. Finite element modeling of the C4–C6 cervical spine unit. Med Eng Phys. October 1996;18(7):569-574.
1999	Kumaresan S, Yoganandan N, Pintar FA, Maiman DJ. Finite element modeling of the cervical spine: role of intervertebral disc under axial and eccentric loads. Med Eng Phys. December 1999;21(10):689-700.
2001	Teo EC, Ng HW. Evaluation of the role of ligaments, facets and disc nucleus in lower cervical spine under compression and sagittal moments using finite element method. Med Eng Phys. April 2001;23(3):155-164.
1998	Goel VK, Clausen JD. Prediction of load sharing among spinal components of a C5-C6 motion segment using the finite element approach. Spine. March 15, 1998;23(6):684-691.
2000	Kumaresan S, Yoganandan N, Pintar FA, Mueller WM. Biomechanics of pediatric cervical spine: compression, flexion and extension responses. J Crash Prev Injury Control. 2000;2(2):87-101.
1998	Camacho DLA. Dynamic Response of the Head and Cervical Spine to Near-Vertex Head Impact: An Experimental and Computational Study [PhD thesis]. Durham, NC: Duke University; 1998.
2006	Esat V. Biomechanical Modelling of the Whole Human Spine for Dynamic Analysis [PhD thesis]. Loughborough University; June 2006.
1997	Kumaresan S. Clinical Studies of the Human Cervical Spine Using Finite Element Modeling [PhD thesis]. Marquette University; December 1997.
2000	Golinski WZ. Three-Dimensional Dynamic Modelling Cervical Spine Human of the in Whiplash Situations [PhD thesis]. Nottingham, UK: Nottingham Trent University; November 2000.
2004	Greaves CY. Spinal Cord Injury Mechanisms: A Finite Element Study [Master's thesis]. Vancouver, BC: University of British Columbia; May 2004.
2007	Hu J. Neck Injury Mechanism in Rollover Crashes: A Systematic Approach for Improving Rollover Neck Protection [PhD thesis]. Detroit, MI: Wayne State University; 2007.