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Biomechanical analysis of stabilization for thoracolumbar anterior spinal failure caused by osteolytic lesions, a finite element comparison of direct lateral corpectomy and posterior long segment instrumentation.

Authors :
Nevzati, Edin
Kemp, Oliver AG
Rhoads, Colin
Witt, Jens-Peter
Finn, Michael
Moser, Manuel
Spiessberger, Alexander
Source :
Spine Journal. Nov2024, Vol. 24 Issue 11, p2181-2190. 10p.
Publication Year :
2024

Abstract

Osteolytic lesions caused by infection or metastatic disease of the spine can induce instability. Different surgical strategies are available to restore stability in this scenario, however little is known how various reconstruction techniques affect spinal biomechanics. To analyze and quantify the biomechanical effects of three different surgical reconstruction techniques in the treatment of a T12 osteolytic model. Finite element analysis of the thoracic spine with a T12 osteolytic lesion. Using CT scans from a 20-year-old man without structural deformity, simulation of an osteolytic lesion with a 50% defect at the posterior aspect of T12 vertebral body was created by a 490 N vertical force to T9. Next, three common instrumentation techniques treating the osteolytic lesion were modeled and biomechanically tested. These included: Model A , corpectomy with short segment fixation (T11-L1) and two long-segment instrumentations; Model B long segment fixation with triple rod construct; Model C long segment fixation with dual rod construct. A load of 480N was then applied on the spine models in vertically downward direction on T9. Von Mises stresses were measured (MPa) in the discs, vertebrae, and implants. Model A demonstrated the lowest stress on construct material, adjacent vertebral bodies, and discs but increased stress on the instrumented vertebrae. Model B was more rigid and demonstrated lower construct stress compared to Model C. However, Model C had the lowest vertebral body stress in flexion, extension, and lateral bending in the most upper instrumented vertebral body, but the highest screw pull-out stress when compared to Model A and Model B. This osteolytic T12 model provides unique biomechanical data that can help to tailor surgical strategies in select scenarios. While optimal outcomes are best achieved with a construct tailored to a specific patient's need for stabilization, our findings can be generalized for instances of cancerous lesions, low bone density, and infectious causes. The results of this study can help with the choice of appropriate surgical reconstruction technique based on patient-specific characteristics. [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
15299430
Volume :
24
Issue :
11
Database :
Academic Search Index
Journal :
Spine Journal
Publication Type :
Academic Journal
Accession number :
180561389
Full Text :
https://doi.org/10.1016/j.spinee.2024.06.570