Analysis of load distribution after transpedicular stabilization of burst fractures in the thoracolumbar junction-Reference-Cited by-同舟云学术

Analysis of load distribution after transpedicular stabilization of burst fractures in the thoracolumbar junction

Published:2024-05-16 Issue:1-2 Volume:25 Page:35-44
ISSN:2307-1397
Container-title:TRAUMA
language:
Short-container-title:TRAUMA

Author:

Nekhlopochyn O.S.^ORCID,Verbov V.V.^ORCID,Cheshuk Ie.V.^ORCID,Karpinsky M.Yu.^ORCID,Yaresko O.V.^ORCID

Abstract

Background. In the structure of all traumatic spine injuries, the thoracolumbar junction is predominant, accounting for over 53 % of all vertebral fractures. One of the most clinically significant types of injuries in this area are burst fractures. The purpose was to study the stress-strain state of the thoracolumbar spine model with a burst fracture of the Th12 vertebra in various transpedicular fixation options under compression load. Materials and methods. The study developed and investigated a finite element model of the thoracolumbar spine with a burst fracture of the Th12 vertebra. The burst fracture was modeled by dividing the vertebral body of the Th12 into several planes, transforming it into separate fragments. The gaps between these fragments were filled with a material that simulated the interfragmentary regenerate. Variants of transpedicular stabilization using different types of screws, mono- or bicortical, and with or without cross-links, were examined. The model was analyzed under compression load. Results. The maximum level of stress among the bone structures directly involved in fixation was registered in the L2 vertebral body. It amounted to 19.9, 15.6, 19.4, and 15.1 MPa, respectively, for models with monocortical screws without cross-links, bicortical screws without cross-links, monocortical screws with cross-links, bicortical screws with cross-links. Simultaneously, the zone of screw entry into the arch of this vertebra shows values of 10.1, 15, 10.2, and 14.3 MPa for these models, respectively. Peak loads on the metal structure elements are observed on the rods, amounting to 212.5, 159.6, 203.7, 142.8 MPa, respectively, for the considered models. Conclusions. The results of the study showed that under the influence of compression load when modeling a burst fracture of the thoracolumbar junction, the use of long screws leads to a reduction in stress levels, both in the elements of the metal structure and in the bone elements of the model, while the use of cross-links has a negligible effect.

Publisher

Publishing House Zaslavsky

Reference29 articles.

GBD 2019 Diseases and Injuries Collaborators. Global burden of 369 diseases and injuries in 204 countries and territories, 1990-2019: a systematic analysis for the Global Burden of Disease Study 2019. Lancet. 2020 Oct 17;396(10258):1204-1222. doi: 10.1016/S0140-6736(20)30925-9.

Nekhlopochyn OS, Nikiforova AN, Verbov VV, Yovenko TA, Cheshuk IV. Analysis of the Epidemiology of Traumatic Vertebral Column Injuries in Eastern European Countries. Ukrainian Neurosurgical Journal. 2023;29(4):22-34. doi: 10.25305/unj.286922.

Baaj AA, Downes K, Vaccaro AR, Uribe JS, Vale FL. Trends in the treatment of lumbar spine fractures in the United States: a socioeconomics perspective: clinical article. J Neurosurg Spine. 2011 Oct;15(4):367-370. doi: 10.3171/2011.5.SPINE10934.

Bouyer B, Vassal M, Zairi F, et al. Surgery in vertebral fracture: epidemiology and functional and radiological results in a prospective series of 518 patients at 1 year's follow-up. Orthop Traumatol Surg Res. 2015 Feb;101(1):11-15. doi: 10.1016/j.otsr.2014.11.012.