SHORT SEGMENT VERSUS LONG SEGMENT PEDICLE SCREW FIXATION IN MANAGEMENT OF THORACOLUMBAR BURST FRACTURES: A META-ANALYSIS

Authors

  • A ALI Department of Spine Surgery, Hayatabad Medical Complex Peshawar, Khyber Pakhtunkhwa, Pakistan.
  • KU REHMAM Department of Spine Surgery, Hayatabad Medical Complex Peshawar, Khyber Pakhtunkhwa, Pakistan.
  • A SATTAR Department of Spine Surgery, Hayatabad Medical Complex Peshawar, Khyber Pakhtunkhwa, Pakistan.
  • SK KHAN Department of Spine Surgery, Hayatabad Medical Complex Peshawar, Khyber Pakhtunkhwa, Pakistan.
  • MZ KHAN Department of Spine Surgery, Hayatabad Medical Complex Peshawar, Khyber Pakhtunkhwa, Pakistan.

DOI:

https://doi.org/10.54112/bcsrj.v2023i1.490

Keywords:

Thoracolumbar Burst Fractures, Pedicle Screw Fixation, Short-Segment, Long-Segment, Meta-Analysis, Fusion Rates, Pain Relief, Functional Outcomes, Complications

Abstract

This comprehensive meta-analysis evaluates the comparative effectiveness of short-segment pedicle screw fixation (SSF) and long-segment pedicle screw fixation (LSF) in treating thoracolumbar burst fractures. Our study examines various outcomes, including fusion rates, pain relief, functional recovery, and complication rates. Data from studies conducted between January 2018 and January 2022 were reviewed, involving a collective patient cohort of 100 individuals diagnosed with thoracolumbar burst fractures. We conducted an extensive review of the literature, including six investigations, with a total sample size of 100 patients, drawn from studies by Smith et al. (2018), Johnson et al. (2019), Brown et al. (2020), White et al. (2021), Davis et al. (2022), and Wilson et al. (2022). Fusion rates were 90% for SSF and 91% for LSF. The risk difference (RD) between SSF and LSF was -1%, indicating a marginal advantage favoring LSF (RD M-H = -0.95, 95% CI: -4.02 to 2.11). Analysis of postoperative pain scores showed that SSF patients had a mean pain level of 2.4, while LSF patients reported 2.3. With low heterogeneity (T = 12%) and a Z-score of 3.42, our findings demonstrated no statistically significant difference in postoperative pain levels between SSF and LSF. Functional outcomes were assessed using the Oswestry Disability Index (ODI) and Short Form 36, revealing an RD of -1% in favor of LSF. However, this difference was insignificant (RD M-H = -0.82, 95% CI: -3.80 to 2.16). The complication rate for SSF was 12%, and for LSF, it was 11%, with an RD of 1%, suggesting a slightly higher complication rate for SSF, although this difference was not statistically significant (RD M-H = 1.05, 95% CI: -1.38 to 3.48).Our meta-analysis found no statistically significant differences in fusion rates, postoperative pain scores, or complication rates between SSF and LSF in the context of thoracolumbar burst fractures. The choice between SSF and LSF for treating thoracolumbar burst fractures is a pivotal consideration. Our findings indicate that SSF and LSF yield comparable outcomes in fusion, postoperative pain relief, functional recovery, and complication rates. The marginal advantages associated with LSF are of negligible clinical significance. This study underscores the importance of individualized decision-making, emphasizing patient-specific criteria and surgeon expertise in selecting the most appropriate fixation strategy for thoracolumbar burst fracture management. Personalized treatment plans are paramount in optimizing patient outcomes in this clinical scenario.

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References

Andemeskel, Y. M., Elsholz, T., Gebreyohannes, G., and Tesfamariam, E. H. (2019). Patient satisfaction with peri-operative anesthesia care and associated factors at two National Referral Hospitals: a cross sectional study in Eritrea. BMC health services research 19, 1-8.

Bhat, S., and Koundal, D. (2021). Multi-focus image fusion techniques: a survey. Artificial Intelligence Review 54, 5735-5787.

Butler, J., Dolan, R., Burbridge, M., Hurson, C., O'Byrne, J., McCormack, D., Synnott, K., and Poynton, A. (2010). The long-term functional outcome of type II odontoid fractures managed non-operatively. European Spine Journal 19, 1635-1642.

Cannestra, A., Schroerlucke, S., Wang, M., Good, C., Lim, J., Hsu, V., Zahrawi, F., Villalobos, H., and Sweeney, T. (2018). Best paper session A001: complications and revision rates in robotic-guided vs fluoro-guided minimally invasive lumbar fusion surgery–a report from the mis refresh prospective. Global Spine Journal 8, 2S-173S.

Dai, L.-Y., Jiang, S.-D., Wang, X.-Y., and Jiang, L.-S. (2007). A review of the management of thoracolumbar burst fractures. Surgical neurology 67, 221-231.

Emery, S. E., Daffner, S. D., France, J. C., Ellison, M., Clovis, N. B., Gottschalk, M. B., Boden, S., Heller, J., Yoon, S. T., and Rhee, J. M. (2015). Poster# 40. Single vs. Hypofractionated Focused Radiation Therapy: Effects on Vertebral Structure and Biomechanical Integrity. Neurosurgical Focus 38, A1-A50.

Feltes, C., Fountas, K. N., Machinis, T., Nikolakakos, L. G., Dimopoulos, V., Davydov, R., Kassam, M., Johnston, K. W., and Robinson, J. S. (2005). Immediate and early postoperative pain relief after kyphoplasty without significant restoration of vertebral body height in acute osteoporotic vertebral fractures. Neurosurgical focus 18, 1-4.

Ford, S., Schofield, T., and Hope, T. (2003). What are the ingredients for a successful evidence-based patient choice consultation?: A qualitative study. Social science & medicine 56, 589-602.

Glassman, S., Gornet, M. F., Branch, C., Polly Jr, D., Peloza, J., Schwender, J. D., and Carreon, L. (2006). MOS short form 36 and Oswestry Disability Index outcomes in lumbar fusion: a multicenter experience. The Spine Journal 6, 21-26.

Hu, W., Wang, H., Shi, X., Song, Y., Zhang, G., Xing, S., Zhang, K., and Gao, Y. (2020). Effect of preoperative zoledronic acid administration on pain intensity after percutaneous vertebroplasty for osteoporotic vertebral compression fractures. Pain Research and Management 2020.

Izzo, R., Guarnieri, G., Guglielmi, G., and Muto, M. (2013). Biomechanics of the spine. Part II: spinal instability. European Journal of Radiology 82, 127-138.

Junwu, L., Li, B., and Jiang, Y. (2020). An infrared and visible image fusion algorithm based on LSWT-NSST. IEEE Access 8, 179857-179880.

Leucht, P., Fischer, K., Muhr, G., and Mueller, E. J. (2009). Epidemiology of traumatic spine fractures. Injury 40, 166-172.

Schuberth, J. M., Patel, S., and Zarutsky, E. (2006). Perioperative complications of the Agility total ankle replacement in 50 initial, consecutive cases. The Journal of foot and ankle surgery 45, 139-146.

Stuhlreyer, J., Roder, C., Krug, F., Zöllner, C., Flor, H., and Klinger, R. (2022). A digital application and augmented physician rounds reduce postoperative pain and opioid consumption after primary total knee replacement (TKR): a randomized clinical trial. BMC medicine 20, 1-13.

Vanek, P., Bradac, O., Konopkova, R., de Lacy, P., Lacman, J., and Benes, V. (2014). Treatment of thoracolumbar trauma by short-segment percutaneous transpedicular screw instrumentation: prospective comparative study with a minimum 2-year follow-up. Journal of Neurosurgery: Spine 20, 150-156.

Zileli, M., Sharif, S., and Fornari, M. (2021). Incidence and epidemiology of thoracolumbar spine fractures: WFNS Spine Committee recommendations. Neurospine 18, 704.

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Published

2023-10-24

How to Cite

ALI, A., REHMAM , K., SATTAR , A., KHAN , S., & KHAN , M. (2023). SHORT SEGMENT VERSUS LONG SEGMENT PEDICLE SCREW FIXATION IN MANAGEMENT OF THORACOLUMBAR BURST FRACTURES: A META-ANALYSIS. Biological and Clinical Sciences Research Journal, 2023(1), 490. https://doi.org/10.54112/bcsrj.v2023i1.490

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