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BMC Surgery
Published in: BMC Surgery 1/2022

Open Access 01-12-2022 | Research

Predictors of accurate intrapedicular screw placement in single-level lumbar (L4-5) fusion: robot-assisted pedicle screw, traditional pedicle screw, and cortical bone trajectory screw insertion

Authors: Hua-Qing Zhang, Can-Can Wang, Ren-Jie Zhang, Lu-Ping Zhou, Chong-Yu Jia, Peng Ge, Cai-Liang Shen

Published in: BMC Surgery | Issue 1/2022

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Abstract

Background

The superiorities in proximal facet joint protection of robot-assisted (RA) pedicle screw placement and screw implantation via the cortical bone trajectory (CBT) have rarely been compared. Moreover, findings on the screw accuracy of both techniques are inconsistent. Therefore, we analyzed the screw accuracy and incidence of facet joint violation (FJV) of RA and CBT screw insertion in the same study and compared them with those of conventional pedicle screw (PS) insertion. The possible factors affecting screw accuracy and FJV were also analyzed.

Methods

A total of 166 patients with lumbar degenerative diseases requiring posterior L4-5 fusion were retrospectively included and divided into the RA, PS, and CBT groups from March 2019 to December 2021. The grades of intrapedicular accuracy and superior FJV were evaluated according to the Gertzbin–Robbins scale and the Babu scale based on postoperative CT. Univariable and multivariable analyses were conducted to assess the possible risk factors associated with intrapedicular accuracy and superior FJV.

Results

The rates of optimal screw insertion in the RA, PS, and CBT groups were 87.3%, 81.3%, and 76.5%, respectively. The difference between the RA and CBT groups was statistically significant (P = 0.004). Superior FJVs occurred in 28.2% of screws in RA, 45.0% in PS, and 21.6% in CBT. The RA and CBT groups had fewer superior FJVs than the PS group (P = 0.008 and P < 0.001, respectively), and no significant difference was observed between the RA and CBT groups (P = 0.267). Multivariable analysis revealed that the CBT technique was an independent risk factor for intrapedicular accuracy. Furthermore, older age, the conventional PS technique and a smaller facet angle were independently associated with the incidence of superior FJVs.

Conclusions

The RA and CBT techniques were associated with fewer proximal FJVs than the PS technique. The RA technique showed a higher rate of intrapedicular accuracy than the CBT technique. The CBT technique was independently associated with screw inaccuracy. Older age, conventional PS technique and coronal orientation of the facet join were independent risk factors for superior FJV.
Literature
1.
Vaccaro AR, Garfin SR. Pedicle-screw fixation in the lumbar spine. J Am Acad Orthop Surg. 1995;3(5):263–74.CrossRef
2.
Boden SD. Overview of the biology of lumbar spine fusion and principles for selecting a bone graft substitute. Spine (Phila Pa 1976). 2002;27(16 Suppl 1):S26–31.CrossRef
3.
Irmola TM, Häkkinen A, Järvenpää S, Marttinen I, Vihtonen K, Neva M. Reoperation rates following instrumented lumbar spine fusion. Spine. 2018;43(4):295–301.CrossRef
4.
Yang JY, Lee J, Song H. The impact of adjacent segment degeneration on the clinical outcome after lumbar spinal fusion. Spine (Philadelphia, Pa 1976). 2008;33(5):503–7.CrossRef
5.
Yugué I, Okada S, Masuda M, Ueta T, Maeda T, Shiba K. Risk factors for adjacent segment pathology requiring additional surgery after single-level spinal fusion: impact of pre-existing spinal stenosis demonstrated by preoperative myelography. Eur Spine J. 2016;25(5):1542–9.CrossRef
6.
Bagheri SR, Alimohammadi E, Zamani Froushani A, Abdi A. Adjacent segment disease after posterior lumbar instrumentation surgery for degenerative disease: incidence and risk factors. J Orthop Surg-Hong K. 2019;27(2):920543725.
7.
Lau K, Samartzis D, To N, Harada GK, An HS, Wong A. Demographic, surgical, and radiographic risk factors for symptomatic adjacent segment disease after lumbar fusion: a systematic review and meta-analysis. J Bone Jt Surg Am. 2021;103(15):1438–50.CrossRef
8.
9.
Wang H, Ma L, Yang D, Wang T, Liu S, Yang S, Ding W. Incidence and risk factors of adjacent segment disease following posterior decompression and instrumented fusion for degenerative lumbar disorders. Medicine. 2017;96(5): e6032.CrossRef
10.
Cardoso MJ, Dmitriev AE, Helgeson M, Lehman RA, Kuklo TR, Rosner MK. Does superior-segment facet violation or laminectomy destabilize the adjacent level in lumbar transpedicular fixation? An in vitro human cadaveric assessment. Spine (Phila Pa 1976). 2008;33(26):2868–73.CrossRef
11.
Y X, X L, Q Z, S K, H L, F D, Z S, B L, D H, Z L et al: Superior-segment bilateral facet violation in lumbar transpedicular fixation, Part III: a biomechanical study of severe violation. Spine. 2020.
12.
Jones-Quaidoo SM, Djurasovic M, Owens RN, Carreon LY. Superior articulating facet violation: percutaneous versus open techniques. J Neurosurg Spine. 2013;18(6):593–7.CrossRef
13.
Han X, Tian W, Liu Y, Liu B, He D, Sun Y, Han X, Fan M, Zhao J, Xu Y, et al. Safety and accuracy of robot-assisted versus fluoroscopy-assisted pedicle screw insertion in thoracolumbar spinal surgery: a prospective randomized controlled trial. J Neurosurg Spine. 2019;30(5):615–22.CrossRef
14.
Kantelhardt SR, Martinez R, Baerwinkel S, Burger R, Giese A, Rohde V. Perioperative course and accuracy of screw positioning in conventional, open robotic-guided and percutaneous robotic-guided, pedicle screw placement. Eur Spine J. 2011;20(6):860–8.CrossRef
15.
Marengo N, Berjano P, Cofano F, Ajello M, Zenga F, Pilloni G, Penner F, Petrone S, Vay L, Ducati A, et al. Cortical bone trajectory screws for circumferential arthrodesis in lumbar degenerative spine: clinical and radiological outcomes of 101 cases. Eur Spine J. 2018;27(Suppl 2):213–21.CrossRef
16.
Sakaura H, Miwa T, Yamashita T, Kuroda Y, Ohwada T. Cortical bone trajectory screw fixation versus traditional pedicle screw fixation for 2-level posterior lumbar interbody fusion: comparison of surgical outcomes for 2-level degenerative lumbar spondylolisthesis. J Neurosurg Spine. 2018;28(1):57–62.CrossRef
17.
Gao S, Lv Z, Fang H. Robot-assisted and conventional freehand pedicle screw placement: a systematic review and meta-analysis of randomized controlled trials. Eur Spine J. 2018;27(4):921–30.CrossRef
18.
Zhang Q, Xu YF, Tian W, Le XF, Liu B, Liu YJ, He D, Sun YQ, Yuan Q, Lang Z, et al. Comparison of superior-level facet joint violations between robot-assisted percutaneous pedicle screw placement and conventional open fluoroscopic-guided pedicle screw placement. Orthop Surg. 2019;11(5):850–6.CrossRef
19.
Zhang R, Zhou L, Zhang L, Zhang H, Ge P, Jia C, Zhang Y, Zhang J, Shen C. The rates and risk factors of intra-pedicular accuracy and proximal facet joint violation for single-level degenerative lumbar diseases. Spine. 2021;46(23):E1274–82.CrossRef
20.
Marengo N, Ajello M, Pecoraro MF, Pilloni G, Vercelli G, Cofano F, Zenga F, Ducati A, Garbossa D. Cortical bone trajectory screws in posterior lumbar interbody fusion: minimally invasive surgery for maximal muscle sparing—a prospective comparative study with the traditional open technique. Biomed Res Int. 2018;2018:1–7.CrossRef
21.
Ringel F, Stüer C, Reinke A, Preuss A, Behr M, Auer F, Stoffel M, Meyer B. Accuracy of robot-assisted placement of lumbar and sacral pedicle screws. Spine. 2012;37(8):E496–501.CrossRef
22.
Marcus HJ, Cundy TP, Nandi D, Yang G, Darzi A. Robot-assisted and fluoroscopy-guided pedicle screw placement: a systematic review. Eur Spine J. 2014;23(2):291–7.CrossRef
23.
Molliqaj G, Schatlo B, Alaid A, Solomiichuk V, Rohde V, Schaller K, Tessitore E. Accuracy of robot-guided versus freehand fluoroscopy-assisted pedicle screw insertion in thoracolumbar spinal surgery. Neurosurg Focus. 2017;42(5):E14.CrossRef
24.
Kim H, Jung W, Chang B, Lee C, Kang K, Yeom JS. A prospective, randomized, controlled trial of robot-assisted vs freehand pedicle screw fixation in spine surgery. Int J Med Robot Comput Assist Surg. 2017;13(3): e1779.CrossRef
25.
26.
Maruo K, Arizumi F, Kusuyama K, Kishima K, Tachibana T. Accuracy and safety of cortical bone trajectory screw placement by an inexperienced surgeon using 3D patient-specific guides for transforaminal lumbar interbody fusion. J Clin Neurosci. 2020;78:147–52.CrossRef
27.
Tan Z, McLachlin S, Whyne C, Finkelstein J. Validation of a freehand technique for cortical bone trajectory screws in the lumbar spine. J Neurosurg Spine. 2019;31(2):201–8.CrossRef
28.
Gertzbein SD, Robbins SE. Accuracy of pedicular screw placement in vivo. Spine (Phila Pa 1976). 1990;15(1):11–4.CrossRef
29.
Babu R, Park JG, Mehta AI, Shan T, Grossi PM, Brown CR, Richardson WJ, Isaacs RE, Bagley CA, Kuchibhatla M, et al. Comparison of superior-level facet joint violations during open and percutaneous pedicle screw placement. Neurosurgery. 2012;71(5):962–70.CrossRef
30.
Grobler LJ, Robertson PA, Novotny JE, Pope MH. Etiology of spondylolisthesis. Assessment of the role played by lumbar facet joint morphology. Spine (Phila Pa 1976). 1993;18(1):80–91.CrossRef
31.
32.
Katonis P, Christoforakis J, Kontakis G, Aligizakis AC, Papadopoulos C, Sapkas G, Hadjipavlou A. Complications and problems related to pedicle screw fixation of the spine. Clin Orthop Relat Res. 2003;411:86–94.CrossRef
33.
Zhou L, Zhang R, Li H, Shen C. Comparison of cranial facet joint violation rate and four other clinical indexes between robot-assisted and freehand pedicle screw placement in spine surgery: a meta-analysis. Spine (Philadelphia, Pa 1976). 2020;45(22):E1532–40.CrossRef
34.
Sakaura H, Ikegami D, Fujimori T, Sugiura T, Mukai Y, Hosono N, Fuji T. Early cephalad adjacent segment degeneration after posterior lumbar interbody fusion: a comparative study between cortical bone trajectory screw fixation and traditional trajectory screw fixation. J Neurosurg Spine. 2020;32(2):155–9.CrossRef
35.
Zhang Q, Han X, Xu Y, Liu Y, Liu B, He D, Sun Y, Tian W. Robot-assisted versus fluoroscopy-guided pedicle screw placement in transforaminal lumbar interbody fusion for lumbar degenerative disease. World Neurosurg. 2019;125:e429–34.CrossRef
36.
Ding H, Han B, Hai Y, Liu Y, Guan L, Pan A, Liu T. The feasibility of assessing the cortical bone trajectory screw placement accuracy using a traditional pedicle screw insertion evaluation system. Clin Spine Surg. 2021;34(2):E112–20.CrossRef
37.
Chen Z, Zhao J, Xu H, Liu A, Yuan J, Wang C. Technical factors related to the incidence of adjacent superior segment facet joint violation after transpedicular instrumentation in the lumbar spine. Eur Spine J. 2008;17(11):1476–80.CrossRef
38.
Chung KJ, Suh SW, Swapnil K, Yang JH, Song HR. Facet joint violation during pedicle screw insertion: a cadaveric study of the adult lumbosacral spine comparing the two pedicle screw insertion techniques. Int Orthop. 2007;31(5):653–6.CrossRef
39.
Teles AR, Paci M, Gutman G, Abduljabbar FH, Ouellet JA, Weber MH, Golan JD. Anatomical and technical factors associated with superior facet joint violation in lumbar fusion. J Neurosurg Spine. 2018;28(2):173.CrossRef
40.
Patel JY, Kundnani VG, Merchant ZI, Jain S, Kire N. Superior facet joint violations in single level minimally invasive and open transforaminal lumbar interbody fusion: a comparative study. Asian Spine J. 2020;14(1):25–32.CrossRef
41.
Tian W, Xu Y, Liu B, Liu Y, He D, Yuan Q, Lang Z, Lyu Y, Han X, Jin P. Lumbar spine superior-level facet joint violations: percutaneous versus open pedicle screw insertion using intraoperative 3-dimensional computer-assisted navigation. Chin Med J-Peking. 2014;127(22):3852–6.
42.
43.
Matsukawa K, Kato T, Yato Y, Sasao H, Imabayashi H, Hosogane N, Asazuma T, Chiba K. Incidence and risk factors of adjacent cranial facet joint violation following pedicle screw insertion using cortical bone trajectory technique. Spine (Philadelphia, Pa 1976). 2016;41(14):E851–6.CrossRef
Metadata
Title
Predictors of accurate intrapedicular screw placement in single-level lumbar (L4-5) fusion: robot-assisted pedicle screw, traditional pedicle screw, and cortical bone trajectory screw insertion
Authors
Hua-Qing Zhang
Can-Can Wang
Ren-Jie Zhang
Lu-Ping Zhou
Chong-Yu Jia
Peng Ge
Cai-Liang Shen
Publication date
01-12-2022
Publisher
BioMed Central
Published in
BMC Surgery / Issue 1/2022
Electronic ISSN: 1471-2482
DOI
https://doi.org/10.1186/s12893-022-01733-6

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