Application value of 3D print navigation module in the precise placement of thoracic and lumbar vertebral arch screws

doi:10.16098/j.issn.0529-1356.2023.03.013

Abstract

Abstract:

Objective To explore the effect of 3D print-based navigation module assisted placement of thoracolumbar pedicle screws. Methods From January 2019 to May 2021, we received 70 thoracic and lumbar fracture patients, divided into 3D technical group and conventional method group according to the surgical method, with 35 patients in each group. In the 3D technology group, pedicle screws were placed under the sight of the navigation module, while in the conventional group, pedicle screws were placed under the conventional C-arm fluoroscopy. The amount of intraoperative bleeding and time of C-arm were counted in each patient. According to the different number of pedicle screw implantation in each patient, the average amount of blood loss, time and C-arm fluoroscopy times of each screw implantation were compared between the two groups. Ideal screw angles were designed for patients in both groups before surgery. Compared with the preoperative design, the difference between preoperative and postoperative screw angle and head angle was calculated and set as the deviation value. Two sets of data were compared. Visual analogue score(VAS), Japanese Orthopaedic Association(JOA) score, Oswestry disability index(ODI), vertebral height recovery ratio and Cobb’s angle were compared between the two groups. Results The amount of blood loss, required time and exposure times of C-arm in 3D screw implantation group were significantly lower than those in conventional screw implantation group(P<0.05); After operation, the deviation of ininclination and head angle in the conventional method group was higher than that in the 3D technique group, and the difference was significant(P<0.05); The VAS, JOA score, ODI, vertebral height recovery ratio and Cobb’s angle were significantly improved compared with the preoperative groups(P<0.05); Three months after surgery, the VAS, JOA score, and ODI were not significantly different between the two groups (P>0.05); In terms of Cobb’s angle and vertebral height recovery ratio, the 3D technique group was better than the conventional method group (P<0.05). Conclusion The 3D printed navigation module can assist the precise placement of thoracolumbar pedicle screws, shorten the operation time, reduce intraoperative bleeding and c-arm exposure times, facilitate the recovery of the injured vertebral height, improve the efficacy.

Key words: Accurate placement, Pedicle screwst, Vertebra thoracalis, Lumbar vertebra, Three-dimensional technology, Human

CLC Number:

R683.2

HU Ding-xiang ZHENG Rui-qing LI Chang-hui CHEN Liang HUANG He DENG Ten-xiao . Application value of 3D print navigation module in the precise placement of thoracic and lumbar vertebral arch screws[J]. Acta Anatomica Sinica, 2023, 54(3): 342-347.

References

［1］Muralidhar BM, Hegde D, Hussain PSB. Management of unstable thoracolumbar spinal fractures by pedicle screws and rods fixation［J］. J Clin Diagn Res, 2014, 8(2): 121-123.

［2］McDonnell M, Shah KN, Paller DJ, et al. Biomechanical analysis of pedicle screw fixation for thoracolumbar burst fractures［J］. Orthopedics, 2016, 39(3): e514-e518.

［3］Arbash MA, Parambathkandi AM, Bacoa M, et al. Impact of screw type on kyphotic deformity correction after spine fracture fixation: cannulated versus solid pedicle screw［J］. Asian Spine J, 2018, 12(6):1053-1059.

［4］Tian F, Tul Y, Gu WF, et al. Percutaneous versus open pedicle screw instrumentation in treatment of thoracic and lumbar spine fractures: a systematic review and metaanalysis［J］. Medicine(Baltimore), 2018, 97(41): e12535.

［5］Li K, Li Z, Ren X, et al. Effect of the percutaneous pediclescrew fixation at the fractured vertebra on the treatment of thoracolumbar fractures［J］. Int Orthop, 2016, 40(6): 1103-1110.

［6］Wang L, Li J, Wang H, et al. Posterior short segment pedicle screw fixation and TLIF for the treatment of unstable thoracolumbar/lumbar fracture［J］. BMC Musculoskelet Disord, 2014, 15:40.

［7］Phan K, Ramachandran V, Tran TM, et al. Systematic review of cortical bone trajectory versus pedicle screw techniques for lumbosacral spine fusion［J］. J Spine Surg, 2017, 3(4): 679-688.

［8］Chi JH, Eichholz KM, Anderson PA, et al. Congress of neurological surgeons systematic review and evidence-based guidelines on the evaluation and treatment of patients with thoracolumbar spine trauma:novel surgical strategies［J］. Neurosurgery, 2019, 84(1):E59-E62.

［9］Vijayeswaran N, Venkatesh R, Murugesan G, et al. Is freehand technique of pedicle screw insertion in thoracolumbar spine safe and accurate? Assessment of 250 screws［J］. J Neurosci Rural Pract，2019，10(2): 256-260.

［10］Qian BP, Zhang YP, Qiao M, et al. Accuracy of freehand pedicle screw placement in surgical correction of thoracolumbar kyphosis secondary to ankylosing spondylitis: a computed tomography investigation of 2314 consecutive screws ［J］. World Neurosurg, 2018, 116: e850-e855.

［11］Kochanski RB, Lombardi JM, Laratta JL, et al. Image-guided navigation and robotics in spine surgery［J］. Neurosurgery,2019, 84(6):1179-1189.

［12］Tian W, Liu YJ, Liu B, et al. Guideline for thoracolumbar pedicle screw placement assisted by orthopaedic surgical robot［J］. Orthop Surg, 2019, 11(2):153-159.

［13］Elmi-Terander A, Nachabe R, Skulason H, et al. Feasibility and accuracy of thoracolumbar minimally invasive pedicle screw placement with augmented reality navigation technology［J］. Spine (Phila Pa 1976),2018, 43(14):1018-1023.

［14］Nakashima D, Kanchiku T, Nishida N, et al. Finite element analysis of compression fractures at the thoracolumbar junction using models constructed from medical images［J］. Exp Ther Med, 2018, 15(4): 3225-3230.

［15］Wiedl A, F?rch S, Fenwick A, et al. Importance of surgical treatment of thoraco-lumbar vertebral fractures for the survival probability of orthogeriatric patients ［J］. Unfallchirurg, 2021, 124(4): 303-310.

［16］Mazel C, Ajavon L. Malunion of post-traumatic thoracolumbar fractures ［J］. Orthop Traumatol Surg Res, 2018,104(1S):S55-S62.

［17］Pang JY, Zhao Y, Xiao YL, et al. Application of three-dimensional printing technology in spinal surgery［J］. Chinese Journal of Tissue Engineering Research, 2016, 20(4): 577-582. (in Chinese)

庞骄阳, 赵岩, 肖宇龙, 等. 3D打印技术在脊柱外科的应用［J］. 中国组织工程研究, 2016, 20(4): 577-582.

［18］Luo M, Wang W, Yang N, et al. Does three-dimensional printing plus pedicle guider technology in severe congenital scoliosis facilitate accurate and efficient pedicle screw placement ［J］ ? Clin Orthop Relat Res, 2019, 477(8): 1904-1912.

［19］Liu K, Zhang Q, Li X, et al. Preliminary application of a multi-level 3D printing drill guide template for pedicle screw placement in severe and rigid scoliosis［J］. Eur Spine J, 2017, 26(6): 1684-1689.

［20］Cao XY, Liu RZh, Zhang HL, et al. Application of flipped classroom teaching mode supported by 3D printing model in embryology experiment teaching［J］. Acta Anatomica Sinica, 2021, 52(3): 479-484.(in Chinese)

曹馨元, 刘润竹, 张翰林, 等. 3D打印模型在人体胚胎学实验教学翻转课堂中的应用［J］. 解剖学报, 2021, 52(3): 479-484.

［21］Wu C, Deng J, Zeng B, et al. Three-dimensional anatomic analysis and navigation templates for C1 pedicle screw placement perpendicular to the coronal plane: a retrospective study［J］. Neurol Res, 2021,43(12):961-969.

［22］Senkoylu A, Daldal I, Cetinkaya M. 3D printing and spine surgery［J］. J Orthop Surg (Hong Kong), 2020,28(2):1-7.

［23］Yan B, Sun YJ, Ouyang HB, et al. Clinical application of accurate lumbar pedicle screws placement assisted by 3D printing navigation modules［J］. Chinese Journal of Clinical Anatomy, 2017, 35(2): 156-159. (in Chinese)

严斌, 孙永建, 欧阳汉斌, 等. 3D打印导航模块辅助腰椎椎弓根螺钉精确植入的应用研究［J］. 中国临床解剖学杂志, 2017, 35(2): 156-159.

［24］Liu ZhP, Wang YH, Chu L, et al. 3D printing assisted pedicle screw placement in instrumented fusion for lumbar spondylolisthesis［J］. Orthopedic Journal of China, 2019, 27(16): 1482-1486. (in Chinese)

刘正蓬, 王雅辉, 褚立, 等. 3D 打印辅助椎弓钉置入融合术治疗腰椎滑脱［J］. 中国矫形外科杂志, 2019, 27(16): 1482-1486.

［25］Sagi HC, Manos R, Benz R, et al. Electromagnetic field-based image-guided spine surgery part one:rsults of a cadaveric study evaluating lumbar pedicle screws placement ［J］.Spine,2003,28(17):2013-2018.

［26］Karim A, Mukherjee D, Gonzalez-Cruz J, et al. Accuracy of pedicle screws placement for lumbar fusion using anatomic land marks versus open laminectomy: a comparison of two surgical techniques in cadaveric specimens［J］. Neurosurgery, 2006, 59(1):13-19.

［27］Chen H, Wu D, Yang H, et al. Clinical use of 3D printing guide plate in posterior lumbar pedicle screw fixation［J］. Med Sci Monit, 2015, 21: 3948-3954.

［28］You W, Liu LJ, Chen HX, et al. Application of 3D printing technology on the treatment of complex proximal humeral fractures(Neer3-part and 4-part)in old people［J］. Orthop Traumatol Surg Res, 2016, 102(7): 897-903.

［29］Kapoen C, Liu Y, Bloemers FW, et al. Pedicle screw fixation of thoracolumbar fractures: conventional short segment versus short segment with intermediate screws at the fracture level-a systematic review and meta-analysis［J］. Eur Spine J, 2020, 29(10): 2491-2504.

［30］Mazel C, Ajavon L. Malunion of post-traumatic thoracolumbar fractures ［J］. Orthop Traumatol Surg Res, 2018, 104(1S): S55-S62.

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