Effectiveness of modified orthopedic robot-assisted percutaneous kyphoplasty in treatment of osteoporotic vertebral compression fracture_Chinese Journal of Reparative and Reconstructive Surgery

Authors：

LIN Shu ,  TAN Ke , HU Jiang , WAN Lun , WANG Yue

Department of Orthopedics, Sichuan Academy of Medical Science, People’s Hospital of Sichuan Province, Chengdu Sichuan, 610072, P. R. China;

Corresponding?author：

TAN Ke, Email: 87151324@qq.com

Keywords：

TiRobot; percutaneous kyphoplasty; osteoporotic vertebral compression fracture; cement leakage

DOI：

10.7507/1002-1892.202204013

Video：

Export PDF Favorites Scan Get Citation

Abstract Full text Figures/Tables Video References Cited by

Objective To evaluate the effectiveness of orthopedic robot with modified tracer fixation (short for modified orthopedic robot) assisted percutaneous kyphoplasty (PKP) in treatment of single-segment osteoporotic vertebral compression fracture (OVCF). Methods The clinical data of 155 patients with single-segment OVCF who were admitted between December 2017 and January 2021 and met the selection criteria was retrospectively analyzed. According to the operation methods, the patients were divided into robot group (87 cases, PKP assisted by modified orthopedic robot) and C-arm group (68 cases, PKP assisted by C-arm X-ray fluoroscopy). There was no significant difference in gender, age, body mass index, T value of bone mineral density, therapeutic segment, grade of vertebral compression fracture, and preoperative visual analogue scale (VAS) score, midline vertebral height, and Cobb angle between the two groups (P>0.05). The effectiveness evaluation indexes of the two groups were collected and compared. The clinical evaluation indexes included the establishment time of working channel, dose of intraoperative fluoroscopy, the amount of injected cement, VAS score before and after operation, and the occurrence of complications. The imaging evaluation indexes included the degree of puncture deviation, the degree of bone cement diffusion, the leakage of bone cement, the midline vertebral height and the Cobb angle before and after operation. Results The establishment time of working channel in robot group was significantly shorter than that in C-arm group, and the dose of intraoperative fluoroscopy was significantly larger than that in C-arm group (P<0.001). There was no significant difference in the amount of injected cement between the two groups (t=1.149, P=0.252). The patients in two groups were followed up 10-14 months (mean, 12 months). Except that the intraoperative VAS score of the robot group was significantly better than that of the C-arm group (P<0.05), there was no significant difference between the two groups at other time points (P>0.05). No severe complication such as infection, spinal cord or nerve injury, and pulmonary embolism occurred in the two groups. Five cases (5.7%) in robot group and 7 cases (10.2%) in C-arm group had adjacent segment fracture, and the difference in incidence of adjacent segment fracture between the two groups was not significant (χ²=1.105, P=0.293). Compared with C-arm group, the deviation of puncture and the diffusion of bone cement at 1 day after operation, the midline vertebral height and Cobb angle at 1 month after operation and last follow-up were significantly better in robot group (P<0.05). Eight cases (9.1%) in the robot group and 16 cases (23.5%) in the C-arm group had cement leakage, and the incidence of cement leakage in the robot group was significantly lower than that in the C-arm group (χ²=5.993, P=0.014). There was no intraspinal leakage in the two groups. Conclusion Compared with traditional PKP assisted by C-arm X-ray fluoroscopy, modified orthopedic robot-assisted PKP in the treatment of single-segment OVCF can significantly reduce intraoperative pain, shorten the establishment time of working channel, and improve the satisfaction of patients with operation. It has great advantages in reducing the deviation of puncture and improving the diffusion of bone cement.

Citation： LIN Shu, TAN Ke, HU Jiang, WAN Lun, WANG Yue. Effectiveness of modified orthopedic robot-assisted percutaneous kyphoplasty in treatment of osteoporotic vertebral compression fracture. Chinese Journal of Reparative and Reconstructive Surgery, 2022, 36(9): 1119-1125. doi: 10.7507/1002-1892.202204013 Copy

1.	劉博, 谷元, 王鵬, 等. 椎體后凸成形術治療580例老年性骨質疏松性椎體壓縮性骨折療效的影響因素分析. 中國骨質疏松雜志, 2019, 25(10): 1469-1473.
2.	Wang B, Zhao CP, Song LX, et al. Balloon kyphoplasty versus percutaneous vertebroplasty for osteoporotic vertebral compression fracture: a meta-analysis and systematic review. J Orthop Surg Res, 2018, 13(1): 264. doi: 10.3389/fcell.2020.00694.
3.	Patel N, Jacobs D, John J, et al. Balloon kyphoplasty vs vertebroplasty: a systematic review of height restoration in osteoporotic vertebral compression fractures. J Pain Res, 2022, 15: 1233-1245.
4.	Khairallah A. Descemet stripping automated endothelialkeratoplasty (DSAEK) versus repeat penetrating keratoplasty (PKP) to manage eyes with failed corneal graft. Ann Saudi Med, 2018, 38(1): 36-41.
5.	Wang B, Cao J, Chang J, et al. Effectiveness of Tirobot-assisted vertebroplasty in treating thoracolumbar osteoporotic compression fracture. J Orthop Surg Res, 2021, 16(1): 65. doi: 10.1186/s13018-021-02211-0.
6.	林書, 胡豇, 萬侖, 等. 機器人輔助經皮椎體后凸成形術治療多節段骨質疏松性椎體壓縮性骨折. 中國修復重建外科雜志, 2020, 34(9): 1136-1141.
7.	袁偉, 孟小童, 劉欣春, 等. 機器人輔助經皮椎體后凸成形術治療單/雙節段骨質疏松性椎體壓縮骨折臨床療效. 中國修復重建外科雜志, 2021, 35(8): 1000-1006.
8.	Genant HK, Wu CY, van Kuijk C, et al. Vertebral fracture assessment using a semiquantitative technique. J Bone Miner Res, 1993, 8(9): 1137-1148.
9.	Gertzbein SD, Robbins SE. Accuracy of pedicular screw placement in vivo. Spine (Phila Pa 1976), 1990, 15(1): 11-14.
10.	Huang M, Tetreault TA, Vaishnav A, et al. The current state of navigation in robotic spine surgery. Ann Transl Med, 2021, 9(1): 86. doi: 10.21037/atm-2020-ioi-07.
11.	鄭筱亭, 王濱城, 呂碧濤, 等. 經皮椎體成形術治療骨質疏松性椎體壓縮性骨折術中采用椎旁神經阻滯的鎮痛效果. 脊柱外科雜志, 2021, 19(6): 377-381.
12.	陳亦豪, 徐仲煌, 張嬌, 等. 經皮椎體強化聯合局部神經阻滯治療椎體壓縮骨折遠處疼痛的效果. 中華骨質疏松和骨礦鹽疾病雜志, 2019, 12(3): 233-239.
13.	Alsalmi S, Capel C, Chenin L, et al. Robot-assisted intravertebral augmentation corrects local kyphosis more effectively than a conventional fluoroscopy-guided technique. J Neurosurg Spine, 2018, 30(2): 289-295.
14.	郭松, 付強, 杭棟華, 等. Mazor脊柱機器人輔助改良經皮椎體成形術治療腰椎骨質疏松性骨折的療效分析. 中國脊柱脊髓雜志, 2021, 31(9): 818-824.
15.	鄭博隆, 郝定均, 林斌, 等. “天璣” 骨科手術機器人輔助與徒手穿刺椎體成形術治療上胸椎骨質疏松性椎體壓縮骨折的療效比較. 中華創傷骨科雜志, 2021, 23(1): 20-26.
16.	王智強, 林路, 陳蕭霖, 等. 經皮椎體強化治療骨質疏松性椎體壓縮性骨折: 導航定位、骨折復位系統、骨水泥滲漏及材料的改良. 中國組織工程研究, 2022, 26(4): 631-636.
17.	Klingler JH, Sircar R, Deininger MH, et al. Vesselplasty: a new minimally invasive approach to treat pathological vertebral fractures in selected tumor patients-preliminary results. Rofo, 2013, 185(4): 340-350.
18.	唐海, 賈璞, 陳浩, 等. 新型Vessel-X經皮椎體強化系統在脊柱微創治療的臨床應用. 中華醫學雜志, 2017, 97(33): 2567-2572.
19.	李凱明, 王尚全, 李玲慧, 等. 囊袋技術與經皮穿刺椎體后凸成形治療胸腰椎骨質疏松性壓縮骨折: 評價改善傷椎術后cobb角及減少骨水泥滲漏的Meta分析. 中國組織工程研究, 2020, 24(4): 650-656.
20.	鐘遠鳴, 萬通, 吳卓檀, 等. 骨質疏松胸腰椎骨折三種椎體增強術網狀薈萃分析. 中國矯形外科雜志, 2021, 29(4): 325-329.
21.	楊柳, 杜建偉. 椎體增強術中降低骨水泥滲漏率的措施. 中國組織工程研究, 2022, 26(22): 3598-3601.
22.	鄭博隆, 郝定均, 閆亮, 等. 自行研發的可彎曲椎體成形器在椎體成形術治療骨質疏松性胸椎壓縮骨折中的應用. 中華創傷骨科雜志, 2019, 21(10): 881-887.
23.	李凡杰, 杜怡斌, 劉藝明, 等. 椎體成形與彎角椎體成形治療骨質疏松性椎體壓縮骨折: 骨水泥注射后分布與滲漏率的比較. 中國組織工程研究, 2020, 24(10): 1484-1490.
24.	Yuan W, Cao W, Meng X, et al. Learning curve of robot-assisted percutaneous kyphoplasty for osteoporotic vertebral compression fractures. World Neurosurg, 2020, 138: e323-e329.
25.	王翔宇, 譚倫, 林旭, 等. 光電導航引導單側穿刺椎體后凸成形術治療胸腰椎骨質疏松性椎體壓縮骨折. 中國修復重建外科雜志, 2018, 32(2): 203-209.
26.	Cui GY, Han XG, Wei Y, et al. Robot-assisted minimally invasive transforaminal lumbar interbody fusion in the treatment of lumbar spondylolisthesis. Orthop Surg, 2021, 13(7): 1960-1968.
27.	Zhang Q, Xu YF, Tian W, 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): 850-856.
28.	林書, 胡豇, 萬侖, 等. 機器人與透視輔助經皮椎弓根螺釘置入的比較. 中國矯形外科雜志, 2020, 28(20): 1830-1834.
29.	袁偉, 孟小童, 劉欣春, 等. 骨科機器人輔助椎體后凸成形術治療骨質疏松性椎體壓縮性骨折的學習曲線. 中華創傷骨科雜志, 2019, 21(8): 670-675.
30.	Malham GM, Wells-Quinn T. What should my hospital buy next?-Guidelines for the acquisition and application of imaging, navigation, and robotics for spine surgery. J Spine Surg, 2019, 5(1): 155-165.
31.	Keric N, Eum DJ, Afghanyar F, et al. Evaluation of surgical strategy of conventional vs. percutaneous robot-assisted spinal trans-pedicular instrumentation in spondylodiscitis. J Robot Surg, 2017, 11(1): 17-25.
32.	Laudato PA, Pierzchala K, Schizas C. Pedicle screw insertion accuracy using o-arm, robotic guidance, or freehand technique: A comparative study. Spine (Phila Pa 1976), 2018, 43(6): E373-E378.

1. 劉博, 谷元, 王鵬, 等. 椎體后凸成形術治療580例老年性骨質疏松性椎體壓縮性骨折療效的影響因素分析. 中國骨質疏松雜志, 2019, 25(10): 1469-1473.
2. Wang B, Zhao CP, Song LX, et al. Balloon kyphoplasty versus percutaneous vertebroplasty for osteoporotic vertebral compression fracture: a meta-analysis and systematic review. J Orthop Surg Res, 2018, 13(1): 264. doi: 10.3389/fcell.2020.00694.
3. Patel N, Jacobs D, John J, et al. Balloon kyphoplasty vs vertebroplasty: a systematic review of height restoration in osteoporotic vertebral compression fractures. J Pain Res, 2022, 15: 1233-1245.
4. Khairallah A. Descemet stripping automated endothelialkeratoplasty (DSAEK) versus repeat penetrating keratoplasty (PKP) to manage eyes with failed corneal graft. Ann Saudi Med, 2018, 38(1): 36-41.
5. Wang B, Cao J, Chang J, et al. Effectiveness of Tirobot-assisted vertebroplasty in treating thoracolumbar osteoporotic compression fracture. J Orthop Surg Res, 2021, 16(1): 65. doi: 10.1186/s13018-021-02211-0.
6. 林書, 胡豇, 萬侖, 等. 機器人輔助經皮椎體后凸成形術治療多節段骨質疏松性椎體壓縮性骨折. 中國修復重建外科雜志, 2020, 34(9): 1136-1141.
7. 袁偉, 孟小童, 劉欣春, 等. 機器人輔助經皮椎體后凸成形術治療單/雙節段骨質疏松性椎體壓縮骨折臨床療效. 中國修復重建外科雜志, 2021, 35(8): 1000-1006.
8. Genant HK, Wu CY, van Kuijk C, et al. Vertebral fracture assessment using a semiquantitative technique. J Bone Miner Res, 1993, 8(9): 1137-1148.
9. Gertzbein SD, Robbins SE. Accuracy of pedicular screw placement in vivo. Spine (Phila Pa 1976), 1990, 15(1): 11-14.
10. Huang M, Tetreault TA, Vaishnav A, et al. The current state of navigation in robotic spine surgery. Ann Transl Med, 2021, 9(1): 86. doi: 10.21037/atm-2020-ioi-07.
11. 鄭筱亭, 王濱城, 呂碧濤, 等. 經皮椎體成形術治療骨質疏松性椎體壓縮性骨折術中采用椎旁神經阻滯的鎮痛效果. 脊柱外科雜志, 2021, 19(6): 377-381.
12. 陳亦豪, 徐仲煌, 張嬌, 等. 經皮椎體強化聯合局部神經阻滯治療椎體壓縮骨折遠處疼痛的效果. 中華骨質疏松和骨礦鹽疾病雜志, 2019, 12(3): 233-239.
13. Alsalmi S, Capel C, Chenin L, et al. Robot-assisted intravertebral augmentation corrects local kyphosis more effectively than a conventional fluoroscopy-guided technique. J Neurosurg Spine, 2018, 30(2): 289-295.
14. 郭松, 付強, 杭棟華, 等. Mazor脊柱機器人輔助改良經皮椎體成形術治療腰椎骨質疏松性骨折的療效分析. 中國脊柱脊髓雜志, 2021, 31(9): 818-824.
15. 鄭博隆, 郝定均, 林斌, 等. “天璣” 骨科手術機器人輔助與徒手穿刺椎體成形術治療上胸椎骨質疏松性椎體壓縮骨折的療效比較. 中華創傷骨科雜志, 2021, 23(1): 20-26.
16. 王智強, 林路, 陳蕭霖, 等. 經皮椎體強化治療骨質疏松性椎體壓縮性骨折: 導航定位、骨折復位系統、骨水泥滲漏及材料的改良. 中國組織工程研究, 2022, 26(4): 631-636.
17. Klingler JH, Sircar R, Deininger MH, et al. Vesselplasty: a new minimally invasive approach to treat pathological vertebral fractures in selected tumor patients-preliminary results. Rofo, 2013, 185(4): 340-350.
18. 唐海, 賈璞, 陳浩, 等. 新型Vessel-X經皮椎體強化系統在脊柱微創治療的臨床應用. 中華醫學雜志, 2017, 97(33): 2567-2572.
19. 李凱明, 王尚全, 李玲慧, 等. 囊袋技術與經皮穿刺椎體后凸成形治療胸腰椎骨質疏松性壓縮骨折: 評價改善傷椎術后cobb角及減少骨水泥滲漏的Meta分析. 中國組織工程研究, 2020, 24(4): 650-656.
20. 鐘遠鳴, 萬通, 吳卓檀, 等. 骨質疏松胸腰椎骨折三種椎體增強術網狀薈萃分析. 中國矯形外科雜志, 2021, 29(4): 325-329.
21. 楊柳, 杜建偉. 椎體增強術中降低骨水泥滲漏率的措施. 中國組織工程研究, 2022, 26(22): 3598-3601.
22. 鄭博隆, 郝定均, 閆亮, 等. 自行研發的可彎曲椎體成形器在椎體成形術治療骨質疏松性胸椎壓縮骨折中的應用. 中華創傷骨科雜志, 2019, 21(10): 881-887.
23. 李凡杰, 杜怡斌, 劉藝明, 等. 椎體成形與彎角椎體成形治療骨質疏松性椎體壓縮骨折: 骨水泥注射后分布與滲漏率的比較. 中國組織工程研究, 2020, 24(10): 1484-1490.
24. Yuan W, Cao W, Meng X, et al. Learning curve of robot-assisted percutaneous kyphoplasty for osteoporotic vertebral compression fractures. World Neurosurg, 2020, 138: e323-e329.
25. 王翔宇, 譚倫, 林旭, 等. 光電導航引導單側穿刺椎體后凸成形術治療胸腰椎骨質疏松性椎體壓縮骨折. 中國修復重建外科雜志, 2018, 32(2): 203-209.
26. Cui GY, Han XG, Wei Y, et al. Robot-assisted minimally invasive transforaminal lumbar interbody fusion in the treatment of lumbar spondylolisthesis. Orthop Surg, 2021, 13(7): 1960-1968.
27. Zhang Q, Xu YF, Tian W, 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): 850-856.
28. 林書, 胡豇, 萬侖, 等. 機器人與透視輔助經皮椎弓根螺釘置入的比較. 中國矯形外科雜志, 2020, 28(20): 1830-1834.
29. 袁偉, 孟小童, 劉欣春, 等. 骨科機器人輔助椎體后凸成形術治療骨質疏松性椎體壓縮性骨折的學習曲線. 中華創傷骨科雜志, 2019, 21(8): 670-675.
30. Malham GM, Wells-Quinn T. What should my hospital buy next?-Guidelines for the acquisition and application of imaging, navigation, and robotics for spine surgery. J Spine Surg, 2019, 5(1): 155-165.
31. Keric N, Eum DJ, Afghanyar F, et al. Evaluation of surgical strategy of conventional vs. percutaneous robot-assisted spinal trans-pedicular instrumentation in spondylodiscitis. J Robot Surg, 2017, 11(1): 17-25.
32. Laudato PA, Pierzchala K, Schizas C. Pedicle screw insertion accuracy using o-arm, robotic guidance, or freehand technique: A comparative study. Spine (Phila Pa 1976), 2018, 43(6): E373-E378.

Chinese Journal of Reparative and Reconstructive Surgery

Effectiveness of modified orthopedic robot-assisted percutaneous kyphoplasty in treatment of osteoporotic vertebral compression fracture

Abstract Full text Figures/Tables Video References Cited by

Previous Article

Next Article

Format

Content