Short-term effectiveness of Mako robot-assisted total hip arthroplasty via posterolateral approach_Chinese Journal of Reparative and Reconstructive Surgery

Authors：

Wuhuzi·Wulamu , ZHANG Xiaogang , Nuerailijiang·Yushan , JI Bachao ,  CAO Li

Department of Joint Surgery, First Affiliated Hospital of Xinjiang Medical University, Urumqi Xinjiang, 830054, P.R.China;

Corresponding author：

CAO Li, Email: xjbone@sina.com

Keywords：

Robot assisted total hip arthroplasty; Mako robot; posterolateral approach; accuracy; safety

DOI：

10.7507/1002-1892.202105120

Video：

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Objective To explore the short-term effectiveness of Mako robot-assisted total hip arthroplasty (THA) via posterolateral approach.Methods The clinical data of 64 patients (74 hips) treated with Mako robot-assisted THA via posterolateral approach (robot group) between May 2020 and March 2021 were retrospectively analyzed and compared with the clinical data of 52 patients (55 hips) treated with traditional THA via posterolateral approach (control group) in the same period. There was no significant difference in general data such as gender, age, side, body mass index, disease type, and preoperative Harris score between the two groups (P>0.05). The operation time, intraoperative blood loss, and complications were recorded and compared between the two groups. Acetabular inclination angle, acetabular anteversion angle, and lower limbs discrepancy were measured after operation. At last follow-up, the improvement of hip pain and function was evaluated by visual analogue scale (VAS) score, Harris score, and forgetting joint score (FJS-12).Results In the robot group, 3 patients (including 1 patient with acetabular fracture during operation) were converted to routine THA because the pelvic data array placed at the anterior superior iliac spine was loose, resulting in data error and unable to register the acetabulum; the other patients in the two groups completed the operation successfully. The operation time and intraoperative blood loss in the robot group were significantly higher than those in the control group (P<0.05). All patients were followed up 1-10 months, with an average of 4.6 months. In the robot group, 1 patient with ankylosing spondylitis had acetabular prosthesis loosening at 2 days after operation, underwent surgical revision, and 10 patients had lower limb intermuscular vein thrombosis; in the control group, 1 patient had left hip dislocation and 5 patients had lower extremity intermuscular vein thrombosis; there was no complication such as sciatic nerve injury, incision exudation, and periprosthetic infection in both groups. There was no significant difference in the incidence of complications between the robot group and the control group (17.2% vs.11.5%) (χ²=0.732, P=0.392). At last follow-up, the acetabular anteversion angle and FJS-12 score in the robot group were was significantly greater than those in the control group, and the lower limbs discrepancy was significantly less than that in the control group (P<0.05); there was no significant difference in acetabular inclination angle and VAS score between the two groups (P>0.05). The Harris scores of the two groups were significantly improved when compared with those before operation (P<0.05), but there was no significant difference in the difference of pre- and post-operative score between the two groups (t=1.632, P=0.119).Conclusion Compared with traditional surgery, Mako robot-assisted THA can optimize the accuracy and safety of acetabular cup implantation, reduce the length difference of the lower limbs, and has a certain learning curve. Its long-term effectiveness needs further research to confirm.

Citation： Wuhuzi·Wulamu, ZHANG Xiaogang, Nuerailijiang·Yushan, JI Bachao, CAO Li. Short-term effectiveness of Mako robot-assisted total hip arthroplasty via posterolateral approach. Chinese Journal of Reparative and Reconstructive Surgery, 2021, 35(10): 1227-1232. doi: 10.7507/1002-1892.202105120 Copy

1.	Conner-Spady BL, Bohm E, Loucks L, et al. Patient expectations and satisfaction 6 and 12 months following total hip and knee replacement. Qual Life Res, 2020, 29(3): 705-719.
2.	Moskal JT, Capps SG. Improving the accuracy of acetabular component orientation: avoiding malposition. J Am Acad Orthop Surg, 2010, 18(5): 286-296.
3.	Domb BG, El Bitar YF, Sadik AY, et al. Comparison of robotic-assisted and conventional acetabular cup placement in THA: a matched-pair controlled study. Clin Orthop Relat Res, 2014, 472(1): 329-336.
4.	Nawabi DH, Conditt MA, Ranawat AS, et al. Haptically guided robotic technology in total hip arthroplasty: a cadaveric investigation. Proc Inst Mech Eng H, 2013, 227(3): 302-309.
5.	郭人文, 柴伟, 李想, 等. 机器人辅助在股骨头坏死全髋关节置换术中的应用. 中华骨科杂志, 2020, 40(13): 819-827.
6.	Lewinnek GE, Lewis JL, Tarr R, et al. Dislocations after total hip-replacement arthroplasties. J Bone Joint Surg (Am), 1978, 60(2): 217-220.
7.	Ranawat CS, Rodriguez JA. Functional leg-length inequality following total hip arthroplasty. J Arthroplasty, 1997, 12(4): 359-364.
8.	Ranawat CS, Rao RR, Rodriguez JA, et al. Correction of limb-length inequality during total hip arthroplasty. J Arthroplasty, 2001, 16(6): 715-720.
9.	Behrend H, Giesinger K, Giesinger JM, et al. The “forgotten joint” as the ultimate goal in joint arthroplasty: validation of a new patient-reported outcome measure. J Arthroplasty, 2012, 27(3): 430-436.
10.	Pivec R, Johnson AJ, Mears SC, et al. Hip arthroplasty. Lancet, 2012, 380(9855): 1768-1777.
11.	Kurtz S, Ong K, Lau E, et al. Projections of primary and revision hip and knee arthroplasty in the United States from 2005 to 2030. J Bone Joint Surg (Am), 2007, 89(4): 780-785.
12.	Mancuso CA, Salvati EA. Patients’ satisfaction with the process of total hip arthroplasty. J Healthc Qual, 2003, 25(2): 12-18.
13.	Katz JN, Wright EA, Wright J, et al. Twelve-year risk of revision after primary total hip replacement in the U.S. Medicare population. J Bone Joint Surg (Am), 2012, 94(20): 1825-1832.
14.	Biedermann R, Tonin A, Krismer M, et al. Reducing the risk of dislocation after total hip arthroplasty: the effect of orientation of the acetabular component. J Bone Joint Surg (Br), 2005, 87(6): 762-769.
15.	Callanan MC, Jarrett B, Bragdon CR, et al. The John Charnley Award: risk factors for cup malpositioning: quality improvement through a joint registry at a tertiary hospital. Clin Orthop Relat Res, 2011, 469(2): 319-329.
16.	Kennedy JG, Rogers WB, Soffe KE, et al. Effect of acetabular component orientation on recurrent dislocation, pelvic osteolysis, polyethylene wear, and component migration. J Arthroplasty, 1998, 13(5): 530-534.
17.	Ng VY, Kean JR, Glassman AH. Limb-length discrepancy after hip arthroplasty. J Bone Joint Surg (Am), 2013, 95(15): 1426-1436.
18.	Konyves A, Bannister GC. The importance of leg length discrepancy after total hip arthroplasty. J Bone Joint Surg (Br), 2005, 87(2): 155-157.
19.	Elson L, Dounchis J, Illgen R, et al. Precision of acetabular cup placement in robotic integrated total hip arthroplasty. Hip Int, 2015, 25(6): 531-536.
20.	侯毅, 刘珂, 高宗炎, 等. 主动机器人系统在人工全髋关节置换术中的应用. 中华关节外科杂志 (电子版), 2017, 11(6): 641-645.
21.	Banerjee S, Cherian JJ, Elmallah RK, et al. Robot-assisted total hip arthroplasty. Expert Rev Med Devices, 2016, 13(1): 47-56.
22.	Chen X, Xiong J, Wang P, et al. Robotic-assisted compared with conventional total hip arthroplasty: systematic review and meta-analysis. Postgrad Med J, 2018, 94(1112): 335-341.
23.	Kayani B, Konan S, Ayuob A, et al. Robotic technology in total knee arthroplasty: a systematic review. EFORT Open Rev, 2019, 4(10): 611-617.
24.	Kamara E, Robinson J, Bas MA, et al. Adoption of robotic vs fluoroscopic guidance in total hip arthroplasty: Is acetabular positioning improved in the learning curve? J Arthroplasty, 2017, 32(1): 125-130.
25.	崔可赜, 郭祥, 陈元良, 等. 后外侧入路人工全髋关节置换术中MAKO机器人手臂辅助与传统人工方法的比较研究. 中国修复重建外科杂志, 2020, 34(7): 883-888.
26.	郭人文, 孔祥朋, 宋平, 等. CroweⅣ型髋关节发育不良的机器人辅助全髋关节置换术两例报告. 骨科, 2021, 12(2): 180-182.

1. Conner-Spady BL, Bohm E, Loucks L, et al. Patient expectations and satisfaction 6 and 12 months following total hip and knee replacement. Qual Life Res, 2020, 29(3): 705-719.
2. Moskal JT, Capps SG. Improving the accuracy of acetabular component orientation: avoiding malposition. J Am Acad Orthop Surg, 2010, 18(5): 286-296.
3. Domb BG, El Bitar YF, Sadik AY, et al. Comparison of robotic-assisted and conventional acetabular cup placement in THA: a matched-pair controlled study. Clin Orthop Relat Res, 2014, 472(1): 329-336.
4. Nawabi DH, Conditt MA, Ranawat AS, et al. Haptically guided robotic technology in total hip arthroplasty: a cadaveric investigation. Proc Inst Mech Eng H, 2013, 227(3): 302-309.
5. 郭人文, 柴伟, 李想, 等. 机器人辅助在股骨头坏死全髋关节置换术中的应用. 中华骨科杂志, 2020, 40(13): 819-827.
6. Lewinnek GE, Lewis JL, Tarr R, et al. Dislocations after total hip-replacement arthroplasties. J Bone Joint Surg (Am), 1978, 60(2): 217-220.
7. Ranawat CS, Rodriguez JA. Functional leg-length inequality following total hip arthroplasty. J Arthroplasty, 1997, 12(4): 359-364.
8. Ranawat CS, Rao RR, Rodriguez JA, et al. Correction of limb-length inequality during total hip arthroplasty. J Arthroplasty, 2001, 16(6): 715-720.
9. Behrend H, Giesinger K, Giesinger JM, et al. The “forgotten joint” as the ultimate goal in joint arthroplasty: validation of a new patient-reported outcome measure. J Arthroplasty, 2012, 27(3): 430-436.
10. Pivec R, Johnson AJ, Mears SC, et al. Hip arthroplasty. Lancet, 2012, 380(9855): 1768-1777.
11. Kurtz S, Ong K, Lau E, et al. Projections of primary and revision hip and knee arthroplasty in the United States from 2005 to 2030. J Bone Joint Surg (Am), 2007, 89(4): 780-785.
12. Mancuso CA, Salvati EA. Patients’ satisfaction with the process of total hip arthroplasty. J Healthc Qual, 2003, 25(2): 12-18.
13. Katz JN, Wright EA, Wright J, et al. Twelve-year risk of revision after primary total hip replacement in the U.S. Medicare population. J Bone Joint Surg (Am), 2012, 94(20): 1825-1832.
14. Biedermann R, Tonin A, Krismer M, et al. Reducing the risk of dislocation after total hip arthroplasty: the effect of orientation of the acetabular component. J Bone Joint Surg (Br), 2005, 87(6): 762-769.
15. Callanan MC, Jarrett B, Bragdon CR, et al. The John Charnley Award: risk factors for cup malpositioning: quality improvement through a joint registry at a tertiary hospital. Clin Orthop Relat Res, 2011, 469(2): 319-329.
16. Kennedy JG, Rogers WB, Soffe KE, et al. Effect of acetabular component orientation on recurrent dislocation, pelvic osteolysis, polyethylene wear, and component migration. J Arthroplasty, 1998, 13(5): 530-534.
17. Ng VY, Kean JR, Glassman AH. Limb-length discrepancy after hip arthroplasty. J Bone Joint Surg (Am), 2013, 95(15): 1426-1436.
18. Konyves A, Bannister GC. The importance of leg length discrepancy after total hip arthroplasty. J Bone Joint Surg (Br), 2005, 87(2): 155-157.
19. Elson L, Dounchis J, Illgen R, et al. Precision of acetabular cup placement in robotic integrated total hip arthroplasty. Hip Int, 2015, 25(6): 531-536.
20. 侯毅, 刘珂, 高宗炎, 等. 主动机器人系统在人工全髋关节置换术中的应用. 中华关节外科杂志 (电子版), 2017, 11(6): 641-645.
21. Banerjee S, Cherian JJ, Elmallah RK, et al. Robot-assisted total hip arthroplasty. Expert Rev Med Devices, 2016, 13(1): 47-56.
22. Chen X, Xiong J, Wang P, et al. Robotic-assisted compared with conventional total hip arthroplasty: systematic review and meta-analysis. Postgrad Med J, 2018, 94(1112): 335-341.
23. Kayani B, Konan S, Ayuob A, et al. Robotic technology in total knee arthroplasty: a systematic review. EFORT Open Rev, 2019, 4(10): 611-617.
24. Kamara E, Robinson J, Bas MA, et al. Adoption of robotic vs fluoroscopic guidance in total hip arthroplasty: Is acetabular positioning improved in the learning curve? J Arthroplasty, 2017, 32(1): 125-130.
25. 崔可赜, 郭祥, 陈元良, 等. 后外侧入路人工全髋关节置换术中MAKO机器人手臂辅助与传统人工方法的比较研究. 中国修复重建外科杂志, 2020, 34(7): 883-888.
26. 郭人文, 孔祥朋, 宋平, 等. CroweⅣ型髋关节发育不良的机器人辅助全髋关节置换术两例报告. 骨科, 2021, 12(2): 180-182.

Chinese Journal of Reparative and Reconstructive Surgery

Short-term effectiveness of Mako robot-assisted total hip arthroplasty via posterolateral approach

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