Value of virtual reality technology in preoperative planning of transtrochanteric curved varus osteotomy for avascular necrosis of femoral head in adults_Chinese Journal of Reparative and Reconstructive Surgery

Authors：

SHI Le , FAN Yanxin , ZHANG Chao ,  SHEN Jirong

Department of Traumatology & Orthopedics, Affiliated Hospital of Nanjing University of Chinese Medicine, Nanjing Jiangsu, 210029, P.R.China;

Corresponding author：

SHEN Jirong, Email: shenjirongjoint@126.com

Keywords：

Virtual reality technology; avascular necrosis of the femoral head; osteotomy; preoperative planning

DOI：

10.7507/1002-1892.201903083

Video：

Export PDF Favorites Scan Get Citation

Abstract Full text Figures/Tables Video References Cited by

Objective To research the value of virtual reality (VR) technology in the preoperative planning of transtrochanteric curved varus osteotomy for avascular necrosis of the femoral head (ANFH) in adults.Methods Between June 2018 and November 2018, 7 patients (11 hips) with ANFH, who were treated with transtrochanteric curved varus osteotomy, were enrolled in the study. There were 4 males (7 hips) and 3 females (4 hips) with an average age of 31.9 years (range, 14-46 years). Among them, 3 patients were unilateral ANFH and 4 patients were bilateral ANFH. There was 1 patient (1 hip) of traumatic ANFH, 2 patients (4 hips) of alcohol-induced ANFH, 2 patients (3 hips) of hormonal ANFH, and 2 patients (3 hips) of idiopathic ANFH. All hips were Association Research Circulation Osseous (ARCO) stage Ⅲ. There were 5 hips for Japanese Investigation Committee (JIC) type C1 and 6 hips for type C2. There were 5 hips for China-Japan Friendship Hospital (CJFH) type L1,1 for type L2, and 5 for type L3. The disease duration ranged from 5 to 12 months (mean, 8 months). Preoperative Harris score was 53.91±7.66. The neck-shaft angle ranged from 128 to 143° (mean, 133.9°). VR technology was adopted for the preoperative planning. CT data were imported into the software to construct the morphology of necrotic area, and the transrtrochanteric varus osteotomy was simulated. The varus angle was designed according to the integrity rate of femoral head. The planned varus angle was 6 to 16° (mean, 9.7°). The transtrochanteric curved varus osteotomy was performed according to the preoperative planning, and the varus angle and loading area were confirmed under fluoroscopy. If the planned varus angle was too small, it would continue to increase under the fluoroscopy until a satisfactory varus angle. Postoperative changes of the neck-shaft angle were calculated and compared with the preoperative planned varus angle (error). The hip function was assessed by using the Harris score.Results All incisions healed by first intention. All patients were followed up 6-11 months with an average of 8 months. The X-ray film at 2 days after operation showed that the neck-shaft angle was 112-135° (mean, 123.4°). The difference of the neck-shaft angle between pre- and post-operation was 6-16° (mean, 11.0°). Among them, the difference of the neck-shaft angle was consistent with planned varus angle in 5 hips, while the error of the remaining 6 hips was 1-4°. There was 1 patient (1 hip) of osteotomy nonunion at 4 months after operation, 1 patient (1 hip) of proximal femur fracture at 2 months after operation. The rest 5 patients (9 hips) obtained union at the osteotomy. At last follow-up, the Harris score was 82.18±16.35, showing significant difference when compared with preoperative score (t=–5.195, P=0.000).Conclusion VR technology is a brand-new preoperative planning method for transtrochanteric curved varus osteotomy in treating ANFH.

Citation： SHI Le, FAN Yanxin, ZHANG Chao, SHEN Jirong. Value of virtual reality technology in preoperative planning of transtrochanteric curved varus osteotomy for avascular necrosis of femoral head in adults. Chinese Journal of Reparative and Reconstructive Surgery, 2019, 33(8): 923-928. doi: 10.7507/1002-1892.201903083 Copy

1.	赵德伟, 谢辉. 成人股骨头坏死保髋手术治疗的策略及探讨. 中国修复重建外科杂志, 2018, 32(7): 792-797.
2.	Ito H, Kaneda K, Matsuno T. Osteonecrosis of the femoral head. Simple varus intertrochanteric osteotomy. J Bone Joint Surg (Br), 1999, 81(6): 969-974.
3.	Mont MA, Fairbank AC, Krackow KA, et al. Corrective osteotomy for osteonecrosis of the femoral head. J Bone Joint Surg (Am), 1996, 78(7): 1032-1038.
4.	Pavlovcic V, Dolinar D. Intertrochanteric osteotomy for osteonecrosis of the femoral head. Int Orthop, 2002, 26(4): 238-242.
5.	夏天卫, 魏伟, 刘金柱, 等. 经外科脱位入路打压植骨术与旋转截骨术治疗 ARCO Ⅲ期股骨头缺血性坏死疗效比较. 中国修复重建外科杂志, 2019, 33(4): 445-450.
6.	郑潮顺, 李春海. 虚拟现实技术在骨科术前规划中的应用. 中国骨科临床与基础研究杂志, 2017, 9(5): 310-315.
7.	Bekelis K, Calnan D, Simmons N, et al. Effect of an immersive preoperative virtual reality experience on patient reported outcomes: A randomized controlled trial. Ann Surg, 2017, 265(6): 1068-1073.
8.	Koo KH, Mont MA, Jones LC. 骨坏死. 李子荣, 孙伟, 主译. 北京: 人民军医出版社, 2015: 295-299.
9.	Hamanishi M, Yasunaga Y, Yamasaki T, et al. The clinical and radiographic results of intertrochanteric curved varus osteotomy for idiopathic osteonecrosis of the femoral head. Arch Orthop Trauma Surg, 2014, 134(3): 305-310.
10.	Okura T, Hasegawa Y, Morita D, et al. What factors predict the failure of curved intertrochanteric varus osteotomy for the osteonecrosis of the femoral head? Arch Orthop Trauma Surg, 2016, 136(12): 1647-1655.
11.	Takao M, Sakai T, Hamada H, et al. Error range in proximal femoral osteotomy using computer tomography-based navigation. Int J Comput Assist Radiol Surg, 2017, 12(12): 2087-2096.
12.	孟颖, 洪如. 虚拟现实技术在骨科手术导航系统中的应用. 装备制造技术, 2010, (5): 104-105.
13.	Lee SC, Fuerst B, Tateno K, et al. Multi-modal imaging, model-based tracking, and mixed reality visualisation for orthopaedic surgery. Healthc Technol Lett, 2017, 4(5): 168-173.
14.	Mavrogenis AF, Savvidou OD, Mimidis G, et al. Computer-assisted navigation in orthopedic surgery. Orthopedics, 2013, 36(8): 631-642.
15.	Fritz J, U-Thainual P, Ungi T, et al. Augmented reality visualization with use of image overlay technology for MR imaging-guided interventions: assessment of performance in cadaveric shoulder and hip arthrography at 1. 5 T. Radiology, 2012, 265(1): 254-259.
16.	Elmi-Terander A, Skulason H, Söderman M, et al. Surgical navigation technology based on augmented reality and integrated 3D intraoperative imaging: A spine cadaveric feasibility and accuracy study. Spine, 2016, 41(21): E1303-E1311.
17.	Abe Y, Sato S, Kato K, et al. A novel 3D guidance system using augmented reality for percutaneous vertebroplasty: technical note. J Neurosurg Spine, 2013, 19(4): 492-501.

1. 赵德伟, 谢辉. 成人股骨头坏死保髋手术治疗的策略及探讨. 中国修复重建外科杂志, 2018, 32(7): 792-797.
2. Ito H, Kaneda K, Matsuno T. Osteonecrosis of the femoral head. Simple varus intertrochanteric osteotomy. J Bone Joint Surg (Br), 1999, 81(6): 969-974.
3. Mont MA, Fairbank AC, Krackow KA, et al. Corrective osteotomy for osteonecrosis of the femoral head. J Bone Joint Surg (Am), 1996, 78(7): 1032-1038.
4. Pavlovcic V, Dolinar D. Intertrochanteric osteotomy for osteonecrosis of the femoral head. Int Orthop, 2002, 26(4): 238-242.
5. 夏天卫, 魏伟, 刘金柱, 等. 经外科脱位入路打压植骨术与旋转截骨术治疗 ARCO Ⅲ期股骨头缺血性坏死疗效比较. 中国修复重建外科杂志, 2019, 33(4): 445-450.
6. 郑潮顺, 李春海. 虚拟现实技术在骨科术前规划中的应用. 中国骨科临床与基础研究杂志, 2017, 9(5): 310-315.
7. Bekelis K, Calnan D, Simmons N, et al. Effect of an immersive preoperative virtual reality experience on patient reported outcomes: A randomized controlled trial. Ann Surg, 2017, 265(6): 1068-1073.
8. Koo KH, Mont MA, Jones LC. 骨坏死. 李子荣, 孙伟, 主译. 北京: 人民军医出版社, 2015: 295-299.
9. Hamanishi M, Yasunaga Y, Yamasaki T, et al. The clinical and radiographic results of intertrochanteric curved varus osteotomy for idiopathic osteonecrosis of the femoral head. Arch Orthop Trauma Surg, 2014, 134(3): 305-310.
10. Okura T, Hasegawa Y, Morita D, et al. What factors predict the failure of curved intertrochanteric varus osteotomy for the osteonecrosis of the femoral head? Arch Orthop Trauma Surg, 2016, 136(12): 1647-1655.
11. Takao M, Sakai T, Hamada H, et al. Error range in proximal femoral osteotomy using computer tomography-based navigation. Int J Comput Assist Radiol Surg, 2017, 12(12): 2087-2096.
12. 孟颖, 洪如. 虚拟现实技术在骨科手术导航系统中的应用. 装备制造技术, 2010, (5): 104-105.
13. Lee SC, Fuerst B, Tateno K, et al. Multi-modal imaging, model-based tracking, and mixed reality visualisation for orthopaedic surgery. Healthc Technol Lett, 2017, 4(5): 168-173.
14. Mavrogenis AF, Savvidou OD, Mimidis G, et al. Computer-assisted navigation in orthopedic surgery. Orthopedics, 2013, 36(8): 631-642.
15. Fritz J, U-Thainual P, Ungi T, et al. Augmented reality visualization with use of image overlay technology for MR imaging-guided interventions: assessment of performance in cadaveric shoulder and hip arthrography at 1. 5 T. Radiology, 2012, 265(1): 254-259.
16. Elmi-Terander A, Skulason H, Söderman M, et al. Surgical navigation technology based on augmented reality and integrated 3D intraoperative imaging: A spine cadaveric feasibility and accuracy study. Spine, 2016, 41(21): E1303-E1311.
17. Abe Y, Sato S, Kato K, et al. A novel 3D guidance system using augmented reality for percutaneous vertebroplasty: technical note. J Neurosurg Spine, 2013, 19(4): 492-501.

Chinese Journal of Reparative and Reconstructive Surgery

Value of virtual reality technology in preoperative planning of transtrochanteric curved varus osteotomy for avascular necrosis of femoral head in adults

Abstract Full text Figures/Tables Video References Cited by

Previous Article

Next Article

Format

Content