Application of augmented reality technique in repairing soft tissue defects of lower limbs with posterior tibial artery perforator flap_Chinese Journal of Reparative and Reconstructive Surgery

Authors：

 HE Shaobo , LIU Jichao , LI Wujian , ZHANG Gensheng , ZHENG Jinzhe , HUANG Bin

Department of Hand and Foot Microscopy and Burn Plastic Surgery, 3201 Hospital Affiliated to Xi’an Jiaotong University, Hanzhong Shaanxi, 723000, P. R. China;

Corresponding author：

HE Shaobo, Email: 675052712@qq.com

Keywords：

Augmented reality technique; posterior tibial artery perforator flap; soft tissue defect; wound repair

DOI：

10.7507/1002-1892.202211109

Video：

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Objective To investigate the accuracy and reliability of augmented reality (AR) technique in locating the perforating vessels of the posterior tibial artery during the repair of soft tissue defects of the lower limbs with the posterior tibial artery perforator flap. Methods Between June 2019 and June 2022, the posterior tibial artery perforator flap was used to repair the skin and soft tissue defects around the ankle in 10 cases. There were 7 males and 3 females with an average age of 53.7 years (mean, 33-69 years). The injury was caused by traffic accident in 5 cases, bruising by heavy weight in 4 cases, and machine injury in 1 case. The size of wound ranged from 5 cm×3 cm to 14 cm×7 cm. The interval between injury and operation was 7-24 days (mean, 12.8 days). The CT angiography of lower limbs before operation was performed and the data was used to reconstruct the three-dimensional images of perforating vessels and bones with Mimics software. The above images were projected and superimposed on the surface of the affected limb using AR technology, and the skin flap was designed and resected with precise positioning. The size of the flap ranged from 6 cm×4 cm to 15 cm×8 cm. The donor site was sutured directly or repaired with skin graft. Results The 1-4 perforator branches of posterior tibial artery (mean, 3.4 perforator branches) in 10 patients were located by AR technique before operation. The location of perforator vessels during operation was basically consistent with that of AR before operation. The distance between the two locations ranged from 0 to 16 mm, with an average of 12.2 mm. The flap was successfully harvested and repaired according to the preoperative design. Nine flaps survived without vascular crisis. The local infection of skin graft occurred in 2 cases and the necrosis of the distal edge of the flap in 1 case, which healed after dressing change. The other skin grafts survived, and the incisions healed by first intention. All patients were followed up 6-12 months, with an average of 10.3 months. The flap was soft without obvious scar hyperplasia and contracture. At last follow-up, according to the American Orthopedic Foot and Ankle Association (AOFAS) score, the ankle function was excellent in 8 cases, good in 1 case, and poor in 1 case. Conclusion AR technique can be used to determine the location of perforator vessels in the preoperative planning of the posterior tibial artery perforator flap, which can reduce the risk of flap necrosis, and the operation is simple.

Citation： HE Shaobo, LIU Jichao, LI Wujian, ZHANG Gensheng, ZHENG Jinzhe, HUANG Bin. Application of augmented reality technique in repairing soft tissue defects of lower limbs with posterior tibial artery perforator flap. Chinese Journal of Reparative and Reconstructive Surgery, 2023, 37(2): 185-188. doi: 10.7507/1002-1892.202211109 Copy

1.	刘春, 杨学林, 胡福兴, 等. 三维CT血管造影辅助血管定位设计游离腓动脉穿支皮瓣修复前足背软组织缺损. 中华创伤杂志, 2021, 37(9): 786-792.
2.	石岩, 何晓清, 杨曦, 等. CT血管造影检查结合三维重建辅助设计腓浅动脉穿支皮瓣修复手部创面的疗效. 中华创伤杂志, 2021, 37(6): 501-507.
3.	周征兵, 潘丁, 唐举玉. 穿支皮瓣术前影像学导航研究进展. 中国现代医学杂志, 2020, 30(9): 49-54.
4.	Otake Y. The cutting-edge in virtual reality and augmented reality and its medical application: Introduction. Med Imag Tech, 2019, 37(1): 1-2.
5.	段崇锋, 焦涛, 任孝燕, 等. 胫后动脉内踝上穿支蒂隐神经营养血管逆行岛状皮瓣修复足背及踝部软组织缺损. 实用手外科杂志, 2016, 30(3): 312-313, 315.
6.	莫勇军, 谭海涛, 杨克勤, 等. 增强现实技术辅助实施腓骨皮瓣游离移植修复胫骨及其软组织缺损. 中华显微外科杂志, 2021, 44(1): 24-28.
7.	莫勇军, 许林, 程志琳, 等. 增强现实技术联合数字化设计在股前外侧穿支皮瓣的应用. 中华显微外科杂志, 2019, 42(2): 189-192.
8.	梁旭权, 杨克勤, 罗翔, 等. 增强现实技术联合多普勒超声在胫后动脉穿支皮瓣修复踝周软组织缺损的应用. 中华显微外科杂志, 2021, 44(3): 267-271.
9.	Zhang Y. Discussion. Application of multidetector-row computed tomography in propeller flap planning. Plast Reconstr Surg, 2011, 127(2): 712-715.
10.	张爱民, 方艳伟, 张英泽. 增强现实技术在创伤骨科疾病的应用现状. 中华老年骨科与康复电子杂志, 2017, 3(2): 120-123.
11.	叶哲伟, 吴星火. 混合现实技术在骨科的最新应用进展. 临床外科杂志, 2018, 26(1): 13-14.
12.	苑博, 佟长贵, 梁海东, 等. 虚拟现实/现实增强技术在游离股前外侧动脉穿支皮瓣中的初步应用. 中华创伤杂志, 2018, 34(6): 552-554.
13.	谢国强, 周小卫, 左毅, 等. 基于智能手机的简易增强现实技术对幕上高血压性脑内血肿定位的价值. 中国临床神经外科杂志, 2019, 24(6): 345-347, 351.
14.	宗海洋, 王腾, 李阳, 等. 术前CTA精准定位胫后动脉穿支皮瓣修复手部创面的应用研究. 创伤外科杂志, 2021, 23(9): 697-700.
15.	欧阳容兰, 刘江涛, 连丽娜. 胫后动脉穿支岛状皮瓣修复小腿中下段皮肤缺损的临床效果研究. 中国美容医学, 2022, 31(1): 16-19.
16.	Hifny MA, Tohamy AMA, Rabie O, et al. Propeller perforator flaps for coverage of soft tissue defects in the middle and distal lower extremities. Ann Chir Plast Esthet, 2020, 65(1): 54-60.
17.	谢毅, 张加尧, 叶哲伟. 混合现实技术在创伤骨科的应用与展望. 中华创伤骨科杂志, 2020, 22(11): 1009-1012.
18.	章振逸, 李彬, 丁焕文, 等. 基于增强现实的骨科手术中引导手术导板精确安放方法. 生物医学工程研究, 2021, 40(4): 413-419.
19.	Masia J, Clavero JA, Larrañaga JR, et al. Multidetector-row computed tomography in the planning of abdominal perforator flaps. J Plast Reconstr Aesthet Surg, 2006, 59(6): 594-599.
20.	Kurbad A. The use of ‘extended reality’ (augmented reality) in esthetic treatment planning. Int J Comput Dent, 2020, 23(2): 149-160.

1. 刘春, 杨学林, 胡福兴, 等. 三维CT血管造影辅助血管定位设计游离腓动脉穿支皮瓣修复前足背软组织缺损. 中华创伤杂志, 2021, 37(9): 786-792.
2. 石岩, 何晓清, 杨曦, 等. CT血管造影检查结合三维重建辅助设计腓浅动脉穿支皮瓣修复手部创面的疗效. 中华创伤杂志, 2021, 37(6): 501-507.
3. 周征兵, 潘丁, 唐举玉. 穿支皮瓣术前影像学导航研究进展. 中国现代医学杂志, 2020, 30(9): 49-54.
4. Otake Y. The cutting-edge in virtual reality and augmented reality and its medical application: Introduction. Med Imag Tech, 2019, 37(1): 1-2.
5. 段崇锋, 焦涛, 任孝燕, 等. 胫后动脉内踝上穿支蒂隐神经营养血管逆行岛状皮瓣修复足背及踝部软组织缺损. 实用手外科杂志, 2016, 30(3): 312-313, 315.
6. 莫勇军, 谭海涛, 杨克勤, 等. 增强现实技术辅助实施腓骨皮瓣游离移植修复胫骨及其软组织缺损. 中华显微外科杂志, 2021, 44(1): 24-28.
7. 莫勇军, 许林, 程志琳, 等. 增强现实技术联合数字化设计在股前外侧穿支皮瓣的应用. 中华显微外科杂志, 2019, 42(2): 189-192.
8. 梁旭权, 杨克勤, 罗翔, 等. 增强现实技术联合多普勒超声在胫后动脉穿支皮瓣修复踝周软组织缺损的应用. 中华显微外科杂志, 2021, 44(3): 267-271.
9. Zhang Y. Discussion. Application of multidetector-row computed tomography in propeller flap planning. Plast Reconstr Surg, 2011, 127(2): 712-715.
10. 张爱民, 方艳伟, 张英泽. 增强现实技术在创伤骨科疾病的应用现状. 中华老年骨科与康复电子杂志, 2017, 3(2): 120-123.
11. 叶哲伟, 吴星火. 混合现实技术在骨科的最新应用进展. 临床外科杂志, 2018, 26(1): 13-14.
12. 苑博, 佟长贵, 梁海东, 等. 虚拟现实/现实增强技术在游离股前外侧动脉穿支皮瓣中的初步应用. 中华创伤杂志, 2018, 34(6): 552-554.
13. 谢国强, 周小卫, 左毅, 等. 基于智能手机的简易增强现实技术对幕上高血压性脑内血肿定位的价值. 中国临床神经外科杂志, 2019, 24(6): 345-347, 351.
14. 宗海洋, 王腾, 李阳, 等. 术前CTA精准定位胫后动脉穿支皮瓣修复手部创面的应用研究. 创伤外科杂志, 2021, 23(9): 697-700.
15. 欧阳容兰, 刘江涛, 连丽娜. 胫后动脉穿支岛状皮瓣修复小腿中下段皮肤缺损的临床效果研究. 中国美容医学, 2022, 31(1): 16-19.
16. Hifny MA, Tohamy AMA, Rabie O, et al. Propeller perforator flaps for coverage of soft tissue defects in the middle and distal lower extremities. Ann Chir Plast Esthet, 2020, 65(1): 54-60.
17. 谢毅, 张加尧, 叶哲伟. 混合现实技术在创伤骨科的应用与展望. 中华创伤骨科杂志, 2020, 22(11): 1009-1012.
18. 章振逸, 李彬, 丁焕文, 等. 基于增强现实的骨科手术中引导手术导板精确安放方法. 生物医学工程研究, 2021, 40(4): 413-419.
19. Masia J, Clavero JA, Larrañaga JR, et al. Multidetector-row computed tomography in the planning of abdominal perforator flaps. J Plast Reconstr Aesthet Surg, 2006, 59(6): 594-599.
20. Kurbad A. The use of ‘extended reality’ (augmented reality) in esthetic treatment planning. Int J Comput Dent, 2020, 23(2): 149-160.

Chinese Journal of Reparative and Reconstructive Surgery

Application of augmented reality technique in repairing soft tissue defects of lower limbs with posterior tibial artery perforator flap

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