泌尿外科机器人手术新趋势

doi:10.3877/cma.j.issn.1674-3253.2023.04.023

近年来,微创手术已成为泌尿外科发展的主流方向之一。机器人手术系统作为一种全新的微创手术方式，目前已广泛地应用于我国微创外科手术领域。随着当今科学技术水平飞速发展，各种新兴技术逐步融合于机器人手术中（增强现实、人工智能、5G通信、单孔机器人、国产机器人等），机器人精准微创外科手术时代已经到来。本文就泌尿外科机器人手术的新趋势进行综述。

关键词: 机器人, 增强现实（AR）, 虚拟现实（VR）, 人工智能（AI）, 5G通信, 单孔机器人, 国产机器人, 精准手术

[1]	Wendler T, van Leeuwen F, Navab N, et al. How molecular imaging will enable robotic precision surgery: The role of artificial intelligence, augmented reality, and navigation[J]. Eur J Nucl Med Mol Imaging, 2021, 48(13): 4201-4224.
[2]	Navab N, Blum T, Wang L, et al. First deployments of augmented reality in operating rooms[J]. Computer, 2012, 45(7): 48-55.
[3]	Schoeb DS, Rassweiler J, Sigle A, et al. Robotics and intraoperative navigation[J]. Der Urologe Ausg, 2021, 60(1): 27-38.
[4]	Thompson S, Penney G, Billia M, et al. Design and evaluation of an image-guidance system for robot-assisted radical prostatectomy[J]. BJU Int, 2013, 111(7): 1081-90.
[5]	Bianchi L, Chessa F, Angiolini A, et al. The use of augmented reality to guide the intraoperative frozen section during robot-assisted radical prostatectomy[J]. Eur Urol, 2021, 80(4): 480-488.
[6]	Schiavina R, Bianchi L, Lodi S, et al. Real-time Augmented reality three-dimensional guided robotic radical prostatectomy: preliminary experience and evaluation of the impact on surgical planning[J]. Eur Urol Focus, 2021, 7(6): 1260-1267.
[7]	Bertolo R, Hung A, Porpiglia F, et al. Systematic review of augmented reality in urological interventions: the evidences of an impact on surgical outcomes are yet to come[J]. World J Urol, 2020, 38(9): 2167-2176.
[8]	Shimizu H, Nakayama KI. Artificial intelligence in oncology[J]. Cancer Sci, 2020, 111(5): 1452-1460.
[9]	Tran BX, Vu GT, Ha GH, et al. Global evolution of research in artificial intelligence in health and medicine: a bibliometric study[J]. J Clin Med, 2019, 8(3): 360.
[10]	Shkolyar E, Jia X, Chang TC, et al. Augmented bladder tumor detection using deep learning[J]. Eur Urol, 2019, 76(6): 714-718.
[11]	Toivonen J, Montoya Perez I, Movahedi P, et al. Radiomics and machine learning of multisequence multiparametric prostate MRI: Towards improved non-invasive prostate cancer characterization[J]. PLoS One, 2019, 14(7): e0217702.
[12]	Huang Q, Gu L, Zhu J, et al. A three-dimensional, anatomy-based nephrometry score to guide nephron-sparing surgery for renal sinus tumors[J]. Cancer, 2020, 126(9): 2062-2072.
[13]	Hung AJ, Chen J, Che Z, et al. Utilizing machine learning and automated performance metrics to evaluate robot-assisted radical prostatectomy performance and predict outcomes[J]. J Endourol, 2018, 32(5): 438-444.
[14]	Zia A, Guo L, Zhou L, et al. Novel evaluation of surgical activity recognition models using task-based efficiency metrics[J]. Int J Comput Assist Radiol Surg, 2019, 14(12): 2155-63.
[15]	Vedula SS, Ghazi A, Collins JW, et al. Artificial Intelligence Methods and Artificial Intelligence-Enabled Metrics for Surgical Education: A Multidisciplinary Consensus[J]. J Am Coll Surg, 2022, 234(6): 1181-1192.
[16]	Chang TC, Seufert C, Eminaga O, et al. Current Trends in Artificial Intelligence Application for Endourology and Robotic Surgery[J]. Urol Clin North Am, 2021, 48(1): 151-160.
[17]	Yang GZ, Cambias J, Cleary K, et al. Medical robotics-Regulatory, ethical, and legal considerations for increasing levels of autonomy[J]. Sci Robot, 2017, 2(4): eaam8638.
[18]	Patriciu A, Petrisor D, Muntener M, et al. Automatic brachytherapy seed placement under MRI guidance[J]. IEEE Trans Biomed Eng, 2007, 54(8): 1499-1506.
[19]	Gilling P, Reuther R, Kahokehr A, et al. Aquablation - image-guided robot-assisted waterjet ablation of the prostate: initial clinical experience[J]. BJU Int, 2016, 117(6): 923-929.
[20]	Saeidi H, Opfermann JD, Kam M, et al. Autonomous robotic laparoscopic surgery for intestinal anastomosis[J]. Sci Robot, 2022, 7(62): eabj2908.
[21]	Connor MJ, Dasgupta P, Ahmed HU, et al. Autonomous surgery in the era of robotic urology: friend or foe of the future surgeon?[J]. Nat Rev Urol, 2020, 17(11): 643-649.
[22]	Georgiou KE, Georgiou E, Satava RM. 5G use in healthcare: the future is present[J]. JSLS, 2021, 25(4): e2021, 00064.
[23]	刘荣, 赵国栋, 孙玉宁, 等. 5G远程机器人手术动物实验研究[J/OL]. 中华腔镜外科杂志(电子版), 2019, 12(1): 45-48.
[24]	Zheng J, Wang Y, Zhang J, et al. 5G ultra-remote robot-assisted laparoscopic surgery in China[J]. Surg Endosc, 2020, 34(11): 5172-5180.
[25]	Jell A, Vogel T, Ostler D, et al. 5th-Generation mobile communication: data highway for surgery 4.0[J]. Surg Technol Int, 2019, 35: 36-42.
[26]	Acemoglu A, Peretti G, Trimarchi M, et al. Operating From a Distance: Robotic Vocal Cord 5G Telesurgery on a Cadaver[J]. Ann Intern Med, 2020, 173(11): 940-941.
[27]	Ayoub CH, El-Asmar JM, Abdulfattah S, et al. Telemedicine and telementoring in urology: a glimpse of the past and a leap into the future[J]. Front Surg, 2022, 9: 811749.
[28]	Hung AJ, Chen J, Shah A, et al. Telementoring and telesurgery for minimally invasive procedures[J]. J Urol, 2018, 199(2): 355-369.
[29]	White MA, Autorino R, Spana G, et al. Robotic laparoendoscopic single site urological surgery: analysis of 50 consecutive cases[J]. J Urol, 2012, 187(5): 1696-1701
[30]	张超, 魏勇, 景泰乐, 等. 国产单孔蛇形臂机器人手术系统在前列腺癌根治术中的初步应用 [J/OL]．中华腔镜泌尿外科杂志(电子版), 2022, 16(4): 293-297.
[31]	Agarwal DK, Hebert KJ, Gettman MT, et al. How to perform a robotic pyeloplasty utilizing the da Vinci SP platform: tips and tricks[J]. Transl Androl Urol, 2020, 9(2): 919-924.
[32]	Ju GQ, Wang ZJ, Shi JZ, et al. A comparison of perioperative outcomes between extraperitoneal robotic single-port and multiport radical prostatectomy with the da vinci si surgical system[J]. Asian J Androl, 2021, 23(6): 640-647.
[33]	Lee HH, Na JC, Yoon YE, et al. Robot-assisted laparoendoscopic single-site upper urinary tract surgery with da Vinci Xi surgical system: Initial experience[J]. Investig Clin Urol, 2020, 61(3): 323-329.
[34]	Wang YL, Li Z, Yi B, et al. Initial experience of Chinese surgical robot "Micro Hand S"-assisted versus open and laparoscopic total mesorectal excision for rectal cancer: Short-term outcomes in a single center[J]. Asian J Surg, 2022, 45(1): 299-306.
[35]	Fan S, Zhang Z, Wang J, et al. Robot-Assisted radical prostatectomy using the kangduo surgical robot-01 system: a prospective, Single-Center, Single-Arm clinical study[J]. J Urol, 2022, 208(1): 119-127.
[36]	张思玮. 首款国产四臂腔镜手术机器人获批上市[N]. 中国科学报, 2022-02-07(003).

[1]	刘伦, 王云鹭, 李锡勇, 韩鹏飞, 张鹏, 李晓东. 机器人辅助膝关节单髁置换术的研究进展[J]. 中华关节外科杂志(电子版), 2023, 17(05): 715-721.
[2]	伊喆, 王志新, 陈伟, 齐伟亚, 方杰, 石海飞, 赵夏, 赵喆, 竺枫, 盛伟, 陈焱, 张宇昊, 朱瑾, 殷耀斌, 杨勇, 陈山林, 刘波. 机器人辅助无移位急性舟骨骨折经皮内固定的诊疗与手术操作规范[J]. 中华损伤与修复杂志(电子版), 2023, 18(06): 464-468.
[3]	罗佳, 赵晶晶, 曹小珍, 钟玲, 范林军, 曾令娟. 单侧腋窝双侧乳晕入路机器人甲状腺术后局部加压预防皮下隧道出血的对照研究[J]. 中华普外科手术学杂志(电子版), 2023, 17(06): 603-606.
[4]	刘波, 涂志坚, 李传富, 李江涛, 陈国栋. 机器人解剖性左半肝切除术[J]. 中华普外科手术学杂志(电子版), 2023, 17(05): 486-486.
[5]	李晓阳, 刘柏隆, 周祥福. 大数据及人工智能对女性盆底功能障碍性疾病的诊断及风险预测[J]. 中华腔镜泌尿外科杂志(电子版), 2023, 17(06): 549-552.
[6]	刘成, 赖聪, 黄健, 王建辰, 罗茜芸, 许可慰. EDGE SP1000单孔手术机器人辅助腹腔镜下猪输尿管部分切除联合端端吻合术的可行性研究[J]. 中华腔镜泌尿外科杂志(电子版), 2023, 17(06): 642-646.
[7]	梅津熠, 王燕, 瞿旻, 董振阳, 周增辉, 沈显琦, 李嘉伦, 高旭. 机器人前列腺癌根治术中"膀胱外中叶"的处理[J]. 中华腔镜泌尿外科杂志(电子版), 2023, 17(05): 429-433.
[8]	吴少峰, 张轶男, 孙杰. 机器人辅助手术在儿童微创泌尿手术中的应用和展望[J]. 中华腔镜泌尿外科杂志(电子版), 2023, 17(05): 440-444.
[9]	李腾成, 谭益元, 黄群雄, 吴杰英, 肖恒军, 胡成, 李茂胤, 高新, 狄金明. 机器人腹腔镜后入路完全筋膜内根治性前列腺切除术治疗早期前列腺癌[J]. 中华腔镜泌尿外科杂志(电子版), 2023, 17(05): 452-456.
[10]	余俊豪, 麻立. 经腹全腹腔镜上尿路尿路上皮癌根治术在临床中的应用[J]. 中华腔镜泌尿外科杂志(电子版), 2023, 17(05): 529-532.
[11]	张立鑫, 朱建交, 李敬东. 机器人肝切除技术的优势与劣势[J]. 中华肝脏外科手术学电子杂志, 2023, 12(05): 477-479.
[12]	韩冰, 顾劲扬. 深度学习神经网络在肝癌诊疗中的研究及应用前景[J]. 中华肝脏外科手术学电子杂志, 2023, 12(05): 480-485.
[13]	雷漫诗, 邓锶锶, 汪昕蓉, 黄锦彬, 向青, 熊安妮, 孟占鳌. 人工智能辅助压缩感知技术在上腹部T2WI压脂序列中的应用[J]. 中华肝脏外科手术学电子杂志, 2023, 12(05): 551-556.
[14]	嵇晋, 管锦坤, 汪刘华, 王伟, 任俊, 张琪, 王道荣, 马从超. 达芬奇机器人对比腹腔镜在低位直肠癌APR手术中盆底腹膜关闭联合腹膜外造口的应用研究[J]. 中华结直肠疾病电子杂志, 2023, 12(05): 381-387.
[15]	党圆圆, 赵虎林. 机器人辅助小脑齿状核脑深部电刺激植入术[J]. 中华脑科疾病与康复杂志(电子版), 2023, 13(05): 320-320.

阅读次数

全文

摘要

选择文件类型/文献管理软件名称

选择包含的内容

New trends of robotic surgery in Urology

模态框（Modal）标题

选择文件类型/文献管理软件名称

选择包含的内容

New trends of robotic surgery in Urology