[1]贺志秀,钱 炜,宋成利.介入手术中导管导向机器人技术的发展[J].介入放射学杂志,2011,(07):584.
 HE Zhi-xiu,QIAN Wei,SONG Cheng-li.The technical development of steerable catheter robot in performing interventional vascular surgery[J].journal interventional radiology,2011,(07):584.
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介入手术中导管导向机器人技术的发展()

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《介入放射学杂志》[ISSN:1008-794X/CN:31-1796/R]

卷:
期数:
2011年07期
页码:
584
栏目:
综述
出版日期:
2011-07-30

文章信息/Info

Title:
The technical development of steerable catheter robot in performing interventional vascular surgery
作者:
贺志秀 钱 炜 宋成利
200093  上海理工大学机械工程学院;上海理工大学医疗器械与食品学院、教育部现代微创医疗器械及技术工程研究中心
Author(s):
HE Zhi-xiu QIAN Wei SONG Cheng-li
College of Mechanical Engineering, University of Shanghai for Science and Technology, Shanghai 200093, China
关键词:
微创介入手术 导管 导向机器人
分类号:
R61
文献标志码:
摘要:
微创介入手术是治疗血管疾病的主要手段之一,导管是介入手术的主要操作工具之一,由于血管系统的复杂和狭小,医师要徒手完成导管在血管内的精准操作十分困难。所以,导管导向机器人的研究也随着微创介入手术的出现而产生了。此文首先综述了导管导向机器人的产生及发展历史,然后分别介绍了世界各国研究人员在导管导向机器人方面进行的主要阶段性研究成果、最新研究进展,最后对导管导向机器人的发展做了一下展望。

参考文献/References:

[1] Besl JP, Mckay DN. A method for registration of 3-d shapes[J]. IEEE Trans Pattern Anal Mach Intell, 1992, 14: 239 - 256.
[2] Cepolina F, Michelini RC. Review of robotic fixtures for minim-ally invasive surgery[J]. Int J Med Robot, 2004, 1: 43 - 63.
[3] Chun KR, Schmidt B, Kktürk B, et al. Catheter ablation-new developments in robotics[J]. Herz, 2008, 33: 586 - 589.
[4] Ernst S. Robotic approach to catheter ablation[J]. Curr Opin Cardiol, 2008, 23: 28 - 31.
[5] Fu Y, Liu H, Wang S, et al. Skeleton-based active catheter navigation[J]. Int J Med Robot, 2009, 5: 125 - 135.
[6] Fu Y, Liu H, Huang W, et al. Steerable catheters in minimally invasive vascular surgery[J]. Int J Med Robot, 2009, 5: 381 - 391.
[7] Criado FJ. Endovascular intervention: basic concepts and techni-ques[M]. UK, Wiley-Blackwell, 1999.
[8] Chun KR, Schmidt B, Kktürk B, et al. Catheter ablation-new developments in robotics[J]. Herz, 2008, 33: 586 - 589.
[9] Haga Y, Mineta T, Esashi M. Multi-functional active catheter[J]. Sensors Update, 2000, 8: 147 - 186.
[10] Sugihara M, Geunbae L, Kitae P, et al. Future of active cath-eters[J]. Sens Actuators a Phys, 1996, 56: 113 - 121.
[11] Haga Y, Esashi M, Maeda S. Bending, torsional and extending active catheter assembled using electroplating[Z]. 2000, 181 - 186.
[12] Haga Y, Esashi M, Mineta T. Active catheter, active guide wire and related sensor systems[C]. //Automation Congress, Proceedings of the 5th Biannual World, 14: tsi press, 2002, 291 - 296.
[13] Mineta T, Mitsui T, Watanable Y, et al. Batch fabricated flat winding Shap memory alloy actuator for active catheter[Z], 2000, 375 - 380.
[14] Aramaki S, Kaneko S, Arai K, et al. Tube type micro mani-pulator using shape memory alloy(SMA)[C]. //Micro Machine and Human Science, 1995. MHS'95. Proceedings of the Sixth International Symposium on, 1995, 115 - 120.
[15] Howe R, Allen M, Berlin A, et al. Microsystems research and development in japan[Z]. 2002, 21 - 24.
[16] Cimino WW. Active tip control for small diameter catheters: po-wer transmission and transduction requirements[Z]. 1992.
[17] Remote magnetic navigation: http:[EB] //dic.academic.ru/dic.nsf//enwiki7241646.
[18] Fukuda GS, Kosuge T, Arai K, et al. Micro catheter system with active guide wire[C]. // Robotics and Automation, 1995. Proceedings. 1995, IEEE International Conference on, 1995: 79 - 84.
[19] Fukuda GS, Arai T, Oguro F, et al. Micro active guide wire catheter system[C].//Intelligent Robots and Systems 95. 'Human Robot Interaction and Cooperative Robots', Proceedings. 1995 IEEE/RSJ International Conference on, 2, 1995, 172 - 177.
[20] Nakamura T, Fukuda T, Guo SX, et al. Micro active catheter using ICPF actuator-characteristic evaluation, electrical model and operability evaluation[C]. //Industrial Electronics, Control, and Instrumentation, 1996, Proceedings of the 1996 IEEE Iecon 22nd International Conference on, 2, 1996: 1312 - 1317.
[21] Yoseph BC. Transition of EAP material from novelty to practical applications-are we there yet﹖[C]. //International Symposium on Smart Structures and Materials, 2001: 4329 - 4332.
[22] Haga Y, Muyari Y, Mineta T, et al. Small diameter hydraulic active bending catheter using laser processed super elastic alloy and silicone rubber tube[C]. //Microtechnology in Medicine and Biology, 2005. 3rd IEEE/EMBS Special Topic Conference on, 2005: 245 - 248.
[23] Montgomery DB, Weggel RJ, Leupold MJ, et al. Supercondu-cting magnet system for intravascular navigation[J]. J Appl Phys, 1969, 40: 2129 - 2132.
[24] Driller J, Parsonnet V. Magnetic materials as biological implants-criteria for selection[J]. IEEE Trans Magn, 1973, 9: 444 - 447.
[25] Tillander H. Selective angiography with a catheter guided by a magnet[J]. IEEE Trans Magn, 1970, 6: 355 - 358.
[26] Brain K. Neural networks in magnetic guidance[D]. University of Virginia, Doctor Dissertation, 1998.
[27] 白 烨, 杨 明, 王秋良, 等. 磁导航外科手术模型系统设计和建造[J]. 北京生物医学工程, 2006, 25: 261 - 264,315.
[28] Da L, Zhang D, Wang T. Overview of the vascular interventional robot[J]. Int J Med Robot, 2008, 4: 289 - 294.
[29] Kiemeneij F, Patterson MS, Amoroso G, et al. Use of the ste-reotaxis niobe magnetic navigation system for percutaneous coronary interventionresults from 350 consecutive patients[J]. Catheter Cardiovasc Interv, 2008, 71: 510 - 516.

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备注/Memo

备注/Memo:
收稿日期:20101116
上海市研究所创新基金(JWCXZSL1002);2011上海市教委科研创新重点项目(1122132)
更新日期/Last Update: 2011-07-30