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Abstract

This paper presents the concept and preliminary modeling of a legged microrobot locomoting in a tubular, compliant and slippery environment. The envisaged application field is related to capsular endoscopy, i.e., the development of a mobile swallowable capsule for navigation inside the gastrointestinal tract for diagnosis and therapy. After introducing and discussing the issue of autonomous locomotion of endoscopic devices, with reference to worldwide ongoing research in the field, the legged solution is proposed and peculiarities of this approach are described. The importance of simulation for developing a legged device is discussed and a locomotion model is presented. Experimental results are described for the definition of biomechanical parameters necessary in the model. Thanks to this work first simulations have been obtained, in which the microrobot’s body moves according to arbitrary gait patterns for the legs and to its interaction with tissue. The resulting tool will be used for the design synthesis, for defining the optimal number of legs and the best number of degrees of freedom for each leg. It will be also used for controlling the device, by identifying the gait pattern to be adopted in order to obtain different capsule movements.

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References

Accoto, D., Stefanini, C., Phee, L., Arena, A., Pernorio, G., Menciassi, A., Carrozza M. C., and Dario, P. 2001. Measurements of the frictional properties of the gastrointestinal tract . World Tribology Congress 2001, Vienna, Austria, 3-7 September, p. 728 .

American Cancer Society. Dataonline available at: http://www.cancer.org/downloads/STT/CAFF2005f4PWSecured.pdf

Bowersox, J. C. 2001. Bits and Bytes of 21st Century Medical Care . The Pfizer Journal 5(2): 20-25 .

Dario, P., Carrozza, M. C., and Pietrabissa, A. 1999. Development and in vitro tests of a miniature robotic system for computer assisted colonoscopy . Journal of Computer Aided Surgery 4: 4-14 .

Dario, P., Accoto, D., Gorini, S., Menciassi, A., Pernorio, G., and Stefanini, C. 2005. Teleoperated endoscopic capsule equipped with active locomotion system. PCT application no. WO2005082248, applied on 2005-09-09.

Dario, P., Ciarletta, P., Menciassi A., and Kim, B. 2004. Modeling and Experimental Validation of the Locomotion of Endoscopic Robots in the Colon . International Journal of Robotics Research 23(4-5): 549-556 .

Iddan, G., Meron, G., Glukhovsky, A., and Swain, P. 2000. Wireless capsule endoscopy . Nature 405: 417 .

Ikuta, K., Tsukamoto, M., and Hirose, S. 1988. Shape memory alloy servo actuator system with electric resistence feedback and application for active endoscope . Proceedings of the 1988 IEEE International Conference on Robotics and Automation, Philadelphia, Pennsylvania, pp. 427-430 .

Jacobson B. and Olbe L. 1963. Intraluminal pressure waves of the stomach in dogs studied by endoradiosondes . Gastroenterology 44(6): 787-796 .

10.

Menciassi, A. and Dario, P. 2003. Bio-inspired solutions for locomotion in the gastrointestinal tract: background and perspectives . Philosophical Transactions of the Royal Society A 361(1811): 2287-2298 .

11.

Menciassi, A., Stefanini, C., Gorini, S., Pernorio, G., Dario, P., Kim, B., and Park, J. O. 2004. Legged locomotion in the gastrointestinal tract - problem analysis and preliminary technological activity . Proceedings of International Conference on Intelligent Robots and Systems IROS 2004, Vol. 1, pp. 937-942 .

12.

Meron, G. 2000. The Development of the Swallowable Video Capsule (M2A) . Gastrointestinal Endoscopy 6: 817-819 .

13.

Nagumo, J.et al. 1962. Echo capsule for medical use (a batteryless endoradiosonde) . IRE Transactions on Bio-Medical Electronics BME-9: 195 .

14.

Nebeker, F. 2002. Golden accomplishments in biomedical engineering . IEEE Engineering in Medicine and Biology Magazine 21(May-June): 17-47 .

15.

Olympus.Dataonlineavailableat:http://www.olympus.co.jp/en/news/2004b/nr041130capsle.cfm?chm=2

16.

Phee, L., Accoto, D., Menciassi, A., Stefanini, C., Carrozza M. C., and Dario, P. 2002. Analysis and Development of Locomotion Devices for the Gastrointestinal Tract . IEEE Transactions on Biomedical Engineering 49(6): 613-616

17.

Phee, S. J., Ng, W. S., Chen, I. M., Seow-Choen, F., and Davies, B. L. 1997. Locomotion and steering aspects in automation of colonoscopy . IEEE Engineering in Medicine and Biology Magazine 16(6): 85-96 .

18.

Satava, R. M. 2004. Disruptive visions: a robot is not a machine...systems integration for surgeons . Surgical Endoscopy 18(4): 617-620 (E-Pub 2004 March 19).

19.

Suzumori, K., Miyagawa, T., Kimura, M., and Hasegawa, Y. 1999. Micro inspection robot for 1-in pipes . IEEE/ASME Transactions on Mechatronics 4(3): 286-292 .

20.

Tabata, O., Kojima, H., Kasatani, T., Isono, Y., and Yoshida, R. 2003. Chemo-mechanical actuator using self-oscillating gel for artificial cilia . IEEE Sixteenth Annual International Conference on Micro Electro Mechanical Systems, (MEMS 2003), Kyoto, pp. 12-15 .

21.

Uehara A. and Hoshina, K. 2003. Capsule endoscope NORIKA system . Minimally Invasive Therapy & Allied Technologies 12(5): 227-234 .

22.

Wakimoto, S., Nakajima, J., Takata, M., Kanda, T., and Suzumori, K. 2003. A micro snake-like robot for small pipe inspection . Proceedings of the International Symposium on Micromechatronics and Human Science (MHS), 19-22 Oct., pp. 303-308 .

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Modeling and Experiments on a Legged Microrobot Locomoting in a Tubular,Compliant and Slippery Environment

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