Analytical model development for the prediction of the frictional resistance of a capsule endoscope inside an intestine

Proceedings of the Institution of Mechanical Engineers, Part H: Journal of Engineering in Medicine

Volumn 221, Issue 8, 2007, Pages 837-845

  Kim, J S ^a   Sung, I H ^b   Kim, Y T ^a   Kim, D E ^a   Jang, Y H ^a  

^a Yonsei University   (South Korea)

^b Hannam University   (South Korea)

Author keywords

Biotribology; Finite element analysis; Frictional resistance; Small intestine; Viscoelasticity

Indexed keywords

ENDOSCOPY; FINITE ELEMENT METHOD; GEOMETRY; MATHEMATICAL MODELS; OPTIMIZATION; VISCOELASTICITY; ANALYTICAL MODELS; FORECASTING; FRICTION; STRESS RELAXATION;

BIOTRIBOLOGY; FRICTIONAL RESISTANCE; SELF-PROPELLED CAPSULE ENDOSCOPE;

BIOMEDICAL ENGINEERING; FINITE ELEMENT METHOD;

BIOTRIBOLOGY; EXPERIMENTAL INVESTIGATIONS; EXPERIMENTAL VALUES; FRICTIONAL RESISTANCE; LOCOMOTION MECHANISM; QUANTITATIVE ESTIMATION; REASONABLE ACCURACY; SMALL INTESTINE;

ARTICLE; BIOLOGICAL MODEL; CAPSULE ENDOSCOPE; COMPUTER SIMULATION; FRICTION; GASTROINTESTINAL MOTILITY; HUMAN; MECHANICAL STRESS; MOTION; MUSCLE CONTRACTION; PHYSIOLOGY; SMALL INTESTINE; SMOOTH MUSCLE;

CAPSULE ENDOSCOPES; COMPUTER SIMULATION; FRICTION; GASTROINTESTINAL MOTILITY; HUMANS; INTESTINE, SMALL; MODELS, BIOLOGICAL; MOTION; MUSCLE CONTRACTION; MUSCLE, SMOOTH; STRESS, MECHANICAL;

EID: 38449120991     PISSN: 09544119     EISSN: None     Source Type: Journal    
DOI: 10.1243/09544119JEIM173     Document Type: Article

References (12)

1. Tendick, E, Sastry, S. S., Fearing, R. S., and Cohn, M. Applications of micromechatronics in minimally invasive surgery. IEEE-ASME Trans. Mechatronics, 1998, 3, 34-42.
2. Howe, R. D. and Matsuoka, Y. Robotics for surgery. A. Rev. Biomed. Engng, 1999, 1, 211-240.
3. Peirs, I., Reynaerts, D., and Van Brussel, H. Design of miniature parallel manipulators for integration in a self-propelling endoscope. Sensors Actuators A - Physics, 2000, 85, 409-417.
4. Kim, B., Lee, S., Park J. H., and Park J. O. Design and fabrication of a locomotive mechanism for capsule-type endoscopes using shape memory alloys (SMAs). IEEE-ASME Trans. Mechatronics, 2005, 10, 77-86.
5. Dario, P, Ciarletta, P., Menciassi, A., and Kim, B. Modeling and experimental validation of the locomotion of endoscopic robots in the colon. Int. J. Robotics Res., 2004, 23, 549-556.
6. Ikeuchi, K., Yoshinaka, K., and Tomita, N. Low invasive propulsion of medical devices by traction using mucus. Wear, 1997, 209, 179-183.
7. Sendoh, M., Ishiyama, K., and Arai, K. I. Fabrication of magnetic actuator for use in a capsule endoscope. IEEE Trans. Magn., 2003, 39, 3232-3234.
8. Baek, N. K., Sung, I. H., and Kim, D. E. Frictional resistance characteristics of a capsule inside the intestine for microendoscope design. Proc. Instn Mech. Engrs, Part H: J. Engineering in Medicine, 2004, 218, 193-201.
9. Kim, J. S., Sung, I. H., Kim, Y. T., Kwon, E. Y., Kim, D. E., and Jang, Y. H. Experimental investigation of frictional and viscoelastic properties of intestine for microendoscope application. Tribology Lett., 2006, 22(2), 143-149.
10. Ugural, A. C. and Fenster, S. K. Advanced strength and applied elasticity, 1995 (Prentice-Hall, Englewood Cliffs, New Jersey).
11. Gere, J. M. and Timoshenko, S. P. Mechanics of material, 1997 (PWS Publishing Company, Boston, Massachusetts).
12. ARAQUS/standard user's manual, 2002 (Hibbit, Karlsson and Sorensen, Inc., Pawtucket, Rhode Island).