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http://dx.doi.org/10.21288/resko.2016.10.3.229

Magneto-Mechatronics : A New Approach to Sensors and Actuators for Next-Generation Biomedical and Rehabilitation Devices  

Yu, Chang Ho (전북대학교 융합기술공학과)
Kim, Sung Hoon (원광대학교 전자융합공학과)
Publication Information
Journal of rehabilitation welfare engineering & assistive technology / v.10, no.3, 2016 , pp. 229-236 More about this Journal
Abstract
Magnetic sensors and actuators have been widely used in industry and medical fields. Integrated systems based on sensors and actuators are defined as mechatronics that is the general combination of mechanics and electronics. Recently, magnetic wireless sensors and actuators have been developed and used at a systematic level. In particular, their mechanisms depend on magnetic, such as magnetic material and physical phenomena. However, their research boundary has not been clear. Researchers talk of magnetic micro-robots, magnetic actuators and sensors. Therefore, a new and correct definition is required. In this study, we introduce the advanced and extended concept of mechatronics, which is a magneto-mechantronics for biomedical and rehabilitation. Among various applications, we focused on wireless pump and sensing system for blood vessel rehabilitation and local motion capture, respectively.
Keywords
Magneto-mechatronics; Magnetic wireless actuator and sensor; Medical rehabilitation; Magnetic torque; Magnetic force;
Citations & Related Records
Times Cited By KSCI : 2  (Citation Analysis)
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1 D. H. Kim, et al., Biofunctionalized magnetic-vortex microdiscs for targeted cancer-cell destruction, Nature Materials 9, 165-171, 2010.   DOI
2 C. Chappert, A. Fert, and F. N. Van Dau, The emergence of spin electronics in data storage, Nature Materials 6, 813-824, 2007.   DOI
3 R. Hergt, S. Dutz, R. Muller, and M. Zeisberger, Magnetic particle hyperthermia: nanoparticle magnetism and materials development for cancer therapy, Journal of Physics: Condensed Matter 18, 2919-2934, 2006.   DOI
4 G. Dogangil, O. Ergeneman, J. J. Abbott, S. Pane, H. Hall, S. Muntwyler, and B. J. Nelson, Toward Targeted Retinal Drug Delivery with Wireless Microrobots, IEEE/RSJ Int. Conf. Intelligent Robots and Systems, 1921-1925, 2008.
5 M. Sendoh, K. Ishiyama, K. I. Arai, Direction and individual control of magnetic micromachine, IEEE Transactions Magnetics 39, 3232-3234, 2003.   DOI
6 S. Nishijima, F. Mishima, T. Terada, S. Takeda, A study on magnetically targeted drug delivery system using superconducting magnet, Physica C: Superconductivity and its applications 1311, 463-465, 2007.
7 D. R. Reyes, D. Iossifidis, P. A. Auroux, and A. Manz, Micro total analysis systems. 1. Introduction, theory, and technology, Analytical Chemistry 74, 2623-2636, 2002.   DOI
8 K. Belharet, D. Folio, and A. Ferreira, Endovascular navigation of a ferromagnetic microrobot using MRI-based predictive control, IEEE/RSJ International Conference on Intelligent Robots and Systems, 2804-2809, 2010.
9 N. Kyura and H. Oho, Mechatronics - An individual perspective, IEEE/ASME Transactions on Mechatronics 1, 10-15, 1996.   DOI
10 T. Mori, Mechatroincs, Yasakawa Internal Trademark Application Memo 21, 1, 1969.
11 F. Harashima, M. Tomizuka, and T. Fukuda, Mechatronics - "What is it, Why, and How?, IEEE/ASME Transactions on Mechatronics 1, 1-4, 1996.   DOI
12 S. M. Song, C. H. Yu, K. Kim, J. J. Kim, W. K. Song, C. U. Hong, T. K. Kwon, Evaluation of human body effects during activities of daily living according to body weight support rate with active harness system, Journal of rehabilitation welfare engineering & assistive technology 10, 47-57, 2016.
13 S. Hashi, M. Toyoda, S. Tanukami, K. Ishiyama, Y. Okazaki, K. I Arai, Wireless Magnetic Motion Capture System for Multi-Marker Detection, IEEE Transactions on Magnetics 4, 3279-3281, 2006.
14 S. M. Song, C. H. Yu, K. Kim, J. J. Kim, W. K. Song, C. U. Hong, T. K. Kwon, Study on lower extremities activities pattern of ADL and treadmill gait according to harness body-weight support percentages, Journal of rehabilitation welfare engineering & assistive technology 9, 319-329, 2015.
15 S. H. Kim, S. Hashi, K. Ishiyama, Actuation of novel blood pump by direct application of rotating magnetic field, IEEE Transactions Magnetics 48, 1869-1874, 2012.   DOI
16 H. Choi, J. Choi, S. Jeong, C. Yu, J. O. Park and S. Park, Two-dimensional locomotion of a microrobot with a novel stationary electromagnetic actuation system, Smart Materials and Structures 18, 115017, 2009.   DOI
17 S. H. Kim, C. H. Yu, K. Ishiyama, Tiny magnetic wireless pump: Fabrication of magnetic impeller and magnetic wireless manipulation for blood circulation in legs, Journal of Applied Physics 117, 17B311 2015.   DOI
18 T. Molet, Z. Huang, R. Boulic, D. Thalmann, An Animation Interface Designed for Motion Capture, Computer Animation 97, 77-85, 1997.