MEMS Scanners for OCT Applications

doi:10.1017/CBO9781139506052.013

13 - MEMS Scanners for OCT Applications

from Part III - Systems and Applications

Published online by Cambridge University Press: 05 December 2015

Hiroshi Toshiyoshi ,

Keiji Isamoto and

Changho Chong

Edited by

Hans Zappe and

Claudia Duppé

Show author details

Hiroshi Toshiyoshi: Affiliation:
The University of Tokyo, Japan
Keiji Isamoto: Affiliation:
Santec Corporation, Japan
Changho Chong: Affiliation:
Santec Corporation, Japan
Hans Zappe: Affiliation:
Albert-Ludwigs-Universität Freiburg, Germany
Claudia Duppé: Affiliation:
Albert-Ludwigs-Universität Freiburg, Germany

Book contents

Get access

Summary

Introduction

OCT, or optical coherence tomography, is an optical signal processing system to visualize the cross-sectional image of a semi-transparent object by spatially scanning the probe light and by reconstructing the internal structural image from the optical interference of the back-scattered light. The principle of OCT was filed as a Japanese patent in 1990 by Tanno et al. with Yamagata University, Japan (Tanno et al. 1990), and the first demonstration was independently performed in 1991 by Fujimoto et al. with MIT, Massachusetts (Huang et al. 1991).

Since the commercial release of the first OCT system in 1996 by Humphrey Instruments (Carl Zeiss Meditec Inc., USA), the non-invasive OCT inspection has been used in various fields of medical diagnosis such as dental caries visualization (Jones et al. 2006), periodontal dentistry (Colston et al. 1997), and esophagus biopsy (Su et al. 2007). The principle of OCT is also used for endoscope applications such as gastroenterology and angioscopy (Tearney et al. 1996, 1997, Bouma et al. 2000). Owing to the three-dimensional (3D) visualization capability, OCT is most beneficial in fundoscopy to diagnose symptoms such as retinal detachment and macular hole that are difficult to perform based on the limited information from the surface observation. The image resolution of the OCT system is generally as good as a few microns, which exceeds those of other instruments such as ultrasonic imaging, computerized tomography (CT) scan, or nuclear magnetic resonance (NMR) imaging. Even a small plaque fragment deposited on the inner wall of a coronary artery can be visualized by vascular endoscopy with OCT (Yabushita et al. 2002).

Optical micro-electro-mechanical systems (MEMS) technology has brought significant breakthroughs to improve the performance of OCT systems in terms of faster frame rate and higher image resolution through the new generation of wavelength tunable light source. It has also contributed a lot to produce optical fiber endoscope OCTs, where compactness is the most valuable factor for medical use. In this chapter, we discuss the principle of the OCT system, and look into the use of optical MEMS scanners for the wavelength tunable light source in OCT systems as well as for the spatial light modulator in endoscope probes.

Information

Type: Chapter
Information: Tunable Micro-optics , pp. 319 - 345

DOI: https://doi.org/10.1017/CBO9781139506052.013 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2015

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

Book purchase

Temporarily unavailable

References

Aguirre, A. D., Herz, P. R., Chen, Y., Fujimoto, J. G., Piyawattanametha, W., Fan, L. & Wu, M. C. (2007), ‘Two-axis MEMS scanning catheter for ultrahigh resolution three-dimensional and en face imaging’, Optics Express 15, 2445–2453.CrossRef Google Scholar

Bouma, B. E. & Tearney, G. J. (2002), Handbook of Optical Coherence Tomography, Marcel Dekker, Inc., New York.Google Scholar

Bouma, B. E., Tearney, G. J., Compton, C. C. & Nishioka, N. S. (2000), ‘High-resolution imaging of the human esophagus and stomach in vivo using optical coherence tomography’, Gastrointestinal Endoscopy 51, 467–474.CrossRef Google Scholar PubMed

Brezinski, M. E. (2006), Optical Coherence Tomography, Academic Press, Burlington.Google Scholar PubMed

Colston, Jr. B.W, Everett, M. J., Silva, L. B. D., Otis, L. L. & Nathel, H. (1997), ‘Optical coherence tomography for diagnosing periodontal disease’, Proceedings of SPIE 2973, 216–220.Google Scholar

Dalzidel, C. F. (1956), ‘Effect of electric shock on man’, IRE Transactions on Medical Electronics PGME-5, 44–62.

Grade, J. D., Yasumura, K. Y. & Jerman, H. (2004), ‘Advanced, vibration-resistant, comb-drive actuators for use in a tunable laser source’, Sensors and Actuators A 114, 413–422.CrossRef Google Scholar

Huang, D., Swanson, E. A., Lin, C. P., Schuman, J. S., Stinson, W. G., Chang, W., Hee, M. R., Flotte, T., Gregory, K., Puliafito, C. A. & Fujimoto, J. G. (1991), ‘Optical coherence tomography’, Science 254, 1178–1181.CrossRef Google Scholar PubMed

Huber, R., Wojtkowski, M., K., Taira, Fujimoto, J. G. & .Hsu, K. (2006), ‘Amplified, frequency swept lasers for frequency domain reflectrometry and OCT imaging design and scaling principles’, Optics Express 13, 3513–3528.Google Scholar

Isamoto, K., Makino, T., Morosawa, A., Chong, C., Fujita, H. & Toshiyoshi, H. (2005), ‘Self-assembly technique for MEMS vertical comb electrostatic actuator’, IEICE Electronics Express 2, 311–315.CrossRef Google Scholar

Isamoto, K., Totsuka, K., Sakai, T., Suzuki, T., Morosawa, A., Chong, C., Fujita, H. & Toshiyoshi, H. (2011), ‘A high speed MEMS scanner for 140-kHz SS-OCT’, Vol. IEEE Int. Conf. on Optical MEMS and Nanophotonics, Istanbul, Turkey, Aug. 8-11, 2011.Google Scholar

Jones, R. S., Darling, C. L., Featherstone, J. D. B. & Fried, D. (2006), ‘Imaging artificial caries on the occlusal surfaces with polarization-sensitive optical coherence tomography’, Caries Research 40, 81–86.CrossRef Google Scholar PubMed

Kim, K. H., Park, B. H., Maguluri, G. N., Lee, T. W., Rogomentich, F. J., Bancu, M. G., Bouma, B. E., de Boer, J. F. & Bernstein, J. J. (2007), ‘Two-axis magnetically-driven mems scanning catheter for endoscopic high-speed optical coherence tomography’, Optics Express 15, 18130–18140.CrossRef Google Scholar PubMed

Leitgeb, R., Hitzenberger, C. K. & Fercher, A. F. (2003), ‘Performance of Fourier domain vs. time domain optical coherence tomography’, Optics Express 11, 889–894.CrossRef Google Scholar PubMed

Maruyama, S., Nakada, M., Mita, M., Takahashi, T., Fujita, H. & Toshiyoshi, H. (2012), ‘An equivalent circuit model for vertical comb drive MEMS optical scanner controlled by pulse width modulation’, IEEJ. Transactions SM 132, 1–9.CrossRef Google Scholar

Milanovic, V. (2004), ‘Multilevel beam SOI-MEMS fabrication and applications’, Journal of Microelectromechanical Systems 13, 19–30.CrossRef Google Scholar

Nguyen, H. D., Dooyong, H., Patterson, P. R., Rumin, C., Piyawattanametha, W., Lau, E. K. & Wu, M. C. (2004), ‘Angular vertical comb-driven tunable capacitor with high-tuning capabilities’, Journal of Microelectromechanical Systems 13, 403–413.CrossRef Google Scholar

Su, J., Zhang, J., Yu, L. & Chen, Z. (2007), ‘In vivo three-dimensional microelectromechanical endoscopic swept source optical coherence tomography’, Optics Express 15, 10390–10396.CrossRef Google Scholar PubMed

Tanno, N., Ichikawa, T. & Saiki, A. (1990), Japanese Patent 2010042.

Tearney, G. J., Boppart, S. A., Bouma, B. E., Brezinski, M. E., Weissman, N. J., Southern, J. F. & Fujimoto, J. G. (1996), ‘Scanning single-mode fiber optics catheter-endoscope for optical coherence tomography’, Optics Letters 21, 543–545.Google Scholar PubMed

Tearney, G. J., Brezinski, M. E., Bouma, B. E., Boppart, S. A., Pitris, C., Southern, J. F. & Fujimoto, J. G. (1997), ‘In vivo endoscopic optical biopsy with optical coherence tomography’, Science 276, 2037–2039.CrossRef Google Scholar PubMed

Xie, T. Q., Xie, H. K., Fedder, G. K. & Pan, Y. T. (2003), ‘Endoscopic optical coherence tomography with a modified microelectromechanical systems mirror for detection of bladder cancers’, Applied Optics 42, 6422–6426.CrossRef Google Scholar PubMed

Yabushita, H., Bouma, B. E., Houser, S. L., Aretz, H. T., Jang, I. K., Schlendorf, K. H., Kauffman, C. R., Shishkov, M., Kang, D. H., Halpern, E. F. & Tearney, G. J. (2002), ‘Characterization of human atherosclerosis by optical coherence tomography’, Circulatin Journal 106, 1640–1645.Google Scholar PubMed

Yano, T., Saitou, H., Kanbara, N., Noda, R., ichiro Tezuka, S., Fujimura, N., Ooyama, M., Watanabe, T., Hirata, T. & Nishiyama, N. (2009), ‘Wavelength modulation over 500 khz of micromechanically tunable inp-based vcsels with Si-MEMS technology’, IEEE Journal of Selected Topics in Quantum Electronics 15, 528–534.CrossRef Google Scholar

Yoda, M., Isamoto, K., Chong, C., Ito, H., Murata, A. & Toshiyoshi, H. (2005), ‘Design and fabrication of a mems 1-d optical scanner using self-assembled vertical combs and scan-angle magnifying mechanism’, Vol. IEEE/LEOS Int. Conf. on Optical MEMS and Their Applications, August 1-4, 2005, Oulu, Finland.Google Scholar

Yun, S. H., Tearney, G. J., de Boer, J. F., Iftimia, N. & Bouma, B. E. (2003), ‘High-speed optical frequency-domain imaging’, Optical Express 11, 2953–2963.CrossRef Google Scholar PubMed

Accessibility standard: Unknown

Why this information is here

This section outlines the accessibility features of this content - including support for screen readers, full keyboard navigation and high-contrast display options. This may not be relevant for you.

Accessibility Information

Accessibility compliance for the PDF of this book is currently unknown and may be updated in the future.