Fry, Martin - University College London - Department of medical physics and biomedical engineering

个人简介

Dr Martin Fry has a BSc(Eng) in Electronic and Electrical Engineering from UCL (1985), an MSc in Medical Electronics and Physics from St. Bartholomew’s Hospital, University of London (1986) and a PhD in Physics from the University of Exeter (1990). His PhD research involved the development of a relatively low-cost MRI system targeted for imaging finger joints, and in particular visualising the cartilage. This scanner produced images of 100 micron resolution, which at the time, were the highest resolution MR images achieved of human subjects in vivo. Since 2000 he has been employed as a Lecturer in Medical Electronics at UCL.

研究领域

Dr Martin Fry has substantial experience in developing Medical Electronic Instrumentation and has co-authored over 50 research publications. He has expertise in numerous applications of electronics to medicine including MRI, electrical stimulation of muscles and near infra-red optical tomography - three areas in which the Department of Medical Physics and Bioengineering at UCL undertakes world-class research. For his doctorate he developed a relatively low-cost (£80k) MRI scanner targeted to imaging finger joints, and in particular visualising the cartilage. This scanner produced images of 100 micron resolution, which at the time, were the highest resolution MR images achieved of living human subjects. The concept of a low-cost MRI scanner was commercialised by Surrey Medical Imaging Systems Limited and enabled many groups around the world to undertake affordable MRI research. He has developed computer-controlled instrumentation to compensate for the effects of eddy currents in MRI systems. This instrumentation was subsequently marketed by Magnex Scientific Limited, Oxford, one of the world’s leading suppliers of MRI magnets. In recognition of “Work in the field of research and development in Medical Engineering”, he was awarded the first J A Lodge Award by the Institution of Electrical Engineers. He has also undertaken research into medical, teaching and environmental monitoring applications of small, low-cost, web-enabled microcontrollers for the implementation of web-controlled instrumentation

近期论文

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Chen, B., Fry, M. E., Lambrou, T., Offiah, A. C., & Todd-Pokropek, A. (2008). Multiscale Modeling and Imaging: The Challenges of Osteogenesis Imperfecta. Norton, J. A., Fry, M. E., Day, B. L., & Donaldson, N. (2004). Simple EMG Control of FES-Cycling. Thorntorn, J., Page, R. A., West, D. A., Fry, M. E., & Ordidge, R. J. (2002). A novel, Non-Invasive Method for the Physiological Monitoring of Small Mammals During High-Field Magnetic Resonance Studies. Berkeley, California, USA: International Society for Magnetic Resonance in Medicine (ISMRM. Pollard, J. (2002). A Web-based mobile, medical, monitoring system. Ukraine: Ternopil Acad. of National Economy. Pollard, J. K., Fry, M. E., Rohman, S., Santerelli, C., Theodorous, A., & Mohoboob, N. (2002). Wireless and Web-based Medical Monitoring in the Home. Medical Informatics and Internet in Medicine, 27 (3), 219-227. Pollard, J. K., Rohmans, S., Fry, M. E., & Sachenko, A. (2001). A Web-based Mobile Medical Monitoring System. doi:10.1109/IDAACS.2001.941973 Pollard, J. K., Rohmans, S., & Fry, M. E. (2001). A Web-based Mobile Medical Monitoring System. Proceedings of Ternopil Academy of National Economy(TANE). Coutinho, B. D., Fry, M. F., & Pollard, J. K. (2001). Web-Controlled Instrumentation for Education Applications. The Institution of Electical Engineers, 1, 6-1. Pollard, J. K., Santarelli, C., Theodorou, A., Mohoboob, N., & Fry, M. E. (2001). Wireless and Web-based Medical Monitoring in the Home. Pollard, J. K., Santarelli, C., Theodorou, A., Mohoboob, N., & Fry, M. E. (2001). Wireless and Web-based Medical Monitoring in the Home. Technology and Health Care, 9 (6). Schmidt, F. E. W., Fry, M. E., Hillman, E. M. C., Hebden, J. C., & Delpy, D. T. (2000). A 32 channel time-resolved instrument for medical optical tomography. Review of Scientific Instruments, 71 (1), 256-265. Arridge, S. R., Hebden, J. C., Schweiger, M., Schmidt, F. E., Fry, M. E., Hillman, E. M., . . . Delpy, D. T. (2000). A method for three-dimensional time-resolved optical tomography. International Journal of Imaging Systems and Technology, 11, 2-11. Arridge, S. R., Hebden, J. C., Schwinger, M., Schmidt, F. E. W., Fry, M. E., Hillman, E. M. C., . . . Delpy, D. T. (2000). A method for three-dimensional time-resolved optical tomography. INTERNATIONAL JOURNAL OF IMAGING SYSTEMS AND TECHNOLOGY, 11 (1), 2-11. Peasgood, W., Whitlock, T., Bateman, A., Fry, M. E., Jones, R. S., & Davis-Smith, A. (2000). EMG-controlled closed loop electrical stimulation using a digital signal processor. Electronics Letters, 36 (22), 1832-1833. Hillman, E. M. C., Hebden, J. C., Schmidt, F. E., Arridge, S. R., Fry, M. E., Schweiger, M., & Delpy, D. T. (2000). Initial clinical testing of the UCL 32 channel time-resolved instrument for optical tomography. Biomedical Optical Spectroscopy and Diagnostics, 38, 100-102. Washington, US: Optical Society of America. Hillman, E. M., Hebden, J. C., Schmidt, F. E., Arridge, S. R., Fry, M. E., Schweiger, M., & Delpy, D. T. (2000). Intitial clinical testing of the UCL 32 channel time-resolved instrument for optical tomography. Schmidt, F. E. W., Hebden, J. C., Hillman, E. M. C., Fry, M. E., Schweiger, M., & Delpy, D. T. (2000). Multiple slice imaging of a tissue equivalent phantom using time resolved optical tomography. Applied Optics, 39, 3380-3387. Schmidt, F. E. W., Hebden, J. C., Hillman, E. M. C., Fry, M. E., Schweiger, M., Delpy, D. T., . . . Dehghani, H. (2000). Multiple-slice imaging of a tissue-equivalent phontom by use of time-resolved optical tomography. Applied Optics, 39 (19), 3380-3387. Hebden, J. C., Schmidt, F. E. W., Fry, M. E., Schweiger, M., Hillman, E. M. C., Delpy, D. T., & Arridge, S. (1999). Simultaneous reconstruction of absorption and scattering images using multi-channel measurement of purely temporal data. Optics Letters, 24, 534-536. Schmidt, F., Fry, M. E., Hebden, J. C., & Delpy, D. T. (1998). The development of a 32 channel time resolved optical tomography system. OSA TOPS on Advances in Optical Imaging and Photon Migration, 21, 120-122. Fry, M. E., Pittard, S., Summers, I. R., Vennart, W., & Goldie, F. T. (1997). A programmable eddy-current compensation system for MRI and localized spectroscopy. Journal of Magnetic Resonance Imaging, 7 (2), 455-458. Peasgood, W., Fry, M. E., Whitlock, T., Bateman, A., & Jones, R. (1997). An inexpensive optical fibre based movement sensor for use in closed loop FES control. Whitlock, T., Peasgood, W., Fry, M. E., Bateman, A., & Jones, R. (1997). Self-optimising electrode arrays. Jones, R., Davies-Smith, A., Nuyens, G., Whitlock, T., Peasgood, W., Fry, M. E., & Bateman, A. (1997). The evaluation of people with multiple sclerosis for the use of FES devices. Gasson, J., Summers, I. R., Fry, M. E., & Vennart, W. (1995). Modified birdcage coils for targeted imaging. Magnetic Resonance Imaging, 13 (7), 1003-1012.