Название | Magnetic Resonance Microscopy |
---|---|
Автор произведения | Группа авторов |
Жанр | Химия |
Серия | |
Издательство | Химия |
Год выпуска | 0 |
isbn | 9783527827251 |
Acknowledgments
The authors would like to thank Jason Stockmann, Patrick McDaniel, Thomas Witzel, Mathew Rosen, and Abitha Srivnivas for their extensive technical help, and John Conklin, Sarah Bates, Farrah Mateen, and Michael Lev for their input to the clinical issues surrounding portable and POC MRI. We thank Alex Barksdale for the superconducting magnet optimizations. Research reported in this publication was supported by the National Institute of Biomedical Imaging and Bioengineering of the National Institutes of Health under award number R01EB018976.
References
1 1 Buller, M.and Karis, J.P. (2017). Introduction of a dedicated emergency department MR imaging scanner at the Barrow Neurological Institute. American Journal of Neuroradiology 38 (8): 1480–1485.
2 2 Redd, V., Levin, S., Toerper, M.et al. (2015). Effects of fully accessible magnetic resonance imaging in the emergency department. Academic Emergency Medicine 22 (6): 741–749.
3 3 Sanchez, Y., Yun, B.J., Prabhakar, A.M.et al. (2017). Magnetic resonance imaging utilization in an emergency department observation unit. The Western Journal of Emergency Medicine 18 (5): 780–784.
4 4 Manna, S., Voutsinas, N., Maron, S.Z.et al. (2020). Leveraging IR’s adaptability during COVID-19: A multicenter single urban health system experience. Journal of Vascular and Interventional Radiology 31 (7): 1192–1194.
5 5 Jacobi, A., Chung, M., Bernheim, A.et al. (2020). Portable chest X-ray in coronavirus disease-19 (COVID-19): A pictorial review. Clinical Imaging 64: 35–42.
6 6 Chung, M., Bernheim, A., Mei, X.et al. (2020). CT imaging features of 2019 novel coronavirus (2019-nCoV). Radiology 295 (1): 202–207.
7 7 El Homsi, M., Chung, M., Bernheim, A.et al. (2020). Review of chest CT manifestations of COVID-19 infection. European Journal of Radiology Open 7: 100239.
8 8 Smith, M.J., Hayward, S.A., Innes, S.M.et al. (2020). Point-of-care lung ultrasound in patients with COVID-19 – A narrative review. Anaesthesia 75: 1096–1104.
9 9 Kandemirli, S.G., Dogan, L., Sarikaya, Z.T.et al. (2020). Brain MRI findings in patients in the intensive care unit with COVID-19 infection. Radiology 297: 201697.
10 10 Ogbole, G.I., Adeyomoye, A.O., Badu-Peprah, A.et al. (2018). Survey of magnetic resonance imaging availability in West Africa. The Pan African Medical Journal 30: 240.
11 11 Geethanath, S.and Vaughan, J.T., Jr. (2019). Accessible magnetic resonance imaging: A review. Journal of Magnetic Resonance Imaging 49 (7): e65–e77.
12 12 Lazaro, P., Beerra, A., Luengo, S.et al. (1994). Health care expenditures and expensive medical technology; the paradox of low-income countries. Annual Meeting International Society of Technology Assessment in Health Care, Baltimore USA.
13 13 Saslow, E. (2019). “Out here, it’s just me”: In the medical desert of rural America, one doctor for 11,000 square miles. The Washington Post 28 September.
14 14 panel discussion (2019). ISMRM Workshop on Accessible MRI. New Delhi, India.
15 15 Wald, L.L., McDaniel, P.C., Witzel, T.et al. (2020). Low-cost and portable MRI. Journal of Magnetic Resonance Imaging 52 (3): 686–696.
16 16 Nakagomi, M., Kajiwara, M., Matsuzaki, J.et al. (2019). Development of a small car-mounted magnetic resonance imaging system for human elbows using a 0.2T permanent magnet. Journal of Magnetic Resonance 304: 1–6.
17 17 Coffey, A.M., Truong, M.L., and Chekmenev, E.Y. (2013). Low-field MRI can be more sensitive than high-field MRI. Journal of Magnetic Resonance 237: 169–174.
18 18 Marques, J.P., Simonis, F.F.J., Webb, A.G., and Low-field, M.R.I. (2019). An MR physics perspective. Journal of Magnetic Resonance Imaging 49 (6): 1528–1542.
19 19 O’Reilly, T.and Webb, A. (2019). Deconstructing and reconstructing MRI hardware. Journal of Magnetic Resonance 306: 134–138.
20 20 Cooley, C.Z., McDaniel, P.C., Stockmann, J.P.et al. (2021). A portable scanner for magnetic resonance imaging of the brain. Nature Biomedical Engineering 5 (3): 229–239.
21 21 Cooley, C.Z., Stockmann, J.P., Armstrong, B.D.et al. (2014). 2D imaging in a lightweight portable MRI scanner without gradient coils. Proceedings of the ISMRM Annual Meeting, Milan, Italy.
22 22 Cooley, C.Z., Stockmann, J.P., Armstrong, B.D.et al. (2015). Two-dimensional imaging in a lightweight portable MRI scanner without gradient coils. Magnetic Resonance in Medicine 73 (2): 872–883.
23 23 Blumler, P. (2016). Proposal for a permanent magnet system with a constant gradient mechanically adjustable in direction and strength. Concepts in Magnetic Resonance. Part B, Magnetic Resonance Engineering 46 (1): 41–48.
24 24 Ren, Z.H., Maréchal, L., Luo, W.et al. (2015). Magnet array for a portable magnetic resonance imaging system. 2015 IEEE MTT-S 2015 International Microwave Workshop Series on RF and Wireless Technologies for Biomedical and Healthcare Applications (IMWS-BIO), Taipei, Taiwan.
25 25 Ren, Z.H., Obruchkov, S., Lu, D.W.et al. (2017). A low-field portable magnetic resonance imaging system for head imaging. 2017 Progress in Electromagnetics Research Symposium – Fall (PIERS – FALL), Singapore.
26 26 McDaniel, P.C., Cooley, C.Z., Stockmann, J.P.et al. (2019). The MR cap: A single-sided MRI system designed for potential point-of-care limited field-of-view brain imaging. Magnetic Resonance in Medicine in press 82 (5): 1946–1950.
27 27 Vogel, M.W., Giorni, A., Vegh, V.et al. (2016). Rotatable small permanent magnet array for ultra-low field nuclear magnetic resonance instrumentation: A concept study. PLoS ONE 11 (6): e0157040.
28 28 Runge, V.M.and Heverhagen, J.T. (2020). The next generation- advanced design low-field MR systems. Siemens Magnetom Flash Special Issue: Head-to-toe Imaging: 11–19.
29 29 Mohr, C. (2002). The Siemens ultra high-field program MAGNETOM Allegra and Trio 3T MR: The next dimension in clinical and research MR systems. Siemens Magnetom Flash 1: 21–22.