Nanodiamond phantoms mimicking human liver: perspective to calibration of T1 relaxation time in magnetic resonance imaging
Abstract
Phantoms of biological tissues are materials that mimic the properties of real tissues. This study shows the development of phantoms with nanodiamond particles for calibration of T1 relaxation time in magnetic resonance imaging. Magnetic resonance imaging (MRI) is a commonly used and non-invasive method of detecting pathological changes inside the human body. Nevertheless, before a new MRI device is approved for use, it is necessary to calibrate it properly and to check its technical parameters. In this article, we present phantoms of tissue with diamond nanoparticles dedicated to magnetic resonance calibration. The method of producing phantoms has been described. As a result of our research, we obtained phantoms that were characterized by the relaxation time T1 the same as the relaxation time of the human tissue T1 = 810.5 ms. Furthermore, the use of diamond nanoparticles in phantoms allowed us to tune the T1 value of the phantoms which open the way to elaborated phantoms of other tissues in the future.
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- Category:
- Articles
- Type:
- artykuły w czasopismach
- Published in:
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Scientific Reports
no. 10,
pages 1 - 6,
ISSN: 2045-2322 - Language:
- English
- Publication year:
- 2020
- Bibliographic description:
- Sękowska A., Majchrowicz D., Sabisz A., Ficek M., Bułło-Piontecka B., Kosowska M., Jing L., Bogdanowicz R., Szczerska M.: Nanodiamond phantoms mimicking human liver: perspective to calibration of T1 relaxation time in magnetic resonance imaging// Scientific Reports -Vol. 10,iss. 1 (2020), s.1-6
- DOI:
- Digital Object Identifier (open in new tab) 10.1038/s41598-020-63581-9
- Bibliography: test
-
- Chrysikopoulos, H. S., Clinical MR Imaging and Physics: A Tutorial, Springer (2009).
- Grover, V. P. B. et al. Magnetic Resonance Imaging: Principles and Techniques: Lessons for Clinicians. Journal of Clinical and Experimental Hepatology 5, 246-255 (2015). open in new tab
- Ridgway, J. P. Cardiovascular magnetic resonance physics for clinicians: part I. Journal of Cardiovascular Magnetic Resonance 12, 71 (2010). open in new tab
- Chundru, S. et al. MRI of diffuse liver disease: characteristics of acute and chronic diseases. Diagn Interv Radiol 20, 200-208 (2014). open in new tab
- Tang, X. et al. Magnetic resonance imaging relaxation time in Alzheimer's disease. Brain Research Bulletin 140, 176-189 (2018). open in new tab
- Feder, I., Duadi, H. & Fixler, D. Experimental system for measuring the full scattering profile of circular phantoms. Biomed Opt Express 6, 2877-2886 (2015). open in new tab
- Esenaliev, R. O., Larin, K. V., Larina, I. V. & Motamedi, M. Noninvasive monitoring of glucose concentration with optical coherence tomography. Opt. Lett., OL 26, 992-994 (2001). open in new tab
- Pogue, B. W. & Patterson, M. S. Review of tissue simulating phantoms for optical spectroscopy, imaging and dosimetry. J Biomed Opt 11, 041102 (2006). open in new tab
- Feder, I., Duadi, H., Dreifuss, T. & Fixler, D. The influence of the blood vessel diameter on the full scattering profile from cylindrical tissues: experimental evidence for the shielding effect. Journal of Biophotonics 9, 1001-1008 (2016). open in new tab
- Dehghani, H., Pogue, B. W., Jiang, S., Poplack, S. P. & Paulsen, K. D. Optical images from pathophysiological signals within breast tissue using three-dimensional near-infrared light. In Optical Tomography and Spectroscopy of Tissue V vol. 4955 191-198 (2013). open in new tab
- Dehghani, H., Pogue, B. W., Shudong, J., Brooksby, B. & Paulsen, K. D. Three-dimensional optical tomography: resolution in small- object imaging. Appl Opt 42, 3117-3128 (2003). open in new tab
- Yoshimura, K. et al. Development of a tissue-equivalent MRI phantom using carrageenan gel. Magnetic Resonance in Medicine 50, 1011-1017 (2003). open in new tab
- Hattori, K. et al. Development of MRI phantom equivalent to human tissues for 3.0-T MRI. Med Phys 40, 032303 (2013). open in new tab
- Mano, I., Goshima, H., Nambu, M. & Iio, M. New polyvinyl alcohol gel material for MRI phantoms. Magnetic Resonance in Medicine 3, 921-926 (1986). open in new tab
- Bae, K. T., Commean, P. K. & Lee, J. Volumetric measurement of renal cysts and parenchyma using MRI: phantoms and patients with polycystic kidney disease. J Comput Assist Tomogr 24, 614-619 (2000). open in new tab
- Ohno, S. et al. Production of a human-tissue-equivalent MRI phantom: optimization of material heating. Magn Reson Med Sci 7, 131-140 (2008). open in new tab
- Hellerbach, A., Schuster, V., Jansen, A. & Sommer, J. MRI Phantoms -Are There Alternatives to Agar? PLOS ONE 8, e70343 (2013). open in new tab
- Kato, H. et al. Composition of MRI phantom equivalent to human tissues. Med Phys 32, 3199-3208 (2005). open in new tab
- Shenderova, O., Hens, S. & McGuire, G. Seeding slurries based on detonation nanodiamond in DMSO. Diamond and Related Materials 19, 260-267 (2010). open in new tab
- Nunn, N. & Shenderova, O. Toward a golden standard in single digit detonation nanodiamond. physica status solidi (a) 213, 2138-2145 (2016). open in new tab
- Wojciechowski, A. M. et al. Optical Magnetometry Based on Nanodiamonds with Nitrogen-Vacancy Color Centers. Materials 12, 2951 (2019). open in new tab
- Hasgall, P. A. et al. IT'IS Database for thermal and electromagnetic parameters of biological tissues, Version 4.0, (May 15, 2018).
- Bazrafshan, B. et al. A liver-mimicking MRI phantom for thermal ablation experiments. Med Phys 38, 2674-2684 (2011). open in new tab
- Brzozowski, P., Penev, K. I., Martinez, F. M., Scholl, T. J. & Mequanint, K. Gellan gum-based gels with tunable relaxation properties for MRI phantoms. Magn Reson Imaging 57, 40-49 (2019). open in new tab
- Baxi, J. et al. Retina-simulating phantom for optical coherence tomography. J Biomed Opt 19, 21106 (2014). open in new tab
- Wróbel, M. S., Popov, A. P., Bykov, A. V., Tuchin, V. V. & Jędrzejewska-Szczerska, M. Nanoparticle-free tissue-mimicking phantoms with intrinsic scattering. Biomed. Opt. Express, BOE 7, 2088-2094 (2016). open in new tab
- Sources of funding:
-
- Program DS Wydziału Elektroniki, Telekomunikacji i Informatyki Politechniki Gdańskiej
- Narodowa Agencja Wymiany Akedemickiej, Program im. Bekkera PPN/BEK/2018/1/00185
- Narodowa Agencja Wymiany Akedemickiej, Program im. Iwanowskiej PPN/IWA/2018/1/00026/U/00001
- Narodowe Centrum Nauki, projekt Preludium, 2017/25/N/ST7/01610
- Fundacja na rzecz Nauki Polskiej, projekt Team-NET No. POIR.04.04.00-00-1644/1
- Verified by:
- Gdańsk University of Technology
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