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Radiological Physics and Technology
Published in: Radiological Physics and Technology 4/2019

01-12-2019 | Magnetic Resonance Imaging

A mask method to assess the uniformity of fat suppression in phantom studies

Authors: Yasuo Takatsu, Masafumi Nakamura, Kenichiro Yamamura, Satoshi Sawa, Masaki Asahara, Michitaka Honda, Tosiaki Miyati

Published in: Radiological Physics and Technology | Issue 4/2019

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Abstract

Fat suppression is a technique used to suppress the signals from adipose tissues, during clinical evaluation of the tissues near the fat–tissue boundary. However, in cases where the scan area has a complicated shape, the effect of fat suppression may demonstrate poor uniformity, resulting in diagnosis-related difficulties. To improve the uniformity of fat suppression, phantom studies are more suitable than volunteer studies. In this study, we evaluated the reliability of the region of interest (ROI) dependency using an unevenness phantom, to develop a method to assess the uniformity of fat suppression while using whole magnetic resonance imaging by masking the surrounding phantom. We modulated different ROI sizes, which were eroded from 100% to approximately 50%, and observed that the normalized absolute average deviation and error increased with decreased ROI. Using our method, more objective, concrete, and accurate data could be obtained by including the whole-body phantom (whole poor uniformity area).
Literature
1.
Bernstein MA, King KF, Zhou XJ. Chapter 4, spectral radiofrequency pulses. In: Bernstein MA, King KF, Zhou XJ, editors. Handbook of MRI pulse sequences. London: Elsevier Academic; 2004. p. 96–124.CrossRef
2.
Bernstein MA, King KF, Zhou XJ. Chapter 5, spatial radiofrequency pulses. In: Bernstein MA, King KF, Zhou XJ, editors. Handbook of MRI pulse sequences. London: Elsevier Academic; 2004. p. 125–76.CrossRef
3.
Bernstein MA, King KF, Zhou XJ. Chapter 6, adiabatic radiofrequency pulses. In: Zhou XJ, editor. Handbook of MRI pulse sequences. London: Elsevier Academic; 2004. p. 177–214.CrossRef
4.
Reeder SB, Yu H, Johnson JW, Shimakawa A, Brittain JH, Pelc NJ, Beaulieu CF, Gold GE. T1- and T2-weighted fast spin-echo imaging of the brachial plexus and cervical spine with IDEAL water-fat separation. J Magn Reson Imaging. 2006;24:825–32.CrossRef
5.
Takatsu Y, Nishiyama K, Miyati T, Miyano H, Kajihara M, Akasaka T. A comparison of shimming techniques for optimizing fat suppression in MR mammography. Radiol Phys Technol. 2013;6:486–91.CrossRef
6.
Rosen Y, Bloch BN, Lenkinski RE, Greenman RL, Marquis RP, Rofsky NM. 3T MR of the prostate: reducing susceptibility gradients by inflating the endorectal coil with a barium sulfate suspension. Magn Reson Med. 2007;57:898–904.CrossRef
7.
Takatsu Y, Kyotani K, Ueyama T, Miyati T, Yamamura K, Andou A. Assessment of the quality of breast MR imaging using the modified Dixon method and frequency-selective fat suppression: a phantom study. Magn Reson Med Sci. 2018;17:350–5.CrossRef
8.
Mirowitz SA, Apicella P, Reinus WR, Hammerman AM. MR imaging of bone marrow lesions: relative conspicuousness on T1-weighted, fat-suppressed T2-weighted, and STIR images. Am J Roentgenol. 1994;162:215–21.CrossRef
9.
Le-Petross H, Kundra V, Szklaruk J, Wei W, Hortobagyi GN, Ma J. Fast three-dimensional dual echo dixon technique improves fat suppression in breast MRI. J Magn Reson Imaging. 2010;31:889–94.CrossRef
10.
National Electrical Manufacturers Association, Determination of image uniformity in diagnostic magnetic resonance images. NEMA Standards Publication MS 3-2008 (NEMA, Rosslyn, VA, 2008), 2008. pp. 1–17.
11.
Otsu N. A threshold selection method from gray-level histograms. IEEE Trans Syst Man Cybern. 1979;9(1):62–6.CrossRef
12.
Kanda Y. Investigation of the freely available easy-to-use software‘EZR’ for medical statistics. Bone Marrow Transpl. 2013;48:452–8.CrossRef
13.
Takatsu Y, Akasaka T, Miyati T. The Dixon technique and the frequency-selective fat suppression technique in three-dimensional T1 weighted MRI of the liver: a comparison of contrast-to-noise ratios of hepatocellular carcinomas-to-liver. Br J Radiol. 2015;88:20150117.CrossRef
Metadata
Title
A mask method to assess the uniformity of fat suppression in phantom studies
Authors
Yasuo Takatsu
Masafumi Nakamura
Kenichiro Yamamura
Satoshi Sawa
Masaki Asahara
Michitaka Honda
Tosiaki Miyati
Publication date
01-12-2019
Publisher
Springer Singapore
Published in
Radiological Physics and Technology / Issue 4/2019
Print ISSN: 1865-0333
Electronic ISSN: 1865-0341
DOI
https://doi.org/10.1007/s12194-019-00531-9

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