Bane, O.
, Hectors, S.
, Wagner, M.
, Arlinghaus, L.
, Aryal, M.
, Cao, Y.
, Chenevert, T.
, Fennessy, F.
, Huang, W.
, Hylton, N.
, Kalpathy-Cramer, J.
, Keenan, K.
, Malyarenko, D.
, Mulkern, R.
, Newitt, D.
, Russek, S.
, Stupic, K.
and Boss, M.
(2017),
Accuracy, repeatability and interplatform reproducibility measurements of T<sub>1</sub> quantification methods used for DCE-MRI: results from a multicenter phantom study., Magnetic Resonance in Medicine, [online], https://tsapps.nist.gov/publication/get_pdf.cfm?pub_id=923148
(Accessed December 13, 2024)
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Accuracy, repeatability and interplatform reproducibility measurements of T1 quantification methods used for DCE-MRI: results from a multicenter phantom study.
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Author(s)
Octavia Bane, Stefanie J. Hectors, Mathilde Wagner, Lori L. Arlinghaus, Madhava P. Aryal, Yue Cao, Thomas L. Chenevert, Fiona Fennessy, Wei Huang, Nola M. Hylton, Jayashree Kalpathy-Cramer, , Dariya I. Malyarenko, Robert V. Mulkern, David C. Newitt, , ,
Abstract
Purpose: To determine the in vitro accuracy, test-retest repeatability, and interplatform reproducibility of T1 quantification protocols used for dynamic contrast-enhanced MRI at 1.5 and 3 T. Methods: A T1 phantom with 14 samples was imaged at eight centers with a common inversion- recovery spin-echo (IR-SE) protocol and a variable flip angle (VFA) protocol using seven flip angles, as well as site-specific protocols (VFA with different flip angles, variable repetition time, proton density, and Look-Locker inversion recovery). Factors influencing the accuracy (deviation from reference NMR T1 measurements) and repeatability were assessed using general linear mixed models. Interplatform reproducibility was assessed using coefficients of variation. Results: For the common IR-SE protocol, accuracy (median error across platforms = 1.4-5.5%) was influenced predominantly by T1 sample (P<10-6), whereas test-retest repeatability (median error = 0.2-8.3%) was influenced by the scanner (P<10-6). For the common VFA protocol, accuracy (median error = 5.7-32.2%) was influenced by field strength (P=0.006), whereas repeatability (median error=0.7-25.8%) was influenced by the scanner (P<0.0001). Interplatform reproducibility with the common VFA was lower at 3 T than 1.5 T (P=0.004), and lower than that of the common IR-SE protocol (coefficient of variation 1.5T: VFA/IR-SE =11.13%/8.21%, P=0.028; 3 T: VFA/IR-SE= 22.87%/5.46%, P=0.001). Among the site-specific protocols, Look-Locker inversion recovery and VFA (2-3 flip angles) protocols showed the best accuracy and repeatability (errors<15%). Conclusions: The VFA protocols with 2 to 3 flip angles optimized for different applications achieved acceptable balance of extensive spatial coverage, accuracy, and repeatability in T1 quantification (errors<15%). Further optimization in terms of flip-angle choice for each tissue application, and the use of B1 correction, are needed to improve the robustness..Citation
Magnetic Resonance in Medicine
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Keywords
MRI, DCE-MRI, T1, repeatability, reproducibility, phantom, VFA, quantitative
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Created August 15, 2017, Updated October 12, 2021