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Test–Retest Reproducibility of In Vivo Magnetization Transfer Ratio and Saturation Index in Mice at 9.4 Tesla
Author(s) -
Rahman Naila,
Ramnarine Jordan,
Xu Kathy,
Brown Arthur,
Baron Corey A.
Publication year - 2022
Publication title -
journal of magnetic resonance imaging
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.563
H-Index - 160
eISSN - 1522-2586
pISSN - 1053-1807
DOI - 10.1002/jmri.28106
Subject(s) - reproducibility , nuclear medicine , magnetization transfer , coefficient of variation , region of interest , medicine , voxel , nuclear magnetic resonance , bland–altman plot , magnetic resonance imaging , biomedical engineering , materials science , radiology , mathematics , limits of agreement , physics , statistics
Background Magnetization transfer saturation (MTsat) imaging was developed to reduce T1 dependence and improve specificity to myelin, compared to the widely used MT ratio (MTR) approach, while maintaining a feasible scan time. As MTsat imaging is an emerging technique, the reproducibility of MTsat compared to MTR must be evaluated. Purpose To assess the test–retest reproducibility of MTR and MTsat in the mouse brain at 9.4 T and calculate sample sizes potentially required to detect effect sizes ranging from 6% to 14%. Study Type Prospective. Subjects Twelve healthy C57Bl /6 mice. Field Strength/Sequence 9.4 T; magnetization transfer imaging using FLASH‐3D Gradient Echo; T2 ‐weighted TurboRARE spin echo. Assessment All mice were scanned at two timepoints (5 days apart). MTR and MTsat maps were analyzed using mean region‐of‐interest (ROIs: corpus callosum [CC], internal capsule [IC], hippocampus [HC], cortex [CX], and thalamus [TH]), and whole brain voxel‐wise analysis. Statistical Tests Bland–Altman plots were used to assess biases between test–retest measurements. Test–retest reproducibility was evaluated via between and within‐subject coefficients of variation (bsCV and wsCV, respectively). Sample sizes required were calculated (significance level: 95%; power: 80%), given effect sizes ranging from 6% to 14%, using both between and within‐subject approaches. Results were considered statistically significant at P ≤ 0.05. Results Bland–Altman plots showed negligible biases between test–retest sessions (MTR: 0.0009; MTsat: 0). ROI‐based and voxel‐wise CVs revealed high reproducibility for both MTR (ROI‐bsCV/wsCV: CC—4.5/2.8%; IC—6.1/5.2%; HC—5.7/4.6%; CX—5.1/2.3%; TH—7.4/4.9%) and MTsat (ROI‐bsCV/wsCV: CC—6.3/4.8%; IC—7.3/5.1%; HC—9.5/6.4%; CX—6.7/6.5%; TH—7.2/5.3%). With a sample size of 6, changes on the order of 15% could be detected in MTR and MTsat, both between and within subjects, while smaller changes (6%–8%) required sample sizes of 10–15 for MTR, and 15–20 for MTsat. Data Conclusion MTsat exhibited comparable reproducibility to MTR, while providing sensitivity to myelin with less T1 dependence than MTR. Evidence Level 2 Technical Efficacy Stage 1