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RESEARCH PRODUCT
Liver methylene fraction by dual- and triple-echo gradient-echo imaging at 3.0T: Correlation with proton MR spectroscopy and estimation of robustness after SPIO administration
David MassonPatrick HillonIsabelle RobinRomaric LoffroyGuiu BorisSerge AhoJean-michel PetitBruno VergèsJean-pierre CercueilDouraied Ben SalemDenis Krausésubject
MaleMagnetic Resonance SpectroscopyMESH : Fatty LiverMESH: Echo-Planar Imaging[SDV]Life Sciences [q-bio]Carbon Compounds InorganicMESH : Statistics as TopicStatistics as TopicMESH : AgedContrast MediaMESH : Carbon Compounds InorganicMESH : Tissue Distribution030218 nuclear medicine & medical imagingCorrelationchemistry.chemical_compound0302 clinical medicineMESH : DextransNon-alcoholic Fatty Liver DiseaseMESH : FemaleTissue DistributionMESH: DextransMethyleneMagnetite NanoparticlesMESH: Fatty LiverMESH: AgedMESH: Middle Agedmedicine.diagnostic_testEcho-Planar ImagingDextransNuclear magnetic resonance spectroscopyMESH : AdultMiddle AgedMESH: Reproducibility of ResultsAdipose TissueLiverFemale030211 gastroenterology & hepatologyMESH : Sensitivity and SpecificityProtonsMESH: Adipose TissueAdultIron OverloadMESH : MaleMESH: Magnetite NanoparticlesMESH : Adipose TissueSensitivity and SpecificityMESH: Iron Overload03 medical and health sciencesFlip angleRobustness (computer science)MESH: Contrast MediaLinear regressionmedicineMESH : ProtonsHumansMESH : Middle AgedRadiology Nuclear Medicine and imagingMESH: Tissue DistributionMESH: Statistics as TopicAgedMESH : Contrast MediaMESH : Iron OverloadMESH: HumansMESH : Echo-Planar Imaging[ SDV ] Life Sciences [q-bio]MESH: Magnetic Resonance Spectroscopybusiness.industryMESH : Reproducibility of ResultsMESH : HumansMESH: Biological MarkersMESH: Carbon Compounds InorganicMESH : LiverMESH : Magnetite NanoparticlesReproducibility of ResultsMESH: AdultMagnetic resonance imagingMESH: MaleMESH: Sensitivity and SpecificityProton mr spectroscopyMESH : Biological MarkersFatty LiverchemistryMESH : Magnetic Resonance SpectroscopyMESH: ProtonsNuclear medicinebusinessMESH: FemaleBiomarkersMESH: Liverdescription
Purpose To assess the systematic errors in liver methylene fraction (LMF) resulting from fat–fat interference effects with dual- and triple-echo gradient-recalled-echo Dual/Triple GRE) sequences and to test the robustness of these sequences after iron overloading. Materials and Methods Forty type-2 diabetic patients underwent LMF measurement by 3.0T 1H magnetic resonance spectroscopy (corrected for T1 and T2 decays) as the reference standard and liver fat fraction (%Fat) measurement by four Dual/Triple GRE sequences with 20° and 60° flip angle (α), corrected for T1 recovery. The same four sequences were repeated in eight patients after ferumoxide injection. Corrections for systematic errors were determined from the linear regressions (spectroscopy LMF values over Dual/Triple GRE %Fat values). Robustness was tested using Wilcoxon's signed-rank test. Results Fat–fat interference effects produced a ∼10% relative systematic error and T2* decay produced a 1.9%–4.2% absolute systematic error in LMF. When comparing before and after ferumoxide, dual-echo imaging with α = 20° and α = 60°, even when corrected, showed absolute differences of 7.23% [2.81%–10.25%] (P = 0.0117) and 5.65% [1.89%–8.216.8%] (P = 0.0117), respectively; compared to only 1.17% [0.08%–2.83%] (P = 0.0251) and 1.15% [0.37%–2.73%] (P = 0.2626) with triple-echo imaging and α = 20° and α = 60°, respectively. Conclusion Triple-echo imaging with α = 60° corrected for both T1 recovery and fat–fat interference effects is robust after superparamagnetic iron oxide (SPIO) administration and can reliably quantify LMF. J. Magn. Reson. Imaging 2011;33:119–127. © 2010 Wiley-Liss, Inc.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2011-01-01 | Journal of Magnetic Resonance Imaging |