Estimation of hepatic proton-density fat fraction by using MR imaging at 3.0 T
T Yokoo, M Shiehmorteza, G Hamilton, T Wolfson… - Radiology, 2011 - pubs.rsna.org
Radiology, 2011•pubs.rsna.org
Purpose To compare the accuracy of several magnetic resonance (MR) imaging–based
methods for hepatic proton-density fat fraction (FF) estimation at 3.0 T, with spectroscopy as
the reference technique. Materials and Methods This prospective study was institutional
review board approved and HIPAA compliant. Informed consent was obtained. One hundred
sixty-three subjects (39 with known hepatic steatosis, 110 with steatosis risk factors, 14
without risk factors) underwent proton MR spectroscopy and non–T1-weighted gradient …
methods for hepatic proton-density fat fraction (FF) estimation at 3.0 T, with spectroscopy as
the reference technique. Materials and Methods This prospective study was institutional
review board approved and HIPAA compliant. Informed consent was obtained. One hundred
sixty-three subjects (39 with known hepatic steatosis, 110 with steatosis risk factors, 14
without risk factors) underwent proton MR spectroscopy and non–T1-weighted gradient …
Purpose
To compare the accuracy of several magnetic resonance (MR) imaging–based methods for hepatic proton-density fat fraction (FF) estimation at 3.0 T, with spectroscopy as the reference technique.
Materials and Methods
This prospective study was institutional review board approved and HIPAA compliant. Informed consent was obtained. One hundred sixty-three subjects (39 with known hepatic steatosis, 110 with steatosis risk factors, 14 without risk factors) underwent proton MR spectroscopy and non–T1-weighted gradient-echo MR imaging of the liver. At spectroscopy, the reference FF was determined from frequency-selective measurements of fat and water proton densities. At imaging, FF was calculated by using two-, three-, or six-echo methods, with single-frequency and multifrequency fat signal modeling. The three- and six-echo methods corrected for T2*; the two-echo methods did not. For each imaging method, the fat estimation accuracy was assessed by using linear regression between the imaging FF and spectroscopic FF. Binary classification accuracy of imaging was assessed at four reference spectroscopic thresholds (0.04, 0.06, 0.08, and 0.10 FF).
Results
Regression intercept of two-, three-, and six-echo methods were −0.0211, 0.0087, and −0.0062 (P <.001 for all three) without multifrequency modeling and −0.0237 (P <.001), 0.0022, and −0.0007 with multifrequency modeling, respectively. Regression slope of two-, three-, and six-echo methods were 0.8522, 0.8528, and 0.7544 (P <.001 for all three) without multifrequency modeling and 0.9994, 0.9775, and 0.9821 with multifrequency modeling, respectively. Significant deviation of intercept and slope from 0 and 1, respectively, indicated systematic error. Classification accuracy was 82.2%–90.1%, 93.9%–96.3%, and 83.4%–89.6% for two-, three-, and six-echo methods without multifrequency modeling and 88.3%–92.0%, 95.1%–96.3%, and 94.5%–96.3% with multifrequency modeling, respectively, depending on the FF threshold. T2*-corrected (three- and six-echo) multifrequency imaging methods had the overall highest FF estimation and classification accuracy. Among methods without multifrequency modeling, the T2*-corrected three-echo method had the highest accuracy.
Conclusion
Non–T1-weighted MR imaging with T2* correction and multifrequency modeling helps accurately estimate hepatic proton-density FF at 3.0 T.
© RSNA, 2011
Radiological Society of North America