Improved R2* measurement in myocardial iron overload

Abstract

Purpose: To optimize R2*(1/T2*) measurements for cardiac iron detection in sickle cell and thalassemia patients. Materials suad Methods: We studied 31 patients with transfusion-dependent sickle cell disease and 48 patients with thalassemia major; myocardial R2* was assessed in a single midpapillary slice using a gated gradient-echo pulse sequence. Pixel-wise maps were coregistered among the patients to determine systematic spatial fluctuations in R2*. The contributions of minimum TE, echo spacing, signal-decay model, and region-of-interest (ROI) choice were compared in synthetic and acquired images. Results: Cardiac relaxivity demonstrated characteristic circumferential variations regardless of the degree of iron overload. Within the interventricular septum, a gradient in R2* from right to left ventricle was noted at high values. Pixel-wise and ROI techniques yielded nearly identical values. Signal decay was exponential but a constant offset or second exponential term was necessary to avoid underestimation at high iron concentration. Systematic underestimation of R2* was observed for higher minimum TE, limiting the range of iron concentrations that can be profiled. Fat-water oscillations, although detectable, represented only 1% of the total signal. Conclusion: Clinical cardiac R2* measurements should be restricted to the interventricular septum and should have a minimum TE ≤ 2 msec. ROI analysis techniques are accurate; however, offset-correction is essential. © 2005 Wiley-Liss, Inc.