J Cardiovasc Magn Reson. 2026 Mar 18:102717. doi: 10.1016/j.jocmr.2026.102717. Online ahead of print.
ABSTRACT
BACKGROUND: Myocardial T2 mapping enables non-invasive assessment of inflammation and oedema. However, in patients with implantable cardiac devices, such as pacemakers or defibrillators (ICDs), off-resonance effects often cause severe image artefacts and inaccurate T2 values.
PURPOSE: The aim of this study was to develop and evaluate a wideband T2-prepared gradient-echo (GRE) myocardial T2 mapping sequence combined with an advanced patch-based denoising approach, designed to reduce artefacts and improve image quality in device-implanted patients at 1.5T.
METHODS: A T2 preparation with wideband adiabatic refocusing pulses (5.0kHz bandwidth) was integrated into a breath-held 2D GRE T2 mapping sequence (TE = 0/27/55 ms). Patch-based denoising was applied after image reconstruction. The sequence was tested in a phantom, eight healthy volunteers with and without ICDs placed on their chests, thirteen patients without devices, seven patients with ICDs or pacemakers, and one sheep scanned before and after induced myocardial infarction with and without external ICD. The proposed sequence was compared against reference conventional GRE and balanced steady-state free-precession (bSSFP) T2 mapping. Patch-based denoising was optimized in patients without devices and impact on T2 precision and accuracy was assessed. Phantom studies included Bland-Altman and correlation analyses between the sequences. In-vivo performance was assessed through global and segmental T2 quantification, coefficient of variation (COV), artefact scoring, and oedema detection. ANOVA with Bonferroni correction and pairwise testing were used for statistical comparisons.
RESULTS: In subjects without devices, wideband and conventional GRE T2 mapping yielded comparable T2 values (P=0.60). With ICDs, conventional GRE T2 mapping underestimated global T2 by 16% (P<0.001) and increased segmental COV up to 30%. In contrast, wideband GRE T2 mapping provided accurate T2 values (P=0.56) and preserved oedema detection, showing relative T2 elevations of 44% comparable to bSSFP. Patch-based denoising significantly improved precision (P=0.006) without biasing mean values (P=0.999). Results were consistent across phantom, volunteer, patient, and animal experiments, including animal ex-vivo histology confirmation.
CONCLUSION: Wideband GRE T2 mapping substantially reduced device-related artefacts, provided accurate T2 values, and allowed oedema detection, offering a clinically feasible solution for patients with cardiac implants in this initial study.
PMID:41861915 | DOI:10.1016/j.jocmr.2026.102717