Removal of local field gradient artifacts in T2*‐weighted images at high fields by gradient‐echo slice excitation profile imaging

Development of high magnetic field MRI techniques is hampered by the significant artifacts produced by B0 field inhomogeneities in the excited slices. A technique, gradient‐echo slice excitation profile imaging (GESEPI), is presented for recovering the signal lost caused by intravoxel phase dispersion in T2*‐weighted images. This technique superimposes an incremental gradient offset on the slice refocusing gradient to sample Jr‐space over the full range of spatial frequencies of the excitation profile. A third Fourier transform of the initial two‐dimensional image set generates an image set in which the artifacts produced by the low‐order B0 inhomogeneity field gradients in the sample are separated and removed from the high‐order microscopic field gradients responsible for T2* contrast. Application to high field brain imaging, at 3.0 T for human and at 9.4 T for immature rat imaging demonstrates the significant improvement in quality of the T2*‐weighted contrast images.

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