Role of very high order and degree B 0 shimming for spectroscopic imaging of the human brain at 7 tesla

With the advent of ultrahigh field systems (7T), significant improvements in spectroscopic imaging (SI) studies of the human brain have been anticipated. These gains are dependent upon the achievable B 0 homogeneity, both globally (σ B   0 Global , over the entire regions of interest or slice) and locally (σ B   0 Global , influencing the linewidth of individual SI voxels within the regions of interest). Typically the B 0 homogeneity is adjusted using shim coils with spatial distributions modeled on spherical harmonics which can be characterized by a degree (radial dependence) and order (azimuthal symmetry). However, the role of very high order and degree shimming (e.g., 3rd and 4th degree) in MRSI studies has been controversial. Measurements of σ B   0 Globaland σ B   0 Localwere determined from B 0 field maps of 64 × 64 resolution. In a 10 mm thick slice taken through the region of the subcortical nuclei, we find that in comparison to 1st–2nd degree shims, use of 1st–3rd and 1st–4th degree shims reduces σ B   0 Globalby 29% and 55%, respectively. Using a SI voxel size of ∼1cc with an estimate of σ B   0 Localfrom 3 × 3 × 3 B 0 map pixels in this subcortical region, the number of pixels with σ B   0 Localof less than 5 Hz increased from 24 to 59% with 1st–3rd and 1st–4th over 1st–2nd degree shims, respectively. Magn Reson Med, 2012. © 2011 Wiley Periodicals, Inc.