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  • Title: Gradient-controlled local Larmor adjustment (GC-LOLA) for simultaneous multislice bSSFP imaging with improved banding behavior.
    Author: Stäb D, Speier P.
    Journal: Magn Reson Med; 2019 Jan; 81(1):129-139. PubMed ID: 30058197.
    Abstract:
    PURPOSE: Simultaneous multislice (SMS) accelerated balanced SSFP (bSSFP) imaging can be impaired by off-resonance effects, due to slice-specific alterations in the frequency response. In this work, we introduce gradient-controlled local Larmor adjustment as a means to restore the frequency response and to stabilize SMS-accelerated bSSFP imaging with respect to banding artifacts. METHODS: Providing each simultaneously excited slice with an individual RF phase cycle in SMS-accelerated bSSFP imaging results in the sequence's frequency response being shifted slice-specifically along the off-resonance axis. The net available pass-band for imaging is effectively reduced, increasing the measurement's susceptibility toward B0 inhomogeneities. To overcome these issues, gradient-controlled local Larmor adjustment modifies the Larmor frequency locally and aligns the slice-specific frequency responses on resonance by (1) unbalancing the slice gradient by a small constant amount and (2) modifying the RF phase cycles homogeneously across all slices. The concept is investigated using simulations and phantom experiments and applied to SMS-accelerated bSSFP cine cardiovascular MR at 3 T. RESULTS: Phantom and in vivo measurements demonstrate the successful removal of banding artifacts and restoration of the bSSFP frequency response using gradient-controlled local Larmor adjustment. For large slice thicknesses and small slice distances, banding artifacts become slightly widened. CONCLUSION: Gradient-controlled local Larmor adjustment successfully restores the frequency response in SMS-accelerated bSSFP imaging without increasing the sequence's susceptibility toward eddy current effects. The concept facilitates combinations of the different SMS encoding concepts and provides a powerful way to actively control off-resonance effects in slice-accelerated bSSFP imaging.
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