| Abstrakt: |
Purpose: Design an efficient CEST scheme for exchange‐dependent images with high contrast‐to‐noise ratio. Theory: Reassembled saturation transfer (REST) signals were defined as Δ$$ \Delta $$r.Z = r.Zref ‐ r.ZCEST and the reassembled exchange‐dependen magnetization transfer ratio r.MTRRex = r.1/Zref ‐ r.1/ZCEST, utilizing the averages over loosely sampled reference frequency offsets as Zref and over densely sampled target offsets as ZCEST. Using r.MTRRex measured under 2 B1,sat values, exchange rate could be estimated. Methods: The REST approach was optimized and assessed quantitatively by simulations for various exchange rates, pool concentration, and water T1. In vivo evaluation was performed on ischemic rat brains at 7 Tesla and human brains at 3 Tesla, in comparison with conventional asymmetrical analysis, Lorentzian difference (LD), an MTRRex_LD. Results: For a broad choice of Δωref$$ \Delta {\omega}_{ref} $$ ranges and numbers, Δr.Z and r.MTRRex exhibited comparable quantification features with conventional LD and MTRRex_LD, respectively, when B1,sat ≤ 1 μT. The subtraction of 2 REST values under distinct B1,sat values showed linear relationships with exchange rate and obtained immunity to field inhomogeneity and variation in MT and water T1. For both rat and human studies, REST images exhibited similar contrast distribution to MTRRex_LD, with superiority in contrast‐to‐noise ratio and acquisition efficiency. Compared with MTRRex_LD, 2‐B1,sat subtraction REST images displayed better resistance to B1 inhomogeneity, with more specific enhanced regions. They also showed higher signals for amide than for nuclear Overhauser enhancement effect in human brain, presumably reflecting the higher increment from faster‐exchanging species as B1,sat increased. Conclusion: Featuring high contrast‐to‐noise ratio efficiency, REST could be a practical exchange‐dependent approach readily applicable to either retrospective Z‐spectra analysis or perspective 6‐offset acquisition. [ABSTRACT FROM AUTHOR] |
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