Abstract
PURPOSE: To optimize pseudo-continuous arterial spin labeling (PCASL) parameters to maximize SNR efficiency for RF power constrained whole brain perfusion imaging at 7 T. METHODS: We used Bloch simulations of pulsatile laminar flow to optimize the PCASL parameters for maximum SNR efficiency, balancing labeling efficiency and total RF power. The optimization included adjusting the inter-RF pulse spacing (TR(PCASL)), mean B(1) (+) (B(1) (+) (ave)), slice-selective gradient amplitude (G(max)), and mean gradient amplitude (G(ave)). In vivo data were acquired from six volunteers at 7 T to validate the optimized parameters. Dynamic B(0)-shimming and flip angle adjustments were used to avoid needing to make the PCASL parameters robust to B(0)/B(1) (+) variations. RESULTS: The optimized PCASL parameters achieved a significant (3.3×) reduction in RF power while maintaining high labeling efficiency. This allowed for longer label durations and minimized deadtime, resulting in a 118% improvement in SNR efficiency in vivo compared to a previously proposed protocol. Additionally, the static tissue response was improved, reducing the required distance between labeling plane and imaging volume. CONCLUSION: These optimized PCASL parameters provide a robust and efficient approach for whole brain perfusion imaging at 7 T, with significant improvements in SNR efficiency and reduced specific absorption rate burden.