Study of Power Equivalent Continuous Approximation Based on the Recent Consensus Recommendations for Brain Tumor Imaging with Pulsed Chemical Exchange Saturation Transfer at 3T

The quantitative analysis of pulsed-chemical exchange saturation transfer (CEST) using a full model-based method is computationally challenging, as it involves dealing with varying RF values in pulsed saturation. A power equivalent continuous approximation of B1 power was usually applied to accelera...

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Veröffentlicht in:	Magnetic Resonance in Medical Sciences 2024, pp.tn.2024-0069
Hauptverfasser:	Pan, Swee Qi, Hum, Yan Chai, Lai, Khin Wee, Yap, Wun-She, Ong, Chi Wei, Tee, Yee Kai
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Sprache:	eng
Schlagworte:	amide proton transfer chemical exchange saturation transfer continuous approximation discretization method model-based analysis
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creator	Pan, Swee Qi Hum, Yan Chai Lai, Khin Wee Yap, Wun-She Ong, Chi Wei Tee, Yee Kai
description	The quantitative analysis of pulsed-chemical exchange saturation transfer (CEST) using a full model-based method is computationally challenging, as it involves dealing with varying RF values in pulsed saturation. A power equivalent continuous approximation of B1 power was usually applied to accelerate the analysis. In line with recent consensus recommendations from the CEST community for pulsed-CEST at 3T, particularly recommending a high RF saturation power (B1 = 2.0 µT) for the clinical application in brain tumors, this technical note investigated the feasibility of using average power (AP) as the continuous approximation. The simulated results revealed excellent performance of the AP continuous approximation in low saturation power scenarios, but discrepancies were observed in the z-spectra for the high saturation power cases. Cautions should be taken, or it may lead to inaccurate fitted parameters, and the difference can be more than 10% in the high saturation power cases.
doi_str_mv	10.2463/mrms.tn.2024-0069
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subjects	amide proton transfer chemical exchange saturation transfer continuous approximation discretization method model-based analysis
title	Study of Power Equivalent Continuous Approximation Based on the Recent Consensus Recommendations for Brain Tumor Imaging with Pulsed Chemical Exchange Saturation Transfer at 3T
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