用于定量心肌T1映射的饱和脉冲设计
Saturation pulse design for quantitative myocardial T1 mapping.
作者信息
Chow Kelvin, Kellman Peter, Spottiswoode Bruce S, Nielles-Vallespin Sonia, Arai Andrew E, Salerno Michael, Thompson Richard B
机构信息
Department of Biomedical Engineering, Faculty of Medicine and Dentistry, 1082 Research Transition Facility, University of Alberta, Edmonton, AB, T6G 2V2, Canada.
National Institutes of Health, Department of Health and Human Services, National Heart, Lung and Blood Institute, Bethesda, MD, USA.
出版信息
J Cardiovasc Magn Reson. 2015 Oct 1;17:84. doi: 10.1186/s12968-015-0187-0.
BACKGROUND
Quantitative saturation-recovery based T1 mapping sequences are less sensitive to systematic errors than the Modified Look-Locker Inversion recovery (MOLLI) technique but require high performance saturation pulses. We propose to optimize adiabatic and pulse train saturation pulses for quantitative T1 mapping to have <1 % absolute residual longitudinal magnetization (|MZ/M0|) over ranges of B0 and [Formula: see text] (B1 scale factor) inhomogeneity found at 1.5 T and 3 T.
METHODS
Design parameters for an adiabatic BIR4-90 pulse were optimized for improved performance within 1.5 T B0 (±120 Hz) and [Formula: see text] (0.7-1.0) ranges. Flip angles in hard pulse trains of 3-6 pulses were optimized for 1.5 T and 3 T, with consideration of T1 values, field inhomogeneities (B0 = ±240 Hz and [Formula: see text]=0.4-1.2 at 3 T), and maximum achievable B1 field strength. Residual MZ/M0 was simulated and measured experimentally for current standard and optimized saturation pulses in phantoms and in-vivo human studies. T1 maps were acquired at 3 T in human subjects and a swine using a SAturation recovery single-SHot Acquisition (SASHA) technique with a standard 90°-90°-90° and an optimized 6-pulse train.
RESULTS
Measured residual MZ/M0 in phantoms had excellent agreement with simulations over a wide range of B0 and [Formula: see text]. The optimized BIR4-90 reduced the maximum residual |MZ/M0| to <1 %, a 5.8× reduction compared to a reference BIR4-90. An optimized 3-pulse train achieved a maximum residual |MZ/M0| <1 % for the 1.5 T optimization range compared to 11.3 % for a standard 90°-90°-90° pulse train, while a 6-pulse train met this target for the wider 3 T ranges of B0 and [Formula: see text]. The 6-pulse train demonstrated more uniform saturation across both the myocardium and entire field of view than other saturation pulses in human studies. T1 maps were more spatially homogeneous with 6-pulse train SASHA than the reference 90°-90°-90° SASHA in both human and animal studies.
CONCLUSIONS
Adiabatic and pulse train saturation pulses optimized for different constraints found at 1.5 T and 3 T achieved <1 % residual |MZ/M0| in phantom experiments, enabling greater accuracy in quantitative saturation recovery T1 imaging.
背景
基于定量饱和恢复的T1映射序列对系统误差的敏感度低于改良Look-Locker反转恢复(MOLLI)技术,但需要高性能的饱和脉冲。我们建议针对定量T1映射优化绝热和脉冲序列饱和脉冲,以在1.5T和3T时发现的B0和γ(B1比例因子)不均匀性范围内,使绝对剩余纵向磁化强度(|MZ/M0|)<1%。
方法
针对绝热BIR4-90脉冲的设计参数进行了优化,以在1.5T B0(±120Hz)和γ(0.7-1.0)范围内提高性能。考虑到T1值、场不均匀性(3T时B0 = ±240Hz且γ = 0.4-1.2)以及可实现的最大B1场强,对3-6个脉冲的硬脉冲序列中的翻转角进行了1.5T和3T的优化。在体模和人体活体研究中,对当前标准和优化后的饱和脉冲的剩余MZ/M0进行了模拟和实验测量。在人体受试者和猪身上,使用饱和恢复单次激发采集(SASHA)技术,采用标准90°-90°-90°和优化的6脉冲序列,在3T下采集T1映射图。
结果
在广泛的B0和γ范围内,体模中测量的剩余MZ/M0与模拟结果具有良好的一致性。优化后的BIR4-90将最大剩余|MZ/M0|降低至<1%,与参考BIR4-90相比降低了5.8倍。对于1.5T优化范围,优化后的3脉冲序列实现的最大剩余|MZ/M0|<1%,而标准90°-90°-90°脉冲序列为11.3%;对于更宽的3T B0和γ范围,6脉冲序列达到了这一目标。在人体研究中,6脉冲序列在心肌和整个视野范围内的饱和比其他饱和脉冲更均匀。在人体和动物研究中,与参考90°-90°-90° SASHA相比,6脉冲序列SASHA的T1映射图在空间上更均匀。
结论
针对1.5T和3T时发现的不同限制条件优化的绝热和脉冲序列饱和脉冲,在体模实验中实现了<1%的剩余|MZ/M0|,从而在定量饱和恢复T1成像中实现了更高的准确性。
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