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三重重复时间饱和转移(TRiST)31P 波谱法测量人肌酸激酶反应动力学。

Triple repetition time saturation transfer (TRiST) 31P spectroscopy for measuring human creatine kinase reaction kinetics.

机构信息

Russell H. Morgan Department of Radiology and Radiological Science, The Johns Hopkins University School of Medicine, Baltimore, Maryland 21287, USA.

出版信息

Magn Reson Med. 2010 Jun;63(6):1493-501. doi: 10.1002/mrm.22347.

DOI:10.1002/mrm.22347
PMID:20512852
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2926802/
Abstract

Human cardiac phosphorus MR saturation transfer experiments to quantify creatine kinase forward rate constants (k(f)) have previously been performed at 1.5 T. Such experiments could benefit from increased signal-to-noise ratio (SNR) and spectral resolution at 3 T. At 1.5 T, the four-angle saturation transfer method was applied with low-angle adiabatic pulses and surface coils. However, low-angle adiabatic pulses are potentially problematic above 1.5 T due to bandwidth limitations, power requirements, power deposition, and intrapulse spin-spin relaxation. For localized metabolite spin-lattice relaxation time (T(1)) measurements, a dual repetition time approach with adiabatic half-passage pulses was recently introduced to solve these problems at 3 T. Because the saturation transfer experiment requires a T(1) measurement performed while one reacting moiety is saturated, we adapt the dual repetition time approach to measure k(f) using a triple repetition time saturation transfer (TRiST) method. A new pulsed saturation scheme with reduced sensitivity to static magnetic field inhomogeneity and compatibility with cardiac triggering is also presented. TRiST measurements of k(f) are validated in human calf muscle against conventional saturation transfer and found to agree within 3%. The first 3-T TRiST measurements of creatine kinase k(f) in the human calf (n = 6), chest muscle, and heart (n = 8) are 0.26 +/- 0.04 s(-1), 0.23 +/- 0.03 s(-1), and 0.32 +/- 0.07 s(-1), respectively, consistent with prior 1.5 T values.

摘要

人体心脏磷磁共振饱和转移实验以前是在 1.5T 下进行的,用于量化肌酸激酶正向速率常数 (k(f))。在 3T 下,此类实验可受益于更高的信噪比 (SNR) 和光谱分辨率。在 1.5T 下,采用低角度绝热脉冲和表面线圈进行了四角度饱和转移方法。然而,由于带宽限制、功率要求、功率沉积和脉冲内自旋-自旋弛豫,低角度绝热脉冲在 1.5T 以上可能会出现问题。对于局部代谢物自旋晶格弛豫时间 (T(1)) 测量,最近引入了双重复时间方法,使用绝热半通过脉冲解决了 3T 下的这些问题。由于饱和转移实验需要在一个反应部分饱和时进行 T(1) 测量,因此我们采用双重复时间方法通过三重复时间饱和转移 (TRiST) 方法来测量 k(f)。还提出了一种新的脉冲饱和方案,该方案对静态磁场不均匀性的敏感性降低,并且与心脏触发兼容。在人体小腿肌肉中,通过与传统饱和转移进行对比,验证了 k(f)的 TRiST 测量值,结果在 3%以内一致。在人体小腿(n=6)、胸部肌肉和心脏(n=8)中首次进行的 3T TRiST 测量的肌酸激酶 k(f)分别为 0.26±0.04s(-1)、0.23±0.03s(-1)和 0.32±0.07s(-1),与之前的 1.5T 值一致。

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