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利用实验因子补偿和 T1 归一化定量化学交换饱和传递(CEST)MRI 提高易变质子浓度加权化学交换率(k(ws))的测量。

Improved measurement of labile proton concentration-weighted chemical exchange rate (k(ws)) with experimental factor-compensated and T(1) -normalized quantitative chemical exchange saturation transfer (CEST) MRI.

机构信息

Department of Radiology, 2nd Affiliated Hospital of Shantou University Medical College, Guangdong, China.

出版信息

Contrast Media Mol Imaging. 2012 Jul-Aug;7(4):384-9. doi: 10.1002/cmmi.505.

DOI:10.1002/cmmi.505
PMID:22649044
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3415239/
Abstract

Chemical exchange saturation transfer (CEST) MRI enables measurement of dilute CEST agents and microenvironment properties such as pH and temperature, holding great promise for in vivo applications. However, because of confounding concomitant radio frequency (RF) irradiation and relaxation effects, the CEST-weighted MRI contrast may not fully characterize the underlying CEST phenomenon. We postulated that the accuracy of quantitative CEST MRI could be improved if the experimental factors (labeling efficiency and RF spillover effect) were estimated and taken into account. Specifically, the experimental factor was evaluated as a function of exchange rate and CEST agent concentration ratio, which remained relatively constant for intermediate RF irradiation power levels. Hence, the experimental factors can be calculated based on the reasonably estimated exchange rate and labile proton concentration ratio, which significantly improved quantification. The simulation was confirmed with creatine phantoms of serially varied concentration titrated to the same pH, whose reverse exchange rate (k(ws)) was found to be linearly correlated with the concentration. In summary, the proposed solution provides simplified yet reasonably accurate quantification of the underlying CEST system, which may help guide the ongoing development of quantitative CEST MRI.

摘要

化学交换饱和传递(CEST)MRI 能够测量稀有的 CEST 试剂和微环境特性,如 pH 值和温度,在体内应用中具有很大的应用前景。然而,由于混杂的伴随射频(RF)辐射和弛豫效应,CEST 加权 MRI 对比可能无法完全描述潜在的 CEST 现象。我们假设,如果估计并考虑实验因素(标记效率和 RF 溢出效应),定量 CEST MRI 的准确性可以提高。具体来说,实验因素被评估为交换率和 CEST 试剂浓度比的函数,对于中间 RF 辐射功率水平,该交换率和 CEST 试剂浓度比保持相对恒定。因此,可以根据合理估计的交换率和不稳定质子浓度比来计算实验因素,这显著提高了定量精度。该模拟通过具有连续变化浓度的肌酸幻影得到了验证,这些浓度被滴定到相同的 pH 值,发现其反向交换率(k(ws))与浓度呈线性相关。总之,所提出的解决方案提供了对潜在 CEST 系统的简化但合理准确的定量,这可能有助于指导定量 CEST MRI 的不断发展。

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