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4.7T下用于脑葡萄糖代谢成像的超极化碳与非超极化氘MRI方法的比较

Comparison of hyperpolarized C and non-hyperpolarized deuterium MRI approaches for imaging cerebral glucose metabolism at 4.7 T.

作者信息

von Morze Cornelius, Engelbach John A, Blazey Tyler, Quirk James D, Reed Galen D, Ippolito Joseph E, Garbow Joel R

机构信息

Mallinckrodt Institute of Radiology, Washington University, St. Louis, Missouri, USA.

GE Healthcare, Dallas, Texas, USA.

出版信息

Magn Reson Med. 2021 Apr;85(4):1795-1804. doi: 10.1002/mrm.28612. Epub 2020 Nov 28.

DOI:10.1002/mrm.28612
PMID:33247884
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8018714/
Abstract

PURPOSE

The purpose of this study was to directly compare two isotopic metabolic imaging approaches, hyperpolarized (HP) C MRI and deuterium metabolic imaging (DMI), for imaging specific closely related segments of cerebral glucose metabolism at 4.7 T.

METHODS

Comparative HP- C and DMI neuroimaging experiments were conducted consecutively in normal rats during the same scanning session. Localized conversions of [1- C]pyruvate and [6,6- H ]glucose to their respective downstream metabolic products were measured by spectroscopic imaging, using an identical 2D-CSI sequence with parameters optimized for the respective experiments. To facilitate direct comparison, a pair of substantially equivalent 2.5-cm double-tuned X/ H RF surface coils was developed. For improved results, multidimensional low-rank reconstruction was applied to denoise the raw DMI data.

RESULTS

Localized conversion of HP [1- C]pyruvate to [1- C]lactate, and [6,6- H ]glucose to [3,3- H ]lactate and Glx-d (glutamate and glutamine), was detected in rat brain by spectroscopic imaging at 4.7 T. The SNR and spatial resolution of HP- C MRI was superior to DMI but limited to a short time window, whereas the lengthy DMI acquisition yielded maps of not only lactate, but also Glx production, albeit with relatively poor spectral discrimination between metabolites at this field strength. Across the individual rats, there was an apparent inverse correlation between cerebral production of HP [1- C]lactate and Glx-d, along with a trend toward increased [3,3- H ]lactate.

CONCLUSION

The HP- C MRI and DMI methods are both feasible at 4.7 T and have significant potential for metabolic imaging of specific segments of glucose metabolism.

摘要

目的

本研究旨在直接比较两种同位素代谢成像方法,即超极化(HP)¹³C磁共振成像(MRI)和氘代谢成像(DMI),用于在4.7 T磁场下对脑葡萄糖代谢的特定紧密相关节段进行成像。

方法

在同一扫描过程中,对正常大鼠连续进行HP¹³C和DMI神经成像对比实验。通过光谱成像测量[1-¹³C]丙酮酸和[6,6-²H]葡萄糖向其各自下游代谢产物的局部转化,使用相同的二维化学位移成像(2D-CSI)序列,其参数针对各自实验进行了优化。为便于直接比较,开发了一对基本等效的2.5厘米双调谐X/¹H射频表面线圈。为了获得更好的结果,应用多维低秩重建对原始DMI数据进行去噪。

结果

在4.7 T磁场下,通过光谱成像在大鼠脑中检测到HP [1-¹³C]丙酮酸向[1-¹³C]乳酸的局部转化,以及[6,6-²H]葡萄糖向[3,3-²H]乳酸和Glx-d(谷氨酸和谷氨酰胺)的局部转化。HP¹³C MRI的信噪比和空间分辨率优于DMI,但仅限于较短的时间窗口,而较长时间的DMI采集不仅产生了乳酸图谱,还产生了Glx生成图谱,尽管在此场强下代谢物之间的光谱分辨相对较差。在个体大鼠中,脑内HP [1-¹³C]乳酸和Glx-d的生成之间存在明显的负相关,同时[3,3-²H]乳酸有增加的趋势。

结论

HP¹³C MRI和DMI方法在4.7 T磁场下均可行,并且在葡萄糖代谢特定节段的代谢成像方面具有巨大潜力。

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