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将超极化碳磁共振成像与肝脏特异性钆造影剂相结合用于肝细胞代谢的选择性评估。

Combining hyperpolarized C MRI with a liver-specific gadolinium contrast agent for selective assessment of hepatocyte metabolism.

作者信息

Ohliger Michael A, von Morze Cornelius, Marco-Rius Irene, Gordon Jeremy, Larson Peder E Z, Bok Robert, Chen Hsin-Yu, Kurhanewicz John, Vigneron Daniel

机构信息

Department of Radiology and Biomedical Imaging, University of California, San Francisco, San Francisco, California, USA.

出版信息

Magn Reson Med. 2017 Jun;77(6):2356-2363. doi: 10.1002/mrm.26296. Epub 2016 Jun 14.

DOI:10.1002/mrm.26296
PMID:27298073
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5156580/
Abstract

PURPOSE

Hyperpolarized C MRI is a powerful tool for studying metabolism, but can lack tissue specificity. Gadoxetate is a gadolinium-based MRI contrast agent that is selectively taken into hepatocytes. The goal of this project was to investigate whether gadoxetate can be used to selectively suppress the hyperpolarized signal arising from hepatocytes, which could in future studies be applied to generate specificity for signal from abnormal cell types.

METHODS

Baseline gadoxetate uptake kinetics were measured using T -weighted contrast enhanced imaging. Relaxivity of gadoxetate was measured for [1- C]pyruvate, [1- C]lactate, and [1- C]alanine. Four healthy rats were imaged with hyperpolarized [1- C]pyruvate using a three-dimensional (3D) MRSI sequence prior to and 15 min following administration of gadoxetate. The lactate:pyruvate ratio and alanine:pyruvate ratios were measured in liver and kidney.

RESULTS

Overall, the hyperpolarized signal decreased approximately 60% as a result of pre-injection of gadoxetate. In liver, the lactate:pyruvate and alanine:pyruvate ratios decreased 42% and 78%, respectively (P < 0.05) following gadoxetate administration. In kidneys, these ratios did not change significantly. Relaxivity of gadoxetate for [1- C]alanine was 12.6 times higher than relaxivity of gadoxetate for [1- C]pyruvate, explaining the greater selective relaxation effect on alanine.

CONCLUSIONS

The liver-specific gadolinium contrast-agent gadoxetate can selectively suppress normal hepatocyte contributions to hyperpolarized C MRI signals. Magn Reson Med 77:2356-2363, 2017. © 2016 International Society for Magnetic Resonance in Medicine.

摘要

目的

超极化碳磁共振成像(C MRI)是研究新陈代谢的有力工具,但可能缺乏组织特异性。钆塞酸二钠是一种基于钆的磁共振成像造影剂,可被肝细胞选择性摄取。本项目的目标是研究钆塞酸二钠是否可用于选择性抑制肝细胞产生的超极化信号,这在未来的研究中可用于生成异常细胞类型信号的特异性。

方法

使用T加权对比增强成像测量钆塞酸二钠的基线摄取动力学。测量钆塞酸二钠对[1- C]丙酮酸、[1- C]乳酸和[1- C]丙氨酸的弛豫率。在给予钆塞酸二钠之前和之后15分钟,使用三维(3D)磁共振波谱成像(MRSI)序列对四只健康大鼠进行超极化[1- C]丙酮酸成像。测量肝脏和肾脏中的乳酸:丙酮酸比值和丙氨酸:丙酮酸比值。

结果

总体而言,由于预先注射钆塞酸二钠,超极化信号下降了约60%。在肝脏中,给予钆塞酸二钠后,乳酸:丙酮酸和丙氨酸:丙酮酸比值分别下降了42%和78%(P < 0.05)。在肾脏中,这些比值没有显著变化。钆塞酸二钠对[1- C]丙氨酸的弛豫率比对[1- C]丙酮酸的弛豫率高12.6倍,这解释了对丙氨酸有更大的选择性弛豫效应。

结论

肝脏特异性钆造影剂钆塞酸二钠可选择性抑制正常肝细胞对超极化C MRI信号的贡献。《磁共振医学》77:2356 - 2363, 2017。© 2016国际磁共振医学学会。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/736c/5156580/2338d99af92f/nihms827856f1.jpg

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