脑内 -3.5ppm 处 NOE 信号的分子起源分配。

Assignment of molecular origins of NOE signal at -3.5 ppm in the brain.

机构信息

Vanderbilt University Institute of Imaging Science, Nashville, Tennessee, USA.

Department of Radiology and Radiological Sciences, Vanderbilt University Medical Center, Nashville, Tennessee, USA.

出版信息

Magn Reson Med. 2023 Aug;90(2):673-685. doi: 10.1002/mrm.29643. Epub 2023 Mar 17.

DOI:10.1002/mrm.29643

PMID:36929814

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10644915/

Abstract

PURPOSE

Nuclear Overhauser enhancemen mediated saturation transfer effect, termed NOE (-3.5 ppm), is a major source of CEST MRI contrasts at 3.5 ppm in the brain. Previous phantom experiments have demonstrated that both proteins and lipids, two major components in tissues, have substantial contributions to NOE (-3.5 ppm) signals. Their relative contributions in tissues are informative for the interpretation of NOE (-3.5 ppm) contrasts that could provide potential imaging biomarkers for relevant diseases, which remain incompletely understood.

METHODS

Experiments on homogenates and supernatants of brain tissues collected from healthy rats, that could isolate proteins from lipids, were performed to evaluate the relative contribution of lipids to NOE (-3.5 ppm) signals. On the other hand, experiments on ghost membranes with varied pH, and reconstituted phospholipids with different chemical compositions were conducted to study the dependence of NOE (-3.5 ppm) on physiological conditions. Besides, CEST imaging on rat brains bearing 9 L tumors and healthy rat brains was performed to analyze the causes of the NOE (-3.5 ppm) contrast variations between tumors and normal tissues, and between gray matter and white matter.

RESULTS

Our experiments reveal that lipids have dominant contributions to the NOE (-3.5 ppm) signals. Further analysis suggests that decreased NOE (-3.5 ppm) signals in tumors and higher NOE (-3.5 ppm) signals in white matter than in gray matter are mainly explained by changes in membrane lipids, rather than proteins.

CONCLUSION

NOE (-3.5 ppm) could be exploited as a highly sensitive MRI contrast for imaging membrane lipids in the brain.

摘要

目的

核 Overhauser 增强介导的饱和转移效应（称为 NOE（-3.5ppm））是大脑中 3.5ppm 处 CEST MRI 对比的主要来源。先前的体模实验已经证明，蛋白质和脂质这两种组织中的主要成分对 NOE（-3.5ppm）信号都有很大的贡献。它们在组织中的相对贡献对于解释 NOE（-3.5ppm）对比非常重要，这可能为相关疾病提供潜在的成像生物标志物，而这些疾病的机制仍不完全清楚。

方法

我们对来自健康大鼠的脑组织匀浆和上清液进行了实验，这些实验可以从脂质中分离蛋白质，以评估脂质对 NOE（-3.5ppm）信号的相对贡献。另一方面，我们还进行了 pH 值不同的幽灵膜和不同化学成分的重组磷脂的实验，以研究 NOE（-3.5ppm）对生理条件的依赖性。此外，我们对患有 9L 肿瘤的大鼠脑和健康大鼠脑进行了 CEST 成像，以分析肿瘤与正常组织之间以及灰质与白质之间的 NOE（-3.5ppm）对比变化的原因。

结果

我们的实验表明，脂质对 NOE（-3.5ppm）信号有主导贡献。进一步的分析表明，肿瘤中 NOE（-3.5ppm）信号的降低和白质中比灰质中更高的 NOE（-3.5ppm）信号主要是由膜脂质的变化而不是蛋白质的变化引起的。

结论

NOE（-3.5ppm）可以作为一种高度敏感的 MRI 对比剂，用于成像大脑中的膜脂质。

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