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使用超极化1-(13)C丙酮酸对博来霉素诱导的肺损伤模型中的炎症进行代谢光谱分析。

Metabolic spectroscopy of inflammation in a bleomycin-induced lung injury model using hyperpolarized 1-(13) C pyruvate.

作者信息

Shaghaghi Hoora, Kadlecek Stephen, Deshpande Charuhas, Siddiqui Sarmad, Martinez Daniel, Pourfathi Mehrdad, Hamedani Hooman, Ishii Masaru, Profka Harrilla, Rizi Rahim

机构信息

Department of Radiology, University of Pennsylvania, Philadelphia, PA, USA.

出版信息

NMR Biomed. 2014 Aug;27(8):939-47. doi: 10.1002/nbm.3139. Epub 2014 May 28.

DOI:10.1002/nbm.3139
PMID:24865640
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4110199/
Abstract

Metabolic activity in the lung is known to change in response to external insults, inflammation, and cancer. We report measurements of metabolism in the isolated, perfused rat lung of healthy controls and in diseased lungs undergoing acute inflammation using hyperpolarized 1-(13) C-labeled pyruvate. The overall apparent activity of lactate dehydrogenase is shown to increase significantly (on average by a factor of 3.3) at the 7 day acute stage and to revert substantially to baseline at 21 days, while other markers indicating monocarboxylate uptake and transamination rate are unchanged. Elevated lung lactate signal levels correlate well with phosphodiester levels as determined with (31) P spectroscopy and with the presence of neutrophils as determined by histology, consistent with a relationship between intracellular lactate pool labeling and the density and type of inflammatory cells present. We discuss several alternate hypotheses, and conclude that the most probable source of the observed signal increase is direct uptake and metabolism of pyruvate by inflammatory cells and primarily neutrophils. This signal is seen in high contrast to the low baseline activity of the lung.

摘要

已知肺部的代谢活动会因外部损伤、炎症和癌症而发生变化。我们报告了使用超极化的1-(13)C标记丙酮酸对健康对照大鼠的离体灌注肺以及处于急性炎症的患病肺的代谢测量结果。乳酸脱氢酶的总体表观活性在急性炎症第7天时显著增加(平均增加3.3倍),并在21天时基本恢复至基线水平,而其他表明单羧酸摄取和转氨速率的标志物则未发生变化。肺部乳酸信号水平的升高与通过(31)P光谱法测定的磷酸二酯水平以及通过组织学测定的中性粒细胞的存在密切相关,这与细胞内乳酸池标记与存在的炎症细胞的密度和类型之间的关系一致。我们讨论了几种替代假设,并得出结论,观察到的信号增加最可能的来源是炎症细胞(主要是中性粒细胞)对丙酮酸的直接摄取和代谢。与肺部的低基线活性形成高对比度的是,这种信号很明显。

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