[18F]F-AraG正电子发射断层扫描（PET）用于心脏成像--缺血再灌注损伤模型中心肌活力的可行性研究

IF 3 4区医学 Q2 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING Molecular Imaging and Biology Pub Date : 2024-10-01 Epub Date: 2024-07-26 DOI:10.1007/s11307-024-01932-y

Uttam M Shrestha, Hee-Don Chae, Qizhi Fang, Randall J Lee, Juliet Packiasamy, Lyna Huynh, Joseph Blecha, Tony L Huynh, Henry F VanBrocklin, Jelena Levi, Youngho Seo

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引用次数: 0

摘要

目的：心肌梗塞（MI）及随后的炎症是导致组织逐渐损伤的最常见心脏疾病之一。评估心肌梗死后组织存活能力的可靠成像标记物有助于确定任何干预措施的风险和益处。在这项研究中，我们研究了一种新的线粒体靶向成像剂--18F标记的2'-脱氧-2'-18F-氟-9-β-d-阿拉伯呋喃糖基鸟嘌呤（[18F]F-AraG）--一种为活化T细胞成像而开发的正电子发射断层扫描（PET）剂，是否适用于心脏成像和测试心肌梗死后的心肌活力：为了检测心肌[18F]-F-AraG信号是来自心肌细胞还是免疫浸润，我们比较了野生型（WT）小鼠和T细胞缺陷Rag1基因敲除（Rag1 KO）小鼠的心肌信号。我们通过比较以纯净饮食喂养的小鼠和以补充核苷酸的纯净饮食喂养的小鼠的[18F]F-AraG 信号，评估了饮食中的核苷酸对正常心脏心肌[18F]F-AraG 摄取的影响。在啮齿动物模型中，用[18F]F-AraG 和 2-脱氧-2[18F]氟-D-葡萄糖（[18F]FDG）对心肌梗死前后的大鼠进行成像，研究心肌活力。所有 PET 信号均以每毫升注射剂量百分比（%ID/cc）进行量化。我们还通过 H&E 分析探讨了[18F]FDG 信号的可变性以及 T 细胞向受累心肌纤维化区域浸润的可能性：结果：Rag1 KO 和 WT 小鼠的 %ID/cc 差异不显著（p = ns），表明心肌中的 [18F]F-AraG 信号主要来自心肌细胞。用纯化饮食和补充核苷酸的纯化饮食喂养的小鼠，其心肌摄取的[18F]F-AraG 信号没有差异（p = ns）。在不同的时间点，[18F]FDG 信号的变化幅度更大。在受影响的 MI 区域观察到明显的 [18F]F-AraG 信号。H&E分析显示，纤维化区域存在T细胞，但它们并不构成主要浸润：我们的初步临床前数据显示，[18F]F-AraG 可在心肌细胞中积聚，这表明它可能适用于心脏成像和心肌梗死后心肌存活能力的评估。

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A Feasibility Study of [¹⁸F]F-AraG Positron Emission Tomography (PET) for Cardiac Imaging-Myocardial Viability in Ischemia-Reperfusion Injury Model.

Purpose: Myocardial infarction (MI) with subsequent inflammation is one of the most common heart conditions leading to progressive tissue damage. A reliable imaging marker to assess tissue viability after MI would help determine the risks and benefits of any intervention. In this study, we investigate whether a new mitochondria-targeted imaging agent, ¹⁸F-labeled 2'-deoxy-2'-¹⁸F-fluoro-9-β-d-arabinofuranosylguanine ([¹⁸F]F-AraG), a positron emission tomography (PET) agent developed for imaging activated T cells, is suitable for cardiac imaging and to test the myocardial viability after MI.

Procedure: To test whether the myocardial [¹⁸F]-F-AraG signal is coming from cardiomyocytes or immune infiltrates, we compared cardiac signal in wild-type (WT) mice with that of T cell deficient Rag1 knockout (Rag1 KO) mice. We assessed the effect of dietary nucleotides on myocardial [¹⁸F]F-AraG uptake in normal heart by comparing [¹⁸F]F-AraG signals between mice fed with purified diet and those fed with purified diet supplemented with nucleotides. The myocardial viability was investigated in rodent model by imaging rat with [¹⁸F]F-AraG and 2-deoxy-2[¹⁸F]fluoro-D-glucose ([¹⁸F]FDG) before and after MI. All PET signals were quantified in terms of the percent injected dose per cc (%ID/cc). We also explored [¹⁸F]FDG signal variability and potential T cell infiltration into fibrotic area in the affected myocardium with H&E analysis.

Results: The difference in %ID/cc for Rag1 KO and WT mice was not significant (p = ns) indicating that the [¹⁸F]F-AraG signal in the myocardium was primarily coming from cardiomyocytes. No difference in myocardial uptake was observed between [¹⁸F]F-AraG signals in mice fed with purified diet and with purified diet supplemented with nucleotides (p = ns). The [¹⁸F]FDG signals showed wider variability at different time points. Noticeable [¹⁸F]F-AraG signals were observed in the affected MI regions. There were T cells in the fibrotic area in the H&E analysis, but they did not constitute the predominant infiltrates.

Conclusions: Our preliminary preclinical data show that [¹⁸F]F-AraG accumulates in cardiomyocytes indicating that it may be suitable for cardiac imaging and to evaluate the myocardial viability after MI.

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来源期刊

Molecular Imaging and Biology 医学-核医学

CiteScore

6.90

自引率

3.20%

发文量

审稿时长

3 months

期刊介绍： Molecular Imaging and Biology (MIB) invites original contributions (research articles, review articles, commentaries, etc.) on the utilization of molecular imaging (i.e., nuclear imaging, optical imaging, autoradiography and pathology, MRI, MPI, ultrasound imaging, radiomics/genomics etc.) to investigate questions related to biology and health. The objective of MIB is to provide a forum to the discovery of molecular mechanisms of disease through the use of imaging techniques. We aim to investigate the biological nature of disease in patients and establish new molecular imaging diagnostic and therapy procedures. Some areas that are covered are: Preclinical and clinical imaging of macromolecular targets (e.g., genes, receptors, enzymes) involved in significant biological processes. The design, characterization, and study of new molecular imaging probes and contrast agents for the functional interrogation of macromolecular targets. Development and evaluation of imaging systems including instrumentation, image reconstruction algorithms, image analysis, and display. Development of molecular assay approaches leading to quantification of the biological information obtained in molecular imaging. Study of in vivo animal models of disease for the development of new molecular diagnostics and therapeutics. Extension of in vitro and in vivo discoveries using disease models, into well designed clinical research investigations. Clinical molecular imaging involving clinical investigations, clinical trials and medical management or cost-effectiveness studies.