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Real time imaging of immune cells and glutamate dynamics by PET and metabolic MRI

通过 PET 和代谢 MRI 对免疫细胞和谷氨酸动态进行实时成像

基本信息

批准号：
10678827
负责人：
Caroline Guglielmetti
金额：
$ 9.39万
依托单位：
UNIVERSITY OF CALIFORNIA, SAN FRANCISCO
依托单位国家：
美国
项目类别：
财政年份：
2022
资助国家：
美国
起止时间：
2022-08-08 至 2023-08-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/10678827
关键词：
Amides Amyotrophic Lateral Sclerosis Animals Anti-Inflammatory Agents Astrocytes Biochemical Reaction Blood - brain barrier anatomy Brain Cancer Model Carbon Cells Cellular Metabolic Process Central Nervous System Clinical Demyelinations Detection Development Diagnosis Disease Disease Progression Disease model Ensure Evaluation Event Excitatory Amino Acid Transporter 2 Functional disorder Glutamate Metabolism Pathway Glutamates Goals Human Image Imaging Techniques Immune Immune System Diseases Immune response Immune system Immunologic Monitoring Immunology Immunology procedure Impairment In Situ Inflammation Inflammatory Innate Immune Response Innate Immune System Investigation Knowledge Label Lesion Lesion by Stage Link Lymphoid Tissue Macrophage Magnetic Resonance Imaging Measures Mentors Metabolic Methods Modeling Monitor Multiple Sclerosis Multiple Sclerosis Lesions Neurologic Pathogenesis Pathologic Peripheral Nervous System Phase Play Positioning Attribute Positron-Emission Tomography Process Production Pyruvate Reporting Research Role Scientist Specificity Spinal Cord T cell infiltration T-Cell Activation T-Lymphocyte Techniques Technology Time Tissues Tracer Training Visualization Work adaptive immune response axon injury career clinical translation clinically relevant cytokine design excitotoxicity first-in-human imaging agent imaging approach imaging biomarker imaging modality imaging study immune activation immune imaging immunoregulation improved in situ imaging in vivo innovation magnetic resonance spectroscopic imaging molecular imaging mouse model multimodality neuroimaging neuroimmunology neuroinflammation non-invasive imaging novel pre-clinical prevent programs progressive neurodegeneration radiotracer real-time images reuptake serial imaging skills success tissue degeneration tool treatment response tumor

项目摘要

ABSTRACT Activation of immune cells plays a critical role in initiation and progression of multiple sclerosis (MS), leading to progressive neurodegeneration of the central nervous system (CNS). While glutamate imbalance has been described in MS brains and has been proposed to contribute to axonal damage and tissue destruction, the relationships between glutamate dynamics and immune activation during disease progression remain unclear. Presently, the lack of clinically available noninvasive imaging methods to detect immune cells and glutamate metabolism limits our understanding of MS pathogenesis and monitoring of responses to therapies. Recent development of radiotracers for positron emission tomography (PET) have shown great potential for detection of cells from the immune system and for imaging glutamate reuptake by astroglial excitatory amino acid transporter-2 (EAAT2). Specifically, 2'-deoxy-2'-[18F]fluoro-9-β-D-arabinofuranosylguanine ([18F]F-AraG) enables the detection of activated T-cells in inflammatory diseases and cancer models. [18F]Fluoro- fluorenylaspartyl amide ([18F]FFAA) has demonstrated the ability to measure EAAT2 activity in the CNS. Hyperpolarized 13C magnetic resonance spectroscopic imaging (HP 13C MRSI) is an emerging imaging technique which measures enzymatic reactions in vivo in real-time. HP 13C pyruvate has been shown to detect highly glycolytic cells from the innate immune system in peripheral and CNS inflammation models. Recently, pyruvate labelled on the second carbon position, [2-13C]pyruvate, provided a new way to monitor glutamate production in the human brain. This project proposes to validate these innovative noninvasive PET and MR methods to provide a new way to investigate the relationships between innate and adaptive immune responses and glutamate dynamics in preclinical MS models. The mentored phase of this project will develop and validate new neuroimaging technologies: Aim 1 will investigate the potential of [18F]F-AraG and [18F]FFAA PET imaging to visualize activated T-cells and glutamate reuptake during disease progression. Aim 2 will develop and validate HP [2-13C]pyruvate as a method to simultaneously detect pro-inflammatory innate immune cells and determine real-time brain glutamate production. The independent phase of this project will build on these initial results and Aim 3 will evaluate the potential of this multimodal PET and MRI approach to monitor immune responses, glutamate production, and astrocyte functions following therapy. Central to the success of this proposal, Dr. Guglielmetti will have the support and guidance from an established group of experts in neuroimaging, particularly HP 13C MR technology (Dr. Myriam Chaumeil and Dr. Peder Larson) and PET imaging (Dr. Henry VanBrocklin) as well as in neuroimmunology and MS (Dr. Ari Green and Dr. Zamvil), providing her with the necessary skillsets to embark on a career as an independent scientist.

摘要免疫细胞的激活在多发性硬化症(MS)的发生和发展中起着关键作用，导致到中枢神经系统(CNS)的进行性神经变性。虽然谷氨酸失衡一直是在多发性硬化症大脑中描述，并被认为有助于轴突损伤和组织破坏，谷氨酸动力学和疾病进展过程中的免疫激活之间的关系尚不清楚。目前，缺乏临床可用的非侵入性成像方法来检测免疫细胞和谷氨酸代谢限制了我们对MS发病机制的理解和对治疗反应的监测。用于正电子发射断层扫描(PET)的放射性示踪剂的最新发展显示出巨大的潜力星形胶质细胞兴奋性氨基酸对免疫系统细胞的检测及谷氨酸再摄取的成像酸转运蛋白2(EAAT2)。具体地说，2‘-deoxy-2’-[18F]fluoro-9-β-D-arabinofuranosylguanine([18F]F-Arag) 能够在炎症性疾病和癌症模型中检测激活的T细胞。[18F]氟- 荧基天冬氨酸酰胺([18F]FFAA)已经证明有能力测量中枢神经系统中EAAT2的活性。超极化~(13)C磁共振波谱成像是一种新兴的成像技术它实时测量体内的酶反应。幽门螺杆菌13C丙酮酸已被证明可高度检测外周和中枢神经系统炎症模型中来自天然免疫系统的糖酵解细胞。最近，丙酮酸标记在第二碳位置上的[2-13C]丙酮酸为监测谷氨酸的产生提供了一种新的方法人类的大脑。本项目建议验证这些创新的无创PET和MR方法，以提供一种新的方法探讨先天性和获得性免疫反应与谷氨酸动态的关系临床前多发性硬化症模型。该项目的指导阶段将开发和验证新的神经成像技术：Aim 1将研究[18F]F-Arag和[18F]FFAA PET成像显示激活的可能性 T细胞和谷氨酸在疾病进展过程中的重新摄取。AIM 2将开发和验证HP[2-13C]丙酮酸作为一种同时检测促炎性先天免疫细胞和确定实时脑功能的方法谷氨酸生产。该项目的独立阶段将建立在这些初步成果的基础上，目标3将评估这种多模式PET和MRI方法监测免疫反应、谷氨酸的潜力治疗后的生产和星形胶质细胞的功能。这项提议成功的关键，古列尔梅蒂博士将得到成熟的神经成像专家小组的支持和指导，特别是HP 13C 磁共振技术(Myriam Chaumeil博士和Peder Larson博士)和PET成像(Henry VanBrocklin博士)也是如此如神经免疫学和多发性硬化症(Ari Green博士和Zamvil博士)，为她提供必要的技能来开始独立科学家的职业生涯。