New Methods for the Expedited Synthesis of C11 and F18 PET Tracers

快速合成 C11 和 F18 PET 示踪剂的新方法

• 批准号: 7898026
• 负责人: SALVATORE D LEPORE
• 金额: $ 21.68万
• 依托单位: FLORIDA ATLANTIC UNIVERSITY
• 依托单位国家: 美国
• 财政年份: 2010
• 资助国家: 美国
• 起止时间: 2010-04-19 至 2013-01-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7898026
• 关键词: Address; Affinity; Alcohols; Arylsulfonates; Baclofen; Binding; Brain; Brain Diseases; Brain imaging; Butyric Acids; Carboxylic Acids; Cations; Chemistry; Chromatography; Cyanides; Cyclotrons; Development; Disease; Dystonia; Epilepsy; Exhibits; Florida; Fluorides; Future; GABA Agonists; GABA Receptor; Gilles de la Tourette syndrome; Goals; Growth; Half-Life; Image; Imaging Techniques; Isotopes; Label; Laboratories; Lead; Left; Medical; Metal exposure; Metals; Methodology; Methods; Molecular; Molecular Probes; Multiple Sclerosis; National Institute of Mental Health; Neuromodulator; Nitriles; Organic Synthesis; Patients; Performance; Phase; Pike fish; Polymers; Positron; Positron-Emission Tomography; Potassium Cyanide; Preparation; Process; Property; Radio; Radioisotopes; Reaction; Reagent; Reporting; Research Personnel; Salts; Series; Side; Solid; Solutions; Solvents; Speed; Staging; Students; System; Techniques; Technology; Temperature; Tetrazoles; Time; Tracer; Training; Travel; Universities; Work; analog; base; chemical reaction; design; gamma-Aminobutyric Acid; high risk; imaging probe; improved; molecular imaging; novel; public health relevance; radiochemical; reaction rate; receptor; small molecule

DESCRIPTION (provided by applicant): Compounds labeled with positron-emitting isotopes 18F and 11C have found powerful applications as tracers for positron emission tomography (PET). These molecular probes have become indispensable for understanding the mechanisms of both normal brain function and brain disorders. Due to the short half-lives of these radioisotopes, the synthesis and purification of 18F- and especially 11C-tracers must be performed with extreme rapidity if they are to retain sufficient radio-emitting properties to be useful as imaging agents. Thus the growth of the PET technique has been closely tied to the development of new rapid-synthesis and purification methods. In this revised proposal, we outline a paradigm shift in radiosynthesis methodology by focusing on the development of a new class of reactive entities that are uniquely activated by metal cations that form part of the nuclide salts most often used in the synthesis of PET agents (e.g. K18F and K11CN). This new reactive system termed nucleophile assisting leaving group (NALG) is expected to significantly expedite the radiosynthesis of imaging agents and limit side-product formation. In our proposed approach, a PET tracer precursor is covalently attached to a polymer support that has been modified to contain the new reactive entity (the NALG). In a second step, cyclotron-derived fluoride or cyanide are added to the polymer resulting in the formation of the desired radio labeled tracer as the only product. In addition to increased reaction rates, this unprecedented strategy has been designed to avoid byproduct formation and minimize the time required for reaction purification. Taken together, these reaction improvements are expected to leave more time for the synthesis of imaging probes with potentially higher specific activities and greater molecular complexity than previously possible. We will employ this new NALG polymer method in the first synthesis of [11C]baclofen, a 3- amino-butyric acid (GABA) receptor agonist. As a well known probe for targeting GABAB, baclofen is widely- used for the management of spasticity exhibited in multiple sclerosis, Tourette syndrome, and dystonia. Made possible by the new polymer-based method, the efficient radio synthesis of [11C] baclofen (and related analogs for better brain permeation) is expected to facilitate future PET studies of GABA receptors and ultimately lead to improved therapies for diseases related to these receptors. PUBLIC HEALTH RELEVANCE: This proposed study introduces new chemistry to significantly improve current methods used to make PET medical imaging compounds thus allowing this imaging technique to be more widely available. Two novel compounds will be targeted to further medical researchers' understanding of brain function in the epileptic and multiple sclerosis patient.

描述(由申请人提供)：标记有正电子发射同位素18F和11C的化合物已被用作正电子发射断层扫描(PET)的示踪剂。这些分子探针已经成为了解正常大脑功能和大脑疾病机制不可或缺的一部分。由于这些放射性同位素的半衰期很短，18F-，特别是11C-示踪剂的合成和提纯必须以极快的速度进行，如果它们要保持足够的放射性发射性能，才能用作显像剂。因此，PET技术的发展与新的快速合成和纯化方法的发展密切相关。在这个修订的提案中，我们概述了放射合成方法学的范式转变，重点是开发一类新的反应实体，这些实体唯一地被金属阳离子激活，这些金属阳离子构成了PET试剂(例如K18F和K11CN)合成中最常用的核素盐的一部分。这一新的被称为亲核剂辅助离开基团(NALG)的反应系统有望显著加快显像剂的放射合成，并限制副产物的形成。在我们提出的方法中，将PET示踪剂前体共价连接到聚合物载体上，该聚合物载体已被修饰以包含新的反应实体(NALG)。在第二步中，将回旋衍生的氟化物或氰化物添加到聚合物中，从而形成所需的放射性标记示踪剂作为唯一产品。除了提高反应速度外，这一史无前例的策略还旨在避免副产物的形成，并最大限度地减少反应净化所需的时间。综上所述，这些反应改进有望为合成具有更高比活性和更大分子复杂性的成像探针留下比以前可能的更多时间。我们将使用这种新的NALG聚合物方法首次合成3-氨基丁酸(GABA)受体激动剂[11C]巴氯芬。作为一种众所周知的针对GABAB的探针，巴氯芬被广泛用于治疗多发性硬化症、多发性抽动症和肌张力障碍的痉挛。通过以聚合物为基础的新方法，高效的放射性合成[11C]巴氯芬(以及相关的类似物，以更好地促进大脑渗透)有望促进未来对GABA受体的PET研究，并最终改进与这些受体相关的疾病的治疗方法。 与公共健康相关：这项拟议的研究引入了新的化学方法，以显着改进目前用于制造PET医学成像化合物的方法，从而使这种成像技术得到更广泛的应用。两种新的化合物将成为进一步医学研究人员了解癫痫和多发性硬化症患者大脑功能的目标。