Automated Synthesis of [11C]PiB via [11CH3OTf]-as Methylating Agent for PET Imaging of β-Amyloid.

IF 1.5 4区 医学 Q3 PHARMACOLOGY & PHARMACY
Akhilesh K Singh, Sanjay Gambhir, Manish Dixit
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引用次数: 0

Abstract

Aim: Efficient synthesis of precursor from commercially available starting materials and automated radiosynthesis of [11C]PiB using commercially available dedicated [11C]- Chemistry module from the synthesized precursor.

Background: [11C]PiB is a promising radiotracer for PET imaging of β-Amyloid, advancing Alzheimer's disease research. The availability of precursors and protocols for efficient radiolabelling foster the applications of any radiotracer. Efficient synthesis of PiB precursor was performed using anisidine and 4-nitrobenzoyl chloride as starting materials in 5 steps, having addition, substitutions, and cyclization chemical methodologies. This precursor was used for fully automated radiosynthesis of [11C]PiB in a commercially available synthesizer, MPS-100 (SHI, Japan). The synthesized [11C]PiB was purified via solid-phase methodology, and its quality control was performed by the quality and safety criteria required for clinical use.

Methods: The synthesis of desired precursors and standard authentic compounds started with commercially available materials with 70-80% yields. The standard analytical methods were characterized all synthesized compounds. The fully automated [11C]-chemistry synthesizer (MPS-100) used for radiosynthesis of [11C]PiB with [11C]CH3OTf acts as a methylating agent. For radiolabelling, varied amounts of precursor and time of reaction were explored. The resulting crude product underwent purification through solid-phase cartridges. The synthesized radiotracer was analyzed using analytical tools such as radio TLC, HPLC, pH endo-toxicity, and half-life.

Results: The precursor for radiosynthesis of [11C]PiB was achieved in excellent yield using simple and feasible chemistry. A protocol for radiolabelling of precursor to synthesized [11C]PiB was developed using an automated synthesizer. The crude radiotracer was purified by solid-phase cartridge, with a decay-corrected radiochemical yield of 40±5% and radiochemical purity of more than 97% in approx 20 minutes (EOB). The specific activity was calculated and found in a 110-121 mCi/μmol range.

Conclusion: A reliable methodology was developed for preparing precursor followed by fully automated radiolabeling using [11C]MeOTf as a methylating agent to synthesize [11C]PiB. The final HPLC-free purification yielded more than 97% radiochemical purity tracer within one radionuclide half-life. The method was reproducible and efficient for any clinical center.

通过[11CH3OTf]甲基化剂自动合成[11C]PiB,用于β-淀粉样蛋白的 PET 成像。
目的:利用市售起始材料高效合成前体,并利用市售专用[11C]-化学模块从合成的前体中自动放射合成[11C]PiB:背景:[11C]PiB 是一种很有前景的放射性示踪剂,可用于 β 淀粉样蛋白的 PET 成像,从而推动阿尔茨海默病的研究。前体的可用性和高效放射性标记的方案促进了任何放射性示踪剂的应用。以甲氧基苯胺和 4-硝基苯甲酰氯为起始原料,通过加成、取代和环化等化学方法,分 5 个步骤高效合成了 PiB 前体。该前体在市售合成器 MPS-100 (SHI,日本)中用于全自动放射性合成 [11C]PiB 。合成的[11C]PiB 通过固相方法纯化,其质量控制符合临床使用所需的质量和安全标准:方法:所需前体和标准真品化合物的合成从市售材料开始,产率为 70-80%。标准分析方法对所有合成化合物进行了表征。全自动[11C]化学合成器(MPS-100)用于[11C]PiB 的放射合成,[11C]CH3OTf 用作甲基化剂。为了进行放射性标记,我们研究了不同的前体用量和反应时间。得到的粗产物通过固相滤芯进行纯化。合成的放射性示踪剂使用无线电 TLC、HPLC、pH 内毒性和半衰期等分析工具进行分析:结果:利用简单可行的化学方法,[11C]PiB 的放射性合成前体产量极高。使用自动合成器制定了对合成的[11C]PiB前体进行放射性标记的方案。粗放射性示踪剂经固相滤芯纯化,衰变校正放射化学收率为 40±5%,放射化学纯度超过 97%,耗时约 20 分钟(EOB)。计算得出的比活度范围为 110-121 mCi/μmol:结论:本研究开发了一种可靠的方法来制备前体,然后使用[11C]MeOTf 作为甲基化剂进行全自动放射性标记,合成[11C]PiB。在一个放射性核素半衰期内,最终的无 HPLC 纯化可获得超过 97% 的放射性化学纯度示踪剂。该方法重复性好、效率高,适用于任何临床中心。
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来源期刊
Current radiopharmaceuticals
Current radiopharmaceuticals PHARMACOLOGY & PHARMACY-
CiteScore
3.20
自引率
4.30%
发文量
43
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