Synthesis and preliminary evaluation of an 18F-labeled oleic acid analog for PET imaging of fatty acid uptake and metabolism

Abstract

IntroductionImaging fatty acid uptake and utilization has broad impact in investigating myocardial diseases, hepatic functions, tumor progression, and the metabolic state of adipose tissue. The SPECT tracer 123I-15-(p-iodophenyl)-3-(R,S)-methylpentadecanoic acid (BMIPP) is a clinically used nuclear medicine tracer to image myocardial uptake of fatty acid. Although FTHA (18F-5) has been in clinical use for PET imaging of adipose tissue as well as the myocardium, here we developed a click oleate analog to compare to FTO, with the goal of improved stability to defluorination and suitability for imaging myocardial uptake and oxidation of fatty acids. MethodsA rapid and convenient synthetic approach for a precursor to a 18F-labeled oleate analog using click chemistry was developed and evaluated for PET imaging in fasted mice. ResultsThe overall yield for the preparation of the labeling precursor of the clicked oleate analog was 12%. This precursor was efficiently radiolabeled with F-18 in 17% non-decay-corrected radiochemical yield. PET/CT imaging and biodistribution results show that this fatty acid analog had reasonable heart uptake (0.94±0.28 %ID/g at 0.5h p.i.) and heart-to-muscle ratio (2.05±0.39 at 0.5h p.i.) and is a potential lead for developing new PET tracers to image fatty acid uptake and utilization using click chemistry methodologies. The synthetic route to FTO was optimized to three steps from known starting materials. ConclusionWhile the uptake of the clicked oleic acid analog was sufficient for visualizing the myocardium in mice, the preliminary metabolism data suggest that only a fraction of the uptake was due to fatty acid beta-oxidation. Studies are under way to explore the uptake/oxidation mechanism and kinetics.