Introduction: LBT-999, (E)-N-(4-fluorobut-2-enyl)-2β-carbomethoxy-3β-(4'-tolyl)nortropane, has been developed for PET imaging of the dopamine transporter. [(18)F]LBT-999 PET studies in baboons showed a lower brain uptake than [(11)C]LBT-999 and a high bone uptake, suggesting the presence of interfering metabolites. Therefore, in vitro and in vivo metabolism of these radiotracers was investigated.
Methods: Rat and human liver microsomal incubations, baboon plasma and rat brain extracts were analyzed by radio-HPLC and LC-MS-MS.
Results: In vitro experiments demonstrated the formation by P450s of five polar metabolites. The main routes of LBT-999 metabolism proposed were N-dealkylation, tolyl-hydroxylation and dealkylation plus tolyl-hydroxylation. In vivo in baboons, [(18)F]LBT-999 was rapidly converted into a [(18)F]hydroxylated metabolite likely oxidized in plasma into a [(18)F]carboxylic acid and into unlabeled N-dealkyl-LBT-999. The latter was detected in baboon plasma and in rat brain by LC-MS-MS. The time course of unchanged [(18)F]LBT-999 decreased rapidly in plasma and was higher than that of [(11)C]LBT-999 due to the formation of unlabeled N-dealkyl-LBT-999. In rats, striatum-to-cerebellum ratios of [(18)F]LBT-999, [(18)F]hydroxylated and [(18)F]acidic metabolite were 20, 4.2 and 1.65, respectively, suggesting a possible accumulation of the hydroxylated compound in the striatum.
Conclusion: P450s catalyzed the formation of dealkylated and hydroxylated metabolites of LBT-999. In baboons, an extensive metabolism of [(18)F]LBT-999, with formation of unlabeled N-dealkyl-LBT-999, [(18)F]fluorobutenaldehyde (or its oxidation product) and [(18)F]hydroxy-LBT-999 able to penetrate the brain, prevented an easy and accurate estimation of the input function of the radiotracer. CYP3A4 being the main P450 involved in the metabolism of LBT-999, a similar pathway may occur in humans and confound PET quantification.
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