PET imaging of brain aromatase in humans and rhesus monkeys by 11C-labeled cetrozole analogs

Aromatase is an estrogen synthetic enzyme that plays important roles in brain functions. To quantify aromatase expression in the brain by positron emission tomography (PET), we had previously developed [C-11]cetrozole, which showed high specificity and affinity. To develop more efficient PET tracer(s) for aromatase imaging, we synthesized three analogs of cetrozole. We synthesized meta-cetrozole, nitro-cetrozole, and iso-cetrozole, and prepared the corresponding C-11-labeled tracers. The inhibitory activities of these three analogs toward aromatase were evaluated using marmoset placenta, and PET imaging of brain aromatase was performed using the C-11-labeled tracers in monkeys. The most promising analog in the monkey study, iso-cetrozole, was evaluated in the human PET study. The highest to lowest inhibitory activity of the analogs toward aromatase in the microsomal fraction from marmoset placenta was in the following order: iso-cetrozole, nitro-cetrozole, cetrozole, and meta-cetrozole. This order showed good agreement with the order of the binding potential (BP) of each C-11-labeled analog to aromatase in the rhesus monkey brain. A human PET study using [C-11]iso-analog showed a similar distribution pattern of binding as that of [C-11]cetrozole. The time-activity curves showed that elimination of [C-11]iso-cetrozole from brain tissue was faster than that of C-11-cetrozole, indicating more rapid metabolism of [C-11]iso-cetrozole. [C-11]Cetrozole has preferable metabolic stability for brain aromatase imaging in humans, although [C-11]iso-cetrozole might also be useful to measure aromatase level in living human brain because of its high binding potential.

Automated summary

This study synthesized three analogs of cetrozole for PET imaging of aromatase in the brain, with iso-cetrozole showing the most promising results. The inhibitory activities of the analogs correlated well with their binding potentials to aromatase in animal models, and iso-cetrozole demonstrated faster metabolism in brain tissue compared to cetrozole.