Evaluation of (99m)Tc-labeled tropanes with alkyl substituents on the 3beta-phenyl ring as potential dopamine transporter tracers.

Technetium(V)-oxo-3beta-(4-chlorophenyl)-8-methyl-8-azabicyclo[3.2.1]oct-2-yl[N-(2-mercaptoethyl), N-(N'-(2-mercaptoethyl)-2-aminoethyl)]-aminomethyl ((99m)Tc-TRODAT-1) and three derivatives with one or two substituents on the 3beta-phenyl ring (4-methylphenyl, 4-ethylphenyl and 2,4-dimethylphenyl) were prepared and evaluated as potential imaging agents for the central nervous dopamine transporter (DAT). Labeling of the ligands with (99m)Tc yielded for each of them a mixture of two radiolabeled species, which were purified and isolated using reversed-phase high-performance liquid chromatography. Employing radio-LC-MS, we found both species to have the same molecular mass suggesting diastereoisomers. After intravenous injection in mice and rats, the compounds were stable in vivo and no important metabolites were found in plasma or urine. Replacement of the 4-chloro atom on the 3beta-phenyl ring by a methyl group causes no loss of affinity for the DAT system. However, substitution of an ethyl group for the 4-chloro atom or introduction of a second methyl group in the 2-position of the phenyl ring results in a serious reduction of the affinity for the DAT transporter. Ex vivo autoradiography on mice brain slices and biodistribution studies in rats showed specific uptake of (99m)Tc-TRODAT-1 and the 4-methylphenyl derivative in striatum and putamen. Although the 4-ethylphenyl and 2,4-dimethylphenyl derivatives show brain uptake in rats and mice, no specific uptake in striatum was found. In addition, differences in biological behavior between the different diastereomers were observed. In conclusion, small changes to (99m)Tc-TRODAT-1 at the phenyl ring in the 3beta position of the tropane moiety significantly change the biological behavior of the studied compounds.

Biological evaluation of a technetium-99m-labeled integrated tropane-BAT and its piperidine congener as potential dopamine transporter imaging agents.

INTRODUCTION: Recently, we have reported modification of (99m)Tc-TRODAT-1 by integrating the N2S2 metal chelating unit and the tropane skeleton. Results of a preliminary biodistribution study in rats were promising with respect to brain uptake. The present report deals with the further biological characterization of the (99m)Tc-labelled integrated TRODAT derivatives ((99m)Tc-TropaBAT and (99m)Tc-norchloro-TropaBAT) and with the synthesis and biological evaluation of a novel (99m)Tc-labelled piperidine-based derivative ((99m)Tc-PipBAT). METHODS: Biodistribution of all radiolabelled complexes was studied in normal mice. A more detailed ex vivo intracerebral distribution study of the two (99m)Tc-TropaBAT complexes was additionally performed in normal rats. Autoradiography of brain sections of normal mice (with or without pretreatment with FP-beta-CIT or haloperidol) and rats was performed. Affinity for the dopamine transporter (DAT) was also assessed in vitro in the presence or absence of cocaine. RESULTS: Both (99m)Tc-TropaBAT complexes show a slightly higher brain uptake than (99m)Tc-TRODAT-1, but the striatum/cerebellum activity ratio is less favourable. Nevertheless, significant striatal uptake was detected after ex vivo autoradiography, but this uptake was also observed after pretreatment with FP-beta-CIT. Unexpectedly, no striatal uptake was detected after in vitro incubation of mouse brain sections with the tracer agents. For (99m)Tc-PipBAT, neither brain uptake nor in vitro striatal uptake was found. CONCLUSION: Both (99m)Tc-TropaBAT complexes exhibit similar diffusion into brain as (99m)Tc-TRODAT-1, and ex vivo autoradiography shows significant striatal uptake. However, the inferior striatum/cerebellum activity ratio, the striatal uptake in mice pretreated with FP-beta-CIT or haloperidol, and the lack of striatal uptake during in vitro incubation prove that the DAT is not targeted. Brain uptake disappears when the tropane skeleton is replaced by a piperidine ring, and also in this case no striatal uptake is found in vitro.

Development and biological evaluation of 99mTc-BAT-tropane esters.

Two (99m)Tc-BAT-tropane conjugates, i.e., technetium(V)-oxo-3-[N-(2-mercaptoethyl), N-(N'-(2-mercaptoethyl)-2-aminoethyl)]-aminopropyl 3beta-(4-chlorophenyl)-8-methyl-8-azabicyclo [3.2.1]octane-2beta-carboxylate and the corresponding norchloro derivative, were prepared and evaluated as potential imaging agents for the central nervous dopamine transporter (DAT) system. In these compounds, a tropane and a (99m)Tc-BAT moiety were linked through an ester bond. Both compounds were formed as a mixture of two diastereomers which could be purified and isolated using reversed-phase high-performance liquid chromatography (HPLC). Radio-LC-MS analysis supported the hypothesised structure of the synthesised technetium complexes. After intravenous injection in mice and rats, the compounds were stable in vivo, and no important metabolites were found in plasma or urine. In vitro testing suggested specific competitive binding to the DAT system, but in vivo experiments in rats showed no significant brain uptake for the diastereomers of both compounds; neither was there any specific uptake in the striatum. The results suggest that replacement of a methylene linker by an ester does not seriously affect the binding properties of the tropane conjugates to the dopamine transporter but results in a drastic reduction of passage over the blood-brain barrier (BBB).

Synthesis and biological evaluation of a technetium-99m(I)-tricarbonyl-labelled phenyltropane derivative.

A new tropane derivative was synthesized by combining a tridentate ligand, N-(2-picolylamine)-N-acetic acid (2-PAA), and a phenyltropane derivative. It was labelled with a [(99m)Tc(CO)(3)](+) moiety, resulting in the formation of two stable and neutral lipophilic isomers. Their identity was confirmed using radio-LC-MS. In normal mice, no brain uptake was observed for any of the isomers and in vitro autoradiography using mouse brain sections showed no specific uptake in the striatal area.

Technetium-99m labelled integrated tropane-BAT as a potential dopamine transporter tracer.

To reduce the molecular weight of 99mTc-labelled tropanes with the aim to enhance the passage over the blood-brain barrier, a so-called integrated tropane-BAT construct was developed. For this purpose a mercaptoethyl substituent was attached to the amine nitrogen atom of a nortropane precursor and the methyl carboxylate in 2beta-position was converted to a 2-mercaptoethylaminomethylene substituent. This integrated tropane-BAT construct could be labelled efficiently (85-90%) with technetium-99m. Results of LC-MS analysis of the tracer agent support the assumed structure. Biodistribution studies in normal rats (n=3) showed a slightly higher brain uptake for the new tracer agents as compared to 99mTc-TRODAT-1. These results indicate that further biological evaluation of the integrated 99mTc-tropane-BAT is warranted.