A new iodinated tropane derivative (beta-CDIT) for in vivo dopamine transporter exploration: comparison with beta-CIT.

SPECT exploration of the dopamine transporter with tropane derivatives such as beta-CIT has already produced very valuable information in humans. However, the high affinity of this tracer for both dopamine and serotonin transporters and its slow in vivo kinetics provide the best images in humans more than 20 h after injection. In order to improve those properties, we performed structural changes in the tropane structure in the phenyl and nitrogen substituents for higher affinity and specificity and obtained a promising ligand, 2 beta-carbomethoxy-3 beta-(3',4' diclorophenyl)-8-(3-iodoprop-2E-enyl) nortropane (beta-CDIT). This iodinated ligand was characterized in vitro and in vivo in the rat in comparison with beta-CIT. In vitro competition studies revealed that beta-CIT and beta-CDIT similarly inhibited the binding of [3H]GBR 12935 (Ki = 27.5 and 29.0 nM, respectively). In contrast, competition studies with [3H]paroxetine and [3H]nisoxetine showed that beta-CDIT had a lower affinity for the serotonin transporter than beta-CIT (Ki = 50 and 3 nM, respectively) and also a lower affinity for the noradrenaline transporter than beta-CIT (Ki = 500 and 80 nM, respectively). In vivo studies in the rat showed that there was high and rapid uptake of [125I] beta-CDIT in the striatum. In addition, preinjection of GBR 12909 prevented accumulation of this ligand in the striatum by 80%, whereas only a 30% decrease was obtained for [125I] beta-CIT. It seems, therefore, that the combination of aromatic and nitrogen substitution improves the properties of tropane derivatives to provide an exclusive dopamine transporter ligand potentially usable in SPECT.

Iodolisuride and iodobenzamide, two ligands for SPECT exploration of the dopaminergic D2 receptors: a comparative study.

Iodobenzamide (IBZM) and iodolisuride (ILIS), which belong to different chemical families, are two radioligands used for SPECT imaging of dopamine D2 receptors. We have compared their cerebral biodistribution in control rats and their ability to detect quantitative modifications of D2 receptors in experimental models. IBZM and ILIS have a similar cerebral distribution in vivo in control rats and permitted the detection of upregulation of striatal dopamine D2 receptors in a model of chronic haloperidol treatment. Moreover, we observed that 1 h after injection of a saturating dose of haloperidol, IBZM uptake was 72% displaced from the striatum, while ILIS uptake was 50% displaced. In an experimental model of excitotoxic striatal lesion, the in vivo accumulation of IBZM was 30% decreased on the lesioned side, in agreement with a decrease in dopamine D2 receptor density. By contrast, the accumulation of ILIS was identical in the lesioned and in the intact striatum. From the results, it appears that IBZM and ILIS, which are both used to image dopamine D2 receptors in vivo, behave differently in pathological experimental models. The ligand for human exploration should then be chosen according to the suspected pathology.

Iododerivative of pargyline: a potential tracer for the exploration of monoamine oxidase sites by SPECT.

Monoamine oxidases are important in the regulation of monoaminergic neurotransmission. An increase in monoamine oxidase B (MAO B) has been observed in some neurodegenerative diseases, and therefore quantification of cerebral MAO B activity by SPECT would be useful for the diagnosis and therapeutic follow-up of these disorders. We have developed an iodinated derivative of pargyline, a selective inhibitor of MAO B, in order to explore this enzyme by SPECT. Stable bromo and iodo derivatives of pargyline were synthesized and chemically characterized. The radioiodinated ligand [125I]-2-iodopargyline was obtained with high specific activity from the bromo precursor by nucleophilic exchange. Affinity and selectivity of 2-iodopargyline were tested in vitro. Biodistribution study of [125I]-2-iodopargyline was performed in rats. Radioiodinated ligand were obtained in a no-carrier-added form. 2-iodopargyline has a higher in vitro affinity for MAO B than pargyline. However, the in vitro selectivity for MAO B was better for pargyline than for 2-iodopargyline. Ex vivo autoradiographic studies and in vivo saturation studies with selective inhibitors of MAO showed that the cerebral biodistribution of [125I]-2-iodopargyline in the rat is consistent with high level binding to MAO B sites in the pineal gland and in the thalamus. In conclusion, 2-iodopargyline preferentially binds in vivo to MAO B sites with high affinity. However, its selectivity for MAO B in rats is not very high, whereas this ligand binds to a lesser extent to MAO A. It will be then of great value to evaluate the specificity of 2-iodopargyline in humans. This new ligand labeled with 123I should therefore be a suitable tool for SPECT exploration of MAO B in the human brain.

Synthesis and characterization of [125I]N-(2-aminoethyl)-4-iodobenzamide as a selective monoamine oxidase B inhibitor.

We described the radiosynthesis of an analog of Ro 16-6491, [125I]N-(2-aminoethyl)-4-iodobenzamide, for SPECT exploration of the monoamine oxidase B (MAO-B) in human brain. The radiolabelling was carried out by nucleophilic exchange of the brominated precursor at solid-state phase in presence of ammonium sulphate. The radiochemical purity of radioiodinated product was higher than 95%. In comparison with Ro 16-6491, the in vitro studies showed a good selectivity of stable N-(2-aminoethyl)-4-iodobenzamide for MAO-B but a slightly lower affinity. Biodistribution studies in the rat showed a high and selective uptake of this compound in the pineal gland 1 h after i.v. injection. The cerebral uptake was low, but the coupling of [125I]N-(2-aminoethyl)-4-iodobenzamide with a lipophilic radical to enhance the passage through the blood-brain barrier can be envisaged.

Synthesis of 4'-iodo-5-methoxy-valerophenone O-(2-aminoethyl)oxime as an agent for exploration of serotoninergic transporter.

The serotonin reuptake process is observed in the central nervous system and in cells derived from the neural crest. It would therefore be of great interest to visualize this reuptake for brain exploration and to visualize the tumors derived from these cells (Apudome). Fluvoxamine has been described as a specific uptake inhibitor for serotonin uptake and we therefore supposed that an iodinated derivative of this compound would be a suitable tracer for this purpose. We had shown by computer-assisted investigation that the trifluoromethyl group of fluvoxamine can be replaced by iodine without changing the steric hindrance of the structure. We therefore expected that this result would allow the development of a new iodinated ligand for human exploration by SPECT which would inhibit for the serotoninergic transporter. This new ligand is 4'-iodo-5-methoxyvalerophenone O-(2-aminoethyl)oxime in its E configuration. In vitro binding studies demonstrated that this iodinated ligand has a weaker affinity for the serotonin uptake sites than fluvoxamine. Steric hindrance is not sufficient to predict affinity, other structural factors such as electronic density and dipole moment must be considered to explain the biological difference between fluvoxamine and its iodinated analog.

Radioiodinated tracers for the evaluation of dopamine receptors in the neonatal rat brain after hypoxic-ischemic injury.

In order to evaluate in vivo single-photon emission tomography (SPET) method of assessing cerebral function after hypoxic-ischemic injury in human neonates, we studied D1 and D2 dopamine receptors in a rat model. Seven-day-old rats underwent permanent unilateral common carotid ligation followed by exposure to 8% O2. Two weeks later, in brains with no visible loss of hemispheric volume, striatal dopaminergic receptors were studied, with [125I]TISCH and [125I]IBZM for the D1 and D2 dopamine receptors, respectively. Using [125I]TISCH, we observed no modifications of D1 receptors, but in contrast, ex vivo and in vitro autoradiographic experiments showed a 40% decrease in the striatal binding of [125I]IBZM on both the ipsilateral and the contralateral side to the carotid ligation. These alterations were detected with IBZM, a D2 dopamine receptor ligand usable for SPET imaging. Therefore, exploration of D2 receptors by SPET in human neonates suffering from perinatal hypoxia-ischemia may be valuable for the diagnosis and follow-up of cerebral function damages.

Comparison of two radioiodinated ligands of dopamine D2 receptors in animal models: iodobenzamide and iodoethylspiperone.

Several iodinated compounds have been developed for in vivo exploration of dopamine D2 receptors by SPECT. It is of great value to understand if the same information could be obtained with different radioligands. For this purpose, we compared in vivo properties of two iodinated ligands, iodoethylspiperone (IES) and iodobenzamide (IBZM), using different pharmacological and lesioning treatments in rats. Cerebral biodistribution performed by ex vivo autoradiograms and dissection of brain areas showed that IES and IBZM bound specifically to D2 receptors since a pre-injection of haloperidol prevented accumulation of both ligands. In contrast, when haloperidol was injected after IES or IBZM, only IBZM was displaced from its binding sites. This could be explained partly by a process of dopamine-dependent internalization with IES. The response to striatal quinolinic acid infusion for lesioning post-synaptic neurons was very different for IES and IBZM. In this model a decrease in IBZM accumulation occurred, corresponding to the loss of D2 receptors located on post-synaptic neurons. In contrast, a unexpected increase in IES accumulation was observed on the lesioned side. From these results we concluded that IES and IBZM, two iodinated ligands belonging to different pharmacological families, bound specifically to dopamine D2 receptors. However they have different properties in animal models. Therefore, it appears that IBZM is a more suitable ligand than IES to detect modifications of D2 receptors by in vivo exploration.