PET evaluation of a tetracyclic, atypical antidepressant, [N-methyl-11C]mianserin, in the living porcine brain.

We synthesized [N-methyl-11C]mianserin by alkylation of N-desmethyl mianserin with [11C]methyl iodide followed by HPLC purification. We used PET for determining the regional cerebral pharmacokinetics of the radiotracer in anesthetized swine. [N-methyl-11C]Mianserin entered most brain regions readily (range of K1 values: 0.66-1.13), reaching highest levels in the basal ganglia and thalamus. The binding potential of [N-methyl-11C]mianserin was relatively low (range: 0.07-0.50), but regional differences were nonetheless observed, with highest values in the temporal cortex and lowest values in the brainstem. These PET findings, which are the first ones for a tetracyclic, antidepressant drug, show that [N-methyl-11C]mianserin has only a limited degree of regional specificity of binding in the living brain.

Normalization of markers for dopamine innervation in striatum of MPTP-lesioned miniature pigs with intrastriatal grafts.

As part of the DaNeX study, the uptake and binding of several positron emitting tracers was recorded in brain of healthy Göttingen minipigs, in minipigs with a syndrome of parkinsonism due to MPTP intoxication, and in parkinsonian minipigs which had received intrastriatal grafts of mesencephalic neurons from fetal pigs. The specific binding of [11C]NS 2214 to catecholamine uptake sites was reduced by two thirds in striatum of the intoxicated animals, while the rate constant for the decarboxylation of [18F]fluorodopa was reduced by 50% in the intoxicated animals. Several months after grafting, both pre-synaptic markers of dopamine fibres were normal in striatum. Dopamine depletion or grafting were without effect on the cerebral perfusion rate, measured with [15O]-water, did not alter the rate of oxygen metabolism (CMRO2) in brain, and did not alter the binding potential of tracers for dopamine D1 or D2 receptors in pig striatum. However, the grafting was associated with a local increase in the binding of [11C]PK 11195, a tracer for reactive gliosis, suggesting that an immunological reaction occurs at the site of graft, which might potentially have reduced the graft patency. However, this apparent immunological response did not preclude the re-establishment of normal [18F]fluorodopa and [11C]NS 2214 uptake in the allografted striatum.

Synthesis and evaluation of racemic [(11)C]NS2456 and enantiomers as selective serotonin reuptake radiotracers for PET.

Positron emission tomography (PET) radiotracers are needed for quantifying serotonin uptake sites in the living brain. Therefore, we evaluated a new selective serotonin reuptake inhibitor, NS2456, to determine whether it is suited for use in PET. Racemic NS2456 [(1RS,5SR)-8-methyl-3-[4-trifluoromethoxyphenyl]-8-azabicyclo [3.2.1]oct-2-ene] and its N-demethylated analog, racemic NS2463, selectively inhibited serotonin uptake in rat brain synaptosomes; their IC(50) values were 3000-fold lower for [(3)H]serotonin than for either [(3)H]dopamine or [(3)H]noradrenaline. The enantiomers of NS2463 were also potent inhibitors of serotonin uptake in vitro, but they failed to show stereoselectivity. Racemic NS2463 as well as its enantiomers were radiolabelled by N-methylation with C-11, yielding [(11)C]NS2456 for use in PET of the living porcine brain. The compounds crossed the blood-brain barrier rapidly and accumulated preferentially in regions rich in serotonin uptake sites (e.g., brainstem, subthalamus and thalamus). However, their binding potentials were relatively low and no stereoselectivity was found. Thus, neither racemic [(11)C]NS2456 nor its [(11)C]-labelled enantiomers are ideal for PET neuroimaging of neuronal serotonin uptake sites.

Kinetics of the metabolism of four PET radioligands in living minipigs.

Most radioligands are substantially metabolised in peripheral organs during the course of positron emission tomography (PET) recordings. Accurate determination of plasma concentrations of unmetabolised radioligands is often important for quantification of data from PET studies. The fractions of untransformed radioligand and radioactive metabolites in plasma extracts must then be measured. Temporal changes in these fractions are influenced by the rate constant of appearance of total radioactive metabolites in plasma (apparent rate constant of metabolism in plasma, k(0)) and the net rate constant of elimination of all radioactive metabolites from plasma (k(-1)). In order to clarify the relationship between radioligand fractions and rate constants, plasma samples collected from Göttingen minipigs during PET recordings using four different binding site ligands were analysed by radio high performance liquid chromatography. The calculated plasma concentrations of parent compounds and their radioactive metabolites were used to calculate k(0) and k(-1) for 11C-labelled NNC 112, NS 2214, PK 11195 and raclopride in minipigs using a novel application of the tissue-slope intercept plot. In general, the apparent rate constant of metabolism in plasma was found to be greater in the minipig than in man. The reported kinetic analysis enables the apparent metabolism of PET radioligands in plasma to be quantified.