Faculty Bibliography

The regional distribution of [11C]d-threo-methylphenidate in mouse brain was very similar to that of [3H]WIN 35,428 ((-)-2 beta-carbomethoxy-3 beta-(4-fluorophenyl)tropane), and the two radioligands were displaced from striatum similarly after administration of the potent cocaine analog RTI-55 ((-)-2 beta-carbomethoxy-3 beta-(4-iodophenyl)tropane). However, while striatal [3H]WIN 35,428 increased between 5 and 30 min, striatal [11C]d-threo-methylphenidate halved. Thus [11C]d-threo-methylphenidate binds similarly to but more reversibly than [3H]WIN 35,428. The methyl ester of L-DOPA (L-3,4-dihydroxyphenylalanine; 200 mg/kg) plus benserazide plus clorgyline, which markedly elevates rat striatal extracellular dopamine (Wachtel and Abercrombie, 1994, J. Neurochem. 63, 108), decreased the mouse striatum-to-cerebellum ratio for [11C]d-threo-methylphenidate at 30 min by 13% (P < 0.05). In positron emission tomographic (PET) baboon studies [11C]d-threo-methylphenidate binding was insensitive to drugs expected to lower endogenous dopamine. These experiments suggest that normal synaptic dopamine does not compete for binding with [11C]d-threo-methylphenidate, and will not affect PET measures of dopamine transporter availability

Mechanistic positron emission tomography (PET) studies using the deuterium isotope effect and specific pharmacological intervention were undertaken to examine the behavior of 6-[18F]fluorodopamine (6-[18F]-FDA; 1) and (-)-6-[18F]fluoronorepinephrine [(-)-6-[18F]FNE; 2] in the baboon heart. Two regiospecifically deuterated derivatives of 6-[18F]FDA [alpha,alpha-D2 (3) and beta,beta-D2 (4)] were used to assess the contributions of monoamine oxidase (MAO) and dopamine beta-hydroxylase, respectively, to the clearance kinetics of 6-[18F]FDA. Compound 3 showed a reduced rate of clearance, consistent with MAO-catalyzed cleavage of the alpha C-D bond, whereas compound 4 showed no change, indicating that cleavage of the beta C-D bond is not a rate-limiting step. Pretreatment with pargyline, an MAO inhibitor, also decreased the rate of clearance. Desipramine and tomoxetine [norepinephrine (NE) uptake inhibitors], but not GBR-12909 (a dopamine uptake inhibitor), blocked the uptake of both (-)-6-[18F]FNE and 6-[18F]FDA, with (-)-6-[18F]FNE showing a higher degree of blockade. Chiral HPLC demonstrated that 6-[18F]FDA is stereoselectively converted to (-)-6-[18F]FNE in vivo in the rat heart. These studies demonstrate that (a) the more rapid clearance of 6-[18F]FDA relative to (-)-6-[18F]FNE can be largely accounted for by metabolism by MAO; (b) selective deuterium substitution can be used to protect a radiotracer from metabolism in vivo and to favor a particular pathway; (c) 6-[18F]FDA and (-)-6-[18F]FNE share the NE transporter; (d) 6-[18F]FDA is stereoselectively converted to (-)-6-[18F]FNE in vivo; and (e) the profile of radioactivity in the heart for 6-[18F]FDA is complex, probably including labeled metabolites as well as neuronal and nonneuronal uptake

BACKGROUND: The purposes of this study were to investigate the pharmacokinetics of methylphenidate hydrochloride (Ritalin) in the human brain, to compare them with those of cocaine, and to evaluate whether cocaine and methylphenidate compete for the same binding sites. METHODS: We used positron emission tomography to measure the temporal and spatial distribution of carbon 11 (11C)-labeled methylphenidate. These results were compared with those obtained previously for [11C]cocaine. Eight healthy male subjects, 20 to 51 years of age, were scanned with [11C]methylphenidate. Three were tested twice to assess test-retest variability, four were tested at baseline and after administration of methylphenidate, and one was tested with [11C]methylphenidate and [11C]cocaine. Two baboons were scanned to evaluate whether there was competition between cocaine and methylphenidate for the same binding sites in the brain. RESULTS: The uptake of [11C]methylphenidate in the brain was high (mean +/- SD, 7.5% +/- 1.5%), and the maximal concentration occurred in striatum. Pretreatment with methylphenidate decreased binding only in striatum (40%). Although the regional distribution of [11C]methylphenidate, was identical to that of [11C]cocaine and they competed with each other for the same binding sites, these two drugs differed markedly in their pharmacokinetics. Clearance of [11C]methylphenidate from striatum (90 minutes) was significantly slower than that of [11C]cocaine (20 minutes). For both drugs, their fast uptake in striatum paralleled the experience of the 'high.' For methylphenidate, the high decreased very rapidly despite significant binding of the drug in the brain. In contrast, for cocaine, the decline in the high paralleled its fast rate of clearance from the brain. CONCLUSION: We speculate that because the experience of the high is associated with the fast uptake of cocaine and methylphenidate in the brain, the slow clearance of methylphenidate from the brain may serve as a limiting factor in promoting its frequent self-administration

Cocaine analogs such as 3 beta-(4-iodophenyl)tropane-2 beta-carboxylic acid methyl ester (RTI-55 or beta CIT) with a higher affinity for the dopamine transporter (DAT) may be potentially useful in interfering with cocaine's actions in brain. This study evaluates the time course of the effects of RTI-55 on cocaine binding in baboon brain using PET and [11C]cocaine. [11C]Cocaine binding was measured prior to, and 90 minutes, 24 hours, 4-5 days and 11-13 days after RTI-55 (0.3 mg/kg i.v.). Parallel studies with [3H]cocaine and RTI-55 (0.5 mg/kg i.v. or 2 mg/kg i.p.) were performed in the mouse. RTI-55 significantly inhibited [11C]cocaine binding at 90 minutes and 24 hours after administration. The half-life for the clearance of RTI-55 from the DAT was estimated to be 2 to 3 days in the baboon brain. In the mouse brain, RTI-55 significantly inhibited [3H]cocaine binding at 60 and 180 minutes after administration and recovery was observed at 12 hours. These results document long-lasting inhibition of cocaine binding by RTI-55 and corroborate that binding kinetics of RTI-55 in striatum observed in imaging studies with [123I]RTI-55 represents binding to DATs

We compared the sensitivity of two dopamine transporter (DAT) ligands ([C-11]cocaine and [C-11]d-threo-methylphenidate) for measurement of extrastriatal DAT availability using positron emission tomography (PET) on separated groups of 10 age matched male volunteers (age range, 21-49 years). DAT availability was obtained using the ratio of the distribution volume in the region of interest to that in the cerebellum (Bmax'/Kd'+ 1). DAT availability measured with [C-11]d-threo-methylphenidate was highest in basal ganglia, followed by thalamus > temporal insula, cingulate > orbitofrontal, frontal and occipital cortices. A similar ranking order for DAT availability was obtained with [C-11]cocaine. Specific binding (Bmax'/Kd') of [C-11]cocaine in thalamus was 25-33% that of basal ganglia and [C-11]d-threo-methylphenidate in thalamus was 11-13% that of basal ganglia. The regional measures with [C-11]cocaine were significantly correlated with those of [C-11]d-threo-methylphenidate (p < or = 0.0001). These results document extrastriatal binding in human brain with two different DAT ligands

We synthesized the o-, m- and p-bromo derivatives of dl-threo-methylphenidate from the corresponding bromophenylacetonitriles by modification of the literature synthesis of methylphenidate (Panizzon, Helv. Chim. Acta 1944, 27, 1748). In in vitro binding assays all three dl-threo bromo compounds had higher affinities than methylphenidate for dopamine transporter sites labeled with [3H]2 beta-carbomethoxy-3 beta-(4-fluorophenyl)tropane ([3H]WIN 35,428; IC50 = 13, 4, 20 and 82 nM for o-, m-, and p-bromo compounds, and unsubstituted methylphenidate, respectively). They also bound more strongly than methylphenidate to norepinephrine reuptake sites labeled with [3H]nisoxetine (IC50 = 32, 20, 31 and 440 nM, respectively), but were weak ligands (IC50 > or = 1 microM) at the serotonin transporter labeled with [3H]paroxetine. In addition, the bromine substituted derivatives demonstrated similar activity to methylphenidate in vivo in rodents in terms of inhibition of heart uptake of [3H](-)-norepinephrine, elevation of striatal extracellular dopamine, and stimulation of locomotor activity

dl-threo-Methylphenidate (Ritalin) was labeled with carbon-11 (t1/2:20.4 minutes) in order to measure its pharmacokinetics, to evaluate it as a radiotracer for the presynaptic dopaminergic neuron, and to examine its sensitivity to the loss of dopaminergic neurons. Positron emission tomographic (PET) studies were carried out in the baboon to determine specificity for the presynaptic dopaminergic neuron and in humans to assess sensitivity to neuronal loss. Studies with [11C]dl-threo-methylphenidate ([11C]MP) in baboon demonstrated high regional uptake in the striatum. Peak uptake (0.04%/cc) occurred at 5-15 minutes post-injection. The half-time for clearance from peak uptake for [11C]MP was 60 minutes and the ratio between the radioactivity in the striatum and that in the cerebellum (ST/CB) ranged from 2.2 to 2.6 at 40 minutes. Repeated measures in the same baboon showed < or = 8% variability in the ST/CB ratio. Pretreatment with unlabeled methylphenidate (0.5 mg/kg) or GBR12909 (1.5 mg/kg) 30 minutes prior to [11C]MP injection markedly reduced the striatal but not the cerebellar uptake of [11C]MP, demonstrating the saturable and specific binding of [11C]MP to a site on the dopamine transporter in the brain. In both cases, the ratio of striatum to cerebellum (ST/CB) after pretreatment was reduced by about 43%. The ratios of distribution volumes at the steady-state for the striatum to cerebellum (ST/CB) for these two separate studies in the same baboon were reduced by 37 and 38%, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)

Positron emission tomography (PET), [11C]cocaine, and (-)-6-[18F]fluoronorepinephrine [(-)-6-[18F]NE] were used to determine the extent to which the binding of labeled cocaine in the baboon heart represents binding to the norepinephrine transporter and to characterize the functional consequences of cocaine administration on the norepinephrine transporter. Peak heart binding of [11C]cocaine was high (0.038-0.055%/g) and clearance was rapid (t1/2 from peak: 2.5-9 min) for both tracer doses and a pharmacological dose. The binding of a tracer dose of labeled cocaine could not be inhibited by desipramine, tomoxetine, cocaine, nomifensine, or benztropine. The behavior of a pharmacological dose of [11C]cocaine could not be distinguished from a tracer dose and also could not be inhibited by tomoxetine. However, pretreatment with cocaine profoundly inhibited norepinephrine uptake as assessed by (-)-6-[18F]NE. Recovery was slow with only 48% of the baseline (-)-6-[18F]NE uptake being recovered by 78 minutes after cocaine administration. [11C]Benzoylecgonine, a vasoactive metabolite of cocaine, showed negligible retention in heart. The results of this study (i.e., the rapid clearance of cocaine from the heart, the inability to inhibit cocaine binding with desipramine and tomoxetine, and its relatively long-lasting effects on norepinephrine uptake) reinforce the need to understand the link between cocaine pharmacokinetics and norepinephrine transporter function and its relationship to cardiotoxicity

(-)-Norepinephrine is the principal neurotransmitter of the mammalian sympathetic nervous system and a major CNS neurotransmitter. The simple ring fluorinated derivatives of (-)- and (+)-norepinephrine [(-)- and (+)6-fluoronorepinephrine] and dopamine (6-fluorodopamine) have been labeled with 18F in high specific activity (2-5 Ci/mumol) and evaluated as tracers for (-)-norepinephrine. Comparative PET studies of (-) and (+)-6-[18F]fluoronorepinephrine [(-)-6-[18F]FNE and (+)-6-[18F]FNE] and 6-[18F]fluorodopamine (6-[18F]FDA) in the same baboon showed strikingly different kinetics in the heart. Analysis of plasma showed more rapid metabolism of 6-[18F]FDA with only 1%-2% of 18F remaining as parent tracer at 10 min after injection of 6-[18F]FDA, in contrast to 28% and 17% remaining after injection of (-) and (+)-6-[18F]FNE. No changes in vital signs were observed at any time during the study. Pretreatment with desipramine (0.5 mg/kg), a tricyclic antidepressant drug which interacts with a binding site associated with norepinephrine reuptake, markedly decreased cardiac uptake of 6-[18F]FDA and (-)-6-[18F]FNE. However, a greater blocking effect was observed for (-)-6-[18F]FNE. These studies show that (-) and (+)-6-[18F]FNE are similar to (-)- and (+)-norepinephrine in their patterns of metabolism and clearance in the heart and that (-)-6-[18F]FNE is a promising tracer for endogenous (-)-norepinephrine

BMY 14802 is a compound containing fluorine developed as a potential antipsychotic drug. It has a moderate affinity for the sigma binding site and a very low affinity for dopamine D2 receptors and has been predicted to have antipsychotic properties without the side effect potential of existing drugs. To assess the brain uptake, pharmacokinetics, stereoselectivity and binding properties of this potential antipsychotic drug, enantiomerically pure samples of (-) and (+)-[18F]BMY 14802 were examined in a baboon with PET. A tissue distribution with racemic labeled BMY 14802 was also carried out in mice. Radiochemical yields of 15% at the end of bombardment (EOB) for the racemic mixture, and 5% for each enantiomer with a specific activity of 2-5 Ci/mumol at EOB were obtained. In baboons, [18F]BMY 14802 cleared rapidly from the plasma and the glucuronidated [18F]BMY 14802 appeared. Radioactivity peaked (0.04-0.07% dose/cc) in all areas of the brain examined at about 5 min postinjection. It then rapidly cleared to about 30% of peak value by 20 min postinjection and to less than 10% of peak by 60 min postinjection in all regions. A similar rapid clearance from brain was also observed in mice. Pretreatment with unlabeled BMY 14802 (7 mg/kg), did not produce the expected reductions in distribution volume and clearance halftimes consistent with receptor binding. Although the rapid kinetics of [18F]BMY 14802 made it difficult to resolve the processes of transport and binding of the labeled drug, the lack of regional distribution consistent with the known distribution of sigma binding sites as well as the lack of stereoselectivity suggest that the behavior of BMY 14802 in the brain is dominated by its transport properties in tissue rather than its binding to sigma sites. Moreover, its rapid clearance from brain may be a limiting factor in its use as an antipsychotic drug