Pridopidine selectively occupies sigma-1 rather than dopamine D2 receptors at behaviorally active doses

Dopamine stabilizers have stimulatory actions under low dopamine tone and inhibitory actions under high dopamine tone without eliciting catalepsy. These compounds are dopamine D-2 receptor (D2R) antagonists or weak partial agonists and may have pro-mnemonic and neuroprotective effects. The mechanism underlying their stimulatory and neuroprotective actions is unknown but could involve sigma-1R binding. The present study examined sigma-1R and D2R occupancy by the dopamine stabilizer pridopidine (ACR16) at behaviorally relevant doses in living rats. Rats were administered 3 or 15 mg/kg pridopidine, or saline, before injection of the radiotracer C-11-SA4503 (sigma-1R) or C-11-raclopride (D2R). Some animals received 60 mg/kg pridopidine and were only scanned with C-11-raclopride. Cerebral C-11-SA4503 binding was quantified using metabolite-corrected plasma input data and distribution volume (V (T)) calculated by Logan graphical analysis. C-11-raclopride binding was quantified using striatum-to-cerebellum ratios and binding potentials calculated with a simplified reference tissue model. Cunningham-Lassen plots indicated sigma-1R occupancies of 57 +/- 2 and 85 +/- 2 % after pretreatment of animals with 3 and 15 mg/kg pridopidine. A significant (44-66 %) reduction of C-11-raclopride binding was only observed at 60 mg/kg pridopidine. At doses shown to elicit neurochemical and behavioral effects, pridopidine occupied a large fraction of sigma-1Rs and a negligible fraction of D(2)Rs. Significant D2R occupancy was only observed at a dose 20-fold higher than was required for sigma-1R occupancy. The characteristics of dopamine stabilizers may result from the combination of high sigma-1R and low D2R affinity

In vivo evaluation of [F-18]FEAnGA-Me:a PET tracer for imaging beta-glucuronidase (beta-GUS) activity in a tumor/inflammation rodent model

Introduction: The PET tracer, 1-O-(4-(2-fluoroethyl-carbamoyloxymethyl)-2-nitrophenyl)-O-beta-D-glucopyronuronate ([F-18]FEAnGA), was recently developed for PET imaging of extracellularl beta-glucuronidase (beta-GUS). However,[F-18]FEAnGA exhibited rapid renal clearance, which resulted in a relatively low tracer uptake in the tumor. To improve the pharmacokinetics of [F-18]FEAnGA, we developed its more lipophilic methyl ester analog, [F-18]FEAnGA-Me. Methods: [F-18]FEAnGA-Me was obtained by alkylation of the O-protected glucuronide methyl ester precursor with [F-18]-fluoroethylamine ([F-18]FEA), followed by removal of the acetate protecting groups with NaOMe/MeOH. The PET tracer was evaluated by in vitro and in vivo studies. Results: [F-18]FEAnGA-Me was obtained in 5%-10% overall radiochemical yield. It is 10-fold less hydrophilic than [F-18]FEAnGA and it is stable in PBS and in the presence of beta-GUS for 1 h. However, in the presence of esterase or plasma [F-18]FEAnGA-Me is converted to [F-18]FEAnGA, and subsequently converted to [F-18]FEA by beta-GUS. MicroPET studies in Wistar rats bearing a C6 glioma and a sterile inflammation showed similar uptake in tumors after injection of either [F-18]FEAnGA-Me or [F-18]FEAnGA. Both tracers had a rapid two-phase clearance of total plasma radioactivity with a half-life of 1 and 8 min. The [F-18]FEAnGA fraction generated from [F-18]FEAnGA-Me by in vivo hydrolysis had a circulation half-life of 1 and 11 min in plasma. Similar distribution volume in the viable part of the tumor was found after injection of either [F-18]FEAnGA-Me or [F-18]FEAnGA. Conclusion: The imaging properties of [F-18]FEAnGA-Me were not significantly better than those of [F-18]FEAnGA. Therefore, other strategies should be applied in order to improve the kinetics of these tracers. (C) 2012 Elsevier Inc. All rights reserved

Steroid hormones affect binding of the sigma ligand C-11-SA4503 in tumour cells and tumour-bearing rats

PURPOSE: Sigma receptors are implicated in memory and cognitive functions, drug addiction, depression and schizophrenia. In addition, sigma receptors are strongly overexpressed in many tumours. Although the natural ligands are still unknown, steroid hormones are potential candidates. Here, we examined changes in binding of the sigma-1 agonist (11)C-SA4503 in C6 glioma cells and in living rats after modification of endogenous steroid levels. METHODS: (11)C-SA4503 binding was assessed in C6 monolayers by gamma counting and in anaesthetized rats by microPET scanning. C6 cells were either repeatedly washed and incubated in steroid-free medium or exposed to five kinds of exogenous steroids (1 h or 5 min before tracer addition, respectively). Tumour-bearing male rats were repeatedly treated with pentobarbital (a condition known to result in reduction of endogenous steroid levels) or injected with progesterone. RESULTS: Binding of (11)C-SA4503 to C6 cells was increased (~50%) upon removal and decreased (~60%) upon addition of steroid hormones (rank order of potency: progesterone > allopregnanolone = testosterone = androstanolone > dehydroepiandrosterone-3-sulphate, IC(50) progesterone 33 nM). Intraperitoneally administered progesterone reduced tumour uptake and tumour-to-muscle contrast (36%). Repeated treatment of animals with pentobarbital increased the PET standardized uptake value of (11)C-SA4503 in tumour (16%) and brain (27%), whereas the kinetics of blood pool radioactivity was unaffected. CONCLUSIONS: The binding of (11)C-SA4503 is sensitive to steroid competition. Since not only increases but also decreases of steroid levels affect ligand binding, a considerable fraction of the sigma-1 receptor population in cultured tumour cells or tumour-bearing animals is normally occupied by endogenous steroids

Binding of the Dual-Action Anti-Parkinsonian Drug AG-0029 to Dopamine D-2 and Histamine H-3 Receptors:A PET Study in Healthy Rats

Introduction: Parkinson's disease (PD) is a neurodegenerative disorder characterized by motor dysfunction and a diverse range of nonmotor symptoms. Functional relationships between the dopaminergic and histaminergic systems suggest that dual-action pharmaceuticals like AG-0029 (D-2/D-3 agonist/H-3 antagonist) could ameliorate both the motor and cognitive symptoms of PD. The current study aimed to demonstrate the interaction of AG-0029 with its intended targets in the mammalian brain using positron emission tomography (PET). Methods: Healthy male Wistar rats were scanned with a small-animal PET camera, using either the dopamine D-2/D-3 receptor ligand [C-11]raclopride or the histamine H-3 receptor ligand [C-11]GSK-189254, before and after treatment with an intravenous, acute, single dose of AG-0029. Dynamic [C-11]raclopride PET data (60 min duration) were analyzed using the simplified reference tissue model 2 (SRTM2) with cerebellum as reference tissue and the nondisplaceable binding potential as the outcome parameter. Data from dynamic [C-11]GSK-189254 scans (60 min duration) with arterial blood sampling were analyzed using Logan graphical analysis with the volume of distribution (V-T) as the outcome parameter. Receptor occupancy was estimated using a Lassen plot. Results: Dopamine D-2/3 receptor occupancies in the striatum were 22.6 +/- 18.0 and 84.0 +/- 3.5% (mean +/- SD) after administration of 0.1 and 1 mg/kg AG-0029, respectively. In several brain regions, the V-T values of [C-11]GSK-189254 were significantly reduced after pretreatment of rats with 1 or 10 mg/kg AG-0029. The H-3 receptor occupancies were 11.9 +/- 8.5 and 40.3 +/- 11.3% for the 1 and 10 mg/kg doses of AG-0029, respectively. Conclusions: Target engagement of AG-0029 as an agonist at dopamine D-2/D-3 receptors and an antagonist at histamine H-3 receptors could be demonstrated in the rat brain with [C-11]raclopride and [C-11]GSK-189254 PET, respectively. The measured occupancy values reflect the previously reported high (subnanomolar) affinity of AG-0029 to D-2/D-3 and moderate (submicromolar) affinity to H-3 receptors

Use of 11C-MPDX and PET to Study Adenosine A1 Receptor Occupancy by Nonradioactive Agonists and Antagonists

Adenosine A1 receptors (A1Rs) in human and rodent brains can be visualized with the radioligand 8-dicyclopropylmethyl-1-11C-methyl-3-propylxanthine (11C-MPDX) and PET. Here we investigated whether A1R occupancy by nonradioactive agonists and antagonists can be assessed with this technique. Methods: Small-animal PET scans with arterial blood sampling were obtained for 4 groups of isoflurane-anesthetized Wistar rats: controls (n = 7); pretreated with a centrally active A1R agonist, N6-cyclopentyladenosine (CPA; 0.25 mg/kg intraperitoneally; dissociation constant, 0.48 nM; n = 7); pretreated with a moderate dose of caffeine (antagonist for A1Rs and adenosine A2A receptors; 4 mg/kg intraperitoneally; dissociation constant, 11 µM; n = 6); and pretreated with a high dose of caffeine (40 mg/kg intraperitoneally; n = 6). Results: The administration of CPA resulted in a strong reduction (>50%) in the heart rate, and caffeine administration resulted in a small increase (10%–15%). A caffeine dose of 4 mg/kg (n = 6) resulted in 65.9% A1R occupancy, and a dose of 40 mg/kg (n = 6) resulted in 98.5% occupancy (calculated from a modified Lassen plot). However, the administration of CPA resulted in an increase in 11C-MPDX binding in the brain. Conclusion: Small-animal PET with 11C-MPDX can be used to assess antagonist but not agonist binding at A1Rs. Changes in tracer uptake after the administration of CPA resembled previously reported changes induced by treatment of rats with ethanol and an adenosine kinase inhibitor (ABT702). Thus, the administration of an exogenous agonist or increasing the level of an endogenous agonist have similar effects. Agonists and antagonists may bind to different sites on the A1R protein having allosteric interactions.

PET imaging of demyelination and remyelination in the cuprizone mouse model for multiple sclerosis:A comparison between [C-11]CIC and [C-11]MeDAS

Multiple Sclerosis (MS) is a neurodegenerative disease characterized by demyelinated lesions. PET imaging using specific myelin radioligands might solve the lack of a specific imaging tool for diagnosing and monitoring demyelination and remyelination in MS patients. In recent years, a few tracers have been developed for in vivo PET imaging of myelin, but they have not been fully evaluated yet. In this study, we compared [(11)C]CIC and [(11)C]MeDAS as PET tracers for monitoring demyelination and remyelination in cuprizone-fed mice. The ex vivo biodistribution of [(11)C]CIC showed decreased tracer uptake in mice fed with 0.2% cuprizone diet for 5 weeks, as compared to control mice. However, tracer uptake did not increase again after normal diet was restored for 5 weeks (remyelination). Surprisingly, in vivo PET imaging with [(11)C]CIC in cuprizone-fed mice revealed a significant reduction in whole brain tracer uptake after 5 weeks of remyelination. No correlation between ex vivo biodistribution and in vivo imaging data was found for [(11)C]CIC (r(2)=0.15, p=0.11). However, a strong correlation was found for [(11)C]MeDAS (r(2)=0.88, p<0.0001). [(11)C]MeDAS ex vivo biodistribution revealed significant decreased brain uptake in the demyelination group, as compared to controls and increased the tracer uptake after 5 weeks of remyelination. [(11)C]MeDAS images showed a low background signal and clear uptake in the brain white matter and spinal cord. Taken together, the results of this comparative study between [(11)C]CIC and [(11)C]MeDAS clearly show that [(11)C]MeDAS is the preferred PET tracer to monitor myelin changes in the brain and spinal cord in vivo

Use of 11C-MPDX and PET to study adenosine A1 receptor occupancy by nonradioactive agonists and antagonists

BACKGROUND: Adenosine A1 receptors (A1Rs) in human and rodent brains can be visualized with the radioligand 8-dicyclopropylmethyl-1-(11)C-methyl-3-propylxanthine ((11)C-MPDX) and PET. Here we investigated whether A1R occupancy by nonradioactive agonists and antagonists can be assessed with this technique. METHODS: Small-animal PET scans with arterial blood sampling were obtained for 4 groups of isoflurane-anesthetized Wistar rats: controls (n = 7); pretreated with a centrally active A1R agonist, N(6)-cyclopentyladenosine (CPA; 0.25 mg/kg intraperitoneally; dissociation constant, 0.48 nM; n = 7); pretreated with a moderate dose of caffeine (antagonist for A1Rs and adenosine A2A receptors; 4 mg/kg intraperitoneally; dissociation constant, 11 μM; n = 6); and pretreated with a high dose of caffeine (40 mg/kg intraperitoneally; n = 6). RESULTS: The administration of CPA resulted in a strong reduction (>50%) in the heart rate, and caffeine administration resulted in a small increase (10%-15%). A caffeine dose of 4 mg/kg (n = 6) resulted in 65.9% A1R occupancy, and a dose of 40 mg/kg (n = 6) resulted in 98.5% occupancy (calculated from a modified Lassen plot). However, the administration of CPA resulted in an increase in (11)C-MPDX binding in the brain. CONCLUSION: Small-animal PET with (11)C-MPDX can be used to assess antagonist but not agonist binding at A1Rs. Changes in tracer uptake after the administration of CPA resembled previously reported changes induced by treatment of rats with ethanol and an adenosine kinase inhibitor (ABT702). Thus, the administration of an exogenous agonist or increasing the level of an endogenous agonist have similar effects. Agonists and antagonists may bind to different sites on the A1R protein having allosteric interactions

PET imaging of glucose metabolism, neuroinflammation and demyelination in the lysolecithin rat model for multiple sclerosis

BACKGROUND: Injection of lysolecithin in the central nervous system results in demyelination accompanied by local activation of microglia and recruitment of monocytes. Positron-emission tomography (PET) imaging, using specific tracers, may be an adequate technique to monitor these events in vivo and therefore may become a tool for monitoring disease progression in multiple sclerosis (MS) patients. OBJECTIVES: The objective of this paper is to evaluate the potential of PET imaging in monitoring local lesions, using [(11)C]MeDAS, [(11)C]PK11195 and [(18)F]FDG as PET tracers for myelin density, microglia activation and glucose metabolism, respectively. METHODS: Sprague-Dawley rats were stereotactically injected with either 1% lysolecithin or saline in the corpus callosum and striatum of the right brain hemisphere. PET imaging was performed three days, one week and four weeks after injection. Animals were terminated after PET imaging and the brains were explanted for (immuno)histochemical analysis. RESULTS: PET imaging was able to detect local demyelination induced by lysolecithin in the corpus callosum and striatum with [(11)C]MeDAS and concomitant microglia activation and monocyte recruitment with [(11)C]PK11195. [(18)F]FDG imaging demonstrated that glucose metabolism was maintained in the demyelinated lesions. CONCLUSION: PET imaging with multiple tracers allows simultaneous in vivo monitoring of myelin density, neuroinflammation and brain metabolism in small MS-like lesions, indicating its potential to monitor disease progression in MS patients

PET imaging of focal demyelination and remyelination in a rat model of multiple sclerosis: Comparison of [C-11]MeDAS, [C-11]CIC and [C-11]PIB

PURPOSE: In this study, we compared the ability of [(11)C]CIC, [(11)C]MeDAS and [(11)C]PIB to reveal temporal changes in myelin content in focal lesions in the lysolecithin rat model of multiple sclerosis. Pharmacokinetic modelling was performed to determine the best method to quantify tracer uptake. METHODS: Sprague-Dawley rats were stereotactically injected with either 1 % lysolecithin or saline into the corpus callosum and striatum of the right brain hemisphere. Dynamic PET imaging with simultaneous arterial blood sampling was performed 7 days after saline injection (control group), 7 days after lysolecithin injection (demyelination group) and 4 weeks after lysolecithin injection (remyelination group). RESULTS: The kinetics of [(11)C]CIC, [(11)C]MeDAS and [(11)C]PIB was best fitted by Logan graphical analysis, suggesting that tracer binding is reversible. Compartment modelling revealed that all tracers were fitted best with the reversible two-tissue compartment model. Tracer uptake and distribution volume in lesions were in agreement with myelin status. However, the slow kinetics and homogeneous brain uptake of [(11)C]CIC make this tracer less suitable for in vivo PET imaging. [(11)C]PIB showed good uptake in the white matter in the cerebrum, but [(11)C]PIB uptake in the cerebellum was low, despite high myelin density in this region. [(11)C]MeDAS distribution correlated well with myelin density in different brain regions. CONCLUSION: This study showed that PET imaging of demyelination and remyelination processes in focal lesions is feasible. Our comparison of three myelin tracers showed that [(11)C]MeDAS has more favourable properties for quantitative PET imaging of demyelinated and remyelinated lesions throughout the CNS than [(11)C]CIC and [(11)C]PIB