Radiosynthesis and Biological Investigation of a Novel Fluorine-18 Labeled Benzoimidazotriazine-Based Radioligand for the Imaging of Phosphodiesterase 2A with Positron Emission Tomography

A specific radioligand for the imaging of cyclic nucleotide phosphodiesterase 2A (PDE2A) via positron emission tomography (PET) would be helpful for research on the physiology and disease-related changes in the expression of this enzyme in the brain. In this report, the radiosynthesis of a novel PDE2A radioligand and the subsequent biological evaluation were described. Our prospective compound 1-(2-chloro-5-methoxy phenyl)-8-(2-fluoropyridin-4-yl)-3- methylbenzo[e]imidazo[5,1-c][1,2,4]triazine, benzoimidazotriazine (BIT1) (IC50 PDE2A = 3.33 nM; 16-fold selectivity over PDE10A) was fluorine-18 labeled via aromatic nucleophilic substitution of the corresponding nitro precursor using the K[18F]F-K2.2.2-carbonate complex system. The new radioligand [18F]BIT1 was obtained with a high radiochemical yield (54 ± 2%, n = 3), a high radiochemical purity (≥99%), and high molar activities (155–175 GBq/μmol, n = 3). In vitro autoradiography on pig brain cryosections exhibited a heterogeneous spatial distribution of [18F]BIT1 corresponding to the known pattern of expression of PDE2A. The investigation of in vivo metabolism of [18F]BIT1 in a mouse revealed sufficient metabolic stability. PET studies in mouse exhibited a moderate brain uptake of [18F]BIT1 with a maximum standardized uptake value of ~0.7 at 5 min p.i. However, in vivo blocking studies revealed a non-target specific binding of [18F]BIT1. Therefore, further structural modifications are needed to improve target selectivity.


Introduction
The cyclic nucleotide phosphodiesterases (PDEs) are a superfamily of enzymes catalyzing the hydrolysis of the intracellular secondary messengers, cyclic adenosine monophosphate (cAMP) and cyclic guanosine monophosphate (cGMP) [1][2][3]. These secondary messengers are involved in a great variety of cellular functions associated with normal and pathophysiological processes in the brain and periphery [3][4][5][6].
The dual-substrate enzyme PDE2A is abundantly expressed in brain, in particular, in caudate, nucleus accumbens, cortex, hippocampus [3,8,9], amygdala [10,11], substantia nigra, as well as olfactory tubercle [11,12], while the expression in the midbrain, hindbrain, and cerebellum is comparatively low [8,11,12]. This specific distribution indicates a role of PDE2A in the modulation of complex neuronal processes, such as learning, concentration, memory, emotion, depression, anxiety, and CNS related disorder [10,13,14]. The pharmacological inhibition of PDE2A has been evaluated in preclinical studies, thus suggesting PDE2A inhibitors as a potential treatment for neurodegenerative diseases, such as Alzheimer's disease, schizophrenia, and dementia [15,16]. PDE2A inhibition has the potential to prolong the duration of cAMP-and cGMP-dependent signaling pathways, eventually improving neural plasticity and memory function [3,13,17].
Positron emission tomography (PET) is a molecular imaging modality that enables the visualization, characterization, and measurement of molecular targets and biochemical processes in living systems [18]. Accordingly, a PDE2A specific radiotracer would allow quantification of PDE2A expression, as well as disease-related changes thereof.
The so far most developed PDE2A radioligands are shown in Figure 1. The first highly potent PDE2A compound [ 18 F]B-23 (IC 50 hPDE2A = 1 nM; IC 50 rPDE10A = 11 nM) was developed by Janssen Pharmaceutica NV (Beerse, Belgium) [10,19]. Biodistribution and microPET imaging studies in rats demonstrated high uptake of activity in the striatum; however, brain-penetrating radio-metabolites limited further evaluation. Pfizer Inc. (New York, NY, USA) also reported on a highly affine PDE2A radioligand, [ 18 F]PF-05270430 (IC 50 hPDE2A = 0.5 nM; IC 50 hPDE10A >3000 nM) [10,20], which has been evaluated in monkeys [20] and translated to clinical trials [21,22]. [ 18 F]PF-05270430 showed high target-specific accumulation in the putamen, caudate, and nucleus-accumbens, as well as good metabolic stability and a favorable kinetic profile, pointing out [ 18 F]PF-05270430 as a promising PDE2A PET ligand [21]. However, using the cerebellum as a reference region, the estimated binding potential of [ 18 F]PF-05270430 was low, and the authors concluded that further studies are required to validate the suitability of the cerebellum as a reference region [21].
In parallel to Pfizer, our group developed further PDE2A radioligands on the basis of pyridoimidazotriazine. The recently published compounds [ 18 F]TA3 (IC 50 PDE2A = 11.4 nM; IC 50 PDE10A = 318 nM) and [ 18 F]TA4 (IC 50 PDE2A = 7.3 nM; IC 50 PDE10A = 913 nM) ( Figure 1) were characterized by high potency and selectivity towards PDE2A [24]. Notably, both radiotracers were found to be suitable radioligands for in vitro imaging of PDE2A; however, in vivo metabolism studies revealed a high fraction of polar radio-metabolites in the brain limiting their use for in vivo PDE2A imaging. The latest radioligand out of this series, [ 18 F]TA5 ((IC 50 PDE2A = 3.0 nM; IC 50 PDE10A >1000 nM, Figure 1), exhibited the highest potency towards PDE2A and selectivity over PDE10A. However, autoradiographic studies of [ 18 F]TA5 showed a homogenous and non-displaceable binding in rat and pig brain cryosections, indicating an insufficient specificity of this radioligand [25]. In addition, [ 18 F]TA5 is degraded extremely fast in the mouse. Therefore, we decided to perform further structural modifications to develop fluorine-18 labeled PET tracers with improved metabolic stability for the molecular imaging of PDE2A.  [10,19,20,[23][24][25].
In parallel to Pfizer, our group developed further PDE2A radioligands on the basis of pyridoimidazotriazine. The recently published compounds [ 18 F]TA3 (IC50 PDE2A = 11.4 nM; IC50 PDE10A = 318 nM) and [ 18 F]TA4 (IC50 PDE2A = 7.3 nM; IC50 PDE10A = 913 nM) ( Figure 1) were characterized by high potency and selectivity towards PDE2A [24]. Notably, both radiotracers were found to be suitable radioligands for in vitro imaging of PDE2A; however, in vivo metabolism studies revealed a high fraction of polar radio-metabolites in the brain limiting their use for in vivo PDE2A imaging. The latest radioligand out of this series, [ 18 F]TA5 ((IC50 PDE2A = 3.0 nM; IC50 PDE10A >1000 nM, Figure 1), exhibited the highest potency towards PDE2A and selectivity over PDE10A. However, autoradiographic studies of [ 18 F]TA5 showed a homogenous and non-displaceable binding in rat and pig brain cryosections, indicating an insufficient specificity of this radioligand [25]. In addition, [ 18 F]TA5 is degraded extremely fast in the mouse. Therefore, we decided to perform further structural modifications to develop fluorine-18 labeled PET tracers with improved metabolic stability for the molecular imaging of PDE2A.
In our continuous effort to develop fluorine-18 labeled PET tracers dedicated to molecular imaging of PDE2A, we selected the benzoimidazotriazine (BIT) scaffold ( Figure 1) as lead structure by replacing the pyrido ring of the TA compounds with a benzo ring [26,27]. As a first result, we very recently reported on the synthesis and inhibitory potency of nine new fluorinated derivatives based on this BIT scaffold [28]. In order to increase the metabolic stability of the corresponding PDE2A radioligands, the fluorine was introduced by substituting a fluoropyridine ring at the benzene moiety. Out of this series, derivative BIT1 ( Figure 1) was selected as the most suitable candidate for 18 F-labeling and biological investigation (IC50 PDE2A = 3.33 nM; 16-fold selectivity over PDE10A) [28].
Herein, we reported on the development and the evaluation of [ 18 F]BIT1, including the synthesis of the corresponding nitro precursor, the manual radiosynthesis, and the transfer to an automated synthesis module, and the subsequent in vitro and in vivo investigations.
In our continuous effort to develop fluorine-18 labeled PET tracers dedicated to molecular imaging of PDE2A, we selected the benzoimidazotriazine (BIT) scaffold ( Figure 1) as lead structure by replacing the pyrido ring of the TA compounds with a benzo ring [26,27]. As a first result, we very recently reported on the synthesis and inhibitory potency of nine new fluorinated derivatives based on this BIT scaffold [28]. In order to increase the metabolic stability of the corresponding PDE2A radioligands, the fluorine was introduced by substituting a fluoropyridine ring at the benzene moiety. Out of this series, derivative BIT1 ( Figure 1) was selected as the most suitable candidate for 18 F-labeling and biological investigation (IC 50 PDE2A = 3.33 nM; 16-fold selectivity over PDE10A) [28].
Herein, we reported on the development and the evaluation of [ 18 F]BIT1, including the synthesis of the corresponding nitro precursor, the manual radiosynthesis, and the transfer to an automated synthesis module, and the subsequent in vitro and in vivo investigations.

Synthesis of the Labeling Precursor 5
The synthesis of the reference compound BIT1 has been reported previously [28]. For an efficient radiosynthesis of [ 18 F]BIT1, we selected the nitro precursor 5 because of its higher reactivity to nucleophilic aromatic substitutions in comparison to a bromo-substituted precursor [29,30]. As depicted in Scheme 1, 5 was prepared in four steps starting from the BIT key intermediate 1 [28]. Firstly, Miyaura borylation of 1 with bis(pinacolato)diboron, using potassium acetate and [Pd(dppf)Cl 2 ] as base and catalyst, afforded the pinacol boronic ester 2 in a satisfactory yield of 85% [31]. By palladium-catalyzed Suzuki coupling with 4-bromo-2-nitropyridine, compound 3 was obtained in 63% yield. This 4-bromo-2-nitropyridine was synthesized according to a slightly modified procedure, already described in the literature [32]. Thereafter, the bromination at 1-position of the imidazole ring using N-bromo-succinimide (NBS) afforded compound 4 in an excellent yield of 97%. Finally, the subsequent Suzuki coupling with 2-chloro-5-methoxy-phenyl boronic acid gave the nitro precursor 5 in 68% yield (NMR spectrums of precursor 5 see in the Supplementary Materials). obtained in 63% yield. This 4-bromo-2-nitropyridine was synthesized according to a slightly modified procedure, already described in the literature [32]. Thereafter, the bromination at 1-position of the imidazole ring using N-bromo-succinimide (NBS) afforded compound 4 in an excellent yield of 97%. Finally, the subsequent Suzuki coupling with 2-chloro-5-methoxy-phenyl boronic acid gave the nitro precursor 5 in 68% yield (NMR spectrums of precursor 5 see in the Supplementary Materials). As shown in Figure 2, after 5 minutes (min) reaction time, a radiochemical yield (RCY) of ~57% was obtained when DMF was used at 150 °C. According to radio-TLC, besides [ 18 F]fluoride, three radioactive by-products were observed, which accounted for 10% of total radioactivity. When the temperature was reduced to 120 °C, an increase of the RCY up to 93% was observed at this early time point. However, the RCY decreased with increasing the reaction time, indicating a decomposition of [ 18 F]BIT1 under these conditions. The highest RCY in DMF (~94%) was achieved when the reaction temperature was further reduced to 100 °C. At this temperature, the product remained stable over 20 min reaction time. By contrast, almost no radiofluorination could be observed when MeCN was used (RCY ≤1%). With DMSO as a solvent, high RCYs (>85%) were obtained at 150 °C and 120 °C, which remained constant up to 20 min reaction time in contrast to the findings with DMF. A further As shown in Figure 2, after 5 min (min) reaction time, a radiochemical yield (RCY) of~57% was obtained when DMF was used at 150 • C. According to radio-TLC, besides [ 18 F]fluoride, three radioactive by-products were observed, which accounted for 10% of total radioactivity. When the temperature was reduced to 120 • C, an increase of the RCY up to 93% was observed at this early time point. However, the RCY decreased with increasing the reaction time, indicating a decomposition of [ 18 F]BIT1 under these conditions. The highest RCY in DMF (~94%) was achieved when the reaction temperature was further reduced to 100 • C. At this temperature, the product remained stable over 20 min reaction time. By contrast, almost no radiofluorination could be observed when MeCN was used (RCY ≤1%). With DMSO as a solvent, high RCYs (>85%) were obtained at 150 • C and 120 • C, which remained constant up to 20 min reaction time in contrast to the findings with DMF. A further decrease to 100 • C resulted in an increase of the RCY (>95%) after 10 min of reaction time. The precursor 5 was stable throughout the time of analysis, as proven by HPLC (data not shown). Based on these results, DMSO was selected for the production of [ 18 F]BIT1.
Due to the similarity of the chromatographic behavior of the nitro precursor and the corresponding 18 F-radiotracer, the use of a low amount of precursor is beneficial for subsequent isolation of the radiotracer via semi-preparative HPLC [33,34]. Accordingly, the further reduction of the amount of the nitro precursor 5 up to 0.5 mg was investigated, achieving an excellent RCY of ≥95% (DMSO, 100 • C, 5 min reaction time). The selection of a suitable column for semi-preparative HPLC was also somewhat crucial in order to have a separation of the radiotracer and its nitro precursor in a reasonable time [33]. According to our previous experiences [33], a slightly polar C18 phase turned out to be most appropriate for the isolation of [ 18 F]BIT1 using a mixture of MeCN/water and ammonium acetate as a buffer.
[ 18  decrease to 100 °C resulted in an increase of the RCY (>95%) after 10 min of reaction time. The precursor 5 was stable throughout the time of analysis, as proven by HPLC (data not shown). Based on these results, DMSO was selected for the production of [ 18 F]BIT1.
Due to the similarity of the chromatographic behavior of the nitro precursor and the corresponding 18 F-radiotracer, the use of a low amount of precursor is beneficial for subsequent isolation of the radiotracer via semi-preparative HPLC [33,34]. Accordingly, the further reduction of the amount of the nitro precursor 5 up to 0.5 mg was investigated, achieving an excellent RCY of ≥95% (DMSO, 100 °C, 5 min reaction time). The selection of a suitable column for semi-preparative HPLC was also somewhat crucial in order to have a separation of the radiotracer and its nitro precursor in a reasonable time [33]. According to our previous experiences [33], a slightly polar C18 phase turned out to be most appropriate for the isolation of [ 18 F]BIT1 using a mixture of MeCN/water and ammonium acetate as a buffer.
[ 18 F]BIT1 was successfully isolated under the aforementioned conditions and further purified by solid-phase extraction (SPE). After formulation in 0.9% saline containing 10% ethanol, [ 18 F]BIT1 was obtained with an RCY of 38% (decay corrected to the end of the bombardment, EOB), and molar activities in the range of 38 GBq/μmol (at the end of synthesis, EOS).

Automated Radiosynthesis of [ 18 F]BIT1
By using the most appropriate conditions of the manual procedure, the automated radiosynthesis of [ 18 F]BIT1 (Scheme 2) was established using a TRACERlab FX2 N synthesis module (GE Healthcare, Waukesha, WI, USA). The detailed configuration is shown in theexperimental part. Briefly, the [ 18 F]Fwas firstly trapped on an anion exchange cartridge and then eluted into the reactor using an aqueous potassium carbonate solution. The reaction took place with the [ 18 F]F -/K2.2.2./K2CO3 system and the nitro precursor 5 (0.5 mg) in DMSO at 100 °C for 5 min. After the isolation of [ 18 F]BIT1 via semi-preparative RP-HPLC ( Figure 3A), the product was purified via SPE on an RP cartridge and formulated in sterile isotonic saline containing 10% of EtOH. The total synthesis time of [ 18 F]BIT1 was approximately 75 min. Analytical radio-and UV-HPLC of the final product, spiked with the non-labeled reference compound BIT1, confirmed the identity of [ 18 F]BIT1 ( Figure 3B). Finally, the radiotracer was obtained with a radiochemical purity of ≥99%, an RCY of 54 ± 2% (EOB,

In vitro Stability and Lipophilicity of [ 18 F]BIT1
The radioligand [ 18 F]BIT1 was stable (radiochemical purity ≥99%) in phosphate-buffered saline (PBS), pig plasma, n-octanol, as well as in the saline formulation containing 10% ethanol at 40 °C for up to 1 h. The lipophilicity was determined by the shake-flask method in the n-octanol/PBS system. With a logD7.4 value of 1.81 ± 0.05, [ 18 F]BIT1 falls within the range of radiotracers with optimal brain passive diffusion [35][36][37]. However, the calculated coefficient distribution value (ACD/Labs, Version 12.0, Advanced Chemistry Development, Inc.) displayed value of 4.03. The significant deviations between the calculation and experimental methods were observed in particular when the pattern of connectivity and non-bonded intramolecular interactions are not included in the applied database [38][39][40][41]. Moreover, the big discrepancy between the experimental and the calculated logD7.4 value was already observed for our PDE2 tracer [ 18 F]TA5 and has been previously discussed [25]. It is assumed that the experimentally determined higher hydrophilicity of [ 18 F]TA5 might be due to the solvation effect related to hydrogen bonding and ionization of the radioligand in the aqueous buffered system [25,35]. Whereas with the software-based determination, this effect may be

In vitro Stability and Lipophilicity of [ 18 F]BIT1
The radioligand [ 18 F]BIT1 was stable (radiochemical purity ≥99%) in phosphate-buffered saline (PBS), pig plasma, n-octanol, as well as in the saline formulation containing 10% ethanol at 40 • C for up to 1 h. The lipophilicity was determined by the shake-flask method in the n-octanol/PBS system. With a logD 7.4 value of 1.81 ± 0.05, [ 18 F]BIT1 falls within the range of radiotracers with optimal brain passive diffusion [35][36][37]. However, the calculated coefficient distribution value (ACD/Labs, Version 12.0, Advanced Chemistry Development, Inc.) displayed value of 4.03. The significant deviations between the calculation and experimental methods were observed in particular when the pattern of connectivity and non-bonded intramolecular interactions are not included in the applied database [38][39][40][41]. Moreover, the big discrepancy between the experimental and the calculated logD 7.4 value was already observed for our PDE2 tracer [ 18 F]TA5 and has been previously discussed [25]. It is assumed that the experimentally determined higher hydrophilicity of [ 18 F]TA5 might be due to the solvation effect related to hydrogen bonding and ionization of the radioligand in the aqueous buffered system [25,35]. Whereas with the software-based determination, this effect may be underestimated [25]. Therefore, the calculated logD value is often higher than the experimentally determined value [25,35]. Since TA5 and BIT1 are rather structurally similar, we assume the apparent strong discrepancy of logD for [ 18 F]BIT1 might also be caused by the same reasons as those for [ 18 F]TA5.

In Vitro Autoradiography of [ 18 F]BIT1
To investigate the distribution of binding sites of [ 18 F]BIT1 in the brain, in vitro autoradiographic studies using cryosections of pig brain were performed. As depicted in Figure 4B, the distribution pattern of [ 18 F]BIT1 corresponds to the known spatial distribution of PDE2A with a high density of binding sites in the caudate nucleus (Cd), nucleus accumbens (Acb), cortex (Cx), and hippocampus (Hip) (Nissl staining of the corresponding slice is shown in Figure 4A). However, [ 18 F]BIT1 also binds to the non-PDE2A specific regions cerebellum (Cb) and thalamus (Th), indicating binding of [ 18 F]BIT1 to other targets. underestimated [25]. Therefore, the calculated logD value is often higher than the experimentally determined value [25,35]. Since TA5 and BIT1 are rather structurally similar, we assume the apparent strong discrepancy of logD for [ 18 F]BIT1 might also be caused by the same reasons as those for [ 18 F]TA5.

In Vitro Autoradiography of [ 18 F]BIT1
To investigate the distribution of binding sites of [ 18 F]BIT1 in the brain, in vitro autoradiographic studies using cryosections of pig brain were performed. As depicted in Figure 4B, the distribution pattern of [ 18 F]BIT1 corresponds to the known spatial distribution of PDE2A with a high density of binding sites in the caudate nucleus (Cd), nucleus accumbens (Acb), cortex (Cx), and hippocampus (Hip) (Nissl staining of the corresponding slice is shown in Figure 4A). However, [ 18 F]BIT1 also binds to the non-PDE2A specific regions cerebellum (Cb) and thalamus (Th), indicating binding of [ 18 F]BIT1 to other targets. To verify these findings, blocking studies with 10 μM of TA1 (a potent PDE2 ligand) [42] ( Figure 4C) and BIT1 ( Figure 4D) were performed. The decrease of [ 18 F]BIT1 binding of ~50% and ~30% in PDE2A specific regions Cd and Acb, respectively, observed for both TA1 and BIT1 indicated in vitro specificity of the radiotracer. However, the simultaneous decrease of [ 18 F]BIT1 binding in the range of 20-30% in Cb by TA1, as well as BIT1, suggested further non-specific binding of the radiotracer. We hypothesized the high non-specific binding of [ 18 F]BIT1 could be related to the moderate selectivity of BIT1 over PDE10A. Accordingly, these results limited the suitability of [ 18 F]BIT1 for in vitro molecular imaging of PDE2A.

In Vivo Metabolism of [ 18 F]BIT1
The in vivo metabolism of [ 18 F]BIT1 was investigated in plasma and brain homogenate obtained from mice at 30 min p.i.. Prior to the analysis with RP-HPLC, the samples were treated with a mixture of MeCN/H2O (4:1, v/v) to precipitate the proteins. The recovery of radioactivity in plasma To verify these findings, blocking studies with 10 µM of TA1 (a potent PDE2 ligand) [42] ( Figure 4C) and BIT1 ( Figure 4D) were performed. The decrease of [ 18 F]BIT1 binding of~50% and~30% in PDE2A specific regions Cd and Acb, respectively, observed for both TA1 and BIT1 indicated in vitro specificity of the radiotracer. However, the simultaneous decrease of [ 18 F]BIT1 binding in the range of 20-30% in Cb by TA1, as well as BIT1, suggested further non-specific binding of the radiotracer. We hypothesized the high non-specific binding of [ 18 F]BIT1 could be related to the moderate selectivity of BIT1 over PDE10A. Accordingly, these results limited the suitability of [ 18 F]BIT1 for in vitro molecular imaging of PDE2A.

In Vivo Metabolism of [ 18 F]BIT1
The in vivo metabolism of [ 18 F]BIT1 was investigated in plasma and brain homogenate obtained from mice at 30 min p.i.. Prior to the analysis with RP-HPLC, the samples were treated with a mixture of MeCN/H 2 O (4:1, v/v) to precipitate the proteins. The recovery of radioactivity in plasma and brain samples was 96% and 99%, respectively. Intact tracer accounted for 43% and 78% of total activity in plasma and brain, respectively, indicating higher metabolic stability of [ 18 F]BIT1 in comparison to our previous PDE2A radioligands [ 18 Figure 5), the two radio-metabolites ([ 18 F]M1 and [ 18 F]M2) found in the brain were also observed in the corresponding plasma sample, indicating their ability to penetrate the blood-brain barrier. For further clarification, samples obtained as previously described in our in vitro metabolism study with BIT1 using mouse liver microsomes [28] were investigated similarly by HPLC, but with UV detection ( Figure 5C). On the basis of the in vitro metabolites M1 and M2, both elucidated by LC-MS in the mentioned study, we can conclude about the brain penetrating radio-metabolites [ 18 F]M1 and [ 18 F]M2 as products of N-oxidation or C-hydroxylation. Besides, some of the more polar radio-metabolites detected in plasma could only tentatively be assigned as formed by mono-oxygenation, di-oxygenation, reduction, and demethylation, but were not investigated further.  [23]. As shown in the chromatograms (Figure 5), the two radio-metabolites ([ 18 F]M1 and [ 18 F]M2) found in the brain were also observed in the corresponding plasma sample, indicating their ability to penetrate the blood-brain barrier. For further clarification, samples obtained as previously described in our in vitro metabolism study with BIT1 using mouse liver microsomes [28] were investigated similarly by HPLC, but with UV detection ( Figure 5C). On the basis of the in vitro metabolites M1 and M2, both elucidated by LC-MS in the mentioned study, we can conclude about the brain penetrating radio-metabolites [ 18 F]M1 and [ 18 F]M2 as products of N-oxidation or C-hydroxylation. Besides, some of the more polar radio-metabolites detected in plasma could only tentatively be assigned as formed by mono-oxygenation, di-oxygenation, reduction, and demethylation, but were not investigated further.

In Vivo PET-MRI Studies of [ 18 F]BIT1
Dynamic PET-MRI studies were performed in female CD-1 mice after intravenous administration of [ 18 F]BIT1. As reflected by the time-activity curves (TACs) shown in Figure 6, the radioactivity uptake in the whole brain, striatum, and cerebellum reached standardized uptake values (SUVs) of about 0.7 at 5 min p.i., indicating blood-brain barrier penetration. Since there is no difference in the TACs between the whole brain, striatum, and cerebellum, [ 18 F]BIT1 is assumed to possess low specific binding also in vivo.
injection of TA1 and [ F]BIT1. However, since no significant reduction of radioactivity uptake in the PDE2A-specific region striatum was detectable (data not shown), the high non-specific binding of [ 18 F]BIT1 already observed in vitro was confirmed.
Overall, the herein reported potential PDE2A radioligand, selected from a new class of 8-pyridinyl-BIT compounds, demonstrated sufficient blood-brain barrier (BBB) permeability. However, [ 18 F]BIT1 was found to be insufficient for in vivo imaging of PDE2A with PET. Further structural modifications are needed to obtain PDE2A selective radioligands for in vitro and in vivo research. Extensive structure-activity relationship (SAR) studies could lead to the improvement of the selectivity and specificity of compounds. In particular, modifications of the set substituents at 1and 8-positions of the BIT scaffold might result in additive as well as nonadditive effects in compound potency [43].

General Methods
All chemicals were purchased from commercial sources and used without further purification. Solvents were dried before used if required. Air and moisture-sensitive reactions were carried out under argon atmosphere. Room temperature (RT) refers to 20-25 °C. Reaction mixtures were monitored by thin-layer chromatography (TLC) using pre-coated TLC-plates POLYGRAM ® SIL G/UV254 (Macherey-Nagel GmbH & Co. KG, Düren, Germany). The spots were detected under UV light at λ 254 nm and 365 nm. For the purification of final products, flash chromatography was performed with silica gel 40-63 μm (Merck KGaA, Darmstadt, Germany). Radio-TLC was performed on Polygram SIL G/UV254 plates (Macherey-Nagel GmbH & Co. KG, Düren, Germany) pre-coated plates with a mixture of chloroform/methanol (10:1, v/v) as eluent. The radio-TLC plates were exposed to storage phosphor screens (BAS-IP MS 2025, FUJIFILM Co., Tokyo, Japan) and To further investigate this hypothesis, blocking studies were performed by concomitant injection of TA1 and [ 18 F]BIT1. However, since no significant reduction of radioactivity uptake in the PDE2A-specific region striatum was detectable (data not shown), the high non-specific binding of [ 18 F]BIT1 already observed in vitro was confirmed.
Overall, the herein reported potential PDE2A radioligand, selected from a new class of 8-pyridinyl-BIT compounds, demonstrated sufficient blood-brain barrier (BBB) permeability. However, [ 18 F]BIT1 was found to be insufficient for in vivo imaging of PDE2A with PET. Further structural modifications are needed to obtain PDE2A selective radioligands for in vitro and in vivo research. Extensive structure-activity relationship (SAR) studies could lead to the improvement of the selectivity and specificity of compounds. In particular, modifications of the set substituents at 1-and 8-positions of the BIT scaffold might result in additive as well as nonadditive effects in compound potency [43].

General Methods
All chemicals were purchased from commercial sources and used without further purification. Solvents were dried before used if required. Air and moisture-sensitive reactions were carried out under argon atmosphere. Room temperature (RT) refers to 20-25 • C. Reaction mixtures were monitored by thin-layer chromatography (TLC) using pre-coated TLC-plates POLYGRAM ® SIL G/UV254 (Macherey-Nagel GmbH & Co. KG, Düren, Germany). The spots were detected under UV light at λ 254 nm and 365 nm. For the purification of final products, flash chromatography was performed with silica gel 40-63 µm (Merck KGaA, Darmstadt, Germany). Radio-TLC was performed on Polygram SIL G/UV 254 plates (Macherey-Nagel GmbH & Co. KG, Düren, Germany) pre-coated plates with a mixture of chloroform/methanol (10:1, v/v) as eluent. The radio-TLC plates were exposed to storage phosphor screens (BAS-IP MS 2025, FUJIFILM Co., Tokyo, Japan) and recorded using the AmershamTyphoon RGB Biomolecular Imager (GE Healthcare Life Sciences, Freiburg, Germany), and the images were quantified with ImageQuant TL8.1 software (GE Healthcare Life Sciences, Freiburg, Germany). Remote-controlled automated syntheses were performed using a TRACERlab FX2 N synthesizer (GE Healthcare, USA) equipped with a N810.3FT.18 pump (KNF Neuburger GmbH, Freiburg, Germany), a BlueShadow UV detector 10D (KNAUER GmbH, Berlin, Germany), NaI(Tl)-counter, and the TRACERlab FX Software.

Precursor Synthesis and Radiochemistry
The final compounds described in this manuscript meet the purity requirement (>95%) determined by UV-HPLC.

Determination of Stability
In vitro stability of [ 18 F]BIT1 was investigated by incubation of the radioligand in phosphate-buffered saline (PBS, pH 7.4), n-octanol, and pig plasma at 40 °C for 60 min (~5 MBq of the radioligand was added to 500 μL of each medium). Samples were taken at 30 and 60 min and analyzed by radio-TLC and radio-HPLC.

Determination of log D
The lipophilicity of [ 18 F]BIT1 was determined by partitioning between n-octanol and phosphate-buffered saline (PBS, pH 7.4) at ambient temperature using the conventional shake-flask method. An aliquot of 10 μL of the formulated solution containing ~500 kBq of [ 18 F]BIT1 was added to a tube containing 6 mL of the n-octanol/PBS-mixture (1:1, v/v, four-fold determination). The tubes were shaken for 20 min using a mechanical shaker (HS250 basic, IKA Labortechnik GmbH & Co. KG, Staufen, Germany) followed by centrifugation (5000 rpm for 5 min) and separation of the phases. Aliquots of 1 mL of the organic and the aqueous phase were taken, and the activity was measured using an automated gamma counter (1480 WIZARD, Fa. Perkin Elmer, Waltham, MA, USA). The distribution coefficient (D) was calculated as [activity (cpm/mL) in n-octanol]/[(activity (cpm/mL) in PBS], specified as the decadic logarithm (logD).

Determination of Stability
In vitro stability of [ 18 F]BIT1 was investigated by incubation of the radioligand in phosphate-buffered saline (PBS, pH 7.4), n-octanol, and pig plasma at 40 • C for 60 min (~5 MBq of the radioligand was added to 500 µL of each medium). Samples were taken at 30 and 60 min and analyzed by radio-TLC and radio-HPLC.

Determination of log D
The lipophilicity of [ 18 F]BIT1 was determined by partitioning between n-octanol and phosphate-buffered saline (PBS, pH 7.4) at ambient temperature using the conventional shake-flask method. An aliquot of 10 µL of the formulated solution containing~500 kBq of [ 18 F]BIT1 was added to a tube containing 6 mL of the n-octanol/PBS-mixture (1:1, v/v, four-fold determination). The tubes were shaken for 20 min using a mechanical shaker (HS250 basic, IKA Labortechnik GmbH & Co. KG, Staufen, Germany) followed by centrifugation (5000 rpm for 5 min) and separation of the phases. Aliquots of 1 mL of the organic and the aqueous phase were taken, and the activity was measured using an automated gamma counter (1480 WIZARD, Fa. Perkin Elmer, Waltham, MA, USA). The distribution coefficient (D) was calculated as [activity (cpm/mL) in n-octanol]/[(activity (cpm/mL) in PBS], specified as the decadic logarithm (logD).
For the time of the experiments, the animals were kept in a dedicated climatic chamber with free access to water and food under a 12:12 h dark:light cycle at a constant temperature of 24 • C. Piglet brains were obtained from anesthetized and euthanized juvenile female German landrace pigs (Lehr-und Versuchsgut Oberholz, Universität Leipzig).

In Vitro Autoradiography of [ 18 F]BIT1
Pig brain cryosections (16 µm; Microm HM560 Cryostat, FischerScientific GmbH, Schwerte, Germany) were thawed, dried in a stream of cold air, and preincubated for 10 min with buffer (50 mM TRIS-HCl, pH 7.4, 120 mM NaCl, 5 mM KCl, 2 mM MgCl 2 ) at room temperature. Afterward, brain sections were incubated with 1.72 nM of [ 18 F]BIT1 in the buffer for 60 min at room temperature. The sections were then washed twice with ice-cold 50 mM TRIS-HCl (pH 7.4), dipped in ice-cold deionized water, dried in a stream of cold air, and exposed for 60 min to an image plate. The analysis was performed using an image plate scanner (HD-CR 35; Duerr NDT GmbH, Bietigheim Bissingen, Germany). Non-specific binding was determined using 10 µM TA1 and BIT1 as blocking compounds.

In Vivo Metabolism of [ 18 F]BIT1
[ 18 F]BIT1 (~19 MBq) was injected in female CD-1 mice (10-12 weeks old) via the tail vein. Brain and blood samples were obtained at 30 min p.i., plasma separated by centrifugation (14,000 rpm, 1 min), and brain homogenized in~1 mL isotonic saline on ice (10 strokes of a PTFE plunge at 1000 rpm) in borosilicate glass.
Protein precipitation of plasma and brain samples was performed in duplicate with ice-cold MeCN/H 2 O (8:2, v/v), which was added to the samples (sample/solvent, 1:4, v/v). The samples were vortexed for 1 min, followed by resting on ice for 10 min. Afterward, the samples were centrifuged for 5 min at 10,000 g. Supernatants were collected, and 100 µL ice-cold MeCN/H 2 O (8:2, v/v) was added to the pellets for the second extraction, applying the same treatment as before. The combined supernatants were concentrated at 70 • C under nitrogen stream until a remaining volume of 100 µL and subsequently quantified by analytical radio-HPLC with an isocratic system (42% MeCN/20 mM NH 4 OAc aq .; flow rate: 1.0 mL/min). The activity recovery was determined by measuring the radioactivity of aliquots taken from supernatants and the pellets using a gamma counter.

Conclusions
In our efforts to develop a specific radioligand for PET imaging of PDE2A in the brain on the basis of a benzoimidazotriazine scaffold, we successfully prepared the novel PDE2A radioligand [ 18 F]BIT1 with a high radiochemical yield, radiochemical purity, as well as molar activity. Our findings showed that this class of compound demonstrated good brain penetration and sufficient in vivo metabolic stability. However, [ 18 F]BIT1 was not suitable for the molecular imaging of PDE2A in the brain because of a high non-specific binding. Further structural modifications are required to obtain more satisfactory PDE2A specific radioligands.