Efficient Reductive N-11C-Methylation Using Arylamines or Alkylamines and In Situ-Generated [11C]Formaldehyde From [11C]Methyl Iodide.

Reductive N-11C-methylation using [11C]formaldehyde and amines has been used to prepare N-11C-methylated compounds. However, the yields of the N-11C-methylated compounds are often insufficient. In this study, we developed an efficient method for base-free reductive N-11C-methylation that is applicable to a wide variety of substrates, including arylamines bearing electron-withdrawing and electron-donating substituents. A 2-picoline borane complex, which is a stable and mild reductant, was used. Dimethyl sulfoxide was used as the primary reaction solvent, and glacial acetic acid or aqueous acetic acid was used as a cosolvent. While reductive N-11C-methylation efficiently proceeded under anhydrous conditions in most cases, the addition of water to the reductive N-11C-methylation generally increased the yield of the N-11C-methylated compounds. Substrates with hydroxy, carboxyl, nitrile, nitro, ester, amide, and phenone moieties and amine salts were applicable to the reaction. This proposed method for reductive N-11C-methylation should be applicable to a wide variety of substrates, including thermo-labile and base-sensitive compounds because the reaction was performed under relatively mild conditions (70°C) without the need for a base.

Evaluation and improvement of CuI-mediated 11 C-cyanation.

CuI-mediated 11 C-cyanation was evaluated by synthesizing [11 C]perampanel ([11 C]5) as a model compound and compared with previous reports. To a DMF solution with 5'-(2-bromophenyl)-1'-phenyl-[2,3'-bipyridin]-6'(1'H)-one (4) and CuI, [11 C]NH4 CN in a stream of ammonia/nitrogen (5:95, v/v) gas was bubbled. Subsequently, the reaction mixture was heated at 180°C for 5 min. After HPLC purification, [11 C]5 was obtained in 7.2 ± 1.0% (n = 4) non-decay corrected radiochemical yield with >99% radiochemical purity and a molar activity of 98 ± 28 GBq/µmol. In vivo evaluations of [11 C]5 were performed using small animals. PET scans to check the kinetics of [11 C]5 in the whole body of mice suggested that [11 C]5 spreads rapidly into the brain, heart, and lungs and then accumulates in the small intestine. To evaluate the performance of CuI-mediated 11 C-cyanation reaction, bromobenzene (6a) was selected as the model compound; however, it failed. Therefore, optimization of the reaction conditions has been performed, and consequently, the addition of K2 CO3 and prolonging the reaction time improved the radiochemical yield about double. With this improved method, CuI-mediated 11 C-cyanation of various (hetero)aromatic bromides was performed to exhibit the tolerance of most functional groups and to provide 11 C-cyanated products in good to moderate radiochemical yields.

11C-Labeled Radiotracer for Noninvasive and Quantitative Assessment of the Thiocyanate Efflux System in the Brain.

Thiocyanate (SCN-) alters the potency of certain agonists for the α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) receptor, and dysfunctions in AMPA receptor signaling are considered to underlie a number of neurological diseases. While humans may be exposed to SCN- from the environment, including food sources, a carrier-mediated system transports SCN- from the brain into the blood and is an important regulator of SCN- distribution in the central nervous system. The assessment of this SCN- efflux system in the brain would thus be useful for understanding the mechanisms underlying the neurotoxicity of SCN- and for elucidating the relationship between the efflux system and brain diseases. However, the currently available technique for studying SCN- efflux is severely limited by its invasiveness. Here, we describe the development of a SCN- protracer, 9-pentyl-6-[11C]thiocyanatopurine ([11C]1), to overcome this limitation. [11C]1 was synthesized by the reaction of the iodo-precursor and [11C]SCN- or the reaction of the disulfide precursor with [11C]NH4CN. The protracer [11C]1 entered the brain after intravenous injection into mice and was rapidly metabolized to [11C]SCN-, which was then eliminated from the brain. The efflux of [11C]SCN- was dose-dependently inhibited by perchlorate, a monovalent anion, and the highest dose caused an 82% reduction in the efflux rate. Our findings demonstrate that [11C]1 can be used for the noninvasive and quantitative assessment of the SCN- efflux system in the brain.

Improved synthesis of 6-bromo-7-[11C]methylpurine for clinical use.

BACKGROUND: Multidrug resistance-associated protein 1 (MRP1), an energy-dependent efflux pump, is expressed widely in various tissues and contributes to many physiological and pathophysiological processes. 6-Bromo-7-[11C]methylpurine ([11C]7m6BP) is expected to be useful for the assessment of MRP1 activity in the human brain and lungs. However, the radiochemical yield (RCY) in the synthesis of [11C]7m6BP was low, limiting its clinical application, because the methylation of the precursor with [11C]CH3I provided primarily the undesired isomer, 6-bromo-9-[11C]methylpurine ([11C]9m6BP). To increase the RCY of [11C]7m6BP, we investigated conditions for improving the [11C]7m6BP/[11C]9m6BP selectivity of the methylation reaction. RESULTS: [11C]7m6BP was manually synthesized via the methylation of 6-bromopurine with [11C]CH3I in various solvents and at different temperatures in the presence of potassium carbonate for 5 min. Several less polar solvents, including tetrahydrofuran (THF), 2-methyltetrahydrofuran (2-MeTHF), and ethyl acetate (AcOEt) improved the [11C]7m6BP/[11C]9m6BP selectivity from 1:1 to 2:1, compared with the conventionally used solvents for the alkylation of 6-halopurines, acetone, acetonitrile, and N,N-dimethylformamide. However, a higher temperature (140 °C or 180 °C) was needed to progress the 11C-methylation in the less polar solvents, and the manual conditions could not be directly translated to an automated synthesis. [11C]Methyl triflate ([11C]CH3OTf) was thus used as a methylating agent to increase the conversion at a lower temperature. The 11C-methylation using [11C]CH3OTf at 100 °C proceeded efficiently in THF, 2-MeTHF, and AcOEt with maintenance of the improved selectivity. Starting from 28 to 34 GBq [11C]CO2, [11C]7m6BP was produced with 2.3-2.6 GBq for THF, 2.7-3.3 GBq for AcOEt, and 2.8-3.9 GBq for 2-MeTHF at approximately 30 min after the end of bombardment (n = 3 per solvent). The isolated RCYs (decay corrected) for THF, 2-MeTHF, and AcOEt were 24-28%, 29-35%, and 22-31% (n = 3), respectively. CONCLUSIONS: The use of THF, 2-MeTHF, and AcOEt improved the [11C]7m6BP/[11C]9m6BP selectivity in the methylation reaction, and the improved method provided [11C]7m6BP with sufficient radioactivity for clinical use.

Imaging of activity of multidrug resistance-associated protein 1 in the lungs.

Multidrug resistance-associated protein 1 (MRP1) transports various xenobiotics and metabolites across cell membranes, and the alteration of MRP1 expression is associated with certain lung diseases. This study sought to examine the feasibility of imaging pulmonary MRP1 activity using 6-bromo-7-[(11)C]methylpurine ([(11)C]1). A positron emission tomography study with [(11)C]1 was performed in wild-type, Mrp1 knockout (KO), and P-glycoprotein/breast cancer resistance protein (Pgp/Bcrp) KO mice. Lung radioactivity in wild-type and Mrp1 KO mice reached a maximum level immediately after the administration of [(11)C]1. Thereafter, radioactivity rapidly decreased in the lungs of wild-type mice, whereas it was mostly retained in the lungs of Mrp1 KO mice. The kinetics in the lungs of Pgp/Bcrp KO mice was quite similar to that of wild-type mice. Analysis of the chemical form confirmed that radioactive compounds in the lungs of Mrp1 KO mice were nearly completely composed of a glutathione conjugate, a MRP1 substrate, 5 minutes after the intravenous administration of [(11)C]1. The effect of an MRP1 inhibitor, MK571, on the kinetics of [(11)C]1 was also examined. Treatment with MK571 delayed the elimination of radioactivity from the lungs, compared with control mice. These results suggest that [(11)C]1 diffuses into the lung tissue after administration and undergoes conversion into the hydrophilic conjugate, which is then specifically expelled by MRP1. In conclusion, [(11)C]1 allows for the imaging of in vivo MRP1 activity in lungs.

PET probes for imaging brain acetylcholinesterase.

Imaging acetylcholinesterase (AChE) is valuable not only for diagnosing and understanding dementia but also for monitoring the effects of cholinesterase inhibitors used as antidementia drugs and for determining the appropriate clinical dosage of newly developed cholinesterase inhibitors. The distribution of AChE in the living brain can be imaged with two different types of radioprobes, including substrate-type and ligand-type probes. The substrate-type positron emission tomography (PET) probes, N-[(11) C]methylpiperidin-4-yl acetate ([(11) C]MP4A), and its propionate, [(11) C]MP4P, have been widely used in clinical studies of dementia, including Alzheimer's disease. [(11) C]MP4A and [(11) C]MP4P have been used to demonstrate a reduction in AChE activity in the brains of dementia patients, as well as the bioavailability of AChE inhibitors, leading to the subsequent development of the widely available (18) F-labeled derivatives of MP4A. In addition, several radiolabeled cholinesterase inhibitors have been developed as PET probes for AChE mapping in the brain. Herein, we have reviewed the development of PET probes for the imaging of AChE in the brain and described the principles of measuring AChE activity in the brain using PET with substrate-type radioprobes. A discussion of the reagents developed from substrate-type PET probes for the specific measurement of AChE activity in vitro has also been provided.

Effects of halogenation on tyrosine phosphorylation and peptide binding to the SRC homology 2 domain of lymphocyte-specific protein tyrosine kinase.

Phosphorylation of tyrosine residues by protein tyrosine kinases (PTK) and phosphotyrosine/Src homology 2 (SH2) domain interactions are crucial not only for signal transduction but also for regulation of PTK activity. Tyrosine residues also receive nitration and halogenation under oxidative conditions. It has been reported that nitration of tyrosine residue caused peptides to be a poor substrate for PTK and that nitrotyrosine residues could bind to SH2 domains as a phosphotyrosine mimic to activate Src family kinase. However, the effect of halogenation on tyrosine phosphorylation or SH2 domain binding is not well understood. We examined the phosphorylation of model peptides containing 3-halotyrosine or 3-nitrotyrosine using typical receptor tyrosine kinase, epidermal growth factor receptor (EGFR), and nonreceptor tyrosine kinase, lymphocyte-specific protein tyrosine kinase (Lck). The EGFR- and Lck-mediated phosphorylation was markedly inhibited by tyrosine halogenation. Iodination showed the strongest inhibition of the phosphorylation among four types of halogenation, and its inhibitory effect was stronger than that of nitration. We also examined the effect of iodination and nitration of tyrosine residues on binding to the SH2 domain of Lck, using a model peptide containing the phosphoTyr-Glu-Glu-Ile motif, which has a high affinity for the SH2 domain. The relative affinities of the modified peptides whose phosphotyrosine was substituted with unphosphorylated tyrosine, 3-nitrotyrosine, and 3-iodotyrosine, and of the model peptide were 0.024, 0.26, 1, and 16, respectively. These results suggest that tyrosine iodination may have an effect on the phosphorylation or binding to the SH2 domain similar to nitration. Tyrosine iodination possibly modulates signal transduction, with the potential impairment of cell function.

Rapid 'on-column' preparation of hydrogen [11C]cyanide from [11C]methyl iodide via [11C]formaldehyde.

Hydrogen [11C]cyanide ([11C]HCN) is a versatile 11C-labelling agent for the production of 11C-labelled compounds used for positron emission tomography (PET). However, the traditional method for [11C]HCN production requires a dedicated infrastructure, limiting accessibility to [11C]HCN. Herein, we report a simple and efficient [11C]HCN production method that can be easily implemented in 11C production facilities. The immediate production of [11C]HCN was achieved by passing gaseous [11C]methyl iodide ([11C]CH3I) through a small two-layered reaction column. The first layer contained an N-oxide and a sulfoxide for conversion of [11C]CH3I to [11C]formaldehyde ([11C]CH2O). The [11C]CH2O produced was subsequently converted to [11C]HCN in a second layer containing hydroxylamine-O-sulfonic acid. The yield of [11C]HCN produced by the current method was comparable to that of [11C]HCN produced by the traditional method. The use of oxymatrine and diphenyl sulfoxide for [11C]CH2O production prevented deterioration of the molar activity of [11C]HCN. Using this method, compounds labelled with [11C]HCN are now made easily accessible for PET synthesis applications using readily available labware, without the need for the 'traditional' dedicated cyanide synthesis infrastructure.

Effect of radiolabeled metabolite elimination from the brain on the accuracy of cerebral enzyme activity estimation using positron emission tomography with substrate tracers.

Cerebral enzyme activity can be quantified using positron emission tomography (PET) in conjunction with a radiolabeled enzyme substrate. We investigated the relationship between the elimination rate (k(el)) of tracer metabolites from the brain and the precision of target enzyme activity estimation (k(3)). An initial simulation study indicated that the precision of k(3) estimates was highly dependent on k(el), and was characterized by several kinetic parameters including the ratio of k(el) and the efflux rate (k(2)) of authentic tracer (ß≡k(el)/k(2)). The optimal tracer condition for high sensitivity was found to be ß<0.1. To verify the simulation results, we performed a PET study with a single monkey using two PET tracers, N-[(18)F]fluoroethylpiperidin-4-ylmethyl acetate ([(18)F]FEP-4MA) and N-[(11)C]methylpiperidin-4-yl acetate ([(11)C]MP4A). Both of these substrate type tracers were developed for measuring cerebral acetylcholinesterase activity. There was good retention of the radioactive metabolite of [(11)C]MP4A in the brain (k(el)=0.0036±0.0013 min(-1), ß=0.028), whereas that of [(18)F]FEP-4MA was eliminated from the brain (k(el)=0.012±0.0010 min(-1), ß=0.085). A non-linear least square analysis for simultaneous estimation of all parameters showed that the precision of the k(3) estimate for [(18)F]FEP-4MA was as high (7.4%) as that for [(11)C]MP4A (10%). These results indicate that tracers with metabolites that are eliminated from the brain at a slow rate (ß<0.1) may be useful for the quantitative measurement of target enzyme activity.

Efficient synthesis and chiral separation of 11C-labeled ibuprofen assisted by DMSO for imaging of in vivo behavior of the individual isomers by positron emission tomography.

The pharmacological mechanisms focusing on chiral isomer of ibuprofen are not fully understood. Only the (S)-isomer of ibuprofen inhibits cyclooxygenases, which mediates the generation of prostanoids and thromboxanes. Consequently, (S)-isomers represent a major promoter of the anti-inflammatory effect, and the effects of the (R)-isomers have not been widely discussed. However, more recently, the cyclooxygenase-independent pharmacological effects of ibuprofen have been elucidated. Pharmacokinetic studies with individual isomers of ibuprofen by positron emission tomography should aid our understanding of the pharmacological mechanisms of ibuprofen. The efficient (11)C-labeling of ibuprofen for chiral separation via the TBAF-promoted α-[(11)C]methylation was achieved by using DMSO rather than THF as the reaction solvent. The robust production of the radiochemically labile (11)C-labeled ibuprofen ester was realized by the protective effect of DMSO on radiolysis. After intravenous injection of each enantiomer of [(11)C]ibuprofen, significantly high radioactivity was observed in the joints of arthritis mice when compared to the levels observed in normal mice. However, the high accumulation was equivalent between the enantiomers, indicating that ibuprofen is accumulated in the arthritic joints regardless of the expression of cyclooxygenases.

In vivo evaluation of N-[18F]fluoroethylpiperidin-4ylmethyl acetate in rats compared with MP4A as a probe for measuring cerebral acetylcholinesterase activity.

[(11)C]MP4A is an established radioprobe for quantification of cerebral acetylcholinesterase (AChE) activity by positron emission tomography (PET) based on the kinetics of AChE-mediated metabolism and metabolite trapping. It has been used to assess the deficiency in cholinergic innervation in the brain of patients with dementia. Because (18)F has a longer half-life than (11)C, (18)F-labeled derivatives of [(11)C]MP4A allow delivery of the probe to other PET centers, making AChE measurement more widely applicable. Previously, N-[(18)F]fluoroethylpiperidin-4ylmethyl acetate ([(18)F]FEP-4MA) showed that the (18)F-labeled analog of MP4A possessed desirable properties for the quantification of cerebral AChE activity by PET. Here, we evaluated the in vivo kinetics of [(18)F]FEP-4MA and validated the responsiveness of brain uptake to AChE activity based on a mathematical model derived from the AChE-mediated trapping rationale and compared it with MP4A in rats. Almost all radioactivity in the brain was composed of [(18)F]FEP-4MA and the hydrolyzed metabolite at 0-60-min postinjection. When the authentic radioprobe was not observed in the brain, the regional (18)F uptake in the brain correlated well with regional MP4A uptake, and the elimination rate of (18)F from the brain was higher than that of the metabolite of MP4A. The responsiveness of regional (18)F uptake in the brain was examined by simultaneous assay of (18)F concentration, relative blood flow, and AChE activity. Regional (18)F uptake correlated with regional AChE activity as well as that of MP4A. Therefore, we concluded that [(18)F]FEP-4MA would be applicable to clinical PET study for quantifying cerebral AChE activity.

Piperidine-4-methanthiol ester derivatives for a selective acetylcholinesterase assay.

The activity of acetylcholinesterase (AChE) is measured to obtain pathological information about the cholinergic system in various disease states and to assess the effect of AChE inhibitors. Using Ellman's method that is commonly used in such examinations, butyrylcholinesterase inhibitors must be added to measure AChE-specific activity because of low selectivity of AChE toward traditional substrates; however, such inhibitors also inhibit AChE. Therefore, it is desirable to obtain an AChE selective substrate that can be used with the Ellman's method. Here, we synthesized novel AChE substrates, 1-methyl-4-acetylthiomethylpiperidine and 1,1-dimethyl-4-acetylthiomethylpiperidine, and evaluated the hydrolysis rate and AChE selectivity by comparison with the results obtained when traditional substrates were used. The hydrolysis rate of the novel compounds by human AChE was one order of magnitude lower than that of the traditional substrates, acetylthiocholine and acetyl-beta-methylthiocholine, whereas the hydrolysis rate using human butyrylcholinesterase was two orders of magnitude lower than that of the traditional substrates. This indicated that AChE showed selectivity towards the novel substrates which was one order of magnitude higher than that of the traditional substrates. The hydrolysis of the novel compounds in a rat cerebral cortical homogenate and a monkey whole blood was completely inhibited by 1 muM of the specific AChE inhibitor, 1,5-bis(4-allyldimethylammoniumphenyl)pentan-3-one, indicating the high specificity of AChE towards the novel substrates in a crude tissue sample. From these results, we conclude that the novel compounds developed would be suitable AChE-selective substrates for Ellman's method.

Country and Gender Differences in the Color Association with Energy Drinks: A Survey in Taiwanese and Japanese Students.

This study investigated differences in the color association with energy drinks between two populations in different cultures, i.e., Taiwanese and Japanese. An anonymous, self-administered paper questionnaire was administered to first- and second-year students at National Taiwan Normal University (Taiwan) and Naragakuen University (Japan). In our inter-country, gender-stratified comparison, the color selected most often in response to the question, "What color comes to your mind for energy drink label?" was red for the Taiwanese and blue for the Japanese. The color associations with energy drinks selected by 20% or more participants in at least one population and showing statistical difference were extracted as noticeable difference. The present study demonstrates that the color and energy drink functions are closely associated. Specifically, yellow and nourishment, black and stimulant, yellow and vitamin supplement, green and dietary fiber supplement, and red and iron supplement are tightly associated regardless of the country. The strong tie between cosmetic and white is specific to the Taiwanese consumers. This suggests that careful color selection based on consumers' environmental and cultural backgrounds is important in communicating information regarding energy drink functions. It would be worth for energy drink manufacturers to consider those associations in designing labels for products.

Mechanisms of glutathione-conjugate efflux from the brain into blood: Involvement of multiple transporters in the course.

Accumulation of detrimental glutathione-conjugated metabolites in the brain potentially causes neurological disorders, and must therefore be exported from the brain. However, in vivo mechanisms of glutathione-conjugates efflux from the brain remain unknown. We investigated the involvement of transporters in glutathione-conjugates efflux using 6-bromo-7-[11C]methylpurine ([11C]1), which enters the brain and is converted into its glutathione conjugate, S-(7-[11C]methylpurin-6-yl)glutathione ([11C]2). In mice of control and knockout of P-glycoprotein/breast cancer resistance protein and multidrug resistance-associated protein 2 ([Mrp2]-/-), [11C]2 formed in the brain was rapidly cleared, with no significant difference in efflux rate. In contrast, [11C]2 formed in the brain of Mrp1-/- mice was slowly cleared, whereas [11C]2 microinjected into the brain of control and Mrp1-/- mice was 75% cleared within 60 min, with no significant difference in efflux rate. These suggest that Mrp1 contributes to [11C]2 efflux across cell membranes, but not BBB. Efflux rate of [11C]2 formed in the brain was significantly lower in Mrp4-/- and organic anion transporter 3 (Oat3)-/- mice compared with control mice. In conclusion, Mrp1, Oat3, and Mrp4 mediate [11C]2 efflux from the brain. Mrp1 may contribute to [11C]2 efflux from brain parenchymal cells, while extracellular [11C]2 is likely cleared across the BBB, partly by Oat3 and Mrp4.

6-[124I]Iodo-9-pentylpurine for Imaging the Activity of the Sodium Iodide Symporter in the Brain.

Iodide homeostasis and thyroid hormone metabolism in the brain are potentially related to changes in the activity of the sodium iodide symporter (NIS). No radiotracers are currently available for imaging brain NIS activity. Here, we synthesized 6-[124I]iodo-9-pentylpurine that can noninvasively measure iodide efflux from the brain and showed that the efflux rate of [124I]I- in NIS knockout mice was 84% lower than that of wild-type mice. Thus, 6-[124I]iodo-9-pentylpurine would be useful for imaging brain NIS activity.

Kinetics and metabolism of apocynin in the mouse brain assessed with positron-emission tomography.

BACKGROUND: Apocynin is a constituent of the medicinal herb Picrorhiza kurroa. It is an inhibitor of nicotinamide adenine dinucleotide phosphate oxidase. This compound shows potential anti-inflammatory and antioxidant effects and has been tested as a neuroprotectant in many animal models of brain disease. In such studies, understanding the brain kinetics of apocynin would be important for interpreting its in vivo efficacy; however, little has been reported on the kinetics of apocynin in the brain. PURPOSE: The purpose of this study is to investigate the kinetics and metabolism of apocynin in the brain of mice. STUDY DESIGN: The kinetics and metabolism of apocynin were examined using [11C]apocynin and positron-emission tomography (PET). METHODS: In vivo PET scanning was performed in mice for 20min after intraperitoneal administration of an apocynin solution containing [11C]apocynin. Metabolites in the brain were analyzed using high-performance liquid chromatography. The doses of apocynin used ranged from <1.5 µg/kg (tracer dose) to 100mg/kg. RESULTS: Brain radioactivity during the period of 0 to 20min after administration was negligible at the tracer dose and extremely low at the dose of 10mg/kg. Moderate radioactivity was observed in the brain a few minutes after administration at the doses of 25 and 50mg/kg and rapidly decreased thereafter. At a dose of 100mg/kg, [11C]apocynin resulted in a high uptake of radioactivity followed by a gradual washout. In contrast to the brain, a clear dose-dependent increase in radioactivity was not observed in the blood. The fraction of the unchanged form in the brain decreased with time, and the degree of the reduction depended on apocynin doses: apocynin was rapidly metabolized in the brain at lower doses, whereas it was slowly decomposed at higher doses. On the basis of these data, the maximum apocynin concentrations in the brain were calculated to be 10 µM (10mg/kg), 49 µM (25mg/kg), 150 µM (50mg/kg), and 380 µM (100mg/kg). A metabolite observed in the brain was found to be apocynin glucuronide but not diapocynin, an active metabolite. CONCLUSION: These results would be useful for an evaluation of the potential efficacy of apocynin as a neuroprotective agent.

Benzyl [(11)C]Hippurate as an Agent for Measuring the Activities of Organic Anion Transporter 3 in the Brain and Multidrug Resistance-Associated Protein 4 in the Heart of Mice.

Multidrug resistance-associated protein 4 (MRP4) and organic anion transporter 3 (OAT3) mediate the efflux of organic anions from the brain and heart. In this study, we have developed a probe for estimating the activity of these transporters in these tissues using positron emission tomography. Several (11)C-labeled hippuric acid ester derivatives were screened with the expectation that they would be hydrolyzed in situ to form the corresponding (11)C-labeled organic acids in target tissues. Among the compounds screened, benzyl [(11)C]hippurate showed favorable hydrolysis rates and uptake properties in the target tissues of mice. Subsequent evaluation using transporter knockout mice revealed that radioactivity was retained in the brain and heart of Oat3(-/-) and Mrp4(-/-) mice, respectively, compared with that of control mice after the intravenous administration of benzyl [(11)C]hippurate. Benzyl [(11)C]hippurate could therefore be used as a probe for estimating the activities of OAT3 and MRP4 in mouse brain and heart, respectively.

An approach for measuring in vivo cerebral redox states using the oxidative conversion of dihydropyridine to pyridinium ion and the metabolic trapping principle.

This study was undertaken to develop radiopharmaceuticals for measuring in vivo cerebral redox states. Based on the oxidative conversion of dihydropyridine to pyridinium ion and the metabolic trapping principle, five N-[(14)C]methyl-3 or 3,5-substituted 1,4-dihydropyridines with different oxidation rates were designed, synthesized, and evaluated as a prototype of radiotracers for measuring in vivo cerebral redox states. When these tracers were injected into mice, they crossed the blood-brain barrier (BBB) and became trapped in the brain depending on their oxidation rates, while the corresponding oxidized forms hardly crossed the BBB. Furthermore, a significant increase in the radioactivity trapped in the brain was observed following injection of N-[(14)C]methyl-3-acetyl-1,4-dihydropyridine to mice pretreated with diethylmaleate that depletes glutathione in the brain. These findings suggested that an approach based on the oxidative conversion of dihydropyridine to the pyridinium ion and the metabolic trapping principle would be useful for measuring in vivo cerebral redox states.

N-[18F] fluoroethylpiperidin-4ylmethyl acetate, a novel lipophilic acetylcholine analogue for PET measurement of brain acetylcholinesterase activity.

The reduction of acetylcholinesterase (AChE) activity in the brain has been measured in dementia disorders such as Alzheimer's disease and dementia with Lewy bodies using (11)C-labeled acetylcholine analogues, N-[(11)C]methylpiperidin-4-yl acetate and propionate, and positron emission tomography (PET). Our aim was to develop an (18)F-labeled acetylcholine analogue useful for brain AChE mapping with PET, since (18)F, with a longer half-life, has advantages over (11)C. In a preliminary study, a series of N-[(14)C]ethylpiperidin-3-yl or -4-ylmethanol esters (acetyl and propionyl esters) were newly designed and evaluated in vitro regarding the reactivity with and specificity to AChE using purified human enzymes, leading to a novel (18)F-labeled acetylcholine analogue, N-[(18)F]fluoroethylpiperidin-4-ylmethyl acetate. In rat experiments, the (18)F-labeled candidate showed desirable properties for PET AChE measurement: high brain uptake of the authentic ester, high AChE specificity, a moderate hydrolysis rate, and low membrane permeability (metabolic trapping) of the metabolite.

A ¹¹C-labeled 1,4-dihydroquinoline derivative as a potential PET tracer for imaging of redox status in mouse brain.

A disturbance in redox balance has been implicated in the pathogenesis of a number of diseases. This study sought to examine the feasibility of imaging brain redox status using a (11)C-labeled dihydroquinoline derivative ([(11)C]DHQ1) for positron emission tomography (PET). The lipophilic PET tracer [(11)C]DHQ1 was rapidly oxidized to its hydrophilic form in mouse brain homogenate. The redox modulators diphenyleneiodonium and apocynin significantly reduced the initial velocity of [(11)C]DHQ1 oxidation, and apocynin also caused concentration-dependent inhibition of the initial velocity. Moreover, [(11)C]DHQ1 readily entered the brain by diffusion after administration and underwent oxidation into the hydrophilic cationic form, which then slowly decreased. By contrast, apocynin treatment inhibited the in vivo oxidation of [(11)C]DHQ1 to the hydrophilic cationic form, leading to a rapid decrease of radioactivity in the brain. Thus, the difference in the [(11)C]DHQ1 kinetics reflects the alteration in redox status caused by apocynin. In conclusion, [(11)C]DHQ1 is a potential PET tracer for imaging of redox status in the living brain.