Metabolism and autoradiographic evaluation of [(18)F]FE@CIT: a Comparison with [(123)I]beta-CIT and [(123)I]FP-CIT.

PURPOSE: Since the late 1980s, cocaine analogues based on the phenyltropane structure, such as [(11)C]CFT and [(123)I]beta-CIT have been used for the imaging of the dopamine transporter. FE@CIT (fluoropropyl ester) and FP-CIT (N-fluoropropyl derivative) are further analogues. The aim of this study was to (1) evaluate and compare the metabolic stability of beta-CIT, FP-CIT and FE@CIT against carboxyl esterases and (2) evaluate selectivity of [(18)F]FE@CIT compared to [(123)I]beta-CIT and [(123)I]FP-CIT using autoradiography. METHODS: In vitro enzymatic hydrolysis assays were performed using different concentrations of beta-CIT, FE@CIT and FP-CIT with constant concentrations of carboxyl esterase. Autoradiography was performed on coronal 20-microm rat brain sections incubated with different radioactivity concentrations of [(123)I]beta-CIT, [(123)I]FP-CIT or [(18)F]FE@CIT and, additionally, with 3-amino-4-(2-dimethylaminomethyl-phenylsulfanyl)-benzonitrile [serotonin transporter (SERT)] and nisoxetine [norepinephrine transporter (NET)] for blocking experiments. RESULTS: In vitro assays showed Michaelis-Menten constants of 175 micromol (beta-CIT), 183 micromol (FE@CIT) and 521 micromol (FP-CIT). Limiting velocities were 0.1005 micromol/min (beta-CIT), 0.1418 micromol/min (FE@CIT) and 0.1308 micromol/min (FP-CIT). This indicates a significantly increased stability of FP-CIT, whereas carboxyl esterase stability of beta-CIT and FE@CIT showed no significant difference. Autoradiographic analyses revealed a good correlation between dopamine transporter (DAT)-rich regions and the uptake pattern of FE@CIT. Blocking experiments showed a higher DAT selectivity for [(18)F]FE@CIT than for the other two tracers. CONCLUSION: We found that (1) the metabolic stability of FE@CIT was comparable to that of beta-CIT, whereas FP-CIT showed higher resistance to enzymatic hydrolysis; and (2) the overall uptake pattern of [(18)F]FE@CIT on brain slices was comparable to that of [(123)I]beta-CIT and [(123)I]FPCIT. After blocking of NET and SERT binding, a significantly higher DAT selectivity was observed for [(18)F]FE@CIT. Hence, [(18)F]FE@CIT may be of interest for further clinical application.

Preparation and first evaluation of [(18)F]FE@SUPPY: a new PET tracer for the adenosine A(3) receptor.

INTRODUCTION: Changes of the adenosine A(3) receptor subtype (A3AR) expression have been shown in a variety of pathologies, especially neurological and affective disorders, cardiac diseases and oncological and inflammation processes. Recently, 5-(2-fluoroethyl) 2,4-diethyl-3-(ethylsulfanylcarbonyl)-6-phenylpyridine-5-carboxylate (FE@SUPPY) was presented as a high-affinity ligand for the A3AR with good selectivity. Our aims were the development of a suitable labeling precursor, the establishment of a reliable radiosynthesis for the fluorine-18-labeled analogue [(18)F]FE@SUPPY and a first evaluation of [(18)F]FE@SUPPY in rats. METHODS: [(18)F]FE@SUPPY was prepared in a feasible and reliable manner by radiofluorination of the corresponding tosylated precursor. Biodistribution was carried out in rats, and organs were removed and counted. Autoradiography was performed on rat brain slices in the presence or absence of 2-Cl-IB-MECA. RESULTS: Overall yields and radiochemical purity were sufficient for further preclinical and clinical applications. The uptake pattern of [(18)F]FE@SUPPY found in rats mainly followed the described mRNA distribution pattern of the A3AR. Specific uptake in brain was demonstrated by blocking with a selective A3AR agonist. CONCLUSION: We conclude that [(18)F]FE@SUPPY has the potential to serve as the first positron emission tomography tracer for the A3AR.

18F fluoroethylations: different strategies for the rapid translation of 11C-methylated radiotracers.

INTRODUCTION: The translation of 11C-labeled compounds into their respective 18F-labeled derivatives is an important tool in the rapid development of positron emission tomography (PET) tracers. Thus, our aim was the development of a general method for the preparation of 18F-fluoroethylated compounds that (a) is applicable to a variety of precursors, (b) can be performed in a fully automated commercially available synthesizer and (c) enables this rapid translation of 11C-methylated tracers into their 18F-fluoroethylated analogs sharing the same precursor molecules. METHODS: Ten methods for the preparation and purification of different 18F-fluoroethylating agents were compared. Subsequently, five 18F-labeled PET tracers were synthesized under fully automated conditions. RESULTS: Radiochemical yields ranged from 34.4% to 60.8%, and time consumption ranged from 20 to 55 min for all methods. Use of 1-bromo-2-[18F]fluoroethane and distillation evinced as the method of choice. CONCLUSIONS: We were able to develop a general method for the preparation of a variety of 18F-fluoroethylated molecules. The provided tool is solely based on commercially available resources and has the potential to simplify and accelerate innovative PET tracer development in the future.

Pre vivo, ex vivo and in vivo evaluations of [68Ga]-EDTMP.

INTRODUCTION: The objectives of this study were to develop a simple preparation method for [68Ga]-EDTMP and to evaluate the applicability of [68Ga]-EDTMP as a potential positron emission tomography (PET) bone imaging agent using pre vivo, ex vivo and in vivo models. METHODS: [68Ga]-EDTMP was prepared using 68Ga]-gallium chloride eluted from the 68Ge/68Ga generator and commercially available Multibone kits. Binding affinity to bone compartments was evaluated using a recently established pre vivo model. In vivo (microPET) and ex vivo experiments were performed in mice, and the results of which were compared with those obtained with [18F]-fluoride. RESULTS: [68Ga]-EDTMP was accessible via simple kit preparation and predominantly accumulated in bone tissue in vivo, ex vivo and pre vivo. Binding to mineral bone was irreversible, and low binding was observed in organic bone. In vivo microPET evaluation revealed predominant uptake in bone with renal excretion. Compared with [18F]-fluoride, the uptake was lower and the PET image quality was reduced. CONCLUSIONS: From the present evaluation, apart from the autonomy for PET centers without an onsite cyclotron, the advantage of [68Ga]-EDTMP over [18F]-fluoride is not apparent and the future clinical prospect of [68Ga]-EDTMP remains speculative.

[18F]FETO: metabolic considerations.

PURPOSE: 11beta-Hydroxylase is a key enzyme in the biosynthesis of adrenocortical steroid hormones and is a suitable target for the imaging of the adrenal cortex. [(11)C]Metomidate (MTO), [(11)C]etomidate (ETO) and desethyl-[(18)F]fluoroethyl-etomidate (FETO) are potent inhibitors of this enzyme and are used for PET imaging of adrenocortical pathologies. The aims of this study were (1) to evaluate and compare the metabolic stability of MTO, ETO and FETO against esterases and (2) to investigate the metabolic pattern of FETO in vivo. METHODS: In vitro assays were performed using different concentrations of MTO, ETO and FETO with constant concentrations of carboxylesterase. Human in vivo studies were performed with human blood samples drawn from the cubital vein. After sample clean-up, the serum was analysed by HPLC methods. RESULTS: In vitro assays showed Michaelis-Menten constants of 115.1 mumol for FETO, 162.0 mumol for MTO and 168.6 mumol for ETO. Limiting velocities were 1.54 mumol/min (FETO), 1.47 mumol/min (MTO) and 1.35 mumol/min (ETO). This implies insignificantly decreased esterase stability of FETO compared with MTO and ETO. In vivo investigations showed a rapid metabolisation of FETO within the first 10 min (2 min: 91.41%+/-6.44%, n=6; 10 min: 23.78%+/-5.54%, n=4) followed by a smooth decrease in FETO from 20 to 90 min (20 min: 11.23%+/-3.79% n=4; 90 min: 3.68%+/-3.65%, n=4). Recovery rate was 61.43%+/-3.19% (n=12). CONCLUSION: In vitro experiments demonstrated that FETO stability against esterases is comparable to that of ETO and MTO. The metabolic profile showed that FETO kinetics in humans are fast.

In vivo disposition of irinotecan (CPT-11) and its metabolites in combination with the monoclonal antibody cetuximab.

BACKGROUND: The present study was designed to investigate whether a combination of irinotecan and the monoclonal antibody cetuximab shows potential to modulate the pharmacokinetics of irinotecan and its metabolites. PATIENTS AND METHODS: All patients, suffering from advanced colorectal cancer, received irinotecan (350 mg/m2) every third week and cetuximab as a loading dose (400 mg/m2) on day 2, followed by a weekly maintenance dose (250 mg/m2). Plasma samples were analysed after the first (MONO) and second (CMAB) irinotecan infusions. RESULTS: No significant alterations in the plasma concentrations and pharmacokinetics of irinotecan and its metabolites were observed after combination with cetuximab. Only differentiation of irinotecan into lactone and carboxylate plasma concentrations resulted in a distinctly lower cmax of the active lactone in the CMAB and a significantly higherAUClast in the MONO schedule (p<0.02). CONCLUSION: The results of this study indicated that cetuximab has no clinically relevant impact on the pharmacokinetics of irinotecan, its activation into SN-38, or its detoxification by beta-D-glucuronidation.

[18F]FETO for adrenocortical PET imaging: a pilot study in healthy volunteers.

PURPOSE: Functional imaging of the adrenal cortex by means of PET may play an important clinical role. Recently, we presented the synthesis and first evaluation of a novel 11beta-hydroxylase inhibitor, [(18)F]FETO, in rats displaying high tracer accumulation in the adrenals. In this study, we aimed to investigate for the first time the potency of [(18)F]FETO as a PET tracer for the adrenal cortex in humans. METHODS: An average preparation yielded 1-2 GBq of [(18)F]FETO ready to use. Ten healthy volunteers aged 24-57 years (five male and five female) were included in the study. After i.v. administration of 365 MBq [(18)F]FETO (246-391 MBq), dynamic images were acquired in 2D standard mode in 14 frames over 45 min. Afterwards, whole-body scanning was performed. In addition to visual interpretation, semi-quantitative analysis using standardised uptake values (SUVs) was conducted. RESULTS: [(18)F]FETO distribution was similar in all scanned volunteers. Visually, pronounced accumulation of [(18)F]FETO was found in the adrenals, whereas moderate uptake was observed-at least in some of the subjects-for liver, renal calices, gallbladder, stomach walls and pancreas. Kidney and bowels showed only faint uptake. Median SUVs for the right and left adrenal glands were 15.6 (10.0-28.6) and 15.7 (10.3-35.9), respectively. The reference tissue (liver) displayed a median SUV of 2.5 (2.2-4.6). CONCLUSION: [(18)F]FETO is a valuable tracer for adrenocortical PET imaging, combining the longer half-life of( 18)F with a high 11beta-hydroxylase selectivity. In accordance with our findings in rats, FETO PET revealed very high accumulation in the adrenal glands in healthy volunteers.

NCA nucleophilic radiofluorination on substituted benzaldehydes for the preparation of [18F]fluorinated aromatic amino acids.

Nucleophilic aromatic substitution is a challenging task in radiochemistry. Therefore, a thorough evaluation and optimisation of this step is needed to provide a satisfactory tool for the routine preparation of [(18)F]fluorinated aromatic amino acids. Two methods, already proposed elsewhere, were evaluated and improved. The yields for the radiofluorination were increased whereas activity loss during solid phase extraction was observed. Radiochemical yields for the two methods were 92.7+/-5.5% (method 1) and 92.1+/-12.3% (method 2) for conversion and 11.1+/-2.8% (method 1) and 34.8+/-0.6% (method 2) for purification, respectively. In total, we demonstrate an optimised method for the preparation of this important class of [(18)F]fluorinated synthons for PET.