Synthesis of [1‐11C]propyl and [1‐11C]butyl iodide from [11C]carbon monoxide and their use in alkylation reactions

A method to prepare [1‐¹¹C]propyl iodide and [1‐¹¹C]butyl iodide from [¹¹C]carbon monoxide via a three step reaction sequence is presented. Palladium mediated formylation of ethene with [¹¹C]carbon monoxide and hydrogen gave [1‐¹¹C]propionaldehyde and [1‐¹¹C]propionic acid. The carbonylation products were reduced and subsequently converted to [1‐¹¹C]propyl iodide. Labelled propyl iodide was obtained in 58±4% decay corrected radiochemical yield and with a specific radioactivity of 270±33 GBq/µmol within 15 min from approximately 12 GBq of [¹¹C]carbon monoxide. The position of the label was confirmed by ¹³C‐labelling and ¹³C‐NMR analysis. [1‐¹¹C]Butyl iodide was obtained correspondingly from propene and approximately 8 GBq of [¹¹C]carbon monoxide, in 34±2% decay corrected radiochemical yield and with a specific radioactivity of 146±20 GBq/µmol. The alkyl iodides were used in model reactions to synthesize [O‐propyl‐1‐¹¹C]propyl and [O‐butyl‐1‐¹¹C]butyl benzoate. Propyl and butyl analogues of etomidate, a β‐11‐hydroxylase inhibitor, were also synthesized. Copyright © 2006 John Wiley & Sons, Ltd.     

Synthesis of [1‐11C]ethyl iodide from [11C]carbon monoxide and its application in alkylation reactions

A method is presented for preparing [1‐¹¹C]ethyl iodide from [¹¹C]carbon monoxide. The method utilizes methyl iodide and [¹¹C]carbon monoxide in a palladium‐mediated carbonylation reaction to form a mixture of [1‐¹¹C]acetic acid and [1‐¹¹C]methyl acetate. The acetates are reduced to [1‐¹¹C]ethanol and subsequently converted to [1‐¹¹C]ethyl iodide. The synthesis time was 20 min and the decay‐corrected radiochemical yield of [1‐¹¹C]ethyl iodide was 55 ± 5%. The position of the label was confirmed by ¹³C‐labelling and ¹³C‐NMR analysis. [1‐¹¹C]Ethyl iodide was used in two model reactions, an O‐alkylation and an N‐alkylation. Starting with approximately 2.5 GBq of [¹¹C]carbon monoxide, the isolated decay‐corrected radiochemical yields for the ester and the amine derivatives were 45 ± 0.5% and 25 ± 2%, respectively, based on [¹¹C]carbon monoxide. Starting with 10 GBq of [¹¹C]carbon monoxide, 0.55 GBq of the labelled ester was isolated within 40 min with a specific radioactivity of 36 GBq/µmol. Copyright © 2004 John Wiley & Sons, Ltd.     

Synthesis of diethyl [carbonyl‐11C]malonate from [11C]carbon monoxide by rhodium‐promoted carbonylation and its application as a reaction intermediate

Rhodium‐mediated carbonylation reaction was applied to synthesize diethyl [carbonyl‐¹¹C]malonate using [¹¹C]carbon monoxide at low concentration. The synthesis was performed starting with ethyl diazoacetate, ethanol and the rhodium complex being made in situ by chloro(1,5‐cyclooctadiene)rhodium(I) dimer ([Rh(cod)Cl]₂) and 1,2‐bis(diphenylphosphino)ethane (dppe), and the reaction is assumed to proceed via a ketene intermediate. The isolated radiochemical yield was 20% (75% analytical radiochemical yield) and the trapping efficiency of [¹¹C]carbon monoxide in the order of 85%. The specific radioactivity of this compound was measured at 127 GBq/µmol (7.28 nmol total mass) after 8 µAh bombardment and 35 min synthesis. The corresponding ¹³C‐labelled compound was synthesized using (¹³C)carbon monoxide to confirm the position of the carbonyl‐labelled atom by ¹³C‐NMR. Diethyl [carbonyl‐¹¹C]malonate was further used in subsequent alkylation step using ethyl iodide and tetrabutylammonium fluoride to obtain diethyl diethyl [carbonyl‐¹¹C]malonate in 50% analytical radiochemical yield. Copyright © 2006 John Wiley & Sons, Ltd.     

[11C]methyl iodide from [11C]methane and iodine using a non‐thermal plasma method

A method and an apparatus for preparing [¹¹C]methyl iodide from [¹¹C]methane and iodine in a single pass through a non‐thermal plasma reactor has been developed. The plasma was created by applying high voltage (400 V/31 kHz) to electrodes in a stream of helium gas at reduced pressure. The [¹¹C]methane used in the experiments was produced from [¹¹C]carbon dioxide via reduction with hydrogen over nickel. [¹¹C]methyl iodide was obtained with a specific radioactivity of 412 ± 32 GBq/µmol within 6 min from approximately 24 GBq of [¹¹C]carbon dioxide. The decay corrected radiochemical yield was 13 ± 3% based on [¹¹C]carbon dioxide at start of synthesis. [¹¹C]Flumazenil was synthesized via a N‐alkylation with the prepared [¹¹C]methyl iodide. Copyright © 2006 John Wiley & Sons, Ltd.     

Rhodium‐mediated [11C]carbonylation: a library of N‐phenyl‐N′‐{4‐(4‐quinolyloxy)‐phenyl}‐[11C]‐urea derivatives as potential PET angiogenic probes

As part of our ongoing investigation into the imaging of angiogenic processes, a small library of eight vascular endothelial growth factor receptor‐2 (VEGFR‐2)/platelet‐derived growth factor receptor β dual inhibitors based on the N‐phenyl‐N′‐4‐(4‐quinolyloxy)‐phenyl‐urea was labelled with ¹¹C (β⁺, t_1/2=20.4 min) in the urea carbonyl position via rhodium‐mediated carbonylative cross‐coupling of an aryl azide and different anilines. The decay‐corrected radiochemical yields of the isolated products were in the range of 38–81% calculated from [¹¹C]carbon monoxide. Starting with 10.7±0.5 GBq of [¹¹C]carbon monoxide, 1‐[4‐(6,7‐dimethoxy‐quinolin‐4‐yloxy)‐3‐fluoro‐phenyl]‐3‐(4‐fluoro‐phenyl)‐[¹¹C]‐urea (2.1 GBq) was isolated after total reaction time of 45 min with a specific activity of 92±4 GBq µmol^?1. Copyright © 2009 John Wiley & Sons, Ltd.     

Synthesis of a 11C‐labelled taxane derivative by [1‐11C]acetylation

The ¹¹C‐labelling of the taxane derivative BAY 59‐8862 ( 1 ), a potent anticancer drug, was carried out as a module‐assisted automated multi‐step synthesis procedure. The radiotracer [¹¹C]1 was synthesized by reacting [1‐¹¹C]acetyl chloride ( 6 ) with the lithium salt of the secondary hydroxy group of precursor 3 followed by deprotection. After HPLC purification of the final product [¹¹C]1 , its solid‐phase extraction, formulation and sterile filtration, the decay‐corrected radiochemical yield of [¹¹C]1 was in the range between 12 and 23% (related to [¹¹C]CO₂; n=10). The total synthesis time was about 54 min after EOB. The radiochemical purity of [¹¹C]1 was greater than 96% and the chemical purity exceeded 80%. The specific radioactivity was 16.8±4.7 GBq/µmol (n=10) at EOS starting from 80 GBq of [¹¹C]CO₂. Copyright © 2006 John Wiley & Sons, Ltd.     

Synthesis and biological evaluation of [carboxyl‐11C]eprosartan

Essential hypertension occurs in approximately 25% of the adult population and one cause of hypertension is primary aldosteronism. Targeting the angiotensin II AT₁ receptor using PET and an appropriate tracer may offer a diagnostic method for adrenocortical tissue. This report describes the synthesis of the selective AT₁ receptor antagonist [carboxyl‐¹¹C]eprosartan 10, 4‐[2‐butyl‐5‐((E)‐2‐carboxy‐3‐thiophen‐2‐yl‐propenyl)‐imidazol‐1‐ylmethyl]‐[carboxyl‐¹¹C]benzoic acid, and its precursor (E)‐3‐[2‐butyl‐3‐(4‐iodo‐benzyl)‐3H‐imidazol‐4‐yl]‐2‐thiophen‐2‐ylmethyl‐acrylic acid 9. ¹¹C‐carboxylation of the iodobenzyl moiety was performed using a palladium‐mediated reaction with [¹¹C]carbon monoxide in the presence of tetra‐n‐butyl‐ammonium hydroxide in a micro‐autoclave using a temperature gradient from 25 to 140°C over 5 min. After purification by semipreparative HPLC, [carboxyl‐¹¹C]eprosartan 10 was obtained in 37–54% decay‐corrected radiochemical yield (from [¹¹C]carbon monoxide) with a radiochemical purity >95% within 35 min of the end of bombardment (EOB). A 5‐µAh bombardment gave 2.04 GBq of 10 (50% rcy from [¹¹C]carbon monoxide) with a specific activity of 160 GBq µmol^?1 at 34 min after EOB. Frozen‐section autoradiography shows specific binding in kidney, lung and adrenal cortex. In vivo experiments in rats demonstrate a high accumulation in kidney, liver and intestinal wall. Copyright © 2009 John Wiley & Sons, Ltd.     

Synthesis of substituted [11C]ureas and [11C]sulphonylureas by Rh(I)‐mediated carbonylation

The urea moiety is present in many biologically active compounds and thus an attractive target for ¹¹C‐labelling. To extend the scope of the rhodium(I)‐mediated carbonylative cross‐coupling reaction between an azide and an amine and investigate its tolerance for functional groups, we have synthesized eight ureas and two sulphonylureas that were ¹¹C‐labelled in the carbonyl position. The decay‐corrected analytical radiochemical yields were in the range of 14–96% (from [¹¹C]carbon monoxide). For example: starting from 1.33 GBq [¹¹C]carbon monoxide, 0.237 GBq (66%) of the cytotoxic sulphonylurea [¹¹C]LY‐181984 11 was isolated within 60 min from end of bombardment. The mild reaction conditions and generality regarding functional groups of this method make it an attractive alternative to the [¹¹C]phosgene method for the synthesis of ¹¹C‐labelled ureas. Copyright © 2010 John Wiley & Sons, Ltd.     

[carbonyl‐11C]Benzyl acetate: Automated radiosynthesis via Pd‐mediated [11C]carbon monoxide chemistry and PET measurement of brain uptake in monkey

[carbonyl‐¹¹C]Benzyl acetate ([¹¹C]1) has been proposed as a potential agent for imaging glial metabolism of acetate to glutamate and glutamine with positron emission tomography. [¹¹C]1 was synthesized from [¹¹C]carbon monoxide, iodomethane and benzyl alcohol via palladium‐mediated chemistry. The radiosynthesis was automated with a modified Synthia platform controlled with in‐house developed Labview software. Under production conditions, [¹¹C]1 was obtained in 10% (n=6) decay‐corrected radiochemical yield from [¹¹C]carbon monoxide in >96% radiochemical purity and with an average specific radioactivity of 2415 mCi/µmol. The total radiosynthesis time was about 45 min. Peak uptake of radioactivity in monkey brain (SUV=3.1) was relatively high and may be amenable to measuring uptake and metabolism of acetate in glial cells of the brain. Published in 2010 by John Wiley & Sons, Ltd.     

Synthesis of (E)‐2,3′,4,5′‐tetramethoxy[2‐11C]stilbene

In this paper, we describe the radiosynthesis of the compound (E)‐2,3′,4,5′‐tetramethoxy[2‐¹¹C]stilbene, a potential, universal tumour positron emission tomography imaging agent. The production of (E)‐2,3′,4,5′‐tetramethoxy[2‐¹¹C]stilbene was carried out via ¹¹C‐methylation of (E)‐2‐(hydroxy)‐3′,4,5′‐trimethoxystilbene by using [¹¹C]methyl trifluoromethanesulfonate ([¹¹C]methyl triflate). (E)‐2,3′,4,5′‐tetramethoxy[2‐¹¹C]stilbene was obtained with a radiochemical purity greater than 95% in a 20 ± 2% decay‐corrected radiochemical yield, based upon [¹¹C]carbon dioxide. Synthesis, purification and formulation were completed on an average of 30 min following the end of bombardment (EOB). The specific radioactivity obtained was 1.9 ± 0.6 GBq/µmol at EOB. Copyright © 2007 John Wiley & Sons, Ltd.     

Synthesis and evaluation of a 11C‐labelled angiotensin II AT2 receptor ligand

Three ¹¹C‐radiolabelled high‐affinity nonpeptide AT₂ receptor‐selective ligands were synthesized and one of these was evaluated as positron emission tomography (PET) tracer. The labelling reaction was performed via palladium(0)‐mediated aminocarbonylation of the aryl iodide substrate using [¹¹C]carbon monoxide as the labelled precursor. As an example, starting with 10.0 GBq [¹¹C]carbon monoxide, 1.10 GBq of the product N‐butoxycarbonyl‐3‐[4‐(N‐benzyl‐[¹¹C]carbamoyl)‐phenyl]‐5‐isobutylthiophene‐2‐sulphonamide [¹¹C]4d was obtained in 36% decay‐corrected radiochemical yield (from [¹¹C]carbon monoxide), 42 min from end of bombardment with a specific activity of 110 GBq·µmol^?1. The N‐isopropyl‐[¹¹C]carbamoyl‐analogue [¹¹C]4c (radiochemical purity >95%) was studied employing autoradiography, organ distribution, and small animal PET. In vitro autoradiography showed specific binding in the pancreas and kidney. Organ distribution in six rats revealed a high uptake in the liver, intestine, kidney, and adrenals. Small animal PET showed rapid and reversible uptake in the kidneys followed by accumulation in the urinary bladder suggesting fast renal excretion of the tracer. In addition, high accumulation was also seen in the liver. For future studies, more metabolically stable tracers will need to be developed. To the best of our knowledge, this is the first attempt of the use of PET imaging for the detection of expressed, fully functional AT₂ receptors in living subjects. Copyright © 2010 John Wiley & Sons, Ltd.     

Synthesis of N‐(2,5‐dimethoxybenzyl)‐N‐(5‐fluoro‐2‐phenoxyphenyl)[carbonyl‐11C]acetamide ([carbonyl‐11C]DAA1106) and analogues using [11C]carbon monoxide and palladium(0) complex

N‐(2,5‐Dimethoxybenzyl)‐N‐(5‐fluoro‐2‐phenoxyphenyl)acetamide (DAA1106), a potent and selective ligand for peripheral benzodiazepine receptor, and eight structurally related analogues were labelled with ¹¹C at the carbonyl position using a low concentration of [¹¹C]carbon monoxide and the micro‐autoclave technique. A combinatorial approach was applied to synthesize the analogues using similar reaction conditions. Palladium‐mediated carbonylation using tetrakis(triphenylphosphine)palladium, various amines and methyl iodide or iodobenzene was employed in the synthesis. The ¹¹C‐labelled products were obtained with 10–55% decay‐corrected radiochemical yields and the final product was more than 97% pure in all cases. Specific radioactivity was determined for the compound [carbonyl‐¹¹C]DAA1106 using a single experiment and a 10‐µA h bombardment. The specific radioactivity, measured 36 min after end of bombardment, was 455 GBq/µmol. Synthetic routes to the precursors and reference compounds were also developed. The presented approach is a novel method for the synthesis of [carbonyl‐¹¹C]DAA1106 and its analogues, and allows the formation of a library of ¹¹C‐labelled DAA1106 analogues which can be used to optimize the performance as a potential positron emission tomography tracer. Copyright © 2007 John Wiley & Sons, Ltd.     

Efficient syntheses of [11C]zidovudine and its analogs by convenient one‐pot palladium(0)–copper(I) co‐mediated rapid C‐[11C]methylation

The nucleosides zidovudine (AZT), stavudine (d4T), and telbivudine (LdT) are approved for use in the treatment of human immunodeficiency virus (HIV) and hepatitis B virus (HBV) infections. To promote positron emission tomography (PET) imaging studies on their pharmacokinetics, pharmacodynamics, and applications in cancer diagnosis, a convenient one‐pot method for Pd(0)–Cu(I) co‐mediated rapid C–C coupling of [¹¹C]methyl iodide with stannyl precursor was successfully established and applied to synthesize the PET tracers [¹¹C]zidovudine, [¹¹C]stavudine, and [¹¹C]telbivudine. After HPLC purification and radiopharmaceutical formulation, the desired PET tracers were obtained with high radioactivity (6.4–7.0 GBq) and specific radioactivity (74–147 GBq/µmol) and with high chemical (>99%) and radiochemical (>99.5%) purities. This one‐pot Pd(0)–Cu(I) co‐mediated rapid C‐[¹¹C]methylation also worked well for syntheses of [methyl‐¹¹C]thymidine and [methyl‐¹¹C]4′‐thiothymidine, resulting twice the radioactivity of those prepared by a previous two‐pot method. The mechanism of one‐pot Pd(0)–Cu(I) co‐mediated rapid C‐[¹¹C]methylation was also discussed.     

Synthesis and evaluation of [11C]RU40555, a selective glucocorticoid receptor antagonist

We demonstrated the synthesis of carbon‐11 labeled 17‐α‐hydroxy‐11‐β‐/4‐/[methyl]‐[1‐methylethyl]‐aminophenyl/‐17α‐[prop‐1‐ynyl]esta‐4‐9‐diene‐3‐one (RU40555), a selective glucocorticoid receptor (GR) antagonist, and examined the in vivo profile of [¹¹C]RU40555. [¹¹C]RU40555 was synthesized by direct N‐methylation with [¹¹C]CH₃OTf at 60°C for 5 min and an injectable solution of [¹¹C]RU40555 was obtained in 31 min at the end of bombardment. The decay‐corrected radiochemical yield was 19%, the specific radioactivity was 57.5±14.0 GBq/µmol, and the radiochemical purity was more than 99% as determined by HPLC. In rat experiments, the effects of adrenalectomy (ADX) on brain accumulation of [¹¹C]RU40555 were examined. ADX significantly decreased plasma corticosterone levels, and significantly increased brain accumulation of [¹¹C]RU40555. We succeeded in developing a rapid automated synthesis method for [¹¹C]RU40555, a GR antagonist, and showed [¹¹C]RU40555 had a potential as a PET tracer for mapping GR. Copyright © 2005 John Wiley & Sons, Ltd.     

A new approach for 11C–C bond formation: Synthesis of 17α‐(3′‐[11C]prop‐1‐yn‐1‐yl)‐3‐methoxy‐3,17β‐estradiol

A new approach for ¹¹C–C bond formation via a Sonogashira‐like cross‐coupling reaction of terminal alkynes with [¹¹C]methyl iodide was exemplified by the synthesis of 17α‐(3′‐[¹¹C]prop‐1‐yn‐1‐yl)‐3‐methoxy‐3,17β‐estradiol. The LC‐purified title compound was obtained in decay‐corrected radiochemical yields of 27–47% (n=8) based on [¹¹C]methyl iodide within 21–27 min after EOB. In a typical synthesis starting from 9.6 GBq [¹¹C]methyl iodide, 1.87 GBq of 17α‐(3′‐[¹¹C]prop‐1‐yn‐1‐yl)‐3‐methoxy‐3,17β‐estradiol was synthesized in radiochemical purity >99%. The specific radioactivity ranged between 10 and 19 GBq/µmol, and the labeling position was verified by ¹³C‐NMR analysis of the corresponding ¹³C‐labeled compound. Copyright © 2003 John Wiley & Sons, Ltd.     

Synthesis of 1,1′ [11C]‐methylene‐di‐(2‐naphthol) ([11C]ST1859) for PET studies in humans

1,1′‐Methylene‐di‐(2‐naphthol) (ST1859), a candidate drug for the treatment of Alzheimer's disease, was radiolabelled with carbon‐11 with the aim to perform PET microdosing studies in humans. The radiosynthesis was automated in a commercial synthesis module (Nuclear Interface PET tracer synthesizer) and proceeded via reaction of [¹¹C]formaldehyde with 2‐naphthol. [¹¹C]formaldehyde was prepared by catalytic dehydrogenation of [¹¹C]methanol (conversion yield: 48±11% (n = 19)) employing a recently developed silver‐containing ceramic catalyst. Starting from 69±3 GBq of [¹¹C]carbon dioxide (n = 19), 4±1 GBq of [¹¹C]ST1859 (decay‐corrected to the end of bombardment), readily formulated for intravenous administration, could be obtained in an average synthesis time of 38 min. The specific radioactivity of [¹¹C]ST1859 at the end of synthesis exceeded 32 GBq/µmol. Copyright © 2005 John Wiley & Sons, Ltd.     

Radiosynthesis of 1‐iodo‐2‐[11C]methylpropane and 2‐methyl‐1‐[11C]propanol and its application for alkylation reactions and C―C bond formation

The multitude of biologically active compounds requires the availability of a broad spectrum of radiolabeled synthons for the development of positron emission tomography (PET) tracers. The aim of this study was to synthesize 1‐iodo‐2‐[¹¹C]methylpropane and 2‐methyl‐1‐[¹¹C]propanol and investigate the use of these reagents in further radiosynthesis reactions. 2‐Methyl‐1‐[¹¹C]propanol was obtained with an average radiochemical yield of 46 ± 6% d.c. and used with fluorobenzene as starting material. High conversion rates of 85 ± 4% d.c. could be observed with HPLC, but large precursor amounts (32 mg, 333 μmol) were needed. 1‐Iodo‐2‐[¹¹C]methylpropane was synthesized with a radiochemical yield of 25 ± 7% d.c. and with a radiochemical purity of 78 ± 7% d.c. The labelling agent 1‐iodo‐2‐[¹¹C]methylpropane was coupled to thiophenol, phenol and phenylmagnesium bromide. Average radiochemical conversions of 83% d.c. for thiophenol, 40% d.c. for phenol, and 60% d.c. for phenylmagnesium bromide were obtained. In addition, [¹¹C]2‐methyl‐1‐propyl phenyl sulphide was isolated with a radiochemical yield of 5 ± 1% d.c. and a molar activity of 346 ± 113 GBq/μmol at the end of synthesis. Altogether, the syntheses of 1‐iodo‐2‐[¹¹C]methylpropane and 2‐methyl‐1‐[¹¹C]propanol were achieved and applied as proof of their applicability.     

Reduction of [11C]CO2 to [11C]CO using solid supported zinc

A new method for the reduction of no‐carrier‐added [¹¹C]carbon dioxide into [¹¹C]carbon monoxide ([¹¹C]CO) is described, in which the reductant (zinc) is supported on fused silica particles. Using this setup, which allows for a reduction temperature (485°C) well above the melting point for zinc (420°C), radiochemical yields of up to 96% (decay‐corrected) were obtained. A slight decrease in radiochemical yield was observed upon repeated [¹¹C]CO productions (93 ± 3%, n  = 20). The methodology is convenient and efficient and provides a straightforward path to no‐carrier‐added production of [¹¹C]CO.     

Exploration of the labeling of [11C]tubastatin A at the hydroxamic acid site with [11C]carbon monoxide

We aimed to label tubastatin A (1) with carbon‐11 (t_1/2 = 20.4 min) in the hydroxamic acid site to provide a potential radiotracer for imaging histone deacetylase 6 in vivo with positron emission tomography. Initial attempts at a one‐pot Pd‐mediated insertion of [¹¹C]carbon monoxide between the aryl iodide (2) and hydroxylamine gave low radiochemical yields (<5%) of [¹¹C]1. Labeling was achieved in useful radiochemical yields (16.1 ± 5.6%, n = 4) through a two‐step process based on Pd‐mediated insertion of [¹¹C]carbon monoxide between the aryl iodide (2) and p‐nitrophenol to give the [¹¹C]p‐nitrophenyl ester ([¹¹C]5), followed by ultrasound‐assisted hydroxyaminolysis of the activated ester with excess hydroxylamine in a DMSO/THF mixture in the presence of a strong phosphazene base P₁‐t‐Bu. However, success in labeling the hydroxamic acid group of [¹¹C]tubastatin A was not transferable to the labeling of three other model hydroxamic acids.     

Synthesis of 1‐(2′‐deoxy‐2′‐fluoro‐β‐D‐arabinofuranosyl)‐[Methyl‐11C]thymine ([11C]FMAU) via a Stille cross‐coupling reaction with [11C]methyl iodide

1‐(2′‐deoxy‐2′‐fluoro‐β‐D‐arabinofuranosyl)‐[methyl‐¹¹C]thymine ([¹¹C]FMAU) [¹¹C]‐ 1 was synthesised via a palladium‐mediated Stille coupling reaction of 1‐(2′‐deoxy‐2′‐fluoro‐β‐D‐arabinofuranosyl)‐5‐(trimethylstannyl)uracil 2 with [¹¹C]methyl iodide in a one‐pot procedure. The reaction conditions were optimized by screening various catalysts and solvents, and by altering concentrations and reaction temperatures. The highest yield was obtained using Pd₂(dba)₃ and P(o‐tolyl)₃ in DMF at 130°C for 5 min. Under these conditions the title compound [¹¹C]‐ 1 was obtained in 28±5% decay‐corrected radiochemical yield calculated from [¹¹C]methyl iodide (number of experiments=7). The radiochemical purity was >99% and the specific radioactivity was 0.1 GBq/μmol at 25 min after end of bombardment. In a typical experiment 700–800 MBq of [¹¹C]FMAU [¹¹C]‐ 1 was obtained starting from 6–7 GBq of [¹¹C]methyl iodide. A mixed ¹¹C/¹³C synthesis to yield [¹¹C]‐ 1 /(¹³C)‐ 1 followed by ¹³C‐NMR analysis was used to confirm the labelling position. The labelling procedure was found to be suitable for automation. Copyright © 2002 John Wiley & Sons, Ltd.